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Siemens MS43: Difference between revisions

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<div style="float:right;">__TOC__</div>
<div style="float:right;">__TOC__</div>
=Memory Layout=
The MS43 can be seperated into three major sections, first comes the bootloader, then the program code, and last the calibration data.
See this table for file locations:
{| class="wikitable"
! style="text-align: center; font-weight:bold;" | Start
! style="text-align: center; font-weight:bold;" | End
! style="text-align: center; font-weight:bold;" | Section
! style="text-align: center; font-weight:bold;" | Size
|-
| style="text-align: center; background-color:#fe996b;" | 00000
| style="text-align: center; background-color:#fe996b;" | 0FFFF
| style="text-align: center; background-color:#fe996b;" | Bootloader Code
| style="text-align: center; background-color:#fe996b;" | 64 kByte
|-
| style="text-align: center; background-color:#fffc9e;" | 10000
| style="text-align: center; background-color:#fffc9e;" | 1FFFF
| rowspan="6" style="text-align: center; background-color:#fffc9e;" | Program Code
| rowspan="6" style="text-align: center; background-color:#fffc9e;" | 384 kByte
|-
| style="text-align: center; background-color:#fffc9e; color:#000000;" | 20000
| style="text-align: center; background-color:#fffc9e; color:#000000;" | 2FFFF
|-
| style="text-align: center; background-color:#fffc9e; color:#000000;" | 30000
| style="text-align: center; background-color:#fffc9e; color:#000000;" | 3FFFF
|-
| style="text-align: center; background-color:#fffc9e; color:#000000;" | 40000
| style="text-align: center; background-color:#fffc9e; color:#000000;" | 4FFFF
|-
| style="text-align: center; background-color:#fffc9e; color:#000000;" | 50000
| style="text-align: center; background-color:#fffc9e; color:#000000;" | 5FFFF
|-
| style="text-align: center; background-color:#fffc9e; color:#000000;" | 60000
| style="text-align: center; background-color:#fffc9e; color:#000000;" | 6FFFF
|-
| style="text-align: center; background-color:#9aff99; color:#000000;" | 70000
| style="text-align: center; background-color:#9aff99; color:#000000;" | 7FFFF
| style="text-align: center; background-color:#9aff99; color:#000000;" | Calibration Data
| style="text-align: center; background-color:#9aff99; color:#000000;" | 64 kByte
|}
'''Bootloader Section'''
The bootloader code section is the most important section of the MS43 and doesnt have to be touched for at least 99% of all use cases.
This section is 64 kByte in size and contains the interrupt setups, input and output initializations, as well as immobilizer information and the UIF (user information fields).
The significant difference between the bootloader section and the others is, that it's only one time programmable under normal operation. That means once a byte has been changed from FF to another value, it is not changeable again.
Unlimited write access to the bootloader section can only be archieved through JMGarage Flasher and is ONLY needed for virginizing the ECU to pair it with a different EWS module or to alter the UIF without increasing the flashcounter.
The newest version of immobilizer and checksum delete will not need bootmode flashing.
'''Programm Code Section'''
All of the MS43 program code is located here.
'''Calibration Data Section'''


=Checksums=
=Checksums=
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* '''ip_tps_sp_pvs''' is used by the ecu to decide how much it should open the throttle for a given pvs input.
* '''ip_tps_sp_pvs''' is used by the ecu to decide how much it should open the throttle for a given pvs input.


* '''ip_isapwm_pvs''' is used by the ecu to decide how much it should open the idle control valve for a given pvs input.
* '''ip_isapwm_pvs''' is used by the ecu to decide how much idle control valve duty cycle should be used for a given pvs input.


If we look at these tables side by side we can see that a stock ecu is setup to primarily use the idle control valve to control airflow when the pvs input is in the range between 0° and 15° and when the pvs input is higher the ecu will also start to open the throttle valve.
If we look at these tables side by side we can see that a stock ecu is setup to primarily use the idle control valve to control airflow when the pvs input is in the range between 0° and 15° and when the pvs input is higher the ecu will switch over to the throttle valve.


==Drivers Wish Input Correction==
==Drivers Wish Input Correction==
Line 1,404: Line 1,466:
Removing the idle control valve (ICV) / idle speed actuator (ISA) is possible due to the motorized throttle body the M54 engine uses.
Removing the idle control valve (ICV) / idle speed actuator (ISA) is possible due to the motorized throttle body the M54 engine uses.


Disconnect the idle control valve connector and either remove the idle control valve and plug the hole in the intake manifold (prefered) or use something to seal the idle control valve air tight.
Disconnect the idle control valve connector and either remove the idle control valve and plug the hole in the intake manifold (preferred) or use something to seal the idle control valve air tight.


The way the ICV delete works is by utilizing the '''ip_pvs_isa_isapwm''' table. This table dictates how much pvs input should be added to the drivers requested pvs input for a given idle control valve duty cycle.
The way the ICV delete works is by utilizing the '''ip_pvs_isa_isapwm''' table. This table dictates how much pvs input should be added to the drivers requested pvs input for a given idle control valve load.


In a stock engine this table is used to extend the duty cycle of the idle control valve so when the duty cycle of the idle control valve reaches 100% the throttle will start to open deliver more air.
In a stock engine this table is used to extend the idle control valve load so when the idle control valve load goes above 100% the throttle will start to open to deliver more air into the engine.


By rescaling this table we are able to completely remove the idle control valve.
By rescaling this table we are able to completely remove the idle control valve.


But be aware that the values in '''ip_pvs_isa_isapwm''' is dependent on the values in '''ip_tps_sp_pvs''' so if '''ip_tps_sp_pvs''' is modified then '''ip_pvs_isa_isapwm''' also needs to be rescaled accordingly to maintain a stable idle.
But be aware that the values in '''ip_pvs_isa_isapwm''' is dependent on the values in '''ip_tps_sp_pvs''' so if '''ip_tps_sp_pvs''' is modified then '''ip_pvs_isa_isapwm''' also needs to be re-scaled accordingly to maintain a stable idle.


The '''ip_pvs_isa_isapwm''' values in the picture are made for a M54B30 so the values may need to be modified to get a stable idle with M54B25 and M54B22 as these engines have a smaller throttle body.
The '''ip_pvs_isa_isapwm''' values in the picture are made for a M54B30 so the values may need to be modified to get a stable idle with M54B25 and M54B22 as these engines have a smaller throttle body.
Line 1,463: Line 1,525:
*'''c_obd_diag_state''' This value represents which OBD standard that the ecu complies to. If set to one the ecu will report that it complies to the OBD-II standard as defined by CARB. A full list of what the values corresponds to can be found [https://en.wikipedia.org/wiki/OBD-II_PIDs#Service_01 here] under the "Service 01 PID 1C" section.
*'''c_obd_diag_state''' This value represents which OBD standard that the ecu complies to. If set to one the ecu will report that it complies to the OBD-II standard as defined by CARB. A full list of what the values corresponds to can be found [https://en.wikipedia.org/wiki/OBD-II_PIDs#Service_01 here] under the "Service 01 PID 1C" section.


==Change E-Thermostat Desired Temp Maps==
==Engine coolant temperature control==
The M54 runs quite warm for the aluminum block and also is very sensitive to temperatures and is one of the leading causes for pulling timing when warm. To set the desired coolant temps, the following maps need to be adjusted:
The M54 engine family is fitted with an e-thermostat that the ecu can control to alter the engine coolant temperature.
By altering these values we can change how hot the engine will run in different conditions.
 
