Developing crossmodal expression recognition based on a deep neural model

Barros, Pablo; Wermter, Stefan

doi:10.1177/1059712316664017

Cited by 63 publications

(60 citation statements)

References 51 publications

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“…[5]), including with reference to decoding tactile (gestural) inputs [12]. Furthermore, Hertenstein et al [25] found a lower mean percentage correct classification/decoding for the Rejection (64%) and Attachment (59%) emotions identified above, than we did in our study.…”

Section: Decoding Emotionscontrasting

confidence: 55%

“…The reason for this was that the instructions vocalized by the experimenters did not request time-limited responding from participants regarding the conveyed emotions. Time-limitation was considered 5 We winsorized 3 values (outliers) for each of the 16 conditions and additionally one extra of the gender-emotion conditions with highest variance female-sadness, male-sadness, female-love, male-love, i.e. 52 values out of 512 data points in total.…”

Section: Durationmentioning

confidence: 99%

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Affective Touch in Human–Robot Interaction: Conveying Emotion to the Nao Robot

Andreasson

Alenljung

Billing

et al. 2017

Int J of Soc Robotics

111

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Affective touch has a fundamental role in human development, social bonding, and for providing emotional support in interpersonal relationships. We present, what is to our knowledge, the first HRI study of tactile conveyance of both positive and negative emotions (affective touch) on the Nao robot, and based on an experimental set-up from a study of human-human tactile communication. In the present work, participants conveyed eight emotions to a small humanoid robot via touch. We found that female participants conveyed emotions for a longer time, using more varied interaction and touching more regions on the robot's body, compared to male participants. Several differences between emotions were found such that emotions could be classified by the valence of the emotion conveyed, by combining touch amount and duration. Overall, these results show high agreement with those reported for human-human affective tactile communication and could also have impact on the design and placement of tactile sensors on humanoid robots.

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Section: Decoding Emotionscontrasting

confidence: 55%

Section: Durationmentioning

confidence: 99%

Affective Touch in Human–Robot Interaction: Conveying Emotion to the Nao Robot

Andreasson

Alenljung

Billing

et al. 2017

Int J of Soc Robotics

111

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“…Studies have typically shown that multiple dimensions of expression facilitate classification analyses [39,44]. We have demonstrated the potential for tactile interaction to provide much information regarding emotional conveyance; nevertheless, emotional interaction in naturalistic contexts is almost always of a context-specific (e.g., dependent on the type of task) and multi-sensory nature.…”

mentioning

confidence: 99%

“…This is a key selling point of adopting textile wearables for use in affective-based human-robot tactile interaction. Studies indicate that emotion decoding is more accurate and more typical, when multi-modal sensors that pick up specific emotional and gestural information are added ( [39], also see [44]). Such multi-modal encoding and decoding allows for contextual nuance in the affective interaction.…”

mentioning

confidence: 99%

Designing for a Wearable Affective Interface for the NAO Robot: A Study of Emotion Conveyance by Touch

Lowe

Andreasson

Alenljung

et al. 2018

MTI

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Abstract:We here present results and analysis from a study of affective tactile communication between human and humanoid robot (the NAO robot). In the present work, participants conveyed eight emotions to the NAO via touch. In this study, we sought to understand the potential for using a wearable affective (tactile) interface, or WAffI. The aims of our study were to address the following: (i) how emotions and affective states can be conveyed (encoded) to such a humanoid robot, (ii) what are the effects of dressing the NAO in the WAffI on emotion conveyance and (iii) what is the potential for decoding emotion and affective states. We found that subjects conveyed touch for longer duration and over more locations on the robot when the NAO was dressed with WAffI than when it was not. Our analysis illuminates ways by which affective valence, and separate emotions, might be decoded by a humanoid robot according to the different features of touch: intensity, duration, location, type. Finally, we discuss the types of sensors and their distribution as they may be embedded within the WAffI and that would likely benefit Human-NAO (and Human-Humanoid) interaction along the affective tactile dimension.

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“…Compared with RNN, CNN is more suitable for computer vision applications; hence, its derivative C3D [107], which uses 3D convolutional kernels with shared weights along the time axis instead of the traditional 2D kernels, has been widely used for dynamic-based FER (e.g., [83], [108], [189], [197], [198]) to capture the spatio-temporal features. Based on C3D, many derived structures have been designed for FER.…”

Section: Rnn and C3dmentioning

confidence: 99%

Deep Facial Expression Recognition: A Survey

Deng

2022

IEEE Trans. Affective Comput.

1,082

593

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With the transition of facial expression recognition (FER) from laboratory-controlled to challenging in-the-wild conditions and the recent success of deep learning techniques in various fields, deep neural networks have increasingly been leveraged to learn discriminative representations for automatic FER. Recent deep FER systems generally focus on two important issues: overfitting caused by a lack of sufficient training data and expression-unrelated variations, such as illumination, head pose and identity bias. In this paper, we provide a comprehensive survey on deep FER, including datasets and algorithms that provide insights into these intrinsic problems. First, we introduce the available datasets that are widely used in the literature and provide accepted data selection and evaluation principles for these datasets. We then describe the standard pipeline of a deep FER system with the related background knowledge and suggestions of applicable implementations for each stage. For the state of the art in deep FER, we review existing novel deep neural networks and related training strategies that are designed for FER based on both static images and dynamic image sequences, and discuss their advantages and limitations. Competitive performances on widely used benchmarks are also summarized in this section. We then extend our survey to additional related issues and application scenarios. Finally, we review the remaining challenges and corresponding opportunities in this field as well as future directions for the design of robust deep FER systems.

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Developing crossmodal expression recognition based on a deep neural model

Cited by 63 publications

References 51 publications

Affective Touch in Human–Robot Interaction: Conveying Emotion to the Nao Robot

Affective Touch in Human–Robot Interaction: Conveying Emotion to the Nao Robot

Designing for a Wearable Affective Interface for the NAO Robot: A Study of Emotion Conveyance by Touch

Deep Facial Expression Recognition: A Survey

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