Presentation is loading. Please wait.

Presentation is loading. Please wait.

Estimation of Skin Color Range Using Achromatic Features

Published byYanti Budiono Modified over 5 years ago

Similar presentations

Presentation on theme: "Estimation of Skin Color Range Using Achromatic Features"— Presentation transcript:

1 Estimation of Skin Color Range Using Achromatic Features
Wen-Hung Liao Department of Computer Science National Chengchi University November 27, 2008

2 Outline Motivation and Related Work Color Spaces
Fixed vs. Dynamic Range Approach Experimental Results Skin color segmentation Hand & finger detection Conclusion

3 Background Previous claims: skin color is restricted to a “fixed” range in certain color coordinates: Sobottka & Pitas: Hue:[0,50º], Saturation:[0.23,0.68] Chai & Ngan: Cb:[77,127], Cr[137,177] Kawato & Ohya: Decision boundary in normalized RGB space

4 Decision Boundary in Normalized RGB Space

5 Sobottka & Pitas: Fixed Hue + Saturation

6 Chai & Ngan: Fixed Cb,Cr

7 Kawato & Ohya

8 Comparative Analysis From: Phung et al, Skin segmentation using color pixel classification: analysis and comparison, IEEE Transactions on PAMI, 2005.

9 Observation It is true that the skin color lies in a small range, yet this range tends to shift under different lighting conditions. Question: Is it possible to dynamically adjust the range of skin color to enhance the robustness of color-based segmentation?

10 The Proposed Solution Use achromatic information (face detection) to help determine the range. Limitation: Face must be present and detected. Suitable for vision-based human computer interface.

11 Five Classes of Color Space
Representative color space Basic color spaces RGB、normalized RGB Perceptual color spaces HSV、HIS Orthogonal color spaces YCbCr、YUV Perceptually uniform color spaces CIELab、CIELuv Other color spaces Mixture

12 Color Spaces Investigated
domains RGB Red、Green、Blue HSV Hue、Saturation、Value CIELab L、a、b YCbCr Y、Cb、Cr CIELuv L、u、v * Dynamically set the threshold in Hue domain

13 Determining the Threshold (I)
Step 1: detecting and locating the face Step 2: mark the cheek area X = X0 +(W0 /5) Y = Y0 +(H0 /2) width = W0 /5 height = H0 /5 Step 3: obtain the hue distribution of the marked area. W0 (X0, Y0) H0

14 Determining the Threshold (II)
Step 4: assume that the histogram is peaked at A: search to the left and right of A until Local minimum <A/10 is uncovered A non-zero global minimum is found 255

15 Face Detection using DSE
Directional Sobel Edges

16 Experiment: Skin Color Segmentation
Compare the performance of 5 different methods: Dynamic threshold Fixed threshold – fixed Hue Kawato & Ohya – fixed Normalized RGB Sobottka & Pitas – fixed Hue & Saturation Chai & Ngan – fixed Cb & Cr Material Images captured by a low-cost webcam under different lighting conditions. A total of 400 images (taken indoor) are manually segmented and labeled.

17 Skin Color Segmentation: Experimental Results
false positive false negative true negative true positive Dynamic Threshold 0.0736 0.1706 0.9264 0.8294 fixed Hue 0.2125 0.3361 0.7875 0.6639 fixed Normalized RGB 0.0504 0.5303 0.9496 0.4697 fixed Hue & Sat 0.0588 0.5747 0.9412 0.4253 fixed Cr & Cb 0.0857 0.2996 0.9143 0.7004

18 Best and Worst Case Performance
best TP worst TP Dynamic Threshold 0.9947 0.3494 fixed Hue 0.9977 0.0733 fixed Normalized RGB 0.9055 0.0002 fixed Hue & Sat 0.8891 0.0005 fixed Cr & Cb 0.9447 0.2234

19 Recall and Precision Recall = TP/(TP+FP) Precision = TP/(TP+FN)

20 Speed-up the Process 1. Detecting Face (After K frames)
2. Record color distribution of cheek area 3. Tracking face 4. Local search 5. Update color distribution

21 Performance Improvement

22 Experiment: Hand Detection
Color-based hand segmentation No post-processing Does not involve statistical modeling and classifier

23 Plamar vs. Dorsal Side Hue histogram Hue histogram

24 Hand Detection: Experimental Results
Dorsal side Dorsal side (fingers) Plamar side Plamar side (fingers) Accuracy 92.65% 94.26% 90.78% 95.01% 24

25 Fingertip Detection 150 images # of fingers detected Dynamic threshold
Fixed Threshold 5 108 72% 17 11% 4 21 14% 22 15% 3 10 7% 23 2 3% 20 13% 1 1% 48 33%

26 Conclusion Perform comparative evaluation of several color-based segmentation methods. Propose and implement a dynamic range estimation algorithm using achromatic features. Superior performance in terms of skin-color segmentation, hand and finger detection. Suitable for vision-based HCI.

27 Thank you Q & A

28 Experimental Result Dynamic Threshold worst TP

29 Experimental Result Fixed Hue worst TP 29

30 Experimental Result Fixed Normalized RGB worst TP 30

31 Experiment Result Fixed Hue & Saturation worst TP 31

32 Experiment Result Fixed Cb & Cr worst TP 32

33 Recall = TP/(TP+FP) Precision = TP/(TP+FN)

Download ppt "Estimation of Skin Color Range Using Achromatic Features"

Similar presentations

Road-Sign Detection and Recognition Based on Support Vector Machines Saturnino, Sergio et al. Yunjia Man ECG 782 Dr. Brendan.

