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Claims  |
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What is claimed is:
1. Apparatus for testing the vision of a subject's eyes comprising:
at least one test target having differing optical characteristics thereover
disposed within the apparatus for viewing by a subject, the test target
being disposed in the field of view of the subject when the eyes of the
subject are located at a predetermined viewing position which is at a
predetermined distance from the test target, the test target when being
illuminated directing a light image of the test target through the field
of view of the subject and towards the subject's eyes, the test target
when illuminated providing a region thereon having a level of illumination
different from the level of illumination of the remaining background
portion of the test target in response to the differing optical
characteristics thereof, the difference in the levels of illumination
establishing a contrast ratio in the light image from the illuminated test
target which can be observed by the subject in the field of view;
means disposed within the apparatus for illuminating the test target;
means disposed within the apparatus for providing a source of diffused
veiling illumination;
means disposed within the apparatus for directing toward the subject's eyes
a level of veiling illumination derived from the diffused veiling
illumination of the source thereof, the veiling illumination directing
means including a member disposed between the at least one test target and
the predetermined viewing position at which the eyes of the subject can be
disposed, said member extending across all portions of the field of view
of the subject and the level of diffused veiling illumination
correspondingly extending throughout all portions of the field of view
between said member and the predetermined viewing position, said member
being operative to transmit the light image of the test target through the
field of view towards the predetermined viewing position and to direct the
diffused veiling illumination from the source thereof through the field of
view toward the predetermined position, said member transmitting the light
image of the test target and directing the diffused veiling illumination
substantially coextensively and in alignment in the field of view from
said member to the predetermined viewing position, the diffused veiling
illumination being directed independently of the illumination of the test
target, the interaction of the diffused veiling illumination with the
light image from the illuminated test target causing a change in the
contrast ratio of the light image from the illuminated test target which
can be observed by the subject in the field of view presented to the
subject's eyes, the change in the contrast ratio being a variable in the
testing of the subject's vision.
2. Apparatus in accordance with claim 1 and further comprising means
connected to the means for directing a level of veiling illumination for
varying the level of veiling illumination over a predetermined range of
levels, the predetermined range of levels providing a plurality of changes
in the contrast ratio.
3. Apparatus in accordance with claim 2 in which said means for varying the
level of veiling illumination over a predetermined range varies the level
of veiling illumination in predetermined steps with each step providing a
different contrast ratio.
4. Apparatus is accordance with claim 1 and further comprising means
connected to the means for illuminating the test target for varying the
illuminating level thereof over a predetermined range, the varying
illumination levels providing a plurality of different contrast ratio.
5. Apparatus in accordance with claim 1 in which said means for directing a
level of veiling illumination toward the subject's eyes comprises:
a partially light-reflective and partially light-transmissive member
extending across the field of view, the partially reflective portion of
the member being adapted to reflect one of the illumination of the
illuminated test target by the illuminating means and the veiling
illumination applied to the member toward the subject's eyes, the
partially transmissive portion of the member being adapted to transmit the
other one of the illumination of the illuminated test target by the
illuminating means and the veiling illumination applied to the member
toward the subject's eyes; and
a source of the veiling illumination adapted to be applied toward the
member, the member enabling the subject to view the composite of the
veiling illumination and the illuminated test target.
6. Apparatus in accordance with claim 5 in which said partially
light-reflective and partially light-transmissive member is a
semi-transparent mirror.
7. Apparatus in accordance with claim 6 in which the source of light is
disposed to one side of the field of view and in which the
semi-transparent mirror is in the form of a plate having its oppositely
disposed sides inclined with respect to the direction of the illumination
extending from the illuminated test target and having its reflective
portion in alignment with the source of light to reflect light from the
source toward the subject's eyes when the subject observes the field of
view.
8. Apparatus in accordance with claim 1 in which:
the region of the target is opaque and the background portion of the test
target is adapted to present light to the field of view when the test
target is illuminated.
9. Apparatus in accordance with claim 8 in which:
the background portion of the test target is translucent, and the means for
illuminating the test target illuminates the test target in a direction
extending therethrough toward the subject's eyes.
10. Apparatus in accordance with claim 8 in which the test target includes:
a plurality of different opaque regions of diminishing size, the regions
being arranged in a predetermined order related to the diminishing of the
sizes of the regions.
