Do you know about - Intranet
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What exactly is an intranet? It's one of those terms that's more thrown around than understood, and has become more of a buzzword than a generally understood idea. Plainly put, an intranet is a incommunicable network with Internet technology used as the basal architecture. An intranet is built using the Internet's Tcp/Ip protocols for communications. Tcp/Ip protocols can be run on many hardware platforms and cabling schemes. The basal hardware is not what makes an intranet-it's the software protocols that matter.
Intranets can co-exist with other local area networking technology. In many companies, existing "legacy systems" together with mainframes, Novell networks, minicomputers, and varied databases, are being integrated into an intranet. A wide variety of tools allow this to happen. Base Gateway Interface (Cgi) scripting is often used to passage inheritance databases from an intranet. The Java programming language can be used to passage inheritance databases as well.
With the astronomical growth of the Internet, an expanding estimate of habitancy in corporations use the Internet for communicating with the face world, for gathering information, and for doing business. It didn't take long for habitancy to recognize that the components that worked so well on the Internet could be equally essential internally and that is why intranets are becoming so popular. Some corporations do not have Tcp/Ip networks, the protocol required to passage the resources of the Internet. Creating an intranet in which all the data and resources can be used seamlessly has many benefits. Tcp/Ip-based networks make it easy for habitancy to passage the network remotely, such as from home or while traveling. Dialing into an intranet in this way is much like connecting to the Internet, except that you're connecting to a incommunicable network instead of to a collective Internet provider. Interoperability in the middle of networks is other astronomical bonus.
Security systems isolate an intranet from the Internet. A company's intranet is protected by firewalls-hardware and software combinations that allow only clear habitancy to passage the intranet for specific purposes.
Intranets can be used for whatever that existing networks are used for-and more. The ease of publishing data on the World Wide Web has made them beloved places for posting corporate data such as company news or company procedures. Corporate databases with easy-to-build front-ends use the Web and programming languages such as Java.
Intranets allow habitancy to work together more nothing else but and more effectively. Software known as groupware is other foremost part of intranets. It allows habitancy to collaborate on projects; to share information; to do videoconferencing; and to develop collect procedures for output work. Free server and client software and the multitude of services, like newsgroups, stimulated the Internet's growth. The consequence of that growth stimulated and fueled the growth of intranets. The ease with which data can be shared, and with which habitancy can recite with one other will continue to drive the building of intranets.
A Global View of an Intranet
An intranet is a incommunicable corporate or educational network that uses the Internet's Tcp/Ip protocols for its basal transport. The protocols can run on a variety of network hardware, and can also co-exist with other network protocols, such as Ipx. habitancy from inside an intranet can get at the larger Internet resources, but those on the Internet cannot get into the intranet, which allows only restricted passage from the Internet.
Videoconferencing is an foremost application that requires sending huge quantities of data. Intranets can be built using components that allow the highly high bandwidths required for transferring such information. Often an intranet is composed of a estimate of dissimilar networks inside a corporation that all recite with one other via Tcp/Ip. These isolate networks are often referred to as subnets. Software that allows habitancy to recite with each other via e-mail and collective message boards and to collaborate on work using workgroup software is among the most mighty intranet programs. Applications that allow dissimilar corporate departments to post information, and for habitancy to fill out corporate forms, such as time sheets, and for tapping into corporate financial data are very popular. Much of the software used on intranets is standard, off-the-shelf Internet software such as the Netscape Navigator and the Microsoft Explorer Web browsers. And customized programs are often built, using the Java programming language and Cgi scripting. Intranets can also be used to allow associates to do business-to-business transactions, such as ordering parts, sending invoices, and production payments. For extra security, these intranet-to-intranet transactions need never go out over the collective Internet, but can voyage over incommunicable leased lines instead. Intranets are a mighty principles for allowing a company to do company online, for example, to allow whatever on the Internet to order products. When someone orders a stock on the Internet, data is sent in a collect manner from the collective Internet to the company's intranet, where the order is processed and