Abstract: A clamping subassembly according includes a first receptacle defining a first hose receiving aperture defining a first longitudinal axis, a first end along the first longitudinal axis and a second end along the first longitudinal axis. A second receptacle defines a second hose receiving aperture defining a second longitudinal axis, a third end along the second longitudinal axis and a fourth end along the second longitudinal axis. The first receptacle includes a first flange disposed adjacent the first end of the first receptacle and the second receptacle includes a second flange disposed adjacent the third end of the second receptacle.

Abstract: This injection molded article has a body part and a movable part. The body part has a first stopper part and a second stopper part, while the movable part has a movable body and a first rib and a second rib that are formed to protrude at both widthwise end parts of the movable body. A first groove and a second groove that extend in the depth direction perpendicular to the axial direction of a hinge part, are respectively formed between the movable body and the first rib and between the movable body and the second rib.

Abstract: A duct 20 includes: wall portions 24, each of which defines a corresponding one face of an air flow path 22 leading air from an air inlet 20a to an air outlet 20b; and groove portions 26, which are provided on at least two of the wall portions 24, 24, respectively, and extend so as to cross an air flow direction of the air flow path 22, and the groove portions 26 are independent from each other for every wall portion 24, and have a concave shape so as to thin the wall portions 24.

Abstract: A vehicle occupant protection control device includes: a seat state detector configured to detect directions of first and second seats inside a vehicle; and a vehicle occupant protection controller configured to open at least one of a first bag body that is opened on a first side in a width direction of the first seat and a second bag body that is opened on a second side diagonal to the first side in a width direction of the second seat in a state in which the first seat faces the second seat when the seat state detector detects that the first seat faces the second seat and an impact on the vehicle is detected or predicted. A first vehicle occupant sitting on the first seat is pressed on the second side in accordance with the opening of the first bag body or a second vehicle occupant sitting on the second seat is pressed on the first side in accordance with the opening of the second bag body.

Abstract: An occupant restraint structure (5) includes a steering wheel (300) provided with a grip section (310), an instrument panel (500) having a panel (510) on the side of a driver's seat, and an airbag (410). The grip section (310) has an acyclic shape. The airbag (410) is deployed behind a rear end reference surface (S) that is an end surface of the panel (510) on the side of the driver's seat on a rear side of the vehicle. At least a part of the grip section (310) is disposed further forward with respect to the vehicle than the rear end reference surface (S) of the panel (510) on the side of the driver's seat.

Abstract: The present invention concerns an airbag device comprising a security module (10) comprising a rigid body forming a casing (12) and a firing channel (20) comprising a top wall (21), two transverse guide flanges (22, 23) and two transverse walls (32B), said body comprising two transverse flanks having teeth (16) engaged in windows (30) provided on said transverse flanges (22, 23) and two side walls (17) in each of which an opening (17B) is provided, positioned close to the vertical of one of said transverse walls (32B) so as to allow two rods (T) that have been inserted through these openings (17B) to bear on these transverse walls (32B) so as to pivot in order to exert a lever effect causing said module (10) to move in translation and the teeth (16) situated on one of said transverse flanks to disengage from the corresponding windows (30).

Abstract: A lining element for use in a vehicle in order to cover an airbag includes a dimensionally stable backing layer with a first predetermined breaking region which is delimited from a surrounding region and/or from a second predetermined breaking region by at least one predetermined breaking line, where a plurality of regularly spaced predetermined breaking points are disposed along the predetermined breaking line.

Abstract: An airbag device includes an airbag. A passenger protection portion of the airbag has a frontal collision restraint surface, an oblique collision restraint surface, and a restraint recess portion. The airbag has a recess portion tether that couples a tip side of a recess of the restraint recess portion and a front end side of the airbag to each other, and at least one longitudinal tether that couples the front end side of the airbag and a recess portion-side region that is located on the restraint recess portion side with respect to a center of the frontal collision restraint surface in a lateral direction to each other, inside the airbag. The frontal collision restraint surface has at least two protruding surfaces that are configured to protrude backward, due to the longitudinal tether. The at least two protruding surfaces are arranged in alignment in the lateral direction.

