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Claims  |
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I claim:
1. A method of providing sound to the ear, comprising, providing a first
path to the ear canal for sound, and providing a second path to the ear
canal for said sound approximately 180 degrees out of phase with the sound
in said first path.
2. The method of claim 1 wherein said paths terminate in proximity to each
other at their ends which provide sound to the ear.
3. The method of claim 2 further including the step of damping at least one
of said paths.
4. The method of claim 3 further including the step of venting at least one
of said paths to the atmosphere.
5. A method of providing sound to the ear comprising providing a first path
from one surface of a diaphragm, which vibrates and causes variable air
pressure, to the ear canal for sound, and providing a second path from
inside the ear at approximately the termination of said first path to a
location having the variable air pressure caused by the other surface of
said diaphragm.
6. The method of claim 5 further including the step of damping at least one
of said paths.
7. The method of claim 5 further including the step of providing a third
path, for venting purposes, from one of said surfaces of said diaphragm to
the atmosphere.
8. An earphone comprising a manifold comprising a chamber having at least
first and second walls, a magnet fixed with respect to said manifold
chamber, a coil of wire adapted to receive electrical signals representing
sound and to provide a magnetic field in accordance with said sound, said
coil of wire disposed near said magnet and adapted to magnetically
interact with said magnet, a diaphragm having its periphery fixed in
proximity to said first wall of said manifold chamber and said diaphragm
being attached to said coil and adapted to be driven thereby to provide
air vibrations, venting means for venting the pressures from said
diaphragm to the atmosphere, said first wall of said manifold chamber in
proximity to said diaphragm having at least one hole therethrough wherein
said diaphragm provides air vibrations through said holes into said
chamber of said manifold, an eartip comprising a first conduit therein
adapted to receive said air vibrations on one end and the other end of
said eartip adapted to fit into the ear, a second conduit running from a
location near said other end of said eartip, to said manifold chamber.
9. An earphone as recited in claim 8 wherein said location is at the end of
said eartip adapted to fit into the ear.
10. An earphone as recited in claim 8 wherein said second conduit extends
past said diaphragm at its periphery.
11. An earphone as recited in claim 8 wherein said venting means includes
damping means.
12. An earphone as recited in claim 8, further including an air baffle
between said diaphragm and said eartip, and wherein said air baffle and
said diaphragm form a sound chamber.
13. An earphone as recited in claim 8 wherein said venting means comprises
a conduit which runs through the center of said magnet to the atmosphere.
14. An earphone as recited in claim 8 wherein said venting means runs from
said manifold chamber to the atmosphere.
15. An earphone as recited in claim 8 wherein said magnet is fixedly
attached to said first wall of said manifold chamber.
16. An earphone as recited in claim 8 wherein said magnet is fixedly
attached to said second wall of said manifold chamber.
17. An earphone comprising a manifold having a chamber having at least two
walls, a magnet fixed with respect to at least one wall of said manifold
chamber, a coil of wire adapted to receive electrical signals representing
sound and to provide a magnetic field in accordance with said sound, said
coil of wire disposed so that said magnetic field magnetically interacts
with said magnet, a diaphragm having first and second sides, and having
its periphery fixed with respect to one of the walls of said manifold
chamber and said diaphragm being attached to said coil and adapted to be
vibrated thereby, providing an output of sound on its first side, the wall
of said manifold chamber near said second side of said diaphragm having a
plurality of holes therethrough, an air baffle next to said diaphragm, on
the first side of said diaphragm, an eartip having a first conduit
therethrough, said first conduit adapted to receive the output through
said air baffle on one side of said eartip which is adapted to fit into
the ear on the other side and a second conduit disposed to run from a
location approximately at the end of said eartip adapted to fit into the
ear, to said manifold chamber.
18. An earphone as recited in claim 17 wherein said second conduit extends
past said diaphragm and said baffle at their peripheries.
19. An earphone as recited in claim 17 wherein said second conduit begins
at the end of said eartip where it fits into the ear.
20. An earphone as recited in claim 17 further including a third conduit,
for venting purposes, from one side of said diaphragm to the atmosphere,
and means for acoustically damping the sound in said third conduit by at
least one of, its length, its size, acoustic damping material covering
said conduit and acoustic damping material within said conduit.
