The instrument panel cluster includes the following indicators:

The indicator bulbs are serviceable from the rear of the instrument cluster. Refer to Instrument Cluster Bulb Replacement .

The instrument cluster indicators may differ slightly from model to model, depending on the following factors:

Certain instrument panel cluster (IPC) features are tested when the ignition is turned on in order to verify the features are working properly. The following occurs at key up:

The instrument panel cluster includes the following gages:

The gages are all serviceable from the instrument panel cluster. Refer to Speedometer Replacement , Tachometer Replacement or Fuel/Temperature Gage Replacement for gage removal and installation procedures.

Important: When replacing a speedometer or an odometer assembly, the law requires the odometer reading of the replacement unit to be set to register the same mileage as the prior odometer.

The total mileage odometer and the two trip odometers are incorporated into the speedometer (9). The speedometer, the total mileage odometer and the trip odometers are serviceable only as a unit.

Odometer

Press the trip/reset switch on the cluster in order to toggle between the total mileage odometer and the trip odometers. Press and hold the trip/reset switch for greater than 2 seconds with either trip odometer displayed in order to reset the trip odometer.

The tachometer displays the engine speed in thousands of revolutions per minute (RPM). The noise suppressor filter sends ground pulses from the ignition system to the tachometer. The tachometer responds to the frequency of the ground pulses, which increase with the engine speed. The purpose of the noise suppressor filter within the circuit is to round off pulses and remove the voltage spikes that noise in the circuit causes.

The magnetic fields of 2 coils move the pointer of the fuel gage. The coils are at right angles to each other. Voltage applies to coil F from the IG fuse. The circuit divides at the opposite (ground) side of the coil. One path seeks a ground through coil E to G103. The other path seeks a ground through the variable resistor in the fuel level sender.

When the fuel level is low, the resistance in the fuel level sender is high. Current flows through coil F and coil E to ground at G103 because current always seeks the path of the least resistance. Because the length of the E coil winding is twice the length of the F coil winding, the magnetic field that the E coil generates is twice as strong as the magnetic field that the F coil generates. The magnetic field therefore pulls the pointer to the E position.

As the fuel level increases, the resistance in the fuel level sender decreases. Since current always seeks the path of the least resistance, more current begins to bypass the E coil and travel directly to ground through the fuel level sender. The coil F magnetic field then becomes stronger than the coil E magnetic field, causing the pointer to move toward the F position.

The magnetic field of 2 coils moves the pointer of the engine coolant temperature (ECT) gage. The coils are at right angles to each other. Voltage applies to the H coil from the IG fuse. The circuit divides at the opposite (ground) side of the coil. One path seeks a ground through coil C. The other path seeks a ground through the variable resistor in the engine coolant temperature (ECT) sending unit.

The resistance in the ECT sending unit is high when the engine coolant temperature is low. Current flows through the H coil and the C coil to ground at G103 because current always seeks the path of the least resistance. Because the length of the C coil winding is twice the length of the coil H winding, the magnetic filed that coil C generates is twice as strong as the magnetic field that coil H generates. The magnetic field therefore pulls the pointer to the C position.

As the engine coolant temperature increases, the resistance in the ECT sending unit decreases. Since current always seeks the path of the least resistance, more current begins to bypass the C coil and travel directly to ground through the ECT sending unit. The coil H magnetic field then becomes stronger than the coil C magnetic field, causing the pointer to move toward the H position.

When the ignition switch is in the ON or START position, battery voltage applies through the IG fuse to the oil pressure indicator in the instrument panel cluster. If the engine oil pressure falls below 32 kPa (4.5 psi), the oil pressure sensor that is in the engine block closes. The closing of the switch provides a ground path to the oil pressure indicator and the bulb lights.