Independent ADC and DAC sample rates
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8b2e66eb57
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1
device.h
1
device.h
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@ -22,6 +22,7 @@
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#define TX_MAXWAIT 2UL
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// CSMA Settings
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#define CONFIG_FULL_DUPLEX false // TODO: Actually implement fdx
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#define CONFIG_CSMA_P 255
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// Packet settings
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@ -22,6 +22,36 @@ int afsk_putchar(char c, FILE *stream);
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// ADC and clock setup
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void AFSK_hw_init(void) {
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// Run ADC initialisation
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AFSK_adc_init();
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// Run DAC initialisation
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AFSK_dac_init();
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// Run LED initialisation
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LED_TX_INIT();
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LED_RX_INIT();
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}
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void AFSK_dac_init(void) {
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// DAC uses all 8 pins of one port,
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// so set all to output
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DAC_DDR |= 0xFF;
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// Set Timer3 to normal operation
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TCCR3A = 0;
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TCCR3B = _BV(CS10) |
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_BV(WGM33)|
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_BV(WGM32);
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ICR3 = DAC_TICKS_BETWEEN_SAMPLES;
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//OCR3A = DAC_TICKS_BETWEEN_SAMPLES;
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TIMSK3 = _BV(ICIE3);
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}
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void AFSK_adc_init(void) {
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// Set Timer1 to normal operation
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TCCR1A = 0;
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@ -31,7 +61,7 @@ void AFSK_hw_init(void) {
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// Set ICR1 register to the amount of ticks needed between
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// each sample capture/synthesis
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ICR1 = TICKS_BETWEEN_SAMPLES;
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ICR1 = ADC_TICKS_BETWEEN_SAMPLES;
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// Set ADMUX register to use external AREF, channel ADC0
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// and left adjust result
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@ -60,12 +90,6 @@ void AFSK_hw_init(void) {
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_BV(ADPS2); // Set ADC prescaler bits to 0b101 = 32
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// At 20MHz, this gives an ADC clock of 625 KHz
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// Run DAC initialisation
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AFSK_DAC_INIT();
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// Run LED initialisation
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LED_TX_INIT();
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LED_RX_INIT();
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}
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void AFSK_init(Afsk *afsk) {
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@ -82,7 +106,7 @@ void AFSK_init(Afsk *afsk) {
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fifo_init(&afsk->txFifo, afsk->txBuf, sizeof(afsk->txBuf));
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// Fill delay FIFO with zeroes
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for (int i = 0; i<SAMPLESPERBIT / 2; i++) {
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for (int i = 0; i<ADC_SAMPLESPERBIT / 2; i++) {
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fifo_push(&afsk->delayFifo, 0);
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}
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@ -185,7 +209,7 @@ uint8_t AFSK_dac_isr(Afsk *afsk) {
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afsk->txBit <<= 1;
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}
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afsk->sampleIndex = SAMPLESPERBIT;
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afsk->sampleIndex = DAC_SAMPLESPERBIT;
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}
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afsk->phaseAcc += afsk->phaseInc;
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@ -375,7 +399,7 @@ void AFSK_adc_isr(Afsk *afsk, int8_t currentSample) {
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afsk->iirX[0] = afsk->iirX[1];
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#if CONFIG_SAMPLERATE == 9600
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#if CONFIG_ADC_SAMPLERATE == 9600
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#if FILTER_CUTOFF == 500
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#define IIR_GAIN 4 // Really 4.082041675
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#define IIR_POLE 2 // Really Y[0] * 0.5100490981
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@ -387,7 +411,7 @@ void AFSK_adc_isr(Afsk *afsk, int8_t currentSample) {
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#error Unsupported filter cutoff!
