The torque converter clutch (TCC) solenoid valve is a three-port assembly which uses negative (-) duty cycle, pulse width modulation (PWM) to control the rate of TCC apply and release. The solenoid's ability to ramp apply and release pressures results in a smoother apply and release of the TCC in all conditions.

The TCC PWM solenoid valve is a normally closed valve, mounted to the upper control valve body and used to control the position of the TCC apply valve.

TCC PWM solenoid valve resistance should be 10-11 ohms when measured at 20°C (68°F). Resistance should be 13-15 ohms when measured at 100°C (212°F).

A transmission pressure control solenoid (PCS) valve, also known as a force motor is a three-port, spool valve, electronic pressure regulator. The solenoid controls pressure based on a flow of current through its coil-winding. The solenoid controls main line pressure by moving a pressure regulator valve against spring pressure.

The position of the PC solenoid valve is controlled by a combination of two methods: high side control and low side control. One terminal of the solenoid receives a fixed frequency signal of 614.0 Hz. This signal varies in positive (+) duty cycle. This feed circuit is called Force HI.

The opposite terminal of the transmission pressure control solenoid is called Force LO. Force LO provides a ground for the solenoid.

This combination of Force HI and Force LO circuitry controls the actual current through the PC solenoid valve. This advanced control method assures instantaneous control of line pressure when changes occur in the TP sensor and adaptive learning.

The resistance on the PC solenoid valve should measure 3.0-8.0 ohms when measured at 20°C (68°F).

A shift solenoid valve is a two-port, feed-bleed device consisting of a coil/plunger-ball assembly. The solenoid assembly works with an orifice to pressurize the shift valve end chamber when voltage is applied to its coil. The controlled pressure then moves the shift valve against a spring causing a shift to occur. When voltage is no longer applied, the chamber opens to exhaust and the opposite shift valve action occurs. Shift solenoids eliminate the need for TV and governor pressures to control shift valve operation.

The 4T80-E transmission uses two shift solenoid valves: the 1-2 and 2-3, which are attached to the lower valve body.

Important: If both solenoids lose power, only Second gear will result.

Shift solenoid resistance should measure 19-24 ohms when measured at 20°C (68°F). Resistance should measure 24-31 ohms when measured at 100°C (212°F). Shift solenoid current flow should not exceed 0.75 amps. The shift solenoid valve should energize at a voltage of 7.5 volts or more, measured across the terminals. The shift solenoid valve should de-energize when voltage is one volt or less.

The automatic transmission fluid pressure (TFP) manual valve position switch assembly consists of two normally-open pressure switches. The assembly is attached to the lower control valve body. The PCM supplies ignition voltage on the two range signal circuits, signal circuit A and signal circuit C. By grounding one of the switches with fluid pressure from the manual valve, the PCM detects a garage shift from PARK/NEUTRAL to REVERSE or PARK/NEUTRAL to DRIVE (D1, D2, D3, or D4). Refer to Transmission Fluid Pressure Manual Valve Position Switch Logic . This information is used by the PCM in order to adjust line pressure during garage shifts.

The vehicle speed sensor (VSS) is mounted on the transmission case extension facing toward the right wheel. This sensor consists of a permanent magnet surrounded by a coil of wire. The sensor mounts into the extension and maintains a slight air gap (0.045-0.109 in) between itself and a rotor which is located on the differential. The VSS measures the speed of the rotor, which contains 31 teeth. As the differential rotates, an AC signal is induced in the VSS. The AC signal varies in frequency and voltage output:

This input is used for TCC, line pressure, shift timing and torque management controls.

Sensor resistance should be 1300-1950 ohms when measured at 20-100°C (68-212°F). Output voltage varies with speed from a minimum of 0.5 volts AC at 100 RPM, to more than 100 volts AC at 8000 RPM.

The automatic transmission input (shaft) speed sensor is mounted in the case cover facing the drive sprocket. The sensor consists of a permanent magnet surrounded by a coil of wire. The sensor mounts into the case and maintains a slight air gap (0.045-0.109 in.) between itself and the drive sprocket. An AC voltage signal is induced in the input sensor by rotating the drive sprocket, which contains 39 teeth cut in its outside diameter. The voltage output and frequency varies with drive sprocket speed:

Inside the PCM, this analog signal changes to a digital signal. The processor then compares this digital signal to a fixed clock signal within the PCM in order to determine the actual turbine speed. The PCM uses input speed for control of line pressure, speed calculation and gear ratio.

Sensor resistance should be 1300-1950 ohms when measured at 20-100°C (68-212°F). Output voltage will vary with speed from a minimum of 0.5 volts AC at 100 RPM, to more than 100 volts AC at 8000 RPM.

The automatic transmission fluid temperature (TFT) sensor controls TCC and line pressure. The TFT sensor attaches to the upper control valve assembly. The TFT signals the PCM regarding transmission fluid temperature. The sensor is a negative temperature coefficient thermistor which receives a five volt signal from the PCM.

When the temperature is cold, the sensor resistance is high; therefore, the PCM sees a high signal voltage. As the fluid warms, the sensor resistance decreases, the voltage drop across the sensor becomes lower.

The TFT sensor may be tested with an ohmmeter across pin terminals L and M of the 20-way transmission connector. Nominal ohm readings at specified temperatures are given in voltage levels at the PCM. Refer to Transmission Fluid Temperature Sensor Specifications .

The temperature sensor mode operates in the following two ways:

A PCM internal shunt circuit comes into play as the temperature increases beyond 50°C (122°F). As the temperature decreases, the internal shunt comes out at 40°C (104°F). There is a 10°C (18°F) overlap.

The transmission internal mode switch (IMS) is a multi-signal switch assembly attached to the lower control valve body. The IMS consists of a set of stationary contacts and a set of sliding contacts. The manual valve link assembly connects the sliding contacts to the manual valve. Electrically, the stationary contacts are connected to ground through the IMS ground circuit and the sliding contacts are connected to the PCM through four IMS signal circuits. The signal voltage at the PCM is high, ignition voltage, when a signal circuit is open and low, 0 volts, when a signal circuit is closed to ground. Each gear selector position grounds one or more of the signal circuits in a unique pattern that enables the PCM to determine gear selector position. Refer to Transmission Internal Mode Switch Logic .