The autonomously driving vehicle is fitted with a GPS unit to which a library of points of interest is assigned, and comprises a human-machine interface that is connected to the GPS unit and which comprises at least one of the following input means for the input of a command for the most immediate possible stopping of the vehicle: a unit for speech input that is connected to the interface, a module for recognizing gestures that is connected to the interface, and a touch-sensitive screen that is connected to the interface.

A vehicle may include a vehicle detector configured to detect an obstacle and a condition of the inside and the outside of the vehicle; and a controller, when a front obstacle is detected by the vehicle detector, configured to determine a required braking distance or a time to collision (TTC) with respect to the obstacle, configured to determine whether a door side collision with the obstacle is estimated, when a collision with the obstacle is estimated according to the result of the determination, and configured to open a door in emergency or convert the door into a manual opening mode when the door side collision is estimated.

A method of operating an electric vehicle having a battery system with a first battery module and a second battery module includes sending a triggering signal. And, in response to the triggering signal, selectively dissipating energy from the first battery module without dissipating energy from the second battery module.

The vehicle includes a powertrain having an axle having a first drive wheel and a second drive wheel. A first gearbox may couple a first power source to the first drive wheel, and a second gearbox may independently couple a second power source to the second drive wheel. And, a controller may be configured to initiate a gear shift in the first gearbox and the second gearbox at different times.

A vehicle seat assembly includes a backrest, a seat including a seat surface, and a partition. The seat is movable between a seat folded position in which the seat surface is disposed along a front surface of the backrest and a seat unfolded position in which the seat surface faces up. The partition to be disposed adjacent to a side surface of the backrest includes a fixing portion and a movable portion. The fixing portion includes a base portion that extends along the side surface and a projecting portion projecting from the base portion farther than the front surface. The movable portion is movable between a folded position adjacent to the base portion and the front surface and an unfolded position away from the base portion and the front surface. The movable portion includes an armrest surface that faces up when the movable portion is in the unfolded position.

A volume tank that houses a material is provided. The volume tank can include a first bulk head, a second bulk head opposite the first bulk head, a non-symmetrical frustoconical shell section, a cylindrical shell section and a transition section in between the non-symmetrical frustoconical shell section and the cylindrical shell section. The volume tank is configured to be coupled to a portion of a frame of a vehicle, and in a non-limiting embodiment, to a school bus.

The power train of an electric vehicle includes an electric motor and a gearbox coupling the electric motor to a drive wheel. A controller may be configured to initiate a gear shift in the gearbox, and activate one or both of (a) a torque jog in electric motor, or (b) a burst of a pressurized fluid in an actuator to assist with the gear shift.

There is disclosed a filter for a vehicle window comprising a layer of filter material, the layer of filter material being for substantially preventing the transmission of radiation at a first predetermined visible wavelength band, the first predetermined visible wavelength band covering the wavelength of a predetermined laser threat, whilst substantially allowing visible wavelengths outside of the band to be transmitted, such that the filter can offer a visible light transmission of at least 70%, and a radiation detector, such that radiation at the first predetermined wavelength band can be detected.

A system method for detecting taillight signals of a vehicle using a convolutional neural network is disclosed. A particular embodiment includes: receiving a plurality of images from one or more image-generating devices; generating a frame for each of the plurality of images; generating a ground truth, wherein the ground truth includes a labeled image with one of the following taillight status conditions for a right or left taillight signal of the vehicle: (1) an invisible right or left taillight signal, (2) a visible but not illuminated right or left taillight signal, and (3) a visible and illuminated right or left taillight signal; creating a first dataset including the labeled images corresponding to the plurality of images, the labeled images including one or more of the taillight status conditions of the right or left taillight signal; and creating a second dataset including at least one pair of portions of the plurality of images, wherein the at least one pair of portions of the plurality of the images are in temporal succession.

An air actuated brake system for use on a heavy-duty vehicle having a frame. Each of a first pair of air actuated brake assemblies is mounted to a first axle supported by the frame. Each of a second pair of air actuated brake assemblies is mounted to a second axle supported by the frame. A source of pressurized air is provided. Valve structure is in fluid communication with the source of pressurized air. The valve structure is located substantially central relative to each of the air actuated brake assemblies. Conduits of substantially equal length and/or volume fluidly connect the valve structure with the first pair of air actuated brake assemblies and with the second pair of air actuated brake assemblies to actuate the air actuated brake assemblies at substantially the same time.