Chapter 9 Network Organization Concepts Understanding Operating Systems, Fourth Edition.
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Chapter 9Network Organization
Concepts
Understanding Operating Systems, Fourth Edition
Understanding Operating Systems, Fourth Edition 2
ObjectivesObjectives
You will be able to describe:
• Several different network topologies—including the star, ring, bus, tree, and hybrid
• Three types of networks: LAN, MAN, and WAN
• The difference between circuit switching and packet switching
• Conflict resolution procedures that allow a network to share common transmission hardware and software effectively
Understanding Operating Systems, Fourth Edition 3
Objectives (continued)Objectives (continued)
You will be able to describe:
• The two transport protocol models (OSI and TCP/IP) and how the layers of each one compare
Understanding Operating Systems, Fourth Edition 4
Basic TerminologyBasic Terminology
• Network: Collection of loosely coupled processors interconnected by communication links using cables, wireless technology, or both– Goal: To provide a convenient way to share
resources (hardware and software) while controlling users’ access to them
• General configurations for OS for networks:– Network operating system (NOS)– Distributed operating system (D/OS)
Understanding Operating Systems, Fourth Edition 5
Basic TerminologyBasic Terminology (continued) (continued)
• Network operating system (NOS): Networking capability added to single-user operating system– Users aware of specific computers and resources in
the network– Access via logon to remote host or by data transfer
from remote host
Understanding Operating Systems, Fourth Edition 6
Basic TerminologyBasic Terminology (continued) (continued)
• Distributed operating system (D/OS): Users can access remote resources as if local resources– Good control for distributed computing systems– Allows resources to be accessed in a unified way– Represents total view across multiple computer
systems for controlling and managing resources without local dependencies
– Management is a cooperative process– Comprised of four managers with a wider scope
Understanding Operating Systems, Fourth Edition 7
Basic TerminologyBasic Terminology (continued) (continued)
• D/OS must provide the following components:– Process or object management– Memory management– File management– Device management– Network management
Understanding Operating Systems, Fourth Edition 8
Basic TerminologyBasic Terminology (continued) (continued)
Figure 9.1: Networked management system
Understanding Operating Systems, Fourth Edition 9
Basic TerminologyBasic Terminology (continued) (continued)
• Advantages of D/OS over traditional systems:– Easy and reliable resource sharing– Faster computation– Adequate load balancing– Good reliability– Dependable electronic communications among the
network’s users
Understanding Operating Systems, Fourth Edition 10
Basic TerminologyBasic Terminology (continued) (continued)
• In distributed system each processor classifies other processors and resources as remote and considers its own resources local
• Site: Indicates a specific location in a network with one or more computers
• Host: Specific computer system found at a site whose services and resources can be used from remote locations
• Node: Refers to the name assigned to a computer system connected to network to identify it to other computers in network
Understanding Operating Systems, Fourth Edition 11
Basic TerminologyBasic Terminology (continued) (continued)
Figure 9.2: Clients request data or services from the host server and wait for the response. If the client host has resources needed by the server host, the roles can be reversed
Understanding Operating Systems, Fourth Edition 12
Network TopologiesNetwork Topologies
• Sites in any networked system can be physically or logically connected in a variety of topologies
• Common topologies: star, ring, bus, tree, hybrid• In each topology there are tradeoffs between
– Need for fast communication among all sites– Tolerance of failure at a site or communication link– Cost of long communication lines– Difficulty of connecting one site to a large number of
other sites
Understanding Operating Systems, Fourth Edition 13
Network TopologiesNetwork Topologies (continued) (continued)
• Four basic criteria :– Basic cost: Expense required to link the various
sites in the system– Communications cost: Time required to send a
message from one site to another– Reliability: Assurance that many sites can still
communicate with each other if a link or site fails– User’s environment: Critical parameters that
network must meet to be a successful business investment
Understanding Operating Systems, Fourth Edition 14
StarStar
• All transmitted data must pass through a central controller when going from a sender to a receiver
• Advantages:– Permits easy routing– Easy access control to the network
• Challenges:– Central site must be extremely reliable and able to
handle all network traffic, no matter how heavy
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StarStar (continued) (continued)
Figure 9.3: Star topology
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RingRing
• All sites are connected in a closed loop with the first site connected to the last
• Network can be connected to other networks via a bridge (same protocols) or gateway (different protocols)
• Data is transmitted in packets with source and destination address fields
• Each packet is passed from node to node in one direction only
