Chengfu Huo scite author profile

Chengfu Huo

5Publications

68Citation Statements Received

17Citation Statements Given

How they've been cited

133

How they cite others

Affiliations

Intelligent Health (United Kingdom), Alibaba Group (China), University of Science and Technology of China

Publications

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Deep Match to Rank Model for Personalized Click-Through Rate Prediction

Lyu

Dong

Huo

et al. 2020

AAAI

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Click-through rate (CTR) prediction is a core task in the field of recommender system and many other applications. For CTR prediction model, personalization is the key to improve the performance and enhance the user experience. Recently, several models are proposed to extract user interest from user behavior data which reflects user's personalized preference implicitly. However, existing works in the field of CTR prediction mainly focus on user representation and pay less attention on representing the relevance between user and item, which directly measures the intensity of user's preference on target item. Motivated by this, we propose a novel model named Deep Match to Rank (DMR) which combines the thought of collaborative filtering in matching methods for the ranking task in CTR prediction. In DMR, we design User-to-Item Network and Item-to-Item Network to represent the relevance in two forms. In User-to-Item Network, we represent the relevance between user and item by inner product of the corresponding representation in the embedding space. Meanwhile, an auxiliary match network is presented to supervise the training and push larger inner product to represent higher relevance. In Item-to-Item Network, we first calculate the item-to-item similarities between user interacted items and target item by attention mechanism, and then sum up the similarities to obtain another form of user-to-item relevance. We conduct extensive experiments on both public and industrial datasets to validate the effectiveness of our model, which outperforms the state-of-art models significantly.

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Transformer-Based Language Model Fine-Tuning Methods for COVID-19 Fake News Detection

Chen

Gao

et al. 2021

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With the pandemic of COVID-19, relevant fake news is spreading all over the sky throughout the social media. Believing in them without discrimination can cause great trouble to people's life. However, universal language models may perform weakly in these fake news detection for lack of large-scale annotated data and sufficient semantic understanding of domain-specific knowledge. While the model trained on corresponding corpora is also mediocre for insufficient learning. In this paper, we propose a novel transformer-based language model fine-tuning approach for these fake news detection. First, the token vocabulary of individual model is expanded for the actual semantics of professional phrases. Second, we adapt the heated-up softmax loss to distinguish the hard-mining samples, which are common for fake news because of the disambiguation of short text. Then, we involve adversarial training to improve the model's robustness. Last, the predicted features extracted by universal language model RoBERTa and domain-specific model CT-BERT are fused by one multiple layer perception to integrate fine-grained and high-level specific representations. Quantitative experimental results evaluated on existing COVID-19 fake news dataset show its superior performances compared to the state-of-the-art methods among various evaluation metrics. Furthermore, the best weighted average F1 score achieves 99.02%.

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Automatic Generation of Pattern-controlled Product Description in E-commerce

Zhang

Huo

et al. 2019

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Compression technique for compressed sensing hyperspectral images

Huo

Zhang

Yin

2011

International Journal of Remote Sensing

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Hyperspectral data compression using sparse representation

Huo

Zhang

Yin

et al. 2012

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Due to all bands of hyperspectral data have the same imaging area, it is reasonable to believe that the dictionary can sparse represent one band may also represent the other bands sparsely. Based on this property, this paper presents a new compression frame for hyperspectral data using sparse representation, and a simplified algorithm under this frame is also proposed. The basic idea of the proposed algorithm is to sparse coding bands using the dictionary learned from one training band, and its innovation is that patches having the same spatial location of all bands are restricted to be represented using the same atoms. Experimental results based on OMP and K-SVD are provided, which reveal that this proposal has better performance than wavelet based compression algorithm at low bit rates.

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Chengfu Huo

Deep Match to Rank Model for Personalized Click-Through Rate Prediction

Transformer-Based Language Model Fine-Tuning Methods for COVID-19 Fake News Detection

Automatic Generation of Pattern-controlled Product Description in E-commerce

Compression technique for compressed sensing hyperspectral images

Hyperspectral data compression using sparse representation

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