You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.

307 lines
8.2 KiB

  1. ;**** **** **** **** ****
  2. ;
  3. ; BLHeli program for controlling brushless motors in helicopters and multirotors
  4. ;
  5. ; Copyright 2011, 2012 Steffen Skaug
  6. ; This program is distributed under the terms of the GNU General Public License
  7. ;
  8. ; This file is part of BLHeli.
  9. ;
  10. ; BLHeli is free software: you can redistribute it and/or modify
  11. ; it under the terms of the GNU General Public License as published by
  12. ; the Free Software Foundation, either version 3 of the License, or
  13. ; (at your option) any later version.
  14. ;
  15. ; BLHeli is distributed in the hope that it will be useful,
  16. ; but WITHOUT ANY WARRANTY; without even the implied warranty of
  17. ; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
  18. ; GNU General Public License for more details.
  19. ;
  20. ; You should have received a copy of the GNU General Public License
  21. ; along with BLHeli. If not, see <http://www.gnu.org/licenses/>.
  22. ;
  23. ;**** **** **** **** ****
  24. ;
  25. ; Hobbywing Platinum 30A hardware definition file
  26. ;
  27. ;**** **** **** **** ****
  28. ;*********************
  29. ; Device SiLabs F390
  30. ;*********************
  31. $include (c8051f390.inc)
  32. ;**** **** **** **** ****
  33. ; Uses internal calibrated oscillator set to 24Mhz
  34. ;**** **** **** **** ****
  35. ;**** **** **** **** ****
  36. ; Constant definitions
  37. ;**** **** **** **** ****
  38. CSEG AT 1A40h
  39. Eep_ESC_Layout: DB "#PlatinumPro30A#" ; ESC layout tag
  40. CSEG AT 1A50h
  41. Eep_ESC_MCU: DB "#BLHELI#F390# " ; Project and MCU tag (16 Bytes)
  42. ONE_S_CAPABLE EQU 0 ; Set to 1 if ESC can operate at 1S
  43. PORT3_EXIST EQU 0 ; Set to 1 if MCU has port3
  44. COMP1_USED EQU 0 ; Set to 1 if MCU has comparator 1 and it is being used
  45. DUAL_BEC_VOLTAGE EQU 0 ; Set to 1 if dual BEC voltage is supported
  46. DAMPED_MODE_ENABLE EQU 1 ; Damped mode disabled
  47. NFETON_DELAY EQU 6 ; Wait delay from pfets off to nfets on
  48. PFETON_DELAY EQU 6 ; Wait delay from nfets off to pfets on
  49. COMP_PWM_HIGH_ON_DELAY EQU 30 ; Wait delay from pwm on until comparator can be read (for high pwm frequency)
  50. COMP_PWM_HIGH_OFF_DELAY EQU 60 ; Wait delay from pwm off until comparator can be read (for high pwm frequency)
  51. COMP_PWM_LOW_ON_DELAY EQU 10 ; Wait delay from pwm on until comparator can be read (for low pwm frequency)
  52. COMP_PWM_LOW_OFF_DELAY EQU 20 ; Wait delay from pwm off until comparator can be read (for low pwm frequency)
  53. ADC_LIMIT_L EQU 85 ; Power supply measurement ADC value for which main motor power is limited (low byte)
  54. ADC_LIMIT_H EQU 0 ; Power supply measurement ADC value for which main motor power is limited (2 MSBs)
  55. TEMP_LIMIT EQU 114 ; Temperature measurement ADC value for which main motor power is limited (low byte, assuming high byte is 1)
  56. TEMP_LIMIT_STEP EQU 4 ; Temperature measurement ADC value increment for which main motor power is further limited
  57. MAIN_SPOOLUP_TIME EQU 10 ; Main motor spoolup time
  58. ;**** **** **** **** ****
  59. ; ESC specific defaults
  60. ;**** **** **** **** ****
  61. DEFAULT_PGM_MAIN_STARTUP_PWR EQU 9 ; 1=0.031 2=0.047 3=0.063 4=0.094 5=0.125 6=0.188 7=0.25 8=0.38 9=0.50 10=0.75 11=1.00 12=1.25 13=1.50
  62. DEFAULT_PGM_TAIL_STARTUP_PWR EQU 9 ; 1=0.031 2=0.047 3=0.063 4=0.094 5=0.125 6=0.188 7=0.25 8=0.38 9=0.50 10=0.75 11=1.00 12=1.25 13=1.50
  63. DEFAULT_PGM_MULTI_STARTUP_PWR EQU 9 ; 1=0.031 2=0.047 3=0.063 4=0.094 5=0.125 6=0.188 7=0.25 8=0.38 9=0.50 10=0.75 11=1.00 12=1.25 13=1.50
  64. DEFAULT_PGM_MAIN_STARTUP_METHOD EQU 2 ; 1=Stepped 2=Direct
  65. DEFAULT_PGM_TAIL_STARTUP_METHOD EQU 2 ; 1=Stepped 2=Direct
  66. DEFAULT_PGM_MULTI_STARTUP_METHOD EQU 2 ; 1=Stepped 2=Direct
  67. ;*********************
  68. ; PORT 0 definitions *
  69. ;*********************
  70. ; EQU 7 ;i
  71. ; EQU 6 ;i
  72. Rcp_In EQU 5 ;i
  73. ; EQU 4 ;i
  74. Mux_A2 EQU 3 ;i
  75. Mux_A1 EQU 2 ;i
  76. Mux_B2 EQU 1 ;i
  77. Mux_B1 EQU 0 ;i
  78. P0_DIGITAL EQU NOT((1 SHL Mux_A1)+(1 SHL Mux_A2)+(1 SHL Mux_B1)+(1 SHL Mux_B2))
  79. P0_INIT EQU 0FFh
  80. P0_PUSHPULL EQU 0
  81. P0_SKIP EQU NOT(1 SHL Rcp_In)
  82. MACRO Get_Rcp_Capture_Values
  83. mov Temp1, PCA0CPL0 ; Get PCA capture values
  84. mov Temp2, PCA0CPH0
  85. ENDM
  86. MACRO Read_Rcp_Int
  87. mov A, P0
  88. jnb Flags3.PGM_RCP_PWM_POL, ($+4) ; Is pwm polarity negative?
