mirror of
https://github.com/dj0abr/SSB_HighSpeed_Modem.git
synced 2024-11-25 13:48:47 -05:00
425 lines
12 KiB
C++
Executable File
425 lines
12 KiB
C++
Executable File
/*
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* High Speed modem to transfer data in a 2,7kHz SSB channel
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* =========================================================
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* Author: DJ0ABR
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*
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* (c) DJ0ABR
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* www.dj0abr.de
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
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*
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* liquid_if.c ... functions using liquid-dsp
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*
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* liquid-dsp must be previously installed by running ./liquid-dsp-install (under linux)
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*
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*/
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#include "hsmodem.h"
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void modulator(uint8_t sym_in);
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void init_demodulator();
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void close_demodulator();
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void init_modulator();
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void close_modulator();
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void init_dsp()
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{
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init_modulator();
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pb_write_fifo_clear();
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init_demodulator();
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}
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void close_dsp()
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{
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close_modulator();
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close_demodulator();
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}
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modulation_scheme getMod()
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{
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if(bitsPerSymbol == 2)
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return LIQUID_MODEM_QPSK;
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else
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{
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return LIQUID_MODEM_APSK8;
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}
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}
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// =========== MODULATOR ==================================================
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// modem objects
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modem mod = NULL;
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// NCOs for mixing baseband <-> 1500 Hz
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#define FREQUENCY 1500
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int type = LIQUID_NCO; // nco type
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nco_crcf upnco = NULL;
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// TX-Interpolator Filter Parameters
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// 44100 input rate for 2205 Sym/s = 20
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// change for other rates
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firinterp_crcf TX_interpolator = NULL;
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unsigned int k_SampPerSymb = 20; // 44100 / (4410/2)
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unsigned int m_filterDelay_Symbols = 15; // not too short for good filter
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float beta_excessBW = 0.2f; // filter excess bandwidth factor
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float tau_FracSymbOffset = -0.2f; // fractional symbol offset
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void init_modulator()
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{
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close_dsp();
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printf("init TX modulator\n");
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k_SampPerSymb = txinterpolfactor;
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// create modulator
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mod = modem_create(getMod());
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// create NCO for upmixing to 1500 Hz
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float RADIANS_PER_SAMPLE = ((2.0f*(float)M_PI*(float)FREQUENCY)/(float)caprate);
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upnco = nco_crcf_create(LIQUID_NCO);
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nco_crcf_set_phase(upnco, 0.0f);
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nco_crcf_set_frequency(upnco, RADIANS_PER_SAMPLE);
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// TX: Interpolator Filter
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// compute delay
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while (tau_FracSymbOffset < 0) tau_FracSymbOffset += 1.0f; // ensure positive tau
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float g = k_SampPerSymb*tau_FracSymbOffset; // number of samples offset
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int ds=(int)floorf(g); // additional symbol delay
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float dt = (g - (float)ds); // fractional sample offset
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// force dt to be in [0.5,0.5]
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if (dt > 0.5f)
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{
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dt -= 1.0f;
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ds++;
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}
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// calculate filter coeffs
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unsigned int h_len_NumFilterCoeefs = 2 * k_SampPerSymb * m_filterDelay_Symbols + 1;
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float h[1000];
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if (h_len_NumFilterCoeefs >= 1000)
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{
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printf("h in h_len_NumFilterCoeefs too small\n");
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return;
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}
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liquid_firdes_prototype( LIQUID_FIRFILT_RRC,
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k_SampPerSymb,
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m_filterDelay_Symbols,
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beta_excessBW,
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dt,
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h);
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// create the filter
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TX_interpolator = firinterp_crcf_create(k_SampPerSymb,h,h_len_NumFilterCoeefs);
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printf("DSP created\n");
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return;
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}
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void close_modulator()
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{
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if(mod != NULL) modem_destroy(mod);
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if(upnco != NULL) nco_crcf_destroy(upnco);
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if(TX_interpolator != NULL) firinterp_crcf_destroy(TX_interpolator);
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mod = NULL;
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upnco = NULL;
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TX_interpolator = NULL;
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}
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// d ... symbols to send
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// len ... number of symbols in d
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void sendToModulator(uint8_t *d, int len)
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{
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if(upnco == NULL) return;
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int symanz = len * 8 / bitsPerSymbol;
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uint8_t syms[10000];
