Difference between revisions of "Template:FMB640 Features settings"

From Wiki Knowledge Base | Teltonika GPS
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     </tr>
 
     </tr>
 
<tr>
 
<tr>
         <td style="width: 8%; text-align:left;">Output Control</td>
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         <td style="width: 8%; text-align:left;">Scenario Settings</td>
         <td style="width: 8%; text-align:left">Enable/Disable Green driving functionality and Activate/Deactivate DOUT.</td>
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         <td style="width: 8%; text-align:left">Enable/Disable Green driving functionality</td>
 
     </tr>
 
     </tr>
 
<tr>
 
<tr>
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<tr>
 
<tr>
 
         <td style="width: 8%; text-align:left">Source</td>
 
         <td style="width: 8%; text-align:left">Source</td>
         <td style="width: 8%; text-align:left">Which source data will be collected from:
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         <td style="width: 8%; text-align:left">Which source data will be collected from.</td>
* '''GNSS''' - When selected source (11007) is GPS device calculates harsh driving values from GPS data at 1 Hz frequency. This means green driving time accuracy is 1s (no ms). Acceleration is calculated every 1 second, based on speed difference between GPS samples. Vehicle speed must be equal or greater than 10 km/h for acceleration/braking and equal or greater than 30 km/h for cornering.<br>
 
* '''Accelerometer''' – Accelerometer data will be used to detect harsh driving. (This algorithm is from FMB device family). Accelerometer calibration needs to be performed with ''“auto_calibrate:set”'' command. <br>
 
*  '''GNSS Algorithm A1''' – GPS data will be used to detect harsh driving. (This algorithm is used in FMA11 devices). The main difference from FM53 is cornering detection which uses advanced math to more precisely calculate harsh cornering value across different vehicle speeds. <br>
 
* '''Accelerometer Algorithm A1''' - Accelerometer data will be used to detect harsh driving. (This algorithm is used in FMA11 device family) <br>
 
<b>Note:</b> To use ''“Accelerometer Algorithm A1”'' option user need to install device as in Figure 1.
 
</td>
 
 
     </tr>
 
     </tr>
 
</table>
 
</table>
{{{pic_accelerometerposition|[[Image:FMB640accelerometerposition.png|300px|right]]}}} {{{model|}}} Device accelerometer position. (With positive Z axis pointing to Ground and antennas face forward in the vehicle). Before operation with the vehicle on level ground user must send “setacc” SMS.
+
 
 +
0 – GNSS -  GPS Data will be used to detect harsh driving.  (This algorithm was used in FM53, FM63 devices) <br>
 +
1 – Accelerometer – Accelerometer data will be used to detect harsh driving. (This algorithm is from FMB device family). Accelerometer calibration needs to be performed with “auto_calibrate:set” command. <br>
 +
2 – GNSS Algorithm A1 – GPS data will be used to detect harsh driving. (This algorithm is used in FMA11 devices). Main difference from FM53 is cornering detection which uses advanced math to more precisely calculate harsh cornering value across different vehicle speeds. <br>
 +
3 – Accelerometer Algorithm A1 - Accelerometer data will be used to detect harsh driving. (This algorithm is used in FMA11 device family) <br>
 +
<b>Note:</b> To use “Accelerometer Algorithm A1” option user need to install device as in Figure 1. {{{pic_accelerometerposition|[[Image:FMB640accelerometerposition.png|300px|right]]}}} FM64 Devcie accelerometer position. (With positive Z axis pointing to Ground and antennas face forward in vehicle). Before operation with vehicle on level ground user must send “setacc” SMS.
 +
 
 +
 
 +
 
  
 
===Auto calibration===
 
===Auto calibration===
 
----
 
----
The auto-calibration process is the following:
+
The auto-calibration process is following:
 
# The vehicle is stopped.
 
# The vehicle is stopped.
 
# There is a straight road ahead.
 
# There is a straight road ahead.
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When vehicle speed exceeds configured maximum speed value the scenario is activated, an event record is generated{{{text_dout| and digital output status is changed to 1 when configured}}}.<br/>Scenario is active until detected speed decreases below the set parameter value.<br/>{{{over_speeding_dout|info}}}
 
