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| Title: | Delay Sensitive Routing for High Speed Packet-switching Networks
高速封包交換網路中考量網路延遲的路由 |
| Authors: | 黃玉昇
Yu-Sheng Huang |
| Contributors: | 連耀南
Yao-Nan Lien
黃玉昇
Yu-Sheng Huang |
| Keywords: | delay sensitive routing
high speed packet switching |
| Date: | 2002 |
| Issue Date: | 2009-09-18 18:25:48 (UTC+8) |
| Abstract: | 在如同全IP網路(ALL-IP Network)這類的分封交換網路(packet-switching network)中提供具時效性的服務(time-sensitive services)必須嚴格的控制時間。路由規劃是網路管理中重要的一環,所以這類網路的路由規劃必須考慮網路延遲。然而就我們目前所知,多數的傳統路由演算法並不以傳輸延遲(path delay)為主要考量因素;例外少數有考量延遲時間的演算法也僅限於鍊結延遲(link delay),而未考慮節點延遲(node delay)。此乃肇因於以往頻寬的成本極為昂貴,因而造成演算法設計者在設計時會儘可能有效利用頻寬,如此免不了會犧牲傳遞速度。在過去幾年間,由於光通訊技術的提升,網路頻寬的成長速度遠遠已超過路由器(router)處理能力的成長。在這樣不對等的成長比例驅使下,節點延遲,亦即路由器處理封包時所耗時間,在傳輸延遲中所佔的比例亦隨之快速增長。也因此我們認為,在為高速封包交換網路設計路由演算法時,必須同時考量鍊結延遲和節點延遲。在本論文中,我們設計了一個訊務流為基礎的路由演算法(flow-based routing algorithm),KLONE,來驗證我們的論點。在規劃路由時,KLONE會把發生在鍊結和節點上的延遲時間一併列入計算,並以全體延遲時間為主要考量。透過我們反覆的測試實驗,我們發現其較之於常用的OSPF演算法,可以在效能上有30%的勝出。藉此,我們的論點得到初步的證實。
Providing time sensitive services becomes an essential task for some packet-switching networks such as All-IP networks, which will carry all the traffics supported by both circuit-switching and packet-switching networks. To fulfill this demand, such networks require a delay sensitive routing mechanism to provide time-related QoS for delay sensitive services. However, most of traditional routing algorithms do not take delay time as a major concern. Only a few are designed for time sensitive services. These time sensitive routing algorithms are designed at the time when the link bandwidth is the only scarce resource. As the bandwidth of communication links grows rapidly in recent years due to the advance of optical communication technologies, link bandwidth is no longer the only scarce resource. The processing speed of nodes, for example, routers, becomes another critical source of delay time. In this thesis, we designed a new flow-based routing algorithm, the KLONE algorithm, which takes average delay time as its minimization objective and takes both nodes and links as delay components. Through an intensive evaluation using simulation method, we demonstrate that a routing algorithm that considers both link and node delay might outperform the traditional OSPF algorithm.
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1 Introduction … … … … … … … … … … … … … … … … … … … … … … … … … … ...1
1.1 Switching Network Technologies ....................................................................2
1.1.1 Circuit-Switching Networks .................................................................2
1.1.2 Packet-Switching Networks ..................................................................4
1.1.3 Network Convergence and ALL-IP Networks ......................................7
1.2 Delay Time Analysis ......................................................................................10
1.2.1 One Trip Delay Time .......................................................................... 11
1.2.2 Categories of Delay Time Components .............................................. 11
1.2.3 Myth of Bandwidth.............................................................................15
1.2.4 Possible Delay in Routers ...................................................................16
1.3 Motivation and Research Objective. ..............................................................18
1.4 Solution Approaches ......................................................................................19
1.5 Performance Evaluation.................................................................................20
2 Related Works … … … … … … … … … … … … … … … … … … … … … … … … … 21
2.1 Routing Approaches .......................................................................................21
2.1.1 Shortest Path Routing .........................................................................21
2.1.2 Flooding ..............................................................................................22
2.1.3 Flow-Based Routing ...........................................................................22
2.1.4 Distance Vector Routing .....................................................................23
2.1.5 Link State Routing ..............................................................................24
2.2 Delay Sensitive Routing ................................................................................24
2.2.1 Resource Reservation..........................................................................25
2.2.2 Probes Flooding ..................................................................................25
2.2.3 Classified Queues................................................................................26
2.2.4 Delay Time Estimation .......................................................................27
2.2.5 Miscellaneous ......................................................................................27
2.3 Summary........................................................................................................28
3 Routing With Node Delay… … … … … … … … … … … … … … … … … … … … … ..29
3.1 An Illustration Example .................................................................................29
3.2 Routing Problem Model.................................................................................31
3.2.1 Traffic Model ......................................................................................31
3.2.3 Objective Function..............................................................................33
3.3 Iterative Solution Algorithm ..........................................................................34
3.3.1 Intra Iteration Procedures....................................................................35
3.3.2 Termination Conditions .......................................................................37
3.2.3 Estimation of Path Delay Time....… … … … … … … … … … … … … … 38
3.3.4 Node Delay to Link Delay Conversion...............................................41
3.4 KLONE Algorithm Detail ..............................................................................43
3.4.2 Pseudo Codes ......................................................................................44
3.4.3 Complexity Analysis ...........................................................................47
3.5 Summary........................................................................................................47
4 Performance Evaluation … … … … … … … … … … … … … … … … … … … … … ..49
4.1 Performance Evaluation Metrics....................................................................49
4.1.1 Convergence of KLONE Algorithm ...................................................50
4.1.2 Performance of KLONE Algorithm....................................................50
4.2 Design of Experiments...................................................................................51
4.2.1 Test Instance Generation.....................................................................51
4.2.2 Experiments ........................................................................................53
4.3 Experiments and Results ................................................................................54
4.3.1 Exp-1: Convergence Test ....................................................................56
4.3.2 Exp-2: Sensitivity to Connectivity......................................................61
4.3.3 Exp-3: Sensitivity to BP Ratio ............................................................63
4.3.4 Exp-4: Sensitivity to Number of Nodes ..............................................65
4.3.5 Comparison with Optimal Solution ....................................................64
4.3.6 Weakness of KLONE Algorithm ........................................................65
4.4 Analysis and Summary ..................................................................................67
5 Concluding Remark and Future Work … … … … … … … … … … … … … … … 68 |
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| Description: | 碩士
國立政治大學
資訊科學學系
88753006
91 |
| Source URI: | http://thesis.lib.nccu.edu.tw/record/#G0088753006 |
| Data Type: | thesis |
| Appears in Collections: | [資訊科學系] 學位論文
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