11. Apparatus in accordance with claim 5 and further comprising:
an elongated housing, the test target and the means for illuminating the
test target being disposed adjacent one end portion of the interior of the
housing and the partially light-reflective and partially
light-transmissive member extending across the central portion of the
housing with the source of light therefor being disposed in the housing
adjacent thereto; and
a viewing assembly extending into the housing at the opposite end portion
thereof and an alignment with the partially light-reflective and partially
light-transmissive member and the test target for enabling the test target
be viewed through the member.
12. Apparatus in accordance with claim 11 in which the test target includes
first and second target portions each facing the viewing assembly and
being arranged in a side-by-side relationship extending in a horizontal
direction.
13. Apparatus in accordance with claim 11 in which the viewing assembly
includes:
first and second apertures which are spaced apart horizontally with respect
to one another at a distance subsantially equal to the interpupillary
distance of a test subject's eyes, the apertures providing a region of
observation into the housing for the eyes of the test subject; and
binocular optical means in alignment with the first and second apertures
for directing the eyes of the subject along different predetermined lines
of sight extending toward the test target; and
means for establishing a predetermined degree of divergence between the
predetermined lines of sight by testing the subject's fusion potential.
14. Apparatus in accordance with claim 13 in which said viewing assembly
further includes:
a mask for selectively blocking one of the first and second apertures; and
means for selectively positioning the mask in any one of the positions in
which the mask blocks the first aperture, blocks the second aperture, and
is clear of the first and second apertures, the mask enabling the viewing
of the test target selectively by either eye of the subject.
15. Apparatus for testing the vision of a subject's eyes under varying
contrast ratios comprising:
a test target having a background portion and test indicia thereon, the
indicia being formed by translucent material which is adapted to plane
polarize light transmitted therethrough;
a source for transmitting light through the translucent material forming
the indicia in a direction extending toward the eyes of the subject;
means for plane polarizing the light transmitted by the source; and
means for selectively positioning the polarizing means to determine the
orientation of the plane of polarization, the interaction between the
light polarized by the polarizing means and the plane of polarization of
the material forming the indicia enabling the amount of light transmitted
therethrough to be selected and thereby contrast ratio of the test target.
16. A method for testing the vision of a subject's eyes comprising the
steps of:
providing at least one test target having differing optical characteristics
thereover disposed for viewing by a subject, the test target being
disposed in the field of view of the subject when the eyes of the subject
are located at a predetermined viewing position which is at a
predeterminted distance from the test target, the test target when being
illuminated directing a light image of the test target through the field
of view of the subject and towards the subject's eyes, the test target
when illuminated providing a region thereon having a level of illumination
different from the level of illumination of the remaining background
portion of the test target in response to the differing optical
characteristics thereof, the difference in the levels of illumination
establishing a contrast ratio in the light image from the illuminated test
target which can be observed by the subject in the field of view;
illuminating the test target;
providing a source of diffused veiling illumination;
directing toward the subject's eyes a level of veiling illumination derived
from the diffused veiling illumination of the source thereof, the veiling
illumination being directed from a member disposed between the at least
one test target and the predetermined viewing position at which the eyes
of the subject can be disposed, said member extending across all portions
of the field of view of the subject and the level of veiling illumination
correspondingly extending throughout all portions of the field of view
between the test target and the predetermined viewing position, said
member being operative to transmit the light image of the test target
through the field of view towards the predetermined viewing position and
to direct the diffused veiling illumination from the source thereof
disposed without the field of view through the field of view towarded the
predetermined position, said member transmitting the light image of the
test target and directing the veiling illumination substantially
coextensively and in alignment in the field of view from said member to
the predetermined viewing position, the veiling illumination being
directed independently of the illumination of the test target, the
interaction of the veiling illumination with the light image from the
illuminated test target causing a change in the contrast ratio of the
light image from the illuminated test target which can be observed by the
subject in the field of view presented to the subject's eyes, the change
in the contrast ratio being a variable in the testing of the subject's
vision.
17. A method in accordance with claim 16 and further comprising the step of
varying the level of veiling illumination over a predetermined range of
levels, the predetermined range of levels providing a plurality of changes
in the contrast ratio.
18. A method in accordance with claim 16 and further comprising varying the
illuminating level of the test target over a predetermined range, the
varying illumination levels providing a plurality of different contrast
ratios.