When vehicle speed exceeds configured maximum speed value the scenario is activated, an event record is generated{{{text_dout| and digital output status is changed to 1 when configured}}}.<br/>Scenario is active until detected speed decreases below the set parameter value.<br/>{{{over_speeding_dout|info}}}
 
DOUT1, DOUT2 or DOUT3 can be activated for a period of time to warn the driver. Output on-time is configured separately for each feature case. For more information please refer to [[DOUT_controls|DOUT controls]].
 
DOUT1, DOUT2 or DOUT3 can be activated for a period of time to warn the driver. Output on-time is configured separately for each feature case. For more information please refer to [[DOUT_controls|DOUT controls]].
<br/><br/><br/><br/><br/>
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<br/><br/><br/><br/><br/><br/><br/><br/><br/><br/>
  
 
==Jamming==
 
==Jamming==
  
{{{pic_jamming|[[Image:Jamming.JPG|300px|right]]}}}
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{{{pic_jamming|[[Image:Jamming.JPG |300px|right]]}}}
  
 
When jamming is detected the scenario is activated, an event record is generated{{{text_dout| and digital output status is changed to 1 when configured}}} once ''Jamming'' timeout runs out. If jamming ends during timeout countdown no event will be generated{{{text_dout| and output will not be controlled}}}.<br/>''Eventual Records'' parameter can be configured: when it is disabled scenario status value will appear in each AVL record, otherwise it will be appended only to eventual records.
 
When jamming is detected the scenario is activated, an event record is generated{{{text_dout| and digital output status is changed to 1 when configured}}} once ''Jamming'' timeout runs out. If jamming ends during timeout countdown no event will be generated{{{text_dout| and output will not be controlled}}}.<br/>''Eventual Records'' parameter can be configured: when it is disabled scenario status value will appear in each AVL record, otherwise it will be appended only to eventual records.
<br/><br/><br/><br/><br/><br/><br/><br/><br/><br/>
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<br/><br/><br/><br/><br/><br/><br/><br/><br/>
 
 
==DOUT Control via Call==
 
 
 
{{{pic_DOUTCONTROL|[[Image:FMB640 DOUT.png|300px|right]]}}}
 
 
 
Activates DOUT on incoming call. <br/>
 
The scenario is activated and digital output is ON when a call is received from a number which is in authorized numbers list.
 
Call control functionality: <br/>
 
* When FMB64 is configured to control DOUT1/DOUT2/DOUT3/DOUT4 device waits for an incoming call from the configured secure number. If the call is received FMB64 turns on DOUT1/DOUT2/ DOUT3/DOUT4 for user-defined Duration timeout (s). If the Duration timeout set to „0“(s), DOUT1/DOUT2/ DOUT3/DOUT4 will be OFF. <br/>
 
* DOUT1/ DOUT2/DOUT3/DOUT4 can be turned off by Duration timeout (s) or by digital input 1, digital input 2, digital input 3, or digital input 4 (DOUT deactivation settings). <br/>
 
* DOUT1/DOUT2/DOUT3/DOUT4 can be turned off before Duration timeout (s) by selected DIN (DOUT deactivation settings).<br/>
 
* DOUT1/DOUT2/DOUT3/DOUT4 always will be ON, if DOUT deactivation set to DIN1 for example, but DIN1 will be never turned ON or set Duration timeout to Max value (2147483647) it is about 68 years.
 
<br/><br/><br/>
 
  
 
==Authorized driving/Immobilizer==
 
==Authorized driving/Immobilizer==
  
{{{pic_immobilizer|[[Image:FMB640_authorizedD.png|300px|right]]}}}
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{{{pic_jamming|[[Image:FMB640_authorizedD.png|250px|right]]}}}
  
*If DOUT Control is disabled, the scenario will only generate events without digital output activation. If DOUT Control is enabled DOUT1/DOUT2 turns ON if ignition turns ON (Ignition Source is configured to 1).  
+
*If DOUT Control is disabled, scenario will only generate events without digital output activation. If DOUT Control is enabled DOUT1/DOUT2 turns ON if ignition turns ON (Ignition Source is configured to 1).  
 
