HUB
Networks using a Star topology require a central point for the
devices to connect. Originally this device was called a concentrator since it
consolidated the cable runs from all network devices. The basic form of
concentrator is the hub.
As shown in Figure; the hub is a hardware device that contains
multiple, independent ports that match the cable type of the network. Most
common hubs interconnect Category 3 or 5 twisted-pair cable with RJ-45 ends,
although Coax BNC and Fiber Optic BNC hubs also exist. The hub is considered
the least common denominator in device concentrators. Hubs offer an inexpensive
option for transporting data between devices, but hubs don't offer any form of
intelligence. Hubs can be active or passive.
An active hub strengthens and regenerates the incoming signals before sending
the data on to its destination.
Passive hubs do nothing with the signal.
Ethernet Hubs
An Ethernet hub is also called a multiport repeater. A repeater
is a device that amplifies a signal as it passes through it, to counteract the
effects of attenuation. If, for example, you have a thin Ethernet network with
a cable segment longer than the prescribed maximum of 185 meters, you can install
a repeater at some point in the segment to strengthen the signals and increase
the maximum segment length. This type of repeater only has two BNC connectors,
and is rarely seen these days.
8 Port mini Ethernet Hub
The hubs used on UTP Ethernet networks are repeaters as well,
but they can have many RJ45 ports instead of just two BNC connectors. When data
enters the hub through any of its ports, the hub amplifies the signal and
transmits it out through all of the other ports. This enables a star network to
have a shared medium, even though each computer has its own separate cable. The
hub relays every packet transmitted by any computer on the network to all of
the other computers, and also amplifies the signals.
The maximum segment length for a UTP cable on an Ethernet
network is 100 meters. A segment is defined as the distance between two
communicating computers. However, because the hub also functions as a repeater,
each of the cables connecting a computer to a hub port can be up to 100 meters
long, allowing a segment length of up to 200 meters when one hub is inserted in
the network.
Multistation Access
Unit
A Multistation Access Unit (MAU) is a special type of hub used for token ring
networks. The word "hub" is used most often in relation to Ethernet networks, and MAU
only refers to token ring networks. On the outside, the MAU looks like a hub.
It connects to multiple network devices, each with a separate cable.
Unlike a hub that uses a logical bus topology
over a physical star, the MAU uses a logical ring topology over a physical
star.
When the MAU detects a problem with a connection, the ring will
beacon. Because it uses a physical star topology, the MAU can easily detect
which port the problem exists on and close the port, or "wrap" it.
The MAU does actively regenerate signals as it transmits data around the ring.
Switches
Switches are a special type of hub that offers an additional
layer of intelligence to basic, physical-layer repeater hubs. A switch must be
able to read the MAC address of each frame it receives. This information allows
switches to repeat incoming data frames only to the computer or computers to
which a frame is addressed. This speeds up the network and reduces congestion.
Switches operate at both the physical layer
and the data link layer of the OSI Model.
Bridges
A bridge is used to join two network segments together, it allows
computers on either segment to access resources on the other. They can also be
used to divide large networks into smaller segments. Bridges have all the
features of repeaters, but can have more nodes, and since the network is
divided, there is fewer computers competing for resources on each segment thus
improving network performance.
Bridges can also connect networks that run at different speeds,
different topologies, or different protocols. But they cannot, join an Ethernet
segment with a Token Ring segment, because these use different networking
standards. Bridges operate at both the Physical Layer and the MAC sublayer of
the Data Link layer. Bridges read the MAC header of each frame to determine on
which side of the bridge the destination device is located, the bridge then
repeats the transmission to the segment where the device is located.
Routers
Routers Are networking devices used to extend or segment
networks by forwarding packets from one logical network to another. Routers are
most often used in large internetworks that use the TCP/IP protocol suite and
for connecting TCP/IP hosts and local area networks (LANs) to the Internet
using dedicated leased lines.
Routers work at the network layer (layer 3) of the Open Systems
Interconnection (OSI) reference model for networking to move packets between
networks using their logical addresses (which, in the case of TCP/IP, are the
IP addresses of destination hosts on the network). Because routers operate at a
higher OSI level than bridges do, they have better packet-routing and filtering
capabilities and greater processing power, which results in routers costing
more than bridges.
Routing tables
Routers contain internal tables of information called routing
tables that keep track of all known network addresses and possible paths
throughout the internetwork, along with cost of reaching each network. Routers
route packets based on the available paths and their costs, thus taking
advantage of redundant paths that can exist in a mesh topology network.
Because routers use destination network addresses of packets,
they work only if the configured network protocol is a routable protocol such
as TCP/IP or IPX/SPX. This is different from bridges, which are protocol
independent. The routing tables are the heart of a router; without them,
there's no way for the router to know where to send the packets it receives.
