RU2461854C1 - Method of determining photographic camera resolution and set of circular marks for realising said method - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: method involves obtaining an image of one perspective and scale using a set of circular marks with the entire image field being filled by each mark. Images of marks with different width of dark rings are selected such that the width of dark rings lies in an interval bounded on one side by the minimum width of rings which are still distinguishable on the entire image field, and on the other side by the maximum width of rings in the image of the mark, already undistinguishable on the entire image field. The resolution for regions of selected images, where dark rings of marks are distinguishable, are determined from the width of the dark ring of the mark on the image. The resolution of the photographic camera on the entire image field is obtained by merging regions with different resolution into one image. The set of circular marks consists of 30 circular marks, each being a system of concentric rings on a light background, wherein the width of the dark ring within one mark is constant and falls from each previous mark, starting from the first to the last, on a geometric progression law with ratio K which lies in the range of 0.91-0.95.

EFFECT: possibility of determination of resolution of a photographic camera on the entire field of the formed using a set of marks.

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Description

The group of inventions relates to the field of photographic technology and can be used in testing the image quality of cameras.

Currently, the resolution is widely used to assess the image quality of photographic systems, in particular cameras. This parameter characterizes the ability of the camera to give separate images of two points of the object close to each other.

As a measure of resolution, the value is usually used - the number of allowed lines per 1 mm in the image plane. Determining the resolution of the optical system is carried out using special test objects called worlds. The resolution of the photographic system is determined by the maximum spatial frequency of the strokes of the test object (worlds) at which these strokes can still be distinguished in the photo image (i.e., they do not merge when they are visually observed). The type of worlds used affects the accuracy of determining resolution.

The unevenness of resolution over the field of the frame can be caused by the peculiarities of the optics used in the camera, as well as the image acquisition technology. It is important for the user to know its value throughout the field of the generated image. In known methods, the resolution is determined, as a rule, in the center of the frame or at several other points along the field of the frame.

There is a method of determining the resolution in the center and in the corner of the frame [http://www.rwpbb.ru/test/trubak2.html, article "Kepler’s tube - macro converter and photo gun in one bottle"]. When testing the Casio QV4000 camera, the radial and annular world were shot. Focusing was carried out when the worlds were located in the center of the frame, after which the camera rotated so that the world was in the corner of the frame. The method determines the resolution for two areas of the image - in the center and corner of the frame and does not allow to obtain a resolution distribution over the entire image field.

The ring world of the Polish standard is known [V.I. Artishevsky, V.M. Gradoboev. Standard worlds for determining the photographic resolution of lenses, "OMP", 1975, No. 11, p. 54-58]. The world consists of eleven elements - concentric rings; Each element contains two light rings on a dark background. The spatial frequency of individual elements increases in the direction of the center of the world in accordance with a series of numbers with a denominator of 1.25, covering the range of spatial frequencies with a ratio of 10. The world has a number of significant drawbacks: a large step in the discreteness of spatial frequencies from element to element (progressive denominator of 1.25 ); the number of rings in the element is 2. The disadvantages of using this worlds include the fact that with its help it is not possible to obtain a resolution distribution over the entire field of the frame.

The closest method of the same purpose to the claimed method in the group of inventions by the totality of features is a method for determining the resolution in five areas by the image field generated by the tested photographic lens on a high resolution Kodak T-MAX 100 film. The method is described in [http: // www .photoweb.ru / Test_pdml.html in A. Kurin's article “Test Procedure for Determining the Resolution of a Lens” based on the test procedure from an article by Yoshihiko Takinami, magazine “Modern Photography”], adopted as a prototype. The method involves the use of five test objects, each of which represents a three-sleeping world of the US Air Force. The same test objects are made in advance and are installed in the center and four corners of the rectangle filling the field of view of the film, making a table of five test objects (a set of five worlds). After precise aiming and focusing of the lens, a series of pictures is taken of a table of one angle and scale. After processing the film through a microscope or magnifier, the resulting images are viewed. As a result of viewing, they find the smallest pair of lines in the center, which is clearly distinguishable by the operator. Repeat the same for corner test objects and select the smallest pair of lines, which is clearly distinguishable in all four corners. Given the magnification factor of the lens, the exact resolution value is determined in the center and at the corners of the image formed by the lens.

The reasons that impede the achievement of the technical result indicated below include the fact that the method, being applied to determining the resolution of the camera, does not allow it to be determined over the entire field of the generated image.

