Abstract: A method of controlling a brake system of an all-wheel driven motor vehicle, which includes an electro-regenerative brake and a number of friction brakes such that a total brake torque comprises brake torque components of the friction brakes and of the electro-regenerative brake; the brake torque of the electro-regenerative brake is subdivided between the front axle and rear axle in predetermined ratios. The brake torque generated by the electro-regenerative brake is limited to such an extent that the brake slip of one axle of the motor vehicle does not exceed a selectable maximum value.

Abstract: In a braking control device which performs braking control to stabilize vehicle behavior, a driving state switching unit changes a driving state of a vehicle. A slip condition detecting unit detects a slip condition of the vehicle. A braking control permission judging unit determines whether actuation of braking control is permitted. The braking control permission judging unit is arranged so that, if the driving state is changed to a direct-connection four-wheel-drive condition by the driving state switching unit, the braking control permission judging unit permits actuation of braking control when the slip condition detected by the slip condition detecting unit exceeds a predetermined slip condition.

Abstract: A method for measuring and aligning front and rear wheels of a four wheel vehicle, including measuring alignment properties of the front wheels, and correcting alignment properties of the rear wheels if all of the measurements of the alignment properties of the front wheels are substantially equal to the manufacturer-specified alignment properties for the front wheels. If all of the measurements of the alignment properties of the front wheels are not substantially equal to the manufacturer-specified alignment properties for the front wheels, then the alignment properties of the front wheels are corrected prior to correcting alignment properties of the rear wheels. The measurements of the alignment properties can be made using a computer-aided, three-dimensional machine vision alignment apparatus.

Abstract: In speed ratio control apparatus and method for a hybrid transmission, an integrated controller calculates a speed ratio manipulated variable in accordance with a deviation between a speed ratio representative command value and a speed ratio representative actually measured value. Then the controller calculates a speed ratio purpose component command value for each drivingly input element torque which is drivingly inputted to a differential mechanism of the hybrid transmission according to the calculated speed ratio manipulated variable, an acceleration ratio of each drivingly input element in a shift motion, and an inertia of each drivingly input element in the shift motion. Then, the controller outputs each calculated speed ratio purpose component command value to a torque actuator of the corresponding drivingly input element.

Abstract: Provided is a method for controlling regenerative braking in an electric vehicle, including operating regenerative braking, checking if a data communication using a control area network (CAN) standard is properly made between a regenerative braking torque controller and a hydraulic pressure braking torque controller, and enabling the regenerative braking torque controller and the hydraulic pressure braking torque controller to maintain regenerative braking torque and hydraulic pressure torque at their respective previous levels or to increase regenerative braking torque and/or hydraulic pressure torque until braking ends, when the data communication fails between the regenerative braking torque controller and the hydraulic pressure braking torque controller.

Abstract: A driving force switching control apparatus in a vehicle which runs by two-wheel drive or four-wheel drive in accordance with the running state. The apparatus includes a device for determining whether the vehicle runs at a constant speed; and a device for determining a drive system of the vehicle running at a constant speed to be the two-wheel drive or the four-wheel drive according to road surface conditions computed using rolling resistance. A threshold value for switching between the two-wheel drive and the four-wheel drive is changed in a manner such that a determination area where the four-wheel drive is selected increases according to increase in the rolling resistance. Sufficient driving force transmitted to the wheels can be secured even when the road surface condition varies, and accordingly, sufficient driving force is secured also when the running condition is changed from constant speed running to acceleration or deceleration running.

Abstract: A vehicle dynamics behavior reproduction system capable of describing accurately behavior of a motor vehicle in a lateral direction even for nonlinear driving situation includes a vertical wheel force arithmetic module (105), a lateral wheel force arithmetic module (110), a cornering stiffness adaptation module (115), a state space model/observer unit (120), a selector (130), a delay module (135), and a tire side slip angle arithmetic module (125). Vertical wheel forces (FZij) and tire side slip angles (?ij) are determined by using sensor information and estimated values while lateral wheel forces (FYij) are determined in accordance with a relatively simple nonlinear approximation equation. The lateral wheel force (FYij) and the tire side slip angle (?ij) provide bases for adaptation of cornering stiffnesses at individual wheels. Vehicle motion is accurately described to a marginal stability by using adapted cornering stiffnesses (Cij) and other information.

Abstract: An antiskid control system for a four-wheel-drive vehicle is arranged to calculate a difference between an average of wheel accelerations of front wheels and an average of wheel acceleration of rear wheels. When the difference is greater than or equal to the vibration determination threshold, the antiskid control system determines that a driveline vibration is generated and executes a control for converging the driveline vibration.

