JPH0928672A - Device for pulpillometry and alzheimer's disease diagnosis - Google Patents

Abstract

PROBLEM TO BE SOLVED: To measure the magnitude of the pupil accurately. SOLUTION: Light sources 3A, 3B project light pulsating at a prescribed period upon eyeballs 22A, 22B. Video cameras 1A, 1B are directed at the eyeballs 22A, 22B, and output image signals about the pupils. The image signals arrive at a digital computer 8 via video camera control units 4A, 4B, a multiplexer 6, and an A/D converter 7. The digital computer 8 processes the image signals for the determination of the magnitude of the pupils.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pupil measuring device for measuring the size of the pupil and a device for diagnosing Alzheimer's dementia (Alzheimer's disease) by measuring the pupil.

[0002]

2. Description of the Related Art It is said that there are about 1 million senile dementia patients in Japan, of which about half are said to have cerebrovascular dementia and the other half are said to have Alzheimer's disease. In the case of this Alzheimer's disease, there has been no conventional method for early diagnosis. Since a drug that delays the progression of the disease is currently being developed, it is possible to delay the progression of the disease if early diagnosis is possible. Therefore, a method for early diagnosis was expected.

Recently, American magazine SCIENCE (VO
(L.266 11NOVEMBER1994) published a method for early diagnosis of Alzheimer's disease by administering a dilated mydriatic drug to the eye and then measuring the enlargement ratio of pupil area or pupil diameter. There is no diagnostic device using this method yet.

[0004]

Therefore, a diagnostic device of this type is constructed by combining a conventional device such as a pupil image pickup unit and a data analysis unit for analyzing the data obtained from the pupil image pickup unit with respect to the enlargement ratio of the pupil area or the pupil diameter. The following problems occur when trying to create.

First, while the conventional pupil image pickup unit irradiates the eye with continuous light by using a continuous illumination device for image pickup,
The pupil was stimulated with flash light, and changes in the pupil area or pupil diameter for the following several seconds were measured. The above-mentioned method for early diagnosis of Alzheimer's disease is required to measure changes in the size of the pupil over 30 minutes to 1 hour. However, during such a long-time measurement, eye movements often occur, and subject blurring occurs, making it difficult to accurately measure the pupil area or pupil diameter.

For example, in order to process a signal obtained from a video camera and reproduce an image on a monitor, the electronic shutter is normally set to 1/60 seconds, which is the standard, and every one minute from the video camera, that is, 1/60 seconds. Data of two consecutive fields is taken from the data output at intervals of 1 to create one screen (one frame) on the monitor screen. In this case, if fast eye movements occur, slippage occurs in the images of the pupils of the two fields with an interval of 1/60 seconds. This will be described in detail as follows.

Eye movements are roughly classified into two types, a slow phase and a rapid phase. The slow phase refers to the slow movement of the eye movement, and the rapid phase refers to the fast movement of the eye movement. What is the rapid phase?
For example, when looking at a train passing through a railroad crossing from left to right, it means a movement to return the eyeball to the left in an instant.
On the contrary, the slow phase means the movement of the eyeball when chasing the train from left to right. The rotational speed of the eyeball in the rapid phase is said to be 300-500 degrees / sec. Temporarily 500 degrees / se
When c, the surface of the eyeball or the pupil that moves with the surface moves as follows. Here, it is assumed that the diameter of the eyeball is 30 mm as shown in FIG. The opening time of the electronic shutter is 1/60 second of the standard. (1) The moving speed of the pupil center is π × 30 × (500/360) mm / se
c = approximately 131mm / sec (2) The moving distance of the pupil center for 1/60 seconds is (131mm / sec)
× (1 / 60sec) = approximately 2.2mm (3) The blurring of the pupil as a subject is as follows.

The size of the pupil is generally about 3 to 5 mm in diameter. Here, it is assumed that it is 4 mm as shown in FIG.
A pupil with a diameter of 4 mm moves 2.2 mm within 1/60 seconds, which means that the diameter in the major axis direction is about 6.2 mm, as shown in Fig. 10.
This means that it will appear as a substantially elliptical image with a diameter of about 4 mm in the minor axis direction. In this case, the apparent area is about the true area.
It becomes more than 150% and more than 50% error occurs. For this reason, it is impossible to accurately measure the pupil area or pupil diameter.

