ECM-5554-112: Difference between revisions
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== | ==Overview== | ||
<gallery> | <gallery> | ||
File:ECM-5554-112.jpg|[ | File:ECM-5554-112.jpg|[https://store.neweagle.net/shop/products/controllers/motohawk-controllers/ecm-engine-control-modules/5554-112-0904-calibratable-engine-control-module/ ECM-5554-112] | ||
</gallery> | </gallery> | ||
===Product Summary=== | ===Product Summary=== | ||
This is a high-end control module family capable of operating in harsh automotive, marine | This is a high-end control module family capable of operating in harsh automotive, marine and off-highway applications. The family and its connector system are environmentally sealed and suitable for engine mounting in many applications. Each controller is available in 'F' (flash) or 'C' (calibratable) versions. Flash modules are typically used for production purposes, while calibratable modules are typically for prototyping/development only and can be calibrated in real time using MotoTune. | ||
These modules are based on Freescale MPC5553 or 5554 processors running at 80 MHz. The 112-pin modules offer a full complement of memory storage, 3 CAN channels, and many digital and analog I/O including frequency, crank position, | These modules are based on Freescale MPC5553 or 5554 processors running at 80 MHz. The 112-pin modules offer a full complement of memory storage, 3 CAN channels, and many digital and analog I/O including frequency, crank position, DSP knock detection and EGO oxygen sensor inputs. Typical applications include EV/HEV supervisory control and full OBD2 8-cylinder sequential engines. | ||
'''Features include:''' | |||
*Motorola MPC5554, 80MHz Microprocessor | |||
*Operating voltage: 9-16VDC, 24V (Jump start), 4.5V (Crank) | |||
*Operating temperatures ranging from -40°C to 105°C | |||
*ECU weight: 0.82 kg (1.8 lbs.) | |||
'''Family includes:''' | |||
*ECM-5554-112-0902 | |||
*ECM-5554-112-0904 | |||
===Datasheets=== | ===<div style="font-size:21px; width:75%; font-weight:bold; text-align:left; padding-top:7px; padding-bottom:7px; background:#800020; color:white;">Datasheets</div>=== | ||
'''[ | '''ECM-5554-112-0902''' | ||
:'''Please contact [mailto:sales@neweagle.net sales]''' | |||
In the ECM-5554-112 | '''ECM-5554-112-0904''' | ||
:'''[http://neweagle.net/support/wiki/ProductDocumentation/Controllers/ECM‐5554‐112/ECM-5554-112-0904_DataSheet.pdf Datasheet]''' | |||
'''ECM-5644-112-064-1400-C''' | |||
:'''[http://Neweagle.net/support/wiki/ProductDocumentation/MotoTron/Controllers/36373rev100.pdf Datasheet]''' | |||
:'''[https://www.neweagle.net/support/wiki/ProductDocumentation/MotoTron/Controllers/35041_0.pdf Hardware Manual]''' | |||
'''GCM-5554-112-1001-C/F''' | |||
:'''[http://Neweagle.net/support/wiki/ProductDocumentation/Controllers/GCM-5554-112/GCM-5554-112_DataSheet.pdf Datasheet]''' | |||
===Known Datasheet Errata=== | |||
In the ECM-5554-112 family of controllers datasheet, the block diagram of ECM-5554-112-0902 (page 4) has C-H4 and C-G4 switched around: | |||
C-G4 goes with HBRIDGE1A and C-H4 goes with HBRIDGE1B. | C-G4 goes with HBRIDGE1A and C-H4 goes with HBRIDGE1B. | ||
In the ECM-5554-112 | In the ECM-5554-112 family of controllers datasheet, there is an error on page 12 that lists the pin B-C3 twice. | ||
AN18M is labeled as B-C3, but it should be B-C4. | |||
===Targets=== | |||
The PCM112-14 has different targets for the main and the S12G auxiliary processor as shown below: | |||
Main Processor | |||
:1751-6685: Target ECM-5644A-112-064-1400 | |||
Auxiliary Processor | |||
:Target ECM-S12G-112-063-1400 PROD Only | |||
<!-- Removed 3-15-23 | |||
=== 3D CAD Data === | === 3D CAD Data === | ||
[[CAD Drawings]] | [[CAD Drawings]] | ||
--> | |||
===Part Number Decoder Ring=== | ===Part Number Decoder Ring=== | ||
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*ECM-5554-112-0902-kP: PCM0902 module with knock development interface, PV release hardware | *ECM-5554-112-0902-kP: PCM0902 module with knock development interface, PV release hardware | ||
*ECM-5554-112-0902-xD: PCM0902 module, DV release hardware | *ECM-5554-112-0902-xD: PCM0902 module, DV release hardware | ||
===Pull- | |||
*Use this target for ECM-5554-112-0902-F00 ("PROD") and ECM-5554-112-0902-CP0 ("DEV") modules: | |||
*:ECM-5554-112-0902-xP: PCM0902 module, PV release hardware | |||
*Use this target for ECM-5554-112-0904-F00 ("PROD") and ECM-5554-112-0904-CP0 ("DEV") modules: | |||
