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By Prof R A Carrasco School of Electrical ,Electronic and Computer Engineering University of Newcastle Upon Tyne. MSc WLAN, IP/TCP and COMM NETWORK Topics. [email protected] Ext: 7332. MSc WLAN, IP/TCP and COMM NETWORK. References - PowerPoint PPT Presentation
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MSc WLAN, IP/TCP and COMM NETWORK
Topics
ByProf R A Carrasco
School of Electrical ,Electronic and Computer Engineering
University of Newcastle Upon Tyne
[email protected]: 7332
MSc WLAN, IP/TCP and COMM NETWORK
ReferencesReferences
[1][1] Tanenbaum, Andrew S., Tanenbaum, Andrew S., Computer NetworksComputer Networks, Fourth Edition ed: Pearson , Fourth Edition ed: Pearson Education International, 2003,Education International, 2003, ISBN: 0-13-038488-7.ISBN: 0-13-038488-7.
[2][2] Comer, Douglas E, Comer, Douglas E, Computer Networks and Internets with Internet Computer Networks and Internets with Internet ApplicationsApplications, Third Edition ed: Prentice Hall, 2001, ISBN: 0-13-091449-5., Third Edition ed: Prentice Hall, 2001, ISBN: 0-13-091449-5.
[3][3] Peterson, Larry L. & Davie, Bruce S., Peterson, Larry L. & Davie, Bruce S., Computer Networks, A Systems Computer Networks, A Systems ApproachApproach: Morgan Kaufman Publishers, 2000, ISBN: 1-55860-577-0.: Morgan Kaufman Publishers, 2000, ISBN: 1-55860-577-0.
[4][4] Halsall, Fred, Halsall, Fred, Data Communications, Computer Networks and Open Data Communications, Computer Networks and Open SystemsSystems: Adison-Wesley Publishing, 1995, ISBN: 0-201-42293-X: Adison-Wesley Publishing, 1995, ISBN: 0-201-42293-X
• Advanced Research Projects Agency Network (ARPAnet), 1969.
• The protocols in the TCP/IP suite either use transport control protocols (TCP) or user datagram protocol (UDP) as the transport protocol.
• Low level functions such as File Transfer Protocol (FTP), the Internet Terminal Protocol (TELNET) and Electronic Mail (E-Mail), remote logon.
• IP is responsible for moving packets of data from node to node. IP forwards each packet based on a four byte destination address (the IP number), different organisation, IP operates on a gateway machine.
• TCP is responsible for verifying the correct delivery of data from client to server. TCP adds support to detect errors or lost data to trigger retransmission until the data is correctly and completely received.
• Sockets is a name given to the package of subroutines that provide access to TCP/IP on most systems
Internet and Protocols
• The Internet Protocol was developed to create a Network of Networks (the Internet). Individual machines are first connected to a LAN (Ethernet or Token Ring). TCP/IP shares the LAN with other users. One device provides the TCP/IP connection between the LAN and the rest of the World.
• A Network consisting of two or more far-apart LANs is a Wide Area Network (WAN)
• Typical Network consisting of Switches, Hubs and Routers are intermediary devices between clients and servers
The Network Layer in the Internet
The Internet can be viewed as a collection of sub-networks The Internet can be viewed as a collection of sub-networks or autonomous systems (AS) that are connected togetheror autonomous systems (AS) that are connected together
There is not real structure, but several major backbones There is not real structure, but several major backbones existexist
These are constructed from high-bandwidth lines and fast These are constructed from high-bandwidth lines and fast routersrouters
Attached to the backbones are regional networks, and Attached to the backbones are regional networks, and attached to these regional networks are LANs attached to these regional networks are LANs (Universities, companies etc.)(Universities, companies etc.)
The glue that holds the Internet together is the network The glue that holds the Internet together is the network layer protocol, IPlayer protocol, IP
The Network Layer in the Internet
The Internet transmits data by packet switching The Internet transmits data by packet switching using a standardised Internet Protocol (IP)using a standardised Internet Protocol (IP)
IP DatagramIP Datagram
The header has a 20-byte fixed part and a variable The header has a 20-byte fixed part and a variable length optional partlength optional part
It is transmitted in big edian order from left to It is transmitted in big edian order from left to right with higher-order bit of the version field right with higher-order bit of the version field going firstgoing first
Ethernet hub is a device for connecting multiple twisted pair or fibre Ethernet devices together.
D. E. Comer, "Computer Networks and Internets with Internet Applications," Prentice Hall, 2001, pp. 157-167.
[2]
Ethernet bridge connects multiple network segments at the data link layer ( layer 2 ) of the OSI model.
http://netbook.cs.purdue.edu/anmtions/anim09_2.htm
A router is a computer networking device that forwards data across
networks towards their destination, through a process known as routing.
http://netbook.cs.purdue.edu/anmtions/anim09_3.htm
Modem is a device that modulates an analogue carrier signal to encode digital information and also demodulate such a carrier signal to decode the transmitted information.
Popular Wired LAN Standards
High-Level Data Link Control (HDLC)High-Level Data Link Control (HDLC) Ethernet (IEEE 802.3)Ethernet (IEEE 802.3) Token Bus (IEEE 802.4)Token Bus (IEEE 802.4) Token Ring (IEEE 802.5)Token Ring (IEEE 802.5)
A. S. TanenBaum, "Computer Networks," Pearson Education, 2003, pp. 234-243, pp. 16-26, pp. 271-291.
[1]
HIGH LEVEL DATA LINK CONTROLA. S. TanenBaum, "Computer Networks," Pearson Education, 2003, pp. 234-243.
[1]
Frame format for bit-oriented protocols.
8 8 >08 816
01111110 address control Data Checksum 01111110
HIGH LEVEL DATA LINK CONTROL(2)
A. S. TanenBaum, "Computer Networks," Pearson Education, 2003, pp. 234-243.
[1]
0 Seq P/F Next(a)
1 13 3
0 Type P/F Next(b)
1 13 3
0 Type P/F Modifier(c)
1 13 3
Control Field of
(a) An information frame
(b) A supervisory frame
(c) An unnumbered frame
PPP- Point to Point Protocol
Bytes
Flag
01111110
Address
11111111
Control
00000011Protocol Payload checksum
Flag
01111110
1 1 1 1 or 2 Variable 2 or 4 1
The PPP full frame format for unnumbered mode operation
Ethernet (IEEE 802.3)
Bus TopologyBus Topology Carrier Sense Multiple Access with Carrier Sense Multiple Access with
Collision Detection (CSMA/CD)Collision Detection (CSMA/CD) 10 Bases denoting 10 Mbit/s10 Bases denoting 10 Mbit/s
http://netbook.cs.purdue.edu/anmtions/anim06_1.htm
Ethernet (IEEE 802.3)
MAC Unit
Protocol Firmware
Network Service
Drop cable
Transceiver
Tap
Ethernet (IEEE 802.3)
PR = Preamble SFD = Start Frame Data DA = Destination Address SA = Source Address TYPE = Type of data FCS = Frame Checksum
PR SFD DA SA FCSTYPE INFORMATION
Data frame
CSMA/CD MAC Protocol
Station checks if there is data being currently Station checks if there is data being currently transmitted (carrier sense)transmitted (carrier sense)
If no data is present, station begins to transmit dataIf no data is present, station begins to transmit data
If two or more stations begin this process If two or more stations begin this process simultaneously, there will be a collision of framessimultaneously, there will be a collision of frames
Station monitors its own receiver output and Station monitors its own receiver output and compares with transmitted signal to detect when compares with transmitted signal to detect when this occurs (collision detection)this occurs (collision detection)
http://netbook.cs.purdue.edu/anmtions/anim06_2.htm
http://netbook.cs.purdue.edu/anmtions/anim06_5.htm
CSMA/CD MAC Protocol
If a collision is detected, the station aborts the If a collision is detected, the station aborts the transmission and sends a jamming signal to inform transmission and sends a jamming signal to inform all other stations that a collision has occurredall other stations that a collision has occurred
Transmitting stations that have caused the Transmitting stations that have caused the collision wait a randomly generated time interval collision wait a randomly generated time interval before reattempting to transmitbefore reattempting to transmit
This avoids step-lock in terms of retransmission This avoids step-lock in terms of retransmission causing repeated collisionscausing repeated collisions
Capacity Calculations
delay
A B
Time
TX - A TX - B
T = Transmitted frame length
Capacity Calculations
TX-A TX-B 2
Sensing time
Time to detect collision
Collision interval
Time to transfer information
a = / T The maximum propagation delay to frame length ratio
The figure above allows a new frame to be transmitted immediately following the previous one, giving a frame rate of 1/T frames/sec
Capacity Calculations
If, on average If, on average KK retries are necessary before retries are necessary before the next frame can be transmitted (in a lightly the next frame can be transmitted (in a lightly loaded network loaded network kk=0), then the average time =0), then the average time for transmitting one frame, for transmitting one frame, ttvv, is given by: , is given by:
ttvv = = TT + + + 2 + 2KK
= = TT + + (1 + 2(1 + 2KK))
= = TT [1 + [1 + //TT(1 +2(1 +2KK)] = )] = TT[1 + [1 + aa(1+(1+2K2K)])]Where Where a=a=//TT
Capacity Calculations
The utilisation factor, The utilisation factor, UU, of the transmission , of the transmission medium is given by:medium is given by:
UU = = TT//ttvv = 1/(1+ = 1/(1+aa(1+2(1+2kk)))) Let Let PPtt be the probability constant for all be the probability constant for all
stations over all time that any particular stations over all time that any particular station wishes to transmit at the end of a station wishes to transmit at the end of a specific 2specific 2 collision detection interval collision detection interval
PPtt = 2 = 2 λλ ,(where ,(where λλ is the rate of packets/s) is the rate of packets/s)
Capacity Calculations
For a successful event, one station transmits, but For a successful event, one station transmits, but nn-1 stations do not-1 stations do not
The probability of n successful transmissions The probability of n successful transmissions pp is is therefore given by:therefore given by:
pp = = nPnPtt(1 - (1 - PPtt))nn-1-1
It can be shown by differentiating It can be shown by differentiating pp with respect with respect to to PPtt that the maximum value of the probability that the maximum value of the probability PPtt is:is:
PPtt = = 11/n/nWhere Where nn is the number of stations is the number of stations
Capacity Calculations
Consequently the maximum value of p is given by:Consequently the maximum value of p is given by: ppmaxmax= n = n 1/ 1/nn(1 – 1/(1 – 1/nn))nn-1-1 = (1 – 1/ = (1 – 1/nn) ) nn-1-1
If If nn→∞→∞ then then ppmaxmax → 1/e where e = 2.718…→ 1/e where e = 2.718… At the end of a 2At the end of a 2 collision detection interval, a further collision detection interval, a further
collision occurs with probability 1-collision occurs with probability 1-pp, while a successful , while a successful transmission occurs with probability transmission occurs with probability PP
Thus, a sequence of K collision intervals occupying a time Thus, a sequence of K collision intervals occupying a time 22K sec, occurs with probability:K sec, occurs with probability:
PP ( (kk) = ) = pp(1-(1-pp))KK-1-1 at least one collision occurring at least one collision occurring
Capacity Calculations
The average number of collisions is The average number of collisions is therefore given by:therefore given by:
kk= = ΣΣkk=1=1
kpkp((kk) = ) = ΣΣkk=1=1
kpkp(1-(1-pp) ) kk-1-1
From this it can be proven that From this it can be proven that kk=1/=1/pp, and , and we obtain the limiting utilisation:we obtain the limiting utilisation:
UU = = TT//ttvv = 1/(1+ = 1/(1+aa(1+2(1+2kk))))
UUmaxmax = 1 / (1+ = 1 / (1+aa(1+2(1+22.718)) = 1/(1+6.442.718)) = 1/(1+6.44aa))
Utilisation with different values for the a parameter
Max Utilisation for different values of
0
0.2
0.4
0.6
0.8
1
0 0.2 0.4
parameter
Max
Uti
lisa
tio
na
a
Ethernet OPNET Simulation
Ethernet with 30 nodes is connected via Ethernet with 30 nodes is connected via coaxial link in a bus topologycoaxial link in a bus topology
The bus is operating at 10MbpsThe bus is operating at 10Mbps collision detection interval 2collision detection interval 2=51.2=51.2µµsec, sec,
data frame length =1024 bytesdata frame length =1024 bytes
Network Snapshot
Utilization vs. Traffic Load
Ethernet Exercises