Therefore, as one method, the opening time of the electronic shutter is kept at 1/60 seconds of the standard, but the same one-field data obtained from the video camera is used twice, and one screen (1 You can use the method of creating a frame). But with this method, if continuous lighting
The image blurs during one field for 1/60 seconds, resulting in an unclear pupil image.

As another measure, there is a method in which the open time of the electronic shutter is set to a short time such as 1/1000 second and continuous illumination of strong light is used. According to this method, as described above, when the rotation speed of the eyeball is 500 degrees / sec and the diameter of the eyeball is 30 mm, the moving speed of the pupil center that moves along the surface of the eyeball is about 131 mm / sec. The movement distance of the pupil center for 1/1000 seconds is (131 mm / sec) × (1/1000 sec) = 0.131 m
m. When the diameter of the pupil is assumed to be 4mm area of the pupil of the apparent compared to the true area, 4.131 ^{2/4 2} = 1.067
(Double), and the error is reduced to about 6.7%.

However, continuous irradiation of strong light on the eyeball is not practical because it may cause corneal damage. On the contrary, the opening time of the electronic shutter is reduced to 1 /
If the time is as short as 1000 seconds, the image becomes dark and image analysis becomes difficult, making it unsuitable for measuring the size of the pupil.

Next, the data analysis unit for analyzing the data obtained from the pupil image pickup unit. Conventionally, since the data regarding the size of the pupil obtained at every predetermined time is used as it is, the pupil itself is reduced or enlarged. However, the fact that the area is constantly changing was ignored and caused an error. For example, if the first measurement value of the pupil area is 100% and the subsequent pupil area is measured once every 0.2 seconds for 40 seconds, the pupil area constantly changes as shown in Fig. 7, and the rate of change is 100- 13
It reaches about 0%. Therefore, it is sufficient to measure minute movements for a short time, but it is not a good method for measuring total changes for a long time, and it is difficult to make a correct diagnosis from such data. there were.

The present invention has been made in view of the fact that it is impossible to diagnose Alzheimer's disease that requires a long measurement time with such a combination of conventional devices, and its object is to accurately determine the size of the pupil. Since clear pupil image data for measurement can be obtained, and even if the measurement data of the pupil area or pupil diameter fluctuates slightly, averaged data can be obtained, enabling accurate diagnosis of Alzheimer's disease. It is to provide a device.

[0014]

The invention according to claim 1 is
As shown in FIG. 8 (A), a video camera a installed toward the eyeball of the subject, a light irradiation means b for irradiating the imaging light of the video camera a in a pulse shape at a predetermined cycle, The video signal output from the video camera a is processed to detect a quantity relating to the size of the pupil by a predetermined number at a plurality of time points.

The invention according to claim 2 is, in the invention according to claim 1, as shown in FIG. 8 (B), an average value for calculating an average value of amounts relating to the size of a predetermined number of pupils detected by the detecting means c. A value calculating means d is provided.

The invention according to claim 3 is, as shown in FIG. 8C, a video camera a installed toward the eyeball of the subject.
A light irradiating means b for irradiating the image pickup light of the video camera a in a pulse shape at a predetermined cycle; and the video camera a.
A detection means c for processing a video signal output from the detection means to detect a predetermined amount of a quantity relating to the size of the pupil at a plurality of time points, and whether or not Alzheimer's disease is present is determined based on the quantity detected by the detection means c. And a determination means for performing the determination.

According to a fourth aspect of the invention, as shown in FIG. 8 (D), a video camera a installed toward the eyeball of the subject.
A light irradiating means b for irradiating the image pickup light of the video camera a in a pulse shape at a predetermined cycle; and the video camera a.
Detecting means c for processing a video signal output from the device to detect a predetermined number of pupil size quantities at a plurality of time points, and an average value of a predetermined number of pupil size quantities detected by the detecting means c. The average value calculating means d for calculating the above is provided, and the determining means e for determining whether or not it is Alzheimer's disease based on the average value of the amount relating to the size of the pupil calculated and calculated by the average value calculating means d.

