KR20040034342A - Method and apparatus for extracting feature vector for use in face recognition and retrieval - Google Patents

Abstract

PURPOSE: A method and a device for extracting a characteristic vector for recognizing/retrieving a face are provided to support a retrieval limitation for the characteristic vector generated from a frequency area and a spatial area by respectively generating a Fourier characteristic vector and an intensity characteristic vector for a normalized face image. CONSTITUTION: A Fourier characteristic generator(121) generates the first and the second normalized vector as the frequency characteristic vector for the entire face area of the normalized entire face image, and the third and the fourth normalized vector as the frequency characteristic vector for the central face area of the normalized entire face image. An entire Fourier characteristic vector generator(123) generates an entire Fourier characteristic vector by combining the first and the second normalized vector, and projecting it to the first linear discriminating space. A central Fourier characteristic vector generator(125) generates a central Fourier characteristic vector by combining the third and the fourth normalized vector, and projecting it to the second linear discriminating space.

Description

Method and apparatus for extracting feature vector for use in face recognition and retrieval

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a face recognition and retrieval system. In particular, the present invention relates to a face recognition and retrieval system, and specifically generates and merges a Fourier feature vector and an intensity feature vector for a normalized face image. A feature vector extraction method and apparatus for face recognition and retrieval that complements a search limit of feature vectors.

In the transition to the 21st century information society, the information of individuals as well as certain organizations has become more important than any asset. In order to protect such important information, various passwords are used, and other technologies that can verify identity are urgently required. Among them, face recognition technology is evaluated as the most convenient and competitive identification method because it has the advantage that the user can perform identification without taking special actions or actions, or even without the user's own recognition.

On the other hand, beyond the protection of information, social demands for identity verification such as credit cards, cash cards, and electronic social security cards continue to expand. I have a problem. Face recognition technology is in the limelight as a way to solve these social problems. In addition, face recognition technology has many application fields such as terminal access control, public place control system, electronic photo album, criminal face recognition, and is considered very useful technology in information society.

As a face recognition technique that is widely used at present, there is a technique of recognizing a face by applying a principal component analysis (hereinafter, abbreviated as PCA) to a face image. Principal component analysis is a technique to reduce the information by projecting the image data into a low dimensional eigenvector space while minimizing the loss of the unique information of the image itself. As a face recognition method using principal component analysis, a method of recognizing a face using a pattern classifier learned from a principal component vector extracted from a pre-registered image after extraction of a principal feature vector of a face has been widely used. However, this method has low recognition speed and reliability in large-capacity face recognition, and it is possible to obtain robust features for lighting by selecting PCA basis vector, but obtains satisfactory face recognition results for facial expression or pose change. There is no problem.

To complement the method, Toshio kamei et al. Recently introduced the Fourier PCLDA concept in "Report of Core Experiment on Fourier Spectral PCA based Face Description" (NEC_MM_TR_2002_330, July 2002) to extract feature vectors for face images in the frequency domain. Tae-Kyun Kim et al. Proposed a method to extract feature vectors for each component in spatial domain by applying LDA at "Component-based LDA face Descriptor for image retrieval" (British Machine Vision Conference 2002, September 2002). It was.

However, the feature vectors on the frequency domain and the feature vectors on the spatial domain, which are extracted by the above methods, have a certain recognition and search limit, respectively.

The technical problem of the present invention is to generate a Fourier feature vector and an intensity feature vector separately for a normalized face image, and then merge them appropriately to generate a search limit based on a feature vector generated in a frequency domain and a space generated in a spatial domain. The present invention provides a feature vector extraction method for face recognition and retrieval that complements a search limit of feature vectors.

Another object of the present invention is to provide a feature vector extraction apparatus for face recognition and retrieval most suitable for realizing the feature vector extraction method for face recognition and retrieval.

In order to achieve the above technical problem, the feature vector extraction method for face recognition and retrieval according to the present invention is (a) a full Fourier using the first and second normalized vectors as frequency feature vectors for the entire face region of the normalized face image. Generating a feature vector and generating a feature vector in the central Fourier using the third and fourth normalized vectors as frequency feature vectors for the central face region; And (b) generating an intensity feature vector for the entire face region of the normalized face image and an intensity feature vector for each predetermined number of face components, and intensifying the first and second normalized vectors and the whole face region. And combining a third feature vector to generate a total complex feature vector, and generating a center composite feature vector by combining the third and fourth normalized vectors and the intensity feature vector for each facial component.

In order to achieve the above object, the feature vector extraction apparatus for face recognition and retrieval according to the present invention uses the first and second normalized vectors as a frequency feature vector for the entire face region of the normalized face image. A first unit generating a feature vector in the central Fourier using the third and fourth normalized vectors as a frequency feature vector for the central face region; And generating an intensity feature vector for the entire face region of the normalized face image and an intensity feature vector for each predetermined number of face components, and generating the first and second normalized vectors and the intensity feature vector for the entire face region. And a second unit for generating a total complex feature vector and combining the third and fourth normalized vectors with the intensity feature vector for each facial component to generate a center complex feature vector.

In order to achieve the above object, the present invention provides a computer-readable recording medium recording a program for executing the method on a computer.

