// Sample Creation routines (encode and filter) for ARDOP Modem #include "ARDOPC.h" #include #define ARDOPBufferSize 12000 * 100 char CWIDMark[32] = ""; extern short ARDOPTXBuffer[4][ARDOPBufferSize]; // Enough to hold whole frame of samples extern int ARDOPTXLen[4]; // Length of frame extern int ARDOPTXPtr[4]; // Tx Pointer extern int intSessionBW; // Negotiated speed #pragma warning(disable : 4244) // Code does lots of float to int FILE * fp1; float dblQAMCarRatio = 1.0f / 1.765f; //Optimum for 8,8 circular constellation with no phase offset: (Dmin inner to inner = Dmin inner to outer) #define MAX(x, y) ((x) > (y) ? (x) : (y)) // Function to generate the Two-tone leader and Frame Sync (used in all frame types) extern short Dummy; int intSoftClipCnt = 0; BOOL SendingHeader200 = 0; // Set when sending header in 200 Hz Modes void ARDOPFlush(); int intBW; // Requested connect speed int intSessionBW; // Negotiated speed UCHAR bytLastReceivedDataFrameType; UCHAR bytLastARQSessionID; int blnPending = 0; int intSessionBW = 500; void ARDOPSampleSink(short Sample); extern CONST short int50BaudTwoToneLeaderTemplate[240]; // holds just 1 symbol (20 ms) of the leader extern int TrailerLength; void AddTrailer(int Chan) { int intAddedSymbols = 1 + TrailerLength / 10; // add 1 symbol + 1 per each 10 ms of MCB.Trailer int i, k; for (i = 1; i <= intAddedSymbols; i++) { for (k = 0; k < 120; k++) { ARDOPSampleSink(intQAM50bdCarTemplate[5][0][k % 60]); } } } extern int Number; void ARDOPFlush(int Chan) { AddTrailer(Chan); // add the trailer. ARDOPTXPtr[Chan] = 0; ARDOPTXLen[Chan] = Number; } // Function to soft clip combined waveforms. int SoftClip(int intInput) { if (intInput > 30000) // soft clip above/below 30000 { intInput = 30000; //min(32700, 30000 + 20 * sqrt(intInput - 30000)); intSoftClipCnt += 1; } else if(intInput < -30000) { intInput = -30000; //max(-32700, -30000 - 20 * sqrt(-(intInput + 30000))); intSoftClipCnt += 1; } if (intInput == 0) intInput = 0; return intInput; } void GetTwoToneLeaderWithSync(int intSymLen) { // Generate a 50 baud (20 ms symbol time) 2 tone leader // leader tones used are 1475 and 1525 Hz. int intSign = 1; int i, j; short intSample; if ((intSymLen & 1) == 1) intSign = -1; for (i = 0; i < intSymLen; i++) //for the number of symbols needed (two symbols less than total leader length) { for (j = 0; j < 240; j++) // for 240 samples per symbol (50 baud) { if (i != (intSymLen - 1)) intSample = intSign * int50BaudTwoToneLeaderTemplate[j]; else intSample = -intSign * int50BaudTwoToneLeaderTemplate[j]; ARDOPSampleSink(intSample); } intSign = -intSign; } } void SendLeaderAndSYNC(UCHAR * bytEncodedBytes, int intLeaderLen) { int intLeaderLenMS; int j, k, n; UCHAR bytMask; UCHAR bytSymToSend; short intSample; if (intLeaderLen == 0) intLeaderLenMS = LeaderLength; else intLeaderLenMS = intLeaderLen; // Create the leader GetTwoToneLeaderWithSync(intLeaderLenMS / 20); //Create the 8 symbols (16 bit) 50 baud 4FSK frame type with Implied SessionID for(j = 0; j < 2; j++) // for the 2 bytes of the frame type { bytMask = 0x30; for(k = 0; k < 4; k++) // for 4 symbols per byte (3 data + 1 parity) { if (k < 3) bytSymToSend = (bytMask & bytEncodedBytes[j]) >> (2 * (2 - k)); else bytSymToSend = ComputeTypeParity(bytEncodedBytes[j]); for(n = 0; n < 240; n++) { // if ( ARQBandwidth == XB2500) // 2500 Hz // { // if (bytSymToSend < 2) // intSample = (0.62 * intFSK50bdCarTemplate[4 + bytSymToSend][n]) + (0.62 * intFSK50bdCarTemplate[bytSymToSend][n]); // 