Researchers are investigating how software-defined cellular networking might be used to give smartphone users the next generation of ultra fast broadband – 5G.
Currently, the fourth generation of mobile phone connection technology, 4G, in as far as it has been adopted provides broadband-type connectivity for enabled devices such as smartphones, tablet computers, laptops and other gadgets through two standards: the Mobile WiMAX standard and the first-release Long Term Evolution (LTE) standard.
Peak speeds were set in the standards at 100 megabits per second (Mbit/s) for mobile users and ten times that for static, domestic 5G users, 1 gigabit per second. 100 Mbits/s is three times faster than the earlier 3G system but users commonly do not see data transfer at such high rates, downloads are usually at best 10 Mbits/s. As yet, there is no single standard for 5G although various systems are being touted based on rebuilding the cellular networks to be super-efficient and exploiting different frequencies with their capacity for greater data rates.
The hope is to be able to achieve download speeds of perhaps 10 Gbits/s, researchers said. In practice, this means that a high-definition movie can be downloaded in less than half an hour. The research is being undertaken by Ming Lei of Samsung Research and Development Institute China, Lei Jiang of NEC Laboratories, Beijing with colleagues at the University of Electronic Science and Technology of China in Chengdu, Beijing Jiaotong University and the University of Kurdistan.
They have assessed the latest developments aimed at 5G systems and have proposed their own novel end-to-end (E2E) software-defined cellular network (SDCN) architecture which
they say offers flexibility, scalability, agility and efficiency.
Moreover, it will be sustainable for providers as well as profitable, researchers said. They are currently building a demonstration system that will allow them to utilise several promising technologies in their architecture for 5G including cloud computing, network virtualisation, network functions virtualisation and dynamic service chaining.
The approach, they suggest, could overcome bandwidth shortage problems, improve quality of service so avoiding delays and data loss, as well as reducing the vast number of error-prone network nodes needed for such a system. The research was published in the International Journal of Communication Networks and Distributed Systems.