JP2003144387A - Method and device for displaying information on selection for intraocular lens - Google Patents

Abstract

PROBLEM TO BE SOLVED: To present information of high accuracy to be used for selecting an intraocular lens. SOLUTION: First of all, one degree of the intraocular lens is selected. Next, on the basis of the optical characteristics of the intraocular lens and the optical characteristics of the eyes of a target person, the locus of a plurality of beams passing through the intraocular lens is calculated. Next, on the basis of the calculated result of the locus, information on selecting the intraocular lens is displayed. This information is the estimate value of a refraction degree on the eye to insert the intraocular lens, for example.

Description

Detailed Description of the Invention

[0001]

FIELD OF THE INVENTION The present invention relates to a method and apparatus for displaying information for selecting an intraocular lens.

[0002]

BACKGROUND OF THE INVENTION Cataracts are cloudiness of the lens. This can be seen in many older people, on steroid administration, or congenitally. To treat severe cataract, surgery is performed by implanting an intraocular lens (called Intraocular Lens, IOL) instead of the lens.

The intraocular lens, unlike the crystalline lens, does not have a refraction adjusting power by itself. For this reason, it is important to select an intraocular lens having an appropriate refractive power before surgery. If the intraocular lens is selected improperly, it becomes necessary to wear strong glasses and to perform surgery again.

As a method for selecting the intraocular lens, there are a regression equation SRK-II equation and a paraxial ray theoretical equation SRK / T equation. However, with respect to these, (a) the structure of the eye or the intraocular lens is approximated so as to be easily calculated, so that the error is large. (B) Essentially, correction by trial and error is necessary. It has been pointed out that there is a problem.

In the conventional method, the intraocular lens power is calculated only from the curvature of the front surface of the cornea and the axial length of the eye. However,
Recently, the cornea may be deformed into an aspherical shape due to PRK or LASIK. SRK-II type and SRK
It is difficult to cope with these cases by the conventional method such as the / T method. In recent years, means for measuring the posterior corneal surface and aspherical corneal information in detail have been established. However, the conventional formula cannot incorporate such information and cannot be effectively used. In addition, a phakic intraocular lens may be used to correct myopia. However, the above-mentioned conventional formula cannot calculate the power of the intraocular lens used in this case.

In addition, as an intraocular lens selection method, W
Some are disclosed in O96 / 35396. This is intended to improve the accuracy of postoperative anterior chamber depth position estimation. However, this technique has problems with regard to the calculation of the intraocular lens power, such as that the number of light refraction sites used for the calculation is small (for example, the posterior surface of the cornea is ignored), or the idea for the aspherical cornea is not shown. , There is room for improvement in terms of accuracy. Further, in the above-mentioned publication, an appropriate postoperative refractive power (which is considered to be equivalent to eyeglass power) for making emmetropia or ametropia is selected in advance, and the blurring of the retinal image is evaluated for various intraocular lenses under this condition. Then, a method of selecting an optimal intraocular lens for appropriate postoperative refractive power is adopted. However, the above-mentioned publication does not disclose a technical method for calculating and presenting object point positions and eyeglass powers (postoperative refractive power) corresponding to various intraocular lenses. More specifically, if there is no intraocular lens that fits the appropriate postoperative refractive power without error (generally not present), the technical procedure will be presented that will provide information including how much postoperative refractive error will occur. However, there is room for improvement in terms of calculation speed and ease of use.

[0007]

The present invention has been made in view of the above circumstances. The display method and the display device of the information for selecting the intraocular lens according to the present invention are intended to present the information for performing the selection of the intraocular lens with higher accuracy to the practitioner.

[0008]

According to a first aspect of the present invention, there is provided an intraocular lens selection information displaying method including the following steps. (1) selecting the optical properties of the intraocular lens,
(2) calculating the trajectories of a plurality of light rays passing through the intraocular lens based on the optical characteristics of the intraocular lens and the optical characteristics of the eye of the subject, (3) Displaying information for selecting an intraocular lens based on the calculation result.