completed. In order to safe sensitive corporate information, and to ensure that hackers don't damage computer systems and data, security barriers called firewalls safe an intranet from the Internet. Firewall technology uses a blend of routers, servers and other hardware and software to allow habitancy on an intranet to use Internet resources, but blocks outsiders from getting into the intranet. Many intranets have to connect to "legacy systems"-hardware and databases that were built before an intranet was constructed. inheritance systems often use older technology not based on the intranet's Tpc/Ip protocols. There are a variety of ways in which intranets can tie to inheritance systems. A Base way is to use Cgi scripts to passage the database data and pour that data into Html formatted text, production it ready to a Web browser. Information sent across an intranet is sent to the allowable destination by routers, which witness each Tcp/Ip packet for the Ip address and rule the packet's destination. It then sends the packet to the next router closest to the destination. If the packet is to be delivered to an address on the same subnetwork of the intranet it was sent from, the packet may be able to be delivered directly without having to go through any other routers. If it is to be sent to other subnetwork on the intranet, it will be sent to other internal router address. If the packet is to be sent to a destination face the intranet-in other words, to an Internet destination-the packet is sent to a router that connects to the Internet
How Tcp/Ip and Ipx Work on Intranets
What distinguishes an intranet from any other kind of incommunicable network is that it is based on Tcp/Ip-the same protocols that apply to the Internet. Tcp/Ip refers to two protocols that work together to deliver data: the Transmission control Protocol (Tcp) and the Internet Protocol (Ip). When you send data across an intranet, the data is broken into small packets. The packets are sent independently through a series of switches called routers. Once all the packets arrive at their destination, they are recombined into their traditional form. The Transmission control Protocol breaks the data into packets and recombines them on the receiving end. The Internet Protocol handles the routing of the data and makes sure it gets sent to the allowable destination.
In some companies, there may be a mix of Tcp/Ip-based intranets and networks based on other networking technology, such as NetWare. In that instance, the Tcp/Ip technology of an intranet can be used to send data in the middle of NetWare or other networks, using a technique called Ip tunneling. In this instance, we'll look at data being sent from one NetWare network to another, via an intranet. NetWare networks use the Ipx (Internet Packet Exchange) protocol as a way to deliver data-and Tcp/Ip networks can't recognize that protocol. To get around this, when an Ipx packet is to be sent across an intranet, it is first encapsulated inside an Ip packet by a NetWare server specifically for and dedicated to providing the Ip converyance mechanism for Ipx packets. Data sent within an intranet must be broken up into packets of less than 1,500 characters each. Tcp breaks the data into packets. As it creates each packet, it calculates and adds a checksum to the packet. The checksum is based on the byte values, that is, the correct estimate of data in the packet. Each packet, along with the checksum, is put into isolate Ip wrappers or "envelopes." These wrappers comprise data that details exactly where on the intranet-or the Internet-the data is to be sent. All of the wrappers for a given piece of data have the same addressing data so that they can all be sent to the same location for reassembly. The packets voyage in the middle of networks by intranet routers. Routers witness all Ip wrappers and look at their addresses. These routers rule the most sufficient path for sending each packet to its final destination. Since the traffic load on an intranet often changes, the packets may be sent along dissimilar routes, and the packets may arrive out of order. If the router sees the address is one settled inside the intranet, the packet may be sent directly to its destination, or it may instead be sent to other router. If the address is settled out on the Internet, it will be sent to other router so it can be sent across the Internet. As the packets arrive at their destination, Tcp calculates a checksum for each packet. It then compares this checksum with the checksum that has been sent in the packet. If the checksums don't match, Tcp knows that the data in the packet has been corrupted while transmission. It then discards the packet and asks that the traditional packet be retransmitted. Tcp includes the capability to check packets and to rule that all the packets have been received. When all the non-corrupt packets are received, Tcp assembles them into their original, unified form. The header data of the packets relays the sequence of how to reassemble the packets. An intranet treats the Ip packet as it would any other, and routes the packet to the receiving NetWare network. On the receiving NetWare network, a NetWare Tcp/Ip server decapsulates the Ip packet-it discards the Ip packet, and reads the traditional Ipx packet. It can now use the Ipx protocol to deliver the data to the allowable destination.
