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ICT and renewable energy: a way forward to the next generation telecom base stations

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Abstract

The tremendous growth in technology is also causing global warming due to harmful greenhouse gas emissions. The Information and Communication Technology (ICT) sector is one of the fastest growing, having the greatest impact on almost every other technology. Energy efficiency and reduction in global warming is now a desire and realization by all key players associated with this technology. Not only there is scope for energy efficiency in ICTs itself but it can also help other sectors in becoming smart i.e., energy efficient. Smart buildings, smart motors, smart logistics and smart grids are being realized with the incorporation of information and communication technologies. The ICT industry is equally aware of the potential benefits of renewable energy sources (RES) in making the future systems greener and sustainable. This is quite evident from the research that is going on towards sustainable ICT solutions, as reviewed in this paper. Not only renewable energy is applicable to large scale applications like telecom base stations (BS), it is also applicable to small and medium scale systems and devices like computer peripherals and electric vehicles. In order to explore the evident potential of RES, all aspects of renewable energy are being addressed by the researchers. These aspects can broadly be categorized as generation, distribution, management and most significantly application of renewable energy. This paper takes a broader look at both aspects in which ICTs are making our world eco-sustainable i.e., making other technologies smarter and incorporating renewable energy sources wherever possible.

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Notes

  1. www.ifgict.org

  2. http://www.green-ict.com/

  3. www.greentouch.org

  4. http://gesi.org/

  5. www.mobilevce.com/green-radio

  6. www.greentouch.org

  7. www.thegreengrid.org

References

  1. Kim, S., Kim, H.-K., & Kim, H. J. 92009). Climate change and icts. In 31st international telecommunications energy conference, 2009 (INTELEC 2009) (pp. 1–4). IEEE.

  2. Butler, M. (2011). Android: Changing the mobile landscape. IEEE Pervasive Computing, 10(1), 4–7.

    Article  Google Scholar 

  3. Energy outlook 2035. [Online]. Available: http://www.bp.com/en/global/corporate/about-bp/energy-economics

  4. Quadrelli, R., & Peterson, S. (2007). The energy-climate challenge: Recent trends in co 2 emissions from fuel combustion. Energy Policy, 35(11), 5938–5952.

    Article  Google Scholar 

  5. Greening, L. A., Greene, D. L., & Difiglio, C. (2000). Energy efficiency and consumption the rebound effecta survey. Energy Policy, 28(6), 389–401.

    Article  Google Scholar 

  6. Lund, H. (2007). Renewable energy strategies for sustainable development. Energy, 32(6), 912–919.

    Article  Google Scholar 

  7. Karanfil, F., & Li, Y. (2015). Electricity consumption and economic growth: Exploring panel-specific differences. Energy Policy, 82, 264–277.

    Article  Google Scholar 

  8. Outlook, A. E. (2008). Energy information administration, Washington, DC. http://www.eia.doe.gov.

  9. Geller, H., Harrington, P., Rosenfeld, A. H., Tanishima, S., & Unander, F. (2006). Polices for increasing energy efficiency: Thirty years of experience in oecd countries. Energy Policy, 34(5), 556–573.

    Article  Google Scholar 

  10. MacLean, D. (2008). Icts, adaptation to climate change, and sustainable development at the edges. In International telecommunication union symposium on ICTs and climate change.

  11. IPCC, A. (2007). Intergovernmental panel on climate change.

  12. Herring, H. (2006). Energy efficiency a critical view. Energy, 31(1), 10–20.

    Article  Google Scholar 

  13. Elliot, S. (2007) Environmentally sustainable ict: A critical topic for is research?. In PACIS 2007 proceedings (p. 114).

  14. Commission et al. S. D. (2010). Smarter moves: How information communications technology can promote sustainable mobility.

  15. Steinert, K., Marom, R., Richard, P., Veiga, G., & WITTERS, L. (2011) Making cities smart and sustainable. In The global innovation index 2011 (p. 87).

  16. Kelly, T., & Adolph, M. (2008). Itu-t initiatives on climate change. IEEE Communications Magazine, 46(10), 108–114.

    Article  Google Scholar 

  17. Berkhout, F., & Hertin, J. (2001). Impacts of information and communication technologies on environmental sustainability: Speculations and evidence. Report to the OECD, Brighton, 21,

  18. Fettweis, G., & Zimmermann, E. (2008). Ict energy consumption-trends and challenges. In Proceedings of the 11th international symposium on wireless personal multimedia communications (Vol. 2(4), p. 6).