  89. cpl A ; Yes - invert
  90. ENDM
  91. MACRO Rcp_Int_Enable
  92. orl PCA0CPM0, #01h ; Interrupt enabled
  93. ENDM
  94. MACRO Rcp_Int_Disable
  95. anl PCA0CPM0, #0FEh ; Interrupt disabled
  96. ENDM
  97. MACRO Rcp_Int_First
  98. anl PCA0CPM0, #0CFh
  99. jb Flags3.PGM_RCP_PWM_POL, ($+6) ; Is pwm polarity positive?
  100. orl PCA0CPM0, #20h ; Capture rising edge
  101. jnb Flags3.PGM_RCP_PWM_POL, ($+6) ; Is pwm polarity negative?
  102. orl PCA0CPM0, #10h ; Capture falling edge
  103. ENDM
  104. MACRO Rcp_Int_Second
  105. anl PCA0CPM0, #0CFh
  106. jb Flags3.PGM_RCP_PWM_POL, ($+6) ; Is pwm polarity positive?
  107. orl PCA0CPM0, #10h ; Capture falling edge
  108. jnb Flags3.PGM_RCP_PWM_POL, ($+6) ; Is pwm polarity negative?
  109. orl PCA0CPM0, #20h ; Capture rising edge
  110. ENDM
  111. MACRO Rcp_Clear_Int_Flag
  112. clr CCF0 ; Clear interrupt flag
  113. ENDM
  114. ;*********************
  115. ; PORT 1 definitions *
  116. ;*********************
  117. CpFET EQU 7 ;o
  118. CnFET EQU 6 ;o
  119. BnFET EQU 5 ;o
  120. BpFET EQU 4 ;o
  121. ApFET EQU 3 ;o
  122. AnFET EQU 2 ;o
  123. Adc_Ip EQU 1 ;i
  124. ; EQU 0 ;i
  125. P1_DIGITAL EQU NOT(1 SHL Adc_Ip)
  126. P1_INIT EQU (1 SHL Adc_Ip)
  127. P1_PUSHPULL EQU (1 SHL AnFET)+(1 SHL BnFET)+(1 SHL CnFET)+(1 SHL ApFET)+(1 SHL BpFET)+(1 SHL CpFET)
  128. P1_SKIP EQU (1 SHL Adc_Ip)
  129. MACRO AnFET_on
  130. mov A, Current_Pwm_Limited
  131. jz ($+12)
  132. jb Flags3.PGM_DIR_REV, ($+5)
  133. setb P1.AnFET
  134. jnb Flags3.PGM_DIR_REV, ($+5)
  135. setb P1.CnFET
  136. ENDM
  137. MACRO AnFET_off
  138. jb Flags3.PGM_DIR_REV, ($+5)
  139. clr P1.AnFET
  140. jnb Flags3.PGM_DIR_REV, ($+5)
  141. clr P1.CnFET
  142. ENDM
  143. MACRO CnFET_on
  144. mov A, Current_Pwm_Limited
  145. jz ($+12)
  146. jb Flags3.PGM_DIR_REV, ($+5)
  147. setb P1.CnFET
  148. jnb Flags3.PGM_DIR_REV, ($+5)
  149. setb P1.AnFET
  150. ENDM
  151. MACRO CnFET_off
  152. jb Flags3.PGM_DIR_REV, ($+5)
  153. clr P1.CnFET
  154. jnb Flags3.PGM_DIR_REV, ($+5)
  155. clr P1.AnFET
  156. ENDM
  157. MACRO BnFET_on
  158. mov A, Current_Pwm_Limited
  159. jz ($+4)
  160. setb P1.BnFET
  161. ENDM
  162. MACRO BnFET_off
  163. clr P1.BnFET
  164. ENDM
  165. MACRO All_nFETs_Off
  166. clr P1.AnFET
  167. clr P1.CnFET
  168. clr P1.BnFET
  169. ENDM
  170. MACRO ApFET_on
  171. jb Flags3.PGM_DIR_REV, ($+5)
  172. setb P1.ApFET
  173. jnb Flags3.PGM_DIR_REV, ($+5)
  174. setb P1.CpFET
  175. ENDM
  176. MACRO ApFET_off
  177. jb Flags3.PGM_DIR_REV, ($+5)
  178. clr P1.ApFET
  179. jnb Flags3.PGM_DIR_REV, ($+5)
  180. clr P1.CpFET
  181. ENDM
  182. MACRO CpFET_on
  183. jb Flags3.PGM_DIR_REV, ($+5)
  184. setb P1.CpFET
  185. jnb Flags3.PGM_DIR_REV, ($+5)
  186. setb P1.ApFET
  187. ENDM
