Nihar Bendre scite author profile

A great number of computer vision publications have focused on distinguishing between human action recognition and classification rather than the intensity of actions performed. Indexing the intensity which determines the performance of human actions is a challenging task due to the uncertainty and information deficiency that exists in the video inputs. To remedy this uncertainty, in this paper we coupled fuzzy logic rules with the neural-based action recognition model to rate the intensity of a human action as intense or mild. In our approach, we used a Spatio-Temporal LSTM to generate the weights of the fuzzy-logic model, and then demonstrate through experiments that indexing of the action intensity is possible. We analyzed the integrated model by applying it to videos of human actions with different action intensities and were able to achieve an accuracy of 89.16% on our intensity indexing generated dataset. The integrated model demonstrates the ability of a neuro-fuzzy inference module to effectively estimate the intensity index of human actions.

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Generalized Zero-Shot Learning Using Multimodal Variational Auto-Encoder With Semantic Concepts

Bendre

Desai

Najafirad

2021

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With the ever-increasing amount of data, the central challenge in multimodal learning involves limitations of labelled samples For the task of classification, techniques such as meta-learning, zero-shot learning, and few-shot learning showcase the ability to learn information about novel classes based on prior knowledge . Recent techniques try to learn a cross-modal mapping between the semantic space and the image space. However, they tend to ignore the local and global semantic knowledge. To overcome this problem, we propose a Multimodal Variational Auto-Encoder (M-VAE) which can learn the shared latent space of image features and the semantic space. In our approach we concatenate multimodal data to a single embedding before passing it to the VAE for learning the latent space. We propose the use of a multi-modal loss during the reconstruction of the feature embedding through the decoder. Our approach is capable to correlating modalities and exploit the local and global semantic knowledge for novel sample predictions. Our experimental results using a MLP classifier on four benchmark datasets show that our proposed model outperforms the current state-of-the-art approaches for generalized zero-shot learning.

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Show Why the Answer is Correct! Towards Explainable AI using Compositional Temporal Attention

Bendre¹,

Desai²,

Najafirad

2021

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Visual Question Answering (VQA) models have achieved significant success in recent times. Despite the success of VQA models, they are mostly black-box models providing no reasoning about the predicted answer, thus raising questions for their applicability in safety-critical such as autonomous systems and cyber-security. Current state of the art fail to better complex questions and thus are unable to exploit compositionality. To minimize the black-box effect of these models and also to make them better exploit compositionality, we propose a Dynamic Neural Network (DMN), which can understand a particular question and then dynamically assemble various relatively shallow deep learning modules from a pool of modules to form a network. We incorporate compositional temporal attention to these deep learning based modules to increase compositionality exploitation. This results in achieving better understanding of complex questions and also provides reasoning as to why the module predicts a particular answer. Experimental analysis on the two benchmark datasets, VQA2.0 and CLEVR, depicts that our model outperforms the previous approaches for Visual Question Answering task as well as provides better reasoning, thus making it reliable for mission critical applications like safety and security.

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Generalized Zero-Shot Learning using Multimodal Variational Auto-Encoder with Semantic Concepts

Bendre¹,

Desai²,

Najafirad³

2021

Preprint

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Natural Disaster Analytics using High Resolution Satellite Images

Bendre

Zand

Bhattarai

et al. 2022

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Nihar Bendre

Human Action Performance Using Deep Neuro-Fuzzy Recurrent Attention Model

Generalized Zero-Shot Learning Using Multimodal Variational Auto-Encoder With Semantic Concepts

Show Why the Answer is Correct! Towards Explainable AI using Compositional Temporal Attention

Generalized Zero-Shot Learning using Multimodal Variational Auto-Encoder with Semantic Concepts

Natural Disaster Analytics using High Resolution Satellite Images

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