upm/examples/c++/h803x.cxx

/*
 * Author: Jon Trulson <jtrulson@ics.com>
 * Copyright (c) 2016 Intel Corporation.
 *
 * This program and the accompanying materials are made available under the
 * terms of the The MIT License which is available at
 * https://opensource.org/licenses/MIT.
 *
 * SPDX-License-Identifier: MIT
 */

#include <iostream>
#include <signal.h>
#include <string>

#include "h803x.hpp"
#include "upm_utilities.h"

using namespace std;

bool shouldRun = true;

void
sig_handler(int signo)
{
    if (signo == SIGINT)
        shouldRun = false;
}

int
main(int argc, char** argv)
{
    signal(SIGINT, sig_handler);

    //! [Interesting]

    string defaultDev = "/dev/ttyUSB0";

    // if an argument was specified, use it as the device instead
    if (argc > 1)
        defaultDev = string(argv[1]);

    cout << "Using device " << defaultDev << endl;
    cout << "Initializing..." << endl;

    // Instantiate an H803X instance, using MODBUS slave address 1, and
    // default comm parameters (9600, 8, N, 2)
    upm::H803X sensor(defaultDev, 1);

    // output the Slave ID string
    cout << "Slave ID: " << sensor.getSlaveID() << endl;
    cout << endl;

    // update and print available values every second
    while (shouldRun) {
        // update our values from the sensor
        sensor.update();

        // H8035 / H8036
        cout << "Consumption (kWh): " << sensor.getConsumption() << endl;
        cout << "Real Power (kW): " << sensor.getRealPower() << endl;

        if (sensor.isH8036()) {
            // The H8036 has much more data available...

            cout << "Reactive Power (kVAR): " << sensor.getReactivePower() << endl;
            cout << "Apparent Power (kVA): " << sensor.getApparentPower() << endl;
            cout << "Power Factor: " << sensor.getPowerFactor() << endl;
            cout << "Volts Line to Line: " << sensor.getVoltsLineToLine() << endl;
            cout << "Volts Line to Neutral: " << sensor.getVoltsLineToNeutral() << endl;

            cout << "Current: " << sensor.getCurrent() << endl;

            cout << "Real Power Phase A (kW): " << sensor.getRealPowerPhaseA() << endl;
            cout << "Real Power Phase B (kW): " << sensor.getRealPowerPhaseB() << endl;
            cout << "Real Power Phase C (kW): " << sensor.getRealPowerPhaseC() << endl;

            cout << "Power Factor Phase A: " << sensor.getPowerFactorPhaseA() << endl;
            cout << "Power Factor Phase B: " << sensor.getPowerFactorPhaseB() << endl;
            cout << "Power Factor Phase C: " << sensor.getPowerFactorPhaseC() << endl;

            cout << "Volts Phase A to B: " << sensor.getVoltsPhaseAToB() << endl;
            cout << "Volts Phase B to C: " << sensor.getVoltsPhaseBToC() << endl;
            cout << "Volts Phase A to C: " << sensor.getVoltsPhaseAToC() << endl;
            cout << "Volts Phase A to Neutral: " << sensor.getVoltsPhaseAToNeutral() << endl;
            cout << "Volts Phase B to Neutral: " << sensor.getVoltsPhaseBToNeutral() << endl;
            cout << "Volts Phase C to Neutral: " << sensor.getVoltsPhaseCToNeutral() << endl;

            cout << "Current Phase A: " << sensor.getCurrentPhaseA() << endl;
            cout << "Current Phase B: " << sensor.getCurrentPhaseB() << endl;
            cout << "Current Phase C: " << sensor.getCurrentPhaseC() << endl;

            cout << "Avg Real Power (kW): " << sensor.getAvgRealPower() << endl;
            cout << "Min Real Power (kW): " << sensor.getMinRealPower() << endl;
            cout << "Max Real Power (kW): " << sensor.getMaxRealPower() << endl;
        }

        cout << endl;

        upm_delay(2);
    }

    cout << "Exiting..." << endl;

    //! [Interesting]

    return 0;
}