Cruise Control Description and Operation Adaptive Cruise
Adaptive Cruise Control (ACC)
The Adaptive Cruise Control (ACC) System is an enhanced cruise control system with the ability to sense and react to forward traffic. Compared to the common cruise control system found on many vehicles, the main functional enhancement of the ACC system
is the ability to detect the presence of a vehicle in the path of the ACC vehicle. The ACC retains the existing cruise control feature that controls the vehicle speed to the driver selected speed. However, ACC allows a driver to set and maintain a following
distance to the preceding nearest vehicle in the ACC vehicle path. The distance sensing cruise control module (DSCC) calculates a follow speed limit to ensure an acceptable distance is maintained to the preceding vehicle in front, should one be present. The
ACC system automatically adjusts the speed of an ACC vehicle when the vehicle comes up behind a slower travelling vehicle in front. The ACC system applies limited automatic braking and throttle control without driver input when necessary to maintain the set
following distance of the ACC vehicle. The preceding vehicles speed and acceleration along with the ACC vehicle speed and acceleration and the distance between the 2 vehicles are factors used by the DSCC to determine the ACC follow speed limit. The ACC
vehicle speeds up to the original driver selected set speed when the pathway becomes clear without driver input.
Adaptive Cruise Control (ACC) System Description
The Adaptive Cruise Control (ACC) System depends on various modules on the vehicle to function and each module performs a function that is critical to the proper operation of the ACC System. ACC will not operate if any components fail. Communication between
modules is via the high-speed General Motors local area network (GMLAN) and the class 2 serial data circuit. The body control module (BCM) provides a translating gateway function between the class 2 and the GMLAN data links. The GMLAN utilizes
the controller area network (CAN) communications protocol. The following is a functional description of the distance sensing cruise control module (DSCC) and the other associated components:
Distance Sensing Cruise Control Module (DSCC)
The distance sensing cruise control module (DSCC) communicates with the forward looking sensor (FLS) via controller area network (CAN) serial data. The DSCC utilizes the FLS to identify and classify objects in the road environment. The FLS scans the road
environment to detect targets within its specified field of view. The DSCC then makes throttle and/or brake commands to the engine control module (ECM) and electronic brake control module (EBCM) via GMLAN serial data circuit to control vehicle acceleration/deceleration
based on data from the FLS radar. The ECM and EBCM provide throttle control and automatic braking needed for proper cruise speed adjustment. An internal yaw rate sensor is used by the DSCC to determine the predicted path of the adaptive cruise control (ACC)
vehicle. The main power feed for the DSCC is the battery and this signal is always at battery potential. However, the ACC system only activates when the ignition 1 input is active and in the RUN position. The ignition 1 voltage signal to the DSCC
has to be 9.2 volts or more to be considered active. When the ignition 1 signal is not active, all ACC functions are disabled. The following is a list of the DSCC functions:
• | The FLS radar processes the road environment to get data concerning any vehicle ahead of the ACC vehicle. Detection, parameter estimation, tracking, object classification and diagnostics are the primary FLS functions. When an object is detected,
the DSCC calculates the object range, range rate, acceleration and azimuth angle parameters. |
• | The DSCC performs ACC state processing automatically - distance control or speed control. The ACC system operates in 2 possible states - Cruise or Follow. The normal operating state is Cruise, whereby the vehicle speed is controlled
to match the driver selected set speed. When a preceding forward target is identified by the FLS, the ACC system will automatically transition into the follow speed state to provide proper lane spacing behind the target vehicle in front. The preceding vehicle's
speed and acceleration, with the ACC vehicle speed, acceleration and distance between the 2 vehicles will be used to determine the ACC follow speed limit. The ACC follow speed limit will ensure that an acceptable distance is maintained to the preceding
vehicle. |
• | The DSCC determines the Follow Speed limit for throttle control by the ECM. |
• | The DSCC arbitrates the ACC system brake and throttle control between the EBCM and the ECM. |
• | The DSCC requests brake light activation during automatic braking. |
• | The DSCC provides operational feedback to the vehicle driver. The DSCC sends signals for telltales and messages to be displayed on the head-up display (HUD) or driver information center (DIC) via the body control module (BCM). The DSCC will provide
