$NOMOD51 ;**** **** **** **** **** ; ; BLHeli program for controlling brushless motors in helicopters and multirotors ; ; Copyright 2011, 2012 Steffen Skaug ; This program is distributed under the terms of the GNU General Public License ; ; This file is part of BLHeli. ; ; BLHeli is free software: you can redistribute it and/or modify ; it under the terms of the GNU General Public License as published by ; the Free Software Foundation, either version 3 of the License, or ; (at your option) any later version. ; ; BLHeli is distributed in the hope that it will be useful, ; but WITHOUT ANY WARRANTY; without even the implied warranty of ; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ; GNU General Public License for more details. ; ; You should have received a copy of the GNU General Public License ; along with BLHeli. If not, see . ; ;**** **** **** **** **** ; ; The software was initially designed for use with Eflite mCP X, but is now adapted to copters/planes in general ; ; The software was inspired by and started from from Bernard Konze's BLMC: http://home.versanet.de/~bkonze/blc_6a/blc_6a.htm ; And also Simon Kirby's TGY: https://github.com/sim-/tgy ; ; This file is best viewed with tab width set to 5 ; ; The input signal can be positive 1kHz, 2kHz, 4kHz, 8kHz or 12kHz PWM (e.g. taken from the "resistor tap" on mCPx) ; And the input signal can be PPM (1-2ms) or OneShot125 (125-250us) at rates up to several hundred Hz. ; The code autodetects the various input modes/frequencies ; The code can also be programmed to accept inverted input signal. ; ; The first lines of the software must be modified according to the chosen environment: ; Uncomment the selected ESC and main/tail/multi mode ; BESCNO EQU "ESC"_"mode" ; ;**** **** **** **** **** ; Revision history: ; - Rev1.0: Initial revision based upon BLHeli for AVR controllers ; - Rev2.0: Changed "Eeprom" initialization, layout and defaults ; Various changes and improvements to comparator reading. Now using timer1 for time from pwm on/off ; Beeps are made louder ; Added programmable low voltage limit ; Added programmable damped tail mode (only for 1S ESCs) ; Added programmable motor rotation direction ; - Rev2.1: (minor changes by 4712) ; Added Disable TX Programming by PC Setup Application ; therfore changed EEPROM_LAYOUT_REVISION = 8 ; Added Vdd Monitor as reset source when writing to "EEProm" ; Changed for use of batch file to assemble, link and make hex files ; - Rev2.2: (minor changes by 4712) ; Added Disable Throttle Re-Arming every motor start by PC Setup Application ; - Rev2.3: (minor changes by 4712) ; Added bugfixed (2x CLR C before j(n)c operations)thx Steffen! ; - Rev2.4: Revisions 2.1 to 2.3 integrated ; - Rev3.0: Added PPM (1050us-1866us) as accepted input signal ; Added startup rpm as a programming parameter ; Added startup acceleration as a programming parameter ; Added option for using voltage measurements to compensate motor power ; Added governor target by setup as a governor mode option ; Governor is kept active regardless of rpm ; Smooth governor spoolup/down in arm and setup modes ; Increased governor P and I gain programming ranges ; Increased and changed low voltage limit programming range ; Disabled tx programming entry for all but the first arming sequence after power on ; Made it possible to skip parameters in tx programming by setting throttle midstick ; Made it default not to rearm for every restart ; - Rev3.1: Fixed bug that prevented chosen parameter to be set in tx programming ; - Rev3.2: ...also updated the EEPROM revision parameter ; - Rev3.3: Fixed negative number bug in voltage compensation ; Fixed bug in startup power calculation for non-default power ; Prevented possibility for voltage compensation fighting low voltage limiting ; Applied overall spoolup control to ensure soft spoolup in any mode ; Added a delay of 3 seconds from initiation of main motor stop until new startup is allowed ; Reduced beep power to reduce power consumption for very strong motors/ESCs ; - Rev3.4: Fixed bug that prevented full power in governor arm and setup modes ; Increased NFETON_DELAY for XP_7A and XP_12A to allow for more powerful fets ; Increased initial spoolup power, and linked to startup power ; - Rev4.0: Fixed bug that made tail tx program beeps very weak ; Added thermal protection feature ; Governor P and I gain ranges are extended up to 8.0x gain ; Startup sequence is aborted upon zero throttle ; Avoided voltage compensation function induced latency for tail when voltage compensation is not enabled ; Improved input signal frequency detection robustness ; - Rev4.1: Increased thermal protection temperature limits ; - Rev5.0: Added multi(copter) operating mode. TAIL define changed to MODE with three modes: MAIN, TAIL and MULTI ; Added programmable commutation timing ; Added a damped light mode that has less damping, but that can be used with all escs ; Added programmable damping force ; Added thermal protection for startup too ; Added wait beeps when waiting more than 30 sec for throttle above zero (after having been armed) ; Modified tail idling to provide option for very low speeds ; Changed PPM range to 1150-1830us ; Arming sequence is dropped for PPM input, unless it is governor arm mode ; Loss of input signal will immediately stop the motor for PPM input ; Bug corrected in Turnigy Plush 6A voltage measurement setup ; FET switching delays are set for original fets. Stronger/doubled/tripled etc fets may require faster pfet off switching ; Miscellaneous other changes ; - Rev6.0: Reverted comparator reading routine to rev5.0 equivalent, in order to avoid tail motor stops ; Added governor range programmability ; Implemented startup retry sequence with varying startup power for multi mode ; In damped light mode, damping is now applied to the active nfet phase for fully damped capable ESCs ; - Rev6.1: Added input signal qualification criteria for PPM, to avoid triggering on noise spikes (fix for plush hardware) ; Changed main and multi mode stop criteria. Will now be in run mode, even if RC pulse input is zero ; Fixed bug in commutation that caused rough running in damped light mode ; Miscellaneous other changes ; - Rev7.0 Added direct startup mode programmability ; Added throttle calibration. Min>=1000us and Max<=2000us. Difference must be >520us, otherwise max is shifted so that difference=520us ; Added programmable throttle change rate ; Added programmable beep strength, beacon strength and beacon delay ; Reduced power step to full power significantly ; Miscellaneous other changes ; - Rev8.0 Added a 2 second delay after power up, to wait for receiver initialization ; Added a programming option for disabling low voltage limit, and made it default for MULTI ; Added programable demag compensation, using the concept of SimonK ; Improved robustness against noisy input signal ; Refined direct startup ; Removed voltage compensation ; Miscellaneous other changes ; - Rev9.0 Increased programming range for startup power, and made its default ESC dependent ; Made default startup method ESC dependent ; Even more smooth and gentle spoolup for MAIN, to suit larger helis ; Improved transition from stepped startup to run ; Refined direct startup ; - Rev9.1 Fixed bug that changed FW revision after throttle calibration or TX programming ; - Rev9.2 Altered timing of throttle calibration in order to work with MultiWii calibration firmware ; Reduced main spoolup time to around 5 seconds ; Changed default beacon delay to 3 minutes ; - Rev9.3 Fixed bug in Plush 60/80A temperature reading, that caused failure in operation above 4S ; Corrected temperature limit for HiModel cool 22/33/41A, RCTimer 6A, Skywalker 20/40A, Turnigy AE45A, Plush 40/60/80A. Limit was previously set too high ; - Rev9.4 Improved timing for increased maximum rpm limit ; - Rev10.0 Added closed loop mode for multi ; Added high/low BEC voltage option (for the ESCs where HW supports it) ; Added method of resetting all programmed parameter values to defaults by TX programming ; Added Turnigy K-force 40A and Turnigy K-force 120A HV ESCs ; Enabled fully damped mode for several ESCs ; Extended startup power range downwards to enable very smooth start for large heli main motors ; Extended damping force with a highest setting ; Corrected temperature limits for F310 chips (Plush 40A and AE 45A) ; Implemented temperature reading average in order to avoid problems with ADC noise on Skywalkers ; Increased switching delays for XP 7A fast, in order to avoid cross conduction of N and P fets ; Miscellaneous other changes ; - Rev10.1 Relaxed RC signal jitter requirement during frequency measurement ; Corrected bug that prevented using governor low ; Enabled vdd monitor always, in order to reduce likelihood of accidental overwriting of adjustments ; Fixed bug that caused stop for PPM input above 2048us, and moved upper accepted limit to 2160us ; - Rev10.2 Corrected temperature limit for AE20-30/XP7-25, where limit was too high ; Corrected temperature limit for 120HV, where limit was too low ; Fixed bug that caused AE20/25/30A not to run in reverse ; - Rev10.3 Removed vdd monitor for 1S capable ESCs, in order to avoid brownouts/resets ; Made auto bailout spoolup for main more smooth ; - Rev10.4 Ensured that main spoolup and governor activation will always be smooth, regardless of throttle input ; Added capability to operate on 12kHz input signal too ; - Rev11.0 Fixed bug of programming default values for governor in MULTI mode ; Disabled interrupts explicitly some places, to avoid possibilities for unintentional fet switching ; Changed interrupt disable strategy, to always allow pwm interrupts, to avoid noise when running at low rpms ; Added governor middle range for MAIN mode ; Added bidirectional mode for TAIL and MULTI mode with PPM input ; Changed and improved demag compensation ; Miscellaneous other changes ; - Rev11.1 Fixed bug of slow acceleration response for MAIN mode running without governor ; Fixed bug with PWM input, where throttle remains high even when zeroing throttle (seen on V922 tail) ; Fixed bug in bidirectional operation, where direction change could cause reset ; Improved autorotation bailout for MAIN ; Reduced min speed back to 1220 erpm ; Misc code cleanups ; - Rev11.2 Fixed throttle calibration bug ; Added high side driver precharge for all-nfet ESCs ; Optimized timing in general and for demag compensation in particular ; Auto bailout functionality modified ; Governor is deactivated for throttle inputs below 10% ; Increased beacon delay times ; - Rev12.0 Added programmable main spoolup time ; Added programmable temperature protection enable ; Bidirectional mode stop/start improved. Motor is now stopped before starting ; Power is limited for very low rpms (when BEMF is low), in order to avoid sync loss ; Damped light mode is made more smooth and quiet, particularly at low and high rpms ; Comparator signal qualification scheme is changed ; Demag compensation scheme is significantly changed ; Increased jitter tolerance for PPM frequency measurement ; Fully damped mode removed, and damped light only supported on damped capable ESCs ; Default tail mode changed to damped light ; Miscellaneous other changes ; - Rev12.1 Fixed bug in tail code ; Improved startup for Atmel ; Added support for multiple high BEC voltages ; Added support for RPM output ; - Rev12.2 Improved running smoothness, particularly for damped light ; Avoiding lockup at full throttle when input signal is noisy ; Avoiding detection of 1-wire programming signal as valid throttle signal ; - Rev13.0 Removed stepped start ; Removed throttle change rate and damping force parameters ; Added support for OneShot125 ; Improved commutation timing accuracy ; - Rev13.1 Removed startup ramp for MULTI ; Improved startup for some odd ESCs ; - Rev13.2 Still tweaking startup to make it more reliable and faster for all ESC/motor combos ; Increased deadband for bidirectional operation ; Relaxed signal detection criteria ; Added support for running 48MHz capable SiLabs MCUs at 48MHz ; Added bootlader to SiLabs code ; Miscellaneous other changes ; - Rev14.0 Improved running at high timing ; Improved running at high RPMs and increased max RPM limit ; Avoid being locked in bootloader (implemented in Suite 13202) ; Improved reliability of 3D (bidirectional) mode and startup ; Smoother running and greatly reduced step to full power in damped light mode ; Removed low voltage limiting for MULTI ; Added pwm dither parameter ; Added setting for enable/disable of low RPM power protection ; Added setting for enable/disable of PWM input ; Better AFW and damping for some ESCs (that have a slow high side driver) ; Miscellaneous other changes ; - Rev14.1 Fixed max throttle calibration bug (for non-oneshot) ; Fixed some closed loop mode bugs ; Relaxed signal jitter requirement for looptimes below 1000 ; Added skipping of damping fet switching near max power, for improved high end throttle linearity, using the concept of SimonK ; Improved sync hold at high rpms ; - Rev14.2 Added stalled motor shutoff after about 10 seconds (for tail and multi code with PPM input) ; Greatly increased maximum rpm limit, and added rpm limiting at 250k erpm (48MHz MCUs at 400k erpm) ; Improved bidirectional operation ; - Rev14.3 Moved reset vector to be just before the settings segment, in order to better recover from partially failed flashing operation ; Added 100ms intialization delay for the Graupner Ultra 20A ESC ; Shortened stall detect time to about 5sec, and prevented going into tx programming after a stall ; Optimizations of software timing and running reliability ; - Rev14.4 Improved startup, particularly for larger motors ; Improved running at very high rpms ; Made damped light default for MULTI on ESCs that support it ; Miscellaneous other changes ; ; ;**** **** **** **** **** ; Up to 8K Bytes of In-System Self-Programmable Flash ; Up to 768 Bytes Internal SRAM ; ;**** **** **** **** **** ; Master clock is internal 24MHz oscillator (or 48MHz, for which the times below are halved) ; Timer 0 (167/500ns counts) always counts up and is used for ; - PWM generation ; Timer 1 (167/500ns counts) always counts up and is used for ; - Time from pwm on/off event ; Timer 2 (500ns counts) always counts up and is used for ; - RC pulse timeout/skip counts and commutation times ; Timer 3 (500ns counts) always counts up and is used for ; - Commutation timeouts ; PCA0 (500ns counts) always counts up and is used for ; - RC pulse measurement ; ;**** **** **** **** **** ; Interrupt handling ; The C8051 does not disable interrupts when entering an interrupt routine. ; Also some interrupt flags need to be cleared by software ; The code disables interrupts in interrupt routines, in order to avoid too nested interrupts ; - Interrupts are disabled during beeps, to avoid audible interference from interrupts ; - RC pulse interrupts are periodically disabled in order to reduce interference with pwm interrupts. ; ;**** **** **** **** **** ; Motor control: ; - Brushless motor control with 6 states for each electrical 360 degrees ; - An advance timing of 0deg has zero cross 30deg after one commutation and 30deg before the next ; - Timing advance in this implementation is set to 15deg nominally ; - "Damped" commutation schemes are available, where more than one pfet is on when pwm is off. This will absorb energy from bemf and make step settling more damped. ; Motor sequence starting from zero crossing: ; - Timer wait: Wt_Comm 15deg ; Time to wait from zero cross to actual commutation ; - Timer wait: Wt_Advance 15deg ; Time to wait for timing advance. Nominal commutation point is after this ; - Timer wait: Wt_Zc_Scan 7.5deg ; Time to wait before looking for zero cross ; - Scan for zero cross 22.5deg , Nominal, with some motor variations ; ; Motor startup: ; There is a startup phase and an initial run phase, before normal bemf commutation run begins. ; ;**** **** **** **** **** ; List of enumerated supported ESCs and modes (main, tail or multi) XP_3A_Main EQU 1 XP_3A_Tail EQU 2 XP_3A_Multi EQU 3 XP_7A_Main EQU 4 XP_7A_Tail EQU 5 XP_7A_Multi EQU 6 XP_7A_Fast_Main EQU 7 XP_7A_Fast_Tail EQU 8 XP_7A_Fast_Multi EQU 9 XP_12A_Main EQU 10 XP_12A_Tail EQU 11 XP_12A_Multi EQU 12 XP_18A_Main EQU 13 XP_18A_Tail EQU 14 XP_18A_Multi EQU 15 XP_25A_Main EQU 16 XP_25A_Tail EQU 17 XP_25A_Multi EQU 18 XP_35A_SW_Main EQU 19 XP_35A_SW_Tail EQU 20 XP_35A_SW_Multi EQU 21 DP_3A_Main EQU 22 DP_3A_Tail EQU 23 DP_3A_Multi EQU 24 Supermicro_3p5A_Main EQU 25 Supermicro_3p5A_Tail EQU 26 Supermicro_3p5A_Multi EQU 27 Turnigy_Plush_6A_Main EQU 28 Turnigy_Plush_6A_Tail EQU 29 Turnigy_Plush_6A_Multi EQU 30 Turnigy_Plush_10A_Main EQU 31 Turnigy_Plush_10A_Tail EQU 32 Turnigy_Plush_10A_Multi EQU 33 Turnigy_Plush_12A_Main EQU 34 Turnigy_Plush_12A_Tail EQU 35 Turnigy_Plush_12A_Multi EQU 36 Turnigy_Plush_18A_Main EQU 37 Turnigy_Plush_18A_Tail EQU 38 Turnigy_Plush_18A_Multi EQU 39 Turnigy_Plush_25A_Main EQU 40 Turnigy_Plush_25A_Tail EQU 41 Turnigy_Plush_25A_Multi EQU 42 Turnigy_Plush_30A_Main EQU 43 Turnigy_Plush_30A_Tail EQU 44 Turnigy_Plush_30A_Multi EQU 45 Turnigy_Plush_40A_Main EQU 46 Turnigy_Plush_40A_Tail EQU 47 Turnigy_Plush_40A_Multi EQU 48 Turnigy_Plush_60A_Main EQU 49 Turnigy_Plush_60A_Tail EQU 50 Turnigy_Plush_60A_Multi EQU 51 Turnigy_Plush_80A_Main EQU 52 Turnigy_Plush_80A_Tail EQU 53 Turnigy_Plush_80A_Multi EQU 54 Turnigy_Plush_Nfet_18A_Main EQU 55 Turnigy_Plush_Nfet_18A_Tail EQU 56 Turnigy_Plush_Nfet_18A_Multi EQU 57 Turnigy_Plush_Nfet_25A_Main EQU 58 Turnigy_Plush_Nfet_25A_Tail EQU 59 Turnigy_Plush_Nfet_25A_Multi EQU 60 Turnigy_Plush_Nfet_30A_Main EQU 61 Turnigy_Plush_Nfet_30A_Tail EQU 62 Turnigy_Plush_Nfet_30A_Multi EQU 63 Turnigy_AE_20A_Main EQU 64 Turnigy_AE_20A_Tail EQU 65 Turnigy_AE_20A_Multi EQU 66 Turnigy_AE_25A_Main EQU 67 Turnigy_AE_25A_Tail EQU 68 Turnigy_AE_25A_Multi EQU 69 Turnigy_AE_30A_Main EQU 70 Turnigy_AE_30A_Tail EQU 71 Turnigy_AE_30A_Multi EQU 72 Turnigy_AE_45A_Main EQU 73 Turnigy_AE_45A_Tail EQU 74 Turnigy_AE_45A_Multi EQU 75 Turnigy_KForce_40A_Main EQU 76 Turnigy_KForce_40A_Tail EQU 77 Turnigy_KForce_40A_Multi EQU 78 Turnigy_KForce_70A_HV_Main EQU 79 Turnigy_KForce_70A_HV_Tail EQU 80 Turnigy_KForce_70A_HV_Multi EQU 81 Turnigy_KForce_120A_HV_Main EQU 82 Turnigy_KForce_120A_HV_Tail EQU 83 Turnigy_KForce_120A_HV_Multi EQU 84 Turnigy_KForce_120A_HV_v2_Main EQU 85 Turnigy_KForce_120A_HV_v2_Tail EQU 86 Turnigy_KForce_120A_HV_v2_Multi EQU 87 Skywalker_20A_Main EQU 88 Skywalker_20A_Tail EQU 89 Skywalker_20A_Multi EQU 90 Skywalker_40A_Main EQU 91 Skywalker_40A_Tail EQU 92 Skywalker_40A_Multi EQU 93 HiModel_Cool_22A_Main EQU 94 HiModel_Cool_22A_Tail EQU 95 HiModel_Cool_22A_Multi EQU 96 HiModel_Cool_33A_Main EQU 97 HiModel_Cool_33A_Tail EQU 98 HiModel_Cool_33A_Multi EQU 99 HiModel_Cool_41A_Main EQU 100 HiModel_Cool_41A_Tail EQU 101 HiModel_Cool_41A_Multi EQU 102 RCTimer_6A_Main EQU 103 RCTimer_6A_Tail EQU 104 RCTimer_6A_Multi EQU 105 Align_RCE_BL15X_Main EQU 106 Align_RCE_BL15X_Tail EQU 107 Align_RCE_BL15X_Multi EQU 108 Align_RCE_BL15P_Main EQU 109 Align_RCE_BL15P_Tail EQU 110 Align_RCE_BL15P_Multi EQU 111 Align_RCE_BL35X_Main EQU 112 Align_RCE_BL35X_Tail EQU 113 Align_RCE_BL35X_Multi EQU 114 Align_RCE_BL35P_Main EQU 115 Align_RCE_BL35P_Tail EQU 116 Align_RCE_BL35P_Multi EQU 117 Gaui_GE_183_18A_Main EQU 118 Gaui_GE_183_18A_Tail EQU 119 Gaui_GE_183_18A_Multi EQU 120 H_King_10A_Main EQU 121 H_King_10A_Tail EQU 122 H_King_10A_Multi EQU 123 H_King_20A_Main EQU 124 H_King_20A_Tail EQU 125 H_King_20A_Multi EQU 126 H_King_35A_Main EQU 127 H_King_35A_Tail EQU 128 H_King_35A_Multi EQU 129 H_King_50A_Main EQU 130 H_King_50A_Tail EQU 131 H_King_50A_Multi EQU 132 Polaris_Thunder_12A_Main EQU 133 Polaris_Thunder_12A_Tail EQU 134 Polaris_Thunder_12A_Multi EQU 135 Polaris_Thunder_20A_Main EQU 136 Polaris_Thunder_20A_Tail EQU 137 Polaris_Thunder_20A_Multi EQU 138 Polaris_Thunder_30A_Main EQU 139 Polaris_Thunder_30A_Tail EQU 140 Polaris_Thunder_30A_Multi EQU 141 Polaris_Thunder_40A_Main EQU 142 Polaris_Thunder_40A_Tail EQU 143 Polaris_Thunder_40A_Multi EQU 144 Polaris_Thunder_60A_Main EQU 145 Polaris_Thunder_60A_Tail EQU 146 Polaris_Thunder_60A_Multi EQU 147 Polaris_Thunder_80A_Main EQU 148 Polaris_Thunder_80A_Tail EQU 149 Polaris_Thunder_80A_Multi EQU 150 Polaris_Thunder_100A_Main EQU 151 Polaris_Thunder_100A_Tail EQU 152 Polaris_Thunder_100A_Multi EQU 153 Platinum_Pro_30A_Main EQU 154 Platinum_Pro_30A_Tail EQU 155 Platinum_Pro_30A_Multi EQU 156 Platinum_Pro_150A_Main EQU 157 Platinum_Pro_150A_Tail EQU 158 Platinum_Pro_150A_Multi EQU 159 Platinum_50Av3_Main EQU 160 Platinum_50Av3_Tail EQU 161 Platinum_50Av3_Multi EQU 162 EAZY_3Av2_Main EQU 163 EAZY_3Av2_Tail EQU 164 EAZY_3Av2_Multi EQU 165 Tarot_30A_Main EQU 166 Tarot_30A_Tail EQU 167 Tarot_30A_Multi EQU 168 SkyIII_30A_Main EQU 169 SkyIII_30A_Tail EQU 170 SkyIII_30A_Multi EQU 171 EMAX_20A_Main EQU 172 EMAX_20A_Tail EQU 173 EMAX_20A_Multi EQU 174 EMAX_40A_Main EQU 175 EMAX_40A_Tail EQU 176 EMAX_40A_Multi EQU 177 EMAX_Nano_20A_Main EQU 178 EMAX_Nano_20A_Tail EQU 179 EMAX_Nano_20A_Multi EQU 180 XRotor_10A_Main EQU 181 XRotor_10A_Tail EQU 182 XRotor_10A_Multi EQU 183 XRotor_20A_Main EQU 184 XRotor_20A_Tail EQU 185 XRotor_20A_Multi EQU 186 XRotor_40A_Main EQU 187 XRotor_40A_Tail EQU 188 XRotor_40A_Multi EQU 189 MDRX62H_Main EQU 190 MDRX62H_Tail EQU 191 MDRX62H_Multi EQU 192 RotorGeeks_20A_Main EQU 193 RotorGeeks_20A_Tail EQU 194 RotorGeeks_20A_Multi EQU 195 Flycolor_Fairy_6A_Main EQU 196 Flycolor_Fairy_6A_Tail EQU 197 Flycolor_Fairy_6A_Multi EQU 198 Flycolor_Fairy_30A_Main EQU 199 Flycolor_Fairy_30A_Tail EQU 200 Flycolor_Fairy_30A_Multi EQU 201 Flycolor_Raptor_20A_Main EQU 202 Flycolor_Raptor_20A_Tail EQU 203 Flycolor_Raptor_20A_Multi EQU 204 Flycolor_Raptor_390_20A_Main EQU 205 Flycolor_Raptor_390_20A_Tail EQU 206 Flycolor_Raptor_390_20A_Multi EQU 207 FVT_Littlebee_20A_Main EQU 208 FVT_Littlebee_20A_Tail EQU 209 FVT_Littlebee_20A_Multi EQU 210 FVT_Littlebee_20A_Pro_Main EQU 211 FVT_Littlebee_20A_Pro_Tail EQU 212 FVT_Littlebee_20A_Pro_Multi EQU 213 FVT_Littlebee_30A_Main EQU 214 FVT_Littlebee_30A_Tail EQU 215 FVT_Littlebee_30A_Multi EQU 216 Graupner_Ultra_20A_Main EQU 217 Graupner_Ultra_20A_Tail EQU 218 Graupner_Ultra_20A_Multi EQU 219 F85_3A_Main EQU 220 F85_3A_Tail EQU 221 F85_3A_Multi EQU 222 ZTW_Spider_Pro_20A_Main EQU 223 ZTW_Spider_Pro_20A_Tail EQU 224 ZTW_Spider_Pro_20A_Multi EQU 225 ZTW_Spider_Pro_20A_Premium_Main EQU 226 ZTW_Spider_Pro_20A_Premium_Tail EQU 227 ZTW_Spider_Pro_20A_Premium_Multi EQU 228 ZTW_Spider_Pro_20A_HV_Main EQU 229 ZTW_Spider_Pro_20A_HV_Tail EQU 230 ZTW_Spider_Pro_20A_HV_Multi EQU 231 ZTW_Spider_Pro_30A_HV_Main EQU 232 ZTW_Spider_Pro_30A_HV_Tail EQU 233 ZTW_Spider_Pro_30A_HV_Multi EQU 234 DYS_XM20A_Main EQU 235 DYS_XM20A_Tail EQU 236 DYS_XM20A_Multi EQU 237 Oversky_MR_20A_Pro_Main EQU 238 Oversky_MR_20A_Pro_Tail EQU 239 Oversky_MR_20A_Pro_Multi EQU 240 TBS_Cube_12A_Main EQU 241 TBS_Cube_12A_Tail EQU 242 TBS_Cube_12A_Multi EQU 243 DALRC_XR20A_Main EQU 244 DALRC_XR20A_Tail EQU 245 DALRC_XR20A_Multi EQU 246 ;**** **** **** **** **** ; Select the ESC and mode to use (or unselect all for use with external batch compile file) ;BESCNO EQU XP_3A_Main ;BESCNO EQU XP_3A_Tail ;BESCNO EQU XP_3A_Multi ;BESCNO EQU XP_7A_Main ;BESCNO EQU XP_7A_Tail ;BESCNO EQU XP_7A_Multi ;BESCNO EQU XP_7A_Fast_Main ;BESCNO EQU XP_7A_Fast_Tail ;BESCNO EQU XP_7A_Fast_Multi ;BESCNO EQU XP_12A_Main ;BESCNO EQU XP_12A_Tail ;BESCNO EQU XP_12A_Multi ;BESCNO EQU XP_18A_Main ;BESCNO EQU XP_18A_Tail ;BESCNO EQU XP_18A_Multi ;BESCNO EQU XP_25A_Main ;BESCNO EQU XP_25A_Tail ;BESCNO EQU XP_25A_Multi ;BESCNO EQU XP_35A_SW_Main ;BESCNO EQU XP_35A_SW_Tail ;BESCNO EQU XP_35A_SW_Multi ;BESCNO EQU DP_3A_Main ;BESCNO EQU DP_3A_Tail ;BESCNO EQU DP_3A_Multi ;BESCNO EQU Supermicro_3p5A_Main ;BESCNO EQU Supermicro_3p5A_Tail ;BESCNO EQU Supermicro_3p5A_Multi ;BESCNO EQU Turnigy_Plush_6A_Main ;BESCNO EQU Turnigy_Plush_6A_Tail ;BESCNO EQU Turnigy_Plush_6A_Multi ;BESCNO EQU Turnigy_Plush_10A_Main ;BESCNO EQU Turnigy_Plush_10A_Tail ;BESCNO EQU Turnigy_Plush_10A_Multi ;BESCNO EQU Turnigy_Plush_12A_Main ;BESCNO EQU Turnigy_Plush_12A_Tail ;BESCNO EQU Turnigy_Plush_12A_Multi ;BESCNO EQU Turnigy_Plush_18A_Main ;BESCNO EQU Turnigy_Plush_18A_Tail ;BESCNO EQU Turnigy_Plush_18A_Multi ;BESCNO EQU Turnigy_Plush_25A_Main ;BESCNO EQU Turnigy_Plush_25A_Tail ;BESCNO EQU Turnigy_Plush_25A_Multi ;BESCNO EQU Turnigy_Plush_30A_Main ;BESCNO EQU Turnigy_Plush_30A_Tail ;BESCNO EQU Turnigy_Plush_30A_Multi ;BESCNO EQU Turnigy_Plush_40A_Main ;BESCNO EQU Turnigy_Plush_40A_Tail ;BESCNO EQU Turnigy_Plush_40A_Multi ;BESCNO EQU Turnigy_Plush_60A_Main ;BESCNO EQU Turnigy_Plush_60A_Tail ;BESCNO EQU Turnigy_Plush_60A_Multi ;BESCNO EQU Turnigy_Plush_80A_Main ;BESCNO EQU Turnigy_Plush_80A_Tail ;BESCNO EQU Turnigy_Plush_80A_Multi ;BESCNO EQU Turnigy_Plush_Nfet_18A_Main ;BESCNO EQU Turnigy_Plush_Nfet_18A_Tail ;BESCNO EQU Turnigy_Plush_Nfet_18A_Multi ;BESCNO EQU Turnigy_Plush_Nfet_25A_Main ;BESCNO EQU Turnigy_Plush_Nfet_25A_Tail ;BESCNO EQU Turnigy_Plush_Nfet_25A_Multi ;BESCNO EQU Turnigy_Plush_Nfet_30A_Main ;BESCNO EQU Turnigy_Plush_Nfet_30A_Tail ;BESCNO EQU Turnigy_Plush_Nfet_30A_Multi ;BESCNO EQU Turnigy_AE_20A_Main ;BESCNO EQU Turnigy_AE_20A_Tail ;BESCNO EQU Turnigy_AE_20A_Multi ;BESCNO EQU Turnigy_AE_25A_Main ;BESCNO EQU Turnigy_AE_25A_Tail ;BESCNO EQU Turnigy_AE_25A_Multi ;BESCNO EQU Turnigy_AE_30A_Main ;BESCNO EQU Turnigy_AE_30A_Tail ;BESCNO EQU Turnigy_AE_30A_Multi ;BESCNO EQU Turnigy_AE_45A_Main ;BESCNO EQU Turnigy_AE_45A_Tail ;BESCNO EQU Turnigy_AE_45A_Multi ;BESCNO EQU Turnigy_KForce_40A_Main ;BESCNO EQU Turnigy_KForce_40A_Tail ;BESCNO EQU Turnigy_KForce_40A_Multi ;BESCNO EQU Turnigy_KForce_70A_HV_Main ;BESCNO EQU Turnigy_KForce_70A_HV_Tail ;BESCNO EQU Turnigy_KForce_70A_HV_Multi ;BESCNO EQU Turnigy_KForce_120A_HV_Main ;BESCNO EQU Turnigy_KForce_120A_HV_Tail ;BESCNO EQU Turnigy_KForce_120A_HV_Multi ;BESCNO EQU Turnigy_KForce_120A_HV_v2_Main ;BESCNO EQU Turnigy_KForce_120A_HV_v2_Tail ;BESCNO EQU Turnigy_KForce_120A_HV_v2_Multi ;BESCNO EQU Skywalker_20A_Main ;BESCNO EQU Skywalker_20A_Tail ;BESCNO EQU Skywalker_20A_Multi ;BESCNO EQU Skywalker_40A_Main ;BESCNO EQU Skywalker_40A_Tail ;BESCNO EQU Skywalker_40A_Multi ;BESCNO EQU HiModel_Cool_22A_Main ;BESCNO EQU HiModel_Cool_22A_Tail ;BESCNO EQU HiModel_Cool_22A_Multi ;BESCNO EQU HiModel_Cool_33A_Main ;BESCNO EQU HiModel_Cool_33A_Tail ;BESCNO EQU HiModel_Cool_33A_Multi ;BESCNO EQU HiModel_Cool_41A_Main ;BESCNO EQU HiModel_Cool_41A_Tail ;BESCNO EQU HiModel_Cool_41A_Multi ;BESCNO EQU RCTimer_6A_Main ;BESCNO EQU RCTimer_6A_Tail ;BESCNO EQU RCTimer_6A_Multi ;BESCNO EQU Align_RCE_BL15X_Main ;BESCNO EQU Align_RCE_BL15X_Tail ;BESCNO EQU Align_RCE_BL15X_Multi ;BESCNO EQU Align_RCE_BL15P_Main ;BESCNO EQU Align_RCE_BL15P_Tail ;BESCNO EQU Align_RCE_BL15P_Multi ;BESCNO EQU Align_RCE_BL35X_Main ;BESCNO EQU Align_RCE_BL35X_Tail ;BESCNO EQU Align_RCE_BL35X_Multi ;BESCNO EQU Align_RCE_BL35P_Main ;BESCNO EQU Align_RCE_BL35P_Tail ;BESCNO EQU Align_RCE_BL35P_Multi ;BESCNO EQU Gaui_GE_183_18A_Main ;BESCNO EQU Gaui_GE_183_18A_Tail ;BESCNO EQU Gaui_GE_183_18A_Multi ;BESCNO EQU H_King_10A_Main ;BESCNO EQU H_King_10A_Tail ;BESCNO EQU H_King_10A_Multi ;BESCNO EQU H_King_20A_Main ;BESCNO EQU H_King_20A_Tail ;BESCNO EQU H_King_20A_Multi ;BESCNO EQU H_King_35A_Main ;BESCNO EQU H_King_35A_Tail ;BESCNO EQU H_King_35A_Multi ;BESCNO EQU H_King_50A_Main ;BESCNO EQU H_King_50A_Tail ;BESCNO EQU H_King_50A_Multi ;BESCNO EQU Polaris_Thunder_12A_Main ;BESCNO EQU Polaris_Thunder_12A_Tail ;BESCNO EQU Polaris_Thunder_12A_Multi ;BESCNO EQU Polaris_Thunder_20A_Main ;BESCNO EQU Polaris_Thunder_20A_Tail ;BESCNO EQU Polaris_Thunder_20A_Multi ;BESCNO EQU Polaris_Thunder_30A_Main ;BESCNO EQU Polaris_Thunder_30A_Tail ;BESCNO EQU Polaris_Thunder_30A_Multi ;BESCNO EQU Polaris_Thunder_40A_Main ;BESCNO EQU Polaris_Thunder_40A_Tail ;BESCNO EQU Polaris_Thunder_40A_Multi ;BESCNO EQU