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dc.contributor.advisorHaritsa, Jayant
dc.contributor.advisorHansdah, R C
dc.contributor.authorSuresha, *
dc.date.accessioned2009-03-20T09:53:10Z
dc.date.accessioned2018-07-31T04:39:38Z
dc.date.available2009-03-20T09:53:10Z
dc.date.available2018-07-31T04:39:38Z
dc.date.issued2009-03-20T09:53:10Z
dc.date.submitted2006
dc.identifier.urihttp://etd.iisc.ac.in/handle/2005/438
dc.description.abstractWebsites are shifting from static model to dynamic model, in order to deliver their users with dynamic, interactive, and personalized experiences. However, dynamic content generation comes at a cost – each request requires computation as well as communication across multiple components within the website and across the Internet. In fact, dynamic pages are constructed on the fly, on demand. Due to their construction overheads and non-cacheability, dynamic pages result in substantially increased user response times, server load and increased bandwidth consumption, as compared to static pages. With the exponential growth of Internet traffic and with websites becoming increasingly complex, performance and scalability have become major bottlenecks for dynamic websites. A variety of strategies have been proposed to address these issues. Many of these solutions perform well in their individual contexts, but have not been analyzed in an integrated fashion. In our work, we have carried out a study of combining a carefully chosen set of these approaches and analyzed their behavior. Specifically, we consider solutions based on the recently-proposed fragment caching technique, since it ensures both correctness and freshness of page contents. We have developed mechanisms for reducing bandwidth consumption and dynamic page construction overheads by integrating fragment caching with various techniques such as proxy-based caching of dynamic contents, pre-generating pages, and caching program code. We start with presenting a dynamic proxy caching technique that combines the benefits of both proxy-based and server-side caching approaches, without suffering from their individual limitations. This technique concentrates on reducing the bandwidth consumption due to dynamic web pages. Then, we move on to presenting mechanisms for reducing dynamic page construction times -- during normal loading, this is done through a hybrid technique of fragment caching and page pre-generation, utilizing the excess capacity with which web servers are typically provisioned to handle peak loads. During peak loading, this is achieved by integrating fragment-caching and code-caching, optionally augmented with page pre-generation. In summary, we present a variety of methods for integrating existing solutions for serving dynamic web pages with the goal of achieving reduced bandwidth consumption from the web infrastructure perspective, and reduced page construction times from user perspective.en
dc.language.isoen_USen
dc.relation.ispartofseriesG21064en
dc.subjectWeb Serversen
dc.subjectFragment Cachingen
dc.subjectProxy-based Cachingen
dc.subjectDynamic Web Pagesen
dc.subjectDatabase Cachingen
dc.subjectStatic Web Pagesen
dc.subjectCode Cachingen
dc.subjectServer-side Cachingen
dc.subjectHybrid Cachingen
dc.subjectIntegrated Cachingen
dc.subjectDynamic Web Cacheen
dc.subjectDynamic Web Page Constructionen
dc.subjectWeb Log Miningen
dc.subject.classificationComputer Scienceen
dc.titleCaching Techniques For Dynamic Web Serversen
dc.typeThesisen
dc.degree.namePhDen
dc.degree.levelDoctoralen
dc.degree.disciplineFaculty of Engineeringen


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