JPH08287139A - Spectacle display device - Google Patents

Abstract

PURPOSE: To display information on edge thickness after unshaped lenses are machined in conformity with the shape of a spectacle frame by displaying the edge thickness at a edge position specified by a specifying means is displayed according to the calculation result of a calculating means which calculates shape data on spectacle lenses after lens rubbing. CONSTITUTION: The spectacle display unit is provided with a data input part 220 which inputs data regarding lenses, a frame shape detection part 100 which detects the frame shape, and a data processing part 240 which inputs the outputs of the data input part 220 and frame shape detection part 100 and calculates the lens weight and lens edge thickness, and further provided with a data output part 280 which outputs the lens weight and lens edge thickness after the output of the data processing part 240 is inputted and the lenses are machined. The data processing part 240 consists of a lens curved surface function arithmetic part 242, a lens shape data generation part 244, a lens weight arithmetic part 246, and a lens edge thickness arithmetic part 248.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a spectacle display device for displaying data relating to the thickness of a spectacle lens to be framed in a spectacle frame, that is, a spectacle lens after the edging process.

[0002]

2. Description of the Related Art Factors for a spectacle wearer to determine that a spectacle is defective after the spectacle wearer puts the spectacle lens in a frame are the weight of the spectacle and the thickness of the lens edge, that is, the thickness of the rim. Because other elements of eyeglasses, such as lens power and frame shape, can be sufficiently investigated and selected before putting the eyeglass lens in the eyeglass frame, but the eyeglass weight and the thickness of the eyeglass lens This is because it could only be known after the ball-slicing process to insert the frame. Therefore, in the past, an eyeglass adjuster may have shown this to the eyeglass wearer by estimating the eyeglass weight and the edge thickness of the eyeglass lens after the edging process based on experience,
Since this estimated value is inaccurate, it is unavoidable that the determination of the defect in the eyeglasses by the spectacle wearer based on this estimated value is also inaccurate. In particular, in recent years, plastics, high-refractive index glass, and the like have been used as the material for spectacle lenses, in addition to conventional inorganic glass. On the other hand, spectacle frames have been manufactured in various sizes from a large size to a small size, and from a circular shape to a considerably deformed shape in accordance with diversification of tastes of spectacle wearers. In such a situation, it is becoming more and more difficult for the eyeglass adjuster to estimate eyeglass weight and thickness.

[0003]

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems when a spectacle lens is framed in a spectacle frame, and an unshaped lens is attached to a spectacle frame by specifying the frame and the lens. It is an object of the present invention to provide a spectacle display device capable of displaying information about the thickness of a tooth after processing according to the shape.

[0004]

SUMMARY OF THE INVENTION The present invention has been made in view of the above conventional problems, and based on the shape data of the eyeglass lens and the mutual position data between the eyeglass frame and the eyeglass lens, the shape data of the eyeglass lens after the edging process. Calculating means for calculating, a designating means for designating a desired edge position in the spectacle lens after the ball-shaving process, and a calculation result of the calculating means, based on the desired edge position designated by the designating means. A spectacles display device comprising: a display unit for displaying the thickness of the garment. In the embodiment of the present invention, the display means displays a figure of the shape of the spectacle lens after the ball-polishing processing based on the calculation result of the calculation means, and the index indicating the designated desired tip position is described above. It is characterized by displaying on a figure. In the configuration of the present invention, as shown in FIG. 1, optical data of eyeglass lenses, material data of eyeglass lenses, shape data of eyeglass frames, and mutual position data between eyeglass frames and eyeglass lenses are input to an input unit. The calculation unit calculates the data of the spectacle lens after the ball-polishing processing from the above input and outputs it to the output unit, and the output unit outputs the spectacle lens data after the ball-polishing processing.

[0005]

Embodiments of the present invention will be described below with reference to the drawings. As shown in FIG. 2, the eyeglass display device includes a data input unit 220 for inputting data regarding a lens, a frame shape detection unit 100 for detecting a frame shape, and a data input unit 2.
20 and the output of the frame shape detection unit 100 are input, and the data processing unit 240 that calculates these inputs to calculate the lens weight and the lens thickness, and the output of the data processing unit 240 are input and after the ball-shaving process. A data output unit 280 for outputting the lens weight and the lens thickness is included. The data input unit 220 includes lens material data 222 indicating the specific gravity of the lens material, lens refractive power data 224 indicating the lens power, lens optical axis position data 226 indicating the position of the lens optical axis with respect to the frame, and the position of the lens of the frame. This is for inputting a child thickness position designation data input unit 228 indicating the child thickness by a keyboard or the like having an appropriate operation knob. The lens material data 222 is the specific gravity p of the lens material itself and is input by a numeric keypad or the like. However, the refractive index thereof is input by three key buttons respectively indicating general inorganic glass, plastic and high refractive index glass. Good.

