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amiro-os / components / DistControl.cpp @ b8085493

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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/DistControl.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 types;
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using namespace constants;
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using namespace constants::DiWheelDrive;
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extern Global global;
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DistControl::DistControl(MotorControl* mc, MotorIncrements* mi)
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    : BaseStaticThread<256>(),
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      motorControl(mc),
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      motorIncrements(mi),
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      period(10)
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       {
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  // initialize velocities
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  this->maxVelocity.y = 0;
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  this->maxVelocity.z = 0;
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  this->maxVelocity.w_x = 0;
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  this->maxVelocity.w_y = 0;
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  this->targetVelocity.x = 0;
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  this->targetVelocity.y = 0;
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  this->targetVelocity.z = 0;
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  this->targetVelocity.w_x = 0;
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  this->targetVelocity.w_y = 0;
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  this->targetVelocity.w_z = 0;
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  this->minVelocity.y = 0;
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  this->minVelocity.z = 0;
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  this->minVelocity.w_x = 0;
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  this->minVelocity.w_y = 0;
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  this->minVelocity.w_z = 0;
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  // set max and min velocities
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  this->maxVelocity.x = 0.15 * 1e6; // 15 cm/s
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  this->minVelocity.x = 0.02 * 1e6; // 2 cm/s
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  this->maxVelocity.w_z = 2*maxVelocity.x / MotorControl::actualWheelBaseDistanceSI;
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  this->minVelocity.w_z = 2*minVelocity.x / MotorControl::actualWheelBaseDistanceSI;
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}
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int DistControl::getCurrentTargetDist() {
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  return (int)(targetDistance*1e6);
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}
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int DistControl::getCurrentTargetAngle() {
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  return (int)(targetAngle*1e6);
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}
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void DistControl::setTargetPosition(int32_t distance, int32_t angle, uint16_t time) {
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  chSysLock();
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  targetDistance = distance; // um
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  drivingForward = distance > 0;
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  if (!drivingForward) {
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    targetDistance *= -1;
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  }
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  targetAngle = angle; // urad
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  turningLeft = angle > 0;
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  if (!turningLeft) {
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    targetAngle *= -1;
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  }
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  restTime = time * 1e3; // us
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  controllerActive = true;
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  chSysUnlock();
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  fullDistance[LEFT_WHEEL] = 0;
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  fullDistance[RIGHT_WHEEL] = 0;
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  motorControl->updateIncrements(motorIncrements, increment, incrementDifference);
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}
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bool DistControl::isActive(void) {
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  return controllerActive;
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}
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void DistControl::deactivateController(void) {
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  chSysLock();
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  controllerActive = false;
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  targetDistance = 0;
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  targetAngle = 0;
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  restTime = 0;
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  for (int idx=0; idx < 2; idx++) {
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    increment[idx] = 0;
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    incrementDifference[idx] = 0;
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    actualDistance[idx] = 0;
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    fullDistance[idx] = 0;
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  }
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  chSysUnlock();
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}
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msg_t DistControl::main(void) {
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  systime_t time = System::getTime();
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  systime_t printTime = time;
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  this->setName("DistControl");
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  DistControl::deactivateController();
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  while (!this->shouldTerminate()) {
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    time += MS2ST(this->period);
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    if (controllerActive) {
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      // get increment differences for each wheel
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      motorControl->updateIncrements(motorIncrements, increment, incrementDifference); // ticks
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      // calculate driven distance difference for each wheel
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      motorControl->updateDistance(incrementDifference, actualDistance); // m
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      // calculate full driven distance for each wheel
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      for (int idxWheel = 0; idxWheel < 2; idxWheel++) {
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        fullDistance[idxWheel] += (int32_t)(actualDistance[idxWheel]*1e6);
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      }
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      // calculate whole driven distance and angle
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      realDistance = (fullDistance[LEFT_WHEEL] + fullDistance[RIGHT_WHEEL]) / 2.0; // um
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      if (!drivingForward) {
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        realDistance *= -1;
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      }
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      realAngle = (fullDistance[RIGHT_WHEEL] - fullDistance[LEFT_WHEEL]) / MotorControl::actualWheelBaseDistanceSI; // urad
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      if (!turningLeft) {
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        realAngle *= -1;
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      }
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      // calculate distance and angle to drive
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      errorDistance = targetDistance - realDistance; // um
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      if (errorDistance < 0) {
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        errorDistance = 0;
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      }
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      errorAngle = targetAngle - realAngle; // urad
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      if (errorAngle < 0) {
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        errorAngle = 0;
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      }
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      // calculate velocities for motor control
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      DistControl::calcVelocities();
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      if (controllerActive && newVelocities) {
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        // set target velocities
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        this->motorControl->setTargetSpeed(targetVelocity);
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        newVelocities = false;
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      }
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/*
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      if (time-printTime > MS2ST(100)) {
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        chprintf((BaseSequentialStream*) &global.sercanmux1, "dist = %i um, angle = %i urad, ed = %i um, ea = %i, v = %i um/s, w = %i urad/s\n", realDistance, realAngle, errorDistance, errorAngle, targetVelocity.x, targetVelocity.w_z);
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        printTime = time;
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      }
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*/
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      // reduce rest time (us)
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      restTime -= period*1e3;
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      if (restTime < 1) {
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        restTime = 1;
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      }
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      // deactivate controller if necessary
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      if (errorDistance == 0 && errorAngle == 0) {
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        deactivateController();
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      }
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    }
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    chThdSleepUntil(time);
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  }
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  return true;
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}
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void DistControl::calcVelocities(void) {
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  // TODO calculate target velocities better
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  // set intuitive velocities
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  int32_t forwardSpeed = (int32_t) (errorDistance * 1e6 / (1.0f*restTime)); // um/s
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  int32_t angleSpeed = (int32_t) (errorAngle * 1e6 / (1.0f*restTime)); // urad/s
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  int32_t maxForward = maxVelocity.x;
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  if (maxForward > errorDistance) {
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    maxForward = errorDistance;
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  }
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  int32_t maxTurn = maxVelocity.w_z;
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  if (maxTurn > errorAngle) {
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    maxTurn = errorAngle;
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  }
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  // check max forward speed
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  if (forwardSpeed > maxForward) {
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    forwardSpeed = maxForward;
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    angleSpeed = (int32_t) (forwardSpeed * ((1.0f*errorAngle) / (1.0f*errorDistance)));
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  }
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  // check max angle speed
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  if (angleSpeed > maxTurn) {
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    angleSpeed = maxTurn;
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    forwardSpeed = (int32_t) (angleSpeed * ((1.0f*errorDistance) / (1.0f*errorAngle)));
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  }
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  // check for too small speeds
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  if (errorDistance > 0 && forwardSpeed < minVelocity.x) {
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    forwardSpeed = minVelocity.x;
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  }
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  if (errorAngle > 0 && errorDistance == 0 && angleSpeed < minVelocity.w_z) {
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    angleSpeed = minVelocity.w_z;
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  }
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  // set velocity directions
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  if (!drivingForward) {
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    forwardSpeed *= -1;
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  }
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  if (!turningLeft) {
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    angleSpeed *= -1;
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  }
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  // if nessecary set new target velocities
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  if (forwardSpeed != targetVelocity.x || angleSpeed != targetVelocity.w_z) {
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    newVelocities = true;
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    targetVelocity.x = forwardSpeed;
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    targetVelocity.w_z = angleSpeed;
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  }
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}