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raw-feather.ino
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raw-feather.ino
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/*
Module: raw-feather.ino
Function:
Slightly improved Raw test example, for Adafruit Feather M0 LoRa
Copyright notice and License:
See LICENSE file accompanying this project.
Author:
Matthijs Kooijman 2015
Terry Moore, MCCI Corporation April 2017
*/
/*******************************************************************************
* Copyright (c) 2015 Matthijs Kooijman
*
* Permission is hereby granted, free of charge, to anyone
* obtaining a copy of this document and accompanying files,
* to do whatever they want with them without any restriction,
* including, but not limited to, copying, modification and redistribution.
* NO WARRANTY OF ANY KIND IS PROVIDED.
*
* This example transmits data on hardcoded channel and receives data
* when not transmitting. Running this sketch on two nodes should allow
* them to communicate.
*******************************************************************************/
#include <lmic.h>
#include <hal/hal.h>
#include <SPI.h>
#include <stdarg.h>
#include <stdio.h>
// we formerly would check this configuration; but now there is a flag,
// in the LMIC, LMIC.noRXIQinversion;
// if we set that during init, we get the same effect. If
// DISABLE_INVERT_IQ_ON_RX is defined, it means that LMIC.noRXIQinversion is
// treated as always set.
//
// #if !defined(DISABLE_INVERT_IQ_ON_RX)
// #error This example requires DISABLE_INVERT_IQ_ON_RX to be set. Update \
// lmic_project_config.h in arduino-lmic/project_config to set it.
// #endif
// How often to send a packet. Note that this sketch bypasses the normal
// LMIC duty cycle limiting, so when you change anything in this sketch
// (payload length, frequency, spreading factor), be sure to check if
// this interval should not also be increased.
// See this spreadsheet for an easy airtime and duty cycle calculator:
// https://docs.google.com/spreadsheets/d/1voGAtQAjC1qBmaVuP1ApNKs1ekgUjavHuVQIXyYSvNc
#define TX_INTERVAL 2000 // milliseconds
#define RX_RSSI_INTERVAL 100 // milliseconds
// Pin mapping for Adafruit Feather M0 LoRa, etc.
//
// Adafruit BSPs are not consistent -- m0 express defs ARDUINO_SAMD_FEATHER_M0,
// m0 defs ADAFRUIT_FEATHER_M0
//
#if defined(ARDUINO_SAMD_FEATHER_M0) || defined(ADAFRUIT_FEATHER_M0)
// /!\ By default Adafruit Feather M0's pin 6 and DIO1 are not connected.
// Please ensure they are connected.
const lmic_pinmap lmic_pins = {
.nss = 8,
.rxtx = LMIC_UNUSED_PIN,
.rst = 4,
.dio = {3, 6, LMIC_UNUSED_PIN},
.rxtx_rx_active = 0,
.rssi_cal = 8, // LBT cal for the Adafruit Feather M0 LoRa, in dB
.spi_freq = 8000000,
};
#elif defined(ARDUINO_AVR_FEATHER32U4)
// Pin mapping for Adafruit Feather 32u4 LoRa, etc.
// Just like Feather M0 LoRa, but uses SPI at 1MHz; and that's only
// because MCCI doesn't have a test board; probably higher frequencies
// will work.
// /!\ By default Feather 32u4's pin 6 and DIO1 are not connected. Please
// ensure they are connected.
const lmic_pinmap lmic_pins = {
.nss = 8,
.rxtx = LMIC_UNUSED_PIN,
.rst = 4,
.dio = {7, 6, LMIC_UNUSED_PIN},
.rxtx_rx_active = 0,
.rssi_cal = 8, // LBT cal for the Adafruit Feather 32U4 LoRa, in dB
.spi_freq = 1000000,
};
#elif defined(ARDUINO_CATENA_4551)
const lmic_pinmap lmic_pins = {
.nss = 7,
.rxtx = 29,
.rst = 8,
.dio = { 25, // DIO0 (IRQ) is D25
26, // DIO1 is D26
27, // DIO2 is D27
},
.rxtx_rx_active = 1,
.rssi_cal = 10,
.spi_freq = 8000000 // 8MHz
};
#else
# error "Unknown target"
#endif
// These callbacks are only used in over-the-air activation, so they are
// left empty here (we cannot leave them out completely unless
// DISABLE_JOIN is set in arduino-lmoc/project_config/lmic_project_config.h,
// otherwise the linker will complain).
