void GPS_NewData(void) { static uint32_t nav_loopTimer; uint32_t dist; int32_t dir; uint8_t axis; int16_t speed; uint16_t c = GPSBufferAvailable(); while (c--) { if (GPS_newFrame(GPSBufferRead())) { if (GPS_Info.GPS_update == 1) GPS_Info.GPS_update = 0; else GPS_Info.GPS_update = 1; if (fgps.GPS_FIX && GPS_Info.GPS_numSat >= 5) { if (!checkArm()) { fgps.GPS_FIX_HOME = 0; } if (!fgps.GPS_FIX_HOME && checkArm()) { GPS_reset_home_position(); } //Apply moving average filter to GPS data #if defined(GPS_FILTERING) GPS_filter_index = (GPS_filter_index+1) % GPS_FILTER_VECTOR_LENGTH; for (axis = 0; axis< 2; axis++) { GPS_data[axis] = GPS_Info.GPS_coord[axis]; //latest unfiltered data is in GPS_latitude and GPS_longitude GPS_degree[axis] = GPS_data[axis] / 10000000; // get the degree to assure the sum fits to the int32_t // How close we are to a degree line ? its the first three digits from the fractions of degree // later we use it to Check if we are close to a degree line, if yes, disable averaging, fraction3[axis] = (GPS_data[axis]- GPS_degree[axis]*10000000) / 10000; GPS_filter_sum[axis] -= GPS_filter[axis][GPS_filter_index]; GPS_filter[axis][GPS_filter_index] = GPS_data[axis] - (GPS_degree[axis]*10000000); GPS_filter_sum[axis] += GPS_filter[axis][GPS_filter_index]; GPS_filtered[axis] = GPS_filter_sum[axis] / GPS_FILTER_VECTOR_LENGTH + (GPS_degree[axis]*10000000); if ( nav_mode == NAV_MODE_POSHOLD) { //we use gps averaging only in poshold mode... if ( fraction3[axis]>1 && fraction3[axis]<999 ) GPS_Info.GPS_coord[axis] = GPS_filtered[axis]; } } #endif //Time for calculating x,y speed and navigation pids dTnav = (float)(getTickCount() - nav_loopTimer)/ 10000.0f; nav_loopTimer = getTickCount(); // prevent runup from bad GPS dTnav = min(dTnav, 1.0f); //calculate distance and bearings for gui and other stuff continously - From home to copter GPS_distance_cm_bearing(&GPS_Info.GPS_coord[LAT],&GPS_Info.GPS_coord[LON],&GPS_Info.GPS_home[LAT],&GPS_Info.GPS_home[LON],&dist,&dir); GPS_Info.GPS_distanceToHome = dist/100; GPS_Info.GPS_directionToHome = dir/100; if (!fgps.GPS_FIX_HOME) { //If we don't have home set, do not display anything GPS_Info.GPS_distanceToHome = 0; GPS_Info.GPS_directionToHome = 0; } //calculate the current velocity based on gps coordinates continously to get a valid speed at the moment when we start navigating GPS_calc_velocity(); if (fgps.GPS_HOLD_MODE || fgps.GPS_HOME_MODE){ //ok we are navigating //do gps nav calculations here, these are common for nav and poshold #if defined(GPS_LEAD_FILTER) GPS_distance_cm_bearing(&GPS_coord_lead[LAT],&GPS_coord_lead[LON],&GPS_WP[LAT],&GPS_WP[LON],&wp_distance,&target_bearing); GPS_calc_location_error(&GPS_WP[LAT],&GPS_WP[LON],&GPS_coord_lead[LAT],&GPS_coord_lead[LON]); #else GPS_distance_cm_bearing(&GPS_coord[LAT],&GPS_coord[LON],&GPS_WP[LAT],&GPS_WP[LON],&wp_distance,&target_bearing); GPS_calc_location_error(&GPS_WP[LAT],&GPS_WP[LON],&GPS_coord[LAT],&GPS_coord[LON]); #endif switch (nav_mode) { case NAV_MODE_POSHOLD: //Desired output is in nav_lat and nav_lon where 1deg inclination is 100 GPS_calc_poshold(); break; case NAV_MODE_WP: speed = GPS_calc_desired_speed(NAV_SPEED_MAX, NAV_SLOW_NAV); //slow navigation // use error as the desired rate towards the target //Desired output is in nav_lat and nav_lon where 1deg inclination is 100 GPS_calc_nav_rate(speed); //Tail control if (NAV_CONTROLS_HEADING) { if (NAV_TAIL_FIRST) { magHold = wrap_18000(nav_bearing-18000)/100; } else { magHold = nav_bearing/100; } } // Are we there yet ?