MJLJ V3 vehicle installation guide: Difference between revisions
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== | ==Parts you will need== | ||
To complete your installation, you will need the following components. Most can be harvested from automotive salvage yards, acquired on ebay, or online vendors. | |||
*EDIS module matching your engine type | |||
**EDIS-8 for 8 cylinder | |||
**EDIS-6 for 6 cylinder | |||
**EDIS-4 for 4 cylinder | |||
*Coil packs: Many use the matching Ford coil packs, but typically most coil packs that have closely matched primary and secondary coil DC resistance will work. | |||
*VR Sensor: We suggest you use a Ford VR sensor- this guarantees best compatibility with the Ford EDIS module. | |||
*Trigger wheel: Many adapt the trigger wheel removed from the crank pulley of a donor Ford engine- others machine the pattern into an existing wheel, or buy a pre-made wheel. | |||
For those of you in the UK, a supplier of trigger wheels and EDIS parts can be found here: [http://www.trigger-wheels.com www.trigger-wheels.com] | |||
''ToDo add table showing donor vehicles by EDIS module type'' | |||
==EDIS installation== | ==EDIS installation== | ||
===Crank timing wheel and sensor installation=== | |||
The Ford EDIS ignition module is designed to work with a 36 tooth wheel, with 1 missing tooth to act as a synchronization reference for engine Top Dead Center. | |||
When mounting the sensor wheel the EDIS module requires specific positioning of the sensor relative to the missing tooth, ''while the engine is at Top Dead Center''. The following table defines the sensor position relative to the missing tooth for 4,6 and 8 cylinder EDIS modules. | |||
<center> | |||
{| border = 1 | |||
|+ Sensor Position | |||
|- bgcolor=grey | |||
!Type!!Degrees BTDC | |||
|- | |||
|EDIS-4||90 | |||
|- | |||
|EDIS-6||60 | |||
|- | |||
|EDIS-8||50 | |||
|} | |||
</center> | |||
With the Engine at TDC for cylinder #1, the sensor should be positioned 'N' degrees after the missing tooth. Since the sensor wheel has a tooth (or the missing tooth) every 10 degrees, the sensor should be positioned N/10 teeth after the missing tooth (9 teeth after the missing tooth for 4 cylinder applications for example). Make sure you take into account the rotation of the engine: clockwise or counter-clockwise, when determining your sensor mounting. | |||
The following graphic illustrates how the sensor position and missing tooth can vary relative to engine TDC- regardless of where the sensor is mounted, the missing tooth must be positioned accordingly. | |||
<center> | |||
[[Image:edis_wheel.gif]]<br/> | |||
'''''Shown: Relationship between engine Top Dead Center and sensor positioning. Wherever you place the sensor, the distance from the missing tooth must remain constant.''''' | |||
</center> | |||
The following photos illustrate an EDIS-4 installation on a Toyota 4AG engine. Notice the thickness of the sensor bracket designed to minimize harmonic vibrations which may affect the sensor signal. The crank pulley was machined down to accommodate the timing wheel from a 1997 Ford Escort, and then tack welded in place. | |||
---- | |||
[[Image:edis_sensor_bracket.jpg|VR Sensor and bracket|320px]] | |||
[[Image:timing_wheel_face.jpg|Machined crank pulley with timing adapted|320px]] | |||
[[Image:timing_wheel_face_close2.jpg|Closeup view of adapted timing wheel|320px]] | |||
[[Image:timing_wheel_end.jpg|Machined pulley with timing wheel adapted|320px]] | |||
[[Image:timing_wheel_mounted.jpg|Modified crank pulley mounted with VR Sensor|320px]] | |||
---- | |||
===EDIS and coil-pack installation=== | ===EDIS and coil-pack installation=== | ||
Line 13: | Line 66: | ||
</center> | </center> | ||
===Wiring notes and guidelines=== | ===EDIS Wiring notes and guidelines=== | ||
*Use shielded cable for the VR Sensor. Be sure to ground the shield as well. A 2 conductor cable with a foil shield works well. | *Use shielded cable for the VR Sensor. Be sure to ground the shield as well. A 22-24 gauge, 2 conductor cable with a foil shield works well. | ||
*Use 12-14 gauge wire for EDIS ground, power and coil pack connections. | |||
*Note the VR sensor is polarized- you will not get spark from the EDIS module if it is wired backwards. If you don't see spark, try reversing the connection on the VR sensor. | *Note the VR sensor is polarized- you will not get spark from the EDIS module if it is wired backwards. If you don't see spark, try reversing the connection on the VR sensor. | ||
*Minimize supply voltage variances and especially ground loop problems: | *Minimize supply voltage variances and especially ground loop problems: | ||
