def _check_battery_state(_battery_acpi_path):
"""
@return BatteryState
"""
rv = BatteryState()
if _battery_acpi_path.startswith('/proc'):
if os.access(_battery_acpi_path, os.F_OK):
o = slerp(_battery_acpi_path + '/state')
else:
raise Exception(_battery_acpi_path + ' does not exist')
batt_info = yaml.load(o)
state = batt_info.get('charging state', 'discharging')
rv.power_supply_status = state_to_val.get(state, 0)
rv.current = _strip_A(batt_info.get('present rate', '-1 mA'))
if rv.power_supply_status == BatteryState.POWER_SUPPLY_STATUS_DISCHARGING:
rv.current = math.copysign(
rv.current, -1) # Need to set discharging rate to negative
rv.charge = _strip_Ah(batt_info.get('remaining capacity',
'-1 mAh')) # /energy_now
rv.voltage = _strip_V(batt_info.get('present voltage',
'-1 mV')) # /voltage_now
rv.present = batt_info.get('present', False) # /present
rv.header.stamp = rospy.get_rostime()
else:
# Charging state; make lowercase and remove trailing eol
state = _read_string(_battery_acpi_path + '/status',
'discharging').lower().rstrip()
rv.power_supply_status = state_to_val.get(state, 0)
if os.path.exists(_battery_acpi_path + '/power_now'):
rv.current = _read_number(_battery_acpi_path + '/power_now')/10e5 / \
_read_number(_battery_acpi_path + '/voltage_now')
else:
rv.current = _read_number(_battery_acpi_path +
'/current_now') / 10e5
if rv.power_supply_status == BatteryState.POWER_SUPPLY_STATUS_DISCHARGING:
rv.current = math.copysign(
rv.current, -1) # Need to set discharging rate to negative
if os.path.exists(_battery_acpi_path + '/energy_now'):
rv.charge = _read_number(_battery_acpi_path + '/energy_now') / 10e5
else:
rv.charge = _read_number(_battery_acpi_path + '/charge_now') / 10e5
rv.voltage = _read_number(_battery_acpi_path + '/voltage_now') / 10e5
rv.present = _read_number(_battery_acpi_path + '/present') == 1
rv.header.stamp = rospy.get_rostime()
return rv
def get_battery_state(self, battery):
"""Get the current state of a battery."""
battery_config = BATTERIES[battery]
battery_state = BatteryState()
battery_voltage = PiPuckBatteryServer.get_battery_voltage(battery_config["path"])
self._battery_history[battery].insert(0, battery_voltage)
self._battery_history[battery] = self._battery_history[battery][:HISTORY_MAX]
split_point = len(self._battery_history[battery]) // 2
head_half = self._battery_history[battery][:split_point]
tail_half = self._battery_history[battery][split_point:]
try:
battery_delta = (sum(head_half) / len(head_half)) - (sum(tail_half) / len(tail_half))
except ZeroDivisionError:
battery_delta = 0.0
battery_state.voltage = battery_voltage
battery_state.present = True
battery_state.design_capacity = battery_config["design_capacity"]
battery_state.power_supply_technology = battery_config["power_supply_technology"]
average_battery_voltage = sum(self._battery_history[battery]) / len(
self._battery_history[battery])
if average_battery_voltage >= battery_config["max_voltage"] * CHARGED_VOLTAGE_MARGIN:
battery_state.power_supply_status = BatteryState.POWER_SUPPLY_STATUS_FULL
elif battery_delta < 0:
battery_state.power_supply_status = BatteryState.POWER_SUPPLY_STATUS_DISCHARGING
elif battery_delta > 0:
battery_state.power_supply_status = BatteryState.POWER_SUPPLY_STATUS_CHARGING
else:
battery_state.power_supply_status = BatteryState.POWER_SUPPLY_STATUS_NOT_CHARGING
if average_battery_voltage >= battery_config["max_voltage"] * OVER_VOLTAGE_MARGIN:
battery_state.power_supply_health = BatteryState.POWER_SUPPLY_HEALTH_OVERVOLTAGE
elif average_battery_voltage <= battery_config["min_voltage"]:
