hal_battery_NoPowerEnPin.c 17 KB

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  1. /*********************************************************************
  2. * INCLUDES
  3. */
  4. #include "usr_config.h"
  5. #include "hal_battery.h"
  6. #include "cli.h"
  7. #define PRINTBLE 0
  8. #define IIDUAN 1
  9. #include "ble_comm.h"
  10. #include "exception.h"
  11. #include "ringframe.h"
  12. RINGFRAME_DEF(battlog, ringframe_size_4096);
  13. char logbuftemp[50];
  14. int logbuftemp_len = 0;
  15. #define log(...) {logbuftemp_len = sprintf(logbuftemp,__VA_ARGS__); while(ringframe_in(&battlog,logbuftemp,logbuftemp_len)!=0){ringframe_throw(&battlog);}}
  16. #include "hal_ble_client.h"
  17. char print_log = 0;
  18. void cb_BLE_Client_ERR(void* handle)
  19. {
  20. // BLE_Client_Rx_t* target = handle;
  21. DEBUG_LOG("cb_BLE_Client_ERR:%d,%d\n", 1, 1);
  22. print_log = 1;
  23. }
  24. int16_t ADC_GetValue(uint32_t channel)
  25. {
  26. int16_t temp = 0;
  27. ADC_Read(channel, &temp);
  28. return temp;
  29. }
  30. //typedef struct
  31. //{
  32. // void * p_buffer;
  33. // short size;
  34. // short index;
  35. // float sum;
  36. //} average_filter_t;
  37. //#define AVERAGE_FILTER_DEF( _name, _size ) \
  38. // float _name##_average_filter_buffer[(_size)]; \
  39. // average_filter_t _name= \
  40. // { \
  41. // .index = 0, \
  42. // .sum = 0.0f, \
  43. // .p_buffer = _name##_average_filter_buffer, \
  44. // .size = (_size), \
  45. // }
  46. //float average_filter_init(average_filter_t * p_avgf)
  47. //{
  48. // short i=0;
  49. // for(i=1;i<p_avgf->size;i++)
  50. // {
  51. // p_avgf->p_buffer[i]=0.0f;
  52. // }
  53. // p_avgf->index=0;
  54. // p_avgf->sum=0.0f;
  55. //}
  56. //float average_filter(average_filter_t * p_avgf,float value_in)
  57. //{
  58. // p_avgf->sum=0.0f;
  59. // p_avgf->p_buffer[p_avgf->index++]=value_in;
  60. //}
  61. battercb_t * battercb=NULL;
  62. void printbatter_cb(battercb_t *c,battercb_t *C_flash)
  63. {
  64. char bytes[256];
  65. int len =0;
  66. len=sprintf(bytes,"%f,%f,%f,%f,%f,%f,%f,%f,%d,%d,%d,%d\r\n",
  67. c->preBestResult_Voltage2power ,
  68. c->preBestResult_chargeV2P_f ,
  69. c->P_mAh,
  70. c->kg,
  71. c->P2 ,
  72. c->P1,
  73. c->Battery_capacity_mAh,
  74. c->adc_tp4056_power,
  75. c->init,
  76. c->sta ,
  77. c->chargeV2P_f_init,
  78. c->Voltage2power_init);
  79. SEGGER_RTT_Write(0,bytes, len);
  80. len=sprintf(bytes,"%f,%f,%f,%f,%f,%f,%f,%f,%d,%d,%d,%d\r\n",
  81. C_flash->preBestResult_Voltage2power ,
  82. C_flash->preBestResult_chargeV2P_f ,
  83. C_flash->P_mAh,
  84. C_flash->kg,
  85. C_flash->P2 ,
  86. C_flash->P1,
  87. C_flash->Battery_capacity_mAh,
  88. C_flash->adc_tp4056_power,
  89. C_flash->init,
  90. C_flash->sta ,
  91. C_flash->chargeV2P_f_init,
  92. C_flash->Voltage2power_init);
  93. SEGGER_RTT_Write(0,bytes, len);
  94. SEGGER_RTT_printf(0,"\r\n");
  95. }
  96. void cb_init(void)
  97. {
  98. battercb = Except_Get_Battery_Record_Buff();
