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Ask a CCNA candidate how they’re preparing for exam day, and you’ll get different answers. Different books, different websites, different practice exams.

One trend I’ve noticed is that some candidates answer the question by reeling off the number and names of the practice exams they’ve purchased. Basically, the candidate is studying by taking a lot of practice exams. And in some cases, I mean a lot of them.

The intent of this article isn’t to slam practice exams. I do want to address this trend among Cisco certification candidates of purchasing as many practice exams as they can find, attempting to pass the CCNA exam by “brute forcing” it, as one Cisco employee recently said.

I have nothing against practice exams. I sell flash cards that serve as a practice exam, if that’s the way the candidate wants to use them. However, you can’t be dependent on them to pass your exams. As I tell students every day, “When you’re in front of a rack of routers, there is no A, B, C, and D choice. You’ve got to know what you’re doing.”

If practice exams are a candidate’s primary tool for exam preparation, though, they’ll most likely be disappointed on exam day. The current Cisco CCNA exams are designed to weed out those who have memorized a chart or two there is a premium not only on knowledge, but the ability to apply that knowledge. Just taking one practice exam after the other will not develop this skill.

Simulators are fine to a certain extent as well, but don’t become dependent on them. The simulators I’ve seen don’t really let you make mistakes in your configuration, and it’s when you have to fix your own mistakes that you truly learn what’s going on.

Keep the long-range view when preparing for your CCNA exams. You’re not just studying for exam day you’re laying the groundwork for a successful career. The study you do for your CCNA exam will be some of the most important study you ever do, since all the work you do for future certifications like the CCNP (and yes, the CCIE!) are based on the foundation you’re building today.

Make it a solid foundation. Stick to a well-rounded study plan, using books, practice exams, and routing equipment, and you’re on your way to success in the Cisco field.

Chris Bryant

CCIE #12933

christhebryantadvantage

Home security is an important issue for any person. A person’s home is their castle and they want to feel safe and secure. There are several security measures that can be implemented to ensure security such as alarms but one that ensures peace of mind is a wireless home security camera package.

What’s need in the package is a camera to fit either just outside the front or back door that transmits a wireless signal. The best one to buy would be one that has night vision to ensure you can see everything at night. The second would be a receiver. Some receivers have screens so you can watch what’s going on no matter where you are and others need to be connected to a computer or television to see the transmission.

If connected to a computer or television the live feed from the camera can be directly recorded to a hard drive or a cassette or DVD depending on which is convenient. Several cameras can be implemented to get several signals meaning more coverage of the home and the surrounding area.

These wireless home security packages are common and can be purchased at most electronics stores. They are on the expensive side but are worth the purchase for the kind of technology it has. With almost everything becoming wireless these days it was only a matter of time until cameras became wireless also.

Most people need some sort of security measure in place, not for protection, but for peace of mind that they are safe in their home. Although there are several other measures that can be implemented in terms of security, the wireless home security camera is a valuable tool for keeping an eye on things at all times. It will complement any other security measure you have in place and will not disappoint.

For anyone concerned about what is left on their PC after using the Internet, Webroot Window Washer can set the mind at ease.

Window Washer wipes away all traces of past PC use. It not only removes Internet history, but also previously deleted files that may still have a presence on the hard disk. A quick cycle of Window Washer can:

• clear Internet history, address bar and cache

• delete selected cookies

• overwrite deleted files

• shred folders with one-click

• provide protection against deleting important files

• schedule washes

• clear unused disk space to ensure faster, smoother PC operation

• clean applications such as iTunes, Adobe Acrobat, Google Toolbar and Macromedia Flash Player

• securely erase whole hard disk

• work with Internet Explorer, Mozilla, Firefox, Netscape, and AOL

When using the Internet all sort of information gets left behind: history of sites visited, web addresses typed into the address bar, a cache of each page visited, cookies holding user information, chat logs…the list goes on. Window Washer will safely remove all of these files so no trace of online activity remains. Not only that, all of this information can slow down working, so cleaning the system makes the PC quicker and more efficient.

In trying to eliminate PC activity, it can be very easy to accidentally get rid of some important file the system needs to run properly. Window Washer provides protection against doing this whilst removing any incriminating information.