1 is a block diagram showing the configuration of an embodiment of a feature vector extraction apparatus for face recognition and search according to the present invention;

FIG. 2 is a block diagram showing the detailed configuration of the Fourier feature generation unit shown in FIG. 1; FIG.

3A and 3B are block diagrams showing the detailed configuration of the block divisional face area shown in FIG. 2;

4 is a block diagram illustrating a detailed configuration of a full Fourier feature vector generator shown in FIG. 1;

FIG. 5 is a block diagram illustrating a detailed configuration of a central Fourier feature vector generator shown in FIG. 1;

6 is a block diagram showing a detailed configuration of the intensity feature generation unit shown in FIG.

FIG. 7 is a block diagram showing a detailed configuration of a pose estimation / compensation unit shown in FIG. 6;

FIG. 8 is a block diagram showing the detailed configuration of the full complex feature vector generator shown in FIG. 1; FIG.

9 is a block diagram showing the detailed configuration of the center complex feature vector generator shown in FIG.

FIG. 10 is a diagram illustrating a raster scan applied to the Fourier feature generation unit shown in FIG. 1.

Next, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing the configuration of an embodiment of a feature vector extraction apparatus for face recognition and retrieval according to the present invention, which comprises a frequency feature vector generation unit 120 and a complex feature vector generation unit 130. Here, the frequency feature vector generation unit 121 includes a Fourier feature generation unit 121, a full Fourier feature vector generation unit 123, and a central Fourier feature vector generation unit 125, and a complex feature vector generation unit 130. Is composed of a Fourier feature generating unit 121, an intensity feature generating unit 131, an entire complex feature vector generating unit 133 and a central compound feature vector generating unit 135.

Referring to FIG. 1, a normalized face image 110 is obtained by scaling an original image, for example, with 56 lines, where each line consists of 46 pixels, for example. In the normalized face image 110, each center of the right eye and the left eye is located in the 16th and 31st columns of the 24th row.

In the frequency feature vector generation unit 120, the Fourier feature generation unit 121 performs Fourier transform on the normalized face image 110, that is, the entire face region and the center face region, to obtain a Fourier spectrum and a Fourier amplitude. First and second feature vectors are defined from the Fourier spectrum and the Fourier amplitudes for the entire face region, and third and fourth feature vectors are defined from the Fourier spectrum and the Fourier amplitudes for the central face region. Each of the first to fourth feature vectors is projected into a linear discriminant analysis of principal components (PCLDA) subspace, and then normalized to a unit vector. The first and second normalized vectors become feature vectors for the entire face region, and the third and fourth normalized vectors become feature vectors for the center face region. Here, the Fourier feature vectors encode a spatial relationship between the pixels constituting the face image.

The whole Fourier feature vector generator 123 combines the first and second normalized vectors provided from the Fourier feature generator 121, projects it into a discrimination space defined by a predetermined basis matrix, and then projects the vector. Each component of is quantized in a predetermined manner and stored as a feature vector in the entire Fourier.

The central Fourier feature vector generation unit 125 combines the third and fourth normalization vectors provided from the Fourier feature generation unit 121, projects them into a discrimination space defined by a predetermined basis matrix, and then projects the vector. Each component of is quantized in a predetermined manner and stored as a feature vector in the central Fourier.

Next, in the complex feature vector generation unit 130, the intensity feature generation unit 131 performs pose estimation and compensation on the normalized face image 110, and the entire face region and a plurality of face-compensated face images 110. For example, five partial images are projected onto the PCLDA subspace, and then normalized to fifth and sixth unit vectors, respectively. The entire internity feature vector for the entire face region is from the fifth feature vector normalized to the fifth unit vector, and the partial intension feature vector for the partial face image is the sixth to tenth feature vectors normalized to the sixth unit vector. Is generated from Here, the intensity feature vector is a coded intensity change of pixels constituting a corresponding face image.

The global complex feature vector generator 133 combines the first and second normalized vectors provided from the Fourier feature generator 121 and the global intensity feature vectors provided from the intensity feature generator 131. After projecting to a discrimination space defined by a given basis matrix, each component of the projected vector is quantized in a predetermined manner and stored as an overall complex feature vector.

The central composite feature vector generator 135 combines the third and fourth normalized vectors provided from the Fourier feature generator 121 with the partial intensity feature vectors provided from the intensity feature generator 131, and After projecting to a discrimination space defined by a given basis matrix, each component of the projected vector is quantized in a predetermined manner and stored as a central complex feature vector.

FIG. 2 is a block diagram illustrating a detailed configuration of the Fourier feature generator 121 shown in FIG. 1. The first image splitter 210, the entire Fourier feature vector generator 220, and a central Fourier feature vector generator are illustrated in FIG. 1. 230. The whole Fourier feature vector generator 220 includes first and second Fourier transform units 222 and 225, first and second PCLDA projection units 223 and 226, and a first vector normalization unit 227, and a central Fourier feature vector. The generation unit 230 includes a third Fourier transform unit 231, third and fourth PCLDA projection units 233 and 234, and a second vector normalization unit 235.

Referring to FIG. 2, the first image splitter 210 divides the normalized face image 210 into the entire face region 221, the block divided face region 224, and the central face region 231.

