//
// This file is part of Dire Wolf, an amateur radio packet TNC.
//
// Copyright (C) 2016, 2019 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 DEBUG1 1 /* display debugging info */
/*------------------------------------------------------------------
*
* Module: demod_psk.c
*
* Purpose: Demodulator for 2400 and 4800 bits per second Phase Shift Keying (PSK).
*
* Input: Audio samples from either a file or the "sound card."
*
* Outputs: Calls hdlc_rec_bit() for each bit demodulated.
*
* References: MFJ-2400 Product description and manual:
*
* http://www.mfjenterprises.com/Product.php?productid=MFJ-2400
* http://www.mfjenterprises.com/Downloads/index.php?productid=MFJ-2400&filename=MFJ-2400.pdf&company=mfj
*
* AEA had a 2400 bps packet modem, PK232-2400.
*
* http://www.repeater-builder.com/aea/pk232/pk232-2400-baud-dpsk-modem.pdf
*
* There was also a Kantronics KPC-2400 that had 2400 bps.
*
* http://www.brazoriacountyares.org/winlink-collection/TNC%20manuals/Kantronics/2400_modem_operators_guide@rgf.pdf
*
*
* From what I'm able to gather, they all used the EXAR XR-2123 PSK modem chip.
*
* Can't find the chip specs on the EXAR website so Google it.
*
* http://www.komponenten.es.aau.dk/fileadmin/komponenten/Data_Sheet/Linear/XR2123.pdf
*
* The XR-2123 implements the V.26 / Bell 201 standard:
*
* https://www.itu.int/rec/dologin_pub.asp?lang=e&id=T-REC-V.26-198811-I!!PDF-E&type=items
* https://www.itu.int/rec/dologin_pub.asp?lang=e&id=T-REC-V.26bis-198811-I!!PDF-E&type=items
* https://www.itu.int/rec/dologin_pub.asp?lang=e&id=T-REC-V.26ter-198811-I!!PDF-E&type=items
*
* "bis" and "ter" are from Latin for second and third.
* I used the "ter" version which has phase shifts of 0, 90, 180, and 270 degrees.
*
* There are ealier references to an alternative B which uses other phase shifts offset
* by another 45 degrees.
*
* After getting QPSK working, it was not much more effort to add V.27 with 8 phases.
*
* https://www.itu.int/rec/dologin_pub.asp?lang=e&id=T-REC-V.27bis-198811-I!!PDF-E&type=items
* https://www.itu.int/rec/dologin_pub.asp?lang=e&id=T-REC-V.27ter-198811-I!!PDF-E&type=items
*
* Compatibility:
* V.26 has two variations, A and B. Initially I implemented the A alternative.
* It later turned out that the MFJ-2400 used the B alternative. In version 1.6 you have a
* choice between compatibility with MFJ (and probably the others) or the original implementation.
*
*---------------------------------------------------------------*/
#include "direwolf.h"
#include
#include
#include
#include
#include
#include
#include
#include
// Fine tuning for different demodulator types.
#define DCD_THRESH_ON 30 // Hysteresis: Can miss 2 out of 32 for detecting lock.
#define DCD_THRESH_OFF 6 // Might want a little more fine tuning.
#define DCD_GOOD_WIDTH 512
#include "fsk_demod_state.h" // Values above override defaults.
#include "audio.h"
#include "tune.h"
#include "fsk_gen_filter.h"
#include "hdlc_rec.h"
#include "textcolor.h"
#include "demod_psk.h"
#include "dsp.h"
static const int phase_to_gray_v26[4] = {0, 1, 3, 2};
static const int phase_to_gray_v27[8] = {1, 0, 2, 3, 7, 6, 4, 5};
static int phase_shift_to_symbol (float phase_shift, int bits_per_symbol, int *bit_quality);
/* Add sample to buffer and shift the rest down. */
__attribute__((hot)) __attribute__((always_inline))
static inline void push_sample (float val, float *buff, int size)
{
memmove(buff+1,buff,(size-1)*sizeof(float));
buff[0] = val;
}
/* FIR filter kernel. */
__attribute__((hot)) __attribute__((always_inline))
static inline float convolve (const float *__restrict__ data, const float *__restrict__ filter, int filter_size)
{
float sum = 0.0;
int j;
//Does pragma make any difference? Annoying warning on Mac.
