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Adding

In the “Administration” section open the “Vehicles” tab and click the “Add” button. Following window opens:

Managing groups

“Vehicle name” - Enter the name of a vehicle to be displayed in Omnicomm Online.

“Terminal type” - Select the type of terminal installed on a vehicle. Possible values: Omnicomm or one of the third-party terminals.

“Server port” - The server port is set automatically depending on the type of selected terminal.

“Factory number” - Enter the factory number listed on the terminal.

To add a vehicle and proceed to the vehicle profile setup, click “Save and proceed to setup”. To add a vehicle without setting up the profile, click the “Save” button. When you go to the settings, the window of editing the vehicle profile opens: VH profile

Profile settings

In the vehicle profile setting in the “Profile” tab, specify the parameter values:

In the “Terminal” section:

VH profile

“Omnicomm ID” displays the identification number of the terminal installed on a vehicle.

“Factory number” shows the factory number of the terminal, which is set at factory.

“Terminal” shows the terminal model.

“Use as a fuel dispenser” (only for Omnicomm Profi terminals) enables/disables the ability to register filling, draining and dispensing of fuel through the fueling gun.

“Type” is the type of vehicle.

“Terminal SIM number” - Enter the phone number of the SIM card installed in the terminal.

“Video terminal ID” - Enter the identification number of Omnicomm OKO Light video terminal installed on a vehicle. Click the “Bind ID” button. ID binding is used to match video files received from Omnicomm OKO Light video terminal with telematics data from the terminal also installed on a vehicle.

In the “Vehicle” section:

Vehicle

“Start date of processing in Omnicomm Online” - date and time of start of data processing by profile in Omnicomm Online.

“Vehicle name” is the name of the vehicle. For example: 10 RU А 123БВ. The vehicle name must be unique for Omnicomm Online. The field “Vehicle name” must not be empty and must not exceed 100 characters.

“Fleet number” is the internal number of a vehicle in an organization.

“Purpose” is the purpose of a vehicle in the organization.

“Brand” is the brand of a vehicle.

“Model” is the model of a vehicle.

“Color” is the color of a vehicle.

“Year of manufacture” is the year of manufacture of a vehicle.

“VIN” is Vehicle Identification Number.

“Engine number” is the engine number of a vehicle.

“Chassis number” - chassis number of a vehicle.

“Vehicle registration plate” shows registration number of a vehicle.

“Manufacturer, model, engine power” - Specify the characteristics of a vehicle engine.

“Vehicle registration certificate” - Enter the number of a vehicle registration certificate.

“Vehicle passport” - Enter a vehicle passport number.

“Lease agreement number” - Enter the agreement number, if a vehicle is leased.

“Vehicle category” - Select the category of a vehicle. Possible options:

• Categories A, B, C, D, D, E, F according to the traffic rules of the Russian Federation

• SPEC category - custom vehicles

“Groups”. Click on the Select group hyperlink for a vehicle being edited and select groups from the list to which a vehicle will belong.

In the “Movement” section: Movement

“Mileage and speed calculation method” allows you to select which data and method to use to calculate mileage and speed. Possible options:

  • “According to terminal data (without excluding coordinate outliers)“ - Omnicomm Online calculates mileage using data received from terminals without excluding drift coordinates.
  • “According to terminal data (excluding coordinate outliers)“ - Omnicomm Online calculates mileage based on data received from terminals with drift coordinates cut-off
  • “Speed by GPS coordinates, mileage by GPS coordinates (excluding coordinate outliers)“ - Omnicomm Online calculates mileage by GPS coordinates, cutting off invalid GPS coordinates or coordinates determined by less than 4 satellites.
  • “Speed by GPS coordinates, mileage by GPS coordinates (without excluding coordinate outliers)“ - Omnicomm Online calculates mileage by GPS coordinates, without cutting off invalid GPS coordinates or coordinates determined by less than 4 satellites.
  • “According to speed sensor data” - Omnicomm Online calculates mileage based on the vehicle's regular speed sensor data, taking into account the correction factor (for cars only)

For the standard speed sensor, set the “Speed sensor correction factor” and “Mileage correction factor”, which provide correction of the speed sensor readings.

“Maximum allowable acceleration, m/s²” - Enter the value of the maximum allowable acceleration of a vehicle (lateral, acceleration, braking), above which a sharp change in the nature of a vehicle movement is detected.

“Track parking for more than, min:sec” - Check the box and specify the number of minutes after which a vehicle parking will be registered if the corresponding conditions are met. The conditions for parking/stops detection depend on the parameter “Take ignition into account when determining parking and stops”.

“Track stops for more than, min:sec” - Check the box and specify the number of minutes after which a vehicle stop will be registered if the corresponding conditions are met.

“Take ignition into account when determining parking and stops” - Check the box if it is necessary to register parking and stops taking into account the state of vehicle ignition. The selection is only active when “Track parking for more than, minutes” or “Track stops for more than, minutes” is enabled.

Condition of parking/stops registration taking into account the state of ignition of a vehicle:

• More time has elapsed since the ignition was switched off than specified in the “Track parking for more than, minutes” parameter

• Vehicle speed less than 2 km/h

The condition of parking/stops registration without taking into account the state of ignition of a vehicle:

• Vehicle speed less than 2 km/h for all consecutive events with raw data

• The distance between any events with raw data is less than 800 m

• The time interval between the first and the last event with raw data is greater than the value of the parameter “Track stops for more than, minutes”.

• The time interval between the first and last raw data event does not include periods of data unavailability

“Take into account engine speeds” - Check the box if it is necessary to take into account engine speeds when rendering reports.

“Minimum duration of data unavailability” is the maximum time between the current and the last valid raw data event, after which Omnicomm registers the event of data “unavailability”.

“Drift by mileage” - Specifies thresholds for movement and mileage to cut off drift coordinates while a vehicle is parked with the GPS module running. When a vehicle is moving at a speed of more than 2 km/h, the drift coordinates are not cut off. The values “Drift by mileage, m” (from 0 to 100 m) and “Drift by mileage, m” (from 0 to 100 m) are adjusted taking into account the average speed of a vehicle. The default value for both parameters is 20 m.

In the “Engine” section:

Engine

“Correction factor for RPM meter” is the factor for converting the number of pulses from the RPM meter to the number of revolutions.

“Engine RPM limit” is the engine RPM value, when exceeded, Omnicomm Online registers a vehicle operation under the load limit. The default value is 5,500 rpm.

“Engine idle RPM level” is the engine RPM value, when exceeded, Omnicomm Online registers vehicle movement. The default value is 1,000 rpm.

In the “Fuel parameters” section:

“Fuel tanks” - Select the number of fuel tanks installed on a vehicle:

  • “Main only” means only one fuel tank is installed on a vehicle
  • “Main and additional” means two fuel tanks are installed on a vehicle. For refuellers, the main tank is the reservoir, the additional tank is the engine fuel tank. For the vehicle, the main tank is the engine fuel tank, the additional tank is the fuel tank for the optional equipment.
  • “Multitank” means up to 6 fuel tanks are installed on a vehicle. Available to users with established rights to objects: Access to Multitank (see Adding and editing a user profile).

