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This commit is contained in:
@ -7,6 +7,8 @@
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- 原地旋转的加速度阈值更宽松
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能够从静止状态到变化状态,去根据阈值来判断这个“变化”:进入滑行状态 / 只是原地摆动
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- 但是还是不够灵敏
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添加了滑雪过程中转弯判断,参数待调
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*/
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#include "skiing_tracker.h"
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@ -17,41 +19,49 @@
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#define G_ACCELERATION 9.81f
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#define DEG_TO_RAD (3.14159265f / 180.0f)
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// --- 算法阈值定义 ---
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// --- ZUPT ---
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//两个判断是否静止的必要条件:动态零速更新(ZUPT)阈值
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// 加速方差阈值,提高阈值,让“刹车”更灵敏,以便在波浪式前进等慢速漂移时也能触发零速更新
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#define ZUPT_ACC_VARIANCE_THRESHOLD 0.2f
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// 陀螺仪方差阈值
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#define ZUPT_GYR_VARIANCE_THRESHOLD 5.0f
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// --- 启动滑雪阈值 ---
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// 加速度模长与重力的差值大于此值,认为开始运动;降低阈值,让“油门”更灵敏,以便能捕捉到真实的慢速启动
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#define START_SKIING_ACC_THRESHOLD 0.5f
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// 陀螺仪方差阈值,以允许启动瞬间的正常抖动,但仍能过滤掉混乱的、非滑雪的晃动。
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#define SKIING_GYR_VARIANCE_THRESHOLD 15.0f
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// --- 原地旋转抖动 ---
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// 用于原地旋转判断的加速度方差阈值。此值比ZUPT阈值更宽松,
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// 以允许原地旋转时身体的正常晃动,但仍能与真实滑行时的剧烈加速度变化区分开。
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#define ROTATING_ACC_VARIANCE_THRESHOLD 0.8f
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// 用于启动滑雪判断的陀螺仪方差阈值。此值比ZUPT阈值更宽松,
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// 以允许启动瞬间的正常抖动,但仍能过滤掉混乱的、非滑雪的晃动。
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#define SKIING_GYR_VARIANCE_THRESHOLD 15.0f
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// 旋转/摆动检测阈值:角速度总模长大于此值(度/秒),认为正在进行非滑雪的旋转或摆动
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#define ROTATION_GYR_MAG_THRESHOLD 90.0f //测试记录:45.0f、90.0f
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// 启动滑雪阈值:加速度模长与重力的差值大于此值,认为开始运动
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// 降低阈值,让“油门”更灵敏,以便能捕捉到真实的慢速启动
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#define START_SKIING_ACC_THRESHOLD 0.5f
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#define ROTATION_GYR_MAG_THRESHOLD 120.0f
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// --- 滑雪转弯动 ---
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// 加速度方差阈值,大于此值,滑雪过程可能发生了急转弯
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#define WHEEL_ACC_VARIANCE_THRESHOLD 7.0f
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// 旋转/摆动检测阈值:角速度总模长大于此值(度/秒),认为滑雪过程中进行急转弯
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#define WHEEL_GYR_MAG_THRESHOLD 220.0f // 150.0f 到 250.0f之间进行调整
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// --- 用于消除积分漂移的滤波器和阈值 ---
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// 高通滤波器系数 (alpha)。alpha 越接近1,滤除低频(直流偏移)的效果越强,但可能滤掉真实的慢速运动。
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// alpha = RC / (RC + dt),
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#define HPF_ALPHA 0.95f // 换算大概就是衰减频率低于约 0.84 Hz 的信号
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// 任何比“大约1秒钟变化一次”还要慢的运动,其加速度信号也会被部分衰减。
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// 而滑雪时的快速转弯、加减速等动作,其频率远高于 0.84 Hz,它们的信号会被保留下来。
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// alpha = RC / (RC + dt),参考RC电路而来
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#define HPF_ALPHA 0.995