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if (symanz >= 10000)
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{
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printf("syms in symanz too small\n");
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return;
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}
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if(bitsPerSymbol == 2)
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convertBytesToSyms_QPSK(d, syms, len);
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else
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convertBytesToSyms_8PSK(d, syms, len);
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for(int i=0; i<symanz; i++)
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{
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// remove gray code
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// this adds gray code, liquid adds it again which removes it
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if(bitsPerSymbol == 2) syms[i] ^= (syms[i]>>1);
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modulator(syms[i]);
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}
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}
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// call for every symbol
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// modulates, filters and upmixes symbols and send it to soundcard
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void modulator(uint8_t sym_in)
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{
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liquid_float_complex sample;
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modem_modulate(mod, sym_in, &sample);
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//printf("TX ================= sample: %f + i%f\n", sample.real, sample.imag);
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// interpolate by k_SampPerSymb
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liquid_float_complex y[100];
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if (k_SampPerSymb >= 100)
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{
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printf("y in k_SampPerSymb too small\n");
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return;
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}
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firinterp_crcf_execute(TX_interpolator, sample, y);
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for(unsigned int i=0; i<k_SampPerSymb; i++)
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{
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// move sample to 1,5kHz carrier
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nco_crcf_step(upnco);
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liquid_float_complex c;
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nco_crcf_mix_up(upnco,y[i],&c);
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float usb = c.real + c.imag;
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// adapt speed to soundcard samplerate
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int fs;
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while(1)
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{
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fs = pb_fifo_freespace(0);
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// wait until there is space in fifo
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if(fs) break;
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sleep_ms(10);
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}
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pb_write_fifo(usb * 0.2f); // reduce volume and send to soundcard
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}
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}
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// =========== DEMODULATOR =============================
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nco_crcf dnnco = NULL;
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symtrack_cccf symtrack = NULL;
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firdecim_crcf decim = NULL;
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// decimator parameters
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unsigned int m_predec = 8; // filter delay
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float As_predec = 40.0f; // stop-band att
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// symtrack parameters
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int ftype_st = LIQUID_FIRFILT_RRC;
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unsigned int k_st = 4; // samples per symbol
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unsigned int m_st = 7; // filter delay (symbols)
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float beta_st = beta_excessBW;//0.30f; // filter excess bandwidth factor
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float bandwidth_st = 0.9f; // loop filter bandwidth
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uint8_t maxLevel = 0; // maximum level over the last x samples in %
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void init_demodulator()
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{
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printf("init RX demodulator\n");
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// downmixer oscillator
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float RADIANS_PER_SAMPLE = ((2.0f*(float)M_PI*(float)FREQUENCY)/(float)caprate);
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dnnco = nco_crcf_create(LIQUID_NCO);
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nco_crcf_set_phase(dnnco, 0.0f);
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nco_crcf_set_frequency(dnnco, RADIANS_PER_SAMPLE);
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// create pre-decimator
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decim = firdecim_crcf_create_kaiser(rxPreInterpolfactor, m_predec, As_predec);
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firdecim_crcf_set_scale(decim, 1.0f/(float)rxPreInterpolfactor);
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// create symbol tracking synchronizer
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//k_st = txinterpolfactor;
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//symtrack = km_symtrack_cccf_create(ftype_st,k_st,m_st,beta_st,getMod());
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km_symtrack_cccf_create(ftype_st, k_st, m_st, beta_st, getMod());
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//symtrack_cccf_set_bandwidth(symtrack,bandwidth_st);
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km_symtrack_cccf_set_bandwidth(bandwidth_st);
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}
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void close_demodulator()
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{
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if(decim != NULL) firdecim_crcf_destroy(decim);
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symtrack = NULL;
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decim = NULL;
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}
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void resetModem()
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{
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//printf("Reset Symtrack\n");
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km_symtrack_cccf_reset(0xff);
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}
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// called for Audio-Samples (FFT)
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void make_FFTdata(float f)
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{
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// send IQ data to FFT for waterfall calculation
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int fftlen = 0;
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uint16_t* fft = make_waterfall(f, &fftlen);
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if (fft != NULL)
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{
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uint8_t txpl[10000];
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if (fftlen > (10000 * 2 + 1))
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{
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printf("GRdata_FFTdata: txpl too small !!!\n");
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return;
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}
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int bidx = 0;
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txpl[bidx++] = 4; // type 4: FFT data follows
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int us = pb_fifo_usedBlocks();
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if (us > 255 || ann_running == 1) us = 255;