  19. Houghton, J. (2010). Icts and the environment in developing countries: Opportunities and developments. In The development dimension ICTs for development improving policy coherence: improving policy coherence (p. 149).

  20. eSustainability Initiative, et al. G. (2008). SMART 2020: Enabling the low carbon economy in the information age. London: Climate Group.

  21. Iqbal, M., Azam, M., Naeem, M., Khwaja, A., & Anpalagan, A. (2014). Optimization classification, algorithms and tools for renewable energy: A review. Renewable and Sustainable Energy Reviews, 39, 640–654.

    Article  Google Scholar 

  22. Agrawal, N., & Agarwal, K. N. (2012). Current trends in green ict. JoAAG, 7(1), 71–85.

    Google Scholar 

  23. Hilty, L., Lohmann, W., & Huang, E. (2011). Sustainability and ictan overview of the field. Politeia, 27(104), 13–28.

    Google Scholar 

  24. Vereecken, W., Van Heddeghem, W., Colle, D., Pickavet, M., & Demeester, P. (2010). Overall ict footprint and green communication technologies. ISCCSP, 10, 1–6.

    Google Scholar 

  25. Hvelplund, F. (2006). Renewable energy and the need for local energy markets. Energy, 31(13), 2293–2302.

    Article  Google Scholar 

  26. Lindley, D. (2010). Smart grids: The energy storage problem. Nature News, 463(7277), 18–20.

    Article  Google Scholar 

  27. Harb, A. (2011). Energy harvesting: State-of-the-art. Renewable Energy, 36(10), 2641–2654.

    Article  Google Scholar 

  28. García Márquez, F . P., Tobias, A . M., Pinar Pérez, J . M., & Papaelias, M. (2012). Condition monitoring of wind turbines: Techniques and methods. Renewable Energy, 46, 169–178.

    Article  Google Scholar 

  29. Hameed, Z., Ahn, S., & Cho, Y. (2010). Practical aspects of a condition monitoring system for a wind turbine with emphasis on its design, system architecture, testing and installation. Renewable Energy, 35(5), 879–894.

    Article  Google Scholar 

  30. Eroğlu, Y., & Seçkiner, S. U. (2013). Wind farm layout optimization using particle filtering approach. Renewable Energy, 58, 95–107.

    Article  Google Scholar 

  31. Mala, K., Schläpfer, A., & Pryor, T. (2008). Solar photovoltaic (pv) on atolls: Sustainable development of rural and remote communities in kiribati. Renewable and Sustainable Energy Reviews, 12(5), 1345–1363.

    Article  Google Scholar 

  32. Woodell, M., & Schupp, B. (1996). The role of pilot projects and public acceptance in developing wireless power transmission as an enabling technology for space solar power systems. Solar Energy, 56(1), 41–51.

    Article  Google Scholar 

  33. Huang, K., & Lau, V. K. (2014). Enabling wireless power transfer in cellular networks: Architecture, modeling and deployment. IEEE Transactions on Wireless Communications, 13(2), 902–912.

    Article  Google Scholar 

  34. Parameshwaran, R., Kalaiselvam, S., Harikrishnan, S., & Elayaperumal, A. (2012). Sustainable thermal energy storage technologies for buildings: A review. Renewable and Sustainable Energy Reviews, 16(5), 2394–2433.

    Article  Google Scholar 

  35. Lu, X., Wang, W., & Ma, J. (2013). An empirical study of communication infrastructures towards the smart grid: Design, implementation, and evaluation. IEEE Transactions on Smart Grid, 4(1), 170–183.

    Article  Google Scholar 

  36. Ackermann, T., Andersson, G., & Söder, L. (2001). Distributed generation: A definition. Electric Power Systems Research, 57(3), 195–204.

    Article  Google Scholar 

  37. Vale, Z., Morais, H., Faria, P., & Ramos, C. (2013). Distribution system operation supported by contextual energy resource management based on intelligent scada. Renewable Energy, 52, 143–153.

    Article  Google Scholar 

  38. Lo, C.-H., & Ansari, N. (2012). The progressive smart grid system from both power and communications aspects. IEEE Communications Surveys & Tutorials, 14(3), 799–821.

    Google Scholar 

  39. Salvadori, F., Gehrke, C., de Oliveira, A., de Campos, M., & Sausen, P. S. (2013). Smart grid infrastructure using a hybrid network architecture. IEEE Transactions on Smart Grid, 4, 1630–1639.

    Article  Google Scholar 

  40. Lo, C.-H., & Ansari, N. (2013). Decentralized controls and communications for autonomous distribution networks in smart grid. IEEE Transactions on Smart Grid, 4(1), 66–77.

