L-Tek
Test program for FF1705.
Dependencies: libxDot-dev-mbed5-deprecated ISL29011
Example/src/peer_to_peer_example.cpp
- Committer:
- jernej_vrscaj
- Date:
- 2017-11-07
- Revision:
- 1:12a289bd6b82
- Parent:
- 0:d96e7e513c16
- Child:
- 2:9b44950b84af
File content as of revision 1:12a289bd6b82:
#include "dot_util.h"
#include "RadioEvent.h"
#include "mDotEvent.h"
#include "C12832.h"
#if ACTIVE_EXAMPLE == PEER_TO_PEER_EXAMPLE
#define TEST_board
//#define REFERENCE_board
/////////////////////////////////////////////////////////////////////////////
// -------------------- DOT LIBRARY REQUIRED ------------------------------//
// * Because these example programs can be used for both mDot and xDot //
// devices, the LoRa stack is not included. The libmDot library should //
// be imported if building for mDot devices. The libxDot library //
// should be imported if building for xDot devices. //
// * https://developer.mbed.org/teams/MultiTech/code/libmDot-dev-mbed5/ //
// * https://developer.mbed.org/teams/MultiTech/code/libmDot-mbed5/ //
// * https://developer.mbed.org/teams/MultiTech/code/libxDot-dev-mbed5/ //
// * https://developer.mbed.org/teams/MultiTech/code/libxDot-mbed5/ //
/////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////
// * these options must match between the two devices in //
// order for communication to be successful
/////////////////////////////////////////////////////////////
/*============================= INIT =========================================*/
static uint8_t network_address[] = { 0x01, 0x02, 0x03, 0x04 };
static uint8_t network_session_key[] = { 0x01, 0x02, 0x03, 0x04, 0x01, 0x02, 0x03, 0x04, 0x01, 0x02, 0x03, 0x04, 0x01, 0x02, 0x03, 0x04 };
static uint8_t data_session_key[] = { 0x01, 0x02, 0x03, 0x04, 0x01, 0x02, 0x03, 0x04, 0x01, 0x02, 0x03, 0x04, 0x01, 0x02, 0x03, 0x04 };
mDot* dot = NULL;
lora::ChannelPlan* plan = NULL;
Serial pc(USBTX, USBRX);
#ifdef TEST_board
C12832 lcd(PB_15, PB_13, PB_14, PA_12, PB_12); // init LCD
DigitalIn joystick_up(PB_2); // init button to start the send routine
DigitalOut led(PB_8, 1); // init LED to indicate sending messages
DigitalIn BTN_1(PA_5); // init LoRa button
DigitalOut LED_1(PA_4, 0); // init LoRa LED
uint8_t trx = 0x2F; // initial sending value (0x2F dec 47)
uint8_t sent = 0;
uint8_t sent_rx = 0;
#elif defined(REFERENCE_board)
DigitalOut led(PA_4, 0); // init LED to indicate sending messages
uint8_t received = 0; // check for RadioEvent
uint16_t *ptr_rx; // init pointer to RxBuffer
#endif
/*============================ END INIT ======================================*/
/*============================== MAIN ========================================*/
int main()
{
// Custom event handler for automatically displaying RX data
RadioEvent events;
uint32_t tx_frequency;
uint8_t tx_datarate;
uint8_t tx_power;
uint8_t frequency_band;
// sending data
pc.baud(115200);
mts::MTSLog::setLogLevel(mts::MTSLog::TRACE_LEVEL);
#if CHANNEL_PLAN == CP_US915
plan = new lora::ChannelPlan_US915();
#elif CHANNEL_PLAN == CP_AU915
plan = new lora::ChannelPlan_AU915();
#elif CHANNEL_PLAN == CP_EU868
plan = new lora::ChannelPlan_EU868();
#elif CHANNEL_PLAN == CP_KR920
plan = new lora::ChannelPlan_KR920();
#elif CHANNEL_PLAN == CP_AS923
plan = new lora::ChannelPlan_AS923();
#elif CHANNEL_PLAN == CP_AS923_JAPAN
plan = new lora::ChannelPlan_AS923_Japan();
#elif CHANNEL_PLAN == CP_IN865
plan = new lora::ChannelPlan_IN865();
#endif
assert(plan);
dot = mDot::getInstance(plan);
assert(dot);
logInfo("mbed-os library version: %d", MBED_LIBRARY_VERSION);
// start from a well-known state
logInfo("defaulting Dot configuration");
dot->resetConfig();
// make sure library logging is turned on
dot->setLogLevel(mts::MTSLog::INFO_LEVEL);