19. A method in accordance with claim 16 and further including the step of
varying the illuminating of the field of view with additional illumination
directed toward the subject, whereby the contrast ratio is varied.
20. A method in accordance with claim 16 and further including the step of
varying the illuminating of the test target, whereby the contrast ratio is
varied.
21. A method in accordance with claim 16 in which the test target includes
a plurality of the region in the form of symbols of diminishing size and
the method further includes the step of:
varying the illuminating of the entire field of view with additional
illumination directed toward the subject until the smallest symbol
observable in the absence of the illuminating of said field of view just
becomes one of discernible or non-discernible.
22. A method in accordance with claim 16 in which the target includes first
and second target portions which are separated and which are in a
side-by-side relationship; and in which the step of presenting the test
target comprises presenting the first target portion to only one eye of
the subject and the presenting of the second target portion to only the
other eye of said subject for causing the first and second target portions
to be viewed by the subject as a single fused target. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
The invention pertains to the art of testing eyesight and more in
particular to the art of testing eyesight under different conditions of
the contrast ratio of a target presented to the test subject. The
invention also pertains to the art of measuring visual performance of a
subject on targets of varying contrast ratios, i.e. when the ratio of dark
to light in the test object of the target is varied. The invention
additionally pertains to the art of testing the fusion potential
(binocular single image) of a subject's eyes under different conditions of
the contrast ratio of the target presented to the test subject. The
invention further pertains to the art of determining glare sensitivity of
a subject's eyes.
2. Description of the Prior Art
U.S. Pat. No. 2,209,728 which issued to H. R. HIGLEY on July 30, 1940,
discloses a device for measuring a subject's sensitivity to glare. Light
from a dazzling brilliant light source is focused by a reflector directly
onto the eyes of a subject who views the brilliant source in an initially
totally darkened chamber. A controllable light source which is off-set and
in front of the dazzling light source is then directed at objects (such as
letters painted dull white) which are in the vicinity of the dazzling
light source. The intensity of this controllable source is then increased
until the viewer is able to see the objects in the presence of the glare
of the source. The value of the intensity of the controllable dazzling
source when the objects just become visible is a measure of the glare
sensitivity of the viewer.
There is no disclosure in this patent of an arrangement for directing
toward the subject a level of glare light extending uniformly across the
field of view.
U.S. Pat. No. 3,684,355 which issued to S. F. MOLNER on Aug. 15, 1972
relates to another glare sensitivity measuring device. Light from a glare
source is directed in pencil-beam fashion at a viewer through a variable
density filter which permits controlling of the intensity of the glare
light reaching the viewer. Out of the path of the glare source but within
the field of vision of the viewer, a target is arranged. The target is
illuminated by another light source arranged in back of the target. A
variable density background filter arranged between the target and the
viewer controls the intensity of the illumination from the target reaching
the viewer. In this apparatus, the relative intensity of the light from
the glare source to the intensity of the target illumination is controlled
by varying the density of the background filter while maintaining the
light from the glare source constant, by varying the intensity of the
glare source while maintaining the density of the background filter
constant, or by varying both. Here again there is no disclosed
construction for directing toward the viewer a level of glare light which
extends uniformly across the field of view.
In U.S. Pat. No. 1,437,809 which issued to L. A. JONES on Dec. 5, 1922
there is disclosed apparatus for measuring the visibility of an object
with respect to its background such as the visibility against the sea and
sky of a marine vessel which has been camouflaged by appropriate painting
of its outer surface. The apparatus includes a telescope for enabling the
user to view the object such as a camouflaged marine vessel. A
semi-transparent mirror extends across the optical axis of the telescope
in a position adapted to reflect light in the form of a veiling light from
a lamp source toward the user's eye. The composite brightness resulting
from the veiling light and the light reflected from the observed object is
preferably maintained substantially constant by decreasing the ligh from
the object and increasing the veiling light or vice versa. Since the
device of this patent was not disclosed as being related to vision
testing, the device was taught as operating with constant composite
brightness with the stated purpose that this condition would eliminate any
change of light level at the user's eyes and thereby prevent the user's
eyes from interfering with the visibility condition being measured. It now
has been discovered in accordance with the invention that the user's eyes
will interfere with the visability condition being measured even when
composite brightness is constant if the contrast ratio changes.