4 is offset to center tones 1350, 1450, 1550, 1650Hz // else // intSample = (0.62 * intFSK50bdCarTemplate[4 + bytSymToSend][n]) + (0.62 * intFSK50bdCarTemplate[8 + bytSymToSend][n]); // 4 is offset to center tones 1350, 1450, 1550, 1650Hz, 8 is offset to tones 1800 and 1900 // } // else intSample = intFSK50bdCarTemplate[bytSymToSend + 4][n]; ARDOPSampleSink(intSample); } bytMask = bytMask >> 2; } } } void Mod4FSKDataAndPlay(unsigned char * bytEncodedBytes, int Len, int intLeaderLen, int Chan) { // Function to Modulate data encoded for 4FSK, create // the 16 bit samples and send to sound interface // Function works for 1, 2 or 4 simultaneous carriers int intNumCar, intBaud, intDataLen, intRSLen, intDataPtr, intSampPerSym, intDataBytesPerCar; BOOL blnOdd; int intSample; char strType[18] = ""; char strMod[16] = ""; UCHAR bytSymToSend, bytMask, bytMinQualThresh; float dblCarScalingFactor; int intLeaderLenMS; int k, m, n; UCHAR Type = bytEncodedBytes[0]; if (!FrameInfo(Type, &blnOdd, &intNumCar, strMod, &intBaud, &intDataLen, &intRSLen, &bytMinQualThresh, strType)) return; if (strcmp(strMod, "4FSK") != 0) return; Debugprintf("Sending Frame Type %s", strType); DrawTXFrame(strType); if (bytEncodedBytes[0] == PktFrameHeader) { // Leader is 4FSK which needs 500 filter if (pktBW[pktMode] < 1000) initFilter(500, 1500, Chan); else initFilter(2500, 1500, Chan); } else { if (ARQBandwidth == XB200) initFilter(200, 1500, Chan); else if (intNumCar == 1) initFilter(500, 1500, Chan); else initFilter(2500, 1500, Chan); } if (intLeaderLen == 0) intLeaderLenMS = LeaderLength; else intLeaderLenMS = intLeaderLen; switch (intBaud) { case 50: intSampPerSym = 240; break; case 100: intSampPerSym = 120; } intDataBytesPerCar = (Len - 2) / intNumCar; // We queue the samples here, so dont copy below SendLeaderAndSYNC(bytEncodedBytes, intLeaderLen); intDataPtr = 2; Reenter: switch (intNumCar) { case 1: // use carriers 0-3 dblCarScalingFactor = 1.0; // (scaling factors determined emperically to minimize crest factor) for (m = 0; m < intDataBytesPerCar; m++) // For each byte of input data { bytMask = 0xC0; // Initialize mask each new data byte for (k = 0; k < 4; k++) // for 4 symbol values per byte of data { bytSymToSend = (bytMask & bytEncodedBytes[intDataPtr]) >> (2 * (3 - k)); // Values 0-3 for (n = 0; n < intSampPerSym; n++) // Sum for all the samples of a symbols { if (intBaud == 50) { if (intSessionBW == 200 && (bytSymToSend == 0 || bytSymToSend == 3)) // This scales down the two outer tones in 200 Hz mode to restrict bandwidth slightly intSample = 0.7f * intFSK50bdCarTemplate[4 + bytSymToSend][n]; //4 is offset to center tones 1350, 1450, 1550, 1650Hz else intSample = intFSK50bdCarTemplate[4 + bytSymToSend][n]; //4 is offset to center tones 1350, 1450, 1550, 1650Hz } else if (intBaud == 100) // Used for OFDMACK { intSample = intFSK100bdCarTemplate[bytSymToSend][n]; } ARDOPSampleSink(intSample); } bytMask = bytMask >> 2; } intDataPtr += 1; } if (Type == PktFrameHeader) { // just sent packet header. Send rest in current mode // Assumes we are using 4FSK for Packet Header bytEncodedBytes[0] = Type = PktFrameData; // Prevent reentry strcpy(strMod, &pktMod[pktMode][0]); intDataBytesPerCar = pktDataLen + pktRSLen + 3; intDataPtr = 11; // Over Header intNumCar = pktCarriers[pktMode]; // This assumes Packet Data is sent as PSK/QAM switch (intNumCar) { case 1: // intCarStartIndex = 4; dblCarScalingFactor = 1.0f; // Starting at 1500 Hz (scaling factors determined