How the Osi Model Works
A group called the International Standards society (Iso) has put together the Open Systems Interconnect (Osi) Reference Model, which is a model that describes seven layers of protocols for computer communications. These layers don't know or care what is on adjacent layers. Each layer, essentially, only sees the reciprocal layer on the other side. The sending application layer sees and talks to the application layer on the destination side. That conversation takes place irrespective of, for example, what buildings exists at the bodily layer, such as Ethernet or Token Ring. Tcp combines the Osi model's application, presentation, and session layers into one which is also called the application layer.
The application layer refers to application interfaces, not programs like word processing. Mhs (Message Handling Service) is such an interface and it operates at this level of the Osi model. Again, this segmentation and interface advent means that a variety of email programs can be used on an intranet so long as they conform to the Mhs suitable at this application interface level. The presentation layer typically Plainly provides a suitable interface in the middle of the application layer and the network layers. This type of segmentation allows for the great flexibility of the Osi model since applications can vary endlessly, but, as long as the results conform to this suitable interface, the applications need not be implicated with any of the other layers. The session layer allows for the communication in the middle of sender and destination. These conversations avoid blurring by speaking in turn. A token is passed to control and to indicate which side is allowed to speak. This layer executes transactions, like rescue a file. If something prevents it from completing the save, the session layer, which has a narrative of the traditional state, returns to the traditional state rather than allowing a corrupt or incomplete transaction to occur. The converyance layer segments the data into suitable packet sizes and is responsible for data integrity of packet segments. There are some levels of service that can be implemented at this layer, together with segmenting and reassembly, error recovery, flow control, and others. The Ip wrapper is put around the packet at the network or Internet layer. The header includes the source and destination addresses, the sequence order, and other data essential for correct routing and rebuilding at the destination. The data-link layer frames the packets-for example, for use with the Ppp (Point to Point). It also includes the logical link quantum of the Mac sublayer of the Ieee 802.2, 802.3 and other standards. Ethernet and Token Ring are the two most Base bodily layer protocols. They function at the Mac (Media passage Control) level and move the data over the cables based on the bodily address on each Nic (Network Interface Card). The bodily layer includes the bodily components of the Ieee 802.3 and other specifications.
How Tcp/Ip Packets Are Processed
Protocols such as Tcp/Ip rule how computers recite with each other over networks such as the Internet. These protocols work in concert with each other, and are layered on top of one other in what is generally referred to as a protocol stack. Each layer of the protocol is designed to perform a specific purpose on both the sending and receiving computers. The Tcp stack combines the application, presentation, and the session layers into a single layer also called the application layer. Other than that change, it follows the Osi model. The illustration below shows the wrapping process that occurs to transmit data.
