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mhsw-espurna/code/espurna/sensors/PZEM004TSensor.h

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// -----------------------------------------------------------------------------
// PZEM004T based power monitor
// Copyright (C) 2018 by Xose Pérez <xose dot perez at gmail dot com>
// -----------------------------------------------------------------------------
// Connection Diagram:
// -------------------
//
// Needed when connecting multiple PZEM004T devices on the same UART
// *You must set the PZEM004T device address prior using this configuration*
//
// +---------+
// | ESPurna | +VCC
// | Node | ^
// | G T R | |
// +-+--+--+-+ R (10K)
// | | | |
// | | +-----------------+---------------+---------------+
// | +-----------------+--|------------+--|------------+ |
// +-----------------+--|--|---------+--|--|---------+ | |
// | | | | | | | | |
// | | V | | V | | V
// | | - | | - | | -
// +-+--+--+-+ +-+--+--+-+ +-+--+--+-+
// | G R T | | G R T | | G R T |
// |PZEM-004T| |PZEM-004T| |PZEM-004T|
// | Module | | Module | | Module |
// +---------+ +---------+ +---------+
//
// Where:
// ------
// G = GND
// R = ESPurna UART RX
// T = ESPurna UART TX
// V = Small Signal Schottky Diode, like BAT43,
// Cathode to PZEM TX, Anode to Espurna RX
// R = Resistor to VCC, 10K
//
// More Info:
// ----------
// See ESPurna Wiki - https://github.com/xoseperez/espurna/wiki/Sensor-PZEM004T
//
// Reference:
// ----------
// UART/TTL-Serial network with single master and multiple slaves:
// http://cool-emerald.blogspot.com/2009/10/multidrop-network-for-rs232.html
#if SENSOR_SUPPORT && PZEM004T_SUPPORT
#pragma once
#include "Arduino.h"
#include "BaseSensor.h"
#include <PZEM004T.h>
#define PZ_MAGNITUDE_COUNT 4
#define PZ_MAGNITUDE_CURRENT_INDEX 0
#define PZ_MAGNITUDE_VOLTAGE_INDEX 1
#define PZ_MAGNITUDE_POWER_ACTIVE_INDEX 2
#define PZ_MAGNITUDE_ENERGY_INDEX 3
class PZEM004TSensor : public BaseSensor {
public:
// ---------------------------------------------------------------------
// Public
// ---------------------------------------------------------------------
PZEM004TSensor(): BaseSensor() {
_sensor_id = SENSOR_PZEM004T_ID;
}
~PZEM004TSensor() {
if (_pzem) delete _pzem;
}
// ---------------------------------------------------------------------
void setRX(unsigned char pin_rx) {
if (_pin_rx == pin_rx) return;
_pin_rx = pin_rx;
_dirty = true;
}
void setTX(unsigned char pin_tx) {
if (_pin_tx == pin_tx) return;
_pin_tx = pin_tx;
_dirty = true;
}
void setSerial(HardwareSerial * serial) {
_serial = serial;
_dirty = true;
}
// Set the devices physical addresses managed by this sensor
void setAddresses(const char *addresses) {
char const * sep = " ";
char tokens[strlen(addresses) + 1];
strlcpy(tokens, addresses, sizeof(tokens));
char *address = tokens;
int i = 0;
address = strtok(address, sep);
while (address != 0 && i++ < PZEM004T_MAX_DEVICES) {
IPAddress addr;
reading_t reading;
reading.current = PZEM_ERROR_VALUE;
reading.voltage = PZEM_ERROR_VALUE;
reading.power = PZEM_ERROR_VALUE;
reading.energy = PZEM_ERROR_VALUE;
if (addr.fromString(address)) {
_devices.push_back(addr);
_energy_offsets.push_back(0);
_readings.push_back(reading);
}
address = strtok(0, sep);
}
_count = _devices.size() * PZ_MAGNITUDE_COUNT;
_dirty = true;
}
// Return the number of devices managed by this sensor
unsigned char getAddressesCount() {
return _devices.size();
}
// Get device physical address based on the device index
String getAddress(unsigned char dev) {
return _devices[dev].toString();
}
// Set the device physical address
bool setDeviceAddress(IPAddress *addr) {
while(_busy) { yield(); };
_busy = true;
bool res = _pzem->setAddress(*addr);
_busy = false;
return res;
}
// ---------------------------------------------------------------------
unsigned char getRX() {
return _pin_rx;
}
unsigned char getTX() {
return _pin_tx;
}
// ---------------------------------------------------------------------
// If called with value = -1, the offset will be the last energy reading
// otherwise, it will be the value provided
