WO2019092639A1 - Method and device for performing an eye test - Google Patents

Abstract

A method and device for performing a psychophysical eye test using a monitor for applying visual stimuli to an individual, comprising the following steps: presenting two peripheral, moving, visual point stimuli, a reference point and a test point, on opposite visual hemifields, wherein the reference point and the test point have a predetermined difference value between them for a visual parameter; registering the response of the individual, indicating which point, the reference point or the test point, the individual found had a greater value for said visual parameter; repeating the steps of presenting the stimuli and registering the response, randomly altering the opposite visual hemifields of the reference point and test point, and gradually reducing the difference values of the visual parameter, until the response of the individual is incorrect regarding whether the reference point or test point has a greater value for said visual parameter, in order to obtain the retinal sensitivity threshold of the individual for said visual parameter.

Description

 DESCRIPTION

 METHOD AND DEVICE FOR PERFORMING VISUAL TESTING

 Technical Domain

 A method and apparatus for conducting psychophysical functional tests for screening various ocular conditions, namely ophthalmological or neuro-ophthalmological disorders, is described.

Background

 Psychophysical functional tests for ocular pathology screening are intended to selectively stimulate certain cellular subgroups present in the retina and / or specific neuronal mechanisms resulting from visual processing.

In fact, the isolation of said cell subgroups constitutes an important factor for the detection of vision loss in early states of pathologies, which preferentially affect some of these cell groups or specific visual functions.

[0004] These psychophysical tests involve early biomarkers for the detection of retinal and optic nerve diseases (among them Glaucoma), as well as for quality control of vision after refractive surgeries, allowing the initiation of treatments earlier and contributing to the combat and attenuation of the lesional processes of pathologies whose progress is currently irreversible for patients.

Indeed, in the current state of the art it is not possible to perform chromatic tests on conventional (low or medium resolution) monitors, since sufficiently fine variations in chromatic and achromatic contrast are not achieved without the use of additional technology, as a general rule because it is based on very high resolution monitors. US9271641B1 exemplifies a system for performing color tests (among others) for the aforementioned clinical purpose, however with the use of an optical system complex and without employing a monitor. Therefore, a solution with evident complexity and high cost.

EP2796088A1 discloses a system and method of testing the visual field using a personal computer. However, it does not allow validation of the data), and, therefore, the respective tests are only conventional perimetry.

Patent document US6227668B1, with regard to psychophysical tests explores a concept of changes in the periphery of vision. However, it uses a stimulus composed of two concentric circles, which exploits a phase change perceptible in time, with changes in the chromatic and achromatic perception in the periphery until the individual does not notice the difference in relation to the background.

On the other hand, WO2014 / 094035A1, relating to a method for the diagnosis of ocular diseases (glaucoma, among others) claims a perimetry examination, with small diameter light stimuli presented at several equidistant locations, covering a field angle of about 20 °, identifying the loss of visual field sensitivity at each of the tested locations. However, in this detection perimetry, the patient only responds when he sees the stimulus.

These facts are described in order to illustrate the technical problem solved by the embodiments of the present document.

summary

The present disclosure relates to a method and device comprising hardware and software components for performing a set of psychophysical functional tests for screening of various ocular conditions at an early stage. Specific psychophysical tests are described for low-resolution monitors that better exploit the capabilities of these monitors in performing these psychophysical tests.

Indeed, the solution described above was based primarily on an analysis of the equipment, and then on an adaptation of these psychophysical tests so that it is possible to have them run on the selected equipment without loss of precision or accuracy.

A way of exploring the regions of the contrast curve versus the luminance of a monitor is described, where the derivative allows to obtain thinner levels, thus being able to use monitors with a resolution of only 8 bits for the execution of psychophysical tests (sensitivity tests for chromatic and achromatic stimuli), whose requirements would normally require monitors with higher resolutions (10 bits to 14 bits). Thus, after a characterization operation of the monitor (comprising a set of procedures aimed at acquiring the luminance response of each color channel of the monitor, testing the independence of each color channel, and the combined response of the various channels), it is it is possible to obtain the mathematical model of its response in the various RGB channels, and thus calculate which regions of the lower slope of the power curves of the monitor. These regions are of particular interest because each RGB threshold can achieve smaller differences in luminous intensity and smaller chromatic variations because these are regions where the resolution of the monitor is higher. With this data, it was then possible to construct and adapt the psychophysical tests so that their execution occurs in these regions, thus taking advantage of a higher resolution although the system has fewer bits in the root.

