FR3001118A1 - Method for assisting measurement of visual acuity of patient, involves determining distance between display support and eye of patient, and adjusting dimension of optotype display according to determined distance - Google Patents

Abstract

The method involves determining a distance between a display support and an eye of a patient (104) by measuring direct flight time between an acoustic wave i.e. ultrasonic wave emission unit (110) from an acoustic source and an ultrasonic wave reception unit (112) by an acoustic sensor. A dimension of an optotype display (102) is adjusted (106) according to the determined distance. An infra-red wave echo is transmitted (114) by an optical transmitter, and the infra-red wave echo is received (116) by an optical receiver. Independent claims are also included for the following: (1) a system for assisting measurement of visual acuity of a patient (2) a portable active target device.

Description

- 1 - "Method and system for assisting in the measurement of a patient's visual acuity, and portable device used in this system" Technical field The present invention relates to a method of assisting the measurement of a patient. visual acuity of a patient, implementing a dynamic display of o ptotype. It also relates to a system and device implementing such a device.

State of the Prior Art The primary function of measurement in ophthalmology is the measurement of visual acuity. Visual acuity consists of measuring the ability of the eye to discriminate two distinct points and thus to measure the smallest angle that can be measured by the human eye. Various embodiments of a device are known for testing the visual performance of an individual by evaluating his visual acuity. The various embodiments of a device for testing the visual performance of an individual all have at least one of the following two defects: either the patient has the head blocked in an apparatus for assessing his visual acuity, or the patient's distance to an optotype display device is not exactly the one prescribed to allow the analysis of the results.

In the first case, the patient is forced, in the second, the assessment of the visual acuity of the individual is wrong. Furthermore, the usual test machines cause a myopic effect due to the insertion of optical device between the patient and the display screen in the machine. The patient finds himself in identical conditions at the ophthalmology or optician's office. An object of the invention is to provide a device which makes it possible to overcome at least these disadvantages. Another object of the present invention is to propose a method and a portable device for testing the visual acuity of a patient making it possible to overcome at least one of the drawbacks of the state of the art recalled here: device more economical than current devices, - to propose a device usable by a person in general, ie which does not require any particular training on the proposed device, - to propose a light device, - to propose a device whose size allows it to be moved easily, in particular to carry out acuity checks of a driver along a road or in a patient's bed, and - to propose a device whose presence of a random character makes it difficult to cheat and therefore improves the accuracy of an acuity test.

DISCLOSURE OF THE INVENTION At least one of these objectives is achieved with a method of assisting the measurement of a patient's visual acuity, implementing an optotype display on a remote display medium. an eye of said patient, characterized in that it further comprises: - a determination of the distance between the display medium and the eye of said patient, and - a setting of at least one dimension of the optotype displayed, depending on the distance thus determined.

Obviously, the distance from the patient to the optotype display device is no longer erroneous. Knowing this distance, the display device can display an optotype of a good size. The method dynamically changes the optotypes based on the distance in real time.

No optical device is interposed between the patient and the screen. The effect of myopisation is thus avoided. There is no risk of learning because the optotypes can be displayed randomly on the display, as will be described below. Advantageously, the determination of the distance can result from a measurement of the direct flight time of an acoustic wave emitted from an acoustic source and received by an acoustic sensor. The source may be located at the display medium. The acoustic sensor may be located at an eye of the patient. Advantageously, the method according to the invention may furthermore comprise an echo to a reception of the acoustic wave by the acoustic sensor, an emission of an echo optical wave by an optical transmitter close to said acoustic sensor, and a reception said echo optical wave by an optical receiver close to the acoustic source. The optical transmitter can be located at an eye of the patient. The receiver of said echo optical wave can be located at the display medium. In addition, the measurement of direct flight time can be obtained by measuring a phase difference between the transmitted acoustic wave and the received echo optical wave. The use of an optics has the advantage that its zero propagation time can be considered over the distance separating its transmission and its reception, which makes it possible to consider only the direct flight time. Advantageously, the optical wave may comprise an infrared wave.

Advantageously, the acoustic wave may comprise an ultrasonic wave. In addition, the respective acoustic and optical waves may comprise respectively acoustic and optical pulse trains.

According to another aspect of the invention, there is provided a system for assisting in measuring a visual acuity of a patient, implementing the method according to any one of the preceding claims, comprising means for displaying a optotype, located remote from an eye of said patient, characterized in that it further comprises: - means for determining the distance between the display means and the eye of said patient, and - means for adjusting at least a dimension of the displayed optotype, depending on the distance thus determined. Advantageously, the distance determining means 35 comprise: means for transmitting an acoustic wave and acoustic reception means, and means for transmitting an optical wave echoing at the reception of the acoustic wave, located at level of the patient's eye, and means for receiving the optical wave; means for determining a phase difference between the transmitted acoustic wave and the received optical wave; and means for processing the phase shift thus determined so as to to generate information on the distance between the patient's eye and the display means. Advantageously, the means for receiving an acoustic wave and the means for transmitting an optical wave may be arranged on a strip disposed on the patient head. In addition, the optical transmission means and the optical reception means 15 may respectively comprise infrared transmitting means and infrared receiving means. In addition, the acoustic emission means and the acoustic reception means may comprise ultrasonic transmission means and ultrasonic reception means. In addition, the acoustic wave transmission means and the optical wave receiving means may be arranged at the display means, while the acoustic wave receiving means and The emission of the optical wave can be arranged at an eye of the patient. Alternatively, the acoustic wave emission means and the optical wave receiving means may be arranged at an eye of the patient, while the acoustic wave receiving means and the means for receiving emission of the optical wave can be arranged at an eye of the patient. According to another aspect of the invention, there is provided a portable active target device, implemented in a visual acuity measuring assistance system according to the invention, comprising means for receiving an acoustic wave emitted from the remote support, means for processing the received acoustic wave and generating an echo signal - means for transmitting an optical wave transmitted from the echo signal thus generated.

