let’s get real! non-line-of-sight wireless backhaul for lte picocell deployments
DESCRIPTION
For more information, see: http://metrocells.blogspot.com/2013/02/non-line-of-sight-wireless-backhaul-for.htmlTRANSCRIPT
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Cambridge Wireless Small Cell SIG
31st January 2013
Let’s Get Real!
Non-Line-of-Sight Wireless Backhaul
for LTE Picocell Deployments
Peter Claydon
Managing Director, Airspan UK v1
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A definition of Small Cells…
• There are many different definitions
• This is ours (for the purpose of this presentation)
• Uses “official” Small Cell Forum use case names
• Three types of small cells
1. Home and Enterprise
• Indoor, Low Power (typically 100mW)
• “Traditional” femtocells
2. Metro
• Outdoor, open access
• Higher power (1W)
• Focus of this presentation
3. Rural - Micro and Compact Macro Cells
• All-in-One outdoor base stations
• Much higher power (2-10W), open access
• Optimized for non-traditional locations
(Rooftops, Sides of Buildings etc…)
HISILICON SEMICONDUCTOR HUAWEI TECHNOLOGIES CO., LTD. Page 7 Huawei Confidential
Comprehensive Suite of Flexible Backhaul Products
Flexible Assembly
AD
SL / VD
SL
FE / PO
E
Op
tical
MW
/ TDD
BH
Small Cell
Radio Transport
+
UE(TDD)
NLOS, PMP
eNB(TDD)
FDD
FDD
FDD
TDD FDD
FDD
FDD
Spectrum
In case of no wire line backhaul
xPON OLT
SFP
Copper
MicroWave
Optical
TDD Backhaul
ADSL/VDSL
FE / POE
Cable
Mobile Network Operators Demand a Portfolio of Backhaul Options Designed for Scenario
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Small Cell HetNets = Network Capacity Enhancement
• Small Cells will deliver huge network capacity increases…
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Macro-only
LTE Network
HetNet LTE
Network
Capacity Enhancement comes from
Aggressive Frequency Re-use
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Dynamic
Resource Block
Allocation
The Power of LTE-Advanced: eICIC and SON
• Enables aggressive deployment
of LTE small cells
• Allowing Time and Frequency
resource block re-use.
• Closely Coupled (Macros)
• Typically a Tri-Sectored Base
Station – sectors share the same
frequency. X2 communication over
Ethernet or internal messages
between sector RRMs
• Loosely Coupled (Small Cells)
• Auto-Optimizing and Configuring
cells that share the same spectrum
(i.e. N=1 re-use). X2
communications over wide-area
backhaul to other cells
All
Resource
Blocks
All
Resource
Blocks All
Resource
Blocks
Loosely Coupled: Omni
Cells at different locations
Closely Coupled:
Sectors at same cell location
Dynamic
Resource Block
Allocation
Frequency
Time
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Small Cells and Frequency Re-use: eICIC at Work
• Small cell capacity gains come from better frequency re-use.
• LTE-Advanced protocols map UEs to the optimal cell (Macro or Pico), i.e. with the best signal
conditions (better MCS and MIMO). Mapping is independent of RSSI (with Cell Range Extension).
• Small cells are typically “Buried in the clutter”, so that propagation is contained and extensive re-
use of frequencies can happen.
• LTE-Advanced eICIC and Almost Blank Sub-frames (ABS) features ensures potential areas of
interference between Macro-Pico, and Pico to Pico are “mapped out”.
Macro Cell Macro Cell
Pico Cells
Small Cells are deployed in locations that are generally Non-Line-of-Sight
from Macro Cells, or other Pico Cells to maximize capacity gains
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Small Cell Networks: Capacity Enhancement
• LTE-Advanced eICIC and SON technology can deliver large capacity gains with even limited
numbers of Pico cells
• Macro cell footprint DL traffic boosted from 33Mbit/s to >130Mbit/s (with 4 Picos) – in Busy Hour
• Actual gains vary significantly depending on number of Pico cells deployed per Macro cell,
location of Pico cells, Busy Hour, versus Non-Busy Hour traffic patterns.