Unlike bridges and switches, routers cannot compile routing
tables from the information in the data packets they process. This is because
the routing table contains more detailed information than is found in a data
packet, and also because the router needs the information in the table to
process the first packets it receives after being activated. A router can't
forward a packet to all possible destinations in the way that a bridge can.
·
Static routers: These must have their routing tables configured manually with
all network addresses and paths in the internetwork.
·
Dynamic routers: These automatically create their routing tables by listening to
network traffic.
·
Routing tables are the means by which a router selects the fastest or nearest
path to the next "hop" on the way to a data packet's final
destination. This process is done through the use of routing metrics.
·
Routing metrics which are the means of determining how much distance or time a
packet will require to reach the final destination. Routing metrics are
provided in different forms.
·
hop is
simply a router that the packet must travel through.
·
Ticks measure
the time it takes to traverse a link. Each tick is 1/18 of a second. When the
router selects a route based on tick and hop metrics, it chooses the one with
the lowest number of ticks first.
You can use routers, to segment a large network, and to connect
local area segments to a single network backbone that uses a different physical
layer and data link layer standard. They can also be used to connect LAN's to a
WAN's.
Brouters
Brouters are a combination of router and bridge. This is a
special type of equipment used for networks that can be either bridged or
routed, based on the protocols being forwarded. Brouters are complex, fairly
expensive pieces of equipment and as such are rarely used.
A Brouter transmits two types of traffic at the exact same time:
bridged traffic and routed traffic. For bridged traffic, the Brouter handles
the traffic the same way a bridge or switch would, forwarding data based on the
physical address of the packet. This makes the bridged traffic fairly fast, but
slower than if it were sent directly through a bridge because the Brouter has
to determine whether the data packet should be bridged or routed.
Gateways
A gateway is a device used to connect networks using different
protocols. Gateways operate at the network layer of the OSI model. In order to
communicate with a host on another network, an IP host must be configured with
a route to the destination network. If a configuration route is not found, the
host uses the gateway (default IP router) to transmit the traffic to the
destination host. The default t gateway is where the IP sends packets that are
destined for remote networks. If no default gateway is specified, communication
is limited to the local network. Gateways receive data from a network using one
type of protocol stack, removes that protocol stack and repackages it with the
protocol stack that the other network can use.
Examples
·
E-mail gateways-for
example, a gateway that receives Simple Mail Transfer Protocol (SMTP) e-mail,
translates it into a standard X.400 format, and forwards it to its destination
·
Gateway Service for
NetWare (GSNW), which enables a machine running Microsoft Windows NT Server or
Windows Server to be a gateway for Windows clients so that they can access file
and print resources on a NetWare server
·
Gateways between a
Systems Network Architecture (SNA) host and computers on a TCP/IP network, such
as the one provided by Microsoft SNA Server
·
A packet
assembler/disassembler (PAD) that provides connectivity between a local area
network (LAN) and an X.25 packet-switching network
CSU / DSU (Channel Service Unit / Data Service Unit)
A CSU/DSU is a device that combines the functionality of a channel service
unit (CSU) and a data service unit (DSU). These devices are used to connect a
LAN to a WAN, and they take care of all the translation required to convert a
data stream between these two methods of communication.
A DSU provides all the handshaking and error correction required to
maintain a connection across a wide area link, similar to a modem. The DSU will
accept a serial data stream from a device on the LAN and translate this into a
useable data stream for the digital WAN network. It will also take care of
converting any inbound data streams from the WAN back to a serial
communication.
A CSU is similar to a DSU except it does not have the ability to
provide handshaking or error correction. It is strictly an interface between
the LAN and the WAN and relies on some other device to provide handshaking and
error correction.
NICs (Network Interface Card)
Network Interface Card, or NIC is a hardware card installed in a
computer so it can communicate on a network. The network adapter provides one
or more ports for the network cable to connect to, and it transmits and
receives data onto the network cable.
Wireless Lan card
Every networked computer must also have a network adapter
driver, which controls the network adapter. Each network adapter driver is
configured to run with a certain type of network adapter.
Network card
Network Interface Adapter Functions
Network interface adapters perform a variety of functions that are crucial to getting data to and from the computer over the network.
Network interface adapters perform a variety of functions that are crucial to getting data to and from the computer over the network.
These functions are as follows:
Data encapsulation
The network interface adapter and its driver are responsible for building the frame around the data generated by the network layer protocol, in preparation for transmission. The network interface adapter also reads the contents of incoming frames and passes the data to the appropriate network layer protocol.
The network interface adapter and its driver are responsible for building the frame around the data generated by the network layer protocol, in preparation for transmission. The network interface adapter also reads the contents of incoming frames and passes the data to the appropriate network layer protocol.
