Directional microphone assembly

Abstract

A microphone capsule for an in-the-ear hearing aid is disclosed. The capsule can include a top plate having first and second spaced openings defining front and rear sound inlets, and a directional microphone cartridge enclosing a diaphragm. The diaphragm is oriented generally perpendicular to the top plate and divides the directional microphone cartridge housing into a front chamber and a rear chamber. A front sound passage communicates between the front sound inlet and the front chamber, and a rear sound passage communicates between the rear sound inlet and the rear chamber. Front and rear acoustic damping resistors having selected resistance values are associated with the front and rear sound passages. The acoustic resistor pair provides a selected time delay, such as about 4 microseconds, between the front and rear sound passages. The use of two acoustic resistors instead of one levels the frequency response, compared to the frequency response provided by a rear acoustic damping resistor alone.

Description

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

Not Applicable.

BACKGROUND OF THE INVENTION

The application of directional microphones to hearing aids is well known in the patent literature (Wittkowski, U.S. Pat. No. 3,662,124 dated 1972; Knowles and Carlson, U.S. Pat. No. 3,770,911 dated 1973; Killion, U.S. Pat. No. 3,835,263 dated 1974; Ribic, U.S. Pat. No. 5,214,709, and Killion et al. U.S. Pat. No. 5,524,056, 1996) as well as commercial practice (Maico hearing aid model MC033, Qualitone hearing aid model TKSAD, Phonak “AudioZoom” hearing aid, and others).

Directional microphones are used in hearing aids to make it possible for those with impaired hearing to carry on a normal conversation at social gatherings and in other noisy environments. As hearing loss progresses, individuals require greater and greater signal-to-noise ratios in order to understand speech. Extensive digital signal processing research has resulted in the universal finding that nothing can be done with signal processing alone to improve the intelligibility of a signal in noise, certainly in the common case where the signal is one person talking and the noise is other people talking. There is at present no practical way to communicate to the digital processor that the listener now wishes to turn his attention from one talker to another, thereby reversing the roles of signal and noise sources.

It is important to recognize that substantial advances have been made in the last decade in the hearing aid art to help those with hearing loss hear better in noise. Available research indicates, however, that the advances amounted to eliminating defects in the hearing aid processing, defects such as distortion, limited bandwidth, peaks in the frequency response, and improper automatic gain control or AGC action. Research conducted in the 1970's, before these defects were corrected, indicated that the wearer of hearing aids typically experienced an additional deficit of 5 to 10 dB above the unaided condition in the signal-to-noise ratio (“S/N”) required to understand speech. Normal hearing individuals wearing those same hearing aids might also experience a 5 to 10 dB deficit in the S/N required to carry on a conversation, indicating that it was indeed the hearing aids that were at fault. These problems were discussed by Applicant Killion in a recent paper “Why some hearing aids don't work well!!!” (Hearing Review, January 1994, pp. 40-42).

Recent data obtained by the Applicants confirm that hearing impaired individuals need an increased signal-to-noise ratio even when no defects in the hearing aid processing exist. As measured on one popular speech-in-noise test, the SIN test, those with mild loss typically need some 2 to 3 dB greater S/N than those with normal hearing; those with moderate loss typically need 5 to 7 dB greater S/N; those with severe loss typically need 9 to 12 dB greater S/N. These figures were obtained under conditions corresponding to defect free hearing aids.

As described below, a headworn first-order directional microphone can provide at least a 3 to 4 dB improvement in signal-to-noise ratio compared to the open ear, and substantially more in special cases. This degree of improvement will bring those with mild hearing loss back to normal hearing ability in noise, and substantially reduce the difficulty those with moderate loss experience in noise. In contrast, traditional omnidirectional head-worn microphones cause a signal-to-noise deficit of about 1 dB compared to the open ear, a deficit due to the effects of head diffraction and not any particular hearing aid defect.

A little noticed advantage of directional microphones is their ability to reduce whistling caused by feedback (Knowles and Carlson, 1973, U.S. Pat. No. 3,770,911). If the ear-mold itself is well fitted, so that the vent outlet is the principal source of feedback sound, then the relationship between the vent and the microphone may sometimes be adjusted to reduce the feedback pickup by 10 or 20 dB. Similarly, the higher-performance directional microphones have a relatively low pickup to the side at high frequencies, so the feedback sound caused by faceplate vibration will see a lower microphone sensitivity than sounds coming from the front.

Despite these many advantages, the application of directional microphones has been restricted to only a small fraction of Behind-The-Ear (BTE) hearing aids, and only rarely to the much more popular In-The-Ear (ITE) hearing aids which presently comprise some 80% of all hearing aid sales.

Part of the reason for this low usage was discovered by Madafarri, who measured the diffraction about the ear and head. He found that for the same spacing between the two inlet ports of a simple first-order directional microphone, the ITE location produced only half the microphone sensitivity. Madafarri found that the diffraction of sound around the head and ear caused the effective port spacing to be reduced to about 0.7 times the physical spacing in the ITE location, while it was increased to about 1.4 times the physical spacing in the BTE location. In addition to a 2:1 sensitivity penalty for the same port spacing, the constraints of ITE hearing aid construction typically require a much smaller port spacing, further reducing sensitivity.

Another part of the reason for the low usage of directional microphones in ITE applications is the difficulty of providing the front and rear sound inlets plus a microphone cartridge in the space available. As shown in FIG. 17 of the '056 patent mentioned above, the prior art uses at least one metal inlet tube (often referred to as a nipple) welded to the side of the microphone cartridge and a coupling tube between the microphone cartridge and the faceplate of the hearing aid. The arrangement of FIG. 17 of the '056 patent wherein the microphone cartridge is also parallel with the faceplate of the hearing aide forces a spacing D as shown in that figure which may not be suitable for all ears.

A further problem is that of obtaining good directivity across frequency. Extensive experiments conducted by Madafarri as well as by the Applicants over the last 25 years have shown that in order to obtain good directivity across the audio frequencies in a head-worn directional microphone it, requires great care and a good understanding of the operation of sound in tubes (as described, for example, by Zuercher, Carlson, and Killion in their paper “Small acoustic tubes,” J. Acoust. Soc. Am., V. 83, pp. 1653-1660, 1988).

A still further problem with the application of directional microphones to hearing aids is that of microphone noise. Under normal conditions, the noise of a typical non-directional hearing aid microphone cartridge is relatively unimportant to the overall performance of a hearing aid. Sound field tests show that hearing aid wearers can often detect tones within the range of 0 to 5 dB Hearing Level, i.e., within 5 dB of average young normal listeners and well within the accepted 0 to 20 dB limits of normal hearing. But when the same microphone cartridges are used to form directional microphones, a low frequency noise problem arises. The subtraction process required in first-order directional microphones results in a frequency response falling at 6 dB/octave toward low frequencies. As a result, at a frequency of 200 Hz, the sensitivity of a directional microphone may be 30 dB below the sensitivity of the same microphone cartridge operated in an omnidirectional mode.

