Nicolas Borla
/
BBR_1Ebene
BBR 1 Ebene
Diff: Motion.cpp
- Revision:
- 0:fbdae7e6d805
--- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/Motion.cpp Mon May 14 11:29:06 2018 +0000 @@ -0,0 +1,605 @@ +/* + * Motion.cpp + * Copyright (c) 2018, ZHAW + * All rights reserved. + */ + +#include <cmath> +#include <algorithm> +#include "Motion.h" + +using namespace std; + +const float Motion::DEFAULT_LIMIT = 1.0f; // default value for limits +const float Motion::MINIMUM_LIMIT = 1.0e-9f; // smallest value allowed for limits + +/** + * Creates a <code>Motion</code> object. + * The values for position, velocity and acceleration are set to 0. + */ +Motion::Motion() { + + position = 0.0; + velocity = 0.0f; + + profileVelocity = DEFAULT_LIMIT; + profileAcceleration = DEFAULT_LIMIT; + profileDeceleration = DEFAULT_LIMIT; +} + +/** + * Creates a <code>Motion</code> object with given values for position and velocity. + * @param position the initial position value of this motion, given in [m] or [rad]. + * @param velocity the initial velocity value of this motion, given in [m/s] or [rad/s]. + */ +Motion::Motion(double position, float velocity) { + + this->position = position; + this->velocity = velocity; + + profileVelocity = DEFAULT_LIMIT; + profileAcceleration = DEFAULT_LIMIT; + profileDeceleration = DEFAULT_LIMIT; +} + +/** + * Creates a <code>Motion</code> object with given values for position and velocity. + * @param motion another <code>Motion</code> object to copy the values from. + */ +Motion::Motion(const Motion& motion) { + + position = motion.position; + velocity = motion.velocity; + + profileVelocity = motion.profileVelocity; + profileAcceleration = motion.profileAcceleration; + profileDeceleration = motion.profileDeceleration; +} + +/** + * Deletes the Motion object. + */ +Motion::~Motion() {} + +/** + * Sets the values for position and velocity. + * @param position the desired position value of this motion, given in [m] or [rad]. + * @param velocity the desired velocity value of this motion, given in [m/s] or [rad/s]. + */ +void Motion::set(double position, float velocity) { + + this->position = position; + this->velocity = velocity; +} + +/** + * Sets the values for position and velocity. + * @param motion another <code>Motion</code> object to copy the values from. + */ +void Motion::set(const Motion& motion) { + + position = motion.position; + velocity = motion.velocity; +} + +/** + * Sets the position value. + * @param position the desired position value of this motion, given in [m] or [rad]. + */ +void Motion::setPosition(double position) { + + this->position = position; +} + +/** + * Gets the position value. + * @return the position value of this motion, given in [m] or [rad]. + */ +double Motion::getPosition() { + + return position; +} + +/** + * Sets the velocity value. + * @param velocity the desired velocity value of this motion, given in [m/s] or [rad/s]. + */ +void Motion::setVelocity(float velocity) { + + this->velocity = velocity; +} + +/** + * Gets the velocity value. + * @return the velocity value of this motion, given in [m/s] or [rad/s]. + */ +float Motion::getVelocity() { + + return velocity; +} + +/** + * Sets the limit for the velocity value. + * @param profileVelocity the limit of the velocity. + */ +void Motion::setProfileVelocity(float profileVelocity) { + + if (profileVelocity > MINIMUM_LIMIT) this->profileVelocity = profileVelocity; else this->profileVelocity = MINIMUM_LIMIT; +} + +/** + * Sets the limit for the acceleration value. + * @param profileAcceleration the limit of the acceleration. + */ +void Motion::setProfileAcceleration(float profileAcceleration) { + + if (profileAcceleration > MINIMUM_LIMIT) this->profileAcceleration = profileAcceleration; else this->profileAcceleration = MINIMUM_LIMIT; +} + +/** + * Sets the