void os_getArtEui (u1_t* buf) { }
void os_getDevEui (u1_t* buf) { }
void os_getDevKey (u1_t* buf) { }
// this gets callled by the library but we choose not to display any info;
// and no action is required.
void onEvent (ev_t ev) {
}
/*************************************************************\
| Work around for inconsistency in providing
| Serial.dtr() method
\*************************************************************/
// Use SFINAE to deal with lack of Serial.dtr() on some platforms
template<class T>
auto getDtr_help(T* obj)
-> decltype( obj->dtr() )
{
return obj->dtr();
}
// use this if there's no dtr() method
auto getDtr_help(...) -> bool
{
return false;
}
// this wrapper lets us avoid use of explicit pointers
template<class T>
bool getDtr(T &obj)
{
return getDtr_help(&obj);
}
/*************************************************************\
| Print stub for use by LMIC
\*************************************************************/
extern "C" {
void lmic_printf(const char *fmt, ...);
};
void lmic_printf(const char *fmt, ...) {
if (! getDtr(Serial))
return;
char buf[256];
va_list ap;
va_start(ap, fmt);
(void) vsnprintf(buf, sizeof(buf) - 1, fmt, ap);
va_end(ap);
// in case we overflowed:
buf[sizeof(buf) - 1] = '\0';
if (getDtr(Serial)) Serial.print(buf);
}
/*************************************************************\
| Application logic
\*************************************************************/
osjob_t txjob;
osjob_t timeoutjob;
static void tx_func (osjob_t* job);
// Transmit the given string and call the given function afterwards
void tx(const char *str, osjobcb_t func) {
// the radio is probably in RX mode; stop it.
os_radio(RADIO_RST);
// wait a bit so the radio can come out of RX mode
delay(1);
// prepare data
LMIC.dataLen = 0;
while (*str)
LMIC.frame[LMIC.dataLen++] = *str++;
// set completion function.
LMIC.osjob.func = func;
// start the transmission
os_radio(RADIO_TX);
Serial.println("TX");
}
// Enable rx mode and call func when a packet is received
void rx(osjobcb_t func) {
LMIC.osjob.func = func;
LMIC.rxtime = os_getTime(); // RX _now_
// Enable "continuous" RX (e.g. without a timeout, still stops after
// receiving a packet)
os_radio(RADIO_RXON);
Serial.println("RX");
}
static void rxtimeout_func(osjob_t *job) {
digitalWrite(LED_BUILTIN, LOW); // off
}
static void rx_func (osjob_t* job) {
// Blink once to confirm reception and then keep the led on
digitalWrite(LED_BUILTIN, LOW); // off
delay(10);
digitalWrite(LED_BUILTIN, HIGH); // on
// Timeout RX (i.e. update led status) after 3 periods without RX
os_setTimedCallback(&timeoutjob, os_getTime() + ms2osticks(3*TX_INTERVAL), rxtimeout_func);
// Reschedule TX so that it should not collide with the other side's
// next TX
os_setTimedCallback(&txjob, os_getTime() + ms2osticks(TX_INTERVAL/2), tx_func);
Serial.print("Got ");
Serial.print(LMIC.dataLen);
Serial.println(" bytes");
Serial.write(LMIC.frame, LMIC.dataLen);
Serial.println();
// Restart RX
rx(rx_func);
}
static void txdone_func (osjob_t* job) {
rx(rx_func);
}
// log text to USART and toggle LED
static void tx_func (osjob_t* job) {
// say hello
tx("Hello, world!", txdone_func);
// reschedule job every TX_INTERVAL (plus a bit of random to prevent
// systematic collisions), unless packets are received, then rx_func
// will reschedule at half this time.
os_setTimedCallback(job, os_getTime() + ms2osticks(TX_INTERVAL + random(500)), tx_func);
}
// application entry point
void setup() {
// delay(3000) makes recovery from botched images much easier, as it
// gives the host time to break in to start a download. Without it,
// you get to the crash before the host can break in.
delay(3000);
// even after the delay, we wait for the host to open the port. operator
// bool(Serial) just checks dtr(), and it tosses in a 10ms delay.
while(! getDtr(Serial))
/* wait for the PC */;
Serial.begin(115200);
Serial.println("Starting");
#ifdef VCC_ENABLE
// For Pinoccio Scout boards
pinMode(VCC_ENABLE, OUTPUT);
digitalWrite(VCC_ENABLE, HIGH);
delay(1000);
#endif
pinMode(LED_BUILTIN, OUTPUT);
// initialize runtime env
os_init();
// Set up these settings once, and use them for both TX and RX
#ifdef ARDUINO_ARCH_STM32
LMIC_setClockError(10*65536/100);
#endif
#if defined(CFG_eu868)
// Use a frequency in the g3 which allows 10% duty cycling.