Polaris_Thunder_60A_Main ;BESCNO EQU Polaris_Thunder_60A_Tail ;BESCNO EQU Polaris_Thunder_60A_Multi ;BESCNO EQU Polaris_Thunder_80A_Main ;BESCNO EQU Polaris_Thunder_80A_Tail ;BESCNO EQU Polaris_Thunder_80A_Multi ;BESCNO EQU Polaris_Thunder_100A_Main ;BESCNO EQU Polaris_Thunder_100A_Tail ;BESCNO EQU Polaris_Thunder_100A_Multi ;BESCNO EQU Platinum_Pro_30A_Main ;BESCNO EQU Platinum_Pro_30A_Tail ;BESCNO EQU Platinum_Pro_30A_Multi ;BESCNO EQU Platinum_Pro_150A_Main ;BESCNO EQU Platinum_Pro_150A_Tail ;BESCNO EQU Platinum_Pro_150A_Multi ;BESCNO EQU Platinum_50Av3_Main ;BESCNO EQU Platinum_50Av3_Tail ;BESCNO EQU Platinum_50Av3_Multi ;BESCNO EQU EAZY_3Av2_Main ;BESCNO EQU EAZY_3Av2_Tail ;BESCNO EQU EAZY_3Av2_Multi ;BESCNO EQU Tarot_30A_Main ;BESCNO EQU Tarot_30A_Tail ;BESCNO EQU Tarot_30A_Multi ;BESCNO EQU SkyIII_30A_Main ;BESCNO EQU SkyIII_30A_Tail ;BESCNO EQU SkyIII_30A_Multi ;BESCNO EQU EMAX_20A_Main ;BESCNO EQU EMAX_20A_Tail ;BESCNO EQU EMAX_20A_Multi ;BESCNO EQU EMAX_40A_Main ;BESCNO EQU EMAX_40A_Tail ;BESCNO EQU EMAX_40A_Multi ;BESCNO EQU EMAX_Nano_20A_Main ;BESCNO EQU EMAX_Nano_20A_Tail ;BESCNO EQU EMAX_Nano_20A_Multi ;BESCNO EQU XRotor_10A_Main ;BESCNO EQU XRotor_10A_Tail ;BESCNO EQU XRotor_10A_Multi ;BESCNO EQU XRotor_20A_Main ;BESCNO EQU XRotor_20A_Tail ;BESCNO EQU XRotor_20A_Multi ;BESCNO EQU XRotor_40A_Main ;BESCNO EQU XRotor_40A_Tail ;BESCNO EQU XRotor_40A_Multi ;BESCNO EQU MDRX62H_Main ;BESCNO EQU MDRX62H_Tail ;BESCNO EQU MDRX62H_Multi ;BESCNO EQU RotorGeeks_20A_Main ;BESCNO EQU RotorGeeks_20A_Tail ;BESCNO EQU RotorGeeks_20A_Multi ;BESCNO EQU Flycolor_Fairy_6A_Main ;BESCNO EQU Flycolor_Fairy_6A_Tail ;BESCNO EQU Flycolor_Fairy_6A_Multi ;BESCNO EQU Flycolor_Fairy_30A_Main ;BESCNO EQU Flycolor_Fairy_30A_Tail ;BESCNO EQU Flycolor_Fairy_30A_Multi ;BESCNO EQU Flycolor_Raptor_20A_Main ;BESCNO EQU Flycolor_Raptor_20A_Tail ;BESCNO EQU Flycolor_Raptor_20A_Multi ;BESCNO EQU Flycolor_Raptor_390_20A_Main ;BESCNO EQU Flycolor_Raptor_390_20A_Tail ;BESCNO EQU Flycolor_Raptor_390_20A_Multi ;BESCNO EQU FVT_Littlebee_20A_Main ;BESCNO EQU FVT_Littlebee_20A_Tail ;BESCNO EQU FVT_Littlebee_20A_Multi ;BESCNO EQU FVT_Littlebee_20A_Pro_Main ;BESCNO EQU FVT_Littlebee_20A_Pro_Tail ;BESCNO EQU FVT_Littlebee_20A_Pro_Multi ;BESCNO EQU FVT_Littlebee_30A_Main ;BESCNO EQU FVT_Littlebee_30A_Tail ;BESCNO EQU FVT_Littlebee_30A_Multi ;BESCNO EQU Graupner_Ultra_20A_Main ;BESCNO EQU Graupner_Ultra_20A_Tail ;BESCNO EQU Graupner_Ultra_20A_Multi ;BESCNO EQU F85_3A_Main ;BESCNO EQU F85_3A_Tail ;BESCNO EQU F85_3A_Multi ;BESCNO EQU ZTW_Spider_Pro_20A_Main ;BESCNO EQU ZTW_Spider_Pro_20A_Tail ;BESCNO EQU ZTW_Spider_Pro_20A_Multi ;BESCNO EQU ZTW_Spider_Pro_20A_Premium_Main ;BESCNO EQU ZTW_Spider_Pro_20A_Premium_Tail ;BESCNO EQU ZTW_Spider_Pro_20A_Premium_Multi ;BESCNO EQU ZTW_Spider_Pro_20A_HV_Main ;BESCNO EQU ZTW_Spider_Pro_20A_HV_Tail ;BESCNO EQU ZTW_Spider_Pro_20A_HV_Multi ;BESCNO EQU ZTW_Spider_Pro_30A_HV_Main ;BESCNO EQU ZTW_Spider_Pro_30A_HV_Tail ;BESCNO EQU ZTW_Spider_Pro_30A_HV_Multi ;BESCNO EQU DYS_XM20A_Main ;BESCNO EQU DYS_XM20A_Tail ;BESCNO EQU DYS_XM20A_Multi ;BESCNO EQU Oversky_MR_20A_Pro_Main ;BESCNO EQU Oversky_MR_20A_Pro_Tail ;BESCNO EQU Oversky_MR_20A_Pro_Multi ;BESCNO EQU TBS_Cube_12A_Main ;BESCNO EQU TBS_Cube_12A_Tail ;BESCNO EQU TBS_Cube_12A_Multi ;BESCNO EQU DALRC_XR20A_Main ;BESCNO EQU DALRC_XR20A_Tail ;BESCNO EQU DALRC_XR20A_Multi ;**** **** **** **** **** ; ESC selection statements IF BESCNO == XP_3A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (XP_3A.inc) ; Select XP 3A pinout ENDIF IF BESCNO == XP_3A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (XP_3A.inc) ; Select XP 3A pinout ENDIF IF BESCNO == XP_3A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (XP_3A.inc) ; Select XP 3A pinout ENDIF IF BESCNO == XP_7A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (XP_7A.inc) ; Select XP 7A pinout ENDIF IF BESCNO == XP_7A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (XP_7A.inc) ; Select XP 7A pinout ENDIF IF BESCNO == XP_7A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (XP_7A.inc) ; Select XP 7A pinout ENDIF IF BESCNO == XP_7A_Fast_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (XP_7A_Fast.inc) ; Select XP 7A Fast pinout ENDIF IF BESCNO == XP_7A_Fast_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (XP_7A_Fast.inc) ; Select XP 7A Fast pinout ENDIF IF BESCNO == XP_7A_Fast_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (XP_7A_Fast.inc) ; Select XP 7A Fast pinout ENDIF IF BESCNO == XP_12A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (XP_12A.inc) ; Select XP 12A pinout ENDIF IF BESCNO == XP_12A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (XP_12A.inc) ; Select XP 12A pinout ENDIF IF BESCNO == XP_12A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (XP_12A.inc) ; Select XP 12A pinout ENDIF IF BESCNO == XP_18A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (XP_18A.inc) ; Select XP 18A pinout ENDIF IF BESCNO == XP_18A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (XP_18A.inc) ; Select XP 18A pinout ENDIF IF BESCNO == XP_18A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (XP_18A.inc) ; Select XP 18A pinout ENDIF IF BESCNO == XP_25A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (XP_25A.inc) ; Select XP 25A pinout ENDIF IF BESCNO == XP_25A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (XP_25A.inc) ; Select XP 25A pinout ENDIF IF BESCNO == XP_25A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (XP_25A.inc) ; Select XP 25A pinout ENDIF IF BESCNO == XP_35A_SW_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (XP_35A_SW.inc) ; Select XP 35A SW pinout ENDIF IF BESCNO == XP_35A_SW_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (XP_35A_SW.inc) ; Select XP 35A SW pinout ENDIF IF BESCNO == XP_35A_SW_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (XP_35A_SW.inc) ; Select XP 35A SW pinout ENDIF IF BESCNO == DP_3A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (DP_3A.inc) ; Select DP 3A pinout ENDIF IF BESCNO == DP_3A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (DP_3A.inc) ; Select DP 3A pinout ENDIF IF BESCNO == DP_3A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (DP_3A.inc) ; Select DP 3A pinout ENDIF IF BESCNO == Supermicro_3p5A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Supermicro_3p5A.inc) ; Select Supermicro 3.5A pinout ENDIF IF BESCNO == Supermicro_3p5A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Supermicro_3p5A.inc) ; Select Supermicro 3.5A pinout ENDIF IF BESCNO == Supermicro_3p5A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Supermicro_3p5A.inc) ; Select Supermicro 3.5A pinout ENDIF IF BESCNO == Turnigy_Plush_6A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_Plush_6A.inc) ; Select Turnigy Plush 6A pinout ENDIF IF BESCNO == Turnigy_Plush_6A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_Plush_6A.inc) ; Select Turnigy Plush 6A pinout ENDIF IF BESCNO == Turnigy_Plush_6A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_Plush_6A.inc) ; Select Turnigy Plush 6A pinout ENDIF IF BESCNO == Turnigy_Plush_10A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_Plush_10A.inc) ; Select Turnigy Plush 10A pinout ENDIF IF BESCNO == Turnigy_Plush_10A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_Plush_10A.inc) ; Select Turnigy Plush 10A pinout ENDIF IF BESCNO == Turnigy_Plush_10A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_Plush_10A.inc) ; Select Turnigy Plush 10A pinout ENDIF IF BESCNO == Turnigy_Plush_12A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_Plush_12A.inc) ; Select Turnigy Plush 12A pinout ENDIF IF BESCNO == Turnigy_Plush_12A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_Plush_12A.inc) ; Select Turnigy Plush 12A pinout ENDIF IF BESCNO == Turnigy_Plush_12A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_Plush_12A.inc) ; Select Turnigy Plush 12A pinout ENDIF IF BESCNO == Turnigy_Plush_18A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_Plush_18A.inc) ; Select Turnigy Plush 18A pinout ENDIF IF BESCNO == Turnigy_Plush_18A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_Plush_18A.inc) ; Select Turnigy Plush 18A pinout ENDIF IF BESCNO == Turnigy_Plush_18A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_Plush_18A.inc) ; Select Turnigy Plush 18A pinout ENDIF IF BESCNO == Turnigy_Plush_25A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_Plush_25A.inc) ; Select Turnigy Plush 25A pinout ENDIF IF BESCNO == Turnigy_Plush_25A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_Plush_25A.inc) ; Select Turnigy Plush 25A pinout ENDIF IF BESCNO == Turnigy_Plush_25A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_Plush_25A.inc) ; Select Turnigy Plush 25A pinout ENDIF IF BESCNO == Turnigy_Plush_30A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_Plush_30A.inc) ; Select Turnigy Plush 30A pinout ENDIF IF BESCNO == Turnigy_Plush_30A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_Plush_30A.inc) ; Select Turnigy Plush 30A pinout ENDIF IF BESCNO == Turnigy_Plush_30A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_Plush_30A.inc) ; Select Turnigy Plush 30A pinout ENDIF IF BESCNO == Turnigy_Plush_40A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_Plush_40A.inc) ; Select Turnigy Plush 40A pinout ENDIF IF BESCNO == Turnigy_Plush_40A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_Plush_40A.inc) ; Select Turnigy Plush 40A pinout ENDIF IF BESCNO == Turnigy_Plush_40A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_Plush_40A.inc) ; Select Turnigy Plush 40A pinout ENDIF IF BESCNO == Turnigy_Plush_60A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_Plush_60A.inc) ; Select Turnigy Plush 60A pinout ENDIF IF BESCNO == Turnigy_Plush_60A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_Plush_60A.inc) ; Select Turnigy Plush 60A pinout ENDIF IF BESCNO == Turnigy_Plush_60A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_Plush_60A.inc) ; Select Turnigy Plush 60A pinout ENDIF IF BESCNO == Turnigy_Plush_80A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_Plush_80A.inc) ; Select Turnigy Plush 80A pinout ENDIF IF BESCNO == Turnigy_Plush_80A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_Plush_80A.inc) ; Select Turnigy Plush 80A pinout ENDIF IF BESCNO == Turnigy_Plush_80A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_Plush_80A.inc) ; Select Turnigy Plush 80A pinout ENDIF IF BESCNO == Turnigy_Plush_Nfet_18A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_Plush_Nfet_18A.inc) ; Select Turnigy Plush Nfet 18A pinout ENDIF IF BESCNO == Turnigy_Plush_Nfet_18A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_Plush_Nfet_18A.inc) ; Select Turnigy Plush Nfet 18A pinout ENDIF IF BESCNO == Turnigy_Plush_Nfet_18A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_Plush_Nfet_18A.inc) ; Select Turnigy Plush Nfet 18A pinout ENDIF IF BESCNO == Turnigy_Plush_Nfet_25A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_Plush_Nfet_25A.inc) ; Select Turnigy Plush Nfet 25A pinout ENDIF IF BESCNO == Turnigy_Plush_Nfet_25A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_Plush_Nfet_25A.inc) ; Select Turnigy Plush Nfet 25A pinout ENDIF IF BESCNO == Turnigy_Plush_Nfet_25A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_Plush_Nfet_25A.inc) ; Select Turnigy Plush Nfet 25A pinout ENDIF IF BESCNO == Turnigy_Plush_Nfet_30A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_Plush_Nfet_30A.inc) ; Select Turnigy Plush Nfet 30A pinout ENDIF IF BESCNO == Turnigy_Plush_Nfet_30A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_Plush_Nfet_30A.inc) ; Select Turnigy Plush Nfet 30A pinout ENDIF IF BESCNO == Turnigy_Plush_Nfet_30A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_Plush_Nfet_30A.inc) ; Select Turnigy Plush Nfet 30A pinout ENDIF IF BESCNO == Turnigy_AE_20A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_AE_20A.inc) ; Select Turnigy AE-20A pinout ENDIF IF BESCNO == Turnigy_AE_20A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_AE_20A.inc) ; Select Turnigy AE-20A pinout ENDIF IF BESCNO == Turnigy_AE_20A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_AE_20A.inc) ; Select Turnigy AE-20A pinout ENDIF IF BESCNO == Turnigy_AE_25A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_AE_25A.inc) ; Select Turnigy AE-25A pinout ENDIF IF BESCNO == Turnigy_AE_25A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_AE_25A.inc) ; Select Turnigy AE-25A pinout ENDIF IF BESCNO == Turnigy_AE_25A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_AE_25A.inc) ; Select Turnigy AE-25A pinout ENDIF IF BESCNO == Turnigy_AE_30A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_AE_30A.inc) ; Select Turnigy AE-30A pinout ENDIF IF BESCNO == Turnigy_AE_30A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_AE_30A.inc) ; Select Turnigy AE-30A pinout ENDIF IF BESCNO == Turnigy_AE_30A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_AE_30A.inc) ; Select Turnigy AE-30A pinout ENDIF IF BESCNO == Turnigy_AE_45A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_AE_45A.inc) ; Select Turnigy AE-45A pinout ENDIF IF BESCNO == Turnigy_AE_45A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_AE_45A.inc) ; Select Turnigy AE-45A pinout ENDIF IF BESCNO == Turnigy_AE_45A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_AE_45A.inc) ; Select Turnigy AE-45A pinout ENDIF IF BESCNO == Turnigy_KForce_40A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_KForce_40A.inc) ; Select Turnigy KForce 40A pinout ENDIF IF BESCNO == Turnigy_KForce_40A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_KForce_40A.inc) ; Select Turnigy KForce 40A pinout ENDIF IF BESCNO == Turnigy_KForce_40A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_KForce_40A.inc) ; Select Turnigy KForce 40A pinout ENDIF IF BESCNO == Turnigy_KForce_70A_HV_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_KForce_70A_HV.inc) ; Select Turnigy KForce 70A HV pinout ENDIF IF BESCNO == Turnigy_KForce_70A_HV_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_KForce_70A_HV.inc) ; Select Turnigy KForce 70A HV pinout ENDIF IF BESCNO == Turnigy_KForce_70A_HV_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_KForce_70A_HV.inc) ; Select Turnigy KForce 70A HV pinout ENDIF IF BESCNO == Turnigy_KForce_120A_HV_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_KForce_120A_HV.inc) ; Select Turnigy KForce 120A HV pinout ENDIF IF BESCNO == Turnigy_KForce_120A_HV_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_KForce_120A_HV.inc) ; Select Turnigy KForce 120A HV pinout ENDIF IF BESCNO == Turnigy_KForce_120A_HV_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_KForce_120A_HV.inc) ; Select Turnigy KForce 120A HV pinout ENDIF IF BESCNO == Turnigy_KForce_120A_HV_v2_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Turnigy_KForce_120A_HV_v2.inc); Select Turnigy KForce 120A HV v2 pinout ENDIF IF BESCNO == Turnigy_KForce_120A_HV_v2_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Turnigy_KForce_120A_HV_v2.inc); Select Turnigy KForce 120A HV v2 pinout ENDIF IF BESCNO == Turnigy_KForce_120A_HV_v2_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Turnigy_KForce_120A_HV_v2.inc); Select Turnigy KForce 120A HV v2 pinout ENDIF IF BESCNO == Skywalker_20A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Skywalker_20A.inc) ; Select Skywalker 20A pinout ENDIF IF BESCNO == Skywalker_20A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Skywalker_20A.inc) ; Select Skywalker 20A pinout ENDIF IF BESCNO == Skywalker_20A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Skywalker_20A.inc) ; Select Skywalker 20A pinout ENDIF IF BESCNO == Skywalker_40A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Skywalker_40A.inc) ; Select Skywalker 40A pinout ENDIF IF BESCNO == Skywalker_40A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Skywalker_40A.inc) ; Select Skywalker 40A pinout ENDIF IF BESCNO == Skywalker_40A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Skywalker_40A.inc) ; Select Skywalker 40A pinout ENDIF IF BESCNO == HiModel_Cool_22A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (HiModel_Cool_22A.inc) ; Select HiModel Cool 22A pinout ENDIF IF BESCNO == HiModel_Cool_22A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (HiModel_Cool_22A.inc) ; Select HiModel Cool 22A pinout ENDIF IF BESCNO == HiModel_Cool_22A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (HiModel_Cool_22A.inc) ; Select HiModel Cool 22A pinout ENDIF IF BESCNO == HiModel_Cool_33A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (HiModel_Cool_33A.inc) ; Select HiModel Cool 33A pinout ENDIF IF BESCNO == HiModel_Cool_33A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (HiModel_Cool_33A.inc) ; Select HiModel Cool 33A pinout ENDIF IF BESCNO == HiModel_Cool_33A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (HiModel_Cool_33A.inc) ; Select HiModel Cool 33A pinout ENDIF IF BESCNO == HiModel_Cool_41A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (HiModel_Cool_41A.inc) ; Select HiModel Cool 41A pinout ENDIF IF BESCNO == HiModel_Cool_41A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (HiModel_Cool_41A.inc) ; Select HiModel Cool 41A pinout ENDIF IF BESCNO == HiModel_Cool_41A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (HiModel_Cool_41A.inc) ; Select HiModel Cool 41A pinout ENDIF IF BESCNO == RCTimer_6A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (RCTimer_6A.inc) ; Select RC Timer 6A pinout ENDIF IF BESCNO == RCTimer_6A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (RCTimer_6A.inc) ; Select RC Timer 6A pinout ENDIF IF BESCNO == RCTimer_6A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (RCTimer_6A.inc) ; Select RC Timer 6A pinout ENDIF IF BESCNO == Align_RCE_BL15X_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Align_RCE_BL15X.inc) ; Select Align RCE-BL15X pinout ENDIF IF BESCNO == Align_RCE_BL15X_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Align_RCE_BL15X.inc) ; Select Align RCE-BL15X pinout ENDIF IF BESCNO == Align_RCE_BL15X_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Align_RCE_BL15X.inc) ; Select Align RCE-BL15X pinout ENDIF IF BESCNO == Align_RCE_BL15P_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Align_RCE_BL15P.inc) ; Select Align RCE-BL15P pinout ENDIF IF BESCNO == Align_RCE_BL15P_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Align_RCE_BL15P.inc) ; Select Align RCE-BL15P pinout ENDIF IF BESCNO == Align_RCE_BL15P_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Align_RCE_BL15P.inc) ; Select Align RCE-BL15P pinout ENDIF IF BESCNO == Align_RCE_BL35X_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Align_RCE_BL35X.inc) ; Select Align RCE-BL35X pinout ENDIF IF BESCNO == Align_RCE_BL35X_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Align_RCE_BL35X.inc) ; Select Align RCE-BL35X pinout ENDIF IF BESCNO == Align_RCE_BL35X_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Align_RCE_BL35X.inc) ; Select Align RCE-BL35X pinout ENDIF IF BESCNO == Align_RCE_BL35P_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Align_RCE_BL35P.inc) ; Select Align RCE-BL35P pinout ENDIF IF BESCNO == Align_RCE_BL35P_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Align_RCE_BL35P.inc) ; Select Align RCE-BL35P pinout ENDIF IF BESCNO == Align_RCE_BL35P_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Align_RCE_BL35P.inc) ; Select Align RCE-BL35P pinout ENDIF IF BESCNO == Gaui_GE_183_18A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Gaui_GE_183_18A.inc) ; Select Gaui GE-183 18A pinout ENDIF IF BESCNO == Gaui_GE_183_18A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Gaui_GE_183_18A.inc) ; Select Gaui GE-183 18A pinout ENDIF IF BESCNO == Gaui_GE_183_18A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Gaui_GE_183_18A.inc) ; Select Gaui GE-183 18A pinout ENDIF IF BESCNO == H_King_10A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (H_King_10A.inc) ; Select H-King 10A pinout ENDIF IF BESCNO == H_King_10A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (H_King_10A.inc) ; Select H-King 10A pinout ENDIF IF BESCNO == H_King_10A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (H_King_10A.inc) ; Select H-King 10A pinout ENDIF IF BESCNO == H_King_20A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (H_King_20A.inc) ; Select H-King 20A pinout ENDIF IF BESCNO == H_King_20A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (H_King_20A.inc) ; Select H-King 20A pinout ENDIF IF BESCNO == H_King_20A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (H_King_20A.inc) ; Select H-King 20A pinout ENDIF IF BESCNO == H_King_35A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (H_King_35A.inc) ; Select H-King 35A pinout ENDIF IF BESCNO == H_King_35A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (H_King_35A.inc) ; Select H-King 35A pinout ENDIF IF BESCNO == H_King_35A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (H_King_35A.inc) ; Select H-King 35A pinout ENDIF IF BESCNO == H_King_50A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (H_King_50A.inc) ; Select H-King 50A pinout ENDIF IF BESCNO == H_King_50A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (H_King_50A.inc) ; Select H-King 50A pinout ENDIF IF BESCNO == H_King_50A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (H_King_50A.inc) ; Select H-King 50A pinout ENDIF IF BESCNO == Polaris_Thunder_12A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Polaris_Thunder_12A.inc) ; Select Polaris Thunder 12A pinout ENDIF IF BESCNO == Polaris_Thunder_12A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Polaris_Thunder_12A.inc) ; Select Polaris Thunder 12A pinout ENDIF IF BESCNO == Polaris_Thunder_12A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Polaris_Thunder_12A.inc) ; Select Polaris Thunder 12A pinout ENDIF IF BESCNO == Polaris_Thunder_20A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Polaris_Thunder_20A.inc) ; Select Polaris Thunder 20A pinout ENDIF IF BESCNO == Polaris_Thunder_20A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Polaris_Thunder_20A.inc) ; Select Polaris Thunder 20A pinout ENDIF IF BESCNO == Polaris_Thunder_20A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Polaris_Thunder_20A.inc) ; Select Polaris Thunder 20A pinout ENDIF IF BESCNO == Polaris_Thunder_30A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Polaris_Thunder_30A.inc) ; Select Polaris Thunder 30A pinout ENDIF IF BESCNO == Polaris_Thunder_30A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Polaris_Thunder_30A.inc) ; Select Polaris Thunder 30A pinout ENDIF IF BESCNO == Polaris_Thunder_30A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Polaris_Thunder_30A.inc) ; Select Polaris Thunder 30A pinout ENDIF IF BESCNO == Polaris_Thunder_40A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Polaris_Thunder_40A.inc) ; Select Polaris Thunder 40A pinout ENDIF IF BESCNO == Polaris_Thunder_40A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Polaris_Thunder_40A.inc) ; Select Polaris Thunder 40A pinout ENDIF IF BESCNO == Polaris_Thunder_40A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Polaris_Thunder_40A.inc) ; Select Polaris Thunder 40A pinout ENDIF IF BESCNO == Polaris_Thunder_60A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Polaris_Thunder_60A.inc) ; Select Polaris Thunder 60A pinout ENDIF IF BESCNO == Polaris_Thunder_60A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Polaris_Thunder_60A.inc) ; Select Polaris Thunder 60A pinout ENDIF IF BESCNO == Polaris_Thunder_60A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Polaris_Thunder_60A.inc) ; Select Polaris Thunder 60A pinout ENDIF IF BESCNO == Polaris_Thunder_80A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Polaris_Thunder_80A.inc) ; Select Polaris Thunder 80A pinout ENDIF IF BESCNO == Polaris_Thunder_80A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Polaris_Thunder_80A.inc) ; Select Polaris Thunder 80A pinout ENDIF IF BESCNO == Polaris_Thunder_80A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Polaris_Thunder_80A.inc) ; Select Polaris Thunder 80A pinout ENDIF IF BESCNO == Polaris_Thunder_100A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Polaris_Thunder_100A.inc); Select Polaris Thunder 100A pinout ENDIF IF BESCNO == Polaris_Thunder_100A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Polaris_Thunder_100A.inc); Select Polaris Thunder 100A pinout ENDIF IF BESCNO == Polaris_Thunder_100A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Polaris_Thunder_100A.inc); Select Polaris Thunder 100A pinout ENDIF IF BESCNO == Platinum_Pro_30A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Platinum_Pro_30A.inc) ; Select Platinum Pro 30A pinout ENDIF IF BESCNO == Platinum_Pro_30A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Platinum_Pro_30A.inc) ; Select Platinum Pro 30A pinout ENDIF IF BESCNO == Platinum_Pro_30A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Platinum_Pro_30A.inc) ; Select Platinum Pro 30A pinout ENDIF IF BESCNO == Platinum_Pro_150A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Platinum_Pro_150A.inc) ; Select Platinum Pro 150A pinout ENDIF IF BESCNO == Platinum_Pro_150A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Platinum_Pro_150A.inc) ; Select Platinum Pro 150A pinout ENDIF IF BESCNO == Platinum_Pro_150A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Platinum_Pro_150A.inc) ; Select Platinum Pro 150A pinout ENDIF IF BESCNO == Platinum_50Av3_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Platinum_50Av3.inc) ; Select Platinum 50A v3 pinout ENDIF IF BESCNO == Platinum_50Av3_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Platinum_50Av3.inc) ; Select Platinum 50A v3 pinout ENDIF IF BESCNO == Platinum_50Av3_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Platinum_50Av3.inc) ; Select Platinum 50A v3 pinout ENDIF IF BESCNO == EAZY_3Av2_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (EAZY_3Av2.inc) ; Select Eazy 3A v2 pinout ENDIF IF BESCNO == EAZY_3Av2_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (EAZY_3Av2.inc) ; Select Eazy 3A v2 pinout ENDIF IF BESCNO == EAZY_3Av2_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (EAZY_3Av2.inc) ; Select Eazy 3A v2 pinout ENDIF IF BESCNO == Tarot_30A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Tarot_30A.inc) ; Select Tarot 30A pinout ENDIF IF BESCNO == Tarot_30A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Tarot_30A.inc) ; Select Tarot 30A pinout ENDIF IF BESCNO == Tarot_30A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Tarot_30A.inc) ; Select Tarot 30A pinout ENDIF IF BESCNO == SkyIII_30A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (SkyIII_30A.inc) ; Select SkyIII 30A pinout ENDIF IF BESCNO == SkyIII_30A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (SkyIII_30A.inc) ; Select SkyIII 30A pinout ENDIF IF BESCNO == SkyIII_30A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (SkyIII_30A.inc) ; Select SkyIII 30A pinout ENDIF IF BESCNO == EMAX_20A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (EMAX_20A.inc) ; Select EMAX 20A pinout ENDIF IF BESCNO == EMAX_20A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (EMAX_20A.inc) ; Select EMAX 20A pinout ENDIF IF BESCNO == EMAX_20A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (EMAX_20A.inc) ; Select EMAX 20A pinout ENDIF IF BESCNO == EMAX_40A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (EMAX_40A.inc) ; Select EMAX 40A pinout ENDIF IF BESCNO == EMAX_40A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (EMAX_40A.inc) ; Select EMAX 40A pinout ENDIF IF BESCNO == EMAX_40A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (EMAX_40A.inc) ; Select EMAX 40A pinout ENDIF IF BESCNO == EMAX_Nano_20A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (EMAX_Nano_20A.inc) ; Select EMAX Nano 20A pinout ENDIF IF BESCNO == EMAX_Nano_20A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (EMAX_Nano_20A.inc) ; Select EMAX Nano 20A pinout ENDIF IF BESCNO == EMAX_Nano_20A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (EMAX_Nano_20A.inc) ; Select EMAX Nano 20A pinout