emperically to minimize crest factor) TODO: needs verification break; case 2: // intCarStartIndex = 3; dblCarScalingFactor = 0.53f; // Starting at 1400 Hz break; case 4: // intCarStartIndex = 2; dblCarScalingFactor = 0.29f; // Starting at 1200 Hz break; case 8: // intCarStartIndex = 0; dblCarScalingFactor = 0.17f; // Starting at 800 Hz } // Reenter to send rest of variable length packet frame if (pktFSK[pktMode]) goto Reenter; else ModPSKDataAndPlay(bytEncodedBytes, 0, 0, Chan); return; } ARDOPFlush(Chan); break; case 2: // use carriers 0-3 and 8-11 (50 baud only) dblCarScalingFactor = 0.6f; // (scaling factors determined emperically to minimize crest factor) for (m = 0; m < intDataBytesPerCar; m++) // For each byte of input data { bytMask = 0xC0; // Initialize mask each new data byte for (k = 0; k < 4; k++) // for 4 symbol values per byte of data { for (n = 0; n < intSampPerSym; n++) // for all the samples of a symbol for 2 carriers { //' First carrier bytSymToSend = (bytMask & bytEncodedBytes[intDataPtr]) >> (2 * (3 - k)); // Values 0-3 intSample = intFSK50bdCarTemplate[bytSymToSend][n]; // Second carrier bytSymToSend = (bytMask & bytEncodedBytes[intDataPtr + intDataBytesPerCar]) >> (2 * (3 - k)); // Values 0-3 intSample = SoftClip(dblCarScalingFactor * (intSample + intFSK50bdCarTemplate[8 + bytSymToSend][n])); ARDOPSampleSink(intSample); } bytMask = bytMask >> 2; } intDataPtr += 1; } ARDOPFlush(Chan); break; } } // Function to extract an 8PSK symbol from an encoded data array UCHAR GetSym8PSK(int intDataPtr, int k, int intCar, UCHAR * bytEncodedBytes, int intDataBytesPerCar) { int int3Bytes = bytEncodedBytes[intDataPtr + intCar * intDataBytesPerCar]; // int intMask = 7; int intSym; UCHAR bytSym; int3Bytes = int3Bytes << 8; int3Bytes += bytEncodedBytes[intDataPtr + intCar * intDataBytesPerCar + 1]; int3Bytes = int3Bytes << 8; int3Bytes += bytEncodedBytes[intDataPtr + intCar * intDataBytesPerCar + 2]; // now have 3 bytes, 24 bits or 8 8PSK symbols // intMask = intMask << (3 * (7 - k)); intSym = int3Bytes >> (3 * (7 - k)); bytSym = intSym & 7; //(intMask && int3Bytes) >> (3 * (7 - k)); return bytSym; } // Function to Modulate data encoded for PSK and 16QAM, create // the 16 bit samples and send to sound interface void ModPSKDataAndPlay(unsigned char * bytEncodedBytes, int Len, int intLeaderLen, int Chan) { int intNumCar, intBaud, intDataLen, intRSLen, intDataPtr, intSampPerSym, intDataBytesPerCar; BOOL blnOdd; int Type = bytEncodedBytes[0]; int intSample; char strType[18] = ""; char strMod[16] = ""; UCHAR bytSym, bytSymToSend, bytMinQualThresh; float dblCarScalingFactor; int intLeaderLenMS; int i, j, k, l = 4, n; int intCarStartIndex; int intPeakAmp; int intCarIndex; BOOL QAM = 0; UCHAR bytLastSym[43]; // = {0}; // Holds the last symbol sent (per carrier). bytLastSym(4) is 1500 Hz carrier (only used on 1 carrier modes) if (!FrameInfo(Type, &blnOdd, &intNumCar, strMod, &intBaud, &intDataLen, &intRSLen, &bytMinQualThresh, strType)) return; intDataBytesPerCar = (Len - 2) / intNumCar; // We queue the samples here, so dont copy below // These new scaling factor combined with soft clipping to provide near optimum scaling Jan 6, 2018 // The Test form was changed to calculate the Peak power to RMS power (PAPR) of the test waveform and count the number of "soft clips" out of ~ 50,000 samples. // These values arrived at emperically using the Test form (Quick brown fox message) to minimize PAPR at a minor decrease in maximum constellation