Likewise, whilst some Internet cookies might be from unsavory sources, others prove invaluable in remembering names and passwords for often visited sites. It’s easy to remove all the cookies in one go, but Window Washer allows selective cookie deletion so only the desired ones remain.

Simply deleting items from the system is not enough to remove them from the hard disk entirely. Free space can actually be full of unused files and bits of deleted files. Window Washer can overwrite this unused data with completely random information, making it worthless to anyone trying to get at it, and clean up these areas for better performance.

Window Washer is also capable of erasing the hard disk completely. Formatting and reinstalling the operating system may not destroy everything contained on the hard disk. Window Washer ensures nothing is left on a PC that might be going to a new owner.

For the most security conscious, it is not even necessary to make an effort to run Window Washer. Once installed, it can be set to wash at specified times, such as when the PC is booted up or shut down, or each time the browser is closed. Window Washer will also clean other applications. Flash Player, Adobe Acrobat, Real Player &ndash they all store document histories of what’s been viewed and, sometimes, when it was viewed. Window Washer will empty these histories for a faster running application.

Minimum system requirements for Webroot Window Washer are not high. Even the most basic PC should be able to run it as long as it has:

• Windows 98 SE/2000/Me/XP

• 266 MHz CPU

• 5 MB hard drive space

• 64 MB RAM

Webroot Window Washer is available for download as a free trial. The full version costs $29.95 for a one year upgrade and support subscription.

The Computer is a very complicated device we use for our every day comfort and the importance of some of its numerical aspects is sometimes neglected. For example: a different number is given to each computer when its user goes online or when it is part of a network. This number is the IP address and knowing about it is like knowing where you live…

What’s my IP and what do its numbers stand for?

IP stands for Internet Protocol and the address is formed from 4 numbers separated by periods. The IP address format is a 32 bit numeric one and each number can be from 0 to 255. The IP address consists of two parts: first one represent the network number and it is similar for more than one user (like the number of a street) and second represents the host name which is different for each user (like the house number). To increase the number of available IP addresses within big networks with a lot of users or small networks with few hosts, the address is divided into 4 classes (A, B, C, and D)

Having an IP address it’s like having a last name in a network. To identify a computer in a network (LAN-local area network, WAN-wide area network or on the Internet) it has to have an IP address. This number is similar to a phone number or to a zip code. It is unique and without it the device or computer can not be used in a network area. Within an isolated network the computers can be assigned different random IP addresses, but if a private network needs to be connected to the Internet the IP has to be registered so that its uniqueness is verified.

Where do I find my IP address?

Connect to a site that recognizes your IP address and let you see it also. You can visit this site for example: iprelated.com. These IP Lookup sites are very easy to use and very useful for others. An IP address can offer a lot information about the person who logs in on the Internet and engages in a certain activity.

This is how illegal activity is sometimes detected and violations are reported. The IP address says less about the user if it is a dynamic one because it changes every time the user logs in.

Another interesting aspect is that some people who have the information from your IP address are interested in taking you computer over and using its resources. This is not impossible! They can use software that enables them to do this so it is better to hide your IP when you are online.

Who gives me my IP address?

The IP address can be static or dynamic, meaning it can be the same every time you are online or it can change. The IP address is provided by a server through a service called DHCP (Dynamic Host Configuration Protocol)

Although things can get pretty complicated when explaining numbers and their significance, this is just a small and easy to understand introduction about the IP address that does not involve technical terms. The importance of these details is very high because starting from these brief explanations one can truly comprehend the necessity and implications of the IP address and of virtual geo location.

As crime globalizes, so does crime fighting. Mobsters, serial killers, and terrorists cross state lines and borders effortlessly, making use of the latest advances in mass media, public transportation, telecommunications, and computer networks. The police - there are 16,000 law enforcement agencies in the Unites States alone - is never very far behind.

Quotes from the official Web pages of some of these databases:

National Center for the Analysis of Violent Crime (NCAVC)

Its mission is to combine investigative and operational support functions, research, and training in order to provide assistance, without charge, to federal, state, local, and foreign law enforcement agencies investigating unusual or repetitive violent crimes. The NCAVC also provides support through expertise and consultation in non-violent matters such as national security, corruption, and white-collar crime investigations.

