Seamless computation offloading for mobile applications using an online learning algorithm

Although recent developments in the hardware of mobile devices, such as processor and memory capacity have increased their capabilities, they are still not comparable to cloud servers. The capacity constraints of mobile devices can be overcome by having the computing intensive work of mobile applica...

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Veröffentlicht in:	Computing 2021-05, Vol.103 (5), p.771-799
Hauptverfasser:	Kaya, Mahir, Çetin-Kaya, Yasemin
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Sprache:	eng
Schlagworte:	Algorithms Applications programs Artificial Intelligence Cloud computing Computation offloading Computer Appl. in Administrative Data Processing Computer Communication Networks Computer Science Distance learning Electronic devices Information Systems Applications (incl.Internet) Machine learning Microprocessors Mobile computing Mobile operating systems Power consumption Regular Paper Response time (computers) Run time (computers) Software Engineering
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creator	Kaya, Mahir Çetin-Kaya, Yasemin
description	Although recent developments in the hardware of mobile devices, such as processor and memory capacity have increased their capabilities, they are still not comparable to cloud servers. The capacity constraints of mobile devices can be overcome by having the computing intensive work of mobile applications performed on powerful local or cloud servers. One of the important aspects of computation offloading is the decision process; this is determined by the costs of running the computation intensive components at run time on the server or at the local. This study proposes a novel hybrid model. An object dependency graph was created by gathering data from the mobile device at run time. This graph was partitioned with a novel model to determine the offloadable parts, which were then sent to the server using an online learning algorithm. Mobile applications were implemented on Android OS to verify the hybrid model. Properly making the offloading decision improved the application performance and decreased the battery consumption. Our algorithm has yielded better results than existing studies. The response time was saved by 2–73% and energy was reduced by 16–44% through offloading the computation intensive parts of mobile applications.
doi_str_mv	10.1007/s00607-020-00873-y
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subjects	Algorithms Applications programs Artificial Intelligence Cloud computing Computation offloading Computer Appl. in Administrative Data Processing Computer Communication Networks Computer Science Distance learning Electronic devices Information Systems Applications (incl.Internet) Machine learning Microprocessors Mobile computing Mobile operating systems Power consumption Regular Paper Response time (computers) Run time (computers) Software Engineering
title	Seamless computation offloading for mobile applications using an online learning algorithm
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