The full Fourier feature vector generator 220 generates a Fourier spectrum for the entire face region 221 and a Fourier amplitude for the block division face region 224, and generates a Fourier feature vector using the Fourier spectrum and the Fourier amplitude. Create If this is explained in more detail as follows.

The first Fourier transform unit 222 performs a Fourier transform on the entire face region 221 and converts it to a frequency domain. In the case where the entire face region 221 is f (x, y), the Fourier spectrum F (u, v) may be expressed by Equation 1 below.

Here, M = 46, N = 56, u = 0.1, 2, ..., 45, v = 0, 1, 2, ..., 55, F (0, 0) is a DC component. The Fourier Spectrum (F (u, v)) is defined by each component as the real part Re [F (u, v)] and the imaginary part Im [F (u, v)] as a result of raster scanning of the Fourier spectrum. Used to obtain a first feature vector x ₁ ^f . Here, raster scanning is performed for scan areas A and B excluding high frequency components of u = 12, 13, ..., 34 as defined in Table 1 below. Table 1 shows raster scan parameters for extracting feature vectors from the Fourier domain.

Here, S _A and S _B correspond to start points in scan areas A and B, and E _A and E _B correspond to end points in scan areas A and B. FIG. An example of the raster scan and the scan area is shown in FIG. As shown in Fig. 10, the Fourier components are extracted from the scan areas A and B by u-direction scanning.

As a result of raster scanning, the first feature vector x ₁ ^f may be expressed as in Equation 2 below, wherein the dimension of the first feature vector x ₁ ^f is 644.

In the first PCLDA projection unit 223, the first feature vector x ₁ ^f extracted by the first Fourier transform unit 222 is a PCLDA (Linear Discriminant Analysis of Principal Components) for the first feature vector x ₁ ^f . Project to the discrimination space obtained by The discrimination space is defined by the pre -learned first basis matrix Ψ ₁ ^f .

On the other hand, the second Fourier transform unit 225 performs a Fourier transform on the block division face area 224 to convert to a frequency domain. As shown in FIG. 3, the block division face area 224 includes an entire area 311, four block division areas 312, and 16 block division areas 313, and performs Fourier transform on each area separately. . Here, the entire area (f ₁ ⁰ (x, y), 311) is obtained by clipping at 44 × 56 image size while removing boundary rows on both sides from the normalized face image 110, as shown in Equation 3 below. Can be represented.

Where x = 0,1,2, ..., 43, y = 0,1,2, ..., 55.

The four block division regions f _k ¹ (x, y) and 312 and the 16 block division regions f _k ² (x, y) and 313 are obtained from the entire region f ₁ ⁰ (x, y) and 311. makin, obtained by dividing into four block partition ^{_{(f k 1 (x, y}} ), 312) is the total area ^{_{(f 1 0 (x, y}} ), 311) evenly, its size is 22 × 28 in four blocks It can be expressed as Equation 4 below.

Where k = 1,2,3,4, x = 0,1,2, ..., 21, y = 0,1,2, ..., 27, s _k ¹ = (k-1) mod2 , t _k ¹ = round ((k-1) / 2).

On the other hand, obtained by dividing the 16-block partition ^{_{(f k 2 (x, y}} ), 313) is the total area ^{_{(f 1 0 (x, y}} ), 311) evenly, its size is 11 × 14, 16 of blocks It may be expressed as Equation 5 below.

Where k = 1,2,3, ..., 16, x = 0,1,2, ..., 10, y = 0,1,2, ..., 13, s _k ² = (k -1) mod4, t _k ² = round ((k-1) / 4)

In the second Fourier transform unit 225, the Fourier transform of the entire region 311, the 4 block division region 312, and the 16 block division region 313 results in a Fourier spectrum F _k ^j (u, v). ) And Fourier amplitude (| F _k ^j (u, v) |) may be expressed as in Equations 6 and 7 below.

Here, Re (z) and Im (z) represent the real part and the imaginary part of complex z respectively. M ^j represents the width of the subblocks of the whole area 311 or the 4 block division area 312 and the 16 block division area 313, for example, M ⁰ = 44, M ¹ = 22, and M ² = 11. do. N ^j represents the height of the subblocks of the entire area 311 or the 4 block division area 312 and the 16 block division area 313, for example, N ⁰ = 56, N ¹ = 28, and N ² = 14. do.

Each Fourier amplitude (| F _k ^j (u, v) |) represented by Equation 8 is subjected to raster scanning excluding high frequency components to define a second feature vector ( x ₂ ^f ) as defined in Table 1 above. Create At this time, the order of the raster scan is the total Fourier amplitude (| F ₁ ⁰ (u, v) |), the four block division Fourier amplitude (| F ₁ ¹ (u, v) |, | F ₂ ¹ (u, v) |, | F ₃ ¹ (u, v) |, | F ₄ ¹ (u, v) |), 16 block division Fourier amplitude (| F ₁ ² (u, v) |, | F ₂ ² (u, v ), ..., | F ₁₆ ² (u, v) |).

As a result of raster scanning, the second feature vector x ₂ ^f may be expressed as in Equation 8, wherein the dimension of the second feature vector x ₂ ^f is 856.

The second PCLDA projection unit 226 projects the second feature vector x ₂ ^f extracted by the second Fourier transform unit 225 into a discriminating space obtained by the PCLDA with respect to the second feature vector x ₂ ^f . Let's do it. The discrimination space is defined by the pre -learned second basis matrix Ψ ₂ ^f .