Abstract: [Problem] To improve the energy absorption amount in a region for covering a pillar without increasing the gas generation amount of an inflator and without causing a shortage in the energy absorption amount in a region for covering the vicinity of the end on the hood side of a front glass. [Resolution means] A pedestrian protecting airbag apparatus includes: an airbag for covering the vicinity of the end on the hood side of a front glass along with at least a part on the lower side of a pillar; and an inflator for supplying gas to the airbag during a collision. The airbag includes: a center chamber for covering the vicinity of the end on the hood side of the front glass; a pillar cover chamber for covering at least the part on the lower side of the pillar; and a support chamber for expanding between this pillar cover chamber and the pillar.

Abstract: In the present invention, a seatbelt device is provided with: a seat state determination unit that determines the state of a sea a movable support section that supports a seatbelt within a range of possible movement on a seat back; a movement mechanism that, with a motor moves the movable support section within the range of possible movement; and a motor control unit that controls the motor in accordance with the usage state of the seat determined by the seat state determination unit. Due to this configuration, the position of the seatbelt is made optimal for an occupant, and the comfort of the occupant is thus improved.

Abstract: A belt retractor for a motor vehicle seat belt device, with a rotatably mounted belt reel onto which a seat belt is wound, and a belt tensioner with a drive wheel (1), which drives the belt reel in the event of an activation. A positively controlled tensioner coupling transfers the drive movement from the drive wheel (1) onto the belt reel. At least one coupling pawl (2,3) mounted on the drive wheel (1) and which is moved into and out of engagement with a toothing (20) rotationally fixed in relation to the belt reel to establish and disconnect a rotational connection of the drive wheel (1) with the belt reel. A friction ring (4) has a control arm (11) coupled with the coupling pawl (2,3), wherein in the event of an activation of the belt tensioner, the friction ring (4) performs a relative movement to the drive wheel (1) by frictional forces and, controls via the control arm (11) the movement of the coupling pawl (2,3) into engagement and disengagement with the toothing (20).

Abstract: A vehicle may include: a conductive coil; and an authenticator configured to be turned on in response to receiving a current and to request an encryption key from a remote control apparatus. An induction current may be induced in the coil when a magnetic body approaches the coil, and the authenticator may be further configured to be activated in response to receiving the induction current from the coil.

Abstract: A content storage system integrates with locking, engine, and other control systems in a vehicle. The system includes a portable storage device comprising a processor, a storage module in electronic communication with the processor, and a wireless communication module. A wireless device is in electronic communication with the wireless communication module of the portable storage device. A transponder is installed in a vehicle configured to transmit a signal on a wire. The wireless device detects the signal on the wire from the transponder and stores the signal. The wireless device is transmits the signal on the wire in response to a command from the portable storage device.

Abstract: A method for activating a function of a vehicle from a portable access device borne by a user. The method includes measurement of the received signal strength of signals exchanged between the access device and transceiver modules installed in the vehicle, detection of human presence, determination of the position of the access device from the signal strength measurements, and activation of a function of the vehicle when human presence has been detected and the position of the authenticated access device is determined as being within a predetermined proximity zone around the vehicle.

Abstract: A method comprising receiving, by a vehicle computer, first information specifying a user, a time, and a location, the first information received by the vehicle computer from a first communication channel; causing the vehicle to navigate to the geographic location so as to arrive at the specified location; at the geographic location: receiving, by the vehicle computer, second information identifying the individual, time and location, the second information received over a second communication channel different than the first communication channel, the second information sent by a mobile device at the location; comparing, by the vehicle computer, the first information and the second information; and responsive to the comparing, causing, by the vehicle computer, one or more doors of the vehicle to unlock or open.

Abstract: An in-vehicle device includes transmitting antennas, an in-vehicle device transmitter configured to transmit request signals from the respective transmitting antennas, an in-vehicle device receiver configured to receive, from a portable device, an answer signal that includes received signal strengths of the respective request signals, and an in-vehicle device controller configured to calculate a distance from the portable device to each of a plurality of areas, based on both the received signal strengths of the respective request signals included in the answer signal and reference values for the request signals, and to identify an area to which the portable device belongs based on the distance. In a case where there is a request signal whose received signal strength is not included in the answer signal, the in-vehicle device controller calculates the distance by utilizing a corresponding reference value for the request signal as the received signal strength of the request signal.

