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Rev | Author | Line No. | Line |
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1910 | - | 1 | /************************************************************************/ |
2 | /* Flight Attitude */ |
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3 | /************************************************************************/ |
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4 | |||
5 | #include <stdlib.h> |
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6 | #include <avr/io.h> |
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7 | |||
8 | #include "attitude.h" |
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9 | #include "dongfangMath.h" |
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10 | |||
11 | // For scope debugging only! |
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12 | #include "rc.h" |
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13 | |||
14 | // where our main data flow comes from. |
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15 | #include "analog.h" |
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16 | |||
17 | #include "configuration.h" |
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18 | #include "output.h" |
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19 | |||
20 | // Some calculations are performed depending on some stick related things. |
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21 | #include "controlMixer.h" |
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22 | |||
23 | // For Servo_On / Off |
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24 | // #include "timer2.h" |
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25 | |||
26 | #define CHECK_MIN_MAX(value, min, max) {if(value < min) value = min; else if(value > max) value = max;} |
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27 | |||
28 | /* |
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29 | * Gyro readings, as read from the analog module. It would have been nice to flow |
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30 | * them around between the different calculations as a struct or array (doing |
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31 | * things functionally without side effects) but this is shorter and probably |
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32 | * faster too. |
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33 | * The variables are overwritten at each attitude calculation invocation - the values |
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34 | * are not preserved or reused. |
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35 | */ |
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36 | int16_t rate_ATT[2], yawRate; |
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37 | |||
38 | // With different (less) filtering |
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39 | int16_t rate_PID[2]; |
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40 | int16_t differential[3]; |
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41 | |||
42 | /* |
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1922 | - | 43 | * Gyro integrals. These are the rotation angles of the airframe compared to the |
44 | * horizontal plane, yaw relative to yaw at start. Not really used for anything else |
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45 | * than diagnostics. |
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1910 | - | 46 | */ |
1922 | - | 47 | int32_t angle[2], yawAngleDiff; |
1910 | - | 48 | |
49 | /* |
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1922 | - | 50 | * Error integrals. Stick is always positive. Gyro is configurable positive or negative. |
51 | * These represent the deviation of the attitude angle from the desired on each axis. |
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1910 | - | 52 | */ |
1922 | - | 53 | int32_t error[3]; |
1910 | - | 54 | |
55 | // Yaw angle and compass stuff. |
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56 | // This is updated/written from MM3. Negative angle indicates invalid data. |
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57 | int16_t compassHeading = -1; |
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58 | |||
59 | // This is NOT updated from MM3. Negative angle indicates invalid data. |
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60 | int16_t compassCourse = -1; |
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61 | |||
62 | // The difference between the above 2 (heading - course) on a -180..179 degree interval. |
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63 | // Not necessary. Never read anywhere. |
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64 | // int16_t compassOffCourse = 0; |
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65 | |||
66 | uint8_t updateCompassCourse = 0; |
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67 | uint8_t compassCalState = 0; |
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68 | uint16_t ignoreCompassTimer = 500; |
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69 | |||
70 | int32_t yawGyroHeading; // Yaw Gyro Integral supported by compass |
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71 | int16_t yawGyroDrift; |
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72 | |||
73 | int16_t correctionSum[2] = { 0, 0 }; |
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74 | |||
75 | // For NaviCTRL use. |
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76 | int16_t averageAcc[2] = { 0, 0 }, averageAccCount = 0; |
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77 | |||
78 | /* |
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79 | * Experiment: Compensating for dynamic-induced gyro biasing. |
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80 | */ |
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81 | int16_t driftComp[2] = { 0, 0 }, driftCompYaw = 0; |
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82 | // int16_t savedDynamicOffsetPitch = 0, savedDynamicOffsetRoll = 0; |
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83 | // int32_t dynamicCalPitch, dynamicCalRoll, dynamicCalYaw; |
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84 | // int16_t dynamicCalCount; |
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85 | |||
86 | /************************************************************************ |
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87 | * Set inclination angles from the acc. sensor data. |
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88 | * If acc. sensors are not used, set to zero. |
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89 | * TODO: One could use inverse sine to calculate the angles more |