It comprises the Behavioral Analysis Unit (BAU), Child Abduction and Serial Murder Investigative Resources Center (CASMIRC), and Violent Criminal Apprehension Program (VICAP).

VICAP is a nationwide data information center designed to collect, collate, and analyze crimes of violence - specifically murder. It collates and analyzes the significant characteristics of all murders, and other violent offenses.

Homicide Investigation Tracking System (HITS)

A program within the Washington state’s Attorney General’s Office that tracks and investigates homicides and rapes.

Violent Crime Linkage System (ViCLAS)

Canada-wide computer system that assists specially trained investigators to identify serial crimes and criminals by focusing on the linkages that exist among crimes by the same offender. This system was developed by the RCMP (Royal Canadian Mounted Police) in the early 1990s.

UTAP, stands for The Utah Criminal Tracking and Analysis Project

Gathers experts from forensic science, crime scene analysis, psychiatry and other fields to screen unsolved cases for local law enforcement agencies.

International Criminal Police Organization (ICPO) - Interpol’s DNA Gateway

Provides for the transfer of profile data between two or more countries and for the comparison of profiles that conform to Interpol standards in a centralized database. Investigators can access the database via their Interpol National Central Bureau (NCB) using Interpol’s secure global police communications system, I-24/7.

Interpol’s I-24/7

Global communication system to connect its member countries and provide them with user-friendly access to police information. Using this system, Interpol National Central Bureaus (NCBs) can search and cross-check data in a matter of seconds, with direct and immediate access to databases containing critical information (ASF Nominal database of international criminals, electronic notices, stolen motor vehicles, stolen/lost/counterfeit travel and ID documents, stolen works of art, payment cards, fingerprints and photographs, a terrorism watch list, a DNA database, disaster victim identification, international weapons tracking and trafficking in human beings-related information, etc).

Interpol Fingerprints

Provides information on the development and implementation of fingerprinting systems for the general public and international law enforcement entities.

Europol (European Union’s criminal intelligence agency) Computer System (TECS)

Member States can directly input data into the information system in compliance with their national procedures, and Europol can directly input data supplied by non EU Member States and third bodies. Also provides analyses and indexing services.

One point of confusion for some CCNA and CCNP candidates is the difference between configuring a static default route and using the Cisco routing command ip default-network.

At first glance, they appear to do the same thing. Both configure a destination to which packets should be routed if there is no more specific route in the routing table.

The major difference between these two options is that configuring a static default route only defines a default route for the router you’re configuring it on, while ip default-network will propagate the route via its routing protocol.

Let’s examine the routing tables of a hub-and-spoke network using the ip default-network command. R1 is the hub and R2 and R3 are the spokes. They are directly connected via the network 172.12.123.0 /24, and each has a loopback with a 32-bit mask that are numbered according to the router number (1.1.1.1, etc.) RIP is running on all three routers and the loopbacks are advertised.

R1 has another serial interface with the IP address 10.1.1.1 /24, and this network has been flagged as a default network with the command ip default-network 10.0.0.0 . It is not being advertised by RIP.

The routing protocol will then advertise this route. With RIP, the default network is advertised as 0.0.0.0 . (With IGRP, it appears as the network number, but is marked as an IGRP External route. ) This route has been designated a candidate default route on R1, as we see with the asterisk next to the 10.0.0.0 /24 network (code table removed for brevity):

R1#show ip route

Gateway of last resort is not set

1.0.0.0/32 is subnetted, 1 subnets

C 1.1.1.1 is directly connected, Loopback0

R 2.0.0.0/8 [120/1] via 172.12.123.2, 00:00:11, Serial0

R 3.0.0.0/8 [120/1] via 172.12.123.3, 00:00:11, Serial0

172.12.0.0/16 is variably subnetted, 2 subnets, 2 masks

C 172.12.21.0/30 is directly connected, BRI0

C 172.12.123.0/24 is directly connected, Serial0

* 10.0.0.0/24 is subnetted, 1 subnets

C 10.1.1.0 is directly connected, Serial1

On R2 and R3, a default RIP route is now seen (code tables again deleted):

