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I am sorry for being this tedious but I reviewed my code several times with the help of a dozen of articles but still my KF doesn't work. By "doesn't work" I mean that the estimates by KF are wrong. Here is a nice paste of Real, Noised and KF estimated positions (just a small chunk).

My example is the same as in every tutorial I've found - I have a state vector of position and velocity. Position is in meters and represents vertical position in air. My real world case is skydiving (with parachute). In my sample generated data I've assumed we start at 3000m and the velocity is 10m/s.

P.S.: I am pretty sure matrix computations are OK - there must be an error with the logic.

Here I generate data:

void generateData(float** inData, float** noisedData, int x, int y){
    inData[0][0]= 3000; //start position
    inData[1][0]= -10; // 10m/s velocity; minus because we assume it's falling

    noisedData[0][0]= 2998; 
    noisedData[1][0]= -10;

    for(int i=1; i<x; i++){
        inData[0][i]= inData[0][i-1] + inData[1][i-1]; 
        inData[1][i]= inData[1][i-1]; //the velocity doesn't change for simplicity's sake

        noisedData[0][i]=inData[0][i]+(rand()%6-3); //we add noise to real measurement
        noisedData[1][i]=inData[1][i]; //velocity has no noise
    }  
}

And this is my implementation (matrices initialization is based on Wikipedia Kalman example):

int main(int argc, char** argv) {
    srand(time(NULL));

    float** inData = createMatrix(100,2); //2 rows, 100 columns
    float** noisedData = createMatrix(100,2);
    float** estData = createMatrix(100,2);

    generateData(inData, noisedData, 100, 2);

    float sampleRate=0.1; //10hz

    float** A=createMatrix(2,2);
    A[0][0]=1;
    A[0][1]=sampleRate;
    A[1][0]=0;
    A[1][1]=1;

    float** B=createMatrix(1,2);
    B[0][0]=pow(sampleRate,2)/2;
    B[1][0]=sampleRate;

    float** C=createMatrix(2,1);
    C[0][0]=1; //we measure only position
    C[0][1]=0;


    float u=1.0; //acceleration magnitude
    float accel_noise=0.2; //acceleration noise
    float measure_noise=1.5; //1.5 m standard deviation
    float R=pow(measure_noise,2); //measure covariance
    float** Q=createMatrix(2,2); //process covariance
    Q[0][0]=pow(accel_noise,2)*(pow(sampleRate,4)/4);
    Q[0][1]=pow(accel_noise,2)*(pow(sampleRate,3)/2);
    Q[1][0]=pow(accel_noise,2)*(pow(sampleRate,3)/2);
    Q[1][1]=pow(accel_noise,2)*pow(sampleRate,2);

    float** P=createMatrix(2,2); //covariance update
    P[0][0]=0;
    P[0][1]=0; 
    P[1][0]=0; 
    P[1][1]=0;

    float** P_est=createMatrix(2,2);
    P_est[0][0]=P[0][0];
    P_est[0][1]=P[0][1];
    P_est[1][0]=P[1][0];
    P_est[1][1]=P[1][1];

    float** K=createMatrix(1,2); //Kalman gain

    float** X_est=createMatrix(1,2); //our estimated state
    X_est[0][0]=3000; X_est[1][0]=10; 

    // !! KALMAN ALGORITHM START !! //
    for(int i=0; i<100; i++)
    {        
        float** temp;
        float** temp2;
        float** temp3;

        float** C_trans=matrixTranspose(C,2,1);
        temp=matrixMultiply(P_est,C_trans,2,2,1,2); //2x1
        temp2=matrixMultiply(C,P_est,2,1,2,2); //1x2
        temp3=matrixMultiply(temp2,C_trans,2,1,1,2); //1x1
        temp3[0][0]+=R;
        K[0][0]=temp[0][0]/temp3[0][0]; // 1. KALMAN GAIN
        K[1][0]=temp[1][0]/temp3[0][0];

        temp=matrixMultiply(C,X_est,2,1,1,2);
        float diff=noisedData[0][i]-temp[0][0]; //diff between meas and est

        X_est[0][0]=X_est[0][0]+(K[0][0]*diff);  // 2. ESTIMATION CORRECTION
        X_est[1][0]=X_est[1][0]+(K[1][0]*diff);

        temp=createMatrix(2,2);
        temp[0][0]=1; temp[0][1]=0; temp[1][0]=0; temp[1][1]=1;
        temp2=matrixMultiply(K,C,1,2,2,1);
        temp3=matrixSub(temp,temp2,2,2,2,2);
        P=matrixMultiply(temp3,P_est,2,2,2,2);  // 3. COVARIANCE UPDATE



        temp=matrixMultiply(A,X_est,2,2,1,2);
        X_est[0][0]=temp[0][0]+B[0][0]*u; 
        X_est[1][0]=temp[1][0]+B[1][0]*u; // 4. PREDICT NEXT STATE


        temp=matrixMultiply(A,P,2,2,2,2);
        float** A_inv=getInverse(A,2);
        temp2=matrixMultiply(temp,A_inv,2,2,2,2);
        P_est=matrixAdd(temp2,Q,2,2,2,2); // 5. PREDICT NEXT COVARIANCE


        estData[0][i]=X_est[0][0]; //just saving here for later to write out
        estData[1][i]=X_est[1][0];
    }

    for(int i=0; i<100; i++) printf("%4.2f  :  %4.2f  :  %4.2f \n", inData[0][i], noisedData[0][i], estData[0][i]); // just writing out

    return (EXIT_SUCCESS);
}
share|improve this question
    
I won't attempt to answer this, but is it correct to assume the -m/s. I see what your getting at with the object falling, but does the continued equations realize that? Would it be better to keep it positive and subtract it where need be? Curious! –  Chief Two Pencils Aug 10 '12 at 11:11
    
I tried that - it's the same! :) –  Primož 'c0dehunter' Kralj Aug 10 '12 at 11:13
    
I figured as much:) –  Chief Two Pencils Aug 10 '12 at 11:14

1 Answer 1

You are doing a lot of weird array indexing.

float** A=createMatrix(2,2);
A[0][0]=1;
A[0][3]=sampleRate;
A[1][0]=0;
A[1][4]=1;

What is the expected outcome of indexing outside of the bounds of the array?

share|improve this answer
    
I don't know where that numbers came from. In my code everything is alright. I've fixed it here too. –  Primož 'c0dehunter' Kralj Aug 10 '12 at 11:16

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