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_P170_HLW8012.ino
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_P170_HLW8012.ino
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//#######################################################################################################
//#################### Plugin 170 HLW8012 AC Current and Voltage measurement sensor #####################
//#######################################################################################################
//
// This plugin is interfacing with HLW8012 IC which is use with some commercial devices:
// -- Sonoff POW
// -- ElectroDragon HLW8012 Breakout board
//
// The Sonoff POW uses the following PINs: SEL=GPIO05(D1), CF1=GPIO13(D8), CF=GPIO14(D5)
// The ED Module has pinheaders so any available PIN on the ESP8266 can be used.
//
// HLW8012 IC works with 5VDC (it seems at 3.3V is not stable in reading)
//
#ifdef PLUGIN_BUILD_TESTING
#include <HLW8012.h>
HLW8012 *Plugin_170_hlw;
#define PLUGIN_170
#define PLUGIN_ID_170 170
#define PLUGIN_170_DEBUG true //activate extra log info in the debug
#define PLUGIN_NAME_170 "Voltage & Current (AC) - HLW8012 [TESTING]"
#define PLUGIN_VALUENAME1_170 "Voltage (V)"
#define PLUGIN_VALUENAME2_170 "Current (A)"
#define PLUGIN_VALUENAME3_170 "Active Power (W)"
#define PLUGIN_VALUENAME4_170 "Power Factor (%)"
//----------------- HLW8012 Default parameters --------------------------------------------------
// Set SEL_PIN to HIGH to sample current
// This is the case for Itead's Sonoff POW, where the SEL_PIN drives a transistor that pulls down
// the SEL pin in the HLW8012 when closed
#define HLW_CURRENT_MODE HIGH
// These are the nominal values for the resistors in the circuit
#define HLW_CURRENT_RESISTOR 0.001
#define HLW_VOLTAGE_RESISTOR_UP ( 5 * 470000 ) // Real: 2280k
#define HLW_VOLTAGE_RESISTOR_DOWN ( 1000 ) // Real 1.009k
//-----------------------------------------------------------------------------------------------
byte StoredTaskIndex;
boolean Plugin_170(byte function, struct EventStruct *event, String& string)
{
boolean success = false;
switch (function)
{
case PLUGIN_DEVICE_ADD:
{
Device[++deviceCount].Number = PLUGIN_ID_170;
Device[deviceCount].Type = DEVICE_TYPE_TRIPLE;
Device[deviceCount].VType = SENSOR_TYPE_QUAD;
Device[deviceCount].Ports = 0;
Device[deviceCount].PullUpOption = false;
Device[deviceCount].InverseLogicOption = false;
Device[deviceCount].FormulaOption = true;
Device[deviceCount].ValueCount = 4;
Device[deviceCount].SendDataOption = true;
Device[deviceCount].TimerOption = true;
Device[deviceCount].GlobalSyncOption = false;
break;
}
case PLUGIN_GET_DEVICENAME:
{
string = F(PLUGIN_NAME_170);
break;
}
case PLUGIN_GET_DEVICEVALUENAMES:
{
strcpy_P(ExtraTaskSettings.TaskDeviceValueNames[0], PSTR(PLUGIN_VALUENAME1_170));