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// 加速度死区阈值 (m/s^2)。低于此阈值的加速度被认为是噪声,不参与积分。
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// 设得太高会忽略真实的慢速启动,设得太低则无法有效抑制噪声。
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#define ACC_DEAD_ZONE_THRESHOLD 0.15f
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#define ACC_DEAD_ZONE_THRESHOLD 0.05f
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// --- 模拟摩擦力,进行速度衰减 ---
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#define SPEED_ATTENUATION 0.98f
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#define SPEED_ATTENUATION 1.0f //暂不模拟
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#ifdef XTELL_TEST
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BLE_KS_send_data_t KS_data;
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debug_t debug1;
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debug_t debug2;
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#endif
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//////////////////////////////////////////////////////////////////////////////////////////////////
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//实现
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/**
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@ -161,8 +171,13 @@ static void update_state_machine(skiing_tracker_t *tracker, const float *acc_dev
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float gyr_variance = calculate_variance(tracker->gyr_buffer); // 计算陀螺仪方差
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float gyr_magnitude = sqrtf(gyr_dps[0]*gyr_dps[0] + gyr_dps[1]*gyr_dps[1] + gyr_dps[2]*gyr_dps[2]);
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float acc_magnitude = sqrtf(acc_device_ms2[0]*acc_device_ms2[0] + acc_device_ms2[1]*acc_device_ms2[1] + acc_device_ms2[2]*acc_device_ms2[2]);
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#ifdef XTELL_TEST
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debug1.acc_variance =acc_variance;
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debug1.gyr_variance =gyr_variance;
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debug1.gyr_magnitude=gyr_magnitude;
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debug1.acc_magnitude=acc_magnitude - G_ACCELERATION;
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#endif
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// --- 状态切换逻辑 (按优先级) ---
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// 优先级1:动态零速更新 (ZUPT) - 最严格和最优先的“刹车”
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@ -177,9 +192,15 @@ static void update_state_machine(skiing_tracker_t *tracker, const float *acc_dev
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return;
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}
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if(tracker->state == SKIING_STATE_SKIING && gyr_magnitude > WHEEL_GYR_MAG_THRESHOLD && acc_variance > WHEEL_ACC_VARIANCE_THRESHOLD){
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//TODO:可以考虑清掉速度消除积分带来的漂移
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tracker->state = SKIING_STATE_ROTATING;
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return;
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}
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// 优先级2:原地旋转 - 特殊的、非滑雪的运动状态
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// 条件:角速度很大,同时线性加速度的晃动在一个“中等”范围内。
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if (gyr_magnitude > ROTATION_GYR_MAG_THRESHOLD && acc_variance < ROTATING_ACC_VARIANCE_THRESHOLD) {
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if (tracker->state == SKIING_STATE_STATIC && gyr_magnitude > ROTATION_GYR_MAG_THRESHOLD && acc_variance < ROTATING_ACC_VARIANCE_THRESHOLD) {
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tracker->state = SKIING_STATE_ROTATING;
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return;
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}
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@ -253,6 +274,9 @@ void skiing_tracker_update(skiing_tracker_t *tracker, float *acc_g, float *gyr_d
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// 垂直方向的速度暂时不积分,极易受姿态误差影响而漂移
