Rev 1.0 4/26/2016 Paul Jaeger - Multitech, Brian Huey - Sprint Changed post interval to 2000ms added temp, analoguv and pressure to http post added alias: TEMP ANALOG-UV PRESSURE concatenated http post, to post all within the same routine and check for error after the post confirmed that data is published to Exosite

Dependencies:   MbedJSONValue mbed mtsas

Fork of UUU_MultiTech_Dragonfly_Sprint by Paul Jaeger

main.cpp

Committer:
mfiore
Date:
2015-09-25
Revision:
4:730b61258422
Parent:
3:f6bceb9e5e1a
Child:
5:a946ef74a8c4

File content as of revision 4:730b61258422:

/*************************************************************************
 * Dragonfly Example program for 2015 AT&T Government Solutions Hackathon
 * 
 * The following hardware is required to successfully run this program:
 *   - MultiTech UDK2 (4" square white PCB with Arduino headers, antenna
 *     connector, micro USB ports, and 40-pin connector for Dragonfly)
 *   - MultiTech Dragonfly (1"x2" green PCB with Telit radio)
 *   - Seeed Studio Base Shield
 *   - Grove moisture sensor (to connect to Base Shield)
 *   - Grove button (to connect to Base Shield)
 *   - MEMs Inertial and Environmental Nucleo Expansion board (LSM6DS0
 *     3-axis accelerometer + 3-axis gyroscope, LIS3MDL 3-axis
 *     magnetometer, HTS221 humidity and temperature sensor and LPS25HB
 *     pressure sensor)
 *
 * What this program does:
 *   - reads data from all sensors on MEMs board and moisture sensor on a
 *     periodic basis
 *   - prints all sensor data to debug port on a periodic basis
 *   - optionally send a SMS containing sensor data when the Grove Button
 *     is pushed (phone number must be configured)
 *   - optionally sends sensor data to AT&T M2X cloud platform (user must
 *     create own M2X account and configure a device)
 *
 * Setup:
 *   - Correctly insert SIM card into Dragonfly
 *   - Seat the Dragonfly on the UDK2 board
 *   - Connect an antenna to the connector on the Dragonfly labled "M"
 *   - Stack the Base Shield on the UDK2 Arduino headers
 *   - Connect the Grove button to the D8 socket on the Base Shield
 *   - Connect the Grove moisture sensor to the A0 socket on the Base
 *     Shield
 *   - Make sure the reference voltage selector switch (next to the A0
 *     socket) is switched to 5V so you get accurate analog readings
 *   - Stack the MEMs board on top of the Base Shield
 *   - Plug in the power cable
 *   - Plug a micro USB cable into the port below and slightly to the
 *     left of the Dragonfly (NOT the port on the Dragonfly)
 *
 * Go have fun and make something cool!
 *
 ************************************************************************/
 
#include "mbed.h"
#include "mtsas.h"
#include "x_nucleo_iks01a1.h"
#include "MbedJSONValue.h"
#include <string>

// Debug serial port
static Serial debug(USBTX, USBRX);

// MTSSerialFlowControl - serial link between processor and radio
static MTSSerialFlowControl* io;

// Cellular - radio object for cellular operations (SMS, TCP, etc)
Cellular* radio;

// APN associated with SIM card
// this APN should work for the AT&T SIM that came with your Dragonfly
//static const std::string apn = "";
static const std::string apn = "broadband";

// Phone number to send SMS messages to
static const std::string phone_number = "1xxxxxxxxxx";

// M2X variables
static const std::string m2x_device_id = "";
static const std::string m2x_key = "";
bool do_cloud_post = false;

// handle to MEMs board object
static X_NUCLEO_IKS01A1* mems = X_NUCLEO_IKS01A1::Instance();

// Moisture sensor
AnalogIn moisture_sensor(A0);

// Button
InterruptIn button(D8);
bool button_pressed = false;

// variables for sensor data
float temp_celsius;
float temp_fahrenheit;
float humidity_percent;
float pressure_mbar;
float moisture_percent;
int32_t mag_mgauss[3];
int32_t acc_mg[3];
int32_t gyro_mdps[3];

// http variables
HTTPClient* http;
HTTPJson* http_json;

// misc variables
static char wall_of_dash[] = "--------------------------------------------------";
bool radio_ok = false;
static int thpm_interval_ms = 2000;
static int motion_interval_ms = 250;
static int print_interval_ms = 5000;
int debug_baud = 115200;

// function prototypes
bool init_mtsas();
void read_temperature();
void read_humidity();
void read_pressure();
void read_moisture();
void read_magnetometer();
void read_accelerometer();
void read_gyroscope();
void button_irq();

// main
int main() {
    mts::MTSLog::setLogLevel(mts::MTSLog::TRACE_LEVEL);
    debug.baud(debug_baud);
    logInfo("starting...");
    
    radio_ok = init_mtsas();
    if (! radio_ok)
        logError("MTSAS init failed");
    else
        logInfo("MTSAS is ok");
        
    button.fall(&button_irq);
        
