The present disclosure relates generally to microphone assemblies and more particularly to microphones integrated with magnetic transducers, hearing devices with such microphone assemblies, and methods therefor.
Some hearing devices and cochlear implants include an integrated antenna or telecoil that receives audio input from a non-acoustic source. Telecoil-equipped hearing aids were originally designed to receive audio input via magnetic coupling with a telephone receiver for improved sound performance during telephone use. The user of the hearing device would typically disable the microphone during telecoil use. Some such hearing devices are also capable of receiving audio input from assistive listening systems of the type having an induction loop that emits a wireless audio signal received by the telecoil. Revisions to the Americans with Disabilities Act (ADA) now require that certain venues and public spaces having amplified sound systems be equipped with assistive listening systems. Electrical coils also find use for wireless charging and noise cancellation in hearing devices. Users of medical and non-medical hearing devices alike can thus benefit from improvements in magnetic transducers.
The various aspects, features and advantages of the present disclosure will become more fully apparent to those having ordinary skill in the art upon consideration of the following Detailed Description and the accompanying drawings described below.
The disclosure is described in more detail below in connection with the appended drawings and in which like reference numerals represent like components:
According to one aspect of the disclosure, a microphone assembly comprises generally a magnetic transducer including an electrical coil disposed about a core, wherein the magnetic transducer is fastened to a housing of the microphone assembly. In one implementation, the electrical coil of the magnetic transducer is disposed or wound about a portion of the housing of the microphone assembly. In another implementation, the electrical coil of the transducer is fastened to the housing but is not wound about the housing.
In embodiments where the magnetic transducer is configured as a telecoil, the core has a medium or high magnetic permeability. In implementations where the electrical coil of the magnetic transducer is disposed about a portion of the housing, the housing portion has a medium or high magnetic permeability. In other implementations, the electrical coil is disposed about a medium or high magnetically permeable core coupled to the housing of the microphone assembly.
In embodiments, where the magnetic transducer is configured as a wireless charging coil, the core does not require a medium or high magnetic permeability. Thus, in implementations where the electrical coil of the magnetic transducer is disposed about a portion of the microphone assembly housing, the housing portion need not have a medium or high magnetic permeability. Similarly, in implementations where the electrical coil is fastened to a portion of the housing, but not wound thereabout, the core of the electrical coil need not have a medium or high magnetic permeability. For example, the core could be air core or some other material with a low magnetic permeability.
The microphone assembly housing generally comprises a sound port and an external-device interface having a plurality of electrical contacts. In one implementation, the external-device interface is a surface-mount interface suitable for integrating the microphone assembly to a host device, for example by reflow or wave soldering or some other known or future surface-mount technology. In one embodiment, the housing includes a base and a can (also referred to as a cover or lid) coupled to a first surface of the base, wherein the external-device interface is disposed on a second surface of the base opposite the first surface. In
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The microphone assembly also comprises an acoustic transducer disposed in the housing and in acoustic communication with the sound port. In
In some embodiments, an electrical circuit is disposed in the housing. The electrical circuit is electrically coupled to the acoustic transducer and to electrical contacts on the external-device interface. In
The magnetic transducer generally comprises an electrical coil 112 disposed about a core 111 wherein the magnetic transducer is fastened to the housing. In
The electrical coil of the magnet transducer comprises two or more leads, at least one of which is terminated at a coil contact of the housing. In
The output of the magnetic transducer may, or may not, be connected to the electrical circuit of the microphone assembly, depending on the use case. In wireless charging applications, the magnetic transducer is not coupled to the electrical circuit. In telecoil applications, the output of the magnetic transducer may be coupled to the electrical circuit of the microphone assembly or alternatively to a processor of a host device, like a hearing device in which the microphone assembly is integrated.
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In some applications where the magnetic transducer is configured as a telecoil, the magnetic transducer may be coupled to the electrical circuit. In
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The angular difference between the microphones in this example creates a phased array. The signals from the two telecoils is summed by the processor and the overall directional sensitivity of the phase array is reduced. The two telecoils may also be summed by connecting them in series before the combined signal reaches the processor. By way of example, hearing aids frequently have two microphones per ear for beam forming the acoustic signal to determine the direction that the sound is coming from.
In implementations where the magnetic transducer is configured as a telecoil, a high conductivity fine gauge copper wire or other appropriate material is employed to form a coil with likely thousands of turns. In another implementation where the coil is configured as a charging coil, such as for charging a battery or other chargeable component, tens or hundreds of turns are likely employed for the coil.