The closest set of world to the claimed set of world in the group of inventions according to the totality of features is a large-scale table of ring worlds for determining the resolution of the camera (developed by V. Gorlov), given in the article [http://club.foto.ru/info/articles/article .php? id = 86, Y. Sukharevsky “Foveon + Sigma: catching up with the strongest”]. The table includes 10 worlds, which are a system of concentric dark rings on a light background, while the width of the rings within one world is constant. For all the worlds included in the table, the width of the ring (taking into account the reduced scale) is converted into the numerical value of the resolution. By visually evaluating a snapshot of a world-wide ring-shaped table obtained using a Sigma SD-9 camera, we determined the resolution of the camera along the long and short sides of the frame, while the vertical axis of the world table image corresponded to the long side of the frame, and the horizontal axis to the short side. The reasons that impede the achievement of the technical result indicated below when using the prototype kit (which is a layout of 10 ring worlds) include the fact that when using it it is difficult to shoot in such a way as to obtain information about each area of the frame, the world does not work out using the table get the distribution of resolution over the entire field of the image.

The essence of the group of inventions is as follows.

The objective of the invention-method in the group of inventions is to determine the resolution of the camera over the entire field of the generated image.

The objective of the invention-set of annular worlds in the group of inventions is to create a set of world that allows you to determine the resolution of the camera over the entire field of the generated image.

The technical result that can be achieved by the implementation of the claimed invention-method is to determine the resolution of the camera over the entire field of the generated image.

The technical result that can be achieved by the implementation of the claimed invention is a set of the world is to create a set of the world, which allows to determine the resolution of the camera over the entire field of the generated image. Using the invention will allow a detailed study of image quality and get the maximum amount of information when comparing various samples of photographic equipment.

The specified technical result in the implementation of the invention-method is achieved by the fact that in the method for determining the resolution of the camera, including obtaining a set of images of the world by the camera, determining the resolution, in accordance with the claimed technical solution, the images are obtained from one angle and scale using a set of annular worlds when filling each world of the entire image field, from the obtained images choose the world image with different widths of dark rings so that the width t of many rings of the selected images lies in an interval limited, on the one hand, by the minimum width of dark rings, which are still distinguishable throughout the image field, and, on the other hand, by the maximum width of dark rings in the image, the worlds, which are already indistinguishable throughout the image field, for each selected images define areas of the image in which the dark rings of the worlds are different, thus forming areas with different resolutions, while the value of resolution for the image area is determined by the width of worlds ring of the selected image, the resolution ability of the camera around the image field is obtained by the union of regions with different resolution into one image.

The specified technical result in the implementation of the invention-set of peace is achieved by the fact that the set of circular worlds, consisting of 10 circular worlds, each of which is a system of concentric dark rings on a light background, while the width of the dark ring within one world is unchanged, in accordance with the claimed technical solution additionally contains 20 ring worlds, each of which completely fills the area of a rectangle with an aspect ratio of 2: 3, the world is the same for all, the width of the dark ring decreases from one of the previous worlds, starting from the first to the next according to the law of geometric progression with the denominator K, while K is selected in the range of 0.91-0.95, the width of the dark ring of the first world is at least 2 mm, in the center of each world there is a white spot with a diameter not less than 4 mm.

The causal relationship between the achieved technical result and the set of essential features of the invention-method is due to the introduction into the list of operations of the method of actions such as obtaining images of the annular world with different ring widths when each world is filled with the entire image field, the selection of all images in which the world rings are different in whole or in part according to the image field, determination on the images of areas with a distinct dark ring width, reference to the resolution cutting the width of the dark ring of the worlds, then combining the areas of images with different resolutions in one image. In this way, you can get the distribution of resolution over the entire field of the image formed by the camera.

The causal relationship between the achieved technical result and the set of essential features of the invention-set of the world is due to the introduction of the following distinctive features into the invention. A set of 10 ring worlds additionally includes another 20 ring worlds, thus forming a set of 30 worlds. Each annular world in the set completely fills the area of the rectangle with a 2: 3 aspect ratio, the same for all the world, while the width of the dark ring within the same world is unchanged. This makes it easy to shoot each world with one angle and scale, and with filling the world with the entire image field. The worlds are made so that the width of the dark ring decreases from each previous world, starting from the first to the next according to the law of geometric progression with the denominator K, while K is selected in the range of 0.91-0.95, the width of the dark ring of the first world is at least 2 mm, in the center of each world there is a white spot with a diameter of at least 4 mm. Such a construction allows the world to use the entire image area most fully and informatively when shooting them, and taking into account the relationship between the resolution of each world and the width of the dark ring, it can obtain accurate information about the image quality, forming data on resolution over the entire image field. The number of worlds included in the set and the choice of the denominator K allows you to examine in detail the image quality, to obtain the distribution of resolution over the entire field of the image with a minimum step.