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// tracker->velocity[2] += tracker->acc_world_filtered[2] * dt;
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}
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#ifdef XTELL_TEST
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debug2.acc_magnitude = acc_horizontal_mag;
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#endif
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// 如果加速度小于阈值,则不更新速度,相当于速度保持不变(或受下一步的阻尼影响而衰减)
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} else {
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@ -291,7 +315,7 @@ BLE_send_data_t sensor_processing_task(signed short * acc_data_buf, signed short
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const float delta_time = DELTA_TIME;
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BLE_send_data_t BLE_send_data;
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BLE_KS_send_data_t KS_data;
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@ -330,13 +354,16 @@ BLE_send_data_t sensor_processing_task(signed short * acc_data_buf, signed short
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skiing_tracker_update(&my_skiing_tracker, calibrated_acc_g, calibrated_gyr_dps, final_angle_data, delta_time);
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// 打印逻辑保持不变
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// static int count = 0;
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// if(count >= 10){
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// printf("State: %d, Speed: %.2f m/s, Distance: %.2f m\n",
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// my_skiing_tracker.state,
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// my_skiing_tracker.speed,
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// my_skiing_tracker.distance);
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// printf("calibrated_acc_g: %.2f, %.2f, %.2f\n",
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// calibrated_acc_g[0],
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// calibrated_acc_g[1],
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// calibrated_acc_g[2]);
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// count = 0;
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// } else {
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// count++;
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@ -350,7 +377,7 @@ BLE_send_data_t sensor_processing_task(signed short * acc_data_buf, signed short
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BLE_send_data.gyr_original[i] = (int)gyr_data_buf[i];
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#endif
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#if KS_BLE
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KS_data.acc_KS_g[i] = (int)calibrated_acc_g[i];
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KS_data.acc_KS[i] = (int)(calibrated_acc_g[i] * G_ACCELERATION * 100); //cm/s^s
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KS_data.gyr_KS_dps[i] = (int)calibrated_gyr_dps[i];
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KS_data.angle_KS[i] = (int)final_angle_data[i];
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#endif
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@ -51,11 +51,19 @@ typedef struct __attribute__((packed)){ //该结构体取消内存对齐
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}BLE_send_data_t;
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typedef struct{
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int acc_KS_g[3]; //卡尔曼后,LSB to g 三轴加速度数据
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int acc_KS[3]; //卡尔曼后,LSB转换后的 三轴加速度数据(cm/s^2)
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int gyr_KS_dps[3]; //卡尔曼后,LSB to dps 三轴陀螺仪数据
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int angle_KS[3]; //卡尔曼后,计算得到的欧若拉角数据
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}BLE_KS_send_data_t;
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#ifdef XTELL_TEST
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typedef struct{
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float acc_variance; //三轴加速度方差之和
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float gyr_variance; //三轴陀螺仪方差之和