Abstract: A plurality of vehicle stabilizing devices which operate according to different strategies and which actuate, independently of the driver, brake actuators which are assigned to the vehicle wheels, in order to stabilize the vehicle are arranged in the vehicle. The vehicle is equipped with at least one switchable differential lock in the drive train. The differential lock assumes a non-switched operating state, a first operating state in which the differential lock is preselected, and a second operating state in which the differential lock is switched. When the differential lock assumes the first operating state, some of the vehicle stabilizing devices, other than that vehicle stabilizing device which, by actuating the brake actuators independently of the driver, prevents the vehicle wheels from locking during a braking operation, are influenced in terms of their operating mode.

Abstract: An antiskid control system for a four-wheel-drive vehicle is arranged to calculate a difference between an average of wheel accelerations of front wheels and an average of wheel acceleration of rear wheels. When the difference is greater than or equal to the vibration determination threshold, the antiskid control system determines that a driveline vibration is generated and executes a control for converging the driveline vibration.

Abstract: A method and an arrangement for monitoring a computing element in a motor vehicle are suggested. The computing element generates, with the aid of the program modules, at least one output quantity for controlling at least one function in the motor vehicle in dependence upon at least one input quantity. At least one program module or at least a part thereof is selected for monitoring the correct function of the computing element (12). This at least one selected module or the at least one selected part thereof or a copy is run through in the computing element (12) on the basis of test data and the result of the test data computation is compared to a pregiven result for fault detection.

Abstract: A rotational speed V1 of a left front wheel T1, a rotational speed V2 of a right front wheel T2, a rotational speed V3 of a left rear wheel T3, and a rotational speed V4 of a right rear wheel T4 are detected by rotational speed sensors S1-S4, respectively. A front-wheel yaw rate ?F arising due to a rotational speed difference between the front wheels T1, T2 and a rear-wheel yaw rate ?R arising due to a rotational speed difference between the rear wheels T3, T4 are monitored. When a significant disparity between the both rotational speed differences is observed, it is determined that tire inflation pressure of any of the wheels T1-T4 has decreased. Upon detection, correction is made to an apparent yaw rate that would be observed in the properly inflated wheel as a result of steering for correction by a driver, thereby improving detection accuracy of underinflation of the tires.

Abstract: A method for controlling the safety mode of a four-wheel drive to control the magnetic clutch at a safety mode duty to reduce overload for a predetermined period of time when the slip of the magnetic clutch is greater than an allowable slip, despite controlling the magnetic clutch at its maximum duty.

Abstract: A torque distribution control device for a four-wheel drive vehicle has a torque distribution device for distributing the drive power transmitted from an engine to either of the front wheels or the rear wheels as prime drive wheels, to other wheels as sub-drive wheels. The control device judges whether or not an abnormality is involved in wheel speed signals which are input from wheel speed sensors associated respectively with the front and rear wheels. A normal-state method of calculating a command torque which is applied to the torque distribution device to vary the drive power transmitted to the sub-drive wheels, is then altered to an abnormal-state method of calculating the command torque based on data which does not include one wheel speed signal involving the abnormality when the same occurs with one of the wheel speed signals, whereby the vehicle is enabled to continue the four-wheel drive even when the abnormality occurs.

Abstract: A vehicle stability enhancement system for a vehicle having a vehicle subsystem includes a sensor for sensing a vehicle parameter, a vehicle control system for adjusting the vehicle subsystem, a memory having a register that includes a bank angle compensation control command, and a controller responsive to the sensor and the memory for controlling the vehicle control system.

Abstract: A system and method for estimating the wheel speed of a vehicle propelled by DC motors mechanically coupled to at least one wheel on the vehicle so as to rotate said one or more wheel. At least one current detector is configured to measure armature and field current in each of the DC motors and produce a signal proportional to said currents and a voltage detector is configured to measure voltage applied to each of the DC motors and produce a signal proportional to said voltage. A processor is configured to determine a rotational speed as a function of the measured currents and voltages and configured to apply a correction factor to the determined rotational speed to obtain a corrected rotational speed.