The first vector normalizer 227 normalizes the vector projected by the first PCLDA projection unit 223 as a unit vector, and generates a first normalized vector y ₁ ^f given by Equation 9 below. The second PCLDA projection unit 226 normalizes the projected vector as a unit vector to generate a second normalized vector y ₂ ^f given by Equation 10 below.

Where m ₁ ^f and m ₂ ^f represent the mean of the previously learned projected vectors, and the dimensions of y ₁ ^f and y ₂ ^f are 70 and 80, respectively.

The central Fourier feature vector generator 230 generates a Fourier spectrum and a Fourier amplitude with respect to the central face region 231, and generates a central Fourier feature vector using the Fourier spectrum and the Fourier amplitude. The central Fourier feature vector generator 230 operates in a similar manner to the entire Fourier feature vector generator 220, which will be described in more detail as follows.

First, the central face region 231 is obtained by clipping the normalized face image f (x, y), 110 to a 32x32 image size starting at (7, 12) and ending at (38,43). .

The third Fourier transform unit 232 performs a Fourier transform on the center face regions g (x, y) and 231 to convert them into a frequency domain to obtain a Fourier spectrum G (u, v) and obtain a Fourier spectrum Raster scanning G (u, v)) yields a third feature vector x ₁ ^g . In this case, raster scanning is performed on the scan areas A and B as defined in Table 1 above, and the dimension of the third feature vector x ₁ ^g is 256 as a result of the raster scanning.

The third PCLDA projection unit 233 projects the third feature vector x ₁ ^g extracted by the third Fourier transform unit 232 into a discriminating space obtained by the PCLDA with respect to the third feature vector x ₁ ^g . Let's do it. The discriminant space is defined by the pre -learned third basis matrix Ψ ₁ ^g .

On the other hand, the fourth Fourier transform unit 235 performs a Fourier transform on the block division face region 234 and converts it to a frequency domain. The block division face area 234 is a center area (g (x, y), 321) of 32 × 32 image size, and 4 block division areas (g _k ¹ (x, y), 322 each having a 16 × 16 image size. And 16 block division regions (g _k ² (x, y), 323) each having an 8 × 8 image size, and Fourier transform is performed separately for each region. The Fourier amplitude for the central region g (x, y), 321 is obtained by | G (u, v) |, and the four block divisions (g _k ¹ (x, y), 322) and 16 block divisions are obtained. The Fourier amplitude for each subblock g _k ^j (x, y) of (g _k ² (x, y), 323) is obtained by | G _k ^j (u, v) |. These Fourier amplitudes are raster scanned to produce a fourth feature vector x ₂ ^g . In this case, raster scanning is performed on the scan areas A and B as defined in Table 1 above. As a result of raster scanning, the dimension of the fourth feature vector x ₂ ^g is 384.

The fourth PCLDA projection unit 236 projects the fourth feature vector x ₂ ^g extracted by the fourth Fourier transform unit 235 into the discriminating space obtained by the PCLDA with respect to the fourth feature vector x ₂ ^g . Let's do it. The discrimination space is defined by the fourth learned matrix Ψ ₂ ^g .

The second vector normalization unit 237 normalizes the vector projected by the third PCLDA projection unit 233 to generate a unit vector using the previously learned average vector m ₁ ^g to generate a third normalized vector y _1. ^g ) and normalized to generate the vector projected by the fourth PCLDA projection unit 236 as a unit vector using the previously learned average vector ( m ₂ ^g ) to generate a fourth normalized vector ( y ₂ ^g ). Create In this case, the dimensions of the third normalization vector y ₁ ^g and the fourth normalization vector y ₂ ^g are 70 and 80, respectively.

FIG. 4 is a block diagram illustrating a detailed configuration of the entire Fourier feature vector generator 123 illustrated in FIG. 1. The first combiner 410, the first LDA projection unit 420, and the first quantizer 430 are illustrated in FIG. )

Referring to FIG. 4, in the first combiner 410, the first and second normalized vectors y ₁ ^f and y provided from the first and second normalized vector generators 220 in the Fourier feature generator 121. ₂ ^f ) are combined to form a join vector whose dimension is 150, for example.

The first LDA projection unit 420 projects the coupling vector provided from the first coupling unit 410 into the linear discrimination space defined by the fifth learned matrix Ψ ₃ ^f . The projected vector z ^f can be expressed as Equation 11 below.

In the first quantization unit 430, each component of the projected vector z ^f provided from the first LDA projection unit 420 is quantized by clipping to a 5-bit unsigned integer using Equation 12, Stored as a Fourier feature vector w _i ^f .

FIG. 5 is a block diagram illustrating a detailed configuration of the central Fourier feature vector generation unit 125 illustrated in FIG. 1, and includes a second coupling unit 510, a second LDA projection unit 520, and a second quantization unit 530. )

Referring to FIG. 5, in the second combiner 510, the third and fourth normalized vectors y ₁ ^g and y provided from the third and fourth normalized vector generators 230 in the Fourier feature generator 121. ₂ ^g ) are combined to form a join vector whose dimension is 150, for example.

