Vertical Dynamics Management

Vertical Dynamics Management

Vertical dynamics management
Vertical dynamics management is standard equipment:
The following functions can be installed as optional extras in the vertical dynamics management (VDM) control module:
- vertical dynamics management
- active roll stabilization (marketing designation: Dynamic Drive)

This document describes the vertical dynamics management.

The VDM control module is activated via the terminal 15N cable by the CAS control module. At the same time, the VDM control module is supplied with terminal 30.







EDC means: Electronic Damper Control

Vertical dynamics management offers the following advantages:
- greater on-road comfort
- greater vehicle agility
- improved self-steering characteristics and load-change characteristics

Vertical dynamics management (VDM) is an enhancement from the X5. VDM is composed of a central control module and 4 intelligent damper satellites with fixed connection to the shock absorbers.

These 5 control modules are networked via FlexRay.

New is that there is one EDC valve for the rebound stage and one for the discharge stage. This means that the control operation no longer has to be clocked so quickly.

Brief description of components
The following components are described for vertical dynamics management:

VDM: vertical dynamics management
The VDM control module is located in the passenger footwell at the A-pillar.







The VDM enhances on-road comfort. Greater on-road comfort is achieved when the vehicle body moves vertically as little as possible: neither due to excitation of the vehicle from the road (irregularities, joins) nor on cornering.

The VDM control module specifies how the damper satellites are to activate the shock absorbers (individual damping force for each wheel). To this end, the VDM control module is connected to the damper satellites via the very fast FlexRay data bus.

With a data transfer rate of 10 MBit/s, FlexRay is significantly faster than the data buses deployed nowadays in motor vehicles (in the area of body and drive or chassis). FlexRay supports not only the greater bandwidth but also data interchange with real-time capability. FlexRay can be configured as fault-tolerant.

Damper satellites
There are 4 damper satellites
- Damper satellite, front left (EDCSVL)
- Damper satellite, front right (EDCSVR)
- Damper satellite, rear left (EDCSHL)
- Damper satellite, rear right (EDCSHR)

The damper satellites electronically control the damping forces. The damper satellites and the EDC valves are inseparably connected to the shock absorbers. The damper satellites each have one EDC valve for the rebound stage and one for the discharge stage. Each damper satellite contains its own vertical-acceleration sensor.







The damper satellites have the following tasks (among others):
- activating the EDC valves on the shock absorbers (characteristic map for damping)
- measuring the internal current (actual value) of the EDC valves and regulating to the nominal value.
- measuring the vertical acceleration of a wheel

Height sensors
There are the following 4 height-level sensors:
- Height-level sensor, front left (single)
- Height-level sensor, front right (single)
- Height-level sensor, rear left (single, double only with single-axle level control)
- Height-level sensor, rear right (double, double only with single-axle level control)

The 4 height-level sensors are series standard. Depending on the options fitted, there are 1 channel and 2-channel sensors on the rear axle. 2-channel sensors deliver the signal to the:
- Integrated Chassis Management (ICM)
- Control module for the electronic ride-height control (EHC = ride-height control)

The height-level sensors are electrically connected to the Integrated Chassis Management (ICM). The ICM implements the signal on the FlexRay.

The height-level sensors deliver dynamic information on the height of the vehicle body. The vertical dynamics management uses this to calculate the body movements as well as wheel accelerations.

In addition, the sensors deliver the information to the automatic headlamp range control.

The height-level sensor proportionally converts distances into an analogue voltage signal using an angle of rotation. The sensor can be rotated by 360°. The measuring range is 70° (depending on the installation location). The signals are output as analogue electrical voltages.







Driving dynamics switch
Driving Dynamics Control is operated using the driving dynamics switch beside the gear selector switch.

The new Driving Dynamics Control has the following new features:
1. All of the drive and driving dynamics systems installed in the vehicle are activated. The central control module for this is the Integrated Chassis Management (ICM).
2. A choice of 4 programs is available:
- COMFORT
- Normal
- Sport
- SPORT+

Driving Dynamics Control influences vertical dynamics management as well as other systems.







The following other control modules deliver signals for the vertical dynamics management:

ICM: Integrated Chassis Management
Integrated Chassis Management (ICM) assumes the following functions in vertical dynamics management:
- Central signal plausibility check for longitudinal and lateral acceleration, and yaw rate
- Central signal provision for driving speed, road longitudinal and lateral inclination
- Central co-ordination of the display of Check Control messages for the chassis control system

DSC: Dynamic Stability Control
The DSC control module delivers the brake pressure on the FlexRay to the VDM.

