/* * SpanDSP - a series of DSP components for telephony * * dds_tests.c * * Written by Steve Underwood * * Copyright (C) 2003 Steve Underwood * * All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2, as * published by the Free Software Foundation. * * 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, write to the Free Software * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ /*! \file */ /*! \page dds_tests_page Direct digital synthesis tests \section dds_tests_page_sec_1 What does it do? ???. \section dds_tests_page_sec_2 How does it work? ???. */ #if defined(HAVE_CONFIG_H) #include "config.h" #endif #include #include #include #include #include #include "spandsp.h" #include "spandsp-sim.h" #define OUTPUT_FILE_NAME "dds.wav" #define OUTPUT_FILE_NAME_COMPLEX "complex_dds.wav" #define SAMPLES_PER_CHUNK 8000 int main(int argc, char *argv[]) { int i; uint32_t phase; int32_t phase_inc; int outframes; complexf_t camp; int16_t buf[2*SAMPLES_PER_CHUNK]; SNDFILE *outhandle; power_meter_t meter; power_meter_t meter_i; power_meter_t meter_q; int scale; power_meter_init(&meter, 10); printf("Non-complex DDS tests.\n"); if ((outhandle = sf_open_telephony_write(OUTPUT_FILE_NAME, 1)) == NULL) { fprintf(stderr, " Cannot create audio file '%s'\n", OUTPUT_FILE_NAME); exit(2); } phase = 0; printf("Test with 123.456789Hz.\n"); phase_inc = dds_phase_rate(123.456789f); scale = dds_scaling_dbm0(-10.0f); for (i = 0; i < SAMPLES_PER_CHUNK; i++) { buf[i] = alaw_to_linear(linear_to_alaw((dds(&phase, phase_inc)*scale) >> 15)); power_meter_update(&meter, buf[i]); } outframes = sf_writef_short(outhandle, buf, SAMPLES_PER_CHUNK); if (outframes != SAMPLES_PER_CHUNK) { fprintf(stderr, " Error writing audio file\n"); exit(2); } printf("Level is %fdBOv/%fdBm0\n", power_meter_current_dbov(&meter), power_meter_current_dbm0(&meter)); if (fabs(power_meter_current_dbm0(&meter) + 10.0f) > 0.1f) { printf("Test failed.\n"); exit(2); } printf("Test with 12.3456789Hz.\n"); phase_inc = dds_phase_rate(12.3456789f); for (i = 0; i < SAMPLES_PER_CHUNK; i++) { buf[i] = alaw_to_linear(linear_to_alaw(dds(&phase, phase_inc))); power_meter_update(&meter, buf[i]); } outframes = sf_writef_short(outhandle, buf, SAMPLES_PER_CHUNK); if (outframes != SAMPLES_PER_CHUNK) { fprintf(stderr, " Error writing audio file\n"); exit(2); } printf("Level is %fdBOv/%fdBm0\n", power_meter_current_dbov(&meter), power_meter_current_dbm0(&meter)); /* Use a wider tolerance for this very low frequency - the power meter will ripple */ if (fabs(power_meter_current_dbov(&meter) + 3.02f) > 0.2f) { printf("Test failed.\n"); exit(2); } printf("Test with 2345.6789Hz.\n"); phase_inc = dds_phase_rate(2345.6789f); scale = dds_scaling_dbov(-10.0f); for (i = 0; i < SAMPLES_PER_CHUNK; i++) { buf[i] = alaw_to_linear(linear_to_alaw((dds(&phase, phase_inc)*scale) >> 15)); power_meter_update(&meter, buf[i]); } outframes = sf_writef_short(outhandle, buf, SAMPLES_PER_CHUNK); if (outframes != SAMPLES_PER_CHUNK) { fprintf(stderr, " Error writing audio file\n"); exit(2); } printf("Level is %fdBOv/%fdBm0\n", power_meter_current_dbov(&meter), power_meter_current_dbm0(&meter)); if (fabs(power_meter_current_dbov(&meter) + 10.0f) > 0.1f) { printf("Test failed.\n"); exit(2); } printf("Test with 3456.789Hz.\n"); phase_inc = dds_phase_rate(3456.789f); for (i = 0; i < SAMPLES_PER_CHUNK; i++) { buf[i] = alaw_to_linear(linear_to_alaw(dds(&phase, phase_inc))); power_meter_update(&meter, buf[i]); } outframes = sf_writef_short(outhandle, buf, SAMPLES_PER_CHUNK); if (outframes != SAMPLES_PER_CHUNK) { fprintf(stderr, " Error writing audio file\n"); exit(2); } printf("Level is %fdBOv/%fdBm0\n", power_meter_current_dbov(&meter), power_meter_current_dbm0(&meter)); if (fabs(power_meter_current_dbov(&meter) + 3.02f) > 0.05f) { printf("Test failed.\n"); exit(2); } if (sf_close_telephony(outhandle)) { fprintf(stderr, " Cannot close audio file '%s'\n", OUTPUT_FILE_NAME); exit(2); } printf("Complex DDS tests,\n"); if ((outhandle = sf_open_telephony_write(OUTPUT_FILE_NAME_COMPLEX, 2)) == NULL) { fprintf(stderr, " Cannot create audio file '%s'\n", OUTPUT_FILE_NAME_COMPLEX); exit(2); } power_meter_init(&meter_i, 7); power_meter_init(&meter_q, 7); phase = 0; phase_inc = dds_phase_ratef(123.456789f); for (i = 0; i < SAMPLES_PER_CHUNK; i++) { camp = dds_complexf(&phase, phase_inc); buf[2*i] = camp.re*10000.0f; buf[2*i + 1] = camp.im*10000.0f; power_meter_update(&meter_i, buf[2*i]); power_meter_update(&meter_q, buf[2*i]); } outframes = sf_writef_short(outhandle, buf, SAMPLES_PER_CHUNK); if (outframes != SAMPLES_PER_CHUNK) { fprintf(stderr, " Error writing audio file\n"); exit(2); } printf("Level is %fdBOv/%fdBm0, %fdBOv/%fdBm0\n", power_meter_current_dbov(&meter_i), power_meter_current_dbm0(&meter_i), power_meter_current_dbov(&meter_q), power_meter_current_dbm0(&meter_q)); if (fabs(power_meter_current_dbov(&meter_i) + 13.42f) > 0.05f || fabs(power_meter_current_dbov(&meter_q) + 13.42f) > 0.05f) { printf("Test failed.\n"); exit(2); } if (sf_close_telephony(outhandle)) { fprintf(stderr, " Cannot close audio file '%s'\n", OUTPUT_FILE_NAME_COMPLEX); exit(2); } printf("Tests passed.\n"); return 0; } /*- End of function --------------------------------------------------------*/ /*- End of file ------------------------------------------------------------*/