The second LDA projection unit 520 projects the combined vector provided from the second combiner 510 into the discrimination space defined by the sixth basis matrix Ψ ₃ ^{g that} has been previously learned to produce the projected vector z ^g . Create

In the second quantization unit 530, each component of the projected vector z ^g provided from the second LDA projection unit 520 is quantized by clipping to a 5-bit unsigned integer using Equation 13, and then centered. Stored as a composite feature vector (w _i ^g ).

FIG. 6 is a block diagram illustrating a detailed configuration of the intensity feature vector generator 230 shown in FIG. 2. The pose estimator / compensator 610, the second image splitter 620, and the entire intensity feature are illustrated in FIG. 2. A vector generator 630 and a partial intensity feature vector generator 640.

Referring to FIG. 6, the pose estimator / compensator 610 estimates a pose of the normalized face image 110 and outputs a front face image by compensating the pose according to the estimation result. The pose estimation / compensator 610 adjusts mismatching according to the change of the pose so that as many intensity feature vectors as possible can be extracted from the same pixel.

In the second image splitter 620, the face image pose-compensated by the pose estimator / compensator 610 has an entire face region having a raster scan region and face components 1 to 5 as shown in Table 2 below. The image is divided into first to fifth partial images. That is, the entire face region has a 46 × 56 image size starting from (0,0), and the first to fifth partial images are (9,4), (6,16), (17,16), ( 7,25) and (16,25) to have 29 × 27, 24 × 21, 24 × 21, 24 × 24, and 24 × 24 image sizes.

Table 2 below shows raster scan and vector dimensions of component-wise regions, where the number of regions and partial facial images of the raster scan, that is, the number of facial components, is not fixed but variable.

In the whole intensity feature vector generating unit 630, the first raster scan unit 631 starts at the upper left corner (0,0) with respect to the entire face region that is pose-compensated, and the lower right corners (46,56). Row fifth raster scan is performed to generate a fifth feature vector x ^h consisting of intensity values of the entire face region. Here, the dimension of the fifth feature vector x ^h is 2576, for example.

The fifth PCLDA projection unit 632 projects the fifth feature vector x ^h provided from the first raster scan unit 631 into the discrimination space defined by the seventh basis matrix Ψ ₁ ^{h previously} learned. .

The fifth vector normalization unit 633 normalizes the vector projected by the fifth PCLDA projection unit 632 to a unit vector y ^h given by Equation 14 to generate the entire intensity feature vector.

Where m ^h represents the mean of the previously learned projected vectors, the dimension of which is 40.

In the partial intensity feature vector generator 640, the second to sixth raster scan units 641a to 645a start at the upper left corner of each image size with respect to the first to fifth partial images that are pose-compensated. A row raster scan is performed at the lower right corner to generate a sixth feature vector ( x _k ^c , k = 1, ..., 5) consisting of intensity values of each partial face region. Here, the dimensions of the sixth feature vector ( x _k ^c , k = 1, ..., 5) are 783, 504, 504, 576, 576 for each raster scan area, respectively.

In the sixth to tenth PCLDA projection units 641b to 645b, the sixth feature vectors x _k ^c , k = 1, ..., 5 provided from the second to sixth raster scan units 641a to 645a. a group learning the sixth basis matrix ^{_{(Ψ k c, k = 1}} , ..., 5) thereby to determine the projection space defined by the.

In the sixth to tenth vector normalizers 641c to 645c, the unit vectors y _k ^c and k = 1, which are given by the sixth to tenth PCLDA projection units 641b to 645b, are given by Equation 15 below. Normalized by ..., 5), it generates a partial intensity feature vector.

Where m _k ^c represents the mean of the previously learned projected vectors, with a dimension of 40 for each vector.

FIG. 7 is a block diagram illustrating a detailed configuration of the pose estimator / compensator 610 of FIG. 6, and includes a pose estimator 710 including n PCA / DFFS blocks 711, 712, 713, and a minimum value detector 714. And a compensating portion 720 including an affine transforming unit 721 and an inverse mapping unit 722.

The pose estimator 710 uses the Principal Component Analysis / Distance From Face Space (PCA / DFFS) method as one of nine predefined pose classes as shown in Table 3 below. For this purpose, the first to n-th PCA projection units 711a, 712a, 713a, where n = 9, use the projection matrix P _i , for the nine different pose classes, for the normalized face image 110. project into the PCA subspace of i = 1,2, ... In this case, the PCA model of each pose class is trained with example images collected from training face images, and face images having poses similar to the pose class may be represented as PCA basis images.

In the first to nth DFFS calculators 711b, 712b, 713b, where n = 9, the distance d _i ( x ) of the image for each pose class is calculated by using Equation 16 below. The distance of the image indicates the degree to which the normalized face image 110 is represented by the PCA subspace for a specific pose class.

Here, x and M _i represent the mean vector of the PCA subspace for the thermal raster scan and pose class (i) of the normalized face image 110, respectively. The projection matrix P _i , i = 1, 2,..., 9, and the mean vector M _i are previously learned.

The minimum value detector 714 has a minimum value among the distances d _i ( x ) of the image provided from the first to nth DFFS calculators 711b, 712b, 713b, where n = 9, as shown in Equation 17 below. The pose class is estimated as the pose class of the normalized face image 110.