*:ECM-5554-112-0904-xD: PCM0904 module, DV and PV release hardware | |||
===Pull-Up and/or Pull-Down on the Analog Inputs of the 5554-112=== | |||
[[Image:ECM-5554-112.JPG]] [[Image:ECM-5554-112.2.JPG]] | [[Image:ECM-5554-112.JPG]] [[Image:ECM-5554-112.2.JPG]] | ||
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Restrictions on Certain Hazardous Substances (EU RoHS) Directive 2002/95/EC requires that certain electrical and electronic products be free (except for trace impurities) of mercury, cadmium, hexavalent chromium, PBB, PBDE and lead as of 2006-7-1. Certain exemptions are allowed such as lead used as an alloying additive in copper, steel and aluminum. These products comply with the EU RoHS directive. These products also comply with the ELV directive. Note that as of July 1, 2008 products that are shown as RoHS compliant do not contain decabromodiphenyl ether. | Restrictions on Certain Hazardous Substances (EU RoHS) Directive 2002/95/EC requires that certain electrical and electronic products be free (except for trace impurities) of mercury, cadmium, hexavalent chromium, PBB, PBDE and lead as of 2006-7-1. Certain exemptions are allowed such as lead used as an alloying additive in copper, steel and aluminum. These products comply with the EU RoHS directive. These products also comply with the ELV directive. Note that as of July 1, 2008 products that are shown as RoHS compliant do not contain decabromodiphenyl ether. | ||
=== General Purpose Use of Knock | === General-Purpose Use of Knock Pins === | ||
The knock sensor pins are dedicated | The knock sensor pins are dedicated and have no alternate purpose other than knock detection. One exception is that this circuitry is known to be used as a hardware "notch" filter. | ||
===Powering the ECM-5554-112-0904 (PCM0904)=== | ===Powering the ECM-5554-112-0904 (PCM0904)=== | ||
Line 70: | Line 98: | ||
'''The 112-pin modules are nominal 12-volt:''' | '''The 112-pin modules are nominal 12-volt:''' | ||
:*VBATT (min) = 4. | :*VBATT (min) = 4.5V (crank transient) and 6.3V (continuous). | ||
:*VBATT (normal) = 9- | :*VBATT (normal) = 9-16V. | ||
This voltage is expected at the BATT, BATT2, KEYSW, DRVG1, DRVG2, fuel injector, H-bridge | This voltage is expected at the BATT, BATT2, KEYSW, DRVG1, DRVG2, fuel injector, H-bridge and low-side drivers. | ||
'''Specifics:''' | '''Specifics:''' | ||
''High Voltage Operation'' | ''High Voltage Operation'' | ||
Measure the Jump Start voltage at the BATT pin, referenced to the PWRGND pins. The module should operate normally when exposed to 24 volts for 5 minutes at an ambient temperature of 23°C. | |||
''Reverse Battery Connection'' | ''Reverse Battery Connection'' | ||
The module | |||
The module will not be damaged by 5 minutes of reverse battery (-12 volts). This is a system level test and assumes a correct harness is in use. Specifically, it is assumed that the main power relay will be off. | |||
''Abnormal Connections'' | ''Abnormal Connections'' | ||
The module | |||
The module will not be damaged by short to ground, short to battery, or intermittent open-circuit faults on any I/O signal. The following signals are excluded from this requirement since they are power rails that are not protected against shorts: | |||
*PWRGND (not protected from short to battery). | |||
*DRVP (not protected from short to ground). | |||
*XDRG (not protected from short to battery). | |||
*GNDREF (not protected from short to battery). | |||
Note: | '''Note:''' For purposes of test, it may be assumed that DRVP is applied to the system prior and during the abnormal connection test. | ||
=== Frequency (Speed) Inputs Notes === | === Frequency (Speed) Inputs Notes === | ||
Line 99: | Line 129: | ||
SPEED1 (B-G2), SPEED2 (B-H2), SPEED3 (B-H1) logic thresholds and hysteresis are hardware configurable. However, this option is not available in MotoHawk, but might be added in the future. | SPEED1 (B-G2), SPEED2 (B-H2), SPEED3 (B-H1) logic thresholds and hysteresis are hardware configurable. However, this option is not available in MotoHawk, but might be added in the future. | ||
SPEED1 - This input is normally used to resolve a variable frequency digital speed signal. | SPEED1 - This input is normally used to resolve a variable frequency digital speed signal. Software will be capable of selecting either a high impedance mode for 0-5V sensors or 1kΩ pull-up to 5 volts for open-drain type sensors, however this option is not available on present versions of MotoHawk. The default value is 1K, when not software selected. | ||
