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Introduction to xDSL Part III

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DSL leaves concept of using 4KHz analog line. Use UTP as general transmission line ... 2 bit PAM called 2B1Q (2 Bits in 1 Quat) 10 3 (Gray code) 11 1. 01 -1. 00 -3 ... – PowerPoint PPT presentation

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Title: Introduction to xDSL Part III

1
IntroductiontoxDSL Part III

Yaakov J. Stein
Chief ScientistRAD Data Communications

2
Introduction to xDSL

I Background
history, theoretical limitations, applications
II Modems
line codes, duplexing, equalization,
error correcting codes, trellis codes
III xDSL - What is x?
xI,A,S,V - specific DSL technologies
competitive technologies

3
Quick recap

Lecture 1
How did we get to where we want to go?
How far can we go?
Lecture 2
How can we get there?
Lecture 3
How can we get there?
What do we do when we get there?

4
Quick Review

DSL leaves concept of using 4KHz analog line
Use UTP as general transmission line
Rate limited by
line loss
thermal noise
NEXT crosstalk
FEXT crosstalk
RF ingress (AM broadcast, ham, etc.)
misc (splices, bridged taps, echo, filters, sync)

5
Introduction to xDSL III

Applications
Deployment topologies
IDSL
HDSL, HDSL2, SDSL
ADSL, G.lite
VDSL
competitors (cable modems,wireless)
HPNA

6
The Baby Bells had a problem ...

1993 cable TV companies started offering
10 Mbps Internet access
Internet seen as potential future market
RBOCs Plan HFC to every home by 1996!
This didnt happen
costs grew
regulatory problems
no standardization
LECs had lower operating expenses
What could be done?

7
Telco Alternatives

Fiber, coax, HFC
COST 10K-20K / mile
TIME months to install
T1
COST gt5K/mile for conditioning
TIME weeks to install
DSL
COST _at_ 0 (just equipment price)
TIME _at_ 0 (just setup time)

8
Analog (or V.90) modems
CO SWITCH
PSTN
UTP subscriber line
modem
CO SWITCH
modem
9
xDSL System Reference Model
CO SWITCH
PSTN
POTS-R
POTS-C
Analog modem
network/
UTP
ISP
POTS
POTS
PDN
SPLITTER
SPLITTER
DSLAM
xTU-R
router
WAN
xTU-C
x H, A, V, ...
10
VoDSL
CO SWITCH
PSTN
POTS-R
POTS-C
network/
UTP
ISP
POTS
POTS
PDN
SPLITTER
SPLITTER
xTU-R
DSLAM
router
xTU-C
WAN
11
Network Reference Model

PDN (Premises Distribution Network) is ethernet
or USB
WAN is typically ATM or FDDI (even though FDDI is
LAN protocol)
Internet is TCP/IP
HDSL connects to DACS and to CSU
Many interconnect possibilities (may impact modem
design)
full STM, full ATM, full packet network,
packet-ATM-packet, etc.
Example, FR WAN, ATM over UTP, Ethenet PDN
Modems should be cell pumps, not bit pumps
(also need CIF protocol to tunnel ATM through
Ethernet)

12
Splitter

Splitter separates POTS from DSL signals
Must guarantee lifeline POTS services!
Hence usually passive filter
Must block impulse noise (e.g. ring) from phone
into DSL
ADSLforum/T1E1.4 specify that splitter be
separate from modem
No interface specification yet (cant buy
splitter and modem from different vendors)
Splitter requires installation
Costly technician visit is the major impediment
to deployment
G.lite is splitterless ADSL

13
xDSL - Maximum Reach
14
Examples of Realistic Reach

More realistical design goals (splices, some
xtalk)
1.5 Mbps 18 Kft 5.5 Km (80 US loops)
2 Mbps 16 Kft 5 Km
6 Mbps 12 Kft 3.5 Km (CSA 50 US loops)
10 Mbps 7 Kft 2Km
13 Mbps 4.5 Kft 1.4 Km
26 Mbps 3 Kft 900 m
52 Mbps 1 Kft 300 m (SONET STS-1 1/3
STM-1)