quality if (strstr(strMod, "16QAM")) { // QAM Modes QAM = 1; l = 2; // 2 symbols per byte switch (intNumCar) { case 1: intCarStartIndex = 5; dblCarScalingFactor = 2.0f; // Starting at 1500 Hz Selected to give < 13% clipped values yielding a PAPR = 1.6 Constellation Quality >98 break; case 2: intCarStartIndex = 4; dblCarScalingFactor = 1.0f; break; case 10: intCarStartIndex = 0; dblCarScalingFactor = 0.4f; } } else // 4PSK { switch (intNumCar) { case 1: intCarStartIndex = 5; dblCarScalingFactor = 2.0f; // Starting at 1500 Hz Selected to give < 13% clipped values yielding a PAPR = 1.6 Constellation Quality >98 break; case 2: intCarStartIndex = 4; dblCarScalingFactor = 1.2f; break; case 10: intCarStartIndex = 0; dblCarScalingFactor = 0.35f; } } if (intBaud == 50) intSampPerSym = 240; else intSampPerSym = 120; if (Type == PktFrameData) { intDataBytesPerCar = pktDataLen + pktRSLen + 3; intDataPtr = 11; // Over Header goto PktLoopBack; } Debugprintf("Sending Frame Type %s", strType); DrawTXFrame(strType); if (intNumCar == 1) initFilter(200, 1500, Chan); else if (intNumCar == 2 || intNumCar == 9) initFilter(500, 1500, Chan); else initFilter(2500, 1500, Chan); if (intLeaderLen == 0) intLeaderLenMS = LeaderLength; else intLeaderLenMS = intLeaderLen; intSoftClipCnt = 0; // Create the leader SendLeaderAndSYNC(bytEncodedBytes, intLeaderLen); SendingHeader200 = FALSE; intPeakAmp = 0; intDataPtr = 2; // initialize pointer to start of data. PktLoopBack: // Reenter here to send rest of variable length packet frame // Now create a reference symbol for each carrier // We have to do each carrier for each sample, as we write // the sample immediately for (n = 0; n < intSampPerSym; n++) // Sum for all the samples of a symbols { intSample = 0; intCarIndex = intCarStartIndex; // initialize to correct starting carrier for (i = 0; i < intNumCar; i++) // across all carriers { bytSymToSend = 0; // using non 0 causes error on first data byte 12/8/2014 ...Values 0-3 not important (carries no data). (Possible chance for Crest Factor reduction?) bytLastSym[intCarIndex] = 0; intSample += intQAM50bdCarTemplate[intCarIndex][0][n % 120]; intCarIndex++; if (intCarIndex == 5) intCarIndex = 6; // skip over 1500 Hz for multi carrier modes (multi carrier modes all use even hundred Hz tones) } intSample = SoftClip(intSample * 0.5 * dblCarScalingFactor); ARDOPSampleSink(intSample); } // End of reference phase generation // Unlike ARDOP_WIN we send samples as they are created, // so we loop through carriers, then data bytes for (j = 0; j < intDataBytesPerCar; j++) // for each referance and data symbol { // Loop through each symbol of byte (4 for PSK 2 for QAM for (k = 0; k < l; k++) { for (n = 0; n < intSampPerSym; n++) { intSample = 0; intCarIndex = intCarStartIndex; // initialize the carrrier index for (i = 0; i < intNumCar; i++) // across all active carriers { if (QAM == 0) { bytSym = (bytEncodedBytes[intDataPtr + i * intDataBytesPerCar] >> (2 * (3 - k))) & 3; bytSymToSend = ((bytLastSym[intCarIndex] + bytSym) & 3); // Values 0-3 if (bytSymToSend < 2) // This uses the symmetry of the symbols to reduce the table size by a factor of 2 intSample += intQAM50bdCarTemplate[intCarIndex][2 * bytSymToSend][n % 120]; // double the symbol value during template lookup for 4PSK. (skips over odd PSK 8 symbols) else if (bytSymToSend < 4) intSample -= intQAM50bdCarTemplate[intCarIndex][2 * (bytSymToSend - 2)][n % 120]; // subtract 2 from the symbol value before doubling and subtract value