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90 | * accurately, but since: 1) the angles are rather small at times when |
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91 | * it makes sense to set the integrals (standing on ground, or flying at |
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92 | * constant speed, and 2) at small angles a, sin(a) ~= constant * a, |
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93 | * it is hardly worth the trouble. |
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94 | ************************************************************************/ |
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95 | |||
96 | int32_t getAngleEstimateFromAcc(uint8_t axis) { |
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97 | return GYRO_ACC_FACTOR * (int32_t) filteredAcc[axis]; |
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98 | } |
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99 | |||
100 | void setStaticAttitudeAngles(void) { |
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101 | #ifdef ATTITUDE_USE_ACC_SENSORS |
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102 | angle[PITCH] = getAngleEstimateFromAcc(PITCH); |
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103 | angle[ROLL] = getAngleEstimateFromAcc(ROLL); |
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104 | #else |
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105 | angle[PITCH] = angle[ROLL] = 0; |
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106 | #endif |
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107 | } |
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108 | |||
109 | /************************************************************************ |
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110 | * Neutral Readings |
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111 | ************************************************************************/ |
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112 | void attitude_setNeutral(void) { |
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113 | // Servo_Off(); // disable servo output. TODO: Why bother? The servos are going to make a jerk anyway. |
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114 | driftComp[PITCH] = driftComp[ROLL] = yawGyroDrift = driftCompYaw = 0; |
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115 | correctionSum[PITCH] = correctionSum[ROLL] = 0; |
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116 | |||
117 | // Calibrate hardware. |
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118 | analog_calibrate(); |
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119 | |||
120 | // reset gyro integrals to acc guessing |
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121 | setStaticAttitudeAngles(); |
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122 | yawAngleDiff = 0; |
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123 | |||
124 | // update compass course to current heading |
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125 | compassCourse = compassHeading; |
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126 | |||
127 | // Inititialize YawGyroIntegral value with current compass heading |
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128 | yawGyroHeading = (int32_t) compassHeading * GYRO_DEG_FACTOR_YAW; |
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129 | |||
130 | // Servo_On(); //enable servo output |
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131 | } |
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132 | |||
133 | /************************************************************************ |
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134 | * Get sensor data from the analog module, and release the ADC |
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135 | * TODO: Ultimately, the analog module could do this (instead of dumping |
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136 | * the values into variables). |
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137 | * The rate variable end up in a range of about [-1024, 1023]. |
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138 | *************************************************************************/ |
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139 | void getAnalogData(void) { |
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140 | uint8_t axis; |
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141 | |||
142 | for (axis = PITCH; axis <= ROLL; axis++) { |
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143 | rate_PID[axis] = gyro_PID[axis] + driftComp[axis]; |
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144 | rate_ATT[axis] = gyro_ATT[axis] + driftComp[axis]; |
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145 | differential[axis] = gyroD[axis]; |
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146 | averageAcc[axis] += acc[axis]; |
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147 | } |
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148 | |||
149 | differential[YAW] = gyroD[YAW]; |
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150 | |||
151 | averageAccCount++; |
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152 | yawRate = yawGyro + driftCompYaw; |
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153 | |||
154 | // We are done reading variables from the analog module. |
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155 | // Interrupt-driven sensor reading may restart. |
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156 | analogDataReady = 0; |
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157 | analog_start(); |
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158 | } |
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159 | |||
160 | void integrate(void) { |
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161 | // First, perform axis coupling. If disabled xxxRate is just copied to ACxxxRate. |
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162 | uint8_t axis; |
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163 | |||
164 | if (staticParams.GlobalConfig & CFG_AXIS_COUPLING_ACTIVE) { |
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1922 | - | 165 | error[PITCH] += (staticParams.ControlSigns & 1 ? rate_ATT[PITCH] : -rate_ATT[PITCH]); |
166 | error[ROLL] += (staticParams.ControlSigns & 2 ? rate_ATT[ROLL] : -rate_ATT[ROLL]); |
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167 | error[YAW] += (staticParams.ControlSigns & 4 ? yawRate : -yawRate); |
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1910 | - | 168 | } else { |
1922 | - | 169 | error[PITCH] += (staticParams.ControlSigns & 1 ? rate_ATT[PITCH] : -rate_ATT[PITCH]); |
