Eyeglass manufacturing method using variable index layer

FIELD OF THE INVENTION

The present invention relates generally to an eyeglass manufacturing method using a layer with a variable index of refraction. More specifically, the present invention pertains to patient-specific spectacle lenses manufactured with an variable index aberrator in order to more accurately correct lower order aberrations and additionally correct higher order aberrations. The present invention also provides a means for correcting vision problems caused by retinal dysfunction.

BACKGROUND OF THE INVENTION

Present manufacturing techniques for eyeglass lenses are capable of producing lenses that correct only the lower order (sphere and cylinder) aberrations. Customarily, lens blanks are available in discrete steps of refractive power of 0.25 diopters. In most cases, these steps are too large to create optimum vision for a patient's eye.

Current manufacturing techniques do not effectively treat vision problems resulting from retinal dysfunction. For example, in macular degeneration, patients suffer from vision loss in selective areas of the fundus, typically close to the center of vision. Laser treatment of the affected areas further destroys retinal tissue, causing blindness at the treated areas. Clinical studies have shown that the human eye and brain are capable of switching to other areas of the retina to substitute the damaged area with an undamaged area. In other words, damaged areas in the retina are essentially bypassed by the brain. Ultimately, vision loss will occur as a portion of an image falls on the damaged retina. Consequently, there is a need to manufacture an eyepiece such that the image may be “warped” around the dysfunctional tissue in order to allow the entire image to focus on the remaining healthy tissue.

In light of the aforementioned problems, the need for an optical element which generates a unique wavefront phase profile becomes apparent. Traditional manufacturing methods create such profiles through grinding and polishing. Such a method of manufacture is very costly due to the amount of time and expertise required.

SUMMARY OF THE PRESENT INVENTION

The present invention utilizes the technology developed by the wavefront aberrator in which a layer of variable index material, such as curable epoxy, can be sandwiched between two plane or curved glass or plastic plates. This sandwich is then exposed to the curing radiation (i.e., UV light) that is modulated spatially or temporally in order to create spatially resolved variations of refractive indices. This will allow the manufacturing of a lens that is capable of introducing or compensating for low and high order aberrations.

In the simplest form, two lens blanks are sandwiched together with a layer of epoxy such that the lenses used in conjunction approximately correct the patient's refractive spherical and cylindrical correction to within 0.25 diopters. Subsequently, the epoxy aberrator would be exposed to curing radiation in a pre-programmed way in order to fine-tune the refractive properties of the spectacle lens to the exact spherical and cylindrical prescription of the patient's eye.

Another application of the present invention is to manufacture multi-focal or progressive addition lenses constructed with a layer of variable index material sandwiched in between the two lens blanks. The drawback of progressive addition lenses today is that, like regular spectacle lenses, a true customization for a patient's eye cannot be achieved due to the current manufacturing techniques. Using the two lenses and epoxy, a customized progressive addition lens or reading lens can be manufactured by appropriately programming the curing of the epoxy aberrator.

The present invention provides a method to manufacture lenses that give patients “supervision.” In order to achieve supervision, higher order aberrations of the patient's eye need to be corrected. Since these higher order aberrations, unlike the spherical and cylindrical refractive error, are highly asymmetrical, centering of the eye's optical axis with the zone of higher order correction (“supervision zone”) is important. To minimize this effect, one could devise a spectacle lens that incorporates a supervision zone only along the central optical axis, allowing the patient to achieve supervision for one or more discrete gazing angles. The remainder of the lens would then be cured to correct only the lower order aberrations. An optional transition zone could be created between the supervision zone and the normal vision zone allowing for a gradual reduction of higher order aberrations. Again, all of this would be achieved by spatially resolved programming of the epoxy aberrator's curing.

In order to cover a larger field of view with supervision, a multitude of supervision “islands” might be created. The supervision islands then are connected by transition zones that are programmed to gradually change the higher order aberrations in order to create smooth transitions.

In bifocal lenses, refractive power in discrete steps of 1 diopter is added in the lower area of the lens to aid the spectacle wearer in near distance viewing, i.e. reading. For cosmetic reasons, the visible dividing line between the distance viewing area and the reading area is disliked by many presbyobic patients. With the event of the progressive addition lens, the sharp dividing line between the distance area and the reading area has been eliminated by introducing a continuous varifocal corridor of vision with a refractive power slowly changing from the distance viewing prescription to the reading prescription.

