//#define DEBUG 1 // // This file is part of Dire Wolf, an amateur radio packet TNC. // // Copyright (C) 2013, 2014, 2015, 2016 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 . // /*------------------------------------------------------------------ * * Module: dtmf.c * * Purpose: Decoder for DTMF, commonly known as "touch tones." * * Description: This uses the Goertzel Algorithm for tone detection. * * References: http://eetimes.com/design/embedded/4024443/The-Goertzel-Algorithm * http://www.ti.com/ww/cn/uprogram/share/ppt/c5000/17dtmf_v13.ppt * * Revisions: 1.4 - Added transmit capability. * *---------------------------------------------------------------*/ #include "direwolf.h" #include #include #include #include #include #include "dtmf.h" #include "hdlc_rec.h" // for dcd_change #include "textcolor.h" #include "gen_tone.h" #if DTMF_TEST #define TIMEOUT_SEC 1 /* short for unit test below. */ #define DEBUG 1 // Don't remove this. We want more output for test. #else #define TIMEOUT_SEC 5 /* for normal operation. */ #endif #define NUM_TONES 8 static int const dtmf_tones[NUM_TONES] = { 697, 770, 852, 941, 1209, 1336, 1477, 1633 }; /* * Current state of the DTMF decoding. */ static struct dd_s { /* Separate for each audio channel. */ int sample_rate; /* Samples per sec. Typ. 44100, 8000, etc. */ int block_size; /* Number of samples to process in one block. */ float coef[NUM_TONES]; int n; /* Samples processed in this block. */ float Q1[NUM_TONES]; float Q2[NUM_TONES]; char prev_dec; char debounced; char prev_debounced; int timeout; } dd[MAX_CHANS]; static int s_amplitude = 100; // range of 0 .. 100 static void push_button (int chan, char button, int ms); /*------------------------------------------------------------------ * * Name: dtmf_init * * Purpose: Initialize the DTMF decoder. * This should be called once at application start up time. * * Inputs: p_audio_config - Configuration for audio interfaces. * * All we care about is: * * samples_per_sec - Audio sample frequency, typically * 44100, 22050, 8000, etc. * * This is a associated with the soundcard. * In version 1.2, we can have multiple soundcards * with potentially different sample rates. * * amp - Signal amplitude, for transmit, on scale of 0 .. 100. * * 100 will produce maximum amplitude of +-32k samples. * * Returns: None. * *----------------------------------------------------------------*/ void dtmf_init (struct audio_s *p_audio_config, int amp) { int j; /* Loop over all tones frequencies. */ int c; /* Loop over all audio channels. */ s_amplitude = amp; /* * Pick a suitable processing block size. * Larger = narrower bandwidth, slower response. */ for (c=0; csample_rate = p_audio_config->adev[a].samples_per_sec; if (p_audio_config->achan[c].dtmf_decode != DTMF_DECODE_OFF) { #if DEBUG text_color_set(DW_COLOR_DEBUG); dw_printf ("channel %d:\n", c); #endif D->block_size = (205 * D->sample_rate) / 8000; #if DEBUG dw_printf (" freq k coef \n"); #endif for (j=0; jblock_size * (float)(dtmf_tones[j]) / (float)(D->sample_rate); D->coef[j] = 2.0f * cosf(2.0f * (float)M_PI * (float)k / (float)(D->block_size)); assert (D->coef[j] > 0.0f && D->coef[j] < 2.0f); #if DEBUG dw_printf ("%8d %5.1f %8.5f \n", dtmf_tones[j], k, D->coef[j]); #endif } } } for (c=0; cn = 0; for (j=0; jQ1[j] = 0; D->Q2[j] = 0; } D->prev_dec = ' '; D->debounced = ' '; D->prev_debounced = ' '; D->timeout = 0; } } /*------------------------------------------------------------------ * * Name: dtmf_sample * * Purpose: Process one audio sample from the sound input source. * * Inputs: c - Audio channel number. * This can process multiple channels in parallel. * input - Audio sample. * * Returns: 0123456789ABCD*# for a button push. * . for nothing happening during sample interval. * $ after several seconds of inactivity. * space between sample intervals. * * *----------------------------------------------------------------*/ __attribute__((hot)) char dtmf_sample (int c, float input) { int i; float Q0; float output[NUM_TONES]; char decoded; char ret; struct dd_s *D; static const char rc2char[16] = { '1', '2', '3', 'A', '4', '5', '6', 'B', '7', '8', '9', 'C', '*', '0', '#', 'D' }; D = &(dd[c]); for (i=0; iQ1[i] * D->coef[i] - D->Q2[i]; D->Q2[i] = D->Q1[i]; D->Q1[i] = Q0; } /* * Is it time to process the block? */ D->n++; if (D->n == D->block_size) { int row, col; for (i=0; iQ1[i] * D->Q1[i] + D->Q2[i] * D->Q2[i] - D->Q1[i] * D->Q2[i] * D->coef[i]); D->Q1[i] = 0; D->Q2[i] = 0; } D->n = 0; /* * The input signal can vary over a couple orders of * magnitude so we can't set some absolute threshold. * * See if one tone is stronger than the sum of the * others in the same group multiplied by some factor. * * For perfect synthetic signals this needs to be in * the range of about 1.33 (very senstive) to 2.15 (very fussy). * * Too low will cause false triggers on random noise. * Too high will won't decode less than perfect signals. * * Use the mid point 1.74 as our initial guess. * It might need some fine tuning for imperfect real world signals. */ #define THRESHOLD 1.74f if (output[0] > THRESHOLD * ( output[1] + output[2] + output[3])) row = 0; else if (output[1] > THRESHOLD * (output[0] + output[2] + output[3])) row = 1; else if (output[2] > THRESHOLD * (output[0] + output[1] + output[3])) row = 2; else if (output[3] > THRESHOLD * (output[0] + output[1] + output[2] )) row = 3; else row = -1; if (output[4] > THRESHOLD * ( output[5] + output[6] + output[7])) col = 0; else if (output[5] > THRESHOLD * (output[4] + output[6] + output[7])) col = 1; else if (output[6] > THRESHOLD * (output[4] + output[5] + output[7])) col = 2; else if (output[7] > THRESHOLD * (output[4] + output[5] + output[6] )) col = 3; else col = -1; for (i=0; i= 0 && col >= 0) { decoded = rc2char[row*4+col]; } else { decoded = ' '; } // Consider valid only if we get same twice in a row. if (decoded == D->prev_dec) { D->debounced = decoded; // Update Data Carrier Detect Indicator. #ifndef DTMF_TEST dcd_change (c, MAX_SUBCHANS, 0, decoded != ' '); #endif /* Reset timeout timer. */ if (decoded != ' ') { D->timeout = ((TIMEOUT_SEC) * D->sample_rate) / D->block_size; } } D->prev_dec = decoded; // Return only new button pushes. // Also report timeout after period of inactivity. ret = '.'; if (D->debounced != D->prev_debounced) { if (D->debounced != ' ') { ret = D->debounced; } } if (ret == '.') { if (D->timeout > 0) { D->timeout--; if (D->timeout == 0) { ret = '$'; } } } D->prev_debounced = D->debounced; #if DEBUG dw_printf (" dec=%c, deb=%c, ret=%c, to=%d \n", decoded, D->debounced, ret, D->timeout); #endif return (ret); } return (' '); } /*------------------------------------------------------------------- * * Name: dtmf_send * * Purpose: Generate DTMF tones from text string. * * Inputs: chan - Radio channel number. * str - Character string to send. 0-9, A-D, *, # * speed - Number of tones per second. Range 1 to 10. * txdelay - Delay (ms) from PTT to start. * txtail - Delay (ms) from end to PTT off. * * Returns: Total number of milliseconds to activate PTT. * This includes delays before the first tone * and after the last to avoid chopping off part of it. * * Description: xmit_thread calls this instead of the usual hdlc_send * when we have a special packet that means send DTMF. * *--------------------------------------------------------------------*/ int dtmf_send (int chan, char *str, int speed, int txdelay, int txtail) { char *p; int len_ms; // Length of tone or gap between. len_ms = (int) ( ( 500.0f / (float)speed ) + 0.5f); push_button (chan, ' ', txdelay); for (p = str; *p != '\0'; p++) { push_button (chan, *p, len_ms); push_button (chan, ' ', len_ms); } push_button (chan, ' ', txtail); #ifndef DTMF_TEST audio_flush(ACHAN2ADEV(chan)); #endif return (txdelay + (int) (1000.0f * (float)strlen(str) / (float)speed + 0.5f) + txtail); } /* end dtmf_send */ /*------------------------------------------------------------------ * * Name: push_button * * Purpose: Generate DTMF tone for a button push. * * Inputs: chan - Radio channel number. * * button - One of 0-9, A-D, *, #. Others result in silence. * '?' is a special case used only for unit testing. * * ms - Duration in milliseconds. * Use 50 ms for tone and 50 ms of silence for max rate of 10 per second. * * Outputs: Audio is sent to radio. * *----------------------------------------------------------------*/ static void push_button (int chan, char button, int ms) { float phasea = 0; float phaseb = 0; float fa = 0; float fb = 0; int i; float dtmf; // Audio. Sum of two sine waves. #if DTMF_TEST char x; static char result[100]; static int result_len = 0; #endif switch (button) { case '1': fa = dtmf_tones[0]; fb = dtmf_tones[4]; break; case '2': fa = dtmf_tones[0]; fb = dtmf_tones[5]; break; case '3': fa = dtmf_tones[0]; fb = dtmf_tones[6]; break; case 'a': case 'A': fa = dtmf_tones[0]; fb = dtmf_tones[7]; break; case '4': fa = dtmf_tones[1]; fb = dtmf_tones[4]; break; case '5': fa = dtmf_tones[1]; fb = dtmf_tones[5]; break; case '6': fa = dtmf_tones[1]; fb = dtmf_tones[6]; break; case 'b': case 'B': fa = dtmf_tones[1]; fb = dtmf_tones[7]; break; case '7': fa = dtmf_tones[2]; fb = dtmf_tones[4]; break; case '8': fa = dtmf_tones[2]; fb = dtmf_tones[5]; break; case '9': fa = dtmf_tones[2]; fb = dtmf_tones[6]; break; case 'c': case 'C': fa = dtmf_tones[2]; fb = dtmf_tones[7]; break; case '*': fa = dtmf_tones[3]; fb = dtmf_tones[4]; break; case '0': fa = dtmf_tones[3]; fb = dtmf_tones[5]; break; case '#': fa = dtmf_tones[3]; fb = dtmf_tones[6]; break; case 'd': case 'D': fa = dtmf_tones[3]; fb = dtmf_tones[7]; break; #if DTMF_TEST case '?': /* check result */ if (strcmp(result, "123A456B789C*0#D123$789$") == 0) { text_color_set(DW_COLOR_REC); dw_printf ("\nSuccess!\n"); } else if (strcmp(result, "123A456B789C*0#D123789") == 0) { text_color_set(DW_COLOR_ERROR); dw_printf ("\n * Time-out failed, otherwise OK *\n"); dw_printf ("\"%s\"\n", result); exit (EXIT_FAILURE); } else { text_color_set(DW_COLOR_ERROR); dw_printf ("\n *** TEST FAILED ***\n"); dw_printf ("\"%s\"\n", result); exit (EXIT_FAILURE); } break; #endif } //dw_printf ("push_button (%d, '%c', %d), fa=%.0f, fb=%.0f. %d samples\n", chan, button, ms, fa, fb, (ms*dd[chan].sample_rate)/1000); for (i = 0; i < (ms*dd[chan].sample_rate)/1000; i++) { // This could be more efficient with a precomputed sine wave table // but I'm not that worried about it. // With a Raspberry Pi, model 