BACKGROUND OF THE INVENTION

The present invention is directed to a device for automatically measuring both the near and far visual acuity of a patient's eyes in a simple and objective manner.

At the present time, there are basically two methods for measuring the visual acuity of the eyes. One of these methods utilizes information provided by the person being tested (subjective testing) and the other method uses external measuring devices (objective testing). In the subjective method, vision testers such as charts, etc. have been widely used for many years. However, these vision testers provide no accurate measurement because they rely on the personal evaluation of the patient in comparing the images of a target while various corrective lenses are placed in front of the eyes. Subjective tests are particularly unsuitable for measuring the visual acuity of children's eyes. For example, this year in the United States, over 2-1/2 million six year old children will enter more than 60,000 elementary sehooLs The American Association for the Prevention of Blindness estimates that one out of every twenty preschool children has a vision problem which, if uncorrected, will interfere with the child's development and education. Young children are unable to subjectively determine whether their vision is "good" or "bad". These young children cannot respond to conventional chart tests because they cannot read. Special devices such as the Landolt C and Pointing E are used to test the visual acuity of children. Since all these tests are subjective, special training and high motivation are necessary in order to obtain

accurate measurements. Consequently, subjective testing methods are difficult to administer, unreliable, time-consuming, and totally impractical for mass vision testing of preschool children.

Objective testing methods are much more effective in measuring the visual acuity of the eyes, particularly the eyes of children. Although automatic objective measuring devices are now available on the market, these devices are not practical for mass vision testing. Existing devices must be operated by trained specialists, usually optometrists or ophthalmologists and they generally are large pedestal mounted devices which occupy a great amount of space and are not portable. Also, since these existing objective devices are complex mechanisms with considerable electronics, the price of these devices is prohibitively high.

As a result of these disadvantages of the existing objective devices, visual acuity is often determined through the use of the Snellen letter chart in which the threshold letter size for the subject is found and converted to a visual acuity measurement. This procedure is subject to several subtle variables which can significantly affect the outcome. For example, inappropriate room lighting, test lamp aging, failure of the examinee to cover each eye properly, examiner recording error and inherent testing pressures all affect the visual acuity measurement. Furthermore, the results of such a visual acuity measurement again are often seriously effected by the desires of the patient. Thus, it is often difficult to ascertain the visual acuity of the patient using such charts and other similar subjective devices. A number of objective devices have been proposed which overcome some of the disadvantages of the subjective devices but which do not overcome all the previously mentioned disadvantages of the objective devices. In the United States Patent 3,824,005 issued to Westman on July 16, 1974, a refractometer is shown in which the eye observes a target image and the reflected light from the retina of the patent's eye is transformed into an electrical signal that reaches a peak when the target image on the retina is in focus. The apparatus includes a primary bar or target which is illuminated by a light source and observed by the patient's eye through various lenses. The target image formed on the retina is reflected via a beam splitter to a photodetector

O

Λ, WI

which is connected to a circuit arrangement to generate an electrical signal related to the visual acuity of the eye. A secondary bar pattern, which is identical to the primary target pattern, is positioned between the beam splitter and the photodetector and vibrated by a vibrator to periodically block and unblock the reflected target image from the retina of the patient's eye. When the patient's eye is in focus on the primary target pattern and the secondary bar pattern is not in a blocking position, the intensity of the light detected by the photodetector is at a maximum. In addition, the primary target pattern is constantly moved toward and away from the patient's eye to permit the image of the primary target pattern to be periodically in focus on the retina of the eye regardless of its refracted state. As a result, the measurement of the position of the axially moving primary target at the instant the amplitude of the light transmitted through the secondary bar pattern is at its maximum will provide an indication of the refractive state of the patient's eye.

Another prior art system is shown in United States Patent

3,888,569 issued to Munnerly et al on June 10, 1975 in which a refractometer is shown having an adjustable compensating lens system for focusing the target image on the retina of the eye. The primary target pattern in the Munnerly patent is movable and the secondary pattern positioned adjacent the photodetector is fixed. The signal received by the photodetector is a function of the focus of the image of the primary target pattern on the retina of the eye. A sharply focused bar pattern produces a less intense signal. The visual acuity of the patient's eye is ' calculated by a computer which controls the focus and position of the patterns and selects and stores results from the signal detected by the photodetector. A compensating lens system is also provided in the Munnerly patent which is controlled by the digital computer and used to adjust the focus of the patient's eye. Several prior art patents show refractometers and other visual acuity measuring devices which include a pulsating light source. For example, in United States Patent 4,021,102 issued to Iizuka on May 3, 1977, a refractometer is shown including a pair of infra-red light sources which are alternately flickered. The light beams generated by the light sources are pased through a vertical slit which is movable to permit

