Added dynamic switching to 300 baud TX

LibAPRS/AFSK.cpp

@@ -62,33 +62,37 @@ void AFSK_init(Afsk *afsk) {
     memset(afsk, 0, sizeof(*afsk));
     AFSK_modem = afsk;
     // Set phase increment
-    afsk->phaseInc = MARK_INC;
+    afsk->dataRate = 1200;
+    afsk->phaseInc = MARK_INC_1200;
     // Initialise FIFO buffers
     fifo_init(&afsk->delayFifo, (uint8_t *)afsk->delayBuf, sizeof(afsk->delayBuf));
     fifo_init(&afsk->rxFifo, afsk->rxBuf, sizeof(afsk->rxBuf));
     fifo_init(&afsk->txFifo, afsk->txBuf, sizeof(afsk->txBuf));
 
     // Fill delay FIFO with zeroes
-    for (int i = 0; i<SAMPLESPERBIT / 2; i++) {
+    for (int i = 0; i<SAMPLESPERBIT_300 / 2; i++) {
         fifo_push(&afsk->delayFifo, 0);
     }
 
     AFSK_hw_init();
+}
 
+void AFSK_setDataRate(Afsk *afsk, uint16_t dataRate) {
+    afsk->dataRate = dataRate;
 }
 
 static void AFSK_txStart(Afsk *afsk) {
     if (!afsk->sending) {
-        afsk->phaseInc = MARK_INC;
+        afsk->phaseInc = afsk->dataRate == 1200 ? MARK_INC_1200 : MARK_INC_300;
         afsk->phaseAcc = 0;
         afsk->bitstuffCount = 0;
         afsk->sending = true;
         LED_TX_ON();
-        afsk->preambleLength = DIV_ROUND(custom_preamble * BITRATE, 8000);
+        afsk->preambleLength = DIV_ROUND(custom_preamble * afsk->dataRate, 8000);
         AFSK_DAC_IRQ_START();
     }
     ATOMIC_BLOCK(ATOMIC_RESTORESTATE) {
-      afsk->tailLength = DIV_ROUND(custom_tail * BITRATE, 8000);
+      afsk->tailLength = DIV_ROUND(custom_tail * afsk->dataRate, 8000);
     }
 }
 
@@ -154,18 +158,18 @@ uint8_t AFSK_dac_isr(Afsk *afsk) {
 
         if (afsk->bitStuff && afsk->bitstuffCount >= BIT_STUFF_LEN) {
             afsk->bitstuffCount = 0;
-            afsk->phaseInc = SWITCH_TONE(afsk->phaseInc);
+            afsk->phaseInc = (afsk->dataRate == 1200) ? SWITCH_TONE_1200(afsk->phaseInc) : SWITCH_TONE_300(afsk->phaseInc);
         } else {
             if (afsk->currentOutputByte & afsk->txBit) {
                 afsk->bitstuffCount++;
             } else {
                 afsk->bitstuffCount = 0;
-                afsk->phaseInc = SWITCH_TONE(afsk->phaseInc);
+                afsk->phaseInc = (afsk->dataRate == 1200) ? SWITCH_TONE_1200(afsk->phaseInc) : SWITCH_TONE_300(afsk->phaseInc);
             }
             afsk->txBit <<= 1;
         }
 
-        afsk->sampleIndex = SAMPLESPERBIT;
+        afsk->sampleIndex = (afsk->dataRate == 1200) ? SAMPLESPERBIT_1200 : SAMPLESPERBIT_300;
     }
 
     afsk->phaseAcc += afsk->phaseInc;
@@ -380,7 +384,7 @@ void AFSK_adc_isr(Afsk *afsk, int8_t currentSample) {
     // our timing to the transmitter, even if it's timing is
     // a little off compared to our own.
     if (SIGNAL_TRANSITIONED(afsk->sampledBits)) {
-        if (afsk->currentPhase < PHASE_THRESHOLD) {
+        if (afsk->currentPhase < PHASE_THRESHOLD_1200) {
             afsk->currentPhase += PHASE_INC;
         } else {
             afsk->currentPhase -= PHASE_INC;
@@ -392,10 +396,10 @@ void AFSK_adc_isr(Afsk *afsk, int8_t currentSample) {
 
     // Check if we have reached the end of
     // our sampling window.
-    if (afsk->currentPhase >= PHASE_MAX) {
+    if (afsk->currentPhase >= PHASE_MAX_1200) {
         // If we have, wrap around our phase
         // counter by modulus
-        afsk->currentPhase %= PHASE_MAX;
+        afsk->currentPhase %= PHASE_MAX_1200;
 
