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相关概念视频

Differential Relays01:20

Differential Relays

113
Differential relays are used to protect generators, buses, and transformers by comparing electrical quantities at different points. When a fault occurs, the difference in current between the two points triggers the relay to operate, opening the circuit breaker. Under normal conditions, the current entering (i1) and leaving (i2) a generator are equal. When a fault occurs, however, these currents become unequal, and the difference current flows in the relay operating coil, causing the relay to...
113
Directional Relays01:25

Directional Relays

93
Directional relays, essential for managing unidirectional fault currents, enhance the safety and efficiency of power systems. On power lines equipped with directional relays, faults downstream (to the right) of the current transformer typically cause the fault current to lag the bus voltage by approximately 90 degrees, known as the forward direction. In contrast, upstream (left-side) faults may result in the fault current leading the bus voltage by nearly 90 degrees, termed the reverse...
93
Pilot and Numeric Relaying01:21

Pilot and Numeric Relaying

82
Pilot relaying is a type of differential protection used in power systems. It compares electrical quantities at the terminals of equipment via a communication channel instead of direct relay interconnection. This method is essential for transmission lines where the terminals are far apart, typically up to 80 km for lines with 69 to 115 kV ratings. Four types of communication channels are used for pilot relaying:
82
Line Protection with Impedance Relays01:27

Line Protection with Impedance Relays

67
Coordinating time-delay overcurrent relays in complex radial systems and directional overcurrent relays in multi-source transmission loops can be challenging. Impedance relays address these issues by responding to the voltage-to-current ratio, specifically measuring the apparent impedance of a line. These relays become more sensitive during faults as current increases and voltage decreases, thereby reducing the apparent impedance.
Under normal conditions, low load currents keep the measured...
67
Overcurrent Relays01:26

Overcurrent Relays

70
Overcurrent relays, crucial for circuit protection, are connected to the secondary current of a current transformer. There are two primary types of overcurrent relays: instantaneous and time-delay.
Instantaneous overcurrent relays activate immediately when the input current exceeds a predetermined value, known as the pickup current, instantly energizing the circuit breaker trip coil. This rapid response is vital for addressing severe faults quickly.
Time-delay overcurrent relays, on the other...
70
Reclosers and Fuses01:26

Reclosers and Fuses

87
Automatic circuit reclosers enhance the protection of distribution circuits by interrupting and auto-reclosing an AC circuit according to a preset sequence. They effectively manage temporary faults on overhead distribution lines, often caused by tree limbs or wildlife, by briefly disrupting service to improve overall reliability. However, contact with reclosers or energized broken conductors on the ground can pose serious hazards.
A comprehensive protection scheme for radial distribution...
87

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相关实验视频

Updated: Jun 9, 2025

Design, Instrumentation and Usage Protocols for Distributed In Situ Thermal Hot Spots Monitoring in Electric Coils using FBG Sensor Multiplexing
10:52

Design, Instrumentation and Usage Protocols for Distributed In Situ Thermal Hot Spots Monitoring in Electric Coils using FBG Sensor Multiplexing

Published on: March 8, 2020

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在混合 DF/AF 继电系统中的秘密通信.

Jihwan Moon1

  • 1Department of Mobile Convergence Engineering, Hanbat National University, Daejeon 34158, Republic of Korea.

Sensors (Basel, Switzerland)
|October 26, 2024
PubMed
概括
此摘要是机器生成的。

本研究介绍了选择解码和转发 (DF) 或放大和转发 (AF) 继电模式的最佳和低复杂性标准,以提高隐蔽通信速率并降低检测风险.

关键词:
放大-然后-向前.隐藏的通信隐藏的通信.解码-然后转发.检测的可能性很低.物理层的安全性是物理层的安全性.

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相关实验视频

Last Updated: Jun 9, 2025

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科学领域:

  • 无线通信系统无线通信系统
  • 信息安全信息安全.
  • 信号处理 信号处理

背景情况:

  • 秘密通信对于传输敏感信息而不被发现至关重要.
  • 混合中继系统提供灵活性,但需要最佳模式选择.
  • 现有的方法在平衡隐蔽率和复杂性方面可能缺乏效率.

研究的目的:

  • 在混合式DF/AF中继系统中开发最佳和低复杂度的模式选择标准.
  • 为了最大限度地提高隐蔽通信速率,同时最大限度地降低检测概率.
  • 分析延迟,隐蔽率和计算复杂性之间的权衡.

主要方法:

  • 对个别的DF和AF模式实现的延迟感知可实现的隐蔽速率的分析.
  • 导出一个最佳的DF/AF模式选择标准.
  • 建议简化,低复杂度的选择标准,用于实际应用.
  • 数字模拟用于评估性能.

主要成果:

  • 最佳标准通过考虑延迟意识可实现的速度来最大限度地提高隐蔽率.
  • 低复杂性标准显著减少了计算时间.
  • 对于特定的系统参数,实现了高达50%的隐藏速度增长和高达20%的运行时间增长.
  • 提出的标准在提高秘密通信性能方面已证明有效.

结论:

  • 拟议的DF/AF模式选择标准有效地提高了隐蔽通信率.
  • 低复杂性标准为现实世界的实施提供了实际优势.
  • 这项研究有助于更安全,更有效的无线通信系统.