OMPI

focus of the slit image on the retina of the patient's eye. The slit image on the retina is reflected via a prism to a pair of photodetectors. The difference between the signals detected by the pair of photodetectors is then measured and, if no difference is detected, the visual acuity of the patient's eye is normal. However, if the eye is myopic or hyperopic, the slit image is not properly focused on the retina and the reflected slit image detected by the photodetectors results in a DC difference which actuates a compensating lens system to automatically correct the focus of the eye, Finally, a number of other prior art patents show refractometers which use a primary target pattern for measuring the visual acuity of the patient's eyes. Some of these prior art patents use flashing or pulsating sources of light such as United States Patent 3,843,240 issued to Consweet on October 22, 1974. Others of these prior art refractometers and other visual acuity devices use a target pattern which is illuminated by a light source which is periodically interrupted by rotating drums or reticles. For example, the Munnerly patent cited above shows a rotating drum or reticle for interrupting the beam of light directed through the target pattern to the patient's eye. Although all the above prior art devices objectively measure the acuity of a patient's eyes, and provide accurate and automatic arrangements for measuring visual acuity, these devices are not practical for mass vision testing because they require trained specialists for operation, they are large and complex mechanisms, and they are prohibitively expensive. Furthermore, these prior art devices generally are not flexible enough to measure both near and far visual acuity. SUMMARY OF THE INVENTION

The primary object of the present invention is to provide a visual acuity device which overcomes the above mentioned disadvantages of the prior art visual acuity devices and is both simple to operate and inexpensive. In particular, it is an object of the present invention to eliminate the complex lens systems, the complicated mechanics, the extensive electronics and the photomultipliers of the prior art visual acuity devices. It is a further object of the present invention to provide a

OM

visual acuity device which is accurate, easy to use, compact, portable, and highly reliable. In this regard, operation by trained specialists is not required because the simple design of the present invention makes operation with accurate results available almost to any person. In addition, large, pedestal type devices are replaced by the easily portable visual acuity device of the present invention. These features, together with the low cost of the visual acuity device of the present invention, make mass vision examination of preschool children practical.

It is also an object of the present invention to provide a visual acuity device for measuring both far and near visual acuity. In this regard, it is an object of the present invention to provide different types of read-out devices for indicating near and far visual acuity including continuous read-out of visual acuity in either digital or analog form. It is a further object of the present invention to provide a visual acuity device that simultaneously detects the in-focus signal reflected from the patient's eye and cancels the out-of-focus signal or glare. Furthermore, it is an object of the present invention to provide a visual acuity device which uses a primary pattern having a relatively large area so that the total light directed on the patient's eye is much greater and, as a result, a stronger reflected signal is generated for easier detection.

The present invention is a visual acuity device for measuring the visual acuity of a patient's eyes by projecting an image on the eye which corresponds to a primary pattern; the focus of the image on the patient's eye is then detected. The visual acuity of the eye corresponds to the line spread of the reflected image of the primary pattern. A discussion of the correspondence between line spread and visual acuity can be found in the technical article "Optical Quality of the Human Eye" by E. W. Cambell and R. W. Gubisch, Journal of Physiology, 186: pp. 558-578 (1966). Although correspondence between line spread and visual acuity has been known for some time, the present invention is directed to a unique arrangement for determining visual acuity by measuring line spread. In particular, the visual acuity device of the present invention

is a combination of an optical system for projecting an image on the patient's eye and receiving the reflected image and a signal detection circuit for generating a signal in response to the reflected image which corresponds to the visual acuity of the eye. A light source is provided for producing a pulsating beam of light which is transmitted to the patient's eye by the optical system. The optical system includes a primary pattern which is positioned near the light source in the direct optical path of the beam of light. The primary pattern is mounted in a fixed position and it has a pattern consisting of a plurality of interleaved transparent and non-transparent portions. An image of the primary pattern is reflected by the retina of the patient's eye and transmitted by the optical system to a pair of analyzer or secondary patterns which are also mounted in a fixed position. One of the analyzer or secondary patterns has a pattern which substantially corresponds to the pattern of the primary pattern and the other has a pattern which is the negative or opposite of the pattern of the primary pattern. In other words, one of the analyzer or secondary patterns admits the in- focus image of the primary pattern reflected from the patient's eye and the other analyzer or secondary pattern blocks the in-focus reflected image. A photoelectric device is associated with each of the analyzer or secondary patterns for detecting the pulsating light reflected from the patient's eye through each of the analyzer patterns. The signal detection circuit is connected to these photoelectric devices to measure the difference between the electric signals generated by these photoelectric devices to thereby cancel the out-of-focus glare in the reflected image. The resulting difference signal is then used in any one of a number of ways to determine the visual acuity of the patient's eye.

