August 2014. LTE Advanced Evolving and expanding in to new frontiers

August 2014 LTE Advanced Evolving and expanding in to new frontiers 1

LTE Advanced: Evolving & expanding into new frontiers 1 Brings carrier aggregation and its evolution led by Qualcomm Technologies 3 Extends benefits of LTE to unlicensed spectrum 2 Enables hyper-dense HetNets; Further gains with enhanced receivers 4 Expands LTE in to new frontiers device-to-device, Broadcast TV, higher bands & more 1000x mobile data challenge enabler 2

LTE Advanced brings different dimensions of improvements Leverage wider bandwidth Carrier aggregation across multiple carriers, multiple bands, and across licensed and unlicensed spectrum F1 LTE Carrier #1 LTE Carrier #2 LTE Carrier #3 LTE Carrier #4 LTE Carrier #5 Carrier aggregation Up to 100 MHz Higher data rates (bps) Leverage more antennas Downlink MIMO up to 8x8, enhanced Multi User MIMO and uplink MIMO up to 4x4 MIMO Higher spectral efficiency (bps/hz) Leverage HetNets With advanced interference management (FeICIC/IC) Higher spectral efficiency per coverage area (bps/hz/km 2 ) Small Cell Range Expansion 3

Carrier Aggregation rapidly expanding and evolving led by Qualcomm Qualcomm Snapdragon is a product of Qualcomm Technologies Inc. 4

Carrier Aggregation fatter pipe to enhance user experience Up to 20 MHz LTE Carrier #1 Up to 20 MHz Up to 20 MHz Up to 20 MHz LTE Carrier #2 LTE Carrier #3 LTE Carrier #4 Aggregated Data Pipe Up to 100 MHz Up to 20 MHz LTE Carrier #5 Higher peak data rates Higher user data rates and lower latencies for all users More capacity for typical bursty usage 1 Leverages all spectrum assets 1 The typical bursty nature of usage, such as web browsing, means that aggregated carriers can support more users at the same response (user experience) compared to two individual carriers, given that the for carriers are partially loaded which is typical in real networks. The gain depends on the load and can exceed 100% for fewer users (less loaded carrier) but less for many users. For completely loaded carrier, there is limited capacity gain between individal carriers and aggregated carriers, 5

User experience Carrier aggregation increases capacity for typical network load Typical bursty smartphone applications You Tube Skype Burst Rate (normalized) 6 5 4 Carrier aggregation capacity gain 2 10MHz Single Carriers 10MHz + 10MHz Carrier Aggregation 3 Pandora Data bursts 2 1 Partially loaded carriers Capacity gain can exceed 2x (for same user experience) 1 Idle time 0 0 63 12 6 18 9 24 12 30 15 Load (Mbps) 1 Carrier aggregation doubles burst rate for all users in the cell, which reduces over-the-air latency ~50%, but if the user experience is kept the same (same burst rate), multicarrier can instead support more users for partially loaded carriers. The gain depends on the load and can exceed 100% for fewer users (less loaded carrier) but less for many users (starting to resemble full buffer with limited gain). Source: Qualcomm simulations, 3GPP simulation framework, FTP traffic model with 1MB file size, 57 macro cells wrap-around, 500m ISD (D1), 2x2 MIMO, TU3, NLOS, 15 degree downtilt 2GHz spectrum., 6

Carrier aggregation gaining momentum Led by Qualcomm Technologies, Inc. 8974 LTE Advanced 9x25 LTE Advanced (Cat4) 9x35 LTE Advanced (Cat6) World s 1 st LTE Advanced carrier aggregation (Launched Jun 2013) LTE Advanced Cat 6 (300 Mbps) (Announced Nov 2013) 150 Mbps peak data rate (cat 4) 10 + 10 MHz in downlink QTI s 3 rd generation Qualcomm Gobi LTE modem HSPA+ 3 carriers DL & 2 carrier UL aggregation Qualcomm Snapdragon and Gobi are products of Qualcomm Technologies, Inc. 300 Mbps peak data rate (cat 6) 20 + 20 MHz in downlink QTI s 4 th generation Qualcomm Gobi LTE modem HSPA+ 3 carriers DL & 2 carrier UL aggregation 7

