Um Ambiente para Avaliação do Consumo de Energia em Múltiplos Dispositivos Baseado na Web

Sidartha Carvalho; Rafael Lima; Carolina Barbosa; Abel Silva-Filho

doi:10.5753/semish.2015.10194

Sidartha Carvalho UFPE
Rafael Lima UFPE
Carolina Barbosa UFPE
Abel Silva-Filho UFPE

DOI: https://doi.org/10.5753/semish.2015.10194

Abstract

Recently can be observed a growth in mobile devices sales, including smartphones and tablets, with its high quantity and diversity of hardware and software models, it has highlighted the problem of fragmentation. The increase of features highlighted the need for greater capacity in mobile batteries to provide an extended time of use. This work proposes an environment for simultaneously tests on mobile devices with support for energy analysis. The tested devices in the environment were: Samsung Galaxy S3 and Galaxy S4. Experiments were conducted to provide energy efficiency optimizations in frequency scaling. From the analysis made in the environment were created techniques using DVFS that allowed energy savings of up to 25%.

References

Android Developer. (2015) “Android, the world's most popular mobile platform”. 2015. Disponível em http://developer.android.com/about/index.html . Acesso em: 02 mar. 2015.

Carroll, A. e Heiser, G. (2013) “Mobile Multicores: Use Them or Waste Them”. Proceedings of the 5th Workshop on Power-Aware Computing and Systems (HotPower’13). 2013.

Chang, Y.M., Hsiu, P.C., Chang, Y.H. e Chang, C.W. (2013) “A Resource-Driven DVFS Scheme for Smart Handheld Devices”. ACM Trans. on Embedded Computer Systems, 13(3):53:1–53:22, 2013

Domeika, M. (2008) “Software Development for Embedded Multi-core Systems: A Practical Guide Using Embedded Intel Architecture”. Newnes, Newton, MA, 2008.

Dong, M., Lai, P. e Li, Z. (2013) “Can We Identify Smartphone App by Power Trace?”. Proceedings of the 8th Asia and South Pacific Design Automation Conference (ASP-DAC). 2013.

Huang, J. (2014) “AppACTS: Mobile App Automated Compatibility Testing Service”. International Conference on Mobile Cloud Computing, Services, and Engineering (MobileCloud), IEEE. 2014.

Huang, J., Qian, F., Mao, Z., Sen, S. and Spatscheck, O. (2012) “Screen-off traffic characterization and optimization in 3g/4g networks”. In IMC ’12.

Liang, Y., Lai, P. e Chiou, C. (2010) “An energy conservation dvfs algorithm for the Android operating system”. Journal of Convergence, Vol. 1, pp.93-100. 2010.

Palit, R., Naik, K. e Singh, A. (2011) “Impact of Packet Aggregation on Energy Consumption in Smartphones”, In Proceedings of the 7th International Wireless Communications and Mobile Computing Conference, Istanbul, Turkey, 2011, pp. 589-594

Pallipadi, V. e Starikovskiy, A. (2006) “The ondemand governor: past, present and future.” In Proceedings of Linux Symposium, vol. 2, pp. 223-238, 2006.

Perrucci, G.P., Fitzek, F.H.P., Sasso, G. , Kellerer, W. and Widmer, J. (2009) “On the Impact of 2G and 3G Networks Usage for Mobile Phones' Battery Life”, in European Wireless Conference.

Shin, D., Lee, W., Kim, K., Wang, Y., Xie, Q., Pedram, M. e Chang, N. (2013) “Online estimation of the remaining energy capacity in mobile systems considering system-wide power consumption and battery characteristics”. In Proc. of Asia South Pacific Design Automation Conference (ASP-DAC), 2013.

Silva-Filho, A.G., Bezerra, P.T.L., Silva, F.Q.B., Junior, A.L.O.C., Santos, A.L.M., Costa, P.H.R. e Miranda, R.C.G. (2012) “Energy-Aware technology-based DVFS mechanism for the Android operating system”. Brazilian Symposium on Computing System Engineering (SBESC), 2012.

Statista. (2014) “The Statistics Portal”. Disponível em: http://www.statista.com/statistics/278305/daily-activations-of-Android-devices . Acesos em: 24 nov. 2014.

Xu, F., Liu, Y., Moscibroda, T., Chandra, R., Jin, L., Zhang, Y. and Li, Q. (2013) “Optimizing background email sync on smartphones”. In Proceeding of the 11th International Conference on Mobile Systems, Applications, and Services, MobiSys ’13, pages 55–68, New York, NY, USA, 2013. ACM.