Signal encoding and decoding
The network interface adapter implements the physical layer encoding scheme that converts the binary data generated by the network layer-now encapsulated in the frame-into electrical voltages, light pulses, or whatever other signal type the network medium uses, and converts received signals to binary data for use by the network layer.
The network interface adapter implements the physical layer encoding scheme that converts the binary data generated by the network layer-now encapsulated in the frame-into electrical voltages, light pulses, or whatever other signal type the network medium uses, and converts received signals to binary data for use by the network layer.
transmission and reception
The primary function of the network interface adapter is to generate and transmit signals of the appropriate type over the network and to receive incoming signals. The nature of the signals depends on the network medium and the data-link layer protocol. On a typical LAN, every computer receives all of the packets transmitted over the network, and the network interface adapter examines the destination address in each packet, to see if it is intended for that computer. If so, the network interface adapter passes the packet to the computer for processing by the next layer in the protocol stack; if not, the network interface adapter discards the packet.
The primary function of the network interface adapter is to generate and transmit signals of the appropriate type over the network and to receive incoming signals. The nature of the signals depends on the network medium and the data-link layer protocol. On a typical LAN, every computer receives all of the packets transmitted over the network, and the network interface adapter examines the destination address in each packet, to see if it is intended for that computer. If so, the network interface adapter passes the packet to the computer for processing by the next layer in the protocol stack; if not, the network interface adapter discards the packet.
Data buffering
Network interface adapters transmit and receive data one frame at a time, so they have built-in buffers that enable them to store data arriving either from the computer or from the network until a frame is complete and ready for processing.
Network interface adapters transmit and receive data one frame at a time, so they have built-in buffers that enable them to store data arriving either from the computer or from the network until a frame is complete and ready for processing.
Serial/parallel conversion
The communication between the computer and the network interface adapter runs in parallel, that is, either 16 or 32 bits at a time, depending on the bus the adapter uses. Network communications, however, are serial (running one bit at a time), so the network interface adapter is responsible for performing the conversion between the two types of transmissions.
The communication between the computer and the network interface adapter runs in parallel, that is, either 16 or 32 bits at a time, depending on the bus the adapter uses. Network communications, however, are serial (running one bit at a time), so the network interface adapter is responsible for performing the conversion between the two types of transmissions.
Media access control
The network interface adapter also implements the MAC mechanism that the data-link layer protocol uses to regulate access to the network medium. The nature of the MAC mechanism depends on the protocol used.
The network interface adapter also implements the MAC mechanism that the data-link layer protocol uses to regulate access to the network medium. The nature of the MAC mechanism depends on the protocol used.
Network protocols
A networked computer must also have one or more protocol drivers
(sometimes called a transport protocol or just a protocol). The protocol driver
works between the upper-level network software and the network adapter to
package data to be sent on the network.
In most cases, for two computers to communicate on a network,
they must use identical protocols. Sometimes, a computer is configured to use
multiple protocols. In this case, two computers need only one protocol in
common to communicate. For example, a computer running File and Printer Sharing
for Microsoft Networks that uses both NetBEUI and TCP/IP can communicate with
computers using only NetBEUI or TCP/IP.
ISDN (Integrated Services Digital Network) adapters
Integrated Services Digital Network adapters can be used to send
voice, data, audio, or video over standard telephone cabling. ISDN adapters
must be connected directly to a digital telephone network. ISDN adapters are
not actually modems, since they neither modulate nor demodulate the digital
ISDN signal.
Like standard modems, ISDN adapters are available both as
internal devices that connect directly to a computer's expansion bus and as
external devices that connect to one of a computer's serial or parallel ports.
ISDN can provide data throughput rates from 56 Kbps to 1.544 Mbps (using a T1
carrier service).
ISDN hardware requires a NT (network termination) device, which
converts network data signals into the signaling protocols used by ISDN. Some
times, the NT interface is included, or integrated, with ISDN adapters and
ISDN-compatible routers. In other cases, an NT device separate from the adapter
or router must be implemented. ISDN works at the physical, data link, network,
and transport layers of the OSI Model.
WAPs (Wireless Access Point)
A wireless network adapter card with a transceiver sometimes
called an access point, broadcasts and receives signals to and from the
surrounding computers and passes back and forth between the wireless computers
and the cabled network.
Access points act as wireless hubs to link multiple wireless
NICs into a single subnet. Access points also have at least one fixed Ethernet
port to allow the wireless network to be bridged to a traditional wired
Ethernet network.
Modems
A modem is a device that makes it possible for computers to
communicate over telephone lines. The word modem comes from Modulate and
Demodulate. Because standard telephone lines use analog signals, and computers
digital signals, a sending modem must modulate its digital signals into analog
signals. The computers modem on the receiving end must then demodulate the
analog signals into digital signals.
