A reception device includes a first electronic component and a second electronic component. The first electronic component includes a first signal processor and a first control circuit controlling the first signal processor. The second electronic component includes a second signal processor and a second control circuit controlling the second signal processor. The first control circuit controls the first signal processor such that transmission of a reception signal from a first transmitter of the first signal processor to the second electronic component and transmission of an analog sound signal from a second transmitter of the first signal processor to the second electronic component are simultaneously started.

A reception device includes a first electronic component and a second electronic component. The first electronic component includes a first signal processor and a first control circuit controlling the first signal processor. The second electronic component includes a second signal processor and a second control circuit controlling the second signal processor. The first control circuit controls the first signal processor such that transmission of a reception signal from a first transmitter of the first signal processor to the second electronic component and transmission of an analog sound signal from a second transmitter of the first signal processor to the second electronic component are simultaneously started.

A system for vibrationally sensing audio includes a vibration output device. The vibration output device includes a haptic actuator; a haptic actuator driver coupled to the haptic actuator; an antenna configured to communicatively receive a haptic pattern from a base unit; and a processor coupled to the antenna and haptic actuator driver. In some embodiments, a haptic pattern includes at least one frequency range. When a total audio power in at least one frequency range reaches a threshold, the processor activates the haptic actuator driver to drive the haptic actuator to produce vibration on a body surface of a user, an inanimate object surface, or a water surface. In some embodiments, the system further includes the base unit. The base unit includes a base unit processor configured to receive an audio signal from an audio emitting device and process the audio signal into the haptic pattern.

Gain factors for amplifying audio data of live broadcasts from mobile devices are selected to ensure that distortions of audio data subsequently generated during the live broadcasts remain within targeted distortion ranges. When a creator initiates a live broadcast from a personal device, audio data captured by the personal device is subjected to amplification and a level of distortion of the audio data is determined. A gain factor for amplifying audio data subsequently captured during the live broadcast is calculated based on a previous gain factor, as well as distortion of the audio data resulting from hard or soft clipping, or any other basis. The gain factor may increase, decrease or remain constant, depending on the prior gain factor and the previously observed distortion.

Gain factors for amplifying audio data of live broadcasts from mobile devices are selected to ensure that distortions of audio data subsequently generated during the live broadcasts remain within targeted distortion ranges. When a creator initiates a live broadcast from a personal device, audio data captured by the personal device is subjected to amplification and a level of distortion of the audio data is determined. A gain factor for amplifying audio data subsequently captured during the live broadcast is calculated based on a previous gain factor, as well as distortion of the audio data resulting from hard or soft clipping, or any other basis. The gain factor may increase, decrease or remain constant, depending on the prior gain factor and the previously observed distortion.

A system for vibrationally sensing audio includes a vibration output device. The vibration output device includes a haptic actuator; a haptic actuator driver coupled to the haptic actuator; an antenna configured to communicatively receive a haptic pattern from a base unit; and a processor coupled to the antenna and haptic actuator driver. In some embodiments, a haptic pattern includes at least one frequency range. When a total audio power in at least one frequency range reaches a threshold, the processor activates the haptic actuator driver to drive the haptic actuator to produce vibration on a body surface of a user, an inanimate object surface, or a water surface. In some embodiments, the system further includes the base unit The base unit includes a base unit processor configured to receive an audio signal from an audio emitting device and process the audio signal into the haptic pattern.

A system for vibrationally sensing audio includes a vibration output device. The vibration output device includes a haptic actuator; a haptic actuator driver coupled to the haptic actuator; an antenna configured to communicatively receive a haptic pattern from a base unit; and a processor coupled to the antenna and haptic actuator driver. In some embodiments, a haptic pattern includes at least one frequency range. When a total audio power in at least one frequency range reaches a threshold, the processor activates the haptic actuator driver to drive the haptic actuator to produce vibration on a body surface of a user, an inanimate object surface, or a water surface. In some embodiments, the system further includes the base unit The base unit includes a base unit processor configured to receive an audio signal from an audio emitting device and process the audio signal into the haptic pattern.

A broadcasting system for providing access information of a broadcast service, wherein a transmission apparatus generates the access information for at least one of a broadcast network and an interaction network, from which the broadcast service is transmitted, and transmits the access information to a terminal via a specific communication network. A reception apparatus receives the access information of the broadcast service via the communication network, analyzes the received access information to determine a network from which the broadcast service is provided, among the broadcast network and the interaction network, and sets an access address for reception of the broadcast service.

A broadcasting system for providing access information of a broadcast service, wherein a transmission apparatus generates the access information for at least one of a broadcast network and an interaction network, from which the broadcast service is transmitted, and transmits the access information to a terminal via a specific communication network. A reception apparatus receives the access information of the broadcast service via the communication network, analyzes the received access information to determine a network from which the broadcast service is provided, among the broadcast network and the interaction network, and sets an access address for reception of the broadcast service.

Systems and methods for generating transcriptions of audio data for presentation at a client device are provided. One or more audio streams, provided by one or more audio sources of one or more client devices of a plurality of users, are received by a broadcasting system. Sensory modality information comprising one or more of auditory, visual, or haptic characteristics of a first user is determined. First audio data from the one or more audio streams corresponding to the first user and additional audio data from the one or more audio streams corresponding to other users are determined using one or more machine learning models. At least one of a first transcription of the first audio data or one or more additional transcription of one or more of the additional audio data are provided for presentation at a first client device according to the auditory, visual, or haptic characteristics.