VictronGX_Custom_Sensors/dbus_batrium_native2/batrium.py

#!/usr/bin/env python3

import sys
import os
import logging
import itertools

from time import time
from datetime import datetime
import can
import struct
from argparse import ArgumentParser

VERSION = '1.0'

class BatriumBattery(can.Listener):
    def __init__(self, connection):
        self.hw_version = 0
        self.sw_version = 0
        self.capacity = 2.2
        self.maxChargeVoltage = 0
        self.numberOfModules = 3
        self.soc = 0
        self.soh = 0
        self.voltage = 0
        self.current = 0
        self.temperature = 0
        self.maxCellTemperature = 0
        self.maxCellTemperatureId = 0
        self.minCellTemperature = 0
        self.minCellTemperatureId = 0
        #self.cellVoltages_min = dict()
        #self.cellVoltages_max = dict()
        #self.cellTemperatures = dict()
        #self.cellBypassTemperatures = dict()
        #self.cellBypassPWM = dict()
        self.maxCellVoltage = 0
        self.maxCellVoltageId = 0
        self.minCellVoltage = 0
        self.minCellVoltageId = 0
        self.maxChargeCurrent = 0
        self.maxDischargeCurrent = 0
        self.updated = -1
        #self.TimeToEmpty = 0
        #self.TimeToFull = 0
        self.AhToEmpty = 0
        #self.AhToFull = 0
        self.NumberInBypass = 0
        #self.alarm_high_temperature = 0
        #self.alarm_high_voltage = 0
        #self.alarm_low_temperature = 0
        #self.alarm_low_voltage = 0
        #self.alarm_low_soc = 0
        #self.alarm_high_charge_current = 0
        #self.alarm_high_discharge_current = 0

        self._ci = can.interface.Bus(channel=connection, bustype='socketcan')

        # check connection and that reported system voltage roughly matches configuration
        found = False
        msg = None

        while True:
            try:
                msg = self._ci.recv(timeout=10)
            except can.CanError:
                logging.error("Canbus error")

            if msg == None:
            #timeout no system connected
                logging.error("No messages on canbus %s received. Check connection and speed." % connection)
                break;

            elif msg.arbitration_id == 0x01:
                logging.info("Found Batrium BMS on %s" % connection)
                found = True
                break;

    def on_message_received(self, msg):
        self.updated = msg.timestamp

        if msg.arbitration_id == 0x00:
            self.hw_version = (((msg.data[1] * 256 + (1 << 8)) + msg.data[0] + (1 << 8)) )
            self.sw_version = (((msg.data[3] * 256 + (1 << 8)) + msg.data[2] + (1 << 8)) )
            self.serial = ((msg.data[7] * 256) + (msg.data[6] * 256) + (msg.data[5] * 256) + msg.data[4]) + (1 << 32)
            logging.debug("HW Version: %d, SW Version: %d, Serialnumber: %d", self.hw_version, self.sw_version, self.serial)

        elif msg.arbitration_id == 0x01:
            self.minCellVoltage =  ((msg.data[1] * 256) + msg.data[0]) * 0.001
            self.maxCellVoltage =  ((msg.data[3] * 256) + msg.data[2]) * 0.001
            #self.avgCellVoltage = ((msg.data[5] * 256) + msg.data[4]) * 0.01
            self.minCellVoltageId = msg.data[6]
            self.maxCellVoltageId = msg.data[7]
            logging.debug("MinCellVolt %1.3fV (ID: %d), MaxCellVolt %1.3fV (ID: %d)", self.minCellVoltage, self.minCellVoltageId, self.maxCellVoltage, self.maxCellVoltageId)

        elif msg.arbitration_id == 0x02:
            self.minCellTemperature =  msg.data[0] - 40
            self.maxCellTemperature =  msg.data[1] - 40
            self.temperature = msg.data[2] - 40
            self.minCellTemperatureId = msg.data[3]
            self.maxCellTemperatureId = msg.data[4]
            logging.debug("MinCellTemp: %d (ID: %d), MaxCellTemp: %d (ID: %d), AverageTemp: %d", self.minCellTemperature, self.minCellTemperatureId, self.maxCellTemperature, self.maxCellTemperatureId, self.temperature)

        elif msg.arbitration_id == 0x03:
            self.NumberInBypass = msg.data[0]
            logging.debug("Cell number in bypass: %d", self.NumberInBypass)

        if msg.arbitration_id == 0x04:
            logging.debug(msg)
            self.voltage = ((msg.data[1] * 256) + msg.data[0]) * 0.1
            self.current = int(((msg.data[3] * 256) + msg.data[2]) * 0.001)
            self.power = int(((msg.data[5] * 256) + msg.data[4]) * 0.1)
            logging.debug("Voltage: %2.2fV, Current: %2.2fA, Power: %2.2fW", self.voltage, self.current, self.power)

        if msg.arbitration_id == 0x05:
            self.soc = (msg.data[1] * 256 + msg.data[0]) * 0.01
            self.soh = (msg.data[3] * 256 + msg.data[2]) * 0.01
            self.AhToEmpty = (msg.data[5] * 256 + msg.data[4]) * 0.1
            self.capacity = (msg.data[7] * 256 + msg.data[6]) * 0.1
            logging.debug("SOC: %2.2f%%, SOH: %2.2f%%, Ah Remain: %2.2fAh, Capacity: %2.2fAh", self.soc, self.soh, self.AhToEmpty, self.capacity)

        elif msg.arbitration_id == 0x06:
            self.maxChargeVoltage = ((msg.data[1] * 256) + msg.data[0]) * 0.1
            self.maxChargeCurrent = ((msg.data[3] * 256) + msg.data[2]) * 0.1
            #self.maxDischargeVoltage = ((msg.data[5] * 256) + msg.data[4]) * 0.01
            self.maxDischargeCurrent = ((msg.data[7] * 256) + msg.data[6]) * 0.1
            logging.debug("MaxChargeVoltage (CVL) %2.2fA, MaxChargeCurrent (CCL) %2.2fV, MaxDischargeCurrent %2.2fA", self.maxChargeCurrent, self.maxChargeVoltage, self.maxDischargeCurrent)