audible feedback to the driver via the BCM and the radio amplifier as well. |
Body Control Module (BCM)
The following are the ACC system functions provided by the BCM:
• | The BCM provides a translating gateway between the class 2 serial data circuit and the high speed GMLAN serial data circuit. |
• | The BCM reads all cruise control switches and the gap switch. The DSCC monitors a variety of user operated switches from the BCM switch status information sent via the GMLAN serial data circuit. |
• | The BCM illuminates the brake light based on a GMLAN message from the DSCC during automatic braking. |
• | The BCM measures the brake pedal position and sends brake pedal travel status via GMLAN serial data circuit to the ECM. The ECM disengages the ACC system when the brake is applied by the driver pressing the brake pedal. |
• | The BCM serves as a gateway to the display system's (HUD, IPC, DIC and Amplifier) visual and audible warnings. The BCM will generate visual and audible warning class 2 messages based on high speed GMLAN signals from the DSCC. |
Engine Control Module (ECM)
The following are the ACC system functions performed by the ECM:
• | The ECM provides the electronic throttle control to the ACC system. The ECM is also responsible for determining when a driver is overriding the adaptive cruise control throttle position by pressing the accelerator pedal. |
• | The ECM processes the cruise control switch requests received via the GMLAN serial data circuit from the BCM. Engaging and disengaging the ACC system are functions performed by the ECM. |
• | The ECM determines the driver selected vehicle speed. Unless the ACC module requests a lower vehicle speed, the ECM will control the vehicle speed to the driver selected set speed. |
• | The ECM allows automatic braking without disengaging the ACC. |
Electronic Brake Control Module (EBCM)
The following are the ACC system functions performed by the EBCM:
• | The EBCM provides automatic braking for the ACC system. The DSCC will request vehicle deceleration via high speed GMLAN serial data circuit. |
• | The EBCM determines when the driver-applied brake pressure is active. The EBCM will communicate this status via the GMLAN serial data circuit to the BCM. |
• | The EBCM releases vehicle automatic braking when there is a throttle override by the driver pressing the accelerator. |
• | The EBCM predicts brake temperatures. Due to automatic braking, the brake system may overheat. When the brakes are overheated, the EBCM requests the ACC system to be temporarily shut down by the ECM until the brakes cool to a normal operating temperature. |
• | The EBCM calculates yaw rate and provides the yaw rate data to the DSCC for vehicle path predictions. |
Refer to
ABS Description and Operation.
Transmission Control Module (TCM)
The transmission control module (TCM) provides a down shift to protect the brakes. When the TCM detects some driver braking activity or ACC automatic braking activity, the TCM down shifts the vehicle transmission to increase engine braking. This helps
reduce the ABS braking activity, extend brake pad life and reduce brake overheating.
Driver Information Center (DIC)
The DIC is a part of the instrument panel cluster (IPC) and displays the ACC system warning messages. The DSCC requests messages to be displayed on the DIC by sending a GMLAN request to the BCM. The BCM sends a class 2 serial data request to the
DIC demanding the display of the warning message. When the message is acknowledged by the driver and the cause of the message resolved, the DIC turns the message off. These displays are accompanied by a chime warning internal to the DIC. The ACC system will
not operate if the DIC fails. The following are the 3 ACC messages that can be displayed on the DIC:
Head-Up Display (HUD)
The head-up display (HUD) displays ACC system telltales and status information. The DSCC sends a message to the BCM via the GMLAN serial data circuit requesting the display of a HUD telltale. The HUD displays the telltale when it receives a class 2
message from the BCM demanding illumination of the telltale. Feedback to a driver action takes precedence over other status information sent to the HUD by the BCM. The HUD is enabled in power mode RUN. The driver may have to adjust the position of the HUD or
the intensity of the display to see the information being displayed. The ACC system will not operate if the HUD fails. The HUD displays the following telltales and ACC status indicators:
• | Cruise Speed Limited Message |
• | Cruise Engaged Telltale |
• | Follow Distance Display |
Radio Amplifier
The amplifier receives audible warning commands via a class 2 message from the BCM. The chime alerts the vehicle driver to certain ACC vehicle conditions. The audible chime accompanies a visual indicator as a warning to the driver. The ACC system
will not operate if the radio amplifier fails.