(within 2 meters of the destination) if ((wp_distance <= GPS_wp_radius) || check_missed_wp()){ //if yes switch to poshold mode nav_mode = NAV_MODE_POSHOLD; if (NAV_SET_TAKEOFF_HEADING) { magHold = nav_takeoff_bearing; } } break; } } //end of gps calcs } } } }
uint8_t GPS_NewData(void) { uint8_t axis; #if defined(I2C_GPS) static uint8_t _i2c_gps_status; //Do not use i2c_writereg, since writing a register does not work if an i2c_stop command is issued at the end //Still investigating, however with separated i2c_repstart and i2c_write commands works... and did not caused i2c errors on a long term test. GPS_numSat = (_i2c_gps_status & 0xf0) >> 4; _i2c_gps_status = i2c_readReg(I2C_GPS_ADDRESS,I2C_GPS_STATUS_00); //Get status register uint8_t *varptr; #if defined(I2C_GPS_SONAR) i2c_rep_start(I2C_GPS_ADDRESS<<1); i2c_write(I2C_GPS_SONAR_ALT); i2c_rep_start((I2C_GPS_ADDRESS<<1)|1); varptr = (uint8_t *)&sonarAlt; // altitude (in cm? maybe) *varptr++ = i2c_readAck(); *varptr = i2c_readNak(); #endif if (_i2c_gps_status & I2C_GPS_STATUS_3DFIX) { //Check is we have a good 3d fix (numsats>5) f.GPS_FIX = 1; if (_i2c_gps_status & I2C_GPS_STATUS_NEW_DATA) { //Check about new data GPS_Frame = 1; i2c_rep_start(I2C_GPS_ADDRESS<<1); i2c_write(I2C_GPS_LOCATION); //Start read from here 2x2 bytes distance and direction i2c_rep_start((I2C_GPS_ADDRESS<<1)|1); varptr = (uint8_t *)&GPS_coord[LAT]; // for latitude displaying *varptr++ = i2c_readAck(); *varptr++ = i2c_readAck(); *varptr++ = i2c_readAck(); *varptr = i2c_readAck(); varptr = (uint8_t *)&GPS_coord[LON]; // for longitude displaying *varptr++ = i2c_readAck(); *varptr++ = i2c_readAck(); *varptr++ = i2c_readAck(); *varptr = i2c_readNak(); i2c_rep_start(I2C_GPS_ADDRESS<<1); i2c_write(I2C_GPS_GROUND_SPEED); i2c_rep_start((I2C_GPS_ADDRESS<<1)|1); varptr = (uint8_t *)&GPS_speed; // speed in cm/s for OSD *varptr++ = i2c_readAck(); *varptr = i2c_readAck(); varptr = (uint8_t *)&GPS_altitude; // altitude in meters for OSD *varptr++ = i2c_readAck(); *varptr = i2c_readAck(); varptr = (uint8_t *)&GPS_ground_course; *varptr++ = i2c_readAck(); *varptr = i2c_readNak(); } else { return 0; } } else { f.GPS_FIX = 0; return 0; } #endif #if defined(GPS_SERIAL) || defined(GPS_FROM_OSD) #if defined(GPS_SERIAL) uint8_t c = SerialAvailable(GPS_SERIAL); if (c==0) return 0; while (c--) { if (GPS_newFrame(SerialRead(GPS_SERIAL))) { #elif defined(GPS_FROM_OSD) { if(GPS_update & 2) { // Once second bit of GPS_update is set, indicate new GPS datas is readed from OSD - all in right format. GPS_update &= 1; // We have: GPS_fix(0-2), GPS_numSat(0-15), GPS_coord[LAT & LON](signed, in 1/10 000 000 degres), GPS_altitude(signed, in meters) and GPS_speed(in cm/s) #endif GPS_Frame = 1; } } #endif return 1; } uint8_t GPS_Compute(void) { if (GPS_Frame == 0) return 