Features of Long Term Evolution LTE www assignmentpoint
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Features of Long Term Evolution (LTE) www. assignmentpoint. com
Features of LTE üThe LTE- Advanced (Long Term Evolution- Advanced) is 4 G wireless service proposed by 3 GPP (Third generation Partnership Project). In 2009 4 G LTE started its commercial service in Scandinavia. Three important features of LTE are: femtocell deployment , OFDMA-based physical layer access and MIMO. üThe FBS (Femto BS) is named as Home evolved Node-B (He. NB) in LTE-A placed in public places to provide higher data rate and improve resource usage to a number of users. Femtocells are different in the sense that they are installed by customers in an ad hoc fashion without any RF planning. Objective of e. Node. B Femtocells lies in offloading of traffic. www. assignmentpoint. com
Two-tier macro-femto network architecture www. assignmentpoint. com
ü LTE provides OFDMA-based physical layer access where: • OFDMA minimizes separation between carriers • Carriers are selected so that they are orthogonal over symbol interval • Carrier orthogonality leads to frequency domain spacing ∆f =1/T, where T is the symbol time • In LTE carrier spacing is 15 KHz and useful part of the symbol is 66. 7 microsec www. assignmentpoint. com
üMIMO communication takes place between e. NB and UE. LTE standard requires support for: e. Node. B can have maximum 4 antennas UE can have maximum 2 antennas www. assignmentpoint. com
S-GW and MME HSS P-GW e. PDG E-UTRAN Untrusted non 3 GPP access Macro Femto Fig. 1 Architecture of LTE www. assignmentpoint. com Trusted non 3 GPP access
User Equipment (UE) üAs the name suggests, a UE is the actual device that the LTE customers use to connect to the LTE network and establish their connectivity. The UE may take several forms; it can be a mobile phone, a tablet, or a data card used by a computer/notebook. üSimilar to all other 3 GPP systems, the UE consists of two main entities: a SIM-card or what is also known as User Service Identity Module (USIM), and the actual equipment known as Terminal Equipment (TE). üSIM-card carries the necessary information provided by the operator for user identification and authentication procedures. The terminal equipment on the other hand provides the users with the necessary hardware (e. g. , processing, storage, operating system) to run their applications and utilize the LTE system services. www. assignmentpoint. com
Evolved UTRAN (E-UTRAN) üThe E-UTRAN in LTE consists of directly interconnected e. Node. Bs which are connected to each other through the X 2 interface and to the core network through the S 1 interface. üThis eliminates one of the biggest drawbacks of the former 3 GPP systems (UMTS): the need to connect and control the Node. Bs through the Radio Network Controller (RNC), which make the system vulnerable to RNC failures. The LTE E-UTRAN architecture can be seen in Figure below. www. assignmentpoint. com
Evolved Packet Core (EPC) The EPC (also known as the LTE core network) consists of three main entities: Mobility Management Entity (MME), Serving Gateway (S-GW) and the Packet Data Network Gateway (PDN-GW). In addition, there are some other logical entities like the Home Subscriber Server (HSS) and Policy and Charging Rules Function (PCRF). www. assignmentpoint. com
The EPC consists of six nodes: Home Subscriber Server (HSS) is like the combination of HLR and AUC of UMTS or GSM The Packet Data Network (PDN) Gateway (P-GW) provides connectivity between UE and external packer switching network. It works like a gateway SGSN (Serving GPRS Support Node) of UMTS. The serving gateway (S-GW) works as a router whose function is to forward data between the BS and the PDN gateway(P-GW). It also works as the mobility anchor of e. NB handovers and do the similar job between LTE and other 3 GPP technologies. www. assignmentpoint. com
Interfaces S 1 (e. Node B to SGSN) S 1 (e. Node B to MME) X 2 between two e. Node Bs (required for handover) Uu (UE to e. Node B) Uu www. assignmentpoint. com
LTE Frame Structure There are two types of LTE frame structure: Type 1: used for the LTE FDD mode systems. Type 2: used for the LTE TDD systems. Type 1 LTE Frame Structure üThe duration of one LTE radio frame is 10 ms. One frame is divided into 10 subframes of 1 ms each, and each subframe is divided into two slots of 0. 5 ms each. www. assignmentpoint. com
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üEach slot contains either six or seven OFDM symbols, depending on the Cyclic Prefix (CP) length. The useful symbol time is 1/15 k. Hz= 66. 6 mircosec. Since normal CP is about 4. 69 microsec long, seven OFDM symbols can be placed in the 0. 5 -ms slot as each symbol occupies (66. 6 + 4. 69) = 71. 29 microseconds. üWhen extended CP (=16. 67 microsec) is used the total OFDM symbol time is (66. 6 + 16. 67) = 83. 27 microseconds. Six OFDM symbols can then be placed in the 0. 5 -ms slot. www. assignmentpoint. com
In LTE, radio resources are allocated in units of Physical Resource Blocks (PRBs). Each PRB contains 12 subcarriers and one slot. www. assignmentpoint. com
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