Parameters of the main fuel tank Main tank

The units of fuel parameters liters or gallons are specified depending on the server settings.

“LLS5”:

LLS5

“Monitor fuel quality LLS 5” - Check the box to monitor fuel quality using Omnicomm LLS 5 level sensors.

“Autotuning coefficient change threshold, %“ - Specify the allowable value of autotuning coefficient change, if exceeded, the “Correction coefficient change threshold exceeded” event will be registered. The default value is 7. Possible values: 0 to 100.

“Autotuning factor stabilization interval, seconds” - 0 (unchangeable value).

“Fuel”:

Fuel

“Parameters of the main fuel tank” for the vehicle and the additional tank for the fuel dispenser:

“Refueling threshold, l” (from 0 to 28,000) is the volume of fuel by which the total volume of fuel of a vehicle must be increased in order for fuel refueling to be registered. The default value of the refueling threshold is 7% of the tank volume.

“Drainage threshold, l” (from 0 to 28,000) is the volume of fuel by which the total volume of fuel of a vehicle must be reduced in order for the fuel drainage to be registered. The default value of the drain threshold is 7% of the tank volume.

“Average consumption per 100 km, l” (from 0 to 1,000 with accuracy to 0.1 l) is the volume of fuel consumed by a vehicle per 100 km (only for cars).

“Average consumption per engine hour, l” (from 0 to 1,000 with accuracy up to 0.1 l) is volume of fuel consumed by a vehicle for an hour of engine operation (only for cars).

“Average fuel consumption for data collection period, l” (from 0 to 1,000 with accuracy up to 0.1 l) is the volume of fuel consumed by a vehicle during the time between taking readings from the sensor (only for cars).

“Correction factor for fuel sensors” (from 0.01 to 1.99) is used to correct readings of Omnicomm LLS fuel level sensors.

“Fuel type” - Select the type of fuel to calculate the amount of CO2 emissions. Possible options: gasoline, diesel and not specified.

“Parameters of fuel data processing algorithms”: Fuel parameters

“Rough filter” is the number of fuel level measurements before and after refueling/draining that are used in the refueling/draining search algorithm to filter out fuel level fluctuations. Coarse filter size (5 - 50), the default value is 15.

The fill/drain thresholds and coarse filter size are selected based on the tank volume, the amount of fill/drain detected and the vehicle operating conditions.

In cases where operating conditions and vehicle characteristics cause large fluctuations in fuel level, it is recommended to increase the values of refueling/drain thresholds and coarse filter value relative to default values.

In cases where operating conditions and vehicle characteristics have little effect on fuel level fluctuations, it is allowed to reduce the values of refueling/drain thresholds and coarse filter value relative to default values.

“Buffer length” - Specify the buffer length for the fuel data smoothing algorithm. Coarse filter size (10 - 100), the default value is 35.

“Additional parameters for the algorithm to search for refills and drains”:

Flexible fuel parameters

For the algorithm for searching for refueling and draining “Take time parameters into account”:

“Maximum allowable refueling interruption time, sec” is the time interval in the process of refueling during which the fuel level may not rise. The default value is 30 s.

“Maximum allowable draining interruption time, sec” is the time interval in the process of draining, during which the fuel level may not drop (taking into account average fuel consumption). The default value is 30 s.

The setting of time parameter values should be done by considering the "Data collection period" value and analyzing specific areas where no drain/fill events were detected.

Quartile is the arithmetic mean of some number of points with fuel raw data before the start or after the end of fuel operation with a quarter of minimum and maximum values screened out and is used to determine the fuel level before and after refueling/draining.

The quartile is calculated by the number of fuel level values obtained during the time specified in the “Time interval for quartile calculation, min” parameter.

“Time of fuel operation start in motion, sec” is the allowable time of fuel operation start in motion.

“Time of fuel operation end in motion, sec” is selected depending on the filtering value set in the terminal.

Recommended values for filtration levels:

• Disabled - 0

• Weak - 60

• Average - 120.

• Strong - 200.

• Maximum - 300.

“Allowable deviation from the movement section boundary, sec” is the time during which the fuel level is current at the start or end of movement.

“Maximum allowed speed for filtering at speed, km/h” - Specify the speed (with filtering enabled) above which fuel operations will not be displayed in reports.

“Fuel weight calculation”:

“Method of mass calculation” - Select the method of fuel mass calculation. Possible options:

• by level, temperature and standard density

• by level and actual density

For the “by level, temperature and standard density “ method:

Method by level, temperature, and rated density

“Fuel average density at 20°C, kg/m3” - Enter the fuel standard density. The default value is 860.0 kg/m3.

“Temperature data source” - Select the universal input to which the temperature sensor is connected.

“Temperature density factor” - Enter the temperature density factor. The default value is 0.7.

For the “by level and actual density” method:

Method by level and actual density

“Density data source” - Select the universal input to which the density sensor is connected.

Multitank parameters

• Select Multitank

• Specify the number of tanks

Multitank

Tank parameters

Specify the following parameters for each tank:

“Tank type” - Select the tank type. Possible variants: consumption tank, non-consumption tank without output counter.

“Name” - Enter the name of the tank.

For consumption and non-consumption tanks, specify the fuel parameters in the same way as for the main tank.

Editing gauging tables Calibration table

Select the number of fuel level sensors installed on a vehicle.

When loading multiple tables from a file, specify the network addresses of the fuel level sensors.

For each fuel level sensor, select the tank (“Main” or “Additional”) in which the fuel level sensor is installed.

In case of Multitank, select the tank in which the sensor is installed by clicking Unlinked.

Highlight with the cursor the row whose values you want to change. In the input cells below the table, enter new values for this row of the table. To enter row values into the table, press Introduce value.

To add/remove a table row, press Add and remove line.

In the “Universal input settings” section:

Analog universal input

“Universal input type” displays the “analog” input type, set during terminal setup.

Analog input 1

“Name of the equipment on the universal input” - Enter the name of the sensor or the name of the measured value.

“Universal input correction factor”.

The default value is 1.

“Take into account the switching state of additional equipment on the universal input” registers the switching on of additional equipment at the universal input.

“Threshold value of switching on the universal input” - For analog sensors it is recommended to set the value beyond the sensor measurement range, which will help to avoid registration of unnecessary sensor switching off events. When the “Take into account the switching state of additional equipment on the universal input” is turned off, the field “Threshold value of switching on the universal input” is not editable.

“Take into account exceeding the allowable value at the universal input” registers exceeding of the allowable value at the universal input.

“Threshold of maximum allowable value on universal input” - Enter the measured value, when exceeded, Omnicomm will register operation with exceeded allowable value. If “Take into account exceeding the allowable value at the universal input” is turned off, the field “Threshold of the maximum allowable value at the universal input” is not available for editing.

To save all changes, click the “Save” button.

Potential universal input

“Universal input type” displays the “potential” input type, set during terminal setup.

UI Potential

“Name of the equipment on universal input” - Enter the name of the sensor or the name of the measured value.

Pulse universal input

“Universal input type” displays the “pulse” input type, set during terminal setup.

UI Pulse

“Name of the equipment on universal input” - Enter the name of the sensor or the name of the measured value.