When an equalization amplifier is used to correct the directional microphone frequency response for its low frequency drop in sensitivity, the amplifier also amplifies the low frequency noise of the microphone. In a reasonably quiet room, the amplified low frequency microphone noise may now become objectionable. Moreover, with or without equalization, the masking of the microphone noise will degrade the best aided sound field threshold at 200 Hz to approximately 35 dB HL, approaching the 40 dB HL lower limits for what is considered a moderate hearing impairment.

The equalization amplifier itself also adds to the complication of the hearing aid circuit. Thus, even in the few cases where ITE aids with directional microphones have been available, to applicant's knowledge, their frequency response has never been equalized. For this reason, Killion et al (U.S. Pat. No. 5,524,056) recommend a combination of a conventional omnidirectional microphone and a directional microphone so that the lower internal noise omnidirectional microphone may be chosen during quiet periods while the external noise rejecting directional microphone may be chosen during noisy periods.

Although directional microphones appear to be the only practical way to solve the problem of hearing in noise for the hearing-impaired individual, they have been seldom used even after nearly three decades of availability. It is the purpose of the present invention to provide an improved and fully practical directional microphone for ITE hearing aids.

Before summarizing the invention, a review of some further background information will be useful. Since the 1930s, the standard measure of performance in directional microphones has been the “directivity index” or DI, the ratio of the on-axis sensitivity of the directional microphone (sound directly in front) to that in a diffuse field (sound coming with equal probability from all directions, sometimes called random incidence sound). The majority of the sound energy at the listener's eardrum in a typical room is reflected, with the direct sound often less than 10% of the energy. In this situation, the direct path interference from a noise source located at the rear of a listener may be rejected by as much as 30 dB by a good directional microphone, but the sound reflected from the wall in front of the listener will obviously arrive from the front where the directional microphone has (intentionally) good sensitivity. If all of the reflected noise energy were to arrive from the front, the directional microphone could not help.

Fortunately, the reflections for both the desired and undesired sounds tend to be more or less random, so the energy is spread out over many arrival angles. The difference between the “random incidence” or “diffuse field” sensitivity of the microphone and its on-axis sensitivity gives a good estimate of how much help the directional microphone can give in difficult situations. An additional refinement can be made where speech intelligibility is concerned by weighing the directivity index at each frequency to the weighing function of the Articulation Index as described, for example, by Killion and Mueller on page 2 of The Hearing Journal, Vol. 43, Number 9, September 1990. Table 1 gives one set of weighing values suitable for estimating the equivalent overall improvement in signal-to-noise ratio as perceived by someone trying to understand speech in noise.

The directivity index (DI) of the two classic, first-order directional microphones, the “cosine” and “cardioid” microphones, is 4.8 dB. In the first case the microphone employs no internal acoustic time delay between the signals at the two inlets, providing a symmetrical FIG. 8 pattern. The cardioid employs a time delay exactly equal to the time it takes on-axis sound to travel between the two inlets. Compared to the cosine microphone, the cardioid has twice the sensitivity for sound from the front and zero sensitivity for sound from the rear. A further increase in directivity performance can be obtained by reducing the internal time delay. The hypercardioid, with minimum sensitivity for sound at 110 degrees from the front, has a DI of 6 dB. The presence of head diffraction complicates the problem of directional microphone design. For example, the directivity index for an omni BTE or ITE microphone is −1.0 to −2.0 dB at 500 and 1000 Hz.

Recognizing the problem of providing good directional microphone performance in a headworn ITE hearing aid application, applicant's set about to discover improved means and methods of such application. It is readily understood that the same solutions which make an ITE application practical can be easily applied to BTE applications as well.

BRIEF SUMMARY OF THE INVENTION

It is an object of the present invention to provide improved speech intelligibility in noise to the wearer of a small in-the-ear hearing aid.

It is a further object of the present invention to provide the necessary mechanical and electrical components to permit practical and economical directional microphone constructions to be used in head-worn hearing aids.

It is a still further object of the present invention to provide a mechanical arrangement which permits a smaller capsule than heretofore possible.

It is a still further object of the present invention to provide a switchable noise reduction feature for a hearing aid whereby the user may switch to an omnidirectional microphone mode for listening in quiet or to music concerts, and then switch to a directional microphone in noisy situations where understanding of conversational speech or other signals would otherwise be difficult or impossible.

It is a still further object of the present invention to provide a self-contained microphone capsule containing the microphone cartridges, acoustic couplings, and electrical equalization necessary to provide essentially the same frequency response for both omnidirectional and directional operation.

It is another object of the invention to provide a replaceable protective screen.

It is yet another object of the invention to provide a means of color match to the hearing aid faceplate.

These and other objects of the invention are obtained in a microphone capsule that employs both an omnidirectional microphone element and a directional microphone element. The capsule contains novel construction features to stabilize performance and minimize cost, as well as novel acoustic features to improve performance.

Known time-delay resistors normally used in first-order directional microphones will, when selected to provide the extremely small time delay associated with ITE hearing aid applications, give insufficient damping of the resonant peak in the microphone. This problem is solved in accordance with one embodiment of the present invention by adding a second novel acoustic damping resistor to the front inlet of the microphone, and adjusting the combination of resistors to produce the proper difference in time delays between the front acoustic delay and the rear acoustic delay, thereby making it possible to provide the desired directional characteristics as well as a smooth frequency response.

In another embodiment of the present invention, a set of gain-setting resistors is included in the equalization circuit so that the sensitivities of the directional and omnidirectional microphones can be inexpensively matched and so the user will experience no loss of sensitivity for the desired frontal signal when switching from omnidirectional to directional microphones.

In still another embodiment of the present invention, a molded manifold is used to align the parts and conduct sound through precise sound channels to each microphone inlet. This manifold repeatably provides the acoustic inertance and volume compliance required to obtain good directivity, especially at high frequencies.

In yet another embodiment of the present invention, a protective screen means is provided which reduces wind noise and provides a protective barrier against debris, but does not appreciably affect the directivity of the module. In addition, the protective screen enables color matching of the microphone to the hearing aid.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

FIG. 1A is a side elevation view of one embodiment of a hearing aid mounted in an ear in accordance with the present invention.

FIG. 1B is a partial cross-sectional view taken along the section line B-B showing the capsule of the present invention.

FIGS. 2A, 2B, and 2C show the isolated capsule of the present invention from the top, side, and bottom views.

FIG. 3 shows a subassembly of one embodiment of the capsule of the present invention, showing a top plate with sound inlets and sound tubes coupling to the two microphone cartridges.

FIG. 4 shows a cutaway view of one embodiment of a complete capsule in accordance with the present invention, the capsule containing two microphone cartridges mounted in the top plate of FIG. 3 along with appropriate coupling tubes and acoustic resistances and an equalization circuit in order to form directional and omnidirectional microphones having similar frequency response after the directional microphone signal has passed through the equalization circuit.

FIG. 5 shows a schematic drawing of one embodiment of the equalization circuit of the present invention.

FIG. 6, plot 41, shows the prominent peak in the frequency response of the directional microphone of the present invention when a single acoustic resistance is placed in the rear inlet tube of the microphone to provide the time delay of approximately 4 microseconds required to obtain good directivity in accordance with the present invention when the capsule is mounted on a head worn ITE hearing aid.

