Lincoln Aviator 2020-2024 Service Manual / Chassis / Steering System / Power Steering / Description and Operation - Power Steering - System Operation and Component Description

Lincoln Aviator: Power Steering / Description and Operation - Power Steering - System Operation and Component Description

System Operation

System Diagram


Item Description
1 EPAS gear
2 EPAS motor
3 EPAS position sensor
4 EPAS torque sensor
5 PSCM
6 GWM
7 PCM
8 IPC
9 BCM
10 RCM
11 ABS
12 IPMB
13 IPMA
14 PAM
15 SASM
16 SCCM
17 SUMA

Network Message Chart

  PSCM Network Input Messages


Broadcast Message Originating Module Message Purpose
Anti-lock brake control activated ABS module Informs the PSCM an anti-lock brake event is taking place. The PSCM modifies operating parameters when an anti-lock brake event is taking place.
Battery voltage   BCM This message is sent to the GWM and then to the PSCM. Provides the PSCM with the current 12-volt battery and charging system voltage.
Driven wheel torque output   PCM This message is sent to the GWM and then to the PSCM. Informs the PSCM of the current torque output available at the driven wheels. This information is used for active park assist operation.
Ignition status   BCM This message is first sent to the GWM and then to the PSCM. Used to confirm the ignition status of the vehicle.
Lateral motion control data   IPMA Contains all the lane keeping assist information necessary for EPAS lane keeping assist operation while driving through a curve.
Lane keep assist data   IPMA Contains all the lane departure and lane keeping assist information necessary for EPAS lane keeping assist operation.
Odometer master value   IPC This message is first sent to the GWM and then to the PSCM. The PSCM uses the odometer information for various self diagnostics.
Outside air temperature   IPC This message is first sent to the GWM and then to the PSCM. The PSCM uses the temperature information for various self diagnostics.
Powertrain status   PCM This message is first sent to the GWM and then to the PSCM. Used to confirm the status of the operating mode; off - torque not available, on - torque not available, start in progress - torque not available or on - torque available.
Ride height status   SUMA Provides the PSCM with the current status of the air suspension ride height.
Reverse gear status   PCM This message is sent to the GWM and then to the PSCM. Informs the PSCM of the current reverse gear status; inactive not confirmed, inactive confirmed, active not confirmed, or active confirmed. This information is used for active park assist operation.
Selectable drive mode chassis request ABS module Informs the PSCM of the current chassis drive mode request.
Stability control activated ABS module Informs the PSCM either an ESC or RSC event is taking place. The PSCM modifies operating parameters when a stability control event is taking place.
Steering angle request   IPMA Contains the steering angle requests for lane keeping assist operation.
Steering angle request   PAM Contains the steering angle requests for parking assist operation.
Steering assist data   IPMA Contains all the collision mitigation by braking information necessary for EPAS collision mitigation operation.
Steering wheel angle information   SASM Provides the active park assist system with the current steering wheel angle, as measured by the adaptive steering system, in degrees as well as the steering wheel angle count (number or revolutions).
Turn signal switch status   SCCM Informs the PSCM of the current, driver selected turn signal switch status; off, left, or right. This message is used for lane keeping system function.
Vehicle configuration information   BCM This message is first sent to the GWM and then to the PSCM. Used to compare the PSCM configuration against the vehicles specific configuration (central car configuration).
Vehicle latitudinal acceleration rate ABS module Used by the PSCM for steering assist calculations.
Vehicle speed data ABS module Determines the level of assist supplied to the steering gear and to validate the steering wheel component angle by comparing the rotational speeds of each wheel. The difference in the speed of each wheel is used to derive a steering angle for comparison against the EPAS motor position sensor.
Vehicle yaw rate ABS module Used by the PSCM for steering assist calculations.
Vehicle yaw rate   RCM Used by the PSCM for steering assist calculations.
Wheel direction ABS module Provides the PSCM with the current direction of travel for all 4 wheels. Used by the PSCM for steering assist calculations.
Wheel speed ABS module Provides the PSCM with the current direction of travel for all 4 wheels. Used by the PSCM for steering assist calculations.

