JP2573126B2 - Expression coding and emotion discrimination device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a facial expression coding and emotion discrimination device for analyzing and calculating the facial expression of a human face.

[0002]

2. Description of the Related Art Attempts to read human facial expressions in terms of technology have been made so far, but all of them treat such facial expressions as mere two-dimensional image information, which is difficult to analyze and store. , A huge amount of processing was required. In addition, in many cases, the discrimination of facial expressions and emotions can be realized by accumulating experience, and is realized by an application system such as a neurocomputer or an expert system. However, it is still insufficient at present.

[0003]

On the other hand, in the field of medical treatment, reading of facial expressions is an important factor indispensable to daily medical treatment in the past, present and future. When considering transmission, there is a strong demand for an appropriate device to read technologically and appropriate image communication in motion. And the research is
It is an important issue not only in science but also in art and life, as long as human beings are human. Therefore, the present invention technology-based classification of facial expression elements based on medical and physiological research such as muscle movement and nervous system connection,
The coding is intended to be concise and appropriate. In addition, medical and physiological studies on the expression of human faces and the development of emotions described above have revealed that there is a clear law of correspondence between facial expressions and emotions. By applying this correspondence to coded expressions, human emotions can be identified by accumulating experience mainly involving human sensory functions. Instead, it seeks to be able to do it very mechanically.

[0004]

The basic theory of the present invention is based on the research results of emotional engineering of facial expressions by the inventor. Here is an outline of the theory. The mechanism by which the facial expression of a human face appears on the face is represented by the block diagram of FIG. The facial expression is the activity of the facial muscles under the control of the facial nerve, and its activity center is the central of the facial nerve. Facial muscles are present under the head and anterior neck subcutaneously.
Each pair on the head and neck, around the eyes, ears and nose, three pairs each,
There are twelve pairs around the lips. Among them, FIG. 2 shows main lines related to facial expressions. These are called facial muscle groups. These facial muscles are striated muscles like other somatic motor muscles,
It is characterized by the fact that it is symmetrically terminated directly from the facial bone to the skin of the face, and the response is simultaneous and the speed is extremely fast. In addition, the expression is such that the dynamic eyelids, lips and accompanying eyebrows, beards, etc., open and close or move up, down, left and right to change the relative position between the static head, ears, nose, etc. It is caused by things. Therefore, it is considered that the initiative of the facial expression lies in the function of the facial muscle that activates the dynamic part, and a dynamic model of the facial muscle can be created from this. In other words, the muscle groups that activate the dynamic part are extracted, and the muscle groups that work cooperatively and antagonistically are collected, so that the facial muscle groups can be divided into the following six groups. These six groups are the minimum muscle group classification required for facial expression recognition.

[Table 1] When the tension of the six groups is expressed as numerical values, the expression can be expressed as a code composed of six numerical values. This is called an "expression element code". By the way, from the electromyographic study,
As shown in the figure, a frontal muscle (F) that forms wrinkles on the forehead, a wrinkle muscle (C) that moves the eyebrows, a cuff muscle (R) that opens and closes the lip, and a cheekbone muscle group that raises the mouth angle (Z) and the orbicularis oculi (O) closing the eyes are in a cooperative innervation relationship, respectively.
In addition, the frontal muscle (F) that forms wrinkles on the forehead, the orbicularis muscle (O) that closes the eyes, the wrinkle muscle (C) that moves the eyebrows, the zygomatic muscle group (Z) that raises the mouth angle, and the orbicularis muscle that closes the lips ( Electromyographic studies confirmed that R) and the muscle group lowering the lower lip (M) had an antagonistic innervation relationship, respectively. Based on these facts, an octahedron having six elements (muscle groups) as vertices is considered, and an element having an antagonistic relationship is set as a diagonal element, whereby an octahedron serving as a dynamic model of facial expression movement can be obtained. Inventor Masashige Furukawa named it "octahedron of expression". This is shown in FIG.
In the octahedron of this expression, an extreme expression appears when three elements, one main element and two cooperative subordinate elements, constituting the eight surfaces are operated. This is shown in FIG. In FIG. 4, a solid line indicates an adjacent surface, and a broken line indicates an opposing surface. In addition, the facial expressions shown in this case correspond to the emotions shown in the following table and FIG.

[Table 2] The following table shows the correspondence between these typical emotions and facial expression elements.

