footPDR.c 20 KB

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  1. #include "pdrStatus.h"
  2. #include "footPDR.h"
  3. #include "system.h"
  4. #define GYR_BUFF_SIZE 3
  5. //当地的重力加速度
  6. float g = 9.8179995f;
  7. float dt = 0.01f;
  8. float P[81], acc_n[3];
  9. float Temporary_array1[9], Temporary_array2[9];
  10. float K[27], P_prev[81], delta_x[9];
  11. float C[9], C_prev[9];
  12. float vel_n[3], pos_n[3];
  13. float last_pos_n[3];
  14. float pos_offset[3];
  15. int stand_num = 0;
  16. float gyr_extreme[6];
  17. float gyr_mean[3];
  18. float num_peak;
  19. float gyrBias[3];
  20. uint32_t frame_index = 0;
  21. //重置磁航向,计算双脚的磁航向,以确定身体的正朝向
  22. float heading_buff[20];
  23. float zupt_heading;
  24. int step_index = 0;
  25. int32_t last_timestamp;
  26. //速度均值
  27. float vel_sum;
  28. int dt_sum;
  29. float vel_mean;
  30. //计算触地持续采样点
  31. int zupt_count;
  32. void set_pdr_status()
  33. {
  34. frame_index = 0;
  35. }
  36. void calVelMean(int zupt)
  37. {
  38. vel_mean = sqrt(vel_n[0] * vel_n[0] + vel_n[1] * vel_n[1] + vel_n[2] * vel_n[2]);
  39. }
  40. float getVelMean()
  41. {
  42. return vel_mean;
  43. }
  44. void saveStepData(int index, float heading)
  45. {
  46. heading_buff[index % 20] = heading;
  47. }
  48. float calDeltaHeading(int index, float now_heading)
  49. {
  50. //寻找相似的方向
  51. int start_index = index - 20;
  52. if(start_index < 0)
  53. start_index = 0;
  54. float deltaHeading;
  55. for(int i = start_index; i < index; i++)
  56. {
  57. deltaHeading = now_heading - heading_buff[i % 20];
  58. if(deltaHeading < -3.141591f)
  59. {
  60. deltaHeading = (deltaHeading + 6.2831852f);
  61. }
  62. else if(deltaHeading > 3.141591f)
  63. {
  64. deltaHeading = (deltaHeading - 6.2831852f);
  65. }
  66. if(fabsf(deltaHeading) < 0.0873f)//5/180*pi
  67. {
  68. return deltaHeading;
  69. }
  70. }
  71. return 99;
  72. }
  73. void calKafmanGain9x4(float *K, float *P)
  74. {
  75. float m_rever[4][4];
  76. float m[4][4];
  77. m[0][0] = P[20];m[0][1] = P[24];m[0][2] = P[25];m[0][3] = P[26];
  78. m[1][0] = P[56];m[1][1] = P[60];m[1][2] = P[61];m[1][3] = P[62];
  79. m[2][0] = P[65];m[2][1] = P[69];m[2][2] = P[70];m[2][3] = P[71];
  80. m[3][0] = P[74];m[3][1] = P[78];m[3][2] = P[79];m[3][3] = P[80];
  81. for(int i = 0; i < 4; i++)
  82. {
  83. m[i][i] += SIGMA_V * SIGMA_V;
  84. }
  85. //m[3][3] += 0.01f*0.01f;
  86. matrix_inverse(m, m_rever);
  87. K[0] = P[2] * m_rever[0][0] + P[6] * m_rever[1][0] + P[7] * m_rever[2][0] + P[8] * m_rever[3][0];
  88. K[1] = P[2] * m_rever[0][1] + P[6] * m_rever[1][1] + P[7] * m_rever[2][1] + P[8] * m_rever[3][1];
  89. K[2] = P[2] * m_rever[0][2] + P[6] * m_rever[1][2] + P[7] * m_rever[2][2] + P[8] * m_rever[3][2];
  90. K[3] = P[2] * m_rever[0][3] + P[6] * m_rever[1][3] + P[7] * m_rever[2][3] + P[8] * m_rever[3][3];
