A technique is disclosed for automatic switching of a mobile device between a videoconference operating mode and a teleconference operating mode, where the automatic switching is based on a detected functional use and current position of the device in relation to a user of the device. In at least some embodiments, the disclosed technology includes a video-audio switching system that works in coordination with a sensor mechanism associated with the device to enable the automatic switching. The technology disclosed herein enables the user to carry out a conversation via the device (i.e., conference session) without interruption when transitioning between different settings, (e.g., using the device while sitting at an office to using it while on-the-go to an appointment).

An audio output device controls the application of active noise cancellation (ANC) levels based on a current status of the device. The audio output device includes a communication interface configured to provide a wired or wireless connection to a playback device, a signal detector configured to detect an audio signal provided through the communication interface, an ANC module configured to apply a first-level ANC to the audio signal, and a control unit configured to determine a level of the ANC to be applied by the ANC module. Upon determining that the audio signal is not provided based on information provided from at least one of the communication interface or the signal detector, the control unit instructs the ANC module to perform a second-level ANC.

A device has a standard female audio connector that is capable of receiving four-pole male connectors and three-pole male connectors and implements: means (CTRL, VCC, S1) for selectively transmitting a DC power supply signal via a first pin (DP1) of said connector; means (CTRL, ANC) for selectively activating a cancellation mechanism for ambient noise from digital audio signals that are intended to be received, via the first pin, in a manner superimposed on said DC power supply signal; means (CTRL, MIF) for selectively transmitting via a second pin of said connector, in a manner superimposed on said audio signals, a timing clock that is intended for digital microphones (DML, DMR) or other sensors; means (CTRL) for configuring itself vis-à-vis the DC power supply signal, the ambient noise cancellation mechanism and the timing clock, according to a determined type of listening device that is effectively connected via said connector.

According to an embodiment of the disclosure, disclosed is an electronic device that includes a first connector electrically connectable to an external electronic device, a second connector electrically connectable to an external audio plug, a wireless communication circuit, and at least one processor. When the electronic device is connected to the external electronic device through the first connector, the at least one processor may receive a first digital audio signal from the external electronic device through the first connector, convert the received first digital audio signal into a first analog audio signal, and output the converted first analog audio signal through the second connector. When the electronic device is connected to the external electronic device through the wireless communication circuit, the at least one processor may receive a second digital audio signal from the external electronic device through the wireless communication circuit, convert the received second digital audio signal into a second analog audio signal having a sound quality lower than that of the first analog audio signal, and output the converted second analog audio signal through the second connector.

A user device determines whether a device connected to its headset jack is an audio accessory device. If the device connected to the headset jack is an audio accessory, the user device connects one or more pins of the headset jack to an audio codec. If the device plugged into the headset jack is not an audio accessory device, the user device connects one or more pins of the headset jack to alternate circuitry. The user device then determines, through the alternate circuitry, an electrical operating parameter requirement of the accessory device, and provides, from the alternate circuitry, the required operating parameter to the accessory device through the headset jack. The alternate circuitry may include an adjustable voltage regulator and/or an adjustable current regulator and the required operating parameter may be one or more of a voltage supply and a current supply.

An earset, according to various examples, comprises: an electronic device connection unit having a microphone terminal connected to a microphone of the earset, an audio ground terminal connected to an audio ground of the earset, a right speaker terminal, and a left speaker terminal; and a switch for allowing, according to a voltage of the microphone terminal, a right speaker and a left speaker of the earset to be mutually connected with one of the right speaker terminal and the left speaker terminal, and the other one of the right speaker terminal and the left speaker terminal to be connected with a shield ground of the earset. Other examples are possible.

Various aspects of a speaker system and a method for auto-configuration of the speaker system is disclosed herein. The speaker system includes an electronic device, which reproduce a first audio in a first speaker configuration. A first sound reproduction device is detected within a pre-defined range of the electronic device. Based on the detection, the first audio is communicated to the first sound reproduction device by the electronic device. The first speaker configuration is modified to a second speaker configuration to reproduce the communicated first audio at the first sound reproduction device.

A method and an electronic device of controlling an audio output are disclosed. The method includes detecting an audio output device connected to an electronic device, determining a type of audio output device associated with the audio output device connected to the electronic device, determining a first audio output level associated with the audio output device connected to the electronic device based on the type of audio output device and a predetermined audio output level, and outputting an audio output at the first audio output level using the audio output device.

An electronic device including a housing, at least one first sound output unit, a connecting module and a second sound output unit is provided. The first sound output unit is located inside or outside the housing. The connecting module is disposed on the housing. The connecting module includes a base and a sensing component. The base has a slot. The sensing component is disposed on the base as corresponding to the slot. The second sound output unit at least includes a plug. The plug is detachably assembled to the slot and is adapted to rotate relative to the base along an axis line, so as to determine whether the plug is sensed by the sensing component to make the electronic device switch between a first sound output mode and a second sound output mode.

This application relates to circuitry for monitoring for instability of an amplifier. The amplifier (100) has a first signal path between an amplifier input (IN.sub.N) and an amplifier output (V.sub.OUT) and a feedback path from the output to form a feedback loop with at least part of the first signal path. A comparator (212) has a first input configured to receive a first signal (IN.sub.N) derived from a first amplifier node which is part of said feedback loop and a second input configured to receive a second signal (IN.sub.P) derived from a second amplifier node which varies with the signal at the amplifier input but does not form part of said feedback loop. The comparator is configured to compare the first signal to the second signal and generate a comparison signal (COMP), wherein in the event of amplifier instability the comparison signal comprises a characteristic indicative of amplifier instability.