Problem: A certain Ethernet system has a Problem: A certain Ethernet system has a maximum bus delay of 16 maximum bus delay of 16 μμsec, and operates with sec, and operates with a bit rate of 10 Mbit/sec. Each frame is 576 bits in a bit rate of 10 Mbit/sec. Each frame is 576 bits in length. Determine the maximum utilisation factor length. Determine the maximum utilisation factor of the medium under collision conditionsof the medium under collision conditions
For the system above, calculate the actual capacity For the system above, calculate the actual capacity if there are 15 active stations, each with an equal if there are 15 active stations, each with an equal amount of data to transmitamount of data to transmit
Token Ring (IEEE 802.5)
Ring Structure
SD AC FC DA SA FCS ED FSINFORMATION
Data frame
SD AC ED
Token framehttp://netbook.cs.purdue.edu/anmtions/anim06_4.htm
Token Ring Frame Structures
SD = Start Delimited (1 octet)SD = Start Delimited (1 octet) AC = Access Control (1 octet)AC = Access Control (1 octet) FC = Frame Control (1 octet)FC = Frame Control (1 octet) DA = Destination Address (2/6)DA = Destination Address (2/6) FCS = Frame Check (4)FCS = Frame Check (4) ED = End Delimiter (1)ED = End Delimiter (1) FS = Frame Status (1)FS = Frame Status (1)
Token Ring
MAC Unit
Protocol Firmware
Network Service
Drop cable
Ring cable
Trunk Coupling Unit (TCU)
Token Ring
AC
B
DFree Token
AC
B
D
AC
B
D
AC
B
D
Busy Token Free Token
A generates data frame
for station A
A removes the data frame
Capacity Calculations
Empty RingEmpty Ring CC = Capacity (bits/sec) = Capacity (bits/sec) = Propagation time around ring= Propagation time around ring NN = Number of stations = Number of stations LL = Delay of = Delay of LL bits in each station on the bits in each station on the
ring (station latency)ring (station latency)
Capacity Calculations
The ring latency is given by:The ring latency is given by: TTLL = = + ( + (NLNL)/)/CC
The free token is 24 bits (3 bytes) in length, The free token is 24 bits (3 bytes) in length, thus the maximum waiting time, if no other thus the maximum waiting time, if no other station is transmitting, is given by:station is transmitting, is given by:
TTmax,emptymax,empty = (24/ = (24/CC + + TTLL))
Capacity Calculations
Full RingFull Ring Consider a full ring, where all stations have Consider a full ring, where all stations have
data to transmitdata to transmit Each station can only transmit when it has the Each station can only transmit when it has the
tokentoken If each frame is limited to M bytes, the If each frame is limited to M bytes, the
transmission time is:transmission time is: TT = 8 = 8MM//CC The maximum waiting time is:The maximum waiting time is: TTmax, Fullmax, Full = ( = (NN-1)(-1)(TT++TTLL))
Capacity Calculations
ExerciseExercise A 4Mbit/s ring has 50 stations, each with a A 4Mbit/s ring has 50 stations, each with a
latency of 2 bits, the total length of the ring is latency of 2 bits, the total length of the ring is 2km, and the propagation delay of the cable is 2km, and the propagation delay of the cable is 55μμs/kms/km
Determine the maximum waiting time when the Determine the maximum waiting time when the ring is empty, and when all stations are ring is empty, and when all stations are transmitting. A full frame is 64 bytes in lengthtransmitting. A full frame is 64 bytes in length
Capacity Calculations
Loaded RingLoaded Ring Traffic load of Traffic load of λλii frame/sec frame/sec TT = Time when transmitted on the ring = Time when transmitted on the ring
for each framefor each frame TTcc = time interval elapsed before the free = time interval elapsed before the free
token arrivestoken arrives ttii = = λλiiTTccTT
Capacity Calculations
The maximum waiting time experienced by The maximum waiting time experienced by every station on the ring Tc is given by:every station on the ring Tc is given by:
TTcc = = TTLL + + ΣΣNNi=1i=1 ttii = = TTLL + + ttcc ΛΛTT
Where Where ΛΛ = = ΣΣNNi=1i=1 λ λii
Here the parameter Here the parameter ΛΛ represents the gross represents the gross input to the ring in frame/secinput to the ring in frame/sec
TTcc//TTLL = 1 / (1- = 1 / (1-UU) and ) and UU = = ΛΛTT
Token Ring OPNET Simulation
Token Ring Parameters
Single Station
Only one station has data to transmitOnly one station has data to transmit MSDU size = 1024 bytesMSDU size = 1024 bytes Test under different Token Holding Timer Test under different Token Holding Timer
(THT) values, which specifies the (THT) values, which specifies the maximum amount of time a token ring maximum amount of time a token ring MAC may use the token before releasing it.MAC may use the token before releasing it.
Utilization vs. THT Duration
Full Ring
All stations have data to transmitAll stations have data to transmit Each station can only transmit when it has Each station can only transmit when it has
the tokenthe token MSDU size = 1024 bytesMSDU size = 1024 bytes
Utilization vs. THT Duration
Tutorial: Network Systems and Technologies by Professor R. A. Carrasco
1) 1) Describe the basic differences between a wide area network and a local area network in terms of:Describe the basic differences between a wide area network and a local area network in terms of: a) Structurea) Structure b) Operationb) Operation 2) 2) The techniques of passing information from node to node across a broadcast network differ according The techniques of passing information from node to node across a broadcast network differ according to to
the type of configuration employed.the type of configuration employed.Compare the methods used for bus and ring networks.Compare the methods used for bus and ring networks.
3) 3) a) What is a baseband LAN?a) What is a baseband LAN? What is a broadband LAN?What is a broadband LAN?
b) What are the advantages of using a star ring architecture in a computer network? What are its b) What are the advantages of using a star ring architecture in a computer network? What are its disadvantages?disadvantages?
4) 4) Describe the effects of a complete failure of a node in the operation of the following network Describe the effects of a complete failure of a node in the operation of the following network configurations:configurations:
a busa bus a ring a ring a stara star
5) 5) List the seven layers of the CCITT ISO architecture for network communications.List the seven layers of the CCITT ISO architecture for network communications.
a) Describe their function and justify the existence of each one.a) Describe their function and justify the existence of each one. b) Which layers are essential to LAN communications and why?b) Which layers are essential to LAN communications and why?
6) 6) Assuming HDLC protocolAssuming HDLC protocol a) Distinguish between the normal response mode and the asynchronous mode of working. How are they a) Distinguish between the normal response mode and the asynchronous mode of working. How are they
defined in the HDLC frame structure?defined in the HDLC frame structure? b) How is flow control achieved through this frame structure?b) How is flow control achieved through this frame structure?
7) 7) Describe the function of the logical link control and medium access control layers as defined in the Describe the function of the logical link control and medium access control layers as defined in the IEEE IEEE
802 standards and indicate their relationship with the lower protocol layers in the ISO 802 standards and indicate their relationship with the lower protocol layers in the ISO seven-layer reference model.seven-layer reference model. 8) 8) a) Describe the basic differences between circuit switching, message switching and packet a) Describe the basic differences between circuit switching, message switching and packet
switching.switching.b) Give examples of each switching technique. Advantages and disadvantages of switching techniques.b) Give examples of each switching technique. Advantages and disadvantages of switching techniques.c) For packet switching technique: give an example. How will the network handle stream of packets?c) For packet switching technique: give an example. How will the network handle stream of packets?
9) 9) i) Discuss IEEE 802 standards and frame format for CSMA/CD, token bus, token ring, 802.2 i) Discuss IEEE 802 standards and frame format for CSMA/CD, token bus, token ring, 802.2 (logical link (logical link
control), 802.3, 802.4 and 802.5 standards.control), 802.3, 802.4 and 802.5 standards.ii) Briefly discuss the comparison of 802.3, 802.4 and 802.5 standards.ii) Briefly discuss the comparison of 802.3, 802.4 and 802.5 standards.
10) 10) Imagine two LAN bridges, both connecting a pair of 802.4 networks. The first bridge is faced with Imagine two LAN bridges, both connecting a pair of 802.4 networks. The first bridge is faced with 1000 1000
512-byte frames per second that must be forwarded. The second is faced with 200 4096-byte 512-byte frames per second that must be forwarded. The second is faced with 200 4096-byte frames per second. frames per second. Which bridge do you think will need the faster CPU? Discuss.Which bridge do you think will need the faster CPU? Discuss.
11) 11) Suppose that the two bridges of the previous problem each connected an 802.4 LAN to an 802.5 Suppose that the two bridges of the previous problem each connected an 802.4 LAN to an 802.5 LAN. Would that LAN. Would that
change have any influence on the previous answer?change have any influence on the previous answer?
12) 12) A bridge between an 802.3 LAN and an 802.4 LAN has a problem with intermittent memory A bridge between an 802.3 LAN and an 802.4 LAN has a problem with intermittent memory errors. Can this problem cause undetected errors with transmitted frames, or will these errors. Can this problem cause undetected errors with transmitted frames, or will these
all be all be caught by the frame checksums?caught by the frame checksums? 13) 13) A large FDDI ring has 100 stations and a token rotation time of 40 msec. The token holding A large FDDI ring has 100 stations and a token rotation time of 40 msec. The token holding
time time is 10 msec. What is the maximum achievable efficiency of the ring?is 10 msec. What is the maximum achievable efficiency of the ring?
A. S. TanenBaum, "Computer Networks," Pearson Education, 2003, pp. 26-49.
[1]
• The Internet uses almost exclusively TCP for layer 4 and IP for layer 3
Clients and servers typically implement all of the seven OSI layers whilst hubs and switches are only aware of MAC addresses
Routers are aware of network address (IP addresses), a layer 3 switch is really a fast router
• Routing protocols differ from routed protocols since they dynamically determine routing and the route taken by one packet can be different to that of another packet taking place in the same transaction.
• Transmission Control Protocol (TCP) is a transport layer protocol layered on top of IP and below the application layer SMTP, Telnet, FTP, HTTP(web) etc.
Transmission Control Protocol (TCP)(RFC 793)• Van Jacobson’s algorithm• Karn’s algorithm• Nagle’s Algorithm
IEEE 802.x, TCP/IP and ISO/OSIArchitecture Comparison
IEEE 802.2
IEEE 802.3 IEEE 802.4 IEEE 802.5 IEEE 802.6
Application
Presentation
Session
Transport
Network
Data Link
Physical
ISO/OSI
Application
Transport
Network (IP)
Ethernet
TCP/IP
IEEE 802.x
A. S. TanenBaum, "Computer Networks," Pearson Education, 2003, pp. 431-449.
[1]
IPThe IP is the internetworking protocol that offers a The IP is the internetworking protocol that offers a
service with the following characteristics:service with the following characteristics:
It is connectionless, so units of network layer data It is connectionless, so units of network layer data protocol ,denominated datagram in the IP context, protocol ,denominated datagram in the IP context, are dealt with in an individual way from the are dealt with in an individual way from the source host up to the destination hostsource host up to the destination host
It is not reliable. The data-grams can be lost, It is not reliable. The data-grams can be lost, duplicated, or disordered, and the network does duplicated, or disordered, and the network does not detect or report this problemnot detect or report this problem
A. S. Tanenbaum, "Computer Networks," Pearson Education, 2003, pp. 431-448.
[1]
http://netbook.cs.purdue.edu/anmtions/anim17_1.htm
IP OPNET Simulation
IP Cloud Model:
Packet Discard Ratio: 1.0%
Packet Latency (secs):
Exponential (0.5)
Results
IP Header format
The version fieldThe version field keeps track of which version of the keeps track of which version of the protocol the datagram belongs to. protocol the datagram belongs to.
