LightFDG: an integrated approach to flow detection and grooming in optical wireless DCNs
LightFDG: an integrated approach to flow detection and grooming in optical wireless DCNs
LightFDG is an integrated approach to flow detection (FD) and flow grooming (FG) in optical wireless data center networks (DCNs), which is interconnected via wavelength division multiplexing (WDM) based free-space optical (FSO) links. Since forwarding bandwidth-hungry elephant flows (EFs) and delay-sensitive mice flows (MFs) on the same path can cause severe performance degradation, the LightFDG optically grooms flows of each class into rack-to-rack (R2R) flows. Then, R2R-MF and R2R-EF flows are separately forwarded over lightpaths of separate MF and EF virtual topologies, respectively. Lightpaths are provisioned by jointly determining the capacity and route based on flows' arrival rate, size, and completion time request. To prevent EFs from congesting the MF lightpaths, high speed and accurate flow-detection mechanisms are also necessary for classifying EFs as soon as possible. Therefore, a fast-lightweight-and-accurate flow detection framework is developed by leveraging the transmission control protocol (TCP) behaviors. The proposed FD scheme has the flexibility of being implemented as in-network or centralized to classify flows of modifiable and unmodifiable hosts, respectively. Since the centralized scheme incurs considerable overhead, the processing and communication overhead is also mitigated by proposed techniques. Numerical results show that LightFDG outperforms traditional load balancers by about 3× for EFs and 10 × for MFs. Along with the developed overhead mitigation methods, the centralized scheme is shown to provide up to 62 × lower overhead with 100% accuracy and with about 224 × higher detection speeds than the existing centralized solutions.
Flow classification, flow grooming, FSO, lightpath provisioning, wavelength division multiplexing
1153-1166
Alghadhban, Amer
b5789d22-f27e-4307-9483-2d5bdcd540d5
Celik, Abdulkadir
f8e72266-763c-4849-b38e-2ea2f50a69d0
Shihada, Basem
3aad5038-5b7e-4a97-9f22-7e310ea68a27
Alouini, Mohamed Slim
3ccd5915-318e-4f4b-b47a-48257ab4c0eb
June 2020
Alghadhban, Amer
b5789d22-f27e-4307-9483-2d5bdcd540d5
Celik, Abdulkadir
f8e72266-763c-4849-b38e-2ea2f50a69d0
Shihada, Basem
3aad5038-5b7e-4a97-9f22-7e310ea68a27
Alouini, Mohamed Slim
3ccd5915-318e-4f4b-b47a-48257ab4c0eb
Alghadhban, Amer, Celik, Abdulkadir, Shihada, Basem and Alouini, Mohamed Slim
(2020)
LightFDG: an integrated approach to flow detection and grooming in optical wireless DCNs.
IEEE Transactions on Network and Service Management, 17 (2), , [8932563].
(doi:10.1109/TNSM.2019.2959740).
Abstract
LightFDG is an integrated approach to flow detection (FD) and flow grooming (FG) in optical wireless data center networks (DCNs), which is interconnected via wavelength division multiplexing (WDM) based free-space optical (FSO) links. Since forwarding bandwidth-hungry elephant flows (EFs) and delay-sensitive mice flows (MFs) on the same path can cause severe performance degradation, the LightFDG optically grooms flows of each class into rack-to-rack (R2R) flows. Then, R2R-MF and R2R-EF flows are separately forwarded over lightpaths of separate MF and EF virtual topologies, respectively. Lightpaths are provisioned by jointly determining the capacity and route based on flows' arrival rate, size, and completion time request. To prevent EFs from congesting the MF lightpaths, high speed and accurate flow-detection mechanisms are also necessary for classifying EFs as soon as possible. Therefore, a fast-lightweight-and-accurate flow detection framework is developed by leveraging the transmission control protocol (TCP) behaviors. The proposed FD scheme has the flexibility of being implemented as in-network or centralized to classify flows of modifiable and unmodifiable hosts, respectively. Since the centralized scheme incurs considerable overhead, the processing and communication overhead is also mitigated by proposed techniques. Numerical results show that LightFDG outperforms traditional load balancers by about 3× for EFs and 10 × for MFs. Along with the developed overhead mitigation methods, the centralized scheme is shown to provide up to 62 × lower overhead with 100% accuracy and with about 224 × higher detection speeds than the existing centralized solutions.
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Published date: June 2020
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© 2019 IEEE.
Keywords:
Flow classification, flow grooming, FSO, lightpath provisioning, wavelength division multiplexing
Identifiers
Local EPrints ID: 504476
URI: http://eprints.soton.ac.uk/id/eprint/504476
ISSN: 1932-4537
PURE UUID: 08b75253-d011-464a-9be1-8e16da910cf9
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Date deposited: 09 Sep 2025 20:10
Last modified: 10 Sep 2025 13:50
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Contributors
Author:
Amer Alghadhban
Author:
Abdulkadir Celik
Author:
Basem Shihada
Author:
Mohamed Slim Alouini
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