[Table 3] According to this table, the emotion can be determined from the expression element code.

Here, the present invention relates to an image input apparatus which takes in a face image as an electric signal, and intelligently encodes the face image according to the "octahedral expression" rule to obtain predetermined face image data. Receiving a predetermined facial image data from the personal computer and extracting a characteristic part image based on the characteristic part extraction condition. A facial expression element extracting means for extracting facial elements to obtain facial expression element information, and further comprising a facial expression element quantifying process based on a predetermined facial expression element quantification rule from the facial expression element information to calculate a facial expression element code It has quantification processing means, and calculates the amount of various emotions by performing arithmetic processing on the expression element code using a predetermined emotion conversion formula, and also calculates the maximum value among them. And an emotion processing unit having an emotion determination unit for determining the type of the emotion responding to the maximum value, and a storage unit for storing the expression element code and the type and size of the emotion And an expression element code / emotion information output device for outputting the type and size of the expression element code and the emotion stored in the arithmetic processing device.

[0006]

With the above configuration, the image input device inputs a face image as an electric signal, encodes the face image data into face image data suitable for processing in the next arithmetic processing device, and sends it to the arithmetic processing device. As shown in the flowchart of FIG. 8, the arithmetic processing device that has received the facial image data extracts characteristic region images from the facial image data based on predetermined characteristic region extraction conditions using characteristic region extraction processing means. The facial expression element extraction processing means extracts the facial expression element from the characteristic part image based on the rule related to the specific facial expression element and the characteristic part, and further, the facial expression element quantifying processing means Based on the expression element information based on the expression element information, the expression element quantification processing is performed, and the above-described six muscle group symbols F, C, O, Z,
An expression element code suitable for R and M is calculated, the expression element code is stored in the storage means, and a predetermined emotion conversion formula is used in the emotion determination means as shown in the flowchart of FIG. Then, the expression element code is processed to calculate the amount of each emotion, and the type of the emotion is determined from the maximum value of the calculated values. In addition to the above-mentioned expression element code, the expression element code is stored in the storage means, and the expression element code / emotional information output device outputs the expression element code and the type and size of the emotion held in the arithmetic processing device. .

[0007]

FIG. 7 shows an embodiment of the "expression encoding and emotion discriminating apparatus" of the present invention. This device is
An image input device 1 that captures a face image as an electric signal, encodes the image, and converts the image into a format that can be processed by an arithmetic processing device;
An arithmetic processing unit 2 for performing a calculation of quantification of the degree of tension of the facial muscles to obtain a facial expression element code and emotional information, and for storing;
A facial expression element code / emotional information output device 3 for outputting the facial expression element code or emotion information calculated by the arithmetic processing unit. The image input device 1 includes a video camera and a video frame memory connected thereto, an image scanner suitable for capturing photos, and the like. The arithmetic processing device 2 extracts a characteristic region image from facial image data based on characteristic region extraction conditions. Characteristic part extraction processing means, expression element extraction processing means for extracting expression elements from the characteristic part image based on the rules relating the expression elements and characteristic parts, and obtaining expression element information, and quantifying the expression elements from the expression element information Expression element quantification processing means for calculating expression element codes by performing expression element quantification processing based on rules, and calculating the amount of various emotions by performing arithmetic processing on the expression element codes using an emotion conversion formula,
A personal computer, a workstation, or the like having an emotion determining means for determining the type of emotion from the maximum value among the calculated values, and storage means for storing the expression element code and the type of emotion; Numerical / symbol display devices as the element code / emotional information output device 3,
A parallel or serial digital signal output device is used. Thus, the expression encoding and emotion discrimination device is governed by the following expression element encoding algorithm and emotion identification algorithm.

[0008] 1. Expression element coding algorithm The image of the face is supplied from the image input device 1 to the arithmetic processing device 2 as two-dimensional grayscale data that can be processed by the arithmetic processing device. The area is stored and held as face image data. Therefore, the facial image data (a) is sequentially processed as follows in accordance with the flowchart of FIG. 8 to obtain the facial expression element code (g). (1) Characteristic part extraction processing According to characteristic part extraction conditions from face image data (a),
A characteristic part extraction image (c) in which a part necessary for facial expression recognition is extracted is obtained. As a specific processing example, the characteristic parts are set to the following six points in the following table, and in the schematic diagram of the algorithm in FIG. 9, the characteristic parts are extracted in the fixed coordinate system by applying the characteristic part extraction conditions in the following table. The procedure of the process in this case is shown in the flowchart of FIG. As a result, FIG.
Characteristic site images (square screens) shown in schematic diagrams 0 to can be cut out.