The Tcp application layer formats the data being sent so that the layer below it, the converyance layer, can send the data. The Tcp application layer performs the equivalent actions that the top three layers of Osi perform: the application, presentation, and session layers. The next layer down is the converyance layer, which is responsible for transferring the data, and ensures that the data sent and the data received are in fact the same data-in other words, that there have been no errors introduced while the sending of the data. Tcp divides the data it gets from the application layer into segments. It attaches a header to each segment. The header contains data that will be used on the receiving end to ensure that the data hasn't been altered en route, and that the segments can be properly recombined into their traditional form. The third layer prepares the data for delivery by putting them into Ip datagrams, and determining the allowable Internet address for those datagrams. The Ip protocol works in the Internet layer, also called the network layer. It puts an Ip wrapper with a header onto each segment. The Ip header includes data such as the Ip address of the sending and receiving computers, and the distance of the datagram, and the sequence order of the datagram. The sequence order is added because the datagram could conceivably exceed the size allowed for network packets, and so would need to be broken into smaller packets. together with the sequence order will allow them to be recombined properly. The Internet layer checks the Ip header and checks to see either the packet is a fragment. If it is, it puts together fragments back into the traditional datagram. It strips off the Ip header, and then sends the datagram to the converyance layer. The converyance layer looks at the remaining header to rule which application layer protocol-Tcp or Udp-should get the data. Then the allowable protocol strips off the header and sends the data to the receiving application. The application layer gets the data and performs, in this case, an Http request. The next layer down, the data link layer, uses protocols such as the Point-to-Point Protocol (Ppp) to put the Ip datagram into a frame. This is done by putting a header-the third header, after the Tcp header and the Ip header-and a footer around the Ip datagram to fra-me it. Included in the frame header is a Crc check that checks for errors in the data as the data travels over the network. The data-link layer ensures that the Crc for the frame is right, and that the data hasn't been altered while it was sent. It strips off the frame header and the Crc, and sends the frame to the Internet layer. On the receiving computer, the packet travels through the stack, but in the opposite order from which the packet was created. In other words, it starts at the bottom layer, and moves its way up through the protocol stack. As it moves up, each layer strips off the header data that was added by the Tcp/Ip stack of the sending computer. The final layer is the bodily network layer, which specifies the bodily characteristics of the network being used to send data. It describes the actual hardware standards, such as the Ethernet specification. The layer receives the frames from the data link layer, and translates the Ip addresses there into the hardware addresses required for the specific network being used. Finally, the layer sends the frame over the network. The bodily network layer receives the packet. It translates the hardware address of the sender and receiver into Ip addresses. Then it sends the frame up to the data link layer.
How Bridges Work
Bridges are hardware and software combinations that connect dissimilar parts of a single network, such as dissimilar sections of an intranet. They connect local area networks (Lans) to each other. They are generally not used, however, for connecting entire networks to each other, for example, for connecting an intranet to the Internet, or an intranet to an intranet, or to connect an entire subnetwork to an entire subnetwork. To do that, more sophisticated pieces of technology called routers are used.
When there is a great estimate of traffic on an Ethernet local area network, packets can collide with one another, reducing the efficiency of the network, and slowing down network traffic. Packets can collide because so much of the traffic is routed among all the workstations on the network. In order to cut down on the collision rate, a single Lan can be subdivided into two or more Lans. For example, a single Lan can be subdivided into some departmental Lans. Most of the traffic in each departmental Lan stays within the agency Lan, and so it needn't voyage through all the workstations on all the Lans on the network. In this way, collisions are reduced. Bridges are used to link the Lans. The only traffic that needs to voyage across bridges is traffic bound for other Lan. Any traffic within the Lan need not voyage across a bridge. Each packet of data on an intranet has more data in it than just the Ip information. It also includes addressing data required for other basal network architecture, such as for an Ethernet network. Bridges look at this outer network addressing data and deliver the packet to the allowable address on a Lan Bridges consult a learning table that has the addresses of all the network nodes in it. If a bridge finds that a packet belongs on its own Lan, it keeps the packet inside the Lan. If it finds that the workstation is on other Lan, it forwards the packet. The bridge constantly updates the learning table as it monitors and routes traffic. Bridges can connect Lans in a variety of dissimilar ways. They can connect Lans using serial connections over traditional phone lines and modems, over Isdn lines, and over direct cable connections. Csu/Dsu units are used to connect bridges to telephone lines for remote connectivity. Bridges and routers are sometimes combined into a single stock called a brouter. A brouter handles both bridging and routing tasks. If the data needs to be sent only to other Lan on the network or subnetwork, it will act only as a bridge delivering the data based on the Ethernet address. If the destination is other network entirely, it will act as a router, examining the Ip packets and routing the data based on the Ip address.
How Intranet Routers Work
Just as routers direct traffic on the Internet, sending data to its allowable destination, and routers on an intranet perform the same function. Routers-equipment that is a blend of hardware and software-can send the data to a computer on the same sub network inside the intranet, to other network on the intranet, or face to the Internet. They do this by examining header data in Ip packets, and then sending the data on its way. Typically, a router will send the packet to the next router closest to the final destination, which in turn sends it to an even closer router, and so on, until the data reaches its intended recipient.