FIG. 6, plot 42, shows the smooth frequency response obtained when an acoustic resistor is added to the front inlet tube of the microphone so that the total resistance is chosen in order to provide the desired response smoothness while the two resistances is chosen in order to provide the required time delay.

FIG. 7 shows the on-axis frequency response of the omnidirectional microphone and the directional microphone after equalization with the circuit of FIG. 5. Both curves were obtained with the capsule of the present invention mounted in an ITE hearing aid as shown in FIG. 1 placed in the ear of a KEMAR mannequin.

FIG. 8 shows polar plots of the directional microphone of the present invention at frequencies of 0.5, 1, 2, 4, 6 and 8 kHz, measured as in FIG. 7.

FIG. 9 shows still another embodiment of the top plate where molded sound passages and a manifold construction eliminate the need for three coupling tubes and their time consuming assembly operations.

FIG. 10 shows a schematic of a simple low frequency adjustment for the directional microphone response for those cases where some low frequency attenuation is desired in high level noise.

FIG. 11 shows yet another embodiment of a microphone assembly built in accordance with the present invention.

FIG. 12 is an exploded view of the microphone assembly of FIG. 11.

FIG. 13 is a different exploded view of the microphone assembly of FIG. 11.

FIG. 14 is a cross-sectional view of the microphone assembly of FIG. 11.

FIG. 15 is an enlarged view of a portion of FIG. 14 illustrating the location of acoustic dampers and the sealing of the microphone sound openings in accordance with the present invention.

FIG. 16 illustrates the frequency response of the directional microphone assembly of FIG. 11 according to the present invention, along with the frequency response of that assembly if only a single acoustic damper were used.

FIG. 17 shows the polar characteristics of the directional microphone assembly of FIG. 11 having only a single acoustic damper.

FIG. 18 shows the polar characteristics of the directional microphone assembly of FIG. 11 having both acoustic dampers according to the present invention.

FIG. 19 illustrates another embodiment of a microphone assembly built in accordance with the present invention.

FIG. 20 illustrates another view of the microphone assembly of FIG. 19.

FIG. 21 illustrates an optional protective screen mounted on the microphone assembly of FIGS. 19 and 20.

FIG. 22 is a partial assembly view of the microphone assembly of FIGS. 19 and 20.

FIG. 23 is another partial assembly view of the microphone assembly of FIGS. 19 and 20.

FIG. 24 illustrates additional detail regarding the directional microphone cartridge of the microphone assembly of FIGS. 19 and 20.

FIG. 25 shows another view of the directional microphone cartridge of the microphone assembly of FIGS. 19 and 20.

FIG. 26 illustrates additional detail regarding the omnidirectional microphone cartridge of the microphone assembly of FIGS. 19 and 20.

FIG. 27 illustrates additional detail regarding the hybrid circuit of the microphone assembly of FIGS. 19 and 20.

FIG. 28 illustrates additional detail regarding one housing portion of the microphone assembly of FIGS. 19 and 20.

FIG. 29 is a cross-sectional view of the microphone assembly of FIGS. 19 and 20.

FIGS. 30A and 30B are end and cross-sectional views, respectively, of the restrictor shown in FIG. 29.

FIGS. 31A and 31B are end and cross-sectional views, respectively, of the o-rings shown in FIG. 29.

FIG. 32 is a block diagram of the omnidirectional cartridge of the microphone assembly of FIGS. 19 and 20.

FIG. 33 illustrates different response curves of the omnidirectional cartridge.

FIGS. 34A and 34B represent polar characteristics of the microphone assembly of FIGS. 19 and 20.

FIGS. 35A and 35B illustrate cross-sectional and end-views, respectively, of an exemplary in-the-ear hearing aid faceplate according to the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Certain elements of the functions of the present invention, in particular the use of a switch to choose directional or omnidirectional operation with the same frequency response, were described in Killion U.S. Pat. No. 3,835,263, dated 1974. The combination of directional and omnidirectional microphones in a hearing aid with an equalization circuit and a switch to provide switching between omnidirectional and directional responses with the same frequency response was described in Killion et al. U.S. Pat. No. 5,524,056, 1996. The disclosures of these two patents are incorporated herein by reference.

A hearing aid apparatus 100 constructed in accordance with one embodiment of the invention is shown generally at 10 of FIG. 1. As illustrated, the hearing aid apparatus 10 utilizes a microphone capsule 40, a switch 55 to select the directional microphone or omnidirectional microphone outputs of capsule 40, and a protective screen 90 to reduce the troublesome effects of wind noise, protect against debris contamination, and provide a visual color match with the hearing aid face plate.

FIG. 2 shows more of the construction of capsule 40, consisting of a top plate 80 (defining an exterior portion of said capsule as worn), a cylinder or housing 50 and an equalization circuit 60.

FIG. 3 shows a subassembly 45 of one embodiment of the capsule 40 of the present invention, showing a top plate 80 with sound tubes 85 and 86 coupling sound inlets 83, 84, to the front chamber 22 and the rear chamber 24 of microphone cartridge 20. Adhesive 27 seals tubes 85 and 86 to microphone cartridge 20. Microphone cartridge 20 is mounted with the plane of the diaphragm 21 generally normal to the top plate 80. This configuration eliminates the need for the prior art metal inlet tube or tubes of the microphone and provides a smaller distance D (measured as shown in FIG. 17 of the '056 patent) than would be possible using prior art constructions. As a result, the diameter of capsule 40 may be maintained at 0.25 inches or less.

Also shown is sound inlet 88, to which omnidirectional microphone cartridge 30 (not shown) is to be connected. Shoulder 89 in inlets 83, 84, and 88 provides a mechanical stop for the tubings 85 and 86 and microphone cartridge 30 (not shown). Tubings 85 and 86 are attached or sealed to top plate 80 and to microphone cartridge 20. Acoustical resistors 81 and 82 provide response smoothing and the time delay required for proper directional operation. Resistors 81 and 82 may for example be like those described by Carlson and Mostardo in U.S. Pat. No. 3,930,560 dated 1976.

FIG. 4 shows a cutaway view of one embodiment of a complete capsule 40 in accordance with the present invention, the capsule containing microphone cartridge 20 mounted as shown in FIG. 3 in order to form a directional microphone, and omnidirectional microphone cartridge 30 mounted into inlet 88 of top plate 80. Each of the microphones 20, 30 is used to convert sound waves into electrical output signals corresponding to the sound waves. Cylinder 50 may be molded in place with compound 51 which may be epoxy, UV cured acrylic, or the like.

Conventional directional microphone construction would utilize only acoustic resistance 81, chosen so that the R-C time constant of resistance 81 and the compliance formed by the sum of the volumes in tube 85 and the rear volume 24 of cartridge 20 would provide the correct time delay. For example, in the present case, the inlets 83 and 84 are mounted approximately 4 mm apart, so the free-space time delay for on-axis sound would be about 12 microseconds. In order to form a cardioid microphone, therefore, an internal time delay of 12 microseconds would be required. In this case, sound from the rear would experience the same time delays reaching rear chamber 24 and front chamber 22 of the microphone, so that the net pressure across diaphragm 21 would be zero and a null in response would occur for 180 degrees sound incidence as is well known to those skilled in the art.