ENDIF IF BESCNO == XRotor_10A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (XRotor_10A.inc) ; Select XRotor 10A pinout ENDIF IF BESCNO == XRotor_10A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (XRotor_10A.inc) ; Select XRotor 10A pinout ENDIF IF BESCNO == XRotor_10A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (XRotor_10A.inc) ; Select XRotor 10A pinout ENDIF IF BESCNO == XRotor_20A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (XRotor_20A.inc) ; Select XRotor 20A pinout ENDIF IF BESCNO == XRotor_20A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (XRotor_20A.inc) ; Select XRotor 20A pinout ENDIF IF BESCNO == XRotor_20A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (XRotor_20A.inc) ; Select XRotor 20A pinout ENDIF IF BESCNO == XRotor_40A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (XRotor_40A.inc) ; Select XRotor 40A pinout ENDIF IF BESCNO == XRotor_40A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (XRotor_40A.inc) ; Select XRotor 40A pinout ENDIF IF BESCNO == XRotor_40A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (XRotor_40A.inc) ; Select XRotor 40A pinout ENDIF IF BESCNO == MDRX62H_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (MDRX62H.inc) ; Select MDRX62H pinout ENDIF IF BESCNO == MDRX62H_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (MDRX62H.inc) ; Select MDRX62H pinout ENDIF IF BESCNO == MDRX62H_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (MDRX62H.inc) ; Select MDRX62H pinout ENDIF IF BESCNO == RotorGeeks_20A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (RotorGeeks_20A.inc) ; Select RotorGeeks 20A pinout ENDIF IF BESCNO == RotorGeeks_20A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (RotorGeeks_20A.inc) ; Select RotorGeeks 20A pinout ENDIF IF BESCNO == RotorGeeks_20A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (RotorGeeks_20A.inc) ; Select RotorGeeks 20A pinout ENDIF IF BESCNO == Flycolor_Fairy_6A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Flycolor_Fairy_6A.inc) ; Select Flycolor Fairy 6A pinout ENDIF IF BESCNO == Flycolor_Fairy_6A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Flycolor_Fairy_6A.inc) ; Select Flycolor Fairy 6A pinout ENDIF IF BESCNO == Flycolor_Fairy_6A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Flycolor_Fairy_6A.inc) ; Select Flycolor Fairy 6A pinout ENDIF IF BESCNO == Flycolor_Fairy_30A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Flycolor_Fairy_30A.inc) ; Select Flycolor Fairy 30A pinout ENDIF IF BESCNO == Flycolor_Fairy_30A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Flycolor_Fairy_30A.inc) ; Select Flycolor Fairy 30A pinout ENDIF IF BESCNO == Flycolor_Fairy_30A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Flycolor_Fairy_30A.inc) ; Select Flycolor Fairy 30A pinout ENDIF IF BESCNO == Flycolor_Raptor_20A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Flycolor_Raptor_20A.inc) ; Select Flycolor Raptor 20A pinout ENDIF IF BESCNO == Flycolor_Raptor_20A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Flycolor_Raptor_20A.inc) ; Select Flycolor Raptor 20A pinout ENDIF IF BESCNO == Flycolor_Raptor_20A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Flycolor_Raptor_20A.inc) ; Select Flycolor Raptor 20A pinout ENDIF IF BESCNO == Flycolor_Raptor_390_20A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Flycolor_Raptor_390_20A.inc) ; Select Flycolor Raptor 390 20A pinout ENDIF IF BESCNO == Flycolor_Raptor_390_20A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Flycolor_Raptor_390_20A.inc) ; Select Flycolor Raptor 390 20A pinout ENDIF IF BESCNO == Flycolor_Raptor_390_20A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Flycolor_Raptor_390_20A.inc) ; Select Flycolor Raptor 390 20A pinout ENDIF IF BESCNO == FVT_Littlebee_20A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (FVT_Littlebee_20A.inc) ; Select Favourite Littlebee 20A pinout ENDIF IF BESCNO == FVT_Littlebee_20A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (FVT_Littlebee_20A.inc) ; Select Favourite Littlebee 20A pinout ENDIF IF BESCNO == FVT_Littlebee_20A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (FVT_Littlebee_20A.inc) ; Select Favourite Littlebee 20A pinout ENDIF IF BESCNO == FVT_Littlebee_20A_Pro_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (FVT_Littlebee_20A_Pro.inc) ; Select Favourite Littlebee 20A Pro pinout ENDIF IF BESCNO == FVT_Littlebee_20A_Pro_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (FVT_Littlebee_20A_Pro.inc) ; Select Favourite Littlebee 20A Pro pinout ENDIF IF BESCNO == FVT_Littlebee_20A_Pro_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (FVT_Littlebee_20A_Pro.inc) ; Select Favourite Littlebee 20A Pro pinout ENDIF IF BESCNO == FVT_Littlebee_30A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (FVT_Littlebee_30A.inc) ; Select Favourite Littlebee 30A pinout ENDIF IF BESCNO == FVT_Littlebee_30A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (FVT_Littlebee_30A.inc) ; Select Favourite Littlebee 30A pinout ENDIF IF BESCNO == FVT_Littlebee_30A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (FVT_Littlebee_30A.inc) ; Select Favourite Littlebee 30A pinout ENDIF IF BESCNO == Graupner_Ultra_20A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Graupner_Ultra_20A.inc) ; Select Graupner Ultra 20A pinout ENDIF IF BESCNO == Graupner_Ultra_20A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Graupner_Ultra_20A.inc) ; Select Graupner Ultra 20A pinout ENDIF IF BESCNO == Graupner_Ultra_20A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Graupner_Ultra_20A.inc) ; Select Graupner Ultra 20A pinout ENDIF IF BESCNO == F85_3A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (F85_3A.inc) ; Select F85 3A pinout ENDIF IF BESCNO == F85_3A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (F85_3A.inc) ; Select F85 3A pinout ENDIF IF BESCNO == F85_3A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (F85_3A.inc) ; Select F85 3A pinout ENDIF IF BESCNO == ZTW_Spider_Pro_20A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (ZTW_Spider_Pro_20A.inc) ; Select ZTW Spider Pro 20A pinout ENDIF IF BESCNO == ZTW_Spider_Pro_20A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (ZTW_Spider_Pro_20A.inc) ; Select ZTW Spider Pro 20A pinout ENDIF IF BESCNO == ZTW_Spider_Pro_20A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (ZTW_Spider_Pro_20A.inc) ; Select ZTW Spider Pro 20A pinout ENDIF IF BESCNO == ZTW_Spider_Pro_20A_Premium_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (ZTW_Spider_Pro_20A_Premium.inc) ; Select ZTW Spider Pro 20A Premium pinout ENDIF IF BESCNO == ZTW_Spider_Pro_20A_Premium_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (ZTW_Spider_Pro_20A_Premium.inc) ; Select ZTW Spider Pro 20A Premium pinout ENDIF IF BESCNO == ZTW_Spider_Pro_20A_Premium_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (ZTW_Spider_Pro_20A_Premium.inc) ; Select ZTW Spider Pro 20A Premium pinout ENDIF IF BESCNO == ZTW_Spider_Pro_20A_HV_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (ZTW_Spider_Pro_20A_HV.inc) ; Select ZTW Spider Pro 20A HV pinout ENDIF IF BESCNO == ZTW_Spider_Pro_20A_HV_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (ZTW_Spider_Pro_20A_HV.inc) ; Select ZTW Spider Pro 20A HV pinout ENDIF IF BESCNO == ZTW_Spider_Pro_20A_HV_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (ZTW_Spider_Pro_20A_HV.inc) ; Select ZTW Spider Pro 20A HV pinout ENDIF IF BESCNO == ZTW_Spider_Pro_30A_HV_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (ZTW_Spider_Pro_30A_HV.inc) ; Select ZTW Spider Pro 30A HV pinout ENDIF IF BESCNO == ZTW_Spider_Pro_30A_HV_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (ZTW_Spider_Pro_30A_HV.inc) ; Select ZTW Spider Pro 30A HV pinout ENDIF IF BESCNO == ZTW_Spider_Pro_30A_HV_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (ZTW_Spider_Pro_30A_HV.inc) ; Select ZTW Spider Pro 30A HV pinout ENDIF IF BESCNO == DYS_XM20A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (DYS_XM20A.inc) ; Select DYS XM20A pinout ENDIF IF BESCNO == DYS_XM20A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (DYS_XM20A.inc) ; Select DYS XM20A pinout ENDIF IF BESCNO == DYS_XM20A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (DYS_XM20A.inc) ; Select DYS XM20A pinout ENDIF IF BESCNO == Oversky_MR_20A_Pro_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (Oversky_MR_20A_Pro.inc) ; Select Oversky MR-20A Pro pinout ENDIF IF BESCNO == Oversky_MR_20A_Pro_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (Oversky_MR_20A_Pro.inc) ; Select Oversky MR-20A Pro pinout ENDIF IF BESCNO == Oversky_MR_20A_Pro_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (Oversky_MR_20A_Pro.inc) ; Select Oversky MR-20A Pro pinout ENDIF IF BESCNO == TBS_Cube_12A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (TBS_Cube_12A.inc) ; Select TBS Cube 12A pinout ENDIF IF BESCNO == TBS_Cube_12A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (TBS_Cube_12A.inc) ; Select TBS Cube 12A pinout ENDIF IF BESCNO == TBS_Cube_12A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (TBS_Cube_12A.inc) ; Select TBS Cube 12A pinout ENDIF IF BESCNO == DALRC_XR20A_Main MODE EQU 0 ; Choose mode. Set to 0 for main motor $include (DALRC_XR20A.inc) ; Select DALRC 20A pinout ENDIF IF BESCNO == DALRC_XR20A_Tail MODE EQU 1 ; Choose mode. Set to 1 for tail motor $include (DALRC_XR20A.inc) ; Select DALRC 20A pinout ENDIF IF BESCNO == DALRC_XR20A_Multi MODE EQU 2 ; Choose mode. Set to 2 for multirotor $include (DALRC_XR20A.inc) ; Select DALRC 20A pinout ENDIF ;**** **** **** **** **** ; TX programming defaults ; ; Parameter dependencies: ; - Governor P gain, I gain and Range is only used if one of the three governor modes is selected ; - Governor setup target is only used if Setup governor mode is selected (or closed loop mode is on for multi) ; ; MAIN DEFAULT_PGM_MAIN_P_GAIN EQU 7 ; 1=0.13 2=0.17 3=0.25 4=0.38 5=0.50 6=0.75 7=1.00 8=1.5 9=2.0 10=3.0 11=4.0 12=6.0 13=8.0 DEFAULT_PGM_MAIN_I_GAIN EQU 7 ; 1=0.13 2=0.17 3=0.25 4=0.38 5=0.50 6=0.75 7=1.00 8=1.5 9=2.0 10=3.0 11=4.0 12=6.0 13=8.0 DEFAULT_PGM_MAIN_GOVERNOR_MODE EQU 1 ; 1=Tx 2=Arm 3=Setup 4=Off DEFAULT_PGM_MAIN_GOVERNOR_RANGE EQU 1 ; 1=High 2=Middle 3=Low DEFAULT_PGM_MAIN_LOW_VOLTAGE_LIM EQU 4 ; 1=Off 2=3.0V/c 3=3.1V/c 4=3.2V/c 5=3.3V/c 6=3.4V/c DEFAULT_PGM_MAIN_COMM_TIMING EQU 3 ; 1=Low 2=MediumLow 3=Medium 4=MediumHigh 5=High IF DAMPED_MODE_ENABLE == 1 DEFAULT_PGM_MAIN_PWM_FREQ EQU 2 ; 1=High 2=Low 3=DampedLight ELSE DEFAULT_PGM_MAIN_PWM_FREQ EQU 2 ; 1=High 2=Low ENDIF DEFAULT_PGM_MAIN_DEMAG_COMP EQU 1 ; 1=Disabled 2=Low 3=High DEFAULT_PGM_MAIN_DIRECTION EQU 1 ; 1=Normal 2=Reversed DEFAULT_PGM_MAIN_RCP_PWM_POL EQU 1 ; 1=Positive 2=Negative DEFAULT_PGM_MAIN_GOV_SETUP_TARGET EQU 180 ; Target for governor in setup mode. Corresponds to 70% throttle DEFAULT_PGM_MAIN_REARM_START EQU 0 ; 1=Enabled 0=Disabled DEFAULT_PGM_MAIN_BEEP_STRENGTH EQU 120 ; Beep strength DEFAULT_PGM_MAIN_BEACON_STRENGTH EQU 200 ; Beacon strength DEFAULT_PGM_MAIN_BEACON_DELAY EQU 4 ; 1=1m 2=2m 3=5m 4=10m 5=Infinite ; TAIL DEFAULT_PGM_TAIL_GAIN EQU 3 ; 1=0.75 2=0.88 3=1.00 4=1.12 5=1.25 DEFAULT_PGM_TAIL_IDLE_SPEED EQU 4 ; 1=Low 2=MediumLow 3=Medium 4=MediumHigh 5=High DEFAULT_PGM_TAIL_COMM_TIMING EQU 3 ; 1=Low 2=MediumLow 3=Medium 4=MediumHigh 5=High IF DAMPED_MODE_ENABLE == 1 DEFAULT_PGM_TAIL_PWM_FREQ EQU 3 ; 1=High 2=Low 3=DampedLight ELSE DEFAULT_PGM_TAIL_PWM_FREQ EQU 1 ; 1=High 2=Low ENDIF DEFAULT_PGM_TAIL_DEMAG_COMP EQU 1 ; 1=Disabled 2=Low 3=High DEFAULT_PGM_TAIL_DIRECTION EQU 1 ; 1=Normal 2=Reversed 3=Bidirectional DEFAULT_PGM_TAIL_RCP_PWM_POL EQU 1 ; 1=Positive 2=Negative DEFAULT_PGM_TAIL_BEEP_STRENGTH EQU 250 ; Beep strength DEFAULT_PGM_TAIL_BEACON_STRENGTH EQU 250 ; Beacon strength DEFAULT_PGM_TAIL_BEACON_DELAY EQU 4 ; 1=1m 2=2m 3=5m 4=10m 5=Infinite DEFAULT_PGM_TAIL_PWM_DITHER EQU 3 ; 1=Off 2=7 3=15 4=31 5=63 ; MULTI DEFAULT_PGM_MULTI_P_GAIN EQU 9 ; 1=0.13 2=0.17 3=0.25 4=0.38 5=0.50 6=0.75 7=1.00 8=1.5 9=2.0 10=3.0 11=4.0 12=6.0 13=8.0 DEFAULT_PGM_MULTI_I_GAIN EQU 9 ; 1=0.13 2=0.17 3=0.25 4=0.38 5=0.50 6=0.75 7=1.00 8=1.5 9=2.0 10=3.0 11=4.0 12=6.0 13=8.0 DEFAULT_PGM_MULTI_GOVERNOR_MODE EQU 4 ; 1=HiRange 2=MidRange 3=LoRange 4=Off DEFAULT_PGM_MULTI_GAIN EQU 3 ; 1=0.75 2=0.88 3=1.00 4=1.12 5=1.25 DEFAULT_PGM_MULTI_COMM_TIMING EQU 3 ; 1=Low 2=MediumLow 3=Medium 4=MediumHigh 5=High IF DAMPED_MODE_ENABLE == 1 DEFAULT_PGM_MULTI_PWM_FREQ EQU 3 ; 1=High 2=Low 3=DampedLight ELSE DEFAULT_PGM_MULTI_PWM_FREQ EQU 1 ; 1=High 2=Low ENDIF DEFAULT_PGM_MULTI_DEMAG_COMP EQU 2 ; 1=Disabled 2=Low 3=High DEFAULT_PGM_MULTI_DIRECTION EQU 1 ; 1=Normal 2=Reversed 3=Bidirectional DEFAULT_PGM_MULTI_RCP_PWM_POL EQU 1 ; 1=Positive 2=Negative DEFAULT_PGM_MULTI_BEEP_STRENGTH EQU 40 ; Beep strength DEFAULT_PGM_MULTI_BEACON_STRENGTH EQU 80 ; Beacon strength DEFAULT_PGM_MULTI_BEACON_DELAY EQU 4 ; 1=1m 2=2m 3=5m 4=10m 5=Infinite DEFAULT_PGM_MULTI_PWM_DITHER EQU 3 ; 1=Off 2=7 3=15 4=31 5=63 ; COMMON DEFAULT_PGM_ENABLE_TX_PROGRAM EQU 1 ; 1=Enabled 0=Disabled DEFAULT_PGM_PPM_MIN_THROTTLE EQU 37 ; 4*37+1000=1148 DEFAULT_PGM_PPM_MAX_THROTTLE EQU 208 ; 4*208+1000=1832 DEFAULT_PGM_PPM_CENTER_THROTTLE EQU 122 ; 4*122+1000=1488 (used in bidirectional mode) DEFAULT_PGM_BEC_VOLTAGE_HIGH EQU 0 ; 0=Low 1+= High or higher DEFAULT_PGM_ENABLE_TEMP_PROT EQU 1 ; 1=Enabled 0=Disabled DEFAULT_PGM_ENABLE_POWER_PROT EQU 1 ; 1=Enabled 0=Disabled DEFAULT_PGM_ENABLE_PWM_INPUT EQU 0 ; 1=Enabled 0=Disabled ;**** **** **** **** **** ; Constant definitions for main IF MODE == 0 GOV_SPOOLRATE EQU 2 ; Number of steps for governor requested pwm per 32ms RCP_TIMEOUT_PPM EQU 10 ; Number of timer2H overflows (about 32ms) before considering rc pulse lost RCP_TIMEOUT EQU 64 ; Number of timer2L overflows (about 128us) before considering rc pulse lost RCP_SKIP_RATE EQU 32 ; Number of timer2L overflows (about 128us) before reenabling rc pulse detection RCP_MIN EQU 0 ; This is minimum RC pulse length RCP_MAX EQU 255 ; This is maximum RC pulse length RCP_VALIDATE EQU 2 ; Require minimum this pulse length to validate RC pulse RCP_STOP EQU 1 ; Stop motor at or below this pulse length RCP_STOP_LIMIT EQU 250 ; Stop motor if this many timer2H overflows (~32ms) are below stop limit PWM_START EQU 50 ; PWM used as max power during start COMM_TIME_MIN EQU 1 ; Minimum time (in us) for commutation wait TEMP_CHECK_RATE EQU 8 ; Number of adc conversions for each check of temperature (the other conversions are used for voltage) ENDIF ; Constant definitions for tail IF MODE == 1 GOV_SPOOLRATE EQU 1 ; Number of steps for governor requested pwm per 32ms RCP_TIMEOUT_PPM EQU 10 ; Number of timer2H overflows (about 32ms) before considering rc pulse lost RCP_TIMEOUT EQU 24 ; Number of timer2L overflows (about 128us) before considering rc pulse lost RCP_SKIP_RATE EQU 6 ; Number of timer2L overflows (about 128us) before reenabling rc pulse detection RCP_MIN EQU 0 ; This is minimum RC pulse length RCP_MAX EQU 255 ; This is maximum RC pulse length RCP_VALIDATE EQU 2 ; Require minimum this pulse length to validate RC pulse RCP_STOP EQU 1 ; Stop motor at or below this pulse length RCP_STOP_LIMIT EQU 130 ; Stop motor if this many timer2H overflows (~32ms) are below stop limit PWM_START EQU 50 ; PWM used as max power during start COMM_TIME_MIN EQU 1 ; Minimum time (in us) for commutation wait TEMP_CHECK_RATE EQU 8 ; Number of adc conversions for each check of temperature (the other conversions are used for voltage) ENDIF ; Constant definitions for multi IF MODE == 2 GOV_SPOOLRATE EQU 1 ; Number of steps for governor requested pwm per 32ms RCP_TIMEOUT_PPM EQU 10 ; Number of timer2H overflows (about 32ms) before considering rc pulse lost RCP_TIMEOUT EQU 24 ; Number of timer2L overflows (about 128us) before considering rc pulse lost RCP_SKIP_RATE EQU 6 ; Number of timer2L overflows (about 128us) before reenabling rc pulse detection RCP_MIN EQU 0 ; This is minimum RC pulse length RCP_MAX EQU 255 ; This is maximum RC pulse length RCP_VALIDATE EQU 2 ; Require minimum this pulse length to validate RC pulse RCP_STOP EQU 1 ; Stop motor at or below this pulse length RCP_STOP_LIMIT EQU 250 ; Stop motor if this many timer2H overflows (~32ms) are below stop limit PWM_START EQU 50 ; PWM used as max power during start COMM_TIME_MIN EQU 1 ; Minimum time (in us) for commutation wait TEMP_CHECK_RATE EQU 8 ; Number of adc conversions for each check of temperature (the other conversions are used for voltage) ENDIF ;**** **** **** **** **** ; Temporary register definitions Temp1 EQU R0 Temp2 EQU R1 Temp3 EQU R2 Temp4 EQU R3 Temp5 EQU R4 Temp6 EQU R5 Temp7 EQU R6 Temp8 EQU R7 ;**** **** **** **** **** ; Register definitions DSEG AT 20h ; Variables segment Bit_Access: DS 1 ; MUST BE AT THIS ADDRESS. Variable at bit accessible address (for non interrupt routines) Bit_Access_Int: DS 1 ; Variable at bit accessible address (for interrupts) Requested_Pwm: DS 1 ; Requested pwm (from RC pulse value) Governor_Req_Pwm: DS 1 ; Governor requested pwm (sets governor target) Current_Pwm: DS 1 ; Current pwm Current_Pwm_Limited: DS 1 ; Current pwm that is limited Current_Pwm_Lim_Dith: DS 1 ; Current pwm that is limited and dithered (applied to the motor output) Rcp_Prev_Edge_L: DS 1 ; RC pulse previous edge timer3 timestamp (lo byte) Rcp_Prev_Edge_H: DS 1 ; RC pulse previous edge timer3 timestamp (hi byte) Rcp_Outside_Range_Cnt: DS 1 ; RC pulse outside range counter (incrementing) Rcp_Timeout_Cntd: DS 1 ; RC pulse timeout counter (decrementing) Rcp_Skip_Cntd: DS 1 ; RC pulse skip counter (decrementing) Flags0: DS 1 ; State flags. Reset upon init_start T3_PENDING EQU 0 ; Timer3 pending flag RCP_MEAS_PWM_FREQ EQU 1 ; Measure RC pulse pwm frequency PWM_ON EQU 2 ; Set in on part of pwm cycle PWM_TIMER0_OVERFLOW EQU 3 ; Set for 48MHz MCUs when PWM timer 0 overflows DEMAG_ENABLED EQU 4 ; Set when demag compensation is enabled (above a min speed and throttle) DEMAG_DETECTED EQU 5 ; Set when excessive demag time is detected DEMAG_CUT_POWER EQU 6 ; Set when demag compensation cuts power HIGH_RPM EQU 7 ; Set when motor rpm is high (Comm_Period4x_H less than 2) Flags1: DS 1 ; State flags. Reset upon init_start MOTOR_SPINNING EQU 0 ; Set when in motor is spinning STARTUP_PHASE EQU 1 ; Set when in startup phase INITIAL_RUN_PHASE EQU 2 ; Set when in initial run phase, before synchronized run is achieved DIR_CHANGE_BRAKE EQU 3 ; Set when braking before direction change COMP_TIMED_OUT EQU 4 ; Set when comparator reading timed out GOV_ACTIVE EQU 5 ; Set when governor is active (enabled when speed is above minimum) SKIP_DAMP_ON EQU 6 ; Set when turning damping fet on is skipped ; EQU 7 Flags2: DS 1 ; State flags. NOT reset upon init_start RCP_UPDATED EQU 0 ; New RC pulse length value available RCP_EDGE_NO EQU 1 ; RC pulse edge no. 0=rising, 1=falling PGM_PWMOFF_DAMPED EQU 2 ; Programmed pwm off damped mode PGM_PWM_HIGH_FREQ EQU 3 ; Progremmed pwm high frequency RCP_PPM EQU 4 ; RC pulse ppm type input (set also when oneshot is set) RCP_PPM_ONESHOT125 EQU 5 ; RC pulse ppm type input is OneShot125 RCP_DIR_REV EQU 6 ; RC pulse direction in bidirectional mode ; EQU 7 Flags3: DS 1 ; State flags. NOT reset upon init_start RCP_PWM_FREQ_1KHZ EQU 0 ; RC pulse pwm frequency is 1kHz RCP_PWM_FREQ_2KHZ EQU 1 ; RC pulse pwm frequency is 2kHz RCP_PWM_FREQ_4KHZ EQU 2 ; RC pulse pwm frequency is 4kHz RCP_PWM_FREQ_8KHZ EQU 3 ; RC pulse pwm frequency is 8kHz RCP_PWM_FREQ_12KHZ EQU 4 ; RC pulse pwm frequency is 12kHz PGM_DIR_REV EQU 5 ; Programmed direction. 0=normal, 1=reversed PGM_RCP_PWM_POL EQU 6 ; Programmed RC pulse pwm polarity. 0=positive, 1=negative FULL_THROTTLE_RANGE EQU 7 ; When set full throttle range is used (1000-2000us) and stored calibration values are ignored ;**** **** **** **** **** ; RAM definitions DSEG AT 30h ; Ram data segment, direct addressing Initial_Arm: DS 1 ; Variable that is set during the first arm sequence after power on Power_On_Wait_Cnt_L: DS 1 ; Power on wait counter (lo byte) Power_On_Wait_Cnt_H: DS 1 ; Power on wait counter (hi byte) Startup_Cnt: DS 1 ; Startup phase commutations counter (incrementing) Startup_Zc_Timeout_Cntd: DS 1 ; Startup zero cross timeout counter (decrementing) Initial_Run_Rot_Cnt: DS 1 ; Initial run rotations counter (incrementing) Stall_Cnt: DS 1 ; Counts start/run attempts that resulted in stall. Reset upon a proper stop Demag_Detected_Metric: DS 1 ; Metric used to gauge demag event frequency Demag_Pwr_Off_Thresh: DS 1 ; Metric threshold above which power is cut Low_Rpm_Pwr_Slope: DS 1 ; Sets the slope of power increase for low rpms Timer2_X: DS 1 ; Timer 2 extended byte Prev_Comm_L: DS 1 ; Previous commutation timer3 timestamp (lo byte) Prev_Comm_H: DS 1 ; Previous commutation timer3 timestamp (hi byte) Prev_Comm_X: DS 1 ; Previous commutation timer3 timestamp (ext byte) Prev_Prev_Comm_L: DS 1 ; Pre-previous commutation timer3 timestamp (lo byte) Prev_Prev_Comm_H: DS 1 ; Pre-previous commutation timer3 timestamp (hi byte) Comm_Period4x_L: DS 1 ; Timer3 counts between the last 4 commutations (lo byte) Comm_Period4x_H: DS 1 ; Timer3 counts between the last 4 commutations (hi byte) Comm_Diff: DS 1 ; Timer3 count difference between the last two commutations Comm_Phase: DS 1 ; Current commutation phase Comparator_Read_Cnt: DS 1 ; Number of comparator reads done Gov_Target_L: DS 1 ; Governor target (lo byte) Gov_Target_H: DS 1 ; Governor target (hi byte) Gov_Integral_L: DS 1 ; Governor integral error (lo byte) Gov_Integral_H: DS 1 ; Governor integral error (hi byte) Gov_Integral_X: DS 1 ; Governor integral error (ex byte) Gov_Proportional_L: DS 1 ; Governor proportional error (lo byte) Gov_Proportional_H: DS 1 ; Governor proportional error (hi byte) Gov_Prop_Pwm: DS 1 ; Governor calculated new pwm based upon proportional error Gov_Arm_Target: DS 1 ; Governor arm target value Wt_Adv_Start_L: DS 1 ; Timer3 start point for commutation advance timing (lo byte) Wt_Adv_Start_H: DS 1 ; Timer3 start point for commutation advance timing (hi byte) Wt_Zc_Scan_Start_L: DS 1 ; Timer3 start point from commutation to zero cross scan (lo byte) Wt_Zc_Scan_Start_H: DS 1 ; Timer3 start point from commutation to zero cross scan (hi byte) Wt_Zc_Tout_Start_L: DS 1 ; Timer3 start point for zero cross scan timeout (lo byte) Wt_Zc_Tout_Start_H: DS 1 ; Timer3 start point for zero cross scan timeout (hi byte) Wt_Comm_Start_L: DS 1 ; Timer3 start point from zero cross to commutation (lo byte) Wt_Comm_Start_H: DS 1 ; Timer3 start point from zero cross to commutation (hi byte) Next_Wt_Start_L: DS 1 ; Timer3 start point for next wait period (lo byte) Next_Wt_Start_H: DS 1 ; Timer3 start point for next wait period (hi byte) Rcp_PrePrev_Edge_L: DS 1 ; RC pulse pre previous edge pca timestamp (lo byte) Rcp_PrePrev_Edge_H: DS 1 ; RC pulse pre previous edge pca timestamp (hi byte) Rcp_Edge_L: DS 1 ; RC pulse edge pca timestamp (lo byte) Rcp_Edge_H: DS 1 ; RC pulse edge pca timestamp (hi byte) Rcp_Prev_Period_L: DS 1 ; RC pulse previous period (lo byte) Rcp_Prev_Period_H: DS 1 ; RC pulse previous period (hi byte) Rcp_Period_Diff_Accepted: DS 1 ; RC pulse period difference acceptable New_Rcp: DS 1 ; New RC pulse value in pca counts Prev_Rcp_Pwm_Freq: DS 1 ; Previous RC pulse pwm frequency (used during pwm frequency measurement) Curr_Rcp_Pwm_Freq: DS 1 ; Current RC pulse pwm frequency (used during pwm frequency measurement) Rcp_Stop_Cnt: DS 1 ; Counter for RC pulses below stop value Auto_Bailout_Armed: DS 1 ; Set when auto rotation bailout is armed Pwm_Limit: DS 1 ; Maximum allowed pwm Pwm_Limit_Spoolup: DS 1 ; Maximum allowed pwm during spoolup Pwm_Limit_By_Rpm: DS 1 ; Maximum allowed pwm for low or high rpms Pwm_Spoolup_Beg: DS 1 ; Pwm to begin main spoolup with Pwm_Motor_Idle: DS 1 ; Motor idle speed pwm Pwm_Dither_Decoded: DS 1 ; Decoded pwm dither value Pwm_Dither_Excess_Power: DS 1 ; Excess power (above max) from pwm dither Random: DS 1 ; Random number from LFSR Spoolup_Limit_Cnt: DS 1 ; Interrupt count for spoolup limit Spoolup_Limit_Skip: DS 1 ; Interrupt skips for spoolup limit increment (1=no skips, 2=skip one etc) Main_Spoolup_Time_3x: DS 1 ; Main spoolup time x3 Main_Spoolup_Time_10x: DS 1 ; Main spoolup time x10 Main_Spoolup_Time_15x: DS 1 ; Main spoolup time x15 Lipo_Adc_Limit_L: DS 1 ; Low voltage limit adc value (lo byte) Lipo_Adc_Limit_H: DS 1 ; Low voltage limit adc value (hi byte) Adc_Conversion_Cnt: DS 1 ; Adc conversion counter Current_Average_Temp: DS 1 ; Current average temperature (lo byte ADC reading, assuming hi byte is 1) Ppm_Throttle_Gain: DS 1 ; Gain to be applied to RCP value for PPM input Beep_Strength: DS 1 ; Strength of beeps Tx_Pgm_Func_No: DS 1 ; Function number when doing programming by tx Tx_Pgm_Paraval_No: DS 1 ; Parameter value number when doing programming by tx Tx_Pgm_Beep_No: DS 1 ; Beep number when doing programming by tx Skip_T2_Int: DS 1 ; Set for 48MHz MCUs when timer 2 interrupt shall be ignored Skip_T2h_Int: DS 1 ; Set for 48MHz MCUs when timer 2 high interrupt shall be ignored Timer0_Overflow_Value: DS 1 ; Remaining timer 0 wait time used with 48MHz MCUs Clock_Set_At_48MHz: DS 1 ; Variable set if 48MHz MCUs run at 48MHz DampingFET: DS 1 ; Port position of fet used for damping ; Indirect addressing data segment. The variables below must be in this sequence ISEG AT 080h Pgm_Gov_P_Gain: DS 1 ; Programmed governor P gain Pgm_Gov_I_Gain: DS 1 ; Programmed governor I gain Pgm_Gov_Mode: DS 1 ; Programmed governor mode Pgm_Low_Voltage_Lim: DS 1 ; Programmed low voltage limit Pgm_Motor_Gain: DS 1 ; Programmed motor gain Pgm_Motor_Idle: DS 1 ; Programmed motor idle speed Pgm_Startup_Pwr: DS 1 ; Programmed startup power Pgm_Pwm_Freq: DS 1 ; Programmed pwm frequency Pgm_Direction: DS 1 ; Programmed rotation direction Pgm_Input_Pol: DS 1 ; Programmed input pwm polarity Initialized_L_Dummy: DS 1 ; Place holder Initialized_H_Dummy: DS 1 ; Place holder Pgm_Enable_TX_Program: DS 1 ; Programmed enable/disable value for TX programming Pgm_Main_Rearm_Start: DS 1 ; Programmed enable/disable re-arming main every start Pgm_Gov_Setup_Target: DS 1 ; Programmed main governor setup target _Pgm_Startup_Rpm: DS 1 ; Programmed startup rpm (unused - place holder) _Pgm_Startup_Accel: DS 1 ; Programmed startup acceleration (unused - place holder) _Pgm_Volt_Comp: DS 1 ; Place holder Pgm_Comm_Timing: DS 1 ; Programmed commutation timing _Pgm_Damping_Force: DS 1 ; Programmed damping force (unused - place holder) Pgm_Gov_Range: DS 1 ; Programmed governor range _Pgm_Startup_Method: DS 1 ; Programmed startup method (unused - place holder) Pgm_Ppm_Min_Throttle: DS 1 ; Programmed throttle minimum Pgm_Ppm_Max_Throttle: DS 1 ; Programmed throttle maximum Pgm_Beep_Strength: DS 1 ; Programmed beep strength Pgm_Beacon_Strength: DS 1 ; Programmed beacon strength Pgm_Beacon_Delay: DS 1 ; Programmed beacon delay _Pgm_Throttle_Rate: DS 1 ; Programmed throttle rate (unused - place holder) Pgm_Demag_Comp: DS 1 ; Programmed demag compensation Pgm_BEC_Voltage_High: DS 1 ; Programmed BEC voltage Pgm_Ppm_Center_Throttle: DS 1 ; Programmed throttle center (in bidirectional mode) Pgm_Main_Spoolup_Time: DS 1 ; Programmed main spoolup time Pgm_Enable_Temp_Prot: DS 1 ; Programmed temperature protection enable Pgm_Enable_Power_Prot: DS 1 ; Programmed low rpm power protection enable Pgm_Enable_Pwm_Input: DS 1 ; Programmed PWM input signal enable Pgm_Pwm_Dither: DS 1 ; Programmed output PWM dither ; The sequence of the variables below is no longer of importance Pgm_Gov_P_Gain_Decoded: DS 1 ; Programmed governor decoded P gain Pgm_Gov_I_Gain_Decoded: DS 1 ; Programmed governor decoded I gain Pgm_Startup_Pwr_Decoded: DS 1 ; Programmed startup power decoded ; Indirect addressing data segment ISEG AT 0D0h Tag_Temporary_Storage: DS 48 ; Temporary storage for tags when updating "Eeprom" ;**** **** **** **** **** CSEG AT 1A00h ; "Eeprom" segment EEPROM_FW_MAIN_REVISION EQU 14 ; Main revision of the firmware EEPROM_FW_SUB_REVISION EQU 4 ; Sub revision of the firmware EEPROM_LAYOUT_REVISION EQU 20 ; Revision