* After any iButton ID is attached, DOUT1/DOUT2/DOUT3 turns OFF.  
 
* After any iButton ID is attached, DOUT1/DOUT2/DOUT3 turns OFF.  
* After iButton identification configured Ignition Source can be turned OFF (Ignition Source is configured to 0) for no longer than 30 seconds, otherwise immobilizer must be repeated.
+
* After iButton identification configured Ignition Source can be turned OFF (Ignition Source is configured to 0) for no longer than 30 seconds, otherwise immobilizer must be repeated. If * iButton List Check parameter is enabled, authorization will be successful only if the attached iButton is specified in iButton list. <br/>
* If iButton List Check parameter is enabled, the authorization will be successful only if the attached iButton is specified in the iButton list. <br/>
+
* Ignition off timeout parameter is used to set the duration after which authorization is activated, when ignition is turned off. <br/>
* Ignition off timeout parameter is used to set the duration after which authorization is activated when the ignition is turned off. <br/>
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* Authorization off timeout parameter is used to set the duration how long the user has time to authorize after switching ignition on. <br/>
* Authorization off timeout parameter is used to set the duration of how long the user has time to authorize after switching the ignition ON. <br/>
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* iButton list gives ability to use vehicle for 1000 specific iButton owners (specified in iButton list). Selected DOUT is controlled by scenario for user needs, to manage buzzer, LED etc.
* iButton list gives the ability to use the vehicle for 1000 specific iButton owners (specified in iButton list). Selected DOUT is controlled by scenario for user needs, to manage buzzer, LED, etc.
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<br/><br/><br/><br/><br/><br/><br/><br/><br/><br/>
<!--
 
* Buzzer duration
 
New parameter implemented - Buzzer duration. Measured in minutes. <br>
 
After the ignition is turned ON, the configured immobilizer output control parameter turns ON (unless it's Disabled or configured as no DOUT control). DOUT can be deactivated by the iButton read from iButton1 or iButton2 readers or if the Buzzer duration parameter timeout occurs. Usage example: Driver or passenger enters the vehicle, turns the ignition ON (DIN1=1) and buzzer (DOUT2) is also turned ON. The buzzer will be ON as long as Buzzer Duration timeout occurs or until iButton will be successfully read.
 
* Passenger iButton
 
New IO element Passenger iButton added. <br>
 
New parameter Passenger iButton source implemented. Min: none (0); Max: DIN4 (4); Default: none (0). Parameter configuration id: 11714.
 
In order to distinguish driver and passenger iButtons while both iButton readers are on the same 1-wire line, special logic applied: if there is no voltage on configured Passenger iButton source DINX then it is taken that Passenger iButton is attached. The value of reading Passenger iButton ID is saved to Passenger iButton IO element. This functionality works with an immobilizer scenario only.
 
-->
 
{{{txt_br|<br/><br/><br/><br/><br/><br/><br/><br/><br/><br/><br/>}}}
 
  
 
==iButton Read Notification==
 
==iButton Read Notification==
  
[[Image:IButton_Read_Notification .png|{{{general|size}}}||right]]
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{{{pic_jamming|[[Image:I button.JPG|300px|right]]}}}
Output control parameter lets the user choose which DOUT will iButton blink. After connecting iButton, DOUT will blink for a period of time, which is configured in DOUT ON Duration parameter. The iButton List checking parameter configures whether the device reads the iButton ID from iButton list or not. For example if configured as Enabled, device will not blink DOUT unless the iButton is in the iButton list.
 
If Depend on Ignition parameter is enabled, then Output will be triggered only if ignition is off (in addition to being in a list if iButton List Checking is also enabled).
 