         // Bitshift to make room for the next
         // bit in our stream of demodulated bits

LibAPRS/AFSK.h

@@ -29,8 +29,9 @@ inline static uint8_t sinSample(uint16_t i) {
     return (i >= (SIN_LEN/2)) ? (255 - sine) : sine;
 }
 
-
-#define SWITCH_TONE(inc)  (((inc) == MARK_INC) ? SPACE_INC : MARK_INC)
+#define DIV_ROUND(dividend, divisor)  (((dividend) + (divisor) / 2) / (divisor))
+#define SWITCH_TONE_300(inc)  (((inc) == MARK_INC_300) ? SPACE_INC_300 : MARK_INC_300)
+#define SWITCH_TONE_1200(inc)  (((inc) == MARK_INC_1200) ? SPACE_INC_1200 : MARK_INC_1200)
 #define BITS_DIFFER(bits1, bits2) (((bits1)^(bits2)) & 0x01)
 #define DUAL_XOR(bits1, bits2) ((((bits1)^(bits2)) & 0x03) == 0x03)
 #define SIGNAL_TRANSITIONED(bits) DUAL_XOR((bits), (bits) >> 2)
@@ -44,15 +45,23 @@ inline static uint8_t sinSample(uint16_t i) {
 #define CONFIG_AFSK_PREAMBLE_LEN 150UL
 #define CONFIG_AFSK_TRAILER_LEN 50UL
 #define SAMPLERATE 9600
-#define BITRATE    1200
-#define SAMPLESPERBIT (SAMPLERATE / BITRATE)
+#define SAMPLESPERBIT_1200 (SAMPLERATE / 1200)
+#define SAMPLESPERBIT_300 (SAMPLERATE / 300)
 #define BIT_STUFF_LEN 5
-#define MARK_FREQ  1200
-#define SPACE_FREQ 2200
+#define MARK_FREQ_300  1600
+#define SPACE_FREQ_300 1800
+#define MARK_FREQ_1200  1200
+#define SPACE_FREQ_1200 2200
 #define PHASE_BITS   8                              // How much to increment phase counter each sample
 #define PHASE_INC    1                              // Nudge by an eigth of a sample each adjustment
-#define PHASE_MAX    (SAMPLESPERBIT * PHASE_BITS)   // Resolution of our phase counter = 64
-#define PHASE_THRESHOLD  (PHASE_MAX / 2)            // Target transition point of our phase window
+#define PHASE_MAX_300 (SAMPLESPERBIT_300 * PHASE_BITS)   // Resolution of our phase counter = 64
+#define PHASE_MAX_1200 (SAMPLESPERBIT_1200 * PHASE_BITS)   // Resolution of our phase counter = 64
+#define PHASE_THRESHOLD_300  (PHASE_MAX_300 / 2)            // Target transition point of our phase window
+#define PHASE_THRESHOLD_1200  (PHASE_MAX_1200 / 2)            // Target transition point of our phase window
+#define MARK_INC_300   (uint16_t)(DIV_ROUND(SIN_LEN * (uint32_t)MARK_FREQ_300, CONFIG_AFSK_DAC_SAMPLERATE))
+#define SPACE_INC_300  (uint16_t)(DIV_ROUND(SIN_LEN * (uint32_t)SPACE_FREQ_300, CONFIG_AFSK_DAC_SAMPLERATE))
+#define MARK_INC_1200   (uint16_t)(DIV_ROUND(SIN_LEN * (uint32_t)MARK_FREQ_1200, CONFIG_AFSK_DAC_SAMPLERATE))
+#define SPACE_INC_1200  (uint16_t)(DIV_ROUND(SIN_LEN * (uint32_t)SPACE_FREQ_1200, CONFIG_AFSK_DAC_SAMPLERATE))
 
 
 typedef struct Hdlc
@@ -85,13 +94,13 @@ typedef struct Afsk
     uint16_t phaseInc;                      // Phase increment per sample
 
     FIFOBuffer txFifo;                      // FIFO for transmit data
-    uint8_t txBuf[CONFIG_AFSK_TX_BUFLEN];   // Actial data storage for said FIFO
+    uint8_t txBuf[CONFIG_AFSK_TX_BUFLEN];   // Actual data storage for said FIFO
 
     volatile bool sending;                  // Set when modem is sending
 
     // Demodulation values
     FIFOBuffer delayFifo;                   // Delayed FIFO for frequency discrimination
-    int8_t delayBuf[SAMPLESPERBIT / 2 + 1]; // Actual data storage for said FIFO
+    int8_t delayBuf[SAMPLESPERBIT_300 / 2 + 1]; // Actual data storage for said FIFO
 
