Grand Marquis V8-4.6L Flex Fuel (2010)
Electronic Throttle Control Module: Description and Operation
TORQUE-BASED ELECTRONIC THROTTLE CONTROL (ETC)
Overview
The torque-based ETC is a hardware and software strategy that delivers an engine output torque (via throttle angle) based on driver demand (pedal
position). It uses an electronic throttle body (ETB), the powertrain control module (PCM), and an accelerator pedal assembly to control the throttle
opening and engine torque.
Torque-based ETC enables aggressive automatic transmission shift schedules (earlier upshifts and later downshifts). This is possible by adjusting the
throttle angle to achieve the same wheel torque during shifts, and by calculating this desired torque, the system prevents engine lugging (low RPM and
low manifold vacuum) while still delivering the performance and torque requested by the driver. It also enables many fuel economy/emission
improvement technologies such as variable camshaft timing (VCT), which delivers same torque during transitions.
Torque-based ETC also results in less intrusive vehicle and engine speed limiting, along with smoother traction control.
Other benefits of torque-based ETC are:
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eliminate cruise control actuators
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eliminate idle air control (IAC) valve
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better airflow range
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packaging (no cable)
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more responsive powertrain at altitude and improved shift quality
The ETC system illuminates a powertrain malfunction indicator (wrench) on the instrument cluster (IC) when a concern is present. Concerns are
accompanied by diagnostic trouble codes (DTCs) and may also illuminate the malfunction indicator lamp (MIL).
Electronic Throttle Body (ETB)
The ETB has the following characteristics:
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The throttle actuator control (TAC) motor is a DC motor controlled by the PCM (requires 2 wires).
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There are 2 designs: parallel and in-line. The parallel design has the motor under the bore parallel to the plate shaft. The motor housing is
integrated into the main housing. The in-line design has a separate motor housing.
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An internal spring is used in both designs to return the throttle plate to a default position. The default position is typically a throttle angle of 7 to 8
degrees from the hard stop angle.
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The closed throttle plate hard stop is used to prevent the throttle from binding in the bore. This hard stop setting is not adjustable and is set to
result in less airflow than the minimum engine airflow required at idle.
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The required idle airflow is provided by the plate angle in the throttle body assembly. This plate angle controls idle, idle quality, and eliminates the
need for an IAC valve.
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There is one reference voltage and one signal return circuit between the PCM and the ETB. The reference voltage and the signal return circuits are
shared with the reference voltage and signal return circuits used by the accelerator pedal position (APP) sensor. There are also 2 throttle position
(TP) signal circuits for redundancy. The redundant TP signals are required for increased monitoring reasons. The first TP signal (TPS1-NS) has a
negative slope (increasing angle, decreasing voltage) and the second signal (TPS2-PS) has a positive slope (increasing angle, increasing voltage).
The TPS2-PS signal reaches a limit of approximately 4.5 volts at approximately 45 degrees of throttle angle.
Accelerator Pedal Position (APP) Sensor
Depending on the application either a 2-track or 3-track APP sensor is used. For additional information on the APP sensor, refer to Engine Control
Components. See: Computers and Control Systems/Description and Operation/Engine Control Components
Electronic Throttle Control (ETC) System Strategy
The torque-based ETC strategy was developed to improve fuel economy and to accommodate variable camshaft timing (VCT). This is possible by not
coupling the throttle angle to the driver pedal position. Uncoupling the throttle angle (produce engine torque) from the pedal position (driver demand)
allows the powertrain control strategy to optimize fuel control and transmission shift schedules while delivering the requested wheel torque.
The ETC monitor system is distributed across 2 processors within the PCM: the main powertrain control processor unit (CPU) and a separate
monitoring processor. The primary monitoring function is carried out by the independent plausibility checker (IPC) software, which resides on the
main processor. It is responsible for determining the driver-demanded torque and comparing it to an estimate of the actual torque delivered. If the
generated torque exceeds driver demand by a specified amount, appropriate corrective action is taken.