* c_tam_min_ect - Minimum ambient temperature threshold for e-thermostat activation
* c_tia_min_ect - Minimum intake air temperature threshold for e-thermostat activation
* c_toil_min_ect - Minimum oil temperature threshold for e-thermostat activation
 
* c_tia_max_ect - Maximum intake air temperature threshold. When exceeded target coolant temperature will be set to c_tco_sp_tia_max
* c_tco_ex_max_ect - Maximum radiator outlet temperature threshold. When exceeded target coolant temperature will be set to c_tco_sp_tco_ex_max
* c_toil_max_ect - Maximum oil temperature threshold. When exceeded target coolant temperature will be set to c_tco_sp_tia_max
 
* c_tco_sp_toil_min - Target coolant temperature until the thresholds set by c_toil_min_ect, c_tam_min_ect, and c_tia_min_ect are exceeded.
* c_tco_sp_tco_ex_max - Target coolant temperature if c_tco_ex_max_ect is exceeded
* c_tco_sp_tia_max - Target coolant temperature if c_toil_max_ect or c_tia_max_ect are exceeded
* c_tco_bol_ect - Target coolant temperature if an external low coolant temperature request has been received
 
* c_tco_min_ect - Minimum coolant temperature threshold for full energization of the e-thermostat
 
* id_tco_sp_ect__n__maf_sub - Target coolant temperature when c_toil_min_ect, c_tam_min_ect, and c_tia_min_ect are exceeded - AC off
* id_tco_sp_ect_acin__n__maf_sub - Target coolant temperature Target coolant temperature when c_toil_min_ect, c_tam_min_ect, and c_tia_min_ect are exceeded - AC on
 
* ip_ectpwm_i__tco_dif - e-thermostat I component
* ip_ectpwm_p__tco_dif - e-thermostat P component
* id_ectpwm_add__n__tco_sp - Required e-thermostat duty cycle to achieve coolant temperature setpoint


*C_TCO_SP_toil_MIN (Minimum Oil temp required to then default to EThermostat maps - 0xCA0h - default 105)
*ID_TCO_SP_ECT (Target Coolant temp without AC - 0x5D3Dh)
*ID_TCO_SP_ACIN_ECT (Target Coolant temp with AC - 0x5D85h)


[[File:Coolant-config.JPG|300px|thumb|none|TunerPro depiction of Coolant Maps]]
[[File:Coolant-config.JPG|300px|thumb|none|TunerPro depiction of Coolant Maps]]
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'''Here are some handy mods when going forced induction [[Forced_Induction_Upgrades]]'''
'''Here are some handy mods when going forced induction [[Forced_Induction_Upgrades]]'''
==M Cluster LED Control==
After swapping in an M3 cluster into a E46 or M5 cluster into E39, there is no more ecometer displaying the momentary fuel consumption, but a more useful oiltemperature gauge.
Using this cluster and some additional code we can also control the LEDs around the RPM gauge to work similar to the E46 M3 and also manage shiftlights behaviour.
Following maps are used:
*'''id_icl_led__n''' - Warmuplights - LED switchpoints for the given temperature
*'''ldpm_toil_led''' - Warmuplights - axis defining the oiltemperature range in °C
*'''id_icl_led__n''' - Shiftlights - LED switchpoints for the given temperature
*'''ldpm_toil_led''' - Shiftlights - axis defining the rpm range
Explaination for the decimal values used:
*112 - all LEDs lit
*96 - 4500 and upwards
*80 - 5000 and upwards
*64 - 5500 and upwards
*48 - 6000 and upwards
*32 - 6500 and upwards
*16 - 7000 and upwards
*00 - 7500 lit
*01 - oil warning LED yellow (M5)
*02 - oil warning LED yellow
*04 - coolant warning LED
Download the warmup and shiftlights patch for TunerPro depending on your software version:
*'''430056:''' [[:File:Siemens_MS43_MS430056_Cluster_LED_Mod_v2.zip|Siemens_MS43_MS430056_Cluster_LED_Mod_v2.zip]]
*'''430066:''' [[:File:Siemens_MS43_MS430066_Cluster_LED_Mod.zip|Siemens_MS43_MS430066_Cluster_LED_Mod.zip]]
'''Use with 512kByte file only. Checksum correction required!'''
[[File:TP_MS43_M3_Cluster_Warmuplights.PNG|320|M3 Cluster warmuplight maps]] [[File:TP_MS43_M3_Cluster_Shiftlights.PNG|320|M3 Cluster shiftlight maps]]
<youtube>jYAudhc02nQ</youtube>


==Launch Control==
==Launch Control==
Line 1,587: Line 1,703:
Configuration Launch Control
Configuration Launch Control


*Launch_PVS_min  (i suggest to set this switch over 50%. Anything lower may lead to non-working LC)
*Launch_PVS_min  (i suggest to set this switch over 50% and UNDER 70%. Anything different may lead to non-working LC)
*Launch_TCO_min  (and this to "-48" )
*Launch_TCO_min  (and this to "-48" )
*Launch_RPM_max
*Launch_RPM_max

Revision as of 16:49, 16 April 2019

Memory Layout

The MS43 can be seperated into three major sections, first comes the bootloader, then the program code, and last the calibration data.

See this table for file locations:

Start End Section Size
00000 0FFFF Bootloader Code 64 kByte
10000 1FFFF Program Code 384 kByte
20000 2FFFF
30000 3FFFF
40000 4FFFF
50000 5FFFF
60000 6FFFF
70000 7FFFF Calibration Data 64 kByte


Bootloader Section

The bootloader code section is the most important section of the MS43 and doesnt have to be touched for at least 99% of all use cases.

This section is 64 kByte in size and contains the interrupt setups, input and output initializations, as well as immobilizer information and the UIF (user information fields).

The significant difference between the bootloader section and the others is, that it's only one time programmable under normal operation. That means once a byte has been changed from FF to another value, it is not changeable again.

Unlimited write access to the bootloader section can only be archieved through JMGarage Flasher and is ONLY needed for virginizing the ECU to pair it with a different EWS module or to alter the UIF without increasing the flashcounter.

The newest version of immobilizer and checksum delete will not need bootmode flashing.


Programm Code Section

All of the MS43 program code is located here.


Calibration Data Section

Checksums

Checksums are used to verify that the data written to the ROM has not become corrupt.

The MS43 uses three CRC16 checksums that covers the boot, program and calibration sections and two addition checksums that covers the data for the monitoring (_mon_) routines.

The variables that the ECU uses to calculate the addition checksum is located in the program section so tools like Ultimo Checksum Corrector can only correct this checksum in a 512KB file.

Both addition checksums have to be corrected before the CRC16 checksums, as the addition checksums are located inside the CRC16 checksum areas.

The checksums are located at the following addresses:

CRC16 Location
Boot 0x3C24
Program 0x6FDE0
Calibration 0x73FE0
Addition Location
Program Part 1 0x6FDAE
Program Part 2 0x6FD80
Calibration Part 1 0x72FFC
Calibration Part 2 0x72FFE

Disabling Calibration Checksums

Disable CRC16 Checksum

To disable the CRC16 calibration checksum on all firmwares do the following.

Hexeditor
1. Set Word at 0x73FFE to 0xFFFF
2. Set Byte at 0x6FFB0 to 0xA8


Disable Addition Checksum

To disable the addition calibration checksum use one of the following methods.

Tunerpro
1. Set lc_swi_cal_mon_cks to 165
Hexeditor
1. Set the Byte in the table to 0xA5
Firmware Location
430037 0x70CE3
430055 0x70D7C
430056 0x70D7E
430064 0x70DA0
430066 0x70E0A
430069 0x70E07

Fueling

Fuel Injection Maps

The injection maps are based on "engine load (mg/stroke) vs. engine speed (rpm)" and the lookup is injection time in milliseconds.

The lambda sensors for closed loop operation are narrowband. Fuel trim learning only happens during closed loop operation, but the learned fuel trims do affect full throttle fueling as well.

When there is no VANOS fault, the engine interpolates between "Injection time at part-load, cold engine, Vanos I/II" and "Injection time at part-load, warm engine, Vanos I/II", where the numbers I or II indicate the two banks of the straight six engine.

Under VANOS fault conditions, the map "Basic Injection Time (ip_tib)" is used.

"Full load enrichment (ip_ti_fl)" is a multiplier of the part load calculations and added to them.

Blending between cold and warm injection maps is done by weighting factor "ip_fac_pl_ivvt__tco__tco_st" for partload and "ip_fac_is_ivvt__tco__tco_st" for idlespeed

Non Stock Injector Maps

Changing the fuel injectors may be needed when supercharging your engine and therefore some constants and maps need to be tweaked.

You will have to calculate the difference in percentage of volume flow between stock and your new injectors.

The following scalars need to be adjusted accordingly:

  • T_TI_AS_[0-5]
  • c_ti_min_iv

Depending on the injectors you will have to finetune the injector latency compensation (injector dead times) as well:

Attention: This table has a wrong correction factor in almost all available definition files. Change this to "X * 0.032".

  • ip_ti_add_dly__vb

If you happen to have stuttering or unclean combustion when stepping on the gas, rescale the cylinder rewetting tables as well:

  • ip_ti_fast_wf_thd_min__tco
  • ip_ti_slow_wf_thd_min__tco

Go here for a list of suitable fuel injectors and their deadtimes.

Correcting Fuel Consumption Gauge

When changing injectors you will discover that the MPG reading on your cluster or other monitoring apps is off.

The table ip_fco_map_cor__pq_main_col handles injection reporting towards the cluster.

For example: If you lowered your fueling tables by MULTIPLIYING them with 0.3, you must DIVIDE the mentioned table by 0.3 to fix MPG reading.