“Universal input correction factor” is recommended to be changed only if the input calibration has been incorrectly performed.

“Take into account the switching state of additional equipment on the universal input” registers the switching on of additional equipment at the universal input.

When the “Take into account the switching state of additional equipment on the universal input” is turned off, the field “Threshold value of switching on the universal input” is not editable.

“Take into account exceeding the allowable value at the universal input” registers exceeding of the allowable value at the universal input.

“Threshold of maximum allowable value on the universal input” - Enter measured value, when exceeded, Omnicomm will register the operation with exceeding the allowable value. If “Take into account exceeding the allowable value at the universal input” is turned off, the field “Threshold of the maximum allowable value at the universal input” is not available for editing.

In the section “Setting initial values for maintenance control”:

Maintenance control

“Mileage record” allows you to select the data source to record a vehicle mileage for control over maintenance. Possible options:

  • “Ignore mileage” - Mileage calculation for maintenance control will not be performed
  • “Use odometer” - The calculation is based on the odometer readings set in the vehicle profile in the “Mileage and speed calculation method” parameter. Possible options: from terminal (with drift), from terminal (without drift), speed by GPS, mileage by GPS coordinates, from speed sensor

Maintenance control odometer

“Initial odometer value, km” - Enter the odometer reading mileage value.

“Date and time of odometer initial reading” - Enter the date and time when the odometer reading was taken.

“Current odometer value, km” displays the mileage value calculated by Omnicomm using the odometer. To display the current odometer value at the first installation or adjustment, you must save the changes to the vehicle profile and then reopen the vehicle profile.

  • “Use CAN-bus odometer value” - The mileage calculation for maintenance control will be performed according to the values received from the CAN-bus

Maintenance control CAN

“Current odometer value, km” displays the last mileage value sent by the terminal based on the CAN-bus odometer readings.

“Engine hours record” allows selecting the source of data to record vehicle’s engine hours for control over maintenance.

Possible options:

  • “Do not count engine hours” - Engine hours will not be counted for the purpose of maintenance control
  • “Use engine hour meter” - the calculation of engine hours will be based on the readings of a vehicle's engine hour meter and engine running time.

Maintenance control Hour meter

“Coefficient for conversion of engine operation time into engine hours” - Specify the coefficient for conversion of engine operation time into engine hours specified in a vehicle passport.

“Initial counter value, eh” is the value of the engine hour meter.

“Date and time when the initial odometer reading was taken” - Enter the date and time when the engine hour meter reading was taken.

  • “Use CAN-bus hours value” - The calculation of the engine hours for the maintenance check will be performed using the values received from the CAN-bus.

Maintenance control CAN hours

“Current hour meter value, eh” - the number of hours received from the CAN-bus.

In the “Assigning a driver to a vehicle” section:

Assigning driver

“Driver registration by applying a tag” - Check the checkbox to register the driver by applying an RFID card or iButton key.

The assignment of a driver to a vehicle is automatically terminated when this driver is assigned to another vehicle or when another driver is assigned to the same very vehicle.

“End registration with ignition off” - Check the box to end registration when ignition off is detected

“End registration by removing the tag from its holder” - check the checkbox to end enrollment when it is detected that the iButton key or RFID card is removed from the holder.

“Restore registration if tag is re-applied within specific time” - Specify the time within which the RFID card or iButton key must be re-applied to automatically restore driver registration. The field is active only if the “End registration by turning off the ignition” or “End registration by removing the tag from its holder” parameter is enabled.

In the “Setting temperature sensors” section:

Temperature sensors

“No.” shows the serial number of the temperature sensor.

“Name” - Enter the name of the temperature sensor. For example, a cabin. The maximum number of characters is 16.

In the “Tyre pressure monitoring” section:

Tyre pressure

“Generate events from TPMS” - Check the checkbox to process data from the tire pressure monitoring system.

“Allowable duration of data unavailability, minutes” - Enter the value after which the “No data from tire pressure monitoring system” event will be registered in case of no data. Possible values: 0 to 1140 min. The default value is 15.

“Number of vehicle axles” - Select the number of vehicle axles. Possible values: 1 to 13.

When using TPMS Conti Pressure Check tire pressure monitoring system, the axles and wheels must match the TPMS Conti Pressure Check configuration:

Tyre pressure display

Tyres

The wheel position data in TPMS Conti Pressure Check is transmitted in CAN J1939 format. The wheels are numbered from left to right from the first (top) axle, so that the first wheel is located on the driver's side.

“Correct tire pressure, kPa” - Enter the tire pressure value set by a vehicle manufacturer. Possible values: 0 to 1,000 kPa.

“Allowable deviation of tire pressure, kPa” - Enter the value of allowable deviation from normal tire pressure, above which the “Tire pressure drop” event is registered.

“Maximum allowable tire temperature, °С” - Enter the value of tire temperature, if exceeded, the “Tire temperature rise” event is registered. Possible values: -125 to 125 °C. The default value is plus 60 °C.

To copy axle, wheel and tolerance settings from another vehicle, click the Copy from another vehicle link.

In the “iQFreeze” section:

iQFreeze

“Process data from iQFreeze” - Check the box to control data from iQFreeze.

“Allowable duration of data unavailability, minutes”. Possible values: 0 to 1,440 min. The default value is 15 min

“Allowable upward deviation of the CHU temperature from the set temperature”. Possible values: 0.00 to 100.00 °C

“Allowable downward deviation of the CHU temperature from the set temperature”. Possible values: 0.00 to 100.00 °C

In the “CAN threshold values” section:

CAN threshold

Add the required CAN parameters and specify the values which are as follows:

“Correction factor” - Enter the value of the correction factor.

“Switching threshold” - Enter measured value, when it reaches which Omnicomm will register switching on.

“Lower threshold of nominal values” - Enter the measured value, above which Omnicomm will register operation at nominal values.

“Upper threshold of nominal values” - Enter measured value, when exceeded, Omnicomm registers operation with exceeding the nominal value.

Parameter settings

Open the vehicle profile and go to the “Parameter settings” tab. A window opens, there you can specify the parameter values.

In the “Calculation method” fields, only the calculation methods supported by the selected third-party terminal are displayed. Before selecting the “Calculation method” options in the “Monitoring” tab, make sure that data from the planned “Calculation method” parameter is available. In the “Terminal” section:

Parameter

“ID Omnicomm” is an identification number of the terminal installed on a vehicle. The ID number is automatically generated based on the unique ID of the terminal.

“Factory number” - Enter the factory number listed on the terminal.

“Terminal type” is the type of terminal installed on a vehicle.

“Terminal SIM number” - Enter the phone number of the SIM card installed in the terminal.

“Date when profile was added” is the time and date when the vehicle profile was added to Omnicomm Online.

“Server port” displays the server port for connection of the selected terminal.

System Parameters

In the “Ignition flag” section:

Ignition flag

Select the parameter on the basis of which Omnicomm Online will register the event of turning on/off a vehicle ignition.

Possible values: • “Analog input”: This calculation method is set when an ignition key signal is connected to the analog input of the terminal. Omnicomm Online will detect the ignition switch on when the voltage on the analog input is equal or more than “Threshold value, V”

If it is necessary to register the ignition switch-on when the analog input voltage is less than the “Threshold value, V”, check the “Invert” checkbox.