    Timer thpm_timer;
    Timer motion_timer;
    Timer print_timer;
    Timer post_timer;
    
    thpm_timer.start();
    motion_timer.start();
    print_timer.start();
    post_timer.start();
    
    while (true) {
        if (motion_timer.read_ms() > motion_interval_ms) {
            read_magnetometer();
            read_accelerometer();
            read_gyroscope();
            motion_timer.reset();
        }
        
        if (thpm_timer.read_ms() > thpm_interval_ms) {
            read_temperature();
            read_humidity();
            read_pressure();
            read_moisture();
            thpm_timer.reset();
        }
        
        if (print_timer.read_ms() > print_interval_ms) {
            logDebug("%s", wall_of_dash);
            logDebug("SENSOR DATA");
            logDebug("temperature: %f C\t%f F", temp_celsius, temp_fahrenheit);
            logDebug("humidity: %f%%",  humidity_percent);
            logDebug("pressure: %f mbar", pressure_mbar);
            logDebug("moisture: %f%%", moisture_percent);
            logDebug("magnetometer:\r\n\tx: %ld\ty: %ld\tz: %ld\tmgauss", mag_mgauss[0], mag_mgauss[1], mag_mgauss[2]);
            logDebug("accelerometer:\r\n\tx: %ld\ty: %ld\tz: %ld\tmg", acc_mg[0], acc_mg[1], acc_mg[2]);
            logDebug("gyroscope:\r\n\tx: %ld\ty: %ld\tz: %ld\tmdps", gyro_mdps[0], gyro_mdps[1], gyro_mdps[2]);
            logDebug("%s", wall_of_dash);
            print_timer.reset();
        }
        
        if (button_pressed) {
            logInfo("Button was pressed");
            button_pressed = false;
            if (radio_ok) {
                MbedJSONValue sms_json;
                string sms_str;
                
                sms_json["temp_C"] = temp_celsius;
                sms_json["temp_F"] = temp_fahrenheit;
                sms_json["humidity_percent"] = humidity_percent;
                sms_json["pressure_mbar"] = pressure_mbar;
                sms_json["moisture_percent"] = moisture_percent;
                sms_json["mag_mgauss"]["x"] = mag_mgauss[0];
                sms_json["mag_mgauss"]["y"] = mag_mgauss[1];
                sms_json["mag_mgauss"]["z"] = mag_mgauss[2];
                sms_json["acc_mg"]["x"] = acc_mg[0];
                sms_json["acc_mg"]["y"] = acc_mg[1];
                sms_json["acc_mg"]["z"] = acc_mg[2];
                sms_json["gyro_mdps"]["x"] = gyro_mdps[0];
                sms_json["gyro_mdps"]["y"] = gyro_mdps[1];
                sms_json["gyro_mdps"]["z"] = gyro_mdps[2];
                
                sms_str = "SENSOR DATA:\n";
                sms_str += sms_json.serialize();
                
                logDebug("sending SMS to %s:\r\n%s", phone_number.c_str(), sms_str.c_str());
                Code ret = radio->sendSMS(phone_number, sms_str);
                if (ret != MTS_SUCCESS)
                    logError("sending SMS failed");
            }
        }
        
        if (post_timer.read_ms() > post_interval_ms && do_cloud_post) {
            if (radio->connect()) {
                logDebug("posting sensor data");
                radio->disconnect();
            } else {
                logError("establishing PPP link failed");
            }
            
            post_timer.reset();
        }
        
        wait_ms(10);
    }
}

// init functions
bool init_mtsas() {
    io = new MTSSerialFlowControl(RADIO_TX, RADIO_RX, RADIO_RTS, RADIO_CTS);
    if (! io)
        return false;
        
    io->baud(115200);
    radio = CellularFactory::create(io);
    if (! radio)
        return false;
        
    Code ret = radio->setApn(apn);
    if (ret != MTS_SUCCESS)
        return false;
        
    return true;
}

// Sensor data acquisition functions
void read_temperature() {
    int ret;
    
    ret = mems->ht_sensor->GetTemperature(&temp_celsius);
    if (ret)
        logError("reading temp (C) failed");
        
    ret = mems->ht_sensor->GetFahrenheit(&temp_fahrenheit);
    if (ret)
        logError("reading temp (F) failed");
}

void read_humidity() {
    int ret;
    
    ret = mems->ht_sensor->GetHumidity(&humidity_percent);
    if (ret)
        logError("reading humidity failed");
}

void read_pressure() {
    int ret;
    
    ret = mems->pt_sensor->GetPressure(&pressure_mbar);
    if (ret)
        logError("reading pressure failed");
}

void read_moisture() {
    moisture_percent = moisture_sensor * 100.0;
}

void read_magnetometer() {
    int ret;
    
    ret = mems->magnetometer->Get_M_Axes(mag_mgauss);
    if (ret)
        logError("reading magnetometer failed");
}

void read_accelerometer() {
    int ret;
    
    ret = mems->GetAccelerometer()->Get_X_Axes(acc_mg);
    if (ret)
        logError("reading accelerometer failed");
}

void read_gyroscope() {
    int ret;
    
    ret = mems->GetGyroscope()->Get_G_Axes(gyro_mdps);
    if (ret)
        logError("reading gyroscope failed");
}

void button_irq() {
    button_pressed = true;
}