Software will be capable of selecting either a high impedance mode for 0 | |||
SPEED2 and 3 - | SPEED2 and 3 - These inputs are normally used to resolve a variable frequency digital speed signal. The sensor will provide a 0-5V signal. Note, the sensor is expected to be a low-side driver with internal pull-up to 5 volts of ~ 4.7kΩ. | ||
The sensor | |||
Note: The SPEED1, CAM | '''Note:''' The SPEED1, CAM and CNK inputs have the hardware ability on the 112 controllers to select a pull-up resistor. The block Passive Pull Strength was added in 2011a to choose this option; however, only the Crank_DG presently has that ability. It is planned to add this functionality for the CAM and SPEED1 inputs, probably in 2012a MotoHawk. | ||
=== Differences | === Differences Between the 0902 and 0904 === | ||
Here is the full list of changes from PCM0902 to PCM0904. | Here is the full list of changes from PCM0902 to PCM0904. | ||
#Removed the H1 H-Bridge and replaced it with two Infineon BTN7930 ½ Bridge devices. | |||
#Removed the H2 H-Bridge and replaced it with two Infineon BTN7930 ½ Bridge devices. | |||
#Removed the On Semi NIF5002 Injector Drivers and replaced with the On Semi NCV8403. | |||
#Removed the TACHLINK transistor (PZT3904) and replaced it with BFN38 device. | |||
#Routing of case ground traces to pin B-C3 (replaces CAN2 shield pin). | |||
The new H-Bridges are more capable than the older parts and can be run at up to 10A depending on total ECU power dissipation. The injector driver change allows the option to run two injectors per driver (2A max) but, again, power dissipation must be considered. The TACHLINK change was to address robustness to transients. | |||
The new H-Bridges are more capable than the older parts and can be run at up to 10A depending on total ECU power dissipation. | |||
An interesting point to | An interesting point to note while using 0902 modules is that, while trying to work with the Motohawk H-bridge output block, the resource allocation might show 'None'. It is because that block is not exposed to the H-bridge pins in the 0902 controller. In this case, using the Motohawk PWM block can give you exactly the same results with the correct resources on the 0902 module. | ||
=== CAN Shielding Differences Between 0902 and 0904 === | === CAN Shielding Differences Between 0902 and 0904 === | ||
For ECM-5554-112-0902 (PCM0902): | For ECM-5554-112-0902 (PCM0902): | ||
CAN_1 is not shielded, | |||
CAN_2 is shielded, not internally terminated. | CAN_1 is not shielded, nor internally terminated. | ||
CAN_3 is shielded | |||
CAN_2 is shielded, but not internally terminated. | |||
CAN_3 is shielded and internally terminated at 120Ω. | |||
CANSHIELD2 and CANSHIELD3 are available for shielded bus connections on the respective buses. The internal connection to the PCM ground consists of a 1Ω resistor in series with a 10 nano-farad capacitor (i.e., no DC path). CAN shielding is not always standardized and this implementation may or may not be appropriate for any specific application. | |||
For ECM-5554-112-0904 (PCM0904): | |||
CAN_1 is not shielded, nor internally terminated. | |||
CAN_2 is not shielded, nor internally terminated. | |||
CAN_3 is shielded and internally terminated at 120Ω. | |||
CANSHIELD3 is available for shielded bus connections. The internal connection to the PCM ground consists of a 1Ω resistor in series with a 1 micro-farad capacitor (i.e., no DC path). CAN shielding is not always standardized and this implementation may or may not be appropriate for any specific application. | |||
For the PCM0904 model, pin B-C3 was changed from CAN2 SHIELD to CASEGND. For typical applications, the CASEGND pin should be left unconnected. | |||
Note the change in capacitor value for the shield between PCM0902 and PCM0904. | Note the change in capacitor value for the shield between PCM0902 and PCM0904. | ||
===CAN Transceiver Notes=== | ===CAN Transceiver Notes=== | ||
The 112 pin module uses an Infineon TLE 6250G transceiver. TLE 6250 is a high speed transceiver with the following features: | The 112-pin module uses an Infineon TLE 6250G transceiver. TLE 6250 is a high-speed transceiver with the following features: | ||
*CAN data transmission rate up to 1 MBaud | *CAN data transmission rate up to 1 MBaud | ||
*Receive-only Mode and Stand-by Mode | *Receive-only Mode and Stand-by Mode | ||
*Suitable for | *Suitable for 12V and 24V applications | ||
*Excellent EMC performance (very high immunity and very low emission) | *Excellent EMC performance (very high immunity and very low emission) | ||