Ignition flag analog “Ignition” flag. This calculation method is set if the terminal transmits ignition on/off data by ignition key position. • “Discrete input”. This calculation method is set when an ignition key signal is connected to the discrete input of the terminal. Omnicomm Online will register the ignition switch on when a discrete input switch-on event is received from the terminal If it is necessary to register the ignition switch on when a discrete input turn-off event is received, check the “Invert” checkbox.

Ignition flag Discrete

“Presence of motion” flag. This calculation method is set if the terminal transmits a flag for the presence of movement. Omnicomm Online will register the ignition switch on when the terminal transmits the “Presence of motion” event

“Engine RPM CAN” flag. This calculation method is set if the terminal transmits the engine speed value from the CAN-bus. Omnicomm Online will register the ignition switch on when receiving an event from the terminal with the presence of engine speed data from the CAN-bus

“Main power supply”. This calculation method is set when the terminal transmits the main power supply. Omnicomm Online will register the ignition switch-on when the voltage of on-board vehicle network is equal to or more than “Threshold value, V”

If it is necessary to register the ignition switch-on when the on-board voltage of a vehicle is less than the “Threshold value, V”, check the “Invert” checkbox.

Ignition flag Main power supply

“Power status” flag. This calculation method is set when the terminal transmits data on the availability of main power and backup battery power. Omnicomm Online will register the ignition switch on when the main power supply is present

“Engine RPM”. This calculation method is set when the terminal transmits the RPM value. Omnicomm Online will register ignition switch on when the engine speed value is greater than 0

“Always On”. This calculation method is the default value or set when ignition control is not available. Omnicomm Online will display the ignition is always on, so the calculation of parameters based on the ignition on/off data will not be performed

In the “GSM connection availability” section:

GSM connection flag

In the “Calculation method” field, select the parameter on the basis of which Omnicomm Online will register the presence of GSM connection.

Possible values:

Always “Connection available”, This calculation method is the default value or is set if GSM connection monitoring is not required. Omnicomm Online will display constant GSM connection availability

“GSM connection” flag. This calculation method is set in case the terminal transmits information about the presence of GSM connection. Omnicomm Online will register the presence of GSM connection, when receiving the GSM connection event from the terminal

GSM signal reception level. This calculation method is set when the terminal transmits signal reception level data. Omnicomm Online will register the presence of GSM connection, when receiving from the terminal the signal reception level value greater than 0

In the “Roaming” section:

In the “Calculation method” field, select the parameter on the basis of which Omnicomm Online will register the presence of a vehicle in roaming.

Roaming flag

Possible values: • Always “On the home network”. This calculation method is the default value or is set when roaming control is not required. Omnicomm Online will display the permanent presence of the terminal on the home network

“Roaming” flag. This calculation method is set when the terminal transmits roaming information. Omnicomm Online will register being in roaming, when receiving a roaming event from the terminal

In the “Power Status” section:

Power supply flag

In the “Calculation method” field, select the parameter on the basis of which Omnicomm Online will register the power status of the terminal.

Possible values:

“Power status” flag. This method allows you to register in Omnicomm the events of switching on/off the main power supply and switching to the backup power supply. The values of the main and standby supply voltage are set when setting the supply voltage

Always “External supply”. This method is set when the terminal does not transmit the “Power supply” parameter (external/internal) or when control of the events Main power on/off and transition to backup power in Omnicomm Online is not required

In the “Alarm button” section:

Alarm button flag

In the “Calculation method” field, select the parameter based on which Omnicomm Online will register the alarm button status.

Possible values:

“Alarm button” flag. This calculation method is set when the terminal transmits information about the status of the panic button. Omnicomm Online will register the alarm button press when the corresponding event is received from the terminal • By discrete input <N>. This calculation method is set if the alarm button is connected to a digital input of the terminal. Omnicomm Online will register the alarm button triggering when a discrete input triggering event is received from the terminal. If it is necessary to register the alarm button triggering when the event of discrete input shutdown is received, check the “Invert” checkbox • Always off. This calculation method is the default value or is set when alarm button status monitoring is not required. Omnicomm Online will always display the absence of alarm button triggers

In the section “Device tampering”:

Device tampering flag

In the “Calculation method” field, select the parameter based on which Omnicomm Online will register terminal tampering.

Possible values:

Always “Device closed”. This calculation method is the default value or is set when tamper switch status monitoring is not required. Omnicomm Online will always display the absence of device tampering

“Device tampering” flag. This calculation method is set if the terminal transmits information about the state of the device's tampering sensor. Omnicomm Online will register device tampering upon receipt of the corresponding event from the terminal

By discrete input <N>. This calculation method is set if a tamper switch is connected to the discrete input of the terminal. Omnicomm Online will register tampering of the device upon receipt of a discrete input enable event from the terminal. If it is necessary to register the enclosure tampering when a digital input shutdown event is received, check the “Invert” box

In the “Discrete output status” section:

Discrete output flag

In the “Calculation method” field, select the parameter, based on which Omnicomm Online will register the state of the discrete output.

Possible values:

Always “Off”. This calculation method is the default value or is set when discrete output monitoring is not required. Omnicomm Online software will always display a disabled digital output

“Discrete output status” flag. This calculation method is set when the terminal transmits information about the state of a digital output

Various parameters

In the “Mileage” section:

In the “Calculation method” field, select the parameter on the basis of which Omnicomm Online will calculate a vehicle's mileage.

Mileage flag

Possible values:

“Relative counter <N>“. This calculation method is set when the terminal transmits the mileage value between consecutive events in units other than meters.

Mileage counter flag

“Decimeter conversion factor”. Enter the factor by which to multiply the mileage obtained from the absolute meter to convert the mileage value to meters. In Omnicomm Online in the settings of the vehicle profile in the parameter “Mileage and speed calculation method” will be set to “Based on data from the terminal” (without excluding coordinate outliers)

“Mileage by CAN: SPN245”. This calculation method is set when the terminal transmits the mileage value from the CAN-bus, SPN245 signal. In Omnicomm Online in the settings of the vehicle profile in the parameter “Mileage and speed calculation method” will be set to “Based on data from the terminal” (without excluding coordinate outliers)

“Total mileage CAN Hi-res (SPN917)”. This calculation method is set when the terminal transmits the mileage value from the CAN-bus, SPN917 signal. In Omnicomm Online in the settings of the vehicle profile in the parameter “Mileage and speed calculation method” will be set to “Based on data from the terminal” (without excluding coordinate outliers)

“Relative mileage”. This calculation method is set if the terminal transmits the mileage value between consecutive events in meters. In Omnicomm Online in the settings of the vehicle profile in the parameter “Mileage and speed calculation method” will be set to “Based on data from the terminal” (without excluding coordinate outliers)

“Calculate in Omnicomm by GPS”. This calculation method is set by default. Mileage will be calculated in Omnicomm Online using GPS coordinates. In Omnicomm Online in the settings of a vehicle profile in the parameter “Mileage and speed calculation method” will be set to “Speed by GPS, mileage by GPS coordinates” (without excluding coordinate outliers)

In the “RPM” section:

In the “Calculation method” field, select the parameter, based on which Omnicomm Online will calculate the vehicle engine speed.