15
xDSL flavors

16
xDSL flavors

17
ITU G.99x standards

G.991 HDSL (G.991.1 HDSL G.991.2 SHDSL)
G.992 ADSL (G.992.1 full rate G.992.2 G.lite
G.992.3,4,5 new)
G.993 VDSL
G.994 HANDSHAKE
G.995 GENERAL (INFO)
G.996 TEST
G.997 PLOAM
G.998 PNT (HPNA)

18
Some xDSL PSDs
PSD(dBm/Hz)
T1
IDSL
HDSL
HDSL2
ADSL

F(MHz)
19
Line Codes

PAM
IDSL, HDSL (2B1Q)
HDSL2 (with TCM and optionally OPTIS)
SDSL
QAM/CAP
proprietary HDSL/ADSL/VDSL
DMT
ADSL
G.lite
VDSL line code war is still raging (but QAM seems
to be winning)

20
T1/E1

DS1 rate
1 bit per symbol AMI
Half duplex on each UTP
Full duplex requires 2 UTP (4W)
Simple DSP
Linear equalization
Needs conditioning
Repeaters (every km)

21
IDSL

Original DSL (1980s)
160 Kbps in 80 KHz BW
resistance design reach (18Kft)
popular in Europe, but not US
2 bit PAM called 2B1Q (2 Bits in 1 Quat)
10 3 (Gray code)
11 1
01 -1
00 -3
alternative line code
4B3T (4 Bits in 3 Ternary symbols)

3
1
-1
-3
22
HDSL

Replace T1/E1 DS1 service
Use 2B1Q line code, DFE
Full duplex on each pair with echo cancellation
Full CSA without conditioning/repeaters
more complex DSP (250 MIPS)
ANSI 2 pairs for T1 (each 784 Kbps)
ETSI 1, 2, 3 or 4 pairs
Most mature of DSL technologies

23
HDSL vs T1(AMI)
T1 HDSL
24
HDSL - continued

HDSL is repeaterless T1/E1
Major application - multiline POTS
Reach is CSA (less than ADSL!)
Can add doublers to extend range
Other applications
PBX extension
digital local loop
campus networks
Internet

25
HDSL2, SDSL, SHDSL, OPTIS

Customers request HDSL service that is
single UTP HDSL
at least full CSA reach
spectrally compatible w/
HDSL, T1, ADSL, etc.
Variously called
HDSL2 (ANSI)
SDSL Symmetric DSL (ETSI)
SHDSL Single pair HDSL (ITU)
This is the DS1 service that will last!

26
OPTIS Overlapping PAM Transmission with
Interlocking Spectra

A solution that achieves these goals
16 level PAM with 517K baud rate
very strong (512 state, gt5 dB) TCM
1D for low (216 msec) latency (speech)
strong DFE
tailored spectra (fits between HDSL and T1)
partially overlapped (interlocking) spectra
folding (around fb/2) enhances SNR!
upstream bump for spectral compatibility

27
OPTIS - continued
28
OPTIS - continued
29
ADSL

Asymmetric - high rate DS lower rate US
Originally designed for video on demand
Almost retired due to lack of interest
but then came the Internet
Studies show DSUS should be about 101
full rate ADSL 512-640 kbps US, 6-8 Mbps DS
G.lite 512 Kbps US, 1.5 Mbps DS
ADSL could mean All Data Subscribers Living

30
Why asymmetry?

NEXT is the worst interferer stops HDSL from
achieving higher rates
FEXT much less (attenuated by line)
FDD eliminates NEXT
All modems must transmit in the SAME direction
A reversal would bring all ADSL modems down
Upstream(US) at lower frequencies and power
density
Downstream (DS) at high frequencies and power

31
Why asymmetry? - continued
PSD (dBm/Hz)
US
DS
F(MHz)
32
Echo cancelled ADSL

FDD gives sweet low frequencies to US only
and the sharp filters enhance ISI
By overlapping DS on US
we can use low frequencies and so increase reach
Power spectral density chart

33
ADSL - continued

ADSL system design criterion BER 10-12 (1 error
every 2 days at 6 Mbps)
Raw modem can not attain this low a BER!
For video on demand
RS and interleaving can deliver (error bursts of
500 msec)
but add 17 msec delay
For Internet
TCP can deliver
high raw delay problematic
So standard defines TWO framers
fast (noninterleaved ) and slow (interleaved)
buffers