However, due to manufacturing limitations several disadvantages exist with the progressive addition lens. First, vision through areas outside the corridor is noticeably distorted, making the progressive addition lens unsuitable for many patients. Second, while the patient's individual prescription is applied to the distance viewing area, the added refractive power for the reading area is only offered in discrete steps of 1 diopter. Third, the distance between the centers of the distance viewing and reading viewing areas is fixed by the lens design and cannot be changed to accommodate for an individual's preference or application. Furthermore, the corridor design is fixed for any particular brand of lens and cannot be changed according to the patient's actual viewing preferences or spectacle frame selected.

Therefore, when prescribing a progressive addition lens, the eye care professional has to choose from an assortment of designs and manufacturers the lens which matches the requirements of the patient most closely. The present invention allows to manufacture a lens that is entirely customized and optimized to the patient's individual requirements.

Lastly, the present invention may be used to “warp” the retinal image so that damaged portions of the retina will be bypassed by the image. In order to do this, the visual field of the patient needs to be mapped with a perimeter or micro-perimeter. From this map of healthy retina, spectacle lenses could be manufactured using the epoxy aberrator.

DESCRIPTION OF THE DRAWINGS

The novel features of this invention, as well as the invention itself, both as to its structure and its operation, will be best understood from the accompanying drawings, taken in conjunction with the accompanying description, in which like reference characters refer to similar parts, and in which:

FIG. 1

is a perspective view of an eyeglass that incorporates a supervision zone for long distance viewing;

FIG. 2

shows a cross sectional view of

FIG. 1

;

FIG. 3

shows a top view of a progressive addition lens, which includes a supervision zone and a reading zone;

FIG. 4

shows a top view of a reading or special application lens;

FIG. 5A

shows a top view of a lens including multitude of supervision islands, which cover a larger view with supervision;

FIG. 5B

shows a top view of a multi-focal lens including a multitude of reading islands, allowing for far vision correction and simultaneous reading correction;

FIG. 6

shows a text object imaged onto a damaged retina;

FIG. 7

shows the image of the same object as

FIG. 6

from the patient's perspective;

FIG. 8

shows the patient's view of the image after the brain shuts down the damaged retina;

FIG. 9

shows an image focused on a damaged retina, with a corrective lens in place;

FIG. 10

shows the image as the patient initially sees it;

FIG. 11

shows the image as the patient sees it after the brain shuts down the damaged retina; and

FIG. 12

shows a sequence of manufacture for the present invention.

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT

Referring initially to

FIG. 1

, a lens assembly that incorporates a supervision zone is shown and generally designated

100

.

FIG. 1

shows that the lens assembly

100

includes an upper lens

102

, a variable index layer

103

, and a lower lens

104

. In a preferred embodiment, the variable index layer is made of ultra-violet curing epoxy which exhibits an index of refraction that can be changed by exposure to ultraviolet radiation. However, it is to be appreciated that other materials which exhibit similar characteristics, namely a variable index of refraction, may be incorporated into the present invention without departing from the spirit of the invention.

The variable index layer

103

makes up the normal vision zone

106

, the transition zone

110

, and the supervision zone

108

, where the epoxy at each zone is cured to a specific index of refraction. The normal vision zone

106

corrects the lower order spherical and cylindrical aberrations of the patient's eye. The transition zone

110

allows for a gradual reduction of higher order aberrations. The supervision zone

108

lies along the patient's optical axis (not shown) and corrects the higher order aberrations allowing the patient to achieve supervision for one or more discrete gazing angles. The shape of the lens

100

is meant to be exemplary of the shape of a typical eyeglass lens, and any shape, including highly curved lenses, may be used while not departing from the present invention.

Referring now to

FIG. 2

, a cross section of lens

100

is represented such that upper lens

102

has a thickness

112

, epoxy layer

103

has a thickness

116

, and the lower lens

104

has a thickness

114

. The epoxy layer

103

is sandwiched between the upper lens

102

and the lower lens

104

and is held in place by a stopper

118

.