In addition, the distance determining means may comprise: means for transmitting an acoustic wave from the remote support for displaying an optotype; means for receiving an optical wave transmitted from said echo display medium; reception of the acoustic wave; means for determining a phase shift between the transmitted acoustic wave and the received optical wave; and means for generating an eye-display distance display information from the thus determined phase shift.

The means for emitting an acoustic wave may be located at the display medium. The means for receiving an emitted optical wave may be located at an eye of the patient. In addition, the acoustic emission means may comprise ultrasonic transmission means.

In addition, the optical reception means may comprise infrared reception means. Advantageously, the device according to the invention can be made in the form of a headband worn on the patient's head.

DESCRIPTION OF THE FIGURES AND EMBODIMENTS Other advantages and particularities of the invention will appear on reading the detailed description of implementations and non-limiting embodiments, and the following appended drawings: FIG. preferred embodiment of a method according to the invention, - Figure 2 describes a preferred embodiment of a system according to the invention - Figure 3 describes in particular a distance determination device implemented in a system according to the invention and FIG. 4 illustrates, in particular, an active target mobile, implemented in a visual acuity measuring assistance system according to the invention.

The same reference appearing in several figures conceals its numbering. Referring to Figure 1, will now be described a method 100 of assistance in measuring a visual acuity of a patient according to the invention. The method 100 implements a display 102 of an optotype on a display medium located remote from an eye of said patient. The method 100 further comprises: - a determination 104 of the distance between the display medium and the eye of said patient, and - a setting 106 of at least one dimension of the displayed optotype, as a function of the distance as well as determined. The determination 104 of the distance results from a measurement 108 of the direct flight time of an acoustic transmitted 110 from an acoustic source and received 112 by an acoustic sensor. In echo with the reception 112 of the acoustic wave by the acoustic sensor, a transmission 114 of an echo optical wave by an optical transmitter close to said acoustic sensor, and a reception 116 of said echo optical wave by a receiver optical close to the acoustic source. Measurement 108 of direct flight time is obtained by measuring 118 of a phase difference between the transmitted acoustic wave 110 and the received echo optical wave 116. As illustrated in FIG. 1, the display process of FIG. the optotype adapts dynamically to the distance between the patient's eye and the optotype display via a modification of the dynamic dimension of the optotype. Referring to Figure 2, will now be described a system 200 of assistance in measuring a visual acuity of a patient according to the invention. The system 200 implementing the method 100 previously described. The system 200 comprises: a screen 204 for displaying an optotype 206; a device 208 for determining the distance d; and means 210 for setting at least one dimension D of the displayed optotype 206, depending on the distance d determined.

The optotype 206 is located at a distance from an eye of said patient 202. The determined distance d is the distance between the display means 204 and the patient's eye 202. The system 200 also comprises a computer (not shown). The screen 204 displays an image generated by the computer. The means 210 for adjusting the dimension D of the optotype 206 displayed on the screen 204 are integrated into the computer in the form of a computer module. With reference to FIG. 3, a distance determining device 208 employed in the system 200 according to the invention will now be described. The device 208 comprises: - transmission means 212 of an acoustic wave 216, and acoustic reception means 214, - emission means 218 of an optical wave 220 echoing the reception of the acoustic wave 216. The optical wave 220 echoed of course the same amplitude X as that received via the acoustic wave, and means for receiving 222 the optical wave 220. The device 208 also comprises: - means for determining 224 a phase shift 226 between the acoustic wave 216 emitted and the optical wave 222 received, and - means for processing 228 the phase shift 226 thus determined so as to generate information on the distance d between the patient's eye 202 and the means 204. In Figure 3, the phase shift 226 appears in the form of the Greek letter (in FIGURE 3, the transmission means 212 of the acoustic wave 216 and the reception means 222 of the optical wave 220 are disposed at a patient's eye 202, tand that the reception means 218 of the acoustic wave 216 and the transmission means 218 of the optical wave 220 are arranged at the level of the display means 204. The optical transmission means 218 and the reception means optical 222 respectively comprise infrared transmitting means and infrared receiving means.