In U.S. Pat. No. 2,799,203 which issued to W. R. Kerr on July 16, 1957,
apparatus is described for determining the degree of gloss of a finished
surface. In this apparatus, the image of a mask comprising a background
upon which are disposed rows of black letters of varying size is projected
onto successive finished surfaces each having a different degree of gloss.
A subject person observing the projected images thus sees images having
different degrees of contrast between their rows of letters and their
backgrounds. The surfaces of higher gloss have a higher contrast between
the letters and background while those of lower gloss have a lower
contrast. The different degrees of contrast give a relative measure of the
different degrees of gloss of the surfaces.
It is known in the prior art to measure the fusion potential of a subject's
eyes by means of a stereoscopic viewer which is adapted to direct each of
the test subject's eyes to a different one of a pair of adjacent eye
charts having dissimilar targets. With fused vision, the two targets are
viewed by the subject as a single fused target. The stereoscopic viewer is
provided with optical wedges which can be adjusted to displace the line of
sight of the subject's eyes from a condition in which the targets appear
fused. The ability of the subject to overcome the displacement of his line
of sight by the optical wedges and then sense a fused image is indication
of the subject's fusion potential. Progressively increasing the degree of
displacement of the line of sight, in the measuring of the ability of the
subject to again sense fused targets, enables a discrete determination of
the fusion potential to be made.
SUMMARY OF THE INVENTION
In accordance with the method and apparatus of the invention a target
having test patterns thereon is presented to the eye. The test patterns
taken with the background of the target present varying contrast ratios
which enable the eye being tested to be compared to the performance of a
"normal" eye for the same patterns. The vision tester of the invention can
be used as a "cataract tester" since it is capable of measuring
intraocular light scattering caused by a cataract condition. Here it
should be noted that other eye abnormalities can cause such light
scattering. Of course, ophthalmoscopic examination would be necessary in
order to relate measurements obtained by use of the vision tester of the
invention to a particular pathological condition.
In accordance with the invention there is provided an eye chart having
black letters on a white translucent background. The eye chart is
illuminated from the side opposite to that bearing the letters with the
result that the dark letters compare in contrast to the white illuminated
background. Since the vision tester of the invention is intended to
measure visual performance of the eye on targets of varying contrast
ratios, the range of contrast ratios between the brightness of the letter
compared to that of the illuminated background can be varied. A veiling
light is superimposed upon the light being directed from the eye chart
toward the eye of the subject. The brightness of the veiling light is
added both to the illuminated background and the black letters of the eye
chart. Means are provided for varying the intensity of either the
background illumination of the chart, the veiling light, or both in order
to provide a range of different contrast ratios. In the preferred
embodiment the intensity of the veiling light is varied.
Any condition within the eye such as a cataract condition which can scatter
light within the eye serves to decrease the contrast ratio of the target
being viewed since the scattered light increases the light level in the
dark parts of the target being used. It is known that normal eyes have
some internal light scattering. As a result a subject with normal sight
can read a given line of an eye chart with no veiling light while a
certain amount of veiling light will reduce the visual acuity of the
subject. By way of example, a given level of background illumination of
the chart, the contrast of the chart (ratio of black to white), the
veiling light or all can reduce the visual acuity from 20/20 to 20/30. The
vision tester of the invention is designed to measure the difference
between the visual acuity of a person with pathological light scattering
in his eyes as compared to the visual acuity of a person having normal
vision.
The vision tester of the invention can also be used to test the fusion
potential of a subject's eyes, that is to say the ability of the eyes to
fuse dissimilar objects or, more simply stated, the ability to use both
eyes as one. A binocular version of the vision tester of the invention can
be used to assess the amount of fusion potential of the eyes under various
contrast ratios. The binocular version provides viewing of an adjacent
pair of eye charts having dissimilar targets. Optical wedges in the viewer
of the binocular version enable the line of sight of the subject to be
displaced to the extent that the subject must exert some degree of effort
to sense a fused image of the targets. It is known that the fusional
ability of the eyes is to an extent dependent upon the contrast ratio of
the scene being viewed. Upon reducing the contrast ratio it is known that
a point is reached at which the eyes become incapable of fusing dissimilar
objects and accordingly the ability of the eyes to act as one ceases. Once
the optical wedges have been set to displace the line of sight, they are
no longer adjusted. The vision tester is operated to provide progressively
increasing levels of veiling light. A point will be reached at which the
progressive reduction of the control ratio of the targets as seen by the
subject will cause the fusion potential of the subject to be exceeded. At
this point, the subject can no longer see a fused image. The lack of
fusion can be detected when the subject reports that two separate images
are seen, or the examiner visually observes that the subject's eyes do not
diverge, or by optical detectors of the change in corneal reflection, or
by electrical measurements of the position of the eyes or by various
combinations of these.