**It's strongly recommended you power the EDIS module and MJLJ from the same electrical circuit. Typically this will be +12V switched (Key to "on" position) | **It's strongly recommended you power the EDIS module and MJLJ from the same electrical circuit. Typically this will be +12V switched (Key to "on" position) | ||
**'''Important! - Ground both the EDIS and MJLJ at the same point on the chassis.''' | **'''Important! - Ground both the EDIS and MJLJ at the same point on the chassis.''' | ||
* Capacitor attached to coil: The capacitor sometimes found attached to OEM coil packs can be safely omitted. | |||
==Installing the MJLJ== | ==Installing the MJLJ== | ||
Line 26: | Line 81: | ||
</center> | </center> | ||
===MJLJ wiring notes and | ===MJLJ wiring notes and guidelines=== | ||
*The MJLJ should be installed inside the passenger compartment. It's not designed to handle the temperature,vibration and moisture extremes of the engine bay. | *The MJLJ should be installed inside the passenger compartment. It's not designed to handle the temperature,vibration and moisture extremes of the engine bay. | ||
*Use shielded cable for the PIP/SAW signal between the MJLJ and | *Use shielded cable for the PIP/SAW signal between the MJLJ and EDIS module. Be sure to ground the shield as well. A 2-conductor cable with a foil shield works well. | ||
*Use 16 gauge wire for the MJLJ ground connection. 18-20 gauge wiring is fine for power and the other connections. | *Use 16 gauge wire for the MJLJ ground connection. 18-20 gauge wiring is fine for power and the other connections. | ||
*For MAP based setups ignore the TPS connections. | *For MAP based setups ignore the TPS connections. | ||
===Load Sensing: Manifold Pressure Sensor (MAP) or Throttle Position Sensor (TPS)=== | |||
====MAP Sensor operation==== | |||
If your MJLJ is optioned with an onboard MAP sensor, find an appropriate spot on your manifold to reference a stable source of vacuum. Run a vacuum line from this location to the barbed connection on the MJLJ. | |||
If you have multiple runners and throttle bodies / carburetors, you may need to buy/build a balance tube to average manifold pressure across all runners. Some opt to construct a miniature reservoir to smooth the pulses across all cylinders. | |||
<center> | |||
[[Image:adapting_map_sensor_for_multiple_runners.png]] | |||
</center> | |||
<center> | |||
[[Image:adapting_map_sensor_for_multiple_runners_balanced_tubes.png]] | |||
<br> | |||
''Alternate technique which may offer a more balanced signal'' | |||
</center> | |||
====Existing Vacuum Advance vacuum port==== | |||
Most vacuum advance takeoff ports are designed in such a way that vacuum is measured through a hole, which is actually covered by the edge of the throttle plate at idle. That is called Ported Vacuum. That is done to cut off all vacuum advance at idle, which in turn slows the engine and makes it easier to achieve stable idle with the tiny throttle plate opening used at idle. Vacuum measured on such a port, therefore, has no vacuum at idle, moves to maximum vacuum just off idle, and then decreasing vacuum as the throttle is opened further. The discontinuity just off idle makes such a port awkward to deal with on the load map. | |||
You can test whether you have ported vacuum or not: pull the vac hose off the vacuum advance unit. With your finger over the end of the hose, you should feel vacuum with the engine revved above idle. Assuming yes, let the engine speed drop back to idle. Is there still vacuum? If not (most likely), that means you have ported vacuum, and should find another source of vacuum, somewhere on the manfold. | |||
====TPS Sensor operation==== | |||
For a TPS setup, wire the TPS unit according to the diagram. Be sure to wire the sensor in such a way that the voltage going to the TPS input increases with throttle opening. If you are unsure, do not finalize the connection of these wires until you can verify operation using the PC software. For Firmware versions 3.1 and later, a calibration routine is available to correctly scale your throttle from 0 to 100%. | |||
===Interfacing to Tachometers=== | ===Interfacing to Tachometers=== | ||
Line 37: | Line 119: | ||
Many tachometers can accept the signal emitted from the TACH OUT on the MJLJ module. This TACH OUT signal provides a 12V pulse for every ignition event. You may use this to provide the signal to compatible tachometers. | Many tachometers can accept the signal emitted from the TACH OUT on the MJLJ module. This TACH OUT signal provides a 12V pulse for every ignition event. You may use this to provide the signal to compatible tachometers. | ||
====Tachometers that require a | ====Tachometers that require a high-voltage kickback pulse==== | ||
