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amiro-os / components / Odometry.cpp @ 8c99e03a

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#include <ch.hpp>
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#include <hal.h>
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#include <qei.h>
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#include <amiro/Odometry.h>
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#include <math.h> // cos(), sin()
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#include <Matrix.h> // Matrixoperations "Matrix::*"
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#include <amiro/Constants.h> // Constants "constants::*"
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#include <chprintf.h>
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#include <global.hpp>
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using namespace chibios_rt;
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using namespace amiro;
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using namespace constants::DiWheelDrive;
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extern Global global;
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Odometry::Odometry(MotorIncrements* mi, L3G4200D* gyroscope)
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    : BaseStaticThread<512>(),
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      motorIncrements(mi),
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      gyro(gyroscope),
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      eventSource(),
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      period(50),
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      incrementsPerRevolution(incrementsPerRevolution),
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      updatesPerMinute(constants::secondsPerMinute * constants::millisecondsPerSecond / this->period),
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      wheelCircumference(wheelCircumferenceSI),
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      wheelBaseDistanceSI(wheelBaseDistanceSI) {
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//  this-> = constants::secondsPerMinute * constants::millisecondsPerSecond / this->period;
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//  this->wheelCircumference = constants::wheelCircumferenceSI;
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//  this->wheelBaseDistanceSI = constants::wheelBaseDistanceSI;
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  this->distance[LEFT_WHEEL] = 0.0f;
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  this->distance[RIGHT_WHEEL] = 0.0f;
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  this->increment[LEFT_WHEEL] = 0;
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  this->increment[RIGHT_WHEEL] = 0;
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  this->incrementDifference[LEFT_WHEEL] = 0.0f;
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  this->incrementDifference[RIGHT_WHEEL] = 0.0f;
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  this->distance[LEFT_WHEEL] = 0.0f;
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  this->distance[RIGHT_WHEEL] = 0.0f;
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  this->wheelError[LEFT_WHEEL] = wheelErrorSI[LEFT_WHEEL];
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  this->wheelError[RIGHT_WHEEL] = wheelErrorSI[RIGHT_WHEEL];
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  this->resetPosition(); // Init position
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  this->resetError(); // Init error Cp
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}
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types::position Odometry::getPosition() {
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  types::position robotPosition;
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  const int32_t piScaled = int32_t(2 * M_PI * 1e6);
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  chSysLock();
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    // Conversion from standard unit to ยต unit
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    robotPosition.x = this->pX * 1e6;
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    robotPosition.y = this->pY * 1e6;
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    robotPosition.f_z = (int32_t(this->pPhi * 1e6) % piScaled) + ((this->pPhi < 0) ? piScaled : 0);  // Get only the postitve angel f_z in [0 .. 2 * pi]
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  chSysUnlock();
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//     chprintf((BaseSequentialStream*) &global.sercanmux1, "X:%d Y:%d Phi:%d", robotPosition.x,robotPosition.y, robotPosition.f_z);
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//     chprintf((BaseSequentialStream*) &global.sercanmux1, "\r\n");
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//     chprintf((BaseSequentialStream*) &global.sercanmux1, "X:%f Y:%f Phi:%f", this->pX,this->pY, this->pPhi);
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//     chprintf((BaseSequentialStream*) &global.sercanmux1, "\r\n");
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  return robotPosition;
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}
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void Odometry::setPosition(float pX, float pY, float pPhi) {
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  chSysLock();
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    this->pX = pX;
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    this->pY = pY;
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    this->pPhi = pPhi;
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  chSysUnlock();
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}
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void Odometry::resetPosition() {
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  this->setPosition(0.0f,0.0f,0.0f);
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}
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void Odometry::setError(float* Cp3x3) {
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  chSysLock();
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    Matrix::copy<float>(Cp3x3,3,3, &(this->Cp3x3[0]),3,3);
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  chSysUnlock();
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}
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void Odometry::resetError() {
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  Matrix::init<float>(&(this->Cp3x3[0]),3,3,0.0f);
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}
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EvtSource* Odometry::getEventSource() {
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  return &this->eventSource;
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}
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msg_t Odometry::main(void) {
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  systime_t time = System::getTime();
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  this->setName("Odometry");
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  while (!this->shouldTerminate()) {
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    time += MS2ST(this->period);
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    // Update the base distance, because it may have changed after a calibration
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    this->updateWheelBaseDistance();
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    // Get the actual speed
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    this->updateDistance();
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    // Calculate the odometry
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    this->updateOdometry();
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//     chprintf((BaseSequentialStream*) &global.sercanmux1, "X:%f Y:%f Phi:%f", this->pX,this->pY, this->pPhi);
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//     chprintf((BaseSequentialStream*) &global.sercanmux1, "\r\n");
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//     chprintf((BaseSequentialStream*) &global.sercanmux1, "distance_left:%f distance_right:%f", this->distance[0],this->distance[1]);
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//     chprintf((BaseSequentialStream*) &global.sercanmux1, "\r\n");
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    if (time >= System::getTime()) {
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        chThdSleepUntil(time);
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    } else {
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        chprintf((BaseSequentialStream*) &global.sercanmux1, "WARNING Odometry: Unable to keep track\r\n");
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    }
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  }
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  return true;
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}
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void Odometry::updateOdometry() {
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  // Get the temporary position and error
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  float Cp3x3[9];
