A vent (also referenced to herein as a “venting channel”) is an important part of a hearing aid. A vent is required to provide air circulation and minimize occlusion. If a vent is not provided, a user will likely have an uneasy feeling caused by an unequal pressure differential present in a space between the users ear drum and an inner ear canal end of the hearing aid housing compared to the atmospheric pressure external to the hearing aid housing outwardly of the ear. Users have described this uneasy feeling as an unnatural pressure differential. Users have also complained of what has been described as an unnatural hollow sound when the hearing aid is used if no vent is provided. Furthermore, care must be given in choosing the size of the vent since if the vent is too large, undesirable acoustic feedback may occur. When marketing experts in the hearing aid industry are asked which shell they would consider ideal, many of them will indicate a shell as small as possible, but with a vent as big as possible. The term “shell” used herein means an outermost wall of the hearing aid housing.
A “collection vent” is a known prior art vent in hearing aids which starts as a regular round vent at a faceplate outer side of the hearing aid (also called a “starter vent” hereafter) and continues some distance as a round vent and then increases in diameter gradually until some size specified by a designer and which terminates at the canal side of the hearing aid near the ear drum.
It is an object to provide an automated software design method for a hearing aid which designs a vent-as-large-as-possible, and which takes as much space as possible in a housing shell of the hearing aid.
A computerized method is provided for designing a vent in a hearing aid housing shell based on an image of a patient's ear canal impression, and wherein a program is provided on a computer-readable medium. With the program, an image of a starter housing shell based on the image of the patient's ear canal impression is created which is longer than a final version of the housing shell to be created. A starter vent running from an inner canal end near the patient's ear drum to an outer end of the starter housing shell is placed inside the shell. Components are then placed substantially as deep as possible inside the starter shell but lying outside of the starter vent. Portions of the starter shell lying beyond where a faceplate is to be mounted are removed and the faceplate is mounted. The starter vent is then grown larger so that it fills substantially all space inside the shell without interfering with the components.
For the purposes of promoting an understanding of the principles of the invention, reference will now be made to the preferred embodiment illustrated in the drawings and specific language will be used to describe the same. It will nevertheless be understood that no limitation of the scope of the invention is thereby intended, and such alterations and further modifications in the illustrated device and such further applications of the principles of the invention as illustrated as would normally occur to one skilled in the art to which the invention relates are included.
When the term “venting channel” or “vent” is used hereafter, it means a structure inside the shell that permits air flow between the inner ear canal near the ear drum and the outside atmosphere where the user is located.
When the acronym CIC is used hereafter, it means completely-in-the-canal.
A main goal is to provide an automated software design method which provides a vent of a biggest possible size, while having the shell of the hearing aid of a smallest possible size. A size of the shell is a more important constraint than a size of the vent. A big vent is desired by a patient to improve air circulation in the ear and to minimize the occlusion effect. The occlusion effect is minimized as the vent acoustic mass is decreased.
The vent designed by the present software techniques of the preferred embodiment is hereinafter known as the “vent-as-large-as-possible” and alternately is also referred to as a “size-maximized vent”.
In a vent designed as-large-as-possible the occlusion effect is comprised of two major sub-functionalities:
1. building the vent-as-large-as-possible for a given location of the components; and
2. insuring insertability of components principally including a receiver in the shell.
The receiver 7 and other components 5 are located in the housing shell as shown in
As shown in
At block 12, “BUILD THE REGULAR ROUND VENT OF A MINIMAL CROSS-SECTION AS A STARTER VENT IN THE STARTER SHELL” the computer constructs an initial vent or what is known hereafter as a “starter” vent 3 which is preferably substantially round in cross-section of relatively small dimensions and runs from the end 8A of the starter shell 8 (
In block 13, “GO BACK TO DETAILING AND SHAPE THE STARTER SHELL AROUND WHERE THE FACEPLATE WILL BE MOUNTED USING VENT PREVIEW”, a shape of an outer end 8B of the shell where the faceplate 16 is to be provided is designed. As shown in
In block 13, the continuous shell surface is created using the previously mentioned triangulation technique Material is also removed near the area where the faceplate is to be mounted to provide room for an opening for the vent and components to be mounted on the faceplate.
