The embodiments of the present disclosure may disclose a vibration sensor, including: an acoustic transducer and a vibration assembly connected with the acoustic transducer. The vibration assembly may be configured to transmit an external vibration signal to the acoustic transducer to generate an electric signal, the vibration assembly includes one or more groups of vibration diaphragms and mass blocks, and the mass blocks may be physically connected with the vibration diaphragms. The vibration assembly may be configured to make a sensitivity degree of the vibration sensor greater than a sensitivity degree of the acoustic transducer in one or more target frequency bands.

There is provided a microphone unit (1) for an action camera, comprising a microphone capsule (10) having at least one speaking hole (11), and a water-tight enclosure (20) which water-tightly encloses the microphone capsule (10). The water-tight enclosure (20) has a water-impermeable passive diaphragm (25) which can oscillate freely and which allows incoming sound to pass substantially undisturbed. The microphone unit has a head (30) having a plurality of holes (31), the head (30) being provided outside the enclosure (20) in front of the passive diaphragm (25). The microphone unit further has a foam portion (40) which is provided in front of the head (30) and has an open-pore foam. The foam portion (40) is in contact with the head (30). The passive diaphragm (25) has an oscillatable minimum area of 20 mm.sup.2; wherein the foam portion (40) has pores which are sufficiently small so that the foam portion (40) can suck water residues away from the holes (31) in the head (30) like a sponge. At the same time however the pores are of such a size that they cannot independently retain water so that water residues, after removal of the microphone unit (1) from the water, run for the greatest part out of the foam portion (40) downwardly under the effect of the force of gravity; wherein the foam portion (40) has a predominant pore density of 15 ppi to 80 ppi.

An audio device with a structure such as an acoustic waveguide, and first and second spaced acoustic transducers that are carried by the structure. A controller is adapted to change the location of the dominant sound source produced by the transducers together in the far field. The device can also be used in a method of facilitating speech communication between two people who speak different languages.

A microphone porting and venting assembly (100) is formed of a remote support substrate (118) providing a (130) acoustically resistive element with dedicated venting cavities (132) along with an external baffle (220) providing acoustic channels (212, 214, 216) which further provide water drainage and external sound sampling points (222, 224, 226). The microphone porting and venting assembly (100) is well suited waterproof, noise cancelling microphone systems.

A deployable speaker includes a driver and an acoustic enclosure made up of a multiplicity of panels. The driver is secured to one of the panels. The acoustic enclosure is deployable from a closed state to a deployed state. All of the panels which make up the enclosure are unitary and formed from a single sheet of composite material. The composite material has an interior layer that includes a first type of material which is skinned in a second type of material.

The present disclosure generally provides an apparatus and method of forming a liquid impermeable sealed audio speaker that can be easily manufactured and provides a high quality audio output. In an effort to overcome the shortcomings of conventional sealed speaker designs that typically utilize complicated and expensive means of shielding their electronic components from liquids and other sources of contamination, one or more of the embodiments of the disclosure provided herein include a sealed enclosure that has at least one liquid impermeable region that prevents or substantially inhibits the movement of a liquid from the exterior region into the internal region. In general, the liquid impermeable regions, or hereafter simply liquid permeable regions, are configured to prevent the ingress of liquids or other contaminants, while allowing the production of a desired sound quality.

A microphone porting and venting assembly (100) is formed of a remote support substrate (118) providing a (130) acoustically resistive element with dedicated venting cavities (132) along with an external baffle (220) providing acoustic channels (212, 214, 216) which further provide water drainage and external sound sampling points (222, 224, 226). The microphone porting and venting assembly (100) is well suited waterproof, noise cancelling microphone systems.

A speaker and a method of producing a speaker, the speaker including: an enclosure; at least one transducer mounted in the enclosure; and at least one passive radiator mounted in the enclosure, including a suspension and a center panel encircled by and adhered to the suspension, wherein the at least one transducer is combined with the at least one passive radiator, and functions as at least a part of the center panel. According to the speaker of the present disclosure, by fully or partly replacing the center panel of the at least one passive radiator by one or more transducer(s), both the internal space and the cost of the speaker are saved without sacrificing the sound quality.

The present disclosure generally provides an apparatus and method of forming a liquid impermeable sealed audio speaker that can be easily manufactured and provides a high quality audio output. In an effort to overcome the shortcomings of conventional sealed speaker designs that typically utilize complicated and expensive means of shielding their electronic components from liquids and other sources of contamination, one or more of the embodiments of the disclosure provided herein include a sealed enclosure that has at least one liquid impermeable region that prevents or substantially inhibits the movement of a liquid from the exterior region into the internal region. In general, the liquid impermeable regions, or hereafter simply liquid permeable regions, are configured to prevent the ingress of liquids or other contaminants, while allowing the production of a desired sound quality.

A deployable speaker includes a driver and an acoustic enclosure made up of a multiplicity of panels. The driver is secured to one of the panels. The acoustic enclosure is deployable from a closed state to a deployed state. When one of the panels is moved by a user from the closed to the deployed state, all but one of the remaining panels are simultaneously moved from the closed to the deployed state.