     FIFOBuffer rxFifo;                      // FIFO for received data
     uint8_t rxBuf[CONFIG_AFSK_RX_BUFLEN];   // Actual data storage for said FIFO
@@ -100,16 +109,13 @@ typedef struct Afsk
     int16_t iirY[2];                        // IIR Filter Y cells
 
     uint8_t sampledBits;                    // Bits sampled by the demodulator (at ADC speed)
-    int8_t currentPhase;                    // Current phase of the demodulator
+    int16_t currentPhase;                   // Current phase of the demodulator
     uint8_t actualBits;                     // Actual found bits at correct bitrate
 
     volatile int status;                    // Status of the modem, 0 means OK
-
+    uint16_t dataRate;                      // Data rate for the modem
 } Afsk;
 
-#define DIV_ROUND(dividend, divisor)  (((dividend) + (divisor) / 2) / (divisor))
-#define MARK_INC   (uint16_t)(DIV_ROUND(SIN_LEN * (uint32_t)MARK_FREQ, CONFIG_AFSK_DAC_SAMPLERATE))
-#define SPACE_INC  (uint16_t)(DIV_ROUND(SIN_LEN * (uint32_t)SPACE_FREQ, CONFIG_AFSK_DAC_SAMPLERATE))
 
 #define AFSK_DAC_IRQ_START()   do { extern bool hw_afsk_dac_isr; hw_afsk_dac_isr = true; } while (0)
 #define AFSK_DAC_IRQ_STOP()    do { extern bool hw_afsk_dac_isr; hw_afsk_dac_isr = false; } while (0)
@@ -131,6 +137,7 @@ typedef struct Afsk
 void AFSK_init(Afsk *afsk);
 void AFSK_transmit(char *buffer, size_t size);
 void AFSK_poll(Afsk *afsk);
+void AFSK_setDataRate(Afsk *afsk, uint16_t rate);
 
 void afsk_putchar(char c);
 int afsk_getchar(void);

LibAPRS/AX25.cpp

@@ -16,6 +16,7 @@
 extern int LibAPRS_vref;
 extern bool LibAPRS_open_squelch;
 
+
 void ax25_init(AX25Ctx *ctx, ax25_callback_t hook) {
     memset(ctx, 0, sizeof(*ctx));
     ctx->hook = hook;

LibAPRS/LibAPRS.cpp

@@ -68,6 +68,14 @@ void APRS_poll(void) {
     ax25_poll(&AX25);
 }
 
+void APRS_setDataRate300() {
+    AFSK_setDataRate(&modem, 300);
+}
+
+void APRS_setDataRate1200() {
+    AFSK_setDataRate(&modem, 1200);
+}
+
 void APRS_setCallsign(char *call, int ssid) {
     memset(CALL, 0, MAX_CALL_LENGTH);
     int i = 0;
@@ -134,6 +142,10 @@ void APRS_useAlternateSymbolTable(bool use) {
     }
 }
 
+void APRS_setSymbolTable(char table) {
+    symbolTable = table;
+}
+
 void APRS_setSymbol(char sym) {
     symbol = sym;
 }
@@ -371,6 +383,11 @@ uint8_t APRS_sendLoc_mice(void *_buffer, size_t length) {
     memcpy(path2.call, PATH2, 6);
     path2.ssid = PATH2_SSID;
 
+    for (int i=0; i<6; i++) {
+        Serial.print((char)DST[i]);
+    }
+
+
     path[0] = dst;
     path[1] = src;
     path[2] = path1;

LibAPRS/LibAPRS.h

@@ -30,6 +30,7 @@ void APRS_setPreamble(unsigned long pre);
 void APRS_setTail(unsigned long tail);
 void APRS_useAlternateSymbolTable(bool use);
 void APRS_setSymbol(char sym);
+void APRS_setSymbolTable(char table);
 
 void APRS_setLat(char *lat);
 void APRS_setLon(char *lon);
@@ -39,6 +40,8 @@ void APRS_setGain(int s);
 void APRS_setDirectivity(int s);
 void APRS_setSpeed(int s);
 void APRS_setCourse(int c);
+void APRS_setDataRate300();
+void APRS_setDataRate1200();
 
 void APRS_sendPkt(void *_buffer, size_t length);
 void APRS_sendLoc(void *_buffer, size_t length);