A router has input ports for receiving Ip packets, and output ports for sending those packets toward their destination. When a packet comes to the input port, the router examines the packet header, and checks the destination in it against a routing table-a database that tells the router how to send packets to varied destinations. Based on the data in the routing table, the packet is sent to a single output port, which sends the packet to the next closest router to the packet's destination. If packets come to the input port more swiftly than the router can process them, they are sent to a keeping area called an input queue. The router then processes packets from the queue in the order they were received. If the estimate of packets received exceeds the capacity of the queue (called the distance of the queue), packets may be lost. When this happens, the Tcp protocol on the sending and receiving computers will have the packets re-sent. In a simple intranet that is a single, completely self-contained network, and in which there are no connections to any other network or the intranet, only minimal routing need be done, and so the routing table in the router is exceedingly simple with very few entries, and is constructed automatically by a agenda called ifconfig. In a slightly more complicated intranet which is composed of a estimate of Tcp/Ip-based networks, and connects to a little estimate of Tcp/Ip-based networks, static routing will be required. In static routing, the routing table has specific ways of routing data to other networks. Only those pathways can be used. Intranet administrators can add routes to the routing table. Static routing is more flexible than minimal routing, but it can't change routes as network traffic changes, and so isn't favorable for many intranets. In more complicated intranets, dynamic routing will be required. Dynamic routing is used to permit multiple routes for a packet to reach its final destination. Dynamic routing also allows routers to change the way they route data based on the estimate of network traffic on some paths and routers. In dynamic routing, the routing table is called a dynamic routing table and changes as network conditions change. The tables are built dynamically by routing protocols, and so constantly change according to network traffic and conditions. There are two broad types of routing protocols: interior and exterior. Interior routing protocols are typically used on internal routers inside an intranet that routes traffic bound only for inside the intranet. A Base interior routing protocol is the Routing data Protocol (Rip). face protocols are typically used for external routers on the Internet. AÊcommon face protocol is the face Gateway Protocol (Egp).
Intranets come in dissimilar sizes. In a small company, an intranet can be composed of only a handful of computers. In a medium-sized business, it may comprise dozens or hundreds of computers. And in a large corporation, there may be thousands of computers spread across the globe, all connected to a single intranet. When intranets get large, they need to be subdivided into private subnets or subnetworks.
To understand how subnetting works, you first need to understand Ip addresses. Every Ip address is a 32-bit numeric address that uniquely identifies a network and then a specific host on that network. The Ip address is divided into two sections: the network section, called the netid, and the host section, called the hostid.
Each 32-bit Ip address is handled differently, according to what class of network the address refers to. There are three main classes of network addresses: Class A, Class B, and Class C. In some classes, more of the 32-bit address space is devoted to the netid, while in others, more of the address space is devoted to the hostid. In a Class A network, the netid is composed of 8 bits, while the hostid is composed of 24 bits. In a Class B network, both the netid and the hostid are composed of 16 bits. In a Class C network, the netid is composed of 24 bits, while the hostid is composed of 8 bits. There's a simple way of knowing what class a network is in. If the first estimate of the Ip address is less than 128, the network is a Class A address. If the first estimate is from 128 to 191, it's a Class B network. If the first estimate is from 192 to 223, it's a Class C network. Numbers above 223 are reserved for other purposes. The smaller the netid, the fewer estimate of networks that can be subnetted, but the larger estimate of hosts on the network. A Class A rating is best for large networks while a Class C is best for small ones.
To originate a subnet, the demarcation line on the Ip address is moved in the middle of the netid and the hostid, to give the netid more bits to work with and to take away bits from the hostid. To do this, a special estimate called a subnet mask is used.
Subnetting is used when intranets grow over a clear size and they begin to have problems. One problem is administration of host Ip addresses-making sure that every computer on the network has a proper, up-to-date host address, and that old host addresses are put out of use until needed in the future. In a corporation spread out over some locations-or across the world-it's difficult, if not impossible, to have one someone responsible for managing the host addresses at every location and agency in the company.