EPAS System

The PSCM controls the functions of the EPAS system and communicates with other modules over the HS-CAN2 and through the GWM.

To activate, the EPAS system requires battery voltage at the hot at all times PSCM input, battery voltage at the PSCM ignition-run input. The PSCM must also be able to communicate with other modules over the HS-CAN2 and must receive the power pack status message from the PCM.

The main input for calculating the level of EPAS assist is the steering torque sensor signal (internal to the PSCM). Vehicle speed is also taken into consideration in order to achieve the vehicle speed dependent steering assist characteristic.

The EPAS gear uses a reversible motor to apply the steering assist by moving the rack inside the steering gear. The motor is connected to the rack of the steering gear by a toothed belt and pulley-bearing assembly.

The PSCM continually monitors and adjusts steering efforts based on the steering torque sensor signal, motor position and HS-CAN2 inputs to enhance the feel of the steering system. As vehicle speed increases, the amount of assist decreases to improve and enhance road feel at the steering wheel. As vehicle speed decreases, the amount of assist increases to ease vehicle maneuvering. Compensation is made to reduce the effect of pull or drift experienced when driving on roads with a high degree of camber. Compensation is also made for the impact of wheel imbalance on steering feel, up to a predetermined threshold.

The steering torque sensor senses the torque at the steering wheel. It is integrated into the PSCM and works by measuring the relative rotation between an input and output shaft which are connected by a torsion bar. The steering torque sensor sends out 2 PWM signals which allows a channel to channel cross-check and an accurate correction of the neutral point.

The PSCM is self-monitoring and is capable of setting and storing Diagnostic Trouble Codes (DTCs). Depending on the DTC set, the PSCM may enter a failure mode. In addition, the PSCM may send a request to the IPC to display a message in the message center, alerting the driver of a potential EPAS concern. The warning message is sent over the HS-CAN2 to the GWM which relays the message to the IPC over the HS-CAN3.

Failure Modes

When a DTC is present in the PSCM, the EPAS enters 1 of these modes of operation.

Limp Aside Mode - The EPAS enters a limp aside mode when an internal failure occurs but short term operation on a backup system is possible. This failure mode reduces steering assist over a short period of time until the steering enters manual steering mode. A warning message is illuminated in the message center indicating a potential EPAS concern.

Limp Home Mode - The EPAS enters a limp home mode when an internal failure occurs but operation on a backup system is possible. This failure mode gives the steering operation a heavier than normal feel in all driving conditions. A warning message is illuminated in the message center indicating a potential EPAS concern.

Manual Steering Mode - The EPAS enters a manual steering mode (no electrical steering assistance is provided) when a concern considered to be a critical safety concern is detected. In manual steering mode, the vehicle has mechanical steering only which gives the steering operation a heavy feel. A warning message is illuminated in the message center indicating a potential EPAS concern.

Reduced Steering Assist Mode - The EPAS enters a reduced steering assist mode to protect the internal components of the EPAS when a non-critical safety concern is detected by the PSCM, concerns such as low battery voltage, high battery voltage or over-temperature are considered non-critical safety concerns. This reduced steering assist mode gives the steering operation a heavier than normal feel.

Pull Drift Compensation (PDC)

EPAS equipped vehicles have a Pull Drift Compensation (PDC) feature to assist drivers in compensating for variation in road and driving conditions. The feature adjusts power assist offset by reducing the steering wheel effort (input torque) required to keep the vehicle traveling straight. The Pull Drift Compensation (PDC) feature is automatically enabled at vehicle speeds above 40 km/h (25 mph) with sensors indicating the vehicle is traveling straight. Pull Drift Compensation (PDC) is designed to compensate for variations in road crown.

The system detects input torque to the wheel by the driver to slowly ramp in a steering assist offset to neutralize, in most situations and within limits, steering efforts for the duration of time those driving conditions exist. Full compensation requires up to 45 seconds. Changing lanes on a multilane road and the expected change in road crown would trigger a change in torque input and a compensation adjustment, and is a normal operation of the Pull Drift Compensation (PDC) feature. The feature updates automatically and continuously, however, since it is based on input torque, the feature only works with hands on the steering wheel while driving in a straight line. The system does not compensate when turning or during slight curves on highways. The system does not compensate if driver input torque, steering wheel angle or vehicle yaw rate is too large. For the system to compensate, the driver must have both hands on the steering wheel.

