# bandpass butterworth filter implementation in C++

I am implementing an image analysis algorithm using openCV and c++, but I found out openCV doesnt have any function for Butterworth Bandpass filter officially. in my project I have to pass a time series of pixels into the Butterworth 5 order filter and the function will return the filtered time series pixels. Butterworth(pixelseries,order, frequency), if you have any idea to help me of how to start please let me know. Thank you

EDIT : after getting help, finally I come up with the following code. which can calculate the Numerator Coefficients and Denominator Coefficients, but the problem is that some of the numbers is not as same as matlab results. here is my code:

``````#include <iostream>
#include <stdio.h>
#include <vector>
#include <math.h>

using namespace std;

#define N 10 //The number of images which construct a time series for each pixel
#define PI 3.14159

double *ComputeLP( int FilterOrder )
{
double *NumCoeffs;
int m;
int i;

NumCoeffs = (double *)calloc( FilterOrder+1, sizeof(double) );
if( NumCoeffs == NULL ) return( NULL );

NumCoeffs[0] = 1;
NumCoeffs[1] = FilterOrder;
m = FilterOrder/2;
for( i=2; i <= m; ++i)
{
NumCoeffs[i] =(double) (FilterOrder-i+1)*NumCoeffs[i-1]/i;
NumCoeffs[FilterOrder-i]= NumCoeffs[i];
}
NumCoeffs[FilterOrder-1] = FilterOrder;
NumCoeffs[FilterOrder] = 1;

return NumCoeffs;
}

double *ComputeHP( int FilterOrder )
{
double *NumCoeffs;
int i;

NumCoeffs = ComputeLP(FilterOrder);
if(NumCoeffs == NULL ) return( NULL );

for( i = 0; i <= FilterOrder; ++i)
if( i % 2 ) NumCoeffs[i] = -NumCoeffs[i];

return NumCoeffs;
}

double *TrinomialMultiply( int FilterOrder, double *b, double *c )
{
int i, j;
double *RetVal;

RetVal = (double *)calloc( 4 * FilterOrder, sizeof(double) );
if( RetVal == NULL ) return( NULL );

RetVal[2] = c[0];
RetVal[3] = c[1];
RetVal[0] = b[0];
RetVal[1] = b[1];

for( i = 1; i < FilterOrder; ++i )
{
RetVal[2*(2*i+1)]   += c[2*i] * RetVal[2*(2*i-1)]   - c[2*i+1] * RetVal[2*(2*i-1)+1];
RetVal[2*(2*i+1)+1] += c[2*i] * RetVal[2*(2*i-1)+1] + c[2*i+1] * RetVal[2*(2*i-1)];

for( j = 2*i; j > 1; --j )
{
RetVal[2*j]   += b[2*i] * RetVal[2*(j-1)]   - b[2*i+1] * RetVal[2*(j-1)+1] +
c[2*i] * RetVal[2*(j-2)]   - c[2*i+1] * RetVal[2*(j-2)+1];
RetVal[2*j+1] += b[2*i] * RetVal[2*(j-1)+1] + b[2*i+1] * RetVal[2*(j-1)] +
c[2*i] * RetVal[2*(j-2)+1] + c[2*i+1] * RetVal[2*(j-2)];
}

RetVal[2] += b[2*i] * RetVal[0] - b[2*i+1] * RetVal[1] + c[2*i];
RetVal[3] += b[2*i] * RetVal[1] + b[2*i+1] * RetVal[0] + c[2*i+1];
RetVal[0] += b[2*i];
RetVal[1] += b[2*i+1];
}

return RetVal;
}

double *ComputeNumCoeffs(int FilterOrder)
{
double *TCoeffs;
double *NumCoeffs;
int i;

NumCoeffs = (double *)calloc( 2*FilterOrder+1, sizeof(double) );
if( NumCoeffs == NULL ) return( NULL );

TCoeffs = ComputeHP(FilterOrder);
if( TCoeffs == NULL ) return( NULL );

for( i = 0; i < FilterOrder; ++i)
{
NumCoeffs[2*i] = TCoeffs[i];
NumCoeffs[2*i+1] = 0.0;
}
NumCoeffs[2*FilterOrder] = TCoeffs[FilterOrder];

free(TCoeffs);

return NumCoeffs;
}

double *ComputeDenCoeffs( int FilterOrder, double Lcutoff, double Ucutoff )
{
int k;            // loop variables
double theta;     // PI * (Ucutoff - Lcutoff) / 2.0
double cp;        // cosine of phi
double st;        // sine of theta
double ct;        // cosine of theta
double s2t;       // sine of 2*theta
double c2t;       // cosine 0f 2*theta
double *RCoeffs;     // z^-2 coefficients
double *TCoeffs;     // z^-1 coefficients
double *DenomCoeffs;     // dk coefficients
double PoleAngle;      // pole angle
double SinPoleAngle;     // sine of pole angle
double CosPoleAngle;     // cosine of pole angle
double a;         // workspace variables

cp = cos(PI * (Ucutoff + Lcutoff) / 2.0);
theta = PI * (Ucutoff - Lcutoff) / 2.0;
st = sin(theta);
ct = cos(theta);
s2t = 2.0*st*ct;        // sine of 2*theta
c2t = 2.0*ct*ct - 1.0;  // cosine of 2*theta

RCoeffs = (double *)calloc( 2 * FilterOrder, sizeof(double) );
TCoeffs = (double *)calloc( 2 * FilterOrder, sizeof(double) );

for( k = 0; k < FilterOrder; ++k )
{
PoleAngle = PI * (double)(2*k+1)/(double)(2*FilterOrder);
SinPoleAngle = sin(PoleAngle);
CosPoleAngle = cos(PoleAngle);
a = 1.0 + s2t*SinPoleAngle;
RCoeffs[2*k] = c2t/a;
RCoeffs[2*k+1] = s2t*CosPoleAngle/a;
TCoeffs[2*k] = -2.0*cp*(ct+st*SinPoleAngle)/a;
TCoeffs[2*k+1] = -2.0*cp*st*CosPoleAngle/a;
}

DenomCoeffs = TrinomialMultiply(FilterOrder, TCoeffs, RCoeffs );
free(TCoeffs);
free(RCoeffs);

DenomCoeffs[1] = DenomCoeffs[0];
DenomCoeffs[0] = 1.0;
for( k = 3; k <= 2*FilterOrder; ++k )
DenomCoeffs[k] = DenomCoeffs[2*k-2];

return DenomCoeffs;
}

void filter(int ord, double *a, double *b, int np, double *x, double *y)
{
int i,j;
y[0]=b[0] * x[0];
for (i=1;i<ord+1;i++)
{
y[i]=0.0;
for (j=0;j<i+1;j++)
y[i]=y[i]+b[j]*x[i-j];
for (j=0;j<i;j++)
y[i]=y[i]-a[j+1]*y[i-j-1];
}
for (i=ord+1;i<np+1;i++)
{
y[i]=0.0;
for (j=0;j<ord+1;j++)
y[i]=y[i]+b[j]*x[i-j];
for (j=0;j<ord;j++)
y[i]=y[i]-a[j+1]*y[i-j-1];
}
}

int main(int argc, char *argv[])
{
//Frequency bands is a vector of values - Lower Frequency Band and Higher Frequency Band

//First value is lower cutoff and second value is higher cutoff
double FrequencyBands[2] = {0.25,0.375};//these values are as a ratio of f/fs, where fs is sampling rate, and f is cutoff frequency
//and therefore should lie in the range [0 1]
//Filter Order

int FiltOrd = 5;

//Pixel Time Series
/*int PixelTimeSeries[N];
int outputSeries[N];
*/
//Create the variables for the numerator and denominator coefficients
double *DenC = 0;
double *NumC = 0;
//Pass Numerator Coefficients and Denominator Coefficients arrays into function, will return the same

NumC = ComputeNumCoeffs(FiltOrd);
for(int k = 0; k<11; k++)
{
printf("NumC is: %lf\n", NumC[k]);
}
//is A in matlab function and the numbers are correct
DenC = ComputeDenCoeffs(FiltOrd, FrequencyBands[0], FrequencyBands[1]);
for(int k = 0; k<11; k++)
{
printf("DenC is: %lf\n", DenC[k]);
}
double y[5];
double x[5]={1,2,3,4,5};
filter(5, DenC, NumC, 5, x, y);
return 1;
}
``````

