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 PCM controls the spark advance of 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. |
The electronic ignition system does not use the conventional
distributor and coil. The ignition system consists of the following components/circuits:
| • | Eight ignition coils/modules |
| • | Eight Ignition Control (IC) circuits |
| • | Camshaft Position (CMP) sensor |
| • | 1X Camshaft reluctor wheel |
| • | Crankshaft Position (CKP) sensor |
| • | 24X Crankshaft reluctor wheel |
| • | Related connecting wires |
| • | Powertrain Control Module (PCM) |
Crankshaft Position Sensor and Reluctor Wheel
The Crankshaft Position
(CKP) sensor is located in the right rear of the engine, behind the starter.
The CKP sensor is a dual magneto resistive type sensor. This sensor
is not speed dependent. The dual micro switches monitor both notches
of the reluctor wheel for greater accuracy. The CKP sensor works
in conjunction with a 24X reluctor wheel. The reluctor wheel is
mounted on the rear of the crankshaft. The 24X reluctor wheel uses
two different width notches that are 15 degrees apart. This Pulse
Width Encoded pattern allows cylinder position identification within
90 degrees of crankshaft rotation. In some cases, cylinder identification
can be located in 45 degrees of crankshaft rotation. This
reluctor wheel also has dual track notches that are 180 degrees
out of phase. The dual track design allows for quicker starts and
accuracy.
The PCM also receives a 4X signal from the Crankshaft Position sensor.
The PCM utilizes the 4X signal for the following:
Observe that as long as the PCM receives the Crankshaft Position sensor
24X signal, the engine will start. The PCM can determine top dead center for
all cylinders by using the Crankshaft Position sensor 24X signal alone.
The Camshaft Position sensor 1X signal is used by the PCM to determine
if the cylinder at top dead center is on the firing stroke, or the exhaust
stroke. The system attempts synchronization and looks for an increase
in engine speed indicating the engine started. If the PCM does not
detect an increase in engine speed, the PCM assumes it incorrectly
synchronized to the exhaust stroke and re-synchronizes to the opposite
cam position. A slightly longer cranking time may be a symptom
of this condition.
Camshaft Position Sensor
The Camshaft Position
(CMP) sensor is mounted through the top of the engine block at the rear of
the valley cover. The CMP sensor works in conjunction with a 1X reluctor
wheel on the camshaft. The CMP sensor is used to determine whether
a cylinder is on the firing or the exhaust stroke. As the camshaft
rotates, the reluctor wheel interrupts a magnetic field produced
by a magnet within the sensor. The CMP sensor internal circuitry
detects this and produces a signal which is used by the PCM. The
PCM uses this signal in combination with the CKP 24X signal to determine
crankshaft position and stroke.
Observe that as long as the PCM receives the Crankshaft Position sensor
24X signal, the engine will start. The PCM can determine top dead center for
all cylinders by using the Crankshaft Position sensor 24X signal alone.
The Camshaft Position sensor 1X signal is used by the PCM to determine
if the cylinder at top dead center is on the firing stroke, or the exhaust
stroke. The system attempts synchronization and looks for an increase
in engine speed indicating the engine started. If the PCM does not
detect an increase in engine speed, the PCM assumes it incorrectly
synchronized to the exhaust stroke and re-synchronizes to the opposite
cam position. A slightly longer cranking time may be a symptom
of this condition.
Ignition Coils/Module
The ignition system on
this vehicle features a multiple coil ignition and is known as coil near
plug. The secondary ignition wires are short compared with a distributor
ignition system wire. Eight ignition coils/modules are individually
mounted above each cylinder on the rocker covers. The coils/modules
are fired sequentially. There is an Ignition Control (IC) circuit
for each ignition coil/module. The eight ignition control circuits
are connected to the PCM. All ignition timing decisions are made
by the PCM, which triggers each coil/module individually. The ignition
coil/modules are supplied with the following circuits:
| • | Ignition control circuit |
The ignition feed circuits are fused separately for each bank of the
engine. The two fuses also supply power to the injectors for that bank of
the engine. Each coil/module is serviced separately.
This system puts out very high ignition energy for plug firing. The
ignition wires are shorter so less energy is lost to ignition wire resistance.
Also, since the firing is sequential, each coil has seven ignition
events to saturate as opposed to the three in a waste spark arrangement.
Futhermore, no energy is lost to the resistance of a waste spark
system.
Circuits Affecting Ignition Control
To properly control ignition timing, the PCM relies on the following
information:
| • | Engine load (manifold pressure or vacuum) |
| • | Atmospheric (barometric) pressure |
The Ignition Control (IC) system consists of the following components:
| • | 24X crankshaft position sensor |
| • | Powertrain Control Module (PCM) |
The Ignition Control utilizes the following to control spark timing
functions:
| • | 24X signal - The 24X crankshaft position sensor sends a signal
to the PCM. The PCM uses this signal to determine crankshaft position.
The PCM also utilizes this signal to trigger the fuel injectors. |
| • | Ignition Control (IC) circuits - The PCM uses these circuits to
trigger the ignition coil/modules. The PCM uses the crankshaft reference
signal to calculate the amount of spark advance needed. |
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.
| • | The ignition coils secondary voltage output capabilities are very
high - more than 40,000 volts. Avoid body contact with secondary high
voltage ignition components when the engine is running, or personal injury
may result! |
| • | The 24X crankshaft position sensor is the most critical part of
the ignition system. If the sensor is damaged so that pulses are not generated,
the engine will not start! |
| • | Crankshaft position sensor clearance is very important! The sensor
must not contact the rotating interrupter ring at any time, or sensor damage
will result. If the interrupter ring is bent, the interrupter
ring blades will destroy the sensor. |
| • | Ignition timing is not adjustable. There are no timing marks on
the crankshaft balancer or timing chain cover. |
| • | Be careful not to damage the secondary ignition wires or boots
when servicing the ignition system. Rotate each boot to dislodge it from the
plug or coil tower before pulling it from either a spark
plug or the ignition coil. Never pierce a secondary ignition
wire or boot for any testing purposes! Future problems
are guaranteed if pinpoints or test lights are pushed through
the insulation for testing. |
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
to calculate Ignition Control (IC) spark timing:
| • | The Engine Coolant Temperature (ECT) sensor |
| • | The Intake Air Temperature (IAT) sensor |
| • | The Mass Air Flow (MAF) sensor |
| • | The Trans Range inputs from Transaxle Range switch |
| • | The Throttle Position (TP) sensor |
| • | The Vehicle Speed Sensor (VSS) |
Results of Incorrect Operation
An Ignition control circuit that is open, grounded, or shorted 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 will set when a malfunction
is detected with an Ignition Control circuit. When an Ignition
control DTC sets, the PCM disables the injector for the appropriate cylinder.
The PCM uses information from the engine coolant temperature sensor
in addition to RPM to calculate spark advance values as follows:
| • | High RPM = more advance |
| • | Cold engine = more advance |
| • | Hot engine = less advance |
Therefore, detonation could be caused by high resistance in the engine
coolant temperature sensor circuit. Poor performance could be caused by low
resistance in the engine coolant temperature sensor circuit.
If the engine cranks but will not run or immediately stalls,
the Engine Cranks But Will Not Run diagnostic table must be used to determine
if the failure is in the ignition system or the fuel system.
If DTC P0300, P0341, P0342, P0343, P0335, P0336 is set,
the appropriate diagnostic trouble code table must be used
for diagnosis.