0x 2x 4x 6x 8x
10x 12x 14x 16x 18x 20x
Downlink Uplink
Macro
Cell Edge
Median
Assumptions*:
N=1 reuse 10 MHz FDD
4 Pico cells per Macro cell
eICIC, SON, High Power
Macro, Hotspot Deployment
SON
* 3GPP TS 36.814, Macro ISD 1500m, Full Buffer Model, Even UE Distribution, Cell Range Extension (12dB), 10 MHz (FDD) at 2.6 GHz
4x Gains using 4 Pico Cell per Macro Cell in Same Spectrum Allocation
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Small Cell Backhaul Requirements
• Assumptions: LTE-A eICIC, Hot Spots Deployment, Urban Model
• Busy Hour vs. Non Busy Hour with statistical sharing of backhaul
• Typical Backhaul for LTE Small Cells is around 40 Mbit/s (for 10 MHz FDD)
• Non Busy Hour Pico backhaul traffic typically ~1.3 times Busy Hour
• Backhaul needed per Pico decreases as number of Pico increases
* 3GPP TS 36.814, Macro ISD 1500m, Full Buffer Model, Even UE Distribution, Cell Range Extension (12dB), 10 MHz (FDD) at 2.6 GHz
0
20
40
60
80
100
120
140
160
180
200
Macro Only 1 Pico 2 Pico 3 Pico 4 Pico
Busy Hour
Non Busy Hour
Average per Pico
Peak per Pico (90%)
Mb
it/s
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Summary
• eICIC, and SON are key features for building LTE Small Cell networks
• These allow aggressive frequency re-use when cells are optimally located
• Small cells will generally be located in NLOS locations
• They can’t see Macro Cells, and mostly can’t see other Pico cells (by design)
• Small cells typically require ~40 Mbit/s backhaul per node
• If backhaul is less than 40 Mbit/s overall network capacity gains reduce
These technical characteristics drive the
backhaul requirements for Small Cells
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Let’s Get Real! Outdoor Picocell Deployments
A variety of deployment locations
Side of Building Metal Scaffold
Poles
Rooftops Wooden
Telephone Pole
Street Lamps Low-rise cell
Towers
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Let’s Get Real! LTE Small Cell Deployment
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Let’s Get Real! LTE Small Cell Deployment
Containing LTE Small Cell Propagation
maximizes capacity gains
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Small Cell Backhaul Traffic
• Three types of traffic from a small cell
• Signaling and Management Traffic, S1 and X2 interfaces – Highest Priority,
Latency Sensitive, Mission Critical
• Synchronization Messages, 1588v2, Sync-E (assisting GPS), often critical
• Real-Time Services Traffic, Voice and Video, Cloud UI, Real-time Gaming etc…
• Non Real-Time Services Traffic, variety of types
• All LTE Traffic is classified using QCIs
• Each UE contains multiple traffic flows with different requirements
• VoLTE requires Real-Time, Low Latency support
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Ba
ck
ha
ul
Impact on QoS of contended backhaul…
• If backhaul is contented (in any way), the QoS
and service reliability delivered over the LTE Uu
interface becomes impaired.
• If the backhaul randomly introduces latency and/or
reduces the capacity allocated to service flows
(especially GBR), the service is negatively impacted.
• Therefore, any backhaul solution must ensure
that the LTE radio-interface QoS is respected
and maintained across the contented backhaul.
• Typically this requires a detailed understanding of the
LTE Air-Interface
• Not something that can easily be done using code-point
markings, or other simple packet marking (ToS bits)
• Any contention based scheduling must take LTE Air-
Interface QoS needs into account.
• Ensuring Signaling gets and Real-Time / GBR
service gets served first
LTE QoS must be supported by any contented
backhaul solution for LTE Small Cells
eNodeB
Traffic
Instantaneous
Backhaul
Capacity
Instantaneous
Offered Load
S1 a
nd X
2,
Sync, M
gm
t
Real-T
ime a
nd G
BR
Serv
ices
Non R
eal-T
ime a
nd
Non-G
BR
Serv
ices
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Wireless Backhaul Characteristics
• The capacity of “Ethernet based” wireless backhaul varies;
• Wireless has variable capacity by design
• Applies to both LOS and NLOS wireless solutions
• LOS capacity varies due to rain-fade
• P-MP backhaul shares it’s capacity over multiple nodes
• Takes advantage of statistical multiplexing
• Best when dimensioned using average, or mean traffic, not peak traffic
• Two Choices
• “Over provision” wireless backhaul to every small cell
• Ensure backhaul capacity always exceeds offered load. Economics are unattractive!