In the case of a head-mounted ITE hearing aid application, however, head diffraction reduces the effective acoustic spacing between the two inlets to approximately 0.7×, or about 8.4 microseconds. If an approximately hypercardioid directional characteristic is desired, the appropriate internal time delay is less than half the external delay, so that the internal time delay required in the present invention would be approximately 4 microseconds. We have found that an acoustic resistance of only 680 Ohms will provide the required time delay. This value is about one-third of the resistance used in conventional hearing aid directional microphone capsules, and leads to special problems as described below.

As shown in FIG. 4, microphone cartridges 20 and 30 are wired to equalization circuit 60 with wires 26 and 28 respectively. Circuit 60 provides equalization for the directional microphone response and convenient solder pads to allow the hearing aid manufacturer to connect to both the omnidirectional and equalized directional microphone electrical outputs. An additional output is also provided for the directional microphone without equalization.

FIG. 5 shows a schematic drawing of one embodiment of equalization circuit 60. Input resistor 61 can be selected from among several available values 61A through 61E at the time of manufacture, allowing the sensitivity of the equalized directional microphone to be made equal to that of the omnidirectional microphone. Transistors 76 and 77 form a high gain inverting amplifier 160, so that the feedback path consisting of resistor 64 and resistor 62 and capacitor 73 can be chosen to provide compensation for the lower gain and the low frequency rolloff of the directional microphone.

Suitable values for the components in equalization circuit 60 are:

61A 56K Ω
61B 47K Ω
61C 39K Ω
61D 33K Ω
61E 27K Ω
62  18K Ω
63  1M Ω
64  47K Ω
65  22K Ω
66  22K Ω
67  1M Ω
68  1M Ω
71  0.047 uF
72  0.1 uF
73  1000 pF
74  0.047 uF
76  2N3904
77  2N3906

Circuit 60 has power supply solder pads VBAT, ground pad GND, omnidirectional microphone signal output pad OMNI, directional microphone signal output pad DIR, and equalized directional microphone output pad DIR-EQ.

FIG. 6 shows an undesirable peak in the directional microphone frequency response curve 41 at approximately 4 kHz. This results when a single resistance such as 680Ω is chosen for resistor 81 in the rear inlet tube 85 of the microphone 20, and a single resistance such as 0Ω is chosen for resistor 82 in the front inlet tube 86 of FIG. 3. This value provides a time delay of approximately 4 microseconds as required to obtain good directivity in accordance with the present invention when the capsule 40 is mounted on the head in an ITE hearing aid, but produces an undesirable peak. Curve 42 of FIG. 6 shows the frequency response obtained when a total resistance of 2500 Ohms is chosen instead for the combination of resistors 81 and 82 to provide the desired response smoothness. The values of resistors 81 and 82 is then chosen to provide the required time delay of approximately 4 microseconds. We have found that a value of 1500Ω for resistor 82 and 1000 Ω for resistor 81 provides a desired combination of response smoothness and time delay when a Knowles Electronics TM-series microphone cartridge is used for microphone 20, as shown in curve 42 of FIG. 6 and the polar plots of FIG. 8. We have also found that a value of 1250Ω for resistor 82 and 1250 Ω for resistor 81 provides a similar desired combination of response smoothness and time delay.

FIG. 7 shows the on-axis frequency response 43 of the omnidirectional microphone 30 and on-axis frequency response 44 of the directional microphone 20 after equalization with the circuit of FIG. 5. Both curves were obtained in an anechoic chamber with the capsule 40 of the present invention mounted in an ITE hearing aid placed in the ear of a KEMAR Mannequin.

FIG. 8 shows polar plots of the directional microphone of the present invention obtained on a KEMAR Mannequin (Right Ear). Table 1 below gives the measurement frequency and the corresponding polar response curve number, Directivity Index, and Articulation Index weighing number.

TABLE 1
Directivity
	Frequency	Curve #	Index	AI weighing
	0.5	kHz	31	3.5 dB	0.20
	1	kHz	32	3.1 dB	0.23
	2	kHz	33	6.3 dB	0.33
	4	kHz	34	6.0 dB	0.24
	6	kHz	35	3.7 dB	0.0
	8	kHz	36	2.4 dB	0.0

The Directivity Index values give an Articulation-Index-weighted average Directivity Index of 4.7 dB. To the Applicant's knowledge, this is the highest figure of merit yet achieved in a headworn hearing aid microphone.

FIG. 9 shows still another embodiment of the capsule of the present invention. Capsule 140 includes top plate 180 which contains molded sound passages 185 and 186 in a manifold type construction, eliminating the need for coupling tubes 85 and 86 of FIG. 4 and their time consuming assembly operations. Gasket 170 may be cut from a thin foam with adhesive on both sides to provide ready seal for microphone cartridges 20 and 30 as well as top plate 180. Cylinder 150 may be molded in place around the microphone cartridges, leaving opening 187 to cooperate with passage 185 of top plate 180. Circuit 60 provides equalization and solder pads as described above with respect to FIG. 4.

By mounting microphone cartridges 20 and 30 adjacent to each other in Capsule 140, a single inlet 184 provides sound access to both microphone cartridges 20 and 30, so that resistor 182 provides damping for both cartridges. In this application, the presence of the second cartridge approximately doubles the acoustic load, so to a first approximation only one half the value for acoustic resistor 182 is required. As before, the values of resistors 182 and 181 are chosen to provide both response smoothness and the correct time delay for proper directional operation.

Alternately, plate 180 can be molded with three inlets as is done with plate 80 of FIG. 3. In this case, the front sound passage 186 and rear sound passage 185 plus 187 can be chosen to duplicate the acoustic properties of tubes 85 and 86 of FIG. 3, so that similar acoustic resistors may be used to provide the desired response and polar plots.

FIG. 10 shows a schematic of a simple low frequency adjustment circuit 200, where a trimpot adjustment of the directional microphone low frequency response can be obtained by adding a variable trimpot resistor 202 and fixed resistor 201 connected in series between the DIR-EQ pad capacitor 205 and ground 225. The output 210 of circuit 200 is connected to switch 55, as is the output 230 of the omnidirectional microphone. By adjusting resistor 202, the low frequency roll-off introduced by circuit 200 can be varied between approximately 200 and 2000 Hz dependent upon the input impedance of the hearing aid amplifier. Switch 55 permits the user to select omnidirectional or directional operation. Although the same frequency response in both cases is often desirable, rolling off the lows when switching to directional mode can provide a more dramatic comparison between switch positions with little or no loss in intelligibility in most cases, according to dozens of research studies over the last decade. In some cases, some low frequency attenuation for the directional microphone response will be desired in high level noise as well as with windy conditions. The degree of such attenuation can be selected by the dispenser by adjusting trimpot 202.