In one embodiment, the visual acuity of the patient's eye is measured by directly measuring the difference signal with a peak hold detector and a DC voltmeter. In more sophisticated embodiments, visual acuity can be measured by using digital pulse techniques by connecting the peak hold detector to an encoder/decoder circuit which drives an LED display to indicate the visual acuity. Timing signals also can be provided to synchronize the operation of the signal detection circuit for

OMPI

measuring visual acuity with the pulsating beam of light. In addition, visual acuity can be measured by adjustment of a lens set, a compensating lens, etc. to focus the target image on the retina of the eye together with observation of the difference signal generated by the signal detection circuit. In this latter case,when the eye reflects an in-focus image, the visual acuity can be determined by the position of the compensating lens, the power of the particular lens of a lens set, etc. All these variations of the electronic arrangement can be used in the present invention to simply and easily measure the visual acuity of the patient's eye.

Finally, the visual acuity device of the present invention also can be used to measure far visual acuity. A pulsating infrared light source together with a coUimating lens prevents accommodation by generating para_le_rinfrared light rays to make the primary fixation pattern appear at optical infinity. The reflected image is then transmitted through a compensating lens and the secondary patterns for detection by the photoelectric devices. The electronic circuit connected to the photoelectric devices then generates a signal which is used to indicate the far visual acuity of the eye. BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 is a diagram showing a top view of the arrangement of the housing of the visual acuity device.

Figure 2 is a diagram showing the optical system for one embodiment of a near visual acuity device of Figure 1. Figure 3 is a diagram showing the optical system for one embodiment of a far visual acuity device according to the present invention.

Figure 4 shows a portion of a radial pattern for the primary pattern. Figures 5A-C show reflected images of the radial pattern of

Figures 4 demonstrating differences in line spread for 20/20, 20/200 and 20/400 vision, respectively.

Figures 6A-C show a modified radial pattern for the primary and analyzer patterns. Figure 7 A shows an equal area pattern for the primary pattern;

OMPI

Figure B is a diagram illustrating the equal areas of the equal area pattern of Figure 7A; and Figure 7C shows a linear graph of visual acuity versus signal strength for the equal area pattern.

Figure 8 shows a first embodiment of the signal detection circuit of Figures 2 and 3 having a DC voltmeter output.

Figure 9 shows another embodiment of the signal detection circuit of Figures 2 and 3 having an AC voltmeter output.

Figures 10 and 11 show additional embodiments of the signal detection circuit of Figures 2 and 3 having digital readouts. Figure 12 shows a schematic diagram of another embodiment of the optical system and the signal detection circuit of the present invention.

Figure 13A-C show waveforms generated by the signal detection circuit of Figure 12. Figures 14-18 show additional modifications of the signal detection circuit of Figures 2 and 3. DETAILED DESCRIPTION OF THE DRAWINGS

The housing 2 of the pulse pattern visual acuity device of the present invention is shown in Figure 1. The housing 2 contains a power supply 4 for supplying power to the flash tube circuit . 6 which contains a flash tube 8 as illustrated in greater detail in Figures 2 and 3. The flash tube circuit 4 and the flash tube 6 together form a pulsating light source which generates a pulsating beam of light 10 directed to the eye of a patient under examination. The pulsating beam of light 10 is transmitted to the eye 12 by an optical system 16. The optical system

16 also transmits a reflected image from the eye 12 to a signal detection circuit 18 which is connected to a display device 20, such as a display meter, to display the visual acuity measurement of the patient's eye.

Although the basic elements of the optical system are shown in the housing 2 of Figure 1, additional details of the optical system 16 for a near vision visual acuity device are shown in Figure 2 and additional details for a far vision visual acuity device are shown in Figure 3. A primary pattern 22 is positioned adjacent the flash tube 8 so that the pulsating beam of light 10 passes along channel 25 from the flash tube 8 through the primary pattern 22 to the patient's eye 12. As a result,