[Table 4] (2) Expression element extraction processing A condition for associating a change in a characteristic part determined based on the mutual relationship between muscle movements and connections of the nervous system found from medical electromyographic research with an expression element, that is, an expression element Characteristic part image (c) according to the rule (d) relating to the characteristic part
Is associated with a facial expression element, and facial expression element information (e) is extracted. The following table shows a specific example of the relation rule (d) between the facial expression element and the characteristic part.

[Table 5] The symbol of each facial expression element and the rule No. for each element. Together with the rule code. That is, the rule code is composed of the muscle group symbols F, C, O, Z, R, M and the rule No. For example, in the case of "Ebrow movement condition No. 2", "C-
2 ". FIG. 12 is a flowchart showing a detailed analysis procedure of the characteristic portion image (c) for each rule code determined in Table 5. By performing the processing according to this flowchart, some measured values are determined as the expression element information (e) for each rule code. Further, when the symbols (F, C, O, Z, R, and M) of each expression element are collectively x, and the measured value (expression element information) of the rule code _xn is represented by p _xn , for example, C-2 Is _pC2 . In addition,
The expression element information p _xn is a scalar if the measured value is one, 2
If it means a vector. (3) Expression element quantification processing Measured values for each rule code of the expression element information (e) are calculated in accordance with the expression element quantification rule (f) to obtain an expression element code (g) which is a numerical value for each expression element. As a specific example of the expression element quantification rule (f), there is a method of using a regression equation obtained based on a measured value and an electromyogram value from a face image. The procedure for obtaining this regression equation is shown in the flowchart of FIG. That is, sampling: focusing on a certain expression element, for example, “F: movement of forehead”
From the most nervous state (the state where wrinkles are made on the forehead as much as possible)
Gradually relax the tension. At this time, the electromyogram and the face image are sampled. The facial image is obtained up to the facial expression element information (e) by the above algorithm. Regression calculation: For each rule code, the state of the most nervous state is set to 1 and the relaxed state is set to 0, the values of the electromyogram are made to correspond, and regression calculation is performed with the expression element information (e) to obtain a regression equation. Here, rules code F1, F-2, the ...... regression equation _{f F1,} f
_F2, ... Next, a regression calculation is performed to combine the regression formulas for each rule code into a regression formula linked to each facial expression element.
The regression equation of the expression element code F thus obtained is

(Equation 1) Note that the above equation is a linear equation, but may be higher.
Here, the measurement value of the F-5 from regular code F-1, and expressed as p _F as a whole. In this case, p _F is the expression element information about F, values obtained by substituting p _F to f _F is a value f of the expression elements codes for F follows.

(Equation 2) Similarly, regression expressions f _C , f _O , f _Z , f _R , and f _M of the expression element codes for the other C, O, Z, R, and _M are obtained. The expression element information (e) is substituted into each regression equation, and the value of the expression element code of the following equation is obtained.

(Equation 3) _{p F, p C, p O} , p Z, p R, p M: follow another expression element information each facial expression element, f, c, o, z , r, m is the symbol F in each facial expression elements, C, O , Z, R and M are the values of the facial expression element codes corresponding to the facial muscles. 2. Emotion discrimination algorithm Table 3 described above shows the relationship between typical emotions and expression element codes. In this table, emotions can be further classified by weighting the expression element codes. Here, a case where Table 3 is used as it is as a specific example of the emotion determination algorithm will be described. (1) Weighting of facial expression elements Weighting of facial expression elements is performed as follows by relating the coefficient k. For the expression element code x, the main element ++ 2k · x << 3k · x when increasing the weighting »Dependent element + k · x Antagonistic element (−) k · (1-x) k: 1/6 means I do. (2) Emotion conversion equation An equation for calculating the amount of each emotion is obtained from the weight (1) of the expression element and Table 3.

(Equation 4) f, c, o, z, r, m: Value of facial expression element code This is called an emotion conversion formula. (3) Emotion discrimination When the expression element code obtained from the face image is substituted into the emotion conversion equation by the expression element encoding algorithm, the amount E _hp -E _SL of each emotion is calculated as described above. The emotion type in which the value of E _hp -E _SL is maximum is determined as the emotion of the face. The maximum value is the amount of emotion. FIG. 14 is a flowchart showing this process.