The present disclosure includes psychophysical tests that best exploit the capabilities of the selected and characterized equipment (monitor) by reversing the logic present in several prior examples in which the monitor resolution requirements are set to fit the requirements of the test . In effect, the solution described includes an analysis of the equipment and the of the test in question, leading to an adaptation of the latter so that it can be run on the selected equipment without loss of precision or accuracy.

The present description relies on individual, peripheral, and set stimuli to different eccentricities, manipulating additional parameters such as speed, in addition to chromatic and achromatic stimulation. Accordingly, the individual's assessment is weighted by the results of multiple tests. The present description allows the validation of the data from an eye-tracker device, allowing the combination of results obtained by three complementary stimulation methods (color, luminance and motion), alternatively or in any combination.

The psychophysical tests described in the present description contemplate a forced response strategy, which greatly reduces the phenomenon of "false positives" and "false negatives" (common problem inherent to perimetry), being effected only to certain eccentricities (key locations "of appearance of the first lesions in the Glaucoma), and not point to point within the central visual field, as it is the case of the perimetrias, being therefore less tiring for the patient, being more reliable. Another relevant advantage has to do with the properties of vision and perception (movement, color and relative brightness) used in the tests, parameters that aim at the size and the time of exposure of the stimuli.

Peripheral point stimuli rely on short duration stimuli, ranging from 400 to 900 milliseconds, with a small spatial amplitude movement, preferably of 1 degree, or within the range of 2 to 3 degrees of visual angle (for the case of a 60Hz refresh rate monitor) or less than 2 degrees of visual angle (for a 100 Hz refresh rate monitor). The peripheral distances of the reference point and the test point relative to the fixation point (center point where the subject must fix during the tests) are 7.5, 10 or 15 visual degrees depending on the selected meridian is 0, 90 , 45 (or 135) degrees, respectively. In one embodiment, for comparison of the two points moving at different speeds, both points correspond to a maximum achromatic (white) stimulus, differing only from each other in the value of the speed at which they move. Both points are square with "n" pixels calculated to occupy this area of visual angles and measure 0.3x0.3 degrees. The reference point moves at a constant velocity, whereas the test point begins by moving at a speed that is clearly faster (the desired maximum velocity that would ideally lie at 50 visual degrees per second). As the subject hits the laterality of the fastest point, the speed of the test point approximates successively the speed of the reference point. The comparative judgment of the individual then comes up with the answer to the question, "What is the fastest point?"

In a preferred embodiment, to be preferably used in a 60 Hz refresh rate monitor, the present description contemplates achieving a compromise between the reduction of the number of points and the increase of the distance, in order to obtain the desired speeds without compromising the perception. The option was thus to increase the range of motion to 2 degrees of visual angle, with a maximum speed with a minimum of 5 points, which allows to have at most a speed of 24 degrees per second. In motion tests, it should preferably be possible to test velocity differences between 0.1 and 15 degrees per second and the reference point should be between 1 and 10 degrees per second.

In a second embodiment, for comparing the two points to different luminances, the peripheral point stimuli measure 0.6x0.6 degrees and move at equal constant velocities throughout the test, having a value of 5 visual degrees per second. Both points correspond to an achromatic (gray) stimulus, differing only the gray luminance value (several tones along the white-black axis), keeping one constant luminance point establishing the reference point, while the other point begins brightness, approaching successively the reference luminance as the subject hits the laterality of the brightest point. The comparative judgment of the individual is then the answer to the question: "What is the brightest (whiter) point?"

In a third embodiment, for comparing the two dots in different colors, the peripheral point stimuli measure 0.6x0.6 degrees and move at equal constant velocities throughout the test, having a value of 5 visual degrees per second. The reference point consists of an achromatic stimulus, while the test point has a chromatic contrast to the reference point. They differ only between themselves the value of this chromatic contrast made along axes that isolate a type of population of cones. One point keeps the chromaticity constant (gray) by setting the reference point, while the other point begins clearly with a sharp color, approximating successively the chroma reference, as the individual hits the laterality of the point with color. The reference point is placed in an area with light intensity of photopic conditions around 30 cd / m ² and that is in the region of lower slope of the intensity curve, and that in a power curve it will normally be between 0-50% of intensity. The comparative judgment of the individual is then the answer to the question: "What is the point with color?"

