A transducer embodying the present invention is assembled on a discrete electrically conductive frame (100) that has been formed to provide both leads (120-140) and a backplate (110). An integrated circuit chip (200) is bonded to one of the leads, and a dielectric inner housing member (300) is molded about the backplate and the portion of the leads adjacent to it. The inner housing member encapsulates the chip, embraces the perimeter of the backplate, and provides a cylindrical opening (310) that extends on each side of the backplate. A conductive outer housing member (400) is subsequently molded about the perimeter of the inner housing member, and a spacer (500), electret diaphragm assembly (600), and conductive gasket (700) are sequentially positioned in the opening on one side of the backplate. Conductive front and back covers (800,900) are thereafter bonded to the outer housing to close the opening and to complete a conductive enclosure that provides electrostatic shielding for the transducer. In addition, electrical continuity is provided between a metalized surface on the electret diaphragm and the conductive enclosure by means of the gasket.

FIELD OF THE INVENTION 
This invention relates to the field of transducers and within that field to 
electroacoustic and/or electret transducers. 
BACKGROUND OF THE INVENTION 
Electret electroacoustic transducers commonly comprise a conductive 
backplate and a permanently charged electret diaphragm that is separated 
from the backplate by a peripheral spacer. The surface of the electret 
diaphragm remote to the backplate is metalized, and the metalized surface 
is engaged by an electrically conductive member that maintains the 
diaphragm under tension. The electrical signal resulting from an 
acoustical signal impinging upon the diaphragm is applied to an impedance 
matching preamplifier circuit, and this circuit is commonly mounted 
adjacent to the backplate to facilitate electrically connecting the 
backplate to the circuit. Finally, to provide electrostatic shielding, 
these components are commonly assembled within an electrically conductive 
housing that makes electrical connection with the conductive tensioning 
member and provides a connection to a ground terminal. 
While this basic structure is found in a variety of different arrangements, 
the problem has been that very few of these arrangements permit the use of 
automated manufacturing, assembly, and testing techniques. 
One arrangement that appears to be directed toward this goal is disclosed 
in U.S. Pat. No. 3,775,572 issued to Ishibashi et al on Nov. 27, 1973. 
Ishibashi discloses a microphone which uses a group of three leads formed 
on a continuous strip. An integrated circuit chip is bonded adjacent to 
the upper end of one of the leads, and then wire connections are made 
between the circuit on the chip and the leads. This assembly is thereafter 
encapsulated in a disk-shaped insulating support with the leads extending 
parallel to the axis of and out the bottom surface of the support. The 
leads are then severed from the continuous strip, and one of the leads is 
cut off essentially flush with the bottom surface of the support. This 
same lead is of a height to extend close to the upper surface of the 
support, and the upper surface is lapped sufficiently to expose the end 
surface of this lead. A backplate is then either attached to the upper 
surface of the support or formed by evaporating metal on the upper 
surface, the backplate being thereby electrically connected to the lead by 
engagement with its exposed end surface. A ring-shaped insulating spacer 
and a diaphragm mounted to the underside of a ring-shaped conductive 
spacer are thereafter sequentially stacked on the support and the 
combination assembled within an inverted metal cup. The assembly is 
completed by stacking a disk-shaped insulating spacer and a conductive 
shield plate on the underside of the support, and then rolling over the 
lip of the metal cup against the shield plate to secure the assembly 
together. 
This design was found by its corporate owner to be unsatisfactory in some 
respects. As stated in the introduction of U.S. Pat. No. 4,170,721, issued 
to Ishibashi et al, on Oct. 9, 1979, "If the conductive material used for 
the backplate is not coated on the insulating member uniformly, or if an 
upper surface of an insulating member is not formed flatly, the distance 
between the backplate and diaphragm is not uniform throughout." This 
subassembly must then be discarded. 