21. An earphone having a diaphragm, said diaphragm having a front side and
a back side, and an eartip which fits inside the ear and which eartip has
two conduits therein; one of said conduits being adapted to receive the
output from the front side of said diaphragm and transmit it to the end of
said eartip which fits inside the ear, a manifold chamber on the back side
of said diaphragm, the other of said conduits running from a location near
the end of said eartip, which fits inside the ear, to said manifold
chamber.
22. An earphone as recited in claim 21, wherein said location is at the end
of said eartip inside the ear.
23. An earphone as recited in claim 21, wherein venting conduit means is
included, venting the back side of said diaphragm to the atmosphere.
24. An earphone comprising a diaphragm adapted to be vibrated in accordance
with sound, a first conduit for delivery of sound vibrations to the ear,
one surface of said diaphragm disposed to deliver sound vibrations to an
ear canal through said first conduit, a second conduit, running from a
location in close proximity to where sound is delivered by said first
conduit, to the other surface of said diaphragm.
25. An earphone as recited in claim 24, wherein said second conduit has
damping means associated therewith to reduce the flow of air through said
second conduit.
26. An eraphone as recited in claim 25, wherein said damping means
comprises at least one of the structural elements of said conduit, said
elements comprising the resilience of the inner walls of such conduit, the
conduit length or the conduit size.
27. An earphone comprised of a diaphragm having front and back sides, first
and second conduit means, one end of said first conduit means disposed to
connect said front side of said diaphragm to a location for delivery of
sound in the ear canal of a wearer of the earphone and one end of said
second conduit means disposed to connect said back side of said diaphragm
to approximately said same location.
28. An earphone as recited in claim 27 wherein said second conduit means
connects said back side of said diaphragm to the same location said first
conduit means delivers sound.
29. An earphone as recited in claim 27 further including means for venting
to the atmosphere at least one of the back side of said diaphragm or said
conduit means.
30. An earphone as recited in claim 29 wherein said means for venting
comprises acoustic damping means.
31. An earphone comprising an eartip having a first path therethrough for
providing sound to the ear canal, a second path for providing sound to the
ear canal for sound approximately 180 degrees out of phase with the sound
in said first path, said first and second paths terminating at
approximately the same location at their ends providing said sound.
32. An earphone as recited in claim 31 wherein means for damping the sound
in one or both of said paths is included.
33. An earphone as recited in claim 31 wherein said second path is provided
at least partially by a channel between the ear canal and said eartip.
34. An earphone as recited in claim 33 wherein said eartip comprises at
least one of a flat surface and a channel running along the outside of
said earphone to a location at the back side of said diaphragm.
35. An earphone as recited in claim 31 wherein said second path is provided
at least in part by space between the circumference of said eartip and the
ear canal when said eartip is disposed in an ear canal.
36. An earphone comprising a manifold comprising a chamber, a diaphragm
disposed in fixed proximity to said chamber and adapted produce sound
vibrations of air in said chamber from one side of said diaphragm, an
eartip in fixed proximity to said diaphragm, a first sound conduit
extending from the other side of said diaphragm through said eartip and a
second sound conduit extending from said chamber to a location near the
end of said first sound conduit. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
This invention relates to an earphone or a hearing aid which provides
greater fidelity in the reproduction of music and other sound. As used
herein, the word "earphone" is intended to include, within its meaning,
the similar part of a "hearing aid". The device of the invention may be
used by persons with normal hearing, desiring greater fidelity sound,
particularly music; and it may also be used by those who have hearing
impairment and need a hearing aid in order to hear.
Some of the effects desired to be achieved in presentation of sound to the
auditory canal of the ear, or to any location, are, little distortion,
little or no undesirable, acoustic or other feedback, and, normally,
linear amplification. Often, an earphone or a hearing aid will provide
sound with a hollowness, as if being heard through a tube. Other systems
do not reproduce the low or the high frequencies adequately. In many
devices of the prior art, distortion is found to occur.