of table } else { // For 16QAM the angle is sent differential but the amplitude is sent as is for the symbol...verified 4/20 2018 bytSym = (bytEncodedBytes[intDataPtr + i * intDataBytesPerCar] >> (4 * (1 - k))) & 15; bytSymToSend = ((bytLastSym[intCarIndex] & 7) + (bytSym & 7) & 7); // Compute the differential phase to send bytSymToSend = bytSymToSend | (bytSym & 8); // add in the amplitude bit directly from symbol // 4bits/symbol (use table symbol values 0, 1, 2, 3, -0, -1, -2, -3) and modulate amplitude with MSB if (bytSymToSend < 4)// This uses the symmetry of the symbols to reduce the table size by a factor of 2 intSample += intQAM50bdCarTemplate[intCarIndex][bytSymToSend][n % 120]; // double the symbol value during template lookup for 4PSK. (skips over odd PSK 8 symbols) else if (bytSymToSend < 8) intSample -= intQAM50bdCarTemplate[intCarIndex][(bytSymToSend - 4)][n % 120]; // subtract 4 from the symbol value before doubling and subtract value of table else if (bytSymToSend < 12) intSample += dblQAMCarRatio * intQAM50bdCarTemplate[intCarIndex][bytSymToSend - 8][n % 120]; // subtract 4 from the symbol value before doubling and subtract value of table else intSample -= dblQAMCarRatio * intQAM50bdCarTemplate[intCarIndex][bytSymToSend - 12][n % 120]; // subtract 4 from the symbol value before doubling and subtract value of table } if (n == intSampPerSym - 1) // Last sample? bytLastSym[intCarIndex] = bytSymToSend; intCarIndex += 1; if (intCarIndex == 5) intCarIndex = 6; // skip over 1500 Hz carrier for multicarrier modes } // Done all carriers - send sample intSample = SoftClip(intSample * 0.5 * dblCarScalingFactor); ARDOPSampleSink(intSample); } // Done all samples for this symbol // now next symbol of byte } intDataPtr++; } if (Type == PktFrameHeader) { // just sent packet header. Send rest in current mode Type = 0; // Prevent reentry strcpy(strMod, &pktMod[pktMode][0]); intDataBytesPerCar = pktDataLen + pktRSLen + 3; intDataPtr = 11; // Over Header intNumCar = pktCarriers[pktMode]; switch (intNumCar) { case 1: intCarStartIndex = 4; // dblCarScalingFactor = 1.0f; // Starting at 1500 Hz (scaling factors determined emperically to minimize crest factor) TODO: needs verification dblCarScalingFactor = 1.2f; // Starting at 1500 Hz Selected to give < 13% clipped values yielding a PAPR = 1.6 Constellation Quality >98 case 2: intCarStartIndex = 3; // dblCarScalingFactor = 0.53f; if (strcmp(strMod, "16QAM") == 0) dblCarScalingFactor = 0.67f; // Carriers at 1400 and 1600 Selected to give < 2.5% clipped values yielding a PAPR = 2.17, Constellation Quality >92 else dblCarScalingFactor = 0.65f; // Carriers at 1400 and 1600 Selected to give < 4% clipped values yielding a PAPR = 2.0, Constellation Quality >95 break; case 4: intCarStartIndex = 2; // dblCarScalingFactor = 0.29f; // Starting at 1200 Hz dblCarScalingFactor = 0.4f; // Starting at 1200 Hz Selected to give < 3% clipped values yielding a PAPR = 2.26, Constellation Quality >95 break; case 8: intCarStartIndex = 0; // dblCarScalingFactor = 0.17f; // Starting at 800 Hz if (strcmp(strMod, "16QAM") == 0) dblCarScalingFactor = 0.27f; // Starting at 800 Hz Selected to give < 1% clipped values yielding a PAPR = 2.64, Constellation Quality >94 else dblCarScalingFactor = 0.25f; // Starting at 800 Hz Selected to give < 2% clipped values yielding a PAPR = 2.5, Constellation Quality >95 } goto PktLoopBack; // Reenter to send rest of variable length packet frame } ARDOPFlush(Chan); if (intSoftClipCnt > 0) Debugprintf("Soft Clips %d ", intSoftClipCnt); } // Resends the last frame void RemodulateLastFrame(int Chan) { int intNumCar, intBaud, intDataLen, intRSLen; UCHAR bytMinQualThresh; BOOL blnOdd; char strType[18] = ""; char strMod[16] = ""; if (!FrameInfo(bytEncodedBytes[0], &blnOdd, &intNumCar, strMod, &intBaud, &intDataLen, &intRSLen, &bytMinQualThresh, strType)) return; if (strcmp(strMod, "4FSK") == 0) { Mod4FSKDataAndPlay(bytEncodedBytes, EncLen, intCalcLeader, Chan); // Modulate Data frame return; } if (strcmp(strMod, "OFDM") == 0) { int save = OFDMMode; OFDMMode = LastSentOFDMMode; ModOFDMDataAndPlay(bytEncodedBytes, EncLen, intCalcLeader, Chan); // Modulate Data frame OFDMMode = save; return; } ModPSKDataAndPlay(bytEncodedBytes, EncLen, intCalcLeader, Chan); // Modulate Data frame } // Filter State Variables static float dblR = (float)0.9995f; // insures stability (must be < 1.0) (Value .9995 7/8/2013 gives good results) static int intN = 120; //Length of filter 12000/100 static float dblRn; static float dblR2; static float dblCoef[34] = {0.0f}; // the coefficients float dblZin = 0, dblZin_1 = 0, dblZin_2 = 0, dblZComb= 0; // Used in the comb generator // The resonators float dblZout_0[34] = {0.0f}; // resonator outputs float dblZout_1[34] = {0.0f}; // resonator outputs delayed one sample float dblZout_2[34] = {0.0f}; // resonator outputs delayed two samples int fWidth; // Filter BandWidth int SampleNo; int outCount = 0; int first, last; // Filter slots int centreSlot; float largest = 0; float smallest = 0; short Last120[256]; // Now need 240 for 200 Hz filter int Last120Get = 0; int Last120Put = 120; extern int Number; // Number waiting to be sent UCHAR bytPendingSessionID; UCHAR bytSessionID = 0x3f; BOOL blnARQConnected; extern unsigned short buffer[2][1200]; unsigned short * DMABuffer; unsigned short * SendtoCard(unsigned short * buf, int n); unsigned short * SoundInit(); // initFilter is called to set up each packet. It selects filter width void initFilter(int Width, int Centre, int Chan) { int i, j; fWidth = Width; centreSlot = Centre / 100; largest = smallest = 0; SampleNo = 0; Number = 0; outCount = 0; memset(Last120, 0, 256); DMABuffer = &ARDOPTXBuffer[Chan][0]; // KeyPTT(TRUE); SoundIsPlaying = TRUE; // StopCapture(); Last120Get = 0; Last120Put = 120; dblRn = powf(dblR, intN); dblR2 = powf(dblR, 2); dblZin_2 = dblZin_1 = 0; switch (fWidth) { case 200: // Used for PSK 200 Hz modulation XMIT filter // implements 5 50 Hz wide sections centered on 1500 Hz (~200 Hz wide @ - 30dB centered on 1500 Hz) SendingHeader200 = TRUE; intN = 240; Last120Put = 240; centreSlot = Centre / 50; first = centreSlot - 3; last = centreSlot + 3; // 7 filter sections break; case 500: // implements 7 100 Hz wide sections centered on 1500 Hz (~500 Hz wide @ - 30dB centered on 1500 Hz) intN = 120; first = centreSlot - 3; last = centreSlot + 3; // 7 filter sections break; case 2500: // implements 26 100 Hz wide sections centered on 1500 Hz (~2000 Hz wide @ - 30dB centered on 1500 Hz) intN = 120; first = centreSlot - 13; last = centreSlot + 13; // 27 filter sections break; default: Debugprintf("Invalid Filter Width %d", fWidth); } for (j = first; j <= last; j++) { dblZout_0[j] = 0; dblZout_1[j] = 0; dblZout_2[j] = 0; } // Initialise the coefficients // if (dblCoef[last] == 0.0) { for (i = first; i <= last; i++) { double x = 2 * M_PI * i / intN; x = cosf(1); dblCoef[i] = 2.0 * dblR * cosf(2 * M_PI * i / intN); // For Frequency = bin i } } } void