O

the retina of the patient's eye 12 reflects an image of the primary pattern 22 in a manner generally known in the art. Any pattern may be used as the primary pattern 22. However, it should be noted that the measurement of visual acuity according to the present invention depends on the analysis of the line spread of the reflected image of the primary pattern from the retina of the eye 12. The relationship between line spread and visual acuity is discussed in the article entitle "Optical Quality of the Human Eye" by F. W. Cambell and R. W. Gubisch, Journal of Physiology 186: pp. 558-578, 1966. Since the measurement of visual acuity according to the present invention is a function of line spread, the size and layout of the primary pattern 22 must be taken into account in adjusting the visual acuity device to measure visual acuity. An example of a radial pattern 22 is shown in Figure 5A whereas an example of an equal area primary pattern 22 is shown in Figure 7A. In addition, a fixation cross 24 is positioned in front of the primary pattern 22 to provide a fixation point for the eye 12 of the patient. The fixation cross 24, which is generally known in the art, may consist of a pattern of alternating red/green/blue/yellow fixation crosses. The flash tube 8 and the flash tube circuit 6 generate a light pulse at the rate of approximately 50Hz or approximately one per second. These light pulses form the pulsating beam of light 10. A pulsating beam of light 10 is used to dramatically increase the peak power more than 1000 times without an increase in average power. By increasing peak power, relatively insensitive, but very simple and very low cost, semiconductor photodiodes 42 and 44 can be used as described in further detail below. The use of this pulsating beam of light 10 results in considerable improvement in the signal to noise ratio of the visual acuity device. In addition, the pulsating beam of light 10 preferably is infrared light. An infrared filter 14 is positioned between the flash tube 8 and the primary pattern 22 as shown in Figures 1-3. The use of infrared light prevents photophobia since the pulsating beam of light 10 is more than 1000 times brigher than a continuous light source of the same average power. Pulsed visible light would blind the eye whereas infrared light is invisible to the eye. In addition, the low level of visible light,

^ ^∑ ij

the pupil expands to enable a stronger reflected signal, that is, more light enters the eye and more light is reflected. A larger, normal size pupil results in visual acuity measurements which are more accurate. In measuring far vision visual acuity as shown in Figure 3, an infrared pulsating beam of light 10 is used as well as a luminous fixation crosspoint 24 in a darkened field so that the eye is unable to focus and the lens of the eye is relaxed in a normal, far vision state. Accommodation of the eye is avoided by using a luminous fixation crosspoint 24 which appears at optical infinity. It should be noted that the internal dimensions of the housing

12 of the visual acuity device are small. The distance from the eyepiece 28 to the primary pattern 22 is only 14 inches. For measurement of near vision with the visual acuity device, the positioning of the primary pattern 22 at a distance of 14 inches forces near vision accommodation. The distance of 14 inches is the normal reading distance at which near vision is measured. On the other hand, for measurement of far vision, several modifications must be made in the apparatus as illustrated in Figure 3 and described in further detail below.

The pulsating beam of light 10 generated by the flash tube 8 passes through the infrared filter 14, the primary pattern 22 and the fixation cross 24 to a beam splitter 26. The primary function of the beam splitter 26 is to direct the reflected image of the primary pattern on the retina of the eye 12 along a different path from the pulsating beam of light 10. An anti-reflective device or glare stop 46 is provided adjacent the beam splitter 26 to reduce the amount of glare generated in the housing 2 by the reflection of the pulsating beam of light 10 as well as the reflected image from the retina of the patient's eye 12. The reflected image of the primary pattern 22 from the retina of the eye 12 is directed to the beam splitter 26 as shown in Figures 1-3. The beam splitter 26 splits the reflected light from the eye 12 and directs the reflected light toward the prism 30 which is positioned in the reflection channel 48. The prism 30 redirects the reflected light along the refleetio channel 48, thereby enhancing the compactness of the housing 2, toward the beam splitter 32. The beam splitter 32 again splits or evenly divides the reflected light to each of a pair of analyzer

O Λ, WI

or secondary patterns 34 or 36. One of the analyzer patterns is positive or admits the in-focus image reflected from the retina of the eye 12 while the other analyzer pattern is negative and blocks the in-focus image reflected by the retina. In other words, the pattern of one of the analyzer patterns is essentially the same as the primary pattern 22 while the other is the opposite or the negative of the primary pattern 22. For example, in Figure 6B, one of the radials of a radial analyzer pattern is shown which is substantially the same as the primary pattern shown in Figure 6A. The other analyzer pattern associated with the analyzer pattern in Figure 6B is the opposite of or the negative of the analyzer pattern in Figure 6B.

As mentioned above, in the pulse pattern visual acuity device, visual acuity and line spread are determined by the size of the figures in the primary pattern and the percent of the primary pattern that is admitted or blocked by the analyzer patterns. First, small figures are used to measure high visual acuity and large figures are used to measure low visual acuity. For example, a pattern with tiny 0.5 millimeter squares (checkerboard, 50 percent transparent and 50 percent opaque) would produce a signal only with high visual acuity. Large 5 millimeter squares would produce a signal either with high or low visual acuity, and a slightly higher signal with higher visual acuity.