170 | error[ROLL] += (staticParams.ControlSigns & 2 ? rate_ATT[ROLL] : -rate_ATT[ROLL]); |
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171 | error[YAW] += (staticParams.ControlSigns & 4 ? yawRate : -yawRate); |
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1910 | - | 172 | } |
173 | |||
1922 | - | 174 | for (axis=PITCH; axis<=YAW; axis++) { |
175 | if (error[axis] > ERRORLIMIT) { |
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176 | error[axis] = ERRORLIMIT; |
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177 | } else if (angle[axis] <= -ERRORLIMIT) { |
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178 | angle[axis] = -ERRORLIMIT; |
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179 | } |
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180 | } |
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181 | |||
1910 | - | 182 | /* |
183 | * Yaw |
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184 | * Calculate yaw gyro integral (~ to rotation angle) |
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185 | * Limit yawGyroHeading proportional to 0 deg to 360 deg |
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186 | */ |
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187 | yawGyroHeading += ACYawRate; |
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188 | yawAngleDiff += yawRate; |
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189 | |||
190 | if (yawGyroHeading >= YAWOVER360) { |
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191 | yawGyroHeading -= YAWOVER360; // 360 deg. wrap |
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192 | } else if (yawGyroHeading < 0) { |
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193 | yawGyroHeading += YAWOVER360; |
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194 | } |
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195 | |||
196 | /* |
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197 | * Pitch axis integration and range boundary wrap. |
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198 | */ |
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199 | for (axis = PITCH; axis <= ROLL; axis++) { |
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1922 | - | 200 | angle[axis] += rate_ATT[axis]; |
1910 | - | 201 | if (angle[axis] > PITCHROLLOVER180) { |
202 | angle[axis] -= PITCHROLLOVER360; |
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203 | } else if (angle[axis] <= -PITCHROLLOVER180) { |
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204 | angle[axis] += PITCHROLLOVER360; |
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205 | } |
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206 | } |
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207 | } |
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208 | |||
209 | /************************************************************************ |
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210 | * A kind of 0'th order integral correction, that corrects the integrals |
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211 | * directly. This is the "gyroAccFactor" stuff in the original code. |
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212 | * There is (there) also a drift compensation |
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213 | * - it corrects the differential of the integral = the gyro offsets. |
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214 | * That should only be necessary with drifty gyros like ENC-03. |
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215 | ************************************************************************/ |
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216 | void correctIntegralsByAcc0thOrder(void) { |
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217 | // TODO: Consider changing this to: Only correct when integrals are less than ...., or only correct when angular velocities |
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218 | // are less than ....., or reintroduce Kalman. |
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219 | // Well actually the Z axis acc. check is not so silly. |
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220 | uint8_t axis; |
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221 | int32_t temp; |
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222 | if (acc[Z] >= -dynamicParams.UserParams[7] && acc[Z] |
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223 | <= dynamicParams.UserParams[7]) { |
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224 | DebugOut.Digital[0] |= DEBUG_ACC0THORDER; |
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225 | |||
226 | uint8_t permilleAcc = staticParams.GyroAccFactor; // NOTE!!! The meaning of this value has changed!! |
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227 | uint8_t debugFullWeight = 1; |
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228 | int32_t accDerived; |
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229 | |||
230 | if ((control[YAW] < -64) || (control[YAW] > 64)) { // reduce further if yaw stick is active |
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231 | permilleAcc /= 2; |
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232 | debugFullWeight = 0; |
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233 | } |
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234 | |||
235 | if ((maxControl[PITCH] > 64) || (maxControl[ROLL] > 64)) { // reduce effect during stick commands. Replace by controlActivity. |
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236 | permilleAcc /= 2; |
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237 | debugFullWeight = 0; |
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238 | } |
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239 | |||
240 | if (debugFullWeight) |
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241 | DebugOut.Digital[1] |= DEBUG_ACC0THORDER; |
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242 | else |
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243 | DebugOut.Digital[1] &= ~DEBUG_ACC0THORDER; |
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244 | |||
245 | /* |
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246 | * Add to each sum: The amount by which the angle is changed just below. |
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247 | */ |
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248 | for (axis = PITCH; axis <= ROLL; axis++) { |
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249 | accDerived = getAngleEstimateFromAcc(axis); |
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250 | // DebugOut.Analog[9 + axis] = (10 * accDerived) / GYRO_DEG_FACTOR_PITCHROLL; |