Upgraded fuel pumps

Under some circumstances, like going forced induction, the OEM fuel pump can't deliver enough fuel to the engine and needs to be upgraded.

Most aftermarket fuelpumps like the Walbros or Deatschwerks don't have a check valve inside and the fuel flows back into the tank once the vehicle is turned off.

The MS43 has two time values (in seconds) for controlling the fuelpump before starting and after stopping the engine:

  • C_T_EFP_PREV: Time the electronic fuel pump relay is on after ignition key ON
  • C_T_EFP: Time delay to shut off the electric fuel pump relay after ignition key OFF

Slightly rising these values may eliminate starting issues.

Timing

Basic Timing Maps

The MS43 uses several ignition maps depending on the engine state and quality of fuel used. Like the injection maps, they are also based on "engine load (mg/stroke) vs. engine speed (rpm)" but obviously the lookup is ignition timing in degrees BTDC (before top dead center).

"Ignition at part-load, RON98 (16x20) Airflow -vs- Engine speed" is the main table used with a healthy engine (so no VANOS fault codes, normal warmed up operating temperature) running RON98/PON93 gasoline.

There is a knock based interpolation between the RON91 and RON98 RON tables. The other tables should be kept safe.

"Ignition at part-load, cold engine (16x20) Airflow -vs- Engine speed" is used on a cold engine, and blended/interpolated towards "Ignition at part-load, RON98 (16x20) Airflow -vs- Engine speed" during warm up.

Catalyst heating "_CH_" in maps retards ignition during warm up.

Antijerk "_AJ_" retards ignition during rapid throttle opening to smooth out torque (can be removed by increasing c_tco_min_aj to 142.5C. Reported to sometimes cause transitional knock on boosted engines, if so consider adjusting other tables designed for this (tra_knk).

Experience on standard or near standard European 330ci in cool climate and with 99 RON fuel suggested sporadic pulling of timing here and there up to a few degrees is common, but rarely sufficient even in hard track use to produce more than 1 degree of learned ignition retard from the 98 RON base map. Shows the RON98 map on a standard car is quite good. Question if fueling could be richened to allow more ignition timing and torque/power.

Vanos

This section contains information on how the dual vanos system is actuated by the DME and how to modify it. Both, intake and exhaust, camshaft can be set independently in relation to the crankshaft.

The aim of that system is to optimize emission, produce better torque at low engine speeds and have better top end power.

The system uses engine oil to pressurize a set of gears at the end of each camshaft.

Even though the variation of °crk is pretty limited, it can be used to compensate for different intakes, different camshafts and even turbo application may be benefitting from perfectly tweaked camshafts.

Basic Vanos Maps

The main maps used for intake camshaft are:

cold engine

  • ip_cam_sp_tco_1_in_is__n__maf_iv(vt)
  • ip_cam_sp_tco_1_in_pl__n__maf_iv(vt)
  • ip_cam_sp_tco_1_in_fl__n

warm engine

  • ip_cam_sp_tco_2_in_is__n__maf_iv
  • ip_cam_sp_tco_2_in_pl__n__maf_iv
  • ip_cam_sp_tco_2_in_fl__n


The main maps used for exhaust camshaft are:

cold engine

  • ip_cam_sp_tco_1_ex_is__n__maf_iv(vt)
  • ip_cam_sp_tco_1_ex_pl__n__maf_iv(vt)
  • ip_cam_sp_tco_1_ex_fl__n

warm engine

  • ip_cam_sp_tco_2_ex_is__n__maf_iv
  • ip_cam_sp_tco_2_ex_pl__n__maf_iv
  • ip_cam_sp_tco_2_ex_fl__n

Blending between cold engine and warm engine is done by:

idlespeed ip_fac_cam_sp_in_is__tco__tco_st ip_fac_cam_sp_ex_is__tco__tco_st

partload ip_fac_cam_sp_in_pl__tco__tco_st ip_fac_cam_sp_ex_pl__tco__tco_st

VANOS Tweak for little extra midrange power

Insert the following tables into the desired part-load map where you need the effect ( part-load cold / part-load warm / both).

*ATTENTION: Only Suitable for M54B30 M54B30 M54B30 M54B30 *

Credits to e46fanatics.com member DoCR ONLY FOR 3L engine M54B30

Vanos tweak.jpg


VANOS Tweak maps in table form for copy and pasting into TunerPro M54B30 ONLY
Exhaust cam setpoint part-load Intake cam setpoint part-load
-105.0 -105.0 -105.0 -104.6 -103.1 -97.5 -96.0 -96.8 -98.3 -104.3 -99.0 -99.0
-105.0 -104.6 -103.9 -102.0 -99.0 -96.0 -95.3 -96.4 -97.9 -103.9 -98.6 -98.6
-104.6 -103.9 -100.9 -97.5 -93.8 -92.6 -93.4 -94.9 -96.4 -101.6 -97.5 -97.5
-103.9 -102.4 -96.4 -92.6 -88.9 -88.1 -90.0 -91.5 -93.8 -97.1 -91.9 -91.9
-103.1 -101.6 -94.9 -91.1 -87.4 -86.6 -88.5 -90.4 -92.6 -96.0 -90.8 -90.8
-100.9 -98.6 -90.4 -87.0 -85.9 -85.1 -85.9 -88.5 -91.1 -95.6 -90.4 -90.4
-99.0 -96.4 -88.5 -85.9 -85.1 -84.8 -85.5 -88.9 -94.1 -97.5 -95.3 -95.3
-97.9 -95.3 -87.8 -85.9 -85.1 -85.1 -85.9 -91.9 -97.5 -100.9 -99.0 -99.0
-96.8 -94.5 -88.5 -86.6 -85.9 -96.0 -95.6 -95.6 -95.6 -95.6 -95.6 -97.5
-95.6 -94.1 -91.1 -88.5 -88.5 -99.8 -101.6 -101.6 -101.6 -101.6 -100.5 -101.3
-95.3 -93.8 -91.9 -90.4 -90.4 -101.3 -102.0 -102.0 -102.0 -102.0 -100.9 -101.6
-93.8 -93.0 -92.3 -92.3 -94.5 -102.4 -101.3 -101.3 -101.3 -101.3 -100.1 -101.3
-91.9 -91.5 -91.9 -92.3 -95.3 -105.8 -106.1 -106.1 -106.1 -106.1 -105.0 -102.8
-87.8 -88.5 -89.6 -91.1 -94.9 -106.1 -106.1 -106.1 -106.1 -106.1 -105.0 -103.1
-85.5 -87.0 -88.5 -90.0 -93.8 -106.1 -106.1 -106.1 -106.1 -106.1 -105.0 -103.1
-84.0 -85.9 -87.4 -88.9 -93.0 -106.1 -106.1 -106.1 -106.1 -106.1 -105.0 -103.1
126.00 126.00 125.63 124.88 123.00 118.88 113.25 106.50 105.00 104.25 108.00 108.00
126.00 126.00 125.25 124.50 122.63 118.50 112.88 106.50 105.00 104.25 105.00 105.00
126.00 125.63 124.88 124.13 122.25 118.13 112.50 105.75 104.25 103.50 100.13 100.13
125.63 124.88 123.75 122.63 120.38 115.88 110.25 103.88 99.75 98.63 91.50 91.50
125.25 124.50 123.38 121.88 119.25 114.75 109.50 102.75 98.63 97.50 90.75 90.75
124.50 123.38 122.25 120.38 117.38 112.50 107.25 101.25 97.50 96.75 90.75 90.75
123.38 122.25 120.75 118.88 114.38 107.63 102.00 98.25 97.13 96.38 90.38 90.38
122.63 121.13 120.00 117.75 112.13 103.50 99.38 97.50 96.75 96.38 91.50 91.50
115.50 113.63 111.75 109.50 104.25 93.75 99.38 98.25 94.50 94.13 94.13 94.13
113.25 111.75 110.25 107.25 100.50 91.88 100.88 99.75 94.88 94.50 94.50 94.50
112.13 110.25 108.00 104.63 94.50 90.38 101.25 100.50 97.50 97.50 97.50 97.50
110.63 105.38 99.75 95.25 89.63 90.75 105.75 105.00 101.63 100.50 100.50 100.50
109.88 104.25 97.50 92.25 109.50 110.25 109.50 110.25 108.75 108.75 108.75 108.75
108.75 103.88 99.38 94.88 115.50 118.13 118.13 118.13 117.75 117.75 117.75 117.75
108.38 106.50 104.25 101.25 118.50 126.00 126.00 126.00 126.00 126.00 122.25 122.25
108.38 108.75 108.00 106.50 122.25 126.00 126.00 126.00 126.00 126.00 126.00 126.00