Brake Pedal Position (BPP) Sensor
The brake pedal position (BPP) sensor helps the BCM determine when pressure is being applied to the brake by the driver stepping on the brake pedal. The BPP sensor receives a low reference signal and a 5-volt reference from the BCM. When the brake is applied,
a signal is applied from the BPP sensor through the BPP sensor signal circuit to the BCM. The BCM utilizes this signal in deciding when to command the activation of the stop lamps. The BCM continuously sends signals via the GMLAN serial data circuit to the EBCM
and the ECM reflecting the brake pedal position status. This will include the initial brake travel signal required for the activation of the ACC system. The ACC system will not engage unless the initial brake pedal travel signal is valid and received by the
BCM. When the BCM brake pedal position signal indicates that brake pedal pressure is being applied by the driver when the ACC system is engaged, the ECM immediately disengages the ACC system. Re-engaging the ACC system will require the driver pressing the set
or resume switch. Refer to
Brake Pedal Position Sensor Calibration and
Exterior Lighting Systems Description and Operation for more information on the brake pedal pressure sensor.
Accelerator Pedal
Deceleration of the ACC vehicle to maintain a certain distance and speed while a slower moving vehicle is in its path is achieved through throttle control by the ECM and the application of light automatic braking by the EBCM. During automatic braking the
ECM is commanded to release the throttle by the DSCC. The DSCC via the GMLAN serial data circuit requests the ECM to release the throttle from the currently controlled cruise position. At the end of automatic braking, the ECM will control the vehicle speed to
the current set vehicle speed. Driver throttle override occurs when the driver of the ACC vehicle depresses the accelerator pedal with the intention of requesting greater speed than the current throttle position. An example is an ACC vehicle driver stepping
on the accelerator for a passing maneuver. The ECM continuously monitors the throttle and reports a throttle override condition. When no throttle override is present, automatic braking is allowed. When throttle override is detected by the ECM, automatic braking
in not allowed to affect the vehicle acceleration.
Cruise Control Switch
The cruise control switch, functionally is a common feature that is shared between the Adaptive Cruise Control (ACC) System and the regular cruise control system. The ACC system will not operate if any cruise switch fails. The cruise control switch comprises
the following cruise control function switches:
The cruise control function switches are arranged in a resistive ladder design whereby each switch function is set up with different resistance values. The body control module (BCM) through the cruise control switch signal circuit detects a predetermined
voltage value when any cruise control switch function is activated. The associated cruise control function signal detected by the BCM is then sent to the engine control module (ECM) as a General Motor local area network (GMLAN) serial data circuit message. The
ECM on receiving the message provides the cruise control function requested by the BCM. The ECM is responsible for recognizing and responding to cruise control switch requests sent by the BCM. The cruise control function switches are used by the ECM to communicate
to the distance sensing cruise control module (DSCC) the driver selected vehicle speed. The driver selected vehicle speed is communicated through GMLAN serial data circuit to the DSCC and the BCM. The ACC system engages and adjusts vehicle speeds based on the
activation of the following cruise control function switches:
On/Off Switch
The BCM monitors the On/Off switch status and makes a determination that the On/Off switch is activated based on a predetermined voltage value at the cruise control switch signal circuit. The On/Off switch state is then relayed to the ECM via the GMLAN
serial data circuit. The ECM will recognize and communicate the On/Off switch input to the DSCC. When the On/Off switch is turned ON, it will cause the ACC system to enter either STANDBY ENABLED or STANDBY DISABLED state. The STANDBY ENABLED state indicates
that every condition required for the ACC system to function have been met but the ACC is not yet engaged. When in the STANDBY DISABLED state, all conditions necessary for the ACC to function has not been met. When the On/Off switch is turned OFF, ACC will enter
the DISABLED state. ACC will not be active in the DISABLED state. When automatic braking is active and the ACC On/Off switch is turned OFF, ACC will delay entering the DISABLED state.
Set/Decrease Switch
The ACC system is engaged when the vehicle driver presses and releases the set/decrease switch. The engaged state of the ACC system can only be entered when the On/Off switch is turned ON. When the set/decrease switch is pressed, the driver selected speed
is set to the current vehicle speed by the ECM. The vehicle speed must be above 40 km/h (25 mph). The current driver selected speed is displayed by the head-up display (HUD). While in the engaged state, the driver selected vehicle speed and following
distance can be adjusted. Pressing the set/decrease switch when the ACC system is engaged allows the driver to decrease the driver selected vehicle speed. Pressing and holding the set/decrease switch will allow the vehicle to decelerate from the current set
vehicle speed without deactivating ACC. The Tap-Down function occurs by momentarily pressing and releasing the set/decrease switch when ACC is engaged. With the Tap-Down function, the driver selected speed is decreased by 1 km/h (1 mph) each time
the set/decrease switch is pressed.
