source: zahid ghadialy, 5g: an advanced introduction“ (slides)

1Source: Zahid Ghadialy, "5G: An Advanced Introduction“ (slides)

Background: Cellular network technologyOverview

1G: Analog voice (no global standard …)

2G: Digital voice (again … GSM vs. CDMA)

3G: Digital voice and data• Again ... UMTS (WCDMA) vs. CDMA2000 (both CDMA-based)

• and … 2.5G: EDGE (GSM-based)

4G: LTE, LTE-Advanced …• OFDM (OFDMA for downlink and SC-OFDM for uplink)

5G …

Trends Advanced networks (SDN, NVF), everything on cloud, immersive

experience, tele presence, massive connectivity, D2D, ...

More data, packet-based switching, shared channel, directional (spatial reuse), multi-antenna, etc.

Other goals: Seamless with other technologies, QoS for multimedia, etc.

2

BSCBTS

Base transceiver station (BTS)

Base station controller (BSC)

Mobile Switching Center (MSC)

Mobile subscribers

Base station system (BSS)

Legend

2G (voice) network architecture

MSC

Public

telephone

network

GatewayMSC

G

7-3Wireless and Mobile Networks

3G (voice+data) network architecture

radionetwork controller

MSC

SGSN

Public

telephone

network

GatewayMSC

G

Serving GPRS Support Node (SGSN)

Gateway GPRS Support Node (GGSN)

Public

Internet

GGSN

G

Key insight: new cellular data

network operates in parallel

(except at edge) with existing

cellular voice network

voice network unchanged in core

data network operates in parallel

7-4Wireless and Mobile Networks

radionetwork controller

MSC

SGSN

Public

telephone

network

GatewayMSC

G

Public

Internet

GGSN

G

radio access networkUniversal Terrestrial Radio

Access Network (UTRAN)

core networkGeneral Packet Radio Service

(GPRS) Core Network

public

Internet

radio interface(WCDMA, HSPA)

3G (voice+data) network architecture

7-5Wireless and Mobile Networks

Code Division Multiple Access (CDMA)

used in several wireless broadcast channels (cellular, satellite, etc) standards

unique “code” assigned to each user; i.e., code set partitioning

all users share same frequency, but each user has own “chipping” sequence (i.e., code) to encode data

encoded signal = (original data) X (chipping sequence)

decoding: inner-product of encoded signal and chipping sequence

allows multiple users to “coexist” and transmit simultaneously with minimal interference (if codes are “orthogonal”)

6

CDMA Encode/Decode

slot 1 slot 0

d1 = -1

1 1 1 1

1- 1- 1- 1-

Zi,m= di.cm

d0 = 1

1 1 1 1

1- 1- 1- 1-

1 1 1 1

1- 1- 1- 1-

1 1 11

1-1- 1- 1-

slot 0

channel

output

slot 1

channel

output

channel output Zi,m

sendercode

data

bits

slot 1 slot 0

d1 = -1

d0 = 1

1 1 1 1

1- 1- 1- 1-

1 1 1 1

1- 1- 1- 1-

1 1 1 1

1- 1- 1- 1-

1 1 11

1-1- 1- 1-

slot 0

channel

output

slot 1

channel

outputreceiver

code

received

input

Di = S Zi,m.cm

m=1

M

M

7

CDMA: two-sender interference

8

Practical chipping codes …

9

Orthogonal even under offset? No synchronization … Random sequence; high probability low cross-correlation

Different chip lengths? different rates, take advantage of silence, more calls

radionetwork controller

MSC

SGSN

Public

telephone

network

GatewayMSC

G

Public

Internet

G

3G versus 4G LTE network architecture

GGSN

radio access networkUniversal Terrestrial Radio

Access Network (UTRAN)

Evolved Packet Core

(EPC)

MME

Public

Internet

P-GW

G

S-GW

G

HSS

3G

4G-LTE

7-10Wireless and Mobile Networks

4G: differences from 3G

all IP core: IP packets tunneled (through core IP network) from base station to gateway

no separation between voice and data – all traffic carried over IP core to gateway

radio access networkUniversal Terrestrial Radio

Access Network (UTRAN)

Evolved Packet Core

(EPC)

Public

Internet

P-GW

G

S-GW

G

UE(user element)

eNodeB(base station)

Packet data networkGateway(P-GW)

Serving Gateway(S-GW)

data

MMEHSS

Mobility Management Entity (MME)

Home Subscriber Server(HSS)(like HLR+VLR)

7-11Wireless and Mobile Networks

Some example responsibilities eNodeB

Admission control and congestion control

Scheduling and allocation of resources to UEs

State transition: IDLE to CONNECTED

Control mobility in connected mode

Buffering of data during handover

MME Handle mobility + maintain context in IDLE mode

Bearer management for UE

S-GW Mobility anchor for data bearers

Buffer downlink data when UE in IDLE mode

P-GW Allocate IP for UE

Maps packets into different QoS-based bearers 12

Radio+Tunneling: UE – eNodeB – PGW

7-13Wireless and Mobile Networks

tunnellink-layer radio net

UEeNodeB

S-GWG

P-GWG

IP packet from UE encapsulated in GPRS Tunneling Protocol (GTP) message at ENodeB

GTP message encapsulated in UDP, then encapsulated in IP. large IP packet addressed to SGW