strcpy_P(ExtraTaskSettings.TaskDeviceValueNames[1], PSTR(PLUGIN_VALUENAME2_170));
strcpy_P(ExtraTaskSettings.TaskDeviceValueNames[2], PSTR(PLUGIN_VALUENAME3_170));
strcpy_P(ExtraTaskSettings.TaskDeviceValueNames[3], PSTR(PLUGIN_VALUENAME4_170));
break;
}
case PLUGIN_WEBFORM_LOAD:
{
addFormNote(string, F("Sonoff POW: 1st(SEL)=GPIO-5, 2nd(CF1)=GPIO-13, 3rd(CF)=GPIO-14"));
addFormSubHeader(string, F("Calibration Values"));
double hlwMultipliers[3];
LoadCustomTaskSettings(event->TaskIndex, (byte*)&hlwMultipliers, sizeof(hlwMultipliers));
addFormTextBox(string, F("Current Multiplier"), F("plugin_170_currmult"), String(hlwMultipliers[0], 2), 25);
addFormTextBox(string, F("Voltage Multiplier"), F("plugin_170_voltmult"), String(hlwMultipliers[1], 2), 25);
addFormTextBox(string, F("Power Multiplier"), F("plugin_170_powmult"), String(hlwMultipliers[2], 2), 25);
success = true;
break;
}
case PLUGIN_WEBFORM_SAVE:
{
double hlwMultipliers[3];
String tmpString, arg1;
arg1 = F("plugin_170_currmult"); tmpString = WebServer.arg(arg1);
hlwMultipliers[0] = atof(tmpString.c_str());
arg1 = F("plugin_170_voltmult"); tmpString = WebServer.arg(arg1);
hlwMultipliers[1] = atof(tmpString.c_str());
arg1 = F("plugin_170_powmult"); tmpString = WebServer.arg(arg1);
hlwMultipliers[2] = atof(tmpString.c_str());
SaveCustomTaskSettings(event->TaskIndex, (byte*)&hlwMultipliers, sizeof(hlwMultipliers));
if (PLUGIN_170_DEBUG) {
String log = F("HLW8012: Saved Calibration from Config Page");
addLog(LOG_LEVEL_INFO, log);
}
if (Plugin_170_hlw) {
Plugin_170_hlw->setCurrentMultiplier(hlwMultipliers[0]);
Plugin_170_hlw->setVoltageMultiplier(hlwMultipliers[1]);
Plugin_170_hlw->setPowerMultiplier(hlwMultipliers[2]);
}
if (PLUGIN_170_DEBUG) {
String log = F("HLW8012: Multipliers Reassigned");
addLog(LOG_LEVEL_INFO, log);
}
success = true;
break;
}
case PLUGIN_READ:
{
Plugin_170_hlw->setMode(MODE_CURRENT); delay(200); double hcurrent = Plugin_170_hlw->getCurrent();
Plugin_170_hlw->setMode(MODE_VOLTAGE); delay(200); unsigned int hvoltage = Plugin_170_hlw->getVoltage();
unsigned int hpower = Plugin_170_hlw->getActivePower();
//unsigned int happpower = Plugin_170_hlw->getApparentPower();
unsigned int hpowfact = (int) (100 * Plugin_170_hlw->getPowerFactor());
if (PLUGIN_170_DEBUG) {
String log = F("HLW8012: Read values");
log += F(" - V="); log += hvoltage;
log += F(" - A="); log += hcurrent;
log += F(" - W="); log += hpower;
log += F(" - Pf%="); log += hpowfact;
addLog(LOG_LEVEL_INFO, log);
}
UserVar[event->BaseVarIndex] = hvoltage;
UserVar[event->BaseVarIndex + 1] = hcurrent;
UserVar[event->BaseVarIndex + 2] = hpower;
UserVar[event->BaseVarIndex + 3] = hpowfact;
//Plugin_170_hlw->toggleMode();
success = true;
break;
}
case PLUGIN_INIT:
{
if (!Plugin_170_hlw)
{
Plugin_170_hlw = new HLW8012;
// This initializes the HWL8012 library.