//#pragma GCC ivdep
for (j=0; jms_filter_size
*
* Returns: None.
*
* Bugs: This doesn't do much error checking so don't give it
* anything crazy.
*
*----------------------------------------------------------------*/
void demod_psk_init (enum modem_t modem_type, enum v26_e v26_alt, int samples_per_sec, int bps, char profile, struct demodulator_state_s *D)
{
int correct_baud; // baud is not same as bits/sec here!
int carrier_freq;
int j;
memset (D, 0, sizeof(struct demodulator_state_s));
D->modem_type = modem_type;
D->u.psk.v26_alt = v26_alt;
D->num_slicers = 1; // Haven't thought about this yet. Is it even applicable?
#ifdef TUNE_PROFILE
profile = TUNE_PROFILE;
#endif
if (modem_type == MODEM_QPSK) {
assert (D->u.psk.v26_alt != V26_UNSPECIFIED);
correct_baud = bps / 2;
carrier_freq = 1800;
#if DEBUG1
dw_printf ("demod_psk_init QPSK (sample rate=%d, bps=%d, baud=%d, carrier=%d, profile=%c\n",
samples_per_sec, bps, correct_baud, carrier_freq, profile);
#endif
switch (toupper(profile)) {
case 'P': /* Self correlation technique. */
D->u.psk.use_prefilter = 0; /* No bandpass filter. */
D->u.psk.lpf_baud = 0.60;
D->u.psk.lp_filter_width_sym = 1.061; // 39. * 1200. / 44100.;
D->u.psk.lp_window = BP_WINDOW_COSINE;
D->pll_locked_inertia = 0.95;
D->pll_searching_inertia = 0.50;
break;
case 'Q': /* Self correlation technique. */
D->u.psk.use_prefilter = 1; /* Add a bandpass filter. */
D->u.psk.prefilter_baud = 1.3;
D->u.psk.pre_filter_width_sym = 1.497; // 55. * 1200. / 44100.;
D->u.psk.pre_window = BP_WINDOW_COSINE;
D->u.psk.lpf_baud = 0.60;
D->u.psk.lp_filter_width_sym = 1.061; // 39. * 1200. / 44100.;
D->u.psk.lp_window = BP_WINDOW_COSINE;
D->pll_locked_inertia = 0.87;
D->pll_searching_inertia = 0.50;
break;
default:
text_color_set (DW_COLOR_ERROR);
dw_printf ("Invalid demodulator profile %c for v.26 QPSK. Valid choices are P, Q, R, S. Using default.\n", profile);
// fall thru.