Some OEM-style tachometers detect the RPM signal by sensing the high voltage | Some OEM-style tachometers detect the RPM signal by sensing the high voltage fly back pulse from the ignition coil. In distributor based setups, there is only one ignition coil from which to detect this pulse. With a wasted spark system, this 'signal' is spread across multiple coils. As a result, you will need a way to combine these pulses across multiple coil packs to drive your tachometer. | ||
The following circuit allows the | The following circuit allows the fly back pulse to be detected across individual coil packs while still isolating the coils from each other. | ||
<center> | <center> | ||
[[Image:tach_circuit.jpg]]<br/> | [[Image:tach_circuit.jpg]]<br/> | ||
''OEM | ''OEM tachometer adapter circuit''<br> | ||
''If the above circuit does not work, try omitting the Zener diode.'' | ''If the above circuit does not work, try omitting the Zener diode.'' | ||
</center> | </center> | ||
=== | ====Using EDIS PIP signal==== | ||
The User defined outputs provided by the MJLJ can be set to trigger on either RPM or Load thresholds. The configuration of these outputs is provided by the PC configuration software, covered in a later section. | An alternative approach that appears to work with older 'Smiths' type tachometers is to share the PIP signal that is emitted from the EDIS module. The PIP output is a 12V square wave with a larger duty cycle than the TACH_OUT provided by the MJLJ. Simply wire the EDIS PIP output to both the MJLJ PIP input as well as the tachometer sense wire. | ||
If this approach is used, you should check to make sure the MJLJ receives the PIP signal consistently, since the PIP line has extra current demand placed upon it. The current demands of the MJLJ PIP input is low, so it should work fine- and a few field reports have shown this. However, a quick check using the configuration software for consistent RPM readings would be prudent. | |||
====Smiths RVI type tachometers==== | |||
Note that there are two types of older Smiths tachometers: RVI - current sensing, and RVC - voltage sensing. These letters, and numbers indicating exactly which variant you have, are printed in small white lettering on the bottom of the face of the tachometer. RVI type tachometers work by routing the coil +ve supply wire through an inductive loop of wire inside the tachometer, and are not compatible with the MJLJ. If you have an RVI type tachomoter, you can replace it, have an add-on circuit board added inside (or build one yourself, see http://www.dinoplex.org/tachoconversion for a start), or replace all the inside working parts with those from a newer tachometer ie retain the original face, but change everything else. For that approach you need a donor which has the same angular swing per 1000rpm, as the Smiths gauge. | |||
===User defined outputs and Shift Light=== | |||
The four user-defined outputs provided by the MJLJ can be set to trigger on either RPM or Load thresholds. The separate 'shift light' output triggers only on RPM, but otherwise behaves identically to the user outputs. | |||
Starting with V3.1 firmware the user outputs have hysteresis control. For RPM, the hysteresis threshold is 100 RPM; for Load, the threshold is 1 KPa or 1% TPS. | |||
The configuration of these outputs is provided by the PC configuration software, covered in a later section. | |||
Each output can supply up to 500mA, which is enough to drive LEDs, small incandescent lamps, relays, and small solenoid valves. If you are unsure on the amount of current drawn by the accessory, you can power it manually and measure it's current using a Volt-Ohm-Amp meter. | Each output can supply up to 500mA, which is enough to drive LEDs, small incandescent lamps, relays, and small solenoid valves. If you are unsure on the amount of current drawn by the accessory, you can power it manually and measure it's current using a Volt-Ohm-Amp meter. | ||
Line 57: | Line 153: | ||
Accessories that have a higher current demand can be controlled by relays, with the MJLJ output driving the relay. | Accessories that have a higher current demand can be controlled by relays, with the MJLJ output driving the relay. | ||
Should you exceed the current capacity of one or more of the user defined outputs and damage the ULN2003 | Should you exceed the current capacity of one or more of the user defined outputs and damage the IC that drives the user outputs (ULN2003 darlington array), replace the chip with a new unit- it is socketed for this specific reason. | ||
<center> | |||
[[Image:MJLJ_User_output_examples.png]] | [[Image:MJLJ_User_output_examples.png]] | ||