In block 14, “GO TO THE COMPONENTS STEP AND FINALIZE LOCATION OF COMPONENTS AS DEEP AS POSSIBLE IN THE STARTER SHELL”, the program does what is necessary to push the components as deep as possible into the starter housing shell without interfering with the starter vent 3.
At block 15, “REMOVE PORTIONS OF THE STARTER SHELL BEYOND WHERE THE FACEPLATE IS TO BE MOUNTED AND MOUNTING THE FACEPLATE”, a starter shell portion 4 having starter shell end 8BB beyond where the faceplate 16 is to be located are removed and the faceplate 16 is mounted.
At block 160, “GO TO THE NEXT STEP AND LET VENT TAKE UP SUBSTANTIALLY ALL FREE SPACE AVAILABLE TO CREATE THE VENT-AS-LARGE-AS POSSIBLE”, an algorithm looks at the shell 8, the location of the components, and the location of the minimal round vent, and increases a size of the starter vent 3 defined by wall 18C so that it occupies the space substantially not occupied by the components such as module 5 and the receiver 7 with receiver tube 7A which are situated in free space 21 inside the shell 8 (see
In block 170, “SELECTIVE FILL AND LABELING”, a selective fill and/or labeling is processed. Fill material is shown in
The material shown as cross-hatching in
Where the cut planes are provided depends upon a location of electronics such as electronics module 5, optional components, receiver 7, receiver hole 6, receiver tube 7A, and values of different preferences parameters that define a shape of the vent 18, vent end 18A and vent end 18B.
Vent design for the vent-as-large-as-possible of the preferred embodiment is very different from vent design for the previously mentioned prior art collection vent. A main difference is that for the collection vent design, an algorithm finds just a biggest contour that can accommodate the vent inlet. In the case of the vent-as-large-as-possible of the preferred embodiment herein, the vent inlet contour can be smaller than the vent inlet for the collection vent, because one needs to avoid collisions with the components and receiver hole, and adhere to other preferences settings not used for the collection vent. Another important difference between the existing prior art vents and the new vent-as-large-as-possible is that prior art vents are built without any consideration of component positions. The vent is built first, and then components are placed into the shell in the prior art. In the vent-as-large-as-possible first the starter vent is placed, then components such as volume control, push button, receiver, electronics module with battery, and microphone are placed as deep as possible in the starter shell, then the starter shell is cut to remove portions beyond where the faceplate is to be located, and then the starter vent is transformed into the vent-as-large as possible.
The shape of the vent end at 18A and vent end at 18B in
The workflow for vent placement design by the software for the vent-as-large-as-possible will again be described, but with some additional details with reference to
1. detail canal (FIG. 1—block 11);
2. go to vent step and place a starter vent, which is in a preferred embodiment a regular round vent (FIG. 1—block 12), possibly accompanied with canal tip modification, receiver and receiver hole placement—the starter vent is preferably the regular round vent of minimal cross-section;
3. go back to detailing, starter vent preview shown during the detailing (FIG. 1—block 13);
4. place electronics, hybrid, optional components and finish detailing—trim shell around the faceplate (FIG. 1—block 14);
5. go to the faceplate mounting step (FIG. 1—block 15) and after the faceplate mounting step the starter vent (regular round vent—block 12 in
6. proceed to a selective fill and/or labeling step (FIG. 1—block 170—a selective fill and labeling) which is selecting an area with a plane and filling it with material, and the labeling is the step of assigning an identification for the shell by engraving or embossing on an inside surface of the shell housing.
The software method of the preferred embodiment ensures that the vent-as-large-as-possible takes as much as possible space in the shell adhering to the constraints provided in the requirements (preference settings).
The software provides the ability to place the vent-as-large-as-possible starter vent (regular round vent) inside the shell in the following manner:
A. a starter section (regular round vent) is equal to a minimal cross-section area of the vent-as-large-as-possible defined in the preferences—for example if the minimal cross-section area as defined in the preferences is S, then a radius of a regular round vent is computed from the formula S=PI*r̂2, where r is the radius of the regular vent, and PI is 3.1415926;
B. a vent is always shown during a preview in detailing the vent-as-large-as-possible if the user has already placed the starter vent (regular round vent);
C. the software does not show the vent at all during the vent preview—in detailing the user has not yet placed the starter vent (regular round vent) for the vent-as-large-as-possible;
D. the software allows the user to place the starter vent (regular round vent) during the vent step—the software generates the vent-as-large-as-possible from the starter vent (regular round vent); and
E. The software builds the vent-as-large-as-possible on all shell types (CIC, Mini-Canal, Canal, Half-Shell, Full-Shell).
