lte-ppt
TRANSCRIPT
LTE stands for Long Term Evolution
LTE is based on standards developed by 3rd Generation Partnership Project(3GPP).
LTE standards are described in Release 8
LTE is next stage of mobile communication which will enable things like IP based voice, high data streaming, on portable devices.
Introduction
3rd Generation Partnership Project, gloaboration between groups of telecommunication association
Its aim is to produce Technical Specifications and Technical Reports for a 3G Mobile system based on evolved mobile systems.
It includes maintenance of the Global System for Mobile Communication (GSM) including GSM evolved radio access technologies
An evolved third Generation and beyond Mobile System based on the evolved 3GPP core networks, and the radio access technologies supported by the Partners (i.e., UTRA both FDD and TDD modes).
An evolved IP Multimedia Subsystem (IMS) developed in an access independent manner
3GPP
First Generation(1G)
1G was developed in seventies It was an analog system Advanced Mobile Phone System(AMPS)
was first launched by US and is a 1G mobile system. Based on FDMA, it allows users to make voice calls in one country.
Major invention of microprocessor.
Drawbacks: Poor Voice Quality, Large Phone Size, No Security,
Poor handoff Reliability
History of LTE
Second Generation(2G)
2G phone uses Global System for Mobile communications (GSM) were first used in the early 1990’s in Europe.
Uses digital modulation for improved audio quality.
GSM provides voice & limited data services.
It includes GSM,D-AMPS,CDMA,PDC
Drawbacks: GSM is a circuit switched ,connection oriented technology, where
the end system are dedicated for entire call session.
This causes inefficiency in usage of bandwidth & resources. GSM enabled systems do not supports high data rates.
Third Generation(3G)
The 3G technology adds multimedia facilities to 2G phones by allowing video, audio, and graphics applications.
The idea behind 3G is to have a single network standard instead of the different types adopted in the US, Europe, and Asia.
3G has HSDPA and HSUPA. 3G Together is call UMTS
Drawbacks:
High Bandwidth requirement High spectrum licensing fees High Capital
HSDPA- High Speed Downlink Packet Access (Release 5)
Increses the peak data rate in downlink direction from 384 kbits to up to 10Mbits/s- in theory up to 14.4 Mbits/s
HSUPA- High Speed Uplink Packet Access(Release 6)
Peak user data rates upto 2 Mbit/s can be achieved
4G is the fourth generation of cellular wireless standards. It is a successor to 3G and 2G families of standards Data Speeds upto 1Gbit/sec approx All 4G devices are based on IP Packet switched network
Dynamically share and utilize the network resources to support more simultaneous users per cell
Smooth handovers across heterogeneous networks Ability to offer high quality of service for next generation multimedia
support LTE and WiMax are cut above technologies that fall under 4G
What is 4G?
Worldwide Interoperability of Microwave Access(WiMax) is described in IEEE 802.16.
WiMax
The following are major points of WiMax (Wireless MAN IEEE 802.16) functionality:
Range - 30-mile (50-km) radius from base station Speed - Up to 70 megabits per second Non-Line-of-sight (NLoS) between the user and a base station
(BSS) Frequency bands - 2 to 11 GHz and 10 to 66 GHz (licensed and
unlicensed bands)
There is no need for line of sight (LOS) connections between subscriber terminals and the base station in WiMAX technology and it can support hundreds if not thousands of subscribers from a single base station.
LTE is a next-generation wireless technology that will put super-fast broadband in the hands of first responders
LTE is a new standard that can be used in radio access networks, which sit between mobile devices, such as cell phones, and the core network
Greater interoperability and enhanced interagency cooperation
It provides low latency, enabling real-time services (VoIP, video).
It is much faster than 3G, employing advanced technologies and deployable in bandwidths ranging from 1.4 MHz to 20 MHz.
LTE
Flat Architecture
Its called flat architecture because its all IP based. The RNC’s are replaced by effective eNode B. There is no Circuit Switch Core Network in LTE
OFDM- Orthogonral Frequency Division Multiplexing (Downlink)
In OFDM the signal is first split into independent sub-carriers and these closely-spaced orthogonal sub-carriers are used to carry the data.