  99. if(battercb->init != 3)
  100. {
  101. battercb->init = 3;
  102. battercb->P1=100.0f;
  103. battercb->adc_tp4056_power=0;
  104. battercb->Battery_capacity_mAh=0;
  105. battercb->kg=1;
  106. battercb->P2=0;
  107. battercb->preBestResult_chargeV2P_f=0;
  108. battercb->preBestResult_Voltage2power=0;
  109. battercb->sta=0;
  110. battercb->P_mAh=0;
  111. battercb->Voltage2power_init=1;
  112. battercb->chargeV2P_f_init =1;
  113. }
  114. }
  115. //返回5V信号,有5V的话返回1,没有的话返回0
  116. static char charge_in(void)
  117. {
  118. uint32_t ch = nrf_gpio_pin_read(PIN_CHARGING);
  119. if (ch)
  120. {
  121. return 1;
  122. }
  123. else
  124. {
  125. return 0;
  126. }
  127. }
  128. static float filter(float value, float kg, float* preBestResult)
  129. {
  130. float new_v = value;
  131. new_v = *preBestResult * (1.0f - kg) + value * kg;
  132. *preBestResult = new_v;
  133. return new_v;
  134. }
  135. #if IIDUAN == 0
  136. //鞋子ADC
  137. static const float poo1o[] = {0, 0, 0.0279893723606430, 0.174605323652602, 0.325796538285416, 0.495164949358988, 0.661918800578876, 0.829024800123971, 1.00225498989324, 1.17936073685608, 1.37258677752597, 1.56525700069634, 1.78680072433224, 2.00361106262195, 2.24466616203811, 2.46699160701705, 2.77834696254638, 3.12186809827754, 3.58442625993982, 4.15025435558636, 4.75855743544068, 5.51189718744822, 6.35834306864975, 7.38461196888009, 8.48997478633724, 9.43096936165977, 10.3817319764220, 11.4116388420216, 12.3939372566211, 13.5048186806524, 14.5904959858255, 15.5237940825920, 16.4790857938893, 17.8137595522187, 18.9982251103467, 20.3392608271850, 21.5817542329461, 22.7218253119165, 23.9444316340532, 25.2939077624602, 26.6264082603126, 27.6802415218000, 29.0022881606974, 30.1783424265851, 31.1179209268523, 32.2887764986448, 33.3732790985050, 34.2380544358441, 35.2041112278740, 36.0163848326001, 36.8624779801428, 37.6634899287154, 38.5186413495501, 39.4878256764553, 40.2471232681709, 41.2081417271725, 42.3322924899204, 43.7047997876243, 44.9058976548061, 46.5044971286874, 47.8927266715832, 49.8558978793141, 51.9022338412845, 54.2586141300707, 56.3903798469888, 58.7696803719223, 60.8764981712366, 62.2358527791606, 63.8383633243999, 65.5021323737117, 67.1556090613014, 69.0159229136298, 70.1420773342446, 71.2282683025524, 72.4548338447843, 73.6556507850819, 74.8128040906371, 75.8695501837768, 77.1323517287879, 78.6365237973046, 80.3752005495001, 82.8468947240450, 86.6163997907370, 91.2910588313494, 93.9702969410882, 95.4930183746766, 96.9114001488224, 97.8493292727541, 98.7169169431273, 99.3270162091455, 99.6869018017068, 99.9917942993789, 99.9689500363163, 99.97, 99.98, 99.98, 99.98, 99.98, 99.99, 99.99, 99.99};
  138. static float interp1(float x)
  139. {
  140. int absx = (int)x - 320;
  141. float max = poo1o[absx + 1];
  142. float min = poo1o[absx];
  143. float temp = x - (float)absx - 320.0f;
  144. return (max - min) * temp + min;
  145. }
  146. #else
  147. #define BAT_100_P 410.0f