*Version for | *Version for 5V and 3.3V microcontrollers | ||
*Bus pins are short circuit proof to ground and battery voltage | *Bus pins are short circuit proof to ground and battery voltage | ||
*Overtemperature protection | *Overtemperature protection | ||
Line 159: | Line 188: | ||
*AEC Qualified | *AEC Qualified | ||
The RF capacitors are 100pF and there is a Zener set for transient protection. | The RF capacitors are 100pF and there is a Zener set for transient protection. | ||
=== 0904 Models without XDRP1 Capacitor === | === 0904 Models without XDRP1 Capacitor === | ||
Differences between VP9DVU12A650-AA and VP9DVU-12A650-AB: | |||
VP9DVU-12A650-AA lacks a 10nF ESD capacitor on the XDRP1 (5V sensor supply) at J1C-D4. The lack of this capacitor leaves the module susceptible to radiated noise coupled onto the application harness. The coupled noise can cause instability in the XDRP1 voltage supply or module resets. Vehicle EMC issues were experienced during Free Field testing at approximately 23V/m and 140-180MHz. | VP9DVU-12A650-AA lacks a 10nF ESD capacitor on the XDRP1 (5V sensor supply) at J1C-D4. The lack of this capacitor leaves the module susceptible to radiated noise coupled onto the application harness. The coupled noise can cause instability in the XDRP1 voltage supply or module resets. Vehicle EMC issues were experienced during Free Field testing at approximately 23V/m and 140-180MHz. | ||
Line 169: | Line 198: | ||
To avoid the issue, the XDRP1 output should be disconnected from the wiring harness. If the XDRP1 output is required, a ferrite choke can be used to filter the noise. Placing a FairRite 43 material solid ferrite or Steward 28 clamp ferrite on the harness wire leading to XDRP1 within one inch of the mating connector will resolve the issue. | To avoid the issue, the XDRP1 output should be disconnected from the wiring harness. If the XDRP1 output is required, a ferrite choke can be used to filter the noise. Placing a FairRite 43 material solid ferrite or Steward 28 clamp ferrite on the harness wire leading to XDRP1 within one inch of the mating connector will resolve the issue. | ||
VP9DVU-12A650-AB incorporates a very small change to the PWB connecting a 10nF capacitor to the XDRP1 J1 pin making the module immune to radiated and coupled noise. | VP9DVU-12A650-AB incorporates a very small change to the PWB connecting a 10nF capacitor to the XDRP1 J1 pin, making the module immune to radiated and coupled noise. | ||
=== What is the LSO output interface? === | === What is the LSO output interface? === | ||
LSO 6 and 7 are designed for O2 heater control, and they make nice, general-purpose low-side drives. The FETs are controlled via an MC33800 pre-driver. The drive IC datasheet, a Freescale MC33800, is found at '''[http://www.freescale.com/webapp/sps/site/prod_summary.jsp?code=MC33800 MC33800 driver]'''. In addition, there is a 10 nF cap on the input for ESD. | |||
=== What is the nominal current draw of the ECM-5554-112? === | === What is the nominal current draw of the ECM-5554-112? === | ||
Line 189: | Line 218: | ||
*AN32 | *AN32 | ||
*AN33 | *AN33 | ||
It is not uncommon to get some extra ADC noise for the pins connected to the VISTA chip, and we have surmised that ADC counts to temperature calculation logic | It is not uncommon to get some extra ADC noise for the pins connected to the VISTA chip, and we have surmised that ADC counts to temperature calculation logic tend to magnify this variation. We recommend that these inputs only be used for sensors that can tolerate that range of variation. | ||
The AN32 and AN33 inputs also have a selectable reference (not exposed in MotoHawk). Prior to MotoHawk 2010b they had been set to use a 1.6V reference. 2010b and on use a 5V reference. So, for MotoHawk 2010A and older you need to use an extension file to set the reference voltage to 5V. | |||
====Analog Input Resolution==== | ====Analog Input Resolution==== | ||
The ECM-5554-112 module has 12 bit resolution for the analog inputs, instead of the 10 bit available on the other MotoHawk ECUs. To get the 12 bit resolution you need to assign it in the Analog Input block. | The ECM-5554-112 module has 12-bit resolution for the analog inputs, instead of the 10-bit available on the other MotoHawk ECUs. To get the 12-bit resolution, you need to assign it in the Analog Input block. | ||
=== Speed Inputs = Hall Effect === | === Speed Inputs = Hall Effect === | ||