Hlen Hlen is provided to tell how long the header is in 32-bit is provided to tell how long the header is in 32-bit wordswords
The type of service fieldThe type of service field allows the host to tell the subnet allows the host to tell the subnet what kind of service it wants. Various combinations of what kind of service it wants. Various combinations of reliability and speed are possible. The three flag bits allow reliability and speed are possible. The three flag bits allow the host to specify what it cares most about from the net the host to specify what it cares most about from the net [delay, throughput, reliability][delay, throughput, reliability]
The total lengthThe total length includes everything in the datagram – includes everything in the datagram – both header and databoth header and data
IP Header Format The identification fieldThe identification field is needed to allow the destination host to is needed to allow the destination host to
determine which datagram a newly arrived fragment belongs to. All determine which datagram a newly arrived fragment belongs to. All the fragments of a datagram contain the same identification valuethe fragments of a datagram contain the same identification valueDF = Don’t FragmentDF = Don’t FragmentMF = More FragmentMF = More Fragment
The fragment offsetThe fragment offset tells where in the current datagram this fragment tells where in the current datagram this fragment belongsbelongs
The time to live fieldThe time to live field is a counter used to limit packet lifetimes is a counter used to limit packet lifetimes
The protocol field tells it which transport process to give it to, TCP, The protocol field tells it which transport process to give it to, TCP, UDP and some othersUDP and some others
IP Header Format The header checksum verifies the header only. Checksum is useful to detecting The header checksum verifies the header only. Checksum is useful to detecting
errors generated by bad memory words inside a routererrors generated by bad memory words inside a router The source address and destination address indicate the network number and The source address and destination address indicate the network number and
host numbershost numbers The option field was designed to provide an escape to allow subsequent version The option field was designed to provide an escape to allow subsequent version
of the protocol to include information not present in the original designof the protocol to include information not present in the original design
Option Description
Security
Strict source routing
Loose source routingRecord routeTimestamp
Specifies how secret the datagram is
Gives the complete path to be followed
Gives a list of routers not to be missedMakes each router append its IP addressMakes each router append its address and timestamp
Fragmentation The IP-level datagram must be encapsulated in a lower The IP-level datagram must be encapsulated in a lower
network level packet to travel in the networknetwork level packet to travel in the network The rules for the fragmentation are as follows:The rules for the fragmentation are as follows:
The size of the resulting fragments must be a multiple The size of the resulting fragments must be a multiple of an octet so that the data displacement records, offset, of an octet so that the data displacement records, offset, within the datagram are done correctlywithin the datagram are done correctly
The size of the fragments are freely chosenThe size of the fragments are freely chosen The gateway must accept datagram with a greater size The gateway must accept datagram with a greater size
than that of the network they are connected to. This is than that of the network they are connected to. This is so larger datagram can be admitted to the networkso larger datagram can be admitted to the network
The host and gateways must handle datagram larger The host and gateways must handle datagram larger than 576 octetsthan 576 octets
D. E. Comer, "Computer Networks and Internets with Internet Applications," Prentice Hall, 2001, pp. 283-297.
[2]
http://netbook.cs.purdue.edu/anmtions/anim16_1.htm
ARP Address Resolution Protocol The IP packet are sent encapsulated in LAN or The IP packet are sent encapsulated in LAN or
WAN frame such as Ethernet, token ring or ATM WAN frame such as Ethernet, token ring or ATM Q. How does the host needs to know the correct Q. How does the host needs to know the correct
Ethernet destination address to put in the frame?Ethernet destination address to put in the frame?
EtherDes EtherSour length IP header PayloadEtherDes EtherSour length IP header Payload
A. It uses ARP to map from the IP destination A. It uses ARP to map from the IP destination address to the Ethernet destination addressaddress to the Ethernet destination address
A. S. TanenBaum, "Computer Networks," Pearson Education, 2003, pp. 450-452.
[1]
http://netbook.cs.purdue.edu/anmtions/anim15_1.htm
ARP cont
The host broadcasts an APR request packet The host broadcasts an APR request packet which contains the IP address of the which contains the IP address of the required stationrequired station
The station which has that IP address The station which has that IP address replies directly (unicast) returning the replies directly (unicast) returning the correct IP addresscorrect IP address
Now the IP packet can be sent directly to Now the IP packet can be sent directly to the correct Ethernet addressthe correct Ethernet address
Reverse Address Resolution Protocol (RARP) Allows a station to determine its IP address from Allows a station to determine its IP address from
its hardware addressits hardware address A server can be configured to respond to RARP A server can be configured to respond to RARP
request automatically allocating IP address across request automatically allocating IP address across the networkthe network
Not used much nowadays, replaced instead by Not used much nowadays, replaced instead by more powerful auto configuration protocols such more powerful auto configuration protocols such as DHCP (Dynamic Host Configuration Protocol)as DHCP (Dynamic Host Configuration Protocol)
A. S. TanenBaum, "Computer Networks," Pearson Education, 2003, pp. 453-454.
[1]
Dynamic Host Configuration Protocol DHCP Allows a client to be configured Allows a client to be configured
automatically over the network.automatically over the network. Means that machines do not have to have Means that machines do not have to have
configured by handconfigured by hand New machines can be added to the IP New machines can be added to the IP
network more easily network more easily Less chance of error (for example duplicate Less chance of error (for example duplicate
IP addresses being configured)IP addresses being configured)
Domain Name Service DNS
IP addresses are very difficult to rememberIP addresses are very difficult to remember DNS translates easier to remember text DNS translates easier to remember text
names www.soc.ncl.ac.uknames www.soc.ncl.ac.uk
into IP address 128.10.20.30into IP address 128.10.20.30 When a host requires a domain name When a host requires a domain name
translation it makes the request to its local translation it makes the request to its local Domain Name ServerDomain Name Server
A. S. TanenBaum, "Computer Networks," Pearson Education, 2003, pp. 579-588,.
[1]
Domain Naming
Each name in DNS can be split up a series of Each name in DNS can be split up a series of domainsdomains
E.g. E.g. www.soc.ncl.ac.ukwww.soc.ncl.ac.uk uk=domain of the UKuk=domain of the UK ac.uk= academic domain within the UKac.uk= academic domain within the UK ncl.ac.uk=Newcastle University domain within ncl.ac.uk=Newcastle University domain within
UK academicUK academic soc.ncl.ac.uk School of computing domain within soc.ncl.ac.uk School of computing domain within
Newcastle University within UK academicNewcastle University within UK academic
Domain Name Servers Each domain name server is responsible domainEach domain name server is responsible domain The first request will go to the server which is the local machine The first request will go to the server which is the local machine
domaindomain DNS server can react in 3 different wayDNS server can react in 3 different way
-DIRECT just send back the correct IP address-DIRECT just send back the correct IP address
-RECURSIVE if it doesn’t know the IP address make a request to another -RECURSIVE if it doesn’t know the IP address make a request to another DNS server for the IP address then send back the IP addressDNS server for the IP address then send back the IP address
-INDIRECT send back the IP address of another DNS server-INDIRECT send back the IP address of another DNS server
The change from IPv4 to IPv6 falls primarily into the following categories:
• Expanded Addressing Capabilities IP address size from 32 bits to 128• Header format simplification• Improved support for extensions and options• Flow labelling capability•Authentication and privacy capabilities
IPv6 extension headers
A. S. TanenBaum, "Computer Networks," Pearson Education, 2003, pp. 464-473.
[1] D. E. Comer, "Computer Networks and Internets with Internet Applications," Prentice Hall, 2001, pp. 339-348.
[2]
Order of extension headers for IPv6
Option header formats
Hop-by-hop extension IPv6 options header
Routing Extension IPv6 header
Routing type 0 header
Fragment extension IPv6 header
TCP and UDP “pseudo-header” for IPv6
TCP Transmission Control Protocol
ServicesServices
-Guarantees end to end delivering of packets-Guarantees end to end delivering of packets
-Control the flow of data from host to host -Control the flow of data from host to host and host into the networkand host into the network
-Multiplexing, the TCP header has a port -Multiplexing, the TCP header has a port number which is used to determine which number which is used to determine which application should receive the packetapplication should receive the packet
A. S. TanenBaum, "Computer Networks," Pearson Education, 2003, pp. 41-49.
[1] http://netbook.cs.purdue.edu/anmtions/anim20_1.htm
TCP Datagram Format, RFC 793A. S. TanenBaum, "Computer Networks," Pearson Education, 2003, pp. 532-553.
[1]
TCP Client Ports
Q. If you have a computer running an e-mail Q. If you have a computer running an e-mail package, 2 web browsers (e.g. Netscape and IE) package, 2 web browsers (e.g. Netscape and IE) how does the compute know when a TCP/IP how does the compute know when a TCP/IP packet arrives which application should receive packet arrives which application should receive the packet?the packet?
A. Each application sets up its connection using a A. Each application sets up its connection using a different port number, when the replies come back different port number, when the replies come back from the server the port number is used to send the from the server the port number is used to send the packet to the current connection.packet to the current connection.
TCP SERVER PORTS
The server must respond to client requestsThe server must respond to client requests Q. How does the client know which port to Q. How does the client know which port to
send its request to?send its request to? A. “Well known port numbers” are assigned A. “Well known port numbers” are assigned
to particular servicesto particular services
TCP Error control
The acknowledgment (ack) and sequence number fields The acknowledgment (ack) and sequence number fields are used to guarantee delivery of packets to the destinationare used to guarantee delivery of packets to the destination
For each packet sent out an ack must be sent back.For each packet sent out an ack must be sent back. If no ack is sent back within a certain time the packet is If no ack is sent back within a certain time the packet is
sent again.sent again. Each new packet to be transmitted is allocated a new Each new packet to be transmitted is allocated a new
sequence no. the returning ack no. informs the sender of sequence no. the returning ack no. informs the sender of the next expected sequence no.the next expected sequence no.
The sequence no. is used to keep the packets in orderThe sequence no. is used to keep the packets in order
http://netbook.cs.purdue.edu/anmtions/anim20_5.htm
TCP flow control
The window size field is used by the receiver to The window size field is used by the receiver to control the flow of packets from the sender.control the flow of packets from the sender.
If the receiver sets the window size to 400 the If the receiver sets the window size to 400 the sender is only allowed to send 400 bytes before sender is only allowed to send 400 bytes before stopping.stopping.
The receiver can stop the sender by setting the The receiver can stop the sender by setting the window size to 0window size to 0
http://netbook.cs.purdue.edu/anmtions/anim20_3.htm
http://netbook.cs.purdue.edu/anmtions/anim20_3.htm
TCP congestion control
TCP uses a slow start algorithm to initially TCP uses a slow start algorithm to initially limit a new connection’s bandwidth.limit a new connection’s bandwidth.
This is so that the connection does not This is so that the connection does not overload the network infrastructureoverload the network infrastructure
TCP increases the flow of data into the TCP increases the flow of data into the network until an ack timeout occurs it will network until an ack timeout occurs it will then cut backthen cut back
TCP OPNET Simulation
TCP Tahoe TCP Reno
(Fast recovery)
A packet loss
A packet loss
UDP User Datagram Protocol
ServicesServices
-provides port allocations the same as TCP-provides port allocations the same as TCP
-does NOT guarantee delivery-does NOT guarantee delivery
-does not guarantee sequencing-does not guarantee sequencing
-useful when speed is more important than -useful when speed is more important than reliability e.g. Internet telephonyreliability e.g. Internet telephony
A. S. TanenBaum, "Computer Networks," Pearson Education, 2003, pp. 524-532.
[1]
User Datagram Protocol (UDP), RFC 768
• Source Port Destination Port Length Field The Checksum
• Internet Protocol IP RFC 791, RFC 792, RFC 826
IPv4, IPv6
Applications of UDP
Appropriate whenAppropriate when
- transport layer overhead must be - transport layer overhead must be minimized or minimized or
- data reliability is not crucial- data reliability is not crucial
- Services such as NFS, DNS, SNMP and - Services such as NFS, DNS, SNMP and Voice over IP (VoIP) use UDPVoice over IP (VoIP) use UDP
Sockets
1 2 65535 1 2 65535
TCP UDP
TCP ports UDP ports
Sockets bound to ports
UDP sockets
Socket references
TCP sockets
Applications
IP
A socket allows applications to send and receive data. It allows an application to connect to a network and communicate with other applications on that network Stream sockets use TCP as the end-to-end protocol with IP underneath Datagram sockets use UDP end-to-end with IP underneath A TCP/IP socket is uniquely identified by an Internet address, type of protocol and a port number
Relationship of Socket Classes
TcpListener TcpClientClass
UdpClientClass
Socket Class
WinSock 2.0 Implementation
WinSock was developed by Microsoft and provides standard socket functions.