Active Park Assist

The active park assist system is controlled by the PAM and, when activated, can detect a parking space and steer the vehicle into the space by sending commands to the EPAS gear (the driver still controls the throttle, brakes and transmission). The active park assist system is comprised of several systems and modules working together to aid in parallel parking maneuvers. The presence of certain Diagnostic Trouble Codes (DTCs) in any of those modules or systems may keep the active park assist system from being enabled or may disable the system if currently being used.
Refer to: Parking Aid - System Operation and Component Description (413-13C Parking Aid - Vehicles With: Active Park Assist, Description and Operation).

Evasive Steer Assist (ESA)

When approaching a stationary vehicle or a slower vehicle traveling in the same direction, the Evasive Steer Assist (ESA) system is designed to help the driver steer around the vehicle. If activated, the system applies additional steering torque to help the driver steer around the vehicle. After passing the vehicle, the system applies steering torque to help the driver steer back into the lane. The system deactivates after passing the vehicle.

Evasive Steer Assist (ESA) can make the steering feel lighter if the driver steers too slow and heavier if the driver steers too aggressively.

Lane Centering Assist (LCA)

NOTE: If equipped, the Lane Centering Assist (LCA) can interfere with accurate EPAS diagnostics. Disable the Lane Centering Assist (LCA) before test driving the vehicle to diagnose EPAS concerns. For information on disabling the Lane Centering Assist (LCA), refer to the Owner's Literature.

The Lane Centering Assist (LCA) utilizes the camera located in the IPMA to detect and track the road lane markings. The Lane Centering Assist (LCA) operates together with ACC. The Lane Centering Assist (LCA) assists the driver by automatically providing steering torque to help the driver keep the vehicle in the center of the lane.
Refer to: Lane Keeping System - System Operation and Component Description (419-07 Lane Keeping System, Description and Operation).

Lane Keeping System (LKS)

NOTE: If equipped, the Lane Keeping System (LKS) can interfere with accurate EPAS diagnostics. Disable the Lane Keeping System (LKS) before test driving the vehicle to diagnose EPAS concerns. For information on disabling the Lane Keeping System (LKS), refer to the Owner's Literature.

The Lane Keeping System (LKS) utilizes the camera located in the IPMA to detect and track the road lane markings. The Lane Keeping System (LKS) has 2 functions, lane keeping alert and lane keeping aid. The lane keeping alert detects unintentional drifting toward the outside of the lane and alerts the driver through steering wheel vibrations and a visual alert in the IPC message center. The lane keeping aid assists the driver by automatically providing steering torque to help the driver keep the vehicle in the lane.
Refer to: Lane Keeping System - System Operation and Component Description (419-07 Lane Keeping System, Description and Operation).

Selectable Drive Modes

The selectable drive mode system optimizes driveability and comfort as well as maximizing traction while operating on different types of terrain. The PSCM adjusts steering effort and feel based on the selected mode. For additional information on selectable drive modes,
Refer to: Anti-Lock Brake System (ABS) and Stability Control - System Operation and Component Description (206-09 Anti-Lock Brake System (ABS) and Stability Control, Description and Operation).

Component Description

EPAS Gear

The EPAS gear is an assembly consisting of a PSCM, a motor, and a steering torque sensor, all of which are serviced as an assembly. The inner and outer tie rods and the steering gear bellows boots can be serviced separately.

  • The steering torque sensor is mounted near the input shaft of the EPAS gear and is used by the PSCM to determine how much force is being used to turn the steering wheel.
  • The EPAS gear has one inner tie rod and one outer tie rod located at each end of the gear assembly.
  • The EPAS gear has one bellows boot located at each side of the EPAS gear assembly. Each boot is held in place with 2 boot clamps.

PSCM

The PSCM is the ECU for the EPAS system. The module monitors all sensor inputs and HS-CAN2 messages relating to the EPAS system and directly controls the output of the EPAS motor.

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