1. ECEN5553 Telecom Systems Week #9 Read [17a] "Rapidly Recovering from the Catastrophic Loss of a Major Telecom Office" [17b] "How IT Leaders Can Best Plan for Disaster" [18] "All Optical Networking" Outline: 12 October (Remote DL) Exam #2: 24 October (Live & Local DL) No Later than 31 October (Remote DL) No Class Friday, 14 October (Fall Break)

2. Outlines Received due 12 October (remote)
91 %

3. Network Used for Numerical Results to follow...
OC-3 Access 2
Voice Switch/
Gateways 1
Routers B
Voice Switch/
Gateways 3 4
OC-12
VoIP Backbone A
G.729 Coders.
MPLS could nail down paths.
20 msec end-to-end propagation delay

4. 150 msec End-to-End Delay 1 Frame per packet
Voice Coding Delay (.015) + Packet Assembly Delay (1*.010)
+ End-to-End Propagation Delay (.020) + Service Times + worst case Queuing Delays at the voice source and all intermediate packet switches + Receiver De-Jitter Buffer Delay + Voice Decoding Delay (.010)
= 55 msec
95 msec to spend - trunks can be heavily loaded
But most bits moved are overhead (47 out of 57B).

5. Gateway A to Gateway B Path
Time
Packet M
Packet 1
Packet 4M
M Packets
Packet 4M
Worst Case Delivery
Packet M
Packet 1
IAT
Packet 1
Packet 1
Packet 1
Our Packet
Distance
GA R R R GB
OC OC OC OC-3

6. 150 msec End-to-End Delay 5 Frames per packet
Voice Coding Delay (.015) + Packet Assembly Delay (5*.010)
+ End-to-End Propagation Delay (.020) + Service Times + worst case Queuing Delays at the voice source and all intermediate packet switches + Receiver De-Jitter Buffer Delay + Voice Decoding Delay (.010)
= 95 msec
55 msec to spend
Optimal for this example.

7. 150 msec End-to-End Delay 10 Frames per packet
Voice Coding Delay (.015) + Packet Assembly Delay (10*.010)
+ End-to-End Propagation Delay (.020) + Service Times + worst case Queuing Delays at the voice source and all intermediate packet switches + Receiver De-Jitter Buffer Delay + Voice Decoding Delay (.010)
= 145 msec
5 msec to spend - Trunks can't carry much traffic
But traffic carried is 2/3 voice (100 out of 147B).

8. 150 msec End-to-End Delay 11 Frames per packet
Voice Coding Delay (.015) + Packet Assembly Delay (11*.010)
+ End-to-End Propagation Delay (.020) + Service Times + worst case Queuing Delays at the voice source and all intermediate packet switches + Receiver De-Jitter Buffer Delay + Voice Decoding Delay (.010)
White Items = 155 msec
0 msec to spend
Impossible to meet delivery specification.

9. Voice Calls Possible Over an OC-12 Trunk (G.729 Fixed Rate Coder)
40000
100 msec
150 msec
30000
Trunk Voice calls supportable
20000
POTS can
support
8,192 calls
on an
OC-12
10000 1 2 3 4 5 6 7 8 9 10 11
Number of Frames per Packet

10. G.729 Variable Rate Coder with Silence Suppression
On a typical interactive conversation… A Specific Voice is Active 40% of time Coder generates 8 Kbps
Voice is Quiet 60% of time Transmit 0 Kbps
Average of 3.2 Kbps generated per simplex call

11. 4*3/2 = 6 Links for this example.
Full Mesh CO CO CO CO
N(N-1)/2 Links
4*3/2 = 6 Links for this example.

12. One connection per Central Office.
Hierarchical CO CO TO CO CO
One connection per Central Office.

13. CO Connectivity CO TO CO TO CO CO Hierarchical Direct Connect
2nd Parallel Hierarchical
Minimum of two
diverse routes out
of Central Office.

