A Study of Facial Features of American and Japanese Cartoon Characters

: Many researchers think that the characters in animated cartoons and comics are designed according to the exaggeration or reduction of some features based on the human face. However, the feature distribution of the human face is relatively symmetrical and uniform. Thus, to ensure the characters look exaggerated, but without breaking the principle of symmetry, some questions remain: Which facial features should be exaggerated during the design process? How exaggerated are the faces of cartoon characters compared to real faces? To answer these questions, we selected 100 cartoon characters from American and Japanese animation, collected data from their facial features and the facial features of real people, and then described the features using angles, lengths, and areas. Finally, we compared cartoon characters’ facial features values with real facial features and determined the key parts and degree of facial exaggeration of animated characters. The research results show that American and Japanese cartoon characters both exaggerate the eyes, nose, ears, forehead, and chin. Compared with human faces, taking the eye area as an example, American animation characters are twice as large compared with human faces, whereas Japanese animation characters are 3.4 times larger than human faces. The study results can be used for reference by animation character designers and researchers.


Introduction
Many cartoon or animation characters have affected us, leaving a lasting impression. They are the key factor for the success of a cartoon or an animation production. People love characters and interact with them in all aspects of their lives. Fictional characters draw us into their stories in films and television. Like people, animated characters must be good conversational partners [1]. Thus, determining how to design an animated character and make it impressive is an important part of cartoon and animation theory and research.
Perkins [2] introduced two core concepts of comics: exaggeration and personalization, showing that exaggeration is the key factor in creating a cartoon character. Johnston and Thomas [3] mentioned the importance and integrity of exaggeration in Disney's 12 Rules. Lasseter [4] mentioned exaggeration in three-dimensional (3D) animation. While, Redman [5] stated that exaggeration is based on the enlargement and reduction of real characteristics but not equivalent to distortion, because distortion completely negates the appearance of the prototype. Exaggeration should be accompanied by the

Differences between Eastern and Western Cartoons
Byatt and Rhodes [8] showed that western cartoon characters have more exaggerated facial features and more recognizable than those of Chinese comic characters. Toku [23] concluded that Japanese children prefer closed lines, strong structure, and exaggerated features comics. McCloud [24] thought that Japanese cartoons subjectively accelerate the speed line and blur the effect to show the character's movement because of cultural differences. Cohn [25] concluded that there are significant differences in characters, space, and perspective between American and Japanese cartoons. Lu [7] mentioned that the characters in Japanese animation are closer to the appearance of European and American people. The purpose of doing so is to cater to western audiences.
In different areas, the cartoon characters have different exaggeration styles and degrees, but few studies have provided a detailed analysis of the forms and degrees that have always existed in the cartoon characters design process.

Calculation Method of Cartoons Based on Facial Feature Recognition
Some researchers proposed the "Eigen face" and "feature face" recognition technology [26,27]. A series of feature criteria were established to calculate the degree of difference between the object and criterion.
Early face recognition can be used to select some geometric facial features, such as eyes, nose, mouth, and chin, marking the manual positioning points to calculate the shape and relative position Yun-Hong et al. [28] concluded that point characteristics can be widely used in various programs and have been well practiced in implementing some algorithms. Yue-Long et al. [29] mentioned that the number of feature points needed is generally about 60. However, if only the basic structure of the face is described, the number of feature points can be reduced correspondingly.
Computers can calculate the contour and angle of facial features by locating points to achieve the purpose of face recognition [30].
Meethongjan [31] described the whole face pattern and provided 48 different feature points with different weights. Cootes and Taylor [32] performed extraction from image features in a one-dimensional range along the vertical contour. Milborrow and Nicolls [33] performed extraction from two-dimensional images using the square neighborhood of feature points Viola and Jones [34] calculated different features of human faces independently according to location points, and calculated the relationship between different features according to the data of independent features. Cabeza and Kato [35] reported that face structures have an important contribution to face recognition.
Some researchers tried to transform real faces into cartoon portraits. Brennan [36] extracted the contours and feature contours of human faces with a computer and transformed them into lines then he exaggerated or reduced these contours to generate cartoons. Talekar [37] changed the length and angle parameters of facial features to generate cartoons. Liang et al. [38] used partial least squares (PLS) to analyze the correlation between images and cartoons, and captured the artist's understanding of facial features and exaggerated styles from the cartoon samples. Mra et al. [39] stated that facial portraits suitable for cartoons should be controlled at an exaggerated level of about 20-40%.
In addition, many achievements have been achieved by capturing facial features and expressions and generating real-time 3D facial animation by some algorithms. Hao Li et al. [40] introduce a method for generating facial blend shape rigs from a set of example poses of a CG character that can automatically create optimal blend shapes from a set of example poses of a digital face model. Thibaut Weise et al. [41] combined geometry and texture registration with pre-recorded animation priors in a single optimization and got a system for performance-based character animation that enables any user to control the facial expressions of a digital avatar in real time. Hao Li et al. [42] introduce a real-time and calibration-free facial performance capture framework which developed an adaptive PCA model using shape correctives that adjust on-the-fly to the actor's expressions through incremental PCA-based learning. Christos et al. [43] presents a solution to retargeting facial animation in a virtual character's face model based on the kernel projection of latent structure (KPLS) regression between semantically similar facial expressions. Which transferring facial animation to face models' efficiency. Mousas et al. [44] presents a method to transfer facial blend shapes from a reference to a source face model automatically. Ma and Deng [45] describe a novel real-time end-to-end system for facial expression transformation, without the need of any driving source. Wei and Deng [46] introduces a simple, efficient, yet practical phoneme-based approach to generate realistic speech animation in real time based on live speech input.