Speed 1, Speed 2 and Speed 3 are Hall Effect type inputs. | |||
===XDRP Current Capability=== | ===XDRP Current Capability=== | ||
As mentioned on the datasheet, the independent current capability of XDRP1 is 50 mA and that of XDRP2 is 100 mA. In other words, each of them is connected to a separate pin on the power supply chip. Further, the same voltage (XDRP1 or 2)is used to reference pulled up AN inputs. | As mentioned on the datasheet, the independent current capability of XDRP1 is 50 mA and that of XDRP2 is 100 mA. In other words, each of them is connected to a separate pin on the power supply chip. Further, the same voltage (XDRP1 or 2) is used to reference pulled up AN inputs. | ||
===Key-Off Timer=== | ===Key-Off Timer=== | ||
The 0904 module has a Key-Off Timer feature which can keep track of the time | The 0904 module has a Key-Off Timer feature which can keep track of the time it's keyed OFF. This may be used with additional logic to create a clock output in some applications. | ||
===Boot Key Recovery=== | ===Boot Key Recovery=== | ||
We have found that the 112 pin modules tend to be faster in booting up than the boot key. So when recovering this module with a boot key, it may help to apply power to the boot key first and the module a few seconds afterwards. For instance, turn the power supply on with the module unplugged, start MotoTune programming, then plug the ECU into the junction box a few seconds later. | We have found that the 112 pin modules tend to be faster in booting up than the boot key. So, when recovering this module with a boot key, it may help to apply power to the boot key first and the module a few seconds afterwards. For instance, turn the power supply on with the module unplugged, start MotoTune programming, then plug the ECU into the junction box a few seconds later. | ||
The CAN baud rate must be set to 250kbps during boot key recovery. | |||
===Measuring Current | ===Measuring Current from the H-Bridge=== | ||
In Simulink you can request to read a current output from the | In Simulink you can request to read a current output from the H-bridge driver. The current is read from the driver chip across a sense resistor and "delivers a current proportional to the forward load current flowing through the active high side switch". The current is directly measured from the pin. So, the current measured would be affected by the load characteristics combined with the parallel sense resistor. Also, if the PWM block is outputting a frequency, instead of being in steady state, then the meter may be giving a calculated RMS current which would differ by a constant multiplier. If the high side switch is inactive or the current is flowing in the reverse direction, no current will be driven except for a marginal leakage current. | ||
=== Low Voltage Operation === | === Low Voltage Operation === | ||
The | The datasheet says the 112 module works from 9-16V. It is actually designed to run at 6.3V continuous. It has been known to work at a "bit less", but this is not guaranteed on every unit. | ||
9V is the min ‘normal’ range. 6.3V is the min without reset (during cranking) but the system will not be able to operate at that voltage since relays will not close and some ICs will fault for low battery voltage. | |||
==Webstore== | ==Webstore== | ||
'''[ | '''[https://store.neweagle.net/product-category/products/controllers/motohawk-controllers/ecm-engine-control-modules/ Motohawk Engine Control Modules]''' | ||
'''[ | ==Other Modules== | ||
'''[[Controllers]]''' | |||
[[Category:Controllers]] | [[Category:Controllers]] |
Latest revision as of 13:50, 23 March 2023
Overview
Product Summary
This is a high-end control module family capable of operating in harsh automotive, marine and off-highway applications. The family and its connector system are environmentally sealed and suitable for engine mounting in many applications. Each controller is available in 'F' (flash) or 'C' (calibratable) versions. Flash modules are typically used for production purposes, while calibratable modules are typically for prototyping/development only and can be calibrated in real time using MotoTune.
These modules are based on Freescale MPC5553 or 5554 processors running at 80 MHz. The 112-pin modules offer a full complement of memory storage, 3 CAN channels, and many digital and analog I/O including frequency, crank position, DSP knock detection and EGO oxygen sensor inputs. Typical applications include EV/HEV supervisory control and full OBD2 8-cylinder sequential engines.
