Abstract
Satellite plays an important role in the environment sensing during the emergency scenario, especially to robust to the natural disaster. Integrated satellite-terrestrial network which combines both advantages of the satellite network and the terrestrial network can achieve all-day seamless coverage and broad coverage areas. Integrated satellite and terrestrial networks can be used to solve communication problems in natural disasters, forestry monitoring and control, and military communication. Unlike traditional communication methods, integrated networks are effective solutions because of their advantages in communication, remote sensing, monitoring, navigation, and all-weather seamless coverage. Monitoring, urban management, and other aspects will also have a wide range of applications. The multi-beam satellite communication system increases spectrum utilization significantly, but it can cause satellite network and the terrestrial network intensive co-frequency interference. However, the exclusion zone makes the signal to interference and noise ratio (SINR) of the satellite-terrestrial link increase significantly. In this chapter, we propose a first builds an integrated network overlay model, and divides the satellite network into two categories: terrestrial network end users and satellite network end users. The energy efficiency, throughput, and signal-to-noise ratio (SINR) are deduced and analyzed. In this chapter, we discuss the influence of various factors, such as transmit power, number of users, size of the protected area, and terminal position, on energy efficiency and SINR. A satellite-sharing scheme with a combination of the user location and a protection zone with high energy efficiency and anti-jamming capability are proposed, to provide better communication quality for end users in integrated satellite and terrestrial networks. Finally, the numerical results show that the performance of proposed scheme is superior to the traditional integrated satellite-terrestrial scheme.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Kamga GN, Sadek M, Aïssa S (2016) Adaptive handoff for multi-antenna mobile satellite systems with ancillary terrestrial component. In: IEEE international conference on communications, IEEE 2016
Fujino Y, Miura A, Hamamoto N (2011) Satellite terrestrial integrated mobile communication system as a disaster countermeasure. In: 2011 XXXth URSI general assembly and scientific symposium, Istanbul, 2011, pp 1–4
Liu SY, Qin F, Gao Z (2013) LTE-satellite: Chinese proposal for satellite component of IMT-advanced system. China Commun 10:47–64
Orsino A, Araniti G, Scopelliti P et al (2017) Optimal subgroup configuration for multicast services over 5G-satellite systems. In IEEE international symposium on broadband multimedia systems and broadcasting, IEEE 2017
Zhu X, Jiang C, Kuang L et al (2017) Non-orthogonal multiple access based integrated terrestrial-satellite networks. IEEE J Sel Areas in Commun (99):1–1
Deslandes V, Tronc J, Beylot AL (2010) Analysis of interference issues in integrated satellite and terrestrial mobile systems. In: Advanced satellite multimedia systems conference, 2010, pp 256–261
Giambene G, Le VA, Bourgeau T et al (2015) Soft frequency reuse schemes for heterogeneous LTE systems In: IEEE international conference on communications, IEEE 2015, pp 3161–3166
Xie H, Wang B, Gao F et al (2016) A full-space spectrum-sharing strategy for massive MIMO cognitive radio system. IEEE J Sel Areas Commun 34(10):2537–2549
Park U, Kim HW, Oh DS et al (2016) Performance analysis of dynamic resource allocation for interference mitigation in integrated satellite and terrestrial systems In: International conference on next generation mobile applications, services and technologies, IEEE 2016, pp 217–221
Sheng M, Wang Y, Li J, Liu R, Zhou D, He L (2017) Toward a flexible and reconfigurable broadband satellite network: Resource management architecture and strategies. IEEE Wireless Commun 24(4):127–133, Aug 2017. http://doi.org/10.1109/MWC.2017.1600173
Jia M, Gu X, Guo Q et al (2016) Broadband hybrid satellite-terrestrial communication systems based on cognitive radio toward 5G. IEEE Wirel Commun 23(6):96–106
Vannithamby R, Talwar S, Chih‐Lin I et al (2016) Towards green and soft towards 5G. Wiley, 53–77
Sheng M, Wang Y, Li J et al (2017) Toward a flexible and reconfigurable broadband satellite network: resource management architecture and strategies. IEEE Wirel Commun 99:2–8
Min Jia, Zhang Ximu Gu, Xuemai Liu Xiaofeng, Qing Guo (2018) Joint UE location energy-efficient resource management in integrated satellite and terrestrial networks. J Commun Inf Netw 3(1):61–67 SD
GPP TR 36.942 V10.3.0 (2012) Technical specification group radio access network, evolved universal terrestrial radio access (E-UTRA), radio frequency (RF) system scenarios(release 10), 2012, pp 14–15
Jia M, Zhang X, Gu X, Guo Q (2018) Energy efficient cognitive spectrum sharing scheme based on inter-cell fairness for integrated satellite-terrestrial communication systems. In: 2018 IEEE VTC Spring. 3–6 June 2018, Porto, Portugal
Jia M, Gu X, Guo Q, Xiang W, Zhang N (2016) Broadband hybrid satellite-terrestrial communication systems based on cognitive radio toward 5G. IEEE Wirel Commun 23(6):96–106
Acknowledgements
This work was supported by National Science Foundations of China (No. 61671183, 61771163 and 91438205) and the Open Research Fund of State Key Laboratory of Space-Ground Integrated Information Technology under grant No. 2015_SGIIT_KFJJ_TX_02.
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2019 Springer Nature Singapore Pte Ltd.
About this chapter
Cite this chapter
Jia, M., Zhang, X., Guo, Q., Gu, X. (2019). Joint Optimization of Resource Allocation with Inter-beam Interference for a Multi-beam Satellite and Terrestrial Communication System. In: Durrani, T., Wang, W., Forbes, S. (eds) Geological Disaster Monitoring Based on Sensor Networks. Springer Natural Hazards. Springer, Singapore. https://doi.org/10.1007/978-981-13-0992-2_10
Download citation
DOI: https://doi.org/10.1007/978-981-13-0992-2_10
Published:
Publisher Name: Springer, Singapore
Print ISBN: 978-981-13-0991-5
Online ISBN: 978-981-13-0992-2
eBook Packages: Earth and Environmental ScienceEarth and Environmental Science (R0)