The data is divided into several parallel data streams or channels, one for each sub-carrier. Each sub-carrier is modulated with a conventional modulation scheme
The OFDM technology used in LTE comprises a maximum of 2048 different sub-carriers having a spacing of 15 kHz
Within the OFDM signal it is possiblr to choose between 3 types
of modulation
- QPSK (=4QAM) 2bits per symbol
-16QAM 4 bits per symbol
- 64QAM 6 bits per symbol
SC-FDMA- Single Carrier Frequency Division Multiple Acess (Uplink)
SC-FDMA is a hybrid transmission scheme combining the low peak to average (PAR) of single carrier schemes with the frequency allocation flexibility and multi-path protection.
This combines the low peak to average ratio offered by single-carrier systems with the multipath interference resilience and flexible subcarrier frequency allocation that OFDM provides.
MIMO- Multiple Input Multiple Output Also called beam forming or smart antennas LTE will support MIMO It describes the possiblity to have multiple transmitter and receiver
antennas in a system Up to four antennas can be used by a single LTE cell MIMO is considered to be the core technology to increase spectral
efficiency
Evolved NodeB No RNC is provided anymore The evolved NodeB’s take over all radio mangagement functionality This will make radio management faster
UL/DL scheduling In UMTS physical resources are shared or dedicated Evolved Node B handles all physical resources via schedular and
assigns them dynamically to users and channels This provides great flexiblity than older system
LTE Key Features
Qos awareness The scheduler must handle and distinguish different quality of
service class Otherwise real time service would not be possible via EUTRAN
Packet Switch Domain Only No circuit switched domain provided If CS application are required, they must be implemented via IP Only one Mobility Management for UE in LTE
Network Feature UMTS Network LTE Network
Major services Primarily voice Voice, data, and rich multi-media
Core Network 1. WAN
2. Circuit/Packet switching
1. Broadband IP
2. All packet switched
Network Architecture WAN (cell based) Integration of WAN/Wireless LAN
Speeds 384 Kbps to 2 Mbps 20 to 100 Mbps mobile
Frequency Band 1800-2400 MHz 2 to 8 GHz
Bandwidth 5-20 MHz 100 MHz (or greater)
Switching Technology Circuit and PacketAll digital switching with
packetized voice
Access Technologies CDMA OFDM and MC-CDMA
Antenna TechnologyOptimized antenna design,
Multi-band adapters
Smart Antennas, software
multiband and wideband radios
IP Capabilities IP 5.0 All IPv6
Difference between Networks
The 3GPP group has defined the following as features and standards for LTE communication
LTE targets requirements of next generation networks including downlink peak rates of at least 100Mbit/s, uplink rates of 50 Mbit/s.
RAN (Radio Access Network) round-trip times of less than 10ms.
It is suitability for deployment in scalable bandwidths ranging from 1.25 MHz to 20 MHz
LTE will also support seamless connection to existing networks, such as GSM, CDMA and WCDMA.
A main objective of Long Term Evolution (LTE) is to support IP multimedia services, including VoIP and high-speed data applications
It enable smooth handoff between heterogeneous network.
LTE requires a completely new RAN.
LTE has reduced Latency
Features of LTE
Video Computer-Aided Dispatching Automatic Vehicle Location GPS Digital Imaging Large Data Files Enhanced Day-to-Day Operations
Applications
Handoff Process Wireless system selection Support for quality of service - Packet level QoS - Transcation level QoS - Circuit level QoS - User level Qos
Limitations
There is next set of proposed system- LTE Advanced.
Proposed Features:
Backward compatibility with LTE and 3gpp legacy systems. Peak data rate 1 Gbps DL and 500 Mbps UL. BW about 70 MHz in DL and 40 MHz in UL. 3 times higher average user throughput than LTE. 3 times more spectral efficient than LTE. Support of scalable BW and spectrum aggregation.
LTE Advanced
LTE is all about Evolution from its Predecessors
Communication so far mostly being about people speaking to people, the future of communication will be about all kind of things speaking to each other through Internet,i.e- Internet of things. Every toaster, AC, car engine could be equipped with low cost LTE chip that will connect to every growing network. LTE takes into a whole new dimension in fact its being called the largest growth opportunity in the history of business
Evolution shows:
Conclusion