Systems and methods for authenticating identification information are disclosed. For example, a system may include an Automated Teller Machine (ATM). An ATM may comprise a user interface. The user interface may comprise a joystick. The user interface may be configured to receive joystick input from a user. The ATM may comprise at least one memory storing instructions. The ATM may comprise at least one processor configured to execute the instructions to perform operations. The operations may comprise receiving identification information from the user. The operations may comprise receiving the joystick input. The operations may comprise extracting a joystick sequence from the joystick input. When the joystick sequence is within a predetermined threshold from a stored joystick sequence corresponding to the identification information, the operations may comprise authenticating the user for an ATM operation.

Systems and methods for authenticating identification information are disclosed. For example, a system may include an Automated Teller Machine (ATM). An ATM may comprise a user interface. The user interface may comprise a joystick. The user interface may be configured to receive joystick input from a user. The ATM may comprise at least one memory storing instructions. The ATM may comprise at least one processor configured to execute the instructions to perform operations. The operations may comprise receiving identification information from the user. The operations may comprise receiving the joystick input. The operations may comprise extracting a joystick sequence from the joystick input. When the joystick sequence is within a predetermined threshold from a stored joystick sequence corresponding to the identification information, the operations may comprise authenticating the user for an ATM operation.

Provided are embodiments of control devices capable of simultaneously measuring six degrees of freedom and electronic systems comprising the control devices. In some embodiments, the control devices are useful for controlling and/or directing movement of vehicles and virtual entities through operation of the control device with a computer processor, computer interface and, optionally a display.

Provided are embodiments of control devices capable of simultaneously measuring six degrees of freedom and electronic systems comprising the control devices. In some embodiments, the control devices are useful for controlling and/or directing movement of vehicles and virtual entities through operation of the control device with a computer processor, computer interface and, optionally a display.

Disclosed are keyboards and keyboard switches sensitive to touch, including, hover and pressure. The keyboard switches have transmit and receive antennae that are spaced apart such that no portion of the transmit antenna touches any portion of the receive antenna. The keyboard switches are arranged in logical rows and logical columns such that each of the keyboard switches is associated with one row and one column. Signal emitters are conductively coupled to the transmit antennae for each of the keyboard switches associated with each of the rows, and each of the signal emitters are adapted to cause each of the transmit antennae to transmit one or more source signals. Receivers are coupled to the receive antennae for each of the keyboard switches associated with each of the columns, and each of the receivers are adapted to capture a frame of signals present on the coupled receive antennae. A signal processor adapted to determine a measurement from each frame, corresponding to an amount of the source signals present on the receive antennae during a time the corresponding frame was received. The signal processor further adapted to determine a keyboard switch touch state from a range of touch states based at least in part on the corresponding measurement.

A handle is adapted to receive one or more fingers or a portion of the hand. A set of sensors is mounted on or near the surface of the handle. Each sensor associated with a different region of the handle. A detector is arranged to detect contact of one or more of the sensors, by one or more fingers or a portion of a hand, to generate an observed touch-point map for the handle for a respective sampling interval. A controller can generate a gain or control response ratio in the electrical signals outputted in response to the observed touch-point map matching or being substantially similar to a reference touch-point map, where the electrical signals are derived from movement or displacement of the handle by a user.

A handle is adapted to receive one or more fingers or a portion of the hand. A set of sensors is mounted on or near the surface of the handle. Each sensor associated with a different region of the handle. A detector is arranged to detect contact of one or more of the sensors, by one or more fingers or a portion of a hand, to generate an observed touch-point map for the handle for a respective sampling interval. A controller can generate a gain or control response ratio in the electrical signals outputted in response to the observed touch-point map matching or being substantially similar to a reference touch-point map, where the electrical signals are derived from movement or displacement of the handle by a user.

A method for controlling movement of a computer display cursor based on a point-of-aim of a pointing device within an interaction region includes projecting an image of a computer display to create the interaction region. At least one calibration point having a predetermined relation to said interaction region is established. A pointing line is directed to substantially pass through the calibration point while measuring a position of and an orientation of the pointing device. The pointing line has a predetermined relationship to said pointing device. Movement of the cursor is controlled within the interaction region using measurements of the position of and the orientation of the pointing device.

A remote control having at least one multifunction button, to which force is applied in one direction by magnets and counter-magnets or mechanical springs, and to which journals with thickened heads are attached, wherein the thickened heads through interaction with bearing shells of a supporting plate serve as centering, guide, and movement stop of the multifunction button.

A switching method and system of interactive modes of a head-mounted device is provided. The interactive modes include gamepad tracking interactive mode and bare hand tracking interactive mode. A standard deviation of position data, a standard deviation of attitude data and a standard deviation of accelerometer data among IMU data are acquired, respectively. Whether the standard deviation of the position data, the standard deviation of the attitude data and the standard deviation of the accelerometer data meet a first preset condition is determined. Moreover, the standard deviation of the accelerometer data within a second preset duration is acquired in real time, and whether the standard deviation of the accelerometer data meets a second preset condition is determined. In cases where the standard deviation of the accelerometer data meets the second preset condition, the bare hand tracking interactive mode is paused, and the gamepad tracking interactive mode is started.