// attach the custom events handler
dot->setEvents(&events);
// update configuration if necessary
if (dot->getJoinMode() != mDot::PEER_TO_PEER) {
logInfo("changing network join mode to PEER_TO_PEER");
if (dot->setJoinMode(mDot::PEER_TO_PEER) != mDot::MDOT_OK) {
logError("failed to set network join mode to PEER_TO_PEER");
}
}
frequency_band = dot->getFrequencyBand();
switch (frequency_band) {
case lora::ChannelPlan::EU868_OLD:
case lora::ChannelPlan::EU868:
// 250kHz channels achieve higher throughput
// DR_6 : SF7 @ 250kHz
// DR_0 - DR_5 (125kHz channels) available but much slower
tx_frequency = 869850000;
tx_datarate = lora::DR_6;
// the 869850000 frequency is 100% duty cycle if the total power is under 7 dBm - tx power 4 + antenna gain 3 = 7
tx_power = 4;
break;
case lora::ChannelPlan::US915_OLD:
case lora::ChannelPlan::US915:
case lora::ChannelPlan::AU915_OLD:
case lora::ChannelPlan::AU915:
// 500kHz channels achieve highest throughput
// DR_8 : SF12 @ 500kHz
// DR_9 : SF11 @ 500kHz
// DR_10 : SF10 @ 500kHz
// DR_11 : SF9 @ 500kHz
// DR_12 : SF8 @ 500kHz
// DR_13 : SF7 @ 500kHz
// DR_0 - DR_3 (125kHz channels) available but much slower
tx_frequency = 915500000;
tx_datarate = lora::DR_13;
// 915 bands have no duty cycle restrictions, set tx power to max
tx_power = 20;
break;
case lora::ChannelPlan::AS923:
case lora::ChannelPlan::AS923_JAPAN:
// 250kHz channels achieve higher throughput
// DR_6 : SF7 @ 250kHz
// DR_0 - DR_5 (125kHz channels) available but much slower
tx_frequency = 924800000;
tx_datarate = lora::DR_6;
tx_power = 16;
break;
case lora::ChannelPlan::KR920:
// DR_5 : SF7 @ 125kHz
tx_frequency = 922700000;
tx_datarate = lora::DR_5;
tx_power = 14;
break;
default:
while (true) {
logFatal("no known channel plan in use - extra configuration is needed!");
wait(5);
}
break;
}
// in PEER_TO_PEER mode there is no join request/response transaction
// as long as both Dots are configured correctly, they should be able to communicate
update_peer_to_peer_config(network_address, network_session_key, data_session_key, tx_frequency, tx_datarate, tx_power);
// save changes to configuration
logInfo("saving configuration");
if (!dot->saveConfig()) {
logError("failed to save configuration");
}
// display configuration
display_config();
#ifdef TEST_board
while (true) {
lcd.locate(0,0);
lcd.printf("Zacni test s pritiskom na JOYSTICK tipko...");
// join network if not joined
if (!dot->getNetworkJoinStatus()) {
join_network();
}
while(!BTN_1) LED_1 = 1; // press btn to light up led
LED_1 = 0; // clear LED
if(joystick_up) { // wait for user input
sent = 1;
lcd.cls();
led = 0;
std::vector<uint8_t> tx_data;
trx++; // +1 to value to be send
tx_data.push_back((trx >> 8) & 0xFF); // shift data eg. 0x0031 -> 0x3100
tx_data.push_back(trx & 0xFF);
logInfo("send_data: 0x%x", trx);
lcd.locate(0,0);
lcd.printf("Poslano: %u", trx);
send_data(tx_data); // send data
wait(1);
if(!(sent && sent_rx))
{
lcd.locate(0,10);
lcd.printf("FAIL!");
lcd.locate(0,20);
lcd.printf("Preveri REFERENCNO platico.");
}
wait(4);
sent = 0;
sent_rx = 0;
lcd.cls();
led = 1;
}
}
#elif defined(REFERENCE_board)
while (true) {
std::vector<uint8_t> tx_data;
// join network if not joined
if (!dot->getNetworkJoinStatus()) {
join_network();
}
if(received) // RadioEvent happened
{
led = 1;
received = 0; // clear event flag
++*ptr_rx; // +1 to received value
tx_data.push_back((*ptr_rx >> 8) & 0xFF); // shift data eg. 0x0031 -> 0x3100
tx_data.push_back(*ptr_rx & 0xFF);
logInfo("Sent *ptr_rx: %#x", *ptr_rx);
send_data(tx_data); // then send back
wait(1);
led = 0;
NVIC_SystemReset(); // reset Reference board
}
}
#endif
return 0;
}
#endif
/*============================ END MAIN =======================================*/