1. Introduction and Overview of Network and Telecommunications (contd.)

2. Review: Video: Warriors of the Net

3. Some Key Points Data is transmitted as packets.
Packets are handled by equipments at different layers.
Each layer has its own protocol to follow.
At each layer, information, or header, is added (or removed) based on the protocol before sending the packet to the lower (or higher) layer.

4. Why using “protocol layers”?

5. Organization of air travel
ticket (purchase)
baggage (check)
gates (load)
runway takeoff
airplane routing
ticket (complain)
baggage (claim)
gates (unload)
runway landing
airplane routing
Ticket
Baggage
Gate
Takeoff/Landing
Advantage of layering: information hiding and reuse
Airplane routing
airplane routing
Layers: each layer implements a service by
Perform certain actions within the layer
Using the services of the layer directly below it

6. Protocols and Layers
Protocols and layering is the main structure method used to divide up network functionality
Each instance of a protocol talks virtually to its peer using the protocol
Each instance of a protocol uses only the services of the lower layer

7. Internet protocol stack
Set of protocols in use in called a protocol stack
e.g., web server
e.g., web browser
e.g., HTTP

8. Internet protocol stack
Application: supporting network applications
FTP, SMTP, HTTP
Transport: process-process data transfer
TCP, UDP
Internet: routing of datagrams from source to destination IP
Link: data transfer between neighboring network elements
Ethernet, (WiFi), PPP
Physical: bits “on the wire”

9. TCP vs. UDP: Two Communication Paradigms
Stream
Message
Connection-oriented
Connectionless
1-1 communication
1-1, 1-many, many-many
Sequence of bytes
Sequence of messages
Arbitrary length transfer
Limited to 64K bytes
Widely used
Multimedia applications
Based on TCP (Guaranteed)
Built on UDP (Not Guaranteed)

10. Message (Connectionless) Transport In the Internet
UDP (message service) does not make any guarantees. A packet may be
Lost
Duplicated
Delayed
Delivered out-of-order

11. Why using message service?
No connection establishment
Get straight to the point
No connection state
A server can support more active clients simultaneously
Fine application-level control over what data is sent, and when

12. Some Examples TCP today: >95% Internet traffic
Application
TCP or UDP?
TCP
Remote terminal access
Web
File transfer
Streaming multimedia
UDP, TCP
Internet telephony
Name translation
Typically UDP
Remote file server
TCP today:
>95% Internet traffic
~75% on-demand and live streaming

13. Encapsulation
Encapsulation is the mechanism used to effect protocol layering
Lower layer wraps higher layer content, adding its own information (header) to make a new message for delivery
Like sending a letter in an envelope; postal service doesn’t look inside

14. <HTML><BODY>Hello World!</BODY></HTML>
HTTP message
TCP
HTTP message IP
TCP
HTTP message
TCP
HTTP message IP
802.11
Wire
802.11 IP
TCP
HTTP message IP
TCP
HTTP message
TCP
HTTP message
HTTP message
<HTML><BODY>HTML Example</BODY></HTML>

15. Another Illustration
Think of these nesting dolls:

16. Why Using Packets?
use the connection effectively and efficiently

17. Connections between Computers
Overhead Telephone and Telegraph Wires in Broadway, 1890
From Book of Old New York. Henry Collins Brown. 1913

19. Switch Model: Reducing the Mess
Analogy
Airport hubs

20. Tie-1 ISP: e.g., Sprint

21. Question
Why you fly, you can check a map to determine what cities are on the route.
However, there is no map of the internet, so how do you know what route a packet is taking?

22. An Analogy State College Philly NYC Boston Remote host: Jack
Local host: Alice

23. Traceroute
Widely used command-line tool to let hosts peek inside the network
On all OSes (tracert on Windows)
Provides delay measurement from source to router along end-end Internet path towards destination.

24. Traceroute Probe successive hops to find network path
sends 3 packets that will reach each router on path towards destination
Each router returns packets to sender
sender times interval between transmission and reply.
3 probes
3 probes
3 probes
Remote host: Jack
Local host: Alice

25. Traceroute
Technically, a hop is defined as the action that occurs when a packet “jumps” from one router to the next.
Remote host: Jack
Local host: Alice
1 hop
2 hop
3 hop
N-1 hop
N hop

26. Traceroute Question 1
How many computers (incl. local host, remote host, and intermediate routers) does this route have?

27. Traceroute Question 2
How many hops does this route have?

28. Traceroute Question 3
Remote host: Jack
Local host: Alice
1 hop
2 hop
3 hop
N-1 hop
N hop
For a route with N hops, how many computer does it have?

29. Traceroute Question 4
Remote host: Jack
Local host: Alice
1 hop
2 hop
3 hop
N-1 hop
N hop
Local host sends 3 packets to each computer on the route (incl. routers and remote host). If the route has N hops, how many packets does local host send in total?

30. Traceroute Question 5
Remote host: Jack
Local host: Alice
1 hop
2 hop
3 hop
N-1 hop
N hop
For a route with N hops, how many packets are forwarded by the router that is closest to the local host?

31. Traceroute Example 1 C:\> tracert allspice.lcs.mit.edu
1 20ms 25ms 15ms philadelphia4.t3.ans.net ( )
ms 120ms 140ms New-York2.t3.ans.net ( )
ms 280ms 260ms Cambridge1.bbnplanet.net ( )
ms 279ms 279ms Allspice.lcs.mit.edu ( )
3 delay measurements

32. Traceroute Question 6 C:\> tracert allspice.lcs.mit.edu
1 20ms 25ms 15ms philadelphia4.t3.ans.net ( )
ms 120ms 140ms New-York2.t3.ans.net ( )
ms 280ms 260ms Cambridge1.bbnplanet.net ( )
ms 279ms 279ms Allspice.lcs.mit.edu ( )
How many computers are there in this route? How many hops?

33. Traceroute Question 7 C:\> tracert allspice.lcs.mit.edu
1 20ms 25ms 15ms philadelphia4.t3.ans.net ( )
ms 120ms 140ms New-York2.t3.ans.net ( )
ms 280ms 260ms Cambridge1.bbnplanet.net ( )
ms 279ms 279ms Allspice.lcs.mit.edu ( )
How many packets are sent by local host?
How many packets are forwarded by New York (New-York2.t3.ans.net )?

34. Traceroute Question 8 C:\> tracert allspice.lcs.mit.edu
1 20ms 25ms 15ms philadelphia4.t3.ans.net ( )
ms 120ms 140ms New-York2.t3.ans.net ( )
ms 280ms 260ms Cambridge1.bbnplanet.net ( )
ms 279ms 279ms Allspice.lcs.mit.edu ( )
What’s the average round trip time form local host to Cambridge1.bbnplanet.net?

35. Traceroute Example 2 C:\> tracert www.oxford.ac.uk comcast
ms ms ms
ms ms ms c hsd1.pa.comcast.net [ ]
ms ms ms te sur02.statecollege.pa.pitt.comcast.net [ ]
ms ms ms be-3-ar03.lowerpaxton.pa.pitt.comcast.net [ ]
ms ms ms he ar01.pittsburgh.pa.pitt.comcast.net[ ]
ms ms ms be-7016-cr01.newyork.ny.ibone.comcast.net [ ]
ms ms ms ae12.edge1.NewYork2.level3.net [ ]
ms ms ms ae-4-4.car1.Manchesteruk1.Level3.net [ ]
ms ms ms ae-4-4.car1.Manchesteruk1.Level3.net [ ]
ms ms ms
ms ms ms ae29.erdiss-sbr1.ja.net [ ]
ms ms ms ae31.londpg-sbr1.ja.net [ ]
ms ms ms ae21.read-rbr3.ja.net [ ]
ms ms ms ae1.read-rbr2.ja.net [ ]
ms ms ms ae2.oxfo-rbr2.ja.net [ ]
ms ms ms Oxford-University-2.ja.net [ ]
ms ms ms csurb.backbone.ox.ac.uk [ ]
ms ms ms boucs.backbone.ox.ac.uk [ ]
ms ms ms boucs-lompi1.sdc.ox.ac.uk [ ]
ms ms ms aurochs-web-154.nsms.ox.ac.uk [ ]
Trace complete.
comcast
Level3: Trans-atlantic link
Janet: UK’s research network
oxford

36. Try it yourself Step 1: Start  Run  cmd Step 2: Trace route to
Somewhere in the U.S.
Somewhere outside U.S.
Discuss the results with classmates next to you
How may hops are there in the path?
What’s the average delay from you computer to the remote host?
How many networks does the path traverse?