  91. K[4] = P[11] * m_rever[0][0] + P[15] * m_rever[1][0] + P[16] * m_rever[2][0] + P[17] * m_rever[3][0];
  92. K[5] = P[11] * m_rever[0][1] + P[15] * m_rever[1][1] + P[16] * m_rever[2][1] + P[17] * m_rever[3][1];
  93. K[6] = P[11] * m_rever[0][2] + P[15] * m_rever[1][2] + P[16] * m_rever[2][2] + P[17] * m_rever[3][2];
  94. K[7] = P[11] * m_rever[0][3] + P[15] * m_rever[1][3] + P[16] * m_rever[2][3] + P[17] * m_rever[3][3];
  95. K[8] = P[20] * m_rever[0][0] + P[24] * m_rever[1][0] + P[25] * m_rever[2][0] + P[26] * m_rever[3][0];
  96. K[9] = P[20] * m_rever[0][1] + P[24] * m_rever[1][1] + P[25] * m_rever[2][1] + P[26] * m_rever[3][1];
  97. K[10] = P[20] * m_rever[0][2] + P[24] * m_rever[1][2] + P[25] * m_rever[2][2] + P[26] * m_rever[3][2];
  98. K[11] = P[20] * m_rever[0][3] + P[24] * m_rever[1][3] + P[25] * m_rever[2][3] + P[26] * m_rever[3][3];
  99. K[12] = P[29] * m_rever[0][0] + P[33] * m_rever[1][0] + P[34] * m_rever[2][0] + P[35] * m_rever[3][0];
  100. K[13] = P[29] * m_rever[0][1] + P[33] * m_rever[1][1] + P[34] * m_rever[2][1] + P[35] * m_rever[3][1];
  101. K[14] = P[29] * m_rever[0][2] + P[33] * m_rever[1][2] + P[34] * m_rever[2][2] + P[35] * m_rever[3][2];
  102. K[15] = P[29] * m_rever[0][3] + P[33] * m_rever[1][3] + P[34] * m_rever[2][3] + P[35] * m_rever[3][3];
  103. K[16] = P[38] * m_rever[0][0] + P[42] * m_rever[1][0] + P[43] * m_rever[2][0] + P[44] * m_rever[3][0];
  104. K[17] = P[38] * m_rever[0][1] + P[42] * m_rever[1][1] + P[43] * m_rever[2][1] + P[44] * m_rever[3][1];
  105. K[18] = P[38] * m_rever[0][2] + P[42] * m_rever[1][2] + P[43] * m_rever[2][2] + P[44] * m_rever[3][2];
  106. K[19] = P[38] * m_rever[0][3] + P[42] * m_rever[1][3] + P[43] * m_rever[2][3] + P[44] * m_rever[3][3];
  107. K[20] = P[47] * m_rever[0][0] + P[51] * m_rever[1][0] + P[52] * m_rever[2][0] + P[53] * m_rever[3][0];
  108. K[21] = P[47] * m_rever[0][1] + P[51] * m_rever[1][1] + P[52] * m_rever[2][1] + P[53] * m_rever[3][1];
  109. K[22] = P[47] * m_rever[0][2] + P[51] * m_rever[1][2] + P[52] * m_rever[2][2] + P[53] * m_rever[3][2];
  110. K[23] = P[47] * m_rever[0][3] + P[51] * m_rever[1][3] + P[52] * m_rever[2][3] + P[53] * m_rever[3][3];
  111. K[24] = P[56] * m_rever[0][0] + P[60] * m_rever[1][0] + P[61] * m_rever[2][0] + P[62] * m_rever[3][0];
  112. K[25] = P[56] * m_rever[0][1] + P[60] * m_rever[1][1] + P[61] * m_rever[2][1] + P[62] * m_rever[3][1];
  113. K[26] = P[56] * m_rever[0][2] + P[60] * m_rever[1][2] + P[61] * m_rever[2][2] + P[62] * m_rever[3][2];
  114. K[27] = P[56] * m_rever[0][3] + P[60] * m_rever[1][3] + P[61] * m_rever[2][3] + P[62] * m_rever[3][3];
  115. K[28] = P[65] * m_rever[0][0] + P[69] * m_rever[1][0] + P[70] * m_rever[2][0] + P[71] * m_rever[3][0];
  116. K[29] = P[65] * m_rever[0][1] + P[69] * m_rever[1][1] + P[70] * m_rever[2][1] + P[71] * m_rever[3][1];