# It is unclear whether this means "out of charge" or "will never charge again", we
# assume here that it means "out of charge".
battery_state.power_supply_health = BatteryState.POWER_SUPPLY_HEALTH_DEAD
else:
battery_state.power_supply_health = BatteryState.POWER_SUPPLY_HEALTH_GOOD
battery_state.percentage = clamp(
(average_battery_voltage - battery_config["min_voltage"]) /
(battery_config["max_voltage"] - battery_config["min_voltage"]), 1.0, 0.0)
battery_state.current = NAN
battery_state.charge = NAN
battery_state.capacity = NAN
battery_state.location = battery_config["location"]
return battery_state
def update_state(self):
voltage_dec_, current_dec_, charge_dec_, percentage_dec_, temperature_dec_, power_supply_status_dec_, cell_voltage_dec_ = self.read_bms(
)
battery_msg = BatteryState()
# Power supply status constants
# uint8 POWER_SUPPLY_STATUS_UNKNOWN = 0
# uint8 POWER_SUPPLY_STATUS_CHARGING = 1
# uint8 POWER_SUPPLY_STATUS_DISCHARGING = 2
# uint8 POWER_SUPPLY_STATUS_NOT_CHARGING = 3
# uint8 POWER_SUPPLY_STATUS_FULL = 4
# Power supply health constants
# uint8 POWER_SUPPLY_HEALTH_UNKNOWN = 0
# uint8 POWER_SUPPLY_HEALTH_GOOD = 1
# uint8 POWER_SUPPLY_HEALTH_OVERHEAT = 2
# uint8 POWER_SUPPLY_HEALTH_DEAD = 3
# uint8 POWER_SUPPLY_HEALTH_OVERVOLTAGE = 4
# uint8 POWER_SUPPLY_HEALTH_UNSPEC_FAILURE = 5
# uint8 POWER_SUPPLY_HEALTH_COLD = 6
# uint8 POWER_SUPPLY_HEALTH_WATCHDOG_TIMER_EXPIRE = 7
# uint8 POWER_SUPPLY_HEALTH_SAFETY_TIMER_EXPIRE = 8
# Power supply technology (chemistry) constants
# uint8 POWER_SUPPLY_TECHNOLOGY_UNKNOWN = 0
# uint8 POWER_SUPPLY_TECHNOLOGY_NIMH = 1
# uint8 POWER_SUPPLY_TECHNOLOGY_LION = 2
# uint8 POWER_SUPPLY_TECHNOLOGY_LIPO = 3
# uint8 POWER_SUPPLY_TECHNOLOGY_LIFE = 4
# uint8 POWER_SUPPLY_TECHNOLOGY_NICD = 5
# uint8 POWER_SUPPLY_TECHNOLOGY_LIMN = 6
# Populate battery parameters.
battery_msg.voltage = voltage_dec_ # Voltage in Volts (Mandatory)
battery_msg.current = current_dec_ # Negative when discharging (A) (If unmeasured NaN)
battery_msg.charge = charge_dec_ # Current charge in Ah (If unmeasured NaN)
battery_msg.capacity = 150 # Capacity in Ah (last full capacity) (If unmeasured NaN)
battery_msg.design_capacity = 150 # Capacity in Ah (design capacity) (If unmeasured NaN)
battery_msg.percentage = percentage_dec_ # Charge percentage on 0 to 1 range (If unmeasured NaN)
battery_msg.power_supply_status = int(
power_supply_status_dec_
) # The charging status as reported. Values defined above
battery_msg.power_supply_health = 0 # The battery health metric. Values defined above
battery_msg.power_supply_technology = battery_msg.POWER_SUPPLY_TECHNOLOGY_LIFE # The battery chemistry. Values defined above
battery_msg.present = True # True if the battery is present
battery_msg.cell_voltage = cell_voltage_dec_
self.pub_batt_state.publish(battery_msg)
def battery_republisher():
global MotorDriverPort
#print "Battery republisher launched"
bat_status = BatteryState()
BAT_FULL = 6*4.2
BAT_MIN = 6*3.3
bat_status.header.frame_id = 'robot'
bat_status.current = float('nan')
bat_status.charge = float('nan')
bat_status.capacity = float('nan')
bat_status.design_capacity = float('nan')
bat_status.power_supply_technology = BatteryState().POWER_SUPPLY_TECHNOLOGY_LIPO
for cell in range(0, 6):
bat_status.cell_voltage.append(float('nan'))
bat_status.location = 'Main Battery'
bat_status.serial_number = "NA"
while 1:
MotorDriverPort.write('GetBatTotal\n')
sleep(0.05)
recv_data = MotorDriverPort.readline()
print recv_data
# print recv_data
bat_status.header.stamp = rospy.Time.now()
try:
bat_status.voltage = float(recv_data)
bat_status.percentage = bat_status.voltage/BAT_FULL
bat_status.present = bat_status.voltage<BAT_FULL and bat_status.voltage>BAT_MIN
battery_pub.publish(bat_status)
except:
if DEBUG:
print "Receive Error"
else:
pass
sleep(0.01)