R2#show ip route

Gateway of last resort is 172.12.123.1 to network 0.0.0.0

R 1.0.0.0/8 [120/1] via 172.12.123.1, 00:00:00, Serial0.213

2.0.0.0/32 is subnetted, 1 subnets

C 2.2.2.2 is directly connected, Loopback0

R 3.0.0.0/8 [120/2] via 172.12.123.1, 00:00:00, Serial0.213

172.12.0.0/16 is variably subnetted, 2 subnets, 2 masks

C 172.12.21.0/30 is directly connected, BRI0

C 172.12.123.0/24 is directly connected, Serial0.213

R* 0.0.0.0/0 [120/1] via 172.12.123.1, 00:00:00, Serial0.213

R3#show ip route

Gateway of last resort is 172.12.123.1 to network 0.0.0.0

R 1.0.0.0/8 [120/1] via 172.12.123.1, 00:00:27, Serial0.31

R 2.0.0.0/8 [120/2] via 172.12.123.1, 00:00:28, Serial0.31

3.0.0.0/32 is subnetted, 1 subnets

C 3.3.3.3 is directly connected, Loopback0

172.12.0.0/24 is subnetted, 1 subnets

C 172.12.123.0 is directly connected, Serial0.31

R* 0.0.0.0/0 [120/1] via 172.12.123.1, 00:00:28, Serial0.31

And the default route works, since we can ping 10.1.1.1 from both R2 and R3. Since they have no other match in their routing tables, they use the default route.

R2#ping 10.1.1.1

Type escape sequence to abort.

Sending 5, 100-byte ICMP Echos to 10.1.1.1, timeout is 2 seconds:

!!!!!

Success rate is 100 percent (5/5), round-trip min/avg/max = 68/68/68 ms

R3#ping 10.1.1.1

Type escape sequence to abort.

Sending 5, 100-byte ICMP Echos to 10.1.1.1, timeout is 2 seconds:

!!!!!

Success rate is 100 percent (5/5), round-trip min/avg/max = 68/68/68 ms

When deciding whether to use a default static route or a default network, keep in mind that if you want the routing protocol to propagate the default route, the ip default-network command will do that for you. But if you want only the local router to have the default route, a static IP route is the way to go.

Article : How To Find Your IP Address . DNS Address . IPv4 . IPv6

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IP address

(Internet Protocol address) is a unique address that certain electronic devices use in order to identify and communicate with each other on a computer network utilizing the Internet Protocol standard (IP)&ndashin simpler terms, a computer address. Any participating network device&ndashincluding routers, computers, time-servers, printers, Internet fax machines, and some telephones&ndashcan have their own unique address.

An IP address can also be thought of as the equivalent of a street address or a phone number ( compare: VoIP (voice over (the) internet protocol)) for a computer or other network device on the Internet. Just as each street address and phone number uniquely identifies a building or telephone, an IP address can uniquely identify a specific computer or other network device on a network. An IP address differs from other contact information, however, because the linkage of a user’s IP address to his/her name is not publicly available information.

IP addresses can appear to be shared by multiple client devices either because they are part of a shared hosting web server environment or because a network address translator (NAT) or proxy server acts as an intermediary agent on behalf of its customers, in which case the real originating IP addresses might be hidden from the server receiving a request. A common practice is to have a NAT hide a large number of IP addresses, in the private address space defined by RFC 1918, an address block that cannot be routed on the public Internet. Only the “outside” interface(s) of the NAT need to have Internet-routable addresses.

Most commonly, the NAT device maps TCP or UDP port numbers on the outside to individual private addresses on the inside. Just as there may be site-specific extensions on a telephone number, the port numbers are site-specific extensions to an IP address.

IP addresses are managed and created by the Internet Assigned Numbers Authority (IANA). The IANA generally allocates super-blocks to Regional Internet Registries, who in turn allocate smaller blocks to Internet service providers and enterprises.

DNS Address:

On the Internet, the Domain Name System (DNS) associates various sorts of information with so-called domain names; most importantly, it serves as the “phone book” for the Internet: it translates human-readable computer hostnames, e.g. en.wikipedia.org, into the IP addresses that networking equipment needs for delivering information. It also stores other information such as the list of mail exchange servers that accept email for a given domain. In providing a worldwide keyword-based redirection service, the Domain Name System is an essential component of contemporary Internet use.