The PCA / DFFS method is described in detail in "Face Recognition using View-Based and Modular Eigenspaces," Automatic Systems for the Identification and Inspection of Humans, SPIE Vol. 2277, July 1994, published by B. Moghaddam and A.Pentland. It is described.

Next, the pose compensator 720 compensates the normalized face image 110 to the front face image according to the pose class estimated by the pose estimator 710, and for this purpose, the pose transform unit 721 poses. The estimation unit 710 loads an Affine transformation matrix into the front pose class corresponding to the estimated pose class. The affine transformation from each pose class to the front pose class is determined by the corresponding points between the front pose class and each pose class. Corresponding points of each pose class are calculated, for example, as an average position for 15 distinguishable face features, and the 15 distinguishable face features may be manually selected from training images assigned to the pose class.

The inverse mapping unit 722 geometrically demaps the normalized face image 110 into the front face image using the affine transformation matrix loaded from the affine transformation unit 721 to provide a pose-compensated face image. The transformation of the pause class j is represented by a six-dimensional vector A _j = {a, b, c, d, e, f} as defined in Table 4 below.

Meanwhile, the intensity at the position (x, y) of the demapped face image is calculated as in Equation 18 below.

Where x '= ceil (a x + b y + c), y' = ceil (d x + e y + f), dx = (a x x b y + c)-x ' , dy = (d · x + e · y + f) −y ', and f (x', y ') represents the intensity of the normalized face image at position (x', y ').

FIG. 8 is a block diagram illustrating a detailed configuration of the entire composite feature vector generator 133 illustrated in FIG. 1, and includes a third combiner 810, a third LDA projection unit 820, and a third quantizer 830. )

Referring to FIG. 8, in the third combiner 810, the first and second normalized vectors y ₁ ^f and y provided from the first and second normalized vector generators 220 in the Fourier feature generator 121. ₂ ^f ) and the whole intensity feature vector y ^h provided from the whole intensity feature vector generator 630 are combined to form a join vector having a dimension of, for example, 190.

The third LDA projection unit 820 projects the coupling vector provided from the third coupling unit 810 into a linear discrimination space defined by a previously learned ninth basis matrix Ψ ₂ ^h . The projected vector z ^h can be expressed as Equation 19 below.

In the third quantization unit 830, each component of the projected vector z ^h provided from the third LDA projection unit 820 is quantized by clipping to a 5-bit unsigned integer using Equation 20, and then Stored as a composite feature vector (w _i ^h ).

FIG. 9 is a block diagram illustrating a detailed configuration of the central composite feature vector generator 135 illustrated in FIG. 1, and includes a fourth coupling unit 910, a fourth LDA projection unit 920, and a fourth quantization unit 730. )

Referring to FIG. 9, in the fourth combiner 910, the third and fourth normalized vectors y ₁ ^g and y provided from the third and fourth normalized vector generators 230 in the Fourier feature generator 121. ₂ ^g ) and the partial intensity feature vector y _k ^c provided from the partial intensity feature vector generator 640 to form a combined vector having a dimension of 350, for example.

The fourth LDA projection unit 920 projects the coupling vector provided from the fourth coupling unit 910 into the discrimination space defined by the previously learned tenth basis matrix Ψ ₆ ^c . The projected vector z ^c can be expressed as Equation 21 below.

In the fourth quantization unit 930, each component of the projected vector z ^c provided from the fourth LDA projection unit 920 is quantized by clipping to a 5-bit unsigned integer using Equation 22, and then centered. Stored as a composite feature vector (w _i ^c ).

Next, the degree of improvement of the search performance will be described through an example in which the feature vector extraction method according to the present invention is applied to face image search.

For the experiment, an MPEG-7 facial dataset consisting of five databases was used as the dataset. The five databases are MPEG-1 Testset (M3) in the Extended Version 1 MPEG-7 Face Database (E1), Altkom Database (A2), XM2VTS Database (M3), FERET Database (F4), and Banca Database respectively. Test set B5. The total number of images was 11,845, of which 3,655 were used as training images for linear discriminant analysis (LDA) projection learning, and 8,190 images were used as test images for performance evaluation. Of the test images, 4190 images were used as basis images for extracting facial feature vectors, and 4000 images obtained in F4 were used as images for face searching. Table 5 shows a detailed list of training images and test images, and knows the ground truth of each image in order to evaluate the performance of the image retrieval algorithm to which the present invention is applied.

Training Image I (50 vs 50) DB People Number of images sum A2 40 15 600 B5 - - - M1 317 5 1,585 M3 147 10 1,470 F4 - - - sum 504 3,655 Test Image I (50 vs 50) DB People Number of images sum A2 40 15 600 B5 52 10 520 M1 318 5 1,590 M3 148 10 1,480 F4 - - 4,000 sum 558 8,190

On the other hand, the accuracy of the search was evaluated by the Average Normalized Modified Retrieval Rate (ANMRR). Details of ANMRR are described in detail in "Introuction to MPEG-7: Multimedia Content Description Interface," John Wiley & Sons Ltd., 2002, by B. S. Manjunath, Philippe Salembier and Thomas Sikora.