The Resume/Increase Switch
When in the resume/increase state, ACC is active and the previously set driver selected speed has not been cleared. The resume/increase switch is used to increase the driver selected speed when ACC is active. The extent to which the driver selected speed
can be increased from the resume/increase switch depends on how long the switch is pressed. The presence of a slower moving vehicle in the path of the ACC vehicle will limit the extent to which the driver selected speed can be achieved. If there is no preceding
vehicle in front limiting the ACC vehicle acceleration, the current vehicle speed attained is the new driver selected speed. The current driver selected speed is displayed by the HUD. Acceleration is terminated when the resume/increase switch is released. Momentarily
pressing and releasing the resume/increase switch will result in the Tap-Up function. With the Tap-Up function, the driver selected speed is increased in increments of 1 km/h (1 mph).
Gap Up/Down Switch
The gap up/down switch allows the driver to determine how closely the adaptive cruise control (ACC) vehicle follows a target vehicle while ACC is engaged. When the ACC vehicle speed is being limited due to a slower travelling vehicle, the ACC vehicle speed
is automatically controlled to the follow speed limit. The gap switch has 6 following distance selections that range from 1-2 seconds. The gap switch following distance between the ACC vehicle and the target vehicle is expressed in time as
opposed to actual distance. The distance maintained for a selected gap will vary based on vehicle speed. The faster the vehicle speed, the further back you will follow. The gap up/down switch is hard-wired to the body control module (BCM) and voltage is provided
to the switch from the BCM via the gap up/down ignition 1 voltage circuit. Based on voltage variations, the BCM is able to read the selected gap up/down switch selection and communicates the switch status on the GMLAN serial data circuit to the distance sensing
cruise control module (DSCC). The gap up/down switch is a 3-position momentary switch - Center, Gap Up and Gap Down - with the following valid signal values:
The initial push of the gap switch recalls the current setting and activates the display. Subsequent pushes of the gap switch will change the gap setting. Momentarily pressing the gap up/down switch will adjust the switch to the desired gap setting. When
the voltage from the gap up/down switch circuit is in an invalid range, the BCM will default to increasing the gap value.
Cruise Indicators and Messages
SERVICE RADAR CRUISE
The distance sensing cruise control module (DSCC) commands the display of the SERVICE RADAR CRUISE message in the driver information center (DIC) when it detects a malfunction in the Adaptive Cruise Control (ACC) System. The DSCC sends a request to the
body control module (BCM) via the GMLAN serial data circuit to display the SERVICE RADAR CRUISE message in the DIC. The DIC displays the SERVICE RADAR CRUISE message when it receives a class 2 serial data request from the BCM. The SERVICE RADAR CRUISE
is displayed in the DIC only when a diagnostic condition is present, the cruise switch is in On position, the vehicle speed is above 40 km/h (25 mph), and cruise is engaged or attempted to be engaged. When the message is displayed in the DIC the
ACC system disengages. The DIC sounds an internal chime anytime it displays the SERVICE RADAR CRUISE message.
CRUISE NOT READY
The DSCC commands the display of the CRUISE NOT READY message in the DIC when ACC cannot engage due to a temporary condition. The ACC vehicle conditions that prompt the display of the CRUISE NOT READY message are temporary and do not require service. If
no target is identified by the forward looking sensor (FLS) and cruise is attempted to be engaged, the CRUISE NOT READY message will be displayed in the DIC until the FLS is able to identify an accepted target. CRUISE NOT READY message is also displayed in the
DIC when the DSCC is too hot and the brakes are too hot. The DIC sounds an internal chime anytime it displays the CRUISE NOT READY message.
CLEAN RADAR
The CLEAN RADAR message displays in the DIC when the DSCC detects a blockage of the FLS and cruise is engaged or attempted to be engaged. The FLS may be blocked by snow, ice, dirt, heavy rain or road spray. The DSCC commands the display of the CLEAN RADAR
message via a GMLAN serial data circuit request to the BCM. The DIC displays the CLEAN RADAR message when it receives a class 2 serial data request from the BCM. When the CLEAN RADAR message is displayed in the DIC, safely park the vehicle and turn OFF
the ignition. Clean the driver side front fascia lens to eliminate the blockage. It may be necessary to clean both the outside surface of the lens, the inside surface of the lens and the DSCC surface. Refer to
Distance Sensing Cruise Control Maintenance for more cleaning information. It is important to turn the ignition OFF before cleaning any of the named surfaces. This is because the CLEAN RADAR message may still display in the DIC after cleaning the 3 surfaces. Cycling
the ignition to OFF for 10 seconds is necessary to clear the CLEAN RADAR indicator if the indicator remains ON in the DIC. The DIC sounds an internal chime anytime it displays the CLEAN RADAR message. In rare instances, the target characteristics or a
vertically misaligned FLS may trigger the activation of the CLEAN RADAR message in the DIC. Refer to
Distance Sensing Cruise Control Aiming.