Output control examples when iButton is detected (if None is selected in Output Control – all of the following steps will be skipped):
 
  
*If both iButton List Checking and Depend on Ignition are disabled – Output is triggered.
+
* If scenario is enabled, when iButton is attached and is successfully read, configured DOUT goes ON for configurable amount of time (min: 0.00 s; max: 5.00 s; default: 0.2 s). <br>
*If iButton List Checking is enabled and Depend on Ignition is disabled – Output is triggered only if iButton is in the list.
+
* If DOUT ON and DOUT OFF durations are both set to 0, DOUT will be ON until iButton will be removed from the reader. <br>
*If iButton List Checking is disabled but Depend on Ignition is enabled – Output is triggered only if ignition is off.
+
* If Immobilizer scenario is enabled and iButton’s indication scenario is enabled and the same DOUT controls are chosen then in case iButton is attached DOUT is not affected.  
*If both iButton List Checking and Depend on Ignition are enabled – Output will trigger if iButton is in the list and ignition is off.
+
IButton’s event generation works as a standard IO event generation
 +
<br/><br/><br/><br/><br/><br/><br/>
  
iButton Read Notification parameters:
+
==DOUT Control via Call==
 +
Activates DOUT on incoming call  <br/>
 +
Scenario is activated and digital output is ON, when call is received from number which is in authorized numbers list.
 +
Call control functionality: <br/>
 +
* When FMB64 is configured to control DOUT1/DOUT2/DOUT3/DOUT4 device waits incoming call from configured secure number. If call is received FMB64 turns on DOUT1/DOUT2/ DOUT3/DOUT4 for user defined Duration timeout (s). If Duration timeout set to „0“(s), DOUT1/DOUT2/ DOUT3/DOUT4 will be OFF. <br/>
 +
* DOUT1/ DOUT2/DOUT3/DOUT4 can be turned off by Duration timeout (s) or by digital input 1, digital input 2, digital input 3, or digital input 4 (DOUT deactivation settings). <br/>
 +
* DOUT1/DOUT2/DOUT3/DOUT4 can be turned off before Duration timeout (s) by selected DIN (DOUT deactivation settings).<br/>
 +
* DOUT1/DOUT2/DOUT3/DOUT4 always will be ON, if DOUT deactivation set to DIN1 for example, but DIN1 will be never turned ON or set Duration timeout to Max value (2147483647) it is about 68 years.
  
*Output control – available scenario settings for module Digital output activation/deactivation
+
{{{pic_DOUTCONTROL|[[Image:FMB640_DOUT_control_via_CALL.png|300px|right]]}}}
*DOUT ON duration – a value in seconds, for how long {{{text_dout|DOUT1/DOUT2/DOUT3}}} should be active.
+
 
*iButton List checking - parameter configures that device reads the iButton ID from list or not.
+
<br/><br/><br/><br/><br/><br/><br/><br/><br/><br/><br/><br/><br/>
*Depend on Ignition - Output will be triggered only if ignition is off
 
<br/><br/>
 
  
 
==Short burst data settings==
 
==Short burst data settings==
  
 +
{{{short_burst|[[Image:Short_burst.JPG|300px|right]]}}}
  
{{{model|}}} supports Iridium devices which can send short burst data (SBD) to the server. This means that some data can be sent from FM device to the server through satellites.
+
FMB640  supports Iridium devices which can send short burst data (SBD) to server. This means that some data can be sent from FM device to server through satellites.  
 
 
In order to properly connect the Iridium device to {{{device|}}}, Iridium has to be connected to the device via RS-232 - COM1 or COM2 (with RJ-45 connector, where 4 pin is GND, 5 pin is RS232 Rx and 6 PIN is RS232 Tx). Additionally '''Pin No. 6''' - power control (reference in the image below) must be connected to one of the {{{model|}}} DOUTs (1/2/3/4), in order to allow the device to power ON/OFF Iridium device on demand. More information about SBD can be found here [[{{{model|}}} _Short_Burst_Data|Short Burst Data]].
 