Uses :

The most basic use of DNS is to translate hostnames to IP addresses. It is in very simple terms like a phone book. For example, if you want to know the internet address of en.wikipedia.org, the Domain Name System can be used to tell you it is 66.230.200.100. DNS also has other important uses.

Pre-eminently, DNS makes it possible to assign Internet destinations to the human organization or concern they represent, independently of the physical routing hierarchy represented by the numerical IP address. Because of this, hyperlinks and Internet contact information can remain the same, whatever the current IP routing arrangements may be, and can take a human-readable form (such as “wikipedia.org”) which is rather easier to remember than an IP address (such as 66.230.200.100). People take advantage of this when they recite meaningful URLs and e-mail addresses without caring how the machine will actually locate them.

The Domain Name System distributes the responsibility for assigning domain names and mapping them to IP networks by allowing an authoritative server for each domain to keep track of its own changes, avoiding the need for a central registrar to be continually consulted and

History :

The practice of using a name as a more human-legible abstraction of a machine’s numerical address on the network predates even TCP/IP, and goes all the way to the ARPAnet era. Back then however, a different system was used, as DNS was only invented in 1983, shortly after TCP/IP was deployed. With the older system, each computer on the network retrieved a file called HOSTS.TXT from a computer at SRI (now SRI International). The HOSTS.TXT file mapped numerical addresses to names. A hosts file still exists on most modern operating systems, either by default or through configuration, and allows users to specify an IP address (eg. 192.0.34.166) to use for a hostname (eg. .example.net) without checking DNS. As of 2006, the hosts file serves primarily for troubleshooting DNS errors or for mapping local addresses to more organic names. Systems based on a hosts file have inherent limitations, because of the obvious requirement that every time a given computer’s address changed, every computer that seeks to communicate with it would need an update to its hosts file.

The growth of networking called for a more scalable system: one that recorded a change in a host’s address in one place only. Other hosts would learn about the change dynamically through a notification system, thus completing a globally accessible network of all hosts’ names and their associated IP Addresses.

At the request of Jon Postel, Paul Mockapetris invented the Domain Name System in 1983 and wrote the first implementation. The original specifications appear in RFC 882 and 883. In 1987, the publication of RFC 1034 and RFC 1035 updated the DNS specification and made RFC 882 and RFC 883 obsolete. Several more-recent RFCs have proposed various extensions to the core DNS protocols.

In 1984, four Berkeley students &ndash Douglas Terry, Mark Painter, David Riggle and Songnian Zhou &ndash wrote the first UNIX implementation, which was maintained by Ralph Campbell thereafter. In 1985, Kevin Dunlap of DEC significantly re-wrote the DNS implementation and renamed it BIND (Berkeley Internet Name Domain, previously: Berkeley Internet Name Daemon). Mike Karels, Phil Almquist and Paul Vixie have maintained BIND since then. BIND was ported to the Windows NT platform in the early 1990s.

Due to BIND’s long history of security issues and exploits, several alternative nameserver/resolver programs have been written and distributed in recent years.

How DNS Work In The Theory :

The domain name space consists of a tree of domain names. Each node or branch in the tree has one or more resource records, which hold information associated with the domain name. The tree sub-divides into zones. A zone consists of a collection of connected nodes authoritatively served by an authoritative DNS nameserver. (Note that a single nameserver can host several zones.)

When a system administrator wants to let another administrator control a part of the domain name space within his or her zone of authority, he or she can delegate control to the other administrator. This splits a part of the old zone off into a new zone, which comes under the authority of the second administrator’s nameservers. The old zone becomes no longer authoritative for what goes under the authority of the new zone.

A resolver looks up the information associated with nodes. A resolver knows how to communicate with name servers by sending DNS requests, and heeding DNS responses. Resolving usually entails iterating through several name servers to find the needed information.

Some resolvers function simplistically and can only communicate with a single name server. These simple resolvers rely on a recursing name server to perform the work of finding information for them.

IPv4:

Internet Protocol version 4 is the fourth iteration of the Internet Protocol (IP) and it is the first version of the protocol to be widely deployed. IPv4 is the dominant network layer protocol on the Internet and apart from IPv6 it is the only protocol used on the Internet.

