// // This file is part of Dire Wolf, an amateur radio packet TNC. // // Copyright (C) 2011,2012,2013 John Langner, WB2OSZ // // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation, either version 2 of the License, or // (at your option) any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program. If not, see . // // #define DEBUG5 1 /* capture 9600 output to log files */ /*------------------------------------------------------------------ * * Module: demod_9600.c * * Purpose: Demodulator for scrambled baseband encoding. * * Input: Audio samples from either a file or the "sound card." * * Outputs: Calls hdlc_rec_bit() for each bit demodulated. * *---------------------------------------------------------------*/ #include #include #include #include #include #include #include #include #include "direwolf.h" #include "tune.h" #include "fsk_demod_state.h" #include "hdlc_rec.h" #include "demod_9600.h" #include "textcolor.h" #include "dsp.h" /* Add sample to buffer and shift the rest down. */ __attribute__((hot)) static inline void push_sample (float val, float *buff, int size) { int j; // TODO: memmove any faster? for (j = size - 1; j >= 1; j--) { buff[j] = buff[j-1]; } buff[0] = val; } /* FIR filter kernel. */ __attribute__((hot)) static inline float convolve (const float *data, const float *filter, int filter_size) { float sum = 0; int j; for (j=0; j= *ppeak) { *ppeak = in * fast_attack + *ppeak * (1. - fast_attack); } else { *ppeak = in * slow_decay + *ppeak * (1. - slow_decay); } if (in <= *pvalley) { *pvalley = in * fast_attack + *pvalley * (1. - fast_attack); } else { *pvalley = in * slow_decay + *pvalley * (1. - slow_decay); } if (*ppeak > *pvalley) { return ((in - 0.5 * (*ppeak + *pvalley)) / (*ppeak - *pvalley)); } return (0.0); } /*------------------------------------------------------------------ * * Name: demod_9600_init * * Purpose: Initialize the 9600 baud demodulator. * * Inputs: samples_per_sec - Number of samples per second. * Might be upsampled in hopes of * reducing the PLL jitter. * * baud - Data rate in bits per second. * * D - Address of demodulator state. * * Returns: None * *----------------------------------------------------------------*/ void demod_9600_init (int samples_per_sec, int baud, struct demodulator_state_s *D) { float fc; memset (D, 0, sizeof(struct demodulator_state_s)); //dw_printf ("demod_9600_init(rate=%d, baud=%d, D ptr)\n", samples_per_sec, baud); D->pll_step_per_sample = (int) round(TICKS_PER_PLL_CYCLE * (double) baud / (double)samples_per_sec); D->filter_len_bits = 72 * 9600.0 / (44100.0 * 2.0); D->lp_filter_size = (int) (( D->filter_len_bits * (float)samples_per_sec / baud) + 0.5); #if TUNE_LP_FILTER_SIZE D->lp_filter_size = TUNE_LP_FILTER_SIZE; #endif D->lpf_baud = 0.59; #ifdef TUNE_LPF_BAUD D->lpf_baud = TUNE_LPF_BAUD; #endif D->agc_fast_attack = 0.080; #ifdef TUNE_AGC_FAST D->agc_fast_attack = TUNE_AGC_FAST; #endif D->agc_slow_decay = 0.00012; #ifdef TUNE_AGC_SLOW D->agc_slow_decay = TUNE_AGC_SLOW; #endif D->pll_locked_inertia = 0.88; D->pll_searching_inertia = 0.67; #if defined(TUNE_PLL_LOCKED) && defined(TUNE_PLL_SEARCHING) D->pll_locked_inertia = TUNE_PLL_LOCKED; D->pll_searching_inertia = TUNE_PLL_SEARCHING; #endif fc = (float)baud * D->lpf_baud / (float)samples_per_sec; //dw_printf ("demod_9600_init: call gen_lowpass(fc=%.2f, , size=%d, )\n", fc, D->lp_filter_size); gen_lowpass (fc, D->lp_filter, D->lp_filter_size, BP_WINDOW_HAMMING); } /* end fsk_demod_init */ /*------------------------------------------------------------------- * * Name: demod_9600_process_sample * * Purpose: (1) Filter & slice the signal. * (2) Descramble it. * (2) Recover clock and data. * * Inputs: chan - Audio channel. 