Materials and Methods
Figure 1 presents the research methods and processes that will be adopted in this study.

Selection of Research Samples
The animation industry in the United States and Japan is relatively developed, and some famous animations come out every year. The cartoon characters of the two countries have typical characteristics. Therefore, we selected 100 cartoon characters as samples of the excellent animations produced in these two countries, as shown in Figure 2. American animated characters come from films nominated for the Academy Awards or top 10 at the box office or the Rotten tomato website (https://www.rottentomatoes.com) [47] film score of more than 7 points between 2005 and 2017. Japanese cartoon characters were selected from the top 10 films at the box office from 2005 to 2017

Selection of Research Samples
The animation industry in the United States and Japan is relatively developed, and some famous animations come out every year. The cartoon characters of the two countries have typical characteristics. Therefore, we selected 100 cartoon characters as samples of the excellent animations produced in these two countries, as shown in Figure 2. American animated characters come from films nominated for the Academy Awards or top 10 at the box office or the Rotten tomato website (https://www.rottentomatoes.com) [47] film score of more than 7 points between 2005 and 2017. Japanese cartoon characters were selected from the top 10 films at the box office from 2005 to 2017 and produced by different companies or directors. From each film, regardless of the primary and secondary

General Model for Basic Face Reference
Exaggeration must be based on a prototype. Mike [12] synthesized 1,000 faces of American men to produce a synthetic face representing all American men and 1000 female faces were synthesized to produce a synthetic American female face. A Japanese male face and a female face were obtained following the same method. In this study, we synthesized the four synthesized faces again, and

General Model for Basic Face Reference
Exaggeration must be based on a prototype. Mike [12] synthesized 1000 faces of American men to produce a synthetic face representing all American men and 1000 female faces were synthesized to produce a synthetic American female face. A Japanese male face and a female face were obtained following the same method. In this study, we synthesized the four synthesized faces again, and selected half of the faces to create an absolutely symmetrical human face, as illustrated in Figure 3. After obtaining a human face, we used this template to represent the faces of the two countries and judged how exaggerated the cartoon characters are compared with the human face. selected half of the faces to create an absolutely symmetrical human face, as illustrated in Figure 3. After obtaining a human face, we used this template to represent the faces of the two countries and judged how exaggerated the cartoon characters are compared with the human face.
(a) (b) Figure 3. (a) Face of Japanese and American man and woman synthesized from multiple photographs [12]; (b) A human face synthesized by Japanese and American mass faces and its 26 location points [12].