It is described in IETF RFC 791 (September 1981) which made obsolete RFC 760 (January 1980). The United States Department of Defense also standardized it as MIL-STD-1777.

IPv4 is a data-oriented protocol to be used on a packet switched internetwork (e.g., Ethernet). It is a best effort protocol in that it does not guarantee delivery. It does not make any guarantees on the correctness of the data; It may result in duplicated packets and/or packets out-of-order. These aspects are addressed by an upper layer protocol (e.g., TCP, and partly by UDP).

The entire purpose of IP is to provide unique global computer addressing to ensure that two computers communicating over the Internet can uniquely identify one another.

Addressing :

IPv4 uses 32-bit (4-byte) addresses, which limits the address space to 4,294,967,296 possible unique addresses. However, some are reserved for special purposes such as private networks (~18 million addresses) or multicast addresses (~1 million addresses). This reduces the number of addresses that can be allocated as public Internet addresses. As the number of addresses available are consumed, an IPv4 address shortage appears to be inevitable, however Network Address Translation (NAT) has significantly delayed this inevitability.

This limitation has helped stimulate the push towards IPv6, which is currently in the early stages of deployment and is currently the only contender to replace IPv4.

Allocation :

Originally, the IP address was divided into two parts:

* Network id : first octet

* Host id : last three octets

This created an upper limit of 256 networks. As the networks began to be allocated, this was soon seen to be inadequate.

To overcome this limit, different classes of network were defined, in a system which later became known as classful networking. Five classes were created (A, B, C, D, & E), three of which (A, B, & C) had different lengths for the network field. The rest of the address field in these three classes was used to identify a host on that network, which meant that each network class had a different maximum number of hosts. Thus there were a few networks with lots of host addresses and numerous networks with only a few addresses. Class D was for multicast addresses and class E was reserved.

Around 1993, these classes were replaced with a Classless Inter-Domain Routing (CIDR) scheme, and the previous scheme was dubbed “classful”, by contrast. CIDR’s primary advantage is to allow re-division of Class A, B & C networks so that smaller (or larger) blocks of addresses may be allocated to entities (such as Internet service providers, or their customers) or Local Area Networks.

The actual assignment of an address is not arbitrary. The fundamental principle of routing is that address encodes information about a device’s location within a network. This implies that an address assigned to one part of a network will not function in another part of the network. A hierarchical structure, created by CIDR and overseen by the Internet Assigned Numbers Authority (IANA) and its Regional Internet Registries (RIRs), manages the assignment of Internet address worldwide. Each RIR maintains a publicly searchable WHOIS database that provides information about IP address assignments; information from these databases plays a central role in numerous tools that attempt to locate IP addresses geographically.

IPv6:

Internet Protocol version 6 (IPv6) is a network layer protocol for packet-switched internetworks. It is designated as the successor of IPv4, the current version of the Internet Protocol, for general use on the Internet.

The main improvement brought by IPv6 is a much larger address space that allows greater flexibility in assigning addresses. While IPv6 could support 2128 (about 3.4׳1038) addresses, or approximately 5׳1028 addresses for each of the roughly 6.5 billion people[1] alive today. It was not the intention of IPv6 designers, however, to give permanent unique addresses to every individual and every computer. Rather, the extended address length eliminates the need to use network address translation to avoid address exhaustion, and also simplifies aspects of address assignment and renumbering when changing providers.

Introduction :

By the early 1990s, it was clear that the change to a classless network introduced a decade earlier was not enough to prevent IPv4 address exhaustion and that further changes to IPv4 were needed.[2] By the winter of 1992, several proposed systems were being circulated and by the fall of 1993, the IETF announced a call for white papers (RFC 1550) and the creation of the “IP, the Next Generation” (IPng Area) of working groups.[2][3]

IPng was adopted by the Internet Engineering Task Force on July 25, 1994 with the formation of several “IP Next Generation” (IPng) working groups.[2] By 1996, a series of RFCs were released defining IPv6, starting with RFC 2460. (Incidentally, IPv5 was not a successor to IPv4, but an experimental flow-oriented streaming protocol intended to support video and audio.)