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251 | |||
252 | // 1000 * the correction amount that will be added to the gyro angle in next line. |
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253 | temp = angle[axis]; //(permilleAcc * (accDerived - angle[axis])) / 1000; |
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254 | angle[axis] = ((int32_t) (1000L - permilleAcc) * temp |
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255 | + (int32_t) permilleAcc * accDerived) / 1000L; |
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256 | correctionSum[axis] += angle[axis] - temp; |
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257 | } |
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258 | } else { |
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259 | DebugOut.Digital[0] &= ~DEBUG_ACC0THORDER; |
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260 | DebugOut.Digital[1] &= ~DEBUG_ACC0THORDER; |
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261 | // DebugOut.Analog[9] = 0; |
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262 | // DebugOut.Analog[10] = 0; |
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263 | |||
264 | DebugOut.Analog[16] = 0; |
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265 | DebugOut.Analog[17] = 0; |
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266 | // experiment: Kill drift compensation updates when not flying smooth. |
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267 | correctionSum[PITCH] = correctionSum[ROLL] = 0; |
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268 | } |
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269 | } |
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270 | |||
271 | /************************************************************************ |
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272 | * This is an attempt to correct not the error in the angle integrals |
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273 | * (that happens in correctIntegralsByAcc0thOrder above) but rather the |
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274 | * cause of it: Gyro drift, vibration and rounding errors. |
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275 | * All the corrections made in correctIntegralsByAcc0thOrder over |
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276 | * DRIFTCORRECTION_TIME cycles are summed up. This number is |
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277 | * then divided by DRIFTCORRECTION_TIME to get the approx. |
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278 | * correction that should have been applied to each iteration to fix |
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279 | * the error. This is then added to the dynamic offsets. |
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280 | ************************************************************************/ |
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281 | // 2 times / sec. = 488/2 |
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282 | #define DRIFTCORRECTION_TIME 256L |
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283 | void driftCorrection(void) { |
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284 | static int16_t timer = DRIFTCORRECTION_TIME; |
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285 | int16_t deltaCorrection; |
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286 | int16_t round; |
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287 | uint8_t axis; |
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288 | |||
289 | if (!--timer) { |
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290 | timer = DRIFTCORRECTION_TIME; |
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291 | for (axis = PITCH; axis <= ROLL; axis++) { |
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292 | // Take the sum of corrections applied, add it to delta |
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293 | if (correctionSum[axis] >=0) |
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294 | round = DRIFTCORRECTION_TIME / 2; |
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295 | else |
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296 | round = -DRIFTCORRECTION_TIME / 2; |
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297 | deltaCorrection = (correctionSum[axis] + round) / DRIFTCORRECTION_TIME; |
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298 | // Add the delta to the compensation. So positive delta means, gyro should have higher value. |
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299 | driftComp[axis] += deltaCorrection / staticParams.GyroAccTrim; |
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300 | CHECK_MIN_MAX(driftComp[axis], -staticParams.DriftComp, staticParams.DriftComp); |
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301 | // DebugOut.Analog[11 + axis] = correctionSum[axis]; |
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302 | DebugOut.Analog[16 + axis] = correctionSum[axis]; |
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303 | DebugOut.Analog[28 + axis] = driftComp[axis]; |
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304 | |||
305 | correctionSum[axis] = 0; |
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306 | } |
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307 | } |
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308 | } |
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309 | |||
310 | /************************************************************************ |
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311 | * Main procedure. |
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312 | ************************************************************************/ |
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313 | void calculateFlightAttitude(void) { |
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314 | getAnalogData(); |
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315 | integrate(); |
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316 | |||
317 | DebugOut.Analog[3] = rate_PID[PITCH]; |
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318 | DebugOut.Analog[4] = rate_PID[ROLL]; |
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319 | DebugOut.Analog[5] = yawRate; |
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320 | |||
321 | #ifdef ATTITUDE_USE_ACC_SENSORS |
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322 | correctIntegralsByAcc0thOrder(); |
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323 | driftCorrection(); |
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324 | #endif |
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325 | } |