When the pressure inside the auditory canal was vented to the atmosphere
(the ambient air, or air outside the canal or outside the ear), it
substantially improved the performance of hearing aids but also introduced
some problems. The sound from the vent path was often picked up by the
input microphone and this caused excessive feedback which led to squealing
or ringing. Various dampers in the sound delivery paths and in the vent
paths reduce the sensitivity of hearing aids to feedback and allow
compromise and adjustment to the specific needs of the user.
SUMMARY OF THE INVENTION
In the device of the invention, a second acoustic path is provided in
addition to the main acoustic path. Such second acoustic path runs from
inside the ear canal at a location relatively near where the sound (air
pressure variation) from the main acoustic path is delivered, to a
location at the back side of the sound-producing diaphragm. Thus, pressure
in the ear canal is relieved, but in a way differently than those devices
which relieve pressure in the ear canal by venting to the atmosphere. The
difference in the device of the invention is that such vented pressure is
not lost, but is returned to the system at a correct location, increasing
its efficiency and, also, its fidelity.
In the device of the invention, it is believed that the second acoustic
path not only provides for relief of the pressure within the ear canal at
a location near where the sound is heard but also provides for
transmission of some sound to the ear. The air pressure is transmitted
both ways in the second acoustic path. By such structure, the range of
frequency response is substantially improved.
Suitable dampers may still be utilized, in one or both paths, to obtain
desired frequency response and to customize the hearing aid to the
particular difficulty of the hearer. In this regard, a system utilizing a
microphone and amplification may additionally use equalization to arrive
at the optimum frequency response for specific use or user. Venting to the
ambient air, by various conduits disclosed herein, may additionally be
utilized in some systems. Still other techniques known to those skilled in
the art may be combined with the instant invention to achieve an improved
hearing aid or earphone.
The device of the invention may be used as an improved earphone, without
being sealed in the ear canal as is customary with a hearing aid. Such an
embodiment may be used with transistor radios and tape players and the
like. The fidelity is excellent and provides improved quality in the
sound. It also may be used as an earphone which is sealed in the ear by a
soft rubber or plastic which is resilient and fits the ear canal. Also, it
may be combined with a customized earmold which is specially fitted to the
user.
The device of the invention may also be used as a hearing aid which has a
customized earmold as well as customized frequency response. Such
customizing of frequency response may occur as a result of testing the
user and adapting the amplification, frequency response, damping or other
aspect.
It is therefore, an object of this invention to provide an improved
earphone or hearing aid.
Another object of this invention is to provide an earphone which has a wide
range of frequency response.
Still another object of this invention is to provide an earphone which is
improved in efficiency.
A further object of this invention is to provide an earphone which may be
customized to the specific needs of a user.
A still further object of this invention is to provide an earphone which
has improved fidelity and may provide sound either inside or outside the
ear canal.
Another object of this invention is to provide an earphone which may be
used with various features of other hearing aids or earphones.
Still other objects and features will become apparent to those skilled in
the art from the following drawings and description.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a view of one embodiment of the earphone.
FIG. 2 is an exploded view showing the main elements of an embodiment of
the earphone, particularly the second sound path from inside the ear to a
manifold at the back side of the diaphragm.
FIG. 3 is a modified version of the earphone, in which a vent to the
atmosphere runs from a central location at the back side of the diaphragm.
FIG. 4 is an exploded view showing the second sound path and the vent to
the atmosphere both terminating in a central location at the back side of
the diaphragm.
FIG. 5 is a simplified manifold, having a vent which terminates near one
edge of the manifold and the second sound path entering the manifold from
the back side.
FIG. 6 shows the second sound path which runs to the manifold, merging with
the vent to the atmosphere.
FIG. 7 shows a vent to the atmosphere, which vent commences in closer
proximity to the diaphragm.
FIG. 8 shows an earmold which is angled and the second sound path runs from
a central location in the earmold, through the center of the diaphragm, to
its back side.
FIG. 9 shows a customized earmold, having a second sound path centrally
located in a sound chamber.
FIG. 10 is an external view of the earphone, showing a microphone,
microelectronics and a vent to the atmosphere from a central location in
the back side of the earphone.
FIG. 11 is an exploded view showing the second sound path running to a
central location at the back side of the diaphragm.
FIG. 12 is an exploded view in which the magnet and the diaphragm are
reversed in relative location.
FIG. 13 is an exploded view showing the "looseness of fit concept" and
feedback channels between the fit of the earphone and the structure of the
ear.