In addition the vision tester of the invention can be used to measure glare
sensitivity of the subject's eyes since this phenomenon at least in part
is a function of the degree of intraocular light scattering.
In another embodiment of the invention a series of test charts having
different contrast ratios under a standard lighting condition are
provided. The targets present different contrast ratios to the subject as
is done with the vision tester of the invention employing veiling light.
The ability of a subject to read charts of reduced contrast is the basis
of measuring light scattering or fusion potential of the test subject's
eyes.
BRIEF DESCRIPTION OF THE DRAWINGS
The above and other features and aspects of the present invention will
become more apparent upon reading the following detailed description in
conjunction with the accompanying drawings, in which:
FIG. 1 is a perspective view of a vision testing apparatus in accordance
with the principles of the invention;
FIG. 2 is a fragmentary horizontal section view of the upper portion of the
apparatus of FIG. 1 showing the provision of a binocular lens system for
viewing a test target through veiling light;
FIG. 3 is a schematic representation of a vertical section view of the
apparatus of FIG. 1 and additionally includes a schematic view of variable
sources of light used with the apparatus;
FIGS. 4-6 are representations of the appearance a test target of the
apparatus of FIG. 1 for different light contrast ratios provided by the
apparatus of the invention; and
FIG. 7 comprises a representation of a plurality of test charts each having
a different viewable contrast ratio.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
FIG. 1 shows vision tester apparatus 10 in accordance with the principles
of the present invention. As shown, vision tester 10 comprises a central
body or enclosure 12 having in its frontal portion, a viewing assembly 13
and in its rearward portion a target assembly 14. The target assembly 14
includes a hollow hexagonal member or drum 15 which is rotatably supported
within the housing. Each hexagonal surface of drum 15 supports a pair of
corresponding targets in a side-by-side relationship. Target pair 16 and
17 and target pair 18 and 19 are specifically illustrated. Each of the
supported targets, in turn, includes a plurality of opaque regions which
are situated on a transparent or translucent background and which may take
on the shape of any letter, number or other symbol. The opaque regions of
the test targets 16 and 17 are horizontally extending rows of letters with
the letters in each row having a different size. Thus each different row
provides a different test of the visual acuity of the eyes of the subject
being tested.
The regions on the targets 18 and 19, on the other hand, are illustrated as
rows of broken rings of different size and orientation with the rings of
corresponding rows of the two charts being unsymmetrical. The charts 18
and 19 can correspond to known eye charts which are used for testing the
fusional potential (binocular single image) of a viewer's eyes.
Interior to the hexagonal drum 15 is a light source 21 shown in dotted
line. The light source or lamp 21 is depicted as a cylindrically shaped
light bulb which extends through the central portion of member 15,
parallel to the hexagonal faces thereof. The light source 21 is supported
in the housing by a threaded coupling 22 to which electrical energy is
applied from a source (not shown) by way of lead 23. In FIG. 1, the drum
15 has been rotated to a position in which the surfaces thereof supporting
the targets 16 and 17 is situated substantially in a vertical plane. This
places the targets in alignment with the viewing assembly 13.
Viewing assembly 13 comprises two horizontally spaced eyepieces 24 and 25
through which the viewer observes the targets. The eyepieces and optics
related thereto can be arranged to provide binocular vision where the
subject is to view a single test target simultaneously with both eyes. The
eyepieces and related optics can also be arranged to restrict the vision
of each eye to a different one of a pair of targets. Thus, as shown in
FIG. 3, assembly 13 can include a binocular optical assembly 41 having
optics 42 and 43 adjacent eyepieces 24 and 25. The binocular optical
assembly can include optical wedges or lenses (not shown) having
cylinders. These lenses when rotated about the line of sight through their
respective eyepieces enable the viewer's vision to be aligned properly
with respect to the different targets in correspondence with the user's
interpupillary distance. A mask 44 is rotatably supported at the center of
the assembly 41 and can be rotated to block either of optics 42 and 43 and
thereby prevent viewing therethrough whenever one eye is to be tested at a
time.
