Template:FMB Accelerometer Features settings

From Wiki Knowledge Base | Teltonika GPS

Accelerometer Calibration

Calibration algorithm is used to recalculate accelerometer axes to represent vehicle‘s axes (see Picture below). Vehicles axes are as follows:
1. X is front.
2. Y is left.
3. Z is down.

Vehicle Axis

Once vehicle‘s axes are calculated, device is considered calibrated.

Note: moving forward along any axis will generate negative values. This means acceleration will generate -X values, accordingly breaking will generate X values. Same goes for other axes.

Configurable parameters can be found at System Settings Accelerometer Auto Calibration

Commands that can be used during calibration:

Command Response Description
auto_calibrate:set Yes Request auto calibration task start
auto_calibrate:get Yes Request calibration info (time, ground vector, side vector)
auto_calibrate:clear Yes Request calibration clear from flash and stop calibration task
auto_calibrate:status Yes Request calibration status and calibration task status

Auto calibration before firmware version 03.25.07.Rev.00.

Accelerometer auto calibration functionality has one purpose - determine how FMB device is mounted in a vehicle. After the calibration process eco driving functionality becomes active and calibration data will be used to determine harsh acceleration, braking and cornering events.
There are two conditions when auto calibration takes place:

  • If on device startup no calibration was detected;
  • If the device receives an SMS/GPRS message with auto_calibrate:set text.

After functionality has started FMB device periodically checks current appliance GNSS, ignition and movement source parameters and if the conditions match:

  • position fix got;
  • GNSS speed is zero;
  • ignition is ON;
  • first calibration vector was not saved yet;

Then first vector is taken. Saved vector will be considered as ground vector and it will be used at further calibration calculations.
Note: When FMB device saves first ground vector vehicle must be parked on flat ground. Crooked vector may have an impact on further calculations.
Afterwards first ground vector was taken, device analyses conditions:

  • position fix got;
  • GNSS speed is at least 20 km/h;
  • ignition is ON;
  • second vector was not saved yet;
  • vehicle driving in the same direction with 5⁰ tolerance;
  • vehicle speed increase by 7km/h within 1 second.

For next vector. Second vector will be taken if all conditions match. Immediately after second vector is received, it will be multiplied by first (ground) vector, the result of these vectors is vector multiplication cross product which is the right side of a car. By using same vector multiplication method, device front, left side will be calculated. At this point calibration is successfully ended as indication device sends an SMS/GPRS message with Device is calibrated, to recalibrate send:auto_calibrate:set.
Note: SMS/GPRS message will be sent only if auto calibration functionality was triggered by SMS/GPRS message.
For user convenience in case auto calibration functionality fails then notification message will be sent. For exact messages, check algorithm section.
Note: SMS/GPRS message will be sent only if auto calibration functionality was triggered by SMS/GPRS message.
To get current calibration status auto_calibrate:get SMS/GPRS command must be sent to the device. If device is calibrated it will respond with Calibration state: calibrated or otherwise Calibration state: not calibrated. Also this command returns saved Ground and Side vectors.
After every TRIP START event, device starts shadow calibration. This type of calibration is running in parallel with already saved vectors (this means that vectors does not reset until shadow calibration have both new vectors). After shadow calibration is done, device updates the vector values to the new ones. There are two conditions when shadow calibration does not run at TRIP start event:

  • Normal calibration is still running.
  • Shadow calibration is still running from previous TRIP event.

To take ground vector these conditions should be met:

  • Ignition is ON
  • Device got GPS FIX
  • Vehicle speed = 0km/h

Device will check these conditions every 1sec until they will pass.
To take side vector these conditions should be met:

  • Vehicle speed >= 20km/h
  • Device got GPS FIX
  • Ignition is ON
  • Device angle does not change more than 5 degrees in past 1 sec
  • Speed need to increase by 7km/h in 1s period.

Device will check these conditions every 1 sec until they will pass.