Another problem has to do with a variety of hardware limitations of networks. dissimilar networks may all be part of an intranet. An intranet may have some sections that are Ethernet, other sections that are Token Ring networks, and conceivably other sections that use dissimilar networking technologies altogether. There is no easy way for an intranet router to link these dissimilar networks together and route the data to the allowable places.
Another set of problems has to do with the bodily limitations of network technology. In some kinds of networks, there are some correct limitations on how far cables can enlarge in the network. In other words, you can't go over a clear distance of cabling without using repeaters or routers. A "thick" Ethernet cable, for example, can only be extended to 500 meters, while a "thin" Ethernet cable can only go to 300 meters. Routers can be used to link these cables together, so that an intranet can be extended well beyond those distances. But when that is done, each distance of wire is essentially thought about its own subnetwork.
Yet one more set of problems has to do with the volume of traffic that travels across an intranet. Often in a corporation, in a given department, most of the traffic is intradepartmental traffic-in other words, mail and other data that habitancy within a agency send to each another. The volume of traffic face to other departments is considerably less. What's called for is a way to confine intradepartmental traffic inside the departments, to cut down on the estimate of data that needs to be routed and managed across the entire intranet.
Subnetting solves all these problems and more. When an intranet is divided into subnets, one central administrator doesn't have to carry on every aspect of the entire intranet. Instead, each subnet can take care of its own administration. That means smaller organizations within the larger society can take care of problems such as address administration and a variety of troubleshooting chores. If an intranet is subnetted by divisions or departments, it means that each agency or agency can guide the improvement of its own network, while adhering to general intranet architecture. Doing this allows departments or divisions more freedom to use technology to pursue their company goals.
Subnets also get around problems that arise when an intranet has within it dissimilar kinds of network architecture, such as Ethernet and Token Ring technologies. Normally-if there is no subnetting-a router can't link these dissimilar networks together because they don't have their own addresses. However, if each of the dissimilar networks is its own subnet-and so has its own network address-routers can then link them together and properly route intranet traffic.
Subnetting can also cut down on the traffic traveling across the intranet and its routers. Since much network traffic may be confined within departments, having each agency be its own subnet means that all that traffic need never cross an intranet router and cross the intranet-it will stay within its own subnet.
Subnetting can also growth the security on an intranet. If the payroll department, for example, were on its own subnet, then much of its traffic would not have to voyage across an intranet. Having its data traveling across the intranet could mean that someone could conceivably hack into the data to read it. Confining the data to its own subnet makes that much less likely to happen.
Dividing an intranet into subnets can also make the entire intranet more stable. If an intranet is divided in this way, then if one subnet goes down or is often unstable, it won't sway the rest of the intranet.
This all may sound rather confusing. To see how it's done, let's take a look at a network, and see how to use the Ip address to originate subnets. Let's say we have a Class B network. That network is assigned the address of 130.97.0.0. When a network is given an address, it is assigned the netid numbers-in this case, the 130.97-and it can assign the host numbers (in this case, 0.0) in any way that it chooses.
The 130.97.0.0 network is a single intranet. It's getting too large to manage, though, and we've decided to divide it into two subnets. What we do is fairly straightforward. We take a estimate from the hostid field and use it to recognize each of the subnets. So one subnet gets the address 130.97.1.0, and the other gets the address 130.97.2.0. private machines on the first subnet get addresses of 130.97.1.1, 130.97.1.2, and so on. private machines on the second subnet get addresses of 130.97.2.1, 130.97.2.2 and so on.
Sounds simple. But we have a problem. The Internet doesn't recognize 130.97.1.0 and 130.97.2.0 as isolate networks. It treats them both as 130.97.0.0 since the "1" and "2" that we're using as a netid is only known to the Internet as a hostid. So our intranet router will not be able to route incoming traffic to the allowable network.
