2015-04-01 17:54:15 -03:00
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% IMPORTANT - This script requires the Matlab symbolic toolbox
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% Author: Paul Riseborough
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% Last Modified: 16 Feb 2015
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% Derivation of a 3-axis gimbal attitude estimator using a local NED earth Tangent
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% Frame. Based on use of a rotation vector for attitude estimation as described
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% here:
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% Mark E. Pittelkau. "Rotation Vector in Attitude Estimation",
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% Journal of Guidance, Control, and Dynamics, Vol. 26, No. 6 (2003),
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% pp. 855-860.
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% The gimbal is assumed to have the following characteristics:
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% A three axis gimbal having a fixed top plate mounted to the vehicle body with a magnetometer
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% Yaw, roll and pitch degrees of freedom (yaw, roll, pitch Euler sequence)
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% with angle measurements on each gimbal axis
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% IMU measuring delta angles and delta velocites mounted on the
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% camera/sensor assembly
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% When the gimbal joints are all at zero degrees, the sensor assembly X,Y,Z
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% axis is aligned with the top plate X,Y,Z axis
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% State vector:
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% error rotation vector - X,Y,Z (rad)
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% Velocity - North, East, Down (m/s)
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% Delta Angle bias - X,Y,Z (rad)
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% Delta Velocity Bias - X,Y,Z (m/s)
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% Observations:
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% NED velocity - N,E,D (m/s)
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% sensor fixed magnetic field vector of base - X,Y,Z
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% Time varying parameters:
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% XYZ delta angle measurements in sensor axes - rad
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% XYZ delta velocity measurements in sensor axes - m/sec
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% yaw, roll, pitch gimbal rotation angles
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%% define symbolic variables and constants
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clear all;
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% specify if we want to incorporate accerometer bias estimation into the
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% filter, 0 = no, 1 = yes
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f_accBiasEst = 0;
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syms dax day daz real % IMU delta angle measurements in sensor axes - rad
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syms dvx dvy dvz real % IMU delta velocity measurements in sensor axes - m/sec
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syms q0 q1 q2 q3 real % quaternions defining attitude of sensor axes relative to local NED
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syms vn ve vd real % NED velocity - m/sec
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syms dax_b day_b daz_b real % delta angle bias - rad
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syms dvx_b dvy_b dvz_b real % delta velocity bias - m/sec
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syms dt real % IMU time step - sec
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syms gravity real % gravity - m/sec^2
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syms daxNoise dayNoise dazNoise dvxNoise dvyNoise dvzNoise real; % IMU delta angle and delta velocity measurement noise
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syms vwn vwe real; % NE wind velocity - m/sec
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syms magX magY magZ real; % XYZ top plate magnetic field measurements - milligauss
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syms magN magE magD real; % NED earth fixed magnetic field components - milligauss
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syms R_VN R_VE R_VD real % variances for NED velocity measurements - (m/sec)^2
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syms R_MAG real % variance for magnetic flux measurements - milligauss^2
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syms rotErr1 rotErr2 rotErr3 real; % error rotation vector
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syms decl real; % earth magnetic field declination from true north
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syms gPsi gPhi gTheta real; % gimbal joint angles yaw, roll, pitch (rad)
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%% define the process equations
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% define the measured Delta angle and delta velocity vectors
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dAngMeas = [dax; day; daz];
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dVelMeas = [dvx; dvy; dvz];
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% define the delta angle bias errors
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dAngBias = [dax_b; day_b; daz_b];
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% define the delta velocity bias errors
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if (f_accBiasEst > 0)
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dVelBias = [dvx_b; dvy_b; dvz_b];
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else
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dVelBias = [0; 0; 0];
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end
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% define the quaternion rotation vector for the state estimate
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estQuat = [q0;q1;q2;q3];
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% define the attitude error rotation vector, where error = truth - estimate
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errRotVec = [rotErr1;rotErr2;rotErr3];
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% define the attitude error quaternion using a first order linearisation
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errQuat = [1;0.5*errRotVec];
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% Define the truth quaternion as the estimate + error
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truthQuat = QuatMult(estQuat, errQuat);
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% derive the truth sensor to nav direction cosine matrix
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Tsn = Quat2Tbn(truthQuat);
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% define the truth delta angle
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% ignore coning acompensation as these effects are negligible in terms of
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% covariance growth for our application and grade of sensor
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dAngTruth = dAngMeas - dAngBias - [daxNoise;dayNoise;dazNoise];
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% Define the truth delta velocity
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dVelTruth = dVelMeas - dVelBias - [dvxNoise;dvyNoise;dvzNoise];
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% define the attitude update equations
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% use a first order expansion of rotation to calculate the quaternion increment
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% acceptable for propagation of covariances
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deltaQuat = [1;
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0.5*dAngTruth(1);
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0.5*dAngTruth(2);
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0.5*dAngTruth(3);
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];
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truthQuatNew = QuatMult(truthQuat,deltaQuat);
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% calculate the updated attitude error quaternion with respect to the previous estimate
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errQuatNew = QuatDivide(truthQuatNew,estQuat);
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% change to a rotaton vector - this is the error rotation vector updated state
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errRotNew = 2 * [errQuatNew(2);errQuatNew(3);errQuatNew(4)];
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% define the velocity update equations
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% ignore coriolis terms for linearisation purposes
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vNew = [vn;ve;vd] + [0;0;gravity]*dt + Tsn*dVelTruth;
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% define the IMU bias error update equations
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dabNew = dAngBias;
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dvbNew = dVelBias;
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% Define the state vector & number of states
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if (f_accBiasEst > 0)
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stateVector = [errRotVec;vn;ve;vd;dAngBias;dVelBias];
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else
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stateVector = [errRotVec;vn;ve;vd;dAngBias];
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end
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nStates=numel(stateVector);
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save 'symeqns.mat';
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%% derive the filter Jacobians
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% Define the control (disturbance) vector. Error growth in the inertial
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% solution is assumed to be driven by 'noise' in the delta angles and
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2016-05-12 14:03:11 -03:00
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% velocities, after bias effects have been removed. This is OK because we
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2015-04-01 17:54:15 -03:00
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% have sensor bias accounted for in the state equations.