Cruise Engaged Indicator
The ACC engaged indicator is displayed in the head-up display (HUD) when the ACC is engaged by pressing the set/decrease switch. When the set/decrease switch is pressed by the driver, the BCM forwards the switch state to the engine control module (ECM)
over the GMLAN serial data circuit. The ECM will use the switch input information from the BCM to determine the driver intended vehicle speed. The ECM communicates to the DSCC over the GMLAN serial data circuit the ACC engaged state and the driver selected speed.
When the DSCC receives the ECM message indicating that ACC is active, the DSCC commands the display of the ACC engaged indicator via a GMLAN serial data message to the BCM. The HUD displays the ACC engaged indicator when it receives a class 2 serial data
message from the BCM requesting the display. The driver may have to adjust the position of the HUD or the intensity of the display to see the information being displayed properly.
Set Speed
The ACC vehicle set speed is displayed at all times in the primary or secondary display of the HUD when ACC is engaged. The set speed is displayed in the primary HUD display for a few seconds after the initial engagement of ACC or a change in the set
speed has just occurred. When, the set speed display time in the primary HUD display elapses, the set speed display is moved to the secondary HUD display. The set speed is also moved to the secondary display when a new ACC related message needs to be displayed.
The DSCC set speed display request is sent to the BCM via the GMLAN serial data circuit. The HUD displays the set speed when it receives a class 2 message from the BCM requesting the set speed displayed in the HUD. The HUD controls when the set speed
is displayed in the primary or secondary HUD display.
Follow Distance
The HUD displays the driver selected following distance when ACC is engaged and the gap up/down switch is active. The current follow distance setting is displayed in the HUD for a few seconds after the gap up/down switch is pressed to increase or decrease
the following distance. The DSCC follow distance display request is sent to the BCM via the GMLAN serial data circuit. The HUD displays the follow distance when it receives a class 2 message from the BCM requesting the follow distance displayed in the
HUD. The HUD will not display the follow distance if an indicator with a higher priority needs to be displayed in the HUD.
CRUISE SPEED LIMITED
The CRUISE SPEED LIMITED indicator displays in the HUD when the DSCC detects that the ACC vehicle is travelling at a speed outside the operational range of the FLS and the vehicle speed is being reduced below the driver set speed. The DSCC limits the vehicle
speed in order to stay within the acceptable speed limitations of the FLS. The DSCC also limits the vehicle speed in order to adjust the vehicle speed for the chosen gap switch setting. The high speed limit of the ACC system is 186.7 km/h (116 mph).
The DSCC requests the display of the CRUISE SPEED LIMITED indicator via a GMLAN serial data message to the BCM. The HUD displays the CRUISE SPEED LIMITED indicator when it receives a class 2 serial data message from the BCM. With a maximum following distance
setting, the maximum operating speed will be limited to 160.9 km/h (100 mph). Selecting a smaller following distance will allow greater operating speeds up to a maximum of 186.7 km/h (116 mph).
Vehicle Ahead Indicator
The vehicle ahead indicator is displayed in the HUD when the FLS identifies an in-path vehicle. The vehicle ahead indicator is a warning to the driver that a vehicle is ahead within a distance of 100 meters (109.3 yards). The indicator also
serves as a feedback to the driver that the FLS is functioning properly. The DSCC commands the display of the vehicle ahead indicator via a GMLAN serial data message to the BCM. The HUD displays the vehicle ahead indicator when it receives a class 2 serial
data message from the BCM. The vehicle ahead indicator only displays with ACC active and may sometimes display for stationary road objects.
TIGHT CURVE
The TIGHT CURVE indicator is displayed in the HUD when the DSCC reduces the vehicle speed for a curve in the road. The tight curve situation exists when the curve of the road extends outside the field of view of the FLS such that the FLS cannot see 100 meters
(109.3 yards) ahead. The degree to which the vehicle speed is reduced depends on the extent the curve on the road reduces the usable range of the FLS field of view. In a tight curve situation, the ACC vehicle speed may be reduced even when there is a
target vehicle in the path of the ACC vehicle. The DSCC uses an internal algorithm to control the vehicle speed to the radius of the curvature of the road. The DSCC requests the display of the TIGHT CURVE indicator via a GMLAN serial data message to the BCM.
