Crossing point detector, camera calibration system, crossing point detection method, camera calibration method, and recording medium

What is claimed is: 1. A coordinate position determiner, comprising: a memory that stores an image obtained by imaging a checker pattern, the checker pattern including a first crossing point of a first line and a second line; and a processor that reads out the image from memory and determines a coordinate position of a second crossing point, in a two-dimensional coordinate system, indicating a crossing point in the image that corresponds to the first crossing point, wherein provided that a position of each pixel in the image is expressed by coordinate position (x k , y k ) in the two-dimensional coordinate system, a pixel value at the coordinate position (x k , y k ) in the image is I(x k , y k ), where k is a natural number less than or equal to n, and n is a total number of pixels included in the image, the second crossing point is a crossing point of a first boundary line and a second boundary line, the first boundary line being located on a boundary between a region that includes a first region included in the image and a second region included in the image, and a region that includes a third region included in the image and a fourth region included in the image, and the second boundary line being located on a boundary between a region that includes the first region and the third region, and a region that includes the second region and the fourth region, each pixel value of the pixels included in the first and fourth regions is greater than each pixel value of the pixels included in the second and third regions, the processor decides parameters of M(x, y) that optimize an evaluation value based on a difference between M(x=x k , y=y k ) and I(x k , y k ), M(x, y) indicates a pixel value at the coordinate position (x, y) in the two-dimensional coordinate system, the processor computes the position of the crossing point of the first boundary line and the second boundary line expressed by using the multiple parameters to thereby obtain the second crossing point with a precision by which a resolution in an x-axis direction of the two-dimensional coordinate system is less than (x k +1−x k ) and a resolution in a y-axis direction of the two-dimensional coordinate system is less than (y k +1−y k ), and M(x, y) expresses a three-dimensional curved surface that is at least first-order differentiable and expresses the first region, the second region, the third region, and the fourth region in the two-dimensional coordinate system, and pixel values at respective positions in the two-dimensional coordinate system on the first boundary line and the second boundary line.