/* Hamshield * Example: CTCSS * This is a simple example to demonstrate HamShield receive * and transmit functionality using CTCSS. The HamShield will * have audio output muted until it receives the correct * sub-audible tone. It does this by polling a tone detection * flag on the HamShield, but it's also possible to do this * using interrupts if you connect GPIO0 from the HamShield * to your Arduino (code for that not provided). * * Setup: * Connect the HamShield to your Arduino. Screw the antenna * into the HamShield RF jack. Plug a pair of headphones into * the HamShield. Connect the Arduino to wall power and then * to your computer via USB. Set the CTCSS tone that you * want to use in the setup() function below. * After uploading this program to your Arduino, open the * Serial Monitor. Press the button on the HamShield to begin * setup. The sketch then works exactly like the HandyTalkie * example, with the exception that only valid CTCSS coded * receptions are put out to the headset. */ #include // create object for radio HamShield radio; #define LED_PIN 13 #define RSSI_REPORT_RATE_MS 5000 #define PWM_PIN 3 #define RESET_PIN A3 #define SWITCH_PIN 2 bool currently_tx; uint32_t freq; float ctcss_tone; bool muted; unsigned long rssi_timeout; void setup() { // NOTE: if not using PWM out, it should be held low to avoid tx noise pinMode(PWM_PIN, OUTPUT); digitalWrite(PWM_PIN, LOW); // prep the switch pinMode(SWITCH_PIN, INPUT_PULLUP); // set up the reset control pin pinMode(RESET_PIN, OUTPUT); digitalWrite(RESET_PIN, LOW); // initialize serial communication Serial.begin(9600); Serial.println("press the switch to begin..."); while (digitalRead(SWITCH_PIN)); // let the AU ot of reset digitalWrite(RESET_PIN, HIGH); delay(5); // wait for device to come up Serial.println("beginning radio setup"); // verify connection Serial.println("Testing device connections..."); Serial.println(radio.testConnection() ? "RDA radio connection successful" : "RDA radio connection failed"); // initialize device Serial.println("Initializing I2C devices..."); radio.initialize(); // initializes automatically for UHF 12.5kHz channel Serial.println("setting default Radio configuration"); radio.dangerMode(); // set frequency Serial.println("changing frequency"); radio.setSQOff(); freq = 446000; radio.frequency(freq); // set to receive radio.setModeReceive(); currently_tx = false; Serial.print("config register is: "); Serial.println(radio.readCtlReg()); Serial.println(radio.readRSSI()); radio.setRfPower(0); // CTCSS Setup code ctcss_tone = 134.4; radio.setCtcss(ctcss_tone); radio.enableCtcss(); Serial.print("ctcss tone: "); Serial.println(radio.getCtcssFreqHz()); // mute audio until we get a CTCSS tone // radio.setMute(); muted = true; // configure Arduino LED for pinMode(LED_PIN, OUTPUT); rssi_timeout = 0; } void loop() { // handle CTCSS tone detection if (!currently_tx) { // check for CTCSS tone if (radio.getCtcssToneDetected()) { if (muted) { muted = false; // radio.setUnmute(); Serial.println("tone"); } } else { if (!muted) { muted = true; // radio.setMute(); Serial.println("no tone"); } } } // handle manual transmit if (!digitalRead(SWITCH_PIN)) { if (!currently_tx) { currently_tx = true; // set to transmit radio.setModeTransmit(); Serial.println("Tx"); //radio.setTxSourceMic(); //radio.setRfPower(1); } } else if (currently_tx) { radio.setModeReceive(); currently_tx = false; Serial.println("Rx"); } // handle serial commands if (Serial.available()) { if (Serial.peek() == 'r') { Serial.read(); digitalWrite(RESET_PIN, LOW); delay(1000); digitalWrite(RESET_PIN, HIGH); radio.initialize(); // initializes automatically for UHF 12.5kHz channel } else { Serial.setTimeout(40); freq = Serial.parseInt(); Serial.flush(); radio.frequency(freq); Serial.print("set frequency: "); Serial.println(freq); } } // periodically read RSSI and print to screen if (!currently_tx && (millis() - rssi_timeout) > RSSI_REPORT_RATE_MS) { Serial.println(radio.readRSSI()); rssi_timeout = millis(); } }