A Comparative Analysis of Emotion-Detecting AI Systems with Respect to Algorithm Performance and Dataset Diversity

Bryant, De’Aira; Howard, Ayanna M.

doi:10.1145/3306618.3314284

Cited by 69 publications

(6 citation statements)

References 21 publications

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“…At this point let us mention that each task and corresponding database contains ambiguous cases: i) there is generally discrepancy in the perception of the disgust, fear, sadness and (negative) surprise emotions across different people (of different ethnicity, race and age) and across databases; emotional displays and their perception are not universal, i.e., facial expressions are displayed and interpreted differently depending on the cultural background of subjects and annotators [59], [60] ; ii) the exact valence and arousal value for a particular affect is also not consistent among databases; iii) the AU annotation process is hard to do and error prone, creating incosistency among databases (e.g., regarding the dependencies among AUs, such as AU12 -lip corner puller-and AU15 -lip corner depressor-that cannot co-occur as their corresponding muscle groups -Zgomaticus major and Depressor anguli oris, respectively-are unlikely to be simultaneously activated).…”

Section: Results: Generalisation To Unseen Databasesmentioning

confidence: 99%

Distribution Matching for Heterogeneous Multi-Task Learning: a Large-scale Face Study

Kollias,

Sharmanska,

Zafeiriou

2021

Preprint

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Multi-Task Learning (MTL) has emerged as a methodology in which multiple tasks are jointly learned by a shared learning algorithm, such as a deep neural network. MTL is based on the assumption that the tasks under consideration are related; therefore it exploits shared knowledge for improving performance on each individual task. Tasks are generally considered to be homogeneous, i.e., to refer to the same type of problem, e.g., classification. Moreover, MTL is usually based on ground truth annotations with full, or partial overlap across tasks; i.e., for each input sample, there exist annotations for all or most of the tasks. In this work, we deal with heterogeneous MTL, simultaneously addressing detection, classification and regression problems. We explore task-relatedness as a means for co-training, in a weakly-supervised way, tasks that contain little, or even non-overlapping annotations. Task-relatedness is introduced in MTL, either explicitly through prior expert knowledge, or through data-driven studies. We propose a novel distribution matching approach, in which knowledge exchange is enabled between tasks, via matching of their predictions' distributions. Based on this approach, we build FaceBehaviorNet, the first framework for large-scale face analysis, by jointly learning all facial behavior tasks. We develop case studies for: i) continuous affect estimation, facial action unit detection and basic emotion recognition; ii) facial attribute detection and face identification. We illustrate that co-training via task relatedness alleviates negative transfer, i.e., cases in which MT model's performance is, in some task(s), worse than that of a single-task model. Since FaceBehaviorNet learns features that encapsulate all aspects of facial behavior, we conduct zero-and few-shot learning to perform tasks beyond the ones that it has been trained for, such as compound emotion recognition. By conducting a very large experimental study, utilizing 10 databases, we illustrate that our approach outperforms, by large margins, the state-of-the-art in all tasks and in all databases, even in these which have not been used in its training.

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Section: Results: Generalisation To Unseen Databasesmentioning

confidence: 99%

Distribution Matching for Heterogeneous Multi-Task Learning: a Large-scale Face Study

Kollias,

Sharmanska,

Zafeiriou

2021

Preprint

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“…This technology can detect eight emotions based on Ekman’s FACS (anger, contempt, disgust, fear, happiness, neutral, sadness, and surprise) from faces on a given photo and assign a score to the emotional categories for each detected face so that the sum of the eight scores will be one (Kim & Kim, 2018). The analysis of still images consists in finding the face in the image, extracting the relevant features (facial action units, AUs), and finally classifying the image using algorithms trained through machine learning techniques (Bryant & Howard, 2019). The emotion detection is performed after detecting the face.…”

Section: Methodsmentioning

confidence: 99%

“…This field of human-computer interaction and affective computing focus on emotion recognition is a new frontier that could have relevant consequences in health care or education. The algorithm uses facial detection and semantic analysis to interpret mood from photos and videos both static and real time (Deshmukh & Jagtap, 2017). Technology that reveals human feelings could be used to identify students in trouble in a classroom environment, help autistics better interact with others, and encourage better relationships based on empathy and understanding.…”

Section: Research-article20202020mentioning

confidence: 99%

Emotional Expression of #body on Instagram

Malighetti

Sciara

Chirico

et al. 2020

Social Media + Society

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Our aim was to explore emotions in Instagram images marked with hashtags referring to body image–related components using an artificial intelligence–based discrete emotional analysis. A total of 500 Instagram photos marked by specific hashtags related to body image components were analyzed and specific discrete emotions expressed in each picture were detected using the Emotion application program interface API from Microsoft Azure Cognitive Service. Results showed that happiness and neutrality were the most intense and recognizable emotions expressed in all images. Happiness intensity was significantly higher in images with #bodyimage and #bodyconfidence and higher levels of neutral emotion were found in images tagged with #body, #bodyfitness, and #thininspirational. This study integrated a discrete emotional model with the conventional dimensional one, and offered a higher degree of granularity in the analysis of emotions–body link on Instagram through an artificial intelligence technology. Future research should deepen the use of discrete emotions on Instagram and the role of neutrality in body image representation.

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“…Machine vision and natural language processing technology is used with ML to "identify" emotions so that applications can respond to a user in real time. There has been critique of this on several grounds, including: the inability of ML mathematical models to grasp the cultural and contextual specificity of emotional facial expressions (Barrett et al, 2019); the racially biased labeling of data sets used in supervised learning to train AI (Rhue, 2018); the lack of representation of children's data that leads to poor prediction outcomes (Bryant & Howard, 2019); and the ethically dubious use of technology to manipulate or "nudge" people's behavior without their knowledge or consent. Moreover, there are persuasive arguments that the use of biometric technology in EdTech is currently without evidence of efficacy for learning, and that it contravenes children's human rights (McStay, 2019).…”

Section: How Is Ai Used In Education?mentioning

confidence: 99%

Digital Disruption In Teaching And Testing

Wyatt-Smith¹,

Lingard²,

Heck³

2021

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This book provides a significant contribution to the increasing conversation concerning the place of big data in education. Offering a multidisciplinary approach with a diversity of perspectives from international scholars and industry experts, chapter authors engage in both research-and industry-informed discussions and analyses on the place of big data in education, particularly as it pertains to largescale and ongoing assessment practices moving into the digital space. This volume offers an innovative, practical, and international view of the future of current opportunities and challenges in education and the place of assessment in this context.

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A Comparative Analysis of Emotion-Detecting AI Systems with Respect to Algorithm Performance and Dataset Diversity

Cited by 69 publications

References 21 publications

Distribution Matching for Heterogeneous Multi-Task Learning: a Large-scale Face Study

Distribution Matching for Heterogeneous Multi-Task Learning: a Large-scale Face Study

Emotional Expression of #body on Instagram

Digital Disruption In Teaching And Testing

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