34
ADSL standard

ITU (G.dmt) G.992.1, ANSI T1.413i2 standard
First ADSL data implementations were CAP
Standard is DMT
DMT allows approaching water pouring capacity
DMT is robust
DMT requires more complex processing
DMT may require more power

35
DMT

Discrete Multitone is a form of FDM (Frequency
Domain Multiplexing)
Discrete Multitone is a form of MCM (MultiCarrier
Modulation)
It uses many different carriers, each modulated
QAM
Each tone is narrow
low baud rate (long frame)
channel characteristics are constant over tone
Number of bits per tone chosen according to water
pouring
Put more bits where SNR is good

36
DMT - continued

DMT is OFDM (Orthogonalized FDM)
Carrier spacing is precisely baud rate
Center of tone is precisely the zero of all other
sincs
ICI minimized
ISI minimized by having a long interframe guard
time
DMT modem can be efficiently implemented using
FFT
DFT is mathematically equivalent to a bank of
filters
Filtering is equivalent to cyclic convolution
So use cyclic prefix rather than guard time

37
DMT - continued

frequency
time
38
ADSL DMT

Baud rate (and channel spacing) is 4.3125 KHz
US uses tones 8 - 32 (below 30 KHz reserved)
DS uses 256 tones (FDM from tone 33, EC from tone
8)

39
DMT misc.

bit handling ((de)framer, CRC, (de)scrambler, RS,
(de)interleaver)
tone handling (bit load, gain scaling, tone
ordering, bit swapping)
QAM modem (symbolizer, slicer)
signal handling (cyclic prefix insertion/deletion,
(I)FFT,
interpolation,
PAR reduction)
synchronization (clock recovery)
channel handling (probing and training, echo
cancelling, FEQ, TEQ)

40
RADSL

Rate Adaptive ADSL
Not variable rate (not small fast variations)
Increases percentage of useable lines
Fine for Internet access
but not for video on demand
Standard ADSL supports 32Kbps steps
RADSL provides management protocols

41
G.lite

ITU (G.lite) G.992.2, UAWG
ADSL compatible DMT compatible using only 128
tones
512 Kbps US / 1.5 Mbps DS
Still much faster than V.34 or V.90 modems
No splitter required!
Certain features removed for simplicity
simpler implementation (only 500 MIPS lt 2000 MIPS
for full rate)

42
New ADSLs

ITU has continued development of G.dmt.bis,
G.lite.bis
Should become G.992.3, G.992.4, G.992.5
ADSL2
Longer reach with higher rate (1.5 Km _at_ 12 Mbps)
4D 16-TCM constellations, Stronger RS FEC
Lower framing overhead (programmable 4-32Kbps
overhead)
Power cutback standby mode
Algo improvements (e.g. real-time tone
re-ordering, relocatable pilot tone)
ADSL
Uses more BW for higher bitrates for short
reaches
double BW (512 bins) - double speed (24 Mbps!)
Annex J
Symmetric 3 Mbps

43
VDSL

Optical network expanding (getting closer to
subscriber)
Optical Network Unit ONU at curb or basement
cabinet
FTTC (curb), FTTB (building)
These scenarios usually dictates low power
Rates can be very high since required reach is
minimal!
Proposed standard has multiple rates and reaches

44
VDSL - rate goals

Symmetric rates
6.5 4.5Kft (1.4 Km)
13 3 Kft (900 m)
26 1 Kft (300 m)
Asymmetric rates (US/DS)
0.8/ 6.5 6 Kft (1.8 Km)
1.6/13 4.5 Kft (1.4Km)
3.2/26 3 Kft (900 m)
6.4/52 1 Kft (300 m)

45
VDSL - Power issues

Basic template is -60 dBm/Hz from 1.1MHz to 20
MHz
Notches reduce certain frequencies to -80 dBm/Hz
Power boost on increase power to -50 dBm/Hz
Power back-off reduces VTU-R power so that wont
block another user
ADSL compatibility off use spectrum down to 300
KHz