According to a second aspect of the present invention, there is provided an intraocular lens selection information display method including the following steps. (1) selecting an initial value of the optical characteristic of the intraocular lens; (2) passing through the intraocular lens based on the optical characteristic of the intraocular lens and the optical characteristic of the eye of the subject. Calculating the trajectories of a plurality of rays, then changing the optical characteristics of the intraocular lens, and calculating the trajectories of the plurality of rays again, (3) based on the calculation result of the trajectory. , A step of displaying information for selecting an intraocular lens.

A third aspect of the present invention is the method for displaying information for selecting an intraocular lens according to the first or second aspect, wherein the calculation of the trajectory of the light beam in the step (2) is performed from the object point side. ing.

A fourth aspect of the present invention is the intraocular lens selection information display method according to the first or second aspect, wherein the calculation of the ray trajectory in the step (2) is performed from the image point side. ing.

According to a fifth aspect of the present invention, the optical characteristics of the intraocular lens include the shape of the front surface of the intraocular lens and the shape of the rear surface of the intraocular lens.
The method for displaying information for selecting an intraocular lens according to any one of 1) to 3) above.

According to a sixth aspect of the present invention, the optical characteristics of the eye of the subject include the shape of the anterior cornea of the subject, the shape of the posterior corneal surface of the subject, the corneal thickness, the axial length of the eye, and the anterior chamber depth. When,
The method for displaying information for selecting an intraocular lens according to any one of claims 1 to 5, further comprising: a refractive index of a light ray passing portion in the eye.

A seventh aspect of the present invention is a method for displaying information for selecting an intraocular lens according to the sixth aspect, wherein the refractive index of the cornea among the refractive indices of the light beam passing portion is set to 1.376. There is.

According to an eighth aspect of the present invention, in the optical characteristic of the eye according to the sixth aspect, the information display method for selecting the intraocular lens further includes a deviation angle between the visual axis of the eye and the optical axis. Has become.

According to a ninth aspect, the intraocular lens selection information to be displayed by the method according to the first or second aspect is:
It is the refractive power of the eye when using an intraocular lens, and the difference between the refractive power of this eye and the refractive power of the eye obtained based on the SRK / T formula is used to indicate whether or not the difference is greater than a reference value. The information display method for selecting an intraocular lens according to any one of claims 1 to 8, further displaying.

According to a tenth aspect, an input section for inputting the optical characteristics of the intraocular lens and the optical characteristics of the eye of the subject, the optical characteristics of the intraocular lens and the optical characteristics of the eye of the subject. Based on, a calculation unit that calculates the trajectory of a plurality of light rays that pass through the intraocular lens, and a display unit that displays information for selecting the intraocular lens based on the calculation result of the trajectory. The information display device for selecting an intraocular lens is characterized by the above.

An eleventh aspect of the present invention is to input an initial value of the optical characteristic of the intraocular lens and an optical characteristic of the eye of the subject, an optical characteristic of the intraocular lens and the eye of the subject. Based on the optical characteristics, the trajectory of a plurality of light rays passing through the intraocular lens is calculated, then the optical characteristics of the intraocular lens are changed, and the trajectory of a plurality of light rays is calculated again. The intraocular lens selection information display device is characterized by comprising: a calculation unit that performs the calculation and a display unit that displays the intraocular lens selection information based on the calculation result of the trajectory.

According to a twelfth aspect, the "information for selecting an intraocular lens" includes information for associating the intraocular lens power with the object point position or the spectacle power when the intraocular lens is used in a one-to-one correspondence. The method for displaying information for selecting an intraocular lens according to claim 1 is characterized in that.

In the thirteenth aspect, the "intraocular lens selection information" includes information for associating the intraocular lens power with the object point position or the spectacle power when the intraocular lens is used in a one-to-one correspondence. The present invention provides a method for displaying information for selecting an intraocular lens according to claim 10 or 11.