Auto calibration rework and improvements from firmware version 03.25.07.Rev.00.

  • Exponential moving average (EMI) Filter added.
Auto-calibration Improvement

Auto calibration task is launched on one of these conditions (assume calibration is enabled in configuration):
1. Every time device turns on, it checks whether it was previously calibrated and has calibration stored in flash. If device has no calibration in flash, auto calibration task is started.
2. Device calibration was previously disabled by configuration and now is enabled.
3. SMS “auto_calibrate:set” is received. Note: SMS response is sent after calibration has been acquired.
This SMS triggers an SMS response to be sent. Response is sent when calibration is acquired. When 1 hour passes without successful calibration, failed SMS response is sent.
4. Calibrated device’s mean axes of set interval differ more than set amount from desired (0,0,1) calibration is considered inaccurate. Calibration is deleted from flash and auto calibration task started.
After auto calibration task has been started, it will go on indefinitely until satisfactory calibration is acquired.

Data Required

Auto calibration need to fill two buffers to calibrate device:
1. All accelerometer data – buffer which collects all data from accelerometer at 10Hz frequency. To fill this buffer set seconds of data samples are needed. When buffer is full, oldest data is dumped and new data is placed into the buffer.
2. Straight accelerometer data – buffer which collect straight accelerations data from accelerometer at 10Hz frequency. To fill this buffer set seconds of data samples (set times Hz samples) are needed. When buffer is full, oldest data is dumped and new data is placed into the buffer. Algorithm rules to acquire these samples:
2.1. GPS fix is present.
2.2. Ignition is on.
2.3. GPS speed is more than 5 km/h.
2.4. GPS heading is equal to last GPS heading (+/-1 degree) at GPS sample rate 1Hz.
2.5. GPS speed more then 5 km/h from last sample (accelerating).
Once both buffers are full, auto calibration is attempted. If calibrated values pass calibration quality threshold, calculated calibration is written to flash as current calibration – device is calibrated.
Note: If GPS fix is lost or ignition is turned off, buffers’ data is dumped and must be gathered from 0 again.


Re-Calibration

When calibration is present, device checks for re-calibration every 60s indefinitely. Re-calibration requires fix and ignition to run also re-calibration is turned off when vehicle is stopped for more than 15s until conditions are satisfied again. When calibrated device’s mean axes of set interval(calibrated accelerometer data) differ more than set amount from desired (0,0,1) (perfect vehicle’s axes) calibration is considered inaccurate, or device’s position has changed and re-calibration is needed. Calibration is cleared from flash and auto calibration task is started.

Note: turning device around calibrated Z axis will not trigger re-calibration, after turning device around Z axis manual re-calibration is advised. After calibration if quality value is less than 0.80, calibration update functionality is run. Calibration update constantly tries calibrating device in background until 0.80 quality is reached. Calibration update functionality does not change calibration if calculated new calibration quality is less than 0.80.

Excessive Idling

Fmb120 excessive idling.png

When vehicle stops for a specific amount of time the scenario is activated, a record will be generated and digital output status will be changed to 1 when configured. You can configure the time it takes to turn on this scenario (Time to Stopped). Scenario is activated until the vehicle starts moving (movement is detected only by the accelerometer) and keeps moving for an amount of time that is configured. You can configure the time it takes to turn off this scenario (Time to Moving)
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Unplug Detection

Fmb120 unplug.png

An event will be generated when FMB1YX is unplugged from external power or plugged back in again.

Scenario settings

  • Disable - disable scenario.
  • Low Priority - when low priority event is triggered, device makes additional record with indication of event cause.
  • High Priority - module makes additional record with High priority flag and sends event packet immediately to the server by

GPRS.

  • Panic Priority - triggers same actions as High priority, but if GPRS fails, it sends AVL packet using SMS mode if SMS is enabled in SMS Data Sending settings.

