# -*- coding: utf-8 -*- """ @file imtq.py @brief Tests for the ISIS IMTQ (Magnettorquer) device handler @author J. Meier @date 25.03.2021 """ import enum import logging import struct from typing import List from eive_tmtc.config.definitions import CustomServiceList from eive_tmtc.pus_tm.defs import PrintWrapper from spacepackets.ecss.tc import PusTelecommand from tmtccmd.config.tmtc import ( tmtc_definitions_provider, OpCodeEntry, TmtcDefinitionWrapper, ) from tmtccmd.tc import DefaultPusQueueHelper from tmtccmd.tc.pus_3_fsfw_hk import ( make_sid, generate_one_diag_command, generate_one_hk_command, create_request_one_diag_command, create_enable_periodic_hk_command, create_disable_periodic_hk_command, create_enable_periodic_hk_command_with_interval, ) from tmtccmd.tc.pus_200_fsfw_mode import pack_mode_data, Mode from tmtccmd.util import ObjectIdU32 from tmtccmd.util.tmtc_printer import FsfwTmTcPrinter _LOGGER = logging.getLogger(__name__) class OpCode: ON = "on" NORMAL = "normal" OFF = "off" SET_DIPOLE = "set_dipole" REQUEST_ENG_HK_NO_TORQUE = "hk_os_eng_hk" REQUEST_MGM_RAW_NO_TORQUE = "hk_os_mgm_raw_no_torque" ENABLE_MGM_RAW_NO_TORQUE = "enb_mgm_raw_no_torque" DISABLE_MGM_RAW_NO_TORQUE = "dis_mgm_raw_no_torque" REQUEST_MGM_RAW_WITH_TORQUE = "hk_os_mgm_raw_with_torque" ENABLE_MGM_RAW_WITH_TORQUE = "enb_mgm_raw_with_torque" DISABLE_MGM_RAW_WITH_TORQUE = "dis_mgm_raw_with_torque" ENABLE_ENG_HK_NO_TORQUE = "enb_eng_hk_no_torque" DISABLE_ENG_HK_NO_TORQUE = "dis_eng_hk_no_torque" POS_X_SELF_TEST = "self_test_pos_x" NEG_X_SELF_TEST = "self_test_neg_x" POS_Y_SELF_TEST = "self_test_pos_y" NEG_Y_SELF_TEST = "self_test_neg_y" POS_Z_SELF_TEST = "self_test_pos_z" NEG_Z_SELF_TEST = "self_test_neg_z" class ImtqSetId(enum.IntEnum): ENG_HK_NO_TORQUE = 1 RAW_MTM_NO_TORQUE = 2 ENG_HK_SET_WITH_TORQUE = 3 RAW_MTM_WITH_TORQUE = 4 STATUS_SET = 5 DIPOLES = 6 CAL_MTM_SET = 9 POSITIVE_X_TEST = 10 NEGATIVE_X_TEST = 11 POSITIVE_Y_TEST = 12 NEGATIVE_Y_TEST = 13 POSITIVE_Z_TEST = 14 NEGATIVE_Z_TEST = 15 class ImtqActionId: start_actuation_dipole = bytearray([0x0, 0x0, 0x0, 0x02]) get_commanded_dipole = bytearray([0x0, 0x0, 0x0, 0x03]) perform_positive_x_test = bytearray([0x0, 0x0, 0x0, 0x07]) perform_negative_x_test = bytearray([0x0, 0x0, 0x0, 0x08]) perform_positive_y_test = bytearray([0x0, 0x0, 0x0, 0x09]) perform_negative_y_test = bytearray([0x0, 0x0, 0x0, 0x0A]) perform_positive_z_test = bytearray([0x0, 0x0, 0x0, 0x0B]) perform_negative_z_test = bytearray([0x0, 0x0, 0x0, 0x0C]) # Initiates the reading of the last performed self test. After sending this command the results # can be downlinked via the housekeeping service by using the appropriate set ids listed above. read_self_test_results = bytearray([0x0, 0x0, 0x0, 0x0D]) @tmtc_definitions_provider def add_imtq_cmds(defs: TmtcDefinitionWrapper): oce = OpCodeEntry() oce.add(OpCode.OFF, "Mode Off") oce.add(OpCode.ON, "Mode On") oce.add(OpCode.NORMAL, "Mode Normal") oce.add(OpCode.REQUEST_ENG_HK_NO_TORQUE, "Request Engineering HK One Shot") oce.add(OpCode.REQUEST_MGM_RAW_NO_TORQUE, "Request MGM Raw Without Torque HK One Shot") oce.add(OpCode.ENABLE_MGM_RAW_NO_TORQUE, "Enable MGM Raw Without Torque HK") oce.add(OpCode.DISABLE_MGM_RAW_NO_TORQUE, "Disable