    Article  Google Scholar 

  41. Zhu, Z., Lambotharan, S., Chin, W. H., & Fan, Z. (2012). Overview of demand management in smart grid and enabling wireless communication technologies. Wireless Communications, IEEE, 19(3), 48–56.

    Article  Google Scholar 

  42. Kostevšek, A., Cizelj, L., Petek, J., & Pivec, A. (2013). A novel concept for a renewable network within municipal energy systems. Renewable Energy, 60, 79–87.

    Article  Google Scholar 

  43. Ekström, R., Kurupath, V., Svensson, O., & Leijon, M. (2013). Measurement system design and implementation for grid-connected marine substation. Renewable energy, 55, 338–346.

    Article  Google Scholar 

  44. Reich, N., Veefkind, M., Sark, W. v, Alsema, E., Turkenburg, W., & Silvester, S. (2009). A solar powered wireless computer mouse: Industrial design concepts. Solar Energy, 83(2), 202–210.

    Article  Google Scholar 

  45. McPhail, D. (2014). Evaluation of ground energy storage assisted electric vehicle dc fast charger for demand charge reduction and providing demand response. Renewable Energy, 67, 103–108.

    Article  Google Scholar 

  46. Benghanem, M. (2010). A low cost wireless data acquisition system for weather station monitoring. Renewable Energy, 35(4), 862–872.

    Article  Google Scholar 

  47. Palm, E., Hedén, F., & Zanma, A. (2001). Solar powered mobile telephony. In Environmentally Conscious Design and Inverse Manufacturing, 2001. Proceedings EcoDesign 2001: Second International Symposium on. IEEE, pp. 219–222.

  48. Park, S., & Hong, D. (2014). Achievable throughput of energy harvesting cognitive radio networks.

  49. Vaze, R., Garg, R., & Pathak, N. (2012). Dynamic power allocation for maximizing throughput in energy-harvesting communication system.

  50. Bajpai, P., Prakshan, N., & Kishore, N. (2009). Renewable hybrid stand-alone telecom power system modeling and analysis. In TENCON 2009-2009 IEEE Region 10 Conference (pp. 1–6). IEEE.

  51. Jiang, L., Liu, D.-Y., & Yang, B., et al. (2004). Smart home research. In Proceedings of the third conference on machine learning and cybernetics SHANGHAI (pp. 659–664).

  52. Han, D.-M., & Lim, J.-H. (2010). Design and implementation of smart home energy management systems based on zigbee. IEEE Transactions on Consumer Electronics, 56(3), 1417–1425.

    Article  Google Scholar 

  53. Davidoff, S., Lee, M. K., Yiu, C., Zimmerman, J., & Dey, A. K. (2006). Principles of smart home control. In Ubiquitous Computing, UbiComp. (2006) (pp. 19–34). Springer.

  54. Jahn, M., Jentsch, M., Prause, C. R., Pramudianto, F., Al-Akkad, A., & Reiners, R. (2010). The energy aware smart home. In 2010 5th international conference on future information technology (FutureTech) (pp. 1–8). IEEE.

  55. Zhao, M., Li, J., & Yang, Y. (2014). A framework of joint mobile energy replenishment and data gathering in wireless rechargeable sensor networks. IEEE Transactions on Mobile Computing, 13, 2689–2705.

    Article  Google Scholar 

  56. Li, Y., Jia, Z., Xie, S., & Liu, F. (2013). Dynamically reconfigurable hardware with a novel scheduling strategy in energy-harvesting sensor networks. IEEE Sensors Journal, 13(5), 2032–2038.

    Article  Google Scholar 

  57. Lin, L., Shroff, N. B., & Srikant, R. (2007). Asymptotically optimal energy-aware routing for multihop wireless networks with renewable energy sources. IEEE/ACM Transactions on Networking, 15(5), 1021–1034.

    Article  Google Scholar 

  58. Park, S., Lee, S., Kim, B., Hong, D., & Lee, J. (2011). Energy-efficient opportunistic spectrum access in cognitive radio networks with energy harvesting. In Proceedings of the 4th international conference on cognitive radio and advanced spectrum management (p. 62). ACM.

  59. Cai, L. X., Liu, Y., Luan, T. H., Shen, X., Mark, J. W., & Poor, H. V. (2011) Adaptiveresource management in sustainable energy powered wireless mesh networks.In Global Telecommunications Conference (GLOBECOM 2011), 2011 IEEE. IEEE, pp. 1–5.

  60. Min, G., Xie, X., Yang, L. T., & Guo, S. (2014). Green communication in energy renewable wireless mesh networks: Routing, rate control, and power allocation. IEEE Transactions on Parallel and Distributed Systems, 1.