[0021]

BEST MODE FOR CARRYING OUT THE INVENTION A method of displaying information for selecting an intraocular lens according to a first embodiment of the present invention will be described below with reference to the accompanying drawings. First, as a premise, the structure of the eye in which the intraocular lens is inserted will be described based on FIG. The eye 1 includes a cornea 2, an intraocular lens 3, and a retina 4. The optical axis of the eye 1 is indicated by reference numeral 5 in the figure. Further, the spectacle surface is indicated by reference numeral 6.

In the display method of this embodiment, first, the optical characteristic data of the target eye 1 is acquired. The optical characteristic data includes the curvature R ₁ (see FIG. 1) as the shape of the front surface of the cornea, the curvature R ₂ as the shape of the rear surface of the cornea, the corneal thickness t ₁ , the diameter W of the cornea, and the anterior chamber depth t. ₂ is a axial length _{t 4} Doo. Of these, the curvature R _{2 of the} posterior surface of the cornea and the anterior chamber depth t ₂ were calculated. The calculation formula used in this embodiment is as follows. _{R 2 = (6.8 / 7.7)} · R 1 t 2 = -0.03730W 3 + 1.2177W 2 -1
3.0662W-0.0006557t ₄ ² +0.10
26t ₄ +48.0676 (millimeter unit)

Data other than these were actually measured using a known method. For the axial length t ₄ , the photoreceptor depth is corrected (for example, +0.2 mm) based on a known method. The corneal shape is not limited to the curvature and may be an aspherical shape. Recent measuring instruments are also capable of measuring aspherical shapes. These characteristic data are manually or mechanically input to the selection device described later (step S2-1).

Then, one power of the intraocular lens 3 is selected (step S2-2). Here, since the simulation before mounting the intraocular lens 3 is performed, one of the candidate intraocular lenses is virtually selected. Therefore, the optical properties of the intraocular lens that can be used are selected here. The data of the intraocular lens is also manually or mechanically input to the selection device described later. The data from the manufacturer can be used for the data of the intraocular lens (for example, the thickness t ₃ of the intraocular lens and the refractive index). Furthermore, the distance t ₅ from the cornea 2 to the spectacle surface 6 may be set to a prescribed value (for example, 12.0 mm). The distance t ₅ may be measured and set for each person. A known value may be set for the refractive index of the ray passing portion of the eye other than the intraocular lens. The refractive index of the cornea is, for example, 1.
A value of 376 is used. In the calculation of the conventional intraocular lens power, since the posterior surface of the cornea is not considered, 1.333, etc.
Although a value different from the original refractive index of the cornea was assumed, the method of the present embodiment does not require such an assumption.

Then, the initial value of the object point position or the spectacle power is set (step S2-3). The spectacle power here is the power of spectacles required for the user to perform a distance vision after the treatment. The object point position and the spectacle power are equivalent ones that can be converted by a known conversion formula, and either numerical value may be set. Also, the power of contact lenses is considered to be equivalent to these. These can be collectively expressed as “postoperative refraction”. In this embodiment, the initial value of the eyeglass power is set according to the actual situation. This value is also manually or mechanically input to the selection device described later.

Then, the ray trajectory is calculated (step S2-4). The calculation of this ray locus is called so-called ray tracing, especially skew ray tracing.
racing). This method is well known and is described, for example, in the following documents. DPFeder. Optical Calculations with Automatic Com
puting Machinery, J Opt Soc Am 41, 630-635, 1951

Ray tracing in this embodiment is
An object point or an equivalent point on the spectacle surface 6 with the object point 5a (a part of which is shown by reference numerals 6a, 6b, and 6c in FIG. 1) is used as a starting point of the light ray. The direction of ray departure from the equivalent point is
Make it equivalent to a ray from an object point. The light ray passes through the anterior surface of the cornea, the posterior surface of the cornea, the anterior surface of the intraocular lens, and the posterior surface of the intraocular lens in this order, and the refraction at each of them is calculated. The calculated number of rays is 201, for example.
For each ray, the distribution of light spots on the retina 4 (image height from the optical axis) is obtained.