Abstract: A system and method of controlling a multi-wheel drive vehicle is provided. The invention is preferably applicable to the steering of such a vehicle and determines the individual velocities for each wheel drive. In this regard, the invention includes two general steps. The first step includes determining the distance of each wheel drive and a vehicle velocity reference point from a turning reference point. The second step includes ratioing each wheel drive's distance from the turning reference point with the vehicle velocity reference point's distance from the turning reference point. The ratios are then applied to a vehicle velocity associated with the vehicle velocity reference point to determine the velocity of each respective wheel drive. Once determined, the velocities are output to each wheel drive.

Abstract: In an electric brake system with at least an electric wheel brake mechanism having a pair of brake friction pads to produce a braking force based on a brake manipulated variable, and a brake friction pad thrust sensor detecting a pressure of either one of the brake friction pad pair against a disk rotor, an electric brake control unit causing a temporary movement of the brake friction pad pair into contact with the disk rotor when a predetermined time period has expired from a time when a brake pedal has been recovered to an inoperative state. In the system, a position of the brake friction pad pair, at which the pressure becomes greater than a predetermined threshold value during the temporary movement of the brake friction pad pair into contact with the disk rotor, is detected or determined as a braking initiation position.

Abstract: A vehicle-behavior control apparatus for a vehicle with a center differential comprising of a control unit adopted to be connected to a braking system and vehicle status sensors. This control unit directs the braking system to distribute suitable braking force to each wheels in response to a spin or driftout moment determined by any outputs of the vehicle sensors and a state of the center differential determined by a differential state sensor.

Abstract: A method for redistributing driving torque between front and rear driving wheels of a vehicle traveling at essentially the same speed. The method includes determining a vehicle condition corresponding to load, based upon at least one vehicle parameter, comparing the determined vehicle condition to a predetermined value, wherein if the determining vehicle condition exceeds the predetermined value, a high load condition exists, and redistributing the driving torque between the front and rear wheels, when the determining step determines that a high load condition exists. By controlling torque redistribution in accordance with one or more high load conditions on the driveline components, subsequent damage of the driveline system can be reduced or prevented.

Abstract: A method for controlling an anti-lock braking system, intended for motor vehicles having all-wheel drive, electric signals representative of the rotational behavior of the vehicle wheels are produced and logically combined. When a locking tendency occurs, the braking pressure is controlled, and the instantaneous wheel slip, the wheel acceleration, and the wheel deceleration are evaluated as control criteria, and wherein the individual wheel speed is compared to a vehicle reference speed which is used as a reference quantity for controlling the braking pressure.

Abstract: A method for detecting misalignment in a motor vehicle sensor system, in which signals are emitted, signals reflected by a stationary object are received, and a relative angle and a relative distance or a longitudinal displacement and a transverse displacement between the detected object and a reference axis of the motor vehicle as well as a relative velocity between the detected object and the motor vehicle are determined on the basis of the signals emitted and received. A correction value is determined for the relative angle on the basis of the relative angle, the relative distance, and a velocity of the vehicle in question or on the basis of the longitudinal displacement, the transverse displacement, and the vehicle's own velocity.

Abstract: An exemplary embodiment of the invention is a method for detecting a potentially locked axle on a vehicle propelled by an AC motor. The method includes conducting a speed test by estimating axle speed and comparing estimated axle speed to measured vehicle speed. The existence of a potential locked axle condition is determined based on the comparing of estimated axle speed to measured vehicle speed. Additional tests are disclosed for determining a potential locked axle condition and a sensor fault condition.

Abstract: An antiskid control system for a four-wheel-drive vehicle is arranged to calculate a difference between an average of wheel accelerations of front wheels and an average of wheel acceleration of rear wheels. When the difference is greater than or equal to the vibration determination threshold, the antiskid control system determines that a driveline vibration is generated and executes a control for converging the driveline vibration.

Abstract: A system and method for ABS stability control is provided, the method comprising the steps of determining whether a first wheel is in an ABS mode; determining whether the first wheel is in an apply mode; determining whether a second parallel wheel is in the release mode; calculating an adjusted wheel slip if the first wheel is in the ABS mode, the first wheel is in the apply mode, and the second parallel wheel is in the release mode; and determining a control mode for the first wheel using the adjusted wheel slip.

Abstract: A four-wheel drive anti-lock brake control in which the existence of torque transfer between the front and rear wheels of the vehicle is detected based on differences in the duration of ABS control used at each of the independently controlled wheels. Such differences are used to determine a ratio of rear-to-front (or front-to-rear) ABS control. If the ratio indicates the presence of torque transfer, the wheel causing the transfer is identified and its brake pressure released as required to alleviate the detected torque transfer, so long as the release will not cause a change in vehicle deceleration.

Abstract: The present invention relates to a method and a device for adjusting the output torque or the output speed of an internal combustion engine in order to protect the differentials. The crux and advantage of the present invention lies in calculating and monitoring the rpm differences or the rpm differences in the transverse direction of any vehicle (front-wheel-, rear-wheel-, and four-wheel-drive) as well as the difference in the Cardan speeds that exists in the longitudinal direction in four-wheel drive vehicles. When a specifiable limiting value is exceeded, an automatic reduction in the drive torque or an automatic limiting of the engine speed to a manageable level takes place. This protective function for the differentials cannot be switched off and is available even in the passively activated drive-torque AMR control system. It can only be realized by software using already existing sensors and actuator devices. The application outlay is minimal.

Abstract: In a vehicular braking control apparatus and method, the hydraulic pressure on a wheel cylinder is gradually reduced with a relatively gentle gradient of reduction (k3) at the time when a braking operation member, operated by an operating person of the vehicle, is detected to have been operated to a predetermined position. At the time when a state of the braking operation is detected to have reached a predetermined threshold, the hydraulic pressure on the wheel cylinder is reduced with a relatively great gradient of reduction (k2). Therefore, it is possible to reduce vibrations of a brake pedal or the change in deceleration while adopting a relatively simple construction.

Abstract: A user interface provides the operator of an industrial process control system the ability to set user-initiated alarms on selected parameters representative of a process being controlled, independent of predetermined alarm limits. The interface allows the operator to identify parameters to monitor, when to monitor the parameters, when to trigger alarms, and allows the operator to determine how to be notified that a user-initiated alarm has been triggered. A template having blanks to fill in information related to the alarm limits is provided and has drop down menus providing alternatives. Selecting an icon on a schematic representative of a process causes the template to pop up in a window type of environment with relevant data already filled in. The completion of the template results in a message being sent to a process module which provides real time values of the parameters.

Abstract: Provided is a braking force control apparatus for vehicles capable of performing appropriate vehicle braking even in a road-contactless state of a wheel. The braking force control apparatus is adapted to a four-wheel drive vehicle having a center differential for distributing and transmitting driving force to the front wheels and rear wheels and a braking system capable of exerting braking force on each of the front and rear wheels, based on voluntary switching between braking according to driver's brake-pedal actuation and forced braking independent of the brake-pedal actuation. It is determined whether the vehicle is in an engine brake state and it is then determined whether at least one of the wheels is in the road-contactless state.

Abstract: A moving behavior control device for a vehicle calculates first target braking forces to be applied to the respective wheels for stabilizing the vehicle against a turn instability, second target braking forces to be applied to the respective wheels for stabilizing the vehicle against a roll instability, and target overall braking forces to be applied to the respective wheels by integrating the first and second target braking forces, and applies braking forces to the respective wheels according to the target overall braking forces, wherein the applied braking forces are decreased according to a first rate schedule by which the applied braking forces are decreased at a first rate according to an excess of the applied braking forces relative to the target overall braking forces when the vehicle is running at no probability of rolling beyond a predetermined threshold roll, and according to a second rate schedule by which the braking forces are lowered at a second rate smaller than the first rate according to the

Abstract: An electrical braking system for a motor vehicle has a controller which detects the actuation of a service-brake operator element, determines therefrom at least one driver's braking input for the brake control, and supplies this set point value to control units for controlling the wheel brakes. This controller also detects the actuation of a parking-brake operator element, determines therefrom a parking-brake input of the driver, and links this parking-brake input with the braking input for the service brake to form the total braking input. An electrical braking system for a motor vehicle includes at least one control unit which is allocated to at least one wheel brake. The controller controls an actuator for actuating the wheel brake on the basis of a setpoint value. The actuator has an electric motor and a locking device, in particular, a disengaging device. To actuate the wheel brake via the electric motor, the locking device is released.

Abstract: An antilock brake system which decreases a braking pressure to prevent drive wheels from locking is applied to a hybrid vehicle wherein an engine and a motor are connected to the drive wheels via a continuously variable transmission. The rotation torque of a motor is applied to the drive wheels when the braking pressure is reduced due to antilock control so that the engine braking force which acts during braking does not interfere with antilock control.

Abstract: A braking control system for agricultural tractors comprises:of the type having a pair of front wheels and a pair of rear wheels with at least one pair being driven through a differential and wherein individual wheel brakes are individually controlled through a hydraulic braking control unit which in turn is controlled by an electronic control unit which causes the braking control unit to apply braking pressure to slow the wheels on the inside of the steering bend in response to signals received by a steering angle sensor.