Secondly, if the analyzer patterns have openings less than 50 percent, more line spread (more blur) is required to reduce the analyzer signal. Referring to Figure 6A, one of the radials of the primary pattern 22 is shown having successive opaque and transparent portions at 10 degree intervals. In practice, the primary pattern is not quite 50/50 because refraction at the edges of the pattern and at the pupil causes a small amount of line spread. So the primary pattern 22 in Figure 6A actually would appear to be 9.5 degrees open and 10.5 degrees closed. Referring to the analyzer pattern of Figure 6B, in order to make alignment easier with the primary pattern, the analyzer patterns for the primary pattern in Figure 6A are 6 degrees open and 14 degrees closed. Figure 6C shows the changes in the require line spread in relation to the radial distance. At the outer region of the pattern, larger line spread is required whereas near the center of the pattern

small line spread affects the resulting signal. This is further illustrated in Figures 5A-5C where the line spread of a radial pattern for different visual acuity measurements is shown. Figure 5A shows line spread for normal vision; Figure 5B shows line spread for 20/200 vision in which the center portion of the pattern is blurred and the line spread of the outer portion of the pattern is observable; and Figure 5C shows line spread for 20/400 vision in which a large portion of the central region of the pattern is blurred and only the outermost region of the pattern is observable. In other words, Figures 5A-C essentially show the image of the primary pattern reflected by the retina of the patient's eye 12. _h accordance with the present invention, these different reflected images are used to generate electrical signals which determine visual acuity.

Differences in visual acuity measurements can be more easily differentiated with finer radial patterns such as a radial pattern which is 5 degrees open and 5 degrees closed because the figures are smaller. These finer radial patterns operate to clearly differentiate small differences in order to detect amblyopia or lazy eye, which if not corrected at an early age can lead to blindness. By using the finer 5 degree pattern, however, the overall measurement range of visual acuity is reduced. For a wide range of visual acuity measurements, there should be both small and large figures, hence an equal area pattern such as shown in Figure 7 A is used. However, it is noted that the same desired result can be achieved with radial patterns by adjusting the size of the openings of the analyzer patterns, that is, providing analyzer patterns having openings less than 50 percent requires more line spread in order to reduce the analyzer signal. In summary, the primary pattern 22 is either positive or negative (as in a transparency with opaque emulsion) and one of the analyzer patterns is negative and the other one is positive. The primary pattern 22 could be asymmetrical or symmetrical,, but in either event, the analyzer patterns 34 and 36 must be positive-negative mirror images of each other.

Returning now to Figures 1-3, the two fixed analyzer or secondary patterns 34 and 36 are essential to the operation of the visual acuity device of the present invention. These analyzer patterns 32 and 36 are used to detect the contrast, that is, light and dark areas of the primary

pattern as seen by the eye 12 and reflected by the retina. One of these analyzer patterns admits the 'light" areas and the second anaylzer pattern blocks the "light" areas of the primary pattern. These patterns 34 and 36, like the primary pattern 22, can be symmetric or asymmetric. Even an ordinary photographic trnasparency of a street scene could be used to make the patterns as long as the primary pattern is either positive or negative and the analyzer patterns consist of one negative and one positive pattern. For simplicity, however, a symmetrical pattern is preferred. A pair of lenses 38 and 40 are positioned behind the analyzer patterns 34 and 36, respectively. These lenses concentrate the reflected light passing through the analyzer patterns 34 and 36 and direct the reflected light to a pair of photodiodes 42 and 44, respectively. These photodiodes 42 and 44 are electrically connected to the signal detection circuit 18. The analyzer patterns 34 and 36 pass the reflected image of the retina of the eye 12 and the signal detection circuit detects the electrical difference signal in the two photodiodes 42 and 44. Essentially, this combination of positive and negative analyzer patterns 34 and 36 together with the detection of the different signal by the signal detection circuit 18 eliminates or cancels the glare in the optical system so that visual acuity can be accurately measured. The signal detection signal 18 basically comprises a differential amplifier, a filter or slicer, and a display circuit including a display device. Various modifications can be made in this signal detection circuit to achieve automatic operation, etc. as described in further detail below.