of the EEPROM layout Eep_FW_Main_Revision: DB EEPROM_FW_MAIN_REVISION ; EEPROM firmware main revision number Eep_FW_Sub_Revision: DB EEPROM_FW_SUB_REVISION ; EEPROM firmware sub revision number Eep_Layout_Revision: DB EEPROM_LAYOUT_REVISION ; EEPROM layout revision number IF MODE == 0 Eep_Pgm_Gov_P_Gain: DB DEFAULT_PGM_MAIN_P_GAIN ; EEPROM copy of programmed governor P gain Eep_Pgm_Gov_I_Gain: DB DEFAULT_PGM_MAIN_I_GAIN ; EEPROM copy of programmed governor I gain Eep_Pgm_Gov_Mode: DB DEFAULT_PGM_MAIN_GOVERNOR_MODE ; EEPROM copy of programmed governor mode Eep_Pgm_Low_Voltage_Lim: DB DEFAULT_PGM_MAIN_LOW_VOLTAGE_LIM ; EEPROM copy of programmed low voltage limit _Eep_Pgm_Motor_Gain: DB 0FFh _Eep_Pgm_Motor_Idle: DB 0FFh Eep_Pgm_Startup_Pwr: DB DEFAULT_PGM_MAIN_STARTUP_PWR ; EEPROM copy of programmed startup power Eep_Pgm_Pwm_Freq: DB DEFAULT_PGM_MAIN_PWM_FREQ ; EEPROM copy of programmed pwm frequency Eep_Pgm_Direction: DB DEFAULT_PGM_MAIN_DIRECTION ; EEPROM copy of programmed rotation direction Eep_Pgm_Input_Pol: DB DEFAULT_PGM_MAIN_RCP_PWM_POL ; EEPROM copy of programmed input polarity Eep_Initialized_L: DB 0A5h ; EEPROM initialized signature low byte Eep_Initialized_H: DB 05Ah ; EEPROM initialized signature high byte Eep_Enable_TX_Program: DB DEFAULT_PGM_ENABLE_TX_PROGRAM ; EEPROM TX programming enable Eep_Main_Rearm_Start: DB DEFAULT_PGM_MAIN_REARM_START ; EEPROM re-arming main enable Eep_Pgm_Gov_Setup_Target: DB DEFAULT_PGM_MAIN_GOV_SETUP_TARGET ; EEPROM main governor setup target _Eep_Pgm_Startup_Rpm: DB 0FFh _Eep_Pgm_Startup_Accel: DB 0FFh _Eep_Pgm_Volt_Comp: DB 0FFh Eep_Pgm_Comm_Timing: DB DEFAULT_PGM_MAIN_COMM_TIMING ; EEPROM copy of programmed commutation timing _Eep_Pgm_Damping_Force: DB 0FFh Eep_Pgm_Gov_Range: DB DEFAULT_PGM_MAIN_GOVERNOR_RANGE ; EEPROM copy of programmed governor range _Eep_Pgm_Startup_Method: DB 0FFh Eep_Pgm_Ppm_Min_Throttle: DB DEFAULT_PGM_PPM_MIN_THROTTLE ; EEPROM copy of programmed minimum throttle (final value is 4x+1000=1148) Eep_Pgm_Ppm_Max_Throttle: DB DEFAULT_PGM_PPM_MAX_THROTTLE ; EEPROM copy of programmed minimum throttle (final value is 4x+1000=1832) Eep_Pgm_Beep_Strength: DB DEFAULT_PGM_MAIN_BEEP_STRENGTH ; EEPROM copy of programmed beep strength Eep_Pgm_Beacon_Strength: DB DEFAULT_PGM_MAIN_BEACON_STRENGTH ; EEPROM copy of programmed beacon strength Eep_Pgm_Beacon_Delay: DB DEFAULT_PGM_MAIN_BEACON_DELAY ; EEPROM copy of programmed beacon delay _Eep_Pgm_Throttle_Rate: DB 0FFh Eep_Pgm_Demag_Comp: DB DEFAULT_PGM_MAIN_DEMAG_COMP ; EEPROM copy of programmed demag compensation Eep_Pgm_BEC_Voltage_High: DB DEFAULT_PGM_BEC_VOLTAGE_HIGH ; EEPROM copy of programmed BEC voltage _Eep_Pgm_Ppm_Center_Throttle: DB 0FFh Eep_Pgm_Main_Spoolup_Time: DB DEFAULT_PGM_MAIN_SPOOLUP_TIME ; EEPROM copy of programmed main spoolup time Eep_Pgm_Temp_Prot_Enable: DB DEFAULT_PGM_ENABLE_TEMP_PROT ; EEPROM copy of programmed temperature protection enable Eep_Pgm_Enable_Power_Prot: DB DEFAULT_PGM_ENABLE_POWER_PROT ; EEPROM copy of programmed low rpm power protection enable Eep_Pgm_Enable_Pwm_Input: DB DEFAULT_PGM_ENABLE_PWM_INPUT ; EEPROM copy of programmed PWM input signal enable _Eep_Pgm_Pwm_Dither: DB 0FFh ENDIF IF MODE == 1 _Eep_Pgm_Gov_P_Gain: DB 0FFh _Eep_Pgm_Gov_I_Gain: DB 0FFh _Eep_Pgm_Gov_Mode: DB 0FFh _Eep_Pgm_Low_Voltage_Lim: DB 0FFh Eep_Pgm_Motor_Gain: DB DEFAULT_PGM_TAIL_GAIN ; EEPROM copy of programmed tail gain Eep_Pgm_Motor_Idle: DB DEFAULT_PGM_TAIL_IDLE_SPEED ; EEPROM copy of programmed tail idle speed Eep_Pgm_Startup_Pwr: DB DEFAULT_PGM_TAIL_STARTUP_PWR ; EEPROM copy of programmed startup power Eep_Pgm_Pwm_Freq: DB DEFAULT_PGM_TAIL_PWM_FREQ ; EEPROM copy of programmed pwm frequency Eep_Pgm_Direction: DB DEFAULT_PGM_TAIL_DIRECTION ; EEPROM copy of programmed rotation direction Eep_Pgm_Input_Pol: DB DEFAULT_PGM_TAIL_RCP_PWM_POL ; EEPROM copy of programmed input polarity Eep_Initialized_L: DB 05Ah ; EEPROM initialized signature low byte Eep_Initialized_H: DB 0A5h ; EEPROM initialized signature high byte Eep_Enable_TX_Program: DB DEFAULT_PGM_ENABLE_TX_PROGRAM ; EEPROM TX programming enable _Eep_Main_Rearm_Start: DB 0FFh _Eep_Pgm_Gov_Setup_Target: DB 0FFh _Eep_Pgm_Startup_Rpm: DB 0FFh _Eep_Pgm_Startup_Accel: DB 0FFh _Eep_Pgm_Volt_Comp: DB 0FFh Eep_Pgm_Comm_Timing: DB DEFAULT_PGM_TAIL_COMM_TIMING ; EEPROM copy of programmed commutation timing _Eep_Pgm_Damping_Force: DB 0FFh _Eep_Pgm_Gov_Range: DB 0FFh _Eep_Pgm_Startup_Method: DB 0FFh Eep_Pgm_Ppm_Min_Throttle: DB DEFAULT_PGM_PPM_MIN_THROTTLE ; EEPROM copy of programmed minimum throttle (final value is 4x+1000=1148) Eep_Pgm_Ppm_Max_Throttle: DB DEFAULT_PGM_PPM_MAX_THROTTLE ; EEPROM copy of programmed minimum throttle (final value is 4x+1000=1832) Eep_Pgm_Beep_Strength: DB DEFAULT_PGM_TAIL_BEEP_STRENGTH ; EEPROM copy of programmed beep strength Eep_Pgm_Beacon_Strength: DB DEFAULT_PGM_TAIL_BEACON_STRENGTH ; EEPROM copy of programmed beacon strength Eep_Pgm_Beacon_Delay: DB DEFAULT_PGM_TAIL_BEACON_DELAY ; EEPROM copy of programmed beacon delay _Eep_Pgm_Throttle_Rate: DB 0FFh Eep_Pgm_Demag_Comp: DB DEFAULT_PGM_TAIL_DEMAG_COMP ; EEPROM copy of programmed demag compensation Eep_Pgm_BEC_Voltage_High: DB DEFAULT_PGM_BEC_VOLTAGE_HIGH ; EEPROM copy of programmed BEC voltage Eep_Pgm_Ppm_Center_Throttle: DB DEFAULT_PGM_PPM_CENTER_THROTTLE ; EEPROM copy of programmed center throttle (final value is 4x+1000=1488) _Eep_Pgm_Main_Spoolup_Time: DB 0FFh Eep_Pgm_Temp_Prot_Enable: DB DEFAULT_PGM_ENABLE_TEMP_PROT ; EEPROM copy of programmed temperature protection enable Eep_Pgm_Enable_Power_Prot: DB DEFAULT_PGM_ENABLE_POWER_PROT ; EEPROM copy of programmed low rpm power protection enable Eep_Pgm_Enable_Pwm_Input: DB DEFAULT_PGM_ENABLE_PWM_INPUT ; EEPROM copy of programmed PWM input signal enable Eep_Pgm_Pwm_Dither: DB DEFAULT_PGM_TAIL_PWM_DITHER ; EEPROM copy of programmed output PWM dither ENDIF IF MODE == 2 Eep_Pgm_Gov_P_Gain: DB DEFAULT_PGM_MULTI_P_GAIN ; EEPROM copy of programmed closed loop P gain Eep_Pgm_Gov_I_Gain: DB DEFAULT_PGM_MULTI_I_GAIN ; EEPROM copy of programmed closed loop I gain Eep_Pgm_Gov_Mode: DB DEFAULT_PGM_MULTI_GOVERNOR_MODE ; EEPROM copy of programmed closed loop mode _Eep_Pgm_Low_Voltage_Lim: DB 0FFh Eep_Pgm_Motor_Gain: DB DEFAULT_PGM_MULTI_GAIN ; EEPROM copy of programmed tail gain _Eep_Pgm_Motor_Idle: DB 0FFh ; EEPROM copy of programmed tail idle speed Eep_Pgm_Startup_Pwr: DB DEFAULT_PGM_MULTI_STARTUP_PWR ; EEPROM copy of programmed startup power Eep_Pgm_Pwm_Freq: DB DEFAULT_PGM_MULTI_PWM_FREQ ; EEPROM copy of programmed pwm frequency Eep_Pgm_Direction: DB DEFAULT_PGM_MULTI_DIRECTION ; EEPROM copy of programmed rotation direction Eep_Pgm_Input_Pol: DB DEFAULT_PGM_MULTI_RCP_PWM_POL ; EEPROM copy of programmed input polarity Eep_Initialized_L: DB 055h ; EEPROM initialized signature low byte Eep_Initialized_H: DB 0AAh ; EEPROM initialized signature high byte Eep_Enable_TX_Program: DB DEFAULT_PGM_ENABLE_TX_PROGRAM ; EEPROM TX programming enable _Eep_Main_Rearm_Start: DB 0FFh _Eep_Pgm_Gov_Setup_Target: DB 0FFh _Eep_Pgm_Startup_Rpm: DB 0FFh _Eep_Pgm_Startup_Accel: DB 0FFh _Eep_Pgm_Volt_Comp: DB 0FFh Eep_Pgm_Comm_Timing: DB DEFAULT_PGM_MULTI_COMM_TIMING ; EEPROM copy of programmed commutation timing _Eep_Pgm_Damping_Force: DB 0FFh _Eep_Pgm_Gov_Range: DB 0FFh _Eep_Pgm_Startup_Method: DB 0FFh Eep_Pgm_Ppm_Min_Throttle: DB DEFAULT_PGM_PPM_MIN_THROTTLE ; EEPROM copy of programmed minimum throttle (final value is 4x+1000=1148) Eep_Pgm_Ppm_Max_Throttle: DB DEFAULT_PGM_PPM_MAX_THROTTLE ; EEPROM copy of programmed minimum throttle (final value is 4x+1000=1832) Eep_Pgm_Beep_Strength: DB DEFAULT_PGM_MULTI_BEEP_STRENGTH ; EEPROM copy of programmed beep strength Eep_Pgm_Beacon_Strength: DB DEFAULT_PGM_MULTI_BEACON_STRENGTH ; EEPROM copy of programmed beacon strength Eep_Pgm_Beacon_Delay: DB DEFAULT_PGM_MULTI_BEACON_DELAY ; EEPROM copy of programmed beacon delay _Eep_Pgm_Throttle_Rate: DB 0FFh Eep_Pgm_Demag_Comp: DB DEFAULT_PGM_MULTI_DEMAG_COMP ; EEPROM copy of programmed demag compensation Eep_Pgm_BEC_Voltage_High: DB DEFAULT_PGM_BEC_VOLTAGE_HIGH ; EEPROM copy of programmed BEC voltage Eep_Pgm_Ppm_Center_Throttle: DB DEFAULT_PGM_PPM_CENTER_THROTTLE ; EEPROM copy of programmed center throttle (final value is 4x+1000=1488) _Eep_Pgm_Main_Spoolup_Time: DB 0FFh Eep_Pgm_Temp_Prot_Enable: DB DEFAULT_PGM_ENABLE_TEMP_PROT ; EEPROM copy of programmed temperature protection enable Eep_Pgm_Enable_Power_Prot: DB DEFAULT_PGM_ENABLE_POWER_PROT ; EEPROM copy of programmed low rpm power protection enable Eep_Pgm_Enable_Pwm_Input: DB DEFAULT_PGM_ENABLE_PWM_INPUT ; EEPROM copy of programmed PWM input signal enable Eep_Pgm_Pwm_Dither: DB DEFAULT_PGM_MULTI_PWM_DITHER ; EEPROM copy of programmed output PWM dither ENDIF Eep_Dummy: DB 0FFh ; EEPROM address for safety reason CSEG AT 1A60h Eep_Name: DB " " ; Name tag (16 Bytes) ;**** **** **** **** **** Interrupt_Table_Definition ; SiLabs interrupts CSEG AT 80h ; Code segment after interrupt vectors ;**** **** **** **** **** ; Table definitions GOV_GAIN_TABLE: DB 02h, 03h, 04h, 06h, 08h, 0Ch, 10h, 18h, 20h, 30h, 40h, 60h, 80h STARTUP_POWER_TABLE: DB 04h, 06h, 08h, 0Ch, 10h, 18h, 20h, 30h, 40h, 60h, 80h, 0A0h, 0C0h PWM_DITHER_TABLE: DB 00h, 07h, 0Fh, 1Fh, 3Fh IF MODE == 0 IF DAMPED_MODE_ENABLE == 1 TX_PGM_PARAMS_MAIN: DB 13, 13, 4, 3, 6, 13, 5, 3, 3, 2, 2 ENDIF IF DAMPED_MODE_ENABLE == 0 TX_PGM_PARAMS_MAIN: DB 13, 13, 4, 3, 6, 13, 5, 2, 3, 2, 2 ENDIF ENDIF IF MODE == 1 IF DAMPED_MODE_ENABLE == 1 TX_PGM_PARAMS_TAIL: DB 5, 5, 13, 5, 3, 5, 3, 3, 2 ENDIF IF DAMPED_MODE_ENABLE == 0 TX_PGM_PARAMS_TAIL: DB 5, 5, 13, 5, 2, 5, 3, 3, 2 ENDIF ENDIF IF MODE == 2 IF DAMPED_MODE_ENABLE == 1 TX_PGM_PARAMS_MULTI: DB 13, 13, 4, 5, 13, 5, 3, 5, 3, 3, 2 ENDIF IF DAMPED_MODE_ENABLE == 0 TX_PGM_PARAMS_MULTI: DB 13, 13, 4, 5, 13, 5, 2, 5, 3, 3, 2 ENDIF ENDIF ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Timer0 interrupt routine ; ; Assumptions: DPTR register must be set to desired pwm_nfet_on label ; Requirements: Temp variables can NOT be used since PSW.3 is not set ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** t0_int: ; Used for pwm control clr EA ; Disable all interrupts IF MCU_48MHZ == 1 ; Check overflow flag jnb Flags0.PWM_TIMER0_OVERFLOW, t0_int_start; Execute this interrupt clr Flags0.PWM_TIMER0_OVERFLOW mov TL0, Timer0_Overflow_Value ; Set timer setb EA ; Enable all interrupts reti t0_int_start: ENDIF push PSW ; Preserve registers through interrupt push ACC ; Check if pwm is on jb Flags0.PWM_ON, t0_int_pwm_off ; Is pwm on? ; Pwm on cycle mov A, Current_Pwm_Limited jz t0_int_pwm_on_exit clr A jmp @A+DPTR ; Jump to pwm on routines. DPTR should be set to one of the pwm_nfet_on labels t0_int_pwm_on_exit: ; Set timer for coming on cycle length mov A, Current_Pwm_Limited ; Load current pwm cpl A ; cpl is 255-x IF MCU_48MHZ == 0 mov TL0, A ; Write start point for timer ELSE clr C rlc A jc t0_int_pwm_on_set_timer mov TL0, #0 setb Flags0.PWM_TIMER0_OVERFLOW mov Timer0_Overflow_Value, A ajmp t0_int_pwm_on_timer_set t0_int_pwm_on_set_timer: mov TL0, A t0_int_pwm_on_timer_set: ENDIF ; Set other variables mov TL1, #0 ; Reset timer1 IF MCU_48MHZ == 1 mov TH1, #0 ENDIF setb Flags0.PWM_ON ; Set pwm on flag ; Exit interrupt pop ACC ; Restore preserved registers pop PSW setb EA ; Enable all interrupts reti ; Pwm off cycle t0_int_pwm_off: IF MCU_48MHZ == 0 mov TL0, Current_Pwm_Lim_Dith ; Load new timer setting ELSE clr C mov A, Current_Pwm_Lim_Dith rlc A jc t0_int_pwm_off_set_timer mov TL0, #0 setb Flags0.PWM_TIMER0_OVERFLOW mov Timer0_Overflow_Value, A ajmp t0_int_pwm_off_timer_set t0_int_pwm_off_set_timer: mov TL0, A t0_int_pwm_off_timer_set: ENDIF ; Clear pwm on flag clr Flags0.PWM_ON ; Set full PWM (on all the time) if current PWM near max. This will give full power, but at the cost of a small "jump" in power mov A, Current_Pwm_Lim_Dith ; Load current pwm cpl A ; Full pwm? jz t0_int_pwm_off_fullpower_exit ; Yes - exit IF DAMPED_MODE_ENABLE == 1 ; Do not execute damped pwm when stopped jnb Flags1.MOTOR_SPINNING, t0_int_pwm_off_exit_nfets_off ; If damped operation, set pFETs on in pwm_off jb Flags2.PGM_PWMOFF_DAMPED, t0_int_pwm_off_damped ; Damped operation? ENDIF t0_int_pwm_off_exit_nfets_off: ; Separate exit commands here for minimum delay mov TL1, #0 ; Reset timer1 IF MCU_48MHZ == 1 mov TH1, #0 ENDIF pop ACC ; Restore preserved registers pop PSW All_nFETs_Off ; Switch off all nfets setb EA ; Enable all interrupts reti t0_int_pwm_off_damped: IF PFETON_DELAY < 128 All_nFETs_Off ; Switch off all nfets jb Flags1.SKIP_DAMP_ON, t0_int_pwm_off_damp_done jb Flags0.DEMAG_CUT_POWER, t0_int_pwm_off_damp_done IF PFETON_DELAY NE 0 mov A, #PFETON_DELAY djnz ACC, $ ENDIF Damping_FET_on t0_int_pwm_off_damp_done: ENDIF IF PFETON_DELAY >= 128 ; "Negative", 1's complement jb Flags1.SKIP_DAMP_ON, t0_int_pwm_off_damp_done jb Flags0.DEMAG_CUT_POWER, t0_int_pwm_off_damp_done Damping_FET_on ; Damping fet on mov A, #PFETON_DELAY cpl A djnz ACC, $ t0_int_pwm_off_damp_done: All_nFETs_Off ; Switch off all nfets ENDIF t0_int_pwm_off_exit: mov TL1, #0 ; Reset timer1 IF MCU_48MHZ == 1 mov TH1, #0 ENDIF pop ACC ; Restore preserved registers pop PSW setb EA ; Enable all interrupts reti t0_int_pwm_off_fullpower_exit: mov TL0, #0 ; Set long time till next interrupt IF MCU_48MHZ == 1 setb Flags0.PWM_TIMER0_OVERFLOW mov Timer0_Overflow_Value, #0 ENDIF clr TF0 ; Clear interrupt flag setb Flags0.PWM_ON ajmp t0_int_pwm_off_exit pwm_nofet: ; Dummy pwm on cycle ajmp t0_int_pwm_on_exit pwm_afet: ; Pwm on cycle afet on jnb Flags1.MOTOR_SPINNING, pwm_afet_exit jb Flags0.DEMAG_CUT_POWER, pwm_afet_exit AnFET_on pwm_afet_exit: ajmp t0_int_pwm_on_exit pwm_bfet: ; Pwm on cycle bfet on jnb Flags1.MOTOR_SPINNING, pwm_bfet_exit jb Flags0.DEMAG_CUT_POWER, pwm_bfet_exit BnFET_on pwm_bfet_exit: ajmp t0_int_pwm_on_exit pwm_cfet: ; Pwm on cycle cfet on jnb Flags1.MOTOR_SPINNING, pwm_cfet_exit jb Flags0.DEMAG_CUT_POWER, pwm_cfet_exit CnFET_on pwm_cfet_exit: ajmp t0_int_pwm_on_exit pwm_afet_damped: ApFET_off jnb Flags1.MOTOR_SPINNING, pwm_afet_damped_exit jb Flags0.DEMAG_CUT_POWER, pwm_afet_damped_exit IF NFETON_DELAY NE 0 mov A, #NFETON_DELAY ; Set delay djnz ACC, $ ENDIF pwm_afet_damped_done: AnFET_on ; Switch nFET pwm_afet_damped_exit: ajmp t0_int_pwm_on_exit pwm_bfet_damped: BpFET_off jnb Flags1.MOTOR_SPINNING, pwm_bfet_damped_exit jb Flags0.DEMAG_CUT_POWER, pwm_bfet_damped_exit IF NFETON_DELAY NE 0 mov A, #NFETON_DELAY ; Set delay djnz ACC, $ ENDIF pwm_bfet_damped_done: BnFET_on ; Switch nFET pwm_bfet_damped_exit: ajmp t0_int_pwm_on_exit pwm_cfet_damped: CpFET_off jnb Flags1.MOTOR_SPINNING, pwm_cfet_damped_exit jb Flags0.DEMAG_CUT_POWER, pwm_cfet_damped_exit IF NFETON_DELAY NE 0 mov A, #NFETON_DELAY ; Set delay djnz ACC, $ ENDIF pwm_cfet_damped_done: CnFET_on ; Switch nFET pwm_cfet_damped_exit: ajmp t0_int_pwm_on_exit ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Timer2 interrupt routine ; ; No assumptions ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** t2_int: ; Happens every 128us for low byte and every 32ms for high byte clr EA clr ET2 ; Disable timer2 interrupts anl EIE1, #0EFh ; Disable PCA0 interrupts push PSW ; Preserve registers through interrupt push ACC setb PSW.3 ; Select register bank 1 for interrupt routines setb EA IF MCU_48MHZ == 1 mov A, Clock_Set_At_48MHz jz t2_int_start ; Check skip variable mov A, Skip_T2_Int jz t2_int_start ; Execute this interrupt mov Skip_T2_Int, #0 ajmp t2_int_exit t2_int_start: mov Skip_T2_Int, #1 ; Skip next interrupt ENDIF ; Clear low byte interrupt flag clr TF2L ; Clear interrupt flag ; Check RC pulse timeout counter mov A, Rcp_Timeout_Cntd ; RC pulse timeout count zero? jz t2_int_pulses_absent ; Yes - pulses are absent ; Decrement timeout counter (if PWM) jb Flags2.RCP_PPM, t2_int_skip_start ; If flag is set (PPM) - branch dec Rcp_Timeout_Cntd ; No - decrement ajmp t2_int_skip_start t2_int_pulses_absent: ; Timeout counter has reached zero, pulses are absent mov Temp1, #RCP_MIN ; RCP_MIN as default mov Temp2, #RCP_MIN jb Flags2.RCP_PPM, t2_int_pulses_absent_no_max ; If flag is set (PPM) - branch Read_Rcp_Int ; Look at value of Rcp_In jnb ACC.Rcp_In, ($+5) ; Is it high? mov Temp1, #RCP_MAX ; Yes - set RCP_MAX Rcp_Int_First ; Set interrupt trig to first again Rcp_Clear_Int_Flag ; Clear interrupt flag clr Flags2.RCP_EDGE_NO ; Set first edge flag Read_Rcp_Int ; Look once more at value of Rcp_In jnb ACC.Rcp_In, ($+5) ; Is it high? mov Temp2, #RCP_MAX ; Yes - set RCP_MAX clr C mov A, Temp1 subb A, Temp2 ; Compare the two readings of Rcp_In jnz t2_int_pulses_absent ; Go back if they are not equal t2_int_pulses_absent_no_max: jnb Flags0.RCP_MEAS_PWM_FREQ, ($+6) ; Is measure RCP pwm frequency flag set? mov Rcp_Timeout_Cntd, #RCP_TIMEOUT ; Yes - set timeout count to start value jb Flags2.RCP_PPM, t2_int_ppm_timeout_set ; If flag is set (PPM) - branch mov Rcp_Timeout_Cntd, #RCP_TIMEOUT ; For PWM, set timeout count to start value t2_int_ppm_timeout_set: mov New_Rcp, Temp1 ; Store new pulse length setb Flags2.RCP_UPDATED ; Set updated flag t2_int_skip_start: jb Flags2.RCP_PPM, t2_int_rcp_update_start ; If flag is set (PPM) - branch ; Check RC pulse skip counter mov A, Rcp_Skip_Cntd jz t2_int_skip_end ; If RC pulse skip count is zero - end skipping RC pulse detection ; Decrement skip counter (only if edge counter is zero) dec Rcp_Skip_Cntd ; Decrement ajmp t2_int_rcp_update_start t2_int_skip_end: ; Skip counter has reached zero, start looking for RC pulses again Rcp_Int_Enable ; Enable RC pulse interrupt Rcp_Clear_Int_Flag ; Clear interrupt flag t2_int_rcp_update_start: ; Process updated RC pulse jb Flags2.RCP_UPDATED, ($+5) ; Is there an updated RC pulse available? ajmp t2_int_current_pwm_update ; No - update pwm limits and exit mov Temp1, New_Rcp ; Load new pulse value jb Flags0.RCP_MEAS_PWM_FREQ, ($+5) ; If measure RCP pwm frequency flag set - do not clear flag clr Flags2.RCP_UPDATED ; Flag that pulse has been evaluated ; Use a gain of 1.0625x for pwm input if not governor mode jb Flags2.RCP_PPM, t2_int_pwm_min_run ; If flag is set (PPM) - branch IF MODE == 0 ; Main - do not adjust gain ajmp t2_int_pwm_min_run ELSE IF MODE == 2 ; Multi mov Temp2, #Pgm_Gov_Mode ; Closed loop mode? cjne @Temp2, #4, t2_int_pwm_min_run; Yes - branch ENDIF ; Limit the maximum value to avoid wrap when scaled to pwm range clr C mov A, Temp1 subb A, #240 ; 240 = (255/1.0625) Needs to be updated according to multiplication factor below jc t2_int_rcp_update_mult mov A, #240 ; Set requested pwm to max mov Temp1, A t2_int_rcp_update_mult: ; Multiply by 1.0625 (optional adjustment gyro gain) mov A, Temp1 swap A ; After this "0.0625" anl A, #0Fh add A, Temp1 mov Temp1, A ; Adjust tail gain mov Temp2, #Pgm_Motor_Gain cjne @Temp2, #3, ($+5) ; Is gain 1? ajmp t2_int_pwm_min_run ; Yes - skip adjustment clr C rrc A ; After this "0.5" clr C rrc A ; After this "0.25" mov Bit_Access_Int, @Temp2 ; (Temp2 has #Pgm_Motor_Gain) jb Bit_Access_Int.0, t2_int_rcp_gain_corr ; Branch if bit 0 in gain is set clr C rrc A ; After this "0.125" t2_int_rcp_gain_corr: jb Bit_Access_Int.2, t2_int_rcp_gain_pos ; Branch if bit 2 in gain is set clr C xch A, Temp1 subb A, Temp1 ; Apply negative correction mov Temp1, A ajmp t2_int_pwm_min_run t2_int_rcp_gain_pos: add A, Temp1 ; Apply positive correction mov Temp1, A jnc t2_int_pwm_min_run ; Above max? mov A, #0FFh ; Yes - limit mov Temp1, A ENDIF t2_int_pwm_min_run: IF MODE == 1 ; Tail - limit minimum pwm ; Limit minimum pwm clr C mov A, Temp1 subb A, Pwm_Motor_Idle ; Is requested pwm lower than minimum? jnc t2_int_pwm_update ; No - branch mov A, Pwm_Motor_Idle ; Yes - limit pwm to Pwm_Motor_Idle mov Temp1, A ENDIF t2_int_pwm_update: ; Update requested_pwm mov Requested_Pwm, Temp1 ; Set requested pwm IF MODE >= 1 ; Tail or multi ; Boost pwm during direct start mov A, Flags1 anl A, #((1 SHL STARTUP_PHASE)+(1 SHL INITIAL_RUN_PHASE)) jz t2_int_current_pwm_update mov A, Startup_Cnt ; Add an extra power boost during start clr C rrc A clr C rrc A add A, #6 add A, Requested_Pwm mov Requested_Pwm, A jnc ($+5) mov Requested_Pwm, #0FFh ENDIF t2_int_current_pwm_update: IF MODE == 0 OR MODE == 2 ; Main or multi mov Temp1, #Pgm_Gov_Mode ; Governor mode? cjne @Temp1, #4, t2_int_pwm_exit ; Yes - branch ENDIF mov Current_Pwm, Requested_Pwm ; Set equal as default IF MODE >= 1 ; Tail or multi ; Set current_pwm_limited mov Temp1, Current_Pwm ; Default not limited clr C mov A, Current_Pwm ; Check against limit subb A, Pwm_Limit jc ($+4) ; If current pwm below limit - branch mov Temp1, Pwm_Limit ; Limit pwm IF MODE == 2 ; Multi ; Limit pwm for low rpms clr C mov A, Temp1 ; Check against limit subb A, Pwm_Limit_By_Rpm jc ($+4) ; If current pwm below limit - branch mov Temp1, Pwm_Limit_By_Rpm ; Limit pwm ENDIF mov Current_Pwm_Limited, Temp1 ; Dither mov A, Pwm_Dither_Decoded ; Load pwm dither jnz ($+4) ; If active - branch ajmp t2_int_current_pwm_no_dither clr C mov A, Temp1 mov Temp3, Pwm_Dither_Decoded subb A, Temp3 ; Calculate pwm minus dither value jnc t2_int_current_pwm_full_dither; If pwm more than dither value, then do full dither mov A, Temp1 ; Set dither level to current pwm mov Temp3, A clr A ; Set pwm minus dither t2_int_current_pwm_full_dither: mov Temp2, A ; Load pwm minus dither value mov A, Temp3 ; Load dither clr C rlc A ; Shift left once mov Temp4, A mov A, Random ; Load random number cpl A ; Invert to create proper DC bias in random code anl A, Temp4 ; And with double dither value add A, Temp2 ; Add pwm minus dither jc t2_int_current_pwm_dither_max_excess_power ; If dither cause power above max - branch and increase excess add A, Pwm_Dither_Excess_Power ; Add excess power from previous cycles mov Temp1, A mov A, Pwm_Dither_Excess_Power ; Decrement excess power jz ($+4) dec Pwm_Dither_Excess_Power jc t2_int_current_pwm_dither_max_power; If dither cause power above max - branch ajmp t2_int_current_pwm_no_dither t2_int_current_pwm_dither_max_excess_power: inc Temp3 ; Add one to dither in order to always reach max power clr C mov A, Pwm_Dither_Excess_Power subb A, Temp3 ; Limit excess power jnc ($+4) inc Pwm_Dither_Excess_Power t2_int_current_pwm_dither_max_power: mov Temp1, #255 ; Set power to max t2_int_current_pwm_no_dither: mov Current_Pwm_Lim_Dith, Temp1 IF DAMPED_MODE_ENABLE == 1 ; Skip damping fet switching for high throttle clr Flags1.SKIP_DAMP_ON clr C mov A, Current_Pwm_Lim_Dith subb A, #248 jc t2_int_pwm_exit setb Flags1.SKIP_DAMP_ON ENDIF ENDIF t2_int_pwm_exit: ; Set demag enabled if pwm is above limit clr C mov A, Current_Pwm_Limited subb A, #40h ; Set if above 25% jc ($+4) setb Flags0.DEMAG_ENABLED t2_int_exit: ; Check if high byte flag is set jb TF2H, t2h_int pop ACC ; Restore preserved registers pop PSW orl EIE1, #10h ; Enable PCA0 interrupts setb ET2 ; Enable timer2 interrupts reti t2h_int: ; High byte interrupt (happens every 32ms) clr TF2H ; Clear interrupt flag inc Timer2_X IF MCU_48MHZ == 1 mov A, Clock_Set_At_48MHz jz t2h_int_start ; Check skip variable mov A, Skip_T2h_Int jz t2h_int_start ; Execute this interrupt mov Skip_T2h_Int, #0 ajmp t2h_int_exit t2h_int_start: mov Skip_T2h_Int, #1 ; Skip next interrupt ENDIF mov Temp1, #GOV_SPOOLRATE ; Load governor spool rate ; Check RC pulse timeout counter (used here for PPM only) mov A, Rcp_Timeout_Cntd ; RC pulse timeout count zero? jz t2h_int_rcp_stop_check ; Yes - do not decrement ; Decrement timeout counter (if PPM) jnb Flags2.RCP_PPM, t2h_int_rcp_stop_check ; If flag is not set (PWM) - branch dec Rcp_Timeout_Cntd ; No flag set (PPM) - decrement t2h_int_rcp_stop_check: ; Check RC pulse against stop value clr C mov A, New_Rcp ; Load new pulse value subb A, #RCP_STOP ; Check if pulse is below stop value jc t2h_int_rcp_stop ; RC pulse higher than stop value, reset stop counter mov Rcp_Stop_Cnt, #0 ; Reset rcp stop counter ajmp t2h_int_rcp_gov_pwm t2h_int_rcp_stop: ; RC pulse less than stop value mov Auto_Bailout_Armed, #0 ; Disarm bailout mov Spoolup_Limit_Cnt, #0 mov A, Rcp_Stop_Cnt ; Increment stop counter add A, #1 mov Rcp_Stop_Cnt, A jnc t2h_int_rcp_gov_pwm ; Branch if counter has not wrapped mov Rcp_Stop_Cnt, #0FFh ; Set stop counter to max t2h_int_rcp_gov_pwm: IF MODE == 0 ; Main ; Update governor variables mov Temp2, #Pgm_Gov_Mode ; Governor target by arm mode? cjne @Temp2, #2, t2h_int_rcp_gov_by_setup ; No - branch jnb Flags1.GOV_ACTIVE, t2h_int_rcp_gov_by_tx; If governor not active - branch (this ensures soft spoolup by tx) clr C mov A, Requested_Pwm subb A, #50 ; Is requested pwm below 20%? jc t2h_int_rcp_gov_by_tx ; Yes - branch (this enables a soft spooldown) mov Requested_Pwm, Gov_Arm_Target ; Yes - load arm target t2h_int_rcp_gov_by_setup: mov Temp2, #Pgm_Gov_Mode ; Governor target by setup mode? cjne @Temp2, #3, t2h_int_rcp_gov_by_tx ; No - branch jnb Flags1.GOV_ACTIVE, t2h_int_rcp_gov_by_tx; If governor not active - branch (this ensures soft spoolup by tx) clr C mov A, Requested_Pwm subb A, #50 ; Is requested pwm below 20%? jc t2h_int_rcp_gov_by_tx ; Yes - branch (this enables a soft spooldown) mov Temp2, #Pgm_Gov_Setup_Target ; Gov by setup - load setup target mov Requested_Pwm, @Temp2 t2h_int_rcp_gov_by_tx: clr C mov A, Governor_Req_Pwm subb A, Requested_Pwm ; Is governor requested pwm equal to requested pwm? jz t2h_int_rcp_gov_pwm_done ; Yes - branch jc t2h_int_rcp_gov_pwm_inc ; No - if lower, then increment dec Governor_Req_Pwm ; No - if higher, then decrement ajmp t2h_int_rcp_gov_pwm_done t2h_int_rcp_gov_pwm_inc: inc Governor_Req_Pwm ; Increment t2h_int_rcp_gov_pwm_done: djnz Temp1, t2h_int_rcp_gov_pwm ; If not number of steps processed - go back inc Spoolup_Limit_Cnt ; Increment spoolup count mov A, Spoolup_Limit_Cnt jnz ($+4) ; Wrapped? dec Spoolup_Limit_Cnt ; Yes - decrement djnz Spoolup_Limit_Skip, t2h_int_exit ; Jump if skip count is not reached mov Spoolup_Limit_Skip, #1 ; Reset skip count. Default is fast spoolup mov Temp1, #5 ; Default fast increase clr C mov A, Spoolup_Limit_Cnt subb A, Main_Spoolup_Time_3x ; No spoolup until 3*N*32ms jc t2h_int_exit clr C mov A, Spoolup_Limit_Cnt subb A, Main_Spoolup_Time_10x ; Slow spoolup until "100"*N*32ms jnc t2h_int_rcp_limit_middle_ramp mov Temp1, #1 ; Slow initial spoolup mov Spoolup_Limit_Skip, #3 jmp t2h_int_rcp_set_limit t2h_int_rcp_limit_middle_ramp: clr C mov A, Spoolup_Limit_Cnt subb A, Main_Spoolup_Time_15x ; Faster spoolup until "150"*N*32ms jnc t2h_int_rcp_set_limit mov Temp1, #1 ; Faster middle spoolup mov Spoolup_Limit_Skip, #1 t2h_int_rcp_set_limit: ; Do not increment spoolup limit if higher pwm is not requested, unless governor is active clr C mov A, Pwm_Limit_Spoolup subb A, Current_Pwm jc t2h_int_rcp_inc_limit ; If Current_Pwm is larger than Pwm_Limit_Spoolup - branch mov Temp2, #Pgm_Gov_Mode ; Governor mode? cjne @Temp2, #4, ($+5) ajmp t2h_int_rcp_bailout_arm ; No - branch jb Flags1.GOV_ACTIVE, t2h_int_rcp_inc_limit ; If governor active - branch mov Pwm_Limit_Spoolup, Current_Pwm ; Set limit to what current pwm is mov A, Spoolup_Limit_Cnt ; Check if spoolup limit count is 255. If it is, then this is a "bailout" ramp inc A jz ($+5) mov Spoolup_Limit_Cnt, Main_Spoolup_Time_3x ; Stay in an early part of the spoolup sequence (unless "bailout" ramp) mov Spoolup_Limit_Skip, #1 ; Set skip count mov Governor_Req_Pwm, #60 ; Set governor requested speed to ensure that it requests higher speed ; 20=Fail on jerk when governor activates ; 30=Ok ; 100=Fail on small governor settling overshoot on low headspeeds ; 200=Fail on governor settling overshoot jmp t2h_int_exit ; Exit t2h_int_rcp_inc_limit: mov A, Pwm_Limit_Spoolup ; Increment spoolup pwm add A, Temp1 jnc t2h_int_rcp_no_limit ; If below 255 - branch mov Pwm_Limit_Spoolup, #0FFh ajmp t2h_int_rcp_bailout_arm t2h_int_rcp_no_limit: mov Pwm_Limit_Spoolup, A t2h_int_rcp_bailout_arm: mov A, Pwm_Limit_Spoolup inc A jnz t2h_int_exit mov Auto_Bailout_Armed, #255 ; Arm bailout mov Spoolup_Limit_Cnt, #255 ENDIF t2h_int_exit: pop ACC ; Restore preserved registers pop PSW orl EIE1, #10h ; Enable PCA0 interrupts setb ET2 ; Enable timer2 interrupts reti ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Timer3 interrupt routine ; ; No assumptions ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** t3_int: ; Used for commutation timing clr EA ; Disable all interrupts push PSW ; Preserve registers through interrupt anl EIE1, #7Fh ; Disable timer3 interrupts clr Flags0.T3_PENDING ; Flag that timer has wrapped ; Set up next wait mov TMR3CN, #00h ; Timer3 disabled and interrupt flag cleared mov TMR3L, Next_Wt_Start_L ; Set wait value mov TMR3H, Next_Wt_Start_H mov TMR3CN, #04h ; Timer3 enabled and interrupt flag cleared pop PSW setb EA ; Enable all interrupts reti ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; PCA interrupt routine ; ; No assumptions ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** pca_int: ; Used for RC pulse timing clr EA anl EIE1, #0EFh ; Disable PCA0 interrupts clr ET2 ; Disable timer2 interrupts push PSW ; Preserve registers through interrupt push ACC push B setb PSW.3 ; Select register bank 1 for interrupt routines setb EA ; Get the PCA counter values Get_Rcp_Capture_Values ; Clear interrupt flag Rcp_Clear_Int_Flag ; Check which edge it is jnb Flags2.RCP_EDGE_NO, ($+5) ; Is it a first edge trig? ajmp pca_int_second_meas_pwm_freq ; No - branch to second Rcp_Int_Second ; Yes - set second edge trig setb Flags2.RCP_EDGE_NO ; Set second edge flag ; Read RC signal level Read_Rcp_Int ; Test RC signal level jb ACC.Rcp_In, ($+5) ; Is it high? ajmp pca_int_fail_minimum ; No - jump to fail minimum ; RC pulse was high, store RC pulse start timestamp mov Rcp_Prev_Edge_L, Temp1 mov Rcp_Prev_Edge_H, Temp2 ajmp pca_int_exit ; Exit pca_int_fail_minimum: ; Prepare for next interrupt Rcp_Int_First ; Set interrupt trig to first again Rcp_Clear_Int_Flag ; Clear interrupt flag clr Flags2.RCP_EDGE_NO ; Set first edge flag jnb Flags2.RCP_PPM, ($+5) ; If flag is not set (PWM) - branch ajmp pca_int_set_timeout ; If PPM - ignore trig as noise mov Temp1, #RCP_MIN ; Set RC pulse value to minimum Read_Rcp_Int ; Test RC signal level again jnb ACC.Rcp_In, ($+5) ; Is it high? ajmp pca_int_set_timeout ; Yes - set new timeout and exit mov New_Rcp, Temp1 ; Store new pulse length ajmp pca_int_limited ; Set new RC pulse, new timeout and exit pca_int_second_meas_pwm_freq: ; Prepare for next interrupt Rcp_Int_First ; Set first edge trig clr Flags2.RCP_EDGE_NO ; Set first edge flag ; Check if pwm frequency shall be measured jb Flags0.RCP_MEAS_PWM_FREQ, ($+5) ; Is measure RCP pwm frequency flag set? ajmp pca_int_fall ; No - skip measurements ; Set second edge trig only during pwm frequency measurement Rcp_Int_Second ; Set second edge trig Rcp_Clear_Int_Flag ; Clear interrupt flag setb Flags2.RCP_EDGE_NO ; Set second edge flag ; Store edge data to RAM mov Rcp_Edge_L, Temp1 mov Rcp_Edge_H, Temp2 ; Calculate pwm frequency clr C mov A, Temp1 subb A, Rcp_PrePrev_Edge_L mov Temp1, A mov A, Temp2 subb A, Rcp_PrePrev_Edge_H mov Temp2, A mov Temp4, #0 mov Temp7, #8 ; Set default period tolerance requirement (MSB) mov Temp3, #0 ; (LSB) ; Check if pulse is too short clr C mov A, Temp1 subb A, #low(140) ; If pulse below 70us, not accepted mov A, Temp2 subb A, #high(140) jnc pca_int_check_12kHz mov Rcp_Period_Diff_Accepted, #0 ; Set not accepted ajmp pca_int_store_data pca_int_check_12kHz: mov Bit_Access_Int, Temp1 mov Temp1, #Pgm_Enable_PWM_Input ; Check if PWM input is enabled mov A, @Temp1 mov Temp1, Bit_Access_Int jz pca_int_restore_edge ; If it is not - branch ; Check if pwm frequency is 12kHz clr C mov A, Temp1 subb A, #low(200) ; If below 100us, 12kHz pwm is assumed mov A, Temp2 subb A, #high(200) jnc pca_int_check_8kHz clr A setb ACC.RCP_PWM_FREQ_12KHZ mov Temp4, A mov Temp3, #10 ; Set period tolerance requirement (LSB) ajmp pca_int_restore_edge_set_msb pca_int_check_8kHz: ; Check if pwm frequency is 8kHz clr C mov A, Temp1 subb A, #low(360) ; If below 180us, 8kHz pwm is assumed mov A, Temp2 subb A, #high(360) jnc pca_int_check_4kHz clr A setb ACC.RCP_PWM_FREQ_8KHZ mov Temp4, A mov Temp3, #15 ; Set period tolerance requirement (LSB) ajmp pca_int_restore_edge_set_msb pca_int_check_4kHz: ; Check if pwm frequency is 4kHz clr C mov A, Temp1 subb A, #low(720) ; If below 360us, 4kHz pwm is assumed mov A, Temp2 subb A, #high(720) jnc pca_int_check_2kHz clr A setb ACC.RCP_PWM_FREQ_4KHZ mov Temp4, A mov Temp3, #30 ; Set period tolerance requirement (LSB) ajmp pca_int_restore_edge_set_msb pca_int_check_2kHz: ; Check if pwm frequency is 2kHz clr C mov A, Temp1 subb A, #low(1440) ; If below 720us, 2kHz pwm is assumed mov A, Temp2 subb A, #high(1440) jnc pca_int_check_1kHz clr A setb ACC.RCP_PWM_FREQ_2KHZ mov Temp4, A mov Temp3, #60 ; Set period tolerance requirement (LSB) ajmp pca_int_restore_edge_set_msb pca_int_check_1kHz: ; Check if pwm frequency is 1kHz clr C mov A, Temp1 subb A, #low(2200) ; If below 1100us, 1kHz pwm is assumed mov A, Temp2 subb A, #high(2200) jnc pca_int_restore_edge clr A setb ACC.RCP_PWM_FREQ_1KHZ mov Temp4, A mov Temp3, #120 ; Set period tolerance requirement (LSB) pca_int_restore_edge_set_msb: mov Temp7, #0 ; Set period tolerance requirement (MSB) pca_int_restore_edge: ; Calculate difference between this period and previous period clr C mov A, Temp1 subb A, Rcp_Prev_Period_L mov Temp5, A mov A, Temp2 subb A, Rcp_Prev_Period_H mov Temp6, A ; Make positive jnb ACC.7, pca_int_check_diff mov A, Temp5 cpl A add A, #1 mov Temp5, A mov A, Temp6 cpl A addc A, #0 mov Temp6, A pca_int_check_diff: ; Check difference mov Rcp_Period_Diff_Accepted, #0 ; Set not accepted as default clr C mov A, Temp5 subb A, Temp3 ; Check difference mov A, Temp6 subb A, Temp7 jnc pca_int_store_data mov Rcp_Period_Diff_Accepted, #1 ; Set accepted pca_int_store_data: ; Store previous period mov Rcp_Prev_Period_L, Temp1 mov Rcp_Prev_Period_H, Temp2 ; Store pre previous edge mov Rcp_PrePrev_Edge_L, Rcp_Edge_L mov Rcp_PrePrev_Edge_H, Rcp_Edge_H mov Temp1, #RCP_VALIDATE ajmp pca_int_limited pca_int_fall: ; RC pulse edge was second, calculate new pulse length clr C mov A, Temp1 subb A, Rcp_Prev_Edge_L mov Temp1, A mov A, Temp2 subb A, Rcp_Prev_Edge_H mov Temp2, A jnb Flags3.RCP_PWM_FREQ_12KHZ, ($+5) ; Is RC input pwm frequency 12kHz? ajmp pca_int_pwm_divide_done ; Yes - branch forward jnb Flags3.RCP_PWM_FREQ_8KHZ, ($+5) ; Is RC input pwm frequency 8kHz? ajmp pca_int_pwm_divide_done ; Yes - branch forward jnb Flags3.RCP_PWM_FREQ_4KHZ, ($+5) ; Is RC input pwm frequency 4kHz? ajmp pca_int_pwm_divide ; Yes - branch forward jb Flags2.RCP_PPM_ONESHOT125, ($+5) ajmp pca_int_fall_not_oneshot mov A, Temp2 ; Oneshot125 - move to I_Temp5/6 mov Temp6, A mov A, Temp1 mov Temp5, A ajmp pca_int_fall_check_range pca_int_fall_not_oneshot: mov A, Temp2 ; No - 2kHz. Divide by 2 clr C rrc A mov Temp2, A mov A, Temp1 rrc A mov Temp1, A jnb Flags3.RCP_PWM_FREQ_2KHZ, ($+5) ; Is RC input pwm frequency 2kHz? ajmp pca_int_pwm_divide ; Yes - branch forward mov A, Temp2 ; No - 1kHz. Divide by 2 again clr C rrc A mov Temp2, A mov A, Temp1 rrc A mov Temp1, A jnb Flags3.RCP_PWM_FREQ_1KHZ, ($+5) ; Is RC input pwm frequency 1kHz? ajmp pca_int_pwm_divide ; Yes - branch forward mov A, Temp2 ; No - PPM. Divide by 2 (to bring range to 256) and move to Temp5/6 clr C rrc A mov Temp6, A mov A, Temp1 rrc A mov Temp5, A pca_int_fall_check_range: ; Skip range limitation if pwm frequency measurement jb Flags0.RCP_MEAS_PWM_FREQ, pca_int_ppm_check_full_range ; Check if 2160us or above (in order to ignore false pulses) clr C mov A, Temp5 ; Is pulse 2160us or higher? subb A, #28 mov A, Temp6 subb A, #2 jc ($+4) ; No - proceed ajmp pca_int_ppm_outside_range ; Yes - ignore pulse pca_int_ppm_below_full_range: ; Check if below 800us (in order to ignore false pulses) mov A, Temp6 jnz pca_int_ppm_check_full_range clr C mov A, Temp5 ; Is pulse below 800us? subb A, #200 jnc pca_int_ppm_check_full_range ; No - proceed pca_int_ppm_outside_range: inc Rcp_Outside_Range_Cnt mov A, Rcp_Outside_Range_Cnt jnz ($+4) dec Rcp_Outside_Range_Cnt clr C mov A, Rcp_Outside_Range_Cnt subb A, #10 ; Allow a given number of outside pulses jnc ($+4) ajmp pca_int_set_timeout ; If below limit - ignore pulse mov New_Rcp, #0 ; Set pulse length to zero setb Flags2.RCP_UPDATED ; Set updated flag ajmp pca_int_set_timeout pca_int_ppm_check_full_range: ; Decrement outside range counter mov A, Rcp_Outside_Range_Cnt jz ($+4) dec Rcp_Outside_Range_Cnt ; Calculate "1000us" plus throttle minimum IF MODE >= 1 ; Tail or multi mov Temp1, #Pgm_Direction ; Check if bidirectional operation (store in Temp2) mov A, @Temp1 mov Temp2, A ENDIF mov A, #0 ; Set 1000us as default minimum jb Flags3.FULL_THROTTLE_RANGE, pca_int_ppm_calculate ; Check if full range is chosen mov Temp1, #Pgm_Ppm_Min_Throttle ; Min throttle value is in 4us units IF MODE >= 1 ; Tail or multi cjne Temp2, #3, ($+5) mov Temp1, #Pgm_Ppm_Center_Throttle ; Center throttle value is in 4us units ENDIF mov A, @Temp1 pca_int_ppm_calculate: add A, #250 ; Add 1000us to minimum mov Temp7, A clr A addc A, #0 mov Temp8, A clr C mov A, Temp5 ; Subtract minimum subb A, Temp7 mov Temp5, A mov A, Temp6 subb A, Temp8 mov Temp6, A IF MODE >= 1 ; Tail or multi mov Bit_Access_Int.0, C cjne Temp2, #3, pca_int_ppm_bidir_dir_set; If not bidirectional operation - branch mov C, Bit_Access_Int.0 jnc pca_int_ppm_bidir_fwd ; If result is positive - branch pca_int_ppm_bidir_rev: jb Flags2.RCP_DIR_REV, pca_int_ppm_bidir_dir_set ; If same direction - branch setb Flags2.RCP_DIR_REV ajmp pca_int_ppm_bidir_dir_set pca_int_ppm_bidir_fwd: jnb Flags2.RCP_DIR_REV, pca_int_ppm_bidir_dir_set ; If same direction - branch clr Flags2.RCP_DIR_REV pca_int_ppm_bidir_dir_set: mov C, Bit_Access_Int.0 ENDIF jnc pca_int_ppm_neg_checked ; If result is positive - branch IF MODE >= 1 ; Tail or multi cjne Temp2, #3, pca_int_ppm_unidir_neg ; If not bidirectional operation - branch mov A, Temp5 ; Change sign cpl A add A, #1 mov Temp5, A mov A, Temp6 cpl A addc A, #0 mov Temp6, A jmp pca_int_ppm_neg_checked pca_int_ppm_unidir_neg: ENDIF mov Temp1, #RCP_MIN ; Yes - set to minimum mov Temp2, #0 ajmp pca_int_pwm_divide_done pca_int_ppm_neg_checked: IF MODE >= 1 ; Tail or multi cjne Temp2, #3, pca_int_ppm_bidir_done ; If not bidirectional operation - branch mov A, Temp5 ; Multiply value by 2 rlc A mov Temp5 A mov A, Temp6 rlc A mov Temp6 A clr C ; Subtract deadband mov A, Temp5 subb A, #10 mov Temp5, A mov A, Temp6 subb A, #0 mov Temp6, A jnc pca_int_ppm_bidir_done mov Temp5, #RCP_MIN mov Temp6, #0 pca_int_ppm_bidir_done: ENDIF clr C ; Check that RC pulse is within legal range (max 255) mov A, Temp5 subb A, #RCP_MAX mov A, Temp6 subb A, #0 jc pca_int_ppm_max_checked mov Temp1, #RCP_MAX mov Temp2, #0 ajmp pca_int_pwm_divide_done pca_int_ppm_max_checked: mov A, Temp5 ; Multiply throttle value by gain mov B, Ppm_Throttle_Gain mul AB xch A, B mov C, B.7 ; Multiply result by 2 (unity gain is 128) rlc A mov Temp1, A ; Transfer to Temp1/2 mov Temp2, #0 jc pca_int_ppm_limit_after_mult jmp pca_int_limited pca_int_ppm_limit_after_mult: mov Temp1, #RCP_MAX mov Temp2, #0 jmp pca_int_limited pca_int_pwm_divide: mov A, Temp2 ; Divide by 2 clr C rrc A mov Temp2, A mov A, Temp1 rrc A mov Temp1, A pca_int_pwm_divide_done: jnb Flags3.RCP_PWM_FREQ_12KHZ, pca_int_check_legal_range ; Is RC input pwm frequency 12kHz? mov A, Temp2 ; Yes - check that value is not more than 255 jz ($+4) mov Temp1, #RCP_MAX clr C mov A, Temp1 ; Multiply by 1.5 rrc A addc A, Temp1 mov Temp1, A clr A addc A, #0 mov Temp2, A pca_int_check_legal_range: ; Check that RC pulse is within legal range clr C mov A, Temp1 subb A, #RCP_MAX mov A, Temp2 subb A, #0 jc pca_int_limited mov Temp1, #RCP_MAX pca_int_limited: ; RC pulse value accepted mov New_Rcp, Temp1 ; Store new pulse length setb Flags2.RCP_UPDATED ; Set updated flag jb Flags0.RCP_MEAS_PWM_FREQ, ($+5) ; Is measure RCP pwm frequency flag set? ajmp pca_int_set_timeout ; No - skip measurements mov A, #((1 SHL RCP_PWM_FREQ_1KHZ)+(1 SHL RCP_PWM_FREQ_2KHZ)+(1 SHL RCP_PWM_FREQ_4KHZ)+(1 SHL RCP_PWM_FREQ_8KHZ)+(1 SHL RCP_PWM_FREQ_12KHZ)) cpl A anl A, Flags3 ; Clear all pwm frequency flags orl A, Temp4 ; Store pwm frequency value in flags mov Flags3, A clr Flags2.RCP_PPM ; Default, flag is not set (PWM) mov A, Temp4 ; Check if all flags are cleared jnz pca_int_set_timeout setb Flags2.RCP_PPM ; Set flag (PPM) pca_int_set_timeout: mov Rcp_Timeout_Cntd, #RCP_TIMEOUT ; Set timeout count to start value jnb Flags2.RCP_PPM, pca_int_ppm_timeout_set ; If flag is not set (PWM) - branch mov Rcp_Timeout_Cntd, #RCP_TIMEOUT_PPM ; No flag set means PPM. Set timeout count pca_int_ppm_timeout_set: jnb Flags0.RCP_MEAS_PWM_FREQ, ($+5) ; Is measure RCP pwm frequency flag set? ajmp pca_int_exit ; Yes - exit jb Flags2.RCP_PPM, pca_int_exit ; If flag is set (PPM) - branch Rcp_Int_Disable ; Disable RC pulse interrupt pca_int_exit: ; Exit interrupt routine jb Flags2.RCP_PPM, ($+6) ; If flag is set (PPP) - branch mov Rcp_Skip_Cntd, #RCP_SKIP_RATE ; Load number of skips pop B ; Restore preserved registers pop ACC pop PSW setb ET2 ; Enable timer2 interrupts orl EIE1, #10h ; Enable PCA0 interrupts reti ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Wait xms ~(x*4*250) (Different entry points) ; ; No assumptions ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** wait1ms: mov Temp2, #1 jmp waitxms_o wait3ms: mov Temp2, #3 jmp waitxms_o wait10ms: mov Temp2, #10 jmp waitxms_o wait30ms: mov Temp2, #30 jmp waitxms_o wait100ms: mov Temp2, #100 jmp waitxms_o wait200ms: mov Temp2, #200 jmp waitxms_o waitxms_o: ; Outer loop mov Temp1, #23 waitxms_m: ; Middle loop clr A djnz ACC, $ ; Inner loop (42.7us - 1024 cycles) djnz Temp1, waitxms_m djnz Temp2, waitxms_o ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Beeper routines (4 different entry points) ; ; No assumptions ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** beep_f1: ; Entry point 1, load beeper frequency 1 settings mov Temp3, #20 ; Off wait loop length mov Temp4, #120 ; Number of beep pulses jmp beep beep_f2: ; Entry point 2, load beeper frequency 2 settings mov Temp3, #16 mov Temp4, #140 jmp beep beep_f3: ; Entry point 3, load beeper frequency 3 settings mov Temp3, #13 mov Temp4, #180 jmp beep beep_f4: ; Entry point 4, load beeper frequency 4 settings mov Temp3, #11 mov Temp4, #200 jmp beep beep: ; Beep loop start mov Temp2, #2 ; Must be an even number (or direction will change) beep_onoff: cpl Flags3.PGM_DIR_REV ; Toggle between using A fet and C fet clr A BpFET_off ; BpFET off djnz ACC, $ ; Allow some time after pfet is turned off BnFET_on ; BnFET on (in order to charge the driver of the BpFET) djnz ACC, $ ; Let the nfet be turned on a while BnFET_off ; BnFET off again djnz ACC, $ ; Allow some time after nfet is turned off BpFET_on ; BpFET on djnz ACC, $ ; Allow some time after pfet is turned on ; Turn on nfet AnFET_on ; AnFET on mov A, Beep_Strength djnz ACC, $ ; Turn off nfet AnFET_off ; AnFET off mov A, #150 ; 25µs off djnz ACC, $ djnz Temp2, beep_onoff ; Copy variable mov A, Temp3 mov Temp1, A beep_off: ; Fets off loop djnz ACC, $ djnz Temp1, beep_off djnz Temp4, beep BpFET_off ; BpFET off ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Division 16bit unsigned by 16bit unsigned ; ; Dividend shall be in Temp2/Temp1, divisor in Temp4/Temp3 ; Result will be in Temp2/Temp1 ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** div_u16_by_u16: clr C mov Temp5, #0 mov Temp6, #0 mov B, #0 div_u16_by_u16_div1: inc B ; Increment counter for each left shift mov A, Temp3 ; Shift left the divisor rlc A mov Temp3, A mov A, Temp4 rlc A mov Temp4, A jnc div_u16_by_u16_div1 ; Repeat until carry flag is set from high-byte div_u16_by_u16_div2: mov A, Temp4 ; Shift right the divisor rrc A mov Temp4, A mov A, Temp3 rrc A mov Temp3, A clr C mov A, Temp2 ; Make a safe copy of the dividend mov Temp8, A mov A, Temp1 mov Temp7, A mov A, Temp1 ; Move low-byte of dividend into accumulator subb A, Temp3 ; Dividend - shifted divisor = result bit (no factor, only 0 or 1) mov Temp1, A ; Save updated dividend mov A, Temp2 ; Move high-byte of dividend into accumulator subb A, Temp4 ; Subtract high-byte of divisor (all together 16-bit substraction) mov Temp2, A ; Save updated high-byte back in high-byte of divisor jnc div_u16_by_u16_div3 ; If carry flag is NOT set, result is 1 mov A, Temp8 ; Otherwise result is 0, save copy of divisor to undo subtraction mov Temp2, A mov A, Temp7 mov Temp1, A div_u16_by_u16_div3: cpl C ; Invert carry, so it can be directly copied into result mov A, Temp5 rlc A ; Shift carry flag into temporary result mov Temp5, A mov A, Temp6 rlc A mov Temp6,A djnz B, div_u16_by_u16_div2 ;Now count backwards and repeat until "B" is zero mov A, Temp6 ; Move result to Temp2/Temp1 mov Temp2, A mov A, Temp5 mov Temp1, A ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Multiplication 16bit signed by 8bit unsigned ; ; Multiplicand shall be in Temp2/Temp1, multiplicator in Temp3 ; Result will be in Temp2/Temp1. Result will divided by 16 ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** mult_s16_by_u8_div_16: mov A, Temp1 ; Read input to math registers mov B, Temp2 mov Bit_Access, Temp3 setb PSW.4 ; Select register bank 2 for math routines mov Temp1, A ; Store in math registers mov Temp2, B mov Temp4, #0 ; Set sign in Temp4 and test sign jnb B.7, mult_s16_by_u8_positive mov Temp4, #0FFh cpl A add A, #1 mov Temp1, A mov A, Temp2 cpl A addc A, #0 mov Temp2, A mult_s16_by_u8_positive: mov A, Temp1 ; Multiply LSB with multiplicator mov B, Bit_Access mul AB mov Temp6, B ; Place MSB in Temp6 mov Temp1, A ; Place LSB in Temp1 (result) mov A, Temp2 ; Multiply MSB with multiplicator mov B, Bit_Access mul AB mov Temp8, B ; Place in Temp8/7 mov Temp7, A mov A, Temp6 ; Add up add A, Temp7 mov Temp2, A mov A, #0 addc A, Temp8 mov Temp3, A mov Temp5, #4 ; Set number of divisions mult_s16_by_u8_div_loop: clr C ; Rotate right mov A, Temp3 rrc A mov Temp3, A mov A, Temp2 rrc A mov Temp2, A mov A, Temp1 rrc A mov Temp1, A djnz Temp5, mult_s16_by_u8_div_loop mov B, Temp4 ; Test sign jnb B.7, mult_s16_by_u8_exit mov A, Temp1 cpl A add A, #1 mov Temp1, A mov A, Temp2 cpl A addc A, #0 mov Temp2, A mult_s16_by_u8_exit: mov A, Temp1 ; Store output mov B, Temp2 clr PSW.4 ; Select normal register bank mov Temp1, A mov Temp2, B ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Calculate governor routines ; ; No assumptions ; ; Governs headspeed based upon the Comm_Period4x variable and pwm ; The governor task is split into several routines in order to distribute processing time ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; First governor routine - calculate governor target IF MODE == 0 ; Main calc_governor_target: mov Temp1, #Pgm_Gov_Mode ; Governor mode? cjne @Temp1, #4, governor_speed_check ; Yes jmp calc_governor_target_exit ; No governor_speed_check: ; Stop governor for stop RC pulse clr C mov A, New_Rcp ; Check RC pulse against stop value subb A, #(RCP_MAX/10) ; Is pulse below stop value? jc governor_deactivate ; Yes - deactivate mov A, Flags1 anl A, #((1 SHL STARTUP_PHASE)+(1 SHL INITIAL_RUN_PHASE)) jnz governor_deactivate ; Deactivate if any startup phase set ; Skip speed check if governor is already active jb Flags1.GOV_ACTIVE, governor_target_calc ; Check speed (do not run governor for low speeds) mov Temp1, #05h ; Default high range activation limit value (~62500 eRPM) mov Temp2, #Pgm_Gov_Range mov A, @Temp2 ; Check if high range (Temp2 has #Pgm_Gov_Range) dec A jz governor_act_lim_set ; If high range - branch mov Temp1, #0Ah ; Middle range activation limit value (~31250 eRPM) dec A jz governor_act_lim_set ; If middle range - branch mov Temp1, #12h ; Low range activation limit value (~17400 eRPM) governor_act_lim_set: clr C mov A, Comm_Period4x_H subb A, Temp1 jc governor_activate ; If speed above min limit - run governor governor_deactivate: jnb Flags1.GOV_ACTIVE, governor_first_deactivate_done; This code is executed continuously. Only execute the code below the first time mov Pwm_Limit_Spoolup, Pwm_Spoolup_Beg mov Spoolup_Limit_Cnt, #255 mov Spoolup_Limit_Skip, #1 governor_first_deactivate_done: mov Current_Pwm, Requested_Pwm ; Set current pwm to requested clr A mov Gov_Target_L, A ; Set target to zero mov Gov_Target_H, A mov Gov_Integral_L, A ; Set integral to zero mov Gov_Integral_H, A mov Gov_Integral_X, A clr Flags1.GOV_ACTIVE jmp calc_governor_target_exit governor_activate: setb Flags1.GOV_ACTIVE governor_target_calc: ; Governor calculations mov Temp2, #Pgm_Gov_Range mov A, @Temp2 ; Check high, middle or low range dec A jnz calc_governor_target_middle mov A, Governor_Req_Pwm ; Load governor requested pwm cpl A ; Calculate 255-pwm (invert pwm) ; Calculate comm period target (1 + 2*((255-Requested_Pwm)/256) - 0.25) rlc A ; Msb to carry rlc A ; To bit0 mov Temp2, A ; Now 1 lsb is valid for H rrc A mov Temp1, A ; Now 7 msbs are valid for L mov A, Temp2 anl A, #01h ; Calculate H byte inc A ; Add 1 mov Temp2, A mov A, Temp1 anl A, #0FEh ; Calculate L byte jmp calc_governor_subtract_025 calc_governor_target_middle: mov A, @Temp2 ; Check middle or low range (Temp2 has #Pgm_Gov_Range) dec A dec A jnz calc_governor_target_low mov A, Governor_Req_Pwm ; Load governor requested pwm cpl A ; Calculate 255-pwm (invert pwm) ; Calculate comm period target (1 + 4*((255-Requested_Pwm)/256)) rlc A ; Msb to carry rlc A ; To bit0 rlc A ; To bit1 mov Temp2, A ; Now 2 lsbs are valid for H rrc A mov Temp1, A ; Now 6 msbs are valid for L mov A, Temp2 anl A, #03h ; Calculate H byte inc A ; Add 1 mov Temp2, A mov A, Temp1 anl A, #0FCh ; Calculate L byte jmp calc_governor_store_target calc_governor_target_low: mov A, Governor_Req_Pwm ; Load governor requested pwm cpl A ; Calculate 255-pwm (invert pwm) ; Calculate comm period target (2 + 8*((255-Requested_Pwm)/256) - 0.25) rlc A ; Msb to carry rlc A ; To bit0 rlc A ; To bit1 rlc A ; To bit2 mov Temp2, A ; Now 3 lsbs are valid for H rrc A mov Temp1, A ; Now 5 msbs are valid for L mov A, Temp2 anl A, #07h ; Calculate H byte inc A ; Add 1 inc A ; Add 1 more mov Temp2, A mov A, Temp1 anl A, #0F8h ; Calculate L byte calc_governor_subtract_025: clr C subb A, #40h ; Subtract 0.25 mov Temp1, A mov A, Temp2 subb A, #0 mov Temp2, A calc_governor_store_target: ; Store governor target mov Gov_Target_L, Temp1 mov Gov_Target_H, Temp2 calc_governor_target_exit: ret ENDIF IF MODE == 1 ; Tail calc_governor_target: ret ENDIF IF MODE == 2 ; Multi calc_governor_target: mov Temp1, #Pgm_Gov_Mode ; Closed loop mode? cjne @Temp1, #4, governor_target_calc ; Yes - branch jmp calc_governor_target_exit ; No governor_target_calc: ; Stop governor for stop RC pulse clr C mov A, New_Rcp ; Check RC pulse against stop value subb A, #RCP_STOP ; Is pulse below stop value? jc governor_deactivate ; Yes - deactivate jmp governor_activate ; No - activate governor_deactivate: mov Current_Pwm, Requested_Pwm ; Set current pwm to requested clr A mov Gov_Target_L, A ; Set target to zero mov Gov_Target_H, A mov Gov_Integral_L, A ; Set integral to zero mov Gov_Integral_H, A mov Gov_Integral_X, A clr Flags1.GOV_ACTIVE jmp calc_governor_target_exit governor_activate: mov Temp1, #Pgm_Gov_Mode ; Store gov mode mov A, @Temp1 mov Temp5, A setb Flags1.GOV_ACTIVE mov A, Requested_Pwm ; Load requested pwm mov Governor_Req_Pwm, A ; Set governor requested pwm ; Calculate comm period target 2*(51000/Requested_Pwm) mov Temp1, #38h ; Load 51000 mov Temp2, #0C7h mov Temp3, Comm_Period4x_L ; Load comm period mov Temp4, Comm_Period4x_H ; Set speed range clr C mov A, Temp4 rrc A mov Temp4, A mov A, Temp3 rrc A mov Temp3, A ; 200k eRPM range here ; Check range mov A, Temp5 dec A jz governor_activate_range_set ; 200k eRPM? - branch governor_activate_100k: clr C mov A, Temp4 rrc A mov Temp4, A mov A, Temp3 rrc A mov Temp3, A ; 100k eRPM range here mov A, Temp5 ; Check range again dec A dec A jz governor_activate_range_set ; 100k eRPM? - branch governor_activate_50k: clr C mov A, Temp4 rrc A mov Temp4, A mov A, Temp3 rrc A mov Temp3, A ; 50k eRPM range here governor_activate_range_set: call div_u16_by_u16 ; Store governor target mov Gov_Target_L, Temp1 mov Gov_Target_H, Temp2 calc_governor_target_exit: ret ENDIF ; Second governor routine - calculate governor proportional error calc_governor_prop_error: IF MODE <= 1 ; Main or tail ; Load comm period and divide by 2 clr C mov A, Comm_Period4x_H rrc A mov Temp2, A mov A, Comm_Period4x_L rrc A mov Temp1, A ; Calculate error clr C mov A, Gov_Target_L subb A, Temp1 mov Temp1, A mov A, Gov_Target_H subb A, Temp2 mov Temp2, A ENDIF IF MODE == 2 ; Multi ; Calculate error clr C mov A, Gov_Target_L subb A, Governor_Req_Pwm mov Temp1, A mov A, Gov_Target_H subb A, #0 mov Temp2, A ENDIF ; Check error and limit jnc governor_check_prop_limit_pos ; Check carry clr C mov A, Temp1 subb A, #80h ; Is error too negative? mov A, Temp2 subb A, #0FFh jc governor_limit_prop_error_neg ; Yes - limit jmp governor_store_prop_error governor_check_prop_limit_pos: clr C mov A, Temp1 subb A, #7Fh ; Is error too positive? mov A, Temp2 subb A, #00h jnc governor_limit_prop_error_pos ; Yes - limit jmp governor_store_prop_error governor_limit_prop_error_pos: mov Temp1, #7Fh ; Limit to max positive (2's complement) mov Temp2, #00h jmp governor_store_prop_error governor_limit_prop_error_neg: mov Temp1, #80h ; Limit to max negative (2's complement) mov Temp2, #0FFh governor_store_prop_error: ; Store proportional mov Gov_Proportional_L, Temp1 mov Gov_Proportional_H, Temp2 calc_governor_prop_error_exit: ret ; Third governor routine - calculate governor integral error calc_governor_int_error: ; Add proportional to integral mov A, Gov_Proportional_L add A, Gov_Integral_L mov Temp1, A mov A, Gov_Proportional_H addc A, Gov_Integral_H mov Temp2, A mov Bit_Access, Gov_Proportional_H ; Sign extend high byte clr A jnb Bit_Access.7, ($+4) cpl A addc A, Gov_Integral_X mov Temp3, A ; Check integral and limit jnb ACC.7, governor_check_int_limit_pos ; Check sign bit clr C mov A, Temp3 subb A, #0F0h ; Is error too negative? jc governor_limit_int_error_neg ; Yes - limit jmp governor_check_pwm governor_check_int_limit_pos: clr C mov A, Temp3 subb A, #0Fh ; Is error too positive? jnc governor_limit_int_error_pos ; Yes - limit jmp governor_check_pwm governor_limit_int_error_pos: mov Temp1, #0FFh ; Limit to max positive (2's complement) mov Temp2, #0FFh mov Temp3, #0Fh jmp governor_check_pwm governor_limit_int_error_neg: mov Temp1, #00h ; Limit to max negative (2's complement) mov Temp2, #00h mov Temp3, #0F0h governor_check_pwm: ; Check current pwm clr C mov A, Current_Pwm subb A, Pwm_Limit ; Is current pwm at or above pwm limit? jnc governor_int_max_pwm ; Yes - branch clr C mov A, #1 subb A, Current_Pwm ; Is current pwm at minimum? jnc governor_int_min_pwm ; Yes - branch jmp governor_store_int_error ; No - store integral error governor_int_max_pwm: mov A, Gov_Proportional_H jb ACC.7, calc_governor_int_error_exit ; Is proportional error negative - branch (high byte is always zero) jmp governor_store_int_error ; Positive - store integral error governor_int_min_pwm: mov A, Gov_Proportional_H jnb ACC.7, calc_governor_int_error_exit ; Is proportional error positive - branch (high byte is always zero) governor_store_int_error: ; Store integral mov Gov_Integral_L, Temp1 mov Gov_Integral_H, Temp2 mov Gov_Integral_X, Temp3 calc_governor_int_error_exit: ret ; Fourth governor routine - calculate governor proportional correction calc_governor_prop_correction: ; Load proportional gain mov Temp1, #Pgm_Gov_P_Gain_Decoded; Load proportional gain mov A, @Temp1 mov Temp3, A ; Store in Temp3 ; Load proportional clr C mov A, Gov_Proportional_L ; Nominal multiply by 2 rlc A mov Temp1, A mov A, Gov_Proportional_H rlc A mov Temp2, A ; Apply gain call mult_s16_by_u8_div_16 ; Check error and limit (to low byte) mov A, Temp2 jnb ACC.7, governor_check_prop_corr_limit_pos ; Check sign bit clr C mov A, Temp1 subb A, #80h ; Is error too negative? mov A, Temp2 subb A, #0FFh jc governor_limit_prop_corr_neg ; Yes - limit ajmp