  117. K[30] = P[65] * m_rever[0][2] + P[69] * m_rever[1][2] + P[70] * m_rever[2][2] + P[71] * m_rever[3][2];
  118. K[31] = P[65] * m_rever[0][3] + P[69] * m_rever[1][3] + P[70] * m_rever[2][3] + P[71] * m_rever[3][3];
  119. K[32] = P[74] * m_rever[0][0] + P[78] * m_rever[1][0] + P[79] * m_rever[2][0] + P[80] * m_rever[3][0];
  120. K[33] = P[74] * m_rever[0][1] + P[78] * m_rever[1][1] + P[79] * m_rever[2][1] + P[80] * m_rever[3][1];
  121. K[34] = P[74] * m_rever[0][2] + P[78] * m_rever[1][2] + P[79] * m_rever[2][2] + P[80] * m_rever[3][2];
  122. K[35] = P[74] * m_rever[0][3] + P[78] * m_rever[1][3] + P[79] * m_rever[2][3] + P[80] * m_rever[3][3];
  123. }
  124. void calDeltaX9x4(float *K, float *measure, float *delta_x)
  125. {
  126. for(int i = 0; i < 9; i++)
  127. {
  128. delta_x[i] = 0.0f;
  129. for(int j = 0; j < 4; j ++)
  130. {
  131. delta_x[i] += (K[i * 4 + j] *measure[j]);
  132. }
  133. }
  134. }
  135. void calStateCov9x4(float *P, float *K)
  136. {
  137. static float P_copy[81];
  138. for(int i = 0; i < 9; i++)
  139. {
  140. for(int j = 0; j < 9; j++)
  141. {
  142. P_copy[i * 9 + j] = K[i * 4] * P[18 + j] + K[i * 4 + 1] * P[54 + j] + K[i * 4 + 2] * P[63 + j] + K[i * 4 + 3] * P[72 + j];
  143. }
  144. }
  145. for(int i = 0; i < 81 ; i ++)
  146. {
  147. P[i] -= P_copy[i];
  148. }
  149. }
  150. float calHeading(float mag[3], float acc[3])
  151. {
  152. float hSqrt;
  153. float eSqrt;
  154. float h[3]; //东向
  155. h[0] = mag[1] * acc[2] - mag[2] * acc[1];
  156. h[1] = mag[2] * acc[0] - mag[0] * acc[2];
  157. h[2] = mag[0] * acc[1] - mag[1] * acc[0];
  158. hSqrt = 1/sqrt(h[0] * h[0] + h[1] * h[1] + h[2] * h[2]);
  159. for(int i = 0; i < 3; i++)
  160. {
  161. h[i] *= hSqrt;
  162. }
  163. float e[3]; //北向
  164. e[0] = acc[1] * h[2] - acc[2] * h[1];
  165. e[1] = acc[2] * h[0] - acc[0] * h[2];
  166. e[2] = acc[0] * h[1] - acc[1] * h[0];
  167. eSqrt = 1/sqrt(e[0] * e[0] + e[1] * e[1] + e[2] * e[2]);
  168. for(int i = 0; i < 3; i++)
  169. {
  170. e[i] *= eSqrt;
  171. }
  172. return atan2(-h[1], e[1]);
  173. }
  174. void resetAttbyMag(float C[9], float acc[3], float mag[3])
  175. {
  176. float accScale = sqrt(acc[0] * acc[0] + acc[1] * acc[1] + acc[2] * acc[2]);
  177. float pitch = asin(-acc[0]/accScale);
  178. float roll = atan2(acc[1], acc[2]);
  179. float pitch_sin = sin(pitch);
  180. float pitch_cos = cos(pitch);
  181. float roll_sin = sin(roll);
  182. float roll_cos = cos(roll);
  183. float mag_heading;
  184. C[0] = pitch_cos;
  185. C[1] = pitch_sin * roll_sin;
  186. C[2] = pitch_sin * roll_cos;
  187. C[3] = 0.0;
  188. C[4] = roll_cos;
  189. C[5] = -roll_sin;
  190. mag_heading = atan2(-C[4] * mag[1] - C[5] * mag[2], C[0] * mag[0] + C[1] * mag[1] + C[2] * mag[2]);