In brief, the described solution includes the characterization of the monitor and the construction of the psychophysical tests, preferably adapted and adapted to the characteristics of said monitor, taking into account the neurophysiology of the vision.

A method for performing a psychophysical visual test using a monitor for applying visual stimuli to an individual is described, comprising the following steps:

 displaying two mobile peripheral point visual stimuli, a reference point and a test point, in opposing visual regions, wherein the reference point and test point has between them a predetermined difference value of a visual parameter,

record the response by the individual, indicating the point of reference or test that the individual considers to have a higher value of said visual parameter, to repeat the steps of displaying stimuli and recording the response, by randomly altering the opposing visual hemi- fields of the reference point and the test point, and

 gradually reducing the values of difference of the visual parameter until the moment the individual's response misses the indication of the reference or test point having the highest value of said visual parameter to obtain the threshold of retinal sensitivity of the individual of said parameter visual.

 In one embodiment, the visual parameters tested are motion, luminance and color.

 In one embodiment, the motions of the reference point and the test point occur at different speeds from each other, either the reference point and test point luminances are different from each other, or the chromaticity of the reference point and the test point are different from each other to test the visual parameters of, respectively, motion perception, luminance and color.

 In one embodiment, the reference point is displayed at a constant speed, luminance or chromaticity and the test point is displayed at a variable speed, luminance or chromaticity, respectively, for testing the visual parameters of motion, luminance and color, respectively.

 In one embodiment, the reference point and the test point are displayed on the same meridian.

 In one embodiment, the motions of the reference point and the test point occur along a linear trajectory of 1 to 3 degrees of visual angle, in particular 2 degrees of visual angle.

 In one embodiment, the motions of the reference point and the test point are pendular motions.

 In one embodiment, the reference point and the test point are displayed at identical and different assay eccentricities.

In one embodiment, the distance from the test point to the reference point is 7.5 degrees for the meridian at 0 degrees, 10 degrees for the meridian at 90 degrees, and 15 degrees for the meridian at 45 or for the meridian a 135 degrees. In one embodiment, the peripheral point visual stimuli are of short duration between 400 and 900 milliseconds.

 In one embodiment, the movement of the test point is displayed at a maximum rate of 50 visual degrees per second to test the visual motion parameter.

In one embodiment, the movement of the test point is displayed at a maximum velocity of 24 visual degrees per second on a monitor with a refresh rate of 60 Hz to test the visual parameter of motion.

 In one embodiment, the reference point and the test point are achromatic square points of 0.3x 0.3 degree dimensions for testing the visual motion parameter or the luminance parameter.

 In one embodiment, the test point is an achromatic square point to the periphery and chromatic in the center, with dimensions of 0.6x0.6 degrees to test the visual parameter of color.

 One embodiment comprises validating the visual psychophysical test by verifying whether the patient fixation coincides with the central fixation point located on the monitor.

 In one embodiment, the alignment of the subject's visual axis relative to the central fixation point is verified by an eye-tracker device.

 A device for performing psychophysical visual tests is described which comprises a data processor configured to perform the method for performing a psychophysical visual test using a monitor to apply visual stimuli to an individual in accordance with any one of the embodiments described.

 A system for performing psychophysical visual tests is described from a personal computer comprising:

 a computer monitor connected to said computer;

 computer configured to perform the method for performing a psychophysical visual test using a monitor to apply visual stimuli to an individual in accordance with any of the described embodiments;

said computer being connected to said monitor to display said movable peripheral point visual stimuli. A non-transient data storage medium comprising programming instructions for implementing a device for performing psychophysical visual tests is described, the programming instructions including executable instructions for performing the method of any of the described embodiments.

Brief Description of Drawings

 [0042] For ease of understanding, the figures are attached, which represent illustrative embodiments which are not intended to limit the object of the present disclosure.

[0043] Figure 1: Representation of the luminance response for the various color channels (red (la), green (l) and blue (lc) channels), noting the typical power response, also known as Gamma response.

Figure 2: Representation of the spectral response of the various color channels (red channel (2a), green (2b) and blue (2c)) at various emission powers. Spectrum constancy test.

[0045] Figure 3: Representation of the motion test with indication of the broken line.

[0046] Figure 4: Representation of achromatic and chromatic stimuli.

Figure 5: Graphical representation of the simultaneous presentation module of the stimulus pairs (0 degrees, 90 degrees, 45 and 135 degrees), also showing the eccentricity (7.5 degrees, 10 degrees and 15 degrees).