 
 
Iridium Edge pinout and RS232 COM 1/2 connection:
 
 
 
[[File:Iridium Edge pinout.png|left]]
 
[[File:FMX640 and RS232 illustration v1.2.png|right|450x201px]]
 
<br></br><br></br><br></br><br></br><br></br><br></br>
 
[[File:SBD settings.gif|right]]
 
When the Iridium edge device is connected '''''Power control DOUT''''' configures DOUT pin which can control Iridium Edge ON/OFF pin. Configure if DOUT pin is connected. Respective power control DOUT to which the Iridium device's ''PIN6'' is connected must be selected.
 
 
 
 
 
'''''Save/Send period''''' configures how long will FMB device wait after losing the signal to generate SBD packet. If the signal is not recovered, it will send it indefinitely (or till the SBD Upload limit is reached, if such is set).
 
  
'''''SBD Upload Limit''''' is configurable and resets every month. This option can ensure that no additional data is used so that no unexpected costs are experienced by the customer. The default value is 8000 (for 8KB plan). This option can be disabled by setting the Upload limit to 0. The monthly data usage counter can be reset by using the SMS/GPRS command - '''sbdlimitsreset'''.
+
FMB640 will enable satellite mode only if device can not send data via GPRS. Satellite mode has his own Save/Send period. If timeout is set to 0 no periodic records will be made. It is not recommended to save records often because of satellites traffic price. 8 kilobytes monthly data limit is hardcoded in firmware. If data limit is reached – data limit counter will reset automatically only on next month first day or you can rest counter by SMS command “sbdlimitsreset”.
  
'''''SBD IO source''''' configures IO source which can trigger SBD record saving. 9 elements can generate an Alarm for SDB sending. These elements are:
+
In addition, you can select which IO element can generate Satellite record. In order to do that you need to go to IO tab select IO record priority Panic and check checkbox “Satellite I/O” what you want to get that data through satellites if there is no GSM connection.
* Digital input 1
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Record which will be sent through Iridium satellites network will be different than the regular record. It will contain: 4 bytes timestamp, 3 bytes longitude, 3 bytes latitude, 1 byte record generation info, 1 byte DIN,DOUT info, 1 byte speed value.
* Digital input 2
 
* Digital input 3
 
* Digital input 4
 
* Digital output 1
 
* Digital output 2
 
* Digital output 3
 
* Digital output 4
 
* Speed
 
<br></br>
 
Configurator parameter IDs and their explanation:
 
{| class="nd-othertables_2" style="width:100%;"
 
|- style="font-weight:bold; text-align:center;"
 
! '''Parameter ID'''<br />
 
! '''Parameter name'''
 
! colspan="3" | '''Values'''
 
! '''Explanation'''
 
|- style="font-weight:bold; text-align:center;"
 
| style="font-weight:normal;" |
 
| style="font-weight:normal;" |
 
| '''Min'''
 
| '''Max'''
 
| '''Default'''
 
| style="font-weight:normal;" |
 
|-
 
| 99420
 
| Iridium Edge
 
| 0
 
| 1
 
| 0
 
| This parameter enables or disables Iridium Edge functionality
 
|-
 
| 99421
 
| Save/Send period
 
| 0
 
| 1440
 
| 1440
 
| This parameter lets to configure Iridium Edge sending period
 
|-
 
| 99422
 
| SBD IO source'''*'''
 
| 0
 
| 8
 
| 0
 
| SBD IO elements which when enabled are included into the SBD record
 
|-
 
| 99423
 
| SBD UploadLimit
 
| 0
 
| 30000
 
| 8000
 
| Limit to save user from exceeding the monthly plan. Max limit of 30000 due to 30KB plan. If set to 0 – limit will be off.
 
|-
 
| 99424
 
| Power control DOUT
 
| 1
 
| 5
 
| 0
 
| Device DOUT which can control ON/OFF pin of the Iridium Edge
 
|-
 
| 151
 
| RS232 Mode
 
| 0
 
| 23
 
| 0
 
| RS-232 mode selection. "Satellite backup" - 15
 
|}
 
  
<br></br>
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{{{pic_overspeeding|[[Image:connection.JPG|300px|center]]}}}
'''*''' SBD IO source parameter is configured with bitmasks:  
 