FIG. 11 illustrates yet another embodiment of a microphone assembly built in accordance with the present invention. Microphone assembly 301 is comprised of assembly portions or halves 303 and 305. As explained more completely below with respect to FIGS. 12 and 13, the portions 303 and 305 fit or snap together during assembly to form the microphone assembly 301. Each of the assembly portions 303 and 305 include a retaining member 307 and a releasable retaining member 309 for releasable mounting of a printed circuit board 311 in the microphone assembly 301. As can be seen, portions of the printed circuit board 311 are received under the retaining members 307 and releasable retaining members 309. The microphone assembly 301 further includes a protective screen assembly 313. It should be noted that this assembly provides an additional benefit of allowing the color of the hearing aid to be matched to that of the microphone.

FIGS. 12 and 13 illustrate different exploded views of the microphone assembly 301 of FIG. 11. FIGS. 12 and 13 show assembly portions 303 and 305, retaining members 307, releasable retaining members 309, printed circuit board 311 and protective screen assembly 313, all disassembled. FIGS. 12 and 13 also illustrate directional microphone cartridge 315 and omnidirectional microphone cartridge 317. Directional microphone cartridge 315 has sound openings 319 and 320 for receiving sound energy therethrough. Omnidirectional microphone cartridge 323 likewise has a sound inlet 329 for receiving sound energy therethrough. Directional microphone cartridge 315 also has a surface 321, and omnidirectional microphone cartridge 317 has a similar surface 323, both for mounting the printed circuit board 311 on the directional microphone cartridge 315 and the omnidirectional microphone cartridge 317. The directional microphone cartridge 315 and omnidirectional microphone cartridge 317 are in turn mounted on the assembly portions 303 and 305.

More specifically, assembly portion 303 has a surface 325, and assembly portion 305 has a similar surface (not shown) that together mount thereon the directional microphone cartridge 315. Assembly portion 303 also has a surface 327, and assembly portion 305 has a similar surface (not shown), that together mount thereon the omnidirectional microphone capsule 317. Inlet port 329 of the omnidirectional microphone capsule 317 fits into a recess 331 of assembly portion 303 and a recess 332 of assembly portion 305.

Note the interference between pins 335 and holes 333 is such that the parts may be assembled in a press fit manner with adequate retention. Furthermore, they allow portions 303 and 305 to be separated for purposes of repair or salvage. Assembly portion 303 also has a pocket 337 that receives therein acoustical damper or resistor 339 and o-ring 341. Assembly portion 305 likewise has a pocket 338 that receives therein acoustical damper or resistor 340 and o-ring 342. O-rings 341 and 342 are preferably made of a resilient material, such as, for example, silicone rubber.

Further, each of assembly portions 303 and 305 includes a recess 312 that receives a corresponding mating element 314 of the protective screen assembly 313, thereby enabling snap assembly of the protective screen assembly 313 onto the assembly portions 303 and 305 when those portions are in an assembled relationship. The protective screen assembly 313 further includes acoustical openings 343 and 345 that permit acoustical coupling of sound energy to sound openings 319 and 320 of the directional microphone cartridge 315 via sound inlet passages 342 and 344 in the assembly portions 303 and 305, respectively. Sound inlet passage 342 has an input end located near acoustical opening 343 and an output end located near sound opening 320. Similarly, sound inlet passage 344 has an input end located near acoustical opening 345 and an output end located near sound opening 319. The protective screen assembly 313 also has an acoustical opening 347 that permits acoustical coupling of sound energy to the omnidirectional microphone cartridge 317 via sound inlet port 329. Each of the acoustical openings 343, 345 and 347 receive screen elements 349 that reduce wind noise and help prevent ear wax or other debris from entering the sound inlet passages 342 and 344 and the inlet port 329.

As mentioned above, the printed circuit board 311 is mounted directly on surfaces 321 and 323 of the directional microphone capsule 315 and omnidirectional microphone capsule 317, respectively. Such a configuration enables the printed circuit board to be soldered directly to the microphone capsules 315 and 317, eliminating the need for any separate wiring. In addition, also as mentioned above, portions of the printed circuit board 311 are received under retaining members 307 and releasable retaining members 309. Thus, if the microphone assembly 301 is damaged during, for example, manufacture, the printed circuit board 311 and microphone capsules 315 and 317, the more costly components, may be removed as a unit and thus salvaged.

FIG. 14 is a cross-sectional view of the microphone assembly of FIG. 11. As can be seen, assembly portions 303 and 305 are in an assembled relationship, with directional microphone cartridge 315 mounted thereon. Also as can be seen, acoustic damper 340 and o-ring 342 are mounted on a surface inside pocket 338, and acoustic damper 339 and o-ring 341 are likewise mounted on a surface inside pocket 337. O-rings 341 and 342 engage surfaces of the microphone cartridge to provide a seal around sound openings 320 and 319, respectively. Adhesive material may be used to cement the acoustic dampers and o-rings in the pockets, as well as to cement the o-rings against the surfaces of the microphone cartridge 315. Further, the printed circuit board 311 is mounted on the microphone cartridges 315 and 317 and is retained by retaining members 307 and 309 as discussed above.

During operation, sound energy enters the acoustical opening 345 in protective screen assembly 313, travels through sound inlet passage 344, the acoustic damper 340 and o-ring 342 and enters sound opening 319 of directional microphone 315 for acoustical coupling with a microphone diaphragm (not shown) as discussed above. Likewise, sound energy also enters the acoustical opening 343 in protective screen assembly 313, travels through sound inlet passage 342, the acoustic damper 339 and o-ring 341 and enters sound opening 320 for acoustical coupling with the microphone diaphragm.

FIG. 15 is an enlarged view of the section 351 of FIG. 14 showing sound inlet passage 344, acoustical damper 340, o-ring 342, pocket 338, and sound opening 319. FIG. 15 better illustrates the mounting of acoustical damper 340 and o-ring 342 on a surface 353 in pocket 338; as well as the mounting of the o-ring 342 against a surface 355 of the microphone cartridge 315 to seal sound opening 319.

As discussed above, two acoustic dampers or resistors are used in the present invention to collectively determine a polar response of the directional microphone and smooth out the frequency response. In other words, these two acoustic dampers primarily perform separate functions. More particularly, the first or “front” acoustic damper generally has a small volume between it and the moving microphone diaphragm and is used primarily, but not exclusively, for damping (i.e., frequency response smoothing). The second or “rear” acoustic damper generally has a relatively larger volume between it and the moving microphone diaphragm and is used primarily, but not exclusively, to produce a time delay (as in the prior art). Such an arrangement allows a relatively high front resistance value for frequency response smoothing without canceling the time delay created by the rear resistor.

In the embodiment of FIG. 4, these two acoustic resistors 81 and 82 are located near outer openings of sound inlets 83 and 84. In the embodiment of FIGS. 11-15, however, the acoustic dampers 339 and 340 are located at opposite ends of sound inlet passages 342 and 344, respectively, near the sound openings 320 and 319 of microphone cartridge 315. Placement of the acoustical dampers 339 and 340 as such provides greater protection from contamination that would tend to increase their acoustical value and thus degrade the performance of the directional microphone. Also, placement of the dampers as such helps prevent damage that may occur thereto by improper installation of the protective screen assembly 313, such as, for example, if the mating elements 314 of the protective screen assembly 313 were mistakenly placed in the sound inlet passages 342 and 344.

