A hands-free apparatus includes a memory, and a hardware processor coupled to the memory. The hardware processor is configured to: perform a hands-free connection process of connecting to a mobile phone by using a hands-free communication protocol for performing a hands-free phone conversation; perform a first data transfer process of making a first connection with the mobile phone by using a data transfer protocol for transferring phone data related to phone, and causing the phone data to be automatically or manually transferred from the mobile phone; and depending on a status of a different data transfer process than the first data transfer process, perform transfer control related to transfer by at least one of the first data transfer process and the different data transfer process.

A voice processing device includes a first sound collecting unit for generating a first voice signal; a human-body vibration obtaining unit for generating a human-body vibration signal; a first distance calculating unit for calculating a ratio in power or amplitude between the human-body vibration signal and the first voice signal and for calculating a first distance from the first sound collecting unit to a sound source in accordance with the ratio and distance estimation information; a second distance calculating unit for calculating, for each of a plurality of frequencies, a second distance from the first sound collecting unit to a sound source which produces a component of a frequency of a first frequency signal; a gain determining unit for determining, for each of the plurality of frequencies, a gain based on a comparison result between the first distance and the second distance.

A downlead cable includes a first connector configured to connect to a headset of a communication system. A second connector is configured to connect to a connection port of a handset or a radio system. The downlead cable further includes wires connecting the first and second connectors and a cable jacket encapsulating the wires. A transformer is wired inline between the first and second connectors. The transformer is configured to enable the headset to mimic the electrical characteristics a microphone which the handset or the radio system is configured to interface.

Apparatuses, systems, methods, and computer-readable media are provided for analyzing an incoming telephonic event (e.g., call, message, and/or notification) to a mobile device during operation of a vehicle in relation to a combination of factors to determine if the incoming telephonic event is to be allowed to be received during vehicle operation. The mobile device may receive the incoming telephonic event during operation of the vehicle. An incoming telephonic event analysis application operating on the mobile device may apply a soft block preventing the incoming telephonic event from being displayed on the mobile device. Based on the incoming telephonic event data, vehicle operational data, user preferences, hands-free device activation, and driver and road ratings, the incoming telephonic event analysis application may determine whether or not to maintain the soft block or allow the incoming telephonic event to be displayed on the mobile device during operation of the vehicle.

The disclosure herein provides a wearable personal wireless media station including a wearable base station and a wireless earbud. The wearable personal wireless media station may detect that the wireless earbud is docked to the wearable base station, play audio through a speaker of the wearable base station while the wireless earbud is docked to the wearable base station, detect that the wireless earbud is undocked from the wearable base station, cease to play sound through the speaker of the wearable base station in response to detecting that the wireless earbud is undocked from the wearable base station, and begin playing audio through the wireless earbud while the wireless earbud is undocked from the wearable base station.

Systems and methods for prioritizing audio announcements are provided. In one embodiment, a method can include obtaining, by one or more processors associated with a computing device, an audio notification that comprises a message and a preferred priority associated with the message. The method can include determining, by the one or more processors, an assigned priority associated with the message based at least in part on a content of the message and the preferred priority associated with the message. The method can include generating, by the one or more processors, an output indicative of the message and the assigned priority associated with the message. The method can include providing, by the one or more processors, the output to an audio device to audibly produce the output based at least in part on the priority associated with the message.

An electronic device may include: a memory, a display, a haptic module comprising haptic circuitry, a sound module comprising audio circuitry, and a processor. The processor may be configured to: detect an event for an output of vibration and sound, delay the output of the vibration, change a sound output mode from a first mode to a second mode for fast output while the output of the vibration is delayed, output the sound using the sound module in the second mode, and output the delayed vibration through the haptic module to be synchronized with the output of the sound. As the sound output mode is changed to the second mode, a sound output path may be opened. The sound output path may be changed from the first path for non-fast output to the second path for fast output.

A device has a communication link, a headset, and an electronics module. The headset is connected to the communication link and has a speaker, and a microphone. The electronics module is connected to the communication link and has a housing with an information conveying tag positioned on a surface, a processor communicatively coupled to the headset through the communication link, a battery, and a wireless transceiver communicatively coupled with a remote terminal.

A vehicle multimedia system includes a connection to a vehicle bus system in the vehicle; there is a data link, via the vehicle bus system, to a seat occupancy system that is used to determine which seats in the vehicle are occupied, and the occupancy of the seats is displayed via a visualization unit of the vehicle multimedia system in accordance with the determined seat occupancy; the display is designed in such a way that at least one mobile terminal of a vehicle passenger can establish a data connection to the vehicle multimedia system in a coupling process, and said mobile terminal/s is/are associated with the respective vehicle passenger via the vehicle multimedia system.

A circuit and a method for controlling an audio adapter are provided. The audio adapter includes a button and a microphone, and the microphone is adapted for generating a recorded data. The control circuit includes a button detection circuit, a first-in, first-out (FIFO) data buffer, a USB endpoint buffer, a mute circuit and a USB endpoint control circuit. The button detection circuit is used for detecting whether the button is triggered. The FIFO data buffer is used for storing the recorded data. The USB endpoint buffer is used for storing the recorded data. The mute circuit is used for controlling whether the recorded data is transmitted to the USB endpoint buffer according to whether the button is triggered. The USB endpoint control circuit is used for controlling whether the audio adapter outputs the recorded data according to whether the button is triggered.