With the mask 44 in its central position, the optics 42 and 43 cause the
respective targets 16 and 17 aligned therewith to appear to the viewing
eyes at the apertures 24 and 25 as a single, that is fused, image. Thus
the optics serve to align the line of sight to each eye with a different
one of test targets 16 and 17. In this position of mask 44, both eyes of
the subject can be tested simultaneously. Rotating the mask 44 to either
side position thereof blocks the respective optics 42 and 43, thereby
permitting individual testing of either eye.
As seen in FIG. 1, the tester 10 includes a hinged top cover 26 which
provides access to the interior of body 12 and prevents ambient light from
impinging upon the target assembly 14. The tester is provided with a
stationary base 27. Body 12 is adjustably supported on base 27 by a
parallel linkage comprising uprights 28 which are pivotally mounted with
respect to the body and the base. Support of the body portion 12 in this
manner enables the body portion to be moved both horizontally and
vertically to adjust the viewing assembly to accommodate the different
positions of the eyes of different subjects.
The basic portions of the tester 10 comprising the body, the drum and lamp,
the eyepiece and optics, and the adjustable supports generally correspond
to those of conventional eye testing apparatus. Thus, typically, in the
use of such apparatus, the viewer is stationed at the viewing assembly 13
with his or her eyes locking into the eyepieces 24 and 25. With the mask
44 at its central position, the lamp 21 is turned on, thereby illuminating
the translucent background of each of the targets 16 and 17 which are in
alignment with the assembly 13. The viewer, thus, is presented with a
fused target whose field of view comprises the opaque symbol regions and
the translucent background region. The viewer is then asked to read the
opaque symbols until he reaches a line at which he can no longer discern
all of the symbols. When this line is reached his visual acuity is thus
established at the acuity associated with the previous line. If the
viewer's eyes are then to be individually tested, the mask 44 is rotated
and the procedure repeated separately for each of the right and left eyes.
As can be appreciated, in the aforesaid testing procedure, the level of
illumination reaching the viewer from the opaque symbol regions is
substantially zero and that from the translucent background region is at a
constant level as determined by the intensity of lamp 21. The contrast
ratio of the target being viewed is thus always at a substantially
constant value which cannot be varied. As a result, with the apparatus of
tester 10 without the provision of veling light in accordance with the
invention, vision testing of the subject is only possible under a single
contrast ratio condition and, hence, the eye conditions and eye
performance discernible from testing under varying contrast ratio
conditions cannot be ascertained.
In accordance with the invention, varying contrast ratio conditions are
realized in the apparatus tester 10 by further including therein a further
illumination means which provides an additional uniform illumination of
the entire field of view of the target being observed. As shown in FIG. 1,
the aforesaid illumination means comprises a half-transmitting
half-reflecting means in the form of a semi-transparent or half-silvered
mirror 29 which is disposed in the central portion of body 12 between the
target assembly 14 and the viewing assembly 13. The mirror 29 is supported
at an angle in body 12 with its upper portion inclined away from the
target assembly. Half-silvered mirror 29 is sufficiently extensive to
intercept the entire field of view of each of the adjacent pairs of
targets on the face of the member 15 aligned with viewing assembly 13.
Thus, the mirror is coextensive with the field view of the targets when
viewed individually or fused from viewing assembly 13.
The illumination means for the half-silvered mirror includes a light source
or lamp 31 in the form of a cylindrical electric lightbulb which is
situated in the region below mirror 29. The source 31 is secured to the
body by a coupling 32 from which extends a lead 33 for attachment to an
electrical source of energy (not shown).
The schematic diagram of FIG. 2 shows the positioning of mirror 29 with
respect to the viewing assembly 13 and target assembly 14. As noted, the
mirror 29 extends across the entire field of view of the targets 16 and 17
being viewed. As can be also seen from FIG. 2, the target assembly 14 and
the illumination means 21 are each also provided with a diffusion screen
such as a ground glass screen to provide more uniform distribution of
light. Thus, target assembly 14 is provided with a diffusion screen 53
which is situated between the source 21 and targets 16 and 17. Likewise,
the illumination means 31 is provided with a diffusion screen 54 situated
between source 31 and mirror 29. Also shown in FIG. 2 are variable
electrical sources 51 and 52 which control the level of illumination of
the sources 21 and 31, respectively. These sources can comprise an
electrical power control which supplies an adjustable level of power to
lamps 21 and 31. The level of power can be adjustable in a continuous or
stepped manner as indicated by pointers 51a and 52a on scales 51a and 52
b, respectively.