• Every node must be functional, or failed node needs to be bypassed for proper operation
Understanding Operating Systems, Fourth Edition 17
RingRing (continued) (continued)
Figure 9.4: Ring topology
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RingRing (continued) (continued)
Figure 9.5: Double loop computer network using a ring topology
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RingRing (continued) (continued)
Figure 9.6: Multiple rings bridged together
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BusBus
• All sites connected to a single communication line
• Messages from any site circulate in both directions
• Only one site can successfully send messages at one time
• Needs control mechanism to prevent collision
• Data may pass directly from one device to another, or it may be routed to an end point controller at the end of the line
Figure 9.7: Bus Topology
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TreeTree
• Tree: A collection of busses connected by a branching cable with no closed loops– Allows users to create networks using bridges– Message from any site can be received by all other
sites, until it reaches an end point– End point controller absorbs a message if it reaches
end point controller without being accepted by a host– Advantage: Message traffic can still flow through
the network even if a single node fails
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Tree ( continued)Tree ( continued)
Figure 9.8: Tree Topology
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HybridHybrid
Figure 9.9: Hybrid topology combining a star and a ring using a bridge
Selects among the strong points of each topology and combines them to meet that system’s communications requirements most effectively
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Hybrid (continued)Hybrid (continued)
Figure 9.10: Hybrid topology combining a star and a bus
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Network TypesNetwork Types
• Grouping of networks according to physical distances they cover
• Network types:– Local area networks (LAN)– Metropolitan area networks (MAN)– Wide area networks (WAN)
Understanding Operating Systems, Fourth Edition 26
Local Area NetworkLocal Area Network
• A configuration found within a single office building, campus, or similarly enclosed environment
• Owned, used, and operated by single organization • Allows computers to communicate directly through
a common communication line• Communications aren’t limited to well-defined local
area only– LAN can be a component of larger communication
network– Provides easy access to outside through bridge or
gateway
Understanding Operating Systems, Fourth Edition 27
Local Area Network Local Area Network (continued) (continued)
• Bridge: Connects two or more geographically distant LANs with same protocols– e.g., simple bridge used to connect 2 Ethernet LANs
• Gateway: Connects two or more LANs or systems that use different protocols– Translates one network’s protocol into another,
resolving hardware and software incompatibilities– e.g., SNA gateway can connect microcomputer
network to mainframe host
Understanding Operating Systems, Fourth Edition 28
Local Area NetworkLocal Area Network (continued) (continued)
• Data rates in LAN vary from 100 Mbps to more than 40 Gbps
• Close physical proximity allows very high-speed transmission
• Star, ring, bus, tree, and hybrid are normally used to construct local area networks
• Transmission medium used may vary from one topology to another– Factors determining transmission medium include
cost, data rate, reliability, number of devices that can be supported, distance between units etc.
Understanding Operating Systems, Fourth Edition 29
Metropolitan Area NetworkMetropolitan Area Network
• Configuration spanning an area larger than a LAN– Ranging from several blocks of buildings to an entire
city but not exceeding a circumference of 100 km
• Owned and operated by a single organization– Usually used by many individuals & organizations– May be owned and operated as public utilities
providing means for internetworking several LANs
• MAN: high-speed network often configured as a logical ring
Understanding Operating Systems, Fourth Edition 30
Wide Area NetworkWide Area Network
• A configuration that interconnects communication facilities in different parts of a country or the world, or that is operated as part of public utility
• Uses communications lines of common carriers (e.g., telephone companies)
• Uses broad range of communication media (e.g., satellite, microwaves)
• WANs are generally slower than LANs• Examples: ARPAnet (first WAN), Internet (most
widely recognized WAN)
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Wireless Local Area NetworkWireless Local Area Network
• LAN that uses wireless technology to connect computers or workstations located within the range of the network
• WLAN typically poses security vulnerabilities
Table 9.1: IEEE standards for wireless networks
WiMax (802.16) would enable wireless broadband connections over much greater ranges (up to 10 miles)
Understanding Operating Systems, Fourth Edition 32
Wireless Local Area NetworkWireless Local Area Network (continued)(continued)
Figure 9.11: Wireless Local Area Network
Understanding Operating Systems, Fourth Edition 33
Software Design IssuesSoftware Design Issues
• Software issues that must be addressed by network designers:– How do sites use addresses to locate other sites?– How are messages routed and how are they sent?– How do processes communicate with each other?– How are conflicting demands for resources
resolved?