Features include:
- Motorola MPC5554, 80MHz Microprocessor
- Operating voltage: 9-16VDC, 24V (Jump start), 4.5V (Crank)
- Operating temperatures ranging from -40°C to 105°C
- ECU weight: 0.82 kg (1.8 lbs.)
Family includes:
- ECM-5554-112-0902
- ECM-5554-112-0904
Datasheets
ECM-5554-112-0902
- Please contact sales
ECM-5554-112-0904
ECM-5644-112-064-1400-C
GCM-5554-112-1001-C/F
Known Datasheet Errata
In the ECM-5554-112 family of controllers datasheet, the block diagram of ECM-5554-112-0902 (page 4) has C-H4 and C-G4 switched around:
C-G4 goes with HBRIDGE1A and C-H4 goes with HBRIDGE1B.
In the ECM-5554-112 family of controllers datasheet, there is an error on page 12 that lists the pin B-C3 twice.
AN18M is labeled as B-C3, but it should be B-C4.
Targets
The PCM112-14 has different targets for the main and the S12G auxiliary processor as shown below:
Main Processor
- 1751-6685: Target ECM-5644A-112-064-1400
Auxiliary Processor
- Target ECM-S12G-112-063-1400 PROD Only
Part Number Decoder Ring
- ECM-5554-112-0902-kD: PCM0902 module with knock development interface, DV release hardware
- ECM-5554-112-0902-kP: PCM0902 module with knock development interface, PV release hardware
- ECM-5554-112-0902-xD: PCM0902 module, DV release hardware
- Use this target for ECM-5554-112-0902-F00 ("PROD") and ECM-5554-112-0902-CP0 ("DEV") modules:
- ECM-5554-112-0902-xP: PCM0902 module, PV release hardware
- Use this target for ECM-5554-112-0904-F00 ("PROD") and ECM-5554-112-0904-CP0 ("DEV") modules:
- ECM-5554-112-0904-xD: PCM0904 module, DV and PV release hardware
Pull-Up and/or Pull-Down on the Analog Inputs of the 5554-112
ECM5554-112 E-Stop
A problem was reported that the Fuel Pump Relay Driver (FUELPR) was not being disabled after a STOP assertion (pinout B-H3). Woodward confirmed the issue and came up with a solution. The correction was completed in the 2010a Beta 5 release. There are open trackers to apply the change in MH2009a and 2009b.
ECM5554-112 RoHS or ELV Compliance
The PCM0904 is compliant to the current ELV (End-of-Life Vehicle Directive) requirements, not RoHS. Note, RoHS applies to consumer electronics products, and ELV is still the applicable directive for automotive parts. Again, this module is fully compliant to ELV and can be sold in Europe.
ELV Compliant End of Life Vehicles (ELV) Directive 2000/53/EC requires that certain automotive products be free (except for trace impurities) of mercury, cadmium and lead as of 2003-7-1. Lead can still be used as an alloying additive in copper, steel and aluminum and in solderable applications. These products comply with the ELV directive.
EU RoHS Compliant Restrictions on Certain Hazardous Substances (EU RoHS) Directive 2002/95/EC requires that certain electrical and electronic products be free (except for trace impurities) of mercury, cadmium, hexavalent chromium, PBB, PBDE and lead as of 2006-7-1. Certain exemptions are allowed such as lead used as an alloying additive in copper, steel and aluminum. These products comply with the EU RoHS directive. These products also comply with the ELV directive. Note that as of July 1, 2008 products that are shown as RoHS compliant do not contain decabromodiphenyl ether.
General-Purpose Use of Knock Pins
The knock sensor pins are dedicated and have no alternate purpose other than knock detection. One exception is that this circuitry is known to be used as a hardware "notch" filter.
Powering the ECM-5554-112-0904 (PCM0904)
The 112-pin modules are nominal 12-volt:
- VBATT (min) = 4.5V (crank transient) and 6.3V (continuous).
- VBATT (normal) = 9-16V.
This voltage is expected at the BATT, BATT2, KEYSW, DRVG1, DRVG2, fuel injector, H-bridge and low-side drivers.
Specifics:
High Voltage Operation
Measure the Jump Start voltage at the BATT pin, referenced to the PWRGND pins. The module should operate normally when exposed to 24 volts for 5 minutes at an ambient temperature of 23°C.
Reverse Battery Connection
The module will not be damaged by 5 minutes of reverse battery (-12 volts). This is a system level test and assumes a correct harness is in use. Specifically, it is assumed that the main power relay will be off.