RPM flag

Possible values:

“Analog Input <N>”. This calculation method is set when the speed sensor is connected to the analog input of the terminal. Omnicomm Online will register the value of revolutions when the corresponding value is received from the terminal

“RPM conversion factor” enter the factor by which the received RPM value should be multiplied to convert the value to RPMs

RPM Analog flag

“Relative Counter <N>”. This calculation method is set if the terminal transmits the value of revolutions between consecutive events in units other than revolutions per minute.

“RPM conversion factor” enter the factor by which the received RPM value should be multiplied to convert the value to RPMs

RPM Counter flag

“Discrete input <N>”. This calculation method is set if the speed value is not calculated and the speed value is set when the discrete input of the terminal is switched on

“Ignition” flag. This calculation method is set if the RPM value is not calculated and the RPM value is set when the ignition switch-on event is received from the terminal.

“MODBUS <N>”. This calculation method is set in case the terminal transmits the engine speed value via MODBUS protocol

“RPM meter” This calculation method is set in case the terminal transmits the engine speed value based on vehicle speed sensor readings

“CAN parameter: SPN190”. This calculation method is set if the terminal transmits the engine speed value from the CAN-bus, SPN190 signal.

“OBDII: Engine RPM”. This calculation method is set when the terminal transmits the RPM value via OBD bus.

“Always 1,000 rpm”. This calculation method is set in case the revolutions control is not required and Omnicomm Online will register a constant value of revolutions – 1,000.

“Always 0”. This calculation method is set in case the revolutions control is not required and Omnicomm Online will register a constant value of revolutions - 0

In the “iButton Identifier” and “iButton2 Identifier” sections:

In the “Calculation method” field, select the calculation method depending on the type of connected optional equipment:

iButton flag

Possible options:

iButton ID - to send iButton key ID in Omnicomm Online

Invert - Check the box to invert the iButton ID value

In the section “Speed by sensor”:

Speed by sensor flag

In the “Calculation method” field, select the parameter on the basis of which Omnicomm Online will calculate the vehicle speed.

Possible values:

“Analog Input <N>”. This calculation method is set when the speed sensor is connected to the analog input of the terminal. Omnicomm Online will register the speed value when receiving the corresponding value from the terminal

|Speed by analog sensor flag

“Speed sensor” This calculation method is set when the terminal transmits the speed value based on vehicle speed sensor readings

“Parameter CAN”. This calculation method is set if the terminal transmits a mileage value from the CAN-bus.

“OBDII: Speed”. This calculation method is set when the terminal transmits the speed value via OBD bus.

In the “Power supply voltage” section:

In the “Calculation method” field, select the parameter on the basis of which Omnicomm Online will register the terminal supply voltage.

Power supply voltage flag

Possible values:

“Analog Input <N>”. This calculation method is set when the analog input of the terminal is connected to the on-board network. Omnicomm Online will register the supply voltage value when it receives the corresponding value from the terminal

Power supply voltage analog flag

“Reduction factor to 1 V”. Enter the factor by which to multiply the resulting supply voltage value to bring the value to the 1 V dimension

“Main power supply”. This calculation method is set when the terminal is connected to the on-board network of a vehicle. Omnicomm Online will only register the value of the main power supply voltage. If necessary, enter an adjustment factor

“Always 0”. This calculation method is set in case the on-board voltage control is not required and Omnicomm Online will register a constant value of supply voltage - 0

Universal inputs

In the “Universal inputs” section:

Universal inputs tab

“Number of connected universal inputs”. Possible values: 0 to 4.

In the “Calculation method” field, select the calculation method depending on the type of connected additional equipment.

Possible options:

Analog input <N>. This calculation method is set when additional equipment is connected to the analog input of the terminal, the measurements of which are to be monitored

Relative counter <N>. This calculation method is set if the terminal transmits the measured value between consecutive events

Outputs pulses through input 1. This calculation method is established in case it is necessary to register pulses throughout the fuel delivery. These values will be displayed in the “Log” report. If it is necessary to convert pulses to liters, specify the Power Factor Correction for universal input (Vehicle profile / Profile).

* Total pulse output. In this method, the terminal transmits the amount of fuel dispensed in pulses. The start of output is registered by the first pulse received. The value of the sum of the pulses is transmitted at the end of the output. If it is necessary to convert pulses to liters, specify the Power Factor Correction for universal input (Vehicle profile / Profile).

* Total dispensed liters. This calculation method is set in case the dispensing source transmits the volume of fuel dispensed in liters. The value of the sum of the liters is transmitted at the end of the output.

LLS <N> This calculation method is set if it is necessary to use the data coming from the terminal in the form of LLS parameters to analyze the operation of additional equipment.

MODBUS <N> This calculation method is set if it is necessary to use the data coming from the terminal in the form of MODBUS parameters to analyze the operation of additional equipment.

Engine coolant temperature: SPN110 This calculation method is set if the data coming from the terminal in the form of SPN110 parameter is to be used to analyze the operation of the additional equipment.

Discrete input <N>. This calculation method is set if additional equipment is connected to the discrete input of the terminal, the switching on and off of which must be monitored. Omnicomm Online software will register the switching on of additional equipment when a discrete input switch-on event is received from the terminal

Temperature sensor. This calculation method is used when the data coming from the temperature sensor must be used to analyze the operation of additional equipment.

Navigation data tab

In the section “GPS speed, km/h”:

GPS speed

Possible options:

GPS data. This calculation method is set when the terminal transmits the speed value based on GPS data

Always 0 km/h. This calculation method is set when the terminal does not transmit GPS speed data. Omnicomm Online will display the value of vehicle speed as 0. With this method, you cannot set the odometer “from terminal (with drift)” in Omnicomm Online

Always 10 km/h. This calculation method is set when the terminal does not transmit GPS speed data. Omnicomm Online will display the value of vehicle speed as 10.

In the section “GPS direction, degree”:

GPS direction

Possible options:

Calculate by coordinates. This calculation method is set when the terminal transmits coordinates based on GPS data

GPS data. This method of calculation is set in case the terminal transmits the direction of vehicle movement according to GPS data

Always 0. This calculation method is set when the terminal does not send GPS directions. Omnicomm Online will not display movement direction

In the “Number of satellites” section:

Number of satellites

Possible options:

“GPS correctness” flag. This calculation method is set if the terminal transmits information about the correctness of GPS data. Omnicomm Online will register the correct GPS data when the corresponding event is received from the terminal

GPS data. This calculation method is set when the terminal sends data on the number of GPS satellites

Always 12. This calculation method is set in case the terminal does not send data on the number of satellites by GPS. Omnicomm Online will register the constant presence of 12 satellites

In the section “GPS altitude, m”:

GPS altitude

Possible options:

GPS data. This calculation method is set in case the terminal transmits the height value of a vehicle position according to GPS data

Always 0. This calculation method is set in case the terminal does not transmit altitude value according to GPS data and Omnicomm Online will not display the altitude value

In the “GPS data accuracy” section:

GPS data accurac

Possible options:

“GPS correctness” flag. This calculation method is set if the terminal transmits information about the correctness of GPS data. Omnicomm Online will register the correct GPS data when the corresponding event is received from the terminal

Number of visible GPS satellites. This method is set if the terminal does not transmit the GPS Correctness flag. Omnicomm Online will register correct GPS data if the number of visible satellites is more than 3

Always Correct data. This calculation method is set if the terminal does not transmit any of the above parameters. Omnicomm Online will capture correct data at all times

Fuel Level Sensor

In the “Fuel level sensor” section:

Fuel level sensor

In the “Calculation method” field, select the parameter, based on which Omnicomm Online will register the fuel level.