Understanding Operating Systems, Fourth Edition 34
Addressing ConventionsAddressing Conventions
• Addressing protocols are closely related to network topology and geographic location of each site– Local name: Name by which a unit is known within
its own system– Global name: Name by which a unit is known
outside its own system• Must follow standard name lengths, formats, and other
global conventions
Understanding Operating Systems, Fourth Edition 35
Addressing Conventions (continued)Addressing Conventions (continued)
• Domain Name Service (DNS) protocol
• The DNS is hierarchical
• Domain names are read from right to left– Rightmost portion is the top-level domain– Next level is the domain name– Next is one or more subdomain names– Leftmost portion is the host
Understanding Operating Systems, Fourth Edition 36
Routing StrategiesRouting Strategies
• Router: Internetworking device, primarily software driven, which directs traffic – Between two different types of LANs, or– Between two network segments with different
protocol addresses• Operates at Network Layer• Role of routers changes as network designs
change• Used extensively for connecting sites to each other
and to Internet
Understanding Operating Systems, Fourth Edition 37
Routing Strategies Routing Strategies (continued)(continued)
• Router functions include:– Securing information generated in predefined areas– Choosing the fastest route from one point to another– Providing redundant network connections
• Routing protocols must consider following:– Addressing– Address resolution– Message format– Error reporting
Understanding Operating Systems, Fourth Edition 38
Routing Strategies Routing Strategies (continued)(continued)
• Message formats allow the protocol to perform its functions, such as – Finding new nodes on a network– Testing to determine whether they’re working– Reporting error conditions– Exchanging routing information– Establishing connections, and transmitting data
• Most widely used routing protocols on Internet:– Routing information protocol (RIP)– Open shortest path first (OSPF)
Understanding Operating Systems, Fourth Edition 39
Routing Information ProtocolRouting Information Protocol
• Selection of a path based on immediate number of nodes, or hops, between source and destination – Path with smallest number of hops chosen always
• Advantages:– Easy to implement
• Disadvantages:– Does not take into consideration bandwidth, data
priority, or type of network– Updating and reissuing of routing table every 30
seconds– Tables propagate from one router to another
Understanding Operating Systems, Fourth Edition 40
Open Shortest Path FirstOpen Shortest Path First
• Selection of a transmission path only after the state of a network has been determined
• Routing update messages sent only when changes in routing environment occur– Reduces number of messages in internetwork– Reduces size of messages by not sending entire
routing table• Disadvantages:
– Increased memory usage– Bandwidth savings offset by higher CPU usage for
shortest path calculation
Understanding Operating Systems, Fourth Edition 41
Connection ModelsConnection Models
• Types of switching:– Circuit switching– Packet switching
• Circuit Switching: Communication model in which dedicated communication path is established between two hosts before data transmission begins– Example: Telephone system– Disadvantage: Delay before signal transfer begins
while the connection is set up
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Packet SwitchingPacket Switching
• A store-and-forward technique in which a message is divided into multiple equal-sized units (packets) before sending to destination– At destination, packets are reassembled into their
original long format– A header containing pertinent information about the
packet is attached to each packet before transmission• Advantages:
– More flexible and more reliable than circuit switching– Provides greater line efficiency– Allows users to allocate priorities to their messages
Understanding Operating Systems, Fourth Edition 43
Packet SwitchingPacket Switching (continued) (continued)
Figure 9.12 : Packet switching; (a) divide the data into addressed packets; (b) send each packet toward its destination; (c) reassemble the data at the destination
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Packet SwitchingPacket Switching (continued) (continued)
Table 9.2: Comparison of circuit and packet switching
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Packet SwitchingPacket Switching (continued) (continued)
• Methods of selecting the path:– Datagrams– Virtual circuits
• Datagrams: Destination and sequence number of packet added to information, uniquely identifying message to which packet belongs– Each packet handled independently and route is
selected as each packet is accepted into network– At destination, all packets of same message are
reassembled
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Packet SwitchingPacket Switching (continued) (continued)
• Datagrams: (continued)– Message can’t be delivered until all packets are
accounted for– Receiving node requests retransmission of lost or
damaged packets– Advantages:
• Helps diminish congestion by sending incoming packets through less heavily used paths
• Provides more reliability, because alternate paths may be set up when one node fails
Understanding Operating Systems, Fourth Edition 47
Packet SwitchingPacket Switching (continued) (continued)
• Virtual Circuit: Complete path from sender to receiver established before transmission starts– All packets belonging to a message use same route– Any node can have several virtual circuits to any