The .NET framework provides higher level classes to simplify programming tasks.
The .NET socket class allows access to the underlying sockets interface.
TcpListener, TcpClient and UdpClient are higher level .NET socket classes that are implemented using the .NET Socket wrapper class.
.NETFramework
Classes
UnderlyingImplementatio
n
TCP Sockets The .NET framework provides two classes for TCP: The .NET framework provides two classes for TCP:
TcpClientTcpClient and and TcpListenerTcpListener
..NET uses the NET uses the EndPoint EndPoint class and class and IPEndPoint IPEndPoint subclass subclass to represent the TCP channel.to represent the TCP channel.
Communication with a TCP client is initiated in three Communication with a TCP client is initiated in three steps:steps:
1.1. Construct an instance of Construct an instance of TcpClientTcpClient2.2. Communicate using the socket’s streamCommunicate using the socket’s stream3.3. Close the connectionClose the connection
TCP Client and Echo server in C#0. using System; //For string, Int32, Console, ArgumentException
1. using System.text; //For Encoding
2. using System.IO; //For IOException
3. using System.Net.Sockets //For TcpClient, NetworkStream, SocketException
4.
5. class TcpEchoClient{
6.
7. static void Main(string[] args){
8.
9. if ((args.Length < 2) || (args.Length > 3)) { // Test for correct no of args
10. throw new ArgumentException(“Parameters: <Server> <Word> [<Port>]”);
11. }
12.
13. String server = args[0]; // Server name or IP address
14.
15.// Convert input String to bytes
16. byte[] byteBuffer = Encoding.ASCII.Getbytes(args[1]);
17.
18. //Use port argument if supplied, otherwise default to 7
19. Int servPort = (args.Length == 3) ? Int32.Parse(args[2]) : 7;
20.
TCP Client and Echo server in C#
21. TcpClient client = null;
22. NetworkStream netStream = null;
23.
24. try{
25. // Create socket that is connected to server on specified port
26. client = new TcpClient(server, servPort);
27.
28. Console.WriteLine(“Connected to server… sending echo string”);
29.
30. netStream = client.GetStream();
31.
32. // Send the encoded string to the server
33. netStream.Write(byteBuffer, 0, byteBuffer.Length);
34.
35. Console.WriteLine(“Sent {0} bytes to server…”, byteBuffer.Length);
36.
37. int totalBytesRcvd = 0; // Total bytes received so far
38. int bytesRcvd = 0; // Bytes received in last read
39.
TCP Client and Echo server in C#
40. //Receive the same string back from the server41. while(totalBytesRcvd < byteBuffer.Length){42. if((bytesRcvd = netStream.Read(byteBuffer, totalBytesRcvd, byteBuffer.Length – totalBytesRcvd)) == 0){43. Console.WriteLine(“Connection closed prematurely.”);45. break;46. }47. totalBytesRcvd += bytesRcvd;48. }49.50. Console.WriteLine(“Received {0} bytes from server: {1}”, totalBytesRcvd, 51. Encoding.ASCII.Getstring(byteBuffer, 0, totalBytesRcvd));52. 53. } catch (Exception e){54. Console.WriteLine(e.Message);55. } finally {56. netStream.Close();57. client.Close();58. }59. }60.}
TCP Client and Echo server in C#
Lines 15-16 convert the echo string to bytesLines 15-16 convert the echo string to bytes Line 19 finds the echo server portLine 19 finds the echo server port Lines 25-26 create the TCP socketLines 25-26 create the TCP socket Line 30 gets the socket streamLine 30 gets the socket stream Lines 32-33 send the string to the echo serverLines 32-33 send the string to the echo server Line 40-48 receive the reply from the echo serverLine 40-48 receive the reply from the echo server Lines 50-51 print the echoed stringLines 50-51 print the echoed string Lines 53-54 handle errorsLines 53-54 handle errors Lines 55-58 close the stream and socketLines 55-58 close the stream and socket
UDP Sockets The .NET framework provides UDP sockets The .NET framework provides UDP sockets
functionality using the class UdpClient. This allows for functionality using the class UdpClient. This allows for both sending and receiving UDP packets, and can be both sending and receiving UDP packets, and can be used to construct a UDP client and server.used to construct a UDP client and server.
The UDP client works in the following way:The UDP client works in the following way:
1.1. Construct an instance of UdpClientConstruct an instance of UdpClient
2.2. Communicate using the Send() and Receive() methods of UdpClientCommunicate using the Send() and Receive() methods of UdpClient
3.3. Use the Close() method of UdpClient to deallocate the socket.Use the Close() method of UdpClient to deallocate the socket.
UDP Client and Echo Server in C#0. using System; //For String, Int32, Console
1. using System.Text; //For Encoding
2. using System.Net; //For IPEndPoint
3. using System.Net.Sockets //For UdpClient, SocketException
4.
5. class UdpEchoClient {
6.
7. static void Main(string[] args) {
8.
9. if((args.Length < 2) || (args.Length > 3)) { // Test for correct no of args
10. throw new System.ArgumentException(“Parameters: <Server> <Word> [<Port>]”);
11. }
12.
13. String server = args[0]; // Server name or IP address
14.
15. // Use port argument if supplied, otherwise default to 7
16. int servPort = (args.Length == 3) ? Int32.Parse(args[2]) : 7;
17.
18. // Convert input String to an array of bytes
19. byte[] sendPacket = Encoding.ASCII.GetBytes(args[1]);
20.
21. // Create a UdpClient instance
22. UdpClient client = new UdpClient();
UDP Client and Echo Server in C#
23 try {24. // Send the echo string to the specified host and port25. client.Send(sendPacket, sendPacket.Length, server, servPort);26. 27. Console.WriteLine(“Sent {0} bytes to the server…”, sendPacket.Length);28.29. // This IPEndPoint instance will be populated with the remote sender’s endpoint information after the
Receive() call30. IPEndPoint remoteIPEndPoint = new IPEndPoint(IPAddress.Any, 0);31.32. // Attempt echo reply receive33. byte[] rcvPacket = client.Receive(ref remoteIPEndPoint);34.35. Console.Writeline(“Received {0} bytes from {1}: {2}”, rcvPacket.Length, remoteIPEndPoint, 36. Encoding.ASCII.Getstring(rcvPacket, 0,
rcvPacket.Length));37.38. } catch (SocketException se) {39. Console.WriteLine(se.ErrorCode + “: “ + se.Message);40. }41.42. client.Close();43. }44. }
UDP Client and Echo Server in C#
Lines 21-22 create the UDP socketLines 21-22 create the UDP socket Lines 24-25 send the datagramLines 24-25 send the datagram Lines 29-30 create a remote IP end point for Lines 29-30 create a remote IP end point for
receivingreceiving Lines 32-33 handle datagram receptionLines 32-33 handle datagram reception Lines 35-36 print reception resultsLines 35-36 print reception results Line 42 closes the socketLine 42 closes the socket
Voice over IP (VoIP)
VoIP is the routing of voice signals over an VoIP is the routing of voice signals over an IP-based network.IP-based network.
The analogue voice signal is converted to a The analogue voice signal is converted to a digital signal.digital signal.
The digital signal is compressed using a The digital signal is compressed using a codec (G.7xxx for voice, H.26xx for video)codec (G.7xxx for voice, H.26xx for video)
The digital signal is then split into packets The digital signal is then split into packets by a process called by a process called PacketizationPacketization
Voice over IP (VoIP)
Advantages:Advantages:
Incoming calls can be routed to a VoIP phone anywhere on Incoming calls can be routed to a VoIP phone anywhere on the networkthe network
Lower cost especially for international callsLower cost especially for international calls
Disadvantages:Disadvantages:
Received IP packets can arrive in any order or even be Received IP packets can arrive in any order or even be missing resulting in poor QoS.missing resulting in poor QoS.
Susceptible to power cuts Susceptible to power cuts
RTSPAudio/VideoApplications
ENUMCodecs
G.xxx, H.26x SDP
H.323 MEGACO/H.248 DNS RTP SAPRTCP MGCP RSVPSIP
TCP UDP
IP
Network Interface Layer Protocols
Voice over IP Protocols
Protocols supporting VoIP
Multicast IPMulticast IP Real-Time Transport Protocol (RTP)Real-Time Transport Protocol (RTP) Real-Time Control Protocol (RTCP)Real-Time Control Protocol (RTCP) Resource Reservation Protocol (RSVP)Resource Reservation Protocol (RSVP) Real-Time Streaming Protocol (RTSP)Real-Time Streaming Protocol (RTSP) Session Description Protocol (SDP)Session Description Protocol (SDP) Session Initiation Protocol (SIP)Session Initiation Protocol (SIP) Electronic Numbers (ENUM)Electronic Numbers (ENUM)
Protocols supporting VoIP
Multicast IPMulticast IP efficiently sends data to multiple receivers at the same efficiently sends data to multiple receivers at the same time on TCP/IP networks.time on TCP/IP networks.
RTPRTP provides end-to-end delivery services for data that requires real- provides end-to-end delivery services for data that requires real-time support.time support.
RTCPRTCP monitors the QoS and conveys information about each user in monitors the QoS and conveys information about each user in the communication session.the communication session.
RSVPRSVP requests an appropriate level of service from the network. requests an appropriate level of service from the network.
RTSPRTSP controls the delivery of data that has real-time properties. controls the delivery of data that has real-time properties.
SDPSDP describes a multimedia session for the purposes of session describes a multimedia session for the purposes of session announcement and invitation. announcement and invitation.
Protocols supporting VoIP
SIPSIP establishes a communication session establishes a communication session between two end-points. It creates, modifies between two end-points. It creates, modifies and terminates sessions between and terminates sessions between participants. participants.
ENUMENUM bridges the gap between telephone bridges the gap between telephone numbers and IP addresses.numbers and IP addresses.
Real-Time Transport Protocol (RTP)
V=2
Contributing Source (CSRC) Identifier(0 to 15 items)
20 ms Voice Sample
PX CC M PT Sequence Number
Timestamp
Synchronisation Source (SSRC) Identifier
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 11 1 1 1 1 1 1 1 1 1 2 2 2 2 2 2 2 2 2 2 3 3
Bits
V = Version (currently 2)
CC = CSRC Count. Counts the number of CSRC identifiers in the RTP header
CSRC – Identifies contributing sources (conferencing) in the payload. There can only be a maximum of 15 contributing sources. These are inserted by a mixer.
SSRC – Identifies synchronisation sources. It is chosen randomly so that two or more synchronisation sources in the same RTP session have the same SSRC identifier.