  191. float yaw_sin = sin(mag_heading);
  192. float yaw_cos = cos(mag_heading);
  193. C[0] = pitch_cos * yaw_cos;
  194. C[1] = pitch_sin * roll_sin * yaw_cos - roll_cos * yaw_sin;
  195. C[2] = pitch_sin * roll_cos * yaw_cos + roll_sin * yaw_sin;
  196. C[3] = pitch_cos * yaw_sin;
  197. C[4] = pitch_sin * roll_sin * yaw_sin + roll_cos * yaw_cos;
  198. C[5] = pitch_sin * roll_cos * yaw_sin - roll_sin * yaw_cos;
  199. C[6] = acc[0];
  200. C[7] = acc[1];
  201. C[8] = acc[2];
  202. }
  203. void Initialize(float *gyr, float *acc)
  204. {
  205. stand_num = 0;
  206. memset(last_pos_n, 0, 3 * sizeof(float));
  207. memset(pos_offset, 0, 3 * sizeof(float));
  208. memset(P, 0, 81 * sizeof(float));
  209. memset(acc_n, 0, 3 * sizeof(float));
  210. memset(vel_n, 0, 3 * sizeof(float));
  211. memset(pos_n, 0, 3 * sizeof(float));
  212. memset(Temporary_array1, 0, 9 * sizeof(float));
  213. memset(Temporary_array2, 0, 9 * sizeof(float));
  214. memset(K, 0, 27 * sizeof(float));
  215. memset(P_prev, 0, 81 * sizeof(float));
  216. memset(delta_x, 0, 9 * sizeof(float));
  217. memset(C, 0, 9 * sizeof(float));
  218. memset(Temporary_array1, 0, 9 * sizeof(float));
  219. memset(Temporary_array2, 0, 9 * sizeof(float));
  220. init_attitude_matrix(C, acc, g);
  221. memcpy(C_prev, C, 9 * sizeof(float));
  222. zupt_count = 0;
  223. // memcpy(gyrBias, (uint32_t *)FLASH_ADD, 3 * sizeof(float));
  224. }
  225. void attitude_matrix_update(float *C, float *Temporary_array1, float *Temporary_array2, float *gyr, float dt)
  226. {
  227. Temporary_array1[0] = 2.0f;
  228. Temporary_array1[1] = dt * gyr[2];
  229. Temporary_array1[2] = -dt * gyr[1];
  230. Temporary_array1[3] = -dt * gyr[2];
  231. Temporary_array1[4] = 2.0f;
  232. Temporary_array1[5] = dt * gyr[0];
  233. Temporary_array1[6] = dt * gyr[1];
  234. Temporary_array1[7] = -dt * gyr[0];
  235. Temporary_array1[8] = 2.0f;
  236. invert3x3(Temporary_array1, Temporary_array2);
  237. memset(Temporary_array1, 0, 9 * sizeof(float));
  238. Temporary_array1[0] = 2 * C[0] + C[1] * dt * gyr[2] - C[2] * dt * gyr[1];
  239. Temporary_array1[1] = 2 * C[1] - C[0] * dt * gyr[2] + C[2] * dt * gyr[0];
  240. Temporary_array1[2] = 2 * C[2] + C[0] * dt * gyr[1] - C[1] * dt * gyr[0];
  241. Temporary_array1[3] = 2 * C[3] + C[4] * dt * gyr[2] - C[5] * dt * gyr[1];
  242. Temporary_array1[4] = 2 * C[4] - C[3] * dt * gyr[2] + C[5] * dt * gyr[0];
  243. Temporary_array1[5] = 2 * C[5] + C[3] * dt * gyr[1] - C[4] * dt * gyr[0];
  244. Temporary_array1[6] = 2 * C[6] + C[7] * dt * gyr[2] - C[8] * dt * gyr[1];
  245. Temporary_array1[7] = 2 * C[7] - C[6] * dt * gyr[2] + C[8] * dt * gyr[0];
  246. Temporary_array1[8] = 2 * C[8] + C[6] * dt * gyr[1] - C[7] * dt * gyr[0];
  247. multiply3x3(Temporary_array1, Temporary_array2, C);
  248. }