*eSBD_IO_Bit_Disabled    = 0x00,
 
*eSBD_IO_Bit_Din1        = 0x01,
 
*eSBD_IO_Bit_Din2        = 0x02,
 
*eSBD_IO_Bit_Din3        = 0x04,
 
*eSBD_IO_Bit_Din4        = 0x08,
 
*eSBD_IO_Bit_Do1          = 0x10,
 
*eSBD_IO_Bit_Do2          = 0x20,
 
*eSBD_IO_Bit_Do3          = 0x40,
 
*eSBD_IO_Bit_Do4          = 0x80,
 
*eSBD_IO_Bit_Speed        = 0x100
 
<br></br>
 
For example: to enable Din1, Din3 and Do4: 0x01 + 0x04 + 0x80 = 0x85 convert to decimal --> 133.
 
  
==Impulse Counters Settings==
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'''NOTE''': Port1/2 cable from FM package can be used for TSM232 connection. For this you need to cut a D-SUB connector and connect wires according instruction above (PIN 4 to TSM GND, PIN5 to TSM Rx, PIN6 to TSM Tx).
  
{{{Impulse counter settingsFM6|[[Image:Impulse counter settingsFM6.png|300px|right]]}}}
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{{{pic_overspeeding|[[Image:connector.JPG|600px|center]]}}}
  
Pulse counter functionality enables the FMX640 devices to count digital impulses going to Digital and Analog Inputs. This means that these inputs of the FMX640 devices can now be used for precise fuel flow meter data reading. Impulse based fuel usage monitoring is much more accurate than a different type of fuel metering sensors and it makes the FMX640 devices a perfect solution for high fuel usage machines like cranes, construction vehicles, mining machines, agriculture equipment.
+
'''NOTE''': SBD data is limited to 8000 Bytes per month. For firmware with bigger SBD data limit, please ask your sales manager.
<br>
+
If data limit is reached you can reset it with SMS command “sbdlimitsreset”
<br>
 
'''How does it work?'''
 
<br>
 
When "Impulse Counter 1/2 input" is selected and "Fuel Counter/Impulse Counter 2" IO elements are enabled, device will count every input state change to HIGH and send the counted number with the next record. Pulse counter value is reset after sending the record.
 
<br>
 
'''NOTE''': Impulse Counters feature is available from FW ver. 01.02.02
 
------
 
'''I/O elements''' - Each counter has a corresponding IO elements for "Impulse Frequency" - value in Hz and "Impulse RPM" - impulse count per minute.
 
<br>
 
<br>
 
[[Image:Image-2021-09-07-18-10-28-631.png]]
 
<br>
 
<br>
 
<br>
 
<br>
 
----
 
'''Additionally''' - some fuel meters have a return flow counter as well:
 
<br>
 
[[File:400px-FMB640 Impulse meter.png]]
 
<br>
 
<br>
 
In this case - you can select which inputs are used for direct (''Impulse counter 1'') and return (''Impulse counter 2'') lines and enable "Return Flow" - when this parameter is enabled - "Fuel Counter" IO element will have a value of Direct Flow impulses substracted by Return Flow impulses.
 
 
 
For example:
 
<br>
 
* Direct Flow=50 impulses.
 
* Return Flow=10 impulses
 
* Fuel Counter=40 - if "Return Flow" is enabled.
 