governor_apply_prop_corr governor_check_prop_corr_limit_pos: clr C mov A, Temp1 subb A, #7Fh ; Is error too positive? mov A, Temp2 subb A, #00h jnc governor_limit_prop_corr_pos ; Yes - limit ajmp governor_apply_prop_corr governor_limit_prop_corr_pos: mov Temp1, #7Fh ; Limit to max positive (2's complement) mov Temp2, #00h ajmp governor_apply_prop_corr governor_limit_prop_corr_neg: mov Temp1, #80h ; Limit to max negative (2's complement) mov Temp2, #0FFh governor_apply_prop_corr: ; Test proportional sign mov A, Temp1 jb ACC.7, governor_corr_neg_prop ; If proportional negative - go to correct negative ; Subtract positive proportional clr C mov A, Governor_Req_Pwm subb A, Temp1 mov Temp1, A ; Check result jc governor_corr_prop_min_pwm ; Is result negative? clr C mov A, Temp1 ; Is result below pwm min? subb A, #1 jc governor_corr_prop_min_pwm ; Yes jmp governor_store_prop_corr ; No - store proportional correction governor_corr_prop_min_pwm: mov Temp1, #1 ; Load minimum pwm jmp governor_store_prop_corr governor_corr_neg_prop: ; Add negative proportional mov A, Temp1 cpl A add A, #1 add A, Governor_Req_Pwm mov Temp1, A ; Check result jc governor_corr_prop_max_pwm ; Is result above max? jmp governor_store_prop_corr ; No - store proportional correction governor_corr_prop_max_pwm: mov Temp1, #255 ; Load maximum pwm governor_store_prop_corr: ; Store proportional pwm mov Gov_Prop_Pwm, Temp1 calc_governor_prop_corr_exit: ret ; Fifth governor routine - calculate governor integral correction calc_governor_int_correction: ; Load integral gain mov Temp1, #Pgm_Gov_I_Gain_Decoded; Load integral gain mov A, @Temp1 mov Temp3, A ; Store in Temp3 ; Load integral mov Temp1, Gov_Integral_H mov Temp2, Gov_Integral_X ; Apply gain call mult_s16_by_u8_div_16 ; Check integral and limit mov A, Temp2 jnb ACC.7, governor_check_int_corr_limit_pos ; Check sign bit clr C mov A, Temp1 subb A, #01h ; Is integral too negative? mov A, Temp2 subb A, #0FFh jc governor_limit_int_corr_neg ; Yes - limit jmp governor_apply_int_corr governor_check_int_corr_limit_pos: clr C mov A, Temp1 subb A, #0FFh ; Is integral too positive? mov A, Temp2 subb A, #00h jnc governor_limit_int_corr_pos ; Yes - limit jmp governor_apply_int_corr governor_limit_int_corr_pos: mov Temp1, #0FFh ; Limit to max positive (2's complement) mov Temp2, #00h jmp governor_apply_int_corr governor_limit_int_corr_neg: mov Temp1, #01h ; Limit to max negative (2's complement) mov Temp2, #0FFh governor_apply_int_corr: ; Test integral sign mov A, Temp2 jb ACC.7, governor_corr_neg_int ; If integral negative - go to correct negative ; Subtract positive integral clr C mov A, Gov_Prop_Pwm subb A, Temp1 mov Temp1, A ; Check result jc governor_corr_int_min_pwm ; Is result negative? clr C mov A, Temp1 ; Is result below pwm min? subb A, #1 jc governor_corr_int_min_pwm ; Yes jmp governor_store_int_corr ; No - store correction governor_corr_int_min_pwm: mov Temp1, #1 ; Load minimum pwm jmp governor_store_int_corr governor_corr_neg_int: ; Add negative integral mov A, Temp1 cpl A add A, #1 add A, Gov_Prop_Pwm mov Temp1, A ; Check result jc governor_corr_int_max_pwm ; Is result above max? jmp governor_store_int_corr ; No - store correction governor_corr_int_max_pwm: mov Temp1, #255 ; Load maximum pwm governor_store_int_corr: ; Store current pwm mov Current_Pwm, Temp1 calc_governor_int_corr_exit: ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Set pwm limit low rpm ; ; No assumptions ; ; Sets power limit for low rpms and disables demag for low rpms ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** set_pwm_limit_low_rpm: ; Set pwm limit and demag disable for low rpms mov Temp1, #0FFh ; Default full power clr Flags0.DEMAG_ENABLED ; Default disabled jb Flags1.STARTUP_PHASE, set_pwm_limit_low_rpm_exit ; Exit if startup phase set jb Flags1.INITIAL_RUN_PHASE, set_pwm_demag_done ; Skip demag portion if initial run phase set setb Flags0.DEMAG_ENABLED ; Enable demag clr C mov A, Comm_Period4x_H subb A, #0Ah ; ~31250 eRPM jc set_pwm_demag_done ; If speed above - branch clr C mov A, Current_Pwm_Limited subb A, #40h ; Do not disable if pwm above 25% jnc set_pwm_demag_done clr Flags0.DEMAG_ENABLED ; Disable demag set_pwm_demag_done: mov Temp2, #Pgm_Enable_Power_Prot ; Check if low RPM power protection is enabled mov A, @Temp2 jz set_pwm_limit_low_rpm_exit ; Exit if disabled mov A, Comm_Period4x_H jz set_pwm_limit_low_rpm_exit ; Avoid divide by zero mov A, #255 ; Divide 255 by Comm_Period4x_H mov B, Comm_Period4x_H div AB mov B, Low_Rpm_Pwr_Slope ; Multiply by slope jnb Flags1.INITIAL_RUN_PHASE, ($+6) ; More protection for initial run phase mov B, #5 mul AB mov Temp1, A ; Set new limit xch A, B jz ($+4) ; Limit to max mov Temp1, #0FFh clr C mov A, Temp1 ; Limit to min subb A, Pwm_Spoolup_Beg jnc set_pwm_limit_low_rpm_exit mov Temp1, Pwm_Spoolup_Beg set_pwm_limit_low_rpm_exit: mov Pwm_Limit_By_Rpm, Temp1 ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Set pwm limit high rpm ; ; No assumptions ; ; Sets power limit for high rpms ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** set_pwm_limit_high_rpm: IF MCU_48MHZ == 1 clr C mov A, Comm_Period4x_L subb A, #0C8h ; Limit Comm_Period to 200, which is 400k erpm mov A, Comm_Period4x_H subb A, #00h ELSE clr C mov A, Comm_Period4x_L subb A, #40h ; Limit Comm_Period to 320, which is 250k erpm mov A, Comm_Period4x_H subb A, #01h ENDIF mov A, Pwm_Limit_By_Rpm jnc set_pwm_limit_high_rpm_inc_limit dec A ajmp set_pwm_limit_high_rpm_store set_pwm_limit_high_rpm_inc_limit: inc A set_pwm_limit_high_rpm_store: jz ($+4) mov Pwm_Limit_By_Rpm, A ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Measure lipo cells ; ; No assumptions ; ; Measure voltage and calculate lipo cells ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** measure_lipo_cells: IF MODE >= 1 ; Tail or multi ; If not supported, then exit jmp measure_lipo_exit ENDIF IF MODE == 0 ; Main ; Load programmed low voltage limit mov Temp1, #Pgm_Low_Voltage_Lim ; Load limit mov A, @Temp1 mov Bit_Access, A ; Store in Bit_Access ; Set commutation to BpFET on call comm5comm6 ; Start adc Start_Adc ; Wait for ADC reference to settle, and then start again call wait1ms Start_Adc ; Wait for ADC conversion to complete measure_lipo_wait_adc: Get_Adc_Status jb AD0BUSY, measure_lipo_wait_adc ; Read ADC result Read_Adc_Result ; Stop ADC Stop_Adc ; Switch power off call switch_power_off ; Set limit step mov Lipo_Adc_Limit_L, #ADC_LIMIT_L mov Lipo_Adc_Limit_H, #ADC_LIMIT_H clr C mov A, #ADC_LIMIT_H ; Divide 3.0V value by 2 rrc A mov Temp6, A mov A, #ADC_LIMIT_L jz measure_lipo_exit ; Exit if disabled rrc A mov Temp5, A mov A, #ADC_LIMIT_L ; Calculate 1.5*3.0V=4.5V value add A, Temp5 mov Temp5, A mov A, #ADC_LIMIT_H addc A, Temp6 mov Temp6, A mov A, Temp5 ; Copy step mov Temp3, A mov A, Temp6 mov Temp4, A measure_lipo_cell_loop: ; Check voltage against xS lower limit clr C mov A, Temp1 subb A, Temp3 ; Voltage above limit? mov A, Temp2 subb A, Temp4 jc measure_lipo_adjust ; No - branch ; Set xS voltage limit mov A, Lipo_Adc_Limit_L add A, #ADC_LIMIT_L mov Lipo_Adc_Limit_L, A mov A, Lipo_Adc_Limit_H addc A, #ADC_LIMIT_H mov Lipo_Adc_Limit_H, A ; Set (x+1)S lower limit mov A, Temp3 add A, Temp5 ; Add step mov Temp3, A mov A, Temp4 addc A, Temp6 mov Temp4, A jmp measure_lipo_cell_loop ; Check for one more battery cell measure_lipo_adjust: mov Temp7, Lipo_Adc_Limit_L mov Temp8, Lipo_Adc_Limit_H ; Calculate 3.125% clr C mov A, Lipo_Adc_Limit_H rrc A mov Temp2, A mov A, Lipo_Adc_Limit_L rrc A mov Temp1, A ; After this 50% clr C mov A, Temp2 rrc A mov Temp2, A mov A, Temp1 rrc A mov Temp1, A ; After this 25% ; Divide three times to get to 3.125% mov Temp3, #3 measure_lipo_divide_loop: clr C mov A, Temp2 rrc A mov Temp2, A mov A, Temp1 rrc A mov Temp1, A djnz Temp3, measure_lipo_divide_loop ; Add the programmed number of 0.1V (or 3.125% increments) mov Temp3, Bit_Access ; Load programmed limit (Bit_Access has Pgm_Low_Voltage_Lim) dec Temp3 jnz measure_lipo_limit_on ; Is low voltage limiting on? mov Lipo_Adc_Limit_L, #0 ; No - set limit to zero mov Lipo_Adc_Limit_H, #0 jmp measure_lipo_exit measure_lipo_limit_on: dec Temp3 mov A, Temp3 jz measure_lipo_update measure_lipo_add_loop: mov A, Temp7 ; Add 3.125% add A, Temp1 mov Temp7, A mov A, Temp8 addc A, Temp2 mov Temp8, A djnz Temp3, measure_lipo_add_loop measure_lipo_update: ; Set ADC limit mov Lipo_Adc_Limit_L, Temp7 mov Lipo_Adc_Limit_H, Temp8 ENDIF measure_lipo_exit: ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Start ADC conversion ; ; No assumptions ; ; Start conversion used for measuring power supply voltage ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** start_adc_conversion: ; Start adc Start_Adc ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Check temperature, power supply voltage and limit power ; ; No assumptions ; ; Used to limit main motor power in order to maintain the required voltage ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** check_temp_voltage_and_limit_power: ; Load programmed low voltage limit mov Temp1, #Pgm_Low_Voltage_Lim mov A, @Temp1 mov Temp8, A ; Store in Temp8 ; Wait for ADC conversion to complete Get_Adc_Status jb AD0BUSY, check_temp_voltage_and_limit_power ; Read ADC result Read_Adc_Result ; Stop ADC Stop_Adc inc Adc_Conversion_Cnt ; Increment conversion counter clr C mov A, Adc_Conversion_Cnt ; Is conversion count equal to temp rate? subb A, #TEMP_CHECK_RATE jc check_voltage_start ; No - check voltage mov Adc_Conversion_Cnt, #0 ; Yes - temperature check. Reset counter mov A, Temp2 ; Move ADC MSB to Temp3 mov Temp3, A mov Temp2, #Pgm_Enable_Temp_Prot ; Is temp protection enabled? mov A, @Temp2 jz temp_check_exit ; No - branch mov A, Temp3 ; Is temperature reading below 256? jnz temp_average_inc_dec ; No - proceed mov A, Current_Average_Temp ; Yes - decrement average jz temp_average_updated ; Already zero - no change jmp temp_average_dec ; Decrement temp_average_inc_dec: clr C mov A, Temp1 ; Check if current temperature is above or below average subb A, Current_Average_Temp jz temp_average_updated_load_acc ; Equal - no change mov A, Current_Average_Temp ; Above - increment average jnc temp_average_inc jz temp_average_updated ; Below - decrement average if average is not already zero temp_average_dec: dec A ; Decrement average jmp temp_average_updated temp_average_inc: inc A ; Increment average jz temp_average_dec jmp temp_average_updated temp_average_updated_load_acc: mov A, Current_Average_Temp temp_average_updated: mov Current_Average_Temp, A clr C subb A, #TEMP_LIMIT ; Is temperature below first limit? jc temp_check_exit ; Yes - exit mov Pwm_Limit, #192 ; No - limit pwm clr C subb A, #TEMP_LIMIT_STEP ; Is temperature below second limit jc temp_check_exit ; Yes - exit mov Pwm_Limit, #128 ; No - limit pwm clr C subb A, #TEMP_LIMIT_STEP ; Is temperature below third limit jc temp_check_exit ; Yes - exit mov Pwm_Limit, #64 ; No - limit pwm clr C subb A, #TEMP_LIMIT_STEP ; Is temperature below final limit jc temp_check_exit ; Yes - exit mov Pwm_Limit, #0 ; No - limit pwm temp_check_exit: Set_Adc_Ip_Volt ; Select adc input for next conversion ret check_voltage_start: IF MODE == 0 ; Main ; Check if low voltage limiting is enabled mov A, Temp8 clr C subb A, #1 ; Is low voltage limit disabled? jz check_voltage_good ; Yes - voltage declared good mov A, #ADC_LIMIT_L ; Is low voltage limit zero (ESC does not support it)? jz check_voltage_good ; Yes - voltage declared good ; Check if ADC is saturated clr C mov A, Temp1 subb A, #0FFh mov A, Temp2 subb A, #03h jnc check_voltage_good ; ADC saturated, can not make judgement ; Check voltage against limit clr C mov A, Temp1 subb A, Lipo_Adc_Limit_L mov A, Temp2 subb A, Lipo_Adc_Limit_H jnc check_voltage_good ; If voltage above limit - branch ; Decrease pwm limit mov A, Pwm_Limit jz check_voltage_lim ; If limit zero - branch dec Pwm_Limit ; Decrement limit jmp check_voltage_lim check_voltage_good: ; Increase pwm limit mov A, Pwm_Limit cpl A jz check_voltage_lim ; If limit max - branch inc Pwm_Limit ; Increment limit check_voltage_lim: mov Temp1, Pwm_Limit ; Set limit clr C mov A, Current_Pwm subb A, Temp1 jnc check_voltage_spoolup_lim ; If current pwm above limit - branch and limit mov Temp1, Current_Pwm ; Set current pwm (no limiting) check_voltage_spoolup_lim: ; Slow spoolup clr C mov A, Temp1 subb A, Pwm_Limit_Spoolup jc check_voltage_exit ; If current pwm below limit - branch mov Temp1, Pwm_Limit_Spoolup mov A, Pwm_Limit_Spoolup ; Check if spoolup limit is max cpl A jz check_voltage_exit ; If max - branch mov Pwm_Limit, Pwm_Limit_Spoolup ; Set pwm limit to spoolup limit during ramp (to avoid governor integral buildup) check_voltage_exit: mov Current_Pwm_Limited, Temp1 mov Current_Pwm_Lim_Dith, Temp1 ENDIF IF MODE == 1 ; Tail ; Increase pwm limit mov A, Pwm_Limit cpl A jz check_voltage_lim ; If limit max - branch inc Pwm_Limit ; Increment limit check_voltage_lim: ENDIF IF MODE == 2 ; Multi ; Increase pwm limit mov A, Pwm_Limit add A, #16 jnc ($+4) ; If not max - branch mov A, #255 mov Pwm_Limit, A ; Increment limit ; Set current pwm limited if closed loop mode mov Temp2, #Pgm_Gov_Mode ; Governor mode? cjne @Temp2, #4, ($+5) ajmp check_voltage_pwm_done ; No - branch clr C mov Temp1, Pwm_Limit ; Set limit mov A, Current_Pwm subb A, Temp1 jnc check_voltage_low_rpm ; If current pwm above limit - branch and limit mov Temp1, Current_Pwm ; Set current pwm (no limiting) check_voltage_low_rpm: ; Limit pwm for low rpms clr C mov A, Temp1 ; Check against limit subb A, Pwm_Limit_By_Rpm jc ($+4) ; If current pwm below limit - branch mov Temp1, Pwm_Limit_By_Rpm ; Limit pwm mov Current_Pwm_Limited, Temp1 mov Current_Pwm_Lim_Dith, Temp1 check_voltage_pwm_done: ENDIF ; Set adc mux for next conversion mov A, Adc_Conversion_Cnt ; Is next conversion for temperature? cjne A, #(TEMP_CHECK_RATE-1), check_voltage_ret Set_Adc_Ip_Temp ; Select temp sensor for next conversion check_voltage_ret: ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Set startup PWM routine ; ; Either the SETTLE_PHASE or the STEPPER_PHASE flag must be set ; ; Used for pwm control during startup ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** set_startup_pwm: ; Adjust startup power mov A, #PWM_START ; Set power mov Temp2, #Pgm_Startup_Pwr_Decoded mov B, @Temp2 mul AB xch A, B mov C, B.7 ; Multiply result by 2 (unity gain is 128) rlc A mov Temp1, A ; Transfer to Temp1 clr C mov A, Temp1 ; Check against limit subb A, Pwm_Limit jc startup_pwm_set_pwm ; If pwm below limit - branch mov Temp1, Pwm_Limit ; Limit pwm startup_pwm_set_pwm: ; Set pwm variables mov Requested_Pwm, Temp1 ; Update requested pwm mov Current_Pwm, Temp1 ; Update current pwm mov Current_Pwm_Limited, Temp1 ; Update limited version of current pwm mov Current_Pwm_Lim_Dith, Temp1 mov Pwm_Spoolup_Beg, Temp1 ; Yes - update spoolup beginning pwm (will use PWM_SETTLE or PWM_SETTLE/2) ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Initialize timing routine ; ; No assumptions ; ; Part of initialization before motor start ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** initialize_timing: mov Comm_Period4x_L, #00h ; Set commutation period registers mov Comm_Period4x_H, #0F0h ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Calculate next commutation timing routine ; ; No assumptions ; ; Called immediately after each commutation ; Also sets up timer 3 to wait advance timing ; Two entry points are used ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** calc_next_comm_timing: ; Entry point for run phase ; Read commutation time clr EA mov TMR2CN, #20h ; Timer2 disabled mov Temp1, TMR2L ; Load timer value mov Temp2, TMR2H mov Temp3, Timer2_X jnb TF2H, ($+4) ; Check if interrupt is pending inc Temp3 ; If it is pending, then timer has already wrapped mov TMR2CN, #24h ; Timer2 enabled setb EA IF MCU_48MHZ == 1 clr C mov A, Temp3 rrc A mov Temp3, A mov A, Temp2 rrc A mov Temp2, A mov A, Temp1 rrc A mov Temp1, A ENDIF ; Calculate this commutation time mov Temp4, Prev_Comm_L mov Temp5, Prev_Comm_H mov Prev_Comm_L, Temp1 ; Store timestamp as previous commutation mov Prev_Comm_H, Temp2 clr C mov A, Temp1 subb A, Temp4 ; Calculate the new commutation time mov Temp1, A mov A, Temp2 subb A, Temp5 jb Flags1.STARTUP_PHASE, calc_next_comm_startup IF MCU_48MHZ == 1 anl A, #7Fh ENDIF mov Temp2, A jnb Flags0.HIGH_RPM, ($+5) ; Branch if high rpm ajmp calc_next_comm_timing_fast ajmp calc_next_comm_normal calc_next_comm_startup: mov Temp6, Prev_Comm_X mov Prev_Comm_X, Temp3 ; Store extended timestamp as previous commutation mov Temp2, A mov A, Temp3 subb A, Temp6 ; Calculate the new extended commutation time IF MCU_48MHZ == 1 anl A, #7Fh ENDIF mov Temp3, A jz ($+6) mov Temp1, #0FFh mov Temp2, #0FFh mov Temp7, Prev_Prev_Comm_L mov Temp8, Prev_Prev_Comm_H mov Prev_Prev_Comm_L, Temp4 mov Prev_Prev_Comm_H, Temp5 clr C mov A, Temp5 subb A, Temp8 ; Calculate previous commutation time (hi byte only) mov Temp5, A clr C mov A, Temp2 subb A, Temp5 ; Calculate the difference between the two previous commutation times (hi bytes only) mov Comm_Diff, A mov Temp1, Prev_Comm_L ; Reload this commutation time mov Temp2, Prev_Comm_H clr C mov A, Temp1 subb A, Temp7 ; Calculate the new commutation time based upon the two last commutations (to reduce sensitivity to offset) mov Temp1, A mov A, Temp2 subb A, Temp8 mov Temp2, A clr C mov A, Comm_Period4x_H ; Average with previous and save rrc A mov Temp4, A mov A, Comm_Period4x_L rrc A mov Temp3, A mov A, Temp1 add A, Temp3 mov Comm_Period4x_L, A mov A, Temp2 addc A, Temp4 mov Comm_Period4x_H, A jnc ($+8) mov Comm_Period4x_L, #0FFh mov Comm_Period4x_H, #0FFh ajmp calc_new_wait_times_setup calc_next_comm_normal: ; Calculate new commutation time mov Temp3, Comm_Period4x_L ; Comm_Period4x(-l-h) holds the time of 4 commutations mov Temp4, Comm_Period4x_H mov Temp5, Comm_Period4x_L ; Copy variables mov Temp6, Comm_Period4x_H mov Temp7, #4 ; Divide Comm_Period4x 4 times as default mov Temp8, #2 ; Divide new commutation time 2 times as default clr C mov A, Temp4 subb A, #04h jc ($+4) dec Temp7 ; Reduce averaging time constant for low speeds dec Temp8 clr C mov A, Temp4 subb A, #08h jc ($+4) dec Temp7 ; Reduce averaging time constant more for even lower speeds dec Temp8 calc_next_comm_avg_period_div: clr C mov A, Temp6 rrc A ; Divide by 2 mov Temp6, A mov A, Temp5 rrc A mov Temp5, A djnz Temp7, calc_next_comm_avg_period_div clr C mov A, Temp3 subb A, Temp5 ; Subtract a fraction mov Temp3, A mov A, Temp4 subb A, Temp6 mov Temp4, A mov A, Temp8 ; Divide new time jz calc_next_comm_new_period_div_done calc_next_comm_new_period_div: clr C mov A, Temp2 rrc A ; Divide by 2 mov Temp2, A mov A, Temp1 rrc A mov Temp1, A djnz Temp8, calc_next_comm_new_period_div calc_next_comm_new_period_div_done: mov A, Temp3 add A, Temp1 ; Add the divided new time mov Temp3, A mov A, Temp4 addc A, Temp2 mov Temp4, A mov Comm_Period4x_L, Temp3 ; Store Comm_Period4x_X mov Comm_Period4x_H, Temp4 jnc calc_new_wait_times_setup; If period larger than 0xffff - go to slow case mov Temp4, #0FFh mov Comm_Period4x_L, Temp4 ; Set commutation period registers to very slow timing (0xffff) mov Comm_Period4x_H, Temp4 calc_new_wait_times_setup: ; Set high rpm bit (if above 156k erpm) clr C mov A, Temp4 subb A, #2 jnc ($+4) setb Flags0.HIGH_RPM ; Set high rpm bit ; Load programmed commutation timing jnb Flags1.STARTUP_PHASE, calc_new_wait_per_startup_done ; Set dedicated timing during startup mov Temp8, #3 ajmp calc_new_wait_per_demag_done calc_new_wait_per_startup_done: mov Temp1, #Pgm_Comm_Timing ; Load timing setting mov A, @Temp1 mov Temp8, A ; Store in Temp8 clr C mov A, Demag_Detected_Metric ; Check demag metric subb A, #130 jc calc_new_wait_per_demag_done inc Temp8 ; Increase timing clr C mov A, Demag_Detected_Metric subb A, #160 jc ($+3) inc Temp8 ; Increase timing again clr C mov A, Temp8 ; Limit timing to max subb A, #6 jc ($+4) mov Temp8, #5 ; Set timing to max calc_new_wait_per_demag_done: IF MCU_48MHZ == 0 ; Set timing reduction IF (NFETON_DELAY < 128) AND (PFETON_DELAY < 128) IF ((NFETON_DELAY + PFETON_DELAY) <= 30) mov Temp7, #(4 + ((NFETON_DELAY + PFETON_DELAY)/10)) ; Min to max ELSE mov Temp7, #7 ; Max ENDIF ELSE mov Temp7, #5 ; Mid ENDIF ELSE IF (NFETON_DELAY < 128) AND (PFETON_DELAY < 128) IF ((NFETON_DELAY + PFETON_DELAY) <= 40) mov Temp7, #(2 + ((NFETON_DELAY + PFETON_DELAY)/20)) ; Min to max ELSE mov Temp7, #4 ; Max ENDIF ELSE mov Temp7, #3 ; Mid ENDIF ENDIF ; Load current commutation timing mov A, Comm_Period4x_H ; Divide 4 times swap A anl A, #00Fh mov Temp2, A mov A, Comm_Period4x_H swap A anl A, #0F0h mov Temp1, A mov A, Comm_Period4x_L swap A anl A, #00Fh add A, Temp1 mov Temp1, A clr C mov A, Temp1 subb A, Temp7 mov Temp3, A mov A, Temp2 subb A, #0 mov Temp4, A jc load_min_time ; Check that result is still positive clr C mov A, Temp3 subb A, #(COMM_TIME_MIN SHL 1) mov A, Temp4 subb A, #0 jnc calc_new_wait_times_exit ; Check that result is still above minumum load_min_time: mov Temp3, #(COMM_TIME_MIN SHL 1) clr A mov Temp4, A calc_new_wait_times_exit: ajmp wait_advance_timing ; Fast calculation (Comm_Period4x_H less than 2) calc_next_comm_timing_fast: ; Calculate new commutation time mov Temp3, Comm_Period4x_L ; Comm_Period4x(-l-h) holds the time of 4 commutations mov Temp4, Comm_Period4x_H mov A, Temp4 ; Divide by 2 4 times swap A mov Temp7, A mov A, Temp3 swap A anl A, #0Fh orl A, Temp7 mov Temp5, A clr C mov A, Temp3 ; Subtract a fraction subb A, Temp5 mov Temp3, A mov A, Temp4 subb A, #0 mov Temp4, A clr C mov A, Temp1 rrc A ; Divide by 2 2 times clr C rrc A mov Temp1, A mov A, Temp3 ; Add the divided new time add A, Temp1 mov Temp3, A mov A, Temp4 addc A, #0 mov Temp4, A mov Comm_Period4x_L, Temp3 ; Store Comm_Period4x_X mov Comm_Period4x_H, Temp4 clr C mov A, Temp4 ; If erpm below 156k - go to normal case subb A, #2 jc ($+4) clr Flags0.HIGH_RPM ; Clear high rpm bit IF MCU_48MHZ == 0 ; Set timing reduction IF (NFETON_DELAY < 128) AND (PFETON_DELAY < 128) IF ((NFETON_DELAY + PFETON_DELAY) <= 30) mov Temp1, #(4 + ((NFETON_DELAY + PFETON_DELAY)/10)) ; Min to max ELSE mov Temp1, #7 ; Max ENDIF ELSE mov Temp1, #5 ; Mid ENDIF ELSE IF (NFETON_DELAY < 128) AND (PFETON_DELAY < 128) IF ((NFETON_DELAY + PFETON_DELAY) <= 40) mov Temp1, #(2 + ((NFETON_DELAY + PFETON_DELAY)/20)) ; Min to max ELSE mov Temp1, #4 ; Max ENDIF ELSE mov Temp1, #3 ; Mid ENDIF ENDIF mov A, Temp4 ; Divide by 2 4 times swap A mov Temp7, A mov Temp4, #0 mov A, Temp3 swap A anl A, #0Fh orl A, Temp7 mov Temp3, A clr C mov A, Temp3 subb A, Temp1 mov Temp3, A jc load_min_time_fast ; Check that result is still positive clr C subb A, #(COMM_TIME_MIN SHL 1) jnc calc_new_wait_times_fast_done ; Check that result is still above minumum load_min_time_fast: mov Temp3, #(COMM_TIME_MIN SHL 1) calc_new_wait_times_fast_done: mov Temp1, #Pgm_Comm_Timing ; Load timing setting mov A, @Temp1 mov Temp8, A ; Store in Temp8 ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Wait advance timing routine ; ; No assumptions ; NOTE: Be VERY careful if using temp registers. They are passed over this routine ; ; Waits for the advance timing to elapse and sets up the next zero cross wait ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** wait_advance_timing: jnb Flags0.T3_PENDING, ($+5) ajmp wait_advance_timing ; Setup next wait time mov Next_Wt_Start_L, Wt_ZC_Tout_Start_L mov Next_Wt_Start_H, Wt_ZC_Tout_Start_H setb Flags0.T3_PENDING orl EIE1, #80h ; Enable timer3 interrupts ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Calculate new wait times routine ; ; No assumptions ; ; Calculates new wait times ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** calc_new_wait_times: clr C clr A subb A, Temp3 ; Negate mov Temp1, A clr A subb A, Temp4 mov Temp2, A IF MCU_48MHZ == 1 clr C mov A, Temp1 ; Multiply by 2 rlc A mov Temp1, A mov A, Temp2 rlc A mov Temp2, A ENDIF jnb Flags0.HIGH_RPM, ($+5) ; Branch if high rpm ajmp calc_new_wait_times_fast mov A, Temp1 ; Copy values mov Temp3, A mov A, Temp2 mov Temp4, A setb C ; Negative numbers - set carry mov A, Temp2 rrc A ; Divide by 2 mov Temp6, A mov A, Temp1 rrc A mov Temp5, A mov Wt_Zc_Tout_Start_L, Temp1; Set 15deg time for zero cross scan timeout mov Wt_Zc_Tout_Start_H, Temp2 clr C mov A, Temp8 ; (Temp8 has Pgm_Comm_Timing) subb A, #3 ; Is timing normal? jz store_times_decrease ; Yes - branch mov A, Temp8 jb ACC.0, adjust_timing_two_steps ; If an odd number - branch mov A, Temp1 ; Add 7.5deg and store in Temp1/2 add A, Temp5 mov Temp1, A mov A, Temp2 addc A, Temp6 mov Temp2, A mov A, Temp5 ; Store 7.5deg in Temp3/4 mov Temp3, A mov A, Temp6 mov Temp4, A jmp store_times_up_or_down adjust_timing_two_steps: mov A, Temp1 ; Add 15deg and store in Temp1/2 add A, Temp1 mov Temp1, A mov A, Temp2 addc A, Temp2 mov Temp2, A clr C mov A, Temp1 add A, #(COMM_TIME_MIN SHL 1) mov Temp1, A mov A, Temp2 addc A, #0 mov Temp2, A mov Temp3, #-(COMM_TIME_MIN SHL 1); Store minimum time in Temp3/4 mov Temp4, #0FFh store_times_up_or_down: clr C mov A, Temp8 subb A, #3 ; Is timing higher than normal? jc store_times_decrease ; No - branch store_times_increase: mov Wt_Comm_Start_L, Temp3 ; Now commutation time (~60deg) divided by 4 (~15deg nominal) mov Wt_Comm_Start_H, Temp4 mov Wt_Adv_Start_L, Temp1 ; New commutation advance time (~15deg nominal) mov Wt_Adv_Start_H, Temp2 mov Wt_Zc_Scan_Start_L, Temp5 ; Use this value for zero cross scan delay (7.5deg) mov Wt_Zc_Scan_Start_H, Temp6 ajmp wait_before_zc_scan store_times_decrease: mov Wt_Comm_Start_L, Temp1 ; Now commutation time (~60deg) divided by 4 (~15deg nominal) mov Wt_Comm_Start_H, Temp2 mov Wt_Adv_Start_L, Temp3 ; New commutation advance time (~15deg nominal) mov Wt_Adv_Start_H, Temp4 mov Wt_Zc_Scan_Start_L, Temp5 ; Use this value for zero cross scan delay (7.5deg) mov Wt_Zc_Scan_Start_H, Temp6 jnb Flags1.STARTUP_PHASE, store_times_exit clr C mov A, Startup_Cnt subb A, #3 jc store_times_exit mov A, Comm_Diff ; Compensate commutation wait for comparator offset mov C, ACC.7 rrc A mov Temp1, A mov A, Wt_Comm_Start_H cpl A add A, #1 addc A, Temp1 jc store_times_exit jb ACC.7, store_times_exit mov Wt_Comm_Start_L, #0FFh cpl A add A, #1 mov Wt_Comm_Start_H, A store_times_exit: ajmp wait_before_zc_scan calc_new_wait_times_fast: mov A, Temp1 ; Copy values mov Temp3, A setb C ; Negative numbers - set carry mov A, Temp1 ; Divide by 2 rrc A mov Temp5, A mov Wt_Zc_Tout_Start_L, Temp1; Set 15deg time for zero cross scan timeout clr C mov A, Temp8 ; (Temp8 has Pgm_Comm_Timing) subb A, #3 ; Is timing normal? jz store_times_decrease_fast; Yes - branch mov A, Temp8 jb ACC.0, adjust_timing_two_steps_fast ; If an odd number - branch mov A, Temp1 ; Add 7.5deg and store in Temp1 add A, Temp5 mov Temp1, A mov A, Temp5 ; Store 7.5deg in Temp3 mov Temp3, A ajmp store_times_up_or_down_fast adjust_timing_two_steps_fast: mov A, Temp1 ; Add 15deg and store in Temp1 add A, Temp1 add A, #(COMM_TIME_MIN SHL 1) mov Temp1, A mov Temp3, #-(COMM_TIME_MIN SHL 1) ; Store minimum time in Temp3 store_times_up_or_down_fast: clr C mov A, Temp8 subb A, #3 ; Is timing higher than normal? jc store_times_decrease_fast; No - branch store_times_increase_fast: mov Wt_Comm_Start_L, Temp3 ; Now commutation time (~60deg) divided by 4 (~15deg nominal) mov Wt_Adv_Start_L, Temp1 ; New commutation advance time (~15deg nominal) mov Wt_Zc_Scan_Start_L, Temp5 ; Use this value for zero cross scan delay (7.5deg) ajmp wait_before_zc_scan store_times_decrease_fast: mov Wt_Comm_Start_L, Temp1 ; Now commutation time (~60deg) divided by 4 (~15deg nominal) mov Wt_Adv_Start_L, Temp3 ; New commutation advance time (~15deg nominal) mov Wt_Zc_Scan_Start_L, Temp5 ; Use this value for zero cross scan delay (7.5deg) ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Wait before zero cross scan routine ; ; No assumptions ; ; Waits for the zero cross scan wait time to elapse ; Also sets up timer 3 for the zero cross scan timeout time ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** wait_before_zc_scan: ; Calculate random number mov A, Random clr C rlc A jnc wait_before_zc_scan_rand xrl A, #06Bh ; Sequence length of 35, when initialized to 1 wait_before_zc_scan_rand: mov Random, A wait_before_zc_scan_wait: jnb Flags0.T3_PENDING, ($+5) ajmp wait_before_zc_scan_wait IF MCU_48MHZ == 1 mov Startup_Zc_Timeout_Cntd, #4 ELSE mov Startup_Zc_Timeout_Cntd, #2 ENDIF setup_zc_scan_timeout: setb Flags0.T3_PENDING orl EIE1, #80h ; Enable timer3 interrupts mov A, Flags1 anl A, #((1 SHL STARTUP_PHASE)+(1 SHL INITIAL_RUN_PHASE)) jz wait_before_zc_scan_exit mov Temp1, Comm_Period4x_L ; Set long timeout when starting mov Temp2, Comm_Period4x_H IF MCU_48MHZ == 0 clr C mov A, Temp2 rrc A mov Temp2, A mov A, Temp1 rrc A mov Temp1, A ENDIF clr EA anl EIE1, #7Fh ; Disable timer3 interrupts mov TMR3CN, #00h ; Timer3 disabled and interrupt flag cleared clr C clr A subb A, Temp1 ; Set timeout mov TMR3L, A clr A subb A, Temp2 mov TMR3H, A mov TMR3CN, #04h ; Timer3 enabled and interrupt flag cleared setb Flags0.T3_PENDING orl EIE1, #80h ; Enable timer3 interrupts setb EA wait_before_zc_scan_exit: ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Wait for comparator to go low/high routines ; ; No assumptions ; ; Waits for the zero cross scan wait time to elapse ; Then scans for comparator going low/high ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** wait_for_comp_out_low: setb Flags0.DEMAG_DETECTED ; Set demag detected flag as default mov Comparator_Read_Cnt, #0 ; Reset number of comparator reads mov Bit_Access, #00h ; Desired comparator output jnb Flags1.DIR_CHANGE_BRAKE, ($+6) mov Bit_Access, #40h jmp wait_for_comp_out_start wait_for_comp_out_high: setb Flags0.DEMAG_DETECTED ; Set demag detected flag as default mov Comparator_Read_Cnt, #0 ; Reset number of comparator reads mov Bit_Access, #40h ; Desired comparator output jnb Flags1.DIR_CHANGE_BRAKE, ($+6) mov Bit_Access, #00h wait_for_comp_out_start: setb EA ; Enable interrupts ; Set number of comparator readings mov Temp1, #1 ; Number of OK readings required jb Flags0.HIGH_RPM, comp_wait_on_comp_able ; Branch if high rpm mov A, Flags1 ; Clear demag detected flag if start phases anl A, #((1 SHL STARTUP_PHASE)+(1 SHL INITIAL_RUN_PHASE)) jz ($+4) clr Flags0.DEMAG_DETECTED clr C ; Set number of readings higher for lower speeds mov A, Comm_Period4x_H subb A, #05h jc comp_wait_on_comp_able mov Temp1, #2 subb A, #05h jc comp_wait_no_of_readings mov Temp1, #3 subb A, #05h ; Set number of consecutive readings higher for lower speeds jc comp_wait_no_of_readings mov Temp1, #6 comp_wait_no_of_readings: jnb Flags1.STARTUP_PHASE, ($+5) ; Set many samples during startup mov Temp1, #10 comp_wait_on_comp_able: jb Flags0.T3_PENDING, comp_wait_on_comp_able_not_timed_out ; Has zero cross scan timeout elapsed? mov A, Comparator_Read_Cnt ; Check that comparator has been read jz comp_wait_on_comp_able_not_timed_out ; If not read - branch jnb Flags1.STARTUP_PHASE, comp_wait_on_comp_able_timeout_extended ; Extend timeout during startup clr C mov A, Startup_Cnt ; Do not extend timeout for the first commutations subb A, #3 jc comp_wait_on_comp_able_timeout_extended djnz Startup_Zc_Timeout_Cntd, comp_wait_on_comp_able_extend_timeout comp_wait_on_comp_able_timeout_extended: setb EA ; Enable interrupts setb Flags1.COMP_TIMED_OUT ajmp setup_comm_wait comp_wait_on_comp_able_extend_timeout: call setup_zc_scan_timeout comp_wait_on_comp_able_not_timed_out: setb EA ; Enable interrupts nop ; Allocate only just enough time to capture interrupt nop clr EA ; Disable interrupts jb Flags0.HIGH_RPM, comp_wait_read_comp ; Branch if high rpm mov A, Comm_Period4x_H ; Reduce required distance to pwm transition for higher speeds clr C mov Temp4, A subb A, #0Fh jc ($+4) mov Temp4, #0Fh mov A, Temp4 add A, #5 jnb Flags2.PGM_PWM_HIGH_FREQ, ($+4) ; More delay for high pwm frequency rl A jnb Flags1.INITIAL_RUN_PHASE, ($+5) mov A, #40 jb Flags0.PWM_ON, ($+4) ; More delay for pwm off rl A mov Temp2, A jnb Flags1.STARTUP_PHASE, ($+5) ; Set a long delay from pwm on/off events during startup mov Temp2, #130 IF MCU_48MHZ == 0 mov A, TL1 ELSE mov A, TH1 rrc A mov A, TL1 rrc A ENDIF clr C subb A, Temp2 jc comp_wait_on_comp_able ; Re-evaluate pwm cycle comp_wait_read_comp: inc Comparator_Read_Cnt ; Increment comparator read count Read_Comp_Out ; Read comparator output anl A, #40h cjne A, Bit_Access, comp_read_wrong ajmp comp_read_ok comp_read_wrong: jnb Flags1.STARTUP_PHASE, comp_read_wrong_not_startup inc Temp1 ; Increment number of OK readings required clr C mov A, Temp1 subb A, #10 ; If above initial requirement - go back and restart jc ($+3) inc Temp1 ajmp comp_wait_on_comp_able ; If below initial requirement - continue to look for good ones comp_read_wrong_not_startup: jb Flags0.DEMAG_DETECTED, ($+5) ajmp wait_for_comp_out_start ; If comparator output is not correct, and timeout already extended - go back and restart clr Flags0.DEMAG_DETECTED ; Clear demag detected flag anl EIE1, #7Fh ; Disable timer3 interrupts mov TMR3CN, #00h ; Timer3 disabled and interrupt flag cleared jnb Flags0.HIGH_RPM, comp_read_wrong_low_rpm ; Branch if not high rpm mov TMR3L, #00h ; Set timeout to 256us IF MCU_48MHZ == 1 mov TMR3H, #0FCh ELSE mov TMR3H, #0FEh ENDIF comp_read_wrong_timeout_set: mov TMR3CN, #04h ; Timer3 enabled and interrupt flag cleared setb Flags0.T3_PENDING orl EIE1, #80h ; Enable timer3 interrupts ajmp wait_for_comp_out_start ; If comparator output is not correct - go back and restart comp_read_wrong_low_rpm: mov Temp7, Comm_Period4x_L ; Set timeout to comm period 4x value mov Temp8, Comm_Period4x_H IF MCU_48MHZ == 1 clr C mov A, Temp7 rlc A mov Temp7, A mov A, Temp8 rlc A mov Temp8, A jnc ($+6) mov Temp7, #0FFh mov Temp8, #0FFh ENDIF clr C clr A subb A, Temp7 mov TMR3L, A clr A subb A, Temp8 mov TMR3H, A ajmp comp_read_wrong_timeout_set comp_read_ok: clr C mov A, Startup_Cnt ; Force a timeout for the first commutations subb A, #2 jnc ($+4) ajmp wait_for_comp_out_start jnb Flags0.DEMAG_DETECTED, ($+5) ; Do not accept correct comparator output if it is demag ajmp wait_for_comp_out_start djnz Temp1, comp_read_ok_jmp ; Decrement readings counter - repeat comparator reading if not zero ajmp ($+4) comp_read_ok_jmp: ajmp comp_wait_on_comp_able clr Flags1.COMP_TIMED_OUT ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Setup commutation timing routine ; ; No assumptions ; ; Sets up and starts wait from commutation to zero cross ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** setup_comm_wait: anl EIE1, #7Fh ; Disable timer3 interrupts mov TMR3CN, #00h ; Timer3 disabled and interrupt flag cleared mov TMR3L, Wt_Comm_Start_L mov TMR3H, Wt_Comm_Start_H mov TMR3CN, #04h ; Timer3 enabled and interrupt flag cleared ; Setup next wait time mov Next_Wt_Start_L, Wt_Adv_Start_L mov Next_Wt_Start_H, Wt_Adv_Start_H setb Flags0.T3_PENDING orl EIE1, #80h ; Enable timer3 interrupts setb EA ; Enable interrupts again ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Evaluate comparator integrity ; ; No assumptions ; ; Checks comparator signal behaviour versus expected behaviour ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** evaluate_comparator_integrity: mov A, Flags1 anl A, #((1 SHL STARTUP_PHASE)+(1 SHL INITIAL_RUN_PHASE)) jz eval_comp_check_timeout jb Flags1.INITIAL_RUN_PHASE, ($+5) ; Do not increment beyond startup phase inc Startup_Cnt ; Increment counter jmp eval_comp_exit eval_comp_check_timeout: jnb Flags1.COMP_TIMED_OUT, eval_comp_exit ; Has timeout elapsed? jb Flags1.DIR_CHANGE_BRAKE, eval_comp_exit ; Do not exit run mode if it is braking jb Flags0.DEMAG_DETECTED, eval_comp_exit ; Do not exit run mode if it is a demag situation dec SP ; Routine exit without "ret" command dec SP ljmp run_to_wait_for_power_on_fail ; Yes - exit run mode eval_comp_exit: ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Wait for commutation routine ; ; No assumptions ; ; Waits from zero cross to commutation ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** wait_for_comm: ; Update demag metric mov Temp1, #0 jnb Flags0.DEMAG_ENABLED, ($+8); If demag disabled - branch jnb Flags0.DEMAG_DETECTED, ($+5) mov Temp1, #1 mov A, Demag_Detected_Metric ; Sliding average of 8, 256 when demag and 0 when not. Limited to minimum 120 mov B, #7 mul AB ; Multiply by 7 mov Temp2, A mov A, B ; Add new value for current demag status add A, Temp1 mov B, A mov A, Temp2 mov C, B.0 ; Divide by 8 rrc A mov C, B.1 rrc A mov C, B.2 rrc A mov Demag_Detected_Metric, A clr C subb A, #120 ; Limit to minimum 120 jnc ($+5) mov Demag_Detected_Metric, #120 clr C mov A, Demag_Detected_Metric ; Check demag metric subb A, Demag_Pwr_Off_Thresh jc wait_for_comm_wait ; Cut power if many consecutive demags. This will help retain sync during hard accelerations setb Flags0.DEMAG_CUT_POWER ; Set demag power cut flag All_nFETs_off wait_for_comm_wait: jnb Flags0.T3_PENDING, ($+5) ajmp wait_for_comm_wait ; Setup next wait time mov Next_Wt_Start_L, Wt_Zc_Scan_Start_L mov Next_Wt_Start_H, Wt_Zc_Scan_Start_H setb Flags0.T3_PENDING orl EIE1, #80h ; Enable timer3 interrupts ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Commutation routines ; ; No assumptions ; ; Performs commutation switching ; Damped routines uses all pfets on when in pwm off to dampen the motor ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; Comm phase 1 to comm phase 2 comm1comm2: Set_RPM_Out jb Flags3.PGM_DIR_REV, comm12_rev clr EA ; Disable all interrupts mov Comm_Phase, #2 BpFET_off ; Turn off pfet ApFET_on ; Turn on pfet setb EA Set_Comp_Phase_B ; Set comparator phase jmp comm_exit comm12_rev: clr EA ; Disable all interrupts mov Comm_Phase, #2 BpFET_off ; Turn off pfet CpFET_on ; Turn on pfet (reverse) setb EA Set_Comp_Phase_B ; Set comparator phase jmp comm_exit ; Comm phase 2 to comm phase 3 comm2comm3: Clear_RPM_Out jnb Flags2.PGM_PWMOFF_DAMPED, comm23_nondamp ; Comm2Comm3 Damped jb Flags3.PGM_DIR_REV, comm23_damp_rev clr EA ; Disable all interrupts mov Comm_Phase, #3 mov DPTR, #pwm_bfet_damped mov DampingFET, #(1 SHL BpFET) CnFET_off ; Turn off fets CpFET_off jnb Flags0.PWM_ON, comm23_nfet_off ; Is pwm on? BnFET_on ; Pwm on - turn on nfet ajmp comm23_fets_done comm23_nfet_off: BpFET_on ; Pwm off - switch damping fets comm23_fets_done: setb EA Set_Comp_Phase_C ; Set comparator phase ljmp comm_exit ; Comm2Comm3 Damped reverse comm23_damp_rev: clr EA ; Disable all interrupts mov Comm_Phase, #3 mov DPTR, #pwm_bfet_damped mov DampingFET, #(1 SHL BpFET) AnFET_off ; Turn off fets (reverse) ApFET_off jnb Flags0.PWM_ON, comm23_nfet_off_rev ; Is pwm on? BnFET_on ; Pwm on - turn on nfet ajmp comm23_fets_done_rev comm23_nfet_off_rev: BpFET_on ; Pwm off - switch damping fets comm23_fets_done_rev: setb EA Set_Comp_Phase_A ; Set comparator phase (reverse) ljmp comm_exit ; Comm2Comm3 Non-damped comm23_nondamp: jb Flags3.PGM_DIR_REV, comm23_nondamp_rev clr EA ; Disable all interrupts mov Comm_Phase, #3 mov DPTR, #pwm_bfet CnFET_off ; Turn off nfet jnb Flags0.PWM_ON, comm23_nfet_done ; Is pwm on? BnFET_on ; Yes - turn on nfet comm23_nfet_done: setb EA Set_Comp_Phase_C ; Set comparator phase ljmp comm_exit ; Comm2Comm3 Non-damped reverse comm23_nondamp_rev: clr EA ; Disable all interrupts mov Comm_Phase, #3 mov DPTR, #pwm_bfet AnFET_off ; Turn off nfet (reverse) jnb Flags0.PWM_ON, comm23_nfet_done_rev ; Is pwm on? BnFET_on ; Yes - turn on nfet comm23_nfet_done_rev: setb EA Set_Comp_Phase_A ; Set comparator phase (reverse) ljmp comm_exit ; Comm phase 3 to comm phase 4 comm3comm4: Set_RPM_Out jb Flags3.PGM_DIR_REV, comm34_rev clr EA ; Disable all interrupts mov Comm_Phase, #4 ApFET_off ; Turn off pfet CpFET_on ; Turn on pfet setb EA Set_Comp_Phase_A ; Set comparator phase jmp comm_exit comm34_rev: clr EA ; Disable all interrupts mov Comm_Phase, #4 CpFET_off ; Turn off pfet (reverse) ApFET_on ; Turn on pfet (reverse) setb EA Set_Comp_Phase_C ; Set comparator phase (reverse) jmp comm_exit ; Comm phase 4 to comm phase 5 comm4comm5: Clear_RPM_Out jnb Flags2.PGM_PWMOFF_DAMPED, comm45_nondamp ; Comm4Comm5 Damped jb Flags3.PGM_DIR_REV, comm45_damp_rev clr EA ; Disable all interrupts mov Comm_Phase, #5 mov DPTR, #pwm_afet_damped mov DampingFET, #(1 SHL ApFET) BnFET_off ; Turn off fets BpFET_off jnb Flags0.PWM_ON, comm45_nfet_off ; Is pwm on? AnFET_on ; Pwm on - turn on nfet ajmp comm45_fets_done comm45_nfet_off: ApFET_on ; Pwm off - switch damping fets comm45_fets_done: setb EA Set_Comp_Phase_B ; Set comparator phase ljmp comm_exit ; Comm4Comm5 Damped reverse comm45_damp_rev: clr EA ; Disable all interrupts mov Comm_Phase, #5 mov DPTR, #pwm_cfet_damped ; (reverse) mov DampingFET, #(1 SHL CpFET) ; (reverse) BnFET_off ; Turn off fets BpFET_off jnb Flags0.PWM_ON, comm45_nfet_off_rev ; Is pwm on? CnFET_on ; Pwm on - turn on nfet (reverse) ajmp comm45_fets_done_rev comm45_nfet_off_rev: CpFET_on ; Pwm off - switch damping fets (reverse) comm45_fets_done_rev: setb EA Set_Comp_Phase_B ; Set comparator phase ljmp comm_exit ; Comm4Comm5 Non-damped comm45_nondamp: jb Flags3.PGM_DIR_REV, comm45_nondamp_rev clr EA ; Disable all interrupts mov Comm_Phase, #5 mov DPTR, #pwm_afet BnFET_off ; Turn off nfet jnb Flags0.PWM_ON, comm45_nfet_done ; Is pwm on? AnFET_on ; Yes - turn on nfet comm45_nfet_done: setb EA Set_Comp_Phase_B ; Set comparator phase ljmp comm_exit ; Comm4Comm5 Non-damped reverse comm45_nondamp_rev: clr EA ; Disable all interrupts mov Comm_Phase, #5 mov DPTR, #pwm_cfet ; (reverse) BnFET_off ; Turn off nfet jnb Flags0.PWM_ON, comm45_nfet_done ; Is pwm on? CnFET_on ; Yes - turn on nfet (reverse) setb EA Set_Comp_Phase_B ; Set comparator phase ljmp comm_exit ; Comm phase 5 to comm phase 6 comm5comm6: Set_RPM_Out jb Flags3.PGM_DIR_REV, comm56_rev clr EA ; Disable all interrupts mov Comm_Phase, #6 CpFET_off ; Turn off pfet BpFET_on ; Turn on pfet setb EA Set_Comp_Phase_C ; Set comparator phase jmp comm_exit comm56_rev: clr EA ; Disable all interrupts mov Comm_Phase, #6 ApFET_off ; Turn off pfet (reverse) BpFET_on ; Turn on pfet setb EA Set_Comp_Phase_A ; Set comparator phase (reverse) jmp comm_exit ; Comm phase 6 to comm phase 1 comm6comm1: Clear_RPM_Out jnb Flags2.PGM_PWMOFF_DAMPED, comm61_nondamp ; Comm6Comm1 Damped jb Flags3.PGM_DIR_REV, comm61_damp_rev clr EA ; Disable all interrupts mov Comm_Phase, #1 mov DPTR, #pwm_cfet_damped mov DampingFET, #(1 SHL CpFET) AnFET_off ; Turn off fets ApFET_off jnb Flags0.PWM_ON, comm61_nfet_off ; Is pwm on? CnFET_on ; Pwm on - turn on nfet ajmp comm61_fets_done comm61_nfet_off: CpFET_on ; Pwm off - switch damping fets comm61_fets_done: setb EA Set_Comp_Phase_A ; Set comparator phase ljmp comm_exit ; Comm6Comm1 Damped reverse comm61_damp_rev: clr EA ; Disable all interrupts mov Comm_Phase, #1 mov DPTR, #pwm_afet_damped ; (reverse) mov DampingFET, #(1 SHL ApFET) ; (reverse) CnFET_off ; Turn off fets (reverse) CpFET_off jnb Flags0.PWM_ON, comm61_nfet_off_rev ; Is pwm on? AnFET_on ; Pwm on - turn on nfet ajmp comm61_fets_done_rev comm61_nfet_off_rev: ApFET_on ; Pwm off - switch damping fets (reverse) comm61_fets_done_rev: setb EA Set_Comp_Phase_C ; Set comparator phase (reverse) ajmp comm_exit ; Comm6Comm1 Non-damped comm61_nondamp: jb Flags3.PGM_DIR_REV, comm61_nondamp_rev clr EA ; Disable all interrupts mov Comm_Phase, #1 mov DPTR, #pwm_cfet AnFET_off ; Turn off nfet jnb Flags0.PWM_ON, comm61_nfet_done ; Is pwm on? CnFET_on ; Yes - turn on nfet comm61_nfet_done: setb EA Set_Comp_Phase_A ; Set comparator phase ajmp comm_exit ; Comm6Comm1 Non-damped reverse comm61_nondamp_rev: clr EA ; Disable all interrupts mov Comm_Phase, #1 mov DPTR, #pwm_afet ; (reverse) CnFET_off ; Turn off nfet (reverse) jnb Flags0.PWM_ON, comm61_nfet_done_rev ; Is pwm on? AnFET_on ; Yes - turn on nfet (reverse) comm61_nfet_done_rev: setb EA Set_Comp_Phase_C ; Set comparator phase (reverse) comm_exit: clr Flags0.DEMAG_CUT_POWER ; Clear demag power cut flag ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Switch power off routine ; ; No assumptions ; ; Switches all fets off ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** switch_power_off: mov DPTR, #pwm_nofet ; Set DPTR register to pwm_nofet mov DampingFET, #0 All_nFETs_Off ; Turn off all nfets All_pFETs_Off ; Turn off all pfets clr Flags0.PWM_ON ; Set pwm cycle to pwm off ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Set default parameters ; ; No assumptions ; ; Sets default programming parameters ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** set_default_parameters: IF MODE == 0 ; Main mov Temp1, #Pgm_Gov_P_Gain mov @Temp1, #DEFAULT_PGM_MAIN_P_GAIN inc Temp1 mov @Temp1, #DEFAULT_PGM_MAIN_I_GAIN inc Temp1 mov @Temp1, #DEFAULT_PGM_MAIN_GOVERNOR_MODE inc Temp1 mov @Temp1, #DEFAULT_PGM_MAIN_LOW_VOLTAGE_LIM inc Temp1 mov @Temp1, #0FFh ; Motor gain inc Temp1 mov @Temp1, #0FFh ; Motor idle inc Temp1 mov @Temp1, #DEFAULT_PGM_MAIN_STARTUP_PWR inc Temp1 mov @Temp1, #DEFAULT_PGM_MAIN_PWM_FREQ inc Temp1 mov @Temp1, #DEFAULT_PGM_MAIN_DIRECTION inc Temp1 mov @Temp1, #DEFAULT_PGM_MAIN_RCP_PWM_POL mov Temp1, #Pgm_Enable_TX_Program mov @Temp1, #DEFAULT_PGM_ENABLE_TX_PROGRAM inc Temp1 mov @Temp1, #DEFAULT_PGM_MAIN_REARM_START inc Temp1 mov @Temp1, #DEFAULT_PGM_MAIN_GOV_SETUP_TARGET inc Temp1 mov @Temp1, #0FFh ; Startup rpm inc Temp1 mov @Temp1, #0FFh ; Startup accel inc Temp1 mov @Temp1, #0FFh ; Voltage comp inc Temp1 mov @Temp1, #DEFAULT_PGM_MAIN_COMM_TIMING inc Temp1 mov @Temp1, #0FFh ; Damping force inc Temp1 mov @Temp1, #DEFAULT_PGM_MAIN_GOVERNOR_RANGE inc Temp1 mov @Temp1, #0FFh ; Startup method inc Temp1 mov @Temp1, #DEFAULT_PGM_PPM_MIN_THROTTLE inc Temp1 mov @Temp1, #DEFAULT_PGM_PPM_MAX_THROTTLE inc Temp1 mov @Temp1, #DEFAULT_PGM_MAIN_BEEP_STRENGTH inc Temp1 mov @Temp1, #DEFAULT_PGM_MAIN_BEACON_STRENGTH inc Temp1 mov @Temp1, #DEFAULT_PGM_MAIN_BEACON_DELAY inc Temp1 mov @Temp1, #0FFh ; Throttle rate inc Temp1 mov @Temp1, #DEFAULT_PGM_MAIN_DEMAG_COMP inc Temp1 mov @Temp1, #DEFAULT_PGM_BEC_VOLTAGE_HIGH inc Temp1 mov @Temp1, #DEFAULT_PGM_PPM_CENTER_THROTTLE inc Temp1 mov @Temp1, #DEFAULT_PGM_MAIN_SPOOLUP_TIME inc Temp1 mov @Temp1, #DEFAULT_PGM_ENABLE_TEMP_PROT inc Temp1 mov @Temp1, #DEFAULT_PGM_ENABLE_POWER_PROT inc Temp1 mov @Temp1, #DEFAULT_PGM_ENABLE_PWM_INPUT inc Temp1 mov @Temp1, #0FFh ; Pwm dither ENDIF IF MODE == 1 ; Tail mov Temp1, #Pgm_Gov_P_Gain mov @Temp1, #0FFh inc Temp1 mov @Temp1, #0FFh ; Governor I gain inc Temp1 mov @Temp1, #0FFh ; Governor mode inc Temp1 mov @Temp1, #0FFh ; Low voltage limit inc Temp1 mov @Temp1, #DEFAULT_PGM_TAIL_GAIN inc Temp1 mov @Temp1, #DEFAULT_PGM_TAIL_IDLE_SPEED inc Temp1 mov @Temp1, #DEFAULT_PGM_TAIL_STARTUP_PWR inc Temp1 mov @Temp1, #DEFAULT_PGM_TAIL_PWM_FREQ inc Temp1 mov @Temp1, #DEFAULT_PGM_TAIL_DIRECTION inc Temp1 mov @Temp1, #DEFAULT_PGM_TAIL_RCP_PWM_POL mov Temp1, #Pgm_Enable_TX_Program mov @Temp1, #DEFAULT_PGM_ENABLE_TX_PROGRAM inc Temp1 mov @Temp1, #0FFh ; Main rearm start inc Temp1 mov @Temp1, #0FFh ; Governor setup target inc Temp1 mov @Temp1, #0FFh ; Startup rpm inc Temp1 mov @Temp1, #0FFh ; Startup accel inc Temp1 mov @Temp1, #0FFh ; Voltage comp inc Temp1 mov @Temp1, #DEFAULT_PGM_TAIL_COMM_TIMING inc Temp1 mov @Temp1, #0FFh ; Damping force inc Temp1 mov @Temp1, #0FFh ; Governor range inc Temp1 mov @Temp1, #0FFh ; Startup method inc Temp1 mov @Temp1, #DEFAULT_PGM_PPM_MIN_THROTTLE inc Temp1 mov @Temp1, #DEFAULT_PGM_PPM_MAX_THROTTLE inc Temp1 mov @Temp1, #DEFAULT_PGM_TAIL_BEEP_STRENGTH inc Temp1 mov @Temp1, #DEFAULT_PGM_TAIL_BEACON_STRENGTH inc Temp1 mov @Temp1, #DEFAULT_PGM_TAIL_BEACON_DELAY inc Temp1 mov @Temp1, #0FFh ; Throttle rate inc Temp1 mov @Temp1, #DEFAULT_PGM_TAIL_DEMAG_COMP inc Temp1 mov @Temp1, #DEFAULT_PGM_BEC_VOLTAGE_HIGH inc Temp1 mov @Temp1, #DEFAULT_PGM_PPM_CENTER_THROTTLE inc Temp1 mov @Temp1, #0FFh inc Temp1 mov @Temp1, #DEFAULT_PGM_ENABLE_TEMP_PROT inc Temp1 mov @Temp1, #DEFAULT_PGM_ENABLE_POWER_PROT inc Temp1 mov @Temp1, #DEFAULT_PGM_ENABLE_PWM_INPUT inc Temp1 mov @Temp1, #DEFAULT_PGM_TAIL_PWM_DITHER ENDIF IF MODE == 2 ; Multi mov Temp1, #Pgm_Gov_P_Gain mov @Temp1, #DEFAULT_PGM_MULTI_P_GAIN inc Temp1 mov @Temp1, #DEFAULT_PGM_MULTI_I_GAIN inc Temp1 mov @Temp1, #DEFAULT_PGM_MULTI_GOVERNOR_MODE inc Temp1 mov @Temp1, #0FFh ; Low voltage limit inc Temp1 mov @Temp1, #DEFAULT_PGM_MULTI_GAIN inc Temp1 mov @Temp1, #0FFh inc Temp1 mov @Temp1, #DEFAULT_PGM_MULTI_STARTUP_PWR inc Temp1 mov @Temp1, #DEFAULT_PGM_MULTI_PWM_FREQ inc Temp1 mov @Temp1, #DEFAULT_PGM_MULTI_DIRECTION inc Temp1 mov @Temp1, #DEFAULT_PGM_MULTI_RCP_PWM_POL mov Temp1, #Pgm_Enable_TX_Program mov @Temp1, #DEFAULT_PGM_ENABLE_TX_PROGRAM inc Temp1 mov @Temp1, #0FFh ; Main rearm start inc Temp1 mov @Temp1, #0FFh ; Governor setup target inc Temp1 mov @Temp1, #0FFh ; Startup rpm inc Temp1 mov @Temp1, #0FFh ; Startup accel inc Temp1 mov @Temp1, #0FFh ; Voltage comp inc Temp1 mov @Temp1, #DEFAULT_PGM_MULTI_COMM_TIMING inc Temp1 mov @Temp1, #0FFh ; Damping force inc Temp1 mov @Temp1, #0FFh ; Governor range inc Temp1 mov @Temp1, #0FFh ; Startup method inc Temp1 mov @Temp1, #DEFAULT_PGM_PPM_MIN_THROTTLE inc Temp1 mov @Temp1, #DEFAULT_PGM_PPM_MAX_THROTTLE inc Temp1 mov @Temp1, #DEFAULT_PGM_MULTI_BEEP_STRENGTH inc Temp1 mov @Temp1, #DEFAULT_PGM_MULTI_BEACON_STRENGTH inc Temp1 mov @Temp1, #DEFAULT_PGM_MULTI_BEACON_DELAY inc Temp1 mov @Temp1, #0FFh ; Throttle rate inc Temp1 mov @Temp1, #DEFAULT_PGM_MULTI_DEMAG_COMP inc Temp1 mov @Temp1, #DEFAULT_PGM_BEC_VOLTAGE_HIGH inc Temp1 mov @Temp1, #DEFAULT_PGM_PPM_CENTER_THROTTLE inc Temp1 mov @Temp1, #0FFh inc Temp1 mov @Temp1, #DEFAULT_PGM_ENABLE_TEMP_PROT inc Temp1 mov @Temp1, #DEFAULT_PGM_ENABLE_POWER_PROT inc Temp1 mov @Temp1, #DEFAULT_PGM_ENABLE_PWM_INPUT inc Temp1 mov @Temp1, #DEFAULT_PGM_MULTI_PWM_DITHER ENDIF ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Decode parameters ; ; No assumptions ; ; Decodes programming parameters ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** decode_parameters: ; Load programmed pwm frequency mov Temp1, #Pgm_Pwm_Freq ; Load pwm freq mov A, @Temp1 mov Temp8, A ; Store in Temp8 clr Flags2.PGM_PWMOFF_DAMPED IF DAMPED_MODE_ENABLE == 1 cjne Temp8, #3, ($+5) setb Flags2.PGM_PWMOFF_DAMPED ENDIF ; Load programmed direction mov Temp1, #Pgm_Direction IF MODE >= 1 ; Tail or multi mov A, @Temp1 clr C subb A, #3 jz decode_params_dir_set ENDIF clr Flags3.PGM_DIR_REV mov A, @Temp1 jnb ACC.1, ($+5) setb Flags3.PGM_DIR_REV decode_params_dir_set: clr Flags3.PGM_RCP_PWM_POL mov Temp1, #Pgm_Input_Pol mov A, @Temp1 jnb ACC.1, ($+5) setb Flags3.PGM_RCP_PWM_POL clr C mov A, Temp8 subb A, #2 jz decode_pwm_freq_low mov CKCON, #01h ; Timer0 set for clk/4 (22kHz pwm) setb Flags2.PGM_PWM_HIGH_FREQ jmp decode_pwm_freq_end decode_pwm_freq_low: mov CKCON, #00h ; Timer0 set for clk/12 (8kHz pwm) clr Flags2.PGM_PWM_HIGH_FREQ decode_pwm_freq_end: ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Decode settings ; ; No assumptions ; ; Decodes various settings ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** decode_settings: ; Decode governor gains mov Temp1, #Pgm_Gov_P_Gain ; Decode governor P gain mov A, @Temp1 dec A mov DPTR, #GOV_GAIN_TABLE movc A, @A+DPTR mov Temp1, #Pgm_Gov_P_Gain_Decoded mov @Temp1, A mov Temp1, #Pgm_Gov_I_Gain ; Decode governor I gain mov A, @Temp1 dec A mov DPTR, #GOV_GAIN_TABLE movc A, @A+DPTR mov Temp1, #Pgm_Gov_I_Gain_Decoded mov @Temp1, A ; Decode startup power mov Temp1, #Pgm_Startup_Pwr mov A, @Temp1 dec A mov DPTR, #STARTUP_POWER_TABLE movc A, @A+DPTR mov Temp1, #Pgm_Startup_Pwr_Decoded mov @Temp1, A IF MODE == 0 ; Main ; Decode spoolup time mov Temp1, #Pgm_Main_Spoolup_Time mov A, @Temp1 mov Temp1, A ; Store jnz ($+3) ; If not zero - branch inc Temp1 clr C mov A, Temp1 subb A, #17 ; Limit to 17 max jc ($+4) mov Temp1, #17 mov A, Temp1 add A, Temp1 add A, Temp1 ; Now 3x mov Main_Spoolup_Time_3x, A add A, Main_Spoolup_Time_3x add A, Main_Spoolup_Time_3x add A, Temp1 ; Now 10x mov Main_Spoolup_Time_10x, A add A, Main_Spoolup_Time_3x add A, Temp1 add A, Temp1 ; Now 15x mov Main_Spoolup_Time_15x, A ENDIF ; Decode demag compensation mov Temp1, #Pgm_Demag_Comp mov A, @Temp1 mov Demag_Pwr_Off_Thresh, #255 ; Set default mov Low_Rpm_Pwr_Slope, #12 ; Set default cjne A, #2, decode_demag_high mov Demag_Pwr_Off_Thresh, #160 ; Settings for demag comp low mov Low_Rpm_Pwr_Slope, #10 decode_demag_high: cjne A, #3, decode_demag_done mov Demag_Pwr_Off_Thresh, #130 ; Settings for demag comp high mov Low_Rpm_Pwr_Slope, #5 decode_demag_done: ; Decode pwm dither mov Temp1, #Pgm_Pwm_Dither mov A, @Temp1 dec A mov DPTR, #PWM_DITHER_TABLE movc A, @A+DPTR mov Pwm_Dither_Decoded, A call switch_power_off ; Reset DPTR ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Set BEC voltage ; ; No assumptions ; ; Sets the BEC output voltage low or high ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** set_bec_voltage: ; Set bec voltage IF HIGH_BEC_VOLTAGE == 1 Set_BEC_Lo ; Set default to low mov Temp1, #Pgm_BEC_Voltage_High mov A, @Temp1 jz set_bec_voltage_exit Set_BEC_Hi ; Set to high set_bec_voltage_exit: ENDIF IF HIGH_BEC_VOLTAGE == 2 Set_BEC_0 ; Set default to low mov Temp1, #Pgm_BEC_Voltage_High mov A, @Temp1 cjne A, #1, set_bec_voltage_2 Set_BEC_1 ; Set to level 1 set_bec_voltage_2: cjne A, #2, set_bec_voltage_exit Set_BEC_2 ; Set to level 2 set_bec_voltage_exit: ENDIF ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Find throttle gain ; ; The difference between max and min throttle must be more than 520us (a Pgm_Ppm_xxx_Throttle difference of 130) ; ; Finds throttle gain from throttle calibration values ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** find_throttle_gain: ; Load programmed minimum and maximum throttle mov Temp1, #Pgm_Ppm_Min_Throttle mov A, @Temp1 mov Temp3, A mov Temp1, #Pgm_Ppm_Max_Throttle mov A, @Temp1 mov Temp4, A mov Temp1, #Pgm_Direction ; Check if bidirectional operation mov A, @Temp1 cjne A, #3, find_throttle_gain_check_full clr C mov A, Temp4 subb A, #14 ; Compensate for higher deadband in bidirectional mov Temp4, A find_throttle_gain_check_full: ; Check if full range is chosen jnb Flags3.FULL_THROTTLE_RANGE, find_throttle_gain_calculate mov Temp3, #0 mov Temp4, #255 find_throttle_gain_calculate: ; Calculate difference clr C mov A, Temp4 subb A, Temp3 mov Temp5, A ; Check that difference is minimum 130 clr C subb A, #130 jnc ($+4) mov Temp5, #130 ; Find gain mov Ppm_Throttle_Gain, #0 test_throttle_gain: inc Ppm_Throttle_Gain mov A, Temp5 mov B, Ppm_Throttle_Gain ; A has difference, B has gain mul AB clr C mov A, B subb A, #125 jc test_throttle_gain ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Average throttle ; ; Outputs result in Temp7 ; ; Averages throttle calibration readings ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** average_throttle: setb Flags3.FULL_THROTTLE_RANGE ; Set range to 1000-2020us call find_throttle_gain ; Set throttle gain call wait30ms mov Temp3, #0 mov Temp4, #0 mov Temp5, #16 ; Average 16 measurments average_throttle_meas: call wait3ms ; Wait for new RC pulse value mov A, New_Rcp ; Get new RC pulse value add A, Temp3 mov Temp3, A mov A, #0 addc A, Temp4 mov Temp4, A djnz Temp5, average_throttle_meas mov Temp5, #4 ; Shift 4 times average_throttle_div: clr C mov A, Temp4 ; Shift right rrc A mov Temp4, A mov A, Temp3 rrc A mov Temp3, A djnz Temp5, average_throttle_div mov Temp7, A ; Copy to Temp7 clr Flags3.FULL_THROTTLE_RANGE call find_throttle_gain ; Set throttle gain ret ;**** **** **** **** **** **** **** **** **** **** **** **** **** ;**** **** **** **** **** **** **** **** **** **** **** **** **** ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Main program start ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** ;**** **** **** **** **** **** **** **** **** **** **** **** **** ;**** **** **** **** **** **** **** **** **** **** **** **** **** pgm_start: ; Check flash lock byte mov A, RSTSRC jb ACC.6, ($+6) ; Check if flash access error was reset source mov Bit_Access, #0 ; No - then this is the first try inc Bit_Access mov DPTR, #LOCK_BYTE_ADDRESS_16K ; First try