The lens refractive power data 244 is the curvature R ₁₉ R ₂ and the center thickness d of the first and second surfaces of the lens. Here, the center thickness d is weight data when calculating the lens weight rather than when calculating the lens refractive power. By the way, since a table showing the relationship between the lens refractive power and the lens shape has been clarified by each lens manufacturer, the data input unit 220 stores this table and inputs only the lens refractive power as the lens refractive power data 224. Good. Lens power data 22
4 is a spherical diopter and a cylindrical diopter which are widely used for displaying the refractive power of a spectacle lens, and a curvature R of one surface of the lens.
_It may be configured with ₁ . Lens optical axis position data 2
26 is constituted by the vertical distance from the upper or lower end of the lens frame portion of the frame to the lens optical axis and the lateral distance from the left or right end of the lens frame portion of the frame to the lens optical axis. (Interpupillary distance-nose width length) / Z may be used instead of the lateral distance. Here, the nose width length is the interval between the left and right lens frame portions of the frame and is a value that is usually shown in the frame, and the interpupillary distance is usually called the φD value, which is the interval between the left and right pupils. The lens thickness information 228 is composed of coordinates indicated by a joystick or the like on the curved surface of the CRT on which a spectacle image to be described later is formed.

As shown in FIG. 3, the frame shape detecting section 100 includes a frame mounting table 2 on which a frame 24 is mounted.
2, the illumination unit 10 that illuminates the frame 24, and the detection unit 30 that optically detects the frame shape. The frame mounting table 22 is L-shaped as a whole, and the mounting section 2
2a is composed of a transparent member. The frame 24 is mounted on the mounting table 22 with the temple part to be worn on the ear opened, that is, in a worn state. The illumination unit 10 is composed of a light source 12, a collimator lens 14, and a reflecting mirror 16. The light source 12 is arranged at the focal position of the collimator lens 14, and the luminous flux emitted from the collimator lens 14 is made into a parallel luminous flux.
Is directed to the placing portion 22. The detection unit 30 includes a reflecting mirror 32, an image forming lens 34, and an area sensor 36, and the lens frame portion of the frame 24 arranged on the mounting table 22 by the image forming lens 34 and the area sensor 36 are conjugated. It is arranged. Therefore, the area sensor 3
An image of the lens frame portion of the frame 24 is formed on 6 and the lens shape can be detected.

The data processing unit 240 includes a lens curved surface function calculation unit 242 to which the lens refractive power data 224 is input, a lens optical axis position data 226, and a lens shape data forming unit 244 to which the output of the area sensor 36 is input, and lens material data 222. And a lens weight calculation unit 246 to which the outputs of the lens curved surface function calculation unit 242 and the lens shape data formation unit 244 are input, and lens barrel thickness position data 228.
A lens frame thickness calculator 248 to which the outputs of the lens curved surface function calculator 242 and the lens shape data generator 244 are input.
Consists of. The lens curved surface function calculation unit 242 determines whether the first lens surface and the second lens surface are 2 based on the lens refractive power data 224.
Computes two lens surface functions. In FIG. 4, it is assumed that the first lens surface is a toroidal surface having a major axis R ₁ and a minor axis R ₂ .
The origin 0 of the three-dimensional coordinates XYZ and the apex of the lens surface are made to coincide, and the normal line at the apex of the lens surface is made to coincide with the Z axis. Then, the lens surface function of the first lens surface is

[0009]

[Equation 1]

[0010] In addition, the second lens surface has a major axis R ₁ ,
Assuming that the toroidal surface has a minor axis R ₂ , the lens surface function of the second lens surface is

[0011]

[Equation 2]

