ee 122: introduction to communication...
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EE 122: Introduction ToCommunication Networks
Fall 2007 (WF 4-5:30 in Cory 277)
Vern Paxson
TAs: Lisa Fowler, Daniel Killebrew & Jorge Ortizhttp://inst.eecs.berkeley.edu/~ee122/
Materials with thanks to Jennifer Rexford, Ion Stoica,and colleagues at Princeton and UC Berkeley
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Some Questions & Answers• Q: Is the class full or can I enroll?
• A: Class size: increased!Welcome to Daniel Killebrew,our new TA:
• New section added: M 4-5PM, 299 Cory–But not next week (holiday)–Do attend one of the other sections next week (socket
programming)
• Q: Will the class be webcast?
• A: No.
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Goals for Today’s Class
• Type of Networks–And the key concept of multiplexing
• What’s a Protocol?
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What Global (non-digital)Communication Network Do You
Use Every Day?
Roughly speaking, how does it work?
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What’s Another Such NetworkThat You Use Every Day?
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• Communication networks can be classified based onthe way in which the nodes exchange information:
Taxonomy of Communication Networks
Commun ic a t io nNe t wo rk
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• Communication networks can be classified based onthe way in which the nodes exchange information:
Taxonomy of Communication Networks
Commun ic a t io nNe t wo rk
Bro a d c a s tComm un ic a t io nNe t wo rk
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• Information transmitted by any node isreceived by every other node in the network– Examples?– Usually in LANs (Local Area Networks)
E.g., Ethernet (classical), WiFi E.g., lecture!
• What problems does this raise?• Problem #1: limited range.• Problem #2: privacy of communication• Problem #3: coordinating access to the shared
communication medium (Multiple AccessProblem)
Broadcast Communication Networks
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• Communication networks can be classified based onthe way in which the nodes exchange information:
Taxonomy of Communication Networks
Commun ic a t io nNe t wo rk
Swit c he dComm un ic a t io nNe t wo rk
Bro a d c a s tComm un ic a t io nNe t wo rk
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• Information transmitted along a path ofintermediary nodes (“switches” or“routers”)
• Basic issue: how the switches figure outthe next hop along the path
Switched Communication Networks
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• Communication networks can be classified based onthe way in which the nodes exchange information:
Taxonomy of Communication Networks
Commun ic a t io nNe t wo rk
Swit c he dComm un ic a t io nNe t wo rk
Bro a d c a s tComm un ic a t io nNe t wo rk
Circ u it -Swit c he dComm un ic a t io nNe t wo rk
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Circuit Switching (e.g., Phone Network)• Establish: source creates circuit to destination
– Nodes along the path store connection info– Nodes generally reserve resources for the connection– If circuit not available: “Busy signal”
• Transfer: source sends data over the circuit– No destination address, since nodes know path
• Teardown: source tears down circuit when done
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Circuit Switching• Node (switch) in a circuit switching network
incoming links outgoing linksNode
How does the node connect the incoming link tothe outgoing?
Telephone Network
• Alexander Graham Bell– 1876: Demonstrates the telephone at US
Centenary Exhibition in Philadelphia
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Circuit Switching With Human Operator
Telephone Network• Almon Brown Strowger (1839 - 1902)– 1889: Invents the “girl-less, cuss-less” telephone system
-- the mechanical switching system
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Timing in Circuit Switching
Host 1 Host 2Switch 1 Switch 2
time
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Timing in Circuit Switching
Circuit Establishment
Host 1 Host 2Switch 1 Switch 2
propagation delay between Host 1 and Switch1
time
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Timing in Circuit Switching
Circuit Establishment
Host 1 Host 2Switch 1 Switch 2
propagation delay between Host 1 and Switch1
Transmission delay
time
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Timing in Circuit Switching
Circuit Establishment
Host 1 Host 2Switch 1 Switch 2
propagation delay between Host 1 and Switch1
Transmission delay
time
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Timing in Circuit Switching
Circuit Establishment
Host 1 Host 2Switch 1 Switch 2
propagation delay between Host 1 and Switch1propagation delay between Host 1 and Host 2
Transmission delay
time
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Timing in Circuit Switching
Information
Circuit Establishment
Transfer
Host 1 Host 2Switch 1 Switch 2
propagation delay between Host 1 and Switch1propagation delay between Host 1 and Host 2
Transmission delay
time
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Timing in Circuit Switching
Information
Circuit Establishment
Transfer
Circuit Teardown
Host 1 Host 2Switch 1 Switch 2
propagation delay between Host 1 and Switch1propagation delay between Host 1 and Host 2
Transmission delay
time
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Circuit Switching• Node (switch) in a circuit switching network
incoming links outgoing linksNode
How do the black and orange circuits share theoutgoing link?