def on_new_telemetry(self, message):
for servo in message.servos:
self.voltages[servo.id] = servo.voltage
if len(self.voltages) == SERVO_COUNT:
voltages = self.voltages.values()
self.voltages.clear()
voltage = max(voltages)
battery_state = BatteryState()
battery_state.header.stamp = rospy.Time.now()
battery_state.voltage = voltage
battery_state.current = float("nan")
battery_state.charge = float("nan")
battery_state.capacity = float("nan")
battery_state.design_capacity = float("nan")
battery_state.percentage = 100 - (MAX_VOLTAGE - voltage) / (
MAX_VOLTAGE - MIN_VOLTAGE) * 100
battery_state.power_supply_status = BatteryState.POWER_SUPPLY_STATUS_DISCHARGING
battery_state.power_supply_health = BatteryState.POWER_SUPPLY_HEALTH_UNKNOWN
battery_state.power_supply_technology = BatteryState.POWER_SUPPLY_TECHNOLOGY_LIPO
battery_state.present = True
battery_state.cell_voltage = [float("nan")] * 3
battery_state.location = "Primary batter bay"
battery_state.serial_number = "N/A"
self.battery_publisher.publish(battery_state)
# skip the first check so that you don't get a warning if battery is already bellow some value
if self.first_check:
self.first_check = False
self.lowest_recorded_voltage = voltage
return
if voltage < 10.2:
if self.last_critical_voltage_warning + self.critical_voltage_warning_period < rospy.Time.now(
):
self.speech_publisher.publish("battery_critical")
self.face_color_publisher.publish("flash:red")
self.last_critical_voltage_warning = rospy.Time.now()
elif voltage < 11 and self.lowest_recorded_voltage >= 11:
self.speech_publisher.publish("battery_below_11")
elif voltage < 12 and self.lowest_recorded_voltage >= 12:
self.speech_publisher.publish("battery_below_12")
if voltage < self.lowest_recorded_voltage:
self.lowest_recorded_voltage = voltage
def publish_state(self):
state = BatteryState()
state.header.frame_id = "usv"
state.header.stamp = rospy.Time.now()
state.voltage = self.voltage
state.current = self.power_battery
state.charge = self.charging_current
#state.capacity = self.design_capacity * (self.percentage / 100.0)
state.design_capacity = self.design_capacity
state.percentage = (self.percentage/100.0)
state.power_supply_status = self.state_charging
state.power_supply_health = BatteryState.POWER_SUPPLY_HEALTH_UNKNOWN
state.power_supply_technology = BatteryState.POWER_SUPPLY_TECHNOLOGY_LIPO
state.present = True
state.cell_voltage = [self.voltage]
state.location = "Slot 1"
state.serial_number = "SUSV LIPO 3000mAH"
self.pub.publish(state)
def batRead():
bat_dir = "/sys/devices/platform/7000c400.i2c/i2c-1/1-0042/iio_device/"
volt0_in = open(bat_dir + "in_voltage0_input")
curr0_in = open(bat_dir + "in_current0_input")
rospy.init_node('BatRead')
pub = rospy.Publisher('jetson_battery', BatteryState, queue_size=20)
rate = rospy.Rate(5) # 5hz
while not rospy.is_shutdown():
try:
# Read voltage in mV, store in V
voltage = float(volt0_in.read().strip()) / 1000
volt0_in.seek(0)
# Read voltage in mA, store in A
current = float(curr0_in.read().strip()) / 1000
curr0_in.seek(0)
except (IOError, ValueError) as e:
rospy.logerr("I/O error: {0}".format(e))
else:
bat_msg = BatteryState()
bat_msg.header.stamp = rospy.Time.now()
bat_msg.voltage = voltage
bat_msg.current = -current
bat_msg.charge = float('NaN')
bat_msg.capacity = float('NaN')
bat_msg.design_capacity = float('NaN')
bat_msg.percentage = float('NaN')
bat_msg.power_supply_status = bat_msg.POWER_SUPPLY_STATUS_UNKNOWN
bat_msg.power_supply_health = bat_msg.POWER_SUPPLY_HEALTH_UNKNOWN
bat_msg.power_supply_technology = bat_msg.POWER_SUPPLY_TECHNOLOGY_UNKNOWN
bat_msg.present = True
rospy.logdebug('New battery message: %s' % bat_msg)
pub.publish(bat_msg)
rate.sleep()
def test__on_receive_battery_state_over_threshold(self, mocked_rospy,
mocked_mqtt):
mocked_rospy.get_param.return_value = utils.get_attrs_params()