Defining Effective Location Points
We marked the location points of 26 positions on the face of the selected character sample. The location points were marked by dots and English letters. For example, the position between the eyebrows center is point "a". Those location points were used to categorize the features with exaggerated components. In this study, facial features, shapes of different parts of the face, and their proportional relationships were measured. The measurements included the length and width of features, areas of different parts of the face and feature areas, and relationships of angles between features and face shapes. If the length, angle, or area of some features could not be measured for some reason, then we selected one of the values that could be measured as a reference value. For example, the length and area of the ear in some samples were covered by hair so could not be measured accurately, therefore the width of the ear was measured to estimate the size and location.
First, the lengths of the features were divided into two groups: vertical and horizontal. Longitudinally, the lengths of the facial features were observed, whereas in the other group, the width of the face was observed. In the process of measuring the longitudinal distance, the length between p-a-c-e-g was chosen as the basic reference length, pa = LA1, ac = LA2, ce = LA3, and eg = LA4. LA1 represents the distance between the hairline and eyebrows' center. LA2 is the distance between the eyebrows center and the nasal floor. LA3 represents the distance from the nasal floor to the lip line. LA4 is the distance between the lip and chin.
The four lengths, LA1, LA2, LA3, and LA4, are distributed on the same axis. Therefore, LA1, LA2, LA3, and LA4 can be listed and combined to obtain six auxiliary reference lengths of LA5, LA6, LA7, LA8, LA9, and LA10. The length between the upper and lower eyebrows, which is not on the axis, was labeled LA11. Thus, in all 11 vertical reference lengths, to measure the width of characters' features, six transverse distance measurements were selected: oq = the width of the forehead, named LB1, kl = the width of the face, named LB2, bd = the width of the nose, named LB3, ij = the width of mandibular, named LB4, and fh = the width of the chin, named LB5. Detail definition of face features are listed in Table 1.

Defining Effective Location Points
We marked the location points of 26 positions on the face of the selected character sample. The location points were marked by dots and English letters. For example, the position between the eyebrows center is point "a". Those location points were used to categorize the features with exaggerated components. In this study, facial features, shapes of different parts of the face, and their proportional relationships were measured. The measurements included the length and width of features, areas of different parts of the face and feature areas, and relationships of angles between features and face shapes. If the length, angle, or area of some features could not be measured for some reason, then we selected one of the values that could be measured as a reference value. For example, the length and area of the ear in some samples were covered by hair so could not be measured accurately, therefore the width of the ear was measured to estimate the size and location.
First, the lengths of the features were divided into two groups: vertical and horizontal. Longitudinally, the lengths of the facial features were observed, whereas in the other group, the width of the face was observed. In the process of measuring the longitudinal distance, the length between p-a-c-e-g was chosen as the basic reference length, pa = LA1, ac = LA2, ce = LA3, and eg = LA4. LA1 represents the distance between the hairline and eyebrows' center. LA2 is the distance between the eyebrows center and the nasal floor. LA3 represents the distance from the nasal floor to the lip line. LA4 is the distance between the lip and chin.
The four lengths, LA1, LA2, LA3, and LA4, are distributed on the same axis. Therefore, LA1, LA2, LA3, and LA4 can be listed and combined to obtain six auxiliary reference lengths of LA5, LA6, LA7, LA8, LA9, and LA10. The length between the upper and lower eyebrows, which is not on the axis, was labeled LA11. Thus, in all 11 vertical reference lengths, to measure the width of characters' features, six transverse distance measurements were selected: oq = the width of the forehead, named LB1, kl = the width of the face, named LB2, bd = the width of the nose, named LB3, ij = the width of mandibular, named LB4, and fh = the width of the chin, named LB5. Detail definition of face features are listed in Table 1.

Methods and Tools for Collecting Location Point Data
Using the measuring tool function of Photoshop CS6 (Adobe System Incorporated, San Jose, CA, America), we could collect coordinate data of a pixel in each picture. Therefore, we created a square of 10 × 10 cm, and enlarged all the character face samples to ensure the whole head of the characters

Methods and Tools for Collecting Location Point Data
Using the measuring tool function of Photoshop CS6 (Adobe System Incorporated, San Jose, CA, America), we could collect coordinate data of a pixel in each picture. Therefore, we created a square of 10 × 10 cm, and enlarged all the character face samples to ensure the whole head of the characters

Methods and Tools for Collecting Location Point Data
Using the measuring tool function of Photoshop CS6 (Adobe System Incorporated, San Jose, CA, America), we could collect coordinate data of a pixel in each picture. Therefore, we created a square of 10 × 10 cm, and enlarged all the character face samples to ensure the whole head of the characters