Taking carrier aggregation global - 4 Th Gen Gobi LTE New Gobi modem paired with new RF solution 4 th Generation LTE modem 40 MHz Support in downlink (20 MHz+ 20MHz) 300 Mbps Peak data rate (LTE Cat6) FDD/TDD Support 1 st 20nm modem HSPA+ 3 carrier downlink & 2 carrier uplink aggregation Common platform for LTE Advanced & HSPA+ carrier aggregation One chip, all carrier aggregation combinations Supports next gen LTE Advanced wideband CA 4th generation LTE transceiver 1 st 28nm RF ~3x* more CA band combinations Note: *Compared to previous generation QCT solutions; Qualcomm Gobi is a product of Qualcomm Technologies, Inc. ; Qualcomm WTR 3925 is a product of Qualcomm Atheros, Inc. 8

Global demand for LTE Carrier Aggregation QTI chipsets designed to support all CA band combinations currently in deployment or in planning ~50 band combinations being defined by 3GPP North America B4 + B17 B4 + B13 B4 + B12 B5 + B12 B2 + B17 B4 + B5 B5 + B17 B4 + B7 B2 + B5 B2 + B29 B4 + B29 B2 + B4 B2 + B13 B23 + B29 B2 + B12 Contiguous B41 Non Contiguous 41 Non Contiguous B4 Non Contiguous B25 South America Contiguous B41 Non Contiguous B7 Europe B3 + B7 B3 + B20 B7 + B20 B8 + B20 China B39 + B41 B1 + B7 Contiguous B38 Contiguous B7 Contiguous B3 Contiguous 40 Non Contiguous 41 Contiguous B39 Australia B3 + B8 B3 + B28 Japan B11 + B18 B3 + B28 B1 + B8 B1 + B18 B1 + B19 B1 + B21 B1 + B26 B3 + B19 B19 + B21 Contiguous B1 South Korea B3 + B8 B1 + B5 B3 + B5 B3 + B26 B8 + B26 Non Contiguous B3 Requirements: 700-2700 MHz Inter-Band CA Intra-Band CA Wider Bandwidth TDD CA FDD CA RFFE + Modem Source: 3GPP, the combinations in blue are completed as of September 2013, remaining represent work items in progress; 3GPP continually defines band combinations 9

Advanced multiple antenna techniques for more capacity 10

More antennas large gain from receive diversity Downlink Diversity, MIMO 1.8x 4x4 MIMO 1.7x 4 Way Receive Diversity (+ 2 x 2 MIMO) LARGE GAIN, NO STANDARDS OR NETWORK IMPACT 1x 2 x 2 MIMO MAINSTREAM COMMERCIAL NodeB Device Relative spectral efficiency Note: LTE Advanced R10 and beyond adds up to 8x8 Downlink MIMO (Multiple Input Multiple Output), enhanced Multi User MIMO and uplink MIMO up to 4x4. Simulations: 3GPP framework, 21 macro cells wrap-around, 500m ISD (D1), 10MHz FDD, carrier freq 2GHz, 25 UEs per cell, TU 3km/h, full-buffer traffic, no imbalance or correlation among antennas. 2x4 MIMO used for receive diversity gain of 1.7x compared to 2x2 MIMO, similarly 2x3 diversity provides a 1.3x gain over 2x2 MIMO 11

Leverage fiber backhaul installations Coordinated Multipoint (CoMP) for more capacity and better user experience Coordinated scheduling Coordinated beamforming Remote Radio Head (RRH) Central processing/scheduling (requires low latency fiber) Macro Same or different cell identity across macro and RRH Remote Radio Head (RRH) Note: CoMP enabled by TM10 transmission modes in the device and network. Picture focuses on downlink CoMP techniques, CoMP can also apply to the uplink 12

LTE R8 LTE R8 LTE Advanced with Range Expansion It s not just about adding small cells LTE Advanced brings even more capacity and enables hyper-dense HetNets 1 2.8X 1X 1.4X Small Cell Range Expansion (FeICIC/IC) Higher capacity, network load balancing, enhanced user experience, user fairness Macro Only Macro+ 4 Picos Data rate improvement 2 Macro+ 4 Picos 1 By applying advanced interference management to HetNets. 2 Median downlink data rate. Assumptions: 4 Picos added per macro and 33% of users dropped in clusters closer to picos (hotspots) : 10 MHz FDD, 2x2 MIMO, 25 users and 500m ISD. Advanced interference management: enhanced timedomain adaptive resource partitioning, advanced receiver devices with enhanced RRM and RLM1Similar gain for the uplink 13