The invention according to claim 5 is, as shown in FIG. 8 (E), a video camera a installed toward the eyeball of the subject.
And a light irradiating means f for irradiating the image pickup light of the video camera a and a video signal output from the video camera a to detect an amount relating to the size of the pupil by a predetermined number at a plurality of time points. Based on the detection means c, the change rate calculation means g for calculating the change rate of the size of the pupil between at least one set time point based on the amount detected by the detection means c, and the change rate calculation means. And a determining means (e) for determining whether Alzheimer's disease is present or absent based on the rate of change of the amount relating to the pupil size.

[0019]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the invention according to claim 1, the light irradiation means b irradiates the eyeball of the subject with light for imaging in a pulsed manner. The video signal output from the video camera a is the video signal of the pupil irradiated with the pulsed light, and the detection means c processes the video signal to obtain a predetermined number of amounts relating to the size of the pupil for a plurality of time points. Detect one by one.

In the invention according to claim 2, the average value calculating means d calculates the average value of the quantities relating to the size of the predetermined number of pupils detected by the detecting means c.

In the invention according to claim 3, the light irradiating means b irradiates the eyeball of the subject with light for imaging in a pulsed manner. The video signal output from the video camera a is the video signal of the pupil irradiated with the pulsed light, and the detection means c processes the video signal to obtain a predetermined number of amounts relating to the size of the pupil for a plurality of time points. Detect one by one. Determination means e
Determines whether Alzheimer's disease or not based on the amount detected by the detection means.

In the invention according to claim 4, the light irradiating means b irradiates the eyeball of the subject with light for imaging in a pulsed manner. The video signal output from the video camera a is the video signal of the pupil irradiated with the pulsed light, and the detection means c processes the video signal to obtain a predetermined number of amounts relating to the size of the pupil for a plurality of time points. Detect one by one. The average value calculation means d calculates the average value of the quantities related to the size of the predetermined number of pupils detected by the detection means c. The determination means e determines whether or not Alzheimer's disease is based on the average value of the amount related to the size of the pupil calculated and calculated by the average value calculation means.

In the invention according to claim 5, the light irradiation means f irradiates the eyeball of the subject with the light for imaging. The video signal output from the video camera a is the video signal of the pupil irradiated with this light, and the detection means c processes this video signal to detect a predetermined number of pupil size quantities at a plurality of time points. . The rate-of-change calculating means g calculates the rate of change in the size of the pupil between at least one set time point based on the amount detected by the detecting means c. Further, whether or not Alzheimer's disease is present is determined based on the average rate of the amount relating to the size of the pupil calculated and calculated by the change rate calculating means.

[0024]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The overall construction of the first embodiment will be described with reference to FIG. The pair of video cameras 1A and 1B each include an optical lens and an image sensor, convert a subject into a two-dimensional image, divide the image into a plurality of pixels, convert each pixel into an electric signal, and convert them into electric signals. The data is output in a predetermined order. In this embodiment, the image sensor is a CCD. In addition, since infrared rays are used in this embodiment, visible light cut filters 2A and 2B for eliminating visible light that becomes noise are provided in front of the video cameras 1A and 1B. Light sources 3A and 3B are provided near the video cameras 1A and 1B, respectively. Light source 3A, 3
B is an LED that emits infrared light.

The video cameras 1A and 1B, the visible light cut filters 2A and 2B, and the light sources 3A and 3B are the goggles 20 as shown in FIG.
It is an element constituting. That is, they are attached to and integrated with the goggle body 21. Light source 3A, 3B
Comprises a plurality of LEDs, which are arranged around the front of the video cameras 1A and 1B.

