An emergency egress system for a multi-passenger vehicle such as a school bus (10) includes a housing (30) that operatively supports a ramp (34) in movable connection therewith. Opening an emergency exit door (18) of the bus causes a housing door (24) to open and the ramp to move outwardly from a retracted position toward an extended position. Opening the emergency exit door also causes the suspension of the bus to be automatically lowered to place the emergency exit opening (16) closer to the ground (166).

Improved passenger access and suspension systems for passenger buses, and controllers configured for use therewith; and passenger buses incorporating such systems and controllers. Integration of access ramp, door, suspension, charge interface, and other systems provides improvements in fully- or semi-automatic deployment of features such as passenger doors and ramps, and charge interface components, as well as navigation to passenger access points.

A method of tilting a vehicle is provided, and a vehicle is provided. The vehicle has a tilt control system to control the tilt of the vehicle. The method includes tilting the tilting vehicle and/or another tilting vehicle in response to at least one external trigger.

A pet mode door and suspension control system and method includes determining whether a door control action has occurred with respect to a door on the vehicle. When determined that the door control action has occurred, the system and method further includes determining whether a pet mode control action is needed. When determined that the pet mode control action is needed, a suspension control command is sent to suspension control system for raising and/or lowering at least one side of the vehicle and a door control command is sent to a power control unit for opening or closing the door in accord with the door control action.

A towable vehicle including a chassis, at least two wheels and a suspension assembly supporting each wheel. The suspension assembly includes a swing arm pivotally mounted to the chassis, an axle mounted proximate an end of the swing arm, the wheel being mounted on the axle, at least one shock absorber extending from the chassis to the swing arm, an airbag swing arm mounting pivotally coupled to the swing arm, an airbag chassis mounting coupled to the chassis, an airbag coupled to the airbag swing arm and airbag chassis mountings so that inflation of the airbag allows a suspension height to be adjusted over an operating range and a pivot arm pivotally mounted to the chassis and the airbag swing arm mounting to maintain an orientation of the airbag swing arm mounting over the operating range.

An air suspension system which uses software logic and internal signals and/or external signals available to automatically adjust the ride height of the vehicle. The air suspension system also may respond to requests from other vehicle systems requesting a change in ride height. Signals available to the vehicle may be used to detect parking lot maneuvers (for example, a combination of low speed, high steering angle, and low lateral acceleration) and automatically begin to lower the ride height of the vehicle to a calibrated entry/exit ride height. Additionally, a camera, radar, and/or parking sensor signals are utilized to detect potential roof or undercarriage clearance issues, and automatically adjust the ride height of the vehicle. The air suspension system may also adjust the ride height of the vehicle when the electronic brake system (EBS) detects rough road, automatically increasing the ride height of the vehicle to increase ground clearance.

A method performed by an intention indicating system of a vehicle, for indicating to a potential observer an ongoing or impending autonomous kinematic action of said vehicle, said method including: determining an ongoing or impending autonomous kinematic action of said vehicle; and performing a vertical vehicle motion representing said autonomous kinematic action, said vertical vehicle motion including raising and/or lowering a front portion and/or a rear portion of a vehicle body of said vehicle.

A hybrid passenger vehicle includes a chassis supported by at least one front wheel and at least one rear wheel, a body coupled to the chassis including at least one door, and a vehicle floor coupled to the chassis. The body defines an interior space configured to be occupied by at least one passenger when operating the vehicle, and the vehicle floor has a front end and a rear end. A rear wall is coupled to the rear end of the vehicle floor such that the rear wall defines a rearmost boundary of the vehicle floor. A rear suspension assembly is coupled to the chassis. The rear wall is arc-shaped, and the rear suspension assembly is located rearward of the rear wall.

A system for adjusting a height of at least one part of a utility vehicle at at least one predetermined location, the utility vehicle having a position determination device and a height adjustment device to determine a position of the utility vehicle and to change a height of the at least one part of the utility vehicle above a ground surface, including: an interface to receive data that indicate a target height of the at least one part of the utility vehicle at the predetermined location; and a control unit that is couple-able to the position determination device and to the height adjustment device, and is configured, based on a determined position, to prompt the height adjustment device of the utility vehicle to adjust the height of the at least one part of the utility vehicle to the target height. Also described are a related utility vehicle and a method.

A hybrid passenger vehicle includes a chassis supported by at least one front wheel and at least one rear wheel, a body coupled to the chassis including at least one door, and a vehicle floor coupled to the chassis. The body defines an interior space configured to be occupied by at least one passenger when operating the vehicle, and the vehicle floor has a front end and a rear end. A rear wall is coupled to the rear end of the vehicle floor such that the rear wall defines a rearmost boundary of the vehicle floor. A rear suspension assembly is coupled to the chassis. The rear wall is arc-shaped, and the rear suspension assembly is located rearward of the rear wall.