MGM Raw Without Torque HK") oce.add(OpCode.REQUEST_MGM_RAW_WITH_TORQUE, "Request MGM Raw With Torque HK One Shot") oce.add(OpCode.ENABLE_MGM_RAW_WITH_TORQUE, "Enable MGM Raw With Torque HK") oce.add(OpCode.DISABLE_MGM_RAW_WITH_TORQUE, "Disable MGM Raw With Torque HK") oce.add(OpCode.POS_X_SELF_TEST, "IMTQ perform pos X self test") oce.add(OpCode.NEG_X_SELF_TEST, "IMTQ perform neg X self test") oce.add(OpCode.POS_Y_SELF_TEST, "IMTQ perform pos Y self test") oce.add(OpCode.NEG_Y_SELF_TEST, "IMTQ perform neg Y self test") oce.add(OpCode.POS_Z_SELF_TEST, "IMTQ perform pos Z self test") oce.add(OpCode.NEG_Z_SELF_TEST, "IMTQ perform neg Z self test") oce.add(OpCode.SET_DIPOLE, "IMTQ command dipole") oce.add("10", "IMTQ get commanded dipole") oce.add("12", "IMTQ get calibrated MTM measurement one shot") defs.add_service(CustomServiceList.IMTQ.value, "IMQT Device", oce) def pack_imtq_test_into(object_id: ObjectIdU32, q: DefaultPusQueueHelper, op_code: str): q.add_log_cmd( f"Testing ISIS IMTQ handler with object id: {object_id.as_hex_string}" ) if op_code == OpCode.OFF: q.add_log_cmd("IMTQ: Set mode off") command = pack_mode_data(object_id.as_bytes, Mode.OFF, 0) q.add_pus_tc(PusTelecommand(service=200, subservice=1, app_data=command)) if op_code == OpCode.ON: q.add_log_cmd("IMTQ: Set mode on") command = pack_mode_data(object_id.as_bytes, Mode.ON, 0) q.add_pus_tc(PusTelecommand(service=200, subservice=1, app_data=command)) if op_code == OpCode.NORMAL: q.add_log_cmd("IMTQ: Mode Normal") command = pack_mode_data(object_id.as_bytes, Mode.NORMAL, 0) q.add_pus_tc(PusTelecommand(service=200, subservice=1, app_data=command)) if op_code == OpCode.POS_X_SELF_TEST: q.add_log_cmd("IMTQ: Perform positive x self test") command = object_id.as_bytes + ImtqActionId.perform_positive_x_test q.add_pus_tc(PusTelecommand(service=8, subservice=128, app_data=command)) q.add_log_cmd("IMTQ: Initiate reading of positive x self test results") command = object_id.as_bytes + ImtqActionId.read_self_test_results q.add_pus_tc(PusTelecommand(service=8, subservice=128, app_data=command)) q.add_log_cmd("IMTQ: Request dataset with positive x self test results") sid = make_sid(object_id.as_bytes, ImtqSetId.POSITIVE_X_TEST) q.add_pus_tc(generate_one_hk_command(sid)) if op_code == OpCode.NEG_X_SELF_TEST: q.add_log_cmd("IMTQ: Perform negative x self test") command = object_id.as_bytes + ImtqActionId.perform_negative_x_test q.add_pus_tc(PusTelecommand(service=8, subservice=128, app_data=command)) q.add_log_cmd("IMTQ: Initiate reading of negative x self test results") command = object_id.as_bytes + ImtqActionId.read_self_test_results q.add_pus_tc(PusTelecommand(service=8, subservice=128, app_data=command)) q.add_log_cmd("IMTQ: Request dataset with negative x self test results") sid = make_sid(object_id.as_bytes, ImtqSetId.NEGATIVE_X_TEST) q.add_pus_tc(generate_one_hk_command(sid)) if op_code == OpCode.POS_Y_SELF_TEST: q.add_log_cmd("IMTQ: Perform positive y self test") command = object_id.as_bytes + ImtqActionId.perform_positive_y_test q.add_pus_tc(PusTelecommand(service=8, subservice=128, app_data=command)) q.add_log_cmd("IMTQ: Initiate reading of positive y self test results") command = object_id.as_bytes + ImtqActionId.read_self_test_results q.add_pus_tc(PusTelecommand(service=8, subservice=128, app_data=command)) q.add_log_cmd("IMTQ: Request dataset with positive y self test results") sid = make_sid(object_id.as_bytes, ImtqSetId.POSITIVE_Y_TEST) q.add_pus_tc(generate_one_hk_command(sid)) if op_code == OpCode.NEG_Y_SELF_TEST: q.add_log_cmd("IMTQ: Perform negative y self test") command = object_id.as_bytes + ImtqActionId.perform_negative_y_test q.add_pus_tc(PusTelecommand(service=8, subservice=128, app_data=command)) q.add_log_cmd("IMTQ: Initiate reading of negative y self test results") command = object_id.as_bytes + ImtqActionId.read_self_test_results q.add_pus_tc(PusTelecommand(service=8, subservice=128, app_data=command)) q.add_log_cmd("IMTQ: Request dataset with negative y self test results") sid = make_sid(object_id.as_bytes, ImtqSetId.NEGATIVE_Y_TEST) q.add_pus_tc(generate_one_hk_command(sid)) if op_code == OpCode.POS_Z_SELF_TEST: q.add_log_cmd("IMTQ: Perform positive z self test") command = object_id.as_bytes + ImtqActionId.perform_positive_z_test q.add_pus_tc(PusTelecommand(service=8, subservice=128, app_data=command)) q.add_log_cmd("IMTQ: Initiate reading of positive z self test results") command = object_id.as_bytes + ImtqActionId.read_self_test_results q.add_pus_tc(PusTelecommand(service=8, subservice=128, app_data=command)) q.add_log_cmd("IMTQ: Request dataset with positive z self test results") sid = make_sid(object_id.as_bytes, ImtqSetId.POSITIVE_Y_TEST) q.add_pus_tc(generate_one_hk_command(sid)) if op_code == OpCode.NEG_Z_SELF_TEST: q.add_log_cmd("IMTQ: Perform negative z self test") command = object_id.as_bytes + ImtqActionId.perform_negative_z_test q.add_pus_tc(PusTelecommand(service=8, subservice=128, app_data=command)) q.add_log_cmd("IMTQ: Initiate reading of negative z self test results") command = object_id.as_bytes + ImtqActionId.read_self_test_results q.add_pus_tc(PusTelecommand(service=8, subservice=128, app_data=command)) q.add_log_cmd("IMTQ: Request dataset with negative z self test results") sid = make_sid(object_id.as_bytes, ImtqSetId.NEGATIVE_Z_TEST) q.add_pus_tc(generate_one_hk_command(sid)) if op_code in OpCode.SET_DIPOLE: x_dipole = int(input("Specify X dipole [range [0, 2000] * 10^-4 * Am^2]: ")) y_dipole = int(input("Specify Y dipole [range [0, 2000] * 10^-4 * Am^2]: ")) z_dipole = int(input("Specify Z dipole [range [0, 2000] * 10^-4 * Am^2]: ")) duration = int( input( f"Specify torque duration [range [0, {pow(2, 16) - 1}, " f"0 for continuous generation until update]: " ) ) dur_str = "infinite" if duration == 0 else str(duration) q.add_log_cmd( f"IMTQ: Commanding dipole X={x_dipole}, Y={y_dipole}, Z={y_dipole}, duration={dur_str}" ) q.add_pus_tc( pack_dipole_command( object_id.as_bytes, x_dipole, y_dipole, z_dipole, duration ) ) if op_code == "10": # doesnt seem to work anymore q.add_log_cmd("IMTQ: Get commanded dipole") command = object_id.as_bytes + ImtqActionId.get_commanded_dipole q.add_pus_tc(PusTelecommand(service=8, subservice=128, app_data=command)) if op_code == OpCode.ENABLE_ENG_HK_NO_TORQUE: q.add_log_cmd("IMTQ: Enable ENG HK") interval = float(input("Please enter collection interval