Abstract: The present invention relates to a rain sensor detecting the size of rain drops based on optical effects. The rain sensor is mounted on a first surface of a pane in order to detect the amount of moisture on an opposing second surface of the pane. The rain sensor comprises at least one emitter for emitting electromagnetic radiation, directed from the first surface to the second surface to form at least two rain-sensitive areas on the second surface At least one receiver is included for sensing radiation emitted by the emitter and that has been internally reflected at the rain-sensitive areas. The rain sensor generates an output signal indicative of an amount of moisture on the rain-sensitive area. A control unit calculates a minimal droplet size based on the output signal.

Abstract: The invention relates to a blade guard (1) for a wiper (100) of a vehicle (200), the blade guard (1) comprising a first part (11) and a second part (12), the first part (11) being configured to allow the blade guard (1) to be attached on the wiper (100), the second part (12) being intended to come into contact with a glazed surface (50) of the vehicle (200), characterized in that the second part (12) is configured to contain a product to be applied onto the glazed surface (50). The invention also relates to a wiper (100) comprising such a blade guard (1).

Abstract: The invention concerns a vehicle, comprising at least one camera and one corresponding washing system (3) for cleaning the camera, the washing system comprising a housing (10) for receiving the camera, a cleaning fluid storage tank (20), a nozzle (12) for spraying the cleaning fluid inside the housing and a pump (22) for pumping the cleaning fluid from the tank to the nozzle. The washing system further includes a passage (18) extending from the housing (10) to the tank (20), for draining, under gravity, used cleaning fluid back into the tank (20).

Abstract: An ice scraping assembly for scraping ice from a windshield includes a bowl that has an outer edge. The outer edge tapers to a point for abrading ice from a windshield. The outer edge has a jagged portion comprising a plurality of teeth. The teeth enhance abrading the ice from the windshield. A grip is coupled to the bowl for gripping.

Abstract: A drum brake according to an embodiment of the present disclosures, which is a drum brake including a drum configured to rotate together with wheels, and a first brake shoe and a second brake shoe to which linings that rub against an inner circumferential surface of the drum are attached, includes: a first pivot fixing part configured to fix one end of the first brake shoe in a pivoting manner so that the first brake shoe outwardly operates and thus the lining of the first brake shoe rubs against the inner circumferential surface of the drum when the first brake shoe pivots in one direction with respect to the one end of the first brake shoe; and a second pivot fixing part configured to fix one end of the second brake shoe in the pivoting manner so that the second brake shoe operates outwardly and thus the lining of the second brake shoe rubs against the inner circumferential surface of the drum when the second brake shoe pivots in the other direction with respect to the one end of the second brake shoe.

Abstract: A thermal management system and methods for use are disclosed. The thermal management system comprises a shield portion and a dissipation portion. The shield portion may comprise a hot side skin, a conduction layer, an insulation layer, and a cool side skin. The dissipation portion may comprise a fin array. Heat absorbed by the shield portion is partially or fully conducted to the dissipation portion for transfer to the ambient environment. The thermal management system may be employed as an aircraft wheel heat shield, an automotive brake heat shield, a gas turbine heat shield, an electronic heat sink, and in various other applications where heat shielding and/or heat transfer are desirable.

Abstract: The invention relates to a method for operating a control device for a braking system of a motor vehicle, wherein the control device receives a braking request from a driver assistance system and determines a target value of a braking operation parameter of the braking system and determines an ideal temporal process for the braking operation parameter, which gradually leads to the target value, complying with a predetermined jerk criterion, and a determines a control fault of an actual value of the braking operation parameter in relation to the ideal process and determines a request value for a controller of a brake pressure pump of the braking system from the control fault on the basis of a controller unit.

Abstract: An automatic brake subsystem (24) includes second accumulators (25F, 25R), a front second line (28) and a rear second line (29), second brake valves (30F, 30R), a first solenoid switching valve (32), first shuttle valves (33F, 33R), and a controller 37. A second solenoid switching valve (34F) and a pressure sensor (35F) are provided in the front second line (28), and a second solenoid switching valve (34R) and a pressure sensor (35R) are provided in the rear second line (29). In a case where it is determined that each of the second brake valve (30F, 30R) is not performing normally based upon a pressure of a hydraulic fluid detected by each of the pressure sensors (35F, 35R) and an operating signal supplied to the first solenoid switching valve (32) or each of the second brake valves (30F, 30R), a controller 37 performs control to switch each of the second solenoid switching valves (34F, 34R).

Abstract: As system for vehicle braking includes: a pedal actuated valve, including a first vent outlet in fluid communication with a fluid sink, a first supply inlet in fluid communication with a fluid source, and a first delivery outlet in fluid communication with a load; an electronically controlled valve in parallel with the pedal actuated valve, including a second vent outlet connected to the fluid sink via the first vent outlet, a second supply inlet in fluid communication with the fluid source, and a second delivery outlet in fluid communication with the load; and, a check valve connected between the load and the first delivery outlet downstream of the second vent outlet. A method for vehicle braking includes: operating at least one of the pedal actuated valve and the electronically controlled valve.

Abstract: Systems and methods are described for coordinating and controlling vehicles, for example heavy trucks, to follow closely to behind each other, or linking to form a platoon. In one aspect, on-board controllers in each vehicle interact with vehicle sensors to monitor and control, for example, gross vehicle weight, axle loads, and stopping distance. In some aspects, two vehicles can determine information associated with their gross weight and axle load, and apply that information to assist with determining a bounding box indicating which vehicle will take longer to stop. Based on which vehicle will take longer to stop, an order of vehicles in a potential platoon is determined.

Abstract: The braking device is provided with an electromagnetic valve, which is an example of a device to be controlled, and a valve control unit for driving the electromagnetic valve by means of PWM control. When driving the electromagnetic valve by inputting a drive signal to the electromagnetic valve, the valve control unit changes the frequency of the drive signal within a frequency range. Note that the width of the frequency range is set on the basis of the minimum audible field among equal-loudness contours.

Abstract: A drive control apparatus is applied to a drive system that is mounted to a vehicle, drives wheels of the vehicle by a motor, and brakes the wheels by a brake apparatus. The drive control apparatus determines a road-surface state of a travel road of the vehicle. The drive control apparatus suppresses slipping of the vehicle by correcting a drive torque by correcting at least either of a motor torque and a brake torque. When determined that the drive torque is to be corrected, the drive control apparatus adjusts a correction amount of the drive torque by adjusting the motor torque with higher priority than the brake torque in response to be determined that the road-surface state is rough.

Abstract: Systems and methods to control the vehicle speed of a vehicle includes a controller communicatively coupled to a motor and a brake mechanism. The controller is structured to receive an indication of a desired change in the vehicle speed, activate a motor speed governor responsive to the brake mechanism being in a released state, adjust an output torque responsive to the vehicle speed, wherein as a load corresponding to the motor increases the vehicle speed decreases.

Abstract: An abnormality diagnostic device and an abnormality diagnostic method for a booster according to the present invention: determine that a negative pressure sensor operates normally, when an output of the negative pressure sensor changes in response to a decrease in intake pressure; determine that a negative pressure pump operates normally, when the pressure in a negative pressure chamber is decreased by operating the negative pressure pump, and the pressure decrease is determined by the negative pressure sensor determined to be normal; determine that the negative pressure pump is abnormal when the pressure decrease is not determined by the negative pressure sensor; and determine that a negative pressure leakage has occurred, when the pressure in the negative pressure chamber, which has been decreased by the negative pressure pump, is not maintained.

Abstract: A master cylinder of a brake for a vehicle may include: a housing having a port through which oil is transferred; a motor connected to the housing so as to supply rotary power; a screw rotatably installed in the motor, and rotated by the rotary power received from the motor; a moving piston engaged with the outside of the screw, and moved in the longitudinal direction of the housing by the rotation of the screw; and a fixed piston fixed to the inside of the housing, and having the moving piston positioned on the outside thereof.

Abstract: An actuator including a drive unit for driving a gear unit of an actuator, the drive unit having an alignment element, which engages with a counter element of the gear unit to be driven, and a fixation arrangement/element is provided between the alignment element and the counter element, which allows the alignment element to be fixed in position in the counter element.

Abstract: The present disclosure pertains to a coupling device for coupling a fluid reservoir for a brake fluid with a brake actuation device. The coupling device includes at least one coupling extension provided at the fluid reservoir with a first recess, a second recess configured in the area of an edge of the brake actuation device as well as a hole configured in the brake actuation device and open to the second recess, a bridge element crossing the second recess along the edge of the brake actuation device and a coupling element with at least one striker, wherein, when the fluid reservoir is coupled to the brake actuation device, the hole is aligned with the first recess along a central longitudinal axis of the striker and the striker passes through the first recess and engages with the hole. The present disclosure also pertains to a vehicle brake system equipped with such a coupling device.

