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Efficient Data Transfer Rate and Speed of Secured Ethernet Interface System.

Shaila Ghanti1, G M Naik1

  • 1Department of Electronics, Goa University, Goa, India.

International Scholarly Research Notices
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Summary
This summary is machine-generated.

This study introduces a Secured Ethernet Interface System to defend internet services from SYN flood attacks. The system enhances genuine client access, data transfer rates, and server response times during attacks.

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Area of Science:

  • Computer Engineering
  • Network Security
  • Embedded Systems

Background:

  • Embedded systems are crucial for various applications, including home automation and health services, and require robust security for internet-connected services.
  • Internet-accessible services are vulnerable to attacks like SYN floods, necessitating specialized protection mechanisms.
  • Existing security measures may not adequately address the specific threats faced by embedded devices.

Purpose of the Study:

  • To design and implement an embedded Secured Ethernet Interface System (ESIS) for protecting internet services from SYN flood attacks.
  • To customize the ESIS for securing web services against SYN flood attack vectors.
  • To evaluate the effectiveness of the ESIS in a real-world experimental setup.

Main Methods:

  • The Secured Ethernet Interface System was designed and implemented as a system on chip (SoC) using an ALTERA Stratix IV FPGA.
  • A modified SYN flood attack protection method was integrated into the ESIS.
  • Experimental validation was conducted to assess the system's performance under simulated SYN flood attack conditions.

Main Results:

  • The ESIS demonstrated an increased capacity to serve genuine clients during SYN flood attacks.
  • Significant improvements in data transfer rates were observed with the implemented system.
  • Enhanced server response times were recorded, indicating better system resilience.

Conclusions:

  • The embedded Secured Ethernet Interface System effectively mitigates SYN flood attacks on internet services.
  • The FPGA-based implementation offers a viable solution for securing embedded devices.
  • The system provides tangible benefits in terms of client accessibility, performance, and responsiveness under attack.