mirror of
https://github.com/RobotechLille/cdf2018-principal
synced 2024-11-14 12:26:06 +01:00
374 lines
10 KiB
Matlab
374 lines
10 KiB
Matlab
global SIMULATION;
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SIMULATION = 0;
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% Paramètres de lecture
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DIRNAME = "/home/geoffrey/CdF/cdf2018-principal/log/";
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FILENAME = "000232.csv";
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PATH = DIRNAME + FILENAME;
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% Paramètres de simulation
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global SIMULATION_TIME SIMULATION_DT;
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SIMULATION_TIME = 10;
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SIMULATION_DT = 1e-6;
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%BEGIN DIMENSIONS
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% Dimensions pistes
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global pisteWidth pisteHeight pisteOrigX pisteOrigY;
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pisteWidth = 3000.0;
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pisteHeight = 2000.0;
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pisteOrigX = 0.0;
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pisteOrigY = 0.0;
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% Dimensions robot
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global width height distanceBetweenWheels wheelDiameter wheelPerimeter motorSpeedGainRPMpV motorSpeedGain motorNominalTension motorControllerAlimentation motorControllerReference motorSaturationMin motorSaturationMax pwmMax coderResolution coderDataFactor coderDataResolution cranReducOut cranReducIn reducRatio coderFullResolution avPerCycle;
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width = 250.0; % mm (from meca)
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height = 100.0; % mm (from random)
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distanceBetweenWheels = width; % mm (from meca)
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wheelDiameter = 80.0; % mm (from meca)
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wheelPerimeter = (wheelDiameter * pi); % mm
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motorSpeedGainRPMpV = 233.0; % rpm/V (from datasheet)
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motorSpeedGain = (motorSpeedGainRPMpV / 60.0); % motor rev/s/V
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motorNominalTension = 24.0; % V (from datasheet)
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motorControllerAlimentation = 24.0; % V (from elec)
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motorControllerReference = 5; % V (from wiring)
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motorSaturationMin = 0.1; % V (from random)
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motorSaturationMax = 12.0; % V (from testing)
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pwmMax = 3.3; % V (from FPGA datasheet)
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coderResolution = 370.0; % cycles/motor rev
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coderDataFactor = 4.0; % increments/motor cycles
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coderDataResolution = (coderResolution * coderDataFactor); % cycles/motor rev
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cranReducOut = 48.0; % nb crans (from meca)
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cranReducIn = 12.0; % nb crans (from meca)
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reducRatio = (cranReducIn / cranReducOut); % reduction ratio
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coderFullResolution = (coderDataResolution / reducRatio); % cycles / wheel rev
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avPerCycle = (wheelPerimeter / coderFullResolution); % mm
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% Constantes asservissement
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global dDirEcartMin dDirEcartMax oDirEcartMin oDirEcartMax oGain;
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dDirEcartMin = 1.0; % mm
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dDirEcartMax = 5.0; % mm
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oDirEcartMin = (2.5 / 360.0 * 2.0 * pi); % rad
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oDirEcartMax = (7.5 / 360.0 * 2.0 * pi); % rad
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oGain = 1;
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P = 2;
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I = 0;
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D = 0;
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%END DIMENSIONS
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global s;
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if SIMULATION == 1
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% Génération de la consigne
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xinit = 50;
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yinit = 50;
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oinit = 4 * pi;
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d1t = 2;
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d1x = 300;
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d1y = -300;
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d1o = 2 * pi;
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dt = SIMULATION_DT;
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global xcons ycons ocons;
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xcons = timeseries([xinit, xinit, d1x, d1x], [0 d1t-dt d1t SIMULATION_TIME]);
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ycons = timeseries([yinit, yinit, d1y, d1y], [0 d1t-dt d1t SIMULATION_TIME]);
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ocons = timeseries([oinit, oinit, d1o, d1o], [0 d1t-dt d1t SIMULATION_TIME]);
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% Simulation
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disp("Lancement de la simulation");
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s = sim("modelisation", "StopTime", string(SIMULATION_TIME));%, "MinStep", string(SIMULATION_DT));
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fprintf("Simulation sampling rate: %f Hz\n", length(s.tout)/SIMULATION_TIME);
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else
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disp("Ouverture des données");
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T = readtable(PATH);
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% Données pratiques → données théoriques
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T.time(1) = 0;
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T.x = T.xConnu;
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T.y = T.yConnu;
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T.o = T.oConnu;
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%T.lVolt = T.lCodTot;
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%T.rVolt = T.rCodTot;
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disp("Enregistrement des données");
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s = containers.Map;
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for name=T.Properties.VariableNames
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nameChar = char(name);
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s(nameChar) = timeseries(T.(nameChar), T.time);
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end
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% Modification pour faire passer comme une simu
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td = getTimePoints();
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SIMULATION_TIME = td(end);
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end
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% Graphes
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clf
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global p;
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% Évolution spatiale
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subplot(2, 2, 1);
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initGraph
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updateToTime(SIMULATION_DT);
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% Roues
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p = subplot(2, 2, 2);
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hold on;
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timeGraph(["lVolt", "rVolt", "lErr", "rErr"]);