Abnormal Connections
The module will not be damaged by short to ground, short to battery, or intermittent open-circuit faults on any I/O signal. The following signals are excluded from this requirement since they are power rails that are not protected against shorts:
- PWRGND (not protected from short to battery).
- DRVP (not protected from short to ground).
- XDRG (not protected from short to battery).
- GNDREF (not protected from short to battery).
Note: For purposes of test, it may be assumed that DRVP is applied to the system prior and during the abnormal connection test.
Frequency (Speed) Inputs Notes
SPEED1 (B-G2), SPEED2 (B-H2), SPEED3 (B-H1) logic thresholds and hysteresis are hardware configurable. However, this option is not available in MotoHawk, but might be added in the future.
SPEED1 - This input is normally used to resolve a variable frequency digital speed signal. Software will be capable of selecting either a high impedance mode for 0-5V sensors or 1kΩ pull-up to 5 volts for open-drain type sensors, however this option is not available on present versions of MotoHawk. The default value is 1K, when not software selected.
SPEED2 and 3 - These inputs are normally used to resolve a variable frequency digital speed signal. The sensor will provide a 0-5V signal. Note, the sensor is expected to be a low-side driver with internal pull-up to 5 volts of ~ 4.7kΩ.
Note: The SPEED1, CAM and CNK inputs have the hardware ability on the 112 controllers to select a pull-up resistor. The block Passive Pull Strength was added in 2011a to choose this option; however, only the Crank_DG presently has that ability. It is planned to add this functionality for the CAM and SPEED1 inputs, probably in 2012a MotoHawk.
Differences Between the 0902 and 0904
Here is the full list of changes from PCM0902 to PCM0904.
- Removed the H1 H-Bridge and replaced it with two Infineon BTN7930 ½ Bridge devices.
- Removed the H2 H-Bridge and replaced it with two Infineon BTN7930 ½ Bridge devices.
- Removed the On Semi NIF5002 Injector Drivers and replaced with the On Semi NCV8403.
- Removed the TACHLINK transistor (PZT3904) and replaced it with BFN38 device.
- Routing of case ground traces to pin B-C3 (replaces CAN2 shield pin).
The new H-Bridges are more capable than the older parts and can be run at up to 10A depending on total ECU power dissipation. The injector driver change allows the option to run two injectors per driver (2A max) but, again, power dissipation must be considered. The TACHLINK change was to address robustness to transients.
An interesting point to note while using 0902 modules is that, while trying to work with the Motohawk H-bridge output block, the resource allocation might show 'None'. It is because that block is not exposed to the H-bridge pins in the 0902 controller. In this case, using the Motohawk PWM block can give you exactly the same results with the correct resources on the 0902 module.
CAN Shielding Differences Between 0902 and 0904
For ECM-5554-112-0902 (PCM0902):
CAN_1 is not shielded, nor internally terminated.
CAN_2 is shielded, but not internally terminated.
CAN_3 is shielded and internally terminated at 120Ω.
CANSHIELD2 and CANSHIELD3 are available for shielded bus connections on the respective buses. The internal connection to the PCM ground consists of a 1Ω resistor in series with a 10 nano-farad capacitor (i.e., no DC path). CAN shielding is not always standardized and this implementation may or may not be appropriate for any specific application.
For ECM-5554-112-0904 (PCM0904):
CAN_1 is not shielded, nor internally terminated.
CAN_2 is not shielded, nor internally terminated.
CAN_3 is shielded and internally terminated at 120Ω.
CANSHIELD3 is available for shielded bus connections. The internal connection to the PCM ground consists of a 1Ω resistor in series with a 1 micro-farad capacitor (i.e., no DC path). CAN shielding is not always standardized and this implementation may or may not be appropriate for any specific application.
For the PCM0904 model, pin B-C3 was changed from CAN2 SHIELD to CASEGND. For typical applications, the CASEGND pin should be left unconnected.
Note the change in capacitor value for the shield between PCM0902 and PCM0904.
CAN Transceiver Notes
The 112-pin module uses an Infineon TLE 6250G transceiver. TLE 6250 is a high-speed transceiver with the following features:
- CAN data transmission rate up to 1 MBaud
- Receive-only Mode and Stand-by Mode
- Suitable for 12V and 24V applications
- Excellent EMC performance (very high immunity and very low emission)
- Version for 5V and 3.3V microcontrollers
- Bus pins are short circuit proof to ground and battery voltage
- Overtemperature protection
- RoHS compliant
- AEC Qualified
The RF capacitors are 100pF and there is a Zener set for transient protection.