in seconds: ")) cmds = create_enable_periodic_hk_command_with_interval( diag=True, sid=make_sid(object_id.as_bytes, ImtqSetId.ENG_HK_NO_TORQUE), interval_seconds=interval, ) for cmd in cmds: q.add_pus_tc(cmd) if op_code == OpCode.DISABLE_ENG_HK_NO_TORQUE: q.add_log_cmd("IMTQ: Disable ENG HK (No Torque)") q.add_pus_tc( create_disable_periodic_hk_command( True, make_sid(object_id.as_bytes, ImtqSetId.ENG_HK_NO_TORQUE) ) ) if op_code == OpCode.REQUEST_ENG_HK_NO_TORQUE: q.add_log_cmd("IMTQ: Get engineering hk set") q.add_pus_tc( generate_one_diag_command( sid=make_sid( object_id=object_id.as_bytes, set_id=ImtqSetId.ENG_HK_NO_TORQUE ) ) ) if op_code == "12": q.add_log_cmd("IMTQ: Get calibrated MTM hk set") q.add_pus_tc( create_request_one_diag_command( sid=make_sid(object_id=object_id.as_bytes, set_id=ImtqSetId.CAL_MTM_SET) ) ) if op_code == OpCode.REQUEST_MGM_RAW_NO_TORQUE: q.add_log_cmd("IMTQ: Get raw MTM hk set") q.add_pus_tc( create_request_one_diag_command( sid=make_sid( object_id=object_id.as_bytes, set_id=ImtqSetId.RAW_MTM_NO_TORQUE ) ) ) if op_code == OpCode.DISABLE_MGM_RAW_NO_TORQUE: q.add_log_cmd("IMTQ: Disable MGM RAW HK (No Torque)") q.add_pus_tc( create_disable_periodic_hk_command( True, make_sid(object_id.as_bytes, ImtqSetId.RAW_MTM_NO_TORQUE) ) ) if op_code == OpCode.ENABLE_MGM_RAW_NO_TORQUE: q.add_log_cmd("IMTQ: Enable MGM RAW HK (No Torque)") interval = float(input("Please enter collection interval in seconds: ")) cmds = create_enable_periodic_hk_command_with_interval( diag=True, sid=make_sid(object_id.as_bytes, ImtqSetId.RAW_MTM_NO_TORQUE), interval_seconds=interval, ) for cmd in cmds: q.add_pus_tc(cmd) if op_code == OpCode.REQUEST_MGM_RAW_WITH_TORQUE: q.add_log_cmd("IMTQ: Get raw MTM hk set") q.add_pus_tc( create_request_one_diag_command( sid=make_sid( object_id=object_id.as_bytes, set_id=ImtqSetId.RAW_MTM_WITH_TORQUE_TORQUE ) ) ) if op_code == OpCode.ENABLE_MGM_RAW_WITH_TORQUE: q.add_log_cmd("IMTQ: Enable MGM RAW HK (No Torque)") interval = float(input("Please enter collection interval in seconds: ")) cmds = create_enable_periodic_hk_command_with_interval( diag=True, sid=make_sid(object_id.as_bytes, ImtqSetId.RAW_MTM_WITH_TORQUE), interval_seconds=interval, ) for cmd in cmds: q.add_pus_tc(cmd) if op_code == OpCode.DISABLE_MGM_RAW_WITH_TORQUE: q.add_log_cmd("IMTQ: Disable MGM RAW HK (No Torque)") q.add_pus_tc( create_disable_periodic_hk_command( True, make_sid(object_id.as_bytes, ImtqSetId.RAW_MTM_WITH_TORQUE) ) ) def pack_dipole_command( object_id: bytes, x_dipole: int, y_dipole: int, z_dipole: int, duration: int ) -> PusTelecommand: """This function packs the command causing the ISIS IMTQ to generate a dipole. :param object_id: The object id of the IMTQ handler. :param x_dipole: The dipole of the x coil in 10^-4*Am^2 (max. 2000) :param y_dipole: The dipole of the y coil in 10^-4*Am^2 (max. 2000) :param z_dipole: The dipole of the z coil in 10^-4*Am^2 (max. 2000) :param duration: The duration in milliseconds the dipole will be generated by the coils. When set to 0, the dipole will be generated until a new dipole actuation command is sent. """ action_id = ImtqActionId.start_actuation_dipole command = object_id + action_id x_dipole = int(round(x_dipole)) y_dipole = int(round(y_dipole)) z_dipole = int(round(z_dipole)) if x_dipole < -2000 or x_dipole > 2000: raise_dipole_error("X dipole", x_dipole) if y_dipole < -2000 or y_dipole > 2000: raise_dipole_error("Y dipole", y_dipole) if z_dipole < -2000 or z_dipole > 2000: raise_dipole_error("Z dipole", z_dipole) duration = int(round(duration)) if duration < 0 or duration > pow(2, 16) - 1: raise ValueError( f"Duration in ms of {duration} smaller than 0 or larger than allowed {pow(2, 16) - 1}" ) command += struct.pack("!h", x_dipole) command += struct.pack("!h", y_dipole) command += struct.pack("!h", z_dipole) command += struct.pack("!H", duration) command = PusTelecommand(service=8, subservice=128, app_data=command) return command def raise_dipole_error(dipole_str: str, value: int): raise ValueError( f"{dipole_str} {value} negative or larger than maximum allowed 2000 * 10^-4*Am^2" ) STATUS_HEADERS = [ "Status Byte Mode", "Status Byte Error", "Status Byte Config", "Status Byte Uptime [s]", ] ENG_HK_HEADERS = [ "Digital Voltage [mV]", "Analog Voltage [mV]", "Digital Current [mA]", "Analog Current [mA]", "Coil Current X [mA]", "Coil Current Y [mA]", "Coil Current Z [mA]", "Coil X Temperature [°C]", "Coil Y Temperature [°C]", "Coil Z Temperature [°C]", "MCU Temperature [°C]", ] def handle_imtq_hk(printer: FsfwTmTcPrinter, hk_data: bytes, set_id: int): if (set_id >= ImtqSetId.POSITIVE_X_TEST) and (set_id <= ImtqSetId.NEGATIVE_Z_TEST): return handle_self_test_data(printer, hk_data) elif set_id == ImtqSetId.ENG_HK_NO_TORQUE: _LOGGER.info("Found engineering HK without torque") return handle_eng_set(printer, hk_data) elif set_id == ImtqSetId.ENG_HK_SET_WITH_TORQUE: _LOGGER.info("Found engineering HK during torque") return handle_eng_set(printer, hk_data) elif set_id == ImtqSetId.CAL_MTM_SET: return handle_calibrated_mtm_measurement(printer, hk_data) elif set_id == ImtqSetId.RAW_MTM_NO_TORQUE: _LOGGER.info("Found raw MTM measurement without torque") return handle_raw_mtm_measurement(printer, hk_data) elif set_id == ImtqSetId.RAW_MTM_WITH_TORQUE: _LOGGER.info("Found raw MTM measurement during torque") return handle_raw_mtm_measurement(printer, hk_data) elif set_id == ImtqSetId.STATUS_SET: return handle_status_set(printer, hk_data) else: _LOGGER.warning( f"IMTQ handler HK reply with unknown or unimplemented set id {set_id}" ) def unpack_status_set(hk_data: bytes) -> List: status_mode = hk_data[0] status_error = hk_data[1] status_conf = hk_data[2] status_uptime = struct.unpack("!I", hk_data[3:7])[0] return [status_mode, status_error, status_conf, status_uptime] def unpack_eng_hk(hk_data: bytes) -> List: digital_voltage = struct.unpack("!H", hk_data[0:2])[0] analog_voltage = struct.unpack("!H", hk_data[2:4])[0] digital_current = struct.unpack("!f", hk_data[4:8])[0] analog_current = struct.unpack("!f", hk_data[8:12])[0] coil_x_current = struct.unpack("!f", hk_data[12:16])[0] coil_y_current = struct.unpack("!f", hk_data[16:20])[0] coil_z_current = struct.unpack("!f", hk_data[20:24])[0] coil_x_temperature = struct.unpack("!h", hk_data[24:26])[0] coil_y_temperature = struct.unpack("!h", hk_data[26:28])[0] coil_z_temperature = struct.unpack("!h", hk_data[28:30])[0] mcu_temperature = struct.unpack("!h", hk_data[30:32])[0] content_list = [ digital_voltage, analog_voltage, digital_current, analog_current, coil_x_current, coil_y_current, coil_z_current, coil_x_temperature, coil_y_temperature, coil_z_temperature, mcu_temperature, ] return content_list def handle_eng_set(printer: FsfwTmTcPrinter, hk_data: bytes): pw = PrintWrapper(printer) content_list = unpack_eng_hk(hk_data) validity_buffer = hk_data[32:] num_of_vars = len(ENG_HK_HEADERS) for k, v in zip(ENG_HK_HEADERS, content_list): pw.dlog(f"{k.ljust(30)}: {v}") printer.print_validity_buffer(validity_buffer=validity_buffer, num_vars=num_of_vars) def handle_status_set(printer: FsfwTmTcPrinter, hk_data: bytes): pw = PrintWrapper(printer) content_list = unpack_status_set(hk_data) validity_buffer = hk_data[7:] num_of_vars = 4 for k, v in zip(STATUS_HEADERS, content_list): pw.dlog(f"{k.ljust(30)}: {v}") printer.print_validity_buffer(validity_buffer=validity_buffer, num_vars=num_of_vars) def handle_calibrated_mtm_measurement(printer: FsfwTmTcPrinter, hk_data: bytes): pw = PrintWrapper(printer) header_list = [ "Calibrated MTM X [nT]", "Calibrated MTM Y [nT]", "Calibrated MTM Z [nT]", "Coil actuation status", ] mtm_x = struct.unpack("!I", hk_data[0:4])[0] mtm_y = struct.unpack("!I", hk_data[4:8])[0] mtm_z = struct.unpack("!I", hk_data[8:12])[0] coil_actuation_status = hk_data[12] validity_buffer = hk_data[12:] content_list = [mtm_x, mtm_y, mtm_z, coil_actuation_status] num_of_vars = len(header_list) pw.dlog(str(header_list)) pw.dlog(str(content_list)) printer.print_validity_buffer(validity_buffer=validity_buffer, num_vars=num_of_vars) def handle_raw_mtm_measurement(printer: FsfwTmTcPrinter, hk_data: bytes): pw = PrintWrapper(printer) header_list = [ "Raw MTM X [nT]", "Raw MTM Y [nT]", "Raw MTM Z [nT]", "Coil actuation status", ] mtm_x = struct.unpack("!f", hk_data[0:4])[0] mtm_y = struct.unpack("!f", hk_data[4:8])[0] mtm_z = struct.unpack("!f", hk_data[8:12])[0] coil_actuation_status = hk_data[12] validity_buffer = hk_data[13:] content_list = [mtm_x, mtm_y, mtm_z, coil_actuation_status] num_of_vars = 2 pw.dlog(str(header_list)) pw.dlog(str(content_list)) printer.print_validity_buffer(validity_buffer=validity_buffer, num_vars=num_of_vars) def handle_self_test_data(printer: FsfwTmTcPrinter, hk_data: bytes): pw = PrintWrapper(printer) header_list = [ "Init Err", "Init Raw Mag X [nT]", "Init Raw Mag Y [nT]", "Init Raw Mag Z [nT]", "Init Cal Mag X [nT]", "Init Cal Mag Y [nT]", "Init Cal Mag Z [nT]", "Init Coil X Current [mA]", "Init Coil Y Current [mA]", "Init Coil Z Current [mA]", "Init Coil X Temperature [°C]", "Init Coil Y Temperature [°C]", "Init Coil Z Temperature [°C]", "Err", "Raw Mag X [nT]", "Raw Mag Y [nT]", "Raw Mag Z [nT]", "Cal Mag X [nT]", "Cal Mag Y [nT]", "Cal Mag Z [nT]", "Coil X Current [mA]", "Coil Y Current [mA]", "Coil Z Current [mA]", "Coil X Temperature [°C]", "Coil Y Temperature [°C]", "Coil Z Temperature [°C]", "Fina Err", "Fina Raw Mag X [nT]", "Fina Raw Mag Y [nT]", "Fina Raw Mag Z [nT]", "Fina Cal Mag X [nT]", "Fina Cal Mag Y [nT]", "Fina Cal Mag Z [nT]", "Fina Coil X Current [mA]", "Fina Coil Y Current [mA]", "Fina Coil Z Current [mA]", "Fina Coil X