Average absolute value of height from the optical axis, that is,
If the distribution of the light spots is not the minimum, the object point or the spectacle power is changed, and the process is repeated from step S2-4 (step S2).
-5 and S2-6). This minimum determination is performed as follows. That is, in the ray tracing in step S2-4, the spectacle power is set to, for example, -8.0D to +3.0.
It is performed while changing the value in the range of D in steps of 0.01D.
As a result, a population of light spot distribution is formed, and the minimum spectacle power is selected from the population. Here, D is diopter (m ⁻¹ ) which is a unit of refractive index.

When the minimum value is obtained for a certain intraocular lens, it is determined whether or not there is another intraocular lens (or another possible set value for the intraocular lens) (step S2-7). If it exists, the processing from step S2-3 is repeated for another intraocular lens (step S2-8).

When all the intraocular lenses have been processed, useful information for selecting the intraocular lens power is displayed (step S2-9). Here, useful information includes, for example, (a) information indicating the position of an object point or the spectacle dioptric power when various intraocular lenses are used, and (b) information for specifying the optimal intraocular lens type.

Based on this information, the practitioner can select an appropriate intraocular lens and perform the treatment on the subject.
In this embodiment, it is possible to clearly indicate where the post-operative object point comes to each intraocular lens. Thereby, it becomes possible to quantitatively evaluate the deviation of the refractive power from the target value after the operation. Here, in the present embodiment, since ray tracing in which the characteristics of the eye of the subject are taken into consideration, the mounting result for each intraocular lens is based on the measurement results of a large number of eye optical system characteristics, and relatively. Can be accurately predicted. Therefore, it is possible to reduce the deviation between the desired value and the focal position or the spectacle power when the intraocular lens is attached. As a result, the wearer's QOV (Quality of Vision) can be improved.

Further, in this embodiment, by using ray tracing without approximation, the shift angle (α between the visual axis of the eye and the optical axis
Angle, γ angle, κ angle, λ angle, etc.). Generally, the lateral spot position is offset from the central axis of the eye by 5 °. By considering this deviation angle, it is possible to use the accurate lateral spot position as a reference,
The intraocular lens can be selected accurately. Furthermore, L
Even when the refraction portion increases, such as intraocular lens insertion when the corneal shape is aspherical by treatment such as ASIK, or power prediction of the intraocular lens in phakic for the purpose of myopic correction, The simulation can be performed relatively accurately. Further, in the present embodiment, the difference in the shape of the intraocular lens between the manufacturers does not pose a problem.

Next, a method of displaying the selection information of the intraocular lens according to the second embodiment of the present invention will be described with reference to FIG. Steps S3-1 and S3-2 are the same as steps S2-1 and S2-2 described above. Next, in this embodiment, the ray trajectory is calculated (step S3-
3). Ray tracing in the present embodiment is performed by the image point,
That is, the retina 4 (more specifically, the lateral patch) is used as the starting point of the light beam. The light rays virtually pass through the back surface of the intraocular lens, the front surface of the intraocular lens, the back surface of the cornea, and the front surface of the cornea. As a result, the intersection of this ray and the optical axis can be obtained. This intersection position is the image point (that is, the object point) of the horizontal spot.
It will be. In the present embodiment, the position of the intersection is converted into the spectacle power equivalent thereto. The calculated number of light rays is, for example, 201 for each intraocular lens. By averaging the calculation results for these rays, it is used as a predicted calculation value of the postoperative spectacle power or object point position.