DESCRIPTION
The device of the invention is illustrated in FIG. 1, which shows an eartip
1 which is intended to fit into a person's ear canal. The end of eartip 1
may be open or covered by an acoustic mesh, such as that shown at 34 foam
rubber or a gauze or other material. Rib 2 aids in sealing eartip 1 within
the ear canal, for improved sound reproduction. A number of component
parts then complete the earphone, as may be understood by reference to
FIG. 2.
It is to be understood that, in some cases, eartip 1 may be very short and
not enter into the ear canal and, in other cases, may enter only very
slightly. Optimally, it would enter the ear canal about half or two-thirds
of the way to the eardrum.
In FIG. 2, a first housing 3 is adapted to receive an air baffle 4 which
helps to form an air chamber next to diaphragm 5. A coil 6 on the
diaghragm receives electrical signals to drive the diaphragm 5, which may
be made of Mylar or other film material, mounted in a ring 14. The
diaphragm is driven to vibrate by the coil 6. The ring mounts in or
against housing 8, depending how much of a chamber is desired. Such
diaghragm, of course, then causes vibrations (compression and expansion)
in the air, which is transmitted through the conduit through eartip 1 and
is delivered to the ear near the end of the eartip 1. Coil 6 interacts
electomagnetically with permanent magnet 7 disposed in housing 8 which has
holes therethrough such as 9 and 10. In the preferred embodiment, such
holes are covered with a foam rubber, a gauze, or other acoustic damping
material. Housing 11, together with housing 8, provide a manifold
comprised of a chamber whose walls are formed by the housings. As may be
seen by reference to FIG. 2, housing 8 provides a front wall for the
manifold chamber and housing 11 provides a rear wall. The holes of housing
8 provide inlets and outlets to such manifold chamber. A vent to the
atmosphere is provided by vent tube 12.
The concept of the invention is illustrated in FIG. 2 wherein a second
sound path 13 (or conduit 13) runs from inside the ear canal to the
manifold chamber between housings 11 and 8. Sound path 13 is shown as
terminating inside eartip 1. It may also terminate at the end of the
eartip, as shown in FIG. 3. This is preferred. It may even extend farther,
but as a practical matter, it is best terminated at the eartip opening. In
those cases wherein eartip 1 is very short and does not enter the ear
canal or hardly enters the ear canal at all, sound path 13 may extend into
the ear beyond the eartip, may end at the end of the eartip or end within
the eartip. Therefore, the second sound path 13 terminates in proximity to
the end of the eartip 1, through which the first sound path runs. Thus,
the two sound paths terminate in proximity to each other, as may be seen
in FIG. 3 and other FIGS. in the drawings. It is noted that an acoustic
mesh 34 covers the end of eartip 1 in FIG. 2 while in FIG. 3 the sound
path having inner wall 35, running through eartip 1, is open at the end.
The other end of sound path 13 has an opening 36 into the manifold chamber
formed by housing 11 and 8.
In one view, the sound path 13 provides a return path for venting the
compressions and rarefactions (of air provided to the ear) to the back
side of the diapghragm. In a second view, sound path 13 provides a second
path to the ear with compressions and rarefactions from the back side of
the diaphragm. These are 180 degrees out of phase with compressions and
rarefactions provided to the ear from the front of the diaphragm. In any
event, it can be seen how a closed loop of sound is obtained. Whenever air
is pushed by the front of the diaphragm, air is pulled by the back side of
the diaphragm, subject to any delay or resistance caused by damping in the
sound channels. Likewise, whenever air is pushed by the back side of the
diaphragm, air is pulled by the front side of the diaphragm.
In FIG. 3 is shown magnet 7 being mounted on housing 11, rather than
housing 8, as in FIG. 2. Such magnet and coil 6 still interact, of course,
to drive diaphragm 5. Atmosphere vent 12 runs through the center of magnet
7 and then runs upwardly to a remote location. This allows the exhaust
from tube 12 to be dissipated with the least effect on a nearby
microphone. Various alternate embodiments may be made. Tube, or sound
path, 13 may enter through the back side of housing 11 but in FIG. 3 is
shown as entering into housing 11 at opening. Also, alternatively, the
device may be designed so that tube 13 runs within one or more of the
circumferences of housings 8 and 11 and air baffle 4 and not outside their
circumferences as shown. For ease of construction it probably would run
outside diaphragm 5, However, ring 14 may be diverted, to accept tube 13
within what would otherwise be the circumference of diaphragm 5.