  249. float max_window_val(float *window, int window_size)
  250. {
  251. float val = window[0];
  252. for (int i = 0; i < window_size; i++)
  253. {
  254. if (window[i] > val)
  255. val = window[i];
  256. }
  257. return val;
  258. }
  259. int max_window_int(int *window, int window_size)
  260. {
  261. int val = window[0];
  262. for (int i = 0; i < window_size; i++)
  263. {
  264. if (window[i] > val)
  265. val = window[i];
  266. }
  267. return val;
  268. }
  269. float min_window_val(float *window, int window_size)
  270. {
  271. float val = window[0];
  272. for (int i = 0; i < window_size; i++)
  273. {
  274. if (window[i] < val)
  275. val = window[i];
  276. }
  277. return val;
  278. }
  279. int min_window_int(int *window, int window_size)
  280. {
  281. int val = window[0];
  282. for (int i = 0; i < window_size; i++)
  283. {
  284. if (window[i] < val)
  285. val = window[i];
  286. }
  287. return val;
  288. }
  289. //press_tren 函数功能:提供走路过程中上升沿,下降沿
  290. //1 为上升 2 为 下降 0为不需要得状态
  291. int press_trend(int index, int *window, int window_size)
  292. {
  293. int i;
  294. int max_val = window[(index - 1) % window_size];
  295. int max_index = index;
  296. int min_val = max_val;
  297. int min_index = max_index;
  298. for (i = 1; i < window_size + 1; i++)
  299. {
  300. if (max_val < window[(index - i) % window_size])
  301. {
  302. max_index = index - i + 1;
  303. max_val = window[(index - i) % window_size];
  304. }
  305. if (min_val > window[(index - i) % window_size])
  306. {
  307. min_index = index - i + 1;
  308. min_val = window[(index - i) % window_size];
  309. }
  310. }
  311. if (max_index > min_index && max_val > min_val + 50000)
  312. {
  313. return 1;
  314. }
  315. if (max_index < min_index && max_val > min_val + 50000)
  316. {
  317. return 2;
  318. }
  319. return 0;
  320. }
  321. void dcm2angle(float *dcm, float *roll, float *pitch, float *yaw)
  322. {
  323. *yaw = atan2(dcm[3], dcm[0]);
  324. *pitch = asin(-dcm[6]);
  325. *roll = atan2(dcm[7], dcm[8]);
  326. }
  327. void quat2angleTest(float qin[4], float *roll, float *pitch, float *yaw)
  328. {
  329. //float r11 = qin[0] * qin[0] + qin[1] * qin[1] - qin[2] * qin[2] - qin[3] * qin[3];
  330. float r11 = 2.0f * (qin[1] * qin[2] + qin[0] * qin[3]);
  331. //float r21 = 2.0f * (qin[1] * qin[2] - qin[0] * qin[3]);
  332. float r12 = qin[0] * qin[0] + qin[1] * qin[1] - qin[2] * qin[2] - qin[3] * qin[3];
  333. float r21 = -2.0f * (qin[1] * qin[3] - qin[0] * qin[2]);
  334. float r31 = 2.0f * (qin[2] * qin[3] + qin[0] * qin[1]);
  335. float r32 = qin[0] * qin[0] - qin[1] * qin[1] - qin[2] * qin[2] + qin[3] * qin[3];
  336. if (r21 < -0.999999999f)
  337. r21 = -1.0f;
  338. else if (r21 > 0.999999999f)
  339. r21 = 1.0f;
  340. *roll = atan2(r11, r12);
  341. *pitch = asin(r21);