Then, it is determined whether the above calculation has been completed for all intraocular lenses (step S3-).
4). If not completed, the condition is changed to the next intraocular lens (step S3-5), and the process is repeated from step S3-3. By this procedure, all postoperative spectacle powers or object point positions corresponding to a plurality of intraocular lenses are obtained. From these, it is possible to select the one that is close to the desired spectacle power. If the processing has been completed for all intraocular lenses, the information for selecting an appropriate intraocular lens is output and displayed as in the first embodiment (step S3-).
6).

According to the method of the second embodiment, since the trajectory of the light beam is calculated from the retina side, it is possible to reduce the number of calculation steps as compared with the first embodiment because the spectacle power is not scanned. it can. Therefore, it is possible to shorten the time required for the calculation to obtain the result. The configuration and advantages other than the above are the same as those of the first embodiment described above.

Next, the display device used in the method for displaying information for selecting an intraocular lens in each of the above embodiments will be described with reference to FIG. This display device, based on the input unit 10 for inputting the optical characteristics of the intraocular lens, the optical characteristics of the intraocular lens and the optical characteristics of the eye of the subject,
A calculation unit 20 that calculates the trajectories of a plurality of light rays that pass through the intraocular lens, a display unit 30 that displays information indicating the intraocular lens to be selected based on the calculation results of the trajectories, and between these elements. It mainly comprises a communication path 40 that enables the communication.

The input section 10 is a computer input device such as a keyboard and a mouse. Input section 10
As the above, a mechanism for automatically taking in data from a device for measuring optical data of the eye may be used. Further, it may be a mechanism for fetching data from a recording medium such as an FD.

The calculation unit 20 is specifically a computer. The calculation unit 20 is adapted to calculate the above-described ray trajectory according to a preset hardware or software configuration. The specific content of the calculation of the ray trajectory is as described in each of the above-described embodiments. The calculation unit 20 performs various calculations for implementing the method described above.

The display unit 30 is, for example, a display such as a CRT or a printer. In short, it is sufficient that the calculation result (that is, the various information described above) obtained by the calculation unit 20 can be displayed.

The communication path 40 is only required to allow communication between the blocks described above, and the transmission medium may be wired or wireless. No communication procedure is specified.

These elements in the selection device only have to exist as functional blocks, and the hardware or software configuration is not limited. It is easy for those skilled in the art to configure these functional blocks. Further, the functional blocks may be combined into one block, or the functional blocks may be realized by a plurality of devices.

[0042]

[Experimental Example 1] The method of the first embodiment and SRK-
Comparative evaluation with the formula II and the SRK / T formula was performed. Evaluation was performed on the eyes in which the intraocular lens was already implanted (10 eyes by a single doctor and a single measuring instrument group). In particular,
With respect to the already-implanted intraocular lens, the spectacle power at which the retinal image was most clear was calculated, and the difference (Spherical Equivalent Error) from the actual spectacle power was calculated. Hereinafter, this difference is referred to as SEE. By taking the absolute value of this SEE, two error evaluation indexes were calculated. 1) The average value of | SEE |

The results of the experiment are as follows. 1) Average value of | SEE | Method of this embodiment: 0.2928D SRK / T: 0.4790D SRK-II: 0.9714D The significance level in the t test is as follows. This Embodiment and SRK / T: p = 0.128 This Embodiment and SRK-II: p <0.005 This result is shown in FIG. In the figure, skew is the value of this embodiment. 2) Ratio of | SEE | ≦ 0.5000D Method of this embodiment: 8/10 SRK / T: 6/10 SRK-II: 2/10 From the above results, the effectiveness of the method of this embodiment is confirmed. did it.

[0044]

[Experimental Example 2] Equivalent verification was performed on 725 eyes obtained from a plurality of doctors and a plurality of measuring instrument groups. The results are as follows. 1) Average value of | SEE | Method of this embodiment: 0.5637D SRK / T: 0.5973D SRK-II: 0.7826D The significance level in the t test is as follows. Method of this embodiment and SRK / T: p <0.05 Method of this embodiment and SRK-II: p <0.01 2) | SEE | <0.5000D Ratio of this embodiment: 424 / 725 SRK / T: 396/725 SRK-II: 280/725 These results are shown in FIG. From this, it can be seen that the method of this embodiment is significantly superior.