Voice over IP Packet Format
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 11 1 1 1 1 1 1 1 1 1 2 2 2 2 2 2 2 2 2 2 3 3
VER
Identifier
Time to live
Source Address
Destination Address
Options + Padding
Source Port
V=2
Contributing Source (CSRC) Identifier(0 – 15 items)
20 ms Voice Sample
IHL Type of service Total Length
Flags Fragment Offset
Protocol Header Checksum
Destination Port
Length Checksum
PX CC M PT Sequence Number
Timestamp
Synchronisation Source (SSRC) Identifier
Bits
IPv4 Header20 octets
+Options
+Padding
UDP Header8 Octets
RTP Header12 octets
+Identifiers
Data20 octets
References
““TCP/IP Illustrated, Volume 1, The Protocols”, W. TCP/IP Illustrated, Volume 1, The Protocols”, W. Richard Stevens, Addison-Wesley Professional Computing Richard Stevens, Addison-Wesley Professional Computing Series, 1994Series, 1994
““TCP/IP Sockets in C#, Practical Guide for Programmers”, TCP/IP Sockets in C#, Practical Guide for Programmers”, David B. Makofske, Michael J. Donahoo, Kenneth L. David B. Makofske, Michael J. Donahoo, Kenneth L. Calvert, The Practical Guide Series, Elsevier, 2004Calvert, The Practical Guide Series, Elsevier, 2004
““Voice over IP Technologies, Building the Converged Voice over IP Technologies, Building the Converged Network”, Mark A. Miller, M&T Books, 2002Network”, Mark A. Miller, M&T Books, 2002
Tutorial Sheet: Network Systems and Technologies by Prof R. A. Carrasco
1) 1) What is the principal difference between connectionless communication and connection-oriented What is the principal difference between connectionless communication and connection-oriented communication?communication?
2) 2) Two networks each provide reliable connection-oriented service. One of them offers a reliable byte Two networks each provide reliable connection-oriented service. One of them offers a reliable byte
stream and the other offers a reliable message stream. Are these identical? If so, why is the distinction stream and the other offers a reliable message stream. Are these identical? If so, why is the distinction mode? If not, give an example of how they differ.mode? If not, give an example of how they differ.
3) 3) What are two reasons for using layered protocols?What are two reasons for using layered protocols? 4) 4) Give two example applications for which connection-oriented service is appropriate. Now give two Give two example applications for which connection-oriented service is appropriate. Now give two
examples for which connectionless service is best.examples for which connectionless service is best. 5) 5) Are there any circumstances when a virtual circuit service will (or at least should) deliver packets out of Are there any circumstances when a virtual circuit service will (or at least should) deliver packets out of
order? Explain.order? Explain. 6) 6) Datagram subnets route each packet as a separate unit, independent of all others. Virtual circuit subnets Datagram subnets route each packet as a separate unit, independent of all others. Virtual circuit subnets
do not have to do this, since each data packet follows a predetermined route. Does this observation mean do not have to do this, since each data packet follows a predetermined route. Does this observation mean that virtual circuit subnets do not need the capability to route isolated packets from an arbitrary source to that virtual circuit subnets do not need the capability to route isolated packets from an arbitrary source to an arbitrary destination? Explain your answer.an arbitrary destination? Explain your answer.
7) 7) What does ‘negotiation’ mean when discussing network protocols? Give an example of it.What does ‘negotiation’ mean when discussing network protocols? Give an example of it.
8) 8) Give three examples of protocol parameters that might be negotiated when a connection is set up.Give three examples of protocol parameters that might be negotiated when a connection is set up. 9) 9) Discuss the advantages and disadvantages of message switching over circuit switching and Discuss the advantages and disadvantages of message switching over circuit switching and
performance comparison.performance comparison. 10) 10) Discuss the advantages/disadvantages of packet switching over circuit switching (and performance Discuss the advantages/disadvantages of packet switching over circuit switching (and performance
comparison)comparison) 11) 11) Discuss the characteristics and medium access control techniques of Broadcast Networks.Discuss the characteristics and medium access control techniques of Broadcast Networks. 12) 12) Describe the routing functions attributes and their elements.Describe the routing functions attributes and their elements. 13) 13) Describe the following routing strategies:Describe the following routing strategies:
Fixed RoutingFixed RoutingFloodingFloodingRandom RoutingRandom RoutingAdaptive RoutingAdaptive Routing
Wireless LANs
AdvantagesAdvantages Increased mobility of usersIncreased mobility of users Increased flexibility and fluidity, Increased flexibility and fluidity,
including ad-hoc networksincluding ad-hoc networks Instant networkingInstant networking Availability of LAN technologyAvailability of LAN technology
A. S. TanenBaum, "Computer Networks," Pearson Education, 2003, pp.292-302.
[1]
Wireless LANs
DisadvantagesDisadvantages Higher CostHigher Cost Lower PerformanceLower Performance Lower Reliability (Variable Channel Lower Reliability (Variable Channel
Characteristics)Characteristics) Multiple StandardsMultiple Standards Poor Inherent SecurityPoor Inherent Security
LAN Design
IEEE 802.11 Wireless LAN Draft Standard
Professor R. A. CarrascoProfessor R. A. Carrasco
A. S. TanenBaum, "Computer Networks," Pearson Education, 2003, pp.292-317.
[1]
Introduction
IEEE 802.11 Draft 5.0 is a draft standard for Wireless IEEE 802.11 Draft 5.0 is a draft standard for Wireless Local Area Network (WLAN) communication.Local Area Network (WLAN) communication.
This tutorial is intended to describe the relationship This tutorial is intended to describe the relationship between 802.11 and other LANs, and to describe some of between 802.11 and other LANs, and to describe some of the details of its operation.the details of its operation.
It is assumed that the audience is familiar with serial data It is assumed that the audience is familiar with serial data communications, the use of LANs and has some communications, the use of LANs and has some knowledge of radios.knowledge of radios.
802.11 Data Frame
Address 1FrameControl Duration Address 2 Address 3 Seq Address 4 Data
Check-sum
Bytes 2 2 6 6 6 2 6 0-2312 4
Version Type SubtypeToDS
FromDS MF
Re-try
Pwr More W O
Bits 2 2 4 1 1 1 1 1 1 1 1
Frame Control
Contents Glossary of 802.11 Wireless TermsGlossary of 802.11 Wireless Terms OverviewOverview 802.11 Media Access Control (MAC)802.11 Media Access Control (MAC) Frequency Hopping and Direct Sequence Spread Spectrum Frequency Hopping and Direct Sequence Spread Spectrum
TechniquesTechniques 802.11 Physical Layer (PHY)802.11 Physical Layer (PHY) SecuritySecurity PerformancePerformance Inter Access Point ProtocolInter Access Point Protocol Implementation SupportImplementation Support Raytheon ImplementationRaytheon Implementation
Glossary of 802.11 Wireless Terms Station (STA): A computer or device with a wireless network Station (STA): A computer or device with a wireless network
interface.interface. Access Point (AP): Device used to bridge the wireless-wired Access Point (AP): Device used to bridge the wireless-wired
boundary, or to increase distance as a wireless packet repeater.boundary, or to increase distance as a wireless packet repeater. Ad Hoc Network: A temporary one made up of stations in mutual Ad Hoc Network: A temporary one made up of stations in mutual
range.range. Infrastructure Network: One with one or more Access Points.Infrastructure Network: One with one or more Access Points. Channel: A radio frequency band, or Infrared, used for shared Channel: A radio frequency band, or Infrared, used for shared
communication.communication. Basic Service Set (BSS): A set of stations communicating wirelessly Basic Service Set (BSS): A set of stations communicating wirelessly
on the same channel in the same area, Ad Hoc or Infrastructure.on the same channel in the same area, Ad Hoc or Infrastructure. Extended Service Set (ESS): A set BSSs and wired LANs with Extended Service Set (ESS): A set BSSs and wired LANs with
Access Points that appear as a single logical BSS.Access Points that appear as a single logical BSS.
Glossary of 802.11 Wireless Terms, cont. BSSID & ESSID: Data fields identifying a stations BSS & BSSID & ESSID: Data fields identifying a stations BSS &
ESS.ESS. Clear Channel Assessment (CCA): A station function used Clear Channel Assessment (CCA): A station function used
to determine when it is OK to transmit.to determine when it is OK to transmit. Association: A function that maps a station to an Access Association: A function that maps a station to an Access
Point.Point. MAC Service Data Unit (MSDU): Data Frame passed MAC Service Data Unit (MSDU): Data Frame passed
between user & MAC.between user & MAC. MAC Protocol Data Unit (MPDU): Data Frame passed MAC Protocol Data Unit (MPDU): Data Frame passed
between MAC & PHY.between MAC & PHY. PLCP Packet (PLCP_PDU): Data Packet passed from PLCP Packet (PLCP_PDU): Data Packet passed from
PHY to PHY over the Wireless Medium.PHY to PHY over the Wireless Medium.
Overview, IEEE 802, and 802.11 Working Group IEEE Project 802 charter:IEEE Project 802 charter:
Local & Metropolitan Area NetworksLocal & Metropolitan Area Networks 1Mb/s to 100Mb/s and higher1Mb/s to 100Mb/s and higher 2 lower layers of 7 Layer OSI Reference Model2 lower layers of 7 Layer OSI Reference Model
IEEE 802.11 Working Group scope:IEEE 802.11 Working Group scope: Wireless connectivity for fixed, portable and moving stations Wireless connectivity for fixed, portable and moving stations
within a limited areawithin a limited area Appear to higher layers (LLC) the same as existing 802 Appear to higher layers (LLC) the same as existing 802
standardsstandards Transparent support of mobility (mobility across router Transparent support of mobility (mobility across router
ports is being address by a higher layer committee)ports is being address by a higher layer committee)
Overview, IEEE 802.11 Committee Committee formed in 1990Committee formed in 1990
Wide attendanceWide attendance Multiple Physical LayersMultiple Physical Layers
Frequency Hopping Spread SpectrumFrequency Hopping Spread Spectrum Direct Sequence Spread SpectrumDirect Sequence Spread Spectrum InfraredInfrared
2.4GHz Industrial, Scientific & Medical shared unlicensed band2.4GHz Industrial, Scientific & Medical shared unlicensed band 2.4 to 2.4835GHz with FCC transmitted power limits2.4 to 2.4835GHz with FCC transmitted power limits
2Mb/s & 1Mb/s data transfer2Mb/s & 1Mb/s data transfer 50 to 200 feet radius wireless coverage50 to 200 feet radius wireless coverage Draft 5.0 Letter Ballot passed and forwarded to Sponsor BallotDraft 5.0 Letter Ballot passed and forwarded to Sponsor Ballot
Published Standard anticipated 1997Published Standard anticipated 1997 Next 802.11 - November 11-14, Vancouver, BCNext 802.11 - November 11-14, Vancouver, BC
Chairman - Victor Hayes, [email protected] - Victor Hayes, [email protected]
Overview, 802.11 Architecture
STASTA
STA STA
STASTASTA STA
APAP
ESS
BSS
BSSBSS
BSS
Existing Wired LAN
Infrastructure Network
Ad Hoc Network
Ad Hoc Network
Overview, Wired vs. Wireless LANs 802.3 (Ethernet) uses CSMA/CD, Carrier Sense 802.3 (Ethernet) uses CSMA/CD, Carrier Sense
Multiple Access with 100% Collision Detect for Multiple Access with 100% Collision Detect for reliable data transferreliable data transfer
802.11 has CSMA/CA (Collision Avoidance)802.11 has CSMA/CA (Collision Avoidance) Large differences in signal strengthsLarge differences in signal strengths Collisions can only be inferred afterwardCollisions can only be inferred afterward
Transmitters fail to get a responseTransmitters fail to get a responseReceivers see corrupted data through a CRC errorReceivers see corrupted data through a CRC error
802.11 Media Access Control
Carrier Sense: Listen before talkingCarrier Sense: Listen before talking Handshaking to infer collisionsHandshaking to infer collisions
DATA-ACK packetsDATA-ACK packets Collision AvoidanceCollision Avoidance