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Circuit Switching: Multiplexing a Link
• Time-division– Each circuit allocated
certain time slots
• Frequency-division– Each circuit allocated
certain frequencies
timefrequency
time
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Time-Division Multiplexing/Demultiplexing
• Time divided into frames; frames into slots• Relative slot position inside a frame determines to which
conversation data belongs– E.g., slot 0 belongs to orange conversation
• Requires synchronization between sender andreceiver—surprisingly non-trivial!
• In case of non-permanent conversations– Need to dynamically bind a slot to a conversation– How to do this?
• If a conversation does not use its circuit the capacity is lost!
Frames
0 1 2 3 4 5 0 1 2 3 4 5Slots =
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5 Minute Break
Questions Before We Proceed?
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• Communication networks can be classified based onthe way in which the nodes exchange information:
Taxonomy of Communication Networks
Commun ic a t io nNe t wo rk
Swit c he dComm un ic a t io nNe t wo rk
Bro a d c a s tComm un ic a t io nNe t wo rk
Circ u it -Swit c he dComm un ic a t io nNe t wo rk
Pa cke t -Swit c he dComm un ic a t io nNe t wo rk
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Packet Switching• Data sent as chunks of formatted bit-sequences (Packets)
• Packets have following structure:
Header and Trailer carry control information(e.g., destination address, checksum)
• Each packet traverses the network from node to nodealong some path (Routing) based on header info.
• Usually, once a node receives the entire packet, it stores it(hopefully briefly) and then forwards it to the next node(Store-and-Forward Networks)
Header Data Trailer (sometimes)
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Packet Switching• Node in a packet switching network
incoming links outgoing linksNode
Memory
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Packet Switching: Multiplexing/Demultiplexing
• Data from any conversation can be transmitted at anygiven time– Single conversation can use the entire link capacity if it is alone
• How to tell them apart?– Use meta-data (header) to describe data
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• Communication networks can be classified based onthe way in which the nodes exchange information:
Taxonomy of Communication Networks
Commun ic a t io nNe t wo rk
Swit c he dComm un ic a t io nNe t wo rk
Bro a d c a s tComm un ic a t io nNe t wo rk
Circ u it -Swit c he dComm un ic a t io nNe t wo rk
Pa cke t -Swit c he dComm un ic a t io nNe t wo rk
Da t a g ram Ne t wo rk
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Datagram Packet Switching• Each packet is independently switched–Each packet header contains full destination address
• No resources are pre-allocated (reserved) inadvance
• Leverages “statistical multiplexing” (or stat-muxing)–Essentially: “chances are good that packets from
different conversations won’t all arrive at the same time,so we can get by without enough capacity for all of themat their peak transmission rate”
–Assuming independence of traffic sources, can computeprobability that there is enough capacity
• Example: IP networks; postal system
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Timing of Datagram Packet Switching
Packet 1
Host 1 Host 2Node 1 Node 2
propagationdelay betweenHost 1 and Node 1
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Timing of Datagram Packet Switching
Packet 1
Host 1 Host 2Node 1 Node 2
propagationdelay betweenHost 1 and Node 1
transmission time of Packet 1at Host 1
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Packet 1
Packet 1
Timing of Datagram Packet Switching
Packet 1 processingdelay ofPacket 1 atNode 2
Host 1 Host 2Node 1 Node 2
propagationdelay betweenHost 1 and Node 1
transmission time of Packet 1at Host 1
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Packet 1
Packet 2
Packet 3
Packet 1
Packet 2
Packet 3
Timing of Datagram Packet Switching
Packet 1
Packet 2
Packet 3
processingdelay ofPacket 1 atNode 2
Host 1 Host 2Node 1 Node 2
propagationdelay betweenHost 1 and Node 1
transmission time of Packet 1at Host 1
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Datagram Packet Switching
Host A
Host BHost E
Host D
Host C
Node 1 Node 2
Node 3
Node 4
Node 5
Node 6 Node 7
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Datagram Packet Switching
Host A
Host BHost E
Host D
Host C
Node 1 Node 2
Node 3
Node 4
Node 5
Node 6 Node 7
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Datagram Packet Switching
Host A
Host BHost E
Host D
Host C
Node 1 Node 2
Node 3
Node 4
Node 5
Node 6 Node 7
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• Communication networks can be classified based onthe way in which the nodes exchange information:
Taxonomy of Communication Networks
Commun ic a t io nNe t wo rk
Swit c he dComm un ic a t io nNe t wo rk
Bro a d c a s tComm un ic a t io nNe t wo rk
Circ u it -Swit c he dComm un ic a t io nNe t wo rk
Pa cke t -Swit c he dComm un ic a t io nNe t wo rk
Da t a g ram Ne t wo rk
Virt ua l Circ u itNe t wo rk
A hybrid of circuits andpackets; headers include a
“circuit identifier” establishedduring a setup phase
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Advantages of Circuit Switching• Guaranteed bandwidth
– Predictable communication performance– Not “best-effort” delivery with no real guarantees
• Simple abstraction– Reliable communication channel between hosts– No worries about lost or out-of-order packets
• Simple forwarding– Forwarding based on time slot or frequency– No need to inspect a packet header
• Low per-packet overhead– Forwarding based on time slot or frequency– No IP (and TCP/UDP) header on each packet
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Disadvantages of Circuit Switching• Wasted bandwidth
– Bursty traffic leads to idle connection during silent period– Unable to achieve gains from “statistical multiplexing”
• Blocked connections– Connection refused when resources are not sufficient– Unable to offer “okay” service to everybody
• Connection set-up delay– No communication until the connection is set up– Unable to avoid extra latency for small data transfers
• Network state– Network nodes must store per-connection information– Unable to avoid per-connection storage and state– This makes failures more disruptive!