• LOS P-P links $,$$$’s per small cell (typically twice the cost of the small cell)
• Dimensioning using “average demand” using P-MP
• Makes economics attractive
• Implies support for QoS mechanisms in backhaul radio interface
LTE small cell deployments must solve
the QoS problem to be successful.
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Solution: Outdoor Picocell deployment with Fibre
• Typical deployment of 5 LTE Pico cells sharing a single Fibre connection
• Metro Ethernet service economically serves 5 LTE Pico Cells. Business case works…
Fibre
Uncontende
d 200 Mbit/s
Metro
Ethernet
NLOS NLOS NLOS NLOS
60Mbit/s
20Mbit/s
60Mbit/s
20Mbit/s
30Mbit/s
10Mbit/s
30Mbit/s
10Mbit/s 1
50
Mb
it/s
5
0M
bit/s
eICIC
Dynamic
Resource
Block
Allocation
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Solution: Picocells with P-P LOS and P-MP NLOS
• Deployment model mirrors the use of Fibre
• Backhaul comes from Macro cells sites
• Uses LOS P-P to a small cell with LOS to Macro cell
NLOS NLOS NLOS
60Mbit/s
20Mbit/s
60Mbit/s
20Mbit/s
30Mbit/s
10Mbit/s
eICIC
Dynamic
Resource
Block
Allocation
NLOS
30Mbit/s
10Mbit/s
Macro
Cell
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Fiber
NLOS Wireless
Backhaul
Coverage
P-MP NLOS Backhaul: Cooperative QoS
LTE Pico
Access
Coverage
LTE Pico
Access
Coverage
LTE Pico
Access
Coverage
P-MP NLOS
Backhaul Base
Station Node
LTE QCI
Scheduler
Information
Real-Time LTE
QCI Service Flow
Data
• In Cooperative QoS mode the Backhaul Scheduler maintains visibility of Pico scheduling
requirements for UEs (MSs), tracking QoS commitments on bandwidth, latency and priority
• In addition the Backhaul Scheduler also has visibility of the backhaul radio interface and it’s
interference environment.
• The scheduling by the Pico cells takes accounts of both requirements to deliver high performance over
the backhaul and end-to-end QoS over the 4G LTE or 4G WiMAX Pico access interface
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Let’s Get Real! AirSynergy: Airspan’s Small Cell
A compact, low power, multi-standard, carrier-class LTE eNodeB with
integrated backhaul
“Single Box, Optimised”
Form-Factor
Integrated High Capacity Backhaul
with Relay Capabilities
Self Optimizing
Access and Backhaul
Airspan | AirSynergy Gen2 | Environment visuals – initial image selection | 22 Feb 2012 | P.6
Environment Visuals – Example renderings Initial renderings indicating the potential level of visualisation
urban setting, visible, eye-level rural setting, invisible, 1k spacing
Airspan | AirSynergy Gen2 | Environment visuals – low res previews | 23 Feb 2012 | P.4
Environment Visuals – Rural 2 Low-res preview
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Let’s Get Real! Carrier Trial - Feeder Base
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Let’s Get Real! Carrier Trial - Feeder Terminal A
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Summary and Conclusions
• LTE small cells can dramatically increase the capacity of LTE networks
• The enabling technology for LTE small cell is cost effective backhaul
• Unless the backhaul costs are right, small cell deployment won’t happen.
• Outdoor LTE small cells will mainly be deployed in NLOS locations
• Requires NLOS Backhaul technology, as Fiber based solution uneconomic
• Supporting QoS across any backhaul technology necessary
There is a Small Cell Backhaul Solution!
Core of the solution is NLOS P-MP Technology
with QoS support augmented with Fibre and
P-P LOS Wireless Backhaul
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Demonstration of eICIC
Cell Range Extension & Almost Blank Subframes
The power of Cooperative QoS
Let’s Get Real!
See it for real
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MWC - Picocells
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MWC - Picocells with LTE-Advanced
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Come and see us
Hall 6 Booth #D90