RTS-CTS-DATA-ACK to request the mediumRTS-CTS-DATA-ACK to request the medium Duration information in each packetDuration information in each packet Random Backoff after collision is determinedRandom Backoff after collision is determined Net Allocation Vector (NAV) to reserve bandwidthNet Allocation Vector (NAV) to reserve bandwidth Hidden Nodes use CTS duration informationHidden Nodes use CTS duration information
802.11 Media Access Control, cont. FragmentationFragmentation
Bit Error Rate (BER) goes up with distance and decreases Bit Error Rate (BER) goes up with distance and decreases the probability of successfully transmitting long framesthe probability of successfully transmitting long frames
MSDUs given to MAC can be broken up into smaller MSDUs given to MAC can be broken up into smaller MPDUs given to PHY, each with a sequence number for MPDUs given to PHY, each with a sequence number for reassemblyreassembly
Can increase range by allowing operation at higher BERCan increase range by allowing operation at higher BER Lessens the impact of collisionsLessens the impact of collisions
• Trade overhead for overhead of RTS-CTSTrade overhead for overhead of RTS-CTS• Less impact from Hidden NodesLess impact from Hidden Nodes
802.11 Media Access Control, cont Beacons used convey network parameters such as Beacons used convey network parameters such as
hop sequencehop sequence Probe Requests and Responses used to join a Probe Requests and Responses used to join a
networknetwork Power Savings ModePower Savings Mode
Frames stored at Access Point or Stations for Frames stored at Access Point or Stations for sleeping Stationssleeping Stations
Traffic Indication Map (TIM) in Frames alerts Traffic Indication Map (TIM) in Frames alerts awaking Stationsawaking Stations
802.11 Protocol Stack
Logical Link Control
802.11Infrared
802.11FHSS
802.11DSSS
802.11aOFDM
802.11bHR-DSSS
802.11gOFDM
MACSub-layer
UpperLayers
DataLinkLayer
PhysicalLayer
Performance of IEEE802.11b
MAC Header30 Bytes
CRC4 Bytes
trt
MPDUsec50 contt
prt
DIFS BackoffPLCP
PreamblePLCP
HeaderMPDU SIFS
PLCP Preamble
Head
er Ack14 Bytes
sec10 prt ackt
Data
Performance of IEEE802.11b
Successful transmission of a single frame Successful transmission of a single frame PLCP = physical layer convergence protocol PLCP = physical layer convergence protocol
preamblepreamble
prt Header transmission time (varies according to the bit rate used by the host
SIFS = 10 sec (Short Inter Frame Space) is the MAC acknowledgement transmission time (10 sec if the selected rate is 11Mb/sec, as the ACK length is 112 bits
Performance of IEEE802.11b
DIFS = DIFS = sec50
trt = is the frame transmission time, when it transmits at 1Mb/s, the long PLCP header is used and
prt = sec192
If it uses 2, 5.5 or 11 Mb/s, then the short PLCP header can be optionally used
prt = sec96
Performance of IEEE802.11b
For bit rates greater than 1Mb/s and the frame size of For bit rates greater than 1Mb/s and the frame size of 1500 Bytes of data (MPDU of total 1534 Bytes), 1500 Bytes of data (MPDU of total 1534 Bytes), proportion p of the useful throughput measured above proportion p of the useful throughput measured above the MAC layer will be:the MAC layer will be:
70.01534
1500
T
tP tr
So, a single host sending long frames over a 11Mb/s So, a single host sending long frames over a 11Mb/s radio channel will have a maximum useful radio channel will have a maximum useful throughput of 7.74Mb/sthroughput of 7.74Mb/s
Performance of IEEE802.11b
If we neglect propagation time, the overall transmission If we neglect propagation time, the overall transmission time is composed of the transmission time and a time is composed of the transmission time and a constant overheadconstant overhead
ovtr ttT
Where the constant overhead
ackprprov ttSIFStDIFSt
Performance of IEEE802.11b
For N hosts, assuming that multiple successive For N hosts, assuming that multiple successive collisions are negligible, collisions are negligible, the proportion of collisions experienced for each packet successfully acknowledged at the MAC is given by:
1min )/11(1)( N
c CWNP
Performance of IEEE802.11b
The overall frame transmission time experienced by a The overall frame transmission time experienced by a single host when competing with N – 1 other hosts has single host when competing with N – 1 other hosts has to be increased by time interval to be increased by time interval ttcontcont that accounts for that accounts for
the time spent in contention proceduresthe time spent in contention procedures
Performance of IEEE802.11b
Backoff interval is doubled when a collision occursBackoff interval is doubled when a collision occurs
min
minmin
2
)(1
)())(1(2
)(
CWN
NPSLOT
N
CWNPNP
N
CWSLOTNt
c
cccont
N stations, mean wait interval per transmissionN stations, mean wait interval per transmission
N
CWSLOT
1
2min
Performance of IEEE802.11b
So the overall transmission timeSo the overall transmission time
)()( NtttNT contovtr
proportion p of the useful throughput measured obtained proportion p of the useful throughput measured obtained by a host:by a host:
)(/)( NTtNp tr
Performance Anomaly of IEEE802.11b Consider how the situation in which N hosts of different Consider how the situation in which N hosts of different
bit rate compete for the radio channel. N-1 hosts use the bit rate compete for the radio channel. N-1 hosts use the high transmission rate R = 11Mb/s and one host transmits high transmission rate R = 11Mb/s and one host transmits at a degraded rate r = 5.5, 2, or 1Mb/sat a degraded rate r = 5.5, 2, or 1Mb/s
r
ST
R
ST d
trd
tr or
dSWhere is the data frame length in bits
Performance Anomaly of IEEE802.11b
fovt s
ovt
contdf
ovf tR
StT
and the associated overhead time
contds
ovs tr
StT
Similarly, let Ts be the corresponding time for a “slow” host transmitting at rate r
Let Tf be the overall transmission time for a “fast” host transmitting at rate R
Performance Anomaly of IEEE802.11b
fsjam TN
TN
t )2
1(2
NtNPTTN
TU
jamcsf
ff
)()1(
where
f
dff T
SUX
The throughput obtained by a “fast” host is given by:
We can express the channel utilization of the “fast” host as
Performance Anomaly of IEEE802.11b
NtNPTTN
TU
jamcsf
ss
)()1(
s
dss T
SUX
Similarly, we can express the channel utilization of the “slow” host as
The throughput obtained by a “slow” host is given by:
Performance Anomaly of IEEE802.11b
sf XX
Result : Result :
Fast hosts transmitting at a higher rate R obtain the Fast hosts transmitting at a higher rate R obtain the same throughput as slow hosts transmitting at a same throughput as slow hosts transmitting at a lower rate r.lower rate r.
Performance Anomaly of IEEE802.11b
Validated by OPNET SimulationValidated by OPNET Simulation
Performance of IEEE802.11b
Study:Study:
The UDP traffic &The UDP traffic &
TCP traffic.TCP traffic.
Flows in IEEE 802.11 WLANsFlows in IEEE 802.11 WLANs
Frequency Hopping and Direct Sequence Spread Spectrum Techniques Spread Spectrum used to avoid interference from licensed and other non-Spread Spectrum used to avoid interference from licensed and other non-
licensed users, and from noise, e.g., microwave ovenslicensed users, and from noise, e.g., microwave ovens
Frequency Hopping (FHSS)Frequency Hopping (FHSS) Using one of 78 hop sequences, hop to a new 1MHz channel (out of Using one of 78 hop sequences, hop to a new 1MHz channel (out of
the total of 79 channels) at least every 400millisecondsthe total of 79 channels) at least every 400milliseconds Requires hop acquisition and synchronizationRequires hop acquisition and synchronization Hops away from interferenceHops away from interference
Direct Sequence (DSSS)Direct Sequence (DSSS) Using one of 11 overlapping channels, multiply the data by an 11-bit Using one of 11 overlapping channels, multiply the data by an 11-bit
number to spread the 1M-symbol/sec data over 11MHznumber to spread the 1M-symbol/sec data over 11MHz Requires RF linearity over 11MHzRequires RF linearity over 11MHz Spreading yields processing gain at receiverSpreading yields processing gain at receiver Less immune to interferenceLess immune to interference
802.11 Physical Layer Preamble Sync, 16-bit Start Frame Delimiter, PLCP Header including 16-bit Preamble Sync, 16-bit Start Frame Delimiter, PLCP Header including 16-bit
Header CRC, MPDU, 32-bit CRCHeader CRC, MPDU, 32-bit CRC
FHSSFHSS 2 & 4GFSK2 & 4GFSK Data Whitening for Bias SuppressionData Whitening for Bias Suppression
32/33 bit stuffing and block inversion32/33 bit stuffing and block inversion 7-bit LFSR scrambler7-bit LFSR scrambler
80-bit Preamble Sync pattern80-bit Preamble Sync pattern 32-bit Header32-bit Header
DSSSDSSS DBPSK & DQPSKDBPSK & DQPSK Data Scrambling using 8-bit LFSRData Scrambling using 8-bit LFSR 128-bit Preamble Sync pattern128-bit Preamble Sync pattern 48-bit Header48-bit Header
802.11 Physical Layer, cont. Antenna DiversityAntenna Diversity
Multipath fading a signal can inhibit receptionMultipath fading a signal can inhibit reception Multiple antennas can significantly minimizeMultiple antennas can significantly minimize Spacial Separation of OrthoganalitySpacial Separation of Orthoganality Choose Antenna during Preamble Sync patternChoose Antenna during Preamble Sync pattern
Presence of Preamble Sync patternPresence of Preamble Sync pattern Presence of energyPresence of energy
• RSSI - Received Signal Strength IndicationRSSI - Received Signal Strength Indication Combination of bothCombination of both
Clear Channel AssessmentClear Channel Assessment Require reliable indication that channel is in use to defer transmissionRequire reliable indication that channel is in use to defer transmission Use same mechanisms as for Antenna DiversityUse same mechanisms as for Antenna Diversity Use NAV informationUse NAV information
A Fragment Burst
Frag1
ACK
RTS Frag2 Frag3
CTS ACK ACK
NAV
NAV
A
B
C
D
Time
Fragment Burst
Security
Authentication: A function that determines Authentication: A function that determines whether a Station is allowed to participate in whether a Station is allowed to participate in network communicationnetwork communication Open System (null authentication) & Open System (null authentication) &
Shared KeyShared KeyWEP - Wired Equivalent PrivacyWEP - Wired Equivalent Privacy
• Encryption of dataEncryption of data
ESSID offers casual separation of trafficESSID offers casual separation of traffic
Performance, Theoretical Maximum Throughput Throughput numbers in Mbits/sec:Throughput numbers in Mbits/sec:
Assumes 100ms beacon interval, RTS, CTS used, no collisionAssumes 100ms beacon interval, RTS, CTS used, no collision Slide courtesy of Matt Fischer, AMDSlide courtesy of Matt Fischer, AMD
1 Mbit/sec 2 Mbit/sec
MSDU size(bytes)
DS FH (400mshop time)
DS FH (400mshop time)
128 0.364 0.364 0.517 0.474
512 0.694 0.679 1.163 1.088
512(frag size = 128)
0.503 0.512 0.781 0.759
2304 0.906 0.860 1.720 1.624
WLAN OPNET Simulation
Maximum Maximum throughput of a throughput of a single station single station as a function of as a function of MSDU size MSDU size (802.11b, (802.11b, 11Mb/s)11Mb/s)
Background for broadband wireless technologies UWB – Ultra Wide Band UWB – Ultra Wide Band
High speed wireless personal area networkHigh speed wireless personal area network Wi-Fi – Wireless fidelity Wi-Fi – Wireless fidelity
Wireless technology for indoor environment (WLANS)Wireless technology for indoor environment (WLANS) broader range that WPANs broader range that WPANs
WiMAX – Worldwide Interoperability for Microwave Access WiMAX – Worldwide Interoperability for Microwave Access Wireless Metropolitan Area Networks (WMANs)Wireless Metropolitan Area Networks (WMANs) For outdoor coverage in LOS and NLOS environment For outdoor coverage in LOS and NLOS environment Fixed and Mobile standards Fixed and Mobile standards
3G – Third generation3G – Third generation Wireless Wide Area Networks (WMANs) are the broadest range wireless Wireless Wide Area Networks (WMANs) are the broadest range wireless
networks networks High speed data transmission and greater voice capacity for mobile usersHigh speed data transmission and greater voice capacity for mobile users
Bluetooth -Bluetooth -A. S. TanenBaum, "Computer Networks," Pearson Education, 2003, pp.310-317.
[1]
What is WiMax?
WiMAX is an IEEE802.16/ETSI HiperMAN WiMAX is an IEEE802.16/ETSI HiperMAN based certificate for equipments fulfilling the based certificate for equipments fulfilling the interoperability requirements set by WiMAX interoperability requirements set by WiMAX Forum.Forum.