Abstract: A vehicle electricity storage device includes a capacitor unit for supplying stored electric power to an electronically controlled system, and a microcomputer including a memory. The memory stores a plurality of thresholds (internal resistance limit values) different from each other. Each of the plurality of thresholds is to be compared with an electrical characteristic value (internal resistance value) related to the capacitor unit for determining a deterioration state of the capacitor unit. The each of the plurality of thresholds is stored in association with an identification ID for identifying the electronically controlled system. The microcomputer acquires the identification ID from the electronically controlled system. And the microcomputer selects, from the plurality of thresholds, a threshold associated with the identification ID acquired. Then the microcomputer determines the deterioration state of the capacitor unit by using the electrical characteristic value and the threshold selected.

Abstract: A method of transporting cargo, a cargo transport system and an unmanned Wing In Ground Effect vessel (UWIG) for transporting the cargo. A wake up signal indicates assignment of a new delivery. The UWIG begins pre-flight, causes cargo to be transported to the UWIG, and causes the cargo loaded into UWIG storage compartments. Once loaded and the loaded UWIG is ready, the UWIG taxis, e.g., to the open sea. Environmentally sealed PAR thrust fans provide PAR thrust during takeoff. The UWIG flies to a delivery location where cargo is unloaded, and may be stored.

Abstract: A vehicle drive-force transmitting apparatus including: a drive gear; a fluid pump that is to driven by rotation of the drive gear; and a casing that stores therein the drive gear and the fluid pump. The fluid pump includes: a pump body; a pump cover; a rotor; a driven gear that meshes with the drive gear; and a pump shaft on which the rotor and the driven gear are mounted. The pump shaft is rotatably supported at its supported portion by the pump body and/or the pump cover. The driven gear is mounted on a free end portion of the pump shaft. An outer peripheral portion of the pump body or an outer peripheral portion of the pump cover is supported by the casing, such that the other portion of the pump body and the other portion of the pump cover are spaced apart from the casing.

Abstract: Disclosed herein are an apparatus and method for compensating for a heading angle. The apparatus for compensating for a heading angle includes a compensation condition determination unit configured to determine whether a predetermined compensation condition is satisfied, to compensate for a heading angle of a camera, and a heading angle processing unit configured to compensate for the heading angle of the camera using a lane distance input from the camera, when it is determined by the compensation condition determination unit that the compensation condition is satisfied.

Abstract: Systems, apparatuses, and methods disclosed provide for receiving internal information, external static information, and external dynamic information of a hybrid vehicle, and selectively enable or disable a stop/start function for the engine of the hybrid vehicle based on the internal hybrid vehicle information, external static information, and external dynamic information. The stop/start function controls selective activation and deactivation of the engine during operation of the hybrid vehicle.

Abstract: A method for operating a hybrid electric vehicle including an electric machine, a battery and an internal combustion engine, the load point of which is shifted upward to drive the electric machine for charging the battery in the generator mode, wherein a target state of charge of the battery is specified; a required target charging capacity is determined; the load point of the internal combustion engine initially is only shifted upward within an engine-map range of the internal combustion engine.

Abstract: A driving support device includes: a setting unit configured to set a target parking position; and a support unit configured to: steer, during forward movement of a towing vehicle, a steering unit to a side opposite to the target parking position in a left-right direction of the towing vehicle; then output steering information for steering the steering unit toward the target parking position; and output stop information for stopping the towing vehicle after a connection state between the towing vehicle and a towed vehicle which is towed by the towing vehicle is inclined toward the target parking position.

Abstract: In one embodiment, an autonomous vehicle (AV) system determines that a collision between itself and another object is imminent based on data obtained from sensors attached to the AV. The AV system determines an optimal vehicle orientation for the collision, determines a vehicle path to position the vehicle in the optimal vehicle orientation, and autonomously controls the vehicle to travel along the determined vehicle path.

Abstract: Disclosed herein are a control device and method for forward collision avoidance in a vehicle. The control device for forward collision avoidance in a vehicle includes a forward object determination unit configured to recognize an object in front of the vehicle and to determine an attribute of the recognized object, a gear position detection unit configured to detect a gear position of the vehicle, and a forward collision-avoidance assist (FCA) control unit configured to finally determine the attribute of the object determined by the forward object determination unit according to the gear position input from the gear position detection unit and to set an FCA control range based on the finally determined object attribute.