Description of Alternative Embodiments

Referring now to

FIG. 3

, an alternative embodiment of the present invention is illustrated as a progressive addition lens and generally designated

200

.

FIG. 3

shows a top view of a transition lens

200

in which there is a supervision zone

202

, a transition zone

204

, and a short distance viewing zone

206

. The normal vision zone

208

of the progressive addition lens

200

is corrected for the lower aberrations. Again, the creation of the various vision zones is by means of selectively curing the epoxy aberrator sandwiched between two glass (or plastic) blanks, not through the traditional means of grinding or molding these features into a blank. The transition lens

200

has a similar cross section as of that depicted in FIG.

2

.

Referring now to

FIG. 4

, another alternative embodiment of the present invention is illustrated as a reading lens and generally designated

300

.

FIG. 4

shows a top view of a reading lens

300

in which there is a supervision zone

302

, a transition zone

304

, and a normal vision zone

306

. The reading lens

300

has a similar cross section as of that depicted in FIG.

2

. The supervision zone

302

may be used for, but not limited to, high-resolution applications such as reading, precision close up work, etc.

Referring now to

FIG. 5A

, an alternative embodiment of the present invention is illustrated as a supervision lens that covers a larger field of view and is generally designated

400

.

FIG. 5A

shows a top view of a supervision lens

400

in which there is a plurality of supervision islands

402

, and a transition zone

404

. The plurality of supervision islands

402

create a larger field of view for the patient, while the transition zone

404

is manufactured to gradually change the higher order aberrations in order to create smooth transitions.

Referring now to

FIG. 5B

, another alternative embodiment of the present invention is illustrated as a multi-focal lens that allows for simultaneous correction for far vision and reading vision and is generally designated

450

.

FIG. 5B

shows a top view of a multi-focal lens

450

in which there is a plurality of optical islands

452

, each representing the patient's reading prescription while the background zone

454

represents the patient's far vision prescription, or vice versa. Ideally, the diameter of the optical islands is in the order of 100 microns so that a maximum number of optical islands falls within the typical pupil size of 2 to 6 mm diameter.

One special application of this invention is the use for correcting vision problems caused by retinal dysfunction, i.e., by eye diseases like glaucoma or macular degeneration.

FIG. 6

shows an eye generally designated

500

, in which an object

502

is imaged by the eye's cornea and lens

504

onto the inner surface of the eye

500

where there is damaged retinal tissue

506

. The patient initially sees only a portion of the image and an obstruction, as shown in FIG.

7

. Eventually the brain shuts off the damaged portion of the retina and the patient's view no longer includes the obstruction, such a view is represented in FIG.

8

. Although the patient no longer sees an obstruction, a portion of the image remains unseen. The present invention is capable of correcting this phenomenon as illustrated in

FIGS. 9-11

.

FIG. 9

again shows an eye generally designated

600

, in which an object

602

is imaged through the eye's cornea and lens

604

onto the inner surface of the eye

600

where there is damaged retinal tissue

606

. However, a lens

608

manufactured using the epoxy wavefront aberrator is placed in front of the eye

600

. The retinal image

609

of the object

602

is warped around damaged retinal tissue

606

such that none of the image

602

is lost.

FIG. 10

shows the image the patient sees. As previously mentioned, over time the brain will terminate the signals generated by the damaged retinal tissue

606

and the patient will see the entire image

602

as shown in FIG.

11

.

FIG. 12

shows a flow chart in which the manufacturing steps of the present invention are disclosed and generally designated

700

. First the patient's eye must be imaged in order to determine the wavefront prescription. Second, both the upper and lower lenses must be selected. This selection corrects both the patient's spherical and cylindrical aberrations to within 0.25 diopters. Next, one side of the first lens is coated with epoxy. The second lens in then placed on the epoxy coated surface of the first lens, such that the epoxy is sandwiched between the two lenses. Finally the epoxy is cured to match the wavefront prescription.

While the different embodiments of the present invention as herein shown and disclosed in detail is fully capable of obtaining the objects and providing the advantages herein before stated, it is to be understood that it is merely illustrative of a preferred embodiment and an alternative embodiment of the invention and that no limitations are intended to the details of construction or design herein shown other than as described in the appended claims.