A finger pointing joystick with magnetic induction is provided. The finger pointing joystick with magnetic induction includes a main housing having a bottom case and an upper cover; a support frame having a fixed end fixedly to an end of the bottom case; a movable sphere disposed on a receiving ring; a joystick body fixed on the movable sphere; an elastic piston piece having a connecting rod inserted through a piston groove, an elastic disc fixed below the connecting rod, a return spring fixed between the movable sphere and the elastic disc, and a magnet correspondingly fixed to the elastic disk; and a magnetic induction element disposed below the magnet.

A controlling device having an activity mode corresponding to a controllable activity in which activation of a command key within a logical group of command keys of the controlling device causes a transmission of command data to control one or more functional operations of an intended target appliance. For a controllable activity the controlling device has a memory in which is stored a plurality of predetermined appliance to logical group of command keys mappings. To configure the controlling device for the controllable activity one or more predetermined keys of the controlling device are activated to thereby designate one or more intended target appliances for the controllable activity. When the controlling device is then placed into the activity mode corresponding to the controllable activity, the controlling device will use the configuration to select one of the plurality of predetermined appliance to logical group of command keys mappings to determine which appliance command data to transmit in response to an activation of a command key within a logical group of command keys.

A controlling device having an activity mode corresponding to a controllable activity in which activation of a command key within a logical group of command keys of the controlling device causes a transmission of command data to control one or more functional operations of an intended target appliance. For a controllable activity the controlling device has a memory in which is stored a plurality of predetermined appliance to logical group of command keys mappings. To configure the controlling device for the controllable activity one or more predetermined keys of the controlling device are activated to thereby designate one or more intended target appliances for the controllable activity. When the controlling device is then placed into the activity mode corresponding to the controllable activity, the controlling device will use the configuration to select one of the plurality of predetermined appliance to logical group of command keys mappings to determine which appliance command data to transmit in response to an activation of a command key within a logical group of command keys.

A controlling device having an activity mode corresponding to a controllable activity in which activation of a command key within a logical group of command keys of the controlling device causes a transmission of command data to control one or more functional operations of an intended target appliance. For a controllable activity the controlling device has a memory in which is stored a plurality of predetermined appliance to logical group of command keys mappings. To configure the controlling device for the controllable activity one or more predetermined keys of the controlling device are activated to thereby designate one or more intended target appliances for the controllable activity. When the controlling device is then placed into the activity mode corresponding to the controllable activity, the controlling device will use the configuration to select one of the plurality of predetermined appliance to logical group of command keys mappings to determine which appliance command data to transmit in response to an activation of a command key within a logical group of command keys.

A load control device may be used to control and deliver power to an electrical load. The load control device may comprise a control circuit for controlling the power delivered to the electrical load. The load control device may comprise multiple actuators, where each of the actuators is connected between a terminal of the control circuit and a current regulating device. The number of the actuators may be greater than the number of the terminals. The control circuit may measure signals at the terminals and determine a state configuration for the actuators based on the measured signals. The control circuit may compare the state configuration to a predetermined dataset to detect a ghosting condition.

A membrane digital analog switch includes an input button surface adapted to receive an input pressure from a user, and a digital switch positioned below the input button surface to generate a digital switch activation signal when the received pressure on the input button surface is greater than or equal to a specified digital pressure threshold. The membrane digital analog switch also includes an analog switch adapted to generate an analog switch activation signal when the received pressure on the input button surface is greater than or equal to a specified analog pressure threshold. The specified analog pressure threshold is greater than the specified digital pressure threshold, the digital switch activation signal is a binary digital signal, and the analog switch activation signal is variable and corresponds to an analog sensed value of the received pressure on the input button surface.

A load control device may be used to control and deliver power to an electrical load. The load control device may comprise a control circuit for controlling the power delivered to the electrical load. The load control device may comprise multiple actuators, where each of the actuators is connected between a terminal of the control circuit and a current regulating device. The number of the actuators may be greater than the number of the terminals. The control circuit may measure signals at the terminals and determine a state configuration for the actuators based on the measured signals. The control circuit may compare the state configuration to a predetermined dataset to detect a ghosting condition.

The present subject matter relates to recognition of simultaneous key presses in a keyboard. The keyboard includes a first group of keys, which includes keys that are to be individually recognized when pressed simultaneously with at least one other key of the first group. Keys of a first sub-group of the first group are connected to key switches that are to be connected to general purpose input/output (GPIO) pins. Keys of a second sub-group of the first group are connected to key switches on at least one of mutually different columns and mutually different rows of a matrix of electrical interconnections. The second sub-group includes at least one key that is not a modifier key.

An input accepting device includes operation keys, a character receiving unit, a converting unit, an operation key state detection unit, a timer, and a conversion control unit. The converting unit converts a combination of characters corresponding to the operation keys sequentially operated into another character or word. The operation key state detection unit detects a first timing and a second timing while the user operates the operation key. The first timing is at which a state of the user becomes a state of touching the operation key from a state of not touching the operation key. The second timing is at which a state of the user becomes a state of not touching the operation key after the first timing. The timer detects an elapsed time from the first timing. The conversion control unit causes the conversions with different contents depending on the elapsed time at the second timing.

An input accepting device includes operation keys, a character receiving unit, a converting unit, an operation key state detection unit, a timer, and a conversion control unit. The converting unit converts a combination of characters corresponding to the operation keys sequentially operated into another character or word. The operation key state detection unit detects a first timing and a second timing while the user operates the operation key. The first timing is at which a state of the user becomes a state of touching the operation key from a state of not touching the operation key. The second timing is at which a state of the user becomes a state of not touching the operation key after the first timing. The timer detects an elapsed time from the first timing. The conversion control unit causes the conversions with different contents depending on the elapsed time at the second timing.