case 'R': /* Mix with local oscillator. */
D->u.psk.psk_use_lo = 1;
D->u.psk.use_prefilter = 0; /* No bandpass filter. */
D->u.psk.lpf_baud = 0.70;
D->u.psk.lp_filter_width_sym = 1.007; // 37. * 1200. / 44100.;
D->u.psk.lp_window = BP_WINDOW_TRUNCATED;
D->pll_locked_inertia = 0.925;
D->pll_searching_inertia = 0.50;
break;
case 'S': /* Mix with local oscillator. */
D->u.psk.psk_use_lo = 1;
D->u.psk.use_prefilter = 1; /* Add a bandpass filter. */
D->u.psk.prefilter_baud = 0.55;
D->u.psk.pre_filter_width_sym = 2.014; // 74. * 1200. / 44100.;
D->u.psk.pre_window = BP_WINDOW_FLATTOP;
D->u.psk.lpf_baud = 0.60;
D->u.psk.lp_filter_width_sym = 1.061; // 39. * 1200. / 44100.;
D->u.psk.lp_window = BP_WINDOW_COSINE;
D->pll_locked_inertia = 0.925;
D->pll_searching_inertia = 0.50;
break;
}
D->u.psk.delay_line_width_sym = 1.25; // Delay line > 13/12 * symbol period
D->u.psk.coffs = (int) round( (11.f / 12.f) * (float)samples_per_sec / (float)correct_baud );
D->u.psk.boffs = (int) round( (float)samples_per_sec / (float)correct_baud );
D->u.psk.soffs = (int) round( (13.f / 12.f) * (float)samples_per_sec / (float)correct_baud );
}
else {
correct_baud = bps / 3;
carrier_freq = 1800;
#if DEBUG1
dw_printf ("demod_psk_init 8-PSK (sample rate=%d, bps=%d, baud=%d, carrier=%d, profile=%c\n",
samples_per_sec, bps, correct_baud, carrier_freq, profile);
#endif
switch (toupper(profile)) {
case 'T': /* Self correlation technique. */
D->u.psk.use_prefilter = 0; /* No bandpass filter. */
D->u.psk.lpf_baud = 1.15;
D->u.psk.lp_filter_width_sym = 0.871; // 32. * 1200. / 44100.;
D->u.psk.lp_window = BP_WINDOW_COSINE;
D->pll_locked_inertia = 0.95;
D->pll_searching_inertia = 0.50;
break;
case 'U': /* Self correlation technique. */
D->u.psk.use_prefilter = 1; /* Add a bandpass filter. */
D->u.psk.prefilter_baud = 0.9;
D->u.psk.pre_filter_width_sym = 0.571; // 21. * 1200. / 44100.;
D->u.psk.pre_window = BP_WINDOW_FLATTOP;
D->u.psk.lpf_baud = 1.15;
D->u.psk.lp_filter_width_sym = 0.871; // 32. * 1200. / 44100.;
D->u.psk.lp_window = BP_WINDOW_COSINE;
D->pll_locked_inertia = 0.87;
D->pll_searching_inertia = 0.50;
break;
default:
text_color_set (DW_COLOR_ERROR);
dw_printf ("Invalid demodulator profile %c for v.27 8PSK. Valid choices are T, U, V, W. Using default.\n", profile);
// fall thru.
case 'V': /* Mix with local oscillator. */
D->u.psk.psk_use_lo = 1;
D->u.psk.use_prefilter = 0; /* No bandpass filter. */
D->u.psk.lpf_baud = 0.85;
D->u.psk.lp_filter_width_sym = 0.844; // 31. * 1200. / 44100.;
D->u.psk.lp_window = BP_WINDOW_COSINE;
D->pll_locked_inertia = 0.925;
D->pll_searching_inertia = 0.50;
break;
case 'W': /* Mix with local oscillator. */
D->u.psk.psk_use_lo = 1;
D->u.psk.use_prefilter = 1; /* Add a bandpass filter. */
D->u.psk.prefilter_baud = 0.85;
D->u.psk.pre_filter_width_sym = 0.844; // 31. * 1200. / 44100.;
D->u.psk.pre_window = BP_WINDOW_COSINE;
D->u.psk.lpf_baud = 0.85;
D->u.psk.lp_filter_width_sym = 0.844; // 31. * 1200. / 44100.;
D->u.psk.lp_window = BP_WINDOW_COSINE;
D->pll_locked_inertia = 0.925;
D->pll_searching_inertia = 0.50;
break;
}
D->u.psk.delay_line_width_sym = 1.25; // Delay line > 10/9 * symbol period
D->u.psk.coffs = (int) round( (8.f / 9.f) * (float)samples_per_sec / (float)correct_baud );
D->u.psk.boffs = (int) round( (float)samples_per_sec / (float)correct_baud );
D->u.psk.soffs = (int) round( (10.f / 9.f) * (float)samples_per_sec / (float)correct_baud );
}
if (D->u.psk.psk_use_lo) {
D->u.psk.lo_step = (int) round( 256. * 256. * 256. * 256. * carrier_freq / (double)samples_per_sec);
// Our own sin table for speed later.
