Various implementations include microphone arrays and related speaker systems. In one implementation, a microphone array is mounted in a housing having a primary X axis, a primary Y axis perpendicular to the primary X axis, and a primary Z axis perpendicular to the primary X axis and the primary Y axis. The microphone array can include a set of microphones positioned in a single plane perpendicular to the primary Z axis, and axially asymmetric with respect to both the primary X axis and the primary Y axis.

Method and system for enhancing acoustic performances in an adverse acoustic environment, where the system comprises: an array of acoustic sensors having different directivities; and an analysis module being configured for optimizing signal enhancement of at least one source, by correlating the sensors according to respective position of the at least one source in respect to the directivity of the acoustic sensors, based on reflections from reverberating surfaces in the specific acoustic environment, wherein the optimization and sensors directivity allows maintaining the sensor array in compact dimensions without affecting signal enhancement and source separation.

Various implementations include microphone arrays and related speaker systems. In one implementation, a microphone array is mounted in a housing having a primary X axis, a primary Y axis perpendicular to the primary X axis, and a primary Z axis perpendicular to the primary X axis and the primary Y axis. The microphone array can include: a set of microphones positioned in a single plane perpendicular to the primary Z axis of the housing and axially asymmetric with respect to both the primary X axis of the housing and the primary Y axis of the housing. In some cases, all microphones in the set of microphones are stationary relative to the housing.

Various implementations include microphone arrays and related speaker systems. In one implementation, a microphone array is mounted in a housing having a primary X axis, a primary Y axis perpendicular to the primary X axis, and a primary Z axis perpendicular to the primary X axis and the primary Y axis. The microphone array can include a set of microphones positioned in a single plane perpendicular to the primary Z axis, and axially asymmetric with respect to both the primary X axis and the primary Y axis.

Systems, devices and methods for communication include an ear canal microphone configured for placement in the ear canal to detect high frequency sound localization cues. An external microphone positioned away from the ear canal can detect low frequency sound, such that feedback can be substantially reduced. The canal microphone and the external microphone are coupled to a transducer, such that the user perceives sound from the external microphone and the canal microphone with high frequency localization cues and decreased feedback. Wireless circuitry can be configured to connect to many devices with a wireless protocol, such that the user can receive and transmit audio signals. A bone conduction sensor can detect near-end speech of the user for transmission with the wireless circuitry in a noisy environment. Noise cancellation of background sounds near the user can be provided

Systems, devices and methods for communication include an ear canal microphone configured for placement in the ear canal to detect high frequency sound localization cues. An external microphone positioned away from the ear canal can detect low frequency sound, such that feedback can be substantially reduced. The canal microphone and the external microphone are coupled to a transducer, such that the user perceives sound from the external microphone and the canal microphone with high frequency localization cues and decreased feedback. Wireless circuitry can be configured to connect to many devices with a wireless protocol, such that the user can receive and transmit audio signals. A bone conduction sensor can detect near-end speech of the user for transmission with the wireless circuitry in a noisy environment. Noise cancellation of background sounds near the user can be provided.

Audio-derived information is provided to a vehicle control system of a vehicle by attaching a microphone externally to a vehicle to generate an analog signal in response to sound waves external to the vehicle. An enclosure containing sound-attenuating material mechanically filters low frequency sounds from reaching the microphone transducer. An analog-to-digital converter converts the analog signal to a digital signal. A vehicle data bus transfers the digital signal to the vehicle control system.

A piezoelectric contact microphone with a mechanical vibration conduction interface provides an improved mobile electronic device microphone. In an embodiment, the mechanical vibration conduction interface is placed on a bone structure and conducts vibration from the bone structure to the piezoelectric contact microphone. Because of the direct contact, this use of piezoelectric contact microphone reduces or eliminates interferences effects due to wind and other airflow over the microphone. The mechanical vibration conduction interface materials and structure are selected to provide effective transmission of vibration from the bone structure to the piezoelectric element within the piezoelectric contact microphone. This piezoelectric contact microphone enables mobile electronic devices to provide improved voice communication, voice transcription, and voice command recognition in the presence of wind noise and other noise.

To provide an audio processing device including a configuration in which a different microphone is used for generation of directivity depending on a frequency band.

A sound collecting apparatus is provided. The sound collecting apparatus includes a plurality of microphones that collects external sounds and sounds from noise sources in the sound collecting apparatus. Each microphone outputs a microphone signal. The microphone signal is divided, on a one-to-one basis for each microphone, into signals in mutually different frequency bands. A signal level is calculated, on a one-to-one basis for each divided microphone signal, for each of the mutually different frequency bands. Correlation values are calculated between the microphones for each group of identical frequency bands according to the signal level calculated for each of the mutually different frequency bands of each divided microphone signal. It is decided whether at least one of the microphones is sound-insulated, according to the correlation values.