Methods and Tools for Collecting Location Point Data
Using the measuring tool function of Photoshop CS6 (Adobe System Incorporated, San Jose, CA, America), we could collect coordinate data of a pixel in each picture. Therefore, we created a square of 10 × 10 cm, and enlarged all the character face samples to ensure the whole head of the characters fit into the square (the top of the head to the chin matched the top and bottom of the square picture and the left and right sides of the ears connected the left and right edges of the square, respectively). The coordinate data of each location point were collected using a measuring tool in Photoshop CS6 (Adobe System Incorporated, San Jose, CA, America) from the location pixel. For example, for a character, point "a" at the eyebrows center, the coordinates are X 697, Y 549. For point "e" at the lip tip, the coordinates are X 698, Y 358. The coordinates of these X and Y can accurately represent the location of a certain point. After obtaining these coordinate data, the data were input to Excel (Microsoft Corporation, Redmond, WA, America), and the lengths, angles, areas between the location points, and the location points were calculated through the program to obtain the initial data: (1) The length or width of the distance between two points: for example, the length value of a-c of a character is 356, a-c represents the length of this character's nose. (2) The angle constructed by three points: for example, for a character, its angle "a-i-g" is 98. The three "a-i-g" points construct the angle from the eyebrows' center point, to the point of the left jaw, and to the point of the chin. (3) The value of the area constructed by four points. For example, the area value of "r-s-t-u" of a character sample is 8176. r-s-t-u represents the area of the eye.
After preliminary calculation of the facial length, angle, and the area of the 100 characters from the two countries was completed, we collected and calculated the initial data of the length, angle, and area of the features of the human face.

Seeking a Common Length from All Features as a Measurement of Normalization
According to the preliminary data, the characteristics of the 100 cartoon characters demonstrated similarities in some characteristics, and large differences in others. At the beginning of data collection, these cartoon characters were placed in a square to give all samples a uniform specification and standard. However, in order to comparatively analyze the exaggeration of all characters, it was necessary to find a common characteristic value from these cartoon facial features as a measurement.
To find the facial feature with the minimal change in length, we used Excel's ranking function (Microsoft Corporation, Redmond, WA, America) to rank the data from the research samples. The ranking steps were as follows. Sixteen features (from LA1 to LA11 and from LB1 to LB5) were ranked by length, and then renamed based on the rank. Hundred faces were measured, and the standard deviations of the ranks of each facial feature were calculated. The facial feature with the minimal deviation was served as the unit of length of the face. Other facial features were divided by the unit of length, and therefore, the lengths of all faces can be compared by the same criteria. For example, the L3 of character A received five points, the L3 of character B received four points, and the L3 of character C was assigned five points. By analogy, we obtained the average length of feature L3 of the 100 characters and finally, calculated the standard deviation of the shortest value and the longest value of the features.
By sorting, the feature parameters with the largest and lowest standard deviations were found. We preliminarily inferred that the feature values with the smallest length standard deviation were the feature values of all characters (without too much design). During cartoon character design, those features with large standard deviation in terms of length are the focus of the design.
After ranking, we changed the length code of L1 to L16 back to LA1 to LB5. Through the ranking result, we found that the minimum value of L15 (LA7) was 13, and the maximum value was 16. Compared to other feature's lengths, L15 (LA7) was the most constant feature length of the 16 lengths. Therefore, the average parameter of L15 (LA7) was used as a reference standard for all character features for normal alignment. After the average parameter L15 (LA7) was obtained, the original length and area data were divided by the value of L15 (LA7), and the length and area values of all character samples for comparison were obtained.
Following the same process, the average values of length, area, and angles of the human face were obtained by dividing the original data for human face length and area by the parameter value of L15 (LA7). The average value of the face norm was assumed to be one to measure the degree of exaggeration of animation characters.

Statistical Methods Description
After dividing the average parameters by LA7, A1 to A13, LA1 to LB5, and R1 to R6 of Japanese and American cartoon characters were tested by independent sample T. The average value and standard deviation were counted to find the differences between Japanese and American characters in 13 angles, 16 lengths, and six areas.
Secondly, the characteristics data of the human face were obtained by a single sample T-test. Then, the face human face data were compared with the length, area, and angle data of the faces of the American and Japanese animated characters. The ratios of the human face to American and Japanese animation facial features were obtained.

Classification Performance Evaluation
Face parameters are used to distinguish between Japan and the USA by a linear classifier. Define Then, the maximum accuracy of the same parameter is collected, with corresponding sensitivity and specificity pairs.