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float acc_magnitude; //三轴加速度模长
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float gyr_magnitude; //三轴陀螺仪模长
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}debug_t;
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#endif
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/**
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* @brief 初始化滑雪追踪器
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*
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@ -1,312 +0,0 @@
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/*
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动态ZUPT+卡尔曼
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多了加速度死区、摩擦力速度衰减、高通滤波
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原地摆动产生的速度、距离变化还是没法消除
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水平移动、斜坡移动效果貌似还行
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*/
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#include "skiing_tracker.h"
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#include "../sensor/SC7U22.h"
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#include <math.h>
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#include <string.h>
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#define G_ACCELERATION 9.81f
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#define DEG_TO_RAD (3.14159265f / 180.0f)
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// --- 算法阈值定义 ---
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//两个判断是否静止的必要条件
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// 动态零速更新(ZUPT)阈值
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// 提高阈值,让“刹车”更灵敏,以便在波浪式前进等慢速漂移时也能触发零速更新
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#define ZUPT_ACC_VARIANCE_THRESHOLD 0.2f
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// 陀螺仪方差阈值
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#define ZUPT_GYR_VARIANCE_THRESHOLD 5.0f
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// 旋转/摆动检测阈值:角速度总模长大于此值(度/秒),认为正在进行非滑雪的旋转或摆动 -- 没法完全消除
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#define ROTATION_GYR_MAG_THRESHOLD 45.0f
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// 启动滑雪阈值:加速度模长与重力的差值大于此值,认为开始运动
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// 降低阈值,让“油门”更灵敏,以便能捕捉到真实的慢速启动
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#define START_SKIING_ACC_THRESHOLD 0.5f
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// --- 用于消除积分漂移的滤波器和阈值 ---
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// 高通滤波器系数 (alpha)。alpha 越接近1,滤除低频(直流偏移)的效果越强,但可能滤掉真实的慢速运动。
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// alpha = RC / (RC + dt),
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#define HPF_ALPHA 0.95f
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// 加速度死区阈值 (m/s^2)。低于此阈值的加速度被认为是噪声,不参与积分。
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// 设得太高会忽略真实的慢速启动,设得太低则无法有效抑制噪声。
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#define ACC_DEAD_ZONE_THRESHOLD 0.1f
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// --- 模拟摩擦力,进行速度衰减 ---
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#define SPEED_ATTENUATION 0.98f
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/**
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* @brief 初始化滑雪追踪器
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*/
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void skiing_tracker_init(skiing_tracker_t *tracker)
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{
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if (!tracker) {
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return;
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}
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// 使用memset一次性清零整个结构体,包括新增的缓冲区
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memset(tracker, 0, sizeof(skiing_tracker_t));
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tracker->state = SKIING_STATE_STATIC;
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}
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/**
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* @brief 将设备坐标系下的加速度转换为世界坐标系
