Patent Grant
11234085
This disclosure relates to earpieces and related articles and devices, and, particularly, to earpieces and ear tips for hearing aids.
All examples and features mentioned below can be combined in any technically possible way.
In one aspect, an earpiece includes an acoustic mass element, and an acoustic resistance element that is arranged acoustically in parallel with the acoustic mass element. The acoustic mass element and the acoustic resistance element are arranged to couple a user's ear canal to an external environment when worn.
Implementations may include one of the following features, or any combination thereof.
In some implementations, the acoustic mass element includes an acoustic port.
In certain implementations, the acoustic resistance element includes a resistive port.
In some cases, the restive port includes an acoustic port and an acoustically resistive material arranged to impede movement of acoustic energy through the acoustic port.
In certain cases, the acoustically resistive material includes a resistive screen.
In some examples, the resistive screen has an acoustic resistance of about 5 Rayl to about 500 Rayl.
In certain examples, the earpiece includes an earbud and an ear tip and at least one of the acoustic mass element and the acoustic resistance element are disposed on the tip.
In some implementations, both the acoustic mass element and the acoustic resistance element are disposed on the tip.
In certain implementations, the earpiece includes an earbud and an ear tip and at least one of the acoustic mass element and the acoustic resistance element are disposed on the earbud.
In some cases, both the acoustic mass element and the acoustic resistance element are disposed on the earbud.
In certain cases, the acoustic resistance element has an acoustic resistance of about 5 Rayl to about 500 Rayl
In some examples, the earpiece includes an earbud and at least one of the acoustic mass element and the acoustic resistance element are disposed on the earbud.
In certain examples, both the acoustic mass element and the acoustic resistance element are disposed on the earbud.
In some implementations, the acoustic resistance element includes an acoustic damper.
In certain implementations, the acoustic damper includes a hollow tube and a resistive screen arranged to resist air flow through the hollow tube.
In another aspect, a hearing aid includes an earpiece that is configured to sit at least partially within the user's ear canal when worn. The earpiece includes an acoustic mass element, and an acoustic resistance element arranged acoustically in parallel with the acoustic mass element. The acoustic mass element and the acoustic resistance element are arranged to couple the user's ear canal to an external environment when worn.
Implementations may include one of the above and/or below features, or any combination thereof.
In certain examples, the hearing aid includes a casing that supports a processor and a microphone and is configured to sit behind a user's ear when worn. The earpiece is coupled to the casing.
In some implementations, the hearing aid includes an electro-acoustic transducer disposed within the casing. The earpiece is coupled to the casing via a tube for conducting acoustic energy from the electro-acoustic transducer to the earpiece.
In certain implementations, the hearing aid includes an electro-acoustic transducer disposed within the earpiece. The earpiece is coupled to the casing via wiring for electrically coupling the electro-acoustic transducer to the sound processor.
In some cases, the earpiece includes an earbud and an ear tip and at least one of the acoustic mass element and the acoustic resistance element are disposed on the tip.
In certain cases, the earpiece includes an earbud and an ear tip and at least one of the acoustic mass element and the acoustic resistance element are disposed on the earbud.
With reference to
Behind-the-ear (BTE) hearing aids have a similar form factor, with a case that sits behind a user's ear, and attached ear piece that directs sound to the user's ear canal. While both RIC and BTE hearing aids are technically behind-the-ear, the BTE has more components behind the ear. In that regard, the BTE hearing aids have the microphone, receiver (speaker), battery, and sound processor all behind the ear, with just a tube running around the ear and into the ear piece for conducting acoustic energy from the speaker to the user's ear canal.
Conventional RIC and BTE style hearing aids often include a compliant tip on the ear piece for engaging the user's ear canal, which help to keep the ear piece in place within the user's ear canal. These ear tips, or “domes,” are typically either i) closed—forming a tight acoustic seal with the user's ear canal (see “closed dome 200” of
The closed dome configuration suffers from what is known as the occlusion effect. The occlusion effect amplifies lower-frequency components of the user's own voice due to the acoustic blockage of the ear canal. Pressure due to the user's voice radiates through the head and into the ear canal. When the ear is not occluded, the pressure escapes out of the ear; when the ear is occluded, and the pressure cannot escape, low-frequency components are grossly amplified inside the user's ear. Occluding the ear causes an additional problem—blocking of the ear canal prevents higher frequency components of the user's voice from traveling around the head and back in the ear. These two issues result in undesirable own-voice quality, typically perceived as the user's voice being “boomy” or “muffled.” By “own-voice,” we refer to the user's perception of their own voice while speaking.