Referring again to FIG. 1, the pair of video camera control units 4A and 4B are the video camera 1
The timing of the operation of the electronic shutters A and 1B, that is, the exposure cycle and exposure time, is controlled, and the video camera 1 is controlled.
A, 1B controls the output of video cameras 1A, 1B
A composite video signal in which a synchronizing signal is included in the video signal output from the PDP is created and output. Synchronous lighting circuit 5
A and 5B are light sources 3A and 3B based on the sync signal of the composite video signal output from the video camera control units 4A and 4B.
This determines the timing of the blinking of B.

The multiplexer 6 selects and outputs each output of the video camera control units 4A and 4B. The A / D converter 7 converts the output of the multiplexer 6 into a digital signal and outputs it.

The digital computer 8 includes video camera control units 4A and 4B, synchronous illumination circuits 5A and 5B,
It controls the multiplexer 6 and the A / D converter 7, and processes the output data of the A / D converter 7.
In this embodiment, it is a personal computer.

The digital computer 8 has a CPU 9
The main memory 10 connected to the CPU 9, the external storage control unit 11, the input / output control unit 13, the keyboard control unit 14, the display control unit 15, the printer control unit 16, the external storage control unit 11,
External storage device 12 connected to keyboard control unit 14, display control unit 15, and printer control unit 16, respectively, keyboard
17, a display device 18 and a printer 19 are provided. CPU
Reference numeral 9 generally controls the digital computer 8 as a whole, and controls various parts and processes data based on a program stored in the main memory 10. The main memory 10 includes a ROM (read only memory) and a RAM (read / write memory). The ROM stores programs and data necessary for the CPU 9 to execute the programs read from the external storage device 12 to the RAM. The RAM stores data necessary for the CPU 9 to perform data processing or data processing results. Various programs and data are stored in the external storage device 12, and the program of FIG. 3 is stored in this embodiment.

The external storage control unit 11 controls the reading and writing of data with respect to the external storage device 12 according to an instruction from the CPU 9. The input / output control unit 13 controls transmission / reception of data to / from an external device or transmission of a control signal.

The keyboard 17 has a plurality of keys and, when these keys are pressed, outputs a signal corresponding to them. The keyboard control unit 14 controls an output signal of the keyboard 17 according to an instruction from the CPU 9 and stores the output signal in the main memory 10. The display device 18 is for visually displaying the given data on a display screen, and is a CRT in this embodiment. The display control unit 15 is provided with a main memory
The data stored in 10 is displayed on the display device 18. The printer 19 prints given data on paper. The printer control unit 16 controls the printer 19 in accordance with an instruction from the CPU 9, and causes the printer 19 to perform printing based on the data stored in the main memory 10.

In this embodiment, the video cameras 1A and 1B
, Light sources 3A and 3B, synchronous lighting circuits 2A and 2B, video camera control units 4A and 4B, and multiplexer 6
The A / D converter 7 and the means constituting the digital computer 8 and the means corresponding to the function of processing the video signal to detect the size of the pupil constitute the pupil measuring apparatus. Of these, the video cameras 1A and 1B correspond to the video cameras, and the light emitting means are composed of the light sources 3A and 3B and the synchronous illumination circuits 5A and 5B.
A, 4B, a multiplexer 6, an A / D converter 7, and a detecting means is composed of a means corresponding to a function of processing a video signal and detecting a size of a pupil among means constituting the digital computer 8. ing.

Further, in the present embodiment, each element constituting the pupil measuring device and means corresponding to the function of judging whether or not Alzheimer's disease is present based on the size of the pupil among the means constituting the digital computer 8. An Alzheimer's disease diagnostic device is configured from. Each element constituting the pupil measuring device corresponds to each element of the above-described embodiment, and corresponds to a function of the means constituting the digital computer 8 for determining whether Alzheimer's disease or not based on the size of the pupil. The means for doing corresponds to the determining means.

Next, the operation of the apparatus of this embodiment thus constructed will be described with reference to the flowchart of FIG. Here, by operating the keyboard 17, the program shown in the flowchart of FIG.
It is assumed that M has been read.