        #elif msg.arbitration_id == 0x00111900:
        #    logging.debug("Ah 0x00111900 received")
            
            # message never arrived, batrium fw bug?

            #self.AhToFull = round((struct.unpack('>f', bytearray([msg.data[3], msg.data[2], msg.data[1], msg.data[0]])))[0] * 0.001, 2)
            #self.AhToEmpty = round((struct.unpack('>f', bytearray([msg.data[7], msg.data[6], msg.data[5], msg.data[4]])))[0] * 0.001, 2)
            #self.capacity = self.AhToEmpty + self.AhToFull
            #logging.debug("Ah to Full: %2.2f", self.AhToFull)
            #logging.debug("Ah to Empty: %2.2f", self.AhToEmpty)
            #logging.debug("Capacity: %2.2f", self.capacity)

        #elif msg.arbitration_id == 0x00140100:
        #    self.alarm_high_temperature = (msg.data[2] >> 3) & 1
        #    logging.debug("High Temp Alarm: %d", self.alarm_high_temperature)
        #    self.alarm_high_voltage = (msg.data[2] >> 1) & 1
        #    logging.debug("High Voltage Alarm: %d", self.alarm_high_voltage)
        #    self.alarm_low_temperature = (msg.data[2] >> 2) & 1
        #    logging.debug("Low Temperature Alarm: %d", self.alarm_low_temperature)
        #    self.alarm_low_voltage = (msg.data[2] >> 0) & 1
        #    logging.debug("Low Voltage Alarm: %d", self.alarm_low_voltage)
        #    self.alarm_high_charge_current = (msg.data[3] >> 3) & 1
        #    logging.debug("High Charge Current Alarm: %d", self.alarm_high_charge_current)
        #    self.alarm_high_discharge_current = (msg.data[3] >> 4) & 1
        #    logging.debug("High Discharge Current Alarm: %d", self.alarm_high_discharge_current)

        #elif msg.arbitration_id == 0x00111800:
        #    self.TimeToEmpty = ((msg.data[5] * 256) + msg.data[4] * 60)
        #    logging.debug("Time to empty: %dmin", self.TimeToEmpty)

        #elif msg.arbitration_id == 0x00111700:
        #    self.TimeToFull = ((msg.data[5] * 256) + msg.data[4] * 60)
        #    logging.debug("Time to full: %dmin", self.TimeToFull)

        #elif ((msg.arbitration_id >= 0x001D1101) and (msg.arbitration_id <= 0x001D11F9)):
        #    cell_id  = msg.arbitration_id & 0xff
            #logging.debug("Cell ID: %d, Voltage_min: %2.2f, Voltage_max: %2.2f, Temperature: %d, Bypass_Temperature: %d, BypassPWM: %d", cell_id, ((msg.data[1] * 256) + msg.data[0]) * 0.001, ((msg.data[3] * 256) + msg.data[2]) * 0.001, msg.data[4] - 40, msg.data[5] - 40, msg.data[6])
        #    self.cellVoltages_min[cell_id] = ((msg.data[1] * 256) + msg.data[0]) * 0.001
        #    self.cellVoltages_max[cell_id] = ((msg.data[3] * 256) + msg.data[2]) * 0.001
        #    self.cellTemperatures[cell_id] = msg.data[4] - 40
        #    self.cellBypassTemperatures[cell_id] = msg.data[5] - 40
        #    self.cellBypassPWM[cell_id] = msg.data[6]
        #    self.numberOfModules = len(self.cellVoltages_min.keys())

    def prnt(self):
        print("SOC: %2d, I: %2.2fA, U: %2.2fV, T:%2.1fC" % (self.soc, self.current, self.voltage, self.maxCellTemperature))
        print("MinCellVolt: %1.2f, MaxCellVolt: %1.2f CellVoltDelta: %1.2f" % (self.minCellVoltage, self.maxCellVoltage, self.maxCellVoltage-self.minCellVoltage))
        print("MaxChargeCurrent (CCL): %4.1f A MaxChargeVoltage (CVL): %2.2f V" % (self.maxChargeCurrent, self.maxChargeVoltage))
        print("Number of modules found: %1.0f" % (self.numberOfModules))

# === All code below is to simply run it from the commandline for debugging purposes ===
def main():
    logging.basicConfig(    format='%(asctime)s,%(msecs)d %(name)s %(levelname)s %(message)s',
                            datefmt='%Y-%m-%d %H:%M:%S',
                            level=logging.DEBUG,
                            stream=sys.stdout,
    )
        
    logging.info('Starting dbus_batrium_native listener')
                 
    logger = can.Logger('logfile.asc')

    bat = BatriumBattery(connection='can0')

    listeners = [
                   logger,          # Regular Listener object
            bat
    ]

    notifier = can.Notifier(bat._ci, listeners)
    for msg in bat._ci:
        if msg.arbitration_id == 0x001:
            bat.prnt()

    # Clean-up
    notifier.stop()
    bat._ci.shutdown()

if __name__ == "__main__":
    main()