In some implementations, the can and lid are made of a medium or high permeability material, such as for a telecoil application. In some implementations, the cup and lid or core are a mu metal 80/20 nickel iron alloy. However, any suitable materials may be employed. High permeability metal in some implementations improves the performance of the telecoil by increasing the telecoil sensitivity compared to stainless steel or air. In other implementations, cast ferrite may also be employed, for example, in a charging coil application. In some implementations, both the lid and cup are plated with gold for high electrical conductivity to provide electromagnetic shielding, however other implementations need not have such material. As shown in some implementations, the application specific integrated circuit or other circuitry is encased with an epoxy and wire bonded to the transducer to receive signals from the transducer. In some implementations where the coil is configured as a charging coil, the can is stainless steel.
In one embodiment, the microphone assembly 100 employs a microphone circuit board subassembly and lid/can subassembly. The microphone subassembly is assembled by assembling the microphone components and integrated circuit(s) to the base using standard processes such as surface mount assembly processes such that the microphone and ASIC or other integrated circuit are affixed to the base. In some implementations, the base includes a metal ring that is coupled to ground and is configured in a shape to correspond to a shape of a base of the can.
For the can subassembly, the lid is attached to the can through a seam welding process, high temperature soldering process, spot weld and glue process or any other suitable process that provides an acoustic seal between the lid and the can. The lid/can subassembly is assembled to the microphone circuit board assembly through a high temperature solder process, in some examples in a solder process that is a lower temperature from the cup to lid solder process. For example, the lid/can subassembly is aligned to the corresponding metal ring on the base and soldered to the base. An additional welding operation may be employed if desired. Each microphone assembly is then separated from a larger board array and the microphone may undergo testing for performance. The assembly process includes winding the wire around the cup or core and terminating the coil leads to a coil contact on the printed circuit board (e.g., base) such as using a local spot weld or wire bonding process. In other implementations, a high temperature solder or conductive epoxy process may be used. It will be recognized that any suitable attachment process may be employed.
In certain implementations, such as for telecoil configurations, the can is made from a high permeability magnetic alloy as opposed to conventional cans that employ stainless steel or brass. The high permeability magnetic alloy in some implementations helps to pull in magnetic flux from an AC magnetic field to facilitate a telecoil operation. In implementations where the coil is configured as the charging coil, the high permeability magnetic alloy need not be employed, and stainless steel or other suitable material may be employed. In some implementations, an AC magnetic field going through the middle of the coil generates a voltage in the coil. For a telecoil operation, the AC field may be in the audio band and the resistance of the coil in some implementations is on the order of 1,000 ohms or any other suitable resistance. The number of turns in some implementations is high such as in the thousands of turns range but any suitable number of turns may be employed. The wire gauge in some implementations is 56 which is about 0.015 mm diameter, however any suitable wire gauge may be employed.
For charging coil configurations, the AC field in some implementations is 100-400 kHz, and the resistance of the coil is on the order of ohms or tens of ohms. However, any suitable resistance or frequency may be configured. The number of turns are also less in a charging coil implementation than in a telecoil implementation. In some implementations, the wire gauge is heavier than the telecoil implementation and in some implementations is a 48-gauge wire, however any suitable size wire may be employed.
Among other advantages, employing an integrated coil with a microphone assembly provides a compact design. Employing magnetic transducers provides for an integrated assembly which provides an advantageous form factor. Other benefits will be recognized by those of ordinary skill in the art.
While the present disclosure and what is presently considered to be the best mode thereof has been described in a manner that establishes possession by the inventors and that enables those of ordinary skill in the art to make and use the same, it will be understood and appreciated that there are myriad modifications, variations and equivalents thereto, all of which are within the scope and spirit of the disclosure, which is to be limited not by the exemplary embodiments but by the appended claims.
This application is a divisional application of co-pending application Ser. No. 17/071,029, filed Oct. 15, 2020, entitled “Acoustic Microphone with Integrated Magnetic Transducer,” the entire contents of which are hereby incorporated by reference, which claims priority to U.S. Provisional Patent Application Ser. No. 62/915,614 filed on Oct. 15, 2019, entitled “Acoustic Microphone with Integrated Magnetic Transducer,” the entire contents of which are hereby incorporated by reference.
Number | Date | Country | |
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62915614 | Oct 2019 | US |
Number | Date | Country | |
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Parent | 17071029 | Oct 2020 | US |
Child | 18322182 | US |