Abstract
Consumers demand more from their technology. Whether it is a television, cellular phone, or refrigerator, the latest technology purchase must have new features. With the advent of the Internet, the most-wanted feature is better, faster access to information. Cellular subscribers pay extra on top of their basic bills for such features as instant messaging, stock quotes, and even Internet access right on their phones. To support such a powerful system, we need pervasive, high-speed wireless connectivity. A number of technologies currently exist to provide users with high-speed digital wireless connectivity; Bluetooth and 802.11 are examples. These two standards provide very high-speed network connections over short distances, typically in tens of meters. The goal is the same: long-range, high-speed wireless, which for the purposes of this chapter will be called 4G, for fourth-generation wireless system. Fourth-generation wireless needs to be standardized due to its enticing advantages to both users and providers. Each generation is characterized by new frequency bands, higher data rates and non-backwards compatible transmission technology. The first release of the 3GPP Long-Term Evolution (LTE) standard does not completely fulfill the ITU 4G requirements called IMT-Advanced. First release LTE is not backwards compatible with 3G, but is a pre-4G or 3.9G technology, however, sometimes branded ā4Gā by the service providers. Its evolution LTE Advanced is a 4G technology. WiMAX is another technology verging on or marketed as 4G.
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Purkayastha, B.B., Sarma, K.K. (2015). Conclusions and Future Direction. In: A Digital Phase Locked Loop based Signal and Symbol Recovery System for Wireless Channel. Signals and Communication Technology. Springer, New Delhi. https://doi.org/10.1007/978-81-322-2041-1_13
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DOI: https://doi.org/10.1007/978-81-322-2041-1_13
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