// mrf89_client.pde
// -*- mode: C++ -*-
// Example sketch showing how to create a simple messageing client
// with the RH_MRF89 class. RH_MRF89 class does not provide for addressing or
// reliability, so you should only use RH_RF95 if you do not need the higher
// level messaging abilities.
// It is designed to work with the other example mrf89_server
// Tested with Teensy and MRF89XAM9A
#include <SPI.h>
#include <RH_MRF89.h>
// Singleton instance of the radio driver
RH_MRF89 mrf89;
void setup()
{
Serial.begin(9600);
while (!Serial)
; // wait for serial port to connect. Needed for native USB
if (!mrf89.init())
Serial.println("init failed");
// Default after init is 1dBm, 915.4MHz, FSK_Rb20Fd40
// But you can change that if you want:
// mrf89.setTxPower(RH_MRF89_TXOPVAL_M8DBM); // Min power -8dBm
// mrf89.setTxPower(RH_MRF89_TXOPVAL_13DBM); // Max power 13dBm
// if (!mrf89.setFrequency(920.0))
// Serial.println("setFrequency failed");
// if (!mrf89.setModemConfig(RH_MRF89::FSK_Rb200Fd200)) // Fastest
// Serial.println("setModemConfig failed");
}
void loop()
{
Serial.println("Sending to mrf89_server");
// Send a message to mrf89_server
uint8_t data[] = "Hello World!";
mrf89.send(data, sizeof(data));
mrf89.waitPacketSent();
// Now wait for a reply
uint8_t buf[RH_MRF89_MAX_MESSAGE_LEN];
uint8_t len = sizeof(buf);
if (mrf89.waitAvailableTimeout(3000))
{
// Should be a reply message for us now
if (mrf89.recv(buf, &len))
{
Serial.print("got reply: ");
Serial.println((char*)buf);
// Serial.print("RSSI: ");
// Serial.println(mrf89.lastRssi(), DEC);
}
else
{
Serial.println("recv failed");
}
}
else
{
Serial.println("No reply, is mrf89_server running?");
}
delay(400);
}
