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performance optimizations
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@ -33,6 +33,7 @@
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#include <math.h>
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#include <stdint.h>
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#include <pios_math.h>
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#include <mathmisc.h>
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// constants/macros/typdefs
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#define NUMX 13 // number of states, X is the state vector
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@ -43,15 +44,15 @@
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// Private functions
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void CovariancePrediction(float F[NUMX][NUMX], float G[NUMX][NUMW],
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float Q[NUMW], float dT, float P[NUMX][NUMX]);
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void SerialUpdate(float H[NUMV][NUMX], float R[NUMV], float Z[NUMV],
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static void SerialUpdate(float H[NUMV][NUMX], float R[NUMV], float Z[NUMV],
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float Y[NUMV], float P[NUMX][NUMX], float X[NUMX],
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uint16_t SensorsUsed);
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void RungeKutta(float X[NUMX], float U[NUMU], float dT);
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void StateEq(float X[NUMX], float U[NUMU], float Xdot[NUMX]);
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void LinearizeFG(float X[NUMX], float U[NUMU], float F[NUMX][NUMX],
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static void RungeKutta(float X[NUMX], float U[NUMU], float dT);
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static void StateEq(float X[NUMX], float U[NUMU], float Xdot[NUMX]);
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static void LinearizeFG(float X[NUMX], float U[NUMU], float F[NUMX][NUMX],
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float G[NUMX][NUMW]);
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void MeasurementEq(float X[NUMX], float Be[3], float Y[NUMV]);
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void LinearizeH(float X[NUMX], float Be[3], float H[NUMV][NUMX]);
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static void MeasurementEq(float X[NUMX], float Be[3], float Y[NUMV]);
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static void LinearizeH(float X[NUMX], float Be[3], float H[NUMV][NUMX]);
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// Private variables
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@ -60,22 +61,22 @@ void LinearizeH(float X[NUMX], float Be[3], float H[NUMV][NUMX]);
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// LinearizeFG() and LinearizeH():
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//
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// usage F: usage G: usage H:
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// 0123456789abc 012345678 0123456789abc
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// -0123456789abc 012345678 0123456789abc
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// 0...X......... ......... X............
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// 1....X........ ......... .X...........
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// 2.....X....... ......... ..X..........
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// 3......XXXX... ...XXX... ...X.........
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// 4......XXXX... ...XXX... ....X........
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// 5......XXXX... ...XXX... .....X.......
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// 6.......XXXXXX XXX...... ......XXXX...
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// 7......X.XXXXX XXX...... ......XXXX...
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// 8......XX.XXXX XXX...... ......XXXX...
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// 9......XXX.XXX XXX...... ..X..........
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// a............. ......X..
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// b............. .......X.
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// c............. ........X
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// 6.....ooXXXXXX XXX...... ......XXXX...
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// 7.....oXoXXXXX XXX...... ......XXXX...
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// 8.....oXXoXXXX XXX...... ......XXXX...
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// 9.....oXXXoXXX XXX...... ..X..........
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// a............. ......Xoo
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// b............. ......oXo
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// c............. ......ooX
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static const int8_t FrowMin[NUMX] = { 3, 4, 5, 6, 6, 6, 7, 6, 6, 6, 13, 13, 13 };
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static const int8_t FrowMin[NUMX] = { 3, 4, 5, 6, 6, 6, 5, 5, 5, 5, 13, 13, 13 };
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static const int8_t FrowMax[NUMX] = { 3, 4, 5, 9, 9, 9, 12, 12, 12, 12, -1, -1, -1 };
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static const int8_t GrowMin[NUMX] = { 9, 9, 9, 3, 3, 3, 0, 0, 0, 0, 6, 7, 8 };
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@ -289,7 +290,7 @@ void INSSetMagNorth(float B[3])
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void INSStatePrediction(float gyro_data[3], float accel_data[3], float dT)
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{
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float U[6];
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float qmag;
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float invqmag;
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// rate gyro inputs in units of rad/s
