A rotation transmitting mechanism may include first and second tubular holders connected to first and second tubular members, respectively, to be incapable of rotating relative thereto, and a third tubular holder provided to project from an inside of the second tubular holder to the first tubular holder side and connected to the second tubular holder to be incapable of rotating relative thereto. The rotation transmitting mechanism may also include an inner coil spring, the ends of which are inserted inside of and respectively fixed to the first and third tubular holders, and an outer coil spring, the ends of which are inserted outside of and respectively fixed to the first and third tubular holders. The coils may have the same winding direction. In certain states, the second and third tubular holders may be connected to be incapable of rotating relative to each other.

A rotation transmitting mechanism may include first and second tubular holders connected to first and second tubular members, respectively, to be incapable of rotating relative thereto, and a third tubular holder provided to project from an inside of the second tubular holder to the first tubular holder side and connected to the second tubular holder to be incapable of rotating relative thereto. The rotation transmitting mechanism may also include an inner coil spring, the ends of which are inserted inside of and respectively fixed to the first and third tubular holders, and an outer coil spring, the ends of which are inserted outside of and respectively fixed to the first and third tubular holders. The coils may have the same winding direction. In certain states, the second and third tubular holders may be connected to be incapable of rotating relative to each other.

The invention refers to a hydraulic control system for controlling operation of a work attachment of a work machine, comprising a controller configured to output a work attachment control value controlling the operation of the work attachment, an operator input device configured to output a command signal depending on the amount of actuation of the operator input device for setting the work attachment control value, a save input device configured to generate a save command signal upon actuating the save input device and a mode select input device configured to select a first mode and a second mode, wherein the controller is configured to save a constant work attachment control value, wherein the constant work attachment control value is the work attachment control value as set by the command signal upon receiving the save command signal.

The invention refers to a hydraulic control system for controlling operation of a work attachment of a work machine, comprising a controller configured to output a work attachment control value controlling the operation of the work attachment, an operator input device configured to output a command signal depending on the amount of actuation of the operator input device for setting the work attachment control value, a save input device configured to generate a save command signal upon actuating the save input device and a mode select input device configured to select a first mode and a second mode, wherein the controller is configured to save a constant work attachment control value, wherein the constant work attachment control value is the work attachment control value as set by the command signal upon receiving the save command signal.

A steering column control module includes a stalk assembly pivotably connected to a control module housing. A plurality of magnets is connected to and movable by the stalk assembly. A plurality of sensors senses the positions of the plurality of magnets and sends signals indicating the positions of the magnets. A controller receives the signals to control vehicle functions.

A steering column control module includes a stalk assembly pivotably connected to a control module housing. A plurality of magnets is connected to and movable by the stalk assembly. A plurality of sensors senses the positions of the plurality of magnets and sends signals indicating the positions of the magnets. A controller receives the signals to control vehicle functions.

A lighting control console for controlling a lighting system, wherein digital adjusting commands are generated in the lighting control console that can be transmitted to the lighting system via data links. At least one dual encoder is provided in the control panel of the lighting control console which allows users to enter input values. The dual encoder includes a first shaft and a second shaft rotatably mounted in a housing, first and second locking mechanisms for locking different rotational positions of the first and second shafts, and at least one first and at least one second rotation signal generator for generating a data signal showing a switchover between two locking positions. Both shafts include actuating elements at which adjusting movements can be transmitted onto the shafts by hand.

A lighting control console for controlling a lighting system, wherein digital adjusting commands are generated in the lighting control console that can be transmitted to the lighting system via data links. At least one dual encoder is provided in the control panel of the lighting control console which allows users to enter input values. The dual encoder includes a first shaft and a second shaft rotatably mounted in a housing, first and second locking mechanisms for locking different rotational positions of the first and second shafts, and at least one first and at least one second rotation signal generator for generating a data signal showing a switchover between two locking positions. Both shafts include actuating elements at which adjusting movements can be transmitted onto the shafts by hand.

Apparatus and methods for a modular robotic device with artificial intelligence that is receptive to training controls. In one implementation, modular robotic device architecture may be used to provide all or most high cost components in an autonomy module that is separate from the robotic body. The autonomy module may comprise controller, power, actuators that may be connected to controllable elements of the robotic body. The controller may position limbs of the toy in a target position. A user may utilize haptic training approach in order to enable the robotic toy to perform target action(s). Modular configuration of the disclosure enables users to replace one toy body (e.g., the bear) with another (e.g., a giraffe) while using hardware provided by the autonomy module. Modular architecture may enable users to purchase a single AM for use with multiple robotic bodies, thereby reducing the overall cost of ownership.

Control devices and systems for self-propelled machinery and related methods are disclosed. In one aspect, a control device for self-propelled machinery includes a central portion disposed between a first gripping portion and a second gripping portion and at least one pressure sensitive trigger control provided over either the first or the second gripping portion. The trigger control can be configured to reduce a speed of the self-propelled machinery by actuating a portion of a potentiometer for varying an electrical signal carried by the control device. In some aspects, the control device can electrically communicate with a control unit of the self-propelled machinery.