  342. *yaw = atan2(r31, r32);
  343. }
  344. void dcm2angleTest(float C[9], short att[3])
  345. {
  346. float yaw, pitch, roll;
  347. pitch = asin(-C[6]);
  348. yaw = atan2(C[3], C[0]);
  349. roll = atan2(C[7], C[8]);
  350. att[0] = (short)(yaw * 10000.f); //yaw
  351. att[1] = (short)(pitch * 10000.f); //pitch
  352. att[2] = (short)(roll * 10000.f); //roll
  353. }
  354. void quat2dcm(float *qin, float *dcm)
  355. {
  356. float qin_norm = 1 / sqrt(qin[0] * qin[0] + qin[1] * qin[1] + qin[2] * qin[2] + qin[3] * qin[3]);
  357. for (int i = 0; i < 4; i++)
  358. qin[i] *= qin_norm;
  359. dcm[0] = qin[0] * qin[0] + qin[1] * qin[1] - qin[2] * qin[2] - qin[3] * qin[3];
  360. dcm[1] = 2.0f * (qin[1] * qin[2] + qin[0] * qin[3]);
  361. dcm[2] = 2.0f * (qin[1] * qin[3] - qin[0] * qin[2]);
  362. dcm[3] = 2.0f * (qin[1] * qin[2] - qin[0] * qin[3]);
  363. dcm[4] = qin[0] * qin[0] - qin[1] * qin[1] + qin[2] * qin[2] - qin[3] * qin[3];
  364. dcm[5] = 2.0f * (qin[2] * qin[3] + qin[0] * qin[1]);
  365. dcm[6] = 2.0f * (qin[1] * qin[3] + qin[0] * qin[2]);
  366. dcm[7] = 2.0f * (qin[2] * qin[3] - qin[0] * qin[1]);
  367. dcm[8] = qin[0] * qin[0] - qin[1] * qin[1] - qin[2] * qin[2] + qin[3] * qin[3];
  368. }
  369. void multiply3x3T(float *a, float *b, float* dst)
  370. {
  371. dst[0] = a[0] * b[0] + a[1] * b[1] + a[2] * b[2];
  372. dst[1] = a[0] * b[3] + a[1] * b[4] + a[2] * b[5];
  373. dst[2] = a[0] * b[6] + a[1] * b[7] + a[2] * b[8];
  374. dst[3] = a[3] * b[0] + a[4] * b[1] + a[5] * b[2];
  375. dst[4] = a[3] * b[3] + a[4] * b[4] + a[5] * b[5];
  376. dst[5] = a[3] * b[6] + a[4] * b[7] + a[5] * b[8];
  377. dst[6] = a[6] * b[0] + a[7] * b[1] + a[8] * b[2];
  378. dst[7] = a[6] * b[3] + a[7] * b[4] + a[8] * b[5];
  379. dst[8] = a[6] * b[6] + a[7] * b[7] + a[8] * b[8];
  380. }
  381. void deltaAttMatrix(float C_prev[9], float C_now[9], float deltaC[9])
  382. {
  383. //detaC = C_prev'* C;
  384. deltaC[0] = C_now[0] * C_prev[0] + C_now[3] * C_prev[3] + C_now[6] * C_prev[6];
  385. deltaC[1] = C_now[1] * C_prev[0] + C_now[4] * C_prev[3] + C_now[7] * C_prev[6];
  386. deltaC[2] = C_now[2] * C_prev[0] + C_now[5] * C_prev[3] + C_now[8] * C_prev[6];
  387. deltaC[3] = C_now[0] * C_prev[1] + C_now[3] * C_prev[4] + C_now[6] * C_prev[7];
  388. deltaC[4] = C_now[1] * C_prev[1] + C_now[4] * C_prev[4] + C_now[7] * C_prev[7];
  389. deltaC[5] = C_now[2] * C_prev[1] + C_now[5] * C_prev[4] + C_now[8] * C_prev[7];
  390. deltaC[6] = C_now[0] * C_prev[2] + C_now[3] * C_prev[5] + C_now[6] * C_prev[8];
  391. deltaC[7] = C_now[1] * C_prev[2] + C_now[4] * C_prev[5] + C_now[7] * C_prev[8];
  392. deltaC[8] = C_now[2] * C_prev[2] + C_now[5] * C_prev[5] + C_now[8] * C_prev[8];
  393. }
  394. void normVector(float a[3])
  395. {
  396. float norm = 1.0f/sqrt(a[0] * a[0] + a[1] * a[1] + a[2] * a[2]);