It is expected that IPv4 will be supported alongside IPv6 for the foreseeable future. IPv4-only nodes (clients or servers) will not be able to communicate directly with IPv6 nodes, and will need to go through an intermediary

Features of IPv6 :

[edit] To a great extent, IPv6 is a conservative extension of IPv4. Most transport- and application-layer protocols need little or no change to work over IPv6; exceptions are applications protocols that embed network-layer addresses (such as FTP or NTPv3).

Applications, however, usually need small changes and a recompile in order to run over IPv6.

Larger address space :

The main feature of IPv6 that is driving adoption today is the larger address space: addresses in IPv6 are 128 bits long versus 32 bits in IPv4.

The larger address space avoids the potential exhaustion of the IPv4 address space without the need for network address translation (NAT) and other devices that break the end-to-end nature of Internet traffic. NAT may still be necessary in rare cases, but Internet engineers recognize that it will be difficult in IPv6 and are trying to avoid it whenever possible. It also makes administration of medium and large networks simpler, by avoiding the need for complex subnetting schemes. Subnetting will, ideally, revert to its purpose of logical segmentation of an IP network for optimal routing and access.

The drawback of the large address size is that IPv6 carries some bandwidth overhead over IPv4, which may hurt regions where bandwidth is limited (header compression can sometimes be used to alleviate this problem). IPv6 addresses are harder to memorize than IPv4 addresses, although even IPv4 addresses are much harder to memorize than Domain Name System (DNS) names. DNS protocols have been modified to support IPv6 as well as IPv4.

Stateless auto configuration of hosts :

IPv6 hosts can be configured automatically when connected to a routed IPv6 network. When first connected to a network, a host sends a link-local multicast request for its configuration parameters; if configured suitably, routers respond to such a request with a router advertisement packet that contains network-layer configuration parameters.

If IPv6 autoconfiguration is not suitable, a host can use stateful autoconfiguration (DHCPv6) or be configured manually. Stateless autoconfiguration is only suitable for hosts: routers must be configured manually or by other means

IPv6 scope :

IPv6 defines 3 unicast address scopes: global, site, and link.

Site-local addresses are non-link-local addresses that are valid within the scope of an administratively-defined site and cannot be exported beyond it.

Companion IPv6 specifications further define that only link-local addresses can be used when generating ICMP Redirect Messages [ND] and as next-hop addresses in most routing protocols.

These restrictions do imply that an IPv6 router must have a link-local next-hop address for all directly connected routes (routes for which the given router and the next-hop router share a common subnet prefix).

Links:

Find IP Info: link .ip-adress.com

Find DNS, IPv4, IPv6 : link: .iplobster.com

Find IP Address: link .myip.dk

I hardly have to tell you how important voice technologies are in today’s networks; what we all need to keep in mind to maximize our career potential is how important knowing voice is going to be tomorrow.

We’ve always got to look forward in IT, both in our work and out studies. Cisco, always the pioneer in technical certifications, now offers a Cisco Certified Voice Professional certification that is gaining a lot of attention from IT professionals looking to add to their skills and their resume.

Cisco’s CCVP track is a rigorous five-exam track that requires you to earn your CCNA (Cisco Certified Network Associate) certification before getting started. The five exams cover a myriad of topics - they’re not giving this one away! Here are the exam numbers and codes you’ll need to know to register for the exams:

642-642 Quality Of Service (QOS)

642-432 Cisco Voice Over IP (CVOICE)

642-425 IP Telephony Troubleshooting (IPTT)

642-444 Cisco IP Telephony (CIPT)

642-452 Cisco Voice Gateways (GWGK)

Many newly-minted CCNAs wonder if they should pursue this or the Security Professional certification immediately after getting their CCNA. I recommend that a new CCNA pursue and achieve the CCNP before going after these more-specialized certifications. While it is not required by Cisco, the routing and switching knowledge your will acquire on your way to the CCNP will be invaluable to your career as well as being helpful with your CCVP pursuits.

Besides, these certifications won’t be going anywhere soon. Think of how valuable you will be with a CCNP, CCVP, and CCSP!

To your success,

Chris Bryant

CCIE #12933

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CCNA and CCNP candidates hear it all the time: “Get some hands-on experience”. From my personal experience climbing the Cisco certification ladder, I can tell you firsthand that there is no learning like hands-on learning. No simulator in the world is going to give you the experience you will get cabling and configuring your own routers.

