An integrated manipulation apparatus for autonomous vehicles and a control method are provided. When a driving mode is switched from an autonomous driving mode to a manual driving mode, a user manipulates the integrated manipulation apparatus, which is portable, to perform chassis functions, such as steering, speed change, acceleration, and braking of a vehicle, and to perform general functions, such as lamp on/off, honking, and turn indication, as needed. A steering dial switch and a speed change slide switch are different in manipulation manner from an acceleration button switch and a braking button switch.

A driving control device for a vehicle, comprising a handle bar interconnected with a brake bar having attachment means for attachment to a brake pedal, the attachment means comprising a locking mechanism comprising an engagement head with a shaft portion and a bail portion having a flat portion, the latter locking mechanism further comprising an engagement socket having a spherical compartment fitting the ball portion and a wall portion in the opening of the socket allowing the engagement head to enter the spherical compartment when the flat portion slides over the wall portion. The driving control device is intended for handicapped drivers and for safe and easy attachment to a vehicle brake pedal.

A control system for an off-highway vehicle including a foot operated drive pedal, a foot operated retard pedal, and a hand operated auxiliary drive/retard control. The auxiliary drive/retard control is operable in a first state to signal a request for drive torque and a second state to signal a request for retard torque.

Throttle control apparatus (810) for a vehicle and a mechanism (800) thereof is provided. A throttle control mechanism (800) includes a first throttle control assembly (802), a second throttle control assembly (804), a first cable (806), a second cable (808), a throttle control apparatus (810), a linkage (812) and a mounting bracket (814). The throttle control apparatus (810) includes a shaft housing (810), a pivot shaft, an intermediate lever (810L) and a lever (810R). The intermediate lever (810L) has a first portion (810Lf) defining a slot (810La) and a second portion (810Ls) defining a slot (810Lb). A first end (806f) of first cable (806) is connected to first throttle control assembly (802) and a second end (806s) of first cable (806) is movably connected to intermediate lever (810L). A first end (808f) of second cable (808) is connected to second throttle control assembly (804) and a second end (808s) of the second cable (808) is movably connected to intermediate lever (810L).

In a self-propelling road construction machine, particularly a road roller (1), comprising a travel drive, a steering device, a control device (30) for the travel drive and the steering device, and a driver's seat (5) rotatable by at least 180° and including an integrated operating element (8) for the vehicle speed, with the operating element (8) generating the control signals for the travel drive in dependence on the direction of the control movement of the operating element (8) or the direction of force application on the operating element (8), it is provided that, in response to a first switching command, the control device (30) will automatically perform a reversing process comprising deceleration, seat rotation, change of direction of travel, and acceleration to the set vehicle speed in opposite direction to the original direction of travel.

A hybrid vehicle system facilitates operator control over electric power generation and use. The system features a motor/generator that can be mounted to an output of a transmission of the vehicle.

An integrated control apparatus for driving a vehicle is provided. The apparatus includes a lever housing mounted in an interior space of the vehicle; a joystick lever coupled to the lever housing and configured to be rotatable in a forward-backward direction and a leftward-rightward direction; and a gentle acceleration lever coupled to the joystick lever and configured to be rotatable in the forward-backward direction. When the gentle acceleration lever is operated, a gentle acceleration signal of the vehicle is generated, and when the joystick lever is operated, one of a sudden acceleration signal, a deceleration signal, a steering signal, or a braking signal of the vehicle is generated.

A movable machine including a chassis, a tool coupled to the chassis, an operator control carried by the chassis and a controller. The controller is communicatively coupled to the operator control. The controller being configured to send a force feedback and/or a vibration feedback to the operator control thereby conveying information to the operator. The information is not related to a load encountered by the tool.

Smart luggage systems are disclosed. A smart luggage system includes a luggage bag including one or more wheels, one or more processors, one or more memory modules, one or more wheel actuators, one or more GPS units, and machine readable instructions stored in the one or more memory modules. When executed by the one or more processors, the machine readable instructions cause the smart luggage system to determine a location of a user, determine a location of the luggage bag based on an output signal from the one or more GPS units, and actuate the one or more wheel actuators to move the luggage bag based on the location of the user and the location of the luggage bag.

A utility table is provided and includes a support table, a plurality of drive wheels, a plurality of guide wheels, and a drive assembly. The support table includes a top frame with a support surface and a pair of side frames extending downward from opposite ends of the top frame. The plurality of drive wheels are positioned along and extend below each of the pair of side frames. The plurality of guide wheels are positioned along an inner surface of the pair of side frames. The drive assembly includes a power source and control system to power the plurality of drive wheels.