Results
The study results are presented in three sections: The comparison of the 13 angles, the comparison of the 16 lengths, and the comparison of the six areas. Each comparison includes the comparison between the human face and the American cartoon characters and the comparison between the human face and Japanese cartoon characters. By comparing the data, we determined how much the certain cartoon character's feature values are exaggerated compared with the value of one assigned to the human face. The feature values that achieve significant differences are identified here by the feature code. Table 2 shows that the cartoon characters are significantly different from the human face at A1, the length and shape of the nose at A2, A9, the shape of the face below the eyebrows at A3, the length of the middle part of the face at A5, A6, the width and sharpness of the jaw at A7, A8, the distance between the left and right mandible at A7, A10, the jaw at A11, the length of the face contour at A12, and A13 the length and position of head contour. Table 2. Comparison of angles of a human face with Japanese and American cartoon characters faces. Data are represented as mean (std). a is p-value of t-testing between human and Japanese Animation. b is p-value of t-testing between human and American animation. * p-value < 0.05; ** p-value < 0.01; *** p-value < 0.001. There were nine significant differences in the angles between human faces and Japanese cartoon characters: A1, A2, A7, A8, A9, A10, A11, A12, and A13. There were six significant differences in the angles between the human face and American cartoon characters: A3, A5, A6, A9, A11, and A12.

American Animation Characters
We assumed that the value of the human face is 1. The average value of A1, A2, A7, A8, A9, A10, A11, A12, and A13 show that Japanese anime characters were exaggerated by 9 • compared with human face in the angle from the eyebrows center to left alar of nose to base of nose, the angle from eyebrows center to left jaw to chin was reduced by 8 • , the sharp angle of the chin was exaggerated by 4.6 • , the jaw was 5 • lower, there was a 5.2 • reduction in the ears and the face was shorter, the nose position was 3.2 • higher, the mouth position was 3.8 • higher, the forehead and upper eyebrows' center positions were 3 • higher, and hairline was 5.4 • lower.
The average values of A3, A5, A6, A9, A11, and A12 show that the American cartoon characters have longer noses, higher brows, and lower mouths than human face; the distances were 6.5 • exaggerated in the distances between these features. The width of the jaw was 8.2 • , 2.5 • lower chin, 4.1 • exaggerated distance between upper ears and lower mouth. and 3.5 • shorter distance between the forehead and the lower eyebrows' center position. There were seven significant differences in angle values between Japanese and American cartoon characters: A1, A3, A8, A10, A11, A12, and A13. American animation characters are larger than Japanese animation characters in angles of A3, A8, A10, A11, and A12 smaller than Japanese animation characters in the angles of A1 (nose length) and A13 (profile of side head). Table 3 shows that the cartoon characters are significantly different from the human face in LA2, length of the nose, LA8, length from the eyebrows' center to the lip line, LB6, the width of the ears, and LA11, the length between the upper and lower eyelids. Table 3. Comparison of lengths of a human face with Japanese and American cartoon character faces. Data are represented as mean (std). a is p-value of t-testing between human and Japanese Animation. b is p-value of t-testing between human and American Animation. * p-value < 0.05; ** p-value < 0.01; *** p-value < 0.001. There were twelve significant differences in the length between the human face and Japanese animation characters: LA2, LA8, LB3, LA3, LA10, LB2, LB6, LB1, LA5, LA6, LA11, and LA4. There were ten significant differences in the lengths between the human face and American animation: LA2, LA8, LA9, LB5, LB4, LB6, LA1, LA11, LB1, and LB2.

American Animation Characters
The average values of LA2, LA8, LB3, LA3, LA10, LB2, LB6, LB1, LA5, LA6, LA11, and LA4 show that Japanese anime characters were 1.1 times exaggerated compared to human faces for the length of the nose, 1.1 times exaggerated for the length of the eyebrows' center to the lip line, 1.6 times lower for the width of nose, 1.2 times exaggerated in the distance from the nose to the lip line, the length from the nose base to the chin exaggerated 1.1 times, 1.1 times exaggerated in the width of the face, 1.9 times exaggerated in the width of the ear, 1.1 times exaggerated in the width of the skull, 1.1 times exaggerated in the distance from the hairline to the base of the nose, exaggerated one time in the distance from the hairline to the lip line, 2.7 times exaggerated the distance between the upper eyelid and the lower eyelid, and 1.6 times lower in the distance between the lip line and the chin.
The  Table 4 showed that there were four significant differences in the feature areas between the human face and Japanese cartoon characters: R1, R4, R5, and R6. There were four significant differences in the feature areas between the human face and American animation: R1, R2, R3, and R6. Table 4. Comparison of areas of a human face with Japanese and American cartoon characters' faces. Data are represented as mean (std). a is p-value of t-testing between human and Japanese Animation. b is p-value of t-testing between human and American Animation. * p-value < 0.05; ** p-value < 0.01; *** p-value < 0.001. The average values of R1, R4, R5, and R6 show that Japanese anime characters has smaller sized of noses by 1.5 times compared with the human face, 1.25 times larger area between the left upper point of the skull to the left cheekbone to the lip bead to the right upper point of the skull, 1.1 times larger area between eyebrows center, the left and right cheekbones, and the chin, and 3.4 times larger eyes.