The solution disclosed in this subsequent patent is a structure in which 
the backplate is encapsulated in a second insulating support, and the 
backplate is of a height to extend below the bottom surface of the second 
support. The lead that is to make electrical contact with the backplate, 
rather than being flush with the upper surface of the first support, 
extends above the upper surface, and an additional insulating member, 
which has an opening for accommodating the lower end of the backplate, is 
positioned between the first and second supports. Furthermore, a connector 
is interposed between the lead and the backplate to electrically connect 
one to the other. Since these components are in addition to the rest of 
the components of the first structure, it is seen that this solution adds 
significantly to the complexity of the structure. 
SUMMARY OF THE INVENTION 
The electroacoustic transducer to the present invention facilitates 
automated manufacture without introducing the problems presented by the 
first above-described patent and without the complexity of the structure 
disclosed in the second above-described patent. 
A transducer in accordance with the present invention is assembled on a 
unitary discrete electrically conductive frame member that is formed to 
provide both a plurality of leads and a backplate. An amplifier chip is 
bonded to one of the leads, and a dielectric inner housing member is 
molded about the backplate and the portion of the leads adjacent to it. 
The inner housing member encapsulates the chip, embraces the perimeter of 
the backplate, and provides a cylindrical opening that extends on each 
side of the backplate. A conductive outer housing member is subsequently 
molded about the perimeter of the inner housing member, and a spacer, 
electret diaphragm assembly, and conductive gasket are sequentially 
positioned in the opening on one side of the backplate. Conductive front 
and back covers are thereafter bonded to the outer housing member to close 
the opening, provide acoustically tuned front and back chambers, and 
complete a conductive enclosure that provides electrostatic shielding for 
the transducer. In addition, electrical continuity is provided between a 
metalized surface on the electret diaphragm and the conductive enclosure 
by means of the gasket.

DETAILED DESCRIPTION 
As seen from FIG. 1 of the drawing, one embodiment of an electroacoustic 
transducer in accordance with the present invention comprises a 
rectangular box-like structure having leads extending out one end. The 
basic component of the structure is a unitary frame member 100 shown in 
FIG. 2. The frame member 100 is advantageously repetitively formed along 
the length of a continuous strip 10 of electrically conductive material, 
such as copper. In addition, the frame member 100 is of sufficient 
thickness to be a discrete, self-supporting member. It does not require an 
additional element, such as a dielectric substrate to give it support or 
rigidity. 
The frame member 100 includes a backplate 110 and three leads 120, 130 and 
140. The backplate 110 has an array of holes 112 in it and is joined to 
the strip 10 by two connecting links 114 and 115. In addition, the 
backplate 110 has an outwardly extending leg 118 at its perimeter. The 
lower ends of the leads 120-140 are joined to the strip 10, while the 
middle portions of the leads are joined to one another and to the strip by 
a web 150. The upper end of the lead 120 includes an arm portion 122 that 
extends adjacent to the upper ends of the leads 130 and 140 and the leg 
118 of the backplate 110. The upper end of the lead 120 also includes a 
connecting link 126 that joins the lead to the backplate 110. 
An integrated circuit chip 200, which advantageously embodies the circuit 
disclosed in the copending patent application of S. H. Early and R. H. 
Minear, Ser. No. 370,498, filed Apr. 21, 1982, and assigned to the same 
assignee as the present application, is bonded to the free end of the arm 
122 of the lead 120 . Circuitry on the chip 200 is electrically connected 
to the leg 118 of the backplate 110, the arm 122 of the lead 120, and the 
upper ends of the leads 130 and 140 by individual connecting wires. A chip 
250 carrying thin film capacitors is also bonded to and electrically 
connected to the leads 120-140. 
Turning now to FIGS. 3 and 4, a dielectric inner housing member 300 is 
molded about the perimeter of the backplate 110, the inner housing member 
having an opening 310 that extends on both sides of the backplate. As seen 
from FIG. 4, the opening 310 is greater in height on one side of the 
backplate 110 than on the other. The portion of greater height is on the 
front of the transducer and is designated 310F, while the other portion is 
on the back of the transducer and is designated 310B. 