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U[0] = gyro_data[0];
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@ -304,11 +305,11 @@ void INSStatePrediction(float gyro_data[3], float accel_data[3], float dT)
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// EKF prediction step
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LinearizeFG(ekf.X, U, ekf.F, ekf.G);
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RungeKutta(ekf.X, U, dT);
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qmag = sqrtf(ekf.X[6] * ekf.X[6] + ekf.X[7] * ekf.X[7] + ekf.X[8] * ekf.X[8] + ekf.X[9] * ekf.X[9]);
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ekf.X[6] /= qmag;
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ekf.X[7] /= qmag;
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ekf.X[8] /= qmag;
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ekf.X[9] /= qmag;
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invqmag = fast_invsqrtf(ekf.X[6] * ekf.X[6] + ekf.X[7] * ekf.X[7] + ekf.X[8] * ekf.X[8] + ekf.X[9] * ekf.X[9]);
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ekf.X[6] *= invqmag;
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ekf.X[7] *= invqmag;
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ekf.X[8] *= invqmag;
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ekf.X[9] *= invqmag;
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// CovariancePrediction(ekf.F,ekf.G,ekf.Q,dT,ekf.P);
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// Update Nav solution structure
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@ -373,8 +374,9 @@ void VelBaroCorrection(float Vel[3], float BaroAlt)
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void INSCorrection(float mag_data[3], float Pos[3], float Vel[3],
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float BaroAlt, uint16_t SensorsUsed)
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{
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float Z[10], Y[10];
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float Bmag, qmag;
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float Z[10] = { 0 };
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float Y[10] = { 0 };
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float invBmag;
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// GPS Position in meters and in local NED frame
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Z[0] = Pos[0];
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@ -385,15 +387,11 @@ void INSCorrection(float mag_data[3], float Pos[3], float Vel[3],
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Z[3] = Vel[0];
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Z[4] = Vel[1];
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Z[5] = Vel[2];
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// magnetometer data in any units (use unit vector) and in body frame
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Bmag =
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sqrtf(mag_data[0] * mag_data[0] + mag_data[1] * mag_data[1] +
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mag_data[2] * mag_data[2]);
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Z[6] = mag_data[0] / Bmag;
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Z[7] = mag_data[1] / Bmag;
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Z[8] = mag_data[2] / Bmag;
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invBmag = fast_invsqrtf(mag_data[0] * mag_data[0] + mag_data[1] * mag_data[1] + mag_data[2] * mag_data[2]);
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Z[6] = mag_data[0] * invBmag;
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Z[7] = mag_data[1] * invBmag;
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Z[8] = mag_data[2] * invBmag;
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// barometric altimeter in meters and in local NED frame
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Z[9] = BaroAlt;
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@ -401,12 +399,12 @@ void INSCorrection(float mag_data[3], float Pos[3], float Vel[3],
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LinearizeH(ekf.X, ekf.Be, ekf.H);
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MeasurementEq(ekf.X, ekf.Be, Y);
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SerialUpdate(ekf.H, ekf.R, Z, Y, ekf.P, ekf.X, SensorsUsed);
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qmag = sqrtf(ekf.X[6] * ekf.X[6] + ekf.X[7] * ekf.X[7] + ekf.X[8] * ekf.X[8] + ekf.X[9] * ekf.X[9]);
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ekf.X[6] /= qmag;
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ekf.X[7] /= qmag;
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ekf.X[8] /= qmag;
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ekf.X[9] /= qmag;
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invBmag = fast_invsqrtf(ekf.X[6] * ekf.X[6] + ekf.X[7] * ekf.X[7] + ekf.X[8] * ekf.X[8] + ekf.X[9] * ekf.X[9]);
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ekf.X[6] *= invBmag;
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ekf.X[7] *= invBmag;
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ekf.X[8] *= invBmag;
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ekf.X[9] *= invBmag;
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// Update Nav solution structure
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Nav.Pos[0] = ekf.X[0];
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Nav.Pos[1] = ekf.X[1];
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@ -440,23 +438,25 @@ void CovariancePrediction(float F[NUMX][NUMX], float G[NUMX][NUMW],
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{
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// Pnew = (I+F*T)*P*(I+F*T)' + (T^2)*G*Q*G' = (T^2)[(P/T + F*P)*(I/T + F') + G*Q*G')]
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float dT1 = 1.0f / dT; // multiplication is faster than division on fpu.
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float dTsq = dT * dT;
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const float dT1 = 1.0f / dT; // multiplication is faster than division on fpu.