Road-Sign Detection and Recognition Based on Support Vector Machines Saturnino, Sergio et al. Yunjia Man ECG 782 Dr. Brendan.
Technische Universität München Face Model Fitting based on Machine Learning from Multi-band Images of Facial Components Institute for Informatics Technische.

Technische Universität München Face Model Fitting based on Machine Learning from Multi-band Images of Facial Components Institute for Informatics Technische.
Evaluating Color Descriptors for Object and Scene Recognition Koen E.A. van de Sande, Student Member, IEEE, Theo Gevers, Member, IEEE, and Cees G.M. Snoek,

Evaluating Color Descriptors for Object and Scene Recognition Koen E.A. van de Sande, Student Member, IEEE, Theo Gevers, Member, IEEE, and Cees G.M. Snoek,
Change Detection C. Stauffer and W.E.L. Grimson, “Learning patterns of activity using real time tracking,” IEEE Trans. On PAMI, 22(8):747-757, Aug 2000.

Change Detection C. Stauffer and W.E.L. Grimson, “Learning patterns of activity using real time tracking,” IEEE Trans. On PAMI, 22(8): , Aug 2000.
Rapid Object Detection using a Boosted Cascade of Simple Features Paul Viola, Michael Jones Conference on Computer Vision and Pattern Recognition 2001.

Rapid Object Detection using a Boosted Cascade of Simple Features Paul Viola, Michael Jones Conference on Computer Vision and Pattern Recognition 2001.
Rear Lights Vehicle Detection for Collision Avoidance Evangelos Skodras George Siogkas Evangelos Dermatas Nikolaos Fakotakis Electrical & Computer Engineering.

Rear Lights Vehicle Detection for Collision Avoidance Evangelos Skodras George Siogkas Evangelos Dermatas Nikolaos Fakotakis Electrical & Computer Engineering.
Wen-Hung Liao Department of Computer Science National Chengchi University November 27, 2008 Estimation of Skin Color Range Using Achromatic Features.

Wen-Hung Liao Department of Computer Science National Chengchi University November 27, 2008 Estimation of Skin Color Range Using Achromatic Features.
VisHap: Guangqi Ye, Jason J. Corso, Gregory D. Hager, Allison M. Okamura Presented By: Adelle C. Knight Augmented Reality Combining Haptics and Vision.

VisHap: Guangqi Ye, Jason J. Corso, Gregory D. Hager, Allison M. Okamura Presented By: Adelle C. Knight Augmented Reality Combining Haptics and Vision.
Image Segmentation Image segmentation (segmentace obrazu) –division or separation of the image into segments (connected regions) of similar properties.

Image Segmentation Image segmentation (segmentace obrazu) –division or separation of the image into segments (connected regions) of similar properties.
Color spaces CIE - RGB space. HSV - space. CIE - XYZ space.

Color spaces CIE - RGB space. HSV - space. CIE - XYZ space.
F ACE TRACKING EE 7700 Name: Jing Chen Shaoming Chen.

F ACE TRACKING EE 7700 Name: Jing Chen Shaoming Chen.
Facial feature localization Presented by: Harvest Jang Spring 2002.

Facial feature localization Presented by: Harvest Jang Spring 2002.
Hue-Grayscale Collaborating Edge Detection & Edge Color Distribution Space Jiqiang Song March 6 th, 2002.

Hue-Grayscale Collaborating Edge Detection & Edge Color Distribution Space Jiqiang Song March 6 th, 2002.
Modeling Pixel Process with Scale Invariant Local Patterns for Background Subtraction in Complex Scenes (CVPR’10) Shengcai Liao, Guoying Zhao, Vili Kellokumpu,

Modeling Pixel Process with Scale Invariant Local Patterns for Background Subtraction in Complex Scenes (CVPR’10) Shengcai Liao, Guoying Zhao, Vili Kellokumpu,
HCI Final Project Robust Real Time Face Detection Paul Viola, Michael Jones, Robust Real-Time Face Detetion, International Journal of Computer Vision,

HCI Final Project Robust Real Time Face Detection Paul Viola, Michael Jones, Robust Real-Time Face Detetion, International Journal of Computer Vision,
1 Learning to Detect Objects in Images via a Sparse, Part-Based Representation S. Agarwal, A. Awan and D. Roth IEEE Transactions on Pattern Analysis and.

1 Learning to Detect Objects in Images via a Sparse, Part-Based Representation S. Agarwal, A. Awan and D. Roth IEEE Transactions on Pattern Analysis and.
1 Color Segmentation: Color Spaces and Illumination Mohan Sridharan University of Birmingham

1 Color Segmentation: Color Spaces and Illumination Mohan Sridharan University of Birmingham
Robust Object Segmentation Using Adaptive Thresholding Xiaxi Huang and Nikolaos V. Boulgouris International Conference on Image Processing 2007.

Robust Object Segmentation Using Adaptive Thresholding Xiaxi Huang and Nikolaos V. Boulgouris International Conference on Image Processing 2007.
Face Detection: a Survey Speaker: Mine-Quan Jing National Chiao Tung University.

Face Detection: a Survey Speaker: Mine-Quan Jing National Chiao Tung University.
Multiple Human Objects Tracking in Crowded Scenes Yao-Te Tsai, Huang-Chia Shih, and Chung-Lin Huang Dept. of EE, NTHU International Conference on Pattern.

Multiple Human Objects Tracking in Crowded Scenes Yao-Te Tsai, Huang-Chia Shih, and Chung-Lin Huang Dept. of EE, NTHU International Conference on Pattern.

Similar presentations

Ads by Google