Below the script I used.
I am trying to get the EnergyMeterPulsSensor working without RF GW but directly connected via USB.
/**
- The MySensors Arduino library handles the wireless radio link and protocol
- between your home built sensors/actuators and HA controller of choice.
- The sensors forms a self healing radio network with optional repeaters. Each
- repeater and gateway builds a routing tables in EEPROM which keeps track of the
- network topology allowing messages to be routed to nodes.
- Created by Henrik Ekblad henrik.ekblad@mysensors.org
- Copyright (C) 2013-2015 Sensnology AB
- Full contributor list: https://github.com/mysensors/Arduino/graphs/contributors
- Documentation: http://www.mysensors.org
- Support Forum: http://forum.mysensors.org
- This program is free software; you can redistribute it and/or
- modify it under the terms of the GNU General Public License
- version 2 as published by the Free Software Foundation.
- DESCRIPTION
- The ArduinoGateway prints data received from sensors on the serial link.
- The gateway accepts input on seral which will be sent out on radio network.
- The GW code is designed for Arduino Nano 328p / 16MHz
- Wire connections (OPTIONAL):
-
- Inclusion button should be connected between digital pin 3 and GND
-
- RX/TX/ERR leds need to be connected between +5V (anode) and digital pin 6/5/4 with resistor 270-330R in a series
- LEDs (OPTIONAL):
-
- To use the feature, uncomment MY_LEDS_BLINKING_FEATURE in MyConfig.h
-
- RX (green) - blink fast on radio message recieved. In inclusion mode will blink fast only on presentation recieved
-
- TX (yellow) - blink fast on radio message transmitted. In inclusion mode will blink slowly
-
- ERR (red) - fast blink on error during transmission error or recieve crc error
*/
// Enable debug prints to serial monitor
#define MY_DEBUG
// Enable and select radio type attached
//#define MY_RADIO_NRF24
//#define MY_RADIO_RFM69
// Set LOW transmit power level as default, if you have an amplified NRF-module and
// power your radio separately with a good regulator you can turn up PA level.
//#define MY_RF24_PA_LEVEL RF24_PA_LOW
// Enable serial gateway
#define MY_GATEWAY_SERIAL
// Flash leds on rx/tx/err
#define MY_LEDS_BLINKING_FEATURE
// Set blinking period
#define MY_DEFAULT_LED_BLINK_PERIOD 300
// Inverses the behavior of leds
//#define MY_WITH_LEDS_BLINKING_INVERSE
// Enable inclusion mode
#define MY_INCLUSION_MODE_FEATURE
// Enable Inclusion mode button on gateway
#define MY_INCLUSION_BUTTON_FEATURE
// Inverses behavior of inclusion button (if using external pullup)
//#define MY_INCLUSION_BUTTON_EXTERNAL_PULLUP
// Set inclusion mode duration (in seconds)
#define MY_INCLUSION_MODE_DURATION 60
// Digital pin used for inclusion mode button
#define MY_INCLUSION_MODE_BUTTON_PIN 3
#define MY_DEFAULT_ERR_LED_PIN 4 // Error led pin
#define MY_DEFAULT_RX_LED_PIN 6 // Receive led pin
#define MY_DEFAULT_TX_LED_PIN 5 // the PCB, on board LED
#include <SPI.h>
#include <MySensor.h>
#define DIGITAL_INPUT_SENSOR 3 // The digital input you attached your light sensor. (Only 2 and 3 generates interrupt!)
#define PULSE_FACTOR 1000 // Nummber of blinks per KWH of your meeter
#define SLEEP_MODE false // Watt-value can only be reported when sleep mode is false.
#define MAX_WATT 10000 // Max watt value to report. This filetrs outliers.
#define INTERRUPT DIGITAL_INPUT_SENSOR-2 // Usually the interrupt = pin -2 (on uno/nano anyway)
#define CHILD_ID 1 // Id of the sensor child
unsigned long SEND_FREQUENCY = 20000; // Minimum time between send (in milliseconds). We don't wnat to spam the gateway.
MySensor gw;
double ppwh = ((double)PULSE_FACTOR)/1000; // Pulses per watt hour
boolean pcReceived = false;
volatile unsigned long pulseCount = 0;
volatile unsigned long lastBlink = 0;
volatile unsigned long watt = 0;
unsigned long oldPulseCount = 0;
unsigned long oldWatt = 0;
double oldKwh;
unsigned long lastSend;
MyMessage wattMsg(CHILD_ID,V_WATT);
MyMessage kwhMsg(CHILD_ID,V_KWH);
MyMessage pcMsg(CHILD_ID,V_VAR1);
void setup()
{
gw.begin(incomingMessage);
// Send the sketch version information to the gateway and Controller
gw.sendSketchInfo("Energy Meter", "1.0");
// Register this device as power sensor
gw.present(CHILD_ID, S_POWER);
// Fetch last known pulse count value from gw
gw.request(CHILD_ID, V_VAR1);
attachInterrupt(INTERRUPT, onPulse, RISING);
lastSend=millis();
}
void presentation() {
// Present locally attached sensors
}
void loop()
{
gw.process();
unsigned long now = millis();
// Only send values at a maximum frequency or woken up from sleep
bool sendTime = now - lastSend > SEND_FREQUENCY;
if (pcReceived && (SLEEP_MODE || sendTime)) {
// New watt value has been calculated
if (!SLEEP_MODE && watt != oldWatt) {
// Check that we dont get unresonable large watt value.
// could hapen when long wraps or false interrupt triggered
if (watt<((unsigned long)MAX_WATT)) {
gw.send(wattMsg.set(watt)); // Send watt value to gw
}
Serial.print("Watt:");
Serial.println(watt);
oldWatt = watt;
}
// Pulse cout has changed
if (pulseCount != oldPulseCount) {
gw.send(pcMsg.set(pulseCount)); // Send pulse count value to gw
double kwh = ((double)pulseCount/((double)PULSE_FACTOR));
oldPulseCount = pulseCount;
if (kwh != oldKwh) {
gw.send(kwhMsg.set(kwh, 4)); // Send kwh value to gw
oldKwh = kwh;
}
}
lastSend = now;
} else if (sendTime && !pcReceived) {
// No count received. Try requesting it again
gw.request(CHILD_ID, V_VAR1);
lastSend=now;
}
if (SLEEP_MODE) {
gw.sleep(SEND_FREQUENCY);
}
}
void incomingMessage(const MyMessage &message) {
if (message.type==V_VAR1) {
pulseCount = oldPulseCount = message.getLong();
Serial.print("Received last pulse count from gw:");
Serial.println(pulseCount);
pcReceived = true;
}
}
void onPulse()
{
if (!SLEEP_MODE) {
unsigned long newBlink = micros();
unsigned long interval = newBlink-lastBlink;
if (interval<10000L) { // Sometimes we get interrupt on RISING
return;
}
watt = (3600000000.0 /interval) / ppwh;
lastBlink = newBlink;
}
pulseCount++;
}