Whenever I mention this to one of my students, they always say it costs too much. The truth is, it is cheaper now to build your own CCNA and CCNP lab than it has ever been. The secret? Used routers.

The word “used” turns off a lot of people not many of us buy used computers or used servers. Cisco routers, though, are robust. I personally own a Cisco 4000 router that I use as a Frame Relay switch in my lab that I’ve had for about four years, and I’ve never had a problem with it.

The good news for current CCNA and CCNP candidates interested in building their own labs is that used Cisco equipment has never been more plentiful or cheaper. eBay is a good way to get an idea of what’s out there and what the prices are, but you don’t have to assemble your lab one piece at a time. Many eBay vendors who sell used Cisco equipment sell ready-made CCNA and CCNP labs for one price, including cables.

I asked one major vendor of CCNA and CCNP labs, .ciscokits.com, what the most common questions are regarding building your own home lab. Here’s what they had to say:

Why do I need real routers instead of a simulator?

You need a physical router,as the simulators just don’t have the ability to give you the “hands on” you need to see what happens when you disconnect a cable or put a cable in the wrong location. You will come to find quickly that mistakes you make on Router 1 are affecting Router 5 all because you did not screw in a cable properly. No simulator can simulate that.

How many routers do I need?

Two routers really are required to see if anything works. If you have a very limited budget, you can receive value from only purchasing a single router over working with a simulator. However, you will not be able to see the main thing we are trying to accomplish. The propagation of route tables!

The only way you can see if your configurations work, is to have at least two routers. Therefore, I strongly recommend that you purchase a dual router kit that comes with all the accessories you need. Otherwise you can spend days trying to find all the little extra pieces you need to get your lab up and running.

Do I need a switch?

Well, it is nice to have. However, with only about 2 questions on the test dedicated to “hands on” switch knowledge, if you have to skimp on something, skimp on the switch.

What routers and switches should I buy?

Choices, choices, choices! Which 2500/2600 router do I pick? I will list some pros and cons of each router below, along with current prices (note that prices are generally lower if you buy a dual router kit instead of a single router). Please note that prices are approximations.

1) Cisco 2501 Router with 16 MB Flash/16MB DRAM $94.99. The cheapest introduction router, and it can support a vast majority of the commands that you will need to learn for your CCNA test. All 2500 routers that we will discuss come with a minimum of two serial ports and an Ethernet port.

You will need to add a transceiver to this unit to convert the Ethernet AUI port to an RJ-45 style Ethernet port.

2) Cisco 2503 Router with 16 MB Flash/16MB DRAM $119.99. This is the same as a Cisco 2501, except it adds an ISDN port so you can complete all your ISDN commands for the CCNA test. You will need to add a transceiver to convert the Ethernet AUI port to an RJ-45 style Ethernet port.

3) Cisco 2505/2507 with 16 MB Flash/16MB DRAM $109.99. The same as a Cisco 2501 except it has a built-in 8 or 16 port hub so you do not have to purchase a transceiver.

4) Cisco 2514 Router with 16 MB Flash/16MB DRAM $149.99. This router is the same as a Cisco 2501 except instead of one Ethernet port you have two. You may ask, what is the big deal? Well, you can use this as your Cable Modem/DSL Modem router. Now you can test your ability to setup a firewall and router in a live environment on the Internet. Lots of fun! You will need to add two transceivers to convert the Ethernet AUI ports to an RJ-45 style Ethernet ports.

5) Cisco 2520 Router with 16 MB Flash/16MB DRAM $119.99. This is the same as a 2503 but it also adds two more serial ports so you can use this as a frame relay switch later in your CCNA studies. It costs the same as a 2503, so this is a great money saving tip.

6) Cisco 2612 Router with 32 DRAM and 8 MB Flash $199.99. This is a modular router unlike any of the 2500 series routers. So the big benefit of this is you can buy extra modules to add functionality such as more serial ports, ISDN ports, Ethernet ports, WICs and such. However, due to the flexibility you will pay a bit more. One day it is a frame relay switch, the next it is your ISDN router. In the long run it will be cheaper than purchