Diff: IIR_filter.cpp

Revision:

0:78ca29b4c49e

Child:

2:769ce5f06d3e

--- /dev/null	Thu Jan 01 00:00:00 1970 +0000
+++ b/IIR_filter.cpp	Tue Apr 03 08:47:41 2018 +0000
@@ -0,0 +1,171 @@
+#include "IIR_filter.h"
+#include "mbed.h"
+using namespace std;
+
+/*
+  IIR filter implemention for the following filter types:
+  init for: first order differentiatior:   G(s) = s/(T*s + 1)
+            first order lowpass with gain  G(s) = K/(T*s + 1)
+            second order lowpass with gain G(s) = K*w0^2/(s^2 + 2*D*w0*s + w0*w0)        
+            nth order, with arbitrary values
+  the billinear transformation is used for s -> z
+  reseting the filter only makes sence for static signals, whatch out if you're using the differnetiator
+*/
+
+// G(s) = s/(T*s + 1)
+IIR_filter::IIR_filter(float T,float Ts){
+           
+    // filter orders
+    nb = 1; // Filter Order
+    na = 1; // Filter Order
+    
+    // filter coefficients
+    B = (float*)malloc((nb+1)*sizeof(float));
+    A = (float*)malloc(na*sizeof(float));    
+    B[0] = 2.0f/(2.0f*T + Ts);
+    B[1] = -B[0];
+    A[0] = -(2.0f*T - Ts)/(2.0f*T + Ts);
+    
+    // signal arrays
+    uk = (float*)malloc((nb+1)*sizeof(float));
+    yk = (float*)malloc(na*sizeof(float));
+    uk[0]= uk[1] = 0.0f;
+    yk[0] = 0.0f;
+    
+    // dc-gain
+    this->K = 0.0f;
+}
+
+// G(s) = K/(T*s + 1)
+IIR_filter::IIR_filter(float T,float Ts,float K){
+    
+    // filter orders
+    nb = 1; // Filter Order
+    na = 1; // Filter Order
+    
+    // filter coefficients
+    B = (float*)malloc((nb+1)*sizeof(float));
+    A = (float*)malloc(na*sizeof(float));      
+    B[0] = Ts/(Ts + 2.0f*T);
+    B[1] = B[0];
+    A[0] = (Ts - 2.0f*T)/(Ts + 2.0f*T); 
+    
+    // signal arrays
+    uk = (float*)malloc((nb+1)*sizeof(float));
+    yk = (float*)malloc(na*sizeof(float));
+    uk[0]= uk[1] = 0.0f;
+    yk[0] = 0.0f;
+    
+    // dc-gain
+    this->K = K;
+}
+
+// G(s) = K*w0^2/(s^2 + 2*D*w0*s + w0^2) 
+IIR_filter::IIR_filter(float w0,float D, float Ts, float K){
+    
+    // filter orders
+    nb = 2; // Filter Order
+    na = 2; // Filter Order
+    
+    // filter coefficients
+    B = (float*)malloc((nb+1)*sizeof(float));
+    A = (float*)malloc(na*sizeof(float));
+    float k0 = Ts*Ts*w0*w0;
+    float k1 = 4.0f*D*Ts*w0;
+    float k2 = k0 + k1 + 4.0f;    
+    B[0] = K*k0/k2;
+    B[1] = 2.0f*B[0];
+    B[2] = B[0]; 
+    A[0] = (2.0f*k0 - 8.0f)/k2;
+    A[1] = (k0 - k1 + 4.0f)/k2;
+    
+    // signal arrays
+    uk = (float*)malloc((nb+1)*sizeof(float));
+    yk = (float*)malloc(na*sizeof(float));
+    uk[0]= uk[1] = uk[2] = 0.0f;
+    yk[0] = yk[1] = 0.0f;
+    
+    // dc-gain
+    this->K = K;
+}
+
+IIR_filter::IIR_filter(float *b,float *a,int nb_, int na_){
+    
+    // filter orders
+    this->nb = nb_-1;    // Filter Order
+    this->na = na_;      // Filter Order
+    
+    // filter coefficients
+    B = (float*)malloc((nb+1)*sizeof(float));
+    A = (float*)malloc(na*sizeof(float));
+    uk = (float*)malloc((nb+1)*sizeof(float));
+    yk = (float*)malloc(na*sizeof(float));
+    
+    for(int k=0;k<=nb;k++){
+        B[k]=b[k];
+        uk[k]=0.0f;
+        }
+    for(int k=0;k<na;k++){
+        A[k] = a[k];
+        yk[k] = 0.0f;
+        }
+    //B[0] = K*k0/k2;
+    //B[1] = 2.0f*B[0];
+    //B[2] = B[0]; 
+    //A[0] = (2.0f*k0 - 8.0f)/k2;
+    //A[1] = (k0 - k1 + 4.0f)/k2;
+    
+    // dc-gain
+    this->K = 1.0f;
+}
+
+    
+IIR_filter::~IIR_filter() {} 
+    
+void IIR_filter::reset(float val) {
+    for(int k=0;k < nb;k++)
+        uk[k] = val;
+    for(int k=0;k < na;k++)
+        yk[k] = val*K;
+        
+}
+
+/* 
+    the filter is operating as follows: 
+    (B[0] + B[1]*z^-1 + ... + B[nb]*z^-nb)*U(z) = (1 + A[0]*z^-1 + ... + A[na-1]*z^-na))*Y(z)
+    y(n) =  B[0]*u(k)   + B[1]*u(k-1) + ... + B[nb]*u(k-nb) + ...
+          - A[0]*y(k-1) - A[1]*y(k-2) - ... - A[na]*y(n-na)
+*/
+float IIR_filter::filter(float input){
+    for(int k = nb;k > 0;k--)    // shift input values back
+        uk[k] = uk[k-1];
+    uk[0] = input;
+    float ret = 0.0f;
+    for(int k = 0;k <= nb;k++)
+        ret += B[k] * uk[k];
+    for(int k = 0;k < na;k++)
+        ret -= A[k] * yk[k];
+    for(int k = na;k > 1;k--)
+        yk[k-1] = yk[k-2];
+    yk[0] = ret;
+    return ret;
+}
+
+// (B[0] + B[1]*z^-1 + ... + B[nb]*z^-nb)*U(z) = (1 + A[0]*z^-1 + ... + A[na-1]*z^-na))*Y(z)
+/*
+IIR_filter::IIR_filter(float *a[], float *b[], float K){
+    
+    this->A = A[0];
+    this->B = B[0];   
+    nb = sizeof(B)/sizeof(B[0]);
+    na = sizeof(A)/sizeof(A[0]);
+    uk = (float*)malloc((nb+1)*sizeof(float));
+    yk = (float*)malloc(na*sizeof(float));
+    for(int ii=0; ii<nb; ii++){
+        uk[ii] = 0.0f;
+    }
+    for(int ii=0; ii<na; ii++){
+        yk[ii] = 0.0f;
+    }
+    this->K = K;       %%% THIS IMPLEMENTATION SUITS NOT THE RESET PROCESS %%%
+}*/
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