[0045]

[Experimental Example 3] With the method of the first embodiment and the method of the second embodiment, calculation was performed under the same conditions for virtual 1000 eyes. As a result, the average calculation time ± standard deviation in 10 trials was as follows: 1st Embodiment: 444.33 ± 2.26 (s) 2nd Embodiment: 5.63 ± 0.07 (s). Therefore, it can be seen that the method of the second embodiment has high processing efficiency and can shorten the calculation time.

It is effective to collate the numerical values shown by the selection methods of the first and second embodiments with the calculation result of the SRK / T formula. For example, the difference between the predictions of both is ± 2D or more (in Experimental Example 2, 14 eyes out of 725 eyes, 1.9 eyes).
Occurred in%. In the case of), it is possible to re-examine. The average | SEE | of these 14 eyes is 1.912D
It was great. Therefore, there is a possibility that an error that may occur when the method of this embodiment is used can be prevented. In Experimental Example 2, the difference from the SRK / T formula was ± 2D or less. At 98.1% (711 eyes), p <0.005 was obtained in the t-test, which is excellent in the method of the present embodiment. Therefore, use of this method is desirable. Although the SRK / T formula is known, it is described in the following document, for example. John A. Retzlaff et al. Development of the SRK / T i
ntra-ocular lens implant power calculation formul
a, J Cataract Reflect Surg 16, 333-340, 1990.

It should be noted that the description of each of the above-described embodiments is merely an example, and does not show the essential structure of the present invention.
The configuration of each part is not limited to the above as long as the object of the present invention can be achieved.

[0048]

According to the present invention, it is possible to provide a method and apparatus capable of displaying the information for selecting the intraocular lens with high accuracy.

[Brief description of drawings]

FIG. 1 is an explanatory diagram showing an outline of an optical structure of an eye.

FIG. 2 is a flowchart showing an outline of a display method according to the first embodiment of the present invention.

FIG. 3 is a flowchart showing an outline of a display method according to a second embodiment of the present invention.

FIG. 4 is a block diagram schematically showing a display device according to an embodiment of the present invention.

FIG. 5 is a graph showing experimental data in the example of the present invention.

FIG. 6 is a graph showing experimental data in the example of the present invention.

[Explanation of symbols]

One eye 2 cornea 3 intraocular lens 4 retina Optical axis of 5 eyes 5a Object point 6 glasses 10 Input section 20 Calculation Department 30 Display 40 communication channels

   ─────────────────────────────────────────────────── ─── Continued front page    (71) Applicant 595046469             Kenji Doi             2-6-30 Nakamachi, Setagaya-ku, Tokyo (71) Applicant 501437237             Nobuhiko Hata             1-22-1-113 Yatocho, Nishi-Tokyo, Tokyo (71) Applicant 501437260             Takakazu Muto             1-13-1-703 Mukogaoka, Bunkyo-ku, Tokyo (72) Inventor Shinya Makoto             2-31-22 Fujigaoka, Aoba-ku, Yokohama-shi, Kanagawa (72) Inventor Tetsuro Oshika             2-7-12 Mejirodai, Bunkyo-ku, Tokyo Urban             Donur Mejirodai 401 (72) Inventor Akihiko Sugawara             4-5-19 Yushima, Bunkyo-ku, Tokyo (72) Inventor Kenji Doi             2-6-30 Nakamachi, Setagaya-ku, Tokyo (72) Inventor Nobuhiko Hata             1-22-1-113 Yatocho, Nishi-Tokyo, Tokyo (72) Inventor Takakazu Muto             1-13-1-703 Mukogaoka, Bunkyo-ku, Tokyo F term (reference) 2G086 HH06