(1) Before administration of mydriatics; in step 301, the subject first puts on the goggles 20 shown in FIG. 2 and prepares for measurement. At this time, as shown in FIG. 1, the left eye 22A is located in front of the video camera 1A, and the right eye 22B is located in front of the video camera 1B. Next, in step 302, when the power of this apparatus is turned on and the measurement is started, the measurement in step 303 is started. As a result, the composite video signals of the left and right eyes are output from the video camera control units 4A and 4B, respectively, as shown in FIGS. 4 (a) and 4 (b). As shown in FIG. 4 (c), the synchronous illumination circuit 5A synchronizes with the synchronous signal of the output of the video camera control unit 4A and outputs a pulse signal having a width of 1 millisecond to the light source 3A, for example. The light source 3A is turned on at the cycle and width designated by this signal. Similarly, the synchronous illumination circuit 5B is synchronized with the synchronous signal of the output of the video camera control unit 4B as shown in FIG. 4 (d), and the period is 0.
It outputs a pulse signal with a width of 1 microsecond for 2 seconds to the light source 3A. The light source 3B is turned on in the time width designated by this signal. The electronic shutter of the video cameras 1A and 1B is controlled by the video camera control units 4A and 4B so that the synchronous illumination circuit
5A and 5B are designed to open at the same timing as when the light sources 3A and 3B are turned on. The multiplexer 6 selects the output of the video camera control unit 4A at the timing of FIG. 4 (e) and outputs it to the A / D converter 7, and selects the output of the video camera control unit 4B at the timing of FIG. 4 (f). Output to the A / D converter 7. For this reason,
The outputs of the video camera control units 4A and 4B are alternately A / D converted for each field and given to the digital computer 8.

On the other hand, the CPU of the digital computer 8
At step 305 shown in FIG. 3, the reference numeral 9 starts the first clocking and, at the same time, fetches the video signals for each of the left and right fields output from the A / D converter 7 and stores them in the RAM of the main memory 10. Next, the CPU 9 carries out step 30.
Proceed to step 6 and binarize the captured video signals for each of the left and right fields to form the contour of the pupil image clearly. Next, the CPU 9 proceeds to step 307, obtains the pupil area from the images of the formed left and right pupils, and stores the data in the RAM of the main memory 10. Next, the CPU 9 proceeds to step 308, waits for 1 minute from the start of the first clocking, and proceeds to step 309 if 1 minute has elapsed. Here, the light source is turned off and the pulsed light irradiation is stopped.

Next, the CPU 9 proceeds to step 310 to obtain the average value of the pupil area for each of the left and right sides obtained so far, and stores them in the RAM of the main memory 10.
If the CPU 9 determines in step 308 that one minute has not elapsed, it returns to step 306. CPU9
After the processing of step 310, waits until a measurement start instruction is given by the key operation of the keyboard 17. Here, the examiner removes the goggles 20 attached to the subject and administers the mydriatic agent to the eyeball of the subject. Then, the subject wears the goggles 20 again. When the inspector confirms that the goggles 20 are properly attached to the subject, the keyboard 17
Input the measurement start instruction by operating the key.

(2) After administration of mydriatic agent: When the measurement start instruction is given in step 312 shown in FIG. 3, the CPU 9 adds 1 to the number of times of measurement and starts the first measurement. That is, returning to step 304 described above, measurement and storage of the pupil area after administration of the mydriatic agent are started. The measurement after administration of the mydriatic agent in this example is performed in step 30.
6 and step 307 are repeated, and the 1-minute measurement is programmed once every 7 minutes for a total of 5 times. Therefore, the pupil areas obtained by subdividing the one minute and measuring a plurality of times are averaged and stored in step 310. Thereafter, the CPU 9 measures the time for waiting 6 minutes in step 311. When it is confirmed that 6 minutes have elapsed in the time measurement, 1 is added to the number of measurements in step 312, and the next measurement is started. This measurement is repeated until it is confirmed that the measurement is completed 5 times in step 313, that is, up to 30 minutes after administration of the mydriatic agent.