*ATTENTION: Only Suitable for M54B30 M54B30 M54B30 M54B30 M54B30 M54B30 M54B30 M54B30 M54B30*

INFO

For stock engine with stock exhaust and intake flow, above vanos tune works best in that form. For a moded engine,or even stock,but with free flow exhaust (really free flow) and CAI type intake, cams overlap can help increase volumetric efficiency in the hi revs (over disa switch point ~4000rpm and up ),resulting in more power! Taking as a base M54B30 engine with Intake cam 126 for max, and 86 for min ; exhaust cam -105 for max ,and -80 for min 126 represent intake cam in its max retard form, and 86 in its max advance position -105 represent exhaust cam in its max advance position, and -80 in its max retard stage

General rule for overlap : Advancing both cams - more low end torque and less top end power

                   Retarding both cams - less low end torque and more top end power

TIPS for full load vanos maps : Begin from low rpm with max number for your cam (intake 126 ,exhaust -105) and progressively reduce number until you reach 4000rpm and lowest cam number (intake 86,exhaust -80) From 4000rpm and up to max ,use inverse technique, start to rise again numbers, progressively. (every engine responds different by exhaust config) Test combinations until you are happy. Also, do changes for intake only, leave exhaust alone if you are on stock exhaust manifold.

note Theoreticaly, there is no risk of damaging engine ( valve hit piston) if you stay within specified range for your particular cams. (m54b30 intake 126/86 ,exhaust -105/-80)

example of random overlap for full load and partload maps

Drive-By-Wire

This section contains information on how the Drive-By-Wire system is controlled by the DME and how it can be modified.

Drivers Wish Tables

Tunerpro comparison of the ip_tps_sp_pvs and ip_isapwm_pvs table.

The Drive-By-Wire system is setup so that the ecu uses both the throttle valve and the idle control valve to control how much air is going into the engine.

  • ip_tps_sp_pvs is used by the ecu to decide how much it should open the throttle for a given pvs input.
  • ip_isapwm_pvs is used by the ecu to decide how much idle control valve duty cycle should be used for a given pvs input.

If we look at these tables side by side we can see that a stock ecu is setup to primarily use the idle control valve to control airflow when the pvs input is in the range between 0° and 15° and when the pvs input is higher the ecu will switch over to the throttle valve.

Drivers Wish Input Correction

The MS43 actively limits how fast the drivers requested pvs input can increase to provide a smoother driving experience.

ip_pvs_cor_max_rpl_[gear] is used by the ecu to decide if the drivers requested pvs input should be limited. The values in the table is the lower limit and the X-axis is the upper limit. If the drivers requested pvs input is between these values then the ecu will start limiting the pvs input.

If the following conditions are met then the ecu will not try to start limiting the pvs input:

  • The driver requested pvs input is decreasing.
  • The driver requested pvs input change gradient is larger than c_pvs_grd_max_rpl(59,99° pvs).
  • The clutch is pressed.
  • The driver requested pvs input is higher than c_pvs_cor_max_rpl(42,5° PVS)

When the ecu starts limiting the pvs input then the pvs input will be increased by the value taken from ip_pvs_cor_rpl_lgrd_[gear] until the following conditions are met:

  • The limitation duration specified in ip_t_pvs_cor_rpl_[gear] has expired.
  • The driver requested pvs input change gradient is larger than c_pvs_grd_max_rpl(59,99° pvs).
  • The limited pvs input is larger than the driver requested pvs input.

If any of those conditions are met then the ecu will use the driver requested pvs input and will not start limiting the pvs input again until the time specified in c_t_dly_pvs_cor_rpl(0,2s) has expired.

The easiest way to disable this function is to set either c_pvs_cor_max_rpl or c_pvs_grd_max_rpl to zero.

Full load detection

Full load detection is the threshold when the ecu stops trying to be economical/ecofriendly and instead focuses on producing power.

The full load detection thresholds are pvs based and are defined in the following tables:

  • id_pvs_fl__n When this threshold is exceeded the injection will operate in open loop and the full load enrichment map is applied to the injection time.
  • id_pvs_fl_ivvt__n When this threshold is exceeded the Vanos will use the full load maps.
  • id_pvs_fl_vim__n_vim_ When this threshold is exceeded the DISA will use the full load maps.

Idlespeed

This section contains information on how the idle is controlled by the DME and how it can be modified.

MS43 has a few different tables that affect the nominal idle speed

  • ip_n_sp_is Nominal idle speed without additional load on the engine.
  • ip_dri_n_sp_is Nominal idle speed with drive engaged for AT gearbox.
  • ip_acin_n_sp_is Nominal idle speed with air conditioner switched on.
  • ip_dri_acin_n_sp_is Nominal idle speed with air conditioner switched on and drive engaged for AT gearbox.

The idle setpoint is modified from the nominal speed above by

  • ip_n_sp_add_cha_cdn_bat Nominal idle speed offset for battery charge state.
  • ip_n_sp_add_heat Nominal idle speed offset with catalyst heating function active.

In addition, the idle speed change rate can be changed with c_n_sp_lgrd_is.

DTC Suppression

DTCs can be suppressed in the MS43 by zeroing out the c_abc_... specific codes. The full list of DTCs can be found here:

DTC variables OBD
Code Description
c_dtc_ad_mec_ref_ivvt_ex P0014 B Camshaft Position - Timing Over-Advanced or System Performance (Bank 1)
c_dtc_ad_mec_ref_ivvt_in P0011 A Camshaft Position - Timing Over-Advanced or System Performance (Bank 1)
c_dtc_amp P0107 Manifold Absolute Pressure/Barometric Pressure Circuit Low Input
P0108 Manifold Absolute Pressure/Barometric Pressure Circuit High Input
c_dtc_bls_plaus P0571 Cruise Control/Brake Switch A Circuit Malfunction
c_dtc_cam P0340 Camshaft Position Sensor Circuit Malfunction
P0344 Camshaft Position Sensor Circuit Intermittent
c_dtc_cam_ex P0365 Camshaft Position Sensor 'B' Circuit Bank 1
P0369 Camshaft Position Sensor 'B' Circuit Intermittent Bank 1
c_dtc_cam_ex_ivvt P1529 "B" Camshaft Position Actuator Control Circuit Signal Low Bank 1
P1530 "B" Camshaft Position Actuator Control Circuit Signal High Bank 1
P1531 "B" Camshaft Position Actuator Control Open Circuit Bank 1
c_dtc_cam_in_ivvt P1523 "A" Camshaft Position Actuator Signal Low Bank 1
P1524 "A" Camshaft Position Actuator Signal High Bank 1
P1525 "A" Camshaft Position Actuator Control Open Circuit Bank 1
c_dtc_can_boff P1610 CANbus offline
c_dtc_cat_diag_1 P0420 Catalyst System Efficiency Below Threshold (Bank 1)
c_dtc_cat_diag_2 P0430 Catalyst System Efficiency Below Threshold (Bank 2)
c_dtc_cat_eff_1 P0421 Warm Up Catalyst Efficiency Below Threshold (Bank 1)
c_dtc_cat_eff_2 P0431 Warm Up Catalyst Efficiency Below Threshold (Bank 2)
c_dtc_cc
c_dtc_cps P0443 Evaporative Emission Control System Purge Control Valve Circuit Malfunction
P0444 Evaporative Emission Control System Purge Control Valve Circuit Open
P0445 Evaporative Emission Control System Purge Control Valve Circuit Shorted
c_dtc_crk P0335 Crankshaft Position Sensor A Circuit Malfunction
P0339 Crankshaft Position Sensor A Circuit Intermittent
c_dtc_cs P0xxx Clutch Switch
c_dtc_ct
c_dtc_ctoc
c_dtc_diagcps P0441 Evaporative Emission Control System Incorrect Purge Flow
c_dtc_dmtl P1444 Diagnostic Module Tank Leakage (DM-TL) Pump Control Open Circuit
P1445 Diagnostic Module Tank Leakage (DM-TL) Pump Control Circuit Signal Low
P1446 Diagnostic Module Tank Leakage (DM-TL) Pump Control Circuit Signal High
c_dtc_dmtl_leak P0455 Evaporative Emission Control System Leak Detected (gross leak)
P0456 EVAP Leak Monitor Small Leak Detected
c_dtc_dmtlm P1447 Diagnostic Module Tank Leakage (DM-TL) Pump Too High During Switching
P1448 Diagnostic Module Tank Leakage (DM-TL) Pump Too Low During Switching
P1449 Diagnostic Module Tank Leakage (DM-TL) Pump Too High
c_dtc_ecf P0480 Cooling Fan 1 Control Circuit Malfunction
c_dtc_ect P1619 MAP Cooling Control Circuit Signal Low
P1620 MAP Cooling Control Circuit Signal High
c_dtc_ect_mec P0128 Range/Performance Problem In Thermostat
c_dtc_ecu P0604 Internal Control Module Random Access Memory (RAM) Error
c_dtc_ef P0477 Exhaust Pressure Control Valve Low
P0478 Exhaust Pressure Control Valve High
c_dtc_er_ad P0xxx Misfire adaptation
c_dtc_igcfb_0 P0351 Ignition Coil 1 Primary/Secondary Circuit Malfunction
P1301 Misfiring Cylinder 1
c_dtc_igcfb_1 P0355 Ignition Coil 5 Primary/Secondary Circuit Malfunction
P1305 Misfiring Cylinder 5
c_dtc_igcfb_2 P0353 Ignition Coil 3 Primary/Secondary Circuit Malfunction
P1303 Misfiring Cylinder 3
c_dtc_igcfb_3 P0356 Ignition Coil 6 Primary/Secondary Circuit Malfunction
P1306 Misfiring Cylinder 6
c_dtc_igcfb_4 P0352 Ignition Coil 2 Primary/Secondary Circuit Malfunction
P1302 Misfiring Cylinder 2
c_dtc_igcfb_5 P0354 Ignition Coil 4 Primary/Secondary Circuit Malfunction
P1304 Misfiring Cylinder 4
c_dtc_imob P1660 EWS system
P1666 EWS system
c_dtc_is P0505 Idle Control System Malfunction
c_dtc_isa_1 P1506 Idle Speed Control Valve Open Solenoid Control Circuit Signal High
P1507 Idle Speed Control Valve Open Solenoid Control Circuit Signal Low
P1508 Idle Speed Control Valve Opening Solenoid Control Open Circuit
c_dtc_isa_2 P1502 Idle Speed Control Valve Closing Solenoid Control Circuit Signal High or Low
P1503 Idle Speed Control Valve Closing Solenoid Control Circuit Signal Low
P1504 Idle Speed Control Valve Closing Solenoid Control Open Circuit
c_dtc_iv_0 P0201 Injector Circuit Malfunction - Cylinder 1
P0261 Cylinder 1 Injector Circuit Low
P0262 Cylinder 1 Injector Circuit High
c_dtc_iv_1 P0205 Injector Circuit Malfunction - Cylinder 5
P0273 Cylinder 5 Injector Circuit Low
P0274 Cylinder 5 Injector Circuit High
c_dtc_iv_2 P0203 Injector Circuit Malfunction - Cylinder 3
P0267 Cylinder 3 Injector Circuit Low
P0268 Cylinder 3 Injector Circuit High
c_dtc_iv_3 P0206 Injector Circuit Malfunction - Cylinder 6
P0276 Cylinder 6 Injector Circuit Low
P0277 Cylinder 6 Injector Circuit High
c_dtc_iv_4 P0202 Injector Circuit Malfunction - Cylinder 2
P0264 Cylinder 2 Injector Circuit Low
P0265 Cylinder 2 Injector Circuit High
c_dtc_iv_5 P0204 Injector Circuit Malfunction - Cylinder 4
P0270 Cylinder 4 Injector Circuit Low
P0271 Cylinder 4 Injector Circuit High
c_dtc_knk_1 P0327 Knock Sensor 1 Circuit Low Input (Bank 1 or Single Sensor)
c_dtc_knk_2 P0332 Knock Sensor 2 Circuit Low Input (Bank 2)
c_dtc_lam_dly_down_1 P0096 Intake Air Temperature Sensor 2 Circuit Range/Performance
P0097 Intake Air Temperature Sensor 2 Circuit Low
c_dtc_lam_dly_down_2 P0098 Intake Air Temperature Sensor 2 Circuit High
P0099 Intake Air Temperature Sensor 2 Circuit Intermittent/Erratic
c_dtc_lam_dly_up_1 P1090 Pre-Catalyst Fuel Trim Too Lean Bank 1
P1092 Pre-Catalyst Fuel Trim Too Lean Bank 2
c_dtc_lam_dly_up_2 P1091 Pre-Catalyst Fuel Trim Too Rich Bank 1
P1093 Pre-Catalyst Fuel Trim Too Rich Bank 2
c_dtc_lam_lim_1 P1083 Fuel Control Mixture Lean (Bank 1 Sensor 1)
P1084 Fuel Control Mixture Rich (Bank 1 Sensor 1)
P1314 Fuel System Error
c_dtc_lam_lim_2 P1085 Fuel Control Mixture Lean (Bank 2 Sensor 1)
P1086 Fuel Control Mixture Rich (Bank 2 Sensor 1)
P1314 Fuel System Error
c_dtc_lam_stop_1 P0171 System too Lean (Bank 1)
P0172 System too Rich (Bank 1)
P1314 Fuel System Error
c_dtc_lam_stop_2 P0174 System too Lean (Bank 2)
P0175 System too Rich (Bank 2)
P1314 Fuel System Error
c_dtc_leak_big P0441 Evaporative Emission Control System Incorrect Purge Flow
c_dtc_leak_small P0442 Evaporative Emission Control System Leak Detected (small leak)
c_dtc_ls_frq_1 P0133 O2 Sensor Circuit Slow Response (Bank 1 Sensor 1)
P1087 O2 Sensor Circuit Slow Response in Lean Control Range (Bank 1 Sensor 1)
P1088 O2 Sensor Circuit Slow Response in Rich Control Range (Bank 1 Sensor 1)
c_dtc_ls_frq_2 P0153 O2 Sensor Circuit Slow Response (Bank 2 Sensor 1)
P1089 O2 Sensor Circuit Slow Response in Lean Control Range (Bank 1 Sensor 2)
P1094 O2 Sensor Circuit Slow Response in Rich Control Range (Bank 2 Sensor 1)
c_dtc_lsh_down_1 P0036 HO2S Heater Control Circuit Bank 1 Sensor 2
P0037 HO2S Heater Circuit Low Voltage Bank 1 Sensor 2
P0038 HO2S Heater Circuit High Voltage Bank 1 Sensor 2
c_dtc_lsh_down_2 P0056 HO2S Heater Circuit Bank 2 Sensor 2
P0057 HO2S Heater Circuit Low Voltage Bank 2 Sensor 2
P0058 HO2S Heater Circuit High Voltage Bank 2 Sensor 2
c_dtc_lsh_obd_down_1 P0141 O2 Sensor Heater Circuit Malfunction (Bank 1 Sensor 2)
c_dtc_lsh_obd_down_2 P0161 O2 Sensor Heater Circuit Malfunction (Bank 2 Sensor 2)
c_dtc_lsh_obd_up_1 P0135 O2 Sensor Heater Circuit Malfunction (Bank 1 Sensor 1)
c_dtc_lsh_obd_up_2 P0155 O2 Sensor Heater Circuit Malfunction (Bank 2 Sensor 1)
c_dtc_lsh_up_1 P0030 HO2S Heater Control Circuit Bank 1 Sensor 1
P0031 HO2S Heater Circuit Low Voltage Bank 1 Sensor 1
P0032 HO2S Heater Circuit High Voltage Bank 1 Sensor 1
c_dtc_lsh_up_2 P0050 HO2S Heater Circuit Bank 2 Sensor 1
P0051 HO2S Heater Circuit Low Voltage Bank 2 Sensor 1
P0052 HO2S Heater Circuit High Voltage Bank 2 Sensor 1
c_dtc_maf P0102 Mass or Volume Air Flow Circuit Low Input
P0103 Mass or Volume Air Flow Circuit High Input
c_dtc_maf_mafm P0101 Mass or Volume Air Flow Circuit Range/Performance Problem
c_dtc_mec_isa P1500 Idle Speed Control Valve Stuck Open
P1501 Idle Speed Control Valve Stuck Closed
c_dtc_mec_ivvt_ex P0015 B Camshaft Position - Timing Over-Retarded (Bank 1)
c_dtc_mec_ivvt_in P0012 A Camshaft Position - Timing Over-Retarded (Bank 1)
c_dtc_mec_sav P0411 Secondary Air Injection System Incorrect Flow Detected
c_dtc_min_saf P0491 Secondary Air Injection System Insufficient Flow Bank 1
c_dtc_mis_0 P0301 Cylinder 1 Misfire Detected
P0313 Misfire Detected With Low Fuel Level
P1342 Misfire During Start Cylinder 1
P1343 Misfire Cylinder 1 With Fuel Cut-off
c_dtc_mis_1 P0305 Cylinder 5 Misfire Detected