In addition, placement of the dampers as such enables the o-ring sealing arrangement discussed above. By sealing the acoustical dampers and o-rings together and against surfaces in the pockets 338 and 337, and by sealing the o-rings 342 and 341 against the microphone cartridge 315 to surround the sound openings 319 and 320, the embodiment of FIGS. 11-15 reduces the amount of sound pick up entering the sound openings 319 and 320 via paths other than the desired sound inlet passages 344 and 342.

FIG. 16 illustrates the frequency response of the directional microphone assembly of FIGS. 11-15, along with the frequency response of that assembly if only a single acoustic damper were used as suggested by the prior art. Curve 401 of FIG. 16 represents the frequency response of the directional microphone assembly of FIGS. 11-15 having only a single 1500Ω acoustic damper as taught by the prior art (i.e., no front or frequency response shaping resistor is used). Curve 403 of FIG. 16 represents the frequency response of the directional microphone assembly of FIGS. 11-15 having two resistors, here each having a value of 1500Ω, as taught by the present invention. As can be seen, at a frequency of about 4 kHz, the frequency response is smoothed by the addition of the second resistor.

FIG. 17 represents the polar characteristics of the microphone assembly of FIGS. 11-15 under free field conditions where only a single 1500Ω acoustic damper is used (i.e., no front or frequency response shaping resistor is used). Curves 405, 407, and 409 represent the characteristics at 500, 1000, and 2000 Hz, respectively, and have a directivity index of 5.5, 5.4, and 5.2 dB, respectively.

FIG. 18, on the other hand, represents that polar characteristics of the microphone assembly of FIGS. 11-15 where two acoustic dampers are used, each having a value of 1500Ω. Curves 411, 413, and 415 represent the characteristics at 500, 1000, and 2000 Hz, respectively, and have a directivity index of 6.0, 5.7, and 5.5 dB, respectively.

FIG. 19 illustrates still another embodiment of a microphone assembly built in accordance with the present invention. Microphone assembly 501 is comprised of assembly portions or halves 503 and 505. The assembly portions 503 and 505 may fit or snap together similarly as discussed above with respect to the embodiment of FIGS. 11-15, or may interlock and be held together by an adhesive such as epoxy, for example. A hole or opening 507 may be included for receiving adhesive.

The assembly 501 further comprises a directional microphone cartridge 509, an omnidirectional microphone cartridge 511 and a hybrid circuit 513. The hybrid circuit 513 may perform equalization, similarly as discussed above with respect to FIG. 5. The hybrid circuit 513 rests on a surface 514 of housing portion 505, and includes contacts 515, 517 and 519 for electrical connection to the directional microphone cartridge 509. Specifically, contacts 515 and 519 provide ground and V⁺ connections, respectively, to the directional microphone cartridge 509, and contact 517 provides an input connection to the hybrid circuit 513 from the directional microphone cartridge 509.

Hybrid circuit 513 also includes contacts 521, 523 and 525 for electrical connection to a hearing aid (i.e., hearing aid amplifier, for example), such as the hearing aid 100 of FIG. 1, for example. Specifically, contacts 521 and 525 provide ground and V⁺ connections, respectively, to a hearing aid, and contact 523 provides an output (i.e., equalized, for example) from the directional microphone cartridge 509 to such hearing aid.

FIG. 19 also illustrates exemplary dimensions of the microphone assembly 501. For example, a mating surface exposed to the sound field (see FIG. 20) may have, for example, a dimension of approximately 0.25 inches (6.35 mm) or less. The housing portions 503 and 505 may have, for example, a height dimension of approximately 0.124 inches (3.15 mm) or less. The assembly 501, from the mating surface exposed to the sound field (see, FIG. 20) to a surface 527 on directional microphone cartridge 509, may have, for example, an overall height dimension of approximately 0.142 inches (3.60 mm) or less. Other exemplary dimensions are also shown in FIG. 19.

FIG. 20 illustrates another view of the microphone assembly 501 of FIG. 19. Microphone assembly 501 includes a mating surface 531 that is exposed to the sound field. Mating surface 531 has openings or inlet ports therein for sound input to sound inlet passages 533 and 535. The sound inlet passages 533 and 535 are located in housing portions 503 and 505, respectively, and acoustically couple sound from the sound field to the directional microphone cartridge 509. Additionally, omnidirectional microphone cartridge 511 has a sound inlet port 536 that acoustically couples sound from the sound field to the interior of the omnidirectional microphone cartridge 511.

As can be seen from FIG. 20, both the directional microphone cartridge 509 and the omnidirectional microphone cartridge 511 have flat or substantially flat surfaces similar to mating surface 531. Mating surface 531 may also include an arrow, such as arrow 537 in FIG. 20, to indicate a forward direction. The arrow 531 may be located, for example, near the front inlet port (i.e., the sound inlet passage 533), as shown in FIG. 20.

FIG. 20 also shows attachment pockets 539 and 541 located in housing portions 503 and 505, respectively, that receive a locking member of an optional protective screen (not shown in FIG. 20) for mounting of the protective screen on the mounting surface 531. More particularly, FIG. 21 illustrates the microphone assembly 501 of FIGS. 19 and 20 having a protective screen 543 mounted on the mounting surface 531. Protective screen 543 includes a locking member 545 that releasably engages the pocket 539 located in housing portion 503. Protective screen 543 also includes another locking member (not shown) that releasably engages the pocket 541 (not shown in FIG. 21) located in housing portion 505. The locking member may be retained in the pockets using a press fit arrangement, and may be released by engaging pry slot 547. In this manner, the protective screen 543 is removable from the mounting surface 531.

Protective screen 543 further includes acoustical openings 549 and 551 that permit acoustical coupling of sound from the sound field to the directional microphone cartridge 509 (via sound inlet passages 533 and 535, respectively, shown in FIG. 20). In addition, protective screen 543 includes an acoustical opening 553 that permits acoustical coupling of sound from the sound field to the omnidirectional microphone cartridge 511 (via inlet port 536 shown in FIG. 20).

As is apparent from FIGS. 19-21, the microphone assembly 501 is configured such that its overall height may be approximately 0.2 inches or less. In fact, the microphone assembly 501 may have, if desired, an overall height that is no greater than the height of either of the directional and omnidirectional microphone cartridges, thereby providing a very compact design.

FIG. 22 is a partial assembly view of the microphone assembly 501 of FIGS. 19 and 20. As can be seen, housing portion 505 has been removed, and directional microphone cartridge 509 and omnidirectional microphone cartridge 511 are shown in assembled positions in housing portion 503. Also as can be seen, hybrid circuit 513 (not shown) has been removed from its mounted position on surface 514 of housing portion 505.

FIG. 23 is another partial assembly view of the microphone assembly 501 of FIGS. 19 and 20. FIG. 23 shows the omnidirectional microphone cartridge 511 removed from its assembled position in housing portion 503.