Plugin_170_hlw->begin(Settings.TaskDevicePin3[event->TaskIndex], Settings.TaskDevicePin2[event->TaskIndex], Settings.TaskDevicePin1[event->TaskIndex], HLW_CURRENT_MODE, false, 1000000);
if (PLUGIN_170_DEBUG) addLog(LOG_LEVEL_INFO, F("HLW8012: Init object done"));
Plugin_170_hlw->setResistors(HLW_CURRENT_RESISTOR, HLW_VOLTAGE_RESISTOR_UP, HLW_VOLTAGE_RESISTOR_DOWN);
if (PLUGIN_170_DEBUG) addLog(LOG_LEVEL_INFO, F("HLW8012: Init Basic Resistor Values done"));
// If multipliers are empty load default ones and save all of them as "CustomTaskSettings"
double hlwMultipliers[3];
LoadCustomTaskSettings(event->TaskIndex, (byte*)&hlwMultipliers, sizeof(hlwMultipliers));
if (hlwMultipliers[0] == 0) { hlwMultipliers[0] = Plugin_170_hlw->getCurrentMultiplier(); }
if (hlwMultipliers[1] == 0) { hlwMultipliers[1] = Plugin_170_hlw->getVoltageMultiplier(); }
if (hlwMultipliers[2] == 0) { hlwMultipliers[2] = Plugin_170_hlw->getPowerMultiplier(); }
SaveCustomTaskSettings(event->TaskIndex, (byte*)&hlwMultipliers, sizeof(hlwMultipliers));
if (PLUGIN_170_DEBUG) addLog(LOG_LEVEL_INFO, F("HLW8012: Saved Calibration after INIT"));
Plugin_170_hlw->setCurrentMultiplier(hlwMultipliers[0]);
Plugin_170_hlw->setVoltageMultiplier(hlwMultipliers[1]);
Plugin_170_hlw->setPowerMultiplier(hlwMultipliers[2]);
if (PLUGIN_170_DEBUG) addLog(LOG_LEVEL_INFO, F("HLW8012: Applied Calibration after INIT"));
StoredTaskIndex = event->TaskIndex; // store task index value in order to use it in the PLUGIN_WRITE routine
}
success = true;
break;
}
case PLUGIN_WRITE:
{
if (Plugin_170_hlw)
{
String tmpString = string;
int argIndex = tmpString.indexOf(',');
if (argIndex)
tmpString = tmpString.substring(0, argIndex);
if (tmpString.equalsIgnoreCase(F("hlwreset")))
{
Plugin_170_hlw->resetMultipliers();
Plugin170_SaveMultipliers();
if (PLUGIN_170_DEBUG) addLog(LOG_LEVEL_INFO, F("HLW8012: Reset Multipliers to DEFAULT"));
success = true;
}
if (tmpString.equalsIgnoreCase(F("hlwcalibrate")))
{
String tmpStr = string;
unsigned int CalibVolt = 0;
double CalibCurr = 0;
unsigned int CalibAcPwr = 0;
int comma1 = tmpStr.indexOf(',');
int comma2 = tmpStr.indexOf(',', comma1+1);
int comma3 = tmpStr.indexOf(',', comma2+1);
if (comma1 != 0) {
if (comma2 == 0) {
CalibVolt = tmpStr.substring(comma1+1).toInt();
} else if (comma3 == 0) {
CalibVolt = tmpStr.substring(comma1+1, comma2).toInt();
CalibCurr = atof(tmpStr.substring(comma2+1).c_str());
} else {
CalibVolt = tmpStr.substring(comma1+1, comma2).toInt();
CalibCurr = atof(tmpStr.substring(comma2+1, comma3).c_str());
CalibAcPwr = tmpStr.substring(comma3+1).toInt();
}
}
if (PLUGIN_170_DEBUG) {
String log = F("HLW8012: Calibration to values");
log += F(" - Expected-V="); log += CalibVolt;
log += F(" - Expected-A="); log += CalibCurr;
log += F(" - Expected-W="); log += CalibAcPwr;
addLog(LOG_LEVEL_INFO, log);
}
if (CalibVolt != 0) { Plugin_170_hlw->expectedVoltage(CalibVolt); }
if (CalibCurr != 0) { Plugin_170_hlw->expectedCurrent(CalibCurr); }
if (CalibAcPwr != 0) { Plugin_170_hlw->expectedActivePower(CalibAcPwr); }
// if at least one calibration value has been provided then save the new multipliers //
if ((CalibVolt + CalibCurr + CalibAcPwr) != 0) { Plugin170_SaveMultipliers(); }
success = true;
}
}
break;
}
}
return success;
}
void Plugin170_SaveMultipliers() {
double hlwMultipliers[3];
hlwMultipliers[0] = Plugin_170_hlw->getCurrentMultiplier();
hlwMultipliers[1] = Plugin_170_hlw->getVoltageMultiplier();
hlwMultipliers[2] = Plugin_170_hlw->getPowerMultiplier();
SaveCustomTaskSettings(StoredTaskIndex, (byte*)&hlwMultipliers, sizeof(hlwMultipliers));
}
#endif