WiMAX Forum comprises of industry leaders WiMAX Forum comprises of industry leaders who are committed to the open interoperability of who are committed to the open interoperability of all products used for broadband wireless access. all products used for broadband wireless access.
The technique or technology behind the standards The technique or technology behind the standards is often referred as WiMAXis often referred as WiMAX
A. S. TanenBaum, "Computer Networks," Pearson Education, 2003, pp.302-310.
[1]
What is WiMax?
Broadband is thus a Broadband Wireless Broadband is thus a Broadband Wireless Access (BWA) techniqueAccess (BWA) technique
WiMax offers fast broadband connections WiMax offers fast broadband connections over long distancesover long distances
The interpretability of different vendor’s The interpretability of different vendor’s product is the most important factor when product is the most important factor when comparing to the other techniques.comparing to the other techniques.
The IEEE 802.16 Standards
The IEEE 802.16 standards family The IEEE 802.16 standards family - broadband wireless wideband internet connection- broadband wireless wideband internet connection- wider coverage than any wired or wireless connection - wider coverage than any wired or wireless connection before before
Wireless system have the capacity to address broad Wireless system have the capacity to address broad geographic areas without the expensive wired geographic areas without the expensive wired infrastructureinfrastructure
For example, a study made in University of Oulu state that For example, a study made in University of Oulu state that WiMax is clearly more cost effective solution for WiMax is clearly more cost effective solution for providing broadband internet connection in Kainuu than providing broadband internet connection in Kainuu than xDSLxDSL
The IEEE 802.16 Standards
The IEEE 802.16 standards family The IEEE 802.16 standards family - broadband wireless wideband internet connection- broadband wireless wideband internet connection- wider coverage than any wired or wireless connection - wider coverage than any wired or wireless connection before before
Wireless system have the capacity to address broad Wireless system have the capacity to address broad geographic areas without the expensive wired geographic areas without the expensive wired infrastructureinfrastructure
For example, a study made in University of Oulu state that For example, a study made in University of Oulu state that WiMax is clearly more cost effective solution for WiMax is clearly more cost effective solution for providing broadband internet connection in Kainuu than providing broadband internet connection in Kainuu than xDSLxDSL
The IEEE 802.16 Standards 802.16, published in April 2002802.16, published in April 2002
- A set od air interfaces on a common MAC protocol - A set od air interfaces on a common MAC protocol - Addresses frequencies 10 to 66 GHz- Addresses frequencies 10 to 66 GHz- Single carrier (SC) and only LOS- Single carrier (SC) and only LOS
802.16a, published in January 2003802.16a, published in January 2003- A completed amendment that extends the physical layer to the 2 to 11 GHz - A completed amendment that extends the physical layer to the 2 to 11 GHz both licensed and lincensed-exempt frequencies both licensed and lincensed-exempt frequencies - SC, 256 point FFT OFDM and 2048 point FFT OFDMA- SC, 256 point FFT OFDM and 2048 point FFT OFDMA- LOS and NLOS- LOS and NLOS
802.16-2004, published in July 2004802.16-2004, published in July 2004- Revises and replaces 802.16, 802.16a and 802.16 REVd.- Revises and replaces 802.16, 802.16a and 802.16 REVd.- This announcements marks a significant milestone in the development of - This announcements marks a significant milestone in the development of future WiMax technology future WiMax technology - P802.16-2004/Corl published on 8.11.2005- P802.16-2004/Corl published on 8.11.2005
IEEE 802.16: Broadband Wireless MAN Standard (WiMAX) An 802.16 wireless service provides a communications path between a An 802.16 wireless service provides a communications path between a
subscriber site and a core network such as the public telephone subscriber site and a core network such as the public telephone network and the Internet. This wireless broadband access standard network and the Internet. This wireless broadband access standard provides the missing link for the "last mile" connection in provides the missing link for the "last mile" connection in metropolitan area networks where DSL, Cable and other broadband metropolitan area networks where DSL, Cable and other broadband access methods are not available or too expensive. access methods are not available or too expensive.
Comparison Overview of IEEE 802.16a
ParametersParameters 802.16a 802.16a (WiMax)(WiMax)
802.11 802.11 (WLAN) (WLAN)
802.15 802.15 (Bluetooth)(Bluetooth)
Frequency BandFrequency Band 2-11GHz2-11GHz 2.4GHz2.4GHz VariesVaries
RangeRange ~31miles~31miles ~100meters~100meters ~10meters~10meters
Data transfer rateData transfer rate 70 Mbps70 Mbps 11 Mbps – 55 11 Mbps – 55 MbpsMbps
20Kbps – 55 20Kbps – 55 MbpsMbps
Number of UsersNumber of Users ThousandsThousands DozensDozens DozensDozens
• IEEE 802.16 and WiMAX are designed as a complimentary technology to Wi-Fi and Bluetooth. The following table provides a quick comparison of 802.16a with to 802.11b
Protocol Structure -IEEE 802.16: Standard (WiMAX) IEEE 802.16 Protocol Architecture has 4 layers: Convergence, MAC, IEEE 802.16 Protocol Architecture has 4 layers: Convergence, MAC,
Transmission and physical, which can be map to two OSI lowest Transmission and physical, which can be map to two OSI lowest layers: physical and data linklayers: physical and data link
WiMAX OPNET Simulation
5 http users
Results
ALOHA and Packet Broadcasting Channel
Prof. R. A. CarrascoProf. R. A. Carrasco
School of Electrical, Electronic and Computer engineeringSchool of Electrical, Electronic and Computer engineering20062006
University of Newcastle-upon-TyneUniversity of Newcastle-upon-Tyne
A. S. TanenBaum, "Computer Networks," Pearson Education, 2003, pp.251-264.
[1]
Packet Broadcasting Related Works by Metcalfe and Abransom1) 1970: N. Abramson, “The ALOHA System – 1) 1970: N. Abramson, “The ALOHA System –
Another alternative for computer Another alternative for computer communications.”, in Proc. AFIPS Press, vol 37, communications.”, in Proc. AFIPS Press, vol 37, 19701970
2) 1973: R. M. Metcalfe, “Packet communication,” 2) 1973: R. M. Metcalfe, “Packet communication,” MIT, Cambridge, MA, Rep. MAC TR-114, July 1973.MIT, Cambridge, MA, Rep. MAC TR-114, July 1973.
3) 1977: N. Abramson, “The Throughput of Packet 3) 1977: N. Abramson, “The Throughput of Packet Broadcasting Channels,” IEEE Trans. Commun., Broadcasting Channels,” IEEE Trans. Commun., vol. COM-25, no. 10, Jan 1977vol. COM-25, no. 10, Jan 1977
4) 1985: N. Abramson, “Development of the 4) 1985: N. Abramson, “Development of the ALOAHANET,” IEEE Trans. Info. Theory., March ALOAHANET,” IEEE Trans. Info. Theory., March 19851985
IEEE Transactions on Information Theory, March 1985
Development of the ALOHANETDevelopment of the ALOHANET
ALOHA Project
Started In September 1968Started In September 1968 GoalGoal
To build computer network in University of To build computer network in University of Hawaii.Hawaii.
To investigate the use of radio communications To investigate the use of radio communications as an alternative to the telephone system for as an alternative to the telephone system for computer communication.computer communication.
To determine those situations where radio To determine those situations where radio communications are preferable to conventional communications are preferable to conventional wire communicationswire communications
Problem
Limited Resource: ChannelLimited Resource: Channel Intermittent operation typical of Intermittent operation typical of
interactive computer terminal interactive computer terminal don’t need point-to-point channels. don’t need point-to-point channels. (FDMA or TDMA)(FDMA or TDMA)
Spread Spectrum is not Spread Spectrum is not appropriate to share the channel.appropriate to share the channel.
Approach
Packet Broadcasting ChannelsPacket Broadcasting Channels Each user transmits its packets over the Each user transmits its packets over the
common broadcast channel.common broadcast channel. Key innovationKey innovation of ALOHANET. of ALOHANET.
There are basically two types of ALOHA There are basically two types of ALOHA systemssystems
--Synchronized or slotted and--Synchronized or slotted and
--Unsynchronized or unslotted--Unsynchronized or unslotted
System Design
1968, they decided main approach (Packet 1968, they decided main approach (Packet Broadcasting) for Broadcasting) for design simplicitydesign simplicity. .
Frequency Band: two 100KHz bandwidth Frequency Band: two 100KHz bandwidth channels at 407.350MHz and 413.475MHz.channels at 407.350MHz and 413.475MHz.
TCU (Terminal Control Unit):TCU (Terminal Control Unit): Formatting of the ALOHA packets.Formatting of the ALOHA packets. Retransmission protocol.Retransmission protocol. A Terminal attached TCU by means of RS232.A Terminal attached TCU by means of RS232. Half duplex mode. (too expensive memory)Half duplex mode. (too expensive memory)
History 1971: start operation in University of Hawaii.1971: start operation in University of Hawaii.
1971-72: build additional TCUs.1971-72: build additional TCUs.
1972: connect to ARPANET using satellite channel. (56kbps)1972: connect to ARPANET using satellite channel. (56kbps)
1973: Metcalfe’s doctorial dissertation about packet broadcasting. 1973: Metcalfe’s doctorial dissertation about packet broadcasting.
1973: PACNET, international satellite networks. (9600 bits/s)1973: PACNET, international satellite networks. (9600 bits/s)
1973 ~ : Many researches about “packet broadcasting”.1973 ~ : Many researches about “packet broadcasting”. 1976: slotted ALOHA.1976: slotted ALOHA.
1984: unslotted ALOHA in the UHF band by Motorola.1984: unslotted ALOHA in the UHF band by Motorola.
Strategic Theoretical Realities An appreciation of the basic capacity of the channels and the An appreciation of the basic capacity of the channels and the
matching of that capacity to the information rate of the signals.matching of that capacity to the information rate of the signals.
In data network, distinguish between the average data rate and In data network, distinguish between the average data rate and the burst data ratethe burst data rate
Network design: to handle different kinds of signals from Network design: to handle different kinds of signals from different source.different source.
Deals with the problem of scaling for large system.Deals with the problem of scaling for large system.
Packet broadcasting channel is more scalable than point-to-Packet broadcasting channel is more scalable than point-to-point channel or switching.point channel or switching.
Theoretical analysis give good guide to design network, but the Theoretical analysis give good guide to design network, but the converse also is true.converse also is true. The operation of a real network can be a valuable guide to the The operation of a real network can be a valuable guide to the
selection of theoretical problems.selection of theoretical problems.
Packet Switching and Packet Broadcasting Packet switching can provide a powerful means of Packet switching can provide a powerful means of
sharing communication resources.sharing communication resources. But it employ point-to-point channels and large But it employ point-to-point channels and large
switches for routing.switches for routing. By use of packet broadcastingBy use of packet broadcasting
Elimination of routing and switches.Elimination of routing and switches. System simplicitySystem simplicity Some channels are basically broadcast channel. Some channels are basically broadcast channel.
(satellite, ..)(satellite, ..)
• Needs unified presentation of packet broadcasting Needs unified presentation of packet broadcasting theory.theory.
Packet Broadcasting Channel Each user transmits packets over the Each user transmits packets over the
common broadcast channel completely common broadcast channel completely unsynchronized.unsynchronized.
Loss due to the overlap. Loss due to the overlap. How many users can share a channel?How many users can share a channel?
Recovery of Lost Packets
Positive Acknowledgements.Positive Acknowledgements.
Transponder Packet Broadcasting.Transponder Packet Broadcasting.
Carrier Sense Packet Broadcasting.Carrier Sense Packet Broadcasting.
Packet Recovery CodesPacket Recovery Codes
ALOHA Systems and Protocols We assume that the start time of packets/s that are We assume that the start time of packets/s that are
transmitted is a Poisson point processtransmitted is a Poisson point process
An average rate of An average rate of λλ packets packets
Let TLet Tpp denote the time duration of a packet denote the time duration of a packet
The normalised channel traffic G is definedThe normalised channel traffic G is defined G=G=λλTTpp
It also called the offered channel trafficIt also called the offered channel traffic
ALOHA Capacity
Errors reduce the ALOHA CapacityErrors reduce the ALOHA Capacity Random noise errorsRandom noise errors Errors caused by packet overlap.Errors caused by packet overlap.