The software builds the vent-as-large-as-possible similar to a collection IROS (an IROS vent is an Ipsolateral Routing of Signal vent):
A. in the preferences the settings are provided for a maximal curvature of the vent end 18A wall—the software ensures that the inlet end 18A wall of the vent-as-large-as-possible does not violate a maximal curvature of the vent inlet end 18A wall defined in the preferences;
B. in the preferences the settings are provided for the maximal curvature of the vent outlet end 18B wall—the software ensures that the outlet 18B wall of the vent-as-large-as-possible does not violate the maximal curvature of the vent outlet end 18B wall defined in the preferences; and
C. the software builds the vent-as-large-as-possible inside the shell 8 similarly to a non-continuous D-shape vent as a straight segment with optional connecting segments—a D-shape vent is a vent which is built as a wall inside the shell with openings at the faceplate and the canal side,—normally this vent has a shape of a “D”.
The software of the preferred embodiment ensures or provides the following:
A. that the vent-as-large-as-possible has no collisions with any of the components (including receiver hole 6);
B. in the preferences, settings are provided for minimal cross-section area inside the vent in mm2;
C. in the preferences, the settings are provided for maximal cross-section area inside the vent in mm2 ;
D. in the preferences, different settings are provided for the vent-as-large-as-possible minimal and maximal cross-section area depending upon the shell type—this vent-as-large-as-possible minimal cross-section depending on the shell type is shown in
E. the vent inlet end 18A and outlet end 18B for the vent-as-large-as-possible 18 does not go outside the suggested vent inlet and outlet cut planes 22 and 23;
F. in the preferences the settings are provided for maximal allowed absolute gradient of two adjacent vent cross-section areas; and
G. the vent-as-large-as-possible generation algorithm (FIG. 1—block 160) ensures that an absolute gradient of adjacent vent slice areas is lower than a preference value—a gradient of adjacent vent slice areas is calculated as (a2−a1)/d, where a2 and a1 are areas of adjacent cross-sections, and d is a distance between cross-sections—if the absolute gradient of adjacent cross-section areas is higher than certain thresholds than this means that in these particular cross-sections the vent makes a large bend—it is desirable that the vent be smooth, therefore with the maximal and minimal ratio one is able to control the smoothness of the vent.
The software also provides for the following:
A. ensures that the hearing aid receiver 7 can be inserted into the shell 8 up to its final location given the vent-as-large-as-possible 18 placement;
B. ensures that the vent generation algorithm does not modify a position of components during the vent-as-large-as-possible 18 integration;
C. allows the user to apply the vent-as-large-as-possible 18 with one mouse click, provided that the starter vent (regular round vent) is already placed—the user interface comprises one button that applies the vent-as-large-as-possible, or the user may go from the faceplate step (FIG. 1—block 15) to the selective fill step (FIG. 1—block 170) and the vent-as-large-as-possible may be applied;
D. allows the user to remove the vent-as-large-as-possible 18 from the shell 8 if no other operation has been applied to the shell 8 after the vent-as-large-as-possible 18 is placed—this can be implemented with an undo button;
E. does not allow adaptive vent tapering on the vent-as-large-as-possible 18 (although the resulting shell 8 of the vent-as-large-as-possible 18 may look similar on the vent inlet end 18A side to the adaptive vent tapering);
F. allows to put into a script file the placement of the vent-as-large-as-possible 18 starter vent (regular round vent);
G. allows the user to position the receiver 7, electronics, hybrid and all optional components prior to the generation of the vent-as-large-as-possible 18 from the starter vent (regular round vent)—the user is not allowed to position the receiver 7, electronics, hybrid and all optional components after the generation of the vent-as-large-as-possible from the starter vent (regular round vent); and
H. does not allow the vent-as-large-as-possible 18 in a combination with RSA (RSA means Receiver Suspension Assembly which is a series of design steps for receiver placement).
While a preferred embodiment has been illustrated and described in detail in the drawings and foregoing description, the same is to be considered as illustrative and not restrictive in character, it being understood that only the preferred embodiment has been shown and described and that all changes and modifications that come within the spirit of the invention both now or in the future are desired to be protected