other node• Advantage: Routing decision made once for all
packets belonging to same message – speeds up transmission
• Disadvantages: – If node fails, all virtual circuits using that node
become unavailable– Congestion is difficult to resolve when heavy traffic
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Conflict ResolutionConflict Resolution
• Some method to control access is necessary to facilitate equal and fair access to network
• Access control techniques:– Round robin– Reservation – Contention
• Medium access control protocols: – Carrier sense multiple access (CSMA)– Token passing– Distributed-queue, dual bus
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Access Control TechniquesAccess Control Techniques
• Round Robin: A node is given certain amount of time to complete transmission, at end of which opportunity is passed to next node– Efficient when many nodes transmitting over long
periods– Substantial overhead when few nodes transmit over
long periods of time• Reservation: Access time on medium is divided
into slots and node can reserve future time slots– Well suited for lengthy and continuous traffic
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Access Control TechniquesAccess Control Techniques (continued)(continued)
• Reservation: (continued)– Good for a configuration with several terminals
connected to host computer through single I/O port • Contention: No attempt is made to determine
whose turn it is to transmit; nodes compete for access to medium– Major advantage: Easy to implement– Better for short and intermittent traffic– Works well under light to moderate traffic– Performance tends to break down under heavy loads
Understanding Operating Systems, Fourth Edition 51
CSMACSMA
• Carrier sense multiple access (CSMA): Contention-based protocol that is easy to implement– Carrier sense means that a node will listen to, or
test, communication medium before transmitting any messages
• Prevents a collision with another node that’s currently transmitting
– Multiple access means that several nodes are connected to same communication line as peers, on the same level, and with equal privileges
Understanding Operating Systems, Fourth Edition 52
CSMA (continued)CSMA (continued)
• Disadvantages of CSMA:– Collision if two or more nodes transmit at same
instant– Probability of collisions increases if nodes are farther
apart • CSMA less appealing access protocol for large or
complex networks
• CSMA/CD: CSMA algorithm modified to include collision detection, e.g., Ethernet– Collisions not completely eliminated but reduced– Reduces wasted transmission capacity
Understanding Operating Systems, Fourth Edition 53
CSMA (continued)CSMA (continued)
CSMA/CD: • Access method prevents multiple nodes from
colliding during transmission– e.g., Implemented in LocalTalk, Apple’s cabling
system• If collisions occur, involve only a small packet, not
actual data (in case of Apple CSMA/CA)• Protocol does not guarantee data will reach its
destination, but ensures that any data that’s delivered will be error free
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Token PassingToken Passing
• Special electronic message (token) is generated and passed along from node to node
• Only node with the token allowed to transmit, and after it has done so, it must pass token on to another node
• Fast access; collisions are nonexistent
• Typical topologies: – Bus– Ring
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Token PassingToken Passing (continued) (continued)
• Token-bus: Token is passed to each node in turn, which upon receipt, attaches data to it and sends to destination
• Receiving node copies data, adds acknowledgment, and returns packet to sending node
• Sending node passes token on to next node in logical sequence
• Initial node order determined by cooperative decentralized algorithm– Once network is running, turns determined by priority
based on node activity
Understanding Operating Systems, Fourth Edition 56
Token PassingToken Passing (continued) (continued)
• Token-bus: (continued)– Higher overhead at each node than CSMA/CD– Nodes may have long waits under certain conditions
before receiving token• Token-ring: Token moves between the nodes in
turn and in one direction only– If a node wants to send a message it must wait for
the free token to come by– Receiving node copies the message in the packet
and sets the copied bit to indicate it was successfully received
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DQDBDQDB
• Distributed-queue, dual bus (DQDB): Intended for use with a dual-bus configuration, where each bus transports data in only one direction
• Transmission on each bus consists of a steady stream of fixed-size slots
• Slots generated at end of each bus marked free and sent downstream, where they’re marked busy and written to by nodes ready to transmit
• Nodes read and copy data from slots, which then continue to travel toward end of bus, where they dissipate
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DQDB (continued)DQDB (continued)
Figure 9.13: DQDB protocol
Understanding Operating Systems, Fourth Edition 59
DQDB (continued)DQDB (continued)
• Advantages of DQDB:– Provides negligible delays under light loads and
predictable queuing under heavy loads– Suitable for MANs that manage large file transfers – Able to satisfy the needs of interactive users
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Transport Protocol StandardsTransport Protocol Standards
• Models intended to address need for universally adopted network architecture:– OSI Reference Model– TCP/IP
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OSI Reference ModelOSI Reference Model
