Cross-layer optimization

Cross-layer optimization is an escape from the pure waterfall-like concept of the OSI communications model with virtually strict boundaries between layers. The cross layer approach transports feedback dynamically via the layer boundaries to enable the compensation for overload, latency or other mismatch of requirements and resources by any control input to another layer, but that layer directly affected by the detected deficiency.[1][2][clarification needed]

Strict boundaries between layers are enforced in the original OSI networking model, where data is kept strictly within a given layer. Cross‑layer optimization removes such strict boundaries to allow communication between layers by permitting one layer to access the data of another layer to exchange information and enable interaction. For example, having knowledge of the current physical state will help a channel allocation scheme or automatic repeat request (ARQ) strategy at the MAC layer in optimizing tradeoffs and achieving throughput maximization.[3][clarification needed]

Especially in information routing with concurrent demand for limited capacity of channels there may be a need for a concept of intervention to balance between e.g. the needs of intelligible speech transmission and of sufficiently dynamic control commands. Any fixed allocation of resources will lead to a mismatch under special conditions of operations.[clarification needed] Any highly dynamic change of resource allocation might affect the intelligibility of voice or the steadiness of videos. However, as with other optimizing strategies, the algorithm consumes time as well.[4]

Principles

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There are principles that a cross-layer design must adhere to:

  • Interactions and the Law of Unintended Consequences
  • Dependency Graph
  • Timescale Separation and Stability
  • The Chaos of Unbridled Cross-Layer Design

Unlike a traditional architectural design approach, where designers can focus on a single problem without worrying about the rest of the protocol stack, one must be careful to prevent unintended effects on other parts of the system. Dependency graphs are helpful for adaptation loops that occur using cross-layer design.[5]

Applications

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Cross-layer optimization can be used for

  • adaptation
  • scheduling
  • resource allocation[6]
  • power control
  • congestion control
  • multihop routing[7]

Its advantages include high adaptivity in a Wireless sensor network and a larger optimization space.[5]

Adjusting quality of service

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Cross-layer optimization shall contribute to an improvement of quality of services under various operational conditions. Such adaptive quality of service management is currently subject of various patent applications, as e.g.[8] The cross-layer control mechanism provides a feedback on concurrent quality information for the adaptive setting of control parameters. The control scheme apply

  • the observed quality parameters
  • a fuzzy logic based reasoning about applying the appropriate control strategy
  • the statistically computed control input to parameter settings and mode switches

Tailoring to resource efficiency of cross-layer

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The quality aspect is not the only approach to tailor the cross-layer optimization strategy. The control adjusted to availability of limited resources is the first mandatory step to achieve at least a minimum level of quality. Respective studies have been performed and will continue.[9]

Adapting MAC scheduling based on PHY parameters

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Communication systems that need to operate over media with non stationary background noise and interference may benefit from having a close coordination between the MAC layer (which is responsible for scheduling transmissions) and the PHY layer (which manages actual transmission and reception of data over the media).[10][11]

In some communications channels (for example, in power lines), noise and interference may be non-stationary and might vary synchronously with the 50 or 60 Hz AC current cycle. In scenarios like this, the overall system performance can be improved if the MAC can get information from the PHY regarding when and how the noise and interference level is changing, so that the MAC can schedule transmission during the periods of time in which noise and interference levels are lower.[11]

An example of a communications system that allows this kind of Cross-layer optimization is the ITU-T G.hn standard, which provides high-speed local area networking over existing home wiring (power lines, phone lines and coaxial cables).

Issues

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Some issues may arise with cross-layer design and optimization by creating unwanted effects as explained in.[12][13] Cross-layer design solutions that allow optimized operation for mobile devices in the modern heterogeneous wireless environment are described in,[14] where in addition the major open technical challenges in the cross-layer design research area are pointed out.

See also

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References

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  1. ^ http://www.ece.purdue.edu/~shroff/Shroff/journal/LSS06.pdf[dead link]
  2. ^ "Archived copy" (PDF). Archived from the original (PDF) on 2008-07-04. Retrieved 2008-06-25.{{cite web}}: CS1 maint: archived copy as title (link)
  3. ^ "IETE Technical Review : Paid Content". Archived from the original on 15 April 2013.
  4. ^ "Archived copy" (PDF). Archived from the original (PDF) on 2008-05-16. Retrieved 2008-06-25.{{cite web}}: CS1 maint: archived copy as title (link)
  5. ^ a b Cognitive Radio Communications and Networks : Principles and Practice. Burlington, MA: Academic Press. 2010. pp. 201–234. ISBN 9780080879321.
  6. ^ Karmokar, Ashok (21 November 2012). "Energy-Efficient Green Radio Communications for Delay Tolerant Applications". Handbook of Green Information and Communication Systems: 183–208. doi:10.1016/B978-0-12-415844-3.00007-3. ISBN 9780124158443.
  7. ^ Wymeersch, Henk (2016). "Multiple access control in wireless networks". Academic Press Library in Mobile and Wireless Communications. Academic Press. pp. 435–465. doi:10.1016/B978-0-12-398281-0.00012-0. ISBN 978-0-12-398281-0.
  8. ^ "Cross-layer integrated collision free path routing - US Patent 7339897". Archived from the original on 2011-06-12. Retrieved 2008-06-25.
  9. ^ http://www.nyman-workshop.org/2003/papers/Cross-Layer%20Optimization%20for%20Sensor%20Networks.pdf Archived 2008-08-28 at the Wayback Machine [bare URL PDF]
  10. ^ S. Shabdanov, P. Mitran, C. Rosenberg, "Cross-Layer Optimization Using Advanced Physical Layer Techniques in Wireless Mesh Networks", in IEEE Transactions on Wireless Communications
  11. ^ a b Guowang Miao; Guocong Song (2014). Energy and spectrum efficient wireless network design. Cambridge University Press. ISBN 978-1107039889.
  12. ^ V. Kawadia, P.R. Kumar, "A cautionary perspective on cross-layer design", in: IEEE Wireless Communications, Volume 12, Issue 1, Feb. 2005.[dead link]
  13. ^ P. Papadimitratos, A. Mishra, and D. Rosenburgh, "A Cross-Layer Design Approach to Enhance 802.15.4", in: IEEE MILCON 2005, Volume 3, pp 1719-1726, June 2005
  14. ^ F. Foukalas et al., "Cross-layer design proposals for wireless mobile networks: a survey and taxonomy "