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const float dTsq = dT * dT;
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float Dummy[NUMX][NUMX];
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int8_t i;
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int8_t k;
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for (i = 0; i < NUMX; i++) { // Calculate Dummy = (P/T +F*P)
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float *Firow = F[i];
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float *Pirow = P[i];
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float *Dirow = Dummy[i];
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int8_t Fistart = FrowMin[i];
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int8_t Fiend = FrowMax[i];
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const int8_t Fistart = FrowMin[i];
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const int8_t Fiend = FrowMax[i];
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int8_t j;
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for (j = 0; j < NUMX; j++) {
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Dirow[j] = Pirow[j] * dT1; // Dummy = P / T ...
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int8_t k;
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}
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for (k = Fistart; k <= Fiend; k++) {
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for (j = 0; j < NUMX; j++) {
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Dirow[j] += Firow[k] * P[k][j]; // [] + F * P
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}
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}
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@ -465,29 +465,45 @@ void CovariancePrediction(float F[NUMX][NUMX], float G[NUMX][NUMW],
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float *Dirow = Dummy[i];
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float *Girow = G[i];
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float *Pirow = P[i];
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int8_t Gistart = GrowMin[i];
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int8_t Giend = GrowMax[i];
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const int8_t Gistart = GrowMin[i];
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const int8_t Giend = GrowMax[i];
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int8_t j;
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for (j = i; j < NUMX; j++) { // Use symmetry, ie only find upper triangular
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float Ptmp = Dirow[j] * dT1; // Pnew = Dummy / T ...
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{
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float *Fjrow = F[j];
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const float *Fjrow = F[j];
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int8_t Fjstart = FrowMin[j];
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int8_t Fjend = FrowMax[j];
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int8_t k;
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for (k = Fjstart; k <= Fjend; k++) {
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k = Fjstart;
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while (k <= Fjend - 3) {
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Ptmp += Dirow[k] * Fjrow[k]; // [] + Dummy*F' ...
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Ptmp += Dirow[k + 1] * Fjrow[k + 1];
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Ptmp += Dirow[k + 2] * Fjrow[k + 2];
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Ptmp += Dirow[k + 3] * Fjrow[k + 3];
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k+=4;
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}
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while (k <= Fjend) {
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Ptmp += Dirow[k] * Fjrow[k];
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k++;
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}
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{
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float *Gjrow = G[j];
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int8_t Gjstart = MAX(Gistart, GrowMin[j]);
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int8_t Gjend = MIN(Giend, GrowMax[j]);
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int8_t k;
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for (k = Gjstart; k <= Gjend; k++) {
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const int8_t Gjstart = MAX(Gistart, GrowMin[j]);
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const int8_t Gjend = MIN(Giend, GrowMax[j]);
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k = Gjstart;
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while (k <= Gjend - 2) {
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Ptmp += Q[k] * Girow[k] * Gjrow[k]; // [] + G*Q*G' ...
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Ptmp += Q[k + 1] * Girow[k + 1] * Gjrow[k + 1];
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Ptmp += Q[k + 2] * Girow[k + 2] * Gjrow[k + 2];
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k+=3;
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}
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if (k <= Gjend) {
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Ptmp += Q[k] * Girow[k] * Gjrow[k];
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if (k <= Gjend - 1) {
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Ptmp += Q[k + 1] * Girow[k + 1] * Gjrow[k + 1];
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}
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}
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@ -560,8 +576,8 @@ void SerialUpdate(float H[NUMV][NUMX], float R[NUMV], float Z[NUMV],
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void RungeKutta(float X[NUMX], float U[NUMU], float dT)
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{
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float dT2 =
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dT / 2.0f, K1[NUMX], K2[NUMX], K3[NUMX], K4[NUMX], Xlast[NUMX];
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const float dT2 = dT / 2.0f;
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float K1[NUMX], K2[NUMX], K3[NUMX], K4[NUMX], Xlast[NUMX];
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uint8_t i;
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for (i = 0; i < NUMX; i++) {
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@ -608,7 +624,7 @@ void RungeKutta(float X[NUMX], float U[NUMU], float dT)
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// H is output of LinearizeH(), all elements not set should be zero
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// ************************************************
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void StateEq(float X[NUMX], float U[NUMU], float Xdot[NUMX])
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static void StateEq(float X[NUMX], float U[NUMU], float Xdot[NUMX])
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{
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float ax, ay, az, wx, wy, wz, q0, q1, q2, q3;
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