  61. Cai, L. X., Liu, Y., Luan, T. H., Shen, X. S., Mark, J. W., & Poor, H. V. (2014). Sustainability analysis and resource management for wireless mesh networks with renewable energy supplies. IEEE Journal on Selected Areas in Communications, 32(2), 345–355.

    Article  Google Scholar 

  62. Zhang, F., & Chanson, S. T. (2005). Improving communication energy efficiency in wireless networks powered by renewable energy sources. IEEE Transactions on Vehicular Technology, 54(6), 2125–2136.

    Article  Google Scholar 

  63. Vo, T.-T., Nguyen, T.-D., & Vo, M.-T. (2014). Ubiquitous sensor network for development of climate change monitoring system based on solar power supply. In 2013 international conference on advanced technologies for communications (ATC) (pp. 121–124). IEEE.

  64. Bhagavatula, V., Wesson, W., & Rudell, J. C. (2011). Green monitoring using a wide area radio network for sensor (warns) communication. In 2011 international green computing conference and workshops (IGCC) (pp. 1–5). IEEE.

  65. Xu, D. Q., Joos, G., Levesque, M., & Maier, M. (2013). Integrated v2g, g2v, and renewable energy sources coordination over a converged fiber-wireless broadband access network. IEEE Transactions on Smart Grid, 4(3), 1381–1390.

    Article  Google Scholar 

  66. Abu-Baker, A., Huang, H., Johnson, E., Misra, S., Asorey-Cacheda, R., & Balakrishnan, M. (2010). Maximizing \(\alpha \)-lifetime of wireless sensor networks with solar energy sources. In Military communications conference, 2010-MILCOM (pp. 125–129). IEEE.

  67. Agarwal, A., & Jagannatham, A. K. (2013). Optimal adaptive modulation for qos constrained wireless networks with renewable energy sources. IEEE Wireless Communications Letters, 2(1), 78–81.

    Article  Google Scholar 

  68. Sarkar, S., Khouzani, M., & Kar, K. (2013). Optimal routing and scheduling in multihop wireless renewable energy networks. IEEE Transactions on Automatic Control, 58(7), 1792–1798.

    Article  Google Scholar 

  69. Morais, R., Boaventura Cunha, J., Cordeiro, M., Serodio, C., Salgado, P., & Couto, C. (1996). Solar data acquisition wireless network for agriculturalapplications. In Nineteenth convention of electrical and electronics engineers in Israel,1996 (pp. 527–530). IEEE.

  70. Torfs, T., Sanders, S., Winters, C., Brebels, S., & Van Hoof, C. (2004). Wireless network of autonomous environmental sensors. In Proceedings of IEEE Sensors (2004) (pp. 923–926). IEEE.

  71. Farhangi, H. (2010). The path of the smart grid. IEEE Power and Energy Magazine, 8(1), 18–28.

    Article  Google Scholar 

  72. Palensky, P., & Dietrich, D. (2011). Demand side management: Demand response, intelligent energy systems, and smart loads. IEEE Transactions on Industrial Informatics, 7(3), 381–388.

    Article  Google Scholar 

  73. Huang, L., Walrand, J., & Ramchandran, K. (2012). Optimal demand response with energy storage management. In 2012 IEEE third international conference on smart grid communications (SmartGridComm) (pp. 61–66). IEEE.

  74. Merei, G., Leuthold, M., & Sauer, D. U. (2013). Optimization of an off-grid hybrid pv-wind-diesel system with different battery technologies-sensitivity analysis. In Proceedings of 2013 35th international telecommunications energy conference ’smart power and efficiency’ (INTELEC) (pp. 1–6). VDE.

  75. Patlitzianas, K. D., Doukas, H., & Askounis, D. T. (2007). An assessment of the sustainable energy investments in the framework of the eu-gcc cooperation. Renewable Energy, 32(10), 1689–1704.

    Article  Google Scholar 

  76. Balachandra, P., & Kristle, H. S. (2010). Commercialization of sustainable energy technologies. Renewable Energy, 35(8), 1842–1851.

    Article  Google Scholar 

  77. Mani, S., & Dhingra, T. (2012). Diffusion of innovation model of consumer behaviour-ideas to accelerate adoption of renewable energy sources by consumer communities in india. Renewable Energy, 39(1), 162–165.

    Article  Google Scholar 

  78. Toklu, E. (2013). Overview of potential and utilization of renewable energy sources in turkey. Renewable Energy, 50, 456–463.