  188. MACRO CpFET_off
  189. jb Flags3.PGM_DIR_REV, ($+5)
  190. clr P1.CpFET
  191. jnb Flags3.PGM_DIR_REV, ($+5)
  192. clr P1.ApFET
  193. ENDM
  194. MACRO BpFET_on
  195. setb P1.BpFET
  196. ENDM
  197. MACRO BpFET_off
  198. clr P1.BpFET
  199. ENDM
  200. MACRO All_pFETs_Off
  201. clr P1.ApFET
  202. clr P1.CpFET
  203. clr P1.BpFET
  204. ENDM
  205. MACRO All_pFETs_On
  206. setb P1.ApFET
  207. setb P1.CpFET
  208. setb P1.BpFET
  209. ENDM
  210. MACRO Set_Comp_Phase_A
  211. jb Flags3.PGM_DIR_REV, ($+6)
  212. mov CPT0MX, #81h ; Set comparator multiplexer to phase A
  213. jnb Flags3.PGM_DIR_REV, ($+6)
  214. mov CPT0MX, #89h
  215. ENDM
  216. MACRO Set_Comp_Phase_C
  217. jb Flags3.PGM_DIR_REV, ($+6)
  218. mov CPT0MX, #89h ; Set comparator multiplexer to phase C
  219. jnb Flags3.PGM_DIR_REV, ($+6)
  220. mov CPT0MX, #81h
  221. ENDM
  222. MACRO Set_Comp_Phase_B
  223. mov CPT0MX, #80h ; Set comparator multiplexer to phase B
  224. ENDM
  225. MACRO Read_Comp_Out
  226. mov A, CPT0CN ; Read comparator output
  227. ENDM
  228. ;*********************
  229. ; PORT 2 definitions *
  230. ;*********************
  231. DebugPin EQU 4 ;o
  232. Mux_C2 EQU 3 ;i
  233. Mux_C1 EQU 2 ;i
  234. Comp_Comm EQU 1 ;i
  235. ; EQU 0 ;i
  236. P2_DIGITAL EQU NOT((1 SHL Mux_C1)+(1 SHL Mux_C2)+(1 SHL Comp_Comm))
  237. P2_INIT EQU 0FFh
  238. P2_PUSHPULL EQU (1 SHL DebugPin)
  239. ;**********************
  240. ; MCU specific macros *
  241. ;**********************
  242. MACRO Interrupt_Table_Definition
  243. CSEG AT 0 ; Code segment start
  244. jmp reset
  245. CSEG AT 0Bh ; Timer0 interrupt
  246. jmp t0_int
  247. CSEG AT 2Bh ; Timer2 interrupt
  248. jmp t2_int
  249. CSEG AT 5Bh ; PCA interrupt
  250. jmp pca_int
  251. CSEG AT 73h ; Timer3 interrupt
  252. jmp t3_int
  253. ENDM
  254. MACRO Initialize_Xbar
  255. mov P2, #P2_INIT ; Do port 2 initialization here
  256. mov P2MDIN, #P2_DIGITAL
  257. mov XBR1, #41h ; Xbar enabled, CEX0 routed to pin Rcp_In
  258. ENDM
  259. MACRO Initialize_Adc
  260. mov REF0CN, #0Eh ; Set vdd (3.3V) as reference. Enable temp sensor and bias
  261. mov ADC0CF, #58h ; ADC clock 2MHz
  262. mov AMX0P, #(8+Adc_Ip) ; Select positive input
  263. mov AMX0N, #11h ; Select negative input as ground
  264. mov ADC0CN, #80h ; ADC enabled
  265. ENDM
  266. MACRO Set_Adc_Ip_Volt
  267. mov AMX0P, #(8+Adc_Ip) ; Select positive input
  268. ENDM
  269. MACRO Set_Adc_Ip_Temp
  270. mov AMX0P, #10h ; Select temp sensor input
  271. ENDM
  272. MACRO Start_Adc
  273. mov ADC0CN, #90h ; ADC start
  274. ENDM
  275. MACRO Get_Adc_Status
  276. mov A, ADC0CN
  277. ENDM
  278. MACRO Read_Adc_Result
  279. mov Temp1, ADC0L
  280. mov Temp2, ADC0H
  281. ENDM
  282. MACRO Stop_Adc
  283. ENDM