The HUD displays the TIGHT CURVE indicator when it receives a class 2 serial data message from the BCM. Since the TIGHT CURVE indicator is only displayed when the vehicle speed is reduced for a curve, the driver may notice a delay between entering the
curve and the display of the TIGHT CURVE indicator.
Driver Alert
The driver alert indicator warns the driver of a certain road or vehicle conditions that require his attention. When the driver alert indicator flashes in the HUD it is accompanied by an audible warning from the audio amplifier. The driver alert indicator
flashes in the HUD and the audible warning sounds when one of the following occurs:
• | The DSCC is requesting maximum automatic braking. |
• | The DSCC automatic braking request is not sufficient to safely stop the vehicle in certain road conditions. |
• | Cruise disengagement not initiated by driver or any driver action. |
• | The vehicle speed is below 32 km/h (20 mph). |
• | Abnormal cruise disengagement |
The DSCC requests the driver alert indicator and the audible warning via a GMLAN serial data message to the BCM. The BCM then sends a class 2 message to the HUD and to the audio amplifier requesting the driver alert indicator and the audible warning
to be activated.
Cruise Engaged
The adaptive cruise control (ACC) system will engage and adjust vehicle speeds based on the activation of the following cruise switches:
ACC will not engage if any inhibit criteria is active. Also, the driver must step on the brakes at each ignition cycle before attempting to engage ACC. The engine control module (ECM) looks to the body control module (BCM) for the brake initial travel
achieved signal indicating that the driver has stepped on the brakes before attempting to engage ACC.
The vehicle speed must be above 40 km/h (25 mph) and below 188.3 km/h (117 mph) for the ACC system to be engaged. In the engaged state, the ACC system allows the driver to override the controlled vehicle speed temporarily while
still remaining in the engaged state.
Cruise Inhibited
DSCC Inhibits
The distance sensing cruise control module (DSCC) inhibits the adaptive cruise control (ACC) system when any of the following conditions exists:
• | RADAR NOT READY message active in the driver information center (DIC) |
• | Initial brake pedal travel signal from brake pedal position sensor (BPPS) not present |
• | ACC system malfunction and/or failure and SERVICE RADAR CRUISE indicator active in the DIC |
• | CLEAN RADAR indicator active in the DIC |
• | Invalid yaw rate data from EBCM |
• | Invalid acceleration data from EBCM |
• | ABS active during automatic braking |
• | Cruise Switch failed message from the body control module (BCM) to the DSCC |
• | Automatic braking failure - GMLAN signal from ABS to DSCC indicating automatic braking failure |
• | Brakes overheated signal from Antilock Brake System (ABS) |
• | Head-up display (HUD) failure |
• | ACC system audible warning not present due to audio amplifier failure |
• | ACC is not present. ACC can be disabled through the BCM ACC disable feature. |
• | Driver applied brake pressure |
ECM Inhibits
The engine control module (ECM) inhibits the ACC system operation when any of the following conditions exists:
• | ACC inhibited signal from DSCC is present. |
• | Vehicle speed drops below 32.2 km/h (20 mph). |
• | Vehicle speed is above 193.1 km/h (120 mph). |
• | Automatic braking failure - GMLAN signal from ABS to ECM indicating automatic braking failure |
• | ACC present signal from BCM is false. |
• | Driver applied brake pressure. |
• | Cruise Control switch failure |
• | Park brake switch signal from BCM is active. |
• | Electronic throttle control (ETC) failure |
• | Traction control is active. |
• | Engine overspeed protection is active. |
• | Vehicle overspeed protection is active. |
• | Engine speed is too high or too low. |
• | Automatic transmission is in First gear, Park, Neutral or Reverse. |
• | Initial brake pedal travel signal from BPPS not present |
Cruise Disengaged
The Adaptive Cruise Control (ACC) System disengages when any of the following occurs:
• | The driver depresses the brake pedal. |
• | The driver turning the ACC On/Off switch OFF |
Pressing the brake pedal while ACC is engaged will disengage the ACC System.