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distVector = [daxNoise;dayNoise;dazNoise;dvxNoise;dvyNoise;dvzNoise];
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% derive the control(disturbance) influence matrix
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if (f_accBiasEst > 0)
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predictedState = [errRotNew;vNew;dabNew;dvbNew];
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else
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predictedState = [errRotNew;vNew;dabNew];
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end
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G = jacobian(predictedState, distVector);
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G = subs(G, {'rotErr1', 'rotErr2', 'rotErr3'}, {0,0,0});
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% derive the state error matrix
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distMatrix = diag(distVector);
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Q = G*distMatrix*transpose(G);
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%matlabFunction(Q,'file','calcQ.m');
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% derive the state transition matrix
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vNew = subs(vNew,{'daxNoise','dayNoise','dazNoise','dvxNoise','dvyNoise','dvzNoise'}, {0,0,0,0,0,0});
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errRotNew = subs(errRotNew,{'daxNoise','dayNoise','dazNoise','dvxNoise','dvyNoise','dvzNoise'}, {0,0,0,0,0,0});
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% Define the state vector & number of states
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if (f_accBiasEst)
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predictedState = [errRotNew;vNew;dabNew;dvbNew];
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else
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predictedState = [errRotNew;vNew;dabNew];
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end
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F = jacobian(predictedState, stateVector);
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F = subs(F, {'rotErr1', 'rotErr2', 'rotErr3'}, {0,0,0});
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%matlabFunction(F,'file','calcF.m');
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%% Derive the predicted covariance
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% This reduces the number of floating point operations by a factor of 4 or
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% more compared to using the standard matrix operations in code
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% define a symbolic covariance matrix using strings to represent
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% '_l_' to represent '( '
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% '_c_' to represent ,
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% '_r_' to represent ')'
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% these can be substituted later to create executable code
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for rowIndex = 1:nStates
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for colIndex = 1:nStates
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eval(['syms OP_l_',num2str(rowIndex),'_c_',num2str(colIndex), '_r_ real']);
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eval(['P(',num2str(rowIndex),',',num2str(colIndex), ') = OP_l_',num2str(rowIndex),'_c_',num2str(colIndex),'_r_;']);
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end
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end
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% Derive the predicted covariance matrix using the standard equation
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PP = F*P*transpose(F) + Q;
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%matlabFunction(PP,'file','calcP.m');
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ccode(PP,'file','calcP.c');
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FixCode('calcP');
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% free up memory
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clear all;
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reset(symengine);
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%% derive equations for fusion of magnetic deviation measurement
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load('symeqns.mat');
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% Define rotation from magnetometer to yaw gimbal
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T3 = [ cos(gPsi) sin(gPsi) 0; ...
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-sin(gPsi) cos(gPsi) 0; ...
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0 0 1];
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% Define rotation from yaw gimbal to roll gimbal
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T1 = [ 1 0 0; ...
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0 cos(gPhi) sin(gPhi); ...
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0 -sin(gPhi) cos(gPhi)];
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% Define rotation from roll gimbal to pitch gimbal
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T2 = [ cos(gTheta) 0 -sin(gTheta); ...
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0 1 0; ...
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sin(gTheta) 0 cos(gTheta)];
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% Define rotation from magnetometer to sensor using a 312 rotation sequence
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Tms = T2*T1*T3;
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% Define rotation from magnetometer to nav axes
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Tmn = Tsn*Tms;
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save 'symeqns.mat';
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% rotate magentic field measured at top plate into nav axes
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magMeasNED = Tmn*[magX;magY;magZ];
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% the predicted measurement is the angle wrt magnetic north of the horizontal
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% component of the measured field
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angMeas = tan(magMeasNED(2)/magMeasNED(1)) - decl;
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H_MAG = jacobian(angMeas,stateVector); % measurement Jacobian
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H_MAG = subs(H_MAG, {'rotErr1', 'rotErr2', 'rotErr3'}, {0,0,0});
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H_MAG = H_MAG(1:3);
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H_MAG = simplify(H_MAG);
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% matlabFunction(H_MAG,'file','calcH_MAG.m');
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ccode(H_MAG,'file','calcH_MAG.c');
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FixCode('calcH_MAG');
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% free up memory
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clear all;
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reset(symengine);
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%% generate helper functions
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load 'symeqns.mat';
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matlabFunction(Tms,'file','calcTms.m');
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Tmn = subs(Tmn, {'rotErr1', 'rotErr2', 'rotErr3'}, {0,0,0});
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matlabFunction(Tmn,'file','calcTmn.m');
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