for (j = 0; j < 256; j++) {
D->u.psk.sin_table256[j] = sinf(2.f * (float)M_PI * j / 256.f);
}
}
#ifdef TUNE_PRE_BAUD
D->u.psk.prefilter_baud = TUNE_PRE_BAUD;
#endif
#ifdef TUNE_PRE_WINDOW
D->u.psk.pre_window = TUNE_PRE_WINDOW;
#endif
#ifdef TUNE_LPF_BAUD
D->u.psk.lpf_baud = TUNE_LPF_BAUD;
#endif
#ifdef TUNE_LP_WINDOW
D->u.psk.lp_window = TUNE_LP_WINDOW;
#endif
#if defined(TUNE_PLL_SEARCHING)
D->pll_searching_inertia = TUNE_PLL_SEARCHING;
#endif
#if defined(TUNE_PLL_LOCKED)
D->pll_locked_inertia = TUNE_PLL_LOCKED;
#endif
/*
* Calculate constants used for timing.
* The audio sample rate must be at least a few times the data rate.
*/
D->pll_step_per_sample = (int) round((TICKS_PER_PLL_CYCLE * (double)correct_baud) / ((double)samples_per_sec));
/*
* Convert number of symbol times to number of taps.
*/
D->u.psk.pre_filter_taps = (int) round( D->u.psk.pre_filter_width_sym * (float)samples_per_sec / (float)correct_baud );
D->u.psk.delay_line_taps = (int) round( D->u.psk.delay_line_width_sym * (float)samples_per_sec / (float)correct_baud );
D->u.psk.lp_filter_taps = (int) round( D->u.psk.lp_filter_width_sym * (float)samples_per_sec / (float)correct_baud );
#ifdef TUNE_PRE_FILTER_TAPS
D->u.psk.pre_filter_taps = TUNE_PRE_FILTER_TAPS;
#endif
#ifdef TUNE_lp_filter_taps
D->u.psk.lp_filter_taps = TUNE_lp_filter_taps;
#endif
if (D->u.psk.pre_filter_taps > MAX_FILTER_SIZE) {
text_color_set (DW_COLOR_ERROR);
dw_printf ("Calculated pre filter size of %d is too large.\n", D->u.psk.pre_filter_taps);
dw_printf ("Decrease the audio sample rate or increase the baud rate or\n");
dw_printf ("recompile the application with MAX_FILTER_SIZE larger than %d.\n",
MAX_FILTER_SIZE);
exit (1);
}
if (D->u.psk.delay_line_taps > MAX_FILTER_SIZE) {
text_color_set (DW_COLOR_ERROR);
dw_printf ("Calculated delay line size of %d is too large.\n", D->u.psk.delay_line_taps);
dw_printf ("Decrease the audio sample rate or increase the baud rate or\n");
dw_printf ("recompile the application with MAX_FILTER_SIZE larger than %d.\n",
MAX_FILTER_SIZE);
exit (1);
}
if (D->u.psk.lp_filter_taps > MAX_FILTER_SIZE) {
text_color_set (DW_COLOR_ERROR);
dw_printf ("Calculated low pass filter size of %d is too large.\n", D->u.psk.lp_filter_taps);
dw_printf ("Decrease the audio sample rate or increase the baud rate or\n");
dw_printf ("recompile the application with MAX_FILTER_SIZE larger than %d.\n",
MAX_FILTER_SIZE);
exit (1);
}
/*
* Optionally apply a bandpass ("pre") filter to attenuate
* frequencies outside the range of interest.
* It's a tradeoff. Attenuate frequencies outside the the range of interest
* but also distort the signal. This demodulator is not compuationally
* intensive so we can usually run both in parallel.