The acoustic emission means 212 and the acoustic reception means 216 comprise ultrasonic transmission means and ultrasonic reception means. In a variant of the device 208 of a system according to the invention 200, the transmission means 212 of the acoustic wave 214 and the reception means 222 of the optical wave 220 are arranged at the level of the display means 204. , while the reception means 216 of the acoustic wave 218 and the transmission means 218 of the optical wave 220 are disposed at an eye of the patient 202.

It is now described with reference to Figure 4 a device 400 according to the invention. Device 400 is a portable active target device. It is made in the form of a headband. The headband is worn on the patient's head 202.

The device 400 is implemented in a system 200 for assisting the measurement of visual acuity according to the invention. The device 400 comprises means for receiving 216 an acoustic wave 214 emitted from the remote display 204. The means 216 for receiving an acoustic wave 214 comprise ultrasonic reception means.

The device 400 also comprises means 402 for processing the acoustic wave received 214. The processing means 402 is a microcontroller configured to process such an acoustic wave. The microcontroller 402 is also configured to generate an echo signal.

The device 400 also comprises means for transmitting 218 an optical waveform 220 from the generated echo signal. The optical transmission means 218 comprise infrared transmission means. Of course, the invention is not limited to the examples which have just been described and numerous adjustments can be made to these examples without departing from the scope of the invention.

Claims (6)

REVENDICATIONS1. A method (100) for measuring a patient's visual acuity, using a display (102) of an optotype on a display medium located remote from an eye of said patient, characterized in that it further comprises: - a determination (104) of the distance between the display medium and the eye of said patient, and - a setting (106) of at least one dimension of the displayed optotype, in function of the distance thus determined. 2. Method according to the preceding claim, characterized in that the determination (104) of the distance results from a measurement (108) of the direct flight time of an acoustic wave emitted (110) from an acoustic source and received by ( 112) an acoustic sensor. 3. Method according to the preceding claim, characterized in that it further comprises, echoing a reception (112) of the acoustic wave by the acoustic sensor, a transmission (114) of an echo optical wave by an optical transmitter close to said acoustic sensor, and a reception (116) of said echo optical wave by an optical receiver close to the acoustic source. 4. Method according to the preceding claim, characterized in that the measurement (108) of direct flight time is obtained by measuring (118) a phase difference between the transmitted acoustic wave (110) and the echo optical wave received (116). 5. Method according to one of claims 3 or 4, characterized in that the optical wave comprises an infrared wave. 6. Method according to one of claims 2 to 5, characterized in that the acoustic wave comprises an ultrasonic wave. A method according to any one of claims 2 to 6, characterized in that the respective acoustic and optical waves comprise impulse trains respectively acoustic and optical. 8. System (200) for measuring a patient's visual acuity (202), using the method (100) according to any of the preceding claims, comprising means for displaying (204) an optotype (206), located at a distance from an eye of said patient (202), characterized in that it further comprises: - means (208) for determining the distance (d) between the display means (204) ) and the eye of said patient (202), and - means (210) for adjusting at least one dimension (D) of the displayed optotype (206), as a function of the distance (d) thus determined. 9. System (200) according to the preceding claim, characterized in that the distance determining means (208) (d) comprise: - means for transmitting (212) an acoustic wave (214), and acoustic reception means (216), - means for transmitting (218) an optical wave (220) echoing the reception of the acoustic wave (216) and means for receiving (222) the optical wave (220), - means for determining (224) a phase shift (226) between the transmitted acoustic wave (216) and the received optical wave (222), and - means for processing (228) the phase shift (226) thus determined so as to generate a information on the distance (d) between the patient's eye (202) and the display means (204). 10. System (200) according to claim 8 or 9, characterized in that the transmitting means (212) of the acoustic wave (216) and the receiving means (222) of the optical wave (220) are disposed at an eye of the patient (202), while the receiving means (218) of the acoustic wave (216) and the transmitting means (218) of the optical wave ( 220) are arranged at the display means (204). 11. System (200) according to claim 8 or 9, characterized in that the transmitting means (212) of the acoustic wave (214) and the receiving means (222) of the optical wave (220) are disposed at the display means (204), while the receiving means (216) of the acoustic wave (214) and the transmitting means (218) of the optical wave (220) are arranged at the level of the from an eye of the patient (202). 12. System (200) according to one of claims 9 to 11, characterized in that the optical transmission means and the optical reception means respectively comprise infrared transmitting means and infrared receiving means. 13. System (200) according to claim 12, characterized in that the acoustic emission means and the acoustic reception means comprise ultrasonic transmission means and ultrasonic reception means. 14.A portable target device (400), implemented in a visual acuity measuring assistance system (200) according to any one of claims 8 to 13, comprising means for receiving (216) a acoustic wave (214) transmitted from the remote display (204), - means (402) for processing the received acoustic wave (214) and generating an echo signal and - means for transmitting (218) an optical wave (220) from the echo signal thus generated. 15. Portable device according to claim 14, characterized in that the acoustic reception means (216) comprise ultrasonic reception means. The portable device according to one of claims 14 or 15, characterized in that the optical transmission means (218) comprise infrared transmission means. 17.Dispositif according to any one of claims 14 to 16, characterized in that it is made in the form of a headband carried on the patient's head.