• Provides basis for connecting open systems for distributed applications processing– “Open” means that any two systems that conform to
reference model and related standards can be connected, regardless of vendor
• Similar functions collected together into seven logical clusters (layers)– Possible to redesign a layer without affecting the
adjacent layers• Handles data transmission from one terminal or
application program to another
Understanding Operating Systems, Fourth Edition 62
OSI Reference ModelOSI Reference Model (continued) (continued)
OSI Reference Model• At every layer of the sending unit, a new header is
attached to the previous packet before it’s passed on to the next lower layer
• At the data link layer, a link trailer (LT) is added, completing the frame, which is passed to the physical layer for transmission
• Receiving unit removes each header or trailer until it delivers the data to the application program at Layer 7
Understanding Operating Systems, Fourth Edition 63
OSI Reference ModelOSI Reference Model (continued) (continued)
Figure 9.14: OSI transport protocol model
Understanding Operating Systems, Fourth Edition 64
OSI Reference Model (continued)OSI Reference Model (continued)
• Layer 1—The Physical Layer: Describes all mechanical, electrical, and functional specifications for connecting a device to a particular network– e.g., 100Base-T, RS449, and CCITT V.35
• Layer 2—The Data Link Layer: – Establishes and controls the physical path of
communications on one side– Checks for transmission errors and resolves
problems on the other side– Typical data link level protocols are HDLC and SDLC
Understanding Operating Systems, Fourth Edition 65
OSI Reference Model (continued)OSI Reference Model (continued)
• Layer 3—The Network Layer: Provides services such as addressing and routing that move data through network to its destination
• Layer 4—The Transport Layer: Maintains reliable data transmission between end users– Example: Transmission Control Protocol (TCP)
• Layer 5—The Session Layer: Responsible for– Providing a user-oriented connection service– Transferring data over communication lines– Example: TCP/IP
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OSI Reference Model (continued)OSI Reference Model (continued)
• Layer 6—The Presentation Layer: Responsible for data manipulation functions common to many applications, such as formatting, compression, and encryption.
• Layer 7—The Application Layer: Application programs, terminals, and computers access the network at this layer– Provides interface to users and responsible for
formatting user data before passing to lower layers
Understanding Operating Systems, Fourth Edition 67
TCP/IP ModelTCP/IP Model
• Transmission Control Protocol/Internet Protocol (TCP/IP): – Oldest transport protocol standard and the basis for
Internet communications– File-transfer protocol to send large files error free– TCP/IP emphasizes internetworking and providing
connectionless services– Organizes a communication system with three main
components: processes, hosts, and networks– TCP/IP model is arranged into four layers
Understanding Operating Systems, Fourth Edition 68
TCP/IP Model TCP/IP Model (continued)(continued)
Figure 9.15: TCP/IP model
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TCP/IP ModelTCP/IP Model (continued) (continued)
• Network Access Layer: Protocols at this layer provide access to a communication network– Flow control, error control between hosts, security,
and priority implementation are performed at this layer
• Internet Layer: Equivalent to portion of network layer of OSI model that performs routing functions– Implemented within gateways and hosts– Example: Internet protocol (IP)
Understanding Operating Systems, Fourth Edition 70
TCP/IP ModelTCP/IP Model (continued) (continued)
• Host-Host Layer: Supports mechanisms to transfer data between two processes on different host computers– Services include error checking, flow control, and an
ability to manipulate connection control signals– e.g., Transmission Control Protocol (TCP)
• Process/Application Layer: Includes protocols for computer-to-computer resource sharing and terminal-to-computer remote access– e.g., FTP, SMTP, and Telnet
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SummarySummary
• Operating systems for networks necessarily include the functions of Memory Manager, Processor Manager, Device Manager, and File Manager
• Network’s operating system must meet the reliability requirements of its owners
• Distributed operating systems allows resources to be accessed in a unified way
• Sites in any networked system can be physically or logically connected to one another in a variety of topologies: star, ring, bus, tree, and hybrid
Understanding Operating Systems, Fourth Edition 72
Summary (continued)Summary (continued)
• Hybrid topology combines the strong points of each topology to meet communications requirements most effectively
• Networks are grouped according to physical distances they cover: LAN, MAN and WAN
• Operating system must detect a failure, change routing instructions to avoid that node, and make sure every lost message is retransmitted until it is successfully received
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Summary (continued)Summary (continued)
• Packet switching provides greater line efficiency than circuit switching
• CSMA/CD prevents multiple nodes from colliding during transmission
• OSI reference model provides basis for connecting open systems for distributed applications processing
• TCP/IP is the oldest transport protocol standard and the basis for Internet communications
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