Detailed Description

The present disclosure also relates to a method of characterizing low resolution monitors by exploiting higher resolution areas and to a specific design of a posteriori psychophysical tests which better exploit the capabilities of the low resolution monitor in performing those areas psychophysical tests. [0049] Any display equipment, regardless of its technology (CRT, LCD, LED, oLED or other), will be characterized photometrically using a spectroradiometer, capable of obtaining the spectrum of light emitted by that device.

[0050] The characterizations of monitors are performed in the dark, thus eliminating the ambient lighting variable of the whole process.

In order to characterize a monitor for its luminance, independent measurements are performed for each color channel - red, green and blue - through a square shown in the center of the monitor. The color coordinate of this square is given by the RGB code, where the value of each of the variables R, G and B ranges from 0 to 255 for a system with a resolution of 8 bits of color ( ²⁸ = 256 levels of color per channel), and the 256 luminance measurements for each isolated channel were recorded.

The RGB code on some systems is given from 0 to 1, instead of 0 to 256 (8-bit system), this being a normalized RGB system and adopting the RGB notation for this case. The use of normalized RGB (rgb) in software is relevant, since it allows to obtain results independent of the color resolution of the rear display system: being 8 bits, the 1 takes the value of 255, being 16 bits, the 1 takes the value of 65 535. or,

C (X) = rR {%) {gG + X) bB + {%) - A _(r} where A (x) = 0

The mathematical model presented is used to characterize the luminance and spectrum response of the monitor, depending on the technology involved (CRT, LCD, LED, oLED or other) and always considering the intrinsic properties of each monitor.

The most widely used models for predicting luminance and spectrum response are linear models that weightedly sum up the individual response of each color channel (red, green, and blue). For the adoption of these models, it is necessary that the monitor in question has a strong spectral constancy of the color channels (called simply by channel constancy), strong local and spatial independence of the channels, strong spatial and temporal homogeneity of the channels. Every These properties cause non-linear deviations to the linear prediction model and should therefore be taken into account when choosing which monitor to use. Thus, when using linear prediction models, it is preferable to use a monitor where the properties causing said non-linear deviations are minimized.

[0055] In the case of CRT monitors (for example), the luminance ratio of the monitor versus input RGB value is given by a power function, known as Gamma function. The Gamma power value is then the unknown that depends on the system in use and which characterizes the luminance / RGB ratio. In different technologies used in CRT monitors, the adjustment curve of these two variables may not already follow an exponential relation, so the best mathematical adjustment that characterizes the luminance / RGB ratio must be sought for each case.

Characterizations of monitors of this type confirm Gamma values close to 2.2, which is in accordance with conventional CRTs and also corresponds to the default value used in most CRT applications.

With the mathematical expression of the luminance / RGB curve, the luminance value of any RGB combination can be calculated with the precision given by the system (usually 8 bits). From the comparison of the luminance of the predicted color to a CRT with that of the measured color, it is found that accuracy is much greater for isolated channels (red, green and pure blue) than for combinations of channels where there will be a substantial deviation from the luminance of the predicted color (caused by the sources of nonlinear deviations already described).

In order to predict the colors that a particular monitor can display, it is necessary to predict the emission spectrum associated with each specific RGB coordinate of that same monitor, see graph 1 and 2. The characterization of the spectral response given by a monitor should be understood as the characterization of the changes caused in the shape of the spectrum, along the energy change of the color channels, either alone or when combined. [0059] In conclusion, in monitors where there is a constancy of the spectrum (with low error) for the prediction of the emission spectrum through a linear model, only two variables are necessary:

The maximum spectrum of each isolated color channel R, G and B (in a system of 8 bits each color isolated at the maximum corresponding to the value 255);

 A multiplicative factor by the maximum spectrum of each color channel, corresponding to the ratio between the predicted energy for the RGB combination to be displayed and the energy associated with the maximum spectrum of each color channel. This ratio is easily obtained through the previous characterization of the luminance, thus consisting of the expected luminance ratio for each channel of the RGB combination that we want to show on the maximum luminance of each channel. These energy adjustment factors (values of 0-1) multiplied by the maximum spectrum of each channel will allow the resulting spectrum to be obtained for each isolated channel and hence allow the spectrum of any combination of these to be obtained. If for a CRT the system response is a priori linearized (by means of hardware or software) and RGB normalized to rgb, in this case it is possible to directly multiply the rgb value of the desired color by the maximum emission spectrum of each channel , obtaining exactly the same effect of the process described in the previous paragraph and assuming a system with non-linearized response.