P0313 Misfire Detected With Low Fuel Level
P1350 Misfire During Start Cylinder 5
P1351 Misfire Cylinder 5 With Fuel Cut-off
c_dtc_mis_2 P0303 Cylinder 3 Misfire Detected
P0313 Misfire Detected With Low Fuel Level
P1346 Misfire During Start Cylinder 3
P1347 Misfire Cylinder 3 With Fuel Cut-off
c_dtc_mis_3 P0306 Cylinder 6 Misfire Detected
P0313 Misfire Detected With Low Fuel Level
P1352 Misfire During Start Cylinder 6
P1353 Misfire Cylinder 6 With Fuel Cut-off
c_dtc_mis_4 P0302 Cylinder 2 Misfire Detected
P0313 Misfire Detected With Low Fuel Level
P1344 Misfire During Start Cylinder 2
P1345 Misfire Cylinder 2 With Fuel Cut-off
c_dtc_mis_5 P0304 Cylinder 4 Misfire Detected
P0313 Misfire Detected With Low Fuel Level
P1348 Misfire During Start Cylinder 4
P1349 Misfire Cylinder 4 With Fuel Cut-off
c_dtc_mis_f P0313 Misfire Detected With Low Fuel Level
c_dtc_mis_mul P0300 Random/Multiple Cylinder Misfire Detected
c_dtc_mis_t_s P0336 Crankshaft Position Sensor A Circuit Range/Performance
c_dtc_mon_plaus P1602 Control Module Self Test, Control Module Defective
c_dtc_mon_tqi_av P1603 Control Module Self Test, Torque Monitoring
c_dtc_mon_tqi_n_max P1604 Control Module Self Test, Speed Monitoring
c_dtc_msw_2 P1565 Multifunction Steering Wheel
c_dtc_msw_3 P1565 Multifunction Steering Wheel
c_dtc_msw_tog P1567 Multifunction Steering Wheel, toggle bit
c_dtc_mtc_ctl_1 P1638 Throttle Valve Position Control; Throttle Stuck Temporarily
c_dtc_mtc_ctl_2 P1639 Throttle Valve Position Control; Throttle Stuck Permanently
c_dtc_mtc_ctl_3 P1637 Throttle Valve Position Control; Control Deviation
c_dtc_mtc_dr P1636 Throttle Valve Control Circuit
c_dtc_otcc P1477 Leakage Diagnostic Pump Reed Switch Did Not Open
c_dtc_pvs_1 P1122 Pedal Position 1 Low Input
P1123 Pedal Position 1 High Input
c_dtc_pvs_2 P1222 Pedal Position Sensor 2 Low Input
P1223 Pedal Position Sensor 2 High Input
c_dtc_pvs_bls P0xxx Simultaneous activation of accelerator pedal and brake pedal
c_dtc_pvs_bls_bts_plaus P0xxx Brakelight switch and brake test switch not plausible
c_dtc_pvs_pvs P1120 Pedal Position Sensor Circuit
c_dtc_pvs_ratio P1121 Pedal Position 1 Range/Performance Problem
c_dtc_r_igcfb P0350 Ignition Coil Primary/Secondary Circuit Malfunction
c_dtc_rly_accout P0532 A/C Refrigerant Pressure Sensor Circuit Low Input
P0533 A/C Refrigerant Pressure Sensor Circuit High Input
c_dtc_rly_efp P0231 Fuel Pump Secondary Circuit Low
P0232 Fuel Pump Secondary Circuit High
c_dtc_rly_main P1695 Main relay
c_dtc_rly_main_dly P0xxx Delay in main relay
c_dtc_sa_1 P0491 Secondary Air Injection System Insufficient Flow Bank 1
c_dtc_sa_2 P0492 Secondary Air Injection System Insufficient Flow Bank 2
c_dtc_sa_conf P0411 Secondary Air Injection System Incorrect Flow Detected
c_dtc_safm P1419 Secondary Air System Air Mass Flow Sensor Disconnected or Stuck Signal
c_dtc_sap P1413 Secondary Air Injection Pump Relay Control Circuit Signal Low
P1414 Secondary Air Injection System Monitor Circuit High
c_dtc_sap_safm P0411 Secondary Air Injection System Incorrect Flow Detected
c_dtc_sav P0413 Secondary Air Injection System Switching Valve A Circuit Open
P0414 Secondary Air Injection System Switching Valve A Circuit Shorted
c_dtc_sav_1_safm P0411 Secondary Air Injection System Incorrect Flow Detected
c_dtc_sav_safm P0411 Secondary Air Injection System Incorrect Flow Detected
c_dtc_t_igcfb_2 P0350 Ignition Coil Primary/Secondary Circuit Malfunction
c_dtc_t_lam_act P0125 Insufficient Coolant Temperature for Closed Loop Fuel Control
c_dtc_tco P0117 Engine Coolant Temperature Circuit Low Input
P0118 Engine Coolant Temperature Circuit High Input
c_dtc_tco_ex P1111 Engine Coolant Temperature Radiator Outlet Sensor Low Input
P1112 Engine Coolant Temperature Radiator Outlet Sensor High Input
c_dtc_tco_max P0116 Engine Coolant Temperature Circuit Range/Performance Problem
c_dtc_teg_down_1 P0xxx Exhaust gas temperature post-cat, bank1
c_dtc_teg_down_2 P0431 Exhaust gas temperature post-cat, bank2
c_dtc_teg_up_1 P0431 Exhaust gas temperature pre-cat, bank1
c_dtc_teg_up_2 P0431 Exhaust gas temperature pre-cat, bank2
c_dtc_tia P0112 Intake Air Temperature Circuit Low Input
P0113 Intake Air Temperature Circuit High Input
c_dtc_toil P0197 Engine Oil Temperature Sensor Low
P0198 Engine Oil Temperature Sensor High
c_dtc_tout_amt_1 P1611 Serial Communicating Link Transmission Control Module
c_dtc_tout_asr_1 P1613 Time-out ASR1
c_dtc_tout_asr_3 P1613 Time-out ASR3
c_dtc_tout_cng_ecu_1 P0xxx Time-out CNG ECU
c_dtc_tout_etcu_1 P0600 Serial Communication Link Malfunction
c_dtc_tout_icl_2 P1612 Time-out instrument cluster2
c_dtc_tout_icl_3 P1612 Time-out instrument cluster3
c_dtc_tout_imob P1661 Time-out EWS system
P1662 Time-out EWS system
c_dtc_tout_pste_1 P0xxx Time-out PowerSteering
c_dtc_tps_1 P0122 Throttle/Pedal Position Sensor/Switch A Circuit Low Input
P0123 Throttle/Pedal Position Sensor/Switch A Circuit High Input
c_dtc_tps_2 P0222 Throttle/Pedal Position Sensor/Switch B Circuit Low Input
P0223 Throttle/Pedal Position Sensor/Switch B Circuit High Input
c_dtc_tps_ad P1632 Throttle Valve Adaptation; Adaptation Condition Not Met
P1633 Throttle Valve Adaptation; Limp Home Position
P1634 Throttle Valve Adaptation; Spring Test Failed
P1635 Throttle Valve Adaptation; Lower Mechanical Stop Not Adapted
c_dtc_tps_maf_1 P0121 Throttle/Pedal Position Sensor/Switch A Circuit Range/Performance Problem
c_dtc_tps_maf_2 P0221 Throttle/Pedal Position Sensor/Switch B Circuit Range/Performance Problem
c_dtc_tps_st_chk_1 P1675 TPS stuck, sensor 1 check condition
c_dtc_tps_st_chk_2 P1694 TPS stuck, sensor 2 check condition
c_dtc_tqi_amt_1 P1653 Indicated torque not matching AMT gearbox request
P1654 Indicated torque not matching AMT gearbox request
P1670 Indicated torque not matching AMT gearbox request
c_dtc_tqi_lim P1605 Limiting criteria for indicated torque
c_dtc_tqi_n_max_nvmy_mon P1604 Control Module Self Test, Speed Monitoring
c_dtc_var_amp P1171 Ambient Pressure Sensor Learned Value Error
P1172 Ambient Pressure Sensor Rationality Check
P1173 Ambient Pressure Sensor Rationality Check
c_dtc_vcc_poti_1 P1624 Pedal Position Sensor Potentiometer Supply Channel 1 Electrical
c_dtc_vcc_poti_2 P1625 Pedal Position Sensor Potentiometer Supply Channel 2 Electrical
c_dtc_vdmtl P1451 Diagnostic Module Tank Leakage (DM-TL) Switching Solenoid Control Circuit Signal Low
P1452 Diagnostic Module Tank Leakage (DM-TL) Switching Solenoid Control Circuit Signal High
c_dtc_vim P1512 DISA Control Circuit Signal Low
P1513 DISA Control Circuit Signal High
c_dtc_vls_down_1 P0137 O2 Sensor Circuit Low Voltage (Bank 1 Sensor 2)
P0138 O2 Sensor Circuit High Voltage (Bank 1 Sensor 2)
P0140 O2 Sensor Circuit No Activity Detected (Bank 1 Sensor 2)
c_dtc_vls_down_2 P0157 O2 Sensor Circuit Low Voltage (Bank 2 Sensor 2)
P0158 O2 Sensor Circuit High Voltage (Bank 2 Sensor 2)
P0160 O2 Sensor Circuit No Activity Detected (Bank 2 Sensor 2)
c_dtc_vls_down_act_chk_1 P1143 ???
P1144 ???
c_dtc_vls_down_act_chk_2 P1149 ???
P1150 ???
c_dtc_vls_down_afl_1 P0139 O2 Sensor Circuit Slow Response (Bank 1 Sensor 2)
c_dtc_vls_down_afl_2 P0159 O2 Sensor Circuit Slow Response (Bank 2 Sensor 2)
c_dtc_vls_down_post_puc_1 P1097 O2 Sensor Circuit Slow Response after Coast Down Fuel Cutoff (Bank 1 Sensor 1)
c_dtc_vls_down_post_puc_2 P1098 O2 Sensor Circuit Slow Response after Coast Down Fuel Cutoff (Bank 2 Sensor 2)
c_dtc_vls_down_t_1 P0139 O2 Sensor Circuit Slow Response (Bank 1 Sensor 2)
c_dtc_vls_down_t_2 P0159 O2 Sensor Circuit Slow Response (Bank 2 Sensor 2)
c_dtc_vls_jump_1 P1088 O2 Sensor Circuit Slow Response in Rich Control Range (Bank 1 Sensor 1)
P1119 ???
P1178 O2 Sensor Signal Circuit Slow Switching From Rich to Lean (Bank 1 Sensor 1)
c_dtc_vls_jump_2 P1095 O2 Sensor Circuit Slow Switching From Lean to Rich (Bank 1 Sensor 1)
P1096 O2 Sensor Circuit Slow Switching From Lean to Rich (Bank 2 Sensor 1)
P1114 ???
c_dtc_vls_stk_1 P0136 O2 Sensor Circuit Malfunction (Bank 1 Sensor 2)
c_dtc_vls_stk_2 P0156 O2 Sensor Circuit Malfunction (Bank 2 Sensor 2)
c_dtc_vls_up_1 P0131 O2 Sensor Circuit Low Voltage (Bank 1 Sensor 1)
P0132 O2 Sensor Circuit High Voltage (Bank 1 Sensor 1)
P0134 O2 Sensor Circuit No Activity Detected (Bank 1 Sensor 1)
c_dtc_vls_up_2 P0151 O2 Sensor Circuit Low Voltage (Bank 2 Sensor 1)
P0152 O2 Sensor Circuit High Voltage (Bank 2 Sensor 1)
P0154 O2 Sensor Circuit No Activity Detected (Bank 2 Sensor 1)
c_dtc_vs P0500 Vehicle Speed Sensor Malfunction

