A device includes an electromagnetic radiation delivery system such as a laser of light emitting diode infrared emitter configured for delivery of electromagnetic radiation within a sealed canal such as an ear canal, a fiber optic cable configured for delivering or capturing the electromagnetic radiation within the sealed canal, and a photo detector coupled to the fiber optic cable forming a portion of a voice communication system. Other embodiments are disclosed.

An optical network element includes a connection to an optical fiber in an optical line system including a coherent receiver; a microphone configured to detect sound; and circuitry connected to the microphone and configured to cause transmission of information related to sounds detected by the microphone to a receiver at an end of the optical line system, wherein the transmission is over the optical fiber in the optical line system to the coherent receiver. The optical network element can include a polarization controlling device connected to the circuitry and configured to modulate a state-of-polarization (SOP) envelope for the transmission.

An optical microphone assembly including a substrate, an interferometric arrangement, a light source, and at least one photo detector. The interferometric arrangement includes a membrane and at least one diffractive optical element spaced from the membrane. The diffractive optical element(s) include a plurality of lines formed in or disposed on a surface of the substrate and arranged in a first pattern. The substrate includes one or more holes extending fully therethrough, the hole(s) arranged in a second pattern that is different from the first pattern. The light source is arranged to provide light to the interferometric arrangement such that first and second portions of the light propagate along respective, different first and second optical paths via the interferometric arrangement. An optical path difference between the first and second optical paths depends on a distance between the membrane and the diffractive optical element(s). The hole(s) are positioned such that at least one of the first and second optical paths at least partly overlaps with the hole(s). The photo detector(s) are arranged to detect at least part of an interference pattern generated by said first and second portions of light dependent on the optical path difference.

An optical microphone with a dual light source is provided. The optical microphone includes: a housing including an inner cavity and a sound inlet communicating the inner cavity with the outside; a MEMS module disposed in the inner cavity and including a flexible membrane and two gratings; two photoelectric modules, one being disposed in a front cavity and the other in a rear cavity, and each of the photoelectric modules including a light source and a light detector; and an ASIC module disposed in the rear cavity and electrically connected to the photoelectric modules. The optical microphone provides differential measurement, such that the output signal change on one of the two sides of the flexible membrane is positive and the output signal change on another side of the flexible membrane is negative. Therefore, a differential measurement structure is formed to improve the performance of the microphone.

An acoustic sensor that uses an optical fiber and has a high directivity is provided. An acoustic sensor includes a sensing part and an interrogator. The sensing part has a sensing element composed of an optical fiber. The interrogator is connected to the sensing part, sends a pulse light P to the sensing part, and detects an acoustic wave sensed by the sensing part based on a reflected return light from the sensing part. The sensing element is composed of the optical fiber folded in such a way that it reciprocates a plurality of number of times along a directivity direction in which directional sensitivity is exhibited.

A vibrating panel assembly configured to radiate sound into a passenger compartment of a vehicle having a support structure is provided. The assembly includes a substrate panel having front and back surfaces. The panel includes an inner portion, an outer boundary portion formed on the perimeter of the panel and an intermediate portion between the inner portion and the outer boundary portion. The vibrating panel has a frequency distribution of modes in a range of audible frequencies. The panel is configured to be attached to the support structure. An electroacoustic vibrator is mounted on the inner portion at the back surface at a predetermined location and is configured to vibrate the panel over the range of audible frequencies in response to an electrical signal. The intermediate portion is configured to increase modal density of the panel.

A vibrating panel assembly configured to radiate sound into a passenger compartment of a vehicle having a support structure is provided. The assembly includes a substrate panel having front and back surfaces. The panel includes an inner portion, an outer boundary portion formed on the perimeter of the panel and an intermediate portion between the inner portion and the outer boundary portion. The vibrating panel has a frequency distribution of modes in a range of audible frequencies. The panel is configured to be attached to the support structure. An electroacoustic vibrator is mounted on the inner portion at the back surface at a predetermined location and is configured to vibrate the panel over the range of audible frequencies in response to an electrical signal. The intermediate portion is configured to increase modal density of the panel.

An integrated optical transducer for detecting dynamic pressure changes comprises a micro-electro-mechanical system, MEMS, die having a MEMS diaphragm with a first side exposed to the dynamic pressure changes and a second side. The transducer further comprises an application specific integrated circuit, ASIC, die having an evaluation circuit configured to detect a deflection of the MEMS diaphragm, in particular of the second side of the MEMS diaphragm. The MEMS die is arranged with respect to the ASIC die such that a gap with a gap height is formed between the second side of the diaphragm and a first surface of the ASIC die and the MEMS diaphragm, the ASIC die and a suspension structure of the MEMS die delineate a back volume of the integrated optical transducer.

An optical network element includes a connection to an optical fiber in an optical line system including a coherent receiver; a microphone configured to detect sound; and circuitry connected to the microphone and configured to cause transmission of information related to sounds detected by the microphone to a receiver at an end of the optical line system, wherein the transmission is over the optical fiber in the optical line system to the coherent receiver. The optical network element can include a polarization controlling device connected to the circuitry and configured to modulate a state-of-polarization (SOP) envelope for the transmission.

An assembly (1) for measuring a relative humidity level inside a watch (2), the watch (2) provided with a movement (10) and a device (4) for determining the humidity level present in the enclosure (9) of a case (3) of this watch (2). The determination device (4) includes a receiver module (6a, 6b, 6c) for receiving at least one acoustic signal from a timepiece component (11) of said movement (10), and a control unit (7) connected to said receiver module (6a, 6b, 6c). The control unit (7) is configured to run a model for evaluating a water vapour content of a gaseous fluid contained inside the enclosure (9) based on the at least one acoustic signal received by the receiver module (6a, 6b, 6c).