Simulation results show that the accuracy of the search is ANMRR, which is 0.354 using only the Fourier feature vectors and 0.390 using only the intensity feature vectors. However, when the Fourier feature vector and the intensity feature vector were merged and used as in the present invention, it was 0.266. The size of a conventional Fourier feature vector is 250 (= 48 x 5) bits, and the size of the Fourier feature vector used in the present invention is 320 (= 64 x 5) bits. The accuracy of the search depends on the dimensions of the LDA projection. For example, if the dimension is 48 (i.e. 240 bits), the ANMRR is 0.280; if the dimension is 64 (i.e. 320 bits), the ANMRR is 0.266; if the dimension is 128 (i.e. 640 bits), the ANMRR is 0.249. . As described above, when the Fourier feature vector and the intensity feature vector are merged and used as in the present invention, it has been proved that the accuracy of the search and the identification result can be provided.

The present invention described above can also be embodied as computer readable code on a computer readable recording medium. The computer-readable recording medium includes all kinds of recording devices in which data that can be read by a computer system is stored. Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage, and the like, and may also be implemented in the form of a carrier wave (for example, transmission over the Internet). Include. The computer readable recording medium can also be distributed over network coupled computer systems so that the computer readable code is stored and executed in a distributed fashion.

As described above, according to the present invention, by generating a Fourier feature vector and an intensity feature vector separately for a normalized face image and merging them, the search limit of the feature vector generated in the frequency domain and the feature vector generated in the spatial domain are obtained. Complementing the search limit has the advantage of significantly improving the accuracy of the search.

So far I looked at the center of the preferred embodiment for the present invention. Those skilled in the art will appreciate that the present invention can be implemented in a modified form without departing from the essential features of the present invention. Therefore, the disclosed embodiments should be considered in descriptive sense only and not for purposes of limitation. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the scope will be construed as being included in the present invention.

Claims (20)