  397. a[0] *= norm;
  398. a[1] *= norm;
  399. a[2] *= norm;
  400. }
  401. void resetUKF(float *UKF_Q, float UKF_P[4][4], float *mag_prev, float *mag, float *UKF_C, float *C)
  402. {
  403. memset(UKF_Q, 0, 4 * sizeof(float));
  404. UKF_Q[0] = 1.0f;
  405. memcpy(mag_prev, mag, 3 * sizeof(float));
  406. memcpy(UKF_C, C, 9 * sizeof(float));
  407. for (int i = 0; i < 4; i++)
  408. for (int j = 0; j < 4; j++)
  409. {
  410. UKF_P[i][j] = 0.0f;
  411. }
  412. for (int i = 0; i < 4; i++)
  413. {
  414. UKF_P[i][i] = 0.0000001f;
  415. }
  416. }
  417. //利用陀螺仪的双极端盘判断是否在稳定的范围
  418. int isStandCon(float gyr_extreme[6])
  419. {
  420. DEBUG_LOG(" left_sh , gyr_extreme[1] - gyr_extreme[0] = %d\n",(int)((gyr_extreme[1] - gyr_extreme[0])*1000.f));
  421. DEBUG_LOG(" left_sh , gyr_extreme[1] - gyr_extreme[0] = %d\n",(int)((gyr_extreme[3] - gyr_extreme[2])*1000.f));
  422. DEBUG_LOG(" left_sh , gyr_extreme[1] - gyr_extreme[0] = %d\n",(int)((gyr_extreme[5] - gyr_extreme[4])*1000.f));
  423. if(gyr_extreme[1] - gyr_extreme[0] < 0.02f && gyr_extreme[3] - gyr_extreme[2] < 0.02f && gyr_extreme[5] - gyr_extreme[4] < 0.02f)
  424. {
  425. return 1;
  426. }
  427. return 0;
  428. }
  429. void estimate_gyr_bias(float *gyr)
  430. {
  431. if (num_peak == 0)
  432. {
  433. for (int i = 0; i < 3; i++)
  434. {
  435. gyr_extreme[2 * i] = gyr[i];
  436. gyr_extreme[2 * i + 1] = gyr[i];
  437. }
  438. }
  439. for (int i = 0; i < 3; i++)
  440. {
  441. if (gyr[i] < gyr_extreme[2 * i])
  442. {
  443. gyr_extreme[2 * i] = gyr[i];
  444. }
  445. if (gyr[i] > gyr_extreme[2 * i + 1])
  446. {
  447. gyr_extreme[2 * i + 1] = gyr[i];
  448. }
  449. }
  450. for (int i = 0; i < 3; i++)
  451. {
  452. gyr_mean[i] += gyr[i];
  453. }
  454. num_peak++;
  455. //在线估计陀螺仪的零偏, 6050的零偏偏大
  456. if (num_peak == 1000)
  457. {
  458. if (isStandCon(gyr_extreme))
  459. {
  460. //识别每一次游戏模式下,静止状态的陀螺仪令零偏
  461. for(int i = 0; i < 3; i++)
  462. {
  463. //gyrBias[i] = gyr_mean[i] * 0.0033f;
  464. gyrBias[i] = gyr_mean[i] * 0.001f;
  465. }
  466. DEBUG_LOG("gyrBias has cor!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!\n");
  467. }
  468. num_peak = 0;
  469. memset(gyr_mean, 0, 3 * sizeof(float));
  470. }
  471. }
  472. void estimate_gyr_bias_interface(int16_t *gyr, int sample_count)
  473. {
  474. static float gyr_f[3];
  475. for(int i = 0; i < 3; i++)
  476. {
  477. gyr_f[i] = gyr[i] * 0.0010642251f;
  478. }
  479. if(sample_count == 0)
  480. {
  481. num_peak = 0;
  482. }
  483. estimate_gyr_bias(gyr_f);
  484. }
  485. unsigned char footPDR(uint32_t num, float *gyr, float *acc, uint16_t front_press, int16_t zupt, int16_t acc_zero, int32_t* pos_res, int16_t* att)
  486. {
  487. unsigned char movement_e = 0;
  488. //dt = 0.00258f;
  489. //直接乘以0.000001f是否有风险?
