A method, computer program product, and computing system for visual diarization of an encounter is executed on a computing device and includes obtaining encounter information of a patient encounter. The encounter information is processed to: associate a first portion of the encounter information with a first encounter participant, and associate at least a second portion of the encounter information with at least a second encounter participant. A visual representation of the encounter information is rendered. A first visual representation of the first portion of the encounter information is rendered that is temporally-aligned with the visual representation of the encounter information. At least a second visual representation of the at least a second portion of the encounter information is rendered that is temporally-aligned with the visual representation of the encounter information.

A vehicular device is disclosed, including a processor and plurality of sensors. The processor receives sensor data and determines vehicle occupant respiration based on the sensor data. The sensors can include acoustic sensors and imaging sensors. The processor can be configured for executing a machine learning algorithm to determine the occupant respiration.

One example method includes generating sound information regarding sound sources in an environment. The sound information is generated by separating and localizing the sound sources. The sound information is then presented as guidance to a user. The guidance may be presented graphically in a user interface, haptically, or in another manner.

There is provided an automated microphone system (100) having a microphone (104). The system (100) comprises a microphone stand (102) having at least one movable arm (1022), at least one movable leg (1024) and a fixed base (1026) attached to the at least one movable leg (1024), the at least one movable arm (1022) being adapted to mount the microphone (104) at a first end and connected with the at least one movable leg (1024) at a second end, one or more sensors (106) disposed at one or more of the at least one movable leg (1024), the at least one movable arm (1022) and the fixed base (1026), one or more motors (108) connected with each of the at least one movable arm (1022), the at least one movable leg (1024) and the fixed base (1026) and a control module (110) connected with the one or more sensors (106) and the one or more motors (108).

A method (S100) for optimizing speech pickup in a speakerphone system, wherein the speakerphone system comprises a microphone system placed in a specific configuration, wherein the method comprising receiving (S10) acoustic input signals (12) by the microphone system, processing (S20) said acoustic input signals (12) by using an algorithm (100) for focusing and steering a selected target sound signal towards a desired direction, and transmitting (S30) an output signal (13) based on said processing.

A conference terminal and a feedback suppression method are provided. In the method, a transmitting sound signal is divided into sub sound signals of multiple frequency bands. Different sub sound signals correspond to different frequency bands. An interfered frequency band corresponding to the howling interference is detected according to the sub sound signals of those frequency bands. The power of the sub sound signal of the interfered frequency band increases along with time. The interfered frequency band is affected by the howling interference. An interference direction is determined according to multiple input sound signals received by the microphone array and merely pass through the interfered frequency band. A sound from the interference direction leads to the howling interference. A beam pattern of the microphone array is determined according to the interference direction. The gain of the beam pattern in the interference direction is reduced.

Techniques for modifying sound based on a direction of interest include determining a direction of interest associated with a user; receiving a set of audio signals associated with the direction of interest; determining one or more salient frequency bands within the set of audio signals; in response to receiving a command from the user to enhance or suppress the set of audio signals, enhancing or suppressing a portion of the set of audio signals corresponding to the one or more salient frequency bands to create a modified set of audio signals; and outputting the modified set of audio signals.

A microphone circuit characterized in that an impedance element can be connected in parallel with the microphone for the purpose of damping resonance and linearizing the proximity effect. The impedance of this element is preferably between 20 and 1000 ohms.

A microphone transmitter has a microcontroller that operates in a high gain mode when the portable housing is in a horizontal position or in a low gain mode when the portable housing is in a vertical position. In another implementation, the microcontroller operates in one of the following modes: (1) operate the microphone at a low microphone gain when the portable housing is in a vertical position and when voice activity is detected; (2) operate the microphone at a lower microphone gain when the portable housing is in a vertical position and when no voice activity is detected; (3) operate the microphone at a high microphone gain when the portable housing is in a horizontal position and when no voice activity is detected; or (4) operate the microphone at a higher microphone gain when the portable housing is in a horizontal position and when voice activity is detected.

An electronic apparatus and/or a controlling method are provided. The electronic apparatus may include a camera for photographing an image, a microphone for receiving an input of a sound of a first channel, and a processor for generating sounds of a plurality of channels based on the input sound, wherein the processor is configured to identify an object and the location of the object from the photographed image, classify the input sound based on an audio source, and allot the sound to the corresponding identified object, copy the classified sound and generate sounds of two channels, adjust characteristics of the generated sounds of two channels based on the audio source allotted to the identified object and the location of the identified object, and mix the sounds of two channels wherein the characteristics were adjusted according to the audio source and generate a stereo sound of two channels.