mocked_mqtt_client = mocked_mqtt.Client.return_value
with freezegun.freeze_time('2018-01-02T03:04:05.123456+09:00'):
bridge = AttrsBridge().connect()
battery = BatteryState()
battery.voltage = 0.1
battery.current = 0.2
battery.charge = 0.3
battery.capacity = 0.4
battery.design_capacity = 0.5
battery.percentage = 0.6
with freezegun.freeze_time('2018-01-02T03:04:06.123457+09:00'):
bridge._on_receive_battery_state(battery)
payload = '2018-01-02T03:04:06.123457+0900|voltage|0.1|current|0.2|charge|0.3|capacity|0.4|' \
'design_capacity|0.5|percentage|0.6'
mocked_mqtt_client.publish.assert_called_once_with(
'/robot/turtlebot3/attrs', payload)
def _hw_robot_state_cb(self, msg):
self._get_wallbanger_state_pub.publish(msg.in_autonomous_mode)
batteryMsg = BatteryState()
if msg.robot_power_state == RobotState.ESTOP_ACTIVE:
batteryMsg.voltage = float('nan')
batteryMsg.percentage = float('nan')
else:
batteryMsg.voltage = msg.voltage # volts
batteryMsg.percentage = max(0, min(msg.voltage / 12.0,
1)) # volts / volts-nominal
batteryMsg.current = float('nan')
batteryMsg.charge = float('nan')
batteryMsg.capacity = float('nan')
batteryMsg.design_capacity = 14.0 #AH (2x batteries)
batteryMsg.power_supply_status = BatteryState.POWER_SUPPLY_STATUS_UNKNOWN
batteryMsg.power_supply_health = BatteryState.POWER_SUPPLY_HEALTH_UNKNOWN
batteryMsg.power_supply_technology = BatteryState.POWER_SUPPLY_TECHNOLOGY_UNKNOWN
batteryMsg.present = True
self._battery_pub.publish(batteryMsg)
self._watchdog_tripped_pub.publish(msg.watchdog_tripped)
strMsg = String()
if msg.robot_power_state == RobotState.POWER_GOOD:
strMsg.data = "power-good"
elif msg.robot_power_state == RobotState.POWER_LOW:
strMsg.data = "power-low"
elif msg.robot_power_state == RobotState.POWER_EMERGENCY:
strMsg.data = "power-emergency"
elif msg.robot_power_state == RobotState.ESTOP_ACTIVE:
strMsg.data = "estop-active"
self._robot_state_pub.publish(strMsg)
def _status_to_battery_(status):
"""
Converts a ds4_driver/Status to sensor_msgs/BatteryState
Reference: https://www.psdevwiki.com/ps4/DualShock_4#Specifications
:param status:
:type status: Status
:return:
"""
msg = BatteryState()
msg.header = status.header
msg.percentage = status.battery_percentage
msg.voltage = Controller.MAX_VOLTAGE * msg.percentage
msg.current = float('NaN')
msg.charge = float('NaN')
msg.capacity = float('NaN')
msg.design_capacity = 1.0
if not status.plug_usb:
msg.power_supply_status = BatteryState.POWER_SUPPLY_STATUS_NOT_CHARGING
elif not status.battery_full_charging:
msg.power_supply_status = BatteryState.POWER_SUPPLY_STATUS_CHARGING
elif status.battery_full_charging:
msg.power_supply_status = BatteryState.POWER_SUPPLY_STATUS_FULL
msg.power_supply_technology = BatteryState.POWER_SUPPLY_TECHNOLOGY_LION
return msg
bsmsg = BatteryState()
bsmsg.header.stamp = rospy.Time.now()
bsmsg.header.frame_id = 'base_link'
bsmsg.header.seq = count
count += 1
# voltage, current, charge capacity, design_capacity, percentage
for li in lines:
if "battery.capacity" in li:
bsmsg.capacity = float(li.split(' ')[-1])
elif "battery.charge" in li and not 'warning' in li and not 'low' in li:
bsmsg.charge = float(li.split(' ')[-1])
elif "battery.current" in li:
bsmsg.current = float(li.split(' ')[-1])
elif "battery.voltage" in li:
bsmsg.voltage = float(li.split(' ')[-1])
elif "device.serial" in li:
serial_number = str(li.split(' ')[-1])
elif "device.input_current" in li:
device_input_current = float(li.split(' ')[-1])
elif "device.output_current" in li:
device_output_current = float(li.split(' ')[-1])
elif "device.input_voltage" in li:
device_input_voltage = float(li.split(' ')[-1])
elif "device.output_voltage" in li:
device_output_voltage = float(li.split(' ')[-1])
def bs_err_inj(tb3_name):
#Create error-injected topic