<br>
 
Note that each Input has a specific requirements for signal frequency and threshold:
 
<table class="nd-othertables_2" style="width: 30%;">
 
<tr>
 
        <th style="width: 10%; text-align:center; vertical-align:middle;">Input</th>
 
        <th style="width: 10%; text-align:center; vertical-align:middle;">Max frequency (Hz)</th>
 
        <th style="width: 10%; text-align:center; vertical-align:middle;">Min Voltage threshold (V)</th>
 
 
 
    </tr>
 
        <tr>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">DIN1</td>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">50</td>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">7.5</td>
 
    </tr>
 
        <tr>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">DIN2</td>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">30 000</td>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">2.5</td>
 
    </tr>
 
        <tr>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">DIN3</td>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">30 000</td>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">2.5</td>
 
    </tr>
 
        <tr>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">DIN4</td>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">30 000</td>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">2.5</td>
 
    </tr>
 
        <tr>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">AIN1</td>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">10 000</td>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">2.5</td>
 
    </tr>
 
        <tr>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">AIN2</td>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">10 000</td>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">2.5</td>
 
    </tr>
 
        <tr>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">AIN3</td>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">10 000</td>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">2.5</td>
 
    </tr>
 
        <tr>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">AIN4</td>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">10 000</td>
 
        <td style="width: 10%; text-align:center; vertical-align:middle;">2.5</td>
 
    </tr>
 
</table>
 

Revision as of 13:22, 22 August 2019

Green Driving

Green driving.JPG

When vehicle parameters exceed the values of Max Acceleration, Max Braking or Max Cornering parameters, the scenario is activated: a record is generated and digital output status is changed to 1 when configured. You can configure all three parameters in m/s2 units. Scenario is activated until current Acceleration, Braking or Cornering value decreases below the set parameter value.
Parameters used with Green Driving functionality are given in a table below.

Parameter name Description
Scenario Settings Enable/Disable Green driving functionality
Max Acceleration Value which can be reached while accelerating without triggering harsh acceleration event.
Max Braking Acceleration Value which can be reached while braking without triggering harsh braking event.
Max Cornering Acceleration Value which can be reached while cornering without triggering harsh cornering event.
Source Which source data will be collected from.

0 – GNSS - GPS Data will be used to detect harsh driving. (This algorithm was used in FM53, FM63 devices)
1 – Accelerometer – Accelerometer data will be used to detect harsh driving. (This algorithm is from FMB device family). Accelerometer calibration needs to be performed with “auto_calibrate:set” command.
2 – GNSS Algorithm A1 – GPS data will be used to detect harsh driving. (This algorithm is used in FMA11 devices). Main difference from FM53 is cornering detection which uses advanced math to more precisely calculate harsh cornering value across different vehicle speeds.
3 – Accelerometer Algorithm A1 - Accelerometer data will be used to detect harsh driving. (This algorithm is used in FMA11 device family)

Note: To use “Accelerometer Algorithm A1” option user need to install device as in Figure 1.

FMB640accelerometerposition.png

FM64 Devcie accelerometer position. (With positive Z axis pointing to Ground and antennas face forward in vehicle). Before operation with vehicle on level ground user must send “setacc” SMS.



Auto calibration


The auto-calibration process is following:

  1. The vehicle is stopped.
  2. There is a straight road ahead.
  3. Send SMS "auto_calibrate:set" to the FMB device.
  4. Accelerate to >30 km/h for 5 sec.
  5. FMB will send a response when calibration is completed successfully.

Calibration is saved to internal flash memory, which means it will stay after a reset. To check auto-calibration status send a following short text message to the FMB device: "auto_calibrate:get".

Over Speeding

FMB640 overspeeding.png

When vehicle speed exceeds configured maximum speed value the scenario is activated, an event record is generated and digital output status is changed to 1 when configured.
Scenario is active until detected speed decreases below the set parameter value.
info DOUT1, DOUT2 or DOUT3 can be activated for a period of time to warn the driver. Output on-time is configured separately for each feature case. For more information please refer to DOUT controls.









Jamming

Jamming.JPG

When jamming is detected the scenario is activated, an event record is generated and digital output status is changed to 1 when configured once Jamming timeout runs out. If jamming ends during timeout countdown no event will be generated and output will not be controlled.
Eventual Records parameter can be configured: when it is disabled scenario status value will appear in each AVL record, otherwise it will be appended only to eventual records.