  148. #define BAT_90_P 403.0f
  149. #define BAT_80_P 393.0f
  150. #define BAT_70_P 388.0f
  151. #define BAT_60_P 382.0f
  152. #define BAT_50_P 372.0f
  153. #define BAT_40_P 365.0f
  154. #define BAT_30_P 361.0f
  155. #define BAT_20_P 354.0f
  156. #define BAT_10_P 345.0f
  157. #define BAT_0_P 320.0f
  158. static float interp1(float x)
  159. {
  160. if(x > BAT_100_P)return 100.0f;
  161. else if((x <= BAT_100_P)&&(x > BAT_90_P)){return (x-BAT_90_P)/(BAT_100_P-BAT_90_P)+90.0f;}
  162. else if((x <= BAT_90_P)&&(x > BAT_80_P)){return (x-BAT_80_P)/(BAT_90_P-BAT_80_P)+80.0f;}
  163. else if((x <= BAT_80_P)&&(x > BAT_70_P)){return (x-BAT_70_P)/(BAT_80_P-BAT_70_P)+70.0f;}
  164. else if((x <= BAT_70_P)&&(x > BAT_60_P)){return (x-BAT_60_P)/(BAT_70_P-BAT_60_P)+60.0f;}
  165. else if((x <= BAT_60_P)&&(x > BAT_50_P)){return (x-BAT_50_P)/(BAT_60_P-BAT_50_P)+50.0f;}
  166. else if((x <= BAT_50_P)&&(x > BAT_40_P)){return (x-BAT_40_P)/(BAT_50_P-BAT_40_P)+40.0f;}
  167. else if((x <= BAT_40_P)&&(x > BAT_30_P)){return (x-BAT_30_P)/(BAT_40_P-BAT_30_P)+30.0f;}
  168. else if((x <= BAT_30_P)&&(x > BAT_20_P)){return (x-BAT_20_P)/(BAT_30_P-BAT_20_P)+20.0f;}
  169. else if((x <= BAT_20_P)&&(x > BAT_10_P)){return (x-BAT_10_P)/(BAT_20_P-BAT_10_P)+10.0f;}
  170. else if((x <= BAT_10_P)&&(x > BAT_0_P)){return (x-BAT_0_P)/(BAT_10_P-BAT_0_P)+0.0f;}
  171. else return 0.0f;
  172. }
  173. #endif
  174. //返回电压百分比
  175. static float Voltage2power(float mV)
  176. {
  177. float rev = 0;
  178. float k = 0;
  179. if (battercb->Voltage2power_init)
  180. {
  181. battercb->preBestResult_Voltage2power = mV / 10;
  182. battercb->Voltage2power_init = 0;
  183. }
  184. k = filter(mV / 10, 0.01, &battercb->preBestResult_Voltage2power);
  185. if (k < 320.0f)
  186. {
  187. rev = 0;
  188. }
  189. else if (k > 420.0f)
  190. {
  191. rev = 100;
  192. }
  193. else
  194. {
  195. rev = interp1(k);
  196. }
  197. return rev;
  198. }
  199. #if IIDUAN == 0
  200. static const float chargeV2P[] = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0.606184684199367, 0.938307744774148, 1.30769659743727, 1.87378869014097, 2.39210582883903, 2.92471759425620, 3.79782257541779, 4.54241638183623, 5.09886597521223, 5.98930945903392, 6.49613916536905, 7.57967916311061, 8.42757721701290, 9.26589943580526, 10.3408809248851, 11.4278317273525, 12.3098089504989, 13.8095299712012, 15.4373756551577, 16.8805115746597, 18.4871688551768, 20.0578462608782, 21.6336381358003, 22.9916066660508, 24.4652374859292, 25.6565902258290, 26.8453581267414, 27.9070922567514, 28.9713295466563, 30.0209078713242, 30.9380166385130, 32.0419258329631, 33.1827748787620, 33.8691297160915, 34.8949274023278, 35.8840553861847, 36.9638277084030, 37.8687458690322, 38.9939274175310, 40.4336758333268, 41.1114865403869, 42.6160733592240, 44.2493873543177, 45.6026105469954, 47.4664557187522, 49.0734043728910, 51.2998758679562, 52.8880367841713, 54.7587352342972, 57.0178625862682, 58.8608281071146, 60.3657347075748, 62.4281274954232, 64.3086188700345, 65.8044424890286, 68.6475622104224, 72.7352289117192, 76.9893033499930, 84.0930819869950, 92.2923770276700, 96.3286261252036, 99.7542287364423};