ARDOPSampleSink(short Sample) { // Filter and send to sound interface // This version is passed samples one at a time, as we don't have // enough RAM in embedded systems to hold a full audio frame int intFilLen = intN / 2; int j; float intFilteredSample = 0; // Filtered sample // We save the previous intN samples // The samples are held in a cyclic buffer if (SampleNo < intN) dblZin = Sample; else dblZin = Sample - dblRn * Last120[Last120Get]; if (++Last120Get == (intN + 1)) Last120Get = 0; // Compute the Comb dblZComb = dblZin - dblZin_2 * dblR2; dblZin_2 = dblZin_1; dblZin_1 = dblZin; // Now the resonators for (j = first; j <= last; j++) { dblZout_0[j] = dblZComb + dblCoef[j] * dblZout_1[j] - dblR2 * dblZout_2[j]; if (dblZout_0[j] != dblZout_0[j]) j = j; dblZout_2[j] = dblZout_1[j]; dblZout_1[j] = dblZout_0[j]; switch (fWidth) { case 200: // scale each by transition coeff and + (Even) or - (Odd) if (SampleNo >= intFilLen) { if (j == first || j == last) { if (SendingHeader200) intFilteredSample -= dblZout_0[j]; // This provides no attenuation to the Frame Type tones at 1350 and 1650 else intFilteredSample -= 0.1 * dblZout_0[j]; // This smaller value required to filter down to 200 Hz bandwidth } else if ((j & 1) == 0) intFilteredSample += (int)dblZout_0[j]; else intFilteredSample -= (int)dblZout_0[j]; } break; case 500: // scale each by transition coeff and + (Even) or - (Odd) // Resonators 12 and 18 scaled to get best shape and side lobe supression to - 45 dB while keeping BW at 500 Hz @ -26 dB // practical range of scaling .05 to .25 // Scaling also accomodates for the filter "gain" of approx 60. if (SampleNo >= intFilLen) { if (j == first || j == last) intFilteredSample += 0.389f * dblZout_0[j]; else if ((j & 1) == 0) intFilteredSample += (int)dblZout_0[j]; else intFilteredSample -= (int)dblZout_0[j]; } break; case 2500: // scale each by transition coeff and + (Even) or - (Odd) // Resonators 2 and 28 scaled to get best shape and side lobe supression to - 45 dB while keeping BW at 500 Hz @ -26 dB // practical range of scaling .05 to .25 // Scaling also accomodates for the filter "gain" of approx 60. if (SampleNo >= intFilLen) { if (j == first || j == last) intFilteredSample += 0.3891f * dblZout_0[j]; else if ((j & 1) == 0) // Even intFilteredSample += (int)dblZout_0[j]; else intFilteredSample -= (int)dblZout_0[j]; } } } if (SampleNo >= intFilLen) { intFilteredSample = intFilteredSample * 0.00833333333f; // rescales for gain of filter largest = max(largest, intFilteredSample); smallest = min(smallest, intFilteredSample); if (intFilteredSample > 32700) // Hard clip above 32700 intFilteredSample = 32700; else if (intFilteredSample < -32700) intFilteredSample = -32700; #ifdef TEENSY int work = (short)(intFilteredSample); DMABuffer[Number++] = (work + 32768) >> 4; // 12 bit left justify #else DMABuffer[Number++] = (short)intFilteredSample; #endif if (Number == ARDOPBufferSize) { // send this buffer to sound interface (shouldn't happen) DMABuffer = SendtoCard(DMABuffer, SendSize); Number = 0; } } Last120[Last120Put++] = Sample; if (Last120Put == (intN + 1)) Last120Put = 0; SampleNo++; } extern int dttTimeoutTrip; extern UCHAR bytSessionID; // Subroutine to make a CW ID Wave File void sendCWID(char * strID, BOOL CWOnOff, int Chan) { // This generates a phase synchronous FSK MORSE keying of strID // FSK used to maintain VOX on some sound cards // Sent at 90% of max ampllitude char strAlphabet[] = "ABCDEFGHIJKLMNOPQRSTUVWXYZ0123456789-/"; //Look