High-Density and De-Densified Smart Campus Communications. Daniel Minoli
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СКАЧАТЬ session bandwidth is often guaranteed for the session's duration once the session is established. Conversely, the service costs for 4G/LTE are relatively high and there are limits to the user throughput; there is relatively limited practical competition among carriers; large base‐station antennas are needed to cover large geographic areas; the technology is complex; indoor reception of voice and data can be problematic, creating the need for more indoor antennas; and 5G will require smaller (therefore, a larger number of) cells. Wi‐Fi is often perceived to be free; the technology is simpler; the hardware and infrastructure are cheaper; it is a consistent technology between the office and the home; there is more competition in the sense that various establishments (e.g. stores, coffee shops, malls, libraries, institutions) make Wi‐Fi service available. However, the technology is subject to interference; the distance is limited; roaming does not work across different providers and may not even work for a given provider, even within limited geography; congestion can occur, and; QoS is not guaranteed. Nonetheless, both technologies fill a role, and both technologies are clearly needed.

      There are several Wireless Local Area (WLAN) standards that have evolved over time, including Institute of Electrical and Electronics Engineers (IEEE) standards 802.11a, 802.11b, 802.11g, 802.11n, 802.11ac, 802.11ax. The new standards have been developed to accommodate the evolving requirements for higher speeds. Some protocols and wireless routers provide backward compatibility with older Wi‐Fi systems. The Wi‐Fi Alliance (an industry group) has announced a banding “generation” designation, as follows:

       Wi‐Fi 4 is 802.11n, released in 2009

       Wi‐Fi 5 is 802.11ac, released in 2014

       Wi‐Fi 6 is the new version, also known as 802.11ax (scheduled for release in 2019)

      Earlier versions of Wi‐Fi have not been officially branded, but one could label the previous generations as follows:

       Wi‐Fi 1: 802.11b, released in 1999

       Wi‐Fi 2: 802.11a, released in 1999

       Wi‐Fi 3: 802.11g, released in 2003

      The upcoming 5G access networks may utilize higher frequencies (i.e. > 6 GHz) to support increasing capacity by allocating larger operating channels and bands, although some lower frequencies can also be used. Millimeter wave (mmWave), the band of spectrum between 30 and 300 GHz, have shorter wavelengths that range from 10 to 1 mm. Currently, much of the mmWave spectrum is underutilized; thus, it can be used to facilitate the deployment of new high‐speed services. While it is known that mmWave signals experience severe path loss, penetration loss, and fading, the shorter wavelength at mmWave frequencies also allows more antennas to be packed in the same physical dimension, which allows for large‐scale spatial multiplexing and highly directional beamforming [8].

      One million connections per square kilometer (also definable as 1 connection per m2) equates to one connection every 10 ft2 (1 km2 = 10 763 910 ft2); СКАЧАТЬ