LMIC.freq = 869525000;
// Use a medium spread factor. This can be increased up to SF12 for
// better range, but then, the interval should be (significantly)
// raised to comply with duty cycle limits as well.
LMIC.datarate = DR_SF9;
// Maximum TX power
LMIC.txpow = 27;
#elif defined(CFG_us915)
// make it easier for test, by pull the parameters up to the top of the
// block. Ideally, we'd use the serial port to drive this; or have
// a voting protocol where one side is elected the controller and
// guides the responder through all the channels, powers, ramps
// the transmit power from min to max, and measures the RSSI and SNR.
// Even more amazing would be a scheme where the controller could
// handle multiple nodes; in that case we'd have a way to do
// production test and qualification. However, using an RWC5020A
// is a much better use of development time.
// set fDownlink true to use a downlink channel; false
// to use an uplink channel. Generally speaking, uplink
// is more interesting, because you can prove that gateways
// *should* be able to hear you.
const static bool fDownlink = false;
// the downlink channel to be used.
const static uint8_t kDownlinkChannel = 3;
// the uplink channel to be used.
const static uint8_t kUplinkChannel = 8 + 3;
// this is automatically set to the proper bandwidth in kHz,
// based on the selected channel.
uint32_t uBandwidth;
if (! fDownlink)
{
if (kUplinkChannel < 64)
{
LMIC.freq = US915_125kHz_UPFBASE +
kUplinkChannel * US915_125kHz_UPFSTEP;
uBandwidth = 125;
}
else
{
LMIC.freq = US915_500kHz_UPFBASE +
(kUplinkChannel - 64) * US915_500kHz_UPFSTEP;
uBandwidth = 500;
}
}
else
{
// downlink channel
LMIC.freq = US915_500kHz_DNFBASE +
kDownlinkChannel * US915_500kHz_DNFSTEP;
uBandwidth = 500;
}
// Use a suitable spreading factor
if (uBandwidth < 500)
LMIC.datarate = US915_DR_SF7; // DR4
else
LMIC.datarate = US915_DR_SF12CR; // DR8
// default tx power for US: 21 dBm
LMIC.txpow = 21;
#elif defined(CFG_au915)
// make it easier for test, by pull the parameters up to the top of the
// block. Ideally, we'd use the serial port to drive this; or have
// a voting protocol where one side is elected the controller and
// guides the responder through all the channels, powers, ramps
// the transmit power from min to max, and measures the RSSI and SNR.
// Even more amazing would be a scheme where the controller could
// handle multiple nodes; in that case we'd have a way to do
// production test and qualification. However, using an RWC5020A
// is a much better use of development time.
// set fDownlink true to use a downlink channel; false
// to use an uplink channel. Generally speaking, uplink
// is more interesting, because you can prove that gateways
// *should* be able to hear you.
const static bool fDownlink = false;
// the downlink channel to be used.
const static uint8_t kDownlinkChannel = 3;
// the uplink channel to be used.
const static uint8_t kUplinkChannel = 8 + 3;
// this is automatically set to the proper bandwidth in kHz,
// based on the selected channel.
uint32_t uBandwidth;
if (! fDownlink)
{
if (kUplinkChannel < 64)
{
LMIC.freq = AU915_125kHz_UPFBASE +
kUplinkChannel * AU915_125kHz_UPFSTEP;
uBandwidth = 125;
}
else
{
LMIC.freq = AU915_500kHz_UPFBASE +
(kUplinkChannel - 64) * AU915_500kHz_UPFSTEP;
uBandwidth = 500;
}
}
else
{
// downlink channel
LMIC.freq = AU915_500kHz_DNFBASE +
kDownlinkChannel * AU915_500kHz_DNFSTEP;
uBandwidth = 500;
}
// Use a suitable spreading factor
if (uBandwidth < 500)
LMIC.datarate = AU915_DR_SF7; // DR4
else
LMIC.datarate = AU915_DR_SF12CR; // DR8
// default tx power for AU: 30 dBm
LMIC.txpow = 30;
#elif defined(CFG_as923)
// make it easier for test, by pull the parameters up to the top of the
// block. Ideally, we'd use the serial port to drive this; or have
// a voting protocol where one side is elected the controller and
// guides the responder through all the channels, powers, ramps
// the transmit power from min to max, and measures the RSSI and SNR.