  201. static float interp1_chargeV2P(float x)
  202. {
  203. int absx = (int)x - 350;
  204. float max = chargeV2P[absx + 1];
  205. float min = chargeV2P[absx];
  206. float temp = x - (float)absx - 350.0f;
  207. return (max - min) * temp + min;
  208. }
  209. #else
  210. #define CHA_100_P BAT_100_P+0.5f
  211. #define CHA_90_P BAT_90_P+0.5f
  212. #define CHA_80_P BAT_80_P+0.2f
  213. #define CHA_70_P BAT_70_P+0.2f
  214. #define CHA_60_P BAT_60_P+0.2f
  215. #define CHA_50_P BAT_50_P+0.2f
  216. #define CHA_40_P BAT_40_P+0.2f
  217. #define CHA_30_P BAT_30_P+0.2f
  218. #define CHA_20_P BAT_20_P+0.2f
  219. #define CHA_10_P BAT_10_P+0.2f
  220. #define CHA_0_P BAT_0_P+0.2f
  221. static float interp1_chargeV2P(float x)
  222. {
  223. if(x > CHA_100_P)return 100.0f;
  224. else if((x <= CHA_100_P)&&(x > CHA_90_P)){return (x-CHA_90_P)/(CHA_100_P-CHA_90_P)+90.0f;}
  225. else if((x <= CHA_90_P)&&(x > CHA_80_P)){return (x-CHA_80_P)/(CHA_90_P-CHA_80_P)+80.0f;}
  226. else if((x <= CHA_80_P)&&(x > CHA_70_P)){return (x-CHA_70_P)/(CHA_80_P-CHA_70_P)+70.0f;}
  227. else if((x <= CHA_70_P)&&(x > CHA_60_P)){return (x-CHA_60_P)/(CHA_70_P-CHA_60_P)+60.0f;}
  228. else if((x <= CHA_60_P)&&(x > CHA_50_P)){return (x-CHA_50_P)/(CHA_60_P-CHA_50_P)+50.0f;}
  229. else if((x <= CHA_50_P)&&(x > CHA_40_P)){return (x-CHA_40_P)/(CHA_50_P-CHA_40_P)+40.0f;}
  230. else if((x <= CHA_40_P)&&(x > CHA_30_P)){return (x-CHA_30_P)/(CHA_40_P-CHA_30_P)+30.0f;}
  231. else if((x <= CHA_30_P)&&(x > CHA_20_P)){return (x-CHA_20_P)/(CHA_30_P-CHA_20_P)+20.0f;}
  232. else if((x <= CHA_20_P)&&(x > CHA_10_P)){return (x-CHA_10_P)/(CHA_20_P-CHA_10_P)+10.0f;}
  233. else if((x <= CHA_10_P)&&(x > CHA_0_P)){return (x-CHA_0_P)/(BAT_10_P-CHA_0_P)+0.0f;}
  234. else return 0.0f;
  235. }
  236. #endif
  237. //返回电压百分比
  238. static float chargeV2P_f(float mV)
  239. {
  240. float rev = 0;
  241. float k = 0;
  242. if (battercb->chargeV2P_f_init)
  243. {
  244. battercb->preBestResult_chargeV2P_f = mV / 10;
  245. battercb->chargeV2P_f_init = 0;
  246. }
  247. k = filter(mV / 10, 0.05, &battercb->preBestResult_chargeV2P_f);
  248. if (k < 350.0f)
  249. {
  250. rev = 0;
  251. }
  252. else if (k > 415.0f)
  253. {
  254. rev = 100;
  255. }
  256. else
  257. {
  258. rev = interp1_chargeV2P(k);
  259. }
  260. return rev;
  261. }
  262. //返回电量百分比
  263. static float Voltage2mah(float mah, float storage_capacity)
  264. {
  265. return mah / storage_capacity * 100.0f;
  266. }
  267. //返回电压剩余绝对容量
  268. static float mah2Voltage(float P, float storage_capacity)
  269. {
  270. return storage_capacity * P / 100.0f;
  271. }
  272. static void Charge(float mV, float* mAh, float interval_s)
  273. {
  274. float A = mV / 3000.0f * 1.1f;
  275. float dmAh = A * 1000.0f * interval_s / 3600.0f;
  276. *mAh = *mAh + dmAh;
  277. }