*/
if (D->u.psk.use_prefilter) {
float f1, f2;
f1 = carrier_freq - D->u.psk.prefilter_baud * correct_baud;
f2 = carrier_freq + D->u.psk.prefilter_baud * correct_baud;
#if DEBUG1
text_color_set(DW_COLOR_DEBUG);
dw_printf ("Generating prefilter %.0f to %.0f Hz.\n", (double)f1, (double)f2);
#endif
if (f1 <= 0) {
text_color_set (DW_COLOR_ERROR);
dw_printf ("Prefilter of %.0f to %.0f Hz doesn't make sense.\n", (double)f1, (double)f2);
f1 = 10;
}
f1 = f1 / (float)samples_per_sec;
f2 = f2 / (float)samples_per_sec;
gen_bandpass (f1, f2, D->u.psk.pre_filter, D->u.psk.pre_filter_taps, D->u.psk.pre_window);
}
/*
* Now the lowpass filter.
*/
float fc = correct_baud * D->u.psk.lpf_baud / (float)samples_per_sec;
gen_lowpass (fc, D->u.psk.lp_filter, D->u.psk.lp_filter_taps, D->u.psk.lp_window, 0);
/*
* No point in having multiple numbers for signal level.
*/
D->alevel_mark_peak = -1;
D->alevel_space_peak = -1;
#if 0
// QPSK - CSV format to make plot.
printf ("Phase shift degrees, bit 0, quality 0, bit 1, quality 1\n");
for (int degrees = 0; degrees <= 360; degrees++) {
float a = degrees * M_PI * 2./ 360.;
int bit_quality[3];
int new_gray = phase_shift_to_symbol (a, 2, bit_quality);
float offset = 3 * 1.5;
printf ("%d, ", degrees);
printf ("%.3f, ", offset + (new_gray & 1)); offset -= 1.5;
printf ("%.3f, ", offset + (bit_quality[0] / 100.)); offset -= 1.5;
printf ("%.3f, ", offset + ((new_gray >> 1) & 1)); offset -= 1.5;
printf ("%.3f\n", offset + (bit_quality[1] / 100.));
}
#endif
#if 0
// 8-PSK - CSV format to make plot.
printf ("Phase shift degrees, bit 0, quality 0, bit 1, quality 1, bit 2, quality 2\n");
for (int degrees = 0; degrees <= 360; degrees++) {
float a = degrees * M_PI * 2./ 360.;
int bit_quality[3];
int new_gray = phase_shift_to_symbol (a, 3, bit_quality);
float offset = 5 * 1.5;
printf ("%d, ", degrees);
printf ("%.3f, ", offset + (new_gray & 1)); offset -= 1.5;
printf ("%.3f, ", offset + (bit_quality[0] / 100.)); offset -= 1.5;
printf ("%.3f, ", offset + ((new_gray >> 1) & 1)); offset -= 1.5;
printf ("%.3f, ", offset + (bit_quality[1] / 100.)); offset -= 1.5;
printf ("%.3f, ", offset + ((new_gray >> 2) & 1)); offset -= 1.5;
printf ("%.3f\n", offset + (bit_quality[2] / 100.));
}
#endif
} /* demod_psk_init */
/*-------------------------------------------------------------------
*
* Name: phase_shift_to_symbol
*
* Purpose: Translate phase shift, between two symbols, into 2 or 3 bits.
*
* Inputs: phase_shift - in radians.
*
* bits_per_symbol - 2 for QPSK, 3 for 8PSK.
*
* Outputs: bit_quality[] - Value of 0 (at threshold) to 100 (perfect) for each bit.
*
* Returns: 2 or 3 bit symbol value in Gray code.