The optical system 16 for the near vision visual acuity device is shown in detail in Figure 2. In measuring near vision line spread, the overall optics provide a type of autocollimation because, when the primary pattern 22 is in focus at the retina of the eye 12, the eye reflects the in-focus image to the analyzer patterns 34 and 36. It should also be noted that for near vision measurement, dl=d2 and dl+d3 (dl is 20 to 26, d2 is 26 to 34 or 36, and d3 is 26 to 12) = 14 inches, which is the standard reading distance. Several different techniques can be used for determining the near vision visual acuity. First of all, a trial lens set 50 may be used in which the lenses are varied in order

to obtain the maximum signal at the display meter 20 through the signal detection circuit 18. The visual acuity then would be determined by the particular lens used to achieve the maximum signal. The lens set 50 could be constructed of individual lenses in a revolving turret, a single compensating lens moved to and fro or a combination of two or more lenses moved closer/farther apart. When a lens set 50 is used, the visual acuity device functions as an automatic refractometer. Alternatively, visual acuity can be measured by changing the size of the primary pattern 22 where the pattern size itself is related to visual acuity. Finally, the signal strength of the signal generated by the signal detection circuit 18 corresponds to line spread which in turn corresponds to visual acuity. In other words, visual acuity is proportional to the signal strength of the signal detected by the signal detection circuit 18 and displayed on the display device 20. The display device 20 can be calibrated to indicated visual acuity. This technique can also be combined with the use of the trial lens 50 by observing whether the signal strength increases or decrease when a plus or minus trial lens is used thereby indicating diopters. That is, for plus or minus diopter determination, a small plus or minus diopter lens flips into the visual path. By observing whether the signal increases, the plus or minus diopter determination can be made. As described in further detail below, the insertion of different lenses into the visual path can be performed automatically using a simple logic circuit with an output to the display device 20 which may be an LED indicator and by pushing a button on a panel to cause the lens to be flipped into place.

When a radial primary portion such as shown in Figure 4 is used, signal strength is proportional to the visual acuity. In this radial pattern, closed and open portions occur at 10 degree intervals. Since the actual distance between the opaque sections of the radial pattern in Figure 4 is different for area A and area B, the line spread measurement or signal strength will vary as a function of visual acuity. For example, as shown in Figure 5, line spread is blurred in the central portion of the radial pattern for 20/200 vision and it is even further blurred for 20/400 vision. It is also possible to construct a primary pattern 22 in which

visual acuity is linearly related to the signal strength or line spread. The line pattern 22 shown in Figure 7A is an equal area pattern in which area A of the pattern in Figure 7A corresponds to 20/20 vision and consists of one-fifth of the total area; area B corresponds to 20/60 vision and consists of one-fifth the total area; area B corresponds to 20/60 vision and also is one-fifth the total area; each of areas C, D and E is one-fifth the total area and correspond to vision measurement up to 20/400. These respective areas are shown diagram matically in Figure B as being equal to each other. The equal areas pattern of Figure 7A is geometrically expanded paatern in which areaa A-E are continuous to obtain proportionally linear measurements from 20/20 to 20/400. Thus, for this equal area primary pattern 22, signal strength is linearly related to visual acuity as illustrated by the graph in Figure 7C. Turning now to Figure 3, a far vision acuity device is shown therein in which a collimating lens 52 is inserted in the optical path of the pulsating beam of light 10. The collimating lens 52 provides parallel infrared rays in the pulsating light beam 10 so that the fixed pattern appears at optical infinity. In addition, an adjustable compensating lens 54 is inserted in the optical path of the reflected image between the beam splitters 26 and 32. The compensating lens 54 makes the distance between the beam splitters 26 and 32 appear to be at optical infinity so that an in-focus reflected image from the retina of the eye would be sharply reproduced at the analyzer or secondary patterns 34 and 36. Finally, it is noted that the lens of the eye 12 must be unaccommodated for measurement of far visual acuity. Therefore, the pulsating beam of light 10 must be infrared and a luminous fixation point must be used to prevent accommodation. If far vision visual acuity is not normal, a sharply reproduced reflected image of the primary pattern 22 can be obtained at the analyzer patterns 34 and 36 by either adjustment of the lens set 50 or by adjustment of the compensating lens 54. The adjustment of the lens set 50 or the adjustable compensating lens 54 produces a maximum signal on the display device 20 through the signal detection circuit 18. This adjustment corresponds to the patient's visual acuity. In addition, visual acuity can be obtained

OMPI

by a direct measurement of the signal strength of the signal generated by the signal detection circuit 18. Also as shown in Figure 3, a timing circuit 56 can be provided for controlling the signal detection circuit 18 as well as the flash tube circuit 6. This timing circuit 56 can also be used to automatically drive or move the adjustable compensating lens 54.