The open dome configuration relieves this occlusion effect, but it introduces other problems. First, the open dome creates an acoustic feedback path between the speaker output and the microphone on the outside of the device, which is meant to detect sound surrounding the user for amplification. The increase in acoustic coupling between the speaker output and microphone input makes the system more susceptible to acoustic oscillation, i.e., audible feedback or squealing. Oscillation is prevented by several measures, but most effectively by reducing the maximum amount of gain the device can apply, so that it doesn't reach the point where oscillation occurs. This prevents instability but compromises the ability of an amplified product to provide its intended function. We refer to the maximum gain that can be applied without causing oscillation, at any frequency, as maximum stable gain.
Second, the open dome configuration reduces the efficiency and bandwidth of the speaker in delivering sound to the ear. The acoustic impact of the open dome configuration is such that the speaker must drive a larger effective acoustic volume. This significantly lowers the acoustic system efficiency, especially at lower frequencies. This in turn can result in poor bandwidth, for example, the low-frequency cut-off of the system may be insufficient for reproducing the lowest frequencies of speech, let alone music.
Third, the open dome configuration allows more sound from the environment to pass through the device and enter the ear than if there were no apertures in the dome. This “passive path” through the device is combined inside the ear with the “aided path,” which is the output of hearing-related signal processing through the loudspeaker, e.g., an amplified representation of the outside sound. We refer to the reduction of sound reaching the ear through the passive path, due to the presence of the earphone, as passive insertion loss. The apertures in the open dome configuration makes the passive insertion loss lower, which increases the magnitude of the passive path contribution to the combined (active plus passive) signal. Several problems result from the increased passive path contribution.
When the acoustic signals from the passive and aided paths are similar in magnitude and close but not identical in arrival time at the ear drum, spectral combing occurs. This is because the aided path is correlated with the passive path but contains greater latency (later arrival time) due to the signal processing. In some examples, the amount of latency is as high as 5 ms; even latency of 1 ms may be distracting. This interaction can result in the perceived spectrum of environmental sounds being “tinny,” “comby,” “tube-like,” or otherwise undesirable and of poor fidelity. The perceptibility of this effect can be reduced by adding substantial gain to the aided path. Up to 20 dB of gain may be required on the aided path to significantly suppress the combing effect, i.e., by vastly exceeding the contribution of the passive path, but this amount of gain may exceed the maximum stable gain of the device. That much gain may also be uncomfortably loud for the user when the environmental sound level is already high and audible through the passive path, or if the user has only a mild impairment.
This disclosure is based on the realization that a better balance may be struck between acoustic impedance and low frequency output if the acoustic impedance can be increased to a point at which occlusion is just noticeable.
Referring now to
A model for this type of impedance is illustrated by curve 800 in
Thus, at high frequencies, the dome with one open hole and one screen covered hole in parallel looks like it has just two open holes in parallel, so the impedance drops because, in effect, a second hole is added. And, at the lowest frequencies, the energy chooses the path of least resistance, which is the open hole, but now it looks like the dome has just one hole instead of two holes, because the screen is blocking the other hole, since the impedance of the screen-covered hole at lower frequencies is so much higher. As a result, the high frequency impedance is maintained at just noticeable levels, while impedance is increased at the lower frequencies closer to just noticeable levels.
A secondary benefit of increasing the dome impedance is that increased insertion gain (rejection of outside sound) at high frequencies, above 2 kHz, can help reduce combing when the time-delayed aided path is played into the ear and sums with the direct passive sound from the environment.
The ear tip 1004 is in the shape of a hollow cylinder with a hollow passage 1016 that is configured to receive the nozzle 1008 of the earbud 1002. The ear tip 1004 is configured to fit at least partially within a person's ear canal. The ear tip 1004 includes a body 1018 that is configured to received and/or be mounted onto the earbud 1002. The body 1018 includes a first end 1020 and a second end 1022 opposite the first end 1020. The body 1018 further includes inner wall 1024 extending between the first end 1020 the second end 1022. The inner wall 1024 defines and surrounds the hollow passage 1016 which can be configured to conduct sound waves. The body 1018 also includes an outer wall 1026 connected to the inner wall 1024 at the first end 1020. The outer wall 1026 extends away from the inner wall 1024 toward the second end 1022. In the illustrated example, the outer wall 1026 is dome-like in shape; however other shapes, such as frustoconical, are contemplated. As shown in
The body 1018 can be made of any suitable soft, flexible materials, including, for example, silicone, polyurethane, polynorbornene (e.g., Norsorex® material available from D-NOV GmbH of Vienna, Austria), thermoplastic elastomer (TPE), and/or fluoroelastomer. In some implementations, the inner wall 1024 and the outer wall 1026 can be formed of different materials, e.g., in an additive manufacturing or two-shot molding process. In some cases, the inner wall 1024 may be formed of a higher durometer material, e.g., to ensure good coupling to the nozzle 1008, and the outer wall 1026 may be formed of a lower durometer material, e.g., for compliance (to ensure a good acoustic seal) and comfort.