  490. dt = (float)(num - last_timestamp) * 0.00100f;
  491. dt *= 0.001f;
  492. if(num < last_timestamp)
  493. {
  494. //dt =(float)(4294967295 - last_timestamp + num) * 0.000001f;
  495. dt = 0.0026f;
  496. }
  497. last_timestamp = num;
  498. for (int i = 0; i < 3; i++)
  499. {
  500. gyr[i] *= (PI / 180.0f);
  501. acc[i] *= g;
  502. }
  503. //估计零偏
  504. estimate_gyr_bias(gyr);
  505. gyr[0] -= gyrBias[0];
  506. gyr[1] -= gyrBias[1];
  507. gyr[2] -= gyrBias[2];
  508. for (int i = 0; i < 3; i++)
  509. {
  510. gyr[i] *= 1.1072f;
  511. }
  512. //下面为惯导解算
  513. if (frame_index == 0)
  514. {
  515. Initialize(gyr, acc);
  516. frame_index = 1;
  517. return movement_e;
  518. }
  519. //惯导解算: 姿态矩阵更新
  520. attitude_matrix_update(C, Temporary_array1, Temporary_array2, gyr, dt);
  521. //惯导解算: 将IMU坐标系的加速度转换到“导航坐标系”下
  522. multiply3x1(C, acc, acc_n);
  523. //惯导解算: 更新IMU速度
  524. vel_n[0] = vel_n[0] + acc_n[0] * dt;
  525. vel_n[1] = vel_n[1] + acc_n[1] * dt;
  526. vel_n[2] = vel_n[2] + (acc_n[2] - g) * dt;
  527. //惯导解算: 更新IMU位置
  528. pos_n[0] = pos_n[0] + vel_n[0] * dt;
  529. pos_n[1] = pos_n[1] + vel_n[1] * dt;
  530. pos_n[2] = pos_n[2] + vel_n[2] * dt;
  531. //ekf步骤: 状态协方差矩阵预测更新
  532. //P = F*P*F' + Q;
  533. State_covariance_matrix_update(P, acc_n, dt);
  534. //zupt
  535. if (zupt == 1 || acc_zero == 1)
  536. {
  537. //ekf步骤: 计算卡尔曼滤波增益
  538. //K = P*H'/(H*P*H' + R);
  539. calKafmanGain9x4(K, P);
  540. //ekf步骤: 观测误差更新
  541. //delta_x = K * [vel_n(:,i);];
  542. float measure[4];
  543. //设置方向误差为0,意味着不要对heading进行修补
  544. memset(measure, 0, 4 *sizeof(float));
  545. measure[1] = vel_n[0];
  546. measure[2] = vel_n[1];
  547. measure[3] = vel_n[2];
  548. calDeltaX9x4(K, measure, delta_x);
  549. //ekf步骤: 状态协方差矩阵观测更新
  550. calStateCov9x4(P, K);
  551. //修正姿态矩阵
  552. Att_matrix_corr(C, C_prev, Temporary_array1, Temporary_array2, delta_x);
  553. //修正位置
  554. //pos_n_corr(pos_n, delta_x);
  555. //修正速度
  556. vel_n_corr(vel_n, delta_x);
  557. // memset(vel_n, 0, 3 * sizeof(float));
  558. //速度设置为0,因为滤波器收敛会导致轨迹有错误的振荡,实测直接设置为0也是可以的
  559. // float sub_vel[3];
  560. //
  561. // if(zupt_count < 10)
  562. // {
  563. // for(int i = 0; i < 3; i++)
  564. // {
  565. // sub_vel[i] = (1.0f - zupt_count*0.1f)* vel_n[i];
  566. //
  567. // vel_n[i] -= sub_vel[i];
  568. // }
  569. // }
  570. memcpy(last_pos_n, pos_n, 3 * sizeof(float));
  571. zupt_count ++;
  572. }
  573. else
  574. {
  575. if(zupt_count > 0)
  576. {
  577. zupt_count--;
  578. }
  579. }
  580. //状态协方差矩阵保持正交性,以防出现退化
  581. State_covariance_matrix_orthogonalization(P);
  582. pos_offset[0] = pos_offset[0] + pos_n[0] - last_pos_n[0];
  583. pos_offset[1] = pos_offset[1] + pos_n[1] - last_pos_n[1];
  584. pos_offset[2] = pos_offset[2] + pos_n[2] - last_pos_n[2];
  585. memcpy(last_pos_n, pos_n, 3 * sizeof(float));
  586. dcm2angleTest(C, att); //航向角,俯仰角, 翻滚角(z y x)
  587. pos_res[0] = (int32_t) (pos_offset[0] * 1000.0f);
  588. pos_res[1] = (int32_t) (pos_offset[1] * 1000.0f);
  589. pos_res[2] = (int32_t) (pos_offset[2] * 1000.0f);
  590. return movement_e;
  591. }