Figure 1 shows the distribution of resolution over the entire field of the image formed by the camera phone Nokia 5230.

Figure 2 presents the image of the first worlds included in the inventive set of the world, with a ring width of 2 mm

The method is implemented in the following sequence of operations. To determine the resolution of the camera, a set of the world is used, designed to implement the method. Worlds are placed on a flat vibration-proof surface. The camera is mounted on a tripod; during the shooting, if possible, use a remote control. Lighting the world should be uniform. The worlds are shot in one perspective and scale so that each world completely fills the frame field of the camera. After obtaining the images of each worlds from the set, images of the world with different ring widths are selected so that the ring width lies in an interval limited, on the one hand, by the minimum width of the rings, still visible throughout the image field, and, on the other hand, by the maximum ring width in image worlds already indistinguishable across the entire image field. For each of the selected images, the regions in which the rings of the worlds in the image are distinguishable are determined. The definition of these areas begins with the image of the world on which the width of the dark ring is minimal. The location of the areas is determined visually. The boundaries of the selected areas are applied to a transparent banner having dimensions identical to the frame size, while the borders of the selected image frames are alternately aligned with the borders of the banner.

The resolution of the camera over the entire field of the image is obtained by combining areas with different resolutions in one image. The combination of image areas is carried out by drawing on a transparent banner the boundaries of regions with different resolution, filling in the entire field of a transparent banner. The resolution of each region is determined through the width of the dark ring according to the well-known formula R = L / (F · d _w ), where L is the distance from the plane of the camera lens to the plane of the world, F is the focal length of the camera lens, d _w is the width of the dark ring of the world in mm Figure 1 presents the distribution of resolution over the entire field of the image formed by the camera phone Nokia 5230 when shooting, carried out from a distance L = 1 meter.

For the manufacture of a set of the world intended for the implementation of the method, a program was compiled to calculate the parameters of the world, generating the required number of the world. All worlds in the set met the following requirements. Each world was a system of concentric dark rings on a light background. Within one world, the width of the dark rings was unchanged, the distance between the boundaries of adjacent rings was equal to the width of the ring. Each world completely filled the area of the rectangle with an aspect ratio of 2: 3, while for all the world the width and length of the rectangles were the same. The width of the dark ring decreased from each previous world, starting from the first to the next according to the law of geometric progression with the denominator K, while K is selected in the range of 0.91-0.95. To obtain a more accurate result, with a smaller step of changing the resolution on the world, you should choose the maximum value of the denominator K. The width of the dark ring on the first world with a minimum resolution was at least 2 mm. In the center of each world there was a white spot with a diameter of at least 4 mm. Figure 2 presents the image of the first worlds included in the inventive set of the world, with a dark ring width of 2 mm and a denominator of K equal to 0.91. The world covers an area of 200 * 300 mm.

Claims (2)

1. The method of determining the resolution of the camera, mainly over the entire field of the image, including obtaining images by the camera using a set of worlds of one angle and scale, determining resolution, characterized in that the images are obtained using a set of annular worlds with each world filling the entire image field, From the obtained images, images of the world with different widths of dark rings are selected so that the width of the dark rings of the selected images lies in the interval limited by on the one hand, the minimum width of the dark rings, which are still distinguishable throughout the image field, and, on the other hand, the maximum width of the dark rings in the image, worlds that are already indistinguishable throughout the image field, determine for each selected image areas of the image in which the dark the worlds rings are different, thus forming regions with different resolution, while the resolution for the image area is determined by the width of the dark ring the worlds of the selected image, the resolution method awn camera around the image field is obtained by the union of regions with different resolution into one image. 2. A set of circular worlds, consisting of 10 circular worlds, each of which is a system of concentric dark rings on a light background, while the width of the dark ring within one world is unchanged, characterized in that it additionally contains 20 circular worlds, each of which the world completely fills the area of the rectangle with an aspect ratio of 2: 3, the same for all the world, the width of the dark ring decreases from each previous world, starting from the first to the next according to the law of geometric progression with the denominator K, while K is chosen raetsya range 0,91-0,95, the width of the first dark ring of the worlds of at least 2 mm, in the center of each worlds has a white spot with a diameter not less than 4 mm.

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