</center> | |||
===Enabling Option Switch (For MJLJ firmware > 3.1.0)=== | ===Enabling Option Switch (For MJLJ firmware > 3.1.0)=== | ||
For MJLJ firmware | For MJLJ firmware versions 3.1.0 and later, the Option input is used to enable on-the-fly switching between Ignition Configurations, controllable via a dash mounted switch. | ||
To enable this feature you must have controller firmware V3.1.0 or later installed, and the feature must be enabled in the controller (covered later). Wire the switch based on how your MJLJ is optioned; use the following diagram as a guide: | To enable this feature you must have controller firmware V3.1.0 or later installed, and the feature must be enabled in the controller (covered later). Wire the switch based on how your MJLJ is optioned; use the following diagram as a guide: | ||
<center> | |||
[[Image:MJLJ_V3_wiring_option_switch.png]] | [[Image:MJLJ_V3_wiring_option_switch.png]] | ||
</center> | |||
===Rev Limit control=== | ===Rev Limit control=== | ||
The ford EDIS system offers no direct ability to disable the ignition coils in an over-rev condition. The indirect way to enable this is through an external circuit that disables power to the ignition coil(s). | |||
The MJLJ offers an output that triggers on the configured rev-limit. An additional feature of the Rev Limit functionality is tha the ignition advance automatically goes to zero 100 RPMs before the configured limit, offering a softer approach to the hard limit. | |||
We are currently developing an external board that accepts this rev limit output and disables the ignition coil(s) when activated. | |||
Current experimental techniques involve either using a mechanical relay to cut power to the coils, or tie the coil (-) to +12V through a current limiting resistor, suppressing spark by preventing the sudden collapse of the coil's magnetic field. | |||
==MJLJ Operation== | ==MJLJ Operation== | ||
===Verifying MJLJ operation=== | |||
After you've double-checked the wiring of the MJLJ, connect a timing light and start the engine. You should observe the ignition advance changing in precise steps in response to throttle changes. If this is what you observe, congratulations!! This may be your first time observing the benefits of precision crank-fired ignition! | |||
If the advance does not change, or appears jittery or unstable, verify your MJLJ installation, especially the PIP / SAW connection, proper grounding and cable shielding. | |||
<!-- | |||
===PC Connection with Configuration Software=== | ===PC Connection with Configuration Software=== | ||
Line 86: | Line 200: | ||
===Interactive Tuning=== | ===Interactive Tuning=== | ||
=== | ===Data logging=== | ||
--> | --> |
Latest revision as of 07:53, 5 January 2010
Parts you will need
To complete your installation, you will need the following components. Most can be harvested from automotive salvage yards, acquired on ebay, or online vendors.
- EDIS module matching your engine type
- EDIS-8 for 8 cylinder
- EDIS-6 for 6 cylinder
- EDIS-4 for 4 cylinder
- Coil packs: Many use the matching Ford coil packs, but typically most coil packs that have closely matched primary and secondary coil DC resistance will work.
- VR Sensor: We suggest you use a Ford VR sensor- this guarantees best compatibility with the Ford EDIS module.
- Trigger wheel: Many adapt the trigger wheel removed from the crank pulley of a donor Ford engine- others machine the pattern into an existing wheel, or buy a pre-made wheel.
For those of you in the UK, a supplier of trigger wheels and EDIS parts can be found here: www.trigger-wheels.com
ToDo add table showing donor vehicles by EDIS module type
EDIS installation
Crank timing wheel and sensor installation
The Ford EDIS ignition module is designed to work with a 36 tooth wheel, with 1 missing tooth to act as a synchronization reference for engine Top Dead Center.
When mounting the sensor wheel the EDIS module requires specific positioning of the sensor relative to the missing tooth, while the engine is at Top Dead Center. The following table defines the sensor position relative to the missing tooth for 4,6 and 8 cylinder EDIS modules.
Type | Degrees BTDC |
---|---|
EDIS-4 | 90 |
EDIS-6 | 60 |
EDIS-8 | 50 |
With the Engine at TDC for cylinder #1, the sensor should be positioned 'N' degrees after the missing tooth. Since the sensor wheel has a tooth (or the missing tooth) every 10 degrees, the sensor should be positioned N/10 teeth after the missing tooth (9 teeth after the missing tooth for 4 cylinder applications for example). Make sure you take into account the rotation of the engine: clockwise or counter-clockwise, when determining your sensor mounting.