Possible variants of the method for calculating the fuel level:

Analog Input. This calculation method is set in case Omnicomm LLS analog fuel level sensor is connected to the analog input of the terminal

Fuel level analog input

“Measured value corresponding to the minimum level in the tank” - Enter the value (in Volts) from the analog sensor calibration table corresponding to the empty tank.

“Measured value corresponding to the maximum level in the tank” - Enter the value (in Volts) from the analog sensor calibration table corresponding to a full tank.

“Method for determining the fuel level sensor status” - Select the method for determining the fuel level sensor status.

Possible options:

“Counting”. This calculation method is set when the terminal transmits the status of the fuel level sensor.

“Always ready”

According to CAN SPN96 parameter. This calculation method is set if only one fuel level sensor is connected to the terminal and the data is transmitted from the CAN-bus, signal SPN96.

According to CAN SPN38 parameter. This calculation method is set when two fuel level sensors are connected to the terminal and data are transmitted from the CAN-bus, signal SPN96 for the first tank and signal SPN38 for the second one.

Fuel level modbus input

LLS <N>. This calculation method is set in case the terminal transmits data received from Omnicomm LLS digital fuel level sensor.

Custom CAN. This calculation method is set if the terminal transmits fuel level data via a configured CAN user parameter

User parameter. This calculation method is set if the terminal transmits fuel level data according to a configured User parameter.

MODBUS <N>. This calculation method is set in case the terminal transmits fuel level data via MODBUS protocol.

“Level is 0” - Select the sensor status when the fuel level is 0.

Possible options:

“Ready”. The “Ready” status is sent to Omnicomm Online when the fuel level sensor power supply is constant

“Not ready”. When the terminal power supply is switched off and, consequently, when the fuel level sensor power supply is switched off, the “Not ready” status is sent to Omnicomm Online.

“Level exceeds 4095” - Select the sensor status when the fuel level is 0.

Possible options:

“Ready”. When the fuel level exceeds 4095, the “Ready” status of the fuel level sensor is sent to Omnicomm Online

“Not ready”. When the fuel level exceeds 4095, the “Not ready” status of the fuel level sensor is sent to Omnicomm Online

“Do not send sensor data”. If the fuel level exceeds 4095, data from the fuel level sensor is not sent to Omnicomm Online

Possible variants of the method for calculating the fuel temperature:

Analog Input. This calculation method is set if an analog temperature sensor is connected to the analog input of the terminal

Temperature via fuel level sensor. This calculation method is set if the terminal transmits fuel temperature data based on the fuel level sensor readings

Temperature sensor. This calculation method is set if the terminal transmits data from a connected temperature sensor

Always 20 degrees Celsius. This calculation method is the default value or is set if the terminal does not transmit fuel temperature data to Omnicomm Online

CAN Data

In the “CAN data “ section:

CAN data 1 tab CAN data 2 tab  CAN data 3 tab

In the “Calculation method” field select the parameter, based on which Omnicomm Online software will register the CAN parameter.

CAN parameters and possible calculation methods:

CAN SPN38 parameter. The terminal transmits the fuel level in tank 2, SPN38 signal

CAN SPN70 parameter. The terminal transmits the parking brake status from the CAN-bus, SPN70 signal

CAN SPN91 parameter. The terminal transmits the accelerator pedal position from the CAN-bus, SPN91 signal

CAN SPN92 parameter. The terminal transmits the engine load status from the CAN-bus, SPN92 signal

CAN SPN96 parameter. The terminal transmits the fuel level in tank 2, SPN96 signal

CAN SPN100 parameter. The terminal transmits the engine oil pressure value from the CAN-bus, SPN100 signal

CAN SPN110 parameter. The terminal transmits the coolant temperature value from the CAN-bus, SPN110 signal

CAN SPN174 parameter. The terminal transmits the fuel temperature value from the CAN-bus, SPN174 signal

CAN SPN175 parameter. The terminal transmits the engine oil temperature value from the CAN-bus, SPN175 signal

CAN SPN182 parameter. The terminal transmits the daily fuel consumption value from the CAN-bus, SPN182 signal

CAN SPN184 parameter. The terminal transmits the instantaneous economy event from the CAN-bus, signal SPN184

CAN SPN190 parameter. The terminal transmits the engine speed value from the CAN-bus, SPN190 signal

CAN SPN244 parameter. The terminal transmits the daily mileage value from the CAN-bus, SPN244 signal.

CAN SPN245 parameter. The terminal transmits the total mileage value from the CAN-bus, SPN245 signal

CAN SPN247 parameter. The terminal transmits the value of the total running time of the motor from the CAN-bus, SPN247 signal.

CAN SPN250 parameter. The terminal transmits the value of the total fuel consumption for the entire time of operation of the vehicle engine from the CAN-bus, SPN250 signal

CAN SPN521 parameter. The terminal transmits the service brake pedal position information from the CAN-bus, SPN521 signal

CAN SPN522 parameter. The terminal transmits clutch pedal position information from the CAN-bus, SPN522 signal

CAN SPN527 parameter. The terminal transmits the cruise control status from the CAN-bus, SPN527 signal

CAN SPN597 parameter. The terminal transmits the normal brake pedal status information from the CAN-bus, SPN597 signal.

CAN SPN598 parameter. The terminal transmits the clutch pedal status information from the CAN-bus, SPN598 signal

CAN SPN914 parameter. The terminal transmits the remaining mileage to the next maintenance from the CAN-bus, SPN914 signal.

CAN SPN916 parameter. The terminal transmits the remaining number of engine hours until the next maintenance from the CAN-bus, SPN916 signal.

CAN SPN917 parameter. The terminal transmits the total mileage data from the CAN-bus, SPN916 signal

CAN SPN1624 parameter. The terminal transmits the value of the instantaneous speed of a vehicle from the CAN-bus, SPN1624 signal

CAN SPN1821 parameter. The terminal transmits information about the status of a vehicle doors from the CAN-bus, SPN1821 signal

CAN SPN1856 parameter. The terminal transmits information about the status of vehicle seat belts from the CAN-bus, SPN1856 signal

CAN SPN5054 parameter. The terminal transmits the total fuel consumption from the CAN-bus, SPN1856 signal

For each of the given CAN parameters, it is possible to set the calculation method in the form of data received via MODBUS protocol or custom CAN parameters.

MODBUS User Parameter Data

Use of MODBUS user parameters is available for the following terminals: Omnicomm, Arnavi 3/4, Arnavi Integral, Arnavi Integral 2, Galileosky 7.0. Correspondences of terminal parameters to parameters in Omnicomm Online are given on the link.