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#endif
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#elif CONFIG_SAMPLERATE == 19200
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#elif CONFIG_ADC_SAMPLERATE == 19200
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#if FILTER_CUTOFF == 150
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#define IIR_GAIN 2 // Really 2.172813446e
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#define IIR_POLE 2 // Really Y[0] * 0.9079534415
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@ -570,17 +594,21 @@ void AFSK_adc_isr(Afsk *afsk, int8_t currentSample) {
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}
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ISR(ADC_vect) {
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TIFR1 = _BV(ICF1);
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ISR(TIMER3_CAPT_vect) {
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if (hw_afsk_dac_isr) {
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DAC_PORT = AFSK_dac_isr(AFSK_modem);
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LED_TX_ON();
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} else {
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// TODO: Enable full duplex if possible
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AFSK_adc_isr(AFSK_modem, (ADCH - 128));
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DAC_PORT = 127;
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LED_TX_OFF();
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DAC_PORT = 127;
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}
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}
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ISR(ADC_vect) {
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TIFR1 = _BV(ICF1);
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if (CONFIG_FULL_DUPLEX || !hw_afsk_dac_isr) {
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AFSK_adc_isr(AFSK_modem, (ADCH - 128));
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}
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++_clock;
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@ -38,8 +38,8 @@ inline static uint8_t sinSample(uint16_t i) {
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#define CPU_FREQ F_CPU
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#define CONFIG_AFSK_RX_BUFLEN CONFIG_SAMPLERATE/150
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#define CONFIG_AFSK_TX_BUFLEN CONFIG_SAMPLERATE/150
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#define CONFIG_AFSK_RX_BUFLEN CONFIG_ADC_SAMPLERATE/150
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#define CONFIG_AFSK_TX_BUFLEN CONFIG_ADC_SAMPLERATE/150
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#define CONFIG_AFSK_RXTIMEOUT 0
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#define CONFIG_AFSK_TXWAIT 0UL
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#define CONFIG_AFSK_PREAMBLE_LEN 150UL
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@ -49,20 +49,24 @@ inline static uint8_t sinSample(uint16_t i) {
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#define BITRATE 1200
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#if BITRATE == 1200
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#define CONFIG_SAMPLERATE 9600UL
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#define CONFIG_ADC_SAMPLERATE 9600UL
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#define CONFIG_DAC_SAMPLERATE 19200UL
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#elif BITRATE == 2400
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#define CONFIG_SAMPLERATE 19200UL
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#define CONFIG_ADC_SAMPLERATE 19200UL
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#define CONFIG_DAC_SAMPLERATE 38400UL
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#endif
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#define SAMPLESPERBIT (CONFIG_SAMPLERATE / BITRATE)
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#define TICKS_BETWEEN_SAMPLES ((((CPU_FREQ+FREQUENCY_CORRECTION)) / CONFIG_SAMPLERATE) - 1)
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#define ADC_SAMPLESPERBIT (CONFIG_ADC_SAMPLERATE / BITRATE)
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#define ADC_TICKS_BETWEEN_SAMPLES ((((CPU_FREQ+FREQUENCY_CORRECTION)) / CONFIG_ADC_SAMPLERATE) - 1)
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#define DAC_SAMPLESPERBIT (CONFIG_DAC_SAMPLERATE / BITRATE)
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#define DAC_TICKS_BETWEEN_SAMPLES ((((CPU_FREQ+FREQUENCY_CORRECTION)) / CONFIG_DAC_SAMPLERATE) - 1)
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// TODO: Maybe revert to only looking at two samples
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#if BITRATE == 1200
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#if CONFIG_SAMPLERATE == 19200
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#if CONFIG_ADC_SAMPLERATE == 19200
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#define SIGNAL_TRANSITIONED(bits) QUAD_XOR((bits), (bits) >> 4)
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#elif CONFIG_SAMPLERATE == 9600
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#elif CONFIG_ADC_SAMPLERATE == 9600
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#define SIGNAL_TRANSITIONED(bits) DUAL_XOR((bits), (bits) >> 2)
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#endif
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#elif BITRATE == 2400
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@ -73,14 +77,14 @@ inline static uint8_t sinSample(uint16_t i) {
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#define PHASE_BITS 8 // Sub-sample phase counter resolution
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#define PHASE_INC 1 // Nudge by above resolution for each adjustment
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#define PHASE_MAX (SAMPLESPERBIT * PHASE_BITS) // Size of our phase counter
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#define PHASE_MAX (ADC_SAMPLESPERBIT * PHASE_BITS) // Size of our phase counter
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// TODO: Test which target is best in real world
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// For 1200, this seems a little better
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#if BITRATE == 1200
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#if CONFIG_SAMPLERATE == 19200
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#if CONFIG_ADC_SAMPLERATE == 19200
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#define PHASE_THRESHOLD (PHASE_MAX / 2)+3*PHASE_BITS // Target transition point of our phase window
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#elif CONFIG_SAMPLERATE == 9600
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#elif CONFIG_ADC_SAMPLERATE == 9600
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#define PHASE_THRESHOLD (PHASE_MAX / 2) // 64 // Target transition point of our phase window
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#endif
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#elif BITRATE == 2400
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@ -88,8 +92,8 @@ inline static uint8_t sinSample(uint16_t i) {
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#endif
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#define DCD_TIMEOUT_SAMPLES CONFIG_SAMPLERATE/100
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#define DCD_MIN_COUNT CONFIG_SAMPLERATE/1600