Modems can be external, connected to the computers serial port
by an RS-232 cable or internal in one of the computers expansion slots. Modems
connect to the phone line using standard telephone RJ-11 connectors.
Transceivers (media converters)
Transceiver short for transmitter-receiver, a device that both
transmits and receives analog or digital signals. The term is used most
frequently to describe the component in local-area networks (LANs) that
actually applies signals onto the network wire and detects signals passing
through the wire. For many LANs, the transceiver is built into the network
interface card (NIC). Some types of networks, however, require an external
transceiver.
In Ethernet networks, a transceiver is also called a Medium
Access Unit (MAU). Media converters interconnect different cable types twisted
pair, fiber, and Thin or thick coax, within an existing network. They are often
used to connect newer 100-Mbps, Gigabit Ethernet, or ATM equipment to existing
networks, which are generally 10BASE-T, 100BASE-T, or a mixture of both. They
can also be used in pairs to insert a fiber segment into copper networks to
increase cabling distances and enhance immunity to electromagnetic interference
(EMI).
Firewalls
In computing, a firewall is a piece of hardware and/or software
which functions in a networked environment to prevent some communications
forbidden by the security policy, analogous to the function of firewalls in
building construction.
A firewall has the basic task of controlling traffic between
different zones of trust. Typical zones of trust include the Internet (a zone
with no trust) and an internal network (a zone with high trust). The ultimate
goal is to provide controlled connectivity between zones of differing trust
levels through the enforcement of a security policy and connectivity model
based on the least privilege principle.
There are three basic types of firewalls
depending on:
·
whether the
communication is being done between a single node and the network, or between
two or more networks
·
whether the
communication is intercepted at the network layer, or at the application layer
·
whether the
communication state is being tracked at the firewall or not
With regard to the scope of filtered
communication these firewalls are exist:
·
Personal firewalls, a
software application which normally filters traffic entering or leaving a
single computer through the Internet.
·
Network firewalls,
normally running on a dedicated network device or computer positioned on the
boundary of two or more networks or DMZs (demilitarized zones). Such a firewall
filters all traffic entering or leaving the connected networks.
In reference to the layers where the traffic
can be intercepted, three main categories of firewalls exist:
·
network layer
firewalls An example would be iptables.
·
application layer
firewalls An example would be TCP Wrapper.
·
application firewalls
An example would be restricting ftp services through /etc/ftpaccess file
These network-layer and application-layer types of firewall may
overlap, even though the personal firewall does not serve a network; indeed,
single systems have implemented both together.
There's also the notion of application firewalls which are
sometimes used during wide area network (WAN) networking on the world-wide web
and govern the system software. An extended description would place them lower
than application layer firewalls, indeed at the Operating System layer, and
could alternately be called operating system firewalls.
Lastly, depending on whether the firewalls
track packet states, two additional categories of firewalls exist:
·
stateful firewalls
·
stateless firewalls
Network layer
firewalls
Network layer firewalls operate at a (relatively low) level of
the TCP/IP protocol stack as IP-packet filters, not allowing packets to pass
through the firewall unless they match the rules. The firewall administrator
may define the rules; or default built-in rules may apply (as in some
inflexible firewall systems).
A more permissive setup could allow any packet to pass the
filter as long as it does not match one or more "negative-rules", or
"deny rules". Today network firewalls are built into most computer
operating system and network appliances.
Modern firewalls can filter traffic based on many packet
attributes like source IP address, source port, destination IP address or port,
destination service like WWW or FTP. They can filter based on protocols, TTL
values, netblock of originator, domain name of the source, and many other
attributes.
Application-layer
firewalls
Application-layer firewalls work on the application level of the
TCP/IP stack (i.e., all browser traffic, or all telnet or ftp traffic), and may
intercept all packets traveling to or from an application. They block other
packets (usually dropping them without acknowledgement to the sender). In
principle, application firewalls can prevent all unwanted outside traffic from
reaching protected machines.
By inspecting all packets for improper content, firewalls can
even prevent the spread of the likes of viruses. In practice, however, this
becomes so complex and so difficult to attempt (given the variety of
applications and the diversity of content each may allow in its packet traffic)
that comprehensive firewall design does not generally attempt this approach.
Proxies
A proxy device (running either on dedicated hardware or as
software on a general-purpose machine) may act as a firewall by responding to
input packets (connection requests, for example) in the manner of an
application, whilst blocking other packets.
Proxies make tampering with an internal system from the external
network more difficult, and misuse of one internal system would not necessarily
cause a security breach exploitable from outside the firewall (as long as the
application proxy remains intact and properly configured). Conversely,
intruders may hijack a publicly-reachable system and use it as a proxy for
their own purposes; the proxy then masquerades as that system to other internal
machines. While use of internal address spaces enhances security, crackers may
still employ methods such as IP spoofing to attempt to pass packets to a target
network.
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