To solve the problem, a subnet mask is used. A subnet mask is a 32-bit estimate in Ip form used by intranet routers and hosts that will help routers understand how to route data to the allowable subnet. To the face Internet, there is still only one network, but the subnet mask allows routers inside the intranet to send traffic to the allowable host.
A subnet mask is a estimate such as 255.255.255.0 (the built-in default for Class C addresses; the Class B default is 255.255.0.0 and the default for Class A is 255.0.0.0). A router takes the subnet mask and applies that estimate against the Ip estimate of incoming mail to the network by using it to perform a calculation. Based on the resulting Ip number, it will route mail to the allowable subnet, and then to a single computer on the subnet. For consistency, everybody in a single intranet will use the same subnet mask.
Subnetting an Intranet
When intranets are over a clear size, or are spread over some geographical locations, it becomes difficult to carry on them as a single network. To solve the problem, the single intranet can be subdivided into some subnets, subsections of an intranet that make them easier to manage. To the face world, the intranet still looks as if it's a single network.
If you're building an intranet and want it to be connected to the Internet, you'll need a unique Ip address for your intranet network, which the InterNic Registration Services will handle. There are three classes of intranet you can have: Class A, Class B, or Class C. Generally, a Class A rating is best for the largest networks, while a Class C is best for the smallest. A Class A network can be composed of 127 networks, and a total of 16,777,214 nodes on the network. A Class B network can be composed of 16,383 networks, and a total of 65,534 nodes. A Class C network can be composed of 2,097,151 networks, and 254 nodes. When an intranet is assigned an address, it is assigned the first two Ip numbers of the Internet numeric address (called the netid field) and the remaining two numbers (called the hostid field) are left blank, so that the intranet itself can assign them, such as 147.106.0.0. The hostid field consists of a estimate for a subnet and a host number. When an intranet is connected to the Internet, a router handles the job of sending packets into the intranet from the Internet. In our example, all incoming mail and data comes to a router for a network with the netid of 147.106.0.0. When intranets grow-for example, if there is a agency settled in other building, city, or country-there needs to be some way to carry on network traffic. It may be impractical and physically impossible to route all the data essential among many dissimilar computers spread across a building or the world. A second network-called a subnetwork or subnet-needs to be created. In order to have a router cope all incoming traffic for a subnetted intranet, the first byte of the hostid field is used. The bits that are used to distinguish among subnets are called subnet numbers. In our example, there are two subnets on the intranet. To the face world, there appears to be only one network. Each computer on each subnet gets its own Ip address, as in a general intranet. The blend of the netid field, the subnet number, and then ultimately a host number, forms the Ip address. The router must be informed that the hostid field in subnets must be treated differently than non-subnetted hostid fields, otherwise it won't be able to properly route data. In order to do this, a subnet mask is used. A subnet mask is a 32-bit estimate such as 255.255.0.0 that is used in concert with the numbers in the hostid field. When a calculation is performed using the subnet mask and the Ip address, the router knows where to route the mail. The subnet mask is put in people's network configuration files.
Overview of an Intranet security System
Any intranet is vulnerable to assault by habitancy intent on destruction or on stealing corporate data. The open nature of the Internet and Tcp/Ip protocols expose a corporation to attack. Intranets require a variety of security measures, together with hardware and software combinations that furnish control of traffic; encryption and passwords to validate users; and software tools to preclude and cure viruses, block objectionable sites, and monitor traffic.
The generic term for a line of defense against intruders is a firewall. A firewall is a hardware/software blend that controls the type of services allowed to or from the intranet. Proxy servers are other Base tool used in building a firewall. A proxy server allows principles administrators to track all traffic advent in and out of an intranet. A bastion server firewall is configured to withstand and preclude unauthorized passage or services. It is typically segmented from the rest of the intranet in its own subnet or perimeter network. In this way, if the server is broken into, the rest of the intranet won't be compromised. Server-based virus-checking software can check every file advent into the intranet to make sure that it's virus-free. Authentication systems are an foremost part of any intranet security scheme. Authentication systems are used to ensure that whatever trying to log into the intranet or any of its resources is the someone they claim to be. Authentication systems typically use user names, passwords, and encryption systems. Server-based site-blocking software can bar habitancy on an intranet from getting objectionable material. Monitoring software tracks where habitancy have gone and what services they have used, such as Http for Web access. One way of ensuring that the wrong habitancy or erroneous data can't get into the intranet is to use a filtering router. This is a special kind of router that examines the Ip address and header data in every packet advent into the network, and allows in only those packets that have addresses or other data, like e-mail, that the principles administrator has decided should be allowed into the intranet.