  278. static float Power_management(float mV_Battery, float mV_Charge)
  279. {
  280. float storage_capacity = 350;
  281. switch (battercb->sta)
  282. {
  283. case 0:
  284. if (mV_Charge > 20)
  285. {
  286. battercb->sta = 2; //充电过程
  287. battercb->P1 = chargeV2P_f(mV_Battery);
  288. battercb->Battery_capacity_mAh=mah2Voltage(battercb->P1, storage_capacity);
  289. }
  290. else
  291. {
  292. battercb->P1 = Voltage2power(mV_Battery);
  293. battercb->sta = 1; //放电过程
  294. }
  295. break;
  296. case 1://放电
  297. if (mV_Charge > 20)
  298. {
  299. battercb->sta = 2; //充电过程
  300. battercb->kg = 0;
  301. // //解决插上充电没接电池状态下突然接上电池时电量不衔接的问题
  302. // if((mV_Battery<4000)&&(P1>95.0f))
  303. // {
  304. // P1=chargeV2P_f(mV_Battery);
  305. // }
  306. battercb->Battery_capacity_mAh=mah2Voltage(battercb->P1, storage_capacity);
  307. }
  308. else
  309. {
  310. battercb->P2 = Voltage2power(mV_Battery);
  311. if (battercb->P1 > battercb->P2) //过滤刚拔掉充电线时候的虚高
  312. {
  313. battercb->P1 = battercb->P2;
  314. }
  315. //解决充满电后充电器不拔出来的情况显示不到100%的情况
  316. if (charge_in() && (battercb->P1 > 95.0f))
  317. {
  318. battercb->P1 = 100.0f;
  319. }
  320. }
  321. break;
  322. case 2://充电
  323. if (mV_Charge < 20)
  324. {
  325. battercb->sta = 1; //放电过程
  326. //初始化滤波器波器
  327. battercb->preBestResult_Voltage2power = mV_Battery / 10;
  328. if ((battercb->P1 > 99.1f)&&(charge_in()))
  329. {
  330. battercb->P1 = 100.0f;
  331. }
  332. }
  333. else
  334. {
  335. //---------------------------------------------------
  336. Charge(mV_Charge, &battercb->Battery_capacity_mAh, 1);
  337. battercb->P_mAh = Voltage2mah(battercb->Battery_capacity_mAh, storage_capacity);
  338. //---------------------------------------------------
  339. battercb->P2 = chargeV2P_f(mV_Battery);
  340. // log("%f\n",P2);
  341. // SEGGER_RTT_Write(0,logbuftemp, logbuftemp_len);
  342. battercb->kg = mV_Charge / 1000.0f;
  343. if (battercb->kg > 1.0f)
  344. {
  345. battercb->kg = 1.0f;
  346. }
  347. battercb->P2 = (1.0f - battercb->kg) * battercb->P2 + battercb->kg * battercb->P_mAh;
  348. if (battercb->P1 < battercb->P2) //过滤刚插上充电线时候的虚低
  349. {
  350. battercb->P1 = battercb->P2;
  351. }
  352. if (battercb->P1 > 100)
  353. {
  354. battercb->P1 = 99.9;
  355. }
  356. }
  357. break;
  358. }
  359. return battercb->P1;
  360. }
  361. int16_t hal_GetBatttery_Adc(void){
  362. int16_t adcVal;
  363. adcVal = ADC_GetValue(PIN_ADC_BAT_CHANNEL);
  364. adcVal = ADC_RESULT_IN_MILLI_VOLTS(adcVal) * 5 / 3;
  365. return adcVal;
  366. }
  367. static void hal_battery_Process(void)
  368. {
  369. static int cprign = 0;
  370. #if PRINTBLE
  371. char buff[256];
  372. unsigned char len = 0;
  373. #endif
  374. int16_t adcVal;
  375. int16_t CHARGMEASURE;
  376. int16_t volTemp;
  377. int16_t volTemp_CHARGMEASURE;
  378. adcVal = ADC_GetValue(PIN_ADC_BAT_CHANNEL);
  379. volTemp = ADC_RESULT_IN_MILLI_VOLTS(adcVal) * 5 / 3; // 电池电压转换计算
  380. CHARGMEASURE = ADC_GetValue(PIN_ADC_CHARGMEASURE_CHANNEL);