Claims (13)

[Claims] 1. A method for displaying information for selecting an intraocular lens, comprising the following steps. (1) selecting the optical properties of the intraocular lens,
(2) calculating the trajectories of a plurality of light rays passing through the intraocular lens based on the optical characteristics of the intraocular lens and the optical characteristics of the eye of the subject, (3) Displaying information for selecting an intraocular lens based on the calculation result. 2. A method for displaying information for selecting an intraocular lens, which comprises the following steps. (1) selecting an initial value of the optical characteristic of the intraocular lens; (2) passing through the intraocular lens based on the optical characteristic of the intraocular lens and the optical characteristic of the eye of the subject. Calculating the trajectories of a plurality of rays, then changing the optical characteristics of the intraocular lens, and calculating the trajectories of the plurality of rays again, (3) based on the calculation result of the trajectory. , A step of displaying information for selecting an intraocular lens. 3. The method for displaying information for selecting an intraocular lens according to claim 1, wherein the calculation of the trajectory of the light beam in step (2) is performed from the object point side. 4. The method for displaying information for selecting an intraocular lens according to claim 1, wherein the calculation of the trajectory of the light beam in step (2) is performed from the image point side. 5. The optical characteristic of the intraocular lens includes the shape of the front surface of the intraocular lens and the shape of the rear surface of the intraocular lens. Item 1. A method of displaying information for selecting an intraocular lens according to Item 1. 6. The optical characteristics of the eye of the subject include:
The shape of the subject's corneal anterior surface, the shape of the subject's posterior corneal surface, the corneal thickness, the axial length of the eye, the anterior chamber depth, and the refractive index of the light ray passing portion of the eye. Item 6. A method for displaying information for selecting an intraocular lens according to any one of Items 1 to 5. 7. The method for displaying information for selecting an intraocular lens according to claim 6, wherein a refractive index of the cornea among the refractive indices of the light ray passing portion is set to 1.376. 8. The method for displaying information for selecting an intraocular lens according to claim 6, wherein the optical characteristics of the eye further include a shift angle between the visual axis of the eye and the optical axis. 9. The intraocular lens selection information to be displayed by the method according to claim 1 is the refractive power of the eye when the intraocular lens is used, and the refractive power of the eye and SRK / The intraocular eye according to any one of claims 1 to 8, further displaying information on whether or not a difference from the refractive power of the eye obtained based on the T formula is larger than a reference value. Information display method for lens selection. 10. An input unit for inputting the optical characteristics of the intraocular lens and the optical characteristics of the eye of the subject, based on the optical characteristics of the intraocular lens and the optical characteristics of the eye of the subject. A calculation unit that calculates the trajectories of a plurality of light rays that pass through the intraocular lens, and a display unit that displays information for selecting the intraocular lens based on the calculation result of the trajectories. Information display device for selecting intraocular lens. 11. An initial value of optical characteristics of an intraocular lens,
An input unit for inputting the optical characteristics of the eye of the subject,
Based on the optical characteristics of the intraocular lens and the optical characteristics of the eye in the subject, calculate the trajectory of a plurality of light rays passing through the intraocular lens, then, the optical characteristics of the intraocular lens An eye characterized by including a calculator for calculating the trajectories of a plurality of light rays, and a display for displaying the information for selecting the intraocular lens based on the calculation results of the trajectories. Information display device for selecting inner lens. 12. The “intraocular lens selection information” is
The information display for selecting an intraocular lens according to claim 1, comprising information for associating an intraocular lens power with an object point position or a spectacle power when the intraocular lens is used in a one-to-one correspondence. Method. 13. The “information for selecting an intraocular lens” is
The information display for selecting an intraocular lens according to claim 10 or 11, which includes information for associating an intraocular lens power with an object point position or a spectacle power when the intraocular lens is used in a one-to-one correspondence. Method.