46
VDSL - duplexing

In Japan and campus applications can operate TDD
(ping pong)
SDMT Synchronous DMT
(2 KHz frame can be heard in adjacent pairs or
hearing aids)
Rest of world PSTN only FDD is allowed
Can divide US and DS into 2 areas (e.g. ADSL) or
more
Need guard frequencies because of clock
master/slave problems
Zipper - large number of interleaved frequency
regions
(even on a bin by bin basis)

47
VDSL line code wars

VDSL Alliance VDSL Coalition
DMT QAM
MORE LESS
robust to noise power
capacity complex
spectral compatibility
expensive
IPR A/D bits
With no complexity constraints probably
equivalent

48
T1E1.4 draft T1.424

T1E1.4 has released a 3-part trial use draft
standard
Part 1 Common Specifications
Part 2 Single Carrier Modulation
Part 3 Multicarrier Modulation
Objective tests have been specified (VDSL
Olympics)
Test definition may determine results
SCM is NOT spectrally compatible with ADSL
Present SCM implementations are more mature
the tests should be of technology, not products
MCM may be more robust in certain noise settings
The trials should be finished by July-August 2003
ITU and IEEE are waiting for the results

49
G.994.1 (G.hs)

Handshaking
Universal flexible method for initialization
Includes
tone negotiation for capability identification
common mode identification
exchange of nonstandard information
line probing (line code dependent)
Currently integral part of ADSL and G.lite
Anticipated that future ITU DSL modems will
support as well

50
G.997 (PLOAM)

Physical Layer Operation Administration and
Maintenance
Includes
physical layer management (SNMP based)
configuration, fault and performance
administration
4 management interfaces
optional OAM channel
far end management
Currently integral part of G.992 (ADSL) family
Anticipated that future ITU DSL modems will
support as well

51
G.996.1 (G.test)

Universal testing procedure for xDSL modems
Finds margins in presence of
POTS signaling
impulse noise
cross-talk from other services
geographical position dependent test loops and
wiring models
Currently integral part of G.992 (ADSL) family
Anticipated that future ITU DSL modems will
support as well

52
G.bond

ISDN defined BONDING of 2B channels to one
128Kbps line
G.991.2 (SHDSL) Annex E has physical layer
bonding
ITU G.bond objectives
1) be higher layer agnostic
2) be backward compatible with the present 2-wire
G.shdsl Annex E solution
3) different rates on different pairs
4) be applicable to all DSL families, not just
SHDSL
5) have low latency and overhead (to support TDM)
6) support dynamic addition and removal of pairs
If succeeds no need for layer 2 aggregation
protocols
(ATM-IMA, MLFR, MLPPP, 802.3ad etc) with
high overhead, high latency, same rates for each
pair,
no dynamic addition/deletion support, etc.

53
cVoDSL

Standard VoDSL sends TDM over ATM layer
Channelized VoDSL reserves N 64Kbps channels
(N1..4)
PRO Implemented on-chip (no GW), higher voice
quality, lower delay
CON Consumes BW even if not used

54
Competitorsandnon-DSLtechnologies
55
G.998 (G.pnt,HPNA)

Studies show that about 50 of US homes have a PC
30 have Internet access, 20 have more than
one PC!
Average consumer has trouble with cabling
HomePNA de facto industry standard for home
networking
Computers, peripherals interconnect (and connect
to Internet?)
using internal phone wiring (user side of
splitter)
Does not interrupt lifeline POTS services
Does not require costly or messy LAN wiring of
the home
Presently 1 Mbps, soon 10 Mbps, eventually 100
Mbps!

56
HPNA

HPNA 1.0 (98Q3) has average data rate 1.0432 Mbps
Line code is PPM (pulse position modulation)
Each pulse is 4 cycles at 7.5 MHz (shaped)
time between pulses 3.27 msec lt t lt 6.07 msec
Can co-exist with full-rate ADSL and G.lite
HPNA 2.0 (ITU G.pnt) 10 - 32 Mbps
QAM line code
HPNA 3.0 up to 100 Mbps
Specification not yet finalized

57
Cable modems
CABLE MODEM
CMTS
CABLE MODEM
OPTICAL FIBER NODE
CATV HEADEND
COAXIAL AMPLIFIER
fiber
coax
CABLE MODEM
CABLE MODEM
58
Cable modems - continued