Market Entry Benchmark of Wired and Wireless … · Market Entry Benchmark of Wired and Wireless...
Transcript of Market Entry Benchmark of Wired and Wireless … · Market Entry Benchmark of Wired and Wireless...
Market Entry Benchmark of Wired and Wireless Technologies with Projections
Source: M. Dècina, 2014, based on data by Bell Labs, G. Fettweis, and others
DSL Access
1Kbit/s
10Kbit/s
100Kbit/s
1Mbit/s
10Mbit/s
100Mbit/s
1Gbit/s
10Gbit/s
100Gbit/s
1Tbit/s
10Tbit/s
100Tbit/s
1Pbit/s
1995 2000 2005 2010 2015 2020 2025 2030 2035
DSL Access WLAN Access Cellular Access
Optical Access Optical Backbone
560 Tbit/s Capacity Limit
1,300-1,620 nm Band
Optical Backbone
Optical Access
WLAN Access
Cellular Access
GPON
10GPON
WDM-PON
NG-PON2
GSM GPRS
3G- Edge
HSDPA
HSPA
LTE
LTE Advanced
LTE Beyond
ISDN
ADSL
ADSL2+ VDSL2
Vectoring
802.11
802.11b
802.11ag 802.11n
802.11ac/ad
Multimode
G.Fast 5G
DEIB–Politecnico di Milano Maurizio Dècina, Evolving Telecom Scenarios, 2017 1
NFV Orchestration Architecture
• Orchestration Platform • Platform to mechanize
management of the life cycle of Virtual Network Functions
• It is composed by several modules, to be offered by different vendors
• Virtual Network Functions • Set of virtual machines
implementing network functions and/or virtualized services
• Infrastructure • Geographically distributed domain
• Includes physical and virtual resources made available by virtualization layer
OSS / BSS
PoP PoP
Servers Switching Storage
PoP
Infrastructure
Physical Topology
VNF
VNF
VNF
VNF
Virtual Network Functions
Logical Topology
Orchestrator
Virtualized Infrastructure
Manager
VNF Manager(s)
Orchestration Platform
Maurizio Dècina, Evolving Telecom Scenarios, 2017 2 DEIB–Politecnico di Milano
Source: ETSI, 2014 ZOOM – Zero-touch Orchestration, Operations and Management
Cloud RAN Architecture: Fronthauling & Backhauling
DEIB–Politecnico di Milano Maurizio Dècina, Evolving Telecom Scenarios, 2017 3
Laye
r-3
Laye
r-2
Syn
c.
Bas
eban
d
Rad
io
RF
Am
p.
Legacy Base Station backhaul
Traditional Architecture
Remote site
Coax Cable
Distributed Architecture (partial centralization)
Distributed Architecture (full centralization)
CPRI (Common Public Radio Interface)
BaseB .
Radio
RF Amp .
BBU
backhaul
Remote site
RRH
Central Office
Fronthauling
(100m → 10 km)
CPRI
Laye
r-3
Laye
r-2
Syn
c.
Radio
RF Amp .
BBU
backhaul
Remote site
RRH
Central Office
Fronthauling (100m → 10 km)
CPRI Edge Computing: BTS Virtualization, Hetnets, …
Cost of LTE GByte in North America 2014-2020
DEIB–Politecnico di Milano Maurizio Dècina, Evolving Telecom Scenarios, 2017 4
Source: Bell Labs, 2016
IoT Market Applications
Massive IoT
Transport & Logistics Fleet management
Asset tracking
Agricolture Agricolture & cattle
monitoring
Environment Monitoring
(climate, water, air, noise,…)
Industry Process monitoring
& control Vending machines
People Wereable sensors Child/animals tracking Healt care monitoring
Smart City Smart biking Smart ligthing Parking sensors
Public Enterprise Smart metering Capillary network
Smart Building Smoke detectors Alarms Domotics
Mission critical
IoT Industry Remote control Factory automation Collaborative robots
Person-object interaction Immersive augmented reality Immersive gaming, Tactile internet
Security Goods & people protection Device to device, 3D – Drones Environment protection: earthquake/flooding
Automotive V2I, V2V, V2P, V2C Car entertainment Traffic control
Medicine Remote surgery E-health: life critical Biomedical sensing
Public Enterprise Smart grid automation Video surveillance
High availability High reliability
Low latency High capacity
Low cost Low power Low capacity High number of devices
Low Power solutions
High-reliability, Low Latency solutions
DEIB–Politecnico di Milano Maurizio Dècina, Evolving Telecom Scenarios, 2017 5
Source: Ericsson, 2015
IoT Communications Protocols
DEIB–Politecnico di Milano Maurizio Dècina, Evolving Telecom Scenarios, 2017 6
Source: A. Capone, Politecnico di Milano, 2016
LPWA Cellular like
Cellular eats IoT!
Diversified Challenges and Gaps to Reach 5G
DEIB–Politecnico di Milano Maurizio Dècina, Evolving Telecom Scenarios, 2017 7
Network Architecture
Slicing Ability
Required
Connections
1,000K Connections
Per km2
Mobility
500km/h
High-speed Railway
Throughput
10Gbps
Per Connection
Latency
1 ms
E2E Latency
5G
100Mbps 10K 350Km/h 30~50ms Inflexible
LTE G
AP
30~50x 100x 100x 1.5x NFV/SDN
Challenges because many of these requirements are conflicting
Source: Huawei, 2016
5G Application Clusters
DEIB–Politecnico di Milano Maurizio Dècina, Evolving Telecom Scenarios, 2017 8
Source: ITU, 2015
eMBB
mMTC uMTC
• Full Virtualization (SDN/NFV)
• Heterogeneous Networks
• Adaptive Radio Interface (multiple RATs)
• New Radio Spectrum (mmWave)
5G Application Verticals
DEIB–Politecnico di Milano Maurizio Dècina, Evolving Telecom Scenarios, 2017 9
Mobile Edge Computing: Connected Car Scenario
DEIB–Politecnico di Milano Maurizio Dècina, Evolving Telecom Scenarios, 2017 10
Source: ETSI, 2016
5G Network Architecture
DEIB–Politecnico di Milano Maurizio Dècina, Evolving Telecom Scenarios, 2017 11
Source: NGMN 5G White Paper, 2015
5G Network Slicing
DEIB–Politecnico di Milano Maurizio Dècina, Evolving Telecom Scenarios, 2017 12
Source: NGMN 5G White Paper, 2015
Adaptive (Software Defined) Radio Interface
DEIB–Politecnico di Milano Maurizio Dècina, Evolving Telecom Scenarios, 2017 13
Source: Huawei, 2016
Multiple RATs
Beam Forming & Massive MIMO
DEIB–Politecnico di Milano Maurizio Dècina, Evolving Telecom Scenarios, 2017 14
Source: Keysight Technologies, 2016
More antennas than user equipment in a single cell? - 64 antennas to start up, than grow to hundreds