0; else GPS_Frame = 0; if (GPS_update == 1) GPS_update = 0; else GPS_update = 1; if (f.GPS_FIX && GPS_numSat >= 5) { #if !defined(DONT_RESET_HOME_AT_ARM) if (!f.ARMED) {f.GPS_FIX_HOME = 0;} #endif if (!f.GPS_FIX_HOME && f.ARMED) { GPS_reset_home_position(); } //Apply moving average filter to GPS data #if defined(GPS_FILTERING) GPS_filter_index = (GPS_filter_index+1) % GPS_FILTER_VECTOR_LENGTH; for (uint8_t axis = 0; axis< 2; axis++) { GPS_read[axis] = GPS_coord[axis]; //latest unfiltered data is in GPS_latitude and GPS_longitude GPS_degree[axis] = GPS_read[axis] / 10000000; // get the degree to assure the sum fits to the int32_t // How close we are to a degree line ? its the first three digits from the fractions of degree // later we use it to Check if we are close to a degree line, if yes, disable averaging, fraction3[axis] = (GPS_read[axis]- GPS_degree[axis]*10000000) / 10000; GPS_filter_sum[axis] -= GPS_filter[axis][GPS_filter_index]; GPS_filter[axis][GPS_filter_index] = GPS_read[axis] - (GPS_degree[axis]*10000000); GPS_filter_sum[axis] += GPS_filter[axis][GPS_filter_index]; GPS_filtered[axis] = GPS_filter_sum[axis] / GPS_FILTER_VECTOR_LENGTH + (GPS_degree[axis]*10000000); if ( nav_mode == NAV_MODE_POSHOLD) { //we use gps averaging only in poshold mode... if ( fraction3[axis]>1 && fraction3[axis]<999 ) GPS_coord[axis] = GPS_filtered[axis]; } } #endif //dTnav calculation //Time for calculating x,y speed and navigation pids static uint32_t nav_loopTimer; dTnav = (float)(millis() - nav_loopTimer)/ 1000.0; nav_loopTimer = millis(); // prevent runup from bad GPS dTnav = min(dTnav, 1.0); //calculate distance and bearings for gui and other stuff continously - From home to copter uint32_t dist; int32_t dir; GPS_distance_cm_bearing(&GPS_coord[LAT],&GPS_coord[LON],&GPS_home[LAT],&GPS_home[LON],&dist,&dir); GPS_distanceToHome = dist/100; GPS_directionToHome = dir/100; if (!f.GPS_FIX_HOME) { //If we don't have home set, do not display anything GPS_distanceToHome = 0; GPS_directionToHome = 0; } //calculate the current velocity based on gps coordinates continously to get a valid speed at the moment when we start navigating GPS_calc_velocity(); if (f.GPS_HOLD_MODE || f.GPS_HOME_MODE){ //ok we are navigating //do gps nav calculations here, these are common for nav and poshold #if defined(GPS_LEAD_FILTER) GPS_distance_cm_bearing(&GPS_coord_lead[LAT],&GPS_coord_lead[LON],&GPS_WP[LAT],&GPS_WP[LON],&wp_distance,&target_bearing); GPS_calc_location_error(&GPS_WP[LAT],&GPS_WP[LON],&GPS_coord_lead[LAT],&GPS_coord_lead[LON]); #else GPS_distance_cm_bearing(&GPS_coord[LAT],&GPS_coord[LON],&GPS_WP[LAT],&GPS_WP[LON],&wp_distance,&target_bearing); GPS_calc_location_error(&GPS_WP[LAT],&GPS_WP[LON],&GPS_coord[LAT],&GPS_coord[LON]); #endif switch (nav_mode) { case NAV_MODE_POSHOLD: //Desired output is in nav_lat and nav_lon where 1deg inclination is 100 GPS_calc_poshold(); break; case NAV_MODE_WP: int16_t speed = GPS_calc_desired_speed(NAV_SPEED_MAX, NAV_SLOW_NAV); //slow navigation // use error as the desired rate towards the target //Desired output is in nav_lat and nav_lon where 1deg inclination is 100 GPS_calc_nav_rate(speed); //Tail control if (NAV_CONTROLS_HEADING) { if (NAV_TAIL_FIRST) { magHold = wrap_18000(nav_bearing-18000)/100; } else { magHold = nav_bearing/100; } } // Are we there yet ?