Quality of Service in LTE

QoS from eNodeB to SGW: min and max guaranteed bit rate

QoS in radio access network: one of 12 QCI values

7-14Wireless and Mobile Networks

LTE and LTE-Advanced

15

ITU, IMT-advanced, 3GPP, and LTE-Advanced ... All traffic is IP-based Base station called enhanced NodeB, eNodeB or eNB

UE

Internet

LTE and LTE-Advanced

16

ITU, IMT-advanced, 3GPP, and LTE-Advanced ... All traffic is IP-based Base station called enhanced NodeB, eNodeB or eNB

UE

InternetRN

LTE and LTE-Advanced

17

ITU, IMT-advanced, 3GPP, and LTE-Advanced ... All traffic is IP-based Base station called enhanced NodeB, eNodeB or eNB

RN

UE

Internet

Evolved packet core

MME HSS

SGW PGW

Data traffic

LTE and LTE-Advanced

18

Relays HetNets etc. Carrier aggregation Downlink (OFDMA) vs uplink (SC-OFDM)

RN

UE

Internet

Evolved packet core

MME HSS

SGW PGW

Data traffic

LTE downlink (OFDMA-based)

19

Data symbols are independently modulated and transmitted over a high number of closely spaced orthogonal subcarriers.

Available modulation schemes for E-UTRA downlink: QPSK, 16QAM, and 64QAM (with 2, 4 , and 6 bits/symbol, respectively)

OFDM signal is generated using Inverse Fast Fourier Transform (IFFT) digital signal processingƒ

Figure from:3GPP TR 25.892; Feasibility Study for Orthogonal Frequency Division Multiplexing (OFDM) for UTRAN enhancement (Release 6)

20

Time domain structure: 10 ms frame consisting of 10 subframes of length 1 ms Each subframe consists of 2 slots of length 0.5 ms Each slot consists of 7 OFDM symbols (6 symbols in case

of extended CP)

ƒ Resource element (RE) One subcarrier during one OFDM symbol

ƒ Resource block (RB) 12 subcarriers during one slot (180 kHz × 0.5 ms)

Figure from: S. Parkvall, “LTE – The Global Standard for Mobile Broadband”, presentation, Ericsson Research

21

Scheduling decisions done in the base station Scheduling algorithm is a vendor-specific, but

typically takes into account Radio link quality situation of different users Overall interference situation Quality of Service requirements Service priorities, etc.

Uplink

22

Downlink vs uplink

23

Parallel transmission on large number of narrowband subcarriers

Avoids own-cell interference

Robust to time dispersion ƒ Bad power-amplifier

efficiency

Single carrier properties Better battery lifetime at

phones/sender (reduced power-amplifier power)

More complexity at receiver (equalizer needed)

Lower throughput

Multi-antenna (*slide from Ericsson)

24

Beamforming

25

Advantages: - Beam towards user- Strong receive signal- Save transmit power (by sending

same signal at lower power)- Less interference

Multi-antenna examples

26

Spatial diversity - Different antennas see “outages” at

different times- Multiple paths to receiver - Path lengths d1 and d2- Multi-path fading: Small movements

make big difference …- “Outage” with probability p- M independent antennas send same

signal: at least on success 1-pM.

Spatial multiplexing

Determine the time delay to locations of users and adjust phase accordingly …

27

y = H s + n

s’ = H-1 y

Note:

- H based on channel

estimation (fading) using

known reference of pilot

signal

- Stability depends on

condition number of H

- Want cond(H) close to 1

- Decomposition methods,

rather than pure inversion

Evolved Multimedia Broadcast/Multicast Service (eMBMS) in LTE-advanced

28

Evolved Multimedia Broadcast/Multicast Service (eMBMS) in LTE-advanced

Separation of control plane and data plane

29

Image from: Lecompte and Gabin, Evolved Multimedia Broadcast/Multicast Service (eMBMS) in LTE-Advanced: Overview and Rel-11 Enhancements, IEEE Communications Magazine, Nov. 2012.

Evolved Multimedia Broadcast/Multicast Service (eMBMS) in LTE-advanced

MBMSFN and use of services areas

30

Image from: Lecompte and Gabin, Evolved Multimedia Broadcast/Multicast Service (eMBMS) in LTE-Advanced: Overview and Rel-11 Enhancements, IEEE Communications Magazine, Nov. 2012.

Some words about 5G

Advanced network (e.g., SDN, NVF, context-aware, content-aware ...)

Millimeter waves (open up new high-frequency spectrum)

Multi-RAT (Radio Access Technology)

Small cells (mini-base stations, e.g., every 250m)

Massive MIMO (100s of ports)

Beamforming (efficient per-device delivery routes)

Full duplex (on same frequency)

Advanced D2D

… 31

Use-case-driven requirements …

32Source: Zahid Ghadialy, "5G: An Advanced Introduction“ (slides)

Use-case-driven requirements …

33Source: Zahid Ghadialy, "5G: An Advanced Introduction“ (slides)

High data rates

High densityUltra reliable +

Low latency

… wish list …

34Source: Zahid Ghadialy, "5G: An Advanced Introduction“ (slides)

5G goals/targets/requirements ...

35Source: Zahid Ghadialy, "5G: An Advanced Introduction“ (slides)

More slides …

36

Overview

37Image: http://www.ltehandbooks.com/2015/09/lte-radio-interface-ofdmofdmasc-fdma.html

Functional split of major LTE components

holds idle UE infoQoS enforcement

handles idle/active UE transitionspages UEsets up eNodeB-PGW tunnel (aka bearer)

7-38Wireless and Mobile Networks