BPSO ve SVM'ye Dayalı Yüzde Duygu Tanıma için Derin Özellik Seçimi
Yıl 2023,
Cilt: 26 Sayı: 1, 131 - 142, 27.03.2023
Kenan Donuk
,
Ali Arı
,
Mehmet Fatih Özdemir
,
Davut Hanbay
Öz
Günlük hayatımızda önemli sosyal iletişim aracı olan yüz ifadeleri, insanların ruhsal durumu hakkında önemli bilgiler vermektedir. Bu bilgiyi doğru bir şekilde elde etmek için araştırmalar yapılmaktadır. Bu araştırmaların insan-bilgisayar etkileşimi alanındaki önemi giderek artmaktadır. Nötr, mutluluk, şaşkınlık, üzüntü, öfke, iğrenme, korku gibi evrensel yüz ifadelerinin akıllı sistemler tarafından yüksek doğrulukla tanınması için birçok yöntem kullanılmıştır. Duygu tanıma, ortam ışığı, yaş, ırk, cinsiyet ve yüz pozisyonu gibi faktörler nedeniyle zorlu bir sınıflandırma örneğidir. Bu makalede, yüz görüntülerinden duygu tanıma için 3 aşamalı bir sistem önerilmiştir. İlk aşamada, tasarlanan CNN tabanlı ağ Fer+ veri seti ile eğitiliyor. İkinci aşamada, eğitilmiş olan CNN ağının tam bağlı katmanındaki özellik vektörüne özellik seçimi için İkili Parçacık Sürü Optimizasyon algoritması uygulanıyor. Seçilen özellikler Destek Vektör Makinesi tarafından sınıflandırılır. Önerilen sistemin performansı Fer+ veri seti ile test edilmiştir. Test sonucunda %85,74 doğruluk ölçülmüştür. Elde edilen sonuçlar İkili Parçacık Sürü Optimizasyon algoritması ve Destek Vektör Makinesi birleşiminin FER+ veri setinin sınıflandırma doğruluğuna ve hızına katkısını ortaya koymuştur.
Destekleyen Kurum
İnönü Üniversitesi Bilimsel Araştırma Projeleri Koordinasyon Birimi (BAP)
Proje Numarası
FDK-2020-2110
Teşekkür
Bu çalışma İnönü Üniversitesi Bilimsel Araştırma Projeleri Koordinasyon Birimi (BAP) tarafından FDK-2020-2110 kodlu proje ile desteklenmiştir.
Kaynakça
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Deep Feature Selection for Facial Emotion Recognition Based on BPSO and SVM
Yıl 2023,
Cilt: 26 Sayı: 1, 131 - 142, 27.03.2023
Kenan Donuk
,
Ali Arı
,
Mehmet Fatih Özdemir
,
Davut Hanbay
Öz
Facial expressions, which are important social communication tools in our daily life, provide important information about the mental state of people. Research is being done to obtain this information accurately. The importance of these researchs in the field of human-computer interaction is increasing. Many methods have been used for the recognition of universal facial expressions such as neutral, happiness, surprise, sadness, anger, disgust, and fear by intelligent systems with high accuracy. Emotion recognition is an example of difficult classification due to factors such as ambient light, age, race, gender, and facial position. In this article, a 3-stage system is proposed for emotion detection from facial images. In the first stage, the CNN-based network is trained with the Fer+ dataset. The Binary Particle Swarm Optimization algorithm is applied for feature selection to the feature vector in the fully connected layer of the CNN network trained in the second stage. Selected features are classified by Support Vector Machine. The performance of the proposed system has been tested with the Fer+ dataset. As a result of the test, 85.74% accuracy was measured. The results show that the combination of BPSO and SVM contributes to the classification accuracy and speed of the FER+ dataset.
Proje Numarası
FDK-2020-2110
Kaynakça
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- [6] Praditsangthong R., Slakkham B. and Bhattarakosol P., “A fear detection method based on palpebral fissure”, Journal of King Saud University - Computer and Information Sciences, (2019).
- [7] Harms M. B., Martin A. and Wallace G. L., “Facial emotion recognition in autism spectrum disorders: A review of behavioral and neuroimaging studies”, In Neuropsychology Review, 20(3): 290-322, (2010).
- [8] Ekman P. and Friesen W., “Facial action coding system: a technique for the measurement of facial movement”, (1978).
- [9] Fan Y., Lam J. C. K. and Li V. O. K., “Demographic effects on facial emotion expression: an interdisciplinary investigation of the facial action units of happiness”, Scientific Reports, 11(1): 5214, (2021).
- [10] Ma J., Li X., Ren Y., Yang R. and Zhao Q., “Landmark-Based Facial Feature Construction and Action Unit Intensity Prediction”, Mathematical Problems in Engineering, (2021).
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- [13] Nadeeshani M., Jayaweera A. and Samarasinghe P., “Facial emotion prediction through action units and deep learning”, ICAC 2020 - 2nd International Conference on Advancements in Computing, Proceedings, 293-298, (2020).
- [14] Sari M., Moussaoui A. and Hadid A., “Automated Facial Expression Recognition Using Deep Learning Techniques: An Overview”, In International Journal of Informatics and Applied Mathematics, 3(1): 39-53, (2020).
- [15] Murugappan M. and Mutawa A., “Facial geometric feature extraction based emotional expression classification using machine learning algorithms”, PloS One, 16(2), (2021).
- [16] S.Bavkar S., S. Rangole J. and U. Deshmukh V., “Geometric Approach for Human Emotion Recognition using Facial Expression”, International Journal of Computer Applications, 118(14): 17-22, (2015).
- [17] Ghimire D. and Lee J., “Geometric feature-based facial expression recognition in image sequences using multi-class AdaBoost and support vector machines”, Sensors (Switzerland), 13(6): 7714-7734, (2013).
- [18] Perez-Gomez V., Rios-Figueroa H. V., Rechy-Ramirez E. J., Mezura-Montes E. and Marin-Hernandez A., “Feature selection on 2d and 3d geometric features to improve facial expression recognition”, Sensors (Switzerland), 20(17), 1–20, (2020).
- [19] Ounachad K., Oualla M. and Sadiq A., “Geometric feature based facial emotion recognition”, International Journal of Advanced Trends in Computer Science and Engineering, 9(3):3417-3425, (2020).
[20] Liu X., Cheng X. and Lee K., “GA-SVM based Facial Emotion Recognition using Facial Geometric Features”, IEEE Sensors Journal, 1-1, (2020).
- [21] Chouhayebi H., Riffi J., Mahraz M. A., Yahyaouy A., Tairi H. and Alioua N., “Facial expression recognition based on geometric features”, 2020 International Conference on Intelligent Systems and Computer Vision, ISCV 2020, 1-6, (2020).
- [22] Ravi R., Yadhukrishna S. V. and Prithviraj R., “A Face Expression Recognition Using CNN LBP”, Proceedings of the 4th International Conference on Computing Methodologies and Communication, ICCMC 2020, 684–689, (2020).
- [23] Niu B., Gao Z. and Guo B., “Facial Expression Recognition with LBP and ORB Features”, Computational Intelligence and Neuroscience, (2021).
- [24] Lakshmi D. and Ponnusamy R., “Facial emotion recognition using modified HOG and LBP features with deep stacked autoencoders”, Microprocessors and Microsystems, 82: 103834, (2021).
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