    Article  Google Scholar 

  79. Jiménez-Fernández, S., Salcedo-Sanz, S., Gallo-Marazuela, D., Gómez-Prada, G., Maellas, J., & Portilla-Figueras, A. (2014). Sizing and maintenance visits optimization of a hybrid photovoltaic-hydrogen stand-alone facility using evolutionary algorithms. Renewable Energy, 66, 402–413.

    Article  Google Scholar 

  80. Wu, J. (2012). Green wireless communications: from concept to reality [industry perspectives]. IEEE Wireless Communications, 19(4), 4–5.

    Article  Google Scholar 

  81. Etoh, M., Ohya, T., & Nakayama, Y. (2008). Energy consumption issues on mobile network systems. In International symposium on applications and the internet 2008 (SAINT 2008) (pp. 365–368). IEEE.

  82. Chen, T., Yang, Y., Zhang, H., Kim, H., & Horneman, K. (2011). Network energy saving technologies for green wireless access networks. IEEE Wireless Communications, 18(5), 30–38.

    Article  Google Scholar 

  83. Hassan, H. A. H., Nuaymi, L., & Pelov, A. (2013). Classification of renewable energy scenarios and objectives for cellular networks. In IEEE 24th international symposium on personal indoor and mobile radio communications (PIMRC) 2013 (pp. 2967–2972). IEEE.

  84. Ambrosy, A., Blume, O., Klessig, H., & Wajda, W. (2011) . Energy saving potential of integrated hardware and resource management solutions for wireless base stations. In IEEE 22nd international symposium on personal indoor and mobile radio communications (PIMRC) 2011 (pp. 2418–2423). IEEE.

  85. Tombaz, S., Vastberg, A., & Zander, J. (2011). Energy-and cost-efficient ultra-high-capacity wireless access. IEEE Wireless Communications, 18(5), 18–24.

    Article  Google Scholar 

  86. Grangeat, C., Grandamy, G.. & Wauquiez, F. (2010). A solution to dynamically decrease power consumption of wireless base stations and power them with alternative energies. In 32nd international telecommunications energy conference (INTELEC) (pp. 1–4). IEEE.

  87. Paudel, S., Shrestha, J. N., Neto, F. J., Ferreira, J. A., & Adhikari, M. (2011). Optimization of hybrid pv/wind power system for remote telecom station. In 2011 international conference on power and energy systems (ICPS) (pp. 1–6). IEEE.

  88. Ericsson, A. (2007). Sustainable energy use in mobile communications. white paper, EAB-07: 02l80l Uen Rev C.

  89. Bian, S., Wang, X., & Congiatu, M. (2013). An off-grid base station powered by sun wind, and water. In Proceedings of 2013 35th international telecommunications energy conference ’smart power and efficiency’ (INTELEC) (pp. 1–5). VDE.

  90. Yu, W., & Qian, X. (2009). Design of 3kw wind and solar hybrid independent power supply system for 3g base station. In Second international symposium on knowledge acquisition and modeling, 2009 (KAM’09) (Vol. 3, pp. 289–292).

  91. Nema, P., Rangnekar, S., & Nema, R. (2010). Pre-feasibility study of pv-solar/wind hybrid energy system for gsm type mobile telephony base station in central india. In 2010 The 2nd international conference on computer and automation engineering (ICCAE) (Vol. 5, pp. 152–156). IEEE.

  92. Marsan, M. A., Bucalo, G.,  Di Caro, A., Meo, M., & Zhang, Y. (2013). Towards zero grid electricity networking: Powering bss with renewable energy sources. In 2013 IEEE international conference on communications workshops (ICC) pp. 596–601. IEEE.

  93. Lior, N. (2002). Thoughts about future power generation systems and the role of exergy analysis in their development. Energy Conversion and Management, 43(9), 1187–1198.

    Article  Google Scholar 

  94. Kalas P. P., & Finlay, A. (2009). Planting the knowledge seed adapting to climate change using ICTs: Concepts, current knowledge and innovative examples. BCO.

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  1. Department of Electrical Engineering, COMSATS Institute of Information Technology, Wah Campus, Wah Cantt., Islamabad, Pakistan

    Faran Ahmed, Muhammad Naeem & Muhammad Iqbal

  2. Department of Electrical and Computer Engineering, Ryerson University, Toronto, ON, Canada

    Muhammad Naeem

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Ahmed, F., Naeem, M. & Iqbal, M. ICT and renewable energy: a way forward to the next generation telecom base stations. Telecommun Syst 64, 43–56 (2017). https://doi.org/10.1007/s11235-016-0156-4

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