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#define DCD_TIMEOUT_SAMPLES CONFIG_ADC_SAMPLERATE/100
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#define DCD_MIN_COUNT CONFIG_ADC_SAMPLERATE/1600
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// TODO: Revamp filtering
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#if BITRATE == 1200
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@ -155,10 +159,10 @@ typedef struct Afsk
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FIFOBuffer delayFifo; // Delayed FIFO for frequency discrimination
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#if BITRATE == 1200
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// TODO: Clean this up
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#if CONFIG_SAMPLERATE == 19200
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int8_t delayBuf[SAMPLESPERBIT / 2 + 1]; // Actual data storage for said FIFO
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#elif CONFIG_SAMPLERATE == 9600
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int8_t delayBuf[SAMPLESPERBIT / 2 + 1]; // Actual data storage for said FIFO
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#if CONFIG_ADC_SAMPLERATE == 19200
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int8_t delayBuf[ADC_SAMPLESPERBIT / 2 + 1]; // Actual data storage for said FIFO
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#elif CONFIG_ADC_SAMPLERATE == 9600
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int8_t delayBuf[ADC_SAMPLESPERBIT / 2 + 1]; // Actual data storage for said FIFO
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#endif
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#elif BITRATE == 2400
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int8_t delayBuf[7 + 1]; // Actual data storage for said FIFO
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@ -170,7 +174,7 @@ typedef struct Afsk
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int16_t iirX[2]; // IIR Filter X cells
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int16_t iirY[2]; // IIR Filter Y cells
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#if SAMPLESPERBIT < 17
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#if ADC_SAMPLESPERBIT < 17
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uint16_t sampledBits; // Bits sampled by the demodulator (at ADC speed)
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#else
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// TODO: Enable error and set up correct size buffers
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@ -185,16 +189,12 @@ typedef struct Afsk
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} Afsk;
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#define DIV_ROUND(dividend, divisor) (((dividend) + (divisor) / 2) / (divisor))
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#define MARK_INC (uint16_t)(DIV_ROUND(SIN_LEN * (uint32_t)MARK_FREQ, CONFIG_SAMPLERATE))
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#define SPACE_INC (uint16_t)(DIV_ROUND(SIN_LEN * (uint32_t)SPACE_FREQ, CONFIG_SAMPLERATE))
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#define MARK_INC (uint16_t)(DIV_ROUND(SIN_LEN * (uint32_t)MARK_FREQ, CONFIG_DAC_SAMPLERATE))
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#define SPACE_INC (uint16_t)(DIV_ROUND(SIN_LEN * (uint32_t)SPACE_FREQ, CONFIG_DAC_SAMPLERATE))
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#define AFSK_DAC_IRQ_START() do { extern bool hw_afsk_dac_isr; hw_afsk_dac_isr = true; } while (0)
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#define AFSK_DAC_IRQ_STOP() do { extern bool hw_afsk_dac_isr; hw_afsk_dac_isr = false; } while (0)
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// DAC uses all 8 pins of one port, set all pins to
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// output direction
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#define AFSK_DAC_INIT() do { DAC_DDR |= 0xFF; } while (0)
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// Here's some macros for controlling the RX/TX LEDs
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// THE _INIT() functions writes to the DDR registers
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// to configure the pins as output pins, and the _ON()
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@ -209,6 +209,8 @@ typedef struct Afsk
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#define LED_RX_OFF() do { LED_PORT &= ~_BV(2); } while (0)
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void AFSK_init(Afsk *afsk);
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void AFSK_adc_init(void);
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void AFSK_dac_init(void);
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void AFSK_transmit(char *buffer, size_t size);
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void AFSK_poll(Afsk *afsk);
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@ -4,8 +4,8 @@ uint8_t adcReference = CONFIG_ADC_REF;
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uint8_t dacReference = CONFIG_DAC_REF;
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void VREF_init(void) {
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//DDRD |= _BV(7);
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DDRD = 0xFF;
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// Enable output for OC2A and OC2B (PD7 and PD6)
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DDRD |= _BV(7) | _BV(6);
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TCCR2A = _BV(WGM20) |
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_BV(WGM21) |
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@ -28,7 +28,7 @@ void kiss_init(AX25Ctx *ax25, Afsk *afsk, Serial *ser) {
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}
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// TODO: Remove debug functions
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//size_t decodes = 0;
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// size_t decodes = 0;
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void kiss_messageCallback(AX25Ctx *ctx) {
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// decodes++;
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// printf("%d\r\n", decodes);
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@ -60,7 +60,7 @@ void kiss_csma(AX25Ctx *ctx, uint8_t *buf, size_t len) {
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}
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}
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while (!sent) {
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if(!channel->hdlc.dcd) {
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if(CONFIG_FULL_DUPLEX || !channel->hdlc.dcd) {
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uint8_t tp = rand() & 0xFF;
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if (tp < p) {
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ax25_sendRaw(ctx, buf, len);
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@ -4,7 +4,7 @@
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#include <util/atomic.h>
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#define DIV_ROUND(dividend, divisor) (((dividend) + (divisor) / 2) / (divisor))
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#define CLOCK_TICKS_PER_SEC CONFIG_SAMPLERATE
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#define CLOCK_TICKS_PER_SEC CONFIG_ADC_SAMPLERATE
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typedef int32_t ticks_t;
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typedef int32_t mtime_t;
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