Capacity scales with small cells deployed - thanks to advanced interference management (FeICIC/IC) ~37X ~21X ~6X +4 Small Cells ~11X +8 Small Cells +16 Small Cells Capacity scales with small cells added 1 LTE Advanced with 2x Spectrum added +32 Small Cells 1 Assumptions: Pico type of small cell, 10MHz@2GHz + 10MHz@3.6GHz,D1 scenario macro 500m ISD, uniform user distribution scenario. Gain is median throughput improvement, from baseline with macro only on 10MHz@2GH, part of gain is addition of 10MHz spectrum. Users uniformly distributed a hotspot scenario could provide higher gains. Macro and outdoor small cells sharing spectrum (co-channel) 14

LTE Advanced - Evolving and expanding into new frontiers Further improving LTE Advanced Aggregated Data Pipe Evolving carrier aggregation Further Enhanced HetNets More advanced antenna features and 256 QAM Higher capacity for Machine-to-machine and Smartphone signaling Enhanced Receivers for superior performance Device Interference cancellation Rel. 12 & beyond New Frontiers 700MHz to 3.8GHz ~3.5 GHz / ASA LTE Advanced in unlicensed spectrum LTE Broadcast going beyond mobile LTE Direct for device to device Higher bands & new licensing models (Authorized Shared Access) 15

Carrier aggregation evolution, Enhanced Hetnets 16

LTE Advanced carrier aggregation continues to evolve Leveraging all spectrum assets Across cells (Multiflow) (Supported in Rel. 12) FDD/TDD Aggregation (Supported in Rel. 12) Paired Unpaired Across licensed/ unlicensed (Specific band combinations to be defined) Traditional Licensed ASA/LSA Licensed Unlicensed (LTE) Anchor 3GPP continually defines band combinations Aggregated Data Pipe 17

MultiFlow Dual-cell connectivity across small cells and across macros and small cells Small cell Booster Macro Anchor Macro Improved offload to small cells Higher cell-edge data rates Robust mobility 18

Further enhancing HetNets performance User deployed 3G/4G Typically indoor small cells Operator deployed 3G/4G Indoor/outdoor small cells 1 4G Relays & Wireless Backhaul ENTERPRISE RESIDENTIAL METRO Multiflow Improve offload to small cells Dual-cell connectivity across cells Enhanced device receiver Data channel interference cancellation for even more gain LTE in unlicensed spectrum Better utilize 5GHz spectrum with unified LTE network & small cells LTE/Wi-Fi tight interworking Converged small cells with LTE & Wi-Fi 1 Such as relay and Pico/Metro/RRH small cells for hotspots. RRH= Remote Radio Heads, in addition Distributed Antenna Systems are used in HetNets 19

Enhanced receivers for superior LTE Advanced performance 20

Enhanced receivers offer better user experience & more capacity Interference Cancellation Interference Cancellation Sync ref. signal Common ref. signal Primary broadcast channel Data channel Rel. 10/11 Re. 12 Better user experience Higher data rates especially at cell-edges Higher network capacity Higher users data rate increases overall network capacity Enhanced performance for HetNets Even more beneficial in managing interference in small cell deployments 21

Throughout Throughout Enhanced receivers further improve HetNet performance Live demonstration at MWC 2014, utilizing our LTE Advanced test network in San Diego Higher network capacity 140 120 Macro 1 100 80 60 Rel. 10/11 Receiver Enhanced Receiver Pico 2 Pico 3 40 20 0 Pico 4 Pico 5 Increased cell-edge data rates 30 25 20 15 10 Rel. 10/11 Receiver Enhanced Receiver 5 0 22

Extending the benefits of LTE Advanced to unlicensed spectrum 23

Extending the benefits of LTE Advanced to unlicensed spectrum Better network performance Longer range and increased capacity Enhanced user experience Thanks to LTE Advanced anchor in licensed spectrum with robust mobility Ideal for small cells Unified LTE Network Common LTE network with common authentication, security and management. LTE in Licensed spectrum 700MHz to 3.8GHz LTE in Unlicensed spectrum 5 GHz Carrier aggregation Coexists with Wi-Fi Features to protect Wi-Fi neighbors 24