Abstract: An anti-skid control system for an automotive vehicle, comprises a plurality of actuators each associated with one of front-left, front-right, rear-left and rear-right road wheels, for adjusting braking forces applied to the road wheels, sensors for detecting wheel speeds of the road wheels to generate wheel-speed indicative signals, and a controller for controlling the actuators in response to the wheel-speed indicative signals. The controller controls a hydraulic actuator associated with a controlled outer rear road wheel through a so-called select-LOW process between a wheel-speed indicative signal value of the controlled rear outer road wheel and a wheel-speed indicative signal value of a diagonal front wheel located on the vehicle diagonally to the controlled outer rear wheel only when the controller determines that the vehicle is in a cornering state with a high lateral acceleration during a braking-force control for the controlled outer rear wheel.

Abstract: In an anti-skid control braking system for a four-wheel drive vehicle with a feature of determination of a road wheel drive state according to the present invention, a determination of an actual drive state of the four-wheel drive vehicle, namely, a determination of whether the four-wheel drive vehicle is running in a two-wheel drive state in which a driving force generated by an engine via a power transmission is distributed through a transfer only toward mainly driven road wheels (rear road wheel pair) or in a four-wheel drive state in which the driving force is distributed through the transfer toward the mainly driven road wheels and secondarily driven road wheels (front road wheel pair) at a predetermined distribution ratio is based on at least one of front and left road wheel speeds (V.sub.WFL, V.sub.WFR, and V.sub.WR) which is detected for the rear road wheel pair without installation of a special-purpose switch (or sensor) especially used to detect the drive state of the four-wheel drive vehicle.

Abstract: Either the front wheels or the rear wheels of a front wheel- and rear wheel-drive vehicle are driven by an engine and the other thereof are driven by an electric motor. A detecting device detects a coefficient of friction on a road surface during running of the vehicle. Control circuit controls to operate the electric motor when the vehicle is subsequently started in a condition in which the coefficient of friction on the road surface is equal to or smaller than a predetermined value. The detecting device for detecting the coefficient of friction on the road surface is made up of a section for detecting the driving force of wheels to be driven by the engine, a section for detecting a slip ratio of the wheels, and a section for obtaining the coefficient of friction on the road surface based on a correlation between the driving force and the slip ratio.

Abstract: A control system for engaging, disengaging and re-engaging a front wheel drive in an agricultural vehicle includes a control circuit configured to receive signals representative of vehicle operating parameters and to generate control signals corresponding to the desired state (i.e. engaged or disengaged) of a front wheel drive engagement circuit. Sensors are associated with the rear wheels, rear service brakes, implement positioning circuit, the vehicle body and the front axle to provide parameter signals related to wheel speed, braking, implement position and vehicle speed. Control logic executed by the control circuit in a continuously cycled routine determines the desired state of the engagement circuit based upon all operating parameters. The control circuit applies an appropriate control signal to the engagement circuit causing engagement or disengagement in accordance with the desired state.

Abstract: In an anti-skid control braking system for a four-wheel drive vehicle with a feature of determination of a road wheel drive state according to the present invention, a determination of an actual drive state of the four-wheel drive vehicle, namely, a determination of whether the four-wheel drive vehicle is running in a two-wheel drive state in which a driving force generated by an engine via a power transmission is distributed through a transfer only toward mainly driven road wheels (rear road wheel pair) or in a four-wheel drive state in which the driving force is distributed through the transfer toward the mainly driven road wheels and secondarily driven road wheels (front road wheel pair) at a predetermined distribution ratio is based on at least one of front and left road wheel speeds (V.sub.WFL, V.sub.WFR, and V.sub.WR) which is detected for the rear road wheel pair without installation of a special-purpose switch (or sensor) especially used to detect the drive state of the four-wheel drive vehicle.

Abstract: The present invention is directed to an anti-skid control system for controlling a braking force applied to road wheels including driven wheels of an electrically operated vehicle which has an electrical motor for driving the driven wheels. A hydraulic braking pressure is supplied to each wheel brake cylinder through an actuator. The actuator is controlled by a braking force controller into which output signals of wheel speed sensors are fed. A band-pass filter is provided for passing the wheel speeds of the driven wheels having an oscillation property within a predetermined band of frequencies, out of the wheel speeds detected by the wheel speed sensors. And, a coefficient of friction of a road is estimated to be relatively low when the output of the band-pass filter is in a predetermined range of frequencies.