Once the described step of characterization of the monitor is completed, an interaction with a software that interprets the data of the characterization is observed and that parameterizes the stimuli of the psychophysical tests so that they are presented in order to fulfill its objective to stimulate a visual pathway selectively, and appropriately adapted to the monitor in question.

Psychophysical tests allow discrimination thresholds for certain attributes of visual function to be obtained, based, for example, on the individual's ability to detect point-of-motion at the periphery, in front of an image on the monitor, and to exercise a comparative judgment between characteristics of two peripheral movements presented simultaneously. These psychophysical tests rely on mobile, individual stimuli at the periphery and placed at different eccentricities (see Figure 5), manipulating additional parameters such as speed, in addition to chromatic and achromatic stimulation. Accordingly, the assessment of the individual is obtained by the weighted result of the multiple tests.

A common feature of the tests described is that the laterality of the reference point and the alterable property point changes from random to test for assay (obviously within the constraints of the chosen meridian, see for example Figure 3). This fact makes the individual has to exercise his comparative judgment without having any previous information.

Figure 3 shows the representation of the motion test with indication of the broken line, showing a reference point (al) and a test point (a2) for a comparative speed test.

Another characteristic common to the described tests is that the peripheral punctual stimuli, as defined, are based on short duration stimuli, between 400 and 900 milliseconds, of small size with a movement of reduced spatial amplitude, 2 to 3 degrees of angle visual, preferably about 1 degree of visual angle. The peripheral distances to the fixation point are 7.5, 10 or 15 visual degrees depending on the selected meridian is 0, 90, 45 or 135 degrees, respectively.

The results of these tests are given by obtaining thresholds that represent the minimum difference of the comparative property for which a subject hits about 50% of the hypotheses, according to the assumption of the result of a psychometric curve.

The other characteristic common to all tests described is that the central fixation is controlled by an eye-tracker device immediately before and after each test. This information is used in real time to validate or discard the assay. In case the test is discarded by non-central fixation it will be repeated successively until it is validated. The individual's response to each test can only be given after a sound stimulus that occurs at the end of the central fixation check. This "eye-tracker" data validation system allows combining results obtained by three complementary stimulation methods (color, luminance and motion).

Another characteristic common to the tests described here is that the described psychophysical tests contemplate a forced response (strongly reducing the phenomenon of "false positives" and "false negatives", a problem common to perimetry), being carried out only to certain eccentricities ("key" sites for the appearance of the first lesions in Glaucoma), not point to point within the central visual field (more tiring for the patient, with negative impact on the results), as is the case with perimetry. Another relevant difference has to do with the properties of vision and perception (relative motion, color and brightness) employed in the tests.

Another characteristic common to all the tests described is that properties such as the bottom of the screen the dimension of the points and the central cross remain constant throughout the three tests, assuming that the only visual property to change during the test is the one that is to be analyzed in each case. The background of the image is achromatic (gray) and has a luminance with a magnitude that guarantees that the test runs in conditions of photopic response (about 30 candelas / m ² ).

[0069] Regarding the description of the stimuli presented during the different psychophysical tests, the following parameters are tested:

Comparison of points with different speeds;

 Comparison of points with different luminances;

 Comparison of points with different color contrasts.

These parameters are tested for various eccentricities which also allows comparing the evolution of each of these along the various eccentricities (see Figure 5). In this figure is represented the embodiment wherein the distance from the test point and the reference point is 7.5 degrees for the meridian at 0 degrees (5rl, 5r2), 10 degrees for the meridian at 90 degrees (5gl, 5g2); 15 degrees for the meridian at 45 degrees (5Î,, 5y2) or 15 degrees for the meridian at 135 degrees (5b, 5b2). As regards the comparative velocity test, according to Figure 4 (4a), both points (a1, a2) correspond to a maximal (white) achromatic stimulus, differing only from each other the value of the velocity to which they move , maintaining the point at a constant velocity and establishing the reference point (al), while the other point (a2) clearly starts at a higher speed (the desired maximum velocity is at 50 visual degrees per second) successively from the reference speed as the individual hits the laterality of the fastest point. The comparative judgment of the individual then comes up with the answer to the question, "What is the fastest point?"