I get this resutls for my code :

B= 1,0,-5,0,10,0,-10,0,5,0,-1 A= 1.000000000000000, -4.945988709743181, 13.556489496973796, -24.700711850327743, 32.994881546824828, -33.180726698160655, 25.546126213403539, -14.802008410165968, 6.285430089797051, -1.772929809750849, 0.277753012228403

but if I want to test the coefficinets in same frequency band in MATLAB, I get the following results:

``````>> [B, A]=butter(5, [0.25,0.375])
``````

B = 0.0002, 0, -0.0008, 0, 0.0016, 0, -0.0016, 0, 0.0008, 0, -0.0002

A = 1.0000, -4.9460, 13.5565, -24.7007, 32.9948, -33.1806, 25.5461, -14.8020, 6.2854, -1.7729, 0.2778

I have test this website :http://www.exstrom.com/journal/sigproc/ code, but the result is equal as mine, not matlab. anybody knows why? or how can I get the same result as matlab toolbox?

• You want to filter in the time domain, i.e. successive frames of a video ? – Paul R Apr 29 '12 at 15:14
• hi paul, tanx for your msg. I already have vectors of pixels in N successive images. lets say the evolution of one pixel in [i][j] position during N images. I need to filter each time series evolution. – user261002 Apr 29 '12 at 15:28
• OK - not too hard to do in straight C or C++ code then - use biquad IIR filters with suitable coefficients: en.wikipedia.org/wiki/Digital_biquad_filter – Paul R Apr 29 '12 at 15:31
• I hope you might be interested in this link tech.groups.yahoo.com/group/OpenCV/message/45937 – Abid Rahman K Apr 30 '12 at 13:57
• At first glance it looks like the B coefficients you have are in the same ratio as Matlab's, so I reckon that you're missing a normalising constant. Look at the matlab docs to see what normalising coefficient it is using. – the_mandrill May 8 '12 at 10:03

I know this is a post on an old thread, and I would usually leave this as a comment, but I'm apparently not able to do that.