0 for left, 1 for right. * * sam - One sample of audio. * Should be in range of -32768 .. 32767. * * Returns: None * * Descripion: "9600 baud" packet is FSK for an FM voice transceiver. * By the time it gets here, it's really a baseband signal. * At one extreme, we could have a 4800 Hz square wave. * A the other extreme, we could go a considerable number * of bit times without any transitions. * * The trick is to extract the digital data which has * been distorted by going thru voice transceivers not * intended to pass this sort of "audio" signal. * * Data is "scrambled" to reduce the amount of DC bias. * The data stream must be unscrambled at the receiving end. * * We also have a digital phase locked loop (PLL) * to recover the clock and pick out data bits at * the proper rate. * * For each recovered data bit, we call: * * hdlc_rec (channel, demodulated_bit); * * to decode HDLC frames from the stream of bits. * * Future: This could be generalized by passing in the name * of the function to be called for each bit recovered * from the demodulator. For now, it's simply hard-coded. * * References: 9600 Baud Packet Radio Modem Design * http://www.amsat.org/amsat/articles/g3ruh/109.html * * The KD2BD 9600 Baud Modem * http://www.amsat.org/amsat/articles/kd2bd/9k6modem/ * * 9600 Baud Packet Handbook * ftp://ftp.tapr.org/general/9600baud/96man2x0.txt * * * TODO: This works in a simulated environment but it has not yet * been successfully tested for interoperability with * other systems over the air. * That's why it is not mentioned in documentation. * * The signal from the radio speaker does NOT have * enough bandwidth and the waveform is hopelessly distorted. * It will be necessary to obtain a signal right after * the discriminator of the receiver. * It will probably also be necessary to tap directly into * the modulator, bypassing the microphone amplifier. * *--------------------------------------------------------------------*/ __attribute__((hot)) void demod_9600_process_sample (int chan, int sam, struct demodulator_state_s *D) { float fsam; float abs_fsam; float amp; float demod_out; #if DEBUG5 static FILE *demod_log_fp = NULL; static int seq = 0; /* for log file name */ #endif int j; int subchan = 0; int demod_data; /* Still scrambled. */ static int descram; /* Data bit de-scrambled. */ assert (chan >= 0 && chan < MAX_CHANS); assert (subchan >= 0 && subchan < MAX_SUBCHANS); /* * Filters use last 'filter_size' samples. * * First push the older samples down. * * Finally, put the most recent at the beginning. * * Future project? Rather than shifting the samples, * it might be faster to add another variable to keep * track of the most recent sample and change the * indexing in the later loops that multipy and add. */ /* Scale to nice number, range -1.0 to +1.0. */ fsam = sam / 32768.0; push_sample (fsam, D->raw_cb, D->lp_filter_size); /* * Low pass filter to reduce noise yet pass the data. */ amp = convolve (D->raw_cb, D->lp_filter, D->lp_filter_size); /* * The input level can vary greatly. * More importantly, there could be a DC bias which we need to remove. * * Normalize the signal with automatic gain control (AGC). * This works by looking at the minimum and maximum signal peaks * and scaling the results to be roughly in the -1.0 to +1.0 range. */ demod_out = 2.0 * agc (amp, D->agc_fast_attack, D->agc_slow_decay, &(D->m_peak), &(D->m_valley)); //dw_printf ("peak=%.2f valley=%.2f amp=%.2f norm=%.2f\n", D->m_peak, D->m_valley, amp, norm); /* Throw in a little Hysteresis??? */ /* (Not to be confused with Hysteria.) */ if (demod_out > 0.01) { demod_data = 1; } else if (demod_out < -0.01) { demod_data = 0; } else { demod_data = D->prev_demod_data; } /* * Next, a PLL is used to sample near the centers of the data bits. * * D->data_clock_pll is a SIGNED 32 bit variable. * When it overflows from a large positive value to a negative value, we * sample a data bit from the demodulated signal. * * Ideally, the the demodulated signal transitions should be near * zero we we sample mid way between the transitions. * * Nudge the PLL by removing some small fraction from the value of * data_clock_pll, pushing it closer to zero. * * This adjustment will never change the sign so it won't cause * any erratic data bit sampling. * * If we adjust it too quickly, the clock will have too much jitter. * If we adjust it too slowly, it will take too long to lock on to a new signal. * * I don't think the optimal value will depend on the audio sample rate * because this happens for each transition from the demodulator. * * This was optimized for 1200 baud AFSK. There might be some opportunity * for improvement here. */ D->prev_d_c_pll = D->data_clock_pll; D->data_clock_pll += D->pll_step_per_sample; if (D->data_clock_pll < 0 && D->prev_d_c_pll > 0) { /* Overflow. */ /* * At this point, we need to descramble the data as * in hardware based designs by G3RUH and K9NG. * * http://www.amsat.org/amsat/articles/g3ruh/109/fig03.gif */ //assert (modem.modem_type[chan] == SCRAMBLE); //if (modem.modem_type[chan] == SCRAMBLE) { // TODO: This needs to be rearranged to allow attempted "fixing" // of corrupted bits later. We need to store the original // received bits and do the descrambling after attempted // repairs. However, we also need to descramble now to // detect the flag sequences. descram = descramble (demod_data, &(D->lfsr)); #if SLICENDICE // TODO: Needs more thought. // Does it even make sense to remember demod_out in this case? // We would need to do the re-thresholding before descrambling. //hdlc_rec_bit_sam (chan, subchan, descram, descram ? 1.0 : -1.0); #else // TODO: raw received bit and true later. hdlc_rec_bit (chan, subchan, descram, 0, D->lfsr); #endif //D->prev_descram = descram; //} //else { /* Baseband signal for completeness - not in common use. */ #if SLICENDICE //hdlc_rec_bit_sam (chan, subchan, demod_data, demod_data ? 1.0 : -1.0); #else //hdlc_rec_bit (chan, subchan, demod_data); #endif //} } if (demod_data != D->prev_demod_data) { // Note: Test for this demodulator, not overall for channel. if (hdlc_rec_data_detect_1 (chan, subchan)) { D->data_clock_pll = (int)(D->data_clock_pll * D->pll_locked_inertia); } else { D->data_clock_pll = (int)(D->data_clock_pll * D->pll_searching_inertia); } } #if DEBUG5 //if (chan == 0) { if (hdlc_rec_data_detect_1 (chan,subchan)) { char fname[30]; if (demod_log_fp == NULL) { seq++; sprintf (fname, "demod96/%04d.csv", seq); if (seq == 1) mkdir ("demod96" #ifndef __WIN32__ , 0777 #endif ); demod_log_fp = fopen (fname, "w"); text_color_set(DW_COLOR_DEBUG); dw_printf ("Starting 9600 decoder log file %s\n", fname); fprintf (demod_log_fp, "Audio, Peak, Valley, Demod, SData, Descram, Clock\n"); } fprintf (demod_log_fp, "%.3f, %.3f, %.3f, %.3f, %.2f, %.2f, %.2f\n", 0.5 * fsam + 3.5, 0.5 * D->m_peak + 3.5, 0.5 * D->m_valley + 3.5, 0.5 * demod_out + 2.0, demod_data ? 1.35 : 1.0, descram ? .9 : .55, (D->data_clock_pll & 0x80000000) ? .1 : .45); } else { if (demod_log_fp != NULL) { fclose (demod_log_fp); demod_log_fp = NULL; } } //} #endif /* * Remember demodulator output (pre-descrambling) so we can compare next time * for the DPLL sync. */ D->prev_demod_data = demod_data; } /* end demod_9600_process_sample */ /* end demod_9600.c */