limit for the deceleration value. + * @param profileDeceleration the limit of the deceleration. + */ +void Motion::setProfileDeceleration(float profileDeceleration) { + + if (profileDeceleration > MINIMUM_LIMIT) this->profileDeceleration = profileDeceleration; else this->profileDeceleration = MINIMUM_LIMIT; +} + +/** + * Sets the limits for velocity, acceleration and deceleration values. + * @param profileVelocity the limit of the velocity. + * @param profileAcceleration the limit of the acceleration. + * @param profileDeceleration the limit of the deceleration. + */ +void Motion::setLimits(float profileVelocity, float profileAcceleration, float profileDeceleration) { + + if (profileVelocity > MINIMUM_LIMIT) this->profileVelocity = profileVelocity; else this->profileVelocity = MINIMUM_LIMIT; + if (profileAcceleration > MINIMUM_LIMIT) this->profileAcceleration = profileAcceleration; else this->profileAcceleration = MINIMUM_LIMIT; + if (profileDeceleration > MINIMUM_LIMIT) this->profileDeceleration = profileDeceleration; else this->profileDeceleration = MINIMUM_LIMIT; +} + +/** + * Gets the time needed to move to a given target position. + * @param targetPosition the desired target position given in [m] or [rad]. + * @return the time to move to the target position, given in [s]. + */ +float Motion::getTimeToPosition(double targetPosition) { + + // calculate position, when velocity is reduced to zero + + double stopPosition = (velocity > 0.0f) ? position+(double)(velocity*velocity/profileDeceleration*0.5f) : position-(double)(velocity*velocity/profileDeceleration*0.5f); + + if (targetPosition > stopPosition) { // positive velocity required + + if (velocity > profileVelocity) { // slow down to profile velocity first + + float t1 = (velocity-profileVelocity)/profileDeceleration; + float t2 = (float)(targetPosition-stopPosition)/profileVelocity; + float t3 = profileVelocity/profileDeceleration; + + return t1+t2+t3; + + } else if (velocity > 0.0f) { // speed up to profile velocity + + float t1 = (profileVelocity-velocity)/profileAcceleration; + float t3 = profileVelocity/profileDeceleration; + float t2 = ((float)(targetPosition-position)-(velocity+profileVelocity)*0.5f*t1)/profileVelocity-0.5f*t3; + + if (t2 < 0.0f) { + float maxVelocity = sqrt((2.0f*(float)(targetPosition-position)*profileAcceleration+velocity*velocity)*profileDeceleration/(profileAcceleration+profileDeceleration)); + t1 = (maxVelocity-velocity)/profileAcceleration; + t2 = 0.0f; + t3 = maxVelocity/profileDeceleration; + } + + return t1+t2+t3; + + } else { // slow down to zero first, and then speed up to profile velocity + + float t1 = -velocity/profileDeceleration; + float t2 = profileVelocity/profileAcceleration; + float t4 = profileVelocity/profileDeceleration; + float t3 = ((float)(targetPosition-position)-velocity*0.5f*t1)/profileVelocity-0.5f*(t2+t4); + + if (t3 < 0.0f) { + float maxVelocity = sqrt((2.0f*(float)(targetPosition-position)*profileDeceleration+velocity*velocity)*profileAcceleration/(profileAcceleration+profileDeceleration)); + t2 = maxVelocity/profileAcceleration; + t3 = 0.0f; + t4 = maxVelocity/profileDeceleration; + } + + return t1+t2+t3+t4; + } + + } else { // negative velocity required + + if (velocity < -profileVelocity) { // slow down to (negative) profile velocity first + + float t1 = (-profileVelocity-velocity)/profileDeceleration; + float t2 = (float)(stopPosition-targetPosition)/profileVelocity; + float t3 = profileVelocity/profileDeceleration; + + return t1+t2+t3; + + } else if (velocity < 0.0f) { // speed up to (negative) profile velocity + + float t1 = (velocity+profileVelocity)/profileAcceleration; + float t3 = profileVelocity/profileDeceleration; + float t2 = ((float)(position-targetPosition)+(velocity-profileVelocity)*0.5f*t1)/profileVelocity-0.5f*t3; + + if (t2 < 0.0f) { + float minVelocity = -sqrt((-2.0f*(float)(targetPosition-position)*profileAcceleration+velocity*velocity)*profileDeceleration/(profileAcceleration+profileDeceleration)); + t1 = (velocity-minVelocity)/profileAcceleration; + t2 = 0.0f; + t3 = -minVelocity/profileDeceleration; + } + + return t1+t2+t3; + + } else { // slow down to zero first, and then speed up to (negative) profile velocity + + float t1 = velocity/profileDeceleration; + float t2 = profileVelocity/profileAcceleration; + float t4 = profileVelocity/profileDeceleration; + float t3 = (-(float)(targetPosition-position)+velocity*0.5f*t1)/profileVelocity-0.5f*(t2+t4); + + if (t3 < 0.0f) { + float minVelocity = -sqrt((-2.0f*(float)(targetPosition-position)*profileDeceleration+velocity*velocity)*profileAcceleration/(profileAcceleration+profileDeceleration)); + t2 = -minVelocity/profileAcceleration; + t3 = 0.0f; + t4 = -minVelocity/profileDeceleration; + } + + return t1+t2+t3+t4; + } + } +} + +/** + * Increments the current motion towards a given target velocity. + * @param targetVelocity the desired target velocity given in [m/s] or [rad/s]. + * @param period the time period to increment the motion values for, given in [s]. + */ +void Motion::incrementToVelocity(float targetVelocity, float period) { + + if (targetVelocity < -profileVelocity) targetVelocity = -profileVelocity; + else if (targetVelocity > profileVelocity) targetVelocity = profileVelocity; + + if (targetVelocity > 0.0f) { + + if (velocity > targetVelocity) { // slow down to target velocity + + float t1 = (velocity-targetVelocity)/profileDeceleration; + + if (t1 > period) { + position += (double)((velocity-profileDeceleration*0.5f*period)*period); + velocity += -profileDeceleration*period; + } else { + position += (double)((velocity-profileDeceleration*0.5f*t1)*t1); + velocity += -profileDeceleration*t1; + position += (double)(velocity*(period-t1)); + } + + } else if (velocity > 0.0f) { // speed up to target velocity + + float t1 = (targetVelocity-velocity)/profileAcceleration; + + if (t1 > period) { + position += (double)((velocity+profileAcceleration*0.5f*period)*period); + velocity += profileAcceleration*period; + } else { + position += (double)((velocity+profileAcceleration*0.5f*t1)*t1); + velocity += profileAcceleration*t1; + position += (double)(velocity*(period-t1)); + } + + } else { // slow down to zero first, and then speed up to target velocity + + float t1 = -velocity/profileDeceleration; + float t2 = targetVelocity/profileAcceleration; + + if (t1 > period) { + position += (double)((velocity+profileDeceleration*0.5f*period)*period); + velocity += profileDeceleration*period; + } else if (t1+t2 > period) { + position += (double)((velocity+profileDeceleration*0.5f*t1)*t1); + velocity += profileDeceleration*t1; + position += (double)((velocity+profileAcceleration*0.5f*(period-t1))*(period-t1)); + velocity += profileAcceleration*(period-t1); + } else { + position += (double)((velocity+profileDeceleration*0.5f*t1)*t1); + velocity += profileDeceleration*t1; + position += (double)((velocity+profileAcceleration*0.5f*t2)*t2); + velocity += profileAcceleration*t2; + position += (double)(velocity*(period-t1-t2)); + } + } + + } else { + + if (velocity < targetVelocity) { // slow down to (negative) target velocity + + float t1 = (targetVelocity-velocity)/profileDeceleration; + + if (t1 > period) { + position += (double)((velocity+profileDeceleration*0.5f*period)*period); + velocity += profileDeceleration*period; + } else { + position += (double)((velocity+profileDeceleration*0.5f*t1)*t1); + velocity += profileDeceleration*t1; + position += (double)(velocity*(period-t1)); + } + + } else if (velocity < 0.0f) { // speed up to (negative) target velocity + + float t1 = (velocity-targetVelocity)/profileAcceleration; + + if (t1 > period) { + position += (double)((velocity-profileAcceleration*0.5f*period)*period); + velocity += -profileAcceleration*period; + } else { + position += (double)((velocity-profileAcceleration*0.5f*t1)*t1); + velocity += -profileAcceleration*t1; + position += (double)(velocity*(period-t1)); + } + + } else { // slow down to zero first, and then speed up to (negative) target velocity + + float t1 = velocity/profileDeceleration; + float t2 = -targetVelocity/profileAcceleration; + + if (t1 > period) { + position += (double)((velocity-profileDeceleration*0.5f*period)*period); + velocity += -profileDeceleration*period; + } else if (t1+t2 > period) { + position += (double)((velocity-profileDeceleration*0.5f*t1)*t1); + velocity += -profileDeceleration*t1; + position += (double)((velocity-profileAcceleration*0.5f*(period-t1))*(period-t1)); + velocity += -profileAcceleration*(period-t1); + } else { + position += (double)((velocity-profileDeceleration*0.5f*t1)*t1); + velocity += -profileDeceleration*t1; + position += (double)((velocity-profileAcceleration*0.5f*t2)*t2); + velocity += -profileAcceleration*t2; + position += (double)(velocity*(period-t1-t2)); + } + } + } +} + +/** + * Increments the current motion towards a given target position. + * @param targetPosition the desired target position given in [m] or [rad]. + * @param period the time period to increment the motion values for, given in [s]. + */ +void Motion::incrementToPosition(double targetPosition, float period) { + + // calculate position, when velocity is reduced to zero + + double stopPosition = (velocity > 0.0f) ? position+(double)(velocity*velocity/profileDeceleration*0.5f) : position-(double)(velocity*velocity/profileDeceleration*0.5f); + + if (targetPosition > stopPosition) { // positive velocity required + + if (velocity > profileVelocity) { // slow down to profile velocity first + + float t1 = (velocity-profileVelocity)/profileDeceleration; + float t2 = (float)(targetPosition-stopPosition)/profileVelocity; + float t3 = profileVelocity/profileDeceleration; + + if (t1 > period) { + position += (double)((velocity-profileDeceleration*0.5f*period)*period); + velocity += -profileDeceleration*period; + } else if (t1+t2 > period) { + position += (double)((velocity-profileDeceleration*0.5f*t1)*t1); + velocity += -profileDeceleration*t1; + position += (double)(velocity*(period-t1)); + } else if (t1+t2+t3 > period) { + position += (double)((velocity-profileDeceleration*0.5f*t1)*t1); + velocity += -profileDeceleration*t1; + position += (double)(velocity*t2); + position += (double)((velocity-profileDeceleration*0.5f*(period-t1-t2))*(period-t1-t2)); + velocity += -profileDeceleration*(period-t1-t2); + } else { + position += (double)((velocity-profileDeceleration*0.5f*t1)*t1); + velocity += -profileDeceleration*t1; + position += (double)(velocity*t2); + position += (double)((velocity-profileDeceleration*0.5f*t3)*t3); + velocity += -profileDeceleration*t3; + } + + } else if (velocity > 0.0f) { // speed up to profile velocity + + float t1 = (profileVelocity-velocity)/profileAcceleration; + float t3 = profileVelocity/profileDeceleration; + float t2 = ((float)(targetPosition-position)-(velocity+profileVelocity)*0.5f*t1)/profileVelocity-0.5f*t3; + + if (t2 < 0.0f) { + float maxVelocity = sqrt((2.0f*(float)(targetPosition-position)*profileAcceleration+velocity*velocity)*profileDeceleration/(profileAcceleration+profileDeceleration)); + t1 = (maxVelocity-velocity)/profileAcceleration; + t2 = 0.0f; + t3 = maxVelocity/profileDeceleration; + } + + if (t1 > period) { + position += (double)((velocity+profileAcceleration*0.5f*period)*period); + velocity += profileAcceleration*period; + } else if (t1+t2 > period) { + position += (double)((velocity+profileAcceleration*0.5f*t1)*t1); + velocity += profileAcceleration*t1; + position += (double)(velocity*(period-t1)); + } else if (t1+t2+t3 > period) { + position += (double)((velocity+profileAcceleration*0.5f*t1)*t1); + velocity += profileAcceleration*t1; + position += (double)(velocity*t2); + position += (double)((velocity-profileDeceleration*0.5f*(period-t1-t2))*(period-t1-t2)); + velocity += -profileDeceleration*(period-t1-t2); + } else { + position += (double)((velocity+profileAcceleration*0.5f*t1)*t1); + velocity += profileAcceleration*t1; + position += (double)(velocity*t2); + position += (double)((velocity-profileDeceleration*0.5f*t3)*t3); + velocity += -profileDeceleration*t3; + } + + } else { // slow down to zero first, and then speed up to profile velocity + + float t1 = -velocity/profileDeceleration; + float t2 = profileVelocity/profileAcceleration; + float t4 = profileVelocity/profileDeceleration; + float t3 = ((float)(targetPosition-position)-velocity*0.5f*t1)/profileVelocity-0.5f*(t2+t4); + + if (t3 < 0.0f) { + float maxVelocity = sqrt((2.0f*(float)(targetPosition-position)*profileDeceleration+velocity*velocity)*profileAcceleration/(profileAcceleration+profileDeceleration)); + t2 = maxVelocity/profileAcceleration; + t3 = 0.0f; + t4 = maxVelocity/profileDeceleration; + } + + if (t1 > period) { + position += (double)((velocity+profileDeceleration*0.5f*period)*period); + velocity += profileDeceleration*period; + } else if (t1+t2 > period) { + position += (double)((velocity+profileDeceleration*0.5f*t1)*t1); + velocity += profileDeceleration*t1; + position += (double)((velocity+profileAcceleration*0.5f*(period-t1))*(period-t1)); + velocity += profileAcceleration*(period-t1); + } else if (t1+t2+t3 > period) { + position += (double)((velocity+profileDeceleration*0.5f*t1)*t1); + velocity += profileDeceleration*t1; + position += (double)((velocity+profileAcceleration*0.5f*t2)*t2); + velocity += profileAcceleration*t2; + position += (double)(velocity*(period-t1-t2)); + } else if (t1+t2+t3+t4 > period) { + position += (double)((velocity+profileDeceleration*0.5f*t1)*t1); + velocity += profileDeceleration*t1; + position += (double)((velocity+profileAcceleration*0.5f*t2)*t2); + velocity += profileAcceleration*t2; + position += (double)(velocity*t3); + position += (double)((velocity-profileDeceleration*0.5f*(period-t1-t2-t3))*(period-t1-t2-t3)); + velocity += -profileDeceleration*(period-t1-t2-t3); + } else { + position += (double)((velocity+profileDeceleration*0.5f*t1)*t1); + velocity += profileDeceleration*t1; + position += (double)((velocity+profileAcceleration*0.5f*t2)*t2); + velocity += profileAcceleration*t2; + position += (double)(velocity*t3); + position += (double)((velocity-profileDeceleration*0.5f*t4)*t4); + velocity += -profileDeceleration*t4; + } + } + + } else { // negative velocity required + + if (velocity < -profileVelocity) { // slow down to (negative) profile velocity first + + float t1 = (-profileVelocity-velocity)/profileDeceleration; + float t2 = (float)(stopPosition-targetPosition)/profileVelocity; + float t3 = profileVelocity/profileDeceleration; + + if (t1 > period) { + position += (double)((velocity+profileDeceleration*0.5f*period)*period); + velocity += profileDeceleration*period; + } else if (t1+t2 > period) { + position += (double)((velocity+profileDeceleration*0.5f*t1)*t1); + velocity += profileDeceleration*t1; + position += (double)(velocity*(period-t1)); + } else if (t1+t2+t3 > period) { + position += (double)((velocity+profileDeceleration*0.5f*t1)*t1); + velocity += profileDeceleration*t1; + position += (double)(velocity*t2); + position += (double)((velocity+profileDeceleration*0.5f*(period-t1-t2))*(period-t1-t2)); + velocity += profileDeceleration*(period-t1-t2); + } else { + position += (double)((velocity+profileDeceleration*0.5f*t1)*t1); + velocity += profileDeceleration*t1; + position += (double)(velocity*t2); + position += (double)((velocity+profileDeceleration*0.5f*t3)*t3); + velocity += profileDeceleration*t3; + } + + } else if (velocity < 0.0f) { // speed up to (negative) profile velocity + + float t1 = (velocity+profileVelocity)/profileAcceleration; + float t3 = profileVelocity/profileDeceleration; + float t2 = ((float)(position-targetPosition)+(velocity-profileVelocity)*0.5f*t1)/profileVelocity-0.5f*t3; + + if (t2 < 0.0f) { + float minVelocity = -sqrt((-2.0f*(float)(targetPosition-position)*profileAcceleration+velocity*velocity)*profileDeceleration/(profileAcceleration+profileDeceleration)); + t1 = (velocity-minVelocity)/profileAcceleration; + t2 = 0.0f; + t3 = -minVelocity/profileDeceleration; + } + + if (t1 > period) { + position += (double)((velocity-profileAcceleration*0.5f*period)*period); + velocity += -profileAcceleration*period; + } else if (t1+t2 > period) { + position += (double)((velocity-profileAcceleration*0.5f*t1)*t1); + velocity += -profileAcceleration*t1; + position += (double)(velocity*(period-t1)); + } else if (t1+t2+t3 > period) { + position += (double)((velocity-profileAcceleration*0.5f*t1)*t1); + velocity += -profileAcceleration*t1; + position += (double)(velocity*t2); + position += (double)((velocity+profileDeceleration*0.5f*(period-t1-t2))*(period-t1-t2)); + velocity += profileDeceleration*(period-t1-t2); + } else { + position += (double)((velocity-profileAcceleration*0.5f*t1)*t1); + velocity += -profileAcceleration*t1; + position += (double)(velocity*t2); + position += (double)((velocity+profileDeceleration*0.5f*t3)*t3); + velocity += profileDeceleration*t3; + } + + } else { // slow down to zero first, and then speed up to (negative) profile velocity + + float t1 = velocity/profileDeceleration; + float t2 = profileVelocity/profileAcceleration; + float t4 = profileVelocity/profileDeceleration; + float t3 = (-(float)(targetPosition-position)+velocity*0.5f*t1)/profileVelocity-0.5f*(t2+t4); + + if (t3 < 0.0f) { + float minVelocity = -sqrt((-2.0f*(float)(targetPosition-position)*profileDeceleration+velocity*velocity)*profileAcceleration/(profileAcceleration+profileDeceleration)); + t2 = -minVelocity/profileAcceleration; + t3 = 0.0f; + t4 = -minVelocity/profileDeceleration; + } + + if (t1 > period) { + position += (double)((velocity-profileDeceleration*0.5f*period)*period); + velocity += -profileDeceleration*period; + } else if (t1+t2 > period) { + position += (double)((velocity-profileDeceleration*0.5f*t1)*t1); + velocity += -profileDeceleration*t1; + position += (double)((velocity-profileAcceleration*0.5f*(period-t1))*(period-t1)); + velocity += -profileAcceleration*(period-t1); + } else if (t1+t2+t3 > period) { + position += (double)((velocity-profileDeceleration*0.5f*t1)*t1); + velocity += -profileDeceleration*t1; + position += (double)((velocity-profileAcceleration*0.5f*t2)*t2); + velocity += -profileAcceleration*t2; + position += (double)(velocity*(period-t1-t2)); + } else if (t1+t2+t3+t4 > period) { + position += (double)((velocity-profileDeceleration*0.5f*t1)*t1); + velocity += -profileDeceleration*t1; + position += (double)((velocity-profileAcceleration*0.5f*t2)*t2); + velocity += -profileAcceleration*t2; + position += (double)(velocity*t3); + position += (double)((velocity+profileDeceleration*0.5f*(period-t1-t2-t3))*(period-t1-t2-t3)); + velocity += profileDeceleration*(period-t1-t2-t3); + } else { + position += (double)((velocity-profileDeceleration*0.5f*t1)*t1); + velocity += -profileDeceleration*t1; + position += (double)((velocity-profileAcceleration*0.5f*t2)*t2); + velocity += -profileAcceleration*t2; + position += (double)(velocity*t3); + position += (double)((velocity+profileDeceleration*0.5f*t4)*t4); + velocity += profileDeceleration*t4; + } + } + } +} + + + +