p-Value between American Animation Characters Japanese Characters
The average value of R1, R2, R3, and R6 show that American cartoon characters have 1.3 times larger noses, 1.3 times larger area between the eyebrows' center, the left and right mandible angles, and the chin, 1.25 times larger area between the left and right mandible angles and the chin, and two times larger eyes.
There were five significant differences between American and Japanese cartoon characters in the areas: R1, R2, R3, R4, and R6 American animation characters are larger than Japanese animation characters in the area of R1, the nose. R2, between the eyebrows center, the left and right mandible angles and the chin, and R3, between the left and right mandible angles and the chin, and smaller than Japanese animation characters in the area of R4, from the left upper point of the skull to the left cheekbone to the lip bead to the right upper point of the skull and R6, the eyes.

Classification Performance Evaluation
Maximum accuracy of selected face parameters is listed in Figure 4. The results of numerical comparison of all the features show that the values of LB3 and R1 are the highest. AUC of LB3 is 0.82, AUC of R1 is 0.78, both are nose-related parameters.
The average value of R1, R2, R3, and R6 show that American cartoon characters have 1.3 times larger noses, 1.3 times larger area between the eyebrows' center, the left and right mandible angles, and the chin, 1.25 times larger area between the left and right mandible angles and the chin, and two times larger eyes.
There were five significant differences between American and Japanese cartoon characters in the areas: R1, R2, R3, R4, and R6 American animation characters are larger than Japanese animation characters in the area of R1, the nose. R2, between the eyebrows center, the left and right mandible angles and the chin, and R3, between the left and right mandible angles and the chin, and smaller than Japanese animation characters in the area of R4, from the left upper point of the skull to the left cheekbone to the lip bead to the right upper point of the skull and R6, the eyes.  LA2  LA4  LA5  LA6  LA8  LA9  LA10  LB1  LB3  LB5  R1  R2  R3  R4  A1  A3  A8  A10  A11 A12 A13 Accuracy Figure 4. Classification accuracy of selected face parameters.

Discussion
Among the 16 proposed features, eyes, nose, ears, and the position of the mouth are the focus of the character's face design, regardless of the eastern or western animation characters.
We aimed to quantitatively explain the exaggerated features and degree of animated characters. Based on the comparison of the norm, the exaggerated features and scales of the American and Japanese animated characters were specifically described. The results confirm the view that early western cartoonists preferred to exaggerate the nose and chin of the character [9]. Through the study of character samples from American classic animated film of 2010-2016, we found that other facial features were exaggerated during the design process of a character, among them, "nose" has become the most obvious feature to distinguish the differences between American and Japanese animation characters. This may be due to the changing of the times, the production of cartoons is increasing, and audience demand for the design of cartoon characters may be changing. Zaw Mra [39] mentioned that the caricatures generated by the face recognition algorithm should be exaggerated by 20-40% compared to human faces. For those 3D animation artists, [10,[40][41][42][43][44][45] the technology of generating 3D real-time facial animation greatly saves the time cost of modeling and manual adjustment of characters action. However, if this kind of real-time animation is to be used in commercial projects, it is necessary to exaggerate the image, expression, and action of the characters in order to make the animated characters interesting. The data provided in this study can provide a reference for them to further study how to generate real-time commercial animated characters on the basis of real facial expression animation.
However, The characteristics of American animated characters have more exaggerated features, this supports Byatt and Rhodes [8] point of view that Western cartoon characters are more recognizable. The Japanese animated characters have obviously big eyes, sharp chins, and a small nose design tendency. This also corresponds to people's general impression of Japanese animation characters. Based on the data above, we inferred that both American and Japanese cartoon characters have a lengthened distance between the upper and lower eyelids. They also increase the eye area. Therefore, the eye is the focus of exaggeration. Thus, the impression of big eyes created by Japanese animation characters is real and universal. Although American cartoon characters also show the phenomenon of exaggerated eyes, they are much smaller than those of Japanese cartoon characters.  Based on the data above, we inferred that both American and Japanese cartoon characters have a lengthened distance between the upper and lower eyelids. They also increase the eye area. Therefore, the eye is the focus of exaggeration. Thus, the impression of big eyes created by Japanese animation characters is real and universal. Although American cartoon characters also show the phenomenon of exaggerated eyes, they are much smaller than those of Japanese cartoon characters. Compared with the human face, the average values of LA2 and R1 show that American cartoon characters are 1.2 times longer in the nose and 1.3 times larger in the nose area.