A basic signal detection circuit 18 is shown in Figure 8. The differential amplifier connected to the photodiodes 42 and 44. Since one of these photodiodes 42 and 44 detects the reflected image which is admitted by one of the analyzer or secondary patterns 34 and 36 and the other photodiode detects the blocked reflected image, the difference signal generated by the differential amplifier 58 balances out or cancels glare and an in-focus signal appears at the output of the differential amplifier 58. Although it is possible to use a filter 68 and an AC voltmeter 70 as shown in Figure 9 to measure the signal strength of the signal generated by the differential amplifier 58, in general, this is not a practical alternative because of the small amount of light reflected by the retina and the low frequency of the pulsating beam of light 10. Thus, as illustrated in Figure 8, the signal generated by the differential amplifier 58 is provided to a filter or slicer 60. The filter 60 reduces spectral noise of the type 1/f by the square root of f. FOr example, if flash frequency is l/1200th second and the filter 60 is a 1000Hz filter, the signal to noise ratio can be improved by the square root of 1000. The significance of improving the signal-to-noise ratio means that either the power of the pulsating beam of light 10 can be reduced or the pulse rate can be increased for the same unfiltered signat-to-noise ratio. The output of the filter 60 is then supplied to the peak hold detector 62. The peak hold detector 62 holds the peak signal generated by the differential amplifier 58. As a result, despite changes in accommodation during examination of the patient's eyes 12 as well as the use of a pulsating beam of light 10, a continuous output signal can be obtained for the DC voltmeter 64. The DC voltmeter 64 can be calibrated to indicate the signal strength of the signal detected by the differential amplifier 58 so that the visual acuity can be determined by any one of the methods described above. Finally, the

peak hold detector can be reset by acutation of the reset switch 66.

It should be noted that the photodiodes 42 and 44 should receive equal amounts of light from the beam splitter 32 in order to properly measure visual acuity. An imbalance in the amount of light detected by the photodiodes 42 and 44 can be corrected by adjusting the common mode rejection resistor of the differential amplifier 58. This differential amplifier 58 is a balanced amplifier since the signal common to the inputs of the differential amplifier 58 can be balanced. A common mode rejection ratio of up to 120 db is possible by adjustment of the differential amplifier 58 and 85 db is easily obtainable.

The visual acuity device of the present invention can be used to measure the visual acuity of the eye 12 using digital pulse techniques as illustrated in Figures 10 and 11. In Figure 10, the output of the peak hold detector 62 is connected to an analog-to-digital converter 72 for converting the analog output of the peak hold detector 62 to a digital signal. The digital signal from the analog-to-digital converter 72 is encoded and decoded by the encoder /decoder 74. The encoder /decoder 74 also includes a driver circuit for driving circuit for driving the light emitting diodes of the LED display device 76. THe LED display device 76 displays a digital read-out of the signal strength of the output signal of the differential amplifier 58. In addition, the output of the analog- to-digital converter 72 can be connected to a printer for printing the signal strength. A somewhat more sophisticated arrangement is shown in Figure 11 wherein a timing circuit 78 is also employed for automatically resetting the peak hold detector 62 through the reset circuit 80. The timing circuit 78 also drives the printer 82 as well as a strip chart recorder and the flash tube circuit 6. An on-off switch 84 is provided for the timing circuit 78. The output at the peak hold detector is connected to the strip chart recorder so that the signal strength generated by the differential amplifier 58 can be recorded as a function of time.

A detailed embodiment of a digital pulse visual acuity device according to the present invention is shown in Figure 12. A clock circuit 86 is provided for driving a free-running timer 88 which is connected to a pulse timing circuit 90. The combination of the clock 86, the free running timer 88 and the pulse timing circuit 90 drive the

OMPI

flash tube circuit 6 to enable the flash tube 8 to generate a pulsating beam of light 10. The pulsating beam of light 10 is condensed by condensing lens 92 and directed toward the eye 12 of the patient. An optional collimating lens 52 and an optional compensating lens 54 are provided for far vision visual acuity measurements. Thus, the visual acuity device of Figure 12 can be used to measure both far and near vision visual acuity. The optical system 16 of the visual acuity device of Figure 12 is the same as described above. In the signal detection circuit 18, the output of the differential amplifier 58 is provided to a comparator 94. The comparator is connected to a wave shaper 96 which provides a signal to the decoder 98. The decoder 98 also receives a clock signal from the clock 86. Thus, the operation of the decoder 98 is synchronized with the clock signals which are used to drive the flash tube circuit 6. The decoder 98 is connected to a driver 100 which is used to drive an LED display 102 for displaying the visual acuity of the patient's eye 12. The output of the driver 100 also drives an automatic lens set circuit 104 which automatically adjusts the lens set 50.