Temperature [°C]", "Fina Coil Y Temperature [°C]", "Fina Coil Z Temperature [°C]", ] # INIT step (no coil actuation) init_err = hk_data[0] init_raw_mag_x = struct.unpack("!f", hk_data[1:5])[0] init_raw_mag_y = struct.unpack("!f", hk_data[5:9])[0] init_raw_mag_z = struct.unpack("!f", hk_data[9:13])[0] init_cal_mag_x = struct.unpack("!f", hk_data[13:17])[0] init_cal_mag_y = struct.unpack("!f", hk_data[17:21])[0] init_cal_mag_z = struct.unpack("!f", hk_data[21:25])[0] init_coil_x_current = struct.unpack("!f", hk_data[25:29])[0] init_coil_y_current = struct.unpack("!f", hk_data[29:33])[0] init_coil_z_current = struct.unpack("!f", hk_data[33:37])[0] init_coil_x_temperature = struct.unpack("!H", hk_data[37:39])[0] init_coil_y_temperature = struct.unpack("!H", hk_data[39:41])[0] init_coil_z_temperature = struct.unpack("!H", hk_data[41:43])[0] # Actuation step err = hk_data[43] raw_mag_x = struct.unpack("!f", hk_data[44:48])[0] raw_mag_y = struct.unpack("!f", hk_data[48:52])[0] raw_mag_z = struct.unpack("!f", hk_data[52:56])[0] cal_mag_x = struct.unpack("!f", hk_data[56:60])[0] cal_mag_y = struct.unpack("!f", hk_data[60:64])[0] cal_mag_z = struct.unpack("!f", hk_data[64:68])[0] coil_x_current = struct.unpack("!f", hk_data[68:72])[0] coil_y_current = struct.unpack("!f", hk_data[72:76])[0] coil_z_current = struct.unpack("!f", hk_data[76:80])[0] coil_x_temperature = struct.unpack("!H", hk_data[80:82])[0] coil_y_temperature = struct.unpack("!H", hk_data[82:84])[0] coil_z_temperature = struct.unpack("!H", hk_data[84:86])[0] # FINA step (no coil actuation) fina_err = hk_data[86] fina_raw_mag_x = struct.unpack("!f", hk_data[87:91])[0] fina_raw_mag_y = struct.unpack("!f", hk_data[91:95])[0] fina_raw_mag_z = struct.unpack("!f", hk_data[95:99])[0] fina_cal_mag_x = struct.unpack("!f", hk_data[99:103])[0] fina_cal_mag_y = struct.unpack("!f", hk_data[103:107])[0] fina_cal_mag_z = struct.unpack("!f", hk_data[107:111])[0] fina_coil_x_current = struct.unpack("!f", hk_data[111:115])[0] fina_coil_y_current = struct.unpack("!f", hk_data[115:119])[0] fina_coil_z_current = struct.unpack("!f", hk_data[119:123])[0] fina_coil_x_temperature = struct.unpack("!H", hk_data[123:125])[0] fina_coil_y_temperature = struct.unpack("!H", hk_data[125:127])[0] fina_coil_z_temperature = struct.unpack("!H", hk_data[127:129])[0] validity_buffer = hk_data[129:] content_list = [ init_err, init_raw_mag_x, init_raw_mag_y, init_raw_mag_z, init_cal_mag_x, init_cal_mag_y, init_cal_mag_z, init_coil_x_current, init_coil_y_current, init_coil_z_current, init_coil_x_temperature, init_coil_y_temperature, init_coil_z_temperature, err, raw_mag_x, init_raw_mag_y, raw_mag_z, cal_mag_x, cal_mag_y, cal_mag_z, coil_x_current, coil_y_current, coil_z_current, coil_x_temperature, coil_y_temperature, coil_z_temperature, fina_err, fina_raw_mag_x, fina_raw_mag_y, fina_raw_mag_z, fina_cal_mag_x, fina_cal_mag_y, fina_cal_mag_z, fina_coil_x_current, fina_coil_y_current, fina_coil_z_current, fina_coil_x_temperature, fina_coil_y_temperature, fina_coil_z_temperature, ] num_of_vars = len(header_list) pw.dlog(str(header_list)) pw.dlog(str(content_list)) printer.print_validity_buffer(validity_buffer=validity_buffer, num_vars=num_of_vars)