*
*--------------------------------------------------------------------*/
__attribute__((hot)) __attribute__((always_inline))
static inline int phase_shift_to_symbol (float phase_shift, int bits_per_symbol, int * __restrict__ bit_quality)
{
// Number of different symbol states.
assert (bits_per_symbol == 2 || bits_per_symbol == 3);
int N = 1 << bits_per_symbol;
assert (N == 4 || N == 8);
// Scale angle to 1 per symbol then separate into integer and fractional parts.
float a = phase_shift * (float)N / (M_PI * 2.0f);
while (a >= (float)N) a -= (float)N;
while (a < 0.) a += (float)N;
int i = (int)a;
if (i == N) i = N-1; // Should be < N. Watch out for possible roundoff errors.
float f = a - (float)i;
assert (i >= 0 && i < N);
assert (f >= -0.001f && f <= 1.001f);
// Interpolate between the ideal angles to get a level of certainty.
int result = 0;
for (int b = 0; b < bits_per_symbol; b++) {
float demod = bits_per_symbol == 2 ?
((phase_to_gray_v26[i] >> b) & 1) * (1.0f - f) + ((phase_to_gray_v26[(i+1)&3] >> b) & 1) * f :
((phase_to_gray_v27[i] >> b) & 1) * (1.0f - f) + ((phase_to_gray_v27[(i+1)&7] >> b) & 1) * f;
// Slice to get boolean value and quality measurement.
if (demod >= 0.5f) result |= 1<= 0 && chan < MAX_CHANS);
assert (subchan >= 0 && subchan < MAX_SUBCHANS);
/* Scale to nice number for plotting during debug. */
float fsam = sam / 16384.0f;
/*
* Optional bandpass filter before the phase detector.
*/
if (D->u.psk.use_prefilter) {
push_sample (fsam, D->u.psk.audio_in, D->u.psk.pre_filter_taps);
fsam = convolve (D->u.psk.audio_in, D->u.psk.pre_filter, D->u.psk.pre_filter_taps);
}
if (D->u.psk.psk_use_lo) {
/*
* Mix with local oscillator to obtain phase.
* The absolute phase doesn't matter.
* We are just concerned with the change since the previous symbol.
*/
float sam_x_cos = fsam * D->u.psk.sin_table256[((D->u.psk.lo_phase >> 24) + 64) & 0xff];
push_sample (sam_x_cos, D->u.psk.I_raw, D->u.psk.lp_filter_taps);
float I = convolve (D->u.psk.I_raw, D->u.psk.lp_filter, D->u.psk.lp_filter_taps);
float sam_x_sin = fsam * D->u.psk.sin_table256[(D->u.psk.lo_phase >> 24) & 0xff];
push_sample (sam_x_sin, D->u.psk.Q_raw, D->u.psk.lp_filter_taps);
float Q = convolve (D->u.psk.Q_raw, D->u.psk.lp_filter, D->u.psk.lp_filter_taps);
float a = my_atan2f(I,Q);
// This is just a delay line of one symbol time.
push_sample (a, D->u.psk.delay_line, D->u.psk.delay_line_taps);
float delta = a - D->u.psk.delay_line[D->u.psk.boffs];
int gray;
int bit_quality[3];
if (D->modem_type == MODEM_QPSK) {
if (D->u.psk.v26_alt == V26_B) {
gray = phase_shift_to_symbol (delta + (float)(-M_PI/4), 2, bit_quality);; // MFJ compatible
}
else {
gray = phase_shift_to_symbol (delta, 2, bit_quality); // Classic
}
}
else {
gray = phase_shift_to_symbol (delta, 3, bit_quality);; // 8-PSK
}
nudge_pll (chan, subchan, slice, gray, D, bit_quality);
D->u.psk.lo_phase += D->u.psk.lo_step;
}
else {
/*
* Correlate with previous symbol. We are looking for the phase shift.