With the above-described illumination means included in tester 10, the
light from the source 31 is directed by diffuser 54 onto mirror 29 and
reflected thereby toward the subject's eyes along with the light
transmitted through the mirror from the targets 16 and 17. As a result,
the subject at the viewing assembly 13 observes the targets through a
uniform level of veiling illumination provided by the mirror. The uniform
level is superimposed upon the light transmitted toward the vision by
targets 16 and 17. Accordingly, the contrast ratio between the
illumination level of the symbol regions and the illumination level of the
background can be changed from that provided by the illuminated targets
alone. Thus the contrast ratio becomes dependent upon the composite of the
selected uniform level of veiling illumination (i.e., the selected
illumination level of source 31) and the level of illumination of the
target itself (i.e., the selected level of illumination of source 21). The
aforesaid contrast ratio can be varied by varying the illumination level
of either light source by means of their respective electrical sources 51
and 52. Here it should be noted that only the veiling light can be added
to the portion of the field of view in alignment with the symbols since
source 21 does not direct light from the dark symbols themselves toward
the subject's eyes.
FIGS. 4, 5 and 6 show the targets 16 and 17 as viewed together by a viewer
for three different increasing levels of illumination provided by the
source 31. As can be seen by progressively increasing the level of veiling
illumination to a maximum condition represented in FIG. 6 causes a
decrease in the contrast ratio between the symbols and the background
adjacent thereto. As a result it can be seen that the decreasing contrast
ratio makes the symbols progressively less discernible.
In another embodiment of the invention (not shown), the position of the
assembly of target assembly 14, diffusion screen 53 and source 21 relative
to half-silvered mirror 29 can be exchanged for the position of the
assembly veiling light source 31 and diffuser 54 with respect to mirror
29. In this embodiment the subject would also view the symbols over a
range of contrast ratios resulting from a range of different levels of
veiling light.
In using the tester 10 for testing of vision, the viewer would again be
positioned at the viewing assembly 13 and the lamp 21 energized in order
to illuminate the target. The viewer would then be asked to read the lines
of the chart to establish his normal visual acuity. After the latter is
established, the lamp 21 would then be decreased in intensity
progressively or in steps until a contrast ratio condition is reached at
which the viewer can only read the line above the previously read lowest
line. At this point the latter line is no longer discernible because of
the decreased contrast ratio between the symbols thereof and the
background. Upon the occurrence of this condition, a record is made of the
viewer's acuity corresponding to the new line and of the contrast
corresponding to that acuity. In this way, a measure of the loss in acuity
with respect to a given change in contrast ratio is obtained. This
measure, in turn, can then be used to determine the various light
scattering properties of the eye and any possible eye disorders associated
therewith.
The tester 10 can also be used to test for the fusion potential of a
subject's eyes. In this case, the member 15 is rotated to place dissimilar
targets 18 and 19 into alignment with the viewing assembly 13. The lamp 21
is then illuminated. The optical wedges or prisms of the binocular optical
assembly 41 are adjusted to diverage the line of sight of the subject with
respect to targets 18 and 19 until a condition is reached at which some
effort is required by the subject to view the symbols of a given line of
the targets as a single fused image. The adjustment of the wedges or
prisms is then held fixed for the subsequent test of the subject's fusion
potential. Instead of diverging the lines of sight by wedges or prisms,
divergence can be obtained by separating the targets.
After divergence is established a minimum level of veiling light is applied
to reduce the contrast ratio. The tests are then repeated. The level of
veiling light is subsequently increased progressively and thereby the
contrast ratio is reduced progressively until a reduced contrast ratio
condition is reached at which the subject can no longer fuse the symbols
on the line of the charts which the subject could fuse, absent the veiling
light. In this way the subject's fusion potential can be determined and
measured. The occurrence of a loss of fusion can be detected by the report
of the subject, by observations of the subject's eyes, or by electrical
instrumentation capable of responding to eye movement.
The use of different levels of the veiling light can also be used in the
testing of color vision, again using the principle of the change of
contrast ratio | | |