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* @param acc_device 设备坐标系下的加速度 [x, y, z]
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* @param angle 姿态角 [pitch, roll, yaw],单位: 度
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* @param acc_world 输出:世界坐标系下的加速度 [x, y, z]
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*/
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static void transform_acc_to_world_frame(const float *acc_device, const float *angle, float *acc_world)
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{
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// 驱动输出的角度与标准航空定义相反,需要取反才能用于标准旋转矩阵。
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float pitch = -angle[0] * DEG_TO_RAD;
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float roll = -angle[1] * DEG_TO_RAD;
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// TODO: 当引入三轴磁力计后,这里的 yaw 应由磁力计和陀螺仪融合解算得出,以解决航向漂移问题。
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// 目前 yaw 暂时不参与计算,因为仅靠加速度计和陀螺仪无法获得准确的绝对航向角。
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// float yaw = -angle[2] * DEG_TO_RAD;
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float cp = cosf(pitch);
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float sp = sinf(pitch);
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float cr = cosf(roll);
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float sr = sinf(roll);
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float ax = acc_device[0];
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float ay = acc_device[1];
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float az = acc_device[2];
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// 使用经过验证的、正确的身体坐标系到世界坐标系的旋转矩阵 (基于 Y-X 旋转顺序)
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// 这个矩阵将设备测量的加速度(ax, ay, az)正确地转换到世界坐标系(acc_world)。
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// 注意:这里没有使用yaw,主要关心的是坡面上的运动,绝对航向暂时不影响速度和距离的计算。
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// TODO
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acc_world[0] = cp * ax + sp * sr * ay + sp * cr * az;
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acc_world[1] = 0 * ax + cr * ay - sr * az;
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acc_world[2] = -sp * ax + cp * sr * ay + cp * cr * az;
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}
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/**
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* @brief 计算缓冲区内三轴数据的方差之和
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*/
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static float calculate_variance(float buffer[VARIANCE_BUFFER_SIZE][3])
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{
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float mean[3] = {0};
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float variance[3] = {0};
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// 1. 计算均值
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for (int i = 0; i < VARIANCE_BUFFER_SIZE; i++) {
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mean[0] += buffer[i][0];
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mean[1] += buffer[i][1];
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mean[2] += buffer[i][2];
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}
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mean[0] /= VARIANCE_BUFFER_SIZE;
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mean[1] /= VARIANCE_BUFFER_SIZE;
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mean[2] /= VARIANCE_BUFFER_SIZE;
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// 2. 计算方差
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for (int i = 0; i < VARIANCE_BUFFER_SIZE; i++) {
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variance[0] += (buffer[i][0] - mean[0]) * (buffer[i][0] - mean[0]);
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variance[1] += (buffer[i][1] - mean[1]) * (buffer[i][1] - mean[1]);
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variance[2] += (buffer[i][2] - mean[2]) * (buffer[i][2] - mean[2]);
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}