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addLimitline(p, motorNominalTension);
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addLimitline(p, -motorNominalTension);
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addLimitline(p, 0);
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title("Roues");
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xlabel("Temps (s)");
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ylabel("Tension (V)");
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legend("Gauche", "Droite", "Err. gauche", "Err. droite");
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% Distance
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p = subplot(2, 2, 3);
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hold on;
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timeGraph(["dDirEcart", "dErr"]);
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addLimitline(p, dDirEcartMin);
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addLimitline(p, dDirEcartMax);
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title("Distance");
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xlabel("Temps (s)");
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ylabel("Distance (mm)");
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legend("Ecart direction", "Err. retenue");
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% Rotation
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p = subplot(2, 2, 4);
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hold on;
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timeGraph(["oDirEcart", "oEcart", "oErr"]);
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addLimitline(p, oDirEcartMax);
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addLimitline(p, oDirEcartMin);
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addLimitline(p, -oDirEcartMax);
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addLimitline(p, -oDirEcartMin);
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title("Rotation");
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xlabel("Temps (s)");
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ylabel("Angle (rad)");
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legend("Ecart direction", "Ecart orientation", "Err. retenue");
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% Fonctions
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function ts = getTS(name)
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global SIMULATION s;
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if SIMULATION == 1
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ts = s.(name);
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else
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name = char(name);
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if s.isKey(name)
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ts = s(name);
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else
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fprintf("Données inconnues : %s\n", name);
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ts = timeseries();
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end
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end
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end
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function pt = getTimePoints()
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global SIMULATION s;
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if SIMULATION == 1
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pt = s.tout;
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else
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ts = getTS('time');
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pt = ts.Time;
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end
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end
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function timeGraph(series)
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global SIMULATION_TIME p;
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m = inf;
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M = -inf;
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for sname=series
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serie = getTS(sname);
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plot(serie);
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if ~isempty(serie.Data)
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m = min(m, min(serie));
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end
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if ~isempty(serie.Data)
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M = max(M, max(serie));
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end
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end
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xlim([0 SIMULATION_TIME]);
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if (abs(m) ~= inf) && (abs(M) ~= inf)
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ylim([m M]);
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end
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addTimeline(p);
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end
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function addLimitline(p, x)
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line(p.XLim, [x x], 'Color', [0.8 0.8 0.8]);
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end
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function addTimeline(p)
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global t timelines;
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timeline = line([t t], p.YLim, 'Color', [0 0 0]);
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timelines = [timelines timeline];
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end
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function play()
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global SIMULATION_TIME speed t playing;
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if playing == 1
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return
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end
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startCpu=cputime;
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startT=t;
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n=0;
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playing=1;
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while t<SIMULATION_TIME && playing == 1
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updateToTime((cputime-startCpu)*speed + startT);
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drawnow limitrate;
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n = n + 1;
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end
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playing=0;
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fprintf("Refresh rate : %f Hz\n", n/(cputime-startCpu));
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end
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function sliderCallback(hObject, ~)
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updateToTime(get(hObject, 'Value'));
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end
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function playCallback(~, ~)
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play();
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end
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function pauseCallback(~, ~)
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global playing;
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playing=0;
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end
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function [x, y] = pointArround(xC, yC, xD, yD, o)
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D = xD + yD * 1i;
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F = abs(D) .* exp(1i * (angle(D) + o - pi/2));
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x = xC + real(F);
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y = yC + imag(F);
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end
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function drawRect(p, x, y, o, w, h)
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[x1, y1] = pointArround(x, y, - w/2, + h/2, o);
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[x2, y2] = pointArround(x, y, + w/2, + h/2, o);
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[x3, y3] = pointArround(x, y, + w/2, - h/2, o);
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[x4, y4] = pointArround(x, y, - w/2, - h/2, o);
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p.XData = [x1, x2, x3, x4, x1];