Other Adaptive Cruise Control (ACC) Features
Automatic Alignment
The Adaptive Cruise Control (ACC) System is equipped with an internal forward looking sensor (FLS) automatic horizontal alignment feature. This feature can not be used for vertical alignment. For proper operation of the ACC System, the FLS must be well
aligned to the vehicle. The FLS alignment to the vehicle is continuously corrected and adjusted as necessary during the ACC vehicle operation. To achieve a complete automatic FLS alignment, the ACC vehicle has to be driven on a road above 56 km/h (35 mph)
with acceptable stationary objects like mail boxes, road signs, trees, ramps and poles etc. The distance that the vehicle needs to be driven to achieve a complete automatic alignment, depends on the number of stationary objects encountered on the road that the
vehicle is travelling. The more stationary objects encountered, the quicker the FLS will achieve automatic alignment. At least 40 acceptable stationary objects must be encountered for proper alignment. When the distance sensing cruise control module (DSCC) is
replaced with a new module, it is necessary for the vehicle to be driven until the internal automatic alignment is complete. The scan tool is equipped to display the automatic alignment status and the degree of alignment error or skew of the FLS. A DTC C1002
sets in the DSCC when the degree of error or skew is 2.5 degrees or over.
It is important when performing a wheel alignment service on a vehicle equipped with the ACC System, to change the Auto Alignment Learn Status parameter in the DSCC scan tool data list to Not Aligned. The Auto Alignment Learn Status parameter of the DSCC
needs to read Not Aligned to allow the FLS to automatically align to the vehicles new wheel alignment setting. Driving the vehicle in an area with stationary objects will cause the FLS to automatically align horizontally to the vehicles new wheel alignment setting.
Mechanical Alignment
Mechanical alignment must be used for vertical alignment. Proper vertical alignment is achieved with a bubble level tool rested against the front face of the FLS, with the bubble centered. When the alignment of the FLS is not achieved, an out of alignment
diagnostic, DTC C1002 is set by the DSCC. The typical horizontal alignment value of the FLS is 0-2 degrees, but it is highly recommended to be as close to 0 degrees as possible. The DSCC diagnostic, DTC C1002 sets when at least
2.5 degrees of skew or error of the FLS is present. Refer to
Distance Sensing Cruise Control Aiming for more information on how to aim and align the FLS. An out of alignment condition may be as a result of tampering
or damage to the FLS, the FLS mounting structures or the FLS adjuster settings. An out of alignment condition may also be as a result of damage to the front end of the vehicle or merely as a result of wear and tear. Refer to
Distance Sensing Cruise Control Module Replacement and
Cruise Control Vehicle Distance Module Sensor Replacement on how to properly locate and mount the ACC module and the FLS.
Cruise Control Description and Operation Conventional Cruise
Cruise control is a speed control system that maintains a desired vehicle speed under normal driving conditions at speeds above 40 km/h (25 mph). Steep grades may cause variations in the selected vehicle speeds.
The following are the main components of the cruise control system:
• | The brake pedal position (BPP) sensor |
• | The body control module (BCM) |
• | The cruise control on/off switch |
• | The cruise control cancel switch |
• | The engine control module (ECM) |
• | The throttle actuator control (TAC) motor |
• | The transmission control module (TCM) |
• | The vehicle speed sensor (VSS) |
The body control module (BCM) monitors the signal circuit of the cruise control switches. The BCM relays the cruise control switch status to the engine control module (ECM) via a serial data message. The ECM uses the status of the cruise control switch
to determine when to capture and maintain the vehicle speed. The ECM monitors the vehicle speed signal circuit in order to determine the desired vehicle speed. The ECM uses the throttle actuator control (TAC) motor in order to maintain the vehicle speed. For
further review of the TAC system, refer to
Throttle Actuator Control (TAC) System Description for the 4.4L engine or to
Throttle Actuator Control (TAC) System Description for
the 4.6L engine.
Ignition voltage is supplied to the cruise control switch from the 2-ampere STRG COL SW fuse located in the integrated BCM fuse block. The cruise control function switches are arranged in a resistive ladder design, with each cruise control function switch
having a different resistance value. The BCM detects a specific voltage value that is associated with the cruise control function switch being activated. When the normally open cruise control on/off switch is turned ON, the switch closes and the BCM sends a
serial data message to the ECM indicating that the on/off switch is active. Similarly, when the normally open + RES switch or the normally open - SET switch are pressed, the switch closes and the BCM detects the predetermined voltage signal
on the cruise control resume/accel and set/coast switch signal circuit. The BCM sends a serial data message to the ECM indicating that the + RES switch or the - SET switch is active. The + RES switch or the - SET switch
will remain inactive when the BCM has not received the predetermined voltage signal from the on/off switch.
