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I'm currently trying to use the Free C++ Extended Kalman Filter Library . I understands the basics of a Kalman filter however I'm having an issue of NaN values being produced with this library. Does anyone on SO have experience using the kalman filter algorithm to spot my mistake?

This is my filter:

class PointEKF : public Kalman::EKFilter<double,1,false,true,false> {
public:
        PointEKF() : Period(0.0) {
            setDim(3, 1, 3, 1, 1);
        }

        void SetPeriod(double p) {
            Period = p;
        }
protected:
        void makeBaseA() {
            A(1, 1) = 1.0;
            //A(1, 2) = Period;
            //A(1, 3) = Period*Period / 2;
            A(2, 1) = 0.0;
            A(2, 2) = 1.0;
            //A(2, 3) = Period;
            A(3, 1) = 0.0;
            A(3, 2) = 0.0;
            A(3, 3) = 1.0;
        }
        void makeBaseH() {
            H(1, 1) = 1.0;
            H(1, 2) = 0.0;
            H(1, 3) = 0.0;
        }
        void makeBaseV() { 
            V(1, 1) = 1.0;
        }
        void makeBaseW() {
            W(1, 1) = 1.0;
            W(1, 2) = 0.0;
            W(1, 3) = 0.0;
            W(2, 1) = 0.0;
            W(2, 2) = 1.0;
            W(2, 3) = 0.0;
            W(3, 1) = 0.0;
            W(3, 2) = 0.0;
            W(3, 3) = 1.0;
        }

        void makeA() {
            double T = Period;
            A(1, 1) = 1.0;
            A(1, 2) = T;
            A(1, 3) = (T*T) / 2;
            A(2, 1) = 0.0;
            A(2, 2) = 1.0;
            A(3, 3) = T;
            A(3, 1) = 0.0;
            A(3, 2) = 0.0;
            A(3, 3) = 1.0;
        }
        void makeH() {
            double T = Period;
            H(1, 1) = 1.0;
            H(1, 2) = T;
            H(1, 3) = T*T / 2;
        }
        void makeProcess() {
            double T = u(1);
            Vector x_(x.size());
            x_(1) = x(1) + x(2) * T + (x(3) * T*T / 2);
            x_(2) = x(2) + x(3) * T;
            x_(3) = x(3);
            x.swap(x_);
        }
        void makeMeasure() {
            z(1) = x(1);
        }

        double Period;
};

I used it as follows:

void init() {
    int n = 3;
    static const double _P0[] = {
                                 1.0, 0.0, 0.0,
                                 0.0, 1.0, 0.0,
                                 0.0, 0.0, 1.0
                                };
    Matrix P0(n, n, _P0);
    Vector x(3);
    x(1) = getPoint(0);
    x(2) = getVelocity(0);
    x(3) = getAccleration(0);
    filterX.init(x, P0);
}

and,

    Vector measurement(1), input(1), u(1);
    u(1) = 0.400;
    double start = data2->positionTimeCounter;
    double end = data->positionTimeCounter;
    double period = (end - start) / (1000*1000);
    filterX.SetPeriod(period);
    measurement(1) = getPoint(0);
    input(1) = period;
    filterX.step(input, measurement);
    auto x = filterX.predict(u);

Note: The data I'm using are x points generated from a unit circle.

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1 Answer 1

up vote 1 down vote accepted

If you use the Base versions of the matrices:

A = [ 1 0 0;
      0 1 0;
      0 0 1 ];
H = [ 1 0 0 ];

you don't have an observable system because your measurements only capture the first state (position) and there is no coupling, in the A matrix, between position and its derivatives (velocity, acceleration). The observability matrix is as follows:

O = [ H;
      H*A;
      H*A*A ];
O = [ 1 0 0;
      1 0 0;
      1 0 0 ];

which is obviously singular, i.e., your system is not observable. And feeding that through a EKF algorithm should produce an error (the situation should be detected by the algorithm), but if it is not detected, it will lead to NaN results in the estimates, exactly as you are experiencing.

Now, the A matrix from the makeA() function is more suitable:

A = [ 1 h h*h/2;
      0 1 h;
      0 0 1 ];
H = [ 1 0 0 ];       // use this H matrix (not [ 1 h h*h/2 ])

leading to an observability matrix:

O = [ 1    0      0;
      1    h  h*h/2;
      1  2*h  2*h*h ];

which is full-rank (not singular), and thus, you have an observable system.

Kalman filtering algorithm can be quite sensitive to the conditioning of the matrices, meaning that if the time-step is really small (e.g. 1e-6), you need to use a continuous-time version. Also, the problem of NaN might come from the linear solver (solves a linear system of equation) which is needed in the KF algorithm. If the author of the library used a naive method (e.g., Gaussian elimination, LU-decomposition with or without pivots, Cholesky without pivots, etc.), then that would make this issue of numerical conditioning much worse.

N.B. You should start your KF filtering with a very high P matrix, because the initial P should reflect the uncertainty on your initial state vector, which is usually very high, so P should be around 1000 * identity.

share|improve this answer
    
what should a correct base version be? –  andre Jan 10 '13 at 19:55
    
@ahenderson The same as what's in makeA(). And the H should be that of makeBaseH(). Why are there two functions makeA and makeBaseA? Is there anything in library docs about the difference between those two? –  Mikael Persson Jan 10 '13 at 20:19
    
"Their role is to fill in the parts of the Kalman matrices that change between iterations." This is from the doc. –  andre Jan 10 '13 at 20:31
    
@ahenderson Then it seems that the makeBaseA() function should have what you currently have in makeA(), and the makeA() function should be empty (or set all variables to zero). In other words, all the terms that do not depend on the state should be put in makeBaseA() and only the state-dependent terms should be put in makeA(). In other words, A = makeBaseA() + makeA();. Also, if one of those functions is empty, you should call NoModification() as it says in the docs. –  Mikael Persson Jan 10 '13 at 22:18

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