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variance[0] /= VARIANCE_BUFFER_SIZE;
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variance[1] /= VARIANCE_BUFFER_SIZE;
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variance[2] /= VARIANCE_BUFFER_SIZE;
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// 返回三轴方差之和,作为一个综合的稳定度指标
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return variance[0] + variance[1] + variance[2];
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}
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/**
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* @brief 状态机更新
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*/
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static void update_state_machine(skiing_tracker_t *tracker, const float *acc_device_ms2, const float *gyr_dps)
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{
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// 缓冲区未填满时,不进行状态判断,默认为静止
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if (!tracker->buffer_filled) {
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tracker->state = SKIING_STATE_STATIC;
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return;
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}
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// --- 计算关键指标 ---
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float acc_variance = calculate_variance(tracker->acc_buffer); // 计算加速度方差
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float gyr_variance = calculate_variance(tracker->gyr_buffer); // 计算陀螺仪方差
|
||||
float gyr_magnitude = sqrtf(gyr_dps[0]*gyr_dps[0] + gyr_dps[1]*gyr_dps[1] + gyr_dps[2]*gyr_dps[2]);
|
||||
float acc_magnitude = sqrtf(acc_device_ms2[0]*acc_device_ms2[0] + acc_device_ms2[1]*acc_device_ms2[1] + acc_device_ms2[2]*acc_device_ms2[2]);
|
||||
|
||||
// --- 状态切换逻辑---
|
||||
|
||||
// 原地旋转/摆动检测
|
||||
// 增加一个关键前提:只在当前不处于滑雪状态时,才检测原地旋转。
|
||||
// 这可以防止滑雪过程中的高速转弯被误判为原地旋转。
|
||||
// 暂时没办法完全消除
|
||||
if (gyr_magnitude > ROTATION_GYR_MAG_THRESHOLD && tracker->state != SKIING_STATE_SKIING) {
|
||||
tracker->state = SKIING_STATE_ROTATING;
|
||||
return;
|
||||
}
|
||||
|
||||
// 动态零速更新 (ZUPT)
|
||||
// 必须同时满足加速度和角速度都稳定,才能判断为“真静止”,以区分匀速运动
|
||||
if (acc_variance < ZUPT_ACC_VARIANCE_THRESHOLD && gyr_variance < ZUPT_GYR_VARIANCE_THRESHOLD) {
|
||||
tracker->state = SKIING_STATE_STATIC;
|
||||
// 速度清零,抑制漂移
|
||||
memset(tracker->velocity, 0, sizeof(tracker->velocity));
|
||||
tracker->speed = 0.0f;
|
||||
//当检测到静止时,必须重置高通滤波器的状态,否则下次启动时会有跳变
|
||||
memset(tracker->acc_world_unfiltered_prev, 0, sizeof(tracker->acc_world_unfiltered_prev));
|
||||
memset(tracker->acc_world_filtered, 0, sizeof(tracker->acc_world_filtered));
|
||||
return;
|
||||
}
|
||||
|
||||
// 从静止/旋转状态启动
|
||||
if (tracker->state == SKIING_STATE_STATIC || tracker->state == SKIING_STATE_ROTATING) {
|
||||
// 最终版启动逻辑:必须同时满足“有足够大的线性加速度”和“旋转不剧烈”两个条件
|
||||
// 新增 gyr_magnitude 判断,防止原地旋转产生的离心加速度被误判为启动
|
||||
if (fabsf(acc_magnitude - G_ACCELERATION) > START_SKIING_ACC_THRESHOLD &&
|
||||
gyr_variance < ZUPT_GYR_VARIANCE_THRESHOLD &&
|
||||
gyr_magnitude < ROTATION_GYR_MAG_THRESHOLD) {
|
||||
tracker->state = SKIING_STATE_SKIING;
|
||||
return;
|
||||
}
|
||||
}
|
||||
// 最后的 fall-through 逻辑已移除,以修复原地旋转被错误判断为滑雪的bug。
|
||||
// 如果不满足任何状态切换条件,状态将保持不变,直到ZUPT或启动条件被满足。
|
||||
}
|
||||
|
||||
|
||||
/**
|
||||
* @brief 主更新函数
|
||||
*/
|
||||
void skiing_tracker_update(skiing_tracker_t *tracker, float *acc_g, float *gyr_dps, float *angle, float dt)
|
||||
{
|
||||
if (!tracker || !acc_g || !gyr_dps || !angle || dt <= 0) {
|
||||
return;
|
||||
}
|
||||
|
||||
// --- 数据预处理和缓冲 ---
|
||||
float acc_device_ms2[3];
|
||||
acc_device_ms2[0] = acc_g[0] * G_ACCELERATION;
|
||||
acc_device_ms2[1] = acc_g[1] * G_ACCELERATION;
|
||||
acc_device_ms2[2] = acc_g[2] * G_ACCELERATION;
|
||||
|
||||
// 将最新数据存入缓冲区
|
||||
memcpy(tracker->acc_buffer[tracker->buffer_index], acc_device_ms2, sizeof(acc_device_ms2));
|
||||
memcpy(tracker->gyr_buffer[tracker->buffer_index], gyr_dps, 3 * sizeof(float));
|
||||
|
||||
tracker->buffer_index++;
|
||||
if (tracker->buffer_index >= VARIANCE_BUFFER_SIZE) {
|
||||
tracker->buffer_index = 0;
|
||||
tracker->buffer_filled = 1; // 标记缓冲区已满
|
||||
}
|
||||
|
||||
