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Hamiltonian Graph Analysis – Mixed Integer Linear Programming (HGA-MILP) Based Link Failure Detection System in Optical Data Center Networks

  • Rajat Gupta , Mona Aggarwal EMAIL logo and and Swaran Ahuja
Published/Copyright: July 24, 2019
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Journal of Optical Communications
From the journal Journal of Optical Communications Volume 44 Issue 3

Abstract

The internet services have become more popular rapidly over the decades. This is because of the inspiration created by new content-hungry applications on end-user devices like smart phones. Wavelength division multiplexed mesh networks are the optical backbone, working as the aggregating point of huge volume traffic, interconnecting several access networks and end users. The need of virtual data center is to retain services in case of failures such as optical link failures and resource or power outage in data centers that occurs in the cloud infrastructure and improve the survivability. The physical infrastructure may disconnect the virtual machines and physical data centers. This leads to the reduction in computational as well as communicational capabilities of the cloud. To overcome these issues, an integer linear programming model called hamiltonian graph analysis – mixed integer linear programming (HGA-MILP) is proposed in this work by utilizing hamiltonian graph model. The main motive of this research is to design a survivable data centre network mapping problem against physical link failures. Use of hamiltonian path methodology is helpful to organize data and improve network performance.

Keywords: cloud infrastructure; hamiltonian graph model; IP over WDM; mixed integer linear programming; optical data centre network; survivability

Acknowledgment

We would like to express our sincere thanks to Ali Hmaity and Massimo Tornatore, Politecnico di Milano, Italy, for their valuable suggestions and guidance from time to time.

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Received: 2019-04-05
Accepted: 2019-06-20
Published Online: 2019-07-24
Published in Print: 2023-07-26

© 2019 Walter de Gruyter GmbH, Berlin/Boston

Articles in the same Issue

  1. Frontmatter
  2. Amplifiers
  3. Fourth-generation Bidirectional Wireless Hybrid Transmission System Employing Power-Doubler-Amplifier and Data Comparator
  4. Devices
  5. PAPR Reduction for O-OFDM UOWC System
  6. An All Optical OR Gate Using BPSK Technique Inside 2D Photonic Crystals
  7. Optical Scheme of Obtaining Highest Transmission Factor in Case of KDP Based Electro-Optic Crystal by the Adjustment of Suitable Biasing Voltage and Number of Feedback Passing
  8. Evaluation of Chirped Fiber Bragg Grating with APD on Designed Optical Fiber Communication Link
  9. Design of Linear Block Code Encoder and Decoder Using Electro-optical and All-optical Units
  10. Fibers
  11. Chirped Large Mode Area Photonic Crystal Modal Fibers and its Resonance Modes Based on Finite Element Technique
  12. Lasers
  13. Radio Over Fiber-Based Wavelength Division Multiplexed/Time Division Multiplexed Passive Optical Network Architecture Employing Mutual Injection Locked Fabry-Perot Laser Diodes
  14. Networks
  15. High Speed Passive Optical Network Based Elastic Optical Communication System
  16. Hamiltonian Graph Analysis – Mixed Integer Linear Programming (HGA-MILP) Based Link Failure Detection System in Optical Data Center Networks
  17. IoT-Based Health Monitoring System Using BeagleBone Black with Optical Sensor
  18. Systems
  19. Performance Analysis of a STBC FDM FSO Communication System with Direct Detection Receiver under Turbulent Condition
  20. Transmission Reliability of Wireless Communication System-Based on Optical Fiber Signal Processing
  21. Crosstalk Limitations due to Intercore Coupling on the BER Performance of an Optical Communication System with Homogeneous Multi-core Fiber
  22. High Speed 2 × 10 Gbps WDM Enabled Inter-Satellite Optical Wireless Communication Link
  23. Theory
  24. Performance Analysis of FSO DF Relays with Log-Normal Fading Channel
  25. Pointing Error Effects on Mixed RF-FSO Link
https://doi.org/10.1515/joc-2019-0090
Keywords for this article
cloud infrastructure; hamiltonian graph model; IP over WDM; mixed integer linear programming; optical data centre network; survivability

Articles in the same Issue

  1. Frontmatter
  2. Amplifiers
  3. Fourth-generation Bidirectional Wireless Hybrid Transmission System Employing Power-Doubler-Amplifier and Data Comparator
  4. Devices
  5. PAPR Reduction for O-OFDM UOWC System
  6. An All Optical OR Gate Using BPSK Technique Inside 2D Photonic Crystals
  7. Optical Scheme of Obtaining Highest Transmission Factor in Case of KDP Based Electro-Optic Crystal by the Adjustment of Suitable Biasing Voltage and Number of Feedback Passing
  8. Evaluation of Chirped Fiber Bragg Grating with APD on Designed Optical Fiber Communication Link
  9. Design of Linear Block Code Encoder and Decoder Using Electro-optical and All-optical Units
  10. Fibers
  11. Chirped Large Mode Area Photonic Crystal Modal Fibers and its Resonance Modes Based on Finite Element Technique
  12. Lasers
  13. Radio Over Fiber-Based Wavelength Division Multiplexed/Time Division Multiplexed Passive Optical Network Architecture Employing Mutual Injection Locked Fabry-Perot Laser Diodes
  14. Networks
  15. High Speed Passive Optical Network Based Elastic Optical Communication System
  16. Hamiltonian Graph Analysis – Mixed Integer Linear Programming (HGA-MILP) Based Link Failure Detection System in Optical Data Center Networks
  17. IoT-Based Health Monitoring System Using BeagleBone Black with Optical Sensor
  18. Systems
  19. Performance Analysis of a STBC FDM FSO Communication System with Direct Detection Receiver under Turbulent Condition
  20. Transmission Reliability of Wireless Communication System-Based on Optical Fiber Signal Processing
  21. Crosstalk Limitations due to Intercore Coupling on the BER Performance of an Optical Communication System with Homogeneous Multi-core Fiber
  22. High Speed 2 × 10 Gbps WDM Enabled Inter-Satellite Optical Wireless Communication Link
  23. Theory
  24. Performance Analysis of FSO DF Relays with Log-Normal Fading Channel
  25. Pointing Error Effects on Mixed RF-FSO Link
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