The visual acuity device of Figure 12 achieves a very high signal- to-noise ratio by taking advantage of the fact that pulse signals require low average power yet have extremely high peak values. Peak to average ratios of 1000-1 are easily produced. As described previously, the reflected in-focus image from the retina of the eye 12 is detected by the difference in light levels between the two photodiodes 42 and 44. One of the analyzer patterns 34 and 36 admits the in-focus image and the other analyzer pattern blocks the in-focus image. The differential amplifier 58 amplifies the difference between the signals generated by the photodiodes 42 and 44 thereby cancelling the out-of- focus glare from the reflected image. The comparator circuit 94 further removes the glare signal as well as circuit noise. The output of the comparator 94 represents the significant difference between the signals generated by the photodiodes 42 and 44 which in turn represents an in- focus image. This output signal is shaped by the wave shaper 96 so that pulse signals can be detected by the decoder 98. Because the decoder 98 is responsive to the clock signal from the clock 86, the driver 100 produces output signals only when the appropriate series of

pulses are received both from the photodiodes and from the clock 86. For example, where the clock 86 generates a series of four pulses or other binary-coded series of pulses as shown in Figure 12, the signal detected by the photodiodes 42 and 44 can easily be distinguished from noise as illustrated in the graphs in Figures 13A-13C. The driver 100 is activated by the decoder 98 upon receipt of the seris of four pulses from the clock 86 so that noise cannot produce an output signal.

In Figures 16 and 17, further modifications of the signal detection circuits are shown. In Figure 16, buffers 106 and 108 are connected to the photodiodes 42 and 44, respectively. The buffers 106 and 108 are buffers which match the high impedance of the photodiodes 42 and 44 to the low impedance of the summer UO. The outputs of the buffers 106 and 108 are combined in the summer 110 and provided to the amplifier 112. A combination of the buffers 106 and 108 and summer 110 detect the difference signal generated by the photodiodes 42 and 44. The output of the amplifier 112 is provided to peak hold detector 62 which is in turn connected to the meter 64. In Figure 17, a pair of comparators 114 and 116 are connected to the photodiodes 42 and 44 respectively. A reference voltage is applied to each of the comparators 114 and 116. The comparators 114 and 116 are used to reduce the common mode signal from the photodiodes 42 and 44 to thereby reduce glare and generate an in-focus difference through the differential amplifier 58. This results in more efficient rejection of glare because the adjustment of the differential amplifier 58 is not as critical and the common mode difference signal ratio is generally reduced.

Turning now to Figure 14, a circuit arrangement is shown for eliminating the effect of pupil size on the signal strength detected by the signal detection circuit 18. The elimination of the effect of pupil size on signal strength increases the accuracy of the visual acuity measurement. This circuit includes a beam splitter 118 adjacent the eye 12 of the patient for directing the reflected image through a lens 120 to an infrared photodiode 122. The signal generated by the infrared photodiode 122 is supplied to an amplifier 124. The photodiode 122 and the amplifier 124 form an automatic level control feedback circuit which adjusts the amplification of the signal detection circuit 18 by adjusting

the amplification of the voltage control amplifier 126. As a result, the visual acuity measurement of the visual acuity device is automatically adjusted in response to the pupil size detected by the photodiode 122. If a high output is detected by the photodiode 122, the amplification of the voltage controlled amplifier 126 is increased and, if a low output is detected by the photodiode 122, the amplification of the voltage controlled amplifier 126 is reduced. Thus, even with changes in pupil size, the measurement of the visual acuity remains accurate. The effect of changes in pupil size for an in-focus image are illustrated by the graphs in Figure 15 wherein a high voltage output from the signal detection circuitry is obtained for large pupil diameters and a low voltage output is obtained for small pupil diameters. Also, a fixed- diameter artifical pupil at the eyepiece can be used to eliminate pupil size effects. Figure 18 shows a circuit equivalent to Figure 14. This configuration eliminates the lens 120 and photodetector 122 to more simply suppress the effects of pupil size on signal strength.

The buffers 128 and 130 and the summer 132 restore the average glare level, which is masked by the positive and negative patterns of the in-focus signal. The amplitude control circuit 126 then functions as previously described. Also, note that this configuration uses two ungrounded photodetectors in a back-to-back arrangement.

Although illustrative embodiments of the invention have been described in detail with reference to the accompanying drawings, it is to be understood that the invention is not limited to those precise embodiments and that various changes and modifications may be effected therein by one skilled in the art without departing from the scope or spirit of the present invention.

^^g ϊ

O