Ignition System Overview
The electronic ignition system controls fuel combustion by providing
a spark to ignite the compressed air/fuel mixture at the correct time. To
provide optimum engine performance, fuel economy, and control of
exhaust emissions, the powertrain control module (PCM) controls
the ignition system. The electronic ignition system has the following
advantages over a mechanical distributor system:
• | Remote mounting capability |
• | No mechanical load on the engine |
• | More coil cool down time between firing events |
• | Elimination of mechanical timing adjustments |
• | Increased available ignition coil saturation time |
Operation
The electronic ignition system does not use the conventional distributor
and coil. The ignition system consists of the following components/circuits:
• | Eight ignition control (IC) circuits |
• | Two ignition control modules (one per cylinder bank) |
• | Camshaft position (CMP) sensor |
• | Crankshaft position (CKP) sensor A |
• | Crankshaft position (CKP) sensor B |
• | Related connecting wires |
• | Powertrain control module (PCM) |
Crankshaft Position Sensors
The powertrain control module (PCM) uses dual crankshaft position (CKP)
A and CKP B sensors to determine crankshaft position. The CKP sensors are
mounted in the engine block approximately 21.5 degrees apart from
each other. Three wires connect each CKP sensor to the PCM. The PCM supplies
an ignition voltage and a ground for each CKP sensor. During engine rotation,
a slotted ring, machined into the crankshaft, causes the sensors to return
a series of ON and OFF pulses to the PCM. The PCM uses these pulses to
decode the position of the engine crankshaft.
The PCM uses two basic methods of decoding the engine position: Angle
Based and Time Based, using either CKP A or CKP B sensor input. During normal
operation, the PCM uses the angle based method. In order to operate in
this mode, the PCM must receive signal pulses from both CKP sensors. The
PCM uses the signal pulses to determine an initial crankshaft position,
and to generate MEDRES (24X reference) and LORES (4X reference) signals.
Once the initial crank position is determined, the PCM continuously monitors
both sensors for valid signal inputs. As long as both signal inputs remain,
the PCM will continue to use the angle based mode.
When either CKP signal is lost, the PCM will compare the MEDRES signal
to the camshaft position (CMP) sensor signal. If the PCM detects a valid CMP
signal, and the MEDRES to CMP signal correlation is correct, the PCM determines
that CKP sensor A is at fault. However, if the MEDRES to CMP correlation
is incorrect, the PCM determines that CKP sensor B is at fault.
If the PCM detects a loss of signal for CKP sensor A, DTC P0335
will set. The PCM will switch from angle based mode to Time Based mode B using
CKP sensor B signal input. If the PCM detects a loss of signal for CKP
sensor B, DTC P0385 will set. The PCM will switch from angle based
mode to Time Based mode A using CKP sensor B signal input. .A noisy signal
input from either CKP sensor will cause the ignition system to re-sync.
If the number of ignition system re-sync is greater than a calibrated
amount, DTC P1372 will set.
Camshaft Position Sensor
The camshaft position (CMP) sensor is mounted in the front of the right
cylinder head assembly. The CMP sensor signal, when combined with the CKP
sensor signal, enables the PCM to determine exactly which cylinder is
on a firing stroke. The PCM can then properly synchronize the ignition
system, fuel injectors, and knock control. The PCM supplies an ignition
voltage and a ground for the CMP sensor. If a problem is detected with
the CMP circuit, DTC P0340 or DTC P0341 will set.
Ignition Coils/Modules
The electronic ignition system uses an individual ignition coil for
each cylinder. There are two separate ignition module assemblies located in
the camshaft cover of each cylinder bank. Each ignition module assembly
contains an ignition control module and four ignition coils. Each ignition
coil connects directly to a spark plug using a boot. This arrangement
eliminates the need for secondary ignition wires. The ignition module
assemblies receive power from a fused ignition feed. Both ignition module
assemblies connect to chassis ground. A reference low and four ignition
control (IC) circuits connect each ignition module assembly to the PCM.
The PCM uses the individual IC circuits to control coil sequencing and
spark timing for each ignition coil. The IC circuits transmit timing pulses
from the PCM to the ignition control module to trigger the ignition coil
and fire the spark plug. The PCM controls ignition system sequencing and
timing events.
This ignition system produces very high energy to fire the spark plug.
There is no energy loss because of ignition wire resistance, or the resistance
of the waste spark system. Also, since the firing is sequential, each
coil has seven ignition events to saturate as opposed to the three in
a waste spark arrangement.
Noteworthy Ignition Information
There are important considerations to point out when servicing the ignition
system. The following noteworthy information will list some of these, to help
the technician in servicing the ignition system.
• | If a boot remains attached to a coil or spark plug, twist the
boot prior to removal using the correct tool. Do not use pliers, screwdrivers,
or any unauthorized tools to remove the boot. |
• | Check the boot for a missing or damaged internal spring. |
• | Do not re-install any component that has visible signs of damage. |
• | Install the boots onto the coils until bottomed out. Then install
the assembly onto the spark plugs. If this is not possible due to space limitations,
just-start the boots onto the spark plugs, and then install the coil
assembly as straight down onto the plugs as possible. |
• | Ensure the boots are installed right side up. |
• | Repair a torn perimeter seal with RTV sealant. |
• | Adhere to the torque specifications when installing the cassette
to the cam cover and the module to the cassette. |
Powertrain Control Module (PCM)
The PCM is responsible for maintaining proper spark and fuel injection
timing for all driving conditions. To provide optimum driveability and emissions,
the PCM monitors input signals from the following components in
calculating ignition control (IC) spark timing:
• | Engine coolant temperature (ECT) sensor |
• | Intake air temperature (IAT) sensor |
• | Mass air flow (MAF) sensor |
• | Trans range inputs from transaxle range switch |
• | Throttle position (TP) sensor |
• | Vehicle speed sensor (VSS) |
Reference Low Circuits
The reference low circuits provide a common ground between the PCM,
and the ignition control modules. These circuits reduce the electrical ground
shifts that may occur between the PCM and the ignition control modules.
A malfunction in the reference low circuits may cause a poor driveability
condition.
Results of Incorrect Operation
An Ignition control circuit that is open, grounded, or short to voltage
will set an ignition control circuit DTC. If a fault occurs in the IC output
circuit when the engine is running, the engine will experience
a misfire. DTCs P0351-P0358 indicate that a short to ground has
been detected on an ignition control circuit. DTCs P1359 and/or
P1360 will set when the PCM detects an open or a short to voltage in the
ignition control circuit. If the malfunction is a short to voltage, a loss
of two cylinders will occur.