Dr. Na Yi | Deep Metric Learning | Best Researcher Award

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Dr. Na Yi | Deep Metric Learning | Best Researcher Award

Doctorate at Heilongjiang University of Science and Technology, China

Profiles

Scopus

Orcid

Academic Background

Dr. Na Yi, born in June 1997 in Acheng, Harbin, is an Associate Professor and a committed member of the Communist Party of China. With a strong academic foundation in Electrical Engineering and Automation, she has quickly risen as a prominent figure in the field of Petroleum and Natural Gas Engineering.

Education

Dr. Na Yi graduated with a degree in Electrical Engineering and Automation from Northeast Petroleum University in 2019. She was subsequently recommended for a doctoral program in Petroleum and Natural Gas Engineering, during which she also studied at Southeast University, earning her doctorate in 2024.

Professional Experience

Throughout her career, Dr. Na Yi has published over 20 research papers in esteemed journals, with 10 SCI-indexed and 5 EI-indexed papers, including highly cited and hot papers. She holds 6 national patents and has participated in 5 significant scientific research projects. Her achievements have earned her more than 10 national and provincial awards.

Research Interests

Dr. Na Yi’s research interests lie in Petroleum Engineering, with a focus on sustainable energy, power systems, and technological innovation. She is an active reviewer for multiple international and Chinese academic journals and has been invited to present her research at several international and domestic conferences.

 Publications

A multi-stage low-cost false data injection attack method for power CPS

  • Authors: Yi, N., Xu, J., Chen, Y., Pan, F.
  • Journal: Zhejiang Electric Power
  • Year: 2023
A New Distributed Power Supply for Distribution Network Considering SOP Access
  • Authors: Peng, C., Xu, J., Zhao, S., Yi, N.
  • Year: 2023
Multi-stage coordinated cyber-physical topology attack method based on deep reinforcement learning
  • Authors: Yi, N., Xu, J., Chen, Y., Sun, D.
  • Journal: Electric Power Engineering Technology
  • Year: 2023
A multi-stage game model for the false data injection attack from attacker’s perspective
  • Authors: Yi, N., Wang, Q., Yan, L., Tang, Y., Xu, J.
  • Journal: Sustainable Energy, Grids and Networks
  • Year: 2021
Insulator Self-Explosion Defect Detection Based on Hierarchical Multi-Task Deep Learning
  • Authors: Xu, J., Huang, L., Yan, L., Yi, N.
  • Journal: Diangong Jishu Xuebao/Transactions of China Electrotechnical Society
  • Year: 2021

Deep Metric Learning

Posted on by ScienceFather

Introduction of Deep Metric Learning

Introduction: Deep Metric Learning is a specialized field within machine learning and computer vision that focuses on training deep neural networks to learn similarity metrics between data points. It aims to discover meaningful representations of data that enable the computation of distances or similarities between samples, which can be useful in various applications, such as image retrieval, face recognition, and recommendation systems. Deep Metric Learning has gained significant attention due to its potential to improve the performance of similarity-based tasks.

Subtopics in Deep Metric Learning:

  1. Siamese Networks: Siamese networks are a foundational architecture in deep metric learning. Researchers in this subfield explore variations and improvements to Siamese networks, which consist of two identical subnetworks that learn to minimize the distance between similar samples and maximize the distance between dissimilar ones.
  2. Triplet Networks: Triplet networks are designed to learn embeddings where the distance between anchor-positive pairs is minimized and the distance between anchor-negative pairs is maximized. Research focuses on triplet loss variations and effective sampling strategies to improve training stability and convergence.
  3. Margin-Based Losses: Margin-based loss functions, like contrastive loss and triplet margin loss, play a key role in deep metric learning. Researchers work on designing and adapting margin-based loss functions to different tasks and datasets to enhance the discriminative power of learned embeddings.
  4. Hard and Semi-Hard Negative Mining: Mining hard or semi-hard negative samples during training is critical for the success of deep metric learning. This subtopic explores strategies to efficiently select challenging negative samples that help improve model performance.
  5. Multi-Modal Metric Learning: Extending deep metric learning to handle data from multiple modalities, such as text and images, to enable cross-modal similarity calculations, which have applications in recommendation systems and content-based retrieval.

Deep Metric Learning research is essential for creating powerful models capable of understanding and leveraging the inherent similarities and differences in data. These subtopics reflect the ongoing efforts to refine techniques and develop robust deep metric learning models for diverse real-world applications.