//Adaptpredict_pcm.c Adaptive predictor to cancel interference #define beta 1E-13 //rate of convergence #define N 60 //# of coefficients of adapt FIR #define NS 256 //size of wideband's buffer #define LEFT 1 //left channel #define RIGHT 0 //right channel const short bufferlength = NS; //buffer length for wideband signal short splusn[N+1]; //buffer wideband signal+interference float w[N+1]; //buffer for weights of adapt FIR float delay[N+1]; //buffer for input to adapt FIR float Fs = 48000.0; //for variable Fs volatile union {unsigned int uint; short channel[2];}CODECData; interrupt void c_int11() //ISR { static short buffercount=0; //init buffer short i; float yn, E; //yn=out adapt FIR, error signal short wb_signal; //wideband desired signal short noise; //external interference CODECData.uint = input_sample(); //input left and right as 32-bit wb_signal = (float) CODECData.channel[LEFT]; //desired on left channel noise = (float) CODECData.channel[RIGHT]; //noise on right channel splusn[0] = (wb_signal + noise); //wideband signal+interference delay[0] = splusn[3]; //delayed input to adaptive FIR yn = 0; //init output of adaptive FIR for (i = 0; i < N; i++) yn += (w[i] * delay[i]); //output of adaptive FIR filter E = splusn[0] - yn; //(wideband+noise)-out adapt FIR for (i = N-1; i >= 0; i--) { w[i] = w[i]+(beta*E*delay[i]); //update weights of adapt FIR delay[i+1] = delay[i]; //update buffer delay samples splusn[i+1] = splusn[i]; //update buffer corrupted wideband } buffercount++; //incr buffer count of wideband if (buffercount >= bufferlength) //if buffer count=length of buffer buffercount = 0; //reinit count output_left_sample((short)E); //overall output from left channel return; } void main() { int T = 0; for (T = 0; T < N; T++) //init variables { w[T] = 0.0; //init weights of adaptive FIR delay[T] = 0.0; //init buffer for delay samples splusn[T] = 0; //init wideband+interference } comm_intr(); //init DSK, codec, McBSP while(1); //infinite loop }