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txpl[bidx++] = us; // usage of TX fifo
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us = cap_fifo_usedPercent();
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if (us > 255) us = 255;
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txpl[bidx++] = us; // usage of TX fifo
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txpl[bidx++] = rxlevel_deteced; // RX level present
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txpl[bidx++] = rx_in_sync;
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for (int i = 0; i < fftlen; i++)
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{
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txpl[bidx++] = fft[i] >> 8;
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txpl[bidx++] = fft[i] & 0xff;
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}
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sendUDP(appIP, UdpDataPort_ModemToApp, txpl, bidx);
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}
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}
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#define MCHECK 1000
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void getMax(float fv)
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{
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static float farr[MCHECK];
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static int idx = 0;
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static int f = 1;
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if (f)
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{
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f = 0;
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for (int i = 0; i < MCHECK; i++)
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farr[i] = 1;
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}
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farr[idx] = fv;
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idx++;
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if (idx == MCHECK)
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{
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idx = 0;
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float max = 0;
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for (int i = 0; i < MCHECK; i++)
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{
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if (farr[i] > max) max = farr[i];
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}
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maxLevel = (uint8_t)(max*100);
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//printf("max: %10.6f\n", max);
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}
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}
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int demodulator()
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{
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static liquid_float_complex ccol[100];
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static int ccol_idx = 0;
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if(dnnco == NULL) return 0;
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// get one received sample
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float f;
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int ret = cap_read_fifo(&f);
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if(ret == 0) return 0;
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// input volume
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f *= softwareCAPvolume;
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getMax(f);
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make_FFTdata(f*60);
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// downconvert into baseband
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// still at soundcard sample rate
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nco_crcf_step(dnnco);
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liquid_float_complex in;
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in.real = f;
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in.imag = f;
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liquid_float_complex c;
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nco_crcf_mix_down(dnnco,in,&c);
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// c is the actual sample, converted to complex and shifted to baseband
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// this is the first decimator. We need to collect rxPreInterpolfactor number of samples
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// then call execute which will give us one decimated sample
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ccol[ccol_idx++] = c;
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if(ccol_idx < rxPreInterpolfactor) return 1;
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ccol_idx = 0;
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// we have rxPreInterpolfactor samples in ccol
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//printf("sc:%10.6f dn:%10.6f j%10.6f ", f, c.real, c.imag);
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liquid_float_complex y;
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firdecim_crcf_execute(decim, ccol, &y);
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unsigned int num_symbols_sync;
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liquid_float_complex syms;
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//symtrack_cccf_execute(symtrack, y, &syms, &num_symbols_sync);
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unsigned int nsym_out; // output symbol
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km_symtrack_execute(y, &syms, &num_symbols_sync,&nsym_out);
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if(num_symbols_sync > 1) printf("symtrack_cccf_execute %d output symbols ???\n",num_symbols_sync);
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if(num_symbols_sync != 0)
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{
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unsigned int sym_out; // output symbol
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sym_out = nsym_out;
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measure_speed_syms(1);
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// try to extract a complete frame
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uint8_t symb = sym_out;
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if(bitsPerSymbol == 2) symb ^= (symb>>1);
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GRdata_rxdata(&symb, 1, NULL);
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// send the data "as is" to app for Constellation Diagram
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// we have about 2000 S/s, but this many points would make the GUI slow
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// so we send only every x
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static int ev = 0;
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if (++ev >= 10)
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{
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ev = 0;
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int32_t re = (int32_t)(syms.real * 16777216.0);
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int32_t im = (int32_t)(syms.imag * 16777216.0);
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uint8_t txpl[13];
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int idx = 0;
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txpl[idx++] = 5; // type 5: IQ data follows
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uint32_t sy = 0x3e8;
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txpl[idx++] = sy >> 24;
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txpl[idx++] = sy >> 16;
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txpl[idx++] = sy >> 8;
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txpl[idx++] = sy;
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txpl[idx++] = re >> 24;
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txpl[idx++] = re >> 16;
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txpl[idx++] = re >> 8;
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txpl[idx++] = re;
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txpl[idx++] = im >> 24;
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txpl[idx++] = im >> 16;
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txpl[idx++] = im >> 8;
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txpl[idx++] = im;
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sendUDP(appIP, UdpDataPort_ModemToApp, txpl, 13);
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}
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}
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return 1;
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}
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