All intranets are vulnerable to attack. Their basal Tcp/Ip architecture is same to that of the Internet. Since the Internet was built for maximum openness and communication, there are countless techniques that can be used to assault intranets. Attacks can involve the theft of vital company data and even cash. Attacks can destroy or deny a company's computing resources and services. Attackers can break in or pose as a company laborer to use the company's intranet resources.
Firewalls are hardware and software combinations that block intruders from passage to an intranet while still allowing habitancy on the intranet to passage the resources of the Internet. Depending on how collect a site needs to be, and on how much time, money, and resources can be spent on a firewall, there are many kinds that can be built. Most of them, though, are built using only a few elements. Servers and routers are the traditional components of firewalls.
Most firewalls use some kind of packet filtering. In packet filtering, a screening router or filtering router looks at every packet of data traveling in the middle of an intranet and the Internet.
Proxy servers on an intranet are used when someone from the intranet wants to passage a server on the Internet. A request from the user's computer is sent to the proxy server instead of directly to the Internet. The proxy server contacts the server on the Internet, receives the data from the Internet, and then sends the data to the requester on the intranet. By acting as a go-between like this, proxy servers can filter traffic and articulate security as well as log all traffic in the middle of the Internet and the network.
Bastion hosts are heavily fortified servers that cope all incoming requests from the Internet, such as Ftp requests. A single bastion host handling incoming requests makes it easier to articulate security and track attacks. In the event of a break in, only that single host has been compromised, instead of the entire network. In some firewalls, multiple bastion hosts can be used, one for each dissimilar kind of intranet service request.
How Firewalls Work
Firewalls safe intranets from any attacks launched against them from the Internet. They are designed to safe an intranet from unauthorized passage to corporate information, and damaging or denying computer resources and services. They are also designed to stop habitancy on the intranet from accessing Internet services that can be dangerous, such as Ftp.
Intranet computers are allowed passage to the Internet only after passing through a firewall. Requests have to pass through an internal screening router, also called an internal filtering routeror choke router. This router prevents packet traffic from being sniffed remotely. A choke router examines all pack-ets for data such as the source and destination of the packet. The router compares the data it finds to rules in a filtering table, and passes or drops the packets based on those rules. For example, some services, such as rlogin, may not be allowed to run. The router also might not allow any packets to be sent to specific suspicious Internet locations. A router can also block every packet traveling in the middle of the Internet and the internal network, except for e-mail. principles administrators set the rules for determining which packets to allow in and which to block. When an intranet is protected by a firewall, the usual internal intranet services are available-such as e-mail, passage to corporate databases and Web services, and the use of groupware. Screened subnet firewalls have one more way to safe the intranet-an face screening router, also called an face filtering router or an passage router. This router screens packets in the middle of the Internet and the perimeter network using the same kind of technology that the interior screening router uses. It can screen packets based on the same rules that apply to the internal screening router and can safe the network even if the internal router fails. It also, however, may have supplementary rules for screening packets specifically designed to safe the bastion host. As a way to supplementary safe an intranet from attack, the bastion host is settled in a perimeter network-a subnet-inside the firewall. If the bastion host was on the intranet instead of a perimeter network and was broken into, the intruder could gain passage to the intranet. A bastion host is the main point of caress for connections advent in from the Internet for all services such as e-mail, Ftp access, and any other data and requests. The bastion host services all those requests-people on the intranet caress only this one server, and they don't directly caress any other intranet servers. In this way, intranet servers are protected from attack.
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