/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * Copyright 2013 - 2020, nymea GmbH * Contact: contact@nymea.io * * This file is part of nymea. * This project including source code and documentation is protected by * copyright law, and remains the property of nymea GmbH. All rights, including * reproduction, publication, editing and translation, are reserved. The use of * this project is subject to the terms of a license agreement to be concluded * with nymea GmbH in accordance with the terms of use of nymea GmbH, available * under https://nymea.io/license * * GNU Lesser General Public License Usage * Alternatively, this project may be redistributed and/or modified under the * terms of the GNU Lesser General Public License as published by the Free * Software Foundation; version 3. This project is distributed in the hope that * it will be useful, but WITHOUT ANY WARRANTY; without even the implied * warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public License * along with this project. If not, see . * * For any further details and any questions please contact us under * contact@nymea.io or see our FAQ/Licensing Information on * https://nymea.io/license/faq * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */ #include "sunspecmeter.h" #include "extern-plugininfo.h" SunSpecMeter::SunSpecMeter(SunSpec *sunspec, SunSpec::ModelId modelId, int modbusAddress) : QObject(sunspec), m_connection(sunspec), m_id(modelId), m_modelModbusStartRegister(modbusAddress) { qCDebug(dcSunSpec()) << "SunSpecMeter: Setting up meter"; connect(m_connection, &SunSpec::modelDataBlockReceived, this, &SunSpecMeter::onModelDataBlockReceived); } SunSpec::ModelId SunSpecMeter::modelId() { return m_id; } void SunSpecMeter::init() { qCDebug(dcSunSpec()) << "SunSpecMeter: Init"; m_connection->readModelHeader(m_modelModbusStartRegister); connect(m_connection, &SunSpec::modelHeaderReceived, this, [this] (uint modbusAddress, SunSpec::ModelId modelId, uint length) { if (modelId == m_id) { qCDebug(dcSunSpec()) << "SunSpecMeter: Model Header received, modbus address:" << modbusAddress << "model Id:" << modelId << "length:" << length; m_modelLength = length; emit initFinished(true); m_initFinishedSuccess = true; } }); QTimer::singleShot(10000, this,[this] { if (!m_initFinishedSuccess) { emit initFinished(false); } }); } void SunSpecMeter::getMeterModelDataBlock() { qCDebug(dcSunSpec()) << "SunSpecMeter: get meter model data block, modbus register" << m_modelModbusStartRegister << "length" << m_modelLength; m_connection->readModelDataBlock(m_modelModbusStartRegister, m_modelLength); } void SunSpecMeter::getMeterModelHeader() { qCDebug(dcSunSpec()) << "SunSpecMeter: get meter model header, modbus register" << m_modelModbusStartRegister << "length" << m_modelLength; m_connection->readModelHeader(m_modelModbusStartRegister); } void SunSpecMeter::onModelDataBlockReceived(SunSpec::ModelId modelId, uint length, QVector data) { if (modelId != m_id) { return; } if (length < m_modelLength) { qCDebug(dcSunSpec()) << "SunSpecMeter: on model data block received, model length is too short" << length; return; } qCDebug(dcSunSpec()) << "SunSpecMeter: Received" << modelId; switch (modelId) { case SunSpec::ModelIdSinglePhaseMeter: case SunSpec::ModelIdSplitSinglePhaseMeter: case SunSpec::ModelIdDeltaConnectThreePhaseMeter: case SunSpec::ModelIdWyeConnectThreePhaseMeter: { MeterData meterData; quint16 currentScaleFactor = data[Model20XCurrentScaleFactor]; meterData.totalAcCurrent = m_connection->convertToFloatWithSSF(data[Model20XTotalAcCurrent], currentScaleFactor); meterData.phaseACurrent = m_connection->convertToFloatWithSSF(data[Model20XPhaseACurrent], currentScaleFactor); meterData.phaseBCurrent = m_connection->convertToFloatWithSSF(data[Model20XPhaseBCurrent], currentScaleFactor); meterData.phaseCCurrent = m_connection->convertToFloatWithSSF(data[Model20XPhaseCCurrent], currentScaleFactor); quint16 voltageScaleFactor = data[Model20XVoltageScaleFactor]; meterData.voltageLN = m_connection->convertToFloatWithSSF(data[Model20XVoltageLN], voltageScaleFactor); meterData.phaseVoltageAN = m_connection->convertToFloatWithSSF(data[Model20XPhaseVoltageAN], voltageScaleFactor); meterData.phaseVoltageBN = m_connection->convertToFloatWithSSF(data[Model20XPhaseVoltageBN], voltageScaleFactor); meterData.phaseVoltageCN = m_connection->convertToFloatWithSSF(data[Model20XPhaseVoltageCN], voltageScaleFactor); meterData.voltageLL = m_connection->convertToFloatWithSSF(data[Model20XVoltageLL], voltageScaleFactor); meterData.phaseVoltageAB = m_connection->convertToFloatWithSSF(data[Model20XPhaseVoltageAB], voltageScaleFactor); meterData.phaseVoltageBC = m_connection->convertToFloatWithSSF(data[Model20XPhaseVoltageBC], voltageScaleFactor); meterData.phaseVoltageCA = m_connection->convertToFloatWithSSF(data[Model20XPhaseVoltageCA], voltageScaleFactor); meterData.frequency = m_connection->convertToFloatWithSSF(data[Model20XFrequency], data[Model20XFrequencyScaleFactor]); meterData.totalRealPower = m_connection->convertToFloatWithSSF(data[Model20XTotalRealPower], data[Model20XRealPowerScaleFactor]); quint16 energyScaleFactor = data[Model20XRealEnergyScaleFactor]; meterData.totalRealEnergyExported = m_connection->convertToFloatWithSSF(data[Model20XTotalRealEnergyExported], energyScaleFactor); meterData.totalRealEnergyImported = m_connection->convertToFloatWithSSF(data[Model20XTotalRealEnergyImported], energyScaleFactor);; meterData.meterEventFlags = (static_cast(data[Model20XMeterEventFlags]) << 16) | data[Model20XMeterEventFlags+1]; emit meterDataReceived(meterData); } break; case SunSpec::ModelIdSinglePhaseMeterFloat: case SunSpec::ModelIdSplitSinglePhaseMeterFloat: case SunSpec::ModelIdDeltaConnectThreePhaseMeterFloat: case SunSpec::ModelIdWyeConnectThreePhaseMeterFloat: { MeterData meterData; meterData.totalAcCurrent = m_connection->convertFloatValues(data[Model21XTotalAcCurrent], data[Model21XTotalAcCurrent+1]); meterData.phaseACurrent = m_connection->convertFloatValues(data[Model21XPhaseACurrent], data[Model21XPhaseACurrent+1]); meterData.phaseBCurrent = m_connection->convertFloatValues(data[Model21XPhaseBCurrent], data[Model21XPhaseBCurrent+1]); meterData.phaseCCurrent = m_connection->convertFloatValues(data[Model21XPhaseCCurrent], data[Model21XPhaseCCurrent+1]); meterData.voltageLN = m_connection->convertFloatValues(data[Model21XVoltageLN], data[Model21XVoltageLN+1]); meterData.phaseVoltageAN = m_connection->convertFloatValues(data[Model21XPhaseVoltageAN], data[Model21XPhaseVoltageAN+1]); meterData.phaseVoltageBN = m_connection->convertFloatValues(data[Model21XPhaseVoltageBN], data[Model21XPhaseVoltageBN+1]); meterData.phaseVoltageCN = m_connection->convertFloatValues(data[Model21XPhaseVoltageCN], data[Model21XPhaseVoltageCN+1]); meterData.voltageLL = m_connection->convertFloatValues(data[Model21XVoltageLL], data[Model21XVoltageLL+1]); meterData.phaseVoltageAB = m_connection->convertFloatValues(data[Model21XPhaseVoltageAB], data[Model21XPhaseVoltageAB+1]); meterData.phaseVoltageBC = m_connection->convertFloatValues(data[Model21XPhaseVoltageBC], data[Model21XPhaseVoltageBC+1]); meterData.phaseVoltageCA = m_connection->convertFloatValues(data[Model21XPhaseVoltageCA], data[Model21XPhaseVoltageCA+1]); meterData.frequency = m_connection->convertFloatValues(data[Model21XFrequency], data[Model21XFrequency+1]); meterData.totalRealPower = m_connection->convertFloatValues(data[Model21XTotalRealPower], data[Model21XTotalRealPower+1]); meterData.totalRealEnergyExported = m_connection->convertFloatValues(data[Model21XTotalRealEnergyExported], data[Model21XTotalRealEnergyExported+1]); meterData.totalRealEnergyImported = m_connection->convertFloatValues(data[Model21XTotalRealEnergyImported], data[Model21XTotalRealEnergyImported+1]); meterData.meterEventFlags = ((static_cast(data[Model21XMeterEventFlags]) << 16) | data[Model21XMeterEventFlags+1]); emit meterDataReceived(meterData); } break; default: break; } }