(within 2 meters of the destination) if ((wp_distance <= GPS_wp_radius) || check_missed_wp()){ //if yes switch to poshold mode nav_mode = NAV_MODE_POSHOLD; if (NAV_SET_TAKEOFF_HEADING) { magHold = nav_takeoff_bearing; } } break; } } //end of gps calcs } } void GPS_reset_home_position(void) { if (f.GPS_FIX && GPS_numSat >= 5) { GPS_home[LAT] = GPS_coord[LAT]; GPS_home[LON] = GPS_coord[LON]; GPS_calc_longitude_scaling(GPS_coord[LAT]); //need an initial value for distance and bearing calc nav_takeoff_bearing = att.heading; //save takeoff heading //Set ground altitude f.GPS_FIX_HOME = 1; } } //reset navigation (stop the navigation processor, and clear nav) void GPS_reset_nav(void) { uint8_t i; for(i=0;i<2;i++) { nav_rated[i] = 0; nav[i] = 0; reset_PID(&posholdPID[i]); reset_PID(&poshold_ratePID[i]); reset_PID(&navPID[i]); nav_mode = NAV_MODE_NONE; } } //Get the relevant P I D values and set the PID controllers void GPS_set_pids(void) { posholdPID_PARAM.kP = (float)conf.pid[PIDPOS].P8/100.0; posholdPID_PARAM.kI = (float)conf.pid[PIDPOS].I8/100.0; posholdPID_PARAM.Imax = POSHOLD_RATE_IMAX * 100; poshold_ratePID_PARAM.kP = (float)conf.pid[PIDPOSR].P8/10.0; poshold_ratePID_PARAM.kI = (float)conf.pid[PIDPOSR].I8/100.0; poshold_ratePID_PARAM.kD = (float)conf.pid[PIDPOSR].D8/1000.0; poshold_ratePID_PARAM.Imax = POSHOLD_RATE_IMAX * 100; navPID_PARAM.kP = (float)conf.pid[PIDNAVR].P8/10.0; navPID_PARAM.kI = (float)conf.pid[PIDNAVR].I8/100.0; navPID_PARAM.kD = (float)conf.pid[PIDNAVR].D8/1000.0; navPID_PARAM.Imax = POSHOLD_RATE_IMAX * 100; }
void GPS_NewData(uint16_t c) { uint8_t axis; static uint32_t nav_loopTimer; uint32_t dist; int32_t dir; int16_t speed; if (GPS_newFrame(c)) { if (GPS_update == 1) GPS_update = 0; else GPS_update = 1; if (GPS_fix == 1 && GPS_numSat >= 5) { if (armed == 0) { GPS_fix_home = 0; } if (GPS_fix_home == 0 && armed) { GPS_fix_home = 1; GPS_home[LAT] = GPS_coord[LAT]; GPS_home[LON] = GPS_coord[LON]; GPS_calc_longitude_scaling(GPS_coord[LAT]); // need an initial value for distance and bearing calc nav_takeoff_bearing = heading; // save takeoff heading } // Apply moving average filter to GPS data #if defined(GPS_FILTERING) GPS_filter_index = ++GPS_filter_index % GPS_FILTER_VECTOR_LENGTH; for (axis = 0; axis < 2; axis++) { GPS_read[axis] = GPS_coord[axis]; // latest unfiltered data is in GPS_latitude and GPS_longitude GPS_degree[axis] = GPS_read[axis] / 10000000; // get the degree to assure the sum fits to the int32_t // How close we are to a degree line ? its the first three digits from the fractions of degree // later we use it to Check if we are close to a degree line, if yes, disable averaging, fraction3[axis] = (GPS_read[axis] - GPS_degree[axis] * 10000000) / 10000; GPS_filter_sum[axis] -= GPS_filter[axis][GPS_filter_index]; GPS_filter[axis][GPS_filter_index] = GPS_read[axis] - (GPS_degree[axis] * 10000000); GPS_filter_sum[axis] += GPS_filter[axis][GPS_filter_index]; GPS_filtered[axis] = GPS_filter_sum[axis] / GPS_FILTER_VECTOR_LENGTH + (GPS_degree[axis] * 10000000); if (nav_mode == NAV_MODE_POSHOLD) { //we use gps averaging only in poshold mode... if (fraction3[axis] > 1 && fraction3[axis] < 999) GPS_coord[axis] = GPS_filtered[axis]; } } #endif // dTnav calculation // Time for calculating x,y speed and navigation pids dTnav = (float) (millis() - nav_loopTimer) / 1000.0f; nav_loopTimer = millis(); // prevent runup from bad GPS dTnav = min(dTnav, 1.0f); // calculate distance and bearings for gui and other stuff continously - From home to copter GPS_distance_cm_bearing(&GPS_coord[LAT], &GPS_coord[LON], &GPS_home[LAT], &GPS_home[LON], &dist, &dir); GPS_distanceToHome = dist / 100; GPS_directionToHome = dir / 100; //calculate the current velocity based on gps coordinates continously to get a valid speed at the moment when we start navigating GPS_calc_velocity(); if (GPSModeHold == 1 || GPSModeHome == 1) { // ok we are navigating // do gps nav calculations here, these are common for nav and poshold GPS_distance_cm_bearing(&GPS_coord[LAT], &GPS_coord[LON], &GPS_WP[LAT], &GPS_WP[LON], &wp_distance, &target_bearing); GPS_calc_location_error(&GPS_WP[LAT], &GPS_WP[LON], &GPS_coord[LAT], &GPS_coord[LON]); switch (nav_mode) { case NAV_MODE_POSHOLD: // Desired output is in nav_lat and nav_lon where 1deg inclination is 100 GPS_calc_poshold(); break; case NAV_MODE_WP: speed = GPS_calc_desired_speed(cfg.nav_speed_max, NAV_SLOW_NAV); //slow navigation // use error as the desired rate towards the target // Desired output is in nav_lat and nav_lon where 1deg inclination is 100 GPS_calc_nav_rate(speed); // Tail control if (cfg.nav_controls_heading) { if (NAV_TAIL_FIRST) { magHold = wrap_18000(nav_bearing - 18000) / 100; } else { magHold = nav_bearing / 100; } } // Are we there yet ?(within x meters of the destination) if ((wp_distance <= cfg.gps_wp_radius) || check_missed_wp()) { // if yes switch to poshold mode nav_mode = NAV_MODE_POSHOLD; if (NAV_SET_TAKEOFF_HEADING) { magHold = nav_takeoff_bearing; } } break; } } //end of gps calcs } } }
void onGpsNewData(void) { int axis; static uint32_t nav_loopTimer; uint16_t speed; if (!(STATE(GPS_FIX) && GPS_numSat >= 5)) { return; } if (!ARMING_FLAG(ARMED)) DISABLE_STATE(GPS_FIX_HOME); if (!STATE(GPS_FIX_HOME) && ARMING_FLAG(ARMED)) GPS_reset_home_position(); // Apply moving average filter to GPS data #if defined(GPS_FILTERING) GPS_filter_index = (GPS_filter_index + 1) % GPS_FILTER_VECTOR_LENGTH; for (axis = 0; axis < 2; axis++) { GPS_read[axis] = GPS_coord[axis]; // latest unfiltered data is in GPS_latitude and GPS_longitude GPS_degree[axis] = GPS_read[axis] / 10000000; // get the degree to assure the sum fits to the int32_t // How close we are to a degree line ? its the first three digits from the fractions of degree // later we use it to Check if we are close to a degree line, if yes, disable averaging, fraction3[axis] = (GPS_read[axis] - GPS_degree[axis] * 10000000) / 10000; GPS_filter_sum[axis] -= GPS_filter[axis][GPS_filter_index]; GPS_filter[axis][GPS_filter_index] = GPS_read[axis] - (GPS_degree[axis] * 10000000); GPS_filter_sum[axis] += GPS_filter[axis][GPS_filter_index]; GPS_filtered[axis] = GPS_filter_sum[axis] / GPS_FILTER_VECTOR_LENGTH + (GPS_degree[axis] * 10000000); if (nav_mode == NAV_MODE_POSHOLD) { // we use gps averaging only in poshold mode... if (fraction3[axis] > 1 && fraction3[axis] < 999) GPS_coord[axis] = GPS_filtered[axis]; } } #endif // // Calculate time delta for navigation loop, range 0-1.0f, in seconds // // Time for calculating x,y speed and navigation pids dTnav = (float)(millis() - nav_loopTimer) / 1000.0f; nav_loopTimer = millis(); // prevent runup from bad GPS dTnav = min(dTnav, 1.0f); GPS_calculateDistanceAndDirectionToHome(); // calculate the current velocity based on gps coordinates continously to get a valid speed at the moment when we start navigating GPS_calc_velocity(); if (FLIGHT_MODE(GPS_HOLD_MODE) || FLIGHT_MODE(GPS_HOME_MODE)) { // we are navigating // gps nav calculations, these are common for nav and poshold GPS_distance_cm_bearing(&GPS_coord[LAT], &GPS_coord[LON], &GPS_WP[LAT], &GPS_WP[LON], &wp_distance, &target_bearing); GPS_calc_location_error(&GPS_WP[LAT], &GPS_WP[LON], &GPS_coord[LAT], &GPS_coord[LON]); switch (nav_mode) { case NAV_MODE_POSHOLD: // Desired output is in nav_lat and nav_lon where 1deg inclination is 100 GPS_calc_poshold(); break; case NAV_MODE_WP: speed = GPS_calc_desired_speed(gpsProfile->nav_speed_max, NAV_SLOW_NAV); // slow navigation // use error as the desired rate towards the target // Desired output is in nav_lat and nav_lon where 1deg inclination is 100 GPS_calc_nav_rate(speed); // Tail control if (gpsProfile->nav_controls_heading) { if (NAV_TAIL_FIRST) { magHold = wrap_18000(nav_bearing - 18000) / 100; } else { magHold = nav_bearing / 100; } } // Are we there yet ?(within x meters of the destination) if ((wp_distance <= gpsProfile->gps_wp_radius) || check_missed_wp()) { // if yes switch to poshold mode nav_mode = NAV_MODE_POSHOLD; if (NAV_SET_TAKEOFF_HEADING) { magHold = nav_takeoff_bearing; } } break; default: break; } } //end of gps calcs }
/*********************** 函数功能:GPS数据更新,将由串口中断调用,在GPS初始化时传入了 ***********************/ static void GPS_NewData(void) { int axis; static uint32_t nav_loopTimer; //记录上一次的循环的时间戳 uint32_t dist; //距离 int32_t dir; //方向 int16_t speed; //速度 SensorsSet(SENSOR_GPS); //置位GPS存在标志 if(GPS_update == 1) GPS_update = 0; else GPS_update = 1; if(f.GPS_FIX && GPS_numSat >= 5)//如果数据有效和卫星数大于5 { if(!f.ARMED) { f.GPS_FIX_HOME = 0;//在没有解锁状态下,清楚GPS HOME点 } if(!f.GPS_FIX_HOME && f.ARMED)//在没有GPS原点又已经解锁了,则设置原点 { f.GPS_FIX_HOME = 1;//标记有原点 GPS_home[LAT] = GPS_coord[LAT];//将当前经纬度记录下 GPS_home[LON] = GPS_coord[LON]; GPS_calc_longitude_scaling(GPS_coord[LAT]); //得到一个初始值用于计算距离和方位 nav_takeoff_bearing = heading; // save takeoff heading XbeePro_ImportanceInfo = XbeePro_ImportanceInfo | 0x10;//发送HOME点给上位机 } //进行滤波,美其名曰滑动平均滤波 GPS_filter_index = (GPS_filter_index + 1) % GPS_FILTER_VECTOR_LENGTH; for (axis = 0; axis < 2; axis++) //axis=0时为纬度,=1时为经度 { GPS_read[axis] = GPS_coord[axis]; //得到最新的未过滤的经纬度 GPS_degree[axis] = GPS_read[axis] / 10000000; //得到经纬度的度 // How close we are to a degree line ? its the first three digits from the fractions of degree // later we use it to Check if we are close to a degree line, if yes, disable