Statistical Analysis:
S: Channel ThroughputG: Channel Traffic
Throughput is maximum 1/2e when channel traffic equals 0.5.
ALOHA Capacity
Meaning of the resultMeaning of the result ALOHA: 9600 bits/sALOHA: 9600 bits/s Terminal: 5bits/sTerminal: 5bits/s
9600 X 1/2e = about 1600 bits/s9600 X 1/2e = about 1600 bits/s The channel can handle the traffic of The channel can handle the traffic of
over 300 active terminals and each over 300 active terminals and each terminal will operate at a peak data terminal will operate at a peak data rate 9600 bits/srate 9600 bits/s
ALOHA OPNET Simulation
20 transmitters, 1 receiver20 transmitters, 1 receiver The packet interarrival time will be varied The packet interarrival time will be varied
to produce different levels of trafficto produce different levels of traffic
Results
Simulation results show Simulation results show that the maximum that the maximum throughput is achieved throughput is achieved near G = 0.5 and is near G = 0.5 and is close to the theoretically close to the theoretically expected value of 0.18 expected value of 0.18
This matches the This matches the theoretical relation theoretical relation given bygiven by
Slotted ALOHA Channel Capacity
Each user can start his packet only Each user can start his packet only at certain fixed instants.at certain fixed instants.
Statistical Analysis
It increase the throughput
Mixed Data Rates
Unslotted ALOHA: Variable Packet LengthsUnslotted ALOHA: Variable Packet Lengths = Long Packet Length/ Short Packet Length= Long Packet Length/ Short Packet Length G1 = Short Packet TrafficG1 = Short Packet Traffic G2 = Long Packet TrafficG2 = Long Packet Traffic
Total channel throughput can undergo a significant decrease.
Slotted ALOHA: Variable Packet Rates Assume ALOHA used by Assume ALOHA used by nn users with different channel users with different channel
traffic.traffic.
ALOHA
Meaning of the resultMeaning of the result In a lightly loaded slotted ALOHA In a lightly loaded slotted ALOHA
channel, a single user can transmit channel, a single user can transmit data at rates above the limit 1/e. data at rates above the limit 1/e. : Excess Capacity.: Excess Capacity.
Important for the network consisting Important for the network consisting of many interactive terminal users of many interactive terminal users and small number of users who send and small number of users who send large but infrequent files.large but infrequent files.
Question 1
In a pure ALOHA system, the channel bit In a pure ALOHA system, the channel bit rate is 2400bits/s. Suppose that each rate is 2400bits/s. Suppose that each terminal transmits a 100-bit message every terminal transmits a 100-bit message every minute on average.minute on average.
i) Determine the maximum number of i) Determine the maximum number of terminals that can use the channelterminals that can use the channel
ii) Repeat (i) if slotted ALOHA is usedii) Repeat (i) if slotted ALOHA is used
Question 2
An alternative derivation for theAn alternative derivation for the
throughput in a pure ALOHA system throughput in a pure ALOHA system
may be obtained from the relationmay be obtained from the relation
G=S+A, where A is the average G=S+A, where A is the average
(normalised) rate of retransmission. Show that(normalised) rate of retransmission. Show that
A=G(1-A=G(1-ee-2G-2G ) and then solve for S. ) and then solve for S.
Question 3
Consider a pure ALOHA system that is Consider a pure ALOHA system that is operating with a throughput S=0.1operating with a throughput S=0.1
and packets are generated with a and packets are generated with a
Poisson arrival rate Poisson arrival rate λλ. Determine: . Determine:
i)i) The value of GThe value of G
ii)ii) The average number of attempted The average number of attempted
transmissions to send a packet.transmissions to send a packet.
Question 4 Consider a CSMA/CD system in which the Consider a CSMA/CD system in which the
transmission rate on the bus is 10 Mtransmission rate on the bus is 10 Mττbits/s. The bits/s. The bus is 2 Km and the propagation delay is 5 bus is 2 Km and the propagation delay is 5 μμs/Km. s/Km.
Packets are 1000 bits long. Packets are 1000 bits long. Determine:Determine:
i) The end-to-end delay i) The end-to-end delay dd..
ii) The packet duration Tii) The packet duration Tpp
iii) The ratio iii) The ratio dd/T/Tpp
iv) The maximum utilization of the bus and the maximum bit iv) The maximum utilization of the bus and the maximum bit rate.rate.
MSc Telecommunications Questions
by Professor R. A. Carrasco 1.1. Describe the evolution of the Internet and protocols for a communication network. Describe the evolution of the Internet and protocols for a communication network.
2.2. Explain the concept of a hub, bridge, router and modem for local area networks. Explain the concept of a hub, bridge, router and modem for local area networks.
3.3. Explain the concept and protocols of Ethernet (IEEE 802.3), Token Bus (IEEE 820.4) and Token Ring Explain the concept and protocols of Ethernet (IEEE 802.3), Token Bus (IEEE 820.4) and Token Ring (IEEE 802.5) (IEEE 802.5)
4.4. Describe how you can determine the utilisation for IEEE 802.3 and proveDescribe how you can determine the utilisation for IEEE 802.3 and prove
5.5. Give advantages and disadvantages of a wireless LAN Give advantages and disadvantages of a wireless LAN
6.6. Describe the criteria for LAN design Describe the criteria for LAN design
7.7. Explain the architecture for IEEE 802.Explain the architecture for IEEE 802.xx, TCP/IP and ISO/OSI , TCP/IP and ISO/OSI
8.8. Describe the OSI and TCP/IP model Describe the OSI and TCP/IP model
9.9. Explain each feature of the IP datagram Explain each feature of the IP datagram
10.10. Explain the Internet classes and give an example of how to design an IP address for a networkExplain the Internet classes and give an example of how to design an IP address for a network
))21(1(
1
kat
TU
v
11.11. Explain the concept of ARP, RARP, DHCP and DNS Explain the concept of ARP, RARP, DHCP and DNS
12.12. Explain IPv4 and IPv6 and how they differ Explain IPv4 and IPv6 and how they differ
13.13. Explain TCP, TCP Client Ports, TCP Server Ports, Error Control, Flow Control and Congestion Explain TCP, TCP Client Ports, TCP Server Ports, Error Control, Flow Control and Congestion Control Control
14.14. Describe UDP Describe UDP
15.15. Explain the concept of TCP sockets and what their relation is with the different socket classes Explain the concept of TCP sockets and what their relation is with the different socket classes
16.16. Repeat for UDP Repeat for UDP
17.17. Give advantages and disadvantages of Voice over IP (VoIP) Give advantages and disadvantages of Voice over IP (VoIP)
18.18. Explain VoIP protocols and how they are related to each other Explain VoIP protocols and how they are related to each other
19.19. Give an overview of the IEEE 802 and IEEE 802.11 working group Give an overview of the IEEE 802 and IEEE 802.11 working group
20.20. Give an example of an IEEE 802.11 WLAN architecture and explain stations and access points Give an example of an IEEE 802.11 WLAN architecture and explain stations and access points
21.21. Explain how to determine the channel utilisation expression to evaluate the performance of IEEE Explain how to determine the channel utilisation expression to evaluate the performance of IEEE 802.11b 802.11b
22.22. Describe the concept of a fragment burst Describe the concept of a fragment burst
23.23. Make comparisons between WiMax, WLAN and Bluetooth Make comparisons between WiMax, WLAN and Bluetooth
24.24. For security in communication networks, describe private and public key cryptography for Internet For security in communication networks, describe private and public key cryptography for Internet browsers. browsers.
25.25. Why is the ALOHA project important in a broadcasting system? Why is the ALOHA project important in a broadcasting system?
26.26. Explain how to determine the ALOHA capacity and channel throughput Explain how to determine the ALOHA capacity and channel throughput
27.27. Answer the followingAnswer the following
(a)(a) What do connection oriented, acknowledged connectionless and connectionless services What do connection oriented, acknowledged connectionless and connectionless services stand for? Give example applications for each of these services.stand for? Give example applications for each of these services.
(b)(b) Explain briefly the following:Explain briefly the following: What is meant by expressions, flow control and error control?What is meant by expressions, flow control and error control? What is HDLCWhat is HDLC Your answer should focus only on the following: What does HDLC stand for? Which Your answer should focus only on the following: What does HDLC stand for? Which
layer of the ISO/OSI layer does it relate to? What is the structure/topology of HDLC layer of the ISO/OSI layer does it relate to? What is the structure/topology of HDLC showing how different nodes communicate with each other indicating if it uses showing how different nodes communicate with each other indicating if it uses distributed communication or master slave based communications?distributed communication or master slave based communications?
(c)(c) Explain with the aid of a diagram how a leaky bucket algorithm works for congestion Explain with the aid of a diagram how a leaky bucket algorithm works for congestion control and how it can be used to aid the transmission of constant bit rate applications.control and how it can be used to aid the transmission of constant bit rate applications.
(d)(d) Give five important quality of service performance parameters and their brief definitions.Give five important quality of service performance parameters and their brief definitions.
28.28. Answer the followingAnswer the following(a)(a) Define classes A,B, and C for IPV4 networks. How many class C networks can be defined Define classes A,B, and C for IPV4 networks. How many class C networks can be defined
under a class A network? What is the standard net mask for a class B network?under a class A network? What is the standard net mask for a class B network?(b)(b) In a class C network that contains 30 hosts, there are 2 IP addresses causing problems in the In a class C network that contains 30 hosts, there are 2 IP addresses causing problems in the
network. You need to create a subnet mask that can identify in which subnets the IP network. You need to create a subnet mask that can identify in which subnets the IP addresses belong to as well as the host numbers.addresses belong to as well as the host numbers.
The IP addresses are:The IP addresses are:193.230.8.57193.230.8.57192.225.18.66192.225.18.66
29.29. Answer the followingAnswer the following(a)(a) What is the TCP standard for four layer structure and what is its relationship with the What is the TCP standard for four layer structure and what is its relationship with the
OSI/ISO reference layer model?OSI/ISO reference layer model?(b)(b) What is the format for IPV4 and IPV6 headers? Highlight the differences between the two.What is the format for IPV4 and IPV6 headers? Highlight the differences between the two.(c)(c) What does SNMP stand for? What are the SNMP main characteristics and how is its layer What does SNMP stand for? What are the SNMP main characteristics and how is its layer
configuration structure?configuration structure?
30. 30. (a)(a) Describe the functionality of the following network devices and highlight their differences. Use the ISO/OSI Describe the functionality of the following network devices and highlight their differences. Use the ISO/OSI
seven layer reference model to associate each of the devices below.seven layer reference model to associate each of the devices below.
• Repeater/HubRepeater/Hub• Logical bridgeLogical bridge• Medium Access Control (MAC) bridgeMedium Access Control (MAC) bridge• RouterRouter• GatewayGateway
(b)(b) Define the functions of the internet working devices [A,B,C,D] shown in figure 1. below and justify your Define the functions of the internet working devices [A,B,C,D] shown in figure 1. below and justify your answer.answer.
Figure 1.Figure 1.
(c)(c) If device B in figure 1. was to be replaced with another internet working device so that more CAN buses can If device B in figure 1. was to be replaced with another internet working device so that more CAN buses can be supported, what device would you replace it with and why?be supported, what device would you replace it with and why?
(d)(d) Certain Ethernet system has a maximum bus delay of 20 μSec, and operates with a bit rate of 100 Mbit/sec. Certain Ethernet system has a maximum bus delay of 20 μSec, and operates with a bit rate of 100 Mbit/sec. Each frame is 1152 bits in length. Determine the maximum utilization factor of the medium under collision Each frame is 1152 bits in length. Determine the maximum utilization factor of the medium under collision conditions. conditions.
Ethernet
CAN
Token Ring (A)
ATM LAN Switching Backbone
(C)
(D) IP WAN Switching Backbone
(A)