Extra Features

Idle Control Valve Delete

Removing the idle control valve (ICV) / idle speed actuator (ISA) is possible due to the motorized throttle body the M54 engine uses.

Disconnect the idle control valve connector and either remove the idle control valve and plug the hole in the intake manifold (preferred) or use something to seal the idle control valve air tight.

The way the ICV delete works is by utilizing the ip_pvs_isa_isapwm table. This table dictates how much pvs input should be added to the drivers requested pvs input for a given idle control valve load.

In a stock engine this table is used to extend the idle control valve load so when the idle control valve load goes above 100% the throttle will start to open to deliver more air into the engine.

By rescaling this table we are able to completely remove the idle control valve.

But be aware that the values in ip_pvs_isa_isapwm is dependent on the values in ip_tps_sp_pvs so if ip_tps_sp_pvs is modified then ip_pvs_isa_isapwm also needs to be re-scaled accordingly to maintain a stable idle.

The ip_pvs_isa_isapwm values in the picture are made for a M54B30 so the values may need to be modified to get a stable idle with M54B25 and M54B22 as these engines have a smaller throttle body.

This modification modifies a monitoring table so the calibration addition checksum needs to be corrected or disabled after applying the changes.

Check here for more information about checksums.

Exhaust Pop Modifications

The current solution for forced exhaust pop is to change the overrun fuel cutoff detection from the ECU. This is accomplished by raising the minimum RPM threshold to a number of revolutions the engine can't reach.

This behaviour can be set different depending on your air condition is turned on or off, because the MS43 has two seperate tables for overrun fuel cutoff handling depending on the engine state ACCIN.

Note: Theorethically every engine state can be used to switch between the two tables. Another one that could be handy is CRU_MAIN_SWI, this state is also represented by the green cruise control light in the cluster. Requires program code editting.


Exhaust pops with activated A/C

TunerPro depiction of overrun fuelcut mod

This screenshot shows the values to have pops when A/C is on. To get exhaust pops with the A/C disabled leave the lower tables stock and only edit the uper ones.

Using these settings B25 engine users have reported throttle hang, poor idling, and decreased performance. Test these settings at your own responsibility.


Timer configurable exhaust pops

It is also possible to tweak gear related timers that will let the engine pop for a given time. After this timer is zero, the engine will go back into overrun-fuelcut. So it's pretty easy to have 2 or 3 pretty loud pops followed by "silence".

The following screenshot is an example for the values at M54B30 which give 3 loud pops.

TunerPro depiction of timered overrun fuelcut mod

If you want to relay fuel cutoff while standing, adjust c_t_puc_deacc_vs to your desired time.


For anyone wanting the best of both worlds:

TunerPro depiction of combined overrun fuelcut mod

Forced OBD Readiness

Common solution for forced OBD readiness monitors seems to be setting the following config switches

File:ForcedOBD.jpg
TunerPro depiction of config switches


  • c_conf_eobd If this value is set to one then the ECU will be able to report the traveled distance with the MIL active.
  • c_obd_diag_state This value represents which OBD standard that the ecu complies to. If set to one the ecu will report that it complies to the OBD-II standard as defined by CARB. A full list of what the values corresponds to can be found here under the "Service 01 PID 1C" section.

Engine coolant temperature control

The M54 engine family is fitted with an e-thermostat that the ecu can control to alter the engine coolant temperature. By altering these values we can change how hot the engine will run in different conditions.

  • c_tam_min_ect - Minimum ambient temperature threshold for e-thermostat activation
  • c_tia_min_ect - Minimum intake air temperature threshold for e-thermostat activation
  • c_toil_min_ect - Minimum oil temperature threshold for e-thermostat activation
  • c_tia_max_ect - Maximum intake air temperature threshold. When exceeded target coolant temperature will be set to c_tco_sp_tia_max
  • c_tco_ex_max_ect - Maximum radiator outlet temperature threshold. When exceeded target coolant temperature will be set to c_tco_sp_tco_ex_max
  • c_toil_max_ect - Maximum oil temperature threshold. When exceeded target coolant temperature will be set to c_tco_sp_tia_max
  • c_tco_sp_toil_min - Target coolant temperature until the thresholds set by c_toil_min_ect, c_tam_min_ect, and c_tia_min_ect are exceeded.
  • c_tco_sp_tco_ex_max - Target coolant temperature if c_tco_ex_max_ect is exceeded
  • c_tco_sp_tia_max - Target coolant temperature if c_toil_max_ect or c_tia_max_ect are exceeded
  • c_tco_bol_ect - Target coolant temperature if an external low coolant temperature request has been received
  • c_tco_min_ect - Minimum coolant temperature threshold for full energization of the e-thermostat
  • id_tco_sp_ect__n__maf_sub - Target coolant temperature when c_toil_min_ect, c_tam_min_ect, and c_tia_min_ect are exceeded - AC off
  • id_tco_sp_ect_acin__n__maf_sub - Target coolant temperature Target coolant temperature when c_toil_min_ect, c_tam_min_ect, and c_tia_min_ect are exceeded - AC on
  • ip_ectpwm_i__tco_dif - e-thermostat I component
  • ip_ectpwm_p__tco_dif - e-thermostat P component
  • id_ectpwm_add__n__tco_sp - Required e-thermostat duty cycle to achieve coolant temperature setpoint


TunerPro depiction of Coolant Maps

Secondary Air Pump Delete

For forced OBD Readiness set C_CONF_SAP: "1"

Lambda Sensor Configuration

Constant "c_conf_cat" has five different options which represent the ecu´s ability to work with different lambda probe setups.