// --- 更新状态机 ---
|
||||
update_state_machine(tracker, acc_device_ms2, gyr_dps);
|
||||
|
||||
// --- 根据状态进行计算 ---
|
||||
if (tracker->state == SKIING_STATE_SKIING) {
|
||||
// 坐标转换 & 移除重力
|
||||
transform_acc_to_world_frame(acc_device_ms2, angle, tracker->acc_world);
|
||||
tracker->acc_world[2] -= G_ACCELERATION;
|
||||
|
||||
// 对世界坐标系下的加速度进行高通滤波,消除直流偏置和重力残差
|
||||
for (int i = 0; i < 3; i++) {
|
||||
tracker->acc_world_filtered[i] = HPF_ALPHA * (tracker->acc_world_filtered[i] + tracker->acc_world[i] - tracker->acc_world_unfiltered_prev[i]);
|
||||
tracker->acc_world_unfiltered_prev[i] = tracker->acc_world[i];
|
||||
}
|
||||
|
||||
// 应用加速度死区,忽略微小抖动和噪声
|
||||
float acc_horizontal_mag = sqrtf(tracker->acc_world_filtered[0] * tracker->acc_world_filtered[0] +
|
||||
tracker->acc_world_filtered[1] * tracker->acc_world_filtered[1]);
|
||||
|
||||
if (acc_horizontal_mag > ACC_DEAD_ZONE_THRESHOLD) {
|
||||
// 只有当水平加速度足够大时,才进行速度积分
|
||||
tracker->velocity[0] += tracker->acc_world_filtered[0] * dt;
|
||||
tracker->velocity[1] += tracker->acc_world_filtered[1] * dt;
|
||||
// 垂直方向的速度暂时不积分,极易受姿态误差影响而漂移
|
||||
// tracker->velocity[2] += tracker->acc_world_filtered[2] * dt;
|
||||
}
|
||||
// 如果加速度小于阈值,则不更新速度,相当于速度保持不变(或受下一步的阻尼影响而衰减)
|
||||
|
||||
} else {
|
||||
// 在静止或旋转状态下,速度已经在状态机内部被清零
|
||||
// 额外增加速度衰减,模拟摩擦力,进一步抑制漂移
|
||||
tracker->velocity[0] *= SPEED_ATTENUATION;
|
||||
tracker->velocity[1] *= SPEED_ATTENUATION;
|
||||
tracker->velocity[2] = 0; // 垂直速度强制归零
|
||||
}
|
||||
|
||||
// --- 更新速率和距离 ---
|
||||
// 只基于水平速度计算速率和距离
|
||||
tracker->speed = sqrtf(tracker->velocity[0] * tracker->velocity[0] +
|
||||
tracker->velocity[1] * tracker->velocity[1]);
|
||||
tracker->distance += tracker->speed * dt;
|
||||
}
|
||||
|
||||
|
||||
// 传感器数据采集与处理任务
|
||||
void sensor_processing_task(signed short * acc_data_buf, signed short * gyr_data_buf) {
|
||||
static skiing_tracker_t my_skiing_tracker;
|
||||
static int initialized = 0;
|
||||
static int calibration_done = 0;
|
||||
|
||||
static signed short combined_raw_data[6];
|
||||
static float final_angle_data[3]; // 计算得到的欧若拉角
|
||||
static float calibrated_acc_g[3]; // 转换后的加速度计数据
|
||||
static float calibrated_gyr_dps[3]; // 转换后的陀螺仪数据
|
||||
|
||||
const float delta_time = 0.01f;
|
||||
|
||||
if (!initialized) {
|
||||
skiing_tracker_init(&my_skiing_tracker);
|
||||
initialized = 1;
|
||||
printf("Skiing Tracker Initialized. Waiting for sensor calibration...\n");
|
||||
}
|
||||
|
||||
memcpy(&combined_raw_data[0], acc_data_buf, 3 * sizeof(signed short));
|
||||
memcpy(&combined_raw_data[3], gyr_data_buf, 3 * sizeof(signed short));
|
||||
|
||||
unsigned char status;
|
||||
if (!calibration_done) { //第1次启动,开启零漂检测
|
||||
status = SL_SC7U22_Angle_Output(1, combined_raw_data, final_angle_data, 0);
|
||||
if (status == 1) {
|
||||
calibration_done = 1;
|
||||
printf("Sensor calibration successful! Skiing mode is active.\n");
|
||||
}
|
||||
} else {
|
||||
status = SL_SC7U22_Angle_Output(0, combined_raw_data, final_angle_data, 0);
|
||||
}
|
||||
|
||||
if (status == 1) {
|
||||
// 加速度 LSB to g
|
||||
calibrated_acc_g[0] = (float)combined_raw_data[0] / 8192.0f;
|
||||
calibrated_acc_g[1] = (float)combined_raw_data[1] / 8192.0f;
|
||||
calibrated_acc_g[2] = (float)combined_raw_data[2] / 8192.0f;
|
||||
|
||||
// 陀螺仪 LSB to dps (度/秒)
|
||||
// ±2000dps量程下,转换系数约为 0.061
|
||||
calibrated_gyr_dps[0] = (float)combined_raw_data[3] * 0.061f;
|
||||
calibrated_gyr_dps[1] = (float)combined_raw_data[4] * 0.061f;
|
||||
calibrated_gyr_dps[2] = (float)combined_raw_data[5] * 0.061f;
|
||||
|
||||
skiing_tracker_update(&my_skiing_tracker, calibrated_acc_g, calibrated_gyr_dps, final_angle_data, delta_time);
|
||||
|
||||
// 打印逻辑保持不变
|
||||
static int count = 0;
|
||||
if(count < 10){
|
||||
count++;
|
||||
return;
|
||||
} else {
|
||||
count = 0;
|
||||
}
|
||||
printf("State: %d, Speed: %.2f m/s, Distance: %.2f m\n",
|
||||
my_skiing_tracker.state,
|
||||
my_skiing_tracker.speed,
|
||||
my_skiing_tracker.distance);
|
||||
|
||||
} else if (status == 0) {
|
||||
// printf("Sensor is calibrating...\n");
|
||||
} else {
|
||||
// printf("Angle calculation error or calibration not finished.\n");
|
||||
}
|
||||
}
|
||||
Reference in New Issue
Block a user