up table for strAlphabet...each bit represents one dot time, 3 adjacent dots = 1 dash // one dot spacing between dots or dashes int intCW[] = {0x17, 0x1D5, 0x75D, 0x75, 0x1, 0x15D, 0x1DD, 0x55, 0x5, 0x1777, 0x1D7, 0x175, 0x77, 0x1D, 0x777, 0x5DD, 0x1DD7, 0x5D, 0x15, 0x7, 0x57, 0x157, 0x177, 0x757, 0x1D77, 0x775, 0x77777, 0x17777, 0x5777, 0x1577, 0x557, 0x155, 0x755, 0x1DD5, 0x7775, 0x1DDDD, 0x1D57, 0x1D57}; float dblHiPhaseInc = 2 * M_PI * 1509.375f / 12000; // 1609.375 Hz High tone float dblLoPhaseInc = 2 * M_PI * 1390.625f / 12000; // 1390.625 low tone float dblHiPhase = 0; float dblLoPhase = 0; int intDotSampCnt = 768; // about 12 WPM or so (should be a multiple of 256 short intDot[768]; short intSpace[768]; int i, j, k; int intAmp = 26000; // Selected to have some margin in calculations with 16 bit values (< 32767) this must apply to all filters as well. char * index; int intMask; int idoffset; int Filter = 1500; if (CWIDMark[0]) { // Want nonstandard tones float Mark = atof(CWIDMark); float Space = Mark - 200; dblHiPhaseInc = 2 * M_PI * Mark / 12000; // 1609.375 Hz High tone dblLoPhaseInc = 2 * M_PI * Space / 12000; // 1390.625 low tone if (CWOnOff) Filter = Mark; else Filter = (Mark + Space) / 2; } strlop(strID, '-'); // Remove any SSID // Generate the dot samples (high tone) and space samples (low tone) for (i = 0; i < intDotSampCnt; i++) { if (CWOnOff) intSpace[i] = 0; else intSpace[i] = sin(dblLoPhase) * 0.9 * intAmp; intDot[i] = sin(dblHiPhase) * 0.9 * intAmp; dblHiPhase += dblHiPhaseInc; if (dblHiPhase > 2 * M_PI) dblHiPhase -= 2 * M_PI; dblLoPhase += dblLoPhaseInc; if (dblLoPhase > 2 * M_PI) dblLoPhase -= 2 * M_PI; } if (CWOnOff) initFilter(500, Filter, Chan); else initFilter(200, Filter, Chan); // if sending 1500 cal tone send mark tone for 10 secs if (strcmp(strID, "1500TONE") == 0) { float m_amplitude = 30000.0f; float m_frequency = 1500.0f; float m_phase = 0.0; float m_time = 0.0; float m_deltaTime = 1.0f / 12000; float x; // generate sin wave in mono for (int sample = 0; sample < 120000; ++sample) { x = m_amplitude * sin(2 * M_PI * m_frequency * m_time + m_phase); ARDOPSampleSink(x); m_time += m_deltaTime; } ARDOPTXPtr[Chan] = 0; ARDOPTXLen[Chan] = Number; Number = 0; return; } //Generate leader for VOX 6 dots long for (k = 6; k >0; k--) for (i = 0; i < intDotSampCnt; i++) ARDOPSampleSink(intSpace[i]); for (j = 0; j < strlen(strID); j++) { index = strchr(strAlphabet, strID[j]); if (index) idoffset = index - &strAlphabet[0]; else idoffset = 0; intMask = 0x40000000; if (index == NULL) { // process this as a space adding 6 dots worth of space to the wave file for (k = 6; k >0; k--) for (i = 0; i < intDotSampCnt; i++) ARDOPSampleSink(intSpace[i]); } else { while (intMask > 0) // search for the first non 0 bit if (intMask & intCW[idoffset]) break; // intMask is pointing to the first non 0 entry else intMask >>= 1; // Right shift mask while (intMask > 0) // search for the first non 0 bit { if (intMask & intCW[idoffset]) for (i = 0; i < intDotSampCnt; i++) ARDOPSampleSink(intDot[i]); else for (i = 0; i < intDotSampCnt; i++) ARDOPSampleSink(intSpace[i]); intMask >>= 1; // Right shift mask } } // add 2 dot spaces for inter letter spacing for (k = 4; k >0; k--) for (i = 0; i < intDotSampCnt; i++) ARDOPSampleSink(intSpace[i]); } //add 3 spaces for the end tail // for (k = 6; k >0; k--) // for (i = 0; i < intDotSampCnt; i++) // ARDOPSampleSink(intSpace[i]); ARDOPTXPtr[Chan] = 0; ARDOPTXLen[Chan] = Number; Number = 0; }