SZL: Steering column switch cluster
The SZL delivers the steering-angle-sensor signal on the FlexRay to the VDM (advance detection of cornering).

DME or DDE: Digital Motor Electronics or Digital Diesel Electronics
The engine management system delivers the signal Engine running . The signal is transferred across the FlexRay.

System function
The following system functions are described for vertical dynamics management:
- Functional networking
- Damping of the wheel accelerations as well as body movements
- Fail safe

Functional networking
A complex composite system with distributed functions in other control modules is necessary for the implementation of vertical dynamics management. The following graphic shows the composite system.







Damping of the wheel movements as well as body movements
To dampen the wheel movements and body movements, the motion of the vehicle is monitored. Here, the following axes are included:
- Vehicle vertical axis
- Vehicle lateral axis
- Vehicle longitudinal axis

The following signals, e.g., are used for monitoring:
- Height and wheel acceleration
- Steering angle and driving speed
- Lateral and longitudinal acceleration

The signals are used to calculate the current driving situation.

For the vehicle vertical axis, the control of the damping is divided into 'comfort' and 'safety'. The vertical dynamics management damps the body movements with regard to comfort. The vertical dynamics management damps the wheel accelerations with regard to safety. At the same time, it must be ensured that the wheels do not lose contact with the road surface. Depending on the situation, optimized vertical force must be transferred.

The vertical dynamics management also takes account of steering angles (e.g. transition from straight-ahead driving into a curve). If a rapid enlargement of the steering angle is detected, the VDM control module concludes that cornering is about to begin. This means that the shock absorbers can be activated accordingly in advance. In doing so, the vertical dynamics management supports active roll stabilization (ARS). This means that the VDM contributes to reducing the rolling motion of the vehicle.

The vertical dynamics management also detects braking and acceleration. To achieve this, the DSC provides the brake pressure and longitudinal acceleration signals. Excessive brake pressure normally leads to a pitching motion of the vehicle. The VDM counteracts this pitching motion with a harder setting of the front shock absorbers. This also counteracts the pitching motion of the vehicle on accelerating.

Depending on the selected damping characteristics (driving dynamics switch), the level of the damping force is adapted by the VDM control module. Independently of this, there is maximum driving safety in critical driving situations despite the selected comfort program.

Fail safe
Depending on the type of fault that has occurred, the fail safe takes effect in 3 stages:
- Stage 1: substitute values
If, for example, the steering-angle-sensor signal is unavailable, other variables are used as substitute values for the detection of cornering. The driver does not receive a Check Control message: no fault memory entry.
- Stage 2: constant power supply
The VDM control module specifies a constant damping force that is the same for all 4 wheels (medium-hard damping). The damper satellites set a constant power supply for the EDC valves. A defective height-level sensor, for example, can be the cause. A Check Control message is output to the driver. A fault is entered in the fault memory.
- Stage 3: no power supply
If a fault has occurred in activation of an EDC valve: The VDM control module indicates to the damper satellites that the EDC valves may no longer be supplied with current. This causes the valve to move to a position that corresponds more to medium to harder damping. A Check Control message is output to the driver. A fault is entered in the fault memory.







Notes for Service department

General information

IMPORTANT: On replacement of the shock absorbers, specify the installation location.

The shock absorbers, the damper satellites and the 2 EDC valves form a single unit. When ordering a new component, the type of vehicle and installation location (e.g. front left) must be specified. There are dependencies e.g. with regard to: engine version, suspension.

Diagnosis instructions

NOTE: a number of fault memories in the vertical dynamics management.

The VDM control module only its own faults in its own fault memory. Faults in the damper satellites are stored in their own fault memory. This is why not only the fault memory of the VDM control module but also that of the damper satellites must be read out in the event of a fault.

IMPORTANT: Run a calibration of the height-level sensors.

After replacement of the ICM control module as well as of a height-level sensor, the calibration values of the height-level sensors must be relearned. The service function "ride-height calibration" on the BMW diagnosis system must be used.

Notes on encoding / programming
After replacement, the VDM control module must be re-encoded.

Switch-on conditions
The vertical dynamics management is activated under the following conditions:
- Ignition on (terminal 15 and wake-up line)
- Speed greater than 0.1 kph

No liability can be accepted for printing or other faults. Subject to changes of a technical nature