[0012] Here, in a so-called external surface astigmatism lens that forms a cylindrical degree on the first lens surface, R ₁ ′ = R
₂ ′, and conversely, R ₁ = R ₂ in a so-called inner surface astigmatism lens that forms a cylindrical degree on the second lens surface. The lens shape data forming unit 244 uses the lens optical axis position data 2
26 and the shape data of the lens frame portion of the frame from the area sensor 36, the following data processing is performed. That is, with the lens optical axis position as the origin, in the two-dimensional coordinates that coincide with the surface orthogonal to the lens optical axis, the lens after the ball-polishing process (hereinafter,
A closed curve g (x) showing the contour of the shaping lens is obtained. The lens weight calculation unit 246 uses the lens material data 22
2. The weight of the shaping lens is calculated from the output of the lens curved surface function calculating unit 242 and the output of the lens shape data forming unit 244. The calculation obtains the area φ enclosed by the closed curve, that is, the cross-sectional area of the surface orthogonal to the optical axis of the shaping lens from the output g (x) from the lens shape data forming unit 244 by the following equation. φ = ∫g (x) dx (3) Next, the area φ and the lens surface function f ₁ (x, y), f
_The shaping lens volume V is obtained from ₂ (x, y) by the following equation.

[0013]

(Equation 3)

Here, the first term of the equation (4) is the first lens surface and X
It shows the volume sandwiched by the Y plane.
The volume sandwiched between Y planes is shown. From the above, the weight W of the shaping lens
Is calculated by the following equation using the specific gravity ρ of the lens material.

[0015]

[Equation 4]

The lens thickness calculation unit 248 calculates the lens thickness position data 228 based on the lens curved surface functions (1) and (2) and the closed curve g (x) indicating the contour of the shaping lens. Calculate the thickness. That is, according to the lens-thickness position data 228, a point (x _E , on the closed straight line g (x),
y _E ) is determined, and Z between the first lens surface and the second lens surface is determined.
The thickness E, which is the difference between the coordinate values, can be obtained by the following equation. E = f ₁ (X _E , Y _E ) −f ₂ (X _E , Y _E ) (6) The data output unit 280 outputs the lens weight calculation unit 246 and the lens barrel thickness 248. Printer 28 input by
2, and an image signal forming unit 284 to which the outputs of the lens curved surface function calculating unit 242, the lens shape data forming unit 244, the lens weight calculating unit 24, and the lens barrel thickness calculating unit 248 are input.
And a CRT (cathode ray tube) to which the output of the image signal forming unit 284 is input. The printer 284 prints out the weight of the shaped lens which is the calculation result of the lens weight calculation unit 246 and the thickness of the shaped lens which is the calculation result of the lens thickness calculation unit 248. The image signal forming unit 284 is
An image signal indicating the weight and thickness of the shaping lens and an image signal indicating the shape of the shaping lens are formed from the lens shape data and the lens curved surface function.

The CRT 286 displays the data and shape of the shaping lens according to the image signal output from the image signal forming section 284. Further, on the screen of the CRT 286, a frame image is formed by a known means, and an index 290 indicating the position of the obtained thickness is displayed.

[0018]

According to the spectacle display device of the first aspect of the present invention, by identifying the frame and the lens, the dent thickness at the desired dent position can be confirmed after the unshaped lens is processed to match the shape of the spectacle frame. Has the effect of being able to.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of an eyeglass display device of the present invention.

FIG. 2 is a block diagram showing a configuration of an eyeglass display device according to an embodiment of the present invention.

FIG. 3 is an optical diagram of a frame shape detection unit according to the embodiment of the present invention.

FIG. 4 is an explanatory diagram of a coordinate system that calculates a lens curved surface function.

[Explanation of symbols]

 10 Illumination unit 14 Collimator lens 20 Frame placement table 30 Detection unit 36 Area sensor 100 Frame shape detection unit 220 Data input unit 240 Data processing unit 242 Lens curved surface function calculation unit 244 Lens shape data formation unit 246 Lens weight calculation unit 248 Lens weight Thickness calculator 280 Data output unit

Claims (2)

[Claims] 1. Calculating means for calculating the shape data of the spectacle lens after the edging process from the shape data of the spectacle lens and the mutual position data between the spectacle frame and the spectacle lens, and the spectacle lens after the edging process. And a display unit for displaying the thickness of the desired child position specified by the specifying unit based on the calculation result of the calculation unit. Eyeglass display device. 2. The display means displays a figure of the shape of the spectacle lens after the ball-shaving process based on the calculation result of the calculating means, and an index indicating the designated desired litter position is displayed on the figure. It is displayed on the screen.
The spectacle display device according to.