is for 16k flash size mov A, Bit_Access dec A jz lock_byte_test mov DPTR, #LOCK_BYTE_ADDRESS_8K ; Second try is for 8k flash size dec A jz lock_byte_test lock_byte_test: movc A, @A+DPTR ; Read lock byte inc A jz lock_byte_ok ; If lock byte is 0xFF, then start code execution IF ONE_S_CAPABLE == 0 mov RSTSRC, #12h ; Generate hardware reset and set VDD monitor ELSE mov RSTSRC, #10h ; Generate hardware reset and disable VDD monitor ENDIF lock_byte_ok: ; Disable the WDT. IF SIGNATURE_001 == 0f3h anl PCA0MD, #NOT(40h) ; Clear watchdog enable bit ENDIF IF SIGNATURE_001 == 0f8h mov WDTCN, #0DEh ; Disable watchdog mov WDTCN, #0ADh ENDIF ; Initialize stack mov SP, #0c0h ; Stack = 64 upper bytes of RAM ; Initialize VDD monitor orl VDM0CN, #080h ; Enable the VDD monitor call wait1ms ; Wait at least 100us IF ONE_S_CAPABLE == 0 mov RSTSRC, #02h ; Set VDD monitor as a reset source (PORSF) if not 1S capable ELSE mov RSTSRC, #00h ; Do not set VDD monitor as a reset source for 1S ESCSs, in order to avoid resets due to it ENDIF ; Set clock frequency IF SIGNATURE_001 == 0f3h orl OSCICN, #03h ; Set clock divider to 1 (not supported on 'f850) ENDIF IF SIGNATURE_001 == 0f8h mov CLKSEL, #00h ; Set clock divider to 1 (not supported on 'f3xx) ENDIF mov A, OSCICL add A, #04h ; 24.5MHz to 24MHz (~0.5% per step) jb ACC.7, reset_cal_done ; Is carry (7bit) set? - branch mov Bit_Access_Int, A IF SIGNATURE_002 <> 010h mov A, OSCLCN ELSE mov A, OSCXCN ENDIF jb ACC.0, reset_cal_done ; Set if cal aleady done mov OSCICL, Bit_Access_Int IF SIGNATURE_002 <> 010h orl OSCLCN, #01h ; Tag that cal is done ELSE orl OSCXCN, #01h ; Tag that cal is done ENDIF reset_cal_done: ; Switch power off call switch_power_off ; Ports initialization mov P0, #P0_INIT mov P0MDOUT, #P0_PUSHPULL mov P0MDIN, #P0_DIGITAL mov P0SKIP, #P0_SKIP mov P1, #P1_INIT mov P1MDOUT, #P1_PUSHPULL mov P1MDIN, #P1_DIGITAL mov P1SKIP, #P1_SKIP IF PORT3_EXIST == 1 mov P2, #P2_INIT ENDIF mov P2MDOUT, #P2_PUSHPULL IF PORT3_EXIST == 1 mov P2MDIN, #P2_DIGITAL mov P2SKIP, #P2_SKIP mov P3, #P3_INIT mov P3MDOUT, #P3_PUSHPULL mov P3MDIN, #P3_DIGITAL ENDIF ; Initialize the XBAR and related functionality Initialize_Xbar ; Clear RAM clr A ; Clear accumulator mov Temp1, A ; Clear Temp1 clear_ram: mov @Temp1, A ; Clear RAM djnz Temp1, clear_ram ; Is A not zero? - jump ; Initialize LFSR mov Random, #1 ; Set default programmed parameters call set_default_parameters ; Read all programmed parameters call read_all_eeprom_parameters ; Set beep strength mov Temp1, #Pgm_Beep_Strength mov Beep_Strength, @Temp1 ; Set initial arm variable mov Initial_Arm, #1 ; Initializing beep clr EA ; Disable interrupts explicitly call wait200ms call beep_f1 call wait30ms call beep_f2 call wait30ms call beep_f3 call wait30ms IF MODE <= 1 ; Main or tail ; Wait for receiver to initialize call wait1s call wait200ms call wait200ms call wait100ms ENDIF ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; No signal entry point ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** init_no_signal: ; Disable interrupts explicitly clr EA ; Check if input signal is high for more than 15ms mov Temp1, #250 input_high_check_1: mov Temp2, #250 input_high_check_2: jnb RTX_PORT.RTX_PIN, bootloader_done ; Look for low djnz Temp2, input_high_check_2 djnz Temp1, input_high_check_1 ljmp 1C00h ; Jump to bootloader bootloader_done: ; Decode parameters call decode_parameters ; Decode settings call decode_settings ; Set BEC voltage call set_bec_voltage ; Find throttle gain from stored min and max settings call find_throttle_gain ; Set beep strength mov Temp1, #Pgm_Beep_Strength mov Beep_Strength, @Temp1 ; Switch power off call switch_power_off ; Set clock frequency IF MCU_48MHZ == 1 Set_MCU_Clk_24MHz ENDIF ; Timer control mov TCON, #50h ; Timer0 and timer1 enabled ; Timer mode mov TMOD, #12h ; Timer0 as 8bit, timer1 as 16bit ; Timer2: clk/12 for 128us and 32ms interrupts mov TMR2CN, #24h ; Timer2 enabled, low counter interrups enabled ; Timer3: clk/12 for commutation timing mov TMR3CN, #04h ; Timer3 enabled ; PCA mov PCA0CN, #40h ; PCA enabled ; Enable interrupts mov IE, #22h ; Enable timer0 and timer2 interrupts mov IP, #02h ; High priority to timer0 interrupts mov EIE1, #90h ; Enable timer3 and PCA0 interrupts ; Initialize comparator mov CPT0CN, #80h ; Comparator enabled, no hysteresis mov CPT0MD, #00h ; Comparator response time 100ns IF COMP1_USED == 1 mov CPT1CN, #80h ; Comparator enabled, no hysteresis mov CPT1MD, #00h ; Comparator response time 100ns ENDIF ; Initialize ADC Initialize_Adc ; Initialize ADC operation call wait1ms setb EA ; Enable all interrupts ; Measure number of lipo cells call Measure_Lipo_Cells ; Measure number of lipo cells ; Initialize RC pulse Rcp_Int_First ; Enable interrupt and set to first edge Rcp_Int_Enable ; Enable interrupt Rcp_Clear_Int_Flag ; Clear interrupt flag clr Flags2.RCP_EDGE_NO ; Set first edge flag call wait200ms ; Measure PWM frequency measure_pwm_freq_init: setb Flags0.RCP_MEAS_PWM_FREQ ; Set measure pwm frequency flag mov Temp4, #3 ; Number of attempts before going back to detect input signal measure_pwm_freq_start: mov Temp3, #12 ; Number of pulses to measure measure_pwm_freq_loop: ; Check if period diff was accepted mov A, Rcp_Period_Diff_Accepted jnz measure_pwm_freq_wait mov Temp3, #12 ; Reset number of pulses to measure djnz Temp4, ($+5) ; If it is not zero - proceed ljmp init_no_signal ; Go back to detect input signal measure_pwm_freq_wait: call wait30ms ; Wait 30ms for new pulse jb Flags2.RCP_UPDATED, ($+6) ; Is there an updated RC pulse available - proceed ljmp init_no_signal ; Go back to detect input signal clr Flags2.RCP_UPDATED ; Flag that pulse has been evaluated mov A, New_Rcp ; Load value clr C subb A, #RCP_VALIDATE ; Higher than validate level? jc measure_pwm_freq_start ; No - start over mov A, Flags3 ; Check pwm frequency flags anl A, #((1 SHL RCP_PWM_FREQ_1KHZ)+(1 SHL RCP_PWM_FREQ_2KHZ)+(1 SHL RCP_PWM_FREQ_4KHZ)+(1 SHL RCP_PWM_FREQ_8KHZ)+(1 SHL RCP_PWM_FREQ_12KHZ)) mov Prev_Rcp_Pwm_Freq, Curr_Rcp_Pwm_Freq ; Store as previous flags for next pulse mov Curr_Rcp_Pwm_Freq, A ; Store current flags for next pulse cjne A, Prev_Rcp_Pwm_Freq, measure_pwm_freq_start ; Go back if new flags not same as previous djnz Temp3, measure_pwm_freq_loop ; Go back if not required number of pulses seen ; Clear measure pwm frequency flag clr Flags0.RCP_MEAS_PWM_FREQ ; Set up RC pulse interrupts after pwm frequency measurement Rcp_Int_First ; Enable interrupt and set to first edge Rcp_Clear_Int_Flag ; Clear interrupt flag clr Flags2.RCP_EDGE_NO ; Set first edge flag mov Temp1, #Pgm_Enable_PWM_Input ; Check if PWM input is enabled mov A, @Temp1 jnz test_for_oneshot ; If it is - proceed setb Flags2.RCP_PPM ; Set PPM flag mov A, Flags3 ; Clear pwm frequency flags anl A, #NOT((1 SHL RCP_PWM_FREQ_1KHZ)+(1 SHL RCP_PWM_FREQ_2KHZ)+(1 SHL RCP_PWM_FREQ_4KHZ)+(1 SHL RCP_PWM_FREQ_8KHZ)+(1 SHL RCP_PWM_FREQ_12KHZ)) mov Flags3, A test_for_oneshot: ; Test whether signal is OneShot125 clr Flags2.RCP_PPM_ONESHOT125 ; Clear OneShot125 flag mov Rcp_Outside_Range_Cnt, #0 ; Reset out of range counter call wait100ms ; Wait for new RC pulse jnb Flags2.RCP_PPM, validate_rcp_start ; If flag is not set (PWM) - branch clr C mov A, Rcp_Outside_Range_Cnt ; Check how many pulses were outside normal PPM range (800-2160us) subb A, #10 jc validate_rcp_start setb Flags2.RCP_PPM_ONESHOT125 ; Set OneShot125 flag ; Validate RC pulse validate_rcp_start: call wait3ms ; Wait for next pulse (NB: Uses Temp1/2!) mov Temp1, #RCP_VALIDATE ; Set validate level as default jnb Flags2.RCP_PPM, ($+5) ; If flag is not set (PWM) - branch mov Temp1, #0 ; Set level to zero for PPM (any level will be accepted) clr C mov A, New_Rcp ; Load value subb A, Temp1 ; Higher than validate level? jc validate_rcp_start ; No - start over ; Beep arm sequence start signal clr EA ; Disable all interrupts call beep_f1 ; Signal that RC pulse is ready call beep_f1 call beep_f1 setb EA ; Enable all interrupts call wait200ms ; Arming sequence start mov Gov_Arm_Target, #0 ; Clear governor arm target arming_start: IF MODE >= 1 ; Tail or multi mov Temp1, #Pgm_Direction ; Check if bidirectional operation mov A, @Temp1 cjne A, #3, ($+5) ajmp program_by_tx_checked ; Disable tx programming if bidirectional operation ENDIF call wait3ms mov Temp1, #Pgm_Enable_TX_Program; Start programming mode entry if enabled mov A, @Temp1 clr C subb A, #1 ; Is TX programming enabled? jnc arming_initial_arm_check ; Yes - proceed jmp program_by_tx_checked ; No - branch arming_initial_arm_check: mov A, Initial_Arm ; Yes - check if it is initial arm sequence clr C subb A, #1 ; Is it the initial arm sequence? jnc arming_ppm_check ; Yes - proceed jmp program_by_tx_checked ; No - branch arming_ppm_check: jb Flags2.RCP_PPM, throttle_high_cal_start ; If flag is set (PPM) - branch ; PWM tx program entry clr C mov A, New_Rcp ; Load new RC pulse value subb A, #RCP_MAX ; Is RC pulse max? jnc program_by_tx_entry_pwm ; Yes - proceed jmp program_by_tx_checked ; No - branch program_by_tx_entry_pwm: clr EA ; Disable all interrupts call beep_f4 setb EA ; Enable all interrupts call wait100ms clr C mov A, New_Rcp ; Load new RC pulse value subb A, #RCP_STOP ; Below stop? jnc program_by_tx_entry_pwm ; No - start over program_by_tx_entry_wait_pwm: clr EA ; Disable all interrupts call beep_f1 call wait10ms call beep_f1 setb EA ; Enable all interrupts call wait100ms clr C mov A, New_Rcp ; Load new RC pulse value subb A, #RCP_MAX ; At or above max? jc program_by_tx_entry_wait_pwm ; No - start over jmp program_by_tx ; Yes - enter programming mode ; PPM throttle calibration and tx program entry throttle_high_cal_start: IF MODE <= 1 ; Main or tail mov Temp8, #5 ; Set 3 seconds wait time ELSE mov Temp8, #2 ; Set 1 seconds wait time ENDIF throttle_high_cal: setb Flags3.FULL_THROTTLE_RANGE ; Set range to 1000-2020us call find_throttle_gain ; Set throttle gain call wait100ms ; Wait for new throttle value clr EA ; Disable interrupts (freeze New_Rcp value) clr Flags3.FULL_THROTTLE_RANGE ; Set programmed range call find_throttle_gain ; Set throttle gain mov Temp7, New_Rcp ; Store new RC pulse value clr C mov A, New_Rcp ; Load new RC pulse value subb A, #(RCP_MAX/2) ; Is RC pulse above midstick? setb EA ; Enable interrupts jc arm_target_updated ; No - branch call wait1ms clr EA ; Disable all interrupts call beep_f4 setb EA ; Enable all interrupts djnz Temp8, throttle_high_cal ; Continue to wait call average_throttle clr C mov A, Temp7 ; Limit to max 250 subb A, #5 ; Subtract about 2% and ensure that it is 250 or lower mov Temp1, #Pgm_Ppm_Max_Throttle ; Store mov @Temp1, A call wait200ms call erase_and_store_all_in_eeprom call success_beep throttle_low_cal_start: mov Temp8, #10 ; Set 3 seconds wait time throttle_low_cal: setb Flags3.FULL_THROTTLE_RANGE ; Set range to 1000-2020us call find_throttle_gain ; Set throttle gain call wait100ms clr EA ; Disable interrupts (freeze New_Rcp value) clr Flags3.FULL_THROTTLE_RANGE ; Set programmed range call find_throttle_gain ; Set throttle gain mov Temp7, New_Rcp ; Store new RC pulse value clr C mov A, New_Rcp ; Load new RC pulse value subb A, #(RCP_MAX/2) ; Below midstick? setb EA ; Enable interrupts jnc throttle_low_cal_start ; No - start over call wait1ms clr EA ; Disable all interrupts call beep_f1 call wait10ms call beep_f1 setb EA ; Enable all interrupts djnz Temp8, throttle_low_cal ; Continue to wait call average_throttle mov A, Temp7 add A, #5 ; Add about 2% mov Temp1, #Pgm_Ppm_Min_Throttle ; Store mov @Temp1, A call wait200ms call erase_and_store_all_in_eeprom call success_beep_inverted program_by_tx_entry_wait_ppm: call wait100ms call find_throttle_gain ; Set throttle gain clr C mov A, New_Rcp ; Load new RC pulse value subb A, #RCP_MAX ; At or above max? jnc ($+4) ajmp arming_ppm_check ; No - go back jmp program_by_tx ; Yes - enter programming mode program_by_tx_checked: clr C mov A, New_Rcp ; Load new RC pulse value subb A, Gov_Arm_Target ; Is RC pulse larger than arm target? jc arm_target_updated ; No - do not update mov Gov_Arm_Target, New_Rcp ; Yes - update arm target arm_target_updated: call wait100ms ; Wait for new throttle value mov Temp1, #RCP_STOP ; Default stop value mov Temp2, #Pgm_Direction ; Check if bidirectional operation mov A, @Temp2 cjne A, #3, ($+5) ; No - branch mov Temp1, #(RCP_STOP+4) ; Higher stop value for bidirectional clr C mov A, New_Rcp ; Load new RC pulse value subb A, Temp1 ; Below stop? jc arm_end_beep ; Yes - proceed jmp arming_start ; No - start over arm_end_beep: ; Beep arm sequence end signal clr EA ; Disable all interrupts call beep_f4 ; Signal that rcpulse is ready call beep_f4 call beep_f4 setb EA ; Enable all interrupts call wait200ms ; Clear initial arm variable mov Initial_Arm, #0 ; Armed and waiting for power on wait_for_power_on: clr A mov Power_On_Wait_Cnt_L, A ; Clear wait counter mov Power_On_Wait_Cnt_H, A wait_for_power_on_loop: inc Power_On_Wait_Cnt_L ; Increment low wait counter mov A, Power_On_Wait_Cnt_L cpl A jnz wait_for_power_on_no_beep; Counter wrapping (about 1 sec)? inc Power_On_Wait_Cnt_H ; Increment high wait counter mov Temp1, #Pgm_Beacon_Delay mov A, @Temp1 mov Temp1, #25 ; Approximately 1 min dec A jz beep_delay_set mov Temp1, #50 ; Approximately 2 min dec A jz beep_delay_set mov Temp1, #125 ; Approximately 5 min dec A jz beep_delay_set mov Temp1, #250 ; Approximately 10 min dec A jz beep_delay_set mov Power_On_Wait_Cnt_H, #0 ; Reset counter for infinite delay beep_delay_set: clr C mov A, Power_On_Wait_Cnt_H subb A, Temp1 ; Check against chosen delay jc wait_for_power_on_no_beep; Has delay elapsed? dec Power_On_Wait_Cnt_H ; Decrement high wait counter mov Power_On_Wait_Cnt_L, #180; Set low wait counter mov Temp1, #Pgm_Beacon_Strength mov Beep_Strength, @Temp1 clr EA ; Disable all interrupts call beep_f4 ; Signal that there is no signal setb EA ; Enable all interrupts mov Temp1, #Pgm_Beep_Strength mov Beep_Strength, @Temp1 call wait100ms ; Wait for new RC pulse to be measured wait_for_power_on_no_beep: call wait10ms mov A, Rcp_Timeout_Cntd ; Load RC pulse timeout counter value jnz wait_for_power_on_ppm_not_missing ; If it is not zero - proceed jnb Flags2.RCP_PPM, wait_for_power_on_ppm_not_missing ; If flag is not set (PWM) - branch jmp init_no_signal ; If ppm and pulses missing - go back to detect input signal wait_for_power_on_ppm_not_missing: mov Temp1, #RCP_STOP jb Flags2.RCP_PPM, ($+5) ; If flag is set (PPM) - branch mov Temp1, #(RCP_STOP+5) ; Higher than stop (for pwm) clr C mov A, New_Rcp ; Load new RC pulse value subb A, Temp1 ; Higher than stop (plus some hysteresis)? jc wait_for_power_on_loop ; No - start over IF MODE >= 1 ; Tail or multi mov Temp1, #Pgm_Direction ; Check if bidirectional operation mov A, @Temp1 clr C subb A, #3 jz wait_for_power_on_check_timeout ; Do not wait if bidirectional operation ENDIF lcall wait100ms ; Wait to see if start pulse was only a glitch wait_for_power_on_check_timeout: mov A, Rcp_Timeout_Cntd ; Load RC pulse timeout counter value jnz ($+5) ; If it is not zero - proceed ljmp init_no_signal ; If it is zero (pulses missing) - go back to detect input signal ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Start entry point ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** init_start: clr EA call switch_power_off clr A mov Requested_Pwm, A ; Set requested pwm to zero mov Governor_Req_Pwm, A ; Set governor requested pwm to zero mov Current_Pwm, A ; Set current pwm to zero mov Current_Pwm_Limited, A ; Set limited current pwm to zero mov Current_Pwm_Lim_Dith, A mov Pwm_Dither_Excess_Power, A setb EA mov Temp1, #Pgm_Motor_Idle ; Set idle pwm to programmed value mov A, @Temp1 clr C rlc A mov Pwm_Motor_Idle, A clr A mov Gov_Target_L, A ; Set target to zero mov Gov_Target_H, A mov Gov_Integral_L, A ; Set integral to zero mov Gov_Integral_H, A mov Gov_Integral_X, A mov Adc_Conversion_Cnt, A mov Flags0, A ; Clear flags0 mov Flags1, A ; Clear flags1 mov Demag_Detected_Metric, A ; Clear demag metric ;**** **** **** **** **** ; Motor start beginning ;**** **** **** **** **** mov Adc_Conversion_Cnt, #TEMP_CHECK_RATE ; Make sure a temp reading is done Set_Adc_Ip_Temp call wait1ms call start_adc_conversion read_initial_temp: Get_Adc_Status jb AD0BUSY, read_initial_temp Read_Adc_Result ; Read initial temperature mov A, Temp2 jnz ($+3) ; Is reading below 256? mov Temp1, A ; Yes - set average temperature value to zero mov Current_Average_Temp, Temp1 ; Set initial average temperature call check_temp_voltage_and_limit_power mov Adc_Conversion_Cnt, #TEMP_CHECK_RATE ; Make sure a temp reading is done next time Set_Adc_Ip_Temp ; Set up start operating conditions mov Temp1, #Pgm_Pwm_Freq mov A, @Temp1 mov Temp7, A ; Store setting in Temp7 mov @Temp1, #2 ; Set nondamped low frequency pwm mode call decode_parameters ; (Decode_parameters uses Temp1 and Temp8) mov Temp1, #Pgm_Pwm_Freq mov A, Temp7 mov @Temp1, A ; Restore settings ; Set max allowed power clr EA ; Disable interrupts to avoid that Requested_Pwm is overwritten mov Pwm_Limit, #0FFh ; Set pwm limit to max call set_startup_pwm mov Pwm_Limit, Requested_Pwm mov Pwm_Limit_Spoolup, Requested_Pwm mov Pwm_Limit_By_Rpm, Requested_Pwm setb EA mov Requested_Pwm, #1 ; Set low pwm again after calling set_startup_pwm mov Current_Pwm, #1 mov Current_Pwm_Limited, #1 mov Current_Pwm_Lim_Dith, #1 mov Spoolup_Limit_Cnt, Auto_Bailout_Armed mov Spoolup_Limit_Skip, #1 ; Begin startup sequence IF MCU_48MHZ == 1 Set_MCU_Clk_48MHz ENDIF mov Temp1, #Pgm_Direction ; Check if bidirectional operation mov A, @Temp1 cjne A, #3, init_start_bidir_done clr Flags3.PGM_DIR_REV ; Set spinning direction. Default fwd jnb Flags2.RCP_DIR_REV, ($+5) ; Check force direction setb Flags3.PGM_DIR_REV ; Set spinning direction init_start_bidir_done: setb Flags1.MOTOR_SPINNING ; Set motor spinning flag setb Flags1.STARTUP_PHASE ; Set startup phase flag mov Startup_Cnt, #0 ; Reset counter call comm5comm6 ; Initialize commutation call comm6comm1 call initialize_timing ; Initialize timing call calc_next_comm_timing ; Set virtual commutation point call initialize_timing ; Initialize timing call calc_next_comm_timing call initialize_timing ; Initialize timing jmp run1 ;**** **** **** **** **** **** **** **** **** **** **** **** **** ; ; Run entry point ; ;**** **** **** **** **** **** **** **** **** **** **** **** **** damped_transition: ; Transition from nondamped to damped if applicable clr EA call decode_parameters ; Set programmed parameters setb EA mov Adc_Conversion_Cnt, #0 ; Make sure a voltage reading is done next time Set_Adc_Ip_Volt ; Set adc measurement to voltage ; Run 1 = B(p-on) + C(n-pwm) - comparator A evaluated ; Out_cA changes from low to high run1: call wait_for_comp_out_high ; Wait zero cross wait and wait for high ; setup_comm_wait ; Setup wait time from zero cross to commutation ; evaluate_comparator_integrity ; Check whether comparator reading has been normal call calc_governor_target ; Calculate governor target call wait_for_comm ; Wait from zero cross to commutation call comm1comm2 ; Commutate call calc_next_comm_timing ; Calculate next timing and start advance timing wait ; wait_advance_timing ; Wait advance timing and start zero cross wait ; calc_new_wait_times ; wait_before_zc_scan ; Wait zero cross wait and start zero cross timeout ; Run 2 = A(p-on) + C(n-pwm) - comparator B evaluated ; Out_cB changes from high to low run2: call wait_for_comp_out_low ; setup_comm_wait ; evaluate_comparator_integrity jnb Flags1.GOV_ACTIVE, ($+6) lcall calc_governor_prop_error jb Flags0.HIGH_RPM, ($+6) ; Skip if high rpm lcall set_pwm_limit_low_rpm jnb Flags0.HIGH_RPM, ($+6) ; Do if high rpm lcall set_pwm_limit_high_rpm call wait_for_comm call comm2comm3 call calc_next_comm_timing ; wait_advance_timing ; calc_new_wait_times ; wait_before_zc_scan ; Run 3 = A(p-on) + B(n-pwm) - comparator C evaluated ; Out_cC changes from low to high run3: call wait_for_comp_out_high ; setup_comm_wait ; evaluate_comparator_integrity jnb Flags1.GOV_ACTIVE, ($+6) lcall calc_governor_int_error call wait_for_comm call comm3comm4 call calc_next_comm_timing ; wait_advance_timing ; calc_new_wait_times ; wait_before_zc_scan ; Run 4 = C(p-on) + B(n-pwm) - comparator A evaluated ; Out_cA changes from high to low run4: call wait_for_comp_out_low ; setup_comm_wait ; evaluate_comparator_integrity jnb Flags1.GOV_ACTIVE, ($+6) lcall calc_governor_prop_correction call wait_for_comm call comm4comm5 call calc_next_comm_timing ; wait_advance_timing ; calc_new_wait_times ; wait_before_zc_scan ; Run 5 = C(p-on) + A(n-pwm) - comparator B evaluated ; Out_cB changes from low to high run5: call wait_for_comp_out_high ; setup_comm_wait ; evaluate_comparator_integrity jnb Flags1.GOV_ACTIVE, ($+6) lcall calc_governor_int_correction call wait_for_comm call comm5comm6 call calc_next_comm_timing ; wait_advance_timing ; calc_new_wait_times ; wait_before_zc_scan ; Run 6 = B(p-on) + A(n-pwm) - comparator C evaluated ; Out_cC changes from high to low run6: call start_adc_conversion call wait_for_comp_out_low ; setup_comm_wait ; evaluate_comparator_integrity call wait_for_comm call comm6comm1 call check_temp_voltage_and_limit_power call calc_next_comm_timing ; wait_advance_timing ; calc_new_wait_times ; wait_before_zc_scan ; Check if it is direct startup jnb Flags1.STARTUP_PHASE, normal_run_checks jb Flags1.DIR_CHANGE_BRAKE, normal_run_checks ; If a direction change - branch ; Set spoolup power variables mov Pwm_Limit, Pwm_Spoolup_Beg ; Set initial max power mov Pwm_Limit_Spoolup, Pwm_Spoolup_Beg ; Set initial slow spoolup power mov Spoolup_Limit_Cnt, Auto_Bailout_Armed mov Spoolup_Limit_Skip, #1 ; Check startup counter mov Temp2, #24 ; Set nominal startup parameters mov Temp3, #12 clr C mov A, Startup_Cnt ; Load counter subb A, Temp2 ; Is counter above requirement? jc direct_start_check_rcp ; No - proceed clr Flags1.STARTUP_PHASE ; Clear startup phase flag setb Flags1.INITIAL_RUN_PHASE ; Set initial run phase flag mov Initial_Run_Rot_Cnt, Temp3 ; Set initial run rotation count IF MODE == 1 ; Tail mov Pwm_Limit, #0FFh ; Allow full power ENDIF IF MODE == 2 ; Multi mov Pwm_Limit, Pwm_Spoolup_Beg mov Pwm_Limit_By_Rpm, Pwm_Spoolup_Beg ENDIF jmp normal_run_checks direct_start_check_rcp: clr C mov A, New_Rcp ; Load new pulse value subb A, #RCP_STOP ; Check if pulse is below stop value jc ($+5) ljmp run1 ; Continue to run jmp run_to_wait_for_power_on normal_run_checks: ; Check if it is initial run phase jnb Flags1.INITIAL_RUN_PHASE, initial_run_phase_done ; If not initial run phase - branch jb Flags1.DIR_CHANGE_BRAKE, initial_run_phase_done ; If a direction change - branch ; Decrement startup rotaton count mov A, Initial_Run_Rot_Cnt dec A ; Check number of nondamped rotations jnz normal_run_check_startup_rot ; Branch if counter is not zero clr Flags1.INITIAL_RUN_PHASE ; Clear initial run phase flag jmp damped_transition ; Do damped transition if counter is zero normal_run_check_startup_rot: mov Initial_Run_Rot_Cnt, A ; Not zero - store counter clr C mov A, New_Rcp ; Load new pulse value subb A, #RCP_STOP ; Check if pulse is below stop value jc ($+5) ljmp run1 ; Continue to run jmp run_to_wait_for_power_on initial_run_phase_done: ; Reset stall count mov Stall_Cnt, #0 IF MODE == 0 ; Main ; Check if throttle is zeroed clr C mov A, Rcp_Stop_Cnt ; Load stop RC pulse counter value subb A, #1 ; Is number of stop RC pulses above limit? jc run6_check_rcp_stop_count ; If no - branch mov Pwm_Limit_Spoolup, Pwm_Spoolup_Beg ; If yes - set initial max powers mov Spoolup_Limit_Cnt, Auto_Bailout_Armed ; And set spoolup parameters mov Spoolup_Limit_Skip, #1 run6_check_rcp_stop_count: ENDIF ; Exit run loop after a given time clr C mov A, Rcp_Stop_Cnt ; Load stop RC pulse counter low byte value mov Temp1, #RCP_STOP_LIMIT subb A, Temp1 ; Is number of stop RC pulses above limit? jnc run_to_wait_for_power_on ; Yes, go back to wait for poweron jnb Flags2.RCP_PPM, run6_check_dir; If flag is not set (PWM) - branch mov A, Rcp_Timeout_Cntd ; Load RC pulse timeout counter value jz run_to_wait_for_power_on ; If it is zero - go back to wait for poweron run6_check_dir: IF MODE >= 1 ; Tail or multi mov Temp1, #Pgm_Direction ; Check if bidirectional operation mov A, @Temp1 cjne A, #3, run6_check_speed jb Flags3.PGM_DIR_REV, run6_check_dir_rev ; Check if actual rotation direction jb Flags2.RCP_DIR_REV, run6_check_dir_change ; Matches force direction ajmp run6_check_speed run6_check_dir_rev: jnb Flags2.RCP_DIR_REV, run6_check_dir_change ajmp run6_check_speed run6_check_dir_change: jb Flags1.DIR_CHANGE_BRAKE, run6_check_speed setb Flags1.DIR_CHANGE_BRAKE ; Set brake flag mov Pwm_Limit, Pwm_Spoolup_Beg ; Set max power while braking jmp run4 ; Go back to run 4, thereby changing force direction run6_check_speed: ENDIF mov Temp1, #0F0h ; Default minimum speed jnb Flags1.DIR_CHANGE_BRAKE, run6_brake_done; Is it a direction change? mov Pwm_Limit, Pwm_Spoolup_Beg ; Set max power while braking mov Temp1, #20h ; Bidirectional braking termination speed run6_brake_done: clr C mov A, Comm_Period4x_H ; Is Comm_Period4x more than 32ms (~1220 eRPM)? subb A, Temp1 jnc ($+4) ; Yes - stop or turn direction ajmp run1 ; No - go back to run 1 IF MODE >= 1 ; Tail or multi jnb Flags1.DIR_CHANGE_BRAKE, run_to_wait_for_power_on ; If it is not a direction change - stop clr Flags1.DIR_CHANGE_BRAKE ; Clear brake flag clr Flags3.PGM_DIR_REV ; Set spinning direction. Default fwd jnb Flags2.RCP_DIR_REV, ($+5) ; Check force direction setb Flags3.PGM_DIR_REV ; Set spinning direction setb Flags1.INITIAL_RUN_PHASE mov Initial_Run_Rot_Cnt, #18 mov Pwm_Limit, Pwm_Spoolup_Beg ; Set initial max power ajmp run1 ; Go back to run 1 ENDIF run_to_wait_for_power_on_fail: inc Stall_Cnt ; Increment stall count mov A, New_Rcp ; Check if RCP is zero, then it is a normal stop jz run_to_wait_for_power_on ajmp run_to_wait_for_power_on_stall_done run_to_wait_for_power_on: mov Stall_Cnt, #0 run_to_wait_for_power_on_stall_done: clr EA call switch_power_off mov Temp1, #Pgm_Pwm_Freq mov A, @Temp1 mov Temp7, A ; Store setting in Temp7 mov @Temp1, #2 ; Set low pwm mode (in order to turn off damping) call decode_parameters ; (Decode_parameters uses Temp1 and Temp8) mov Temp1, #Pgm_Pwm_Freq mov A, Temp7 mov @Temp1, A ; Restore settings clr A mov Requested_Pwm, A ; Set requested pwm to zero mov Governor_Req_Pwm, A ; Set governor requested pwm to zero mov Current_Pwm, A ; Set current pwm to zero mov Current_Pwm_Limited, A ; Set limited current pwm to zero mov Current_Pwm_Lim_Dith, A mov Pwm_Motor_Idle, A ; Set motor idle to zero clr Flags1.MOTOR_SPINNING ; Clear motor spinning flag IF MCU_48MHZ == 1 Set_MCU_Clk_24MHz ENDIF setb EA call wait1ms ; Wait for pwm to be stopped call switch_power_off IF MODE == 0 ; Main jnb Flags2.RCP_PPM, run_to_next_state_main ; If flag is not set (PWM) - branch mov A, Rcp_Timeout_Cntd ; Load RC pulse timeout counter value jnz run_to_next_state_main ; If it is not zero - branch jmp init_no_signal ; If it is zero (pulses missing) - go back to detect input signal run_to_next_state_main: mov Temp1, #Pgm_Main_Rearm_Start mov A, @Temp1 clr C subb A, #1 ; Is re-armed start enabled? jc jmp_wait_for_power_on ; No - do like tail and start immediately jmp validate_rcp_start ; Yes - go back to validate RC pulse jmp_wait_for_power_on: jmp wait_for_power_on ; Go back to wait for power on ENDIF IF MODE >= 1 ; Tail or multi jnb Flags2.RCP_PPM, jmp_wait_for_power_on ; If flag is not set (PWM) - branch clr C mov A, Stall_Cnt subb A, #5 jc jmp_wait_for_power_on jmp init_no_signal jmp_wait_for_power_on: jmp wait_for_power_on ; Go back to wait for power on ENDIF ;**** **** **** **** **** **** **** **** **** **** **** **** **** $include (BLHeliTxPgm.inc) ; Include source code for programming the ESC with the TX $include (BLHeliBootLoad.inc) ; Include source code for bootloader ;**** **** **** **** **** **** **** **** **** **** **** **** **** CSEG AT 19FDh reset: ljmp pgm_start END