Cruise Control Engaged
The cruise control system will engage and adjust vehicle speeds, based on the activation of the following cruise control switches:
To engage the cruise control system, ensure that the vehicle speed is above 40.2 km/h (25 mph), turn the cruise on/off switch ON and momentarily press the - SET switch. The ECM will engage the cruise control system and record
the vehicle speed. The ECM sends a serial data message to the BCM. The BCM then sends a serial data message to the head-up display (HUD) in order to illuminate the Cruise Speed SET XXX message.
Pressing the accelerator pedal while the cruise control system is engaged, allows the driver to override the cruise control system in order to accelerate the vehicle beyond the current set vehicle speed. When the accelerator pedal is released, the vehicle
will decelerate and resume the current set vehicle speed. The driver can also override the current set vehicle speed via the - SET switch and the + RES switch. When the cruise control system is engaged, pressing and holding the - SET
switch will allow the vehicle to decelerate from the current set vehicle speed without deactivating the cruise control system. When the - SET switch is released, the ECM will record the vehicle speed and maintain the vehicle speed as the new set
vehicle speed. When the cruise control system is engaged, momentarily pressing the - SET switch will allow the vehicle to decelerate at 1.6 km/h (1 mph) increments for each time that the - SET is momentarily pressed, with
a minimum vehicle speed of 37 km/h (23 mph).
Pressing and holding the + RES switch, when the cruise control system is engaged, will allow the vehicle to accelerate to a greater vehicle speed than the current set vehicle speed. When the + RES switch is released, the ECM will record the
vehicle speed and maintain the vehicle speed as the new set vehicle speed. When the cruise control system is engaged, momentarily pressing the + RES switch will allow the vehicle to accelerate at 1.6 km/h (1.0 mph) increments for each time
that the + RES switch is momentarily pressed, with the maximum acceleration total of 16 km/h (10 mph) over the current set vehicle speed. Momentarily activating the + RES switch will recall the previous vehicle speed, after the cruise
control system is disengaged by pressing the brake pedal or CANCEL switch.
Cruise Control Disengaged
The engine control module (ECM) disengages the cruise control operation based on the signals from the following switches:
• | The brake pedal position (BPP) sensor |
• | The cruise control On/Off switch |
• | The cruise control cancel switch |
The Cruise Control System will disengage when the brake pedal is applied. The body control module (BCM) monitors the BPP sensor via the BPP sensor signal circuit as the voltage signal increases while the pedal reaches the fully applied position. The ECM
monitors the BPP signal through a discrete input and a serial data message signal from the BCM indicating the brake status. When both signals indicate the brake pedal is applied, the ECM will disengage the cruise control system. For further information on the
BPP sensor, refer to
Exterior Lighting Systems Description and Operation or to
Brake Pedal Position Sensor Calibration.
The Cruise Control System will also disengage when the cruise control on/off switch is switched OFF, or the cruise control cancel switch is activated. The body control module (BCM) determines when the cruise control cancel switch is activated. When the
normally open cancel switch is closed, the BCM detects a high signal voltage on the cruise control cancel switch signal circuit. The BCM sends a serial data message to the ECM in order to disengage the cruise control system. The BCM then sends a serial data
message to the HUD in order to turn OFF the Cruise Speed SET XXX message. The vehicle speed stored in the memory of the engine control module will be erased when the cruise control On/Off switch is turned OFF, or the ignition switch is turned OFF. The cruise
control system will also disengage when the ECM detects that a driver override function has been active for approximately 60 seconds.
Every time the cruise control system is disengaged, the ECM will keep track of the reason for system disengagement. The last 8 disengagement reasons will be recorded within the ECM memory. The scan tool will display the last 8 Cruise Disengage History
parameters, in which one out of approximately 50 possible reasons will be displayed in each of these 8 parameters. For the disengagement reason to be displayed within the scan tool parameter either the cruise control system is active and disengagement is requested,
or engagement of the system is requested but a fault is present. For a list of each disengagement reason along with each definition, refer to
Control Module References in the ECM.
Cruise Control Inhibited
The engine control module (ECM) inhibits the cruise control operation when any of the following conditions exist:
• | A cruise control system DTC has been set. |
• | The vehicle speed is less than 40.2 km/h (25 mph). |
• | The vehicle speed is too high. |
• | The vehicle is in PARK, REVERSE, NEUTRAL, or 1st gear. |
• | The engine RPM is too low. |
• | The engine RPM is too high. |
• | The system voltage is not between 9-16 volts. |
• | The antilock brake system/traction control system is active for more than 2 seconds. |