Nose
The data indicate that the noses of Japanese cartoon characters are narrow and long, whereas American cartoon characters have longer and larger noses.

Ears
The data for LB6 as shown in figure 7 show that the average ear width of Japanese cartoon characters is 1.9 times larger than those of the human face, whereas the average ear width of the American cartoon characters is 1.4 times larger than the human face. Therefore, the ears are also the The data indicate that the noses of Japanese cartoon characters are narrow and long, whereas American cartoon characters have longer and larger noses.

Ears
The data for LB6 as shown in Figure 7 show that the average ear width of Japanese cartoon characters is 1.9 times larger than those of the human face, whereas the average ear width of the American cartoon characters is 1.4 times larger than the human face. Therefore, the ears are also the focus of cartoon character designers, both American and Japanese cartoon characters have exaggerated ears.

Size of Different Areas of the Face
Besides facial features, the size of different areas of the face is an important aspect of cartoon character design. Five important components of facial shape were selected for analysis in this study: The size of the face, the size of the forehead, the size of the chin, the sharpness of the chin, and the width between the left and right mandible angle.    Figure 8 compared with the human face, the average values of LA3 and LA4 show that Japanese cartoon characters have a 1.2 times longer nasal floor to lip line and a 1.6 times shorter length from the lip line to the chin. American cartoon characters are not significantly different from the human face in the above two lengths. The data above show that Japanese cartoon characters are 1.2-1.6 times lower in the mouth position than the human face on average. Therefore, the position of the mouth is an important part of the character design of Japanese cartoon characters. However, the mouth position does not vary significantly compared to the human face for American cartoon characters

Size of Different Areas of the Face
Besides facial features, the size of different areas of the face is an important aspect of cartoon character design. Five important components of facial shape were selected for analysis in this study: The size of the face, the size of the forehead, the size of the chin, the sharpness of the chin, and the width between the left and right mandible angle.

Size of Different Areas of the Face
Besides facial features, the size of different areas of the face is an important aspect of cartoon character design. Five important components of facial shape were selected for analysis in this study: The size of the face, the size of the forehead, the size of the chin, the sharpness of the chin, and the width between the left and right mandible angle. Figure 9 compared with the human face, the average value of R4 shows that Japanese cartoon characters have 1. 25   We can learn from the data that Japanese animated characters exaggerate the facial area above the eyes. American cartoon characters have exaggerated areas in the middle face below the hairline and the area below the nose, but have smaller foreheads.

Size of Jaw
The average values of R3, LB5, and LB4 shown in figure 10 demonstrated that there was no significant difference between Japanese cartoon characters and the human face for these aspects. However, the average value of R3, LB5, and LB4 shows that American cartoon characters have 1.25 times larger area between the left and right mandible angles and the chin, 1.1 times wider mandible angle, and 1.4 times longer distance from the nasal floor to the lip line. We can learn from the data that Japanese animated characters exaggerate the facial area above the eyes. American cartoon characters have exaggerated areas in the middle face below the hairline and the area below the nose, but have smaller foreheads.

Size of Jaw
The average values of R3, LB5, and LB4 shown in Figure 10 demonstrated that there was no significant difference between Japanese cartoon characters and the human face for these aspects. However, the average value of R3, LB5, and LB4 shows that American cartoon characters have 1.25 times larger area between the left and right mandible angles and the chin, 1.1 times wider mandible angle, and 1.4 times longer distance from the nasal floor to the lip line. As we showed above, Japanese cartoon character faces are smaller than the human face but there was no significant difference from the human face.
Data of the area, the length, and the width of the jaw prove that American cartoon characters have larger jaws, whereas Japanese animated characters have smaller jaws, but they are not significantly different from the jaws of the human face.