  381. volTemp_CHARGMEASURE = ADC_RESULT_IN_MILLI_VOLTS(CHARGMEASURE);// 电池电压转换计算
  382. battercb->adc_tp4056_power = Power_management((float)volTemp, (float)volTemp_CHARGMEASURE);
  383. #if PRINTBLE
  384. len = sprintf(buff, "%4d ,%4d ,%4d,%f\r\n", TIME_GetTicks(), volTemp, volTemp_CHARGMEASURE, battercb->adc_tp4056_power);
  385. send_bytes_client((unsigned char*)buff, len);
  386. #endif
  387. if (cprign % 600 == 0)
  388. {
  389. log("%4d,%4d,%4d,%2.1f,%d,%2.1f,%2.1f,%2.1f\n", TIME_GetTicks(), volTemp, volTemp_CHARGMEASURE, battercb->adc_tp4056_power, battercb->sta, battercb->P_mAh, battercb->P2, battercb->kg);
  390. SEGGER_RTT_Write(0,logbuftemp, logbuftemp_len);
  391. logbuftemp[logbuftemp_len] = 0;
  392. Except_TxError(EXCEPT_DATA_BATTERY, logbuftemp);
  393. }
  394. cprign++;
  395. // cli_process(&clirtt);
  396. // uint8_t persent = 0;
  397. // persent = (uint8_t)(adc_tp4056_power+0.5f);
  398. // DEBUG_LOG("hal_battery_Process:%d,%d\n",persent,volTemp);
  399. if(print_log==1)
  400. {
  401. log("%4d,%4d,%4d,%2.1f,%d,%2.1f,%2.1f,%2.1f\n", TIME_GetTicks(), volTemp, volTemp_CHARGMEASURE, battercb->adc_tp4056_power, battercb->sta, battercb->P_mAh, battercb->P2, battercb->kg);
  402. SEGGER_RTT_Write(0,logbuftemp, logbuftemp_len);
  403. logbuftemp[logbuftemp_len] = 0;
  404. Except_TxError(EXCEPT_DATA_BATTERY, logbuftemp);
  405. print_log=2;
  406. }
  407. if (print_log==2)
  408. {
  409. unsigned char length = 0;
  410. while (ringframe_peek(&battlog, logbuftemp, &length) == 0)
  411. {
  412. if (send_bytes_client((unsigned char*)logbuftemp, length) != 0)
  413. {
  414. return;
  415. }
  416. ringframe_throw(&battlog);
  417. SEGGER_RTT_Write(0, logbuftemp, length);
  418. }
  419. print_log = 0;
  420. }
  421. }
  422. //返回的电量范围: 0~100 表示电量百分比
  423. uint8_t GetBatteryPersent(void)
  424. {
  425. uint8_t persent = 0;
  426. persent = (uint8_t)(battercb->adc_tp4056_power + 0.5f);
  427. // if(persent>95)persent=100;
  428. // else if((persent>85)&&(persent<=95))persent=90;
  429. // else if((persent>75)&&(persent<=85))persent=80;
  430. // else if((persent>65)&&(persent<=75))persent=70;
  431. // else if((persent>55)&&(persent<=65))persent=60;
  432. // else if((persent>45)&&(persent<=55))persent=50;
  433. // else if((persent>35)&&(persent<=45))persent=40;
  434. // else if((persent>25)&&(persent<=35))persent=30;
  435. // else if((persent>15)&&(persent<=25))persent=20;
  436. // else if((persent>10)&&(persent<=15))persent=10;
  437. if(persent>10)
  438. {
  439. persent=persent/10;
  440. persent=persent*10;
  441. }
  442. if (persent > 100)
  443. {
  444. persent = 100;
  445. }
  446. else if(persent<=0)
  447. {
  448. persent = 0;
  449. }
  450. return persent;
  451. }
  452. void hal_battery_init(void)
  453. {
  454. cb_init();
  455. hal_battery_Process();
  456. BLE_Client_Rx_Regist(BLE_ERR, cb_BLE_Client_ERR);
  457. Process_Start(1000, "hal_battery_Process", hal_battery_Process);
  458. }