Leverages existing LTE standards, ecosystem and scale LTE transmitted according to unlicensed spectrum regulations, such as power levels 1 Large scale, global LTE deployments 268+ network launches in 100+ countries 1 LTE Advanced 3GPP R10 launched June 2013 2 LTE in unlicensed spectrum 3 for USA, Korea and China LTE Advanced 3GPP R10 Targets 5 GHz unlicensed bands Wi-Fi and LTE co-existence features 2 LTE in unlicensed spectrum everywhere Extend deployment to regions with Listen Before Talk (LBT) regulations Optimized waveform enabling LBT, carrier discovery and expanded uplink coverage Candidate for 3GPP R13 standard Common core network with common mobility, security, authentication and more. Ideal for small cells R10 Converged 3G/4G small cells with LTE for licensed and unlicensed spectrum as well as Wi-Fi Unified network for licensed and unlicensed spectrum 1 Per GSA as of as of Feb 5 th 2014. 2 With Carrier Sensing and Adaptive Transmission (CSAT) in the time domain. 25

Making LTE broadcast dynamic and extending to terrestrial TV 26

LTE broadcast is commercial Powered by Qualcomm Snapdragon processors 1 st World s 1st LTE Broadcast solution Gobi LTE Modem integrated into Snapdragon 800-800 LTE Advanced Qualcomm Snapdragon and Gobi are products of Qualcomm Technologies, Inc. Source: http://www.totaltele.com/view.aspx?id=485128 KT Corp launches world s first commercial LTE Broadcast service By Nick Wood, Total Telecom Monday 27, January 2014 South Korean operator to use embms technology to deliver mobile TV service to Samsung Galaxy Note 3 smartphones. KT Corp on Monday launched the world s first commercial LTE Broadcast service, delivering mobile TV content to Samsung Galaxy Note 3 users. Called Olleh LTE Play, the service is based on embms (evolved multimedia broadcast multicast services) solutions developed in 27

LTE broadcast Higher capacity even with fewer users Leveraging LTE infrastructure and spectrum Unicast LTE Broadcast 7X 3X 1.7X X X X 1 user/ cell 2 users/cell 5 users /cell Network capacity/throughput Source: Qualcomm Research; Simulation assumptions - 2GHz carrier frequency, 5MHz spectrum, 500m site-to-site distance, cluster embms with 19 sites MBSFN deployment (100% of carrier usage), comparison with unicast (based on average throughput) 28 is based on the same amount of resource allocation.

Dynamic switching to broadcast offers even more flexibility Users accessing same content on unicast Users moved to broadcast Event or demand driven Pre-scheduled (e.g. at stadium only during games) Based on demand (e.g. breaking news) Seamless transition Make-before break connection Fully transparent to user Part of Rel. 12 1 Dynamically switch between unicast and broadcast (based on operator configured triggers) 1 This feature is called Mood (Multicast operation on Demand) in Rel 12 29

Terrestrial TV service using LTE Broadcast Enabling broadcasters to reach mobile devices LTE Broadcast Single Frequency Network (SFN) for the whole coverage area - Using LTE sites/infrastructure LTE (Unicast) Broadcast TV LTE Broadcast on a dedicated spectrum Enhanced user experience in the Assisted Mode (e.g. On-demand content, interactivity ) Assisted Mode Stand-alone Mode Devices in Stand-alone or Assisted mode ~2x Higher capacity than today s broadcast (DVB-T/ATSC) - Opportunity to free-up spectrum for mobile broadband Current broadcast technology operates in Multi Frequency Network (MFN) mode with a frequency reuse of at least 4 with a spectrum efficiency of up to 4 bps/hz inside each cell. This corresponds to an overall spectrum efficiency of approx. 1bps/Hz. Whereas LTE-B operates in SFN over the entire coverage area with a spectrum efficiency of up to 2bps/Hz. 30