To view raw and converted values of MODBUS user parameters, click the “Monitoring” tab (see View current values).

In the “MODBUS user parameter data” section for Omnicomm and third-party terminals:

MODBUS User Parameter Data

Specify the number of MODBUS user parameters. Possible values: Without calculation or from 1 to 70.

If the terminal has been added earlier, make sure that the values of parameters "ID", "Address", "Function", "Register" correspond to those set earlier in Omnicomm Configurator.

“ID” shows an automatically generated identification number.

“Parameter name” - Enter the name of the parameter to be displayed in Omnicomm Online reports.

“Address” (only for Omnicomm terminals) - Enter the address of the slave device. Possible values: 1 to 247.

“Function” (only for Omnicomm terminals) - Select the register type. Possible values: Coil, Discrete Input, Holding Registers, Input Registers.

“Register” (only for Omnicomm terminals) - Specify register address. Possible values: 0 to 65535.

“User parameter number” (for third-party terminals only) - number of the user parameter, which is displayed in the Monitoring tab.

“Byte and word order” - Select the order of bytes and words. Possible options: Direct word and byte order; Reverse word order, Reverse byte order, Reverse word and byte order.

“Type of value before conversion”. Possible values: long.

“Data type after conversion”. Possible values: integer, float, bin, s16, u16, s32, u32, u64, double.

“Minimum value” - Specify the minimum allowable value of the parameter. If the value of the parameter being processed is less than the specified value, the parameter will be ignored.

“Maximum value” - Specify the maximum allowable value of the parameter. If the value of the parameter being processed is greater than the specified value, the parameter will be ignored.

“Coefficient” - Enter the value by which you want to multiply the value of the processed parameter.

“Offset” - Enter the value to be added to the value of the parameter to be processed. A negative value is allowed.

“Number of decimal places” (only for value types after conversion: float or double) - Enter the number of decimal places of the converted value. Possible options: 0 to 9.

Once configured, the MODBUS user parameters are ready to be used as a data source for Fuel Level Sensor, CAN Parameters and RPM.

CAN User Parameter Data

Use of CAN user parameters is available for the following terminals: Omnicomm, ADM-100/50, ADM-300, ADM-600, ADM-700, Teltonika FM1100/1200/2200/5300/5500, Teltonika FM4100/4200, Teltonika Professional Codec 8, Teltonika Professional Codec 8 Ext, UMKa300, UMKa300 (Wialon Combine). Correspondences of terminal parameters to parameters in Omnicomm Online are given on the link.

To view raw and converted values of CAN user parameters, click the “Monitoring” tab (see View current values).

In the “CAN user parameter data” section for Omnicomm and third-party terminals:

CAN User Parameter Data

Specify the number of CAN user parameters. Possible values: Without calculation or from 1 to 70.

For Omnicomm terminals it is possible to select “Model of special equipment” as a template for CAN user parameter settings. Possible values:

• UMG with Chinese units

• Load by axle groups (spn409, 4073)

• GAZ Cummins ISF

• CAN Extender

• PTZ K4, K7

• TG series grader

• Indicators GEOSVIP SVS-30-M1 (spn524025, spn524024)

• Extended CAN parameter set

“Parameter name” - Enter the name of the parameter to be displayed in Omnicomm Online reports.

“SPN number” (only for Omnicomm terminals) is the SPN number of the parameter according to J1939 standard.

“User parameter number” (for third-party terminals only) - number of the user parameter, which is displayed in the Monitoring tab:

CAN User Parameter Monitoring

“Offset” - Enter the value to be added to the value of the parameter to be processed. A negative value is allowed.

“Length” is the length of the data.

“Value type before conversion” is the data type before conversion. Possible values: integer, array_integer, double, array_double, compareHalfBytes.

“Value type after conversion” is the data type after conversion. Possible values: integer, array_integer, double, array_double, string.

“Minimum value” - Specify the minimum allowable value of the parameter. If the value of the parameter being processed is less than the specified value, the parameter will be ignored.

“Maximum value” - Specify the maximum allowable value of the parameter. If the value of the parameter being processed is greater than the specified value, the parameter will be ignored.

“Coefficient” is the value by which you want to multiply the value of the processed parameter. If the value type after conversion is array, it applies to all values.

“Offset” - Enter the value to be added to the value of the parameter to be processed. A negative value is allowed.

“Number of decimal places” (only for value types after conversion: double or array_double) - Enter the number of decimal places of the converted value. Possible options: 0 to 9.

“Key” (only for value type after string conversion) is the value coming from the terminal.

“Value” (only for value type after string conversion) is the converted value to be displayed in Omnicomm Online reports.

CAN User Parameter Set

Once configured, the CAN user parameters are ready to be used as a data source for Fuel Level Sensor, CAN Parameters and RPM.

User Parameter Data

The use of user parameters is available for the following terminals: Galileosky 7.0, Galileosky Base Block, Navtelecom Flex, Montrans, XIRGO. Correspondences of terminal parameters to parameters in Omnicomm Online are given on the link.

To view raw and converted values of user parameters, go to the “Monitoring” tab (see View current values).

In the “User parameters” section:

“ID” shows an automatically generated identification number.

“Parameter name” - Enter the name of the parameter to be displayed in Omnicomm Online reports.

“User parameter number” (for third-party terminals only) - number of the user parameter, which is displayed in the Monitoring tab:

CAN User Parameter Monitoring

“Byte and word order” - Select the order of bytes and words. Possible options: Direct word and byte order; Reverse word order, Reverse byte order, Reverse word and byte order.

“Value type before conversion” is the data type before conversion. Possible values: signed_byte, unsigned_byte, signed_short, unsigned_short, float, signed_int, unsigned_int, double, long.

“Value type after conversion” is the data type after conversion. Possible values: integer, float, bin, s16, u16, s32, u32, u64, double.

“Minimum value” - Specify the minimum allowable value of the parameter. If the value of the parameter being processed is less than the specified value, the parameter will be ignored.

“Maximum value” - Specify the maximum allowable value of the parameter. If the value of the parameter being processed is greater than the specified value, the parameter will be ignored.

“Coefficient” is the value by which you want to multiply the value of the processed parameter. If the value type after conversion is array, it applies to all values.

“Offset” - Enter the value to be added to the value of the parameter to be processed. A negative value is allowed.

“Number of decimal places” (only for value types after conversion: double or array_double) - Enter the number of decimal places of the converted value. Possible options: 0 to 9.