In any case, for people searching for similar code, I thought I would post the link from where this code originates (it also has C code for other types of Butterworth filter coefficients and some other cool signal processing code).

The code is located here: http://www.exstrom.com/journal/sigproc/

Additionally, I think there is a piece of code which calculates said scaling factor for you already.

``````/**********************************************************************
sf_bwbp - calculates the scaling factor for a butterworth bandpass filter.
The scaling factor is what the c coefficients must be multiplied by so
that the filter response has a maximum value of 1.
*/

double sf_bwbp( int n, double f1f, double f2f )
{
int k;            // loop variables
double ctt;       // cotangent of theta
double sfr, sfi;  // real and imaginary parts of the scaling factor
double parg;      // pole angle
double sparg;     // sine of pole angle
double cparg;     // cosine of pole angle
double a, b, c;   // workspace variables

ctt = 1.0 / tan(M_PI * (f2f - f1f) / 2.0);
sfr = 1.0;
sfi = 0.0;

for( k = 0; k < n; ++k )
{
parg = M_PI * (double)(2*k+1)/(double)(2*n);
sparg = ctt + sin(parg);
cparg = cos(parg);
a = (sfr + sfi)*(sparg - cparg);
b = sfr * sparg;
c = -sfi * cparg;
sfr = b - c;
sfi = a - b - c;
}

return( 1.0 / sfr );
}
``````
• You need 50 reputation to post comments. Focus on answering questions and you should receive enough reputation to do so in no time. – BoltClock Nov 17 '13 at 7:55

I finally found it. I just need to implement the following code from matlab source code to c++ . "the_mandrill" were right, I need to add the normalizing constant into the coefficient:

``````kern = exp(-j*w*(0:length(b)-1));
b = real(b*(kern*den(:))/(kern*b(:)));
``````

EDIT: and here is the final edition, which the whole code will return numbers exactly equal to MATLAB :

``````double *ComputeNumCoeffs(int FilterOrder,double Lcutoff, double Ucutoff, double *DenC)
{
double *TCoeffs;
double *NumCoeffs;
std::complex<double> *NormalizedKernel;
double Numbers[11]={0,1,2,3,4,5,6,7,8,9,10};
int i;

NumCoeffs = (double *)calloc( 2*FilterOrder+1, sizeof(double) );
if( NumCoeffs == NULL ) return( NULL );

NormalizedKernel = (std::complex<double> *)calloc( 2*FilterOrder+1, sizeof(std::complex<double>) );
if( NormalizedKernel == NULL ) return( NULL );

TCoeffs = ComputeHP(FilterOrder);
if( TCoeffs == NULL ) return( NULL );

for( i = 0; i < FilterOrder; ++i)
{
NumCoeffs[2*i] = TCoeffs[i];
NumCoeffs[2*i+1] = 0.0;
}
NumCoeffs[2*FilterOrder] = TCoeffs[FilterOrder];
double cp[2];
double Bw, Wn;
cp[0] = 2*2.0*tan(PI * Lcutoff/ 2.0);
cp[1] = 2*2.0*tan(PI * Ucutoff / 2.0);

Bw = cp[1] - cp[0];
//center frequency
Wn = sqrt(cp[0]*cp[1]);
Wn = 2*atan2(Wn,4);
double kern;
const std::complex<double> result = std::complex<double>(-1,0);

for(int k = 0; k<11; k++)
{
NormalizedKernel[k] = std::exp(-sqrt(result)*Wn*Numbers[k]);
}
double b=0;
double den=0;
for(int d = 0; d<11; d++)
{
b+=real(NormalizedKernel[d]*NumCoeffs[d]);
den+=real(NormalizedKernel[d]*DenC[d]);
}
for(int c = 0; c<11; c++)
{
NumCoeffs[c]=(NumCoeffs[c]*den)/b;
}

free(TCoeffs);
return NumCoeffs;
}
``````
• Did you also have to modify the posted code for your filter function to get this to work properly? It looks like you may have some problems with the bounds. E.g. for (i=ord+1;i<np+1;i++) looks like it will step past the end of the x array. – grantnz Dec 6 '12 at 3:24
• Interesting thread.. I transformed this into MATLAB and created my own Butterworth filter :) Thanks! By the way, your new edited "ComputeNumCoeffs" subroutine is only set up for `FilterOrder = 5`, since you are iterating `k=0-->11`. I know that it's easy to make it general.. but just wanted to alert whoever sees this thread later. – user2044147 Feb 5 '13 at 17:46

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