The CPU 9 stores the data averaged in step 310 and, at the same time, calculates the ratio to the pupil area before administration of the mydriatic agent and draws a graph as shown in FIG. 5 on the screen of the display device 17. Is programmed to. Further, in FIG. 5, the data for the left eye to which the mydriatic agent has been administered and the data for the right eye to which the mydriatic agent has not been administered are simultaneously displayed so that the comparison can be facilitated. In addition, in the figure, the images of the right eye and the left eye themselves are also displayed in an overlapping manner, so that the state of change is also observed and configured to assist diagnosis.

In step 314, the CPU 9 determines whether Alzheimer's disease or not based on the measurement result. This determination is performed as follows.

First, the CPU 9 finds the lowest value among the average values every 3 seconds in the last one minute measurement (fifth measurement), and if the value exceeds 113 (%), it is Alzheimer's disease. It is determined that there is, and if the value does not exceed 113 (%), it is determined that it is not Alzheimer's disease, and the results are displayed on the display device 18.

Next, the grounds for making such a determination will be described. First, when the measurement for one minute is performed five times, the data as shown in FIG. 5 is displayed on the display screen of the display device 18 as described above. Here, the end point of the measurement for the last 1 minute is the point of time when 29 minutes have passed since the mydriatic drug was administered to the subject. At the time when 29 minutes have passed, the dilation rate of the pupils of Alzheimer's disease patients and those without Alzheimer's disease is clearly different as shown in FIG. 6 (see the above-mentioned science journal). In other words, the pupils of Alzheimer's disease patients receive mydriatics 29
After the lapse of minutes, the expansion rate is 113% or more.

In this embodiment, the state of the change in the pupil of the subject is displayed on the display device in real time, so that the examiner can immediately determine the medical condition of the subject. On the other hand, the video signal output of the video camera at the time of measurement may be recorded using a recording device, and the signal may be analyzed later. Also in this case, for example, after performing the measurement for 1 minute, and providing a blank for 6 minutes several times, the recording device is kept in the recording state during the whole measurement.
The illumination should be turned on at a certain cycle (for example, 1/60 second cycle) only during measurement (for example, 1 minute). If you do this, you can see the elapsed time of the measurement when playing the recording,
Analysis work becomes easy. In addition, since the eyeball is not irradiated for a long time, the corneal disorder that has occurred during continuous illumination does not occur. Especially in the case of infrared light, the effect is great.

In this embodiment, when the size of the pupil is measured, the area of the pupil is measured. However, the diameter of the pupil may be measured.

In this embodiment, since the visible light cut filter is provided on the front surface of the video camera and the infrared light is used as the image pickup light, it is unnecessary for the measurement even when the goggles are removed from the subject. A large amount of natural light is not taken in as a video signal. Therefore, it is possible to accurately measure the pupil diameter or the pupil area.

In the above example, Alzheimer's disease was diagnosed by observing the dilation rate of the pupil for about 30 minutes after applying the mydriatic agent. However, it is not possible to impose long-time measurement on patients suffering from this kind of illness, which impedes accurate diagnosis. Therefore, the second
In the embodiment of the present invention, as is clear from the graph of FIG. 6, the diagnosis is made by focusing on the fact that the expansion rate (change rate) of the pupil area or pupil diameter of Alzheimer's disease patients is considerably large from the start of measurement. An apparatus for performing the operation is provided. Specifically, the first measurement value (enlargement ratio) in FIG.
The diagnosis of this disease is made when the slope connecting the second measurement value (magnification rate) and the second measurement value becomes equal to or larger than a predetermined value. According to this embodiment, quick measurement can be performed in a shorter time without burdening the patient.

According to the present embodiment, a plurality of time points in the vicinity of each predetermined time point are measured, the average value thereof is taken, and the respective slopes are obtained based on this, so that a highly reliable value is obtained. Obtainable.

[0048]

According to the first aspect of the present invention, the light for imaging is applied to the pupil in a pulsed manner, so that the light quantity required for imaging can be obtained even if the exposure time is short. Therefore, a clear image of the pupil can be obtained even if eye movement occurs during measurement, and the size of the pupil can be accurately measured.