Set the following values that suit you needs:

  • 0: Single bank with one pre-cat lambda sensor or cat-preparation (SA199)
  • 1: Twin bank with two pre-cat lambda sensors or cat-preparation (SA199) and automatic learning of postcat sensors
  • 2: Single bank with one precat lambda sensor and one post-cat lambda sensor
  • 3: Twin bank with two pre-cat lambda sensors and one post-cat lambda sensors
  • 4: Twin bank with two pre-cat lambda sensors and two post-cat lambda sensors

The automatic learning process of post-cat lambda sensors starts after deleting "learned variants" with INPA.

After installing catless headers, it could be useful to eliminate post-cat sensors with setting "c_conf_cat" to "1".

MAF Sensor Scalar Adjustments

The standard MAF sensor map is a non-interpolated 16*16 lookup table, that can also be shown as 1*256 "voltage (v) vs. airflow (kg/h)" table. The 10 bit analog to digital conversion is reduced to 8 bits and 4 bits of each are used to lookup the MAF value.

There are differences in flow between the M54B22/M54B25 and M54B30 MAF sensors, as the diametre is different. Differences in cross sectional area would be expected to rescale the values, but the sensor is part of the tube and not easily modified.

Replacement slot type sensors (Ford based) are often used in high output blow through configurations for turbocharging, as the BMW OEM sensors are not well suited to boost in blow through setup.

"Engine load (mg/stroke) is proportional to "airflow (kg/h)" divided by RPM and is used to reference most of the important injection and ignition tables.

There is a factory airflow limit of 1024kg/h that can be doubled or quadrupled with a patch that has undergone basic testing, but the maximum engine load is still limited to 1389mg/stroke, unless there are massive code rewrites.

A M54B30 pulls about 600mg/stroke in cold conditions with a maximum airflow of about 630kg/h.

Changes to MAF tables should be kept smooth and progressive. Fuel trims plotted against MAF voltage can be used to fine tune the closed loop areas.

RPM limiter

The Siemens MS43 has two gear dependant rpm limiters, a softlimiter and a hardlimiter for each gearbox type (manual or automatic transmission).

The softlimiter works by cutting injectors based on fuelcut pattern, whereas the hardlimiter immediately cuts off all cylinders.

  • ID_N_MAX_AT: softlimiter for AT gearbox
  • ID_N_MAX_MAX_AT: hardlimiter for AT gearbox
  • ID_N_MAX_MT: softlimiter for MT gearbox
  • ID_N_MAX_MAX_MT: hardlimiter for MT gearbox

In addition to that, you will want to raise "ID_N_MAX_VS_MAX_AT" or "ID_N_MAX_VS_MAX_MT" slightly above the hardlimiter.

The Siemens MS43 gets it's vehicle speed signal (_VS) from the ABS control unit and not from a sensor inside the differential, like older chassis.

In case the ECU doesn't get a valid vehicle speed signal, for example when you put an M54 engine in an older chassis, or strip out the ABS block for weight reasons, a third RPM limiter is applied:

  • C_N_MAX_VS_DIAG: RPM limiter in case of missing vehicle speed

VMAX limiter

The Siemens MS43 has two gearbox dependant speed limiters, set them to 255 to have unrestricted vehicle speed.

  • C_VS_MAX_AT_1
  • C_VS_MAX_MT_1

Fake Race Camshafts / Lumpy Idle Mod

Faking some serious camshafts is pretty easy as M54 engine has adjustable camshafts. So basically whats happening when going camshafts is, the valve overlap will be increased by a huge amount. This means, intake and exhaust valves are open at the same time.

  • ip_cam_sp_tco_1_ex_is__n__maf_iv
  • ip_cam_sp_tco_2_ex_is__n__maf_iv
  • ip_cam_sp_tco_1_in_is__n__maf_iv
  • ip_cam_sp_tco_2_in_is__n__maf_iv
  • c_n_min_er >idlespeed, to not trigger during when engine idles lumpy.

Max adjustable value for the different engine specs:

Vanos specs

The biggest valve overlap will be achieved when using the lowest adjustable value on the intake side (80° respectively 86°) and the lowest adjustable value on the exhaust side (-80°)

TunerPro depiction of min allowed Vanos setpoints


A good starting point for further optimization could be:

TunerPro depiction of GhostCam mod

Safety Features

The following information need to be handled with care as you´re able to turn off safety features! This can lead to severe damage and you´re doing so at your own risk!

Misfire Detection

  • c_n_min_er: minimum engine speed for detection of misfire!
  • c_n_max_er: maximum engine speed for detection of misfire!

Knock Detection

  • id_iga_dec_knk_1__n: ignition angle reduction based on knock stage1
  • id_iga_dec_knk_2__n: ignition angle reduction based on knock stage2

Injection Adaptation

  • c_n_ti_ad_fac_min: min engine speed to allow adapation of fuel trim, multiplicative
  • c_n_ti_ad_add_max: max engine speed to allow adapation of fuel trim, additive

Special Functions

Please look here for the special functions that need licencing: Daniel_F._Special_Functions

Here are some handy mods when going forced induction Forced_Induction_Upgrades

M Cluster LED Control

After swapping in an M3 cluster into a E46 or M5 cluster into E39, there is no more ecometer displaying the momentary fuel consumption, but a more useful oiltemperature gauge.

Using this cluster and some additional code we can also control the LEDs around the RPM gauge to work similar to the E46 M3 and also manage shiftlights behaviour.

Following maps are used:

  • id_icl_led__n - Warmuplights - LED switchpoints for the given temperature
  • ldpm_toil_led - Warmuplights - axis defining the oiltemperature range in °C
  • id_icl_led__n - Shiftlights - LED switchpoints for the given temperature
  • ldpm_toil_led - Shiftlights - axis defining the rpm range

Explaination for the decimal values used:

  • 112 - all LEDs lit
  • 96 - 4500 and upwards
  • 80 - 5000 and upwards
  • 64 - 5500 and upwards
  • 48 - 6000 and upwards
  • 32 - 6500 and upwards
  • 16 - 7000 and upwards
  • 00 - 7500 lit
  • 01 - oil warning LED yellow (M5)
  • 02 - oil warning LED yellow
  • 04 - coolant warning LED

Download the warmup and shiftlights patch for TunerPro depending on your software version:

Use with 512kByte file only. Checksum correction required!

M3 Cluster warmuplight maps M3 Cluster shiftlight maps

Launch Control

TunerPro launch control maps

Setting up LC:

Set the following maps in TunerPro:

Configuration Launch Control

  • Launch_PVS_min (i suggest to set this switch over 50% and UNDER 70%. Anything different may lead to non-working LC)
  • Launch_TCO_min (and this to "-48" )
  • Launch_RPM_max
  • Launch_VS_max (set to "1")

Using LC:

  1. Make sure coolant temp is equal or above the threshold and ASC/DSC is turned off
  2. Depress the clutch pedal
  3. Put car into first gear
  4. Floor the accelerator pedal! (At least that °PVS matches the threshold!)
  5. Engine speed should bounce at chosen rpm setpoint. There may be offset which engine speed bounces, like +/- 200rpm
  6. Release clutch pedal while holding accelerator pedal down.
  7. Engine speed will be reduced until vehicle speed exceeds chosen threshold (currently not working!)


Engine RPM setting may be adjusted according to road conditions/tire setup, in order to minimize wheel spin.

For additional aggressiveness set "c_n_max_hys_max" to 32 or 64, then LC is much less bouncy

Example video:

Alternative for non working LC

LC fix Brakeswitch.jpg

Map reduction "fewmaps"

The _fewmaps file reduces the number of used maps to the following ones:

  • Injection
    • Idlespeed: ip_ti_tco_1_is_ivvt__n__maf
    • Part load: ip_tib__n__maf
    • Full load:
  • Ignition
    • Idlespeed: ip_igab_is__n__maf
    • Part- & full loadip_igab__n__maf
  • VANOS
    • Idle speed: IP_CAM_SP_tco_1_IN_IS / IP_CAM_SP_tco_1_EX_IS
    • Part load: IP_CAM_SP_tco_1_IN_PL / IP_CAM_SP_tco_1_EX_PL
    • Full load: IP_CAM_SP_tco_1_IN_FL / IP_CAM_SP_tco_1_EX_FL

This is great for finding basemaps.