The opening 310 is basically cylindrical. However, as seen most clearly 
from FIG. 3, the internal surface defining the opening 310 includes three 
recesses 314, 315 and 316 aligned with the connecting links 114, 115 and 
126 whereby these links are left exposed. Alternatively, the opening 310 
can be completely cylindrical and three additional openings provided 
respectively in alignment with the three connecting links. 
The inner housing member 300 is also molded about the portions of the leads 
120-140 adjacent to the backplate 110, the inner housing member 
encapsulating the integrated circuit chip 200, the connecting wires, and 
the capacitor 250. As seen most clearly in FIG. 3, the web 150 is left 
exposed. In addition, the left side of the inner housing member 300 has a 
recess 320 that leaves exposed a portion of the lead 120. The inner 
housing member 300 is advantageously molded from a semiconductor grade 
molding compound. 
Referring now to FIGS. 5 and 6, an electrically conductive outer housing 
member 400 is molded about the inner housing member 300. The outer housing 
member 400 includes rectangular openings 410F and 410B that are larger 
than and in registration with the openings 310F and 310B. Aside from these 
openings, the outer housing member covers all of the inner housing member 
surfaces other than the end immediately adjacent to the leads 120-140. 
Since the outer housing member 400 fills the recess 320 (FIG. 3) in the 
side of the inner housing member 300, it does engage and is thereby 
electrically connected directly to the lead 120. The outer housing member 
400 is advantageously molded from a conductive grade acrylonitrile 
butadiene styrene. 
Turning now to FIGS. 5 and 7, with the completion of the molding of the 
outer housing 400, a subassembly 450 is produced that is fully or 
partially separable from the strip 10. Full separation is accomplished by 
severing portions of the connecting links 114 and 115 extending on the 
outside of the outer housing member 400, severing the lower ends of the 
leads 120-140, and removing the web 150. The outer housing member 400 is 
then electrically isolated from the leads 130 and 140. At the same time 
that the subassembly 450 is separated from the strip 10, the backplate 110 
is separated from the rest of the frame member 100. This is accomplished 
by severing the portions of the connecting links 114, 115 and 126, 
respectively, within the recesses 314, 315 and 316 of the opening 310 in 
the inner housing member 300. The backplate 110 is then electrically 
isolated except for its connection to the circuitry on the chip 200 (FIG. 
2) via the associated connecting wire. 
The connecting links 114, 115 and 126 when severed are also bent upwardly 
to increase the electrical isolation of the backplate from these links. 
The connecting link 126 is also bent in a generally S-shaped curve to 
provide a contacting surface at its free end that extends generally 
parallel to the plane of the subassembly 450. 
It is more advantageous to only partially separate the subassembly 450 from 
the strip 10. Referring to FIG. 5, partial separation involves only 
severing the lower ends of leads 130 and 140 and removing the portions of 
the web 150 that extend between the lead 120 and the lead 130, between the 
lead 130 and the lead 140, and between the lead 140 and the strip 10, As 
with full separation, the backplate 110 is at the same time separated from 
the rest of the frame member 100 in the manner previously described. The 
leads 130 and 140 are then electrically isolated except for their 
connection to the circuitry on the chip 200 (FIG. 2) and the capacitors on 
the chip 250. The backplate 110 is also electrically isolated except for 
its connection to the circuitry on the chip 200. 
As a result, although the subassembly 450 is still physically supported on 
the strip 10, the circuitry of the subassembly 450 can be readily tested 
before any additional components are combined with the subassembly. The 
testing is accomplished by applying an appropriate signal between the 
backplate 110 and the lead 120 or strip 10, applying a bias between the 
lead 140 and the lead 120 or strip 10, and detecting the output on lead 
130. It is seen that this arrangement of partial separation lends itself 
to automated testing. 