The following graphic illustrates how the sensor position and missing tooth can vary relative to engine TDC- regardless of where the sensor is mounted, the missing tooth must be positioned accordingly.
Shown: Relationship between engine Top Dead Center and sensor positioning. Wherever you place the sensor, the distance from the missing tooth must remain constant.
The following photos illustrate an EDIS-4 installation on a Toyota 4AG engine. Notice the thickness of the sensor bracket designed to minimize harmonic vibrations which may affect the sensor signal. The crank pulley was machined down to accommodate the timing wheel from a 1997 Ford Escort, and then tack welded in place.
EDIS and coil-pack installation
Since the EDIS module can operate the engine by itself in a "limp-home" mode, with the advance fixed at 10 degrees BTDC, it's recommended you install the EDIS module and coil packs first, and then verify your engine runs before wiring in the MJLJ.
Wire up the EDIS module and coil pack(s) using the following diagram, matching your engine type (EDIS 4 = 4 cylinder, EDIS 6 = 6 cylinder, EDIS 8 = 8 cylinder). Engines with 'even-fire' configurations are supported, which represents the vast majority of 4,6, and 8 cylinder engines in production.
EDIS Wiring notes and guidelines
- Use shielded cable for the VR Sensor. Be sure to ground the shield as well. A 22-24 gauge, 2 conductor cable with a foil shield works well.
- Use 12-14 gauge wire for EDIS ground, power and coil pack connections.
- Note the VR sensor is polarized- you will not get spark from the EDIS module if it is wired backwards. If you don't see spark, try reversing the connection on the VR sensor.
- Minimize supply voltage variances and especially ground loop problems:
- It's strongly recommended you power the EDIS module and MJLJ from the same electrical circuit. Typically this will be +12V switched (Key to "on" position)
- Important! - Ground both the EDIS and MJLJ at the same point on the chassis.
- Capacitor attached to coil: The capacitor sometimes found attached to OEM coil packs can be safely omitted.
Installing the MJLJ
MJLJ wiring notes and guidelines
- The MJLJ should be installed inside the passenger compartment. It's not designed to handle the temperature,vibration and moisture extremes of the engine bay.
- Use shielded cable for the PIP/SAW signal between the MJLJ and EDIS module. Be sure to ground the shield as well. A 2-conductor cable with a foil shield works well.
- Use 16 gauge wire for the MJLJ ground connection. 18-20 gauge wiring is fine for power and the other connections.
- For MAP based setups ignore the TPS connections.
Load Sensing: Manifold Pressure Sensor (MAP) or Throttle Position Sensor (TPS)
MAP Sensor operation
If your MJLJ is optioned with an onboard MAP sensor, find an appropriate spot on your manifold to reference a stable source of vacuum. Run a vacuum line from this location to the barbed connection on the MJLJ.
If you have multiple runners and throttle bodies / carburetors, you may need to buy/build a balance tube to average manifold pressure across all runners. Some opt to construct a miniature reservoir to smooth the pulses across all cylinders.
Existing Vacuum Advance vacuum port
Most vacuum advance takeoff ports are designed in such a way that vacuum is measured through a hole, which is actually covered by the edge of the throttle plate at idle. That is called Ported Vacuum. That is done to cut off all vacuum advance at idle, which in turn slows the engine and makes it easier to achieve stable idle with the tiny throttle plate opening used at idle. Vacuum measured on such a port, therefore, has no vacuum at idle, moves to maximum vacuum just off idle, and then decreasing vacuum as the throttle is opened further. The discontinuity just off idle makes such a port awkward to deal with on the load map.
You can test whether you have ported vacuum or not: pull the vac hose off the vacuum advance unit. With your finger over the end of the hose, you should feel vacuum with the engine revved above idle. Assuming yes, let the engine speed drop back to idle. Is there still vacuum? If not (most likely), that means you have ported vacuum, and should find another source of vacuum, somewhere on the manfold.
TPS Sensor operation
For a TPS setup, wire the TPS unit according to the diagram. Be sure to wire the sensor in such a way that the voltage going to the TPS input increases with throttle opening. If you are unsure, do not finalize the connection of these wires until you can verify operation using the PC software. For Firmware versions 3.1 and later, a calibration routine is available to correctly scale your throttle from 0 to 100%.
Interfacing to Tachometers
Using the TACH OUT on the MJLJ
Many tachometers can accept the signal emitted from the TACH OUT on the MJLJ module. This TACH OUT signal provides a 12V pulse for every ignition event. You may use this to provide the signal to compatible tachometers.