*/
push_sample (fsam, D->u.psk.delay_line, D->u.psk.delay_line_taps);
float sam_x_cos = fsam * D->u.psk.delay_line[D->u.psk.coffs];
push_sample (sam_x_cos, D->u.psk.I_raw, D->u.psk.lp_filter_taps);
float I = convolve (D->u.psk.I_raw, D->u.psk.lp_filter, D->u.psk.lp_filter_taps);
float sam_x_sin = fsam * D->u.psk.delay_line[D->u.psk.soffs];
push_sample (sam_x_sin, D->u.psk.Q_raw, D->u.psk.lp_filter_taps);
float Q = convolve (D->u.psk.Q_raw, D->u.psk.lp_filter, D->u.psk.lp_filter_taps);
int gray;
int bit_quality[3];
float delta = my_atan2f(I,Q);
if (D->modem_type == MODEM_QPSK) {
if (D->u.psk.v26_alt == V26_B) {
gray = phase_shift_to_symbol (delta + (float)(M_PI/2), 2, bit_quality); // MFJ compatible
}
else {
gray = phase_shift_to_symbol (delta + (float)(3*M_PI/4), 2, bit_quality); // Classic
}
}
else {
gray = phase_shift_to_symbol (delta + (float)(3*M_PI/2), 3, bit_quality);
}
nudge_pll (chan, subchan, slice, gray, D, bit_quality);
}
} /* end demod_psk_process_sample */
__attribute__((hot))
static void nudge_pll (int chan, int subchan, int slice, int demod_bits, struct demodulator_state_s *D, int *bit_quality)
{
/*
* Finally, a PLL is used to sample near the centers of the data bits.
*
* D points to a demodulator for a channel/subchannel pair.
*
* 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.
*
* Be a little more agressive about adjusting the PLL
* phase when searching for a signal.
* Don't change it as much when locked on to a signal.
*/
D->slicer[slice].prev_d_c_pll = D->slicer[slice].data_clock_pll;
// Perform the add as unsigned to avoid signed overflow error.
D->slicer[slice].data_clock_pll = (signed)((unsigned)(D->slicer[slice].data_clock_pll) + (unsigned)(D->pll_step_per_sample));
if (D->slicer[slice].data_clock_pll < 0 && D->slicer[slice].prev_d_c_pll >= 0) {
/* Overflow of PLL counter. */
/* This is where we sample the data. */
if (D->modem_type == MODEM_QPSK) {
int gray = demod_bits;
hdlc_rec_bit (chan, subchan, slice, (gray >> 1) & 1, 0, bit_quality[1]);
hdlc_rec_bit (chan, subchan, slice, gray & 1, 0, bit_quality[0]);
}
else {
int gray = demod_bits;
hdlc_rec_bit (chan, subchan, slice, (gray >> 2) & 1, 0, bit_quality[2]);
hdlc_rec_bit (chan, subchan, slice, (gray >> 1) & 1, 0, bit_quality[1]);
hdlc_rec_bit (chan, subchan, slice, gray & 1, 0, bit_quality[0]);
}
pll_dcd_each_symbol2 (D, chan, subchan, slice);
}
/*
* If demodulated data has changed,
* Pull the PLL phase closer to zero.
* Use "floor" instead of simply casting so the sign won't flip.
* For example if we had -0.7 we want to end up with -1 rather than 0.
*/
// TODO: demod_9600 has an improved technique. Would it help us here?
if (demod_bits != D->slicer[slice].prev_demod_data) {
pll_dcd_signal_transition2 (D, slice, D->slicer[slice].data_clock_pll);
if (D->slicer[slice].data_detect) {
D->slicer[slice].data_clock_pll = (int)floorf((float)(D->slicer[slice].data_clock_pll) * D->pll_locked_inertia);
}
else {
D->slicer[slice].data_clock_pll = (int)floorf((float)(D->slicer[slice].data_clock_pll) * D->pll_searching_inertia);
}
}
/*
* Remember demodulator output so we can compare next time.
*/
D->slicer[slice].prev_demod_data = demod_bits;
} /* end nudge_pll */
/* end demod_psk.c */