mirror of https://github.com/ArduPilot/ardupilot
71 lines
2.8 KiB
Matlab
71 lines
2.8 KiB
Matlab
%% Set initial conditions
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clear all;
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load('fltTest.mat');
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startDelayTime = 100; % number of seconds to delay filter start (used to simulate in-flight restart)
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dt = 1/50;
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startTime = 0.001*(IMU(1,2));
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stopTime = 0.001*(IMU(length(IMU),2));
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indexLimit = length(IMU);
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magIndexlimit = length(MAG);
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statesLog = zeros(11,indexLimit);
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eulLog = zeros(4,indexLimit);
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velInnovLog = zeros(4,indexLimit);
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angErrLog = velInnovLog;
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decInnovLog = zeros(2,magIndexlimit);
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velInnovVarLog = velInnovLog;
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decInnovVarLog = decInnovLog;
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% initialise the filter to level
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quat = [1;0;0;0];
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states = zeros(10,1);
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Tbn = Quat2Tbn(quat);
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% Set the expected declination
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measDec = 0.18;
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% define the state covariances with the exception of the quaternion covariances
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Sigma_velNED = 0.5; % 1 sigma uncertainty in horizontal velocity components
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Sigma_dAngBias = 5*pi/180*dt; % 1 Sigma uncertainty in delta angle bias
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Sigma_quatErr = 1; % 1 Sigma uncertainty in angular misalignment (rad)
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covariance = single(diag([Sigma_quatErr*[1;1;1;1];Sigma_velNED*[1;1;1];Sigma_dAngBias*[1;1;1]].^2));
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%% Main Loop
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magIndex = 1;
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time = 0;
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tiltError = 0;
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headingAligned = 0;
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angErrVec = [0;0;0];
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startIndex = max(11,ceil(startDelayTime/dt));
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for index = startIndex:indexLimit
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time=time+dt + startIndex*dt;
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% read IMU measurements and correct rates using estimated bias
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angRate = IMU(index,3:5)' - states(7:9)./dt;
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accel = IMU(index,6:8)';
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% predict states
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[quat, states, Tbn, delAng, delVel] = PredictStates(quat,states,angRate,accel,dt);
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statesLog(1,index) = time;
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statesLog(2:11,index) = states;
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eulLog(1,index) = time;
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eulLog(2:4,index) = QuatToEul(quat);
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% predict covariance matrix
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covariance = PredictCovariance(delAng,delVel,quat,states,covariance,dt);
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% read magnetometer measurements
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while ((MAG(magIndex,1) < IMU(index,1)) && (magIndex < magIndexlimit))
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magIndex = magIndex + 1;
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% fuse magnetometer measurements if new data available and when tilt has settled
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if ((MAG(magIndex,1) >= IMU(index,1)) && ((angErrVec(1)^2 + angErrVec(2)^2) < 0.05^2) && (index > 50))
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magBody = 0.001*MAG(magIndex,3:5)';
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[states,covariance,decInnov,decInnovVar] = FuseMagnetometer(states,covariance,magBody,measDec,Tbn);
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decInnovLog(1,magIndex) = time;
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decInnovLog(2,magIndex) = decInnov;
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decInnovVarLog(1,magIndex) = time;
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decInnovVarLog(2,magIndex) = decInnovVar;
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end
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end
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% fuse velocity measurements - use synthetic measurements
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measVel = [0;0;0];
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[states,covariance,velInnov,velInnovVar] = FuseVelocity(states,covariance,measVel);
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velInnovLog(1,index) = time;
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velInnovLog(2:4,index) = velInnov;
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velInnovVarLog(1,index) = time;
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velInnovVarLog(2:4,index) = velInnovVar;
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end
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%% Generate Plots
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PlotData; |