LTE Direct Operator-owned global platform for continuous proximity awareness 31

Designed for autonomous Always-ON discovery Licensed spectrum utilized for continuous proximity awareness DISCOVERY Up to 500m range LTE 20s 64ms LTE Discover 1000s of services in milliseconds Privacy sensitive Device based, connectionless discovery without location tracking Negligible LTE capacity impact <1% of uplink resources for thousands of services Source: Qualcomm simulations; Assumes 10MHz system 32

Operator platform that enables new mobile services Mobile Proximity and Discovery services at scale Operator owned LTE Direct platform Managed, owned, monetized by mobile operator Common discovery network Enables discovery horizontally across apps, OS, operators Expected to be in every Rel 12 device Part of 3GPP Release 12 standard 33

Utilizing higher bands & new licensing models (Authorized Shared Access) 34

ASA leverages underutilized spectrum for exclusive use Exclusive Use Incumbents (i.e., government) may not use spectrum at all times and locations Used in both macros and small cells Small cells can be closer to incumbent than macros 3G/4G Macro Base Station 3G/4G Small Cells Incumbent user Protects spectrum incumbents Binary use either incumbent or rights holder with protection zones Regular Multi-band Device 1 Incentive-based cooperation model Allows incumbents to monetize unused spectrum 1 No device impact due to ASA, just a regular 3G/4G device supporting global harmonized bands targeted for ASA. Carrier aggregation would be beneficial to aggregate new ASA spectrum with existing spectrum, but is not required. 35

ASA/LSA 1 Implementation underway in Europe and USA POLICY Endorsed by 28 EU member states Nov 13 REGULATORY Defined by CEPT in report published in Feb 14 2 for harmonizing 2.3 GHz 3 STANDARDS Specified by ETSI Currently working on requirements PROOF OF CONCEPT Demonstrated by many infra/device vendors; 2.3 GHz and 3.5 GHz demos at MWC Feb 14 OPERATOR INTEREST Trialed Live in Finland in Sep 13 Evaluation by NTIA Endorsed by 28 EU member states Nov 13 Proposed by FCC To make 3.5GHz 4 band dedicated to licensed shared access for mobile broadband 1 ASA has been named LSA (Licensed Shared Access) in the EU by the Radio Spectrum Policy Group; 2 3ECC Report 205; 3 3Draft ECC decision on harmonized technical and regulatory conditions for the use of the band 2300-2400 MHz for MFCN; 3GPP Band 40, 2.3-2.4 GHz; 4 Target 3.5 GHz in the US is 3550-3650 MHz 36

LTE Advanced - 1000x data challenge enabler Continue to evolve LTE: -- Multiflow, Hetnets enhancements -- Opportunistic HetNets LTE in unlicensed spectrum LTE Broadcast and LTE Direct Carrier Aggregation (TDD and FDD) Authorized Shared Access (ASA) Higher spectrum bands (esp. TDD) Hetnets with FeICIC/IC Full interference management New deployment models, e.g. neighborhood small cells More Small Cells is Key to 1000x 37

Qualcomm Technologies LTE advanced leadership Standards Leadership A main contributor to key LTE Advanced features Instrumental in driving interference cancellation and other Hetnets features Pioneering work on LTE Direct and LTE in unlicensed spectrum Industry-first Demos MWC 2012: Live Over-The-Air HetNet Demo with Mobility MWC 2013: Live OTA opportunistic HetNet Demo with VoIP Mobility. Authorized Shared Access (ASA) demo MWC 2014: Enhanced HetNets with datachannel interference cancellation Industry-first Chipsets from QTI World s 1 st LTE Advanced solution (Jun 13) First with LTE Broadcast (Jan 14) LTE Advanced cat 6 (300 Mbps) solution announced in Nov. 13 800 LTE Advanced MDM 9x35 LTE Advanced Qualcomm Snapdragon and Qualcomm Gobi are products of Qualcomm Technologies, Inc. World s 1 st LTE Advanced solution 300Mpbs (Cat 6) solution 38

LTE Advanced: Evolving & expanding into new frontiers 1 Brings carrier aggregation and its evolution led by Qualcomm Technologies 3 Extends benefits of LTE to unlicensed spectrum 2 Enables hyper-dense HetNets; Further gains with enhanced receivers 4 Expands LTE in to new frontiers device-to-device, Broadcast TV, higher bands & more 1000x mobile data challenge enabler 39

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