FIG. 24 illustrates additional detail regarding the directional microphone cartridge 509 of the microphone assembly 501 of FIGS. 19 and 20. Directional microphone cartridge 509 includes a front sound inlet opening or port 551 that, upon assembly of the microphone assembly 501, becomes acoustically coupled to sound inlet passage 533 located in housing portion 503 (see FIG. 20). During use, sound entering the sound inlet passage 533 is coupled, via port 551, to a front side of a diaphragm (not shown) located inside the directional microphone cartridge 509. Port 551 may have a diameter dimension of approximately 0.022 inches, for example, as shown in FIG. 24. Of course, other dimensions for port 551 are possible.

FIG. 25 is another view of the directional microphone cartridge 509 illustrated in FIG. 24. As can be seen from FIG. 25, directional microphone cartridge 509 also includes a rear sound inlet opening or port 553. Upon assembly of the microphone assembly 501, port 553 becomes acoustically coupled to the sound inlet passage 535 located in housing portion 505 (see FIG. 20). During use, sound entering the sound inlet passage 535 is likewise coupled, via port 553, to a rear side of the diaphragm (not shown) located inside the directional microphone cartridge 509. Port 553 may have a diameter dimension of approximately 0.040 inches, for example, as shown in FIG. 25. Other dimensions for port 553 are likewise possible.

As can be seen from FIGS. 24 and 25, the directional microphone cartridge 509 may have a rear sound inlet port that is larger than the front sound inlet port. A larger rear inlet port may be used when it is desirable to reduce the acoustical inertance of such rear inlet port. As can be seen more completely below from FIG. 29, the ports may also be offset from each other.

FIG. 26 illustrates additional detail regarding the omnidirectional microphone cartridge 511 of microphone assembly 501 of FIGS. 19 and 20. Omnidirectional microphone cartridge 511 includes a protrusion 555 located thereon to accommodate an internal capacitor (discussed more completely below). As mentioned above, omnidirectional microphone cartridge 511 has a sound inlet port 536 and a flat or substantially flat surface (designated by reference numeral 557 and FIG. 26). Such a configuration is an improvement over prior designs, which include a tube protruding from the outer surface of the omnidirectional cartridge, since it takes up less valuable space, for example.

Omnidirectional cartridge 511 further includes contacts 558, 559 and 561 for electrical connection to a hearing aid (i.e., hearing aid amplifier, for example), such as the hearing aid 100 of FIG. 1, for example.

FIG. 27 illustrates additional detail regarding the hybrid circuit 513 of microphone assembly 501 of FIGS. 19 and 20. FIG. 27 specifically shows exemplary dimensions of the hybrid circuit 513. Of course, other dimensions for the hybrid circuit 513 are also possible.

FIG. 28 illustrates additional detail regarding the housing portion 503 of microphone assembly 501 of FIGS. 19 and 20. Housing portion 503 has a pocket that receives therein an acoustical damper or resistor 563 and an o-ring 565. As discussed more completely below, the o-ring 565 may have a rectangular cross-section, to form a better acoustic seal between the sound inlet passage 533 and the port 553 of directional microphone cartridge 509. The o-ring 565 may be made of a resilient material, such as, for example, silicone rubber.

Housing portion 505 (not shown) may be similarly configured, having a damper or resistor and o-ring located in its own receiving pocket. Both the housing portions 503 and 505 may be made of a moldable plastic material, such as, for example, polyethylene terephthalate.

FIG. 29 is a cross-sectional view of the microphone assembly 501 of FIGS. 19 and 20. FIG. 29 also shows the optional protective screen 543 of FIG. 21 mounted on the mating surface 531 of microphone assembly 501. FIG. 29 specifically illustrates housing portions 503 and 505, directional microphone cartridge 509, sound inlet passages 533 and 535, hybrid circuit 513, acoustical damper or resistor 563 and o-ring 565 discussed above. In addition FIG. 29 shows a damper or resistor 567 and an o-ring 569 seated in a pocket in housing portion 505, as mentioned above. In the case of both housing portions 503 and 505, an adhesive material or cement may be added to insure an acoustic seal between the resistor and o-ring. For example, arrow 571 shows one area in housing portion 505 where cement, for example, may be added to resistor 567 and o-ring 569. Cement may also be added to a similar area on the opposite sides of resistor 567 and o-ring 569, and also to similar areas in housing portion 503 (with respect to resistor 563 and o-ring 565).

FIG. 29 also illustrates a restrictor 573 inserted into (front) sound inlet passage 533. The restrictor 573 may be friction fitted into an input end 574 the inlet passage 533, so that, for example, it is flush with the mating surface 531. The restrictor 573 may be made of PVC tubing, for example, and may be used when it is desired to increase the acoustical inertance of the front inlet passage 533.

As mentioned above, the front and rear sound inlet ports of the directional microphone cartridge 509 may be offset from each other. Such a configuration is shown in FIG. 29. As can be seen, an output end 577 of sound inlet passage 533 is located at a point lower on the directional microphone cartridge 509 than an output end 579 of sound inlet passage 535, relative to a surface 575 of directional microphone cartridge 509, to the mating surface 531, and to the sound field. In this configuration, the corresponding front inlet portion 551 (FIG. 24) of directional microphone cartridge 509 is likewise located at a point lower than rear inlet port 553 (FIG. 25). In other words, a center point of front port 551 is lower on the front side of the directional microphone cartridge 509 than a center point of rear inlet port 553 on the rear side of the directional microphone cartridge 509, relative to the surface 575 of directional microphone cartridge 509, to the mating surface 531 and to the sound field (see dashed lines in FIG. 29). Of course, other locations of the front and rear ports are possible, and are within the scope of the present invention.

FIGS. 30A and 30B are end and cross-sectional views, respectively, of the restrictor 573 of FIG. 29. FIGS. 30A and 30B illustrate exemplary dimensions for the restrictor 573. Of course, other dimensions and types of restrictors are possible and within the scope of the present invention.

FIGS. 31A and 31B are end and cross-sectional views, respectively, of the o-rings 565 and 569 shown in FIG. 29. FIGS. 31A and 31B illustrate exemplary dimensions for the o-rings 565 and 569. In addition, as mentioned above and as can be seen in FIG. 31B, the o-rings may have a rectangular cross-section, to form a better seal between the sound inlet passages and the inlet ports of the directional microphone cartridge. Other dimensions and types of o-rings are possible, however, and are within the scope of the present invention.

FIG. 32 is a block diagram of the omnidirectional cartridge 511 of microphone assembly 501 of FIGS. 19 and 20. As mentioned above with respect to FIG. 26, omnidirectional microphone cartridge 511 includes a protrusion 555 located thereon to accommodate an internal capacitor. Such a capacitor is shown in FIG. 32, and is designated by the reference numeral 581. As shown, capacitor 581 is connected across the output of the omnidirectional microphone cartridge 511. The capacitor 581 may have a value of 0.01 microfarads, for example. Adding a capacitor as such provides an omnidirectional microphone cartridge having an improved self-noise performance over prior designs.