The outer wall 1026 is configured to engage a user's ear canal when worn and to form an acoustic seal therebetween. Notably, the ear tip 1004 is provided with an acoustic mass element, in the form of a first, open (unobstructed) hole 1028 or “port” (a/k/a “acoustic port”), and an acoustic resistance element, in the form of a second hole 1030 with an acoustically resistive material, e.g., a resistive screen 1032, disposed therein to provide a resistive port. The acoustic mass and acoustic resistance elements are acoustically in parallel and are arranged to acoustically couple a user's ear canal to the external environment when the earpiece 1000 is worn so as to provide a one open hole and one screen-covered hole configuration, such as described above, for just noticeable occlusion.
The first, open hole 1028 is about 1 mm to about 3 mm in diameter, e.g., 1.5 mm in diameter. The second hole 1030 is also about 1 mm to about 3 mm in diameter, e.g., 1.5 mm to 2 mm in diameter. Both the first and second holes 1028, 1030 extend through the outer wall 1026 which has a thickness of about 1 mm in the region of the first and second holes 1028, 1030. The acoustically resistive material may have an acoustic resistance of about 5 Rayl to about 500 Rayl, e.g., about 5 Rayl to about 100 Rayl. Suitable resistive screens in the form of woven polyester are available from Sefar Inc., Buffalo, N.Y. The resistive screen 1032 may be secured over one open end of the second hole 1030, e.g., using a room temperature vulcanizing (RTV) silicone. Alternatively, the screen 1032 may be insert molded with the body 1018. Alternatively, a separate resistive element in the form of a small cylindrical housing carrying an acoustically resistive material (e.g., a screen) may be inserted into the second hole 1030 and/or insert molded with the body 1018. Suitable resistive elements of this type include acoustic dampers commercially available from Knowles Electronics, LLC., Itasca, Ill.
As shown in
In the case of a BTE style hearing aid, the earpiece is coupled to the casing via tubing 1112 for conducting acoustic energy from an electro-acoustic transducer 1114 supported in the casing 1102 to the earpiece 1000.
Other Implementations
While an implementation has been described in which an acoustically parallel combination of an open hole and a resistive port are provided in a wall of an ear tip, in other implementations one or both of the open hole and the resistive port may be provided in an earbud. For example,
While various examples have been discussed above with specific reference to RIC and BTE style hearing aids, one of ordinary skill in the art would appreciate that the principles discussed herein would also be applicable to concha-only earpieces, such as Invisible-In-the-Canal (IIC), Completely-In-Canal (CIC), In-The-Canal (ITC), and In-The-Ear (ITE) styles of hearing aids. For example,
In the implementation of
Although implementations have been described in which an earpiece includes an earbud and an ear tip coupled to the earbud,
While acoustic mass elements in the form of open holes or “acoustic ports” have been described, in some cases, other acoustic mass elements may be used. For example, in some implementations a passive radiator may be used as an acoustic mass element.
Furthermore, while an example of a resistive element in the form of a port with a screen has been described, in some implementation the resistive element could take the form of a number of small apertures formed directly in the ear tip or earbud arranged to provide the desired impedance.
Although examples of earpiece have been described which include a single acoustic mass element arranged in parallel with a single acoustic resistance element, other implementations may have additional acoustic mass and/or acoustic resistance elements arranged acoustically in parallel. Additionally, in such implementations, not every mass or resistance element needs to necessarily have the same mass or resistance value. The inclusion of additional mass and/or resistance elements with each potentially having different mass or resistance values can allow for greater flexibility for achieving a more precise shaping of the response.
While various implementations have been described in which an earpiece couples with a casing that houses electronics and is designed to sit behind a user's ear, in other implementations the electronics may be housed in a casing that is designed to wrap around a user's neck, a so-called “nape band,” or in a casing that rests behind a user's head.
One of ordinary skill in the art would readily appreciate that many hearing aids have more than one microphone for beamforming, thus, it should be understood that reference to a microphone in the foregoing description is intended to cover configurations with one or more microphones including configurations with microphone arrays.
A number of implementations have been described. Nevertheless, it will be understood that additional modifications may be made without departing from the scope of the inventive concepts described herein, and, accordingly, other implementations are within the scope of the following claims.
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