14. POTS Connectivity Small Cities have a CO Big Cities have CO’s
Hierarchical system, add
High Usage Direct Lines between CO’s
Tandem (Trunk-to-Trunk) Switches
Minimum of two physically separate routes out of all switches desired
Best compromise of cost & reliability

15. POTS
Items in a typical wired phone: microphone & speaker hybrid dialing circuitry (DTMF) on/off hook switch ring circuitry
Items in a typical CO: crosspoint switch hybrids A/D & D/A converters echo cancelers TDM or VoIP

16. Legacy Wired Phone Speaker Ring Circuitry On Hook Hybrid Off Hook
Dialing
Circuitry
Wall
Socket
Microphone
4 Wire
2 Wire

17. Home Phone Speaker Inbound Audio Ring Circuitry On Hook Hybrid Off
Dialing
Circuitry
Wall
Socket
Microphone
4 Wire
2 Wire

18. Home Phone Speaker Sidetone Ring On Circuitry Hook Outbound Audio
Hybrid
Outbound Audio
Off
Hook
Dialing
Circuitry
Wall
Socket
Microphone
4 Wire
2 Wire

19. One Wire Speaker Microphone Earth Ground
To get audio out of speaker, need a closed path to get a voltage drop across the speaker inputs
Need two 'wires' to get a voltage drop across a speaker
one wire can be an actual wire
second 'wire' can be the earth
Very Susceptible to static

20. Two Wires This configuration provides one-way commo Speaker Microphone
Resistant to static
Susceptible to EM interference over long distances
Twisting the wires slashes interference Used widely after 1891
This configuration provides one-way commo
Need another mic, speaker, & 2 more wires

21. Two Wires
Speaker
Hybrid
Hybrid
Hybrids allow Telco Two Wire lines to carry both outbound and inbound traffic
short distances (local loop)
Two wire local loops, instead of 4 wire
saves $$ on cable plant

22. Four Wires Easier to amplify traffic moving one direction
Microphone
Speaker
Amp
Amp
Speaker
Microphone
Easier to amplify traffic moving one direction
Telco Four Wire lines
2, one-way, 2 wire connections
Long distance

23. Dual Tone Multifrequency

24. POTS Connectivity (1920) Copper Local Loop Copper Local Loop Copper
Long
Haul CO CO
Phone
Phone
4 Wire
2 Wire
4 Wire
2 Wire
4 Wire
Analog

25. POTS Connectivity (1970) Copper Local Loop Copper Local Loop Copper
Long
Haul CO CO
Phone
Phone
4 Wire
2 Wire
4 Wire
2 Wire
4 Wire
Analog
Digital TDM
64 Kbps
Analog

26. POTS Connectivity (1990) Copper Local Loop Copper Local Loop Fiber
Optic
Trunk CO CO
Phone
Phone
4 Wire
2 Wire
‘4 Wire’
2 Wire
4 Wire
Analog
Digital TDM
64 Kbps
Analog

27. Simplified Central Office Switch
Space
Switch
TDM
deMux
D/A
Local Loops
Echo
Canceler
Hybrid
TDM
Mux +
A/D
2 Wire
T1 Line
4 Wire
Analog
Digital

28. Simplified CO-to-CO connectivity
Space
Switch
TDM
deMux
D/A
Local Loops
Echo
Canceler
Hybrid +
A/D
TDM
Mux
Space
Switch
TDM
deMux
D/A
Local Loops
Echo
Canceler
Hybrid +
A/D
TDM
Mux

29. The Legacy Phone System...
Parts are 4 wire (headset and long haul)
4 wire = two unidirectional simplex signals
simplex signals make amplification a lot easier
Parts are 2 wire (local loop)
2 wire = one bi-directional full duplex signal
Turn-of-the-century decision to save $$$ and go 2 wire on local loops
Parts are analog (phone & local loop)
About 70% of U.S. Local Loops are copper all-the-way
Parts are digital (long haul, most CO switches, some local loops)
About 20-30% of U.S. Local Loops use Digital Loop Carriers