Referring now to FIGS. 1, 8 and 9, the next step in the assembly of the 
transducer, whether fully or partially separated from the strip 10, is the 
placement of a dielectric annular spacer 500 into the front opening 310F 
in the inner housing member 300, the spacer resting on the backplate 110. 
This is followed by the placement of a diaphragm assembly 600 within the 
front opening in engagement with the spacer 500. The diaphragm assembly 
600 comprises a circular electret diaphragm 625 and a rigid electrically 
conductive annular support 650. The upper surface of the diaphragm 625 is 
metalized to provide an electrically conductive surface and the support 
650 is bonded to this surface while the diaphragm is restrained under 
radial tension. Thus, the support 650 maintains the diaphragm 625 under 
tension. 
The final component positioned within the front opening 310F of the inner 
housing 300 is an electrically conductive compressible gasket 700 which 
rests on the support 650. The gasket 700 is basically an annular member 
that is of the same configuration as the support 650, but it includes a 
tab portion 716 that generally conforms to the recess 316 in the opening 
310 of the inner housing member 300. As described above, the connecting 
link 126 (FIG. 7) extends upwardly within the recess 316 and consequently 
is engaged by the tab portion 716 of the gasket 700. Thus, the conductive 
surface of the diaphragm 625 is electrically connected via the support 
650, the gasket 700, and the connecting link 126 to the lead 120, this 
being the same lead to which the outer housing member 400 is electrically 
connected. The gasket 700 is advantageously formed from a conductive 
silicone rubber compound. 
The assembly of the transducer is completed by the joining of an 
electrically conductive front cover 800 and an electrically conductive 
back cover 900 to the outer housing member 400. The perimeters of the 
front cover 800 and the back cover 900, respectively, conform to the 
perimeters of the front opening 410F and the back opening 410B in the 
outer housing member 400. The covers 800 and 900 are advantageously formed 
from basically the same polymer as the outer housing member 400 and are 
advantageously joined to the outer housing member by ultrasonic bonding. 
The front cover 800 when joined to the outer housing member 400 compresses, 
and is thereby electrically connected to, the gasket 700. As a result, the 
gasket 700 electrically connects the conductive surface of the diaphragm 
625 to the lead 120 both through the connecting link 126 (FIG. 7) and the 
outer housing member 400. In addition, the compressed gasket 700 provides 
a biasing force that ensures that the diaphragm assembly 600 is in direct 
engagement with the spacer 500 and the spacer is in direct engagement with 
the backplate 110. Controlled air gap spacing between the diaphragm 625 
and the backplate 110 is thereby achieved. 
The front cover 800 has a number of holes 810 extending through it that 
serve as acoustic filters providing electroacoustic frequency response 
shaping. These holes are advantageously very small to provide a large 
acoustic impedance, eliminating the need for the addition of a screen to 
perform this function. Holes of such size can be advantageously obtained 
by laser drilling. 
Finally, the front cover 800 and the back cover 900, respectively, have 
protrusions 820 and 920 that extend into the openings 310F and 310B. The 
protrusions 820 and 920 provide a convenient way to adjust the front and 
back acoustic chamber volumes to yield a desired frequency response shape 
for a particular application. 
The transducer can be modified to be noise cancelling by providing external 
openings that communicate with the back chamber. This can be accomplished 
by either providing holes in the back cover 900 or by providing additional 
holes in the front cover 800 that communicate with the recesses 314 and 
315 (FIG. 7) in the opening 310 of the inner housing member 300. 
The transducer can also be modified to use piezoelectric polymer rather 
than an electret for the diaphragm 625. In that arrangement, diaphragm 625 
would be metalized on both its upper and lower surfaces, and the spacer 
500 would be formed from a conductive rather than a dielectric material. 
These and other modifications may be made by persons skilled in the art 
without departing from the spirit and scope of the invention.