(a) A feature vector is generated in the entire Fourier using the first and second normalization vectors as frequency feature vectors for the entire face region of the normalized face image, and third and fourth normalization as frequency feature vectors for the central face region. Generating a feature vector in the central Fourier using the vector; And (b) generating an intensity feature vector for the entire face region of the normalized face image and an intensity feature vector for each predetermined number of face components, and intensities for the first and second normalized vectors and the whole face region; Combining the feature vectors to generate a full complex feature vector, and combining the third and fourth normalized vectors with the intensity feature vectors for each face component to generate a center feature vector. And feature vector extraction method for retrieval. The method of claim 1, wherein step (a) performing a Fourier transform on the entire face region to obtain a Fourier spectrum and a Fourier amplitude, and defining first and second feature vectors using the obtained Fourier spectrum and Fourier amplitude; (a2) performing a Fourier transform on the central face region to obtain a Fourier spectrum and a Fourier amplitude, and defining third and fourth feature vectors using the obtained Fourier spectrum and Fourier amplitude; (a3) The first and second feature vectors are projected into the first PCLDA subspace and then normalized to generate the first and second normalized vectors, which are then combined and projected into the first predetermined linear discrimination space to characterize the entire Fourier. Generating a vector; And (a4) The third and fourth feature vectors are projected into the second PCLDA subspace and then normalized to generate the third and fourth normalized vectors, which are then combined and projected into a second predetermined linear discriminant space to characterize the central fury. A feature vector extraction method for face recognition and retrieval, characterized by generating a vector. 3. The method of claim 2, wherein in the step (a1), the Fourier spectrum is obtained from an entire face region and the Fourier amplitude is obtained from a first block division face region. The face recognition of claim 3, wherein the first block division face area comprises an entire area obtained by clipping the entire face area to a predetermined size, a four block division area, and a 16 block division area of the entire area. And feature vector extraction method for retrieval. 3. The method of claim 2, wherein in the step (a2), the Fourier spectrum is obtained from a central face region, and the Fourier amplitude is obtained from a second block division face region. The face recognition and retrieval feature of claim 5, wherein the second block divisional face area comprises a central area corresponding to the central face area, a four block division area of the central area, and a sixteen block division area. Vector extraction method. The method of claim 1, wherein step (b) (b1) generating first and second normalized vectors as frequency feature vectors for the entire face region of the normalized face image and third and fourth normalized vectors as frequency feature vectors for the central face region; (b2) generating an intensity feature vector and a predetermined number of intensity feature vectors for each face component of the entire face region of the normalized face image; (b3) combining the Fourier feature vector for the entire face region and the intensity feature vector for the whole face region and projecting them into a third predetermined linear discrimination space to generate a total complex feature vector; And and (b4) combining the Fourier feature vector for the central face region and the intensity feature vector for each facial component to project into a fourth predetermined linear discrimination space to generate a center complex feature vector. Feature Vector Extraction Method for Recognition and Retrieval. The method of claim 7, wherein step (b2) (b21) converting the normalized face image into a front face image by performing pose estimation and compensation; (b22) defining a fifth feature vector by raster scanning the entire face area of the pose compensated face image; (b23) defining a sixth feature vector by raster scanning a plurality of face component regions of the pose compensated face image; (b24) projecting the fifth feature vector into a third PCLDA subspace and then normalizing the fifth feature vector to a fifth unit vector to generate a full intensity feature vector; And (b25) extracting the feature vector for face recognition and retrieval comprising projecting the sixth feature vector into a fourth PCLDA subspace and then normalizing the sixth feature vector into a sixth unit vector to generate a partial intensity feature vector. Way. The method of claim 8, wherein in step (b21), a pose of the normalized face image is estimated by a PCA-DFFS method. The method of claim 7, wherein step (b3) (b31) combining the first and second normalization vectors generated in step (b1) with the entire intensity feature vector generated in step (b2); (b32) projecting the combined feature vectors into the third predetermined linear discrimination space; And and (b33) quantizing each component of the projected vector and storing them as a total complex feature vector. The method of claim 7, wherein step (b4) (b41) combining the third and fourth normalized vectors generated in step (b1) with the partial intensity feature vectors generated in step (b2); (b42) projecting the combined feature vectors into the fourth predetermined linear discrimination space; And and (b43) quantizing each component of the projected vector and storing them as a central complex feature vector. (a) generating first and second normalized vectors as frequency feature vectors for the entire face region of the normalized face image and third and fourth normalized vectors as frequency feature vectors for the central face region; (b) generating an intensity feature vector for the entire face region of the normalized face image and an intensity feature vector for each predetermined number of face components; (c) combining the Fourier feature vector for the entire face region and the intensity feature vector for the whole face region and projecting them into a first predetermined linear discrimination space to generate a total complex feature vector; And and (d) combining the Fourier feature vector for the central face region and the intensity feature vector for each facial component to project to a second predetermined linear discrimination space to generate a center complex feature vector. Feature vector extraction method for recognition and retrieval. A computer-readable recording medium having recorded thereon a program capable of executing the method according to any one of claims 1 to 12. A feature vector is generated in the entire Fourier using the first and second normalized vectors as the frequency feature vectors for the entire face region of the normalized face image, and the third and fourth normalized vectors are used as the frequency feature vectors for the central face region. A first unit for generating a feature vector at the central Fourier; And An intensity feature vector for the entire face region of the normalized face image and an intensity feature vector for each predetermined number of face components are generated, and the intensity feature vectors for the first and second normalized vectors and the entire face region are generated. And combining the third and fourth normalized vectors with the intensity feature vectors for each face component to generate a center composite feature vector. Feature vector extraction method for searching. The method of claim 14, wherein the first unit A Fourier feature generator for generating first and second normalized vectors as frequency feature vectors for the entire face region of the normalized face image and third and fourth normalized vectors as frequency feature vectors for the central face region; A total Fourier feature vector generator for combining the first and second normalized vectors and projecting the first and second normalized vectors into a first predetermined linear discriminating space to generate a feature vector in all Fourier; And And a central Fourier feature vector generator for combining the third and fourth normalized vectors to project the second predetermined linear discrimination space to generate a feature vector in the central Fourier. The method of claim 14, wherein the second unit A Fourier feature generator for generating first and second normalized vectors as frequency feature vectors for the entire face region of the normalized face image and third and fourth normalized vectors as frequency feature vectors for the central face region; An intensity feature generation unit for generating an intensity feature vector for the entire face region of the normalized face image and an intensity feature vector for each predetermined number of face components; A total complex feature vector generator for generating a total complex feature vector by combining the first and second normalized vectors for the full face region and the intensity feature vector for the full face region; And And a center complex feature vector generator for generating a center complex feature vector by combining the third and fourth normalized vectors of the center face region with the intensity feature vectors for each face component. Vector Extractor. The method of claim 16, wherein the Fourier feature generation unit A total Fourier that projects the first and second feature vectors defined from the Fourier spectrum and the Fourier amplitude obtained as a result of Fourier transform of the entire face region into the first PCLDA subspace and then normalizes to generate the first and second normalized vectors. Feature vector generator; And A central Fourier which projects the third and fourth feature vectors defined from the Fourier spectrum and the Fourier amplitude obtained from the Fourier transform of the central face region into the second PCLDA subspace and then normalizes to generate the third and fourth normalized vectors. A feature vector extractor for face recognition and retrieval, comprising a feature vector generator. 18. The apparatus of claim 17, wherein the Fourier spectrum is generated by the Fourier feature vector generating unit from an entire face region, and the Fourier amplitude is an entire region obtained by clipping the entire face region to a predetermined size, a four block division region of the entire region, and A feature vector extraction apparatus for face recognition and retrieval, characterized in that each is obtained from 16 block division areas. 18. The apparatus of claim 17, wherein the Fourier spectrum is obtained from the central face region and the Fourier amplitude is obtained from the central region, the four block division region and the sixteen block division region, respectively. Feature vector extraction device for face recognition and search. The method of claim 16, wherein the intensity feature generation unit A pose estimator / compensator for estimating a pose of the normalized face image and converting the pose to a front face image; A fifth feature vector obtained as a result of raster scanning of the entire face region of the pose estimated face image is projected into a third PCLDA subspace, and then normalized to a fifth unit vector to generate a full intensity feature vector. A tensory feature vector generator; And A sixth feature vector obtained as a result of raster scanning of the plurality of face component regions of the pose estimated face image is projected into a fourth PCLDA subspace, and then normalized to a sixth unit vector to generate a partial intensity feature vector. A feature vector extraction apparatus for face recognition and retrieval comprising a partial intensity feature vector generator.