Eventual Records

  • Disable - scenario status value is sent in each AVL record.
  • Enable - scenario status value is sent only in eventual AVL records.

Unplug Detection mode

  • Simple - unplug detection according to external voltage only. Is used in cars where power voltage is not dependent on ignition (recommended).
  • Advanced - unplug detection according to external votage and accelerometer. Is used in cars where power voltage is disconnected when ignition is switched off.

Towing Detection

Fmb120 towing.png

Towing Detection feature helps to inform the driver about unexpected car movement when it was parked. FMB1YX generates an event when car is being towed or lifted, for example, in a case of vehicle evacuation. FMB1YX activates towing function when following conditions are met:

  1. Ignition (configured Ignition Source) is OFF.
  2. Activation Timeout is reached.

When towing function is engaged FMB1YX monitors accelerometer data. If acceleration Threshold or Angle reach configured values for a configured Duration, and Ignition is still OFF for a period of time that is longer than Event Timeout, then an event is generated. When configured, Make Call To and Send SMS To functions make a call or send an SMS to a predefined phone number. Towing function will be reactivated after FMB1YX detects a change of Ignition state from ON to OFF or if the confgured Activation Timeout is reached again.






Crash Detection

Crash Detection cfg.PNG

If Crash Detection is enabled, it monitors acceleration on each axis which helps to detect an accident. Threshold and Duration values are set depending on the impact magnitude that is required to be detected. FMT100 can detect events ranging between a slight tapping on the device and a severe accident.
If Crash Trace is disabled only one eventual crash record will be generated when Duration (ms) and Threshold (mg) values are exceeded.

If Crash Trace is enabled, FMT100 will collect crash trace data with frequency defined by Trace ODR (Hz) parameter. Acceleration, GNSS and IO data monitoring duration during the crash event is defined by these parameters:

  • Accel duration (s). Acceleration data duration can be set for up to 15 seconds before crash event and 15 seconds after;
  • GNSS duration (s). GNSS data duration can be set for up to 30 seconds before crash event and 30 seconds after.
  • IO duration (s). IO data duration can be set for up to 30 seconds before crash event and 30 seconds after.

There are three configurable Crash Trace modes:
Trace Full

  • Data tracked: all GNSS and acceleration data

Trace Full with IO's

  • Data tracked: all GNSS and acceleration data with IO's, configured in I/O settings as "Crash" parameter (see picture below)
Crash event input.png

Trace Changes

  • Data tracked: GNSS and acceleration data, when acceleration values are changed by more then 50mG

NOTE: with Crash Trace mode enabled, it is recommended to use Codec 8 Extended Data Protocol. This helps to optimize crash trace data sending from device to server.

Codec 8 Extended setting.png

Each record will have accurate timestamps in milliseconds.


Fmb120 crash trace.png

Crash Data Visualisation

With Teltonika CrashDataVisualizer tool you can analyze crash trace data visually: determine impact to vehicle direction, view crash trace on the map, also see the change of mG and speed values during crash time period. CrashDataVisualizer is dedicated to work with TAVL application, it means that only crash trace log files exported from TAVL is compatible. To have ability to export crash trace log files, device must be configured to send data by Codec8E.

To start using CrashDataVisualizer
Download and install TAVL (version 4.15.0.1 or later) + CrashDataVisualizer applications from here:
Link: https://teltonika.lt/client
Login: CrashDataVisualizer
Password: crasHdaTa789

To get crash data

Login to TAVL application (please contact your Sales manager for TAVL login information).

Crash data steps.png

In TAVL application:
1. Go to Events
2. Set the date of event
3. Select the object you want to analyze
4. Press "Crashes" button







Crash event list window will show up. Press Download icon and save crash event file (.JSON).

JSON download.png


Viewing crash data in application
Open CrashDataVisualizer application. Drag and Drop or Browse crash data file (.JSON).

Crash Data Visualizer start screen.png

Use the Visualizer.

Crash Data Visualizer main.png