Demonstrates how to connect to Senet LoRaWAN Network and send data
Dependencies: libmDot mbed-rtos mbed
main.cpp
- Committer:
- shaunkrnelson
- Date:
- 2016-03-10
- Revision:
- 0:b6af80e4feef
- Child:
- 1:cf44cafafa48
File content as of revision 0:b6af80e4feef:
/*************************************************************************************************************** * Senet is the leading IoT network services provider for low cost, long range IoT applications. * * Senet provides network services for application developers who are searching for an affordable IoT * * network to launch and scale their solutions. * * * * This program demonstrates how to connect to Senet's public network with an mDot and sends some data * * * * On the Senet Developer Portal website you can view device transactions and even configure forwarding * * to IoT data collection and analysis services. * * * * Get started by registering for a Senet Developer Portal account at http://app.enertrac.com/senetdev/ * ****************************************************************************************************************/ #include "mbed.h" #include "mDot.h" #include "MTSLog.h" #include <string> #include <vector> #include <algorithm> // Senet Developer Portal Application EUI static uint8_t senetDevPortalAppEUI[8] = {0x00,0x25,0x0C,0x00,0x00,0x01,0x00,0x01}; // Your Device's application key provided by Senet on the Device setup page static uint8_t senetDevPortalAppKey[16] = {0xCA,0x40,0x36,0xB8,0xB2,0xB3,0x9F,0x4F,0xAB,0x84,0xD7,0xB3,0x65,0x8C,0x80,0xD3}; // Helper macro to initialize std::vector from array #define INIT_FROM_ARRAY(ar) ar, ar + sizeof(ar) / sizeof(ar[0]) // Uncomment this line if using a full sized UDK2.0 instead of a Micro UDK #define UDK2 1 #ifdef UDK2 DigitalOut led(LED1); DigitalOut tx_led(PA_1); #else DigitalOut led(XBEE_RSSI); #endif // Led blink ticker Ticker tick; // LED states #define OFF 1 #define ON 0 // Ticker callback function to change LED state void blink() { led = !led; } int main() { int32_t ret; mDot* dot; std::vector<uint8_t> data; std::string data_str = "hello!"; std::vector<uint8_t> appEUI(INIT_FROM_ARRAY(senetDevPortalAppEUI)); std::vector<uint8_t> appKey(INIT_FROM_ARRAY(senetDevPortalAppKey)); // configure the Ticker to blink the LED on 500ms interval while joining network led = OFF; tx_led = OFF; tick.attach(&blink, 0.5); // get a mDot handle dot = mDot::getInstance(); //******************************************* // configuration //******************************************* // reset to default config so we know what state we're in dot->resetConfig(); // Turn on mDot logging - output is on the debug UART at 9600 baud dot->setLogLevel(mts::MTSLog::INFO_LEVEL); // set up the mDot with our network information: frequency sub band, application, application encryption key // these can all be saved in NVM so they don't need to be set every time - see mDot::saveConfig() // Senet is a Public Network if ((ret = dot->setPublicNetwork(true))!= mDot::MDOT_OK) { logError("failed to set public network %d:%s", ret, mDot::getReturnCodeString(ret).c_str()); } // frequency sub band is only applicable in the 915 (US) frequency band // if using a gateway that only supports the first 8 channels, use sub band 1 (channels 1 - 8) // if using a gateway that supports all 64 channels, use sub band 0 - the mDot will use all 64 channels static uint8_t config_frequency_sub_band = 1; logInfo("setting frequency sub band"); if ((ret = dot->setFrequencySubBand(config_frequency_sub_band)) != mDot::MDOT_OK) { logError("failed to set frequency sub band %d:%s", ret, mDot::getReturnCodeString(ret).c_str()); } // Set Application Id to Senet Developer Portal logInfo("setting application EUI"); if ((ret = dot->setNetworkId(appEUI)) != mDot::MDOT_OK) { logError("failed to set application EUI %d:%s", ret, mDot::getReturnCodeString(ret).c_str()); } // Set AES-128 Application secret key logInfo("setting application key"); if ((ret = dot->setNetworkKey(appKey)) != mDot::MDOT_OK) { logError("failed to set network key %d:%s", ret, mDot::getReturnCodeString(ret).c_str()); } // a higher spreading factor allows for longer range but lower throughput // in the 915 (US) frequency band, spreading factors 7 - 10 are available logInfo("setting TX spreading factor"); if ((ret = dot->setTxDataRate(mDot::SF_10)) != mDot::MDOT_OK) { logError("failed to set TX datarate %d:%s", ret, mDot::getReturnCodeString(ret).c_str()); } // Enable Adaptive Data Rate Control so that the Network server can optimize our data rate and // transmit power for the network if((ret = dot->setAdr(true)) != mDot::MDOT_OK){ logError("failed to set ADR %d:%s", ret, mDot::getReturnCodeString(ret).c_str()); } // Set Join byte order to LSB if((ret = dot->setJoinByteOrder(mDot::LSB)) != mDot::MDOT_OK){ logError("failed to set join LSB byte order %d:%s", ret, mDot::getReturnCodeString(ret).c_str()); } // Set Over The Air Join mode if((ret = dot->setJoinMode(mDot::OTA)) != mDot::MDOT_OK){ logError("failed to set join OTA mode %d:%s", ret, mDot::getReturnCodeString(ret).c_str()); } // save this configuration to the mDot's NVM logInfo("saving config"); if (! dot->saveConfig()) { logError("failed to save configuration"); } //******************************************* // end of configuration //******************************************* // attempt to join the network logInfo("joining network"); while ((ret = dot->joinNetwork()) != mDot::MDOT_OK) { logError("failed to join network %d:%s", ret, mDot::getReturnCodeString(ret).c_str()); osDelay(5000); } // Detach ticker led callback tick.detach(); // Leave led ON led = ON; // format data to send for (std::string::iterator it = data_str.begin(); it != data_str.end(); it++) data.push_back((uint8_t) *it); while (true) { // send data tx_led = ON; if ((ret = dot->send(data)) != mDot::MDOT_OK) { logError("failed to send", ret, mDot::getReturnCodeString(ret).c_str()); } else { logInfo("successfully sent data on Senet network"); } tx_led = OFF; // Wait before transmitting again osDelay(60000); } }