// Even more amazing would be a scheme where the controller could
// handle multiple nodes; in that case we'd have a way to do
// production test and qualification. However, using an RWC5020A
// is a much better use of development time.
const static uint8_t kChannel = 0;
uint32_t uBandwidth;
LMIC.freq = AS923_F1 + kChannel * 200000;
uBandwidth = 125;
// Use a suitable spreading factor
if (uBandwidth == 125)
LMIC.datarate = AS923_DR_SF7; // DR7
else
LMIC.datarate = AS923_DR_SF7B; // DR8
// default tx power for AS: 21 dBm
LMIC.txpow = 16;
if (LMIC_COUNTRY_CODE == LMIC_COUNTRY_CODE_JP)
{
LMIC.lbt_ticks = us2osticks(AS923JP_LBT_US);
LMIC.lbt_dbmax = AS923JP_LBT_DB_MAX;
}
#elif defined(CFG_kr920)
// make it easier for test, by pull the parameters up to the top of the
// block. Ideally, we'd use the serial port to drive this; or have
// a voting protocol where one side is elected the controller and
// guides the responder through all the channels, powers, ramps
// the transmit power from min to max, and measures the RSSI and SNR.
// Even more amazing would be a scheme where the controller could
// handle multiple nodes; in that case we'd have a way to do
// production test and qualification. However, using an RWC5020A
// is a much better use of development time.
const static uint8_t kChannel = 0;
uint32_t uBandwidth;
LMIC.freq = KR920_F1 + kChannel * 200000;
uBandwidth = 125;
LMIC.datarate = KR920_DR_SF7; // DR7
// default tx power for KR: 14 dBm
LMIC.txpow = KR920_TX_EIRP_MAX_DBM;
if (LMIC.freq < KR920_F14DBM)
LMIC.txpow = KR920_TX_EIRP_MAX_DBM_LOW;
LMIC.lbt_ticks = us2osticks(KR920_LBT_US);
LMIC.lbt_dbmax = KR920_LBT_DB_MAX;
#elif defined(CFG_in866)
// make it easier for test, by pull the parameters up to the top of the
// block. Ideally, we'd use the serial port to drive this; or have
// a voting protocol where one side is elected the controller and
// guides the responder through all the channels, powers, ramps
// the transmit power from min to max, and measures the RSSI and SNR.
// Even more amazing would be a scheme where the controller could
// handle multiple nodes; in that case we'd have a way to do
// production test and qualification. However, using an RWC5020A
// is a much better use of development time.
const static uint8_t kChannel = 0;
uint32_t uBandwidth;
LMIC.freq = IN866_F1 + kChannel * 200000;
uBandwidth = 125;
LMIC.datarate = IN866_DR_SF7; // DR7
// default tx power for IN: 30 dBm
LMIC.txpow = IN866_TX_EIRP_MAX_DBM;
#else
# error Unsupported LMIC regional configuration.
#endif
// disable RX IQ inversion
LMIC.noRXIQinversion = true;
// This sets CR 4/5, BW125 (except for EU/AS923 DR_SF7B, which uses BW250)
LMIC.rps = updr2rps(LMIC.datarate);
Serial.print("Frequency: "); Serial.print(LMIC.freq / 1000000);
Serial.print("."); Serial.print((LMIC.freq / 100000) % 10);
Serial.print("MHz");
Serial.print(" LMIC.datarate: "); Serial.print(LMIC.datarate);
Serial.print(" LMIC.txpow: "); Serial.println(LMIC.txpow);
Serial.println("Started");
Serial.flush();
// setup initial job
os_setCallback(&txjob, tx_func);
}
void loop() {
// execute scheduled jobs and events
os_runloop_once();
}