Specifically, FIG. 33 illustrates different response curves of the omnidirectional microphone cartridge 511. Curve 583 shows the response of the omnidirectional microphone cartridge without acoustic damping. As can be seen, there is a peak at higher frequencies. Curve 585 shows the response of the omnidirectional microphone cartridge having an acoustic damping of 425Ω, for example. Such damping flattens the peak, but also creates a roll-off at higher frequencies. Curve 587 shows the response of the omnidirectional microphone cartridge without acoustic damping, but with the addition of a 0.01 microfarad capacitor, as shown in FIG. 32. The self-noise improvement over the undamped and damping conditions may be shown by the following table, for example.

Microphone Condition	Noise (dBA-weighted)	Improvement in dB
Damped (Curve 585)	28.1	0
Undamped (Curve 583)	27.9	+0.2
Undamped w/Capacitor	25.9	+2.2
(Curve 587)

FIGS. 34A and 34B represent the polar characteristics of microphone assembly 501 of the present invention under free field conditions and using a value of 700Ω for each of the acoustic resistors or dampers. At 500, 1000, and 2000 Hz, the directivity index achieved is 6.0, 5.9, and 5.9, respectively. These directivity values are an improvement over those achieved by previous designs at the same frequencies (see FIG. 18 and accompanying description). In addition, microphone assembly 501 maintains a greater directivity at higher frequencies compared to previous designs, in which the directivity tapered off above 2000 Hz, for example.

FIGS. 35A and 35B illustrate cross-sectional and end-views, respectively, of an exemplary in-the-ear hearing aid faceplate according to the present invention. Faceplate 591 is generally shown in a pre-assembly condition, that is, prior to its modification (by cutting, for example) to fit a particular hearing aid shell.

The faceplate 591 includes a battery drawer or holder 592 (hinged door not shown) for mounting a battery. The faceplate 591 also includes a mating pocket 593 that accepts the microphone assembly 501. The mating pocket 593 orients the microphone assembly 501 in the proper position, and provides an acoustical seal therebetween to insure that sound does not enter the hearing aid housing other than through the ports of microphone assembly 501.

FIG. 35A illustrates a sound entry port 595 in the faceplate 591 that couples sound to the rear sound inlet passage (i.e., sound inlet passage 535 of FIG. 20) of the directional microphone cartridge 509. The faceplate 591 also has a similar port (not shown in the cross-sectional view of FIG. 35A) that likewise couples sound to the front sound inlet passage (i.e., sound inlet passage 533 of FIG. 20) of the directional microphone cartridge 509. In addition, FIG. 35 illustrates a sound entry port 597 that couples sound to the port 536 (FIG. 20) of the omnidirectional microphone cartridge 511.

When the microphone assembly 501 is inserted into the faceplate 591, the faceplate itself acts as a protective screen. In other words, a protective screen and/or its functionality is integrated as part of the faceplate itself, similarly as shown in FIG. 1 above, and a separate protective screen is not necessary.

The shape of the sound entry ports of the faceplate, as well as the contour of the outer surface of the faceplate and the dimensions shown in FIGS. 35A and 35B are exemplary only. Other shapes, contours and dimensions are possible and within the scope of the present invention.

Many modifications and variations of the present invention are possible in light of the above teachings. Thus, it is to be understood that, within the scope of the appended claims, the invention may be practiced otherwise than as described hereinabove.

Claims

1. A microphone assembly for an in-the-ear hearing aid comprising: at least one microphone cartridge having a first sound opening and a second sound opening;a first sound inlet passage acoustically coupling sound energy to the first sound opening;a restrictor associated with the first sound passage; anda second sound inlet passage acoustically coupling sound energy to the second sound opening, said assembly for use in an in-the-ear hearing aid and having a height dimension of 0.20 inches of less.

2. The microphone assembly of claim 1 wherein the height dimension is approximately 0.142 inches.

3. The microphone assembly of claim 1 wherein the height dimension is no greater than a height dimension of the microphone cartridge.

4. The microphone assembly of claim 1 wherein the first sound opening has a first diameter dimension and the second sound opening has a second diameter dimension, and wherein the first diameter dimension is smaller than the second diameter dimension.

5. The microphone assembly of claim 4 wherein the first diameter dimension approximately one-half the second diameter dimension.

6. The microphone assembly of claim 5 wherein the first diameter dimension is approximately 0.022 inches, and the second diameter dimension is approximately 0.040 inches.

7. The microphone assembly of claim 1 wherein the first and second sound inlet passages are offset from each other.

8. The microphone assembly of claim 1 wherein the restrictor increases the inertance of the first sound passage.

9. The microphone assembly of claim 1 further comprising a first acoustic damper associated with the first sound passage and a second acoustic damper associated with the second sound passage.

10. The microphone assembly of claim 1 wherein the at least one microphone cartridge comprises a directional microphone cartridge, and further comprising an omnidirectional microphone cartridge having a sound inlet port.

11. The microphone assembly of claim 10 wherein the sound inlet port is located in a substantially flat surface of the omnidirectional microphone cartridge.

12. The microphone assembly of claim 10 further comprising a capacitor connected across an output of the omidirectional microphone cartridge.

13. The microphone assembly of claim 12 wherein the capacitor has a value of approximately 0.01 microfarads.

14. A microphone assembly for an in-the-ear hearing aid comprising: at least one microphone cartridge having a first sound opening, a second sound opening, and a height dimension;a first sound inlet passage acoustically coupling sound energy to the first sound opening;a restrictor associated with the first sound passage; anda second sound inlet passage acoustically coupling sound energy to the second sound opening, said assembly having a height dimension no greater than the height dimension of the at least one microphone cartridge.

15. The microphone assembly of claim 14 wherein said assembly has a height dimension of approximately 0.142 inches.

16. The microphone assembly of claim 14 wherein the first sound opening has a first diameter dimension and the second sound opening has a second diameter dimension, and wherein the first diameter dimension is smaller than the second diameter dimension.

17. The microphone assembly of claim 16 wherein the first diameter dimension approximately one-half the second diameter dimension.

18. The microphone assembly of claim 17 wherein the first diameter dimension is approximately 0.022 inches, and the second diameter dimension is approximately 0.040 inches.

19. The microphone assembly of claim 14 wherein the first and second sound inlet passages are offset from each other.

20. The microphone assembly of claim 14 wherein the restrictor increases the inertance of the first sound passage.

21. The microphone assembly of claim 14 further comprising a first acoustic damper associated with the first sound passage and a second acoustic damper associated with the second sound passage.

22. The microphone assembly of claim 14, wherein the at least one microphone cartridge comprises a directional microphone cartridge, and further comprising an omnidirectional microphone cartridge having a sound inlet port.

23. The microphone assembly of claim 22 wherein the sound inlet port is located in a substantially flat surface of the omnidirectional microphone cartridge.

24. The microphone assembly of claim 22 further comprising a capacitor connected across an output of the omnidirectional microphone cartridge.

25. The microphone assembly of claim 24 wherein the capacitor has a value of approximately 0.01 microfarads.