FIG. 4 shows the second sound path 13 entering the manifold from the back
side, through magnet 7. Atmospheric vent tube 12 also enters the manifold
from the back side through magnet 7. A desirable balance between the vent
and the second sound path can be achieved by selection of relative tube
inner diameter sizes, tube lengths, by the use of foam rubber, sintered
metal, lamb's wool or other acoustic damping material to cover the tube
openings or to be placed inside the tubes. Bass response can be improved
by acoustic damping of the vent path to the atmosphere, or ambient air. It
is noted that vent tube 12 is shown substantially smaller than tube 13,
and that they both open up into a channel through magnet 7.
In FIG. 5 is shown an embodiment in which there is no housing 11, but
rather the sound path 13 enters from the back side of housing 8 and the
manifold chamber it enters is formed between the diaphragm 5 and the
housing 8. As in the other embodiments, acoustic damping may be provided
in one or both of the tubes 12 or 13. Also, one conduit may be heavily
damped and the other lightly damped. Preferably, the vent tube 12 to the
atmosphere would be more heavily damped than the sound path 13.
FIG. 6 illustrates a concept in which sound path 13 enters the manifold
provided by housings 8 and 11, at opening 36 and sound path 13 is joined
by the vent tube 12. In FIG. 6, the vent tube 12 is smaller than the sound
path 13. Balance between venting and feedback to the manifold (or feed
from the manifold outward) can be achieved by relative tube sizes or
damping materials disposed within such tubes and at their openings.
FIG. 7 illustrates a venting embodiment in which the vent tube 12 runs to
the inside of housing 8. Additional venting, if desired, can be obtained
through the center of magnet 7. Sound path 13 runs to the manifold, as
before discussed.
In FIG. 8 is shown an angled eartip which more closely resembles an actual
shape of an eartip which has been molded to the ear. The sound path 13 is
shown terminating (or beginning) centrally within the passageway in eartip
1. It passes centrally through air baffle 4 and passes through diaphragm 5
to the manifold between diaphragm 5 and housing 8. Diaphragm is mounted
around sound path 13 so as to firmly hold it, yet be enabled to freely
vibrate as required.
FIG. 9 shows an eartip 1 having a first sound path therein (shown by inner
wall 35), and which eartip may have been molded (an earmold) to fit a
specific person's ear. A sound chamber such as shown at 19 may be provided
in eartip 1, so that air vibrations can pass readily to the ear with a
pleasing sound. In FIG. 9, sound path 13 is shown running through the
center of the sound chamber in eartip 1. It may be constructed, of course,
to commence at the center of the end of eartip 1 and slope to the bottom
of the eartip, as shown in FIG. 11.
As used in this specification and in the claims, "eartip" is intended to
include an earmold, or any of the structures intended to transmit sound
waves to, into or in the ear canal.
FIG. 10. shows the outside appearance of the earphone. The view is a side
view of FIG. 9, looking in the direction indicated by the line 10--10 of
FIG. 9. The vent tube 12 is disposed so that it does not readily cause
feedback to microphone 15 which is shown mounted on microcircuit 16. Any
suitable miniature microphone may be used. One such suitable microphone
that is commonly used is an electret or a condenser type microphone which
is used in pressure zone microphones which are commonly available in
retail radio and electronic stores. Most any of the microphones used in
hearing aids would also be suitable. A particular feature of an earphone
having a microphone is that it allows the earphone to have an eartip which
is sealed in the ear (so that the hearer can listen to high fidelity music
on a tape player or radio) and still hear outside sound. This is an
important safety feature.
In FIG. 10 a battery is not shown, but one would, of course, be required in
order to operate the microcircuit and, possibly, the microphone. If the
earphone is connected to a radio or tape player, power may be drawn from
that.
FIG. 11 illustrates the sound path 13 entering from the back side of the
hearing aid and passing through magnet 7 into the manifold space between
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