1 / 25

A configuration method for structured P2P overlay network considering delay variations

A configuration method for structured P2P overlay network considering delay variations. Tomoya KITANI (Shizuoka Univ. 、 Japan) Yoshitaka NAKAMURA (NAIST, Japan). Overview. A Novel Space Filling Curve efficiently lets a 2D space coordinate be converted into a 1D space

gabe
Download Presentation

A configuration method for structured P2P overlay network considering delay variations

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. A configuration method for structured P2P overlay networkconsidering delay variations Tomoya KITANI (Shizuoka Univ.、Japan) Yoshitaka NAKAMURA (NAIST, Japan)

  2. Overview • A Novel Space Filling Curve • efficiently lets a 2D space coordinate be converted into a 1D space • easily gives each node ID from the space coordinate and the link delay between the nodes

  3. Backgrounds • Realization of location-aware serviceby the spread of mobile Internet environment • Providing the service that considered the location information of the node • P2P overlay network based on location information • Advertisement for the specific area is possible • Range specified information search

  4. Related work • LL-net • Structured P2P overlay network where the area on the map is hierarchically divided into 4 sub areas, and in each hierarchy the overlay links should be the different length • Dynamic construction of overlay network by join/leave of mobile terminals

  5. Related work • SkipGraph • Performance of LL-net turns worse by deflection of nodes • LL-net constructs quad-tree and search over the tree • Depth of the tree is biased because nodes are distributed following power law in reality • Efficiency of the search can be kept O(log N) at any time by usingSkipGraph into LL-net • SkipGraph uses ID mapping 2D information to 1D Mapping 2D->1D Space Filling Curve

  6. Space filling curve • known as technique to map information of a multi-dimensional space such as location information onto the one-dimensional(1D) space such as ID • One-dimensional ID • Can use the distributed resource management technique of P2P • DHT, SkipGraph, etc. • Conventional Space Filling Curves • Lebesgue curve (Z-ordering) • Hilbert curve • Sierpinski curve

  7. Lebesgue Curve(Z-ordering) • Divide into 4 clusters and connect nodes in the shape of Z • Physical link length between clusters is long • The nodes that are near on 2D space may not become near on 1D space either • Lebesgue is used well practically because conversion from latitude and longitude is easy

  8. Node labeling using location information • Geographical location information ((x,y)) of 2D space is converted into 1D • x = (x1x2x3 ... xH) • y = (y1y2y3 ... yH) • p = (x1y1x2y2x3y3 ... xHyH) • Go around in order of assuming p as a binary number -> Lebesgue Curve (Z-ordering) x 00 01 10 11 00 01 y 10 11

  9. Hilbert Curve • All nodes are connected with a link of length 1 • Neighbor nodes on the 2D space are relatively near also on 1D space • It is complex to calculate the position in 1D space from latitude and longitude

  10. Advantage of space filling curve • Geographically near nodes are close in 1D-ID • Information search that specifies the range is efficiently executable when the information related to location information Divide into 5 ranges and search Divide into 3 ranges and search

  11. New space filling curve • Purpose • Convertible from latitude and longitude easily as the Lebesgue curve • Convertible geographically near node into near ID • Introduction of label and connection relationship of Hierarchical Chordal Ring Network • Hamming distance between the neighbor nodes’ ID can be 1

  12. Hierarchical Chordal Ring Network20) • Topology where number of average hops and network diameter are assumed O(log N) based on ring type network • HCRN has the ring type structure and the tree structure • HCRN is originally designed so that number of necessary wave length may become O(log N) on ring type WDM network

  13. ID labeling of HCRN x 00 01 10 11 00 01 y 10 11 00 10 01 11

  14. Correspondence to dynamic join/leave of nodes • Hierarchical number of each segmented domain depends on the number of participating nodes • Space filling curve that covers all nodes that belong to all hierarchies is proposed • In Lebesgue, it is possible to correspond by enhancing to arrange nodes of a higher hierarchy in the oblique side of Z character

  15. Generation processes of HCRN from latitude & longitude • Generate by the following conversion processes • (x,y) : latitude & longitude of the node of the k th hierarchy • To adjust Hamming distance of the label between the neighbor nodes to 1, • Each even number bits of x, y are reversed and p = (x1y1x2y2x3y3 ... xkyk)= (p1... p2k) is obtained • Sequence number seqp is obtained by right expression (H is the maximum number of hierarchy) • Nodes are connected in order of seqp

  16. New space filling curve using HCRN • Label lp of HCRN is obtained from p with the following conversions • Nodes with Hamming distance 1 are connected • This curve is closed space filling curve looks like Hilbert and is connected hierarchically

  17. Evaluation of proposed curve • Object of comparison • Proposed curve(2D-HCRN) • Lebesgue curve • Lebesgue enhanced to multi hierarchies(2D-Lebesgue) • Lowest hierarchy of proposed curve • Hilbert curve • Evaluation item • Distance on 1D-ID with the neighborhood nodes on 2D by Index Range. • Delay to need to go around all nodes by simulation

  18. Index Range19) • To evaluate how far each two nodes physically in 4 neighborhoods on the filling curves • Logarithmic average distance on 1D-ID of geographically 4 neighborhoods • seq(i) : Sequence number on 1D-ID of node i • pos(i) : Position (x,y) on 2D-plane of node i

  19. Index Range of each space filling curve Smaller is better

  20. Simulation environment • 10-10,000 nodes participate into the network sequentially • Nodes join according to the following algorithm • The node with latitude & longitude p = (x1y1x2y2 ... xH yH) = (p1p2 ... p2H) joins • i = 2 • If the node with the label of p’ = (p1... pi) does not exist yet, p’ is assumed to be a label that shows the location information of the node • If there is p‘ , i = i + 2 and go to 3. • Position p of the participation node is decided by a random number according to "random distribution" and "Zipf distribution"

  21. Average physical distance between neighbor nodes in ID (Randomly distributed)

  22. Average physical distance between neighbor nodes in ID (Distributed following Zipf law)

  23. Square average of physical distance between neighbor nodes in ID (Randomly distributed)

  24. Square average of physical distance between neighbor nodes in ID (Distributed following Zipf law)

  25. Conclusions • We proposed the new space filling curve for small delay structured P2P overlay network • Geographical round distance is small and conversion is comparatively easy • More suitable for hierarchical-spread nodes than the conventional curves • Future work • Performance evaluation of the proposed space filling curve in the real network environment especially in node distribution with bias • Reexamination of the routing entry of each node to improve the performance

More Related