float resetEnergy(unsigned char dev, float value = -1) {
_energy_offsets[dev] = value != -1 ? value : _readings[dev].energy;
return _energy_offsets[dev];
}
// ---------------------------------------------------------------------
// Sensor API
// ---------------------------------------------------------------------
// Initialization method, must be idempotent
void begin() {
if (!_dirty) return;
if (_pzem) delete _pzem;
if (_serial) {
_pzem = new PZEM004T(_serial);
} else {
_pzem = new PZEM004T(_pin_rx, _pin_tx);
}
if(_devices.size() == 1) _pzem->setAddress(_devices[0]);
_ready = true;
_dirty = false;
}
// Descriptive name of the sensor
String description() {
char buffer[27];
if (_serial) {
snprintf(buffer, sizeof(buffer), "PZEM004T @ HwSerial");
} else {
snprintf(buffer, sizeof(buffer), "PZEM004T @ SwSerial(%u,%u)", _pin_rx, _pin_tx);
}
return String(buffer);
}
// Descriptive name of the slot # index
String slot(unsigned char index) {
int dev = index / PZ_MAGNITUDE_COUNT;
char buffer[25];
snprintf(buffer, sizeof(buffer), "(%u/%s)", dev, getAddress(dev).c_str());
return description() + String(buffer);
};
// Address of the sensor (it could be the GPIO or I2C address)
String address(unsigned char index) {
int dev = index / PZ_MAGNITUDE_COUNT;
return _devices[dev].toString();
}
// Type for slot # index
unsigned char type(unsigned char index) {
int dev = index / PZ_MAGNITUDE_COUNT;
index = index - (dev * PZ_MAGNITUDE_COUNT);
if (index == PZ_MAGNITUDE_CURRENT_INDEX) return MAGNITUDE_CURRENT;
if (index == PZ_MAGNITUDE_VOLTAGE_INDEX) return MAGNITUDE_VOLTAGE;
if (index == PZ_MAGNITUDE_POWER_ACTIVE_INDEX) return MAGNITUDE_POWER_ACTIVE;
if (index == PZ_MAGNITUDE_ENERGY_INDEX) return MAGNITUDE_ENERGY;
return MAGNITUDE_NONE;
}
// Current value for slot # index
double value(unsigned char index) {
int dev = index / PZ_MAGNITUDE_COUNT;
index = index - (dev * PZ_MAGNITUDE_COUNT);
double response = 0;
if (index == PZ_MAGNITUDE_CURRENT_INDEX) response = _readings[dev].current;
if (index == PZ_MAGNITUDE_VOLTAGE_INDEX) response = _readings[dev].voltage;
if (index == PZ_MAGNITUDE_POWER_ACTIVE_INDEX) response = _readings[dev].power;
if (index == PZ_MAGNITUDE_ENERGY_INDEX) response = (_readings[dev].energy * 3600) - _energy_offsets[dev];
if (response < 0) response = 0;
return response;
}
// Post-read hook (usually to reset things)
void post() {
_error = SENSOR_ERROR_OK;
}
// Loop-like method, call it in your main loop
void tick() {
static unsigned char dev = 0;
static unsigned char magnitude = 0;
static unsigned long last_millis = 0;
if (_busy || millis() - last_millis < PZEM004T_READ_INTERVAL) return;
_busy = true;
// Clear buffer in case of late response(Timeout)
while(Serial.available() > 0) Serial.read();
float read;
float* readings_p;
switch(magnitude) {
case PZ_MAGNITUDE_CURRENT_INDEX:
read = _pzem->current(_devices[dev]);
readings_p = &_readings[dev].current;
break;
case PZ_MAGNITUDE_VOLTAGE_INDEX:
read = _pzem->voltage(_devices[dev]);
readings_p = &_readings[dev].voltage;
break;
case PZ_MAGNITUDE_POWER_ACTIVE_INDEX:
read = _pzem->power(_devices[dev]);
readings_p = &_readings[dev].power;
break;
case PZ_MAGNITUDE_ENERGY_INDEX:
read = _pzem->energy(_devices[dev]);
readings_p = &_readings[dev].energy;
break;
default:
_busy = false;
return;
}
if(read == PZEM_ERROR_VALUE) {
_error = SENSOR_ERROR_TIMEOUT;
} else {
*readings_p = read;
}
if(++dev == _devices.size()) {
dev = 0;
last_millis = millis();
if(++magnitude == PZ_MAGNITUDE_COUNT) {
magnitude = 0;
}
}
_busy = false;
}
protected:
// ---------------------------------------------------------------------
// Protected
// ---------------------------------------------------------------------
unsigned int _pin_rx = PZEM004T_RX_PIN;
unsigned int _pin_tx = PZEM004T_TX_PIN;
bool _busy = false;
typedef struct {
float voltage;
float current;
float power;
float energy;
} reading_t;
std::vector<reading_t> _readings;
std::vector<float> _energy_offsets;
std::vector<IPAddress> _devices;
HardwareSerial * _serial = NULL;
PZEM004T * _pzem = NULL;
};
#endif // SENSOR_SUPPORT && PZEM004T_SUPPORT