Systems and methods for operating an engine and a torque converter are presented. In one example, slip of a torque converter is adjusted via at least partially closing or opening a torque converter clutch in response to vehicle vibration. The vehicle vibration may be based on road surface conditions and an actual total number of operating cylinders of the engine.

A method for preventing a rollover of a vehicle or a tractor-trailer combination in curves, by counteracting a rollover risk of the vehicle by independent regulating interventions, performed without action by a vehicle driver, in a regulation system that actuates the drive and/or the brakes of the vehicle, the method including: capturing the current driving situation and the current load of the vehicle or the tractor-trailer combination as to the current driving position of the vehicle or the tractor-trailer combination, ascertaining a maximum admissible transverse acceleration at the current driving position, at which maximum admissible transverse acceleration the vehicle or the tractor-trailer combination just does not roll over, as to the current driving situation and the current load of the vehicle or the tractor-trailer combination. Also described is a related apparatus for preventing a rollover of a vehicle or a tractor-trailer combination in curves.

Control system, which is adapted for application in a vehicle and intended to recognize vehicles driving in front on the basis of environmental data which are obtained from at least one environmental sensor (110) disposed on the vehicle. The at least one environmental sensor (110) is adapted to provide an electronic controller (200) of the control system with the environmental data which reflect the area (115) in front of the vehicle. The control system is at least adapted and intended to detect another vehicle (alter) participating in traffic in front of the own vehicle (ego) with the at least one environmental sensor (110) during a predetermined time period or continuously and to recognize a position change of the other vehicle (alter). If a position change of the other vehicle (alter) is recognized, a signal (255) is output, which is suitable to warn a driver of the own vehicle (ego) of an irregularity in the road surface and/or to adjust a speed and/or a vehicle setting of the own vehicle (ego).

A vehicle system is provided that optimizes vehicle operation by utilizing artificial intelligence and machine learning and providing dynamic changes to the vehicle characteristics. The vehicle system includes one or more sub-systems controlled by a vehicle operating system utilizing artificial intelligence and machine learning.

A tire load calculation section of a controller calculates tire load factors of the respective wheels. A target tire load-factor calculation section calculates a tire load factor average value (.sub.ave) obtained by averaging the tire load factors (.sub.i) of the respective wheels as a target tire load factor. A target tire vertical-load calculation section calculates target tire vertical loads (Fzref.sub.i) for the respective wheels so that the tire load factors of the respective wheels become equal to the tire load factor average value. A vertical-load control section and a suspension control section control thrusts of electromagnetic dampers for the respective wheels so as to achieve the target tire vertical loads.

A plurality of segments of a predetermined route are identified based on a plurality of transition points. A setting of at least one of a plurality of vehicle subsystems is adjusted according to an assigned operating mode when a vehicle enters one of the segments. The vehicle subsystems are actuated according to the assigned operating mode. The assigned operating mode is one of a plurality of operating modes. Each operating mode includes at least one predetermined setting for each one of the vehicle subsystems. The predetermined settings are defined according to data collected from operation of the vehicle in the route by a user.

Some embodiments provide an autonomous navigation system which can navigate a vehicle through an environment according to a selected comfort profile, where the comfort profile associates a particular set of occupant profiles and a particular set of driving control parameters, so that the vehicle is navigated based on the particular set of driving control parameters. The comfort profile is selected based on a determined correlation between the occupants detected in the vehicle interior and the occupants specified by the set of occupant profiles included in the comfort profile. The driving control parameters included in a comfort profile can be adjusted based on monitoring occupants of the vehicle for feedback when the vehicle is being autonomously navigated according to the comfort profile.

A threat emitter system comprising a threat emitter comprising a main power supply, an external power source, a first sequencer, a driver amp, a second sequencer, a main amp, and a radio; a three-way power supply; a mixer, synthesizer, pre-amp, and cooling fans receiving electrical power from the three-way power supply; and an antenna in communication with the main amp; a user interface in communication with radio; the radio in communication with the mixer; the mixer in communication with the synthesizer; a filter in communication between the mixer and the pre-amp; the driver amp in communication with the pre-amp; the first sequencer in communication with the driver amp; the driver amp in communication with the main amp; a second sequencer in communication with the main amp; and a processor with access to a memory storing instructions executable by the processor.

In some examples, a controller includes at least one processor configured to receive information regarding a condition associated with a cargo transportation unit (CTU), the received information regarding the condition including information of an environment around the CTU at a location of the CTU, and adjust an adjustable mechanical element of the CTU in response to the received information.

A vehicle rear wheel steering assist control system is provided where a wheel deflection angle measuring instrument is mounted at a front wheel for measuring a steering angle of the front wheel, a rotational velocity measuring instrument is also mounted at the front wheel for testing a velocity of the front wheel, output ends of the wheel deflection angle measuring instrument and the rotational velocity measuring instrument are electrically connected to the data acquisition module, the data acquisition module is electrically connected to the controller, the controller is electrically connected to a data execution module, the rear wheel active steering device is mounted at a rear wheel of the automobile, the rear wheel active steering device is electrically connected to the data execution module, the controller is electrically connected to an ECU of the automobile, each automobile seat is provided with a weight sensor, which are electrically connected to the controller.