averaging, fraction3[axis] = (GPS_read[axis] - GPS_degree[axis] * 10000000) / 10000;//得到小数点后三位的分,即0.xxx度的xxx GPS_filter_sum[axis] -= GPS_filter[axis][GPS_filter_index]; GPS_filter[axis][GPS_filter_index] = GPS_read[axis] - (GPS_degree[axis] * 10000000); GPS_filter_sum[axis] += GPS_filter[axis][GPS_filter_index]; GPS_filtered[axis] = GPS_filter_sum[axis] / GPS_FILTER_VECTOR_LENGTH + (GPS_degree[axis] * 10000000); if (nav_mode == NAV_MODE_POSHOLD) //我们只在poshold模式下使用GPS平均值 nav_mode == NAV_MODE_POSHOLD { if (fraction3[axis] > 1 && fraction3[axis] < 999) GPS_coord[axis] = GPS_filtered[axis]; //将滤波后的值保存 } } //进入计算 x,y 、速度、航向 的PID等 dTnav = (float) (TimMsGet() - nav_loopTimer) / 1000.0f;//计算两次之间的时间差 现在单位为s nav_loopTimer = TimMsGet(); //记录时间戳 单位为ms dTnav = min(dTnav, 1.0f); //防止GPS出错,产生超长时间差(不大于1S) //计算距离、方位给GUI,从原点到灰机的 GPS_distance_cm_bearing(&GPS_coord[LAT], &GPS_coord[LON], &GPS_home[LAT], &GPS_home[LON], &dist, &dir); GPS_distanceToHome = dist / 100; //将单位变为米 GPS_directionToHome = dir / 100; //现在单位是度了 //计算基于GPS的速率,当我们有启动导航 GPS_calc_velocity(); if(f.GPS_HOLD_MODE || f.GPS_HOME_MODE) //悬停或者返回原点模式,则启动导航哈 { if(GS_Nav) // 地面站有新导航任务 GS_Nav标志置一 ReadyForNextWP置一 ReadyToMove = 0; nav_mode = NAV_MODE_POSHOLD; wp=0; { if(ReadyForNextWP) //已经到达航点,为下一个航点做准备 { if(AutoHeading==0) //如果不需要自动转向 就直接飞向下一个航点 { ReadyToMove = 1; //这样就不会执行下面的转向和等待转向 } if(ReadyToMove) // 如果转向完毕,或不需要转向,则设定下一个航点并开启飞航线模式 { Set_nextwp(); nav_mode = NAV_MODE_WP; pid_nav_crosstrack._integrator = 0; pid_nav_crosstrack._last_input = 0; pid_nav_crosstrack._last_derivative = 0; } else //执行自动转向 { magHold = GPS_BearingForNextwp(&GPS_coord[LAT], &GPS_coord[LON], &Waypoint[wp][LAT], &Waypoint[wp][LON]);//计算下个点的方位角 magHold /=100; //切记切记 // if(abs(heading - magHold) < 10 || abs(heading - magHold) > 350) //航向调整完再走 nav_bearing/100 // { ReadyToMove = 1; // } } } } //GPS导航计算 GPS_distance_cm_bearing(&GPS_coord[LAT], &GPS_coord[LON], &GPS_WP[LAT], &GPS_WP[LON], &wp_distance, &target_bearing);//计算直线距离和方位角 GPS_calc_location_error(&GPS_WP[LAT], &GPS_WP[LON], &GPS_coord[LAT], &GPS_coord[LON]);//得到X,Y距离 switch (nav_mode) { case NAV_MODE_POSHOLD: //位置保持模式 GPS_calc_poshold(); break; case NAV_MODE_WP: // if(Waypoint[wp+1][0]==0) speed = GPS_calc_desired_speed(NAV_Speed, true);//只有到最后一个点才减速 // else // speed = GPS_calc_desired_speed(NAV_Speed, false); // cfg.nav_speed_max // use error as the desired rate towards the target // 期望的输出是在导航纬度和经度,1度倾向是100 GPS_calc_nav_rate(speed); //方向控制,即调整YAW if (AutoHeading) { #if (NAV_TAIL_FIRST) magHold = wrap_18000(target_bearing - 18000) / 100; #else magHold = target_bearing / 100; // nav_bearing #endif } //判断是否到达目的地(在一个允许的半径内) if ((wp_distance <= cfg.gps_wp_radius) || check_missed_wp()) //暂时是2米半径 { // nav_mode = NAV_MODE_POSHOLD;//如果到达或失去目标则进入悬停 ReadyForNextWP=1; ReadyToMove = 1 ; if(Waypoint[wp][LAT]==0) //没有下一个航点了 { nav_mode = NAV_MODE_POSHOLD;//如果到达或失去目标则进入悬停 GPS_hold[LAT] = GPS_WP[LAT]; //更新hold点坐标 GPS_hold[LON] = GPS_WP[LON]; XbeePro_ImportanceInfo = XbeePro_ImportanceInfo | 0x01;//发送HOLD点给上位机 ReadyForNextWP=0; GS_Nav = 0; //没有新航点时 ,保证不更行航点 if (NAV_SET_TAKEOFF_HEADING)//是否保持与起飞时的方向相同 { magHold = nav_takeoff_bearing; } } } else { ReadyForNextWP = 0; //不要更新航点 } break; } } } }