Disclosed herein is an input device including: a plurality of input members; an upper surface having a right region in which a part of the plurality of input members is disposed, a left region in which another part of the plurality of input members is disposed, and a center region that is a region between the right region and the left region; and a light emitting region formed along an outer edge of the center region. The light emitting region includes a first light emitting portion configured to indicate identification information assigned to a plurality of input devices connected to an information processing apparatus, and a second light emitting portion configured to emit light based on information different from the identification information.

Disclosed herein is an input device including: a plurality of input members; an upper surface having a right region in which a part of the plurality of input members is disposed, a left region in which another part of the plurality of input members is disposed, and a center region that is a region between the right region and the left region; and a light emitting region formed along an outer edge of the center region. The light emitting region includes a first light emitting portion configured to indicate identification information assigned to a plurality of input devices connected to an information processing apparatus, and a second light emitting portion configured to emit light based on information different from the identification information.

An interactive vehicle simulation system having a virtual reality engine that generates a virtual operating environment that includes a user operated vehicle having a plurality of wheel types, a vehicle position, vehicle orientation, vehicle velocity and vehicle acceleration.

Methods and apparatus provide for controlling an operating device, wherein the operating device includes: (i) a grip part to be gripped by a user; and (ii) an operation part for activation by a finger of the user gripping the grip part, where the operation part includes: (i) a movable part capable of moving from a resting position toward another position in response to a force applied by the finger of the user, (ii) a biasing element operating to urge the movable part toward the resting position, (iii) a sensor operating to measure the force applied by the finger of the user to the movable part and produce a sensing signal therefrom, and (iv) a motorized assembly operating to receive a drive signal, and in response, apply an amount of force to the movable part in opposition to the force applied by the finger of the user, and where the drive signal is a variable dependent on variations in the sensing signal, such that the amount of force applied to the movable part in opposition to the force applied by the finger of the user provides the user with haptic feedback.

Methods and apparatus provide for controlling an operating device, wherein the operating device includes: (i) a grip part to be gripped by a user; and (ii) an operation part for activation by a finger of the user gripping the grip part, where the operation part includes: (i) a movable part capable of moving from a resting position toward another position in response to a force applied by the finger of the user, (ii) a biasing element operating to urge the movable part toward the resting position, (iii) a sensor operating to measure the force applied by the finger of the user to the movable part and produce a sensing signal therefrom, and (iv) a motorized assembly operating to receive a drive signal, and in response, apply an amount of force to the movable part in opposition to the force applied by the finger of the user, and where the drive signal is a variable dependent on variations in the sensing signal, such that the amount of force applied to the movable part in opposition to the force applied by the finger of the user provides the user with haptic feedback.

Disclosed is an operation device including an interaction member, a microphone, a control circuit, and an audio signal processing circuit. The interaction member is used for interacting with a user. The control circuit periodically acquires scan data indicating the acting status of the interaction member. The audio signal processing circuit executes a noise removal process of removing noise from a collected audio signal collected by the microphone. The control circuit periodically transmits previously acquired scan data to the audio signal processing circuit. The audio signal processing circuit executes the noise removal process by using the scan data transmitted from the control circuit.

Implementations relate to hand presence sensing at a control input device. In some implementations, a control input device includes a base member, a handle coupled to the base member and configured to be manually contacted at a grip portion of the handle and moved by a hand of a user in one or more degrees of freedom, one or more control input sensors configured to detect positions or orientations of the handle in the one or more degrees of freedom, and a presence sensor coupled to the base member. The presence sensor has a sensing field, and at least a portion of the sensing field is located proximate to the handle.

Implementations relate to hand presence sensing at a control input device. In some implementations, a control input device includes a base member, a handle coupled to the base member and configured to be manually contacted at a grip portion of the handle and moved by a hand of a user in one or more degrees of freedom, one or more control input sensors configured to detect positions or orientations of the handle in the one or more degrees of freedom, and a presence sensor coupled to the base member. The presence sensor has a sensing field, and at least a portion of the sensing field is located proximate to the handle.

In some aspects, the disclosure is directed to methods and systems for a hybrid position and rate control input device comprising: a housing comprising an upper portion and a lower portion; a force-detecting sensor configured to detect a translation or rotation of the upper portion relative to the lower portion; a motion-detecting sensor within one of the upper portion and the lower portion of the housing, configured to detect motion of the housing relative to a surface; a communication interface positioned within the housing; and a processor positioned within the housing configured to select between a first translation signal from the motion-detecting sensor and a second translation signal from the force-detecting sensor; and transmit, via the communication interface to a computing device, the selected translation signal.

The present invention relates to a heated joystick that is configured to be used with heavy-duty machines, excavators, snowplows, dump trucks and the like. The heated joystick comprises integrated heating elements for heating the surface of the joystick, a controller for controlling the operation of the integrated heating elements, and a wiring circuit to power the integrated heating elements and the controller. The wiring circuit can be connected to an external battery or to the vehicle's power system to supply power to the heated joystick. The heated joystick with the integrated heating elements provides heating of a joystick surface, thereby allowing an operator to easily hold the joystick with their bare hands in cold weather conditions.