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p.YData = [y1, y2, y3, y4, y1];
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end
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function initGraph()
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cla;
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global SIMULATION_TIME;
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global t speed playing timelines;
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t = 0;
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speed = 1;
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playing = 0;
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timelines = [];
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global timeSlider;
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timeSlider = uicontrol('Style', 'slider', 'Callback', @sliderCallback, 'Min', 0, 'Max', SIMULATION_TIME, 'Position', [20 20 500 20], 'Value', t);
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global timeText;
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timeText = uicontrol('Style', 'text', 'Position', [520 20 120 20], 'String', sprintf("t = %f", t));
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uicontrol('Style', 'pushbutton', 'String', 'Play', 'Position', [640 20 60 20], 'Callback', @playCallback);
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uicontrol('Style', 'pushbutton', 'String', 'Pause', 'Position', [700 20 60 20], 'Callback', @pauseCallback);
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hold on;
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xTs = getTS('x');
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yTs = getTS('y');
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plot(xTs.Data, yTs.Data, 'b--');
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global height;
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global lQuiver;
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lQuiver = quiver(0, 0, 0, 0, 'Color', 'Red', 'MaxHeadSize', height/4);
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global rQuiver;
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rQuiver = quiver(0, 0, 0, 0, 'Color', 'Red', 'MaxHeadSize', height/4);
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global robotRect;
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robotRect = plot(0, 0);
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global robotPath;
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robotPath = plot(0, 0, 'b');
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global dirQuiver;
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dirQuiver = quiver(0, 0, 0, 0, 'Color', 'Blue', 'MaxHeadSize', height/4);
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global consQuiver;
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consQuiver = quiver(0, 0, 0, 0, 'Color', 'Green', 'MaxHeadSize', height/4);
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% Draw track
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global pisteWidth;
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global pisteHeight;
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global pisteOrigX;
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global pisteOrigY;
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rectangle('Position', [pisteOrigX pisteOrigY pisteWidth pisteHeight]);
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% Set limits
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margin = 300;
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ampl = max(xTs.max - xTs.min, yTs.max - yTs.min);
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xlim([xTs.min - margin, xTs.min + ampl + margin]);
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ylim([yTs.min - margin, yTs.min + ampl + margin]);
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title("Évolution spatiale");
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xlabel("X (mm)");
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ylabel("Y (mm)");
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end
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function d = getTSData(name, i)
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ts = getTS(name);
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if isempty(ts.Data)
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d = 0;
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else
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d = ts.Data(i);
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end
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end
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function updateToTime(newT)
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% Update ui
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global timeSlider timeText t SIMULATION_TIME;
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t = max(min(SIMULATION_TIME, newT), 0);
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timeSlider.Value = t;
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timeText.String = sprintf("t = %f", t);
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% Get values
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i = find(getTimePoints() <= t);
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i = i(end);
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x = getTSData('x', i);
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y = getTSData('y', i);
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o = getTSData('o', i);
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xCons = getTSData('xCons', i);
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yCons = getTSData('yCons', i);
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oCons = getTSData('oCons', i);
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lVit = getTSData('lVit', i);
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rVit = getTSData('rVit', i);
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% Add event
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tEvent = tsdata.event('tEvent', t);
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xTs = getTS('x');
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xS = xTs.addevent(tEvent);
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yTs = getTS('y');
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yS = yTs.addevent(tEvent);
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% Draw path
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global robotPath;
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robotPath.XData = xS.gettsbeforeevent('tEvent').Data;
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robotPath.YData = yS.gettsbeforeevent('tEvent').Data;
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% Draw robot
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global width height;
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global robotRect dirQuiver;
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drawRect(robotRect, x, y, o, width, height);
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dirQuiver.XData = x; dirQuiver.YData = y;
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dirQuiver.UData = cos(o) * height/2; dirQuiver.VData = sin(o) * height/2;
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% Arrow for wheels
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global lQuiver rQuiver;
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[lQuiver.XData, lQuiver.YData] = pointArround(x, y, -width/2, 0, o);
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lQuiver.UData = cos(o) * lVit; lQuiver.VData = sin(o) * lVit;
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[rQuiver.XData, rQuiver.YData] = pointArround(x, y, +width/2, 0, o);
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rQuiver.UData = cos(o) * rVit; rQuiver.VData = sin(o) * rVit;
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% Draw cons
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global consQuiver;
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consQuiver.XData = xCons; consQuiver.YData = yCons;
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consQuiver.UData = cos(oCons) * height/2 ; consQuiver.VData = sin(oCons) * height/2;
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% Draw timelines
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global timelines
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for i = 1:length(timelines)
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timelines(i).XData = [t t];
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end
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end
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