2, default 1200 receiving takes about 14% of one CPU core. // When transmitting tones, it briefly shoots up to about 33%. if (fa > 0 && fb > 0) { dtmf = sinf(phasea) + sinf(phaseb); phasea += 2.0f * (float)M_PI * fa / dd[chan].sample_rate; phaseb += 2.0f * (float)M_PI * fb / dd[chan].sample_rate; } else { dtmf = 0; } #if DTMF_TEST /* Make sure it is insensitive to signal amplitude. */ /* (Uncomment each of below when testing.) */ x = dtmf_sample (0, dtmf); //x = dtmf_sample (0, dtmf * 1000); //x = dtmf_sample (0, dtmf * 0.001); if (x != ' ' && x != '.') { result[result_len] = x; result_len++; result[result_len] = '\0'; } #else // 'dtmf' can be in range of +-2.0 because it is sum of two sine waves. // Amplitude of 100 would use full +-32k range. int sam = (int)(dtmf * 16383.0f * (float)s_amplitude / 100.0f); gen_tone_put_sample (chan, ACHAN2ADEV(chan), sam); #endif } } /*------------------------------------------------------------------ * * Name: main * * Purpose: Unit test for functions above. * * Usage: rm a.exe ; gcc -DDTMF_TEST dtmf.c textcolor.c ; ./a.exe * or * make dtmftest * *----------------------------------------------------------------*/ #if DTMF_TEST static struct audio_s my_audio_config; int main () { int c = 0; // radio channel. memset (&my_audio_config, 0, sizeof(my_audio_config)); my_audio_config.adev[ACHAN2ADEV(c)].defined = 1; my_audio_config.adev[ACHAN2ADEV(c)].samples_per_sec = 44100; my_audio_config.achan[c].valid = 1; my_audio_config.achan[c].dtmf_decode = DTMF_DECODE_ON; dtmf_init(&my_audio_config, 50); text_color_set(DW_COLOR_INFO); dw_printf ("\nFirst, check all button tone pairs. \n\n"); /* Max auto dialing rate is 10 per second. */ push_button (c, '1', 50); push_button (c, ' ', 50); push_button (c, '2', 50); push_button (c, ' ', 50); push_button (c, '3', 50); push_button (c, ' ', 50); push_button (c, 'A', 50); push_button (c, ' ', 50); push_button (c, '4', 50); push_button (c, ' ', 50); push_button (c, '5', 50); push_button (c, ' ', 50); push_button (c, '6', 50); push_button (c, ' ', 50); push_button (c, 'B', 50); push_button (c, ' ', 50); push_button (c, '7', 50); push_button (c, ' ', 50); push_button (c, '8', 50); push_button (c, ' ', 50); push_button (c, '9', 50); push_button (c, ' ', 50); push_button (c, 'C', 50); push_button (c, ' ', 50); push_button (c, '*', 50); push_button (c, ' ', 50); push_button (c, '0', 50); push_button (c, ' ', 50); push_button (c, '#', 50); push_button (c, ' ', 50); push_button (c, 'D', 50); push_button (c, ' ', 50); text_color_set(DW_COLOR_INFO); dw_printf ("\nShould reject very short pulses.\n\n"); push_button (c, '1', 20); push_button (c, ' ', 50); push_button (c, '1', 20); push_button (c, ' ', 50); push_button (c, '1', 20); push_button (c, ' ', 50); push_button (c, '1', 20); push_button (c, ' ', 50); push_button (c, '1', 20); push_button (c, ' ', 50); text_color_set(DW_COLOR_INFO); dw_printf ("\nTest timeout after inactivity.\n\n"); /* For this test we use 1 second. */ /* In practice, it will probably more like 5. */ push_button (c, '1', 250); push_button (c, ' ', 500); push_button (c, '2', 250); push_button (c, ' ', 500); push_button (c, '3', 250); push_button (c, ' ', 1200); push_button (c, '7', 250); push_button (c, ' ', 500); push_button (c, '8', 250); push_button (c, ' ', 500); push_button (c, '9', 250); push_button (c, ' ', 1200); /* Check for expected results. */ push_button (c, '?', 0); exit (EXIT_SUCCESS); } /* end main */ #endif /* end dtmf.c */