Sharpness of the Chin
The average values of A5 and A6 shown in figure 11 demonstrated that there was no significant difference between Japanese cartoon characters and the human face. American cartoon characters are 8° larger in the sharpness angle of the chin than the human face, which is a significant difference, and 4.6° smaller in the angle between the chin and the common point at the lower right corner of the picture Figure 10. Comparisons of the area and length of the jaw between the human face and American and Japanese cartoon characters.
As we showed above, Japanese cartoon character faces are smaller than the human face but there was no significant difference from the human face.
Data of the area, the length, and the width of the jaw prove that American cartoon characters have larger jaws, whereas Japanese animated characters have smaller jaws, but they are not significantly different from the jaws of the human face.

Sharpness of the Chin
The average values of A5 and A6 shown in Figure 11 demonstrated that there was no significant difference between Japanese cartoon characters and the human face. American cartoon characters are 8 • larger in the sharpness angle of the chin than the human face, which is a significant difference, and 4.6 • smaller in the angle between the chin and the common point at the lower right corner of the picture. The data above together show that the chins of Japanese cartoon characters are sharper than the human face but notably so, whereas the chins of American cartoon characters are rounder than human faces and Japanese cartoon characters.

Width between Left and Right Mandible Angle
The average values of A7 and A8 shown in figure 12 demonstrated that Japanese cartoon characters exaggerated the angle from the left mandible angle to the chin and to the lower right corner of the picture by 4.6° and reduced the angle from the right mandible angle to the chin and to the lower right corner of the picture by 5° . There was no significant difference between American cartoon characters and the human face. Therefore, Japanese cartoon characters have wider mandibles than human faces and American cartoon characters.

Conclusion
By measuring and comparing the facial features of 100 American and Japanese cartoon characters with human facial features, we found that selecting a length value of a feature from a The data above together show that the chins of Japanese cartoon characters are sharper than the human face but notably so, whereas the chins of American cartoon characters are rounder than human faces and Japanese cartoon characters.

Width between Left and Right Mandible Angle
The average values of A7 and A8 shown in Figure 12 demonstrated that Japanese cartoon characters exaggerated the angle from the left mandible angle to the chin and to the lower right corner of the picture by 4.6 • and reduced the angle from the right mandible angle to the chin and to the lower right corner of the picture by 5 • . There was no significant difference between American cartoon characters and the human face. Therefore, Japanese cartoon characters have wider mandibles than human faces and American cartoon characters. The data above together show that the chins of Japanese cartoon characters are sharper than the human face but notably so, whereas the chins of American cartoon characters are rounder than human faces and Japanese cartoon characters.

Width between Left and Right Mandible Angle
The average values of A7 and A8 shown in figure 12 demonstrated that Japanese cartoon characters exaggerated the angle from the left mandible angle to the chin and to the lower right corner of the picture by 4.6° and reduced the angle from the right mandible angle to the chin and to the lower right corner of the picture by 5° . There was no significant difference between American cartoon characters and the human face. Therefore, Japanese cartoon characters have wider mandibles than human faces and American cartoon characters.

Conclusion
By measuring and comparing the facial features of 100 American and Japanese cartoon characters with human facial features, we found that selecting a length value of a feature from a

Conclusions
By measuring and comparing the facial features of 100 American and Japanese cartoon characters with human facial features, we found that selecting a length value of a feature from a cartoon character which has the smallest standard deviation of all characters, as a common parameter is effective for the calculation of facial features of different cartoon characters.
Compared with the human face, seven main features were exaggerated. Designers always focused on the exaggeration or reduction of eyes, nose, ears, and chin, and considered the position of the ears and mouth. Compared with a human face, these features were exaggerated or reduced by different degrees. In addition, "nose" is the most obvious feature to distinguish the differences between American and Japanese animation characters.
Moreover, the facial features of animated characters were lengthened or shortened in the upper and lower distances and the left and right distances, without breaking the principle of symmetry.
This research provides a reference for the application and research of cartoon character facial design. However, the number of research samples is a limiting factor in this study. In future work, more samples should be collected for data analysis. In addition, new methods should be developed to measure occluded features. The research methods in this paper can be used to analyze the body proportion of cartoon characters.