Authorized driving/Immobilizer

FMB640 authorizedD.png
  • If DOUT Control is disabled, scenario will only generate events without digital output activation. If DOUT Control is enabled DOUT1/DOUT2 turns ON if ignition turns ON (Ignition Source is configured to 1).
  • After any iButton ID is attached, DOUT1/DOUT2/DOUT3 turns OFF.
  • After iButton identification configured Ignition Source can be turned OFF (Ignition Source is configured to 0) for no longer than 30 seconds, otherwise immobilizer must be repeated. If * iButton List Check parameter is enabled, authorization will be successful only if the attached iButton is specified in iButton list.
  • Ignition off timeout parameter is used to set the duration after which authorization is activated, when ignition is turned off.
  • Authorization off timeout parameter is used to set the duration how long the user has time to authorize after switching ignition on.
  • iButton list gives ability to use vehicle for 1000 specific iButton owners (specified in iButton list). Selected DOUT is controlled by scenario for user needs, to manage buzzer, LED etc.











iButton Read Notification

I button.JPG
  • If scenario is enabled, when iButton is attached and is successfully read, configured DOUT goes ON for configurable amount of time (min: 0.00 s; max: 5.00 s; default: 0.2 s).
  • If DOUT ON and DOUT OFF durations are both set to 0, DOUT will be ON until iButton will be removed from the reader.
  • If Immobilizer scenario is enabled and iButton’s indication scenario is enabled and the same DOUT controls are chosen then in case iButton is attached DOUT is not affected.

IButton’s event generation works as a standard IO event generation






DOUT Control via Call

Activates DOUT on incoming call
Scenario is activated and digital output is ON, when call is received from number which is in authorized numbers list. Call control functionality:

  • When FMB64 is configured to control DOUT1/DOUT2/DOUT3/DOUT4 device waits incoming call from configured secure number. If call is received FMB64 turns on DOUT1/DOUT2/ DOUT3/DOUT4 for user defined Duration timeout (s). If Duration timeout set to „0“(s), DOUT1/DOUT2/ DOUT3/DOUT4 will be OFF.
  • DOUT1/ DOUT2/DOUT3/DOUT4 can be turned off by Duration timeout (s) or by digital input 1, digital input 2, digital input 3, or digital input 4 (DOUT deactivation settings).
  • DOUT1/DOUT2/DOUT3/DOUT4 can be turned off before Duration timeout (s) by selected DIN (DOUT deactivation settings).
  • DOUT1/DOUT2/DOUT3/DOUT4 always will be ON, if DOUT deactivation set to DIN1 for example, but DIN1 will be never turned ON or set Duration timeout to Max value (2147483647) it is about 68 years.
FMB640 DOUT control via CALL.png














Short burst data settings

Short burst.JPG

FMB640 supports Iridium devices which can send short burst data (SBD) to server. This means that some data can be sent from FM device to server through satellites.

FMB640 will enable satellite mode only if device can not send data via GPRS. Satellite mode has his own Save/Send period. If timeout is set to 0 no periodic records will be made. It is not recommended to save records often because of satellites traffic price. 8 kilobytes monthly data limit is hardcoded in firmware. If data limit is reached – data limit counter will reset automatically only on next month first day or you can rest counter by SMS command “sbdlimitsreset”.

In addition, you can select which IO element can generate Satellite record. In order to do that you need to go to IO tab select IO record priority Panic and check checkbox “Satellite I/O” what you want to get that data through satellites if there is no GSM connection. Record which will be sent through Iridium satellites network will be different than the regular record. It will contain: 4 bytes timestamp, 3 bytes longitude, 3 bytes latitude, 1 byte record generation info, 1 byte DIN,DOUT info, 1 byte speed value.

Connection.JPG

NOTE: Port1/2 cable from FM package can be used for TSM232 connection. For this you need to cut a D-SUB connector and connect wires according instruction above (PIN 4 to TSM GND, PIN5 to TSM Rx, PIN6 to TSM Tx).

Connector.JPG

NOTE: SBD data is limited to 8000 Bytes per month. For firmware with bigger SBD data limit, please ask your sales manager. If data limit is reached you can reset it with SMS command “sbdlimitsreset”