According to the second aspect of the invention, since the average value of the measured pupil size is taken, even if each measured value includes an error, it is affected as a whole by this. The size of the pupil can be measured almost accurately.

According to the third aspect of the present invention, a clear image of the pupil can be obtained even if eye movements occur during measurement, so that it can be accurately determined whether or not Alzheimer's disease is present.

According to the fourth aspect of the present invention, it is possible to accurately determine whether or not Alzheimer's disease is present even if the measured values of the size of each pupil include a large error.

According to the invention of claim 5, Alzheimer's disease can be determined in a short time.

[Brief description of drawings]

FIG. 1 is a diagram showing an overall configuration of an embodiment of the present invention.

FIG. 2 is a diagram showing the appearance of goggles used in an embodiment of the present invention.

FIG. 3 is a diagram showing a flowchart for explaining the operation of the embodiment of the present invention.

FIG. 4 is a diagram showing a timing chart for explaining the operation of the embodiment of the invention.

FIG. 5 is a diagram showing an example of data displayed on the display device according to the embodiment of the present invention.

FIG. 6 is a diagram for explaining changes in pupil area of Alzheimer's patients and those not.

FIG. 7 is a diagram showing changes in the measured values of the pupil area when the average is not calculated.

FIG. 8 is a diagram showing a schematic configuration of the invention according to each claim of the present application.

FIG. 9 is a diagram for explaining a moving speed of a pupil center due to eye movement.

FIG. 10 is a diagram for explaining blurring of a pupil as a subject.

[Explanation of symbols]

 1A, 1B Video camera 3A, 3B Light source 4A, 4B Video camera control unit 5A, 5B Synchronous lighting circuit 6 Multiplexer 7 A / D converter 8 Digital computer

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[Procedure amendment]

[Submission date] July 3, 1996

[Procedure amendment 1]

[Document name to be amended] Drawing

[Correction target item name] Fig. 5

[Correction method] Change

[Correction contents]

[Figure 5]

Claims (5)

[Claims] 1. A video camera installed toward an eyeball of a subject, a light irradiating unit for irradiating the image pickup light of the video camera in a pulse shape at a predetermined cycle, and the light output from the video camera. A pupil measuring device, comprising: a detection unit configured to process a video signal and detect a predetermined amount of a plurality of pupil sizes at a plurality of time points. 2. The pupil measuring apparatus according to claim 1, further comprising an average value calculating means for calculating an average value of the quantities relating to the size of a predetermined number of pupils detected by said detecting means. 3. A video camera installed toward the eyeball of the subject, a light irradiating means for irradiating the image pickup light of the video camera in a pulse shape at a predetermined cycle, and the light output from the video camera. Alzheimer's disease diagnosis comprising a detection means for processing a video signal to detect an amount relating to the size of the pupil at a plurality of time points, and a determination means for determining whether or not Alzheimer's disease is detected based on the amount detected by the detection means. apparatus. 4. A video camera installed toward an eyeball of a subject, a light irradiating unit for irradiating light for imaging by the video camera in a pulse shape at a predetermined cycle, and output from the video camera. Detecting means for processing the video signal to detect a predetermined number of pupil size quantities at a plurality of time points, and an average value calculation for calculating an average value of the predetermined number of pupil size quantities detected by the detecting means. An Alzheimer's disease diagnosing device comprising: means and a judging means for judging whether or not Alzheimer's disease is present, based on the average value of the amount relating to the size of the pupil calculated and calculated by the average value calculating means. 5. A video camera installed toward the eyeball of the subject, a light irradiating means for irradiating the image pickup light of the video camera in a pulse shape at a predetermined cycle, and the video camera outputs the light. Detecting means for processing the video signal to detect an amount relating to the size of the pupil for a plurality of time points, and a change rate of the size of the pupil between at least one predetermined time point based on the amounts detected by the detecting means. An Alzheimer's disease diagnostic apparatus comprising: a change rate calculating means for calculating the change rate; and a means for determining whether Alzheimer's disease is present or absent based on the change rate of the amount related to the size of the pupil calculated and calculated by the change rate calculating means.