Table of Correspondence of User, CAN and MODBUS Parameters of Terminals to Omnicomm Online Parameters

MODBUS user parameters:

Terminals Terminal parameter Description Omnicomm Parameter Name Displayed during Monitoring
Arnavi 3/4, Arnavi Integral, Arnavi Integral 2 120 - 129 MODBUS mbus CUSTOM_MODBUS_1 - CUSTOM_MODBUS_10 MODBUS user parameter №1 -MODBUS user parameter №10
160 - 169 MODBUS CUSTOM_MODBUS_11 - CUSTOM_MODBUS_20 MODBUS user parameter №11 - MODBUS user parameter №20
Galileosky 7.0 0-31 (0x0001 - 0x0020) Modbus tags with numbers 0-31 CUSTOM_MODBUS_0 - CUSTOM_MODBUS_31 MODBUS user parameter №0 - MODBUS user parameter №31
85-128 (0x0061 - 0x0080) Modbus tags with numbers 32-63 CUSTOM_MODBUS_32 - CUSTOM_MODBUS_63 MODBUS user parameter №32 - MODBUS user parameter №63

CAN user parameters:

Terminals Terminal parameter Description Omnicomm Parameter Name Displayed during Monitoring
ADM-100/50, ADM-300, ADM-600, ADM-700 CAN 0-9 - CAN0 - CAN63 CAN user parameter №0 - CAN user parameter №63
Teltonika FM1100/1200/2200/5300/5500, Teltonika FM4100/4200 CAN 0-9 - CAN0 - CAN63 CAN user parameter №0 - CAN user parameter №09
Teltonika Professional Codec 8, Teltonika Professional Codec 8 Ext CAN 0-24 - CAN0 - CAN24 CAN user parameter №0 - CAN user parameter №24
UMKa300, UMKa300 (Wialon Combine) can32 CAN. User filter 0 (Can32 in “History” tab) CAN32 CAN user parameter №32
can33 CAN. User filter 1 (Can33 in “History” tab) CAN33 CAN user parameter №33
can34 CAN. User filter 2 (Can34 in “History” tab) CAN34 CAN user parameter №34
can35 CAN. User filter 3 (Can35 in “History” tab) CAN35 CAN user parameter №35
can36 CAN. User filter 4 (Can36 in “History” tab) CAN36 CAN user parameter №36
can37 CAN. User filter 5 (Can37 in “History” tab) CAN37 CAN user parameter №37
can38 CAN. User filter 6 (Can38 in “History” tab) CAN38 CAN user parameter №38
can39 CAN. User filter 7 (Can39 in “History” tab) CAN39 CAN user parameter №39

User parameters:

Terminals Terminal parameter Description Omnicomm Parameter Name Displayed during Monitoring
Galileosky 7.0, Galileosky Base Block CAN8_0 - CAN8_30 - USER_PARAM_1S_0 - USER_PARAM_1S_30; USER_PARAM_1U_0 - USER_PARAM_1U_30 User parameter 1 byte (signed byte) №0 - User parameter 1 byte (signed byte) №30; User parameter 1 byte (unsigned byte) №0 - User parameter 1 byte (unsigned byte) №30
CAN16_0 - CAN16_14 - USER_PARAM_2S_0 - USER_PARAM_2S_14; USER_PARAM_2U_0 - USER_PARAM_2U_14 User parameter 2 bytes (signed short) №0 - User parameter 2 bytes (signed short) №14; User parameter 2 bytes (unsigned short) №0 - User parameter 2 bytes (unsigned short) №14
CAN32_0 - CAN32_14 - USER_PARAM_4S_0 - USER_PARAM_4S_14; USER_PARAM_4U_0 - USER_PARAM_4U_14 User parameter 4 bytes (signed int) №0 - User parameter 4 bytes (signed int) №14; User parameter 4 bytes (unsigned int) №0 - User parameter 4 bytes (unsigned int) №14
Navtelecom Flex Montrans 207 - 222 - USER_PARAM_1S_1 - USER_PARAM_1S_16, USER_PARAM_1U_1 - USER_PARAM_1U_16 User parameter 1 byte (signed byte) №1 - User parameter 1 byte (signed byte) №16, User parameter 1 byte (unsigned byte) №1 - User parameter 1 byte (unsigned byte) №16
223 - 237 - USER_PARAM_2S_1 - USER_PARAM_2S_16, USER_PARAM_2U_1 - USER_PARAM_2U_16 User parameter 2 bytes (signed short) №1 - User parameter 2 bytes (signed short) №15, User parameter 2 bytes (unsigned short) №1 - User parameter 2 bytes (unsigned short) №15
238 - 252 - USER_PARAM_4F_1 - USER_PARAM_4F_16, USER_PARAM_4S_1 - USER_PARAM_4S_16, USER_PARAM_4U_1 - USER_PARAM_4U_16 User parameter 4 bytes (float) №1 - User parameter 4 bytes (float) №15, User parameter 4 bytes (signed int) №1 - User parameter 4 bytes (signed int) №15, User parameter 4 bytes (unsigned int) №1 - User parameter 4 bytes (unsigned int) №15
253 - 255 - USER_PARAM_8D_1 - USER_PARAM_8D_3, USER_PARAM_8S_1 - USER_PARAM_8S_3 User parameter 8 byte (double) №1 - User parameter 8 byte (double) №3, User parameter 8 byte (long) №1 - User parameter 8 byte (long) №3
XIRGO SENSOR_U8_0 (0x200B) - SENSOR_U8_21 (0x2020) - USER_PARAM_1U_0 - USER_PARAM_1U_21 User parameter 1 byte (unsigned byte) №0 - User parameter 1 byte (unsigned byte) №21
SENSOR_S8_0 (0x6000) - SENSOR_S8_9 (0x6009) - USER_PARAM_1S_0 - USER_PARAM_1S_9 User parameter 1 byte (signed byte) №0 - User parameter 1 byte (signed byte) №9
SENSOR_U16_0 (0x300D) - SENSOR_U16_15 (0x301C) - USER_PARAM_2U_0 - USER_PARAM_2U_15 User parameter 2 bytes (unsigned short) №0 - User parameter 2 bytes (unsigned short) №15
SENSOR_S16_0 (0x7004) - SENSOR_S16_9 (0x700D) - USER_PARAM_2S_0 - USER_PARAM_2S_9 User parameter 2 bytes (signed short) №0 - User parameter 2 bytes (signed short) №9
SENSOR_F32_0 (0xA003) - SENSOR_F32_19 (0xA016) - USER_PARAM_4F_0 - USER_PARAM_4F_19 User parameter 4 bytes (float) №0 - User parameter 4 bytes (float) №19
SENSOR_U32_0 (0x4005) - SENSOR_U32_19 (0x4018) - USER_PARAM_4U_0 - USER_PARAM_4U_19 User parameter 4 bytes (unsigned int) №0 - User parameter 4 bytes (unsigned int) №19
SENSOR_S32_0 (0x8000) - SENSOR_S32_9(0x8009) - USER_PARAM_4S_0 - USER_PARAM_4S_9 User parameter 4 bytes (signed int) №0 - User parameter 4 bytes (signed int) №9

View Current Values

In vehicle profile settings, go to the “Monitoring” tab. A window opens that displays the current values of the terminal parameters.

A window opens that displays the current parameter values:

“Parameter measurement time in the last message” (DD/MM/YYYYY hh:mm:ss) is the time of value/event registration from the last received message.

“Last message received” (DD/MM/YYYYYY hh:mm:ss) is the time when the last message was received.

Monitoring

The “Monitoring” section displays parameters depending on the type of third-party terminal.

“Measured” is the time of the last registration of the parameter value by the third-party terminal.

“Received” is the time when the parameter value was last received.