A wireless receiver includes a guided user interface to enable and assist users to optimally select groups and frequencies for wireless communication with wireless transmitters is provided. The wireless receiver may automatically detect the connectedness and parameters of wireless receivers in order to adaptively display and select setup options and messages. The guided user interface may improve user satisfaction and reduce the configuration time of the wireless receivers.

Aspects of the disclosure relate to a remote control which may include one or more buttons configured to provide input to the remote control upon being activated, a transmitter for transmitting data, a receiver for receiving data, a processor and memory storing computer executable instructions that, when executed, cause the two-way remote control to perform a method for configuring repeat transmission behavior of one or more of the buttons of the two-way remote control. Further, the receiver may be configured to receive data from a device configured to be controlled by the remote control and the data may include instructions for configuring the repeat transmission behavior of the one or more buttons of the two-way remote control. Additionally, the two-way remote control may configure the repeat transmission behavior of the one or more buttons of the two-way remote control based on the data received from the device.

A filter (22A) includes: a series arm circuit (11) that is connected between an input/output terminal (22m) and an input/output terminal (22n); and a parallel arm circuit (12) that is connected between a node (x1), which is on a path that connects the input/output terminal (22m) and the input/output terminal (22n), and ground. The parallel arm circuit (12) includes a parallel arm resonator (22p) and an impedance circuit (13) that is serially connected to the parallel arm resonator (22p). The impedance circuit (13) includes a first impedance element, which is one of an inductor and a capacitor, a second impedance element, which is the other of an inductor and a capacitor, and a switch (22SW) that is serially connected to the second impedance element. A first series circuit (14) comprising of the second impedance element and the switch (22SW) is connected in parallel with the first impedance element.

A filter (22A) includes: a series arm circuit (11) that is connected between an input/output terminal (22m) and an input/output terminal (22n); and a parallel arm circuit (12) that is connected between a node (x1), which is on a path that connects the input/output terminal (22m) and the input/output terminal (22n), and ground. The parallel arm circuit (12) includes a parallel arm resonator (22p) and an impedance circuit (13) that is serially connected to the parallel arm resonator (22p). The impedance circuit (13) includes a first impedance element, which is one of an inductor and a capacitor, a second impedance element, which is the other of an inductor and a capacitor, and a switch (22SW) that is serially connected to the second impedance element. A first series circuit (14) comprising of the second impedance element and the switch (22SW) is connected in parallel with the first impedance element.

A device for the acquisition and/or transmission of digital and/or analog signals comprising a plurality of three-pin connectors which allow connection to a number of sensors and/or actuators, the device being controllable and/or configurable remotely by way of web communication protocols.

A device for the acquisition and/or transmission of digital and/or analog signals comprising a plurality of three-pin connectors which allow connection to a number of sensors and/or actuators, the device being controllable and/or configurable remotely by way of web communication protocols.

Aspects of the disclosure relate to a remote control which may include one or more buttons configured to provide input to the remote control upon being activated, a transmitter for transmitting data, a receiver for receiving data, a processor and memory storing computer executable instructions that, when executed, cause the two-way remote control to perform a method for configuring repeat transmission behavior of one or more of the buttons of the two-way remote control. Further, the receiver may be configured to receive data from a device configured to be controlled by the remote control and the data may include instructions for configuring the repeat transmission behavior of the one or more buttons of the two-way remote control. Additionally, the two-way remote control may configure the repeat transmission behavior of the one or more buttons of the two-way remote control based on the data received from the device.

The present invention relates to a wireless microphone system which, when recording voice data in an interval from a recording start time and a recording stop time, further records voice data by a predetermined period of time in the forward and backward directions of the recording start time and the recording stop time with reference to the time axis, thereby maximally securing voice data for identifying situations of various scenes such as an event, an accident and a criminal scene. The wireless microphone system according to the present invention comprises: a transmission unit for wirelessly transmitting voice data and a recording start signal; a reception unit for transmitting, to a reception target, the voice data and the recording start signal wirelessly transmitted from the transmission unit; and a DVR for temporarily storing the voice data transmitted from the reception unit in a first storage unit for a predetermined period of time, storing the voice data transmitted from the reception unit in a second storage unit and simultaneously storing voice data over a predetermined period of time before the point of reception of the recording start signal in the second storage unit using the voice data in the first storage unit when the recording start signal is received from the reception unit, and storing voice data over a predetermined period of time after the time when a recording stop signal is input through a recording stop signal input unit for stopping recording, included in the DVR.

A voice enabled device includes a transducer to capture multiple inaudible signals received from multiple ultrasonic speakers and audio recording electronics to process the multiple inaudible signals to generate digital output samples, which are recorded sound data comprising non-linearities from frequency-shifted versions of the multiple inaudible signals to within an audible frequency range. A processing device is to detect, within the recorded sound data, at least a portion of the non-linearities, e.g., via: comparison of the recorded sound data with expected patterns from an audible audio signal generated by human voice; and detection of non-linear variations within the recorded sound data as compared to the expected patterns. In response to the detection, the processing device is further to suppress an action programmed for response to a voice command corresponding to the recorded sound data.

A voice enabled device includes a transducer to capture multiple inaudible signals received from multiple ultrasonic speakers and audio recording electronics to process the multiple inaudible signals to generate digital output samples, which are recorded sound data comprising non-linearities from frequency-shifted versions of the multiple inaudible signals to within an audible frequency range. A processing device is to detect, within the recorded sound data, at least a portion of the non-linearities, e.g., via: comparison of the recorded sound data with expected patterns from an audible audio signal generated by human voice; and detection of non-linear variations within the recorded sound data as compared to the expected patterns. In response to the detection, the processing device is further to suppress an action programmed for response to a voice command corresponding to the recorded sound data.