An improved cruise control system is configured to be retrofit with an electrical mobility scooter. The cruise control system has module that is a self-contained unit, comprising an assembly of electronic components and associated wiring, including a processor and memory with software for processing by the processor, which performs defined tasks, and which is linked with the scooter controller, power supply and scooter throttle control.

A laser radar module includes a laser radar, an upper cover disposed above the laser radar, a lower case disposed below the laser radar, and a locking assembly for connecting the upper cover to the lower case. A gap is formed between the upper cover and the lower case for the laser radar to transmit and receive signals.

A laser radar module includes a laser radar, an upper cover disposed above the laser radar, a lower case disposed below the laser radar, and a locking assembly for connecting the upper cover to the lower case. A gap is formed between the upper cover and the lower case for the laser radar to transmit and receive signals.

An exemplary electrified vehicle assembly includes a coolant circuit and a controller configured to selectively direct energy into at least one component of the coolant circuit to provide a negative wheel torque.

An exemplary electrified vehicle assembly includes a coolant circuit and a controller configured to selectively direct energy into at least one component of the coolant circuit to provide a negative wheel torque.

An off-road vehicle with a driver's seat; a seat belt apparatus provided for the driver's seat; a seat belt detecting device for detecting the set state of the seat belt apparatus provided for the driver's seat; and a controller for controlling the off-road vehicle. The controller has a rotation speed control mode for controlling the rotation speed of the engine to a predetermined rotation speed or less, and the controller releases the rotation speed control mode when the seat belt detecting device detects the set state of the seat belt apparatus provided for the driver's seat.

An off-road vehicle with a driver's seat; a seat belt apparatus provided for the driver's seat; a seat belt detecting device for detecting the set state of the seat belt apparatus provided for the driver's seat; and a controller for controlling the off-road vehicle. The controller has a rotation speed control mode for controlling the rotation speed of the engine to a predetermined rotation speed or less, and the controller releases the rotation speed control mode when the seat belt detecting device detects the set state of the seat belt apparatus provided for the driver's seat.

A control method for a motor-driven vehicle is provided. The method includes calculating a correction torque of a drive motor through a difference between speeds of wheels or a variance rate of the difference between speeds of the wheels and comparing a calculated correction torque with a current required torque of the drive motor. When the calculated correction torque is greater than the current required torque, the drive motor is operated based on the current required torque. When the calculated correction torque is less than or equal to the current required torque, the drive motor is operated based on the calculated correction torque, or the required torque of the drive motor is corrected to correspond to the calculated correction torque and the drive motor is operated based on a corrected required torque of the drive motor.

A control method for a motor-driven vehicle is provided. The method includes calculating a correction torque of a drive motor through a difference between speeds of wheels or a variance rate of the difference between speeds of the wheels and comparing a calculated correction torque with a current required torque of the drive motor. When the calculated correction torque is greater than the current required torque, the drive motor is operated based on the current required torque. When the calculated correction torque is less than or equal to the current required torque, the drive motor is operated based on the calculated correction torque, or the required torque of the drive motor is corrected to correspond to the calculated correction torque and the drive motor is operated based on a corrected required torque of the drive motor.

The present disclosure includes a wheelchair configured to reposition an occupant between a lowered and a raised position. The wheelchair can include a frame, a seat moveable relative to the frame, a drive wheel, one or more pairs of arm assemblies, and one or more sensors. The arm assembly includes a wheel configured to move from a first spatial location when the wheelchair is operating on flat, level ground to a second spatial location that is different than the first spatial location. Arm limiters can selectively engage the arm assembly based on at least one of a seat position, position of the arm assembly, and surface conditions of ground surface. The arm limiters can limit the range of motion of the arm assembly and sometimes other operational aspects of the chair.