0904 Models without XDRP1 Capacitor
Differences between VP9DVU12A650-AA and VP9DVU-12A650-AB:
VP9DVU-12A650-AA lacks a 10nF ESD capacitor on the XDRP1 (5V sensor supply) at J1C-D4. The lack of this capacitor leaves the module susceptible to radiated noise coupled onto the application harness. The coupled noise can cause instability in the XDRP1 voltage supply or module resets. Vehicle EMC issues were experienced during Free Field testing at approximately 23V/m and 140-180MHz.
To avoid the issue, the XDRP1 output should be disconnected from the wiring harness. If the XDRP1 output is required, a ferrite choke can be used to filter the noise. Placing a FairRite 43 material solid ferrite or Steward 28 clamp ferrite on the harness wire leading to XDRP1 within one inch of the mating connector will resolve the issue.
VP9DVU-12A650-AB incorporates a very small change to the PWB connecting a 10nF capacitor to the XDRP1 J1 pin, making the module immune to radiated and coupled noise.
What is the LSO output interface?
LSO 6 and 7 are designed for O2 heater control, and they make nice, general-purpose low-side drives. The FETs are controlled via an MC33800 pre-driver. The drive IC datasheet, a Freescale MC33800, is found at MC33800 driver. In addition, there is a 10 nF cap on the input for ESD.
What is the nominal current draw of the ECM-5554-112?
Minimum 'on' current is typically not specified as this is not usually a concern since the engine (and alternator) are running. The current draw is really application dependent as the MPR may or may not be on, and any sensors connected will draw current. Looking at a couple production (PROD or FLASH) units, 300mA is the draw without any sensors or loads connected.
Analog Inputs
According to Woodward and the ECM-5554-112-0904 module schematic, the following inputs are connected to the VISTA chip instead of the MPC5554 processor's integrated ADC.
- AN12
- AN13
- AN18
- AN19
- AN20
- AN31
- AN32
- AN33
It is not uncommon to get some extra ADC noise for the pins connected to the VISTA chip, and we have surmised that ADC counts to temperature calculation logic tend to magnify this variation. We recommend that these inputs only be used for sensors that can tolerate that range of variation.
The AN32 and AN33 inputs also have a selectable reference (not exposed in MotoHawk). Prior to MotoHawk 2010b they had been set to use a 1.6V reference. 2010b and on use a 5V reference. So, for MotoHawk 2010A and older you need to use an extension file to set the reference voltage to 5V.
Analog Input Resolution
The ECM-5554-112 module has 12-bit resolution for the analog inputs, instead of the 10-bit available on the other MotoHawk ECUs. To get the 12-bit resolution, you need to assign it in the Analog Input block.
Speed Inputs = Hall Effect
Speed 1, Speed 2 and Speed 3 are Hall Effect type inputs.
XDRP Current Capability
As mentioned on the datasheet, the independent current capability of XDRP1 is 50 mA and that of XDRP2 is 100 mA. In other words, each of them is connected to a separate pin on the power supply chip. Further, the same voltage (XDRP1 or 2) is used to reference pulled up AN inputs.
Key-Off Timer
The 0904 module has a Key-Off Timer feature which can keep track of the time it's keyed OFF. This may be used with additional logic to create a clock output in some applications.
Boot Key Recovery
We have found that the 112 pin modules tend to be faster in booting up than the boot key. So, when recovering this module with a boot key, it may help to apply power to the boot key first and the module a few seconds afterwards. For instance, turn the power supply on with the module unplugged, start MotoTune programming, then plug the ECU into the junction box a few seconds later.
The CAN baud rate must be set to 250kbps during boot key recovery.
Measuring Current from the H-Bridge
In Simulink you can request to read a current output from the H-bridge driver. The current is read from the driver chip across a sense resistor and "delivers a current proportional to the forward load current flowing through the active high side switch". The current is directly measured from the pin. So, the current measured would be affected by the load characteristics combined with the parallel sense resistor. Also, if the PWM block is outputting a frequency, instead of being in steady state, then the meter may be giving a calculated RMS current which would differ by a constant multiplier. If the high side switch is inactive or the current is flowing in the reverse direction, no current will be driven except for a marginal leakage current.
Low Voltage Operation
The datasheet says the 112 module works from 9-16V. It is actually designed to run at 6.3V continuous. It has been known to work at a "bit less", but this is not guaranteed on every unit.
9V is the min ‘normal’ range. 6.3V is the min without reset (during cranking) but the system will not be able to operate at that voltage since relays will not close and some ICs will fault for low battery voltage.
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