acid-drop/lib/RadioLib/examples/Si443x/Si443x_Settings/Si443x_Settings.ino

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2024-05-23 22:42:03 +00:00
/*
RadioLib Si443x Settings Example
This example shows how to change all the properties of RF69 radio.
RadioLib currently supports the following settings:
- pins (SPI slave select, nIRQ, shutdown)
- carrier frequency
- bit rate
- receiver bandwidth
- frequency deviation
- output power during transmission
- sync word
For default module settings, see the wiki page
https://github.com/jgromes/RadioLib/wiki/Default-configuration#si443xrfm2x
For full API reference, see the GitHub Pages
https://jgromes.github.io/RadioLib/
*/
// include the library
#include <RadioLib.h>
// Si4432 has the following connections:
// nSEL pin: 10
// nIRQ pin: 2
// SDN pin: 9
Si4432 radio1 = new Module(10, 2, 9);
// Si4432 has the following connections:
// nSEL pin: 8
// nIRQ pin: 3
// SDN pin: 7
Si4432 radio2 = new Module(8, 3, 7);
// or using RadioShield
// https://github.com/jgromes/RadioShield
//Si4432 radio3 = RadioShield.ModuleB;
void setup() {
Serial.begin(9600);
// initialize Si4432 with default settings
Serial.print(F("[Si4432] Initializing ... "));
int state = radio1.begin();
if (state == RADIOLIB_ERR_NONE) {
Serial.println(F("success!"));
} else {
Serial.print(F("failed, code "));
Serial.println(state);
while (true);
}
// initialize Si4432 with non-default settings
Serial.print(F("[Si4432] Initializing ... "));
// carrier frequency: 868.0 MHz
// bit rate: 200.0 kbps
// frequency deviation: 60.0 kHz
// Rx bandwidth: 335.5 kHz
// output power: 17 dBm
// preamble length: 32 bits
state = radio2.begin(868.0, 200.0, 60.0, 335.5, 17, 32);
if (state == RADIOLIB_ERR_NONE) {
Serial.println(F("success!"));
} else {
Serial.print(F("failed, code "));
Serial.println(state);
while (true);
}
// you can also change the settings at runtime
// and check if the configuration was changed successfully
// set carrier frequency to 433.5 MHz
if (radio1.setFrequency(433.5) == RADIOLIB_ERR_INVALID_FREQUENCY) {
Serial.println(F("[Si4432] Selected frequency is invalid for this module!"));
while (true);
}
// set bit rate to 100.0 kbps
state = radio1.setBitRate(100.0);
if (state == RADIOLIB_ERR_INVALID_BIT_RATE) {
Serial.println(F("[Si4432] Selected bit rate is invalid for this module!"));
while (true);
} else if (state == RADIOLIB_ERR_INVALID_BIT_RATE_BW_RATIO) {
Serial.println(F("[Si4432] Selected bit rate to bandwidth ratio is invalid!"));
Serial.println(F("[Si4432] Increase receiver bandwidth to set this bit rate."));
while (true);
}
// set receiver bandwidth to 284.8 kHz
state = radio1.setRxBandwidth(284.8);
if (state == RADIOLIB_ERR_INVALID_RX_BANDWIDTH) {
Serial.println(F("[Si4432] Selected receiver bandwidth is invalid for this module!"));
while (true);
}
// set frequency deviation to 10.0 kHz
if (radio1.setFrequencyDeviation(10.0) == RADIOLIB_ERR_INVALID_FREQUENCY_DEVIATION) {
Serial.println(F("[Si4432] Selected frequency deviation is invalid for this module!"));
while (true);
}
// set output power to 2 dBm
if (radio1.setOutputPower(2) == RADIOLIB_ERR_INVALID_OUTPUT_POWER) {
Serial.println(F("[Si4432] Selected output power is invalid for this module!"));
while (true);
}
// up to 4 bytes can be set as sync word
// set sync word to 0x01234567
uint8_t syncWord[] = {0x01, 0x23, 0x45, 0x67};
if (radio1.setSyncWord(syncWord, 4) == RADIOLIB_ERR_INVALID_SYNC_WORD) {
Serial.println(F("[Si4432] Selected sync word is invalid for this module!"));
while (true);
}
Serial.println(F("[Si4432] All settings changed successfully!"));
}
void loop() {
// nothing here
}