Since conventional monitors operate at a refresh rate of 60 Hz, this implies that it is possible to change frame from 1/60 to 1/60 second, which for a short distance as a degree and for high speeds, that the movement of the point is not perceived, since, in 1/60 seconds, few points, or possibly none, are shown between the extremes of this distance due to the high velocity that the point has. The analysis of the fastest point can then be intuitively misrepresented because of this effect, making the point even judged to be the slowest.

Assuming that for a correct perception of velocity a simulation of a continuous motion in space is required and not a "bouncing" motion, it is necessary to have several points along a path, the more the better.

[0074] This number of points can be calculated as follows:

Route X Refresh Rate

Points - ^ro ¾; - ^-: - 1

 View Maxima deity

[0075] Where the path is given at visual angles, the refresh rate is given in hertz and the maximum velocity is given at visual angles per second. From here, for example, having 10 points on a 1-degree path of visual angle for a monitor with a refresh rate of 60 Hz, we have:

 l X 60

Maximum Speed = i J = 6 ^a fs

10 To overcome this difficulty and to reach a high speed there would be three options:

Increase the refresh rate of the monitor;

 Increase the path; or

 Decrease the number of points.

Since the third option referred to leads to a misperception and the first involves expensive monitors, the present invention contemplates a compromise between reducing the number of points and increasing the distance with a view to achieve desired speeds without compromising perception. The option was thus to increase the range of motion to 2 degrees of visual angle, with a maximum speed with a minimum of 5 points, which allows to have at most a speed of 24 degrees per second.

With respect to the comparative test of achromatic / luminance contrast, according to Figure 4 (4b), the peripheral point stimuli are defined in the same way used in the comparative speed test, based on short duration stimuli of the order of 400 to 900 milliseconds, soon of small size, with a movement of reduced spatial amplitude, with the stipulated 2 degrees of visual angle. The velocity of the colon is equal and constant throughout the test, taking the value of 5 visual degrees per second.

Both points (b1, b2) correspond to an achromatic (gray) stimulus, differing only in gray luminance (several tones along the white-black axis), one constant luminance point being established by establishing the point (b), while the other point (b2) starts clearly brighter, approaching successively the reference luminance as the subject strikes the laterality of the brighter point. The comparative judgment of the individual is then the answer to the question: "What is the brightest (whiter) point?"

With respect to the comparative chromatic / color test, according to Figure 4 (4c), the peripheral point stimuli were defined as in the comparative speed test and were based on short duration stimuli, between 400 and 900 milliseconds, of small size, with a movement of spatial amplitude reduced of about 2 degrees of visual angle. The velocity of the colon is equal and constant throughout the test, taking the value of 5 visual degrees per second.

The reference point (cl) consists of an achromatic stimulus, whereas the test point (c2) has a chromatic contrast with respect to the reference point. They differ only between themselves the value of this chromatic contrast made along axes that isolate a type of cone. One point keeps the chromaticity constant (eg gray) by setting the reference point, while the other point clearly begins with a sharp color (eg red), approaching successively the chroma reference, as the individual hits the laterality of the dot with color. The comparative judgment of the individual is then the answer to the question: "What is the point with color?"

Alternatively, the reference point may have a color in contrast to a test point, with one point starting at a given chromaticity (eg red) setting the reference point, while the other point begins with a contrasting color (for example, green), approaching one color successively in the other, as the individual hits the laterality of the point with a given color. The comparative judgment of the individual is then the answer to the question: "What is the point with green color?".

For each of the above parameters (speed, luminance and color), the threshold of retinal sensitivity is evaluated.

The threshold is calculated by an adaptive method with a logarithmic staircase function. The number of inversions to complete the test and the number of inversions used to calculate the threshold will be the target of post-validation optimization of the tests, for validation, safe parameters will be chosen for these two properties.

The validation curve has on the XX axis the test number and on the YY axis the value of the property distinguishable between the reference point and the altered point. As regards the presentation of test results, their simultaneous visualization - of the psychophysical tests and of the interface - on two monitors implies the visualization configuration of these in dual view mode, taking into account that the presentation of stimuli should occur on the monitor set as the primary monitor. Both monitors should have the same screen resolution, color and refresh rate.

The laterality in which the reference point appears and the test point is random, either point has a rectilinear trajectory of the shuttle type, moving along its line (line segment) and when encountering one end of that line segment reverses the direction of movement. This line where the points move takes several angles - also these random - and positions itself to different eccentricities according to the chosen meridian of test.