[0010]

According to the present invention, it is possible to technologically classify and encode elements of real facial expressions based on medical and physiological studies, such as movements of muscles of the human face and connections of the nervous system. Possible, and with such intelligent coding,
By eliminating unnecessary information processing and performing necessary, sufficient, and small information processing, processing can be performed simply, appropriately, and quickly, and required expression element codes can be quickly and accurately extracted. Also, if the expression element code is stored in a magnetic storage device or the like, the conventional expression of the human face can be reduced to the conventional 10%.
It is possible to store a large amount of data of about ten thousand times. Furthermore, based on the fact that emotional engineering research revealed that there is a simple correspondence between human facial expressions and emotions, by applying this correspondence to the facial expression element code, human emotions can be discriminated. Can be performed extremely mechanically and rationally, and can be conveniently used for reading facial expressions in daily medical treatment. In addition, it can be widely used for both art and life, and can achieve its intended purpose. Thus, for example, a video camera is provided in the driver's seat of an automobile to read the facial expression of the driver, discriminate the emotion, and apply an alarm to a drowsiness alarm for automobiles that sounds an alarm when a sleepy expression occurs. Further, it is possible to make the emergency stop device in an emergency by further proceeding the operation and directly interlocking with the brake and detecting the expression of fear.
In addition, the present invention can be widely applied to reading of a facial expression of a subject, discrimination of the emotion, and monitoring of a change in the emotion of the subject in response to a question.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an internal model of a human emotion expression mechanism according to the present invention.

FIG. 2 is a diagram showing facial muscles of a human face according to the present invention.

FIG. 3 is a diagram showing an octahedron of a human facial expression according to the present invention;

FIG. 4 is a diagram illustrating a relationship between an image pattern of a human facial expression and emotion according to the present invention.

FIG. 5 is a diagram showing a cooperative / antagonistic relationship of six facial muscle groups of the human face according to the present invention.

FIG. 6 is a diagram relating to the operation of an octahedron in the expression of a human face and the rendering of the expression according to the present invention.

FIG. 7 is a block diagram showing an embodiment of a facial expression encoding and emotion determining apparatus according to the present invention.

FIG. 8 is a flowchart showing expression element encoding in the same example.

FIG. 9 is an explanatory diagram of a feature portion extraction algorithm of the fixed coordinate system of the same example.

FIG. 10 is an explanatory diagram showing a characteristic part extraction image extracted from FIG. 9;

FIG. 11 is a flowchart of a characteristic portion extraction process of the same example.

FIG. 12 is a flowchart illustrating an example of a characteristic part image analysis procedure of the same example.

FIG. 13 is a flowchart showing an example of an expression element quantification regression calculation procedure of the same example.

FIG. 14 is a flowchart showing an emotion determination algorithm of the same example.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Image input device 2 Operation processing device 3 Expression element code / emotional information output device

 ────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Yoichi Furuno 2-15-15 Nakahara Nishi, Tobata-ku, Kitakyushu-shi, Fukuoka Prefecture 603 Nisshin Pale Stage Kyutech (56) Reference JP-A-3-252775 (JP, A )

Claims (1)

(57) [Claims] 1. An image input device that captures and encodes a face image as an electric signal to obtain predetermined face image data, and receives predetermined face image data from the image input device,
A facial expression extracting means for extracting a characteristic part image based on a characteristic part extraction condition, and extracting a facial expression element from the characteristic part image based on a predetermined facial expression element and a rule relating to the characteristic part to obtain facial expression element information Having element extraction processing means,
Further, there is provided a facial expression element quantification processing means for performing a facial expression element quantification process based on the facial expression element information based on a predetermined facial expression element quantification rule to calculate a facial expression element code. There is an emotion discriminating means for calculating the amount of each type of emotion by performing an arithmetic process using an expression, selecting the maximum value from among them, and discriminating the type of emotion responding to the maximum value. And an arithmetic processing unit having storage means for storing the expression element code and the type and size of the emotion, and outputting the expression element code and the type and size of the emotion stored in the arithmetic processing device. A facial expression encoding / emotional discrimination device, comprising: a facial expression element code / emotional information output device.