/* * Copyright (c) Contributors, http://opensimulator.org/ * See CONTRIBUTORS.TXT for a full list of copyright holders. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * Neither the name of the OpenSimulator Project nor the * names of its contributors may be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE DEVELOPERS ``AS IS'' AND ANY * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE CONTRIBUTORS BE LIABLE FOR ANY * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * */ using System; using System.Collections.Generic; using System.Text; using OpenMetaverse; using OpenSim.Framework; namespace OpenSim.Region.PhysicsModule.BulletS { public abstract class BSMotor { // Timescales and other things can be turned off by setting them to 'infinite'. public const float Infinite = 12345.6f; public readonly static Vector3 InfiniteVector = new Vector3(BSMotor.Infinite, BSMotor.Infinite, BSMotor.Infinite); public BSMotor(string useName) { UseName = useName; PhysicsScene = null; Enabled = true; } public virtual bool Enabled { get; set; } public virtual void Reset() { } public virtual void Zero() { } public virtual void GenerateTestOutput(float timeStep) { } // A name passed at motor creation for easily identifyable debugging messages. public string UseName { get; private set; } // Used only for outputting debug information. Might not be set so check for null. public BSScene PhysicsScene { get; set; } protected void MDetailLog(string msg, params Object[] parms) { if (PhysicsScene != null) { PhysicsScene.DetailLog(msg, parms); } } } // Motor which moves CurrentValue to TargetValue over TimeScale seconds. // The TargetValue decays in TargetValueDecayTimeScale. // This motor will "zero itself" over time in that the targetValue will // decay to zero and the currentValue will follow it to that zero. // The overall effect is for the returned correction value to go from large // values to small and eventually zero values. // TimeScale and TargetDelayTimeScale may be 'infinite' which means no decay. // For instance, if something is moving at speed X and the desired speed is Y, // CurrentValue is X and TargetValue is Y. As the motor is stepped, new // values of CurrentValue are returned that approach the TargetValue. // The feature of decaying TargetValue is so vehicles will eventually // come to a stop rather than run forever. This can be disabled by // setting TargetValueDecayTimescale to 'infinite'. // The change from CurrentValue to TargetValue is linear over TimeScale seconds. public class BSVMotor : BSMotor { // public Vector3 FrameOfReference { get; set; } // public Vector3 Offset { get; set; } public virtual float TimeScale { get; set; } public virtual float TargetValueDecayTimeScale { get; set; } public virtual float Efficiency { get; set; } public virtual float ErrorZeroThreshold { get; set; } public virtual Vector3 TargetValue { get; protected set; } public virtual Vector3 CurrentValue { get; protected set; } public virtual Vector3 LastError { get; protected set; } public virtual bool ErrorIsZero() { return ErrorIsZero(LastError); } public virtual bool ErrorIsZero(Vector3 err) { return err.ApproxZero(ErrorZeroThreshold); } public BSVMotor(string useName) : base(useName) { TimeScale = TargetValueDecayTimeScale = BSMotor.Infinite; Efficiency = 1f; CurrentValue = TargetValue = Vector3.Zero; ErrorZeroThreshold = 0.001f; } public BSVMotor(string useName, float timeScale, float decayTimeScale, float efficiency) : this(useName) { TimeScale = timeScale; TargetValueDecayTimeScale = decayTimeScale; Efficiency = efficiency; CurrentValue = TargetValue = Vector3.Zero; } public void SetCurrent(Vector3 current) { CurrentValue = current; } public void SetTarget(Vector3 target) { TargetValue = target; } public override void Zero() { base.Zero(); CurrentValue = TargetValue = Vector3.Zero; } // Compute the next step and return the new current value. // Returns the correction needed to move 'current' to 'target'. public virtual Vector3 Step(float timeStep) { if (!Enabled) return TargetValue; Vector3 origTarget = TargetValue; // DEBUG Vector3 origCurrVal = CurrentValue; // DEBUG Vector3 correction = Vector3.Zero; Vector3 error = TargetValue - CurrentValue; if (!ErrorIsZero(error)) { correction = StepError(timeStep, error); CurrentValue += correction; // The desired value reduces to zero which also reduces the difference with current. // If the decay time is infinite, don't decay at all. float decayFactor = 0f; if (TargetValueDecayTimeScale != BSMotor.Infinite) { decayFactor = (1.0f / TargetValueDecayTimeScale) * timeStep; TargetValue *= (1f - decayFactor); } MDetailLog("{0}, BSVMotor.Step,nonZero,{1},origCurr={2},origTarget={3},timeStep={4},err={5},corr={6}", BSScene.DetailLogZero, UseName, origCurrVal, origTarget, timeStep, error, correction); MDetailLog("{0}, BSVMotor.Step,nonZero,{1},tgtDecayTS={2},decayFact={3},tgt={4},curr={5}", BSScene.DetailLogZero, UseName, TargetValueDecayTimeScale, decayFactor, TargetValue, CurrentValue); } else { // Difference between what we have and target is small. Motor is done. if (TargetValue.ApproxEquals(Vector3.Zero, ErrorZeroThreshold)) { // The target can step down to nearly zero but not get there. If close to zero // it is really zero. TargetValue = Vector3.Zero; } CurrentValue = TargetValue; MDetailLog("{0}, BSVMotor.Step,zero,{1},origTgt={2},origCurr={3},currTgt={4},currCurr={5}", BSScene.DetailLogZero, UseName, origCurrVal, origTarget, TargetValue, CurrentValue); } LastError = error; return correction; } // version of step that sets the current value before doing the step public virtual Vector3 Step(float timeStep, Vector3 current) { CurrentValue = current; return Step(timeStep); } // Given and error, computer a correction for this step. // Simple scaling of the error by the timestep. public virtual Vector3 StepError(float timeStep, Vector3 error) { if (!Enabled) return Vector3.Zero; Vector3 returnCorrection = Vector3.Zero; if (!ErrorIsZero(error)) { // correction = error / secondsItShouldTakeToCorrect Vector3 correctionAmount; if (TimeScale == 0f || TimeScale == BSMotor.Infinite) correctionAmount = error * timeStep; else correctionAmount = error / TimeScale * timeStep; returnCorrection = correctionAmount; MDetailLog("{0}, BSVMotor.Step,nonZero,{1},timeStep={2},timeScale={3},err={4},corr={5}", BSScene.DetailLogZero, UseName, timeStep, TimeScale, error, correctionAmount); } return returnCorrection; } // The user sets all the parameters and calls this which outputs values until error is zero. public override void GenerateTestOutput(float timeStep) { // maximum number of outputs to generate. int maxOutput = 50; MDetailLog("{0},BSVMotor.Test,{1},===================================== BEGIN Test Output", BSScene.DetailLogZero, UseName); MDetailLog("{0},BSVMotor.Test,{1},timeScale={2},targDlyTS={3},eff={4},curr={5},tgt={6}", BSScene.DetailLogZero, UseName, TimeScale, TargetValueDecayTimeScale, Efficiency, CurrentValue, TargetValue); LastError = BSMotor.InfiniteVector; while (maxOutput-- > 0 && !ErrorIsZero()) { Vector3 lastStep = Step(timeStep); MDetailLog("{0},BSVMotor.Test,{1},cur={2},tgt={3},lastError={4},lastStep={5}", BSScene.DetailLogZero, UseName, CurrentValue, TargetValue, LastError, lastStep); } MDetailLog("{0},BSVMotor.Test,{1},===================================== END Test Output", BSScene.DetailLogZero, UseName); } public override string ToString() { return String.Format("<{0},curr={1},targ={2},lastErr={3},decayTS={4}>", UseName, CurrentValue, TargetValue, LastError, TargetValueDecayTimeScale); } } // ============================================================================ // ============================================================================ public class BSFMotor : BSMotor { public virtual float TimeScale { get; set; } public virtual float TargetValueDecayTimeScale { get; set; } public virtual float Efficiency { get; set; } public virtual float ErrorZeroThreshold { get; set; } public virtual float TargetValue { get; protected set; } public virtual float CurrentValue { get; protected set; } public virtual float LastError { get; protected set; } public virtual bool ErrorIsZero() { return ErrorIsZero(LastError); } public virtual bool ErrorIsZero(float err) { return (err >= -ErrorZeroThreshold && err <= ErrorZeroThreshold); } public BSFMotor(string useName, float timeScale, float decayTimescale, float efficiency) : base(useName) { TimeScale = TargetValueDecayTimeScale = BSMotor.Infinite; Efficiency = 1f; CurrentValue = TargetValue = 0f; ErrorZeroThreshold = 0.01f; } public void SetCurrent(float current) { CurrentValue = current; } public void SetTarget(float target) { TargetValue = target; } public override void Zero() { base.Zero(); CurrentValue = TargetValue = 0f; } public virtual float Step(float timeStep) { if (!Enabled) return TargetValue; float origTarget = TargetValue; // DEBUG float origCurrVal = CurrentValue; // DEBUG float correction = 0f; float error = TargetValue - CurrentValue; if (!ErrorIsZero(error)) { correction = StepError(timeStep, error); CurrentValue += correction; // The desired value reduces to zero which also reduces the difference with current. // If the decay time is infinite, don't decay at all. float decayFactor = 0f; if (TargetValueDecayTimeScale != BSMotor.Infinite) { decayFactor = (1.0f / TargetValueDecayTimeScale) * timeStep; TargetValue *= (1f - decayFactor); } MDetailLog("{0}, BSFMotor.Step,nonZero,{1},origCurr={2},origTarget={3},timeStep={4},err={5},corr={6}", BSScene.DetailLogZero, UseName, origCurrVal, origTarget, timeStep, error, correction); MDetailLog("{0}, BSFMotor.Step,nonZero,{1},tgtDecayTS={2},decayFact={3},tgt={4},curr={5}", BSScene.DetailLogZero, UseName, TargetValueDecayTimeScale, decayFactor, TargetValue, CurrentValue); } else { // Difference between what we have and target is small. Motor is done. if (Util.InRange(TargetValue, -ErrorZeroThreshold, ErrorZeroThreshold)) { // The target can step down to nearly zero but not get there. If close to zero // it is really zero. TargetValue = 0f; } CurrentValue = TargetValue; MDetailLog("{0}, BSFMotor.Step,zero,{1},origTgt={2},origCurr={3},ret={4}", BSScene.DetailLogZero, UseName, origCurrVal, origTarget, CurrentValue); } LastError = error; return CurrentValue; } public virtual float StepError(float timeStep, float error) { if (!Enabled) return 0f; float returnCorrection = 0f; if (!ErrorIsZero(error)) { // correction = error / secondsItShouldTakeToCorrect float correctionAmount; if (TimeScale == 0f || TimeScale == BSMotor.Infinite) correctionAmount = error * timeStep; else correctionAmount = error / TimeScale * timeStep; returnCorrection = correctionAmount; MDetailLog("{0}, BSFMotor.Step,nonZero,{1},timeStep={2},timeScale={3},err={4},corr={5}", BSScene.DetailLogZero, UseName, timeStep, TimeScale, error, correctionAmount); } return returnCorrection; } public override string ToString() { return String.Format("<{0},curr={1},targ={2},lastErr={3},decayTS={4}>", UseName, CurrentValue, TargetValue, LastError, TargetValueDecayTimeScale); } } // ============================================================================ // ============================================================================ // Proportional, Integral, Derivitive ("PID") Motor // Good description at http://www.answers.com/topic/pid-controller . Includes processes for choosing p, i and d factors. public class BSPIDVMotor : BSVMotor { // Larger makes more overshoot, smaller means converge quicker. Range of 0.1 to 10. public Vector3 proportionFactor { get; set; } public Vector3 integralFactor { get; set; } public Vector3 derivFactor { get; set; } // The factors are vectors for the three dimensions. This is the proportional of each // that is applied. This could be multiplied through the actual factors but it // is sometimes easier to manipulate the factors and their mix separately. public Vector3 FactorMix; // Arbritrary factor range. // EfficiencyHigh means move quickly to the correct number. EfficiencyLow means might over correct. public float EfficiencyHigh = 0.4f; public float EfficiencyLow = 4.0f; // Running integration of the error Vector3 RunningIntegration { get; set; } public BSPIDVMotor(string useName) : base(useName) { proportionFactor = new Vector3(1.00f, 1.00f, 1.00f); integralFactor = new Vector3(1.00f, 1.00f, 1.00f); derivFactor = new Vector3(1.00f, 1.00f, 1.00f); FactorMix = new Vector3(0.5f, 0.25f, 0.25f); RunningIntegration = Vector3.Zero; LastError = Vector3.Zero; } public override void Zero() { base.Zero(); } public override float Efficiency { get { return base.Efficiency; } set { base.Efficiency = Util.Clamp(value, 0f, 1f); // Compute factors based on efficiency. // If efficiency is high (1f), use a factor value that moves the error value to zero with little overshoot. // If efficiency is low (0f), use a factor value that overcorrects. // TODO: might want to vary contribution of different factor depending on efficiency. // float factor = ((1f - this.Efficiency) * EfficiencyHigh + EfficiencyLow) / 3f; float factor = (1f - this.Efficiency) * EfficiencyHigh + EfficiencyLow; proportionFactor = new Vector3(factor, factor, factor); integralFactor = new Vector3(factor, factor, factor); derivFactor = new Vector3(factor, factor, factor); MDetailLog("{0}, BSPIDVMotor.setEfficiency,eff={1},factor={2}", BSScene.DetailLogZero, Efficiency, factor); } } // Advance the PID computation on this error. public override Vector3 StepError(float timeStep, Vector3 error) { if (!Enabled) return Vector3.Zero; // Add up the error so we can integrate over the accumulated errors RunningIntegration += error * timeStep; // A simple derivitive is the rate of change from the last error. Vector3 derivitive = (error - LastError) * timeStep; // Correction = (proportionOfPresentError + accumulationOfPastError + rateOfChangeOfError) Vector3 ret = error / TimeScale * timeStep * proportionFactor * FactorMix.X + RunningIntegration / TimeScale * integralFactor * FactorMix.Y + derivitive / TimeScale * derivFactor * FactorMix.Z ; MDetailLog("{0}, BSPIDVMotor.step,ts={1},err={2},lerr={3},runnInt={4},deriv={5},ret={6}", BSScene.DetailLogZero, timeStep, error, LastError, RunningIntegration, derivitive, ret); return ret; } } }