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  int32_t angular_ud;
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  int32_t angularRate_udps;
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  chSysLock();
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    float pX = this->pX;
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    float pY = this->pY;
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    float pPhi = this->pPhi;
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    Matrix::copy<float>(this->Cp3x3,3,3,Cp3x3,3,3);
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    // TODO Get the gyro (or gyro rate) information and do something with it
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    // angular_ud = gyro->getAngular_ud(L3G4200D::AXIS_Z);
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    // angularRate_udps = gyro->getAngularRate_udps(L3G4200D::AXIS_Z);
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  chSysUnlock();
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  ////////////////
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  // Temporary calculations
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  ////////////////
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  // TMP: Rotated angular
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  float dPhi = (this->distance[RIGHT_WHEEL] - this->distance[LEFT_WHEEL]) / this->wheelBaseDistanceSI;
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  // TODO Calculate the differential angel dPhi from either the angular (1. line) or angular rate (2.+3. line)
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  // float dPhi = ((float(angular_ud * 1e-3) * M_PI ) * 1e-3) / 180.0f;
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  // const float angular_md = float((angularRate_udps * this->period / constants::millisecondsPerSecond) * 1e-3);
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  // float dPhi = ((angular_md * M_PI) * 1e-3) / 180.0f;
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  // TMP: Moved distance
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  float dDistance = (this->distance[RIGHT_WHEEL] + this->distance[LEFT_WHEEL]) / 2.0f;
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  // TMP: Argument for the trigonometric functions
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  float trigArg = pPhi + dPhi / 2.0f;
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  // TMP: Trigonometric functions
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  float cosArg = cos(trigArg);
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  float sinArg = sin(trigArg);
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  // TMP: Delta distance
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  float dPX = dDistance * cosArg;
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  float dPY = dDistance * sinArg;
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  ////////////////
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  // Position Update
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  ////////////////
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  // Update distance
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  pX += dPX;
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  pY += dPY;
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  pPhi += dPhi;
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  ////////////////
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  // Temporary error calculations
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  ////////////////
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  // position propagation error (3x3 matrix)
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  float Fp3x3[9]  = {1.0f, 0.0f, -dPY,
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                     0.0f, 1.0f,  dPX,
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                     0.0f, 0.0f, 1.0f};
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  // steering error (2x2 matrix)
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  float Cs2x2[4] = {abs(this->distance[RIGHT_WHEEL])*wheelError[RIGHT_WHEEL],0.0f,
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                    0.0f, abs(this->distance[LEFT_WHEEL])*wheelError[LEFT_WHEEL]};
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  // steering propagation error (3x2 matrix)
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  float Fs3x2[6] = {(cosArg+dDistance*sinArg/this->wheelBaseDistanceSI)/2.0f, (sinArg+dDistance*cosArg/this->wheelBaseDistanceSI)/2.0f,
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                 (sinArg-dDistance*cosArg/this->wheelBaseDistanceSI)/2.0f, (cosArg-dDistance*sinArg/this->wheelBaseDistanceSI)/2.0f,
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                 -1.0f/this->wheelBaseDistanceSI                         , 1.0f/this->wheelBaseDistanceSI};
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  ////////////////
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  // Error calculations tmpCp = Fp*Cp*~Fp
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  ////////////////
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  // New position error
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  float tmpCp3x3[9] = {0.0f};
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  float tmpFpCp3x3[9] = {0.0f};
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  // tmpFpCp = Fp*Cp
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  Matrix::XdotY<float>(&(Fp3x3[0]),3,3,&(Cp3x3[0]),3,3,&(tmpFpCp3x3[0]),3,3);
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  // tmpCp = tmpFpCp*~Fp
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  Matrix::XdotYtrans<float>(&(tmpFpCp3x3[0]),3,3,&(Fp3x3[0]),3,3,&(tmpCp3x3[0]),3,3);
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  ////////////////
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  // Error calculations tmpCs = Fs*Cs*~Fs
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  ////////////////
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  // New steering error
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  float tmpCs3x3[9] = {0.0f};
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  float tmpFsCs3x2[6] = {0.0f};
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  // tmpFsCs = Fs*Cs
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  Matrix::XdotY<float>(&(Fs3x2[0]),3,2,&(Cs2x2[0]),2,2,&(tmpFsCs3x2[0]),3,2);
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  // tmpCs = tmpFsCs*~Fs
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  Matrix::XdotYtrans<float>(&(tmpFsCs3x2[0]),3,2,&(Fs3x2[0]),3,2,&(tmpCs3x3[0]),3,3);
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  ////////////////
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  // Error calculations Cp = Fp*Cp*~Fp + Fs*Cs*~Fs
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  ////////////////
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  Matrix::XplusY<float>(tmpCp3x3,3,3,tmpCs3x3,3,3,Cp3x3,3,3);
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  ////////////////
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  // Write back
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  ////////////////
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  // Write back
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  this->setPosition(pX,pY,pPhi);
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  chSysLock();
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    Matrix::copy<float>(Cp3x3,3,3,this->Cp3x3,3,3);
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  chSysUnlock();
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}
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void Odometry::updateWheelBaseDistance() {
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  this->wheelBaseDistanceSI = MotorControl::actualWheelBaseDistanceSI;
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}
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void Odometry::updateDistance() {
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  // Get the current increments of the QEI
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  MotorControl::updateIncrements(this->motorIncrements, this->increment, this->incrementDifference);
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//
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//  chprintf((BaseSequentialStream*) &global.sercanmux1, "\ni_right = %d \t i_left = %d", this->increment[RIGHT_WHEEL], this->increment[LEFT_WHEEL]);
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//  chprintf((BaseSequentialStream*) &global.sercanmux1, "\niDiff_right = %d \t iDiff_left = %d", this->incrementDifference[RIGHT_WHEEL], this->incrementDifference[LEFT_WHEEL]);
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  // Get the driven distance for each wheel
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  MotorControl::updateDistance(this->incrementDifference, this->distance);
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//  chprintf((BaseSequentialStream*) &global.sercanmux1, "\nx_right = %f \t x_left = %f", this->distance[RIGHT_WHEEL], this->distance[LEFT_WHEEL]);
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}