Tachometers that require a high-voltage kickback pulse
Some OEM-style tachometers detect the RPM signal by sensing the high voltage fly back pulse from the ignition coil. In distributor based setups, there is only one ignition coil from which to detect this pulse. With a wasted spark system, this 'signal' is spread across multiple coils. As a result, you will need a way to combine these pulses across multiple coil packs to drive your tachometer.
The following circuit allows the fly back pulse to be detected across individual coil packs while still isolating the coils from each other.
OEM tachometer adapter circuit
If the above circuit does not work, try omitting the Zener diode.
Using EDIS PIP signal
An alternative approach that appears to work with older 'Smiths' type tachometers is to share the PIP signal that is emitted from the EDIS module. The PIP output is a 12V square wave with a larger duty cycle than the TACH_OUT provided by the MJLJ. Simply wire the EDIS PIP output to both the MJLJ PIP input as well as the tachometer sense wire.
If this approach is used, you should check to make sure the MJLJ receives the PIP signal consistently, since the PIP line has extra current demand placed upon it. The current demands of the MJLJ PIP input is low, so it should work fine- and a few field reports have shown this. However, a quick check using the configuration software for consistent RPM readings would be prudent.
Smiths RVI type tachometers
Note that there are two types of older Smiths tachometers: RVI - current sensing, and RVC - voltage sensing. These letters, and numbers indicating exactly which variant you have, are printed in small white lettering on the bottom of the face of the tachometer. RVI type tachometers work by routing the coil +ve supply wire through an inductive loop of wire inside the tachometer, and are not compatible with the MJLJ. If you have an RVI type tachomoter, you can replace it, have an add-on circuit board added inside (or build one yourself, see http://www.dinoplex.org/tachoconversion for a start), or replace all the inside working parts with those from a newer tachometer ie retain the original face, but change everything else. For that approach you need a donor which has the same angular swing per 1000rpm, as the Smiths gauge.
User defined outputs and Shift Light
The four user-defined outputs provided by the MJLJ can be set to trigger on either RPM or Load thresholds. The separate 'shift light' output triggers only on RPM, but otherwise behaves identically to the user outputs.
Starting with V3.1 firmware the user outputs have hysteresis control. For RPM, the hysteresis threshold is 100 RPM; for Load, the threshold is 1 KPa or 1% TPS.
The configuration of these outputs is provided by the PC configuration software, covered in a later section.
Each output can supply up to 500mA, which is enough to drive LEDs, small incandescent lamps, relays, and small solenoid valves. If you are unsure on the amount of current drawn by the accessory, you can power it manually and measure it's current using a Volt-Ohm-Amp meter.
Accessories that have a higher current demand can be controlled by relays, with the MJLJ output driving the relay.
Should you exceed the current capacity of one or more of the user defined outputs and damage the IC that drives the user outputs (ULN2003 darlington array), replace the chip with a new unit- it is socketed for this specific reason.
Enabling Option Switch (For MJLJ firmware > 3.1.0)
For MJLJ firmware versions 3.1.0 and later, the Option input is used to enable on-the-fly switching between Ignition Configurations, controllable via a dash mounted switch.
To enable this feature you must have controller firmware V3.1.0 or later installed, and the feature must be enabled in the controller (covered later). Wire the switch based on how your MJLJ is optioned; use the following diagram as a guide:
Rev Limit control
The ford EDIS system offers no direct ability to disable the ignition coils in an over-rev condition. The indirect way to enable this is through an external circuit that disables power to the ignition coil(s).
The MJLJ offers an output that triggers on the configured rev-limit. An additional feature of the Rev Limit functionality is tha the ignition advance automatically goes to zero 100 RPMs before the configured limit, offering a softer approach to the hard limit.
We are currently developing an external board that accepts this rev limit output and disables the ignition coil(s) when activated.
Current experimental techniques involve either using a mechanical relay to cut power to the coils, or tie the coil (-) to +12V through a current limiting resistor, suppressing spark by preventing the sudden collapse of the coil's magnetic field.
MJLJ Operation
Verifying MJLJ operation
After you've double-checked the wiring of the MJLJ, connect a timing light and start the engine. You should observe the ignition advance changing in precise steps in response to throttle changes. If this is what you observe, congratulations!! This may be your first time observing the benefits of precision crank-fired ignition!
If the advance does not change, or appears jittery or unstable, verify your MJLJ installation, especially the PIP / SAW connection, proper grounding and cable shielding.