rospy.init_node('batterystate_err_inj')
#########################################
#Create new message
batterystate_msg = BatteryState()
#Fill message with values
batterystate_msg.header.seq = 0
batterystate_msg.header.stamp.secs = 0
batterystate_msg.header.stamp.nsecs = 0
batterystate_msg.header.frame_id = ""
batterystate_msg.voltage = 0.0
batterystate_msg.current = 0.0
batterystate_msg.charge = 0.0
batterystate_msg.capacity = 0.0
batterystate_msg.design_capacity = 0.0
batterystate_msg.percentage = 0.0
batterystate_msg.power_supply_status = 0
batterystate_msg.power_supply_health = 0
batterystate_msg.power_supply_technology = 0
batterystate_msg.bool = 1
batterystate_msg.cell_voltage = []
batterystate_msg.location = ""
batterystate_msg.serial_number = ""
#########################################
rate = rospy.Rate(50)
#Publish message into new topic
while not rospy.is_shutdown():
my_pub = rospy.Publisher(tb3_name + 'batterystate_err_inj',
BatteryState,
queue_size=10)
my_sub = rospy.Subscriber(tb3_name + 'battery_state', BatteryState,
listener)
#########################################
#INJECT ERRORS HERE
batterystate_msg.header.seq = actual_seq
batterystate_msg.header.stamp.secs = actual_secs
batterystate_msg.header.stamp.nsecs = actual_nsecs
batterystate_msg.header.frame_id = actual_frameid
batterystate_msg.voltage = actual_voltage
batterystate_msg.current = actual_current
batterystate_msg.charge = actual_charge
batterystate_msg.capacity = actual_capacity
batterystate_msg.design_capacity = actual_designcapacity
batterystate_msg.percentage = actual_percentage
batterystate_msg.power_supply_status = actual_powersupplystatus
batterystate_msg.power_supply_health = actual_powersupplyhealth
batterystate_msg.power_supply_technology = actual_powersupplytechnology
batterystate_msg.present = actual_present
batterystate_msg.cell_voltage = actual_cellvoltage
batterystate_msg.location = actual_location
batterystate_msg.serial_number = actual_serialnumber
#########################################
my_pub.publish(batterystate_msg)
rate.sleep()
rospy.spin()
#!/usr/bin/env python
from __future__ import print_function
import roslib
import rospy
import std_msgs
import numpy
from sensor_msgs.msg import BatteryState
if __name__ == "__main__":
rospy.init_node('battery_node')
pub = rospy.Publisher("battery", BatteryState, queue_size=1)
tinit = rospy.Time.now().to_time()
speed = 0.05
try:
while not rospy.is_shutdown():
msg = BatteryState()
t = rospy.Time.now().to_time()
msg.charge = 10 * numpy.exp(speed * (tinit - t)) - 1.0
rospy.sleep(0.5)
pub.publish(msg)
except Exception as e:
print(e)
# 13.44 Volt battery voltage resulted in 2,94 Volt on the ADC channel with my circuit (voltage divider w/ two resistors (39k + 11k)).
# This resulted in a ADC 'value' of 1465.
# The conversion factor for the battery voltage is then: 1465 / 13.44 = 109.00297619047619
#
voltage = (value / 109.00297619047619)
else:
# simulated value!
voltage = demoVoltage
# print out pure ADC voltage
# rospy.loginfo("Battery: %.1f Volt" % voltage)
# completing the ROS message
# @SA http://docs.ros.org/jade/api/sensor_msgs/html/msg/BatteryState.html
battery_msg.charge = 0.0
battery_msg.capacity = 0.0
battery_msg.design_capacity = 2.2 # 2.2 Ah
battery_msg.percentage = 0.0 # 0 to 1!
# battery_msg.power_supply_status = POWER_SUPPLY_STATUS_DISCHARGING
# battery_msg.power_supply_health = POWER_SUPPLY_HEALTH_GOOD
# battery_msg.power_supply_technology = POWER_SUPPLY_TECHNOLOGY_LIPO
battery_msg.power_supply_status = 2
battery_msg.power_supply_health = 1
battery_msg.power_supply_technology = 3
battery_msg.present = True
battery_msg.cell_voltage = [float(0)]
battery_msg.location = "1" # The location into which the battery is inserted. (slot number or plug)
battery_msg.serial_number = "1"
# this is the battery voltage
