10.9. SINGULAR CONVERSION

Lecture



The singular transformation [34] is a two-dimensional unitary transformation based on the singular decomposition of matrices (see Chapter 5). A direct singular transformation is by definition equal to

10.9. SINGULAR CONVERSION , (10.9.1)

and the inverse transform

10.9. SINGULAR CONVERSION . (10.9.2)

String Conversion Matrix 10.9. SINGULAR CONVERSION provides a diagonalization operation

10.9. SINGULAR CONVERSION , (10.9.3)

Where 10.9. SINGULAR CONVERSION - diagonal matrix, elements 10.9. SINGULAR CONVERSION which are eigenvalues ​​of the matrix 10.9. SINGULAR CONVERSION . Similarly

10.9. SINGULAR CONVERSION . (10.9.4)

Substituting expression (10.9.2) into equalities (10.9.3) and (10.9.4), we get

10.9. SINGULAR CONVERSION , (10.9.5)

where elements of the diagonal matrix 10.9. SINGULAR CONVERSION are numbers 10.9. SINGULAR CONVERSION called the singular values ​​of the matrix 10.9. SINGULAR CONVERSION and equal to the square root of the corresponding eigenvalues 10.9. SINGULAR CONVERSION .

The image matrix can be written in a very compact form using the matrix product of vectors obtained by singular decomposition. According to equality (10.1.14b),

10.9. SINGULAR CONVERSION , (10.9.6)

Where 10.9. SINGULAR CONVERSION and 10.9. SINGULAR CONVERSION are vectors consisting of elements 10.9. SINGULAR CONVERSION columns of matrices 10.9. SINGULAR CONVERSION and 10.9. SINGULAR CONVERSION .

Using a singular transformation, the image matrix 10.9. SINGULAR CONVERSION containing 10.9. SINGULAR CONVERSION items can be fully described 10.9. SINGULAR CONVERSION values ​​representing 10.9. SINGULAR CONVERSION coefficients 10.9. SINGULAR CONVERSION . However, it should be noted that the specific values ​​of the elements of the transformation matrices in rows and columns in this case depend on the image elements.

In fig. 10.9.1 shows an example of a singular transformation of the image. Shown here are works 10.9. SINGULAR CONVERSION and 10.9. SINGULAR CONVERSION as well as the corresponding transformation matrices in rows 10.9. SINGULAR CONVERSION and by columns 10.9. SINGULAR CONVERSION . The singular values ​​of the image in question are shown in Fig. 10.9.2. In fig. 10.9.3 shows several matrix products 10.9. SINGULAR CONVERSION .

10.9. SINGULAR CONVERSION

Fig. 10.9.1. Singular transformation of the image "Portrait". All arrays from 10.9. SINGULAR CONVERSION elements are derived from size arrays 10.9. SINGULAR CONVERSION element by means of bilinear interpolation.

and - the initial image, a matrix 10.9. SINGULAR CONVERSION ; b - the result of a singular transformation matrix 10.9. SINGULAR CONVERSION ; in - matrix 10.9. SINGULAR CONVERSION ; g - matrix 10.9. SINGULAR CONVERSION ; d - the matrix consisting of the modules of the elements of the matrix 10.9. SINGULAR CONVERSION ; е - the matrix consisting of the modules of the elements of the matrix 10.9. SINGULAR CONVERSION .

10.9. SINGULAR CONVERSION

Fig. 10.9.2. Singular values ​​of the image "Portrait".

10.9. SINGULAR CONVERSION

Fig. 10.9.3. Basic images for the image "Portrait".

Figures a, b, c, d, d, e correspond 10.9. SINGULAR CONVERSION , 10.9. SINGULAR CONVERSION , 10.9. SINGULAR CONVERSION , 10.9. SINGULAR CONVERSION , 10.9. SINGULAR CONVERSION , 10.9. SINGULAR CONVERSION .

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Digital image processing

Terms: Digital image processing