Abstract: In a driving assistance apparatus, an object detecting unit detects an object that is present in a periphery of an own vehicle based on an image captured by an imaging apparatus provided in the own vehicle. An avoidance control unit performs collision avoidance control for avoiding a collision between the detected object and the own vehicle when a collision between the object and the own vehicle is likely. A light distribution control unit switches irradiated light of an irradiation apparatus provided in the own vehicle between high beam and low beam based on a predetermined switching condition. The light distribution control unit performs switching suppression control to suppress switching of the irradiated light from high beam to low beam while the avoidance control unit is performing collision avoidance control in a case where the irradiated light is set to high beam.

Abstract: In a given computing node comprising at least one processor operatively coupled to a memory and implemented in a given vehicle, the method comprises obtaining at the given computing node data from at least one of: (i) one or more sensors on the given vehicle; (ii) one or more computing nodes associated with one or more other vehicles via at least one vehicle-to-vehicle communication protocol; and (iii) one or more data sources along the path of the given vehicle. The given computing node utilizes at least a portion of the obtained data to compute a risk assessment for the given vehicle with respect to an operational safety level of a proposed vehicle action. The given computing node initiates or prevents the proposed vehicle action for the given vehicle based on the computed risk assessment.

Abstract: Disclosed herein are an autonomous vehicle for preventing collisions effectively, and an apparatus and a method for controlling the autonomous vehicle. According to the autonomous vehicle, and the apparatus and the method for controlling the autonomous vehicle of the present disclosure, an area to which the vehicle has to move to avoid a collision may be preset through simple data before the collision at the same time as driving information is generated for regular autonomous driving, and when the collision occurrence is predicted, the collision is prevented by allowing the vehicle to move to the preset collision-avoidance area. An autonomous vehicle, to which the present disclosure is applied, may be a vehicle that can drive itself to a destination without operations of a user.

Abstract: A travelling assist apparatus executing a collision avoidance control between other vehicle and an own vehicle is provided with an approach determination unit determining whether the other vehicle will enter an own lane from an adjacent lane of the own lane; a passing determination unit determining whether the other vehicle is able to pass across the own lane; an interruption determination unit determining whether the other vehicle interrupts the own lane; and a collision avoidance unit executing the collision avoidance control under a condition where the interruption determination unit determines that the other vehicle interrupts the own lane and the passing determination unit determines that the other vehicle is able to pass across the own lane, and executes the collision avoidance control regardless of a determination of the interruption determination unit, when the passing determination unit determines that the other vehicle is unable to pass across the own lane.

Abstract: A driver assistance system (10) for a vehicle includes a control unit (11), and a communication device (12) for receiving data from a server (30). The control unit (11) is configured to calculate a trajectory (T) for the vehicle on the basis of sensor data. The control unit (11) is also configured to replace the calculated trajectory (T) for the vehicle (20) with an offboard trajectory (T1) received from the server (30) under certain circumstances.

Abstract: A system for controlling a vehicle includes a processor configured to execute instructions stored on a non-transitory computer readable medium. The system also includes a sensor coupled to the processor and configured to receive sensory input. The system also includes a controller coupled to the processor and configured to control the vehicle. The processor is further configured to: create a synthetic image based on the sensory input; derive a deep reinforcement learning (RL) policy using the synthetic image, wherein the deep RL policy determines a longitudinal control for the vehicle; and instruct the controller to control the vehicle based on the deep RL policy.

Abstract: Disclosed is a driving support control device (ECU) 10 capable of controlling a vehicle 1 in accordance with any one selected from plural driving support modes by a driver. The driving support control device 10 is configured to temporally repeatedly calculate a target traveling course (R1 to R3) along which the vehicle 1 should travel, and to, in a given one (preceding vehicle following mode) of the driving support modes, execute control of causing the vehicle 1 to travel on and along the target traveling course, wherein the driving support control device 10 is operable, in a situation where a current position of the vehicle 1 deviates beyond a given distance dth laterally from the target traveling course, to, even when the driver selects the given driving support mode, prohibit transition to the given driving support mode.

Abstract: A thermal management system for active thermal management of an autonomously operable motor vehicle. In order to further improve the energy efficiency during operation of an active thermal management system, in an autonomous driving operation, controllable drive components are incorporated in the thermal management system in terms of temperature control in such a way that the drive components are operated in a maximally efficient temperature range.