The embodiments described above are combinable with each other.

The present invention is of course not in any way restricted to the embodiments described herein and a person having ordinary skill in the art may foresee many possibilities of modifying it and replacing technical features with other equivalent ones depending on the requirements of each situation as defined in the appended claims.

Claims

R E I V I N D I C A T E S

A method for performing a visual psychophysical test using a monitor for applying visual stimuli to an individual comprising the following steps:

displaying two mobile peripheral point visual stimuli, a reference point and a test point, in opposing visual regions, wherein the reference point and test point has between them a predetermined difference value of a visual parameter,

record the response by the individual, indicating the point of reference or test that the individual considers to have a higher value of said visual parameter, to repeat the steps of displaying stimuli and recording the response,

by randomly altering the opposing visual hemi- fields of the reference point and the test point, and

gradually reducing the values of difference of the visual parameter until the moment the individual's response misses the indication of the reference or test point having the highest value of said visual parameter to obtain the threshold of retinal sensitivity of the individual of said parameter visual.

A method according to the preceding claim, wherein the visual stimuli are displayed in a range of isolating chromatic coordinates by prior RGB calibration of each channel of said monitor.

A method according to any one of the preceding claims, wherein said stepwise reduction is calculated through a logarithmic staircase function.

A method according to the preceding claim, wherein the visual parameters tested are motion, luminance and color, wherein the motions of the reference point and the test point occur at different speeds from one another, or the luminances of the reference point and the test point are different from each other, or the chromaticity of the reference point and the test point are different between yes to test the visual parameters of, respectively, motion perception, luminance and color.

The method according to the preceding claim, wherein the set point is displayed at a constant speed, luminance or chromaticity and the test point is displayed at a variable velocity, luminance or chromaticity, respectively, for testing the visual parameters of movement, luminance and color, respectively.

Method according to any one of the preceding claims, wherein the motions of the reference point and the test point are pendular motions.

A method according to any one of the preceding claims, wherein the reference point and the test point are displayed on the same meridian.

Method according to any one of the preceding claims, wherein the motions of the reference point and the test point occur along a linear trajectory of 1 to 3 degrees of visual angle, in particular 2 degrees of visual angle.

A method according to any one of the preceding claims, wherein the set point and the test point are displayed at identical and different assay eccentricities.

A method according to any one of the preceding claims, wherein the distance from the test point and the reference point is 7.5 degrees for the meridian at 0 degrees, 10 degrees for the meridian at 90 degrees, and 15 degrees for the meridian a 45 or to the meridian at 135 degrees.

A method according to any one of the preceding claims, wherein the peripheral point visual stimuli are of short duration between 400 and 900 milliseconds.

A method according to any one of the preceding claims, wherein the movement of the test point is displayed at a maximum speed of 50 visual degrees per second to test the visual parameter of movement.

A method according to any one of the preceding claims wherein the movement of the test point is displayed at a maximum rate of 24 visual degrees per second on a monitor with a refresh rate of 60 Hz to test the visual parameter of motion.

A method according to any one of the preceding claims, wherein the reference point and the test point are achromatic square points of 0.3x0.3 degree dimensions for testing the visual movement parameter or the luminance parameter.

A method according to any one of the preceding claims, wherein the test point is an achromatic square point to the periphery and chromatic in the center, with dimensions of 0.6x0.6 degrees to test the visual parameter of color.

A method according to any one of the preceding claims, which comprises validating the visual psychophysical test by verifying whether the patient fixation coincides with the central fixation point located on the monitor.

A method according to the preceding claim, wherein the alignment of the subject's visual axis relative to the central fixation point is verified by an eye-tracker device.

A device for performing psychophysical visual tests, comprising a data processor configured to perform the method for performing visual psychophysical test using a monitor to apply visual stimuli to an individual according to any one of claims 1-17.

A system for performing psychophysical visual tests from a personal computer comprising:

 a computer monitor connected to said computer;

 computer configured to perform the method for performing a psychophysical visual test using a monitor to apply visual stimuli to an individual according to any one of claims 1-17;

 said computer being connected to said monitor to display said movable peripheral point visual stimuli.

A non-transient data storage medium comprising programming instructions for implementing a device for performing psychophysical visual tests, the programming instructions including executable instructions for performing the method of any one of claims 1-17.