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Packet-Switching vs. Circuit-Switching• Critical advantage of packet-switching over circuit
switching: Exploitation of statistical multiplexing
• Another: since routers don’t know about individualconversations, when a router or link fails, it’s:Easy to fail over to a different path
• A third: easier for different parties to link their networkstogether because they’re not promising to reserveresources for one another
• However, packet-switching must handle congestion:– More complex routers– Harder to provide good network services (e.g., delay and
bandwidth guarantees)
• In practice, sometimes combined, e.g., IP over SONET
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Questions?
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What Is A Protocol?
• A protocol is an agreement on how tocommunicate
• Includes syntax and semantics– How a communication is specified & structured
Format, order messages are sent and received– What a communication means
Actions taken when transmitting, receiving, or when a timerexpires
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Examples of Protocols in Human Interactions
• Telephone1. (Pick up / open up the phone.)2. Listen for a dial tone / see that you have service.3. Dial.4. Should hear ringing …5. Callee: “Hello?”6. Caller: “Hi, it’s Alice ….”
Or: “Hi, it’s me” (← what’s that about?)7. Caller: “Hey, do you think … blah blah blah …” pause8. Callee: “Yeah, blah blah blah …” pause
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Examples of Protocols in Human Interactions
• Asking a question1. Raise your hand.2. Wait to be called on.
3. Or: wait for speaker to pause and vocalize
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Examples of Protocols in Human Interactions
• Expressing approvalfor a performance.1. Applause.
Who is this woman?
Why don’t her fansapplaud her performances?
2. Foot-stomping
3. The key: a protocolshould effectively enablecommunication.
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Example: HyperText Transfer Protocol
GET /courses/archive/spring06/cos461/ HTTP/1.1Host: www.cs.princeton.eduUser-Agent: Mozilla/4.03CRLF
HTTP/1.1 200 OKDate: Mon, 6 Feb 2006 13:09:03 GMTServer: Netscape-Enterprise/3.5.1Last-Modified: Mon, 6 Feb 2006 11:12:23 GMTContent-Length: 21CRLFSite under construction
Request
Response
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Example: IP Packet
4-bitVersion
4-bitHeaderLength
8-bit Type ofService (TOS) 16-bit Total Length (Bytes)
16-bit Identification 3-bitFlags 13-bit Fragment Offset
8-bit Time to Live (TTL)
8-bit Protocol 16-bit Header Checksum
32-bit Source IP Address
32-bit Destination IP Address
Options (if any)
Payload
20-byte20-byteheaderheader
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IP: “Best-Effort” Packet Delivery
• Datagram packet switching–Send data in packets–Header with source & destination address
• Service it provides:–Packets may be lost–Packets may be corrupted–Packets may be delivered out of order
source destination
IP network
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Example: Transmission Control Protocol
• Communication service– Ordered, reliable byte stream– Simultaneous transmission in both directions
• Key mechanisms at end hosts– Retransmit lost and corrupted packets– Discard duplicate packets and put packets in order– Flow control to avoid overloading the receiver buffer– Congestion control to adapt sending rate to network
load
source network destination
TCP connection
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Protocol Standardization• Ensure communicating hosts speak the same
protocol– Standardization to enable multiple implementations– Or, the same folks have to write all the software
• Standardization: Internet Engineering Task Force– Based on working groups that focus on specific issues– Produces “Request For Comments” (RFCs)
Promoted to standards via rough consensus and running code– IETF Web site is http://www.ietf.org– RFCs archived at http://www.rfc-editor.org
• De facto standards: same folks writing the code– P2P file sharing, Skype, <your protocol here>…
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Summary
• Types of communication networks– Broadcast, circuit-switched, packet-switched– Advantages & disadvantages of each
• Protocols: agreement on how to communicate– For networks, often requires formal standardization
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Next Lecture• Architecture, Layering, and the “End-to-End
Principle”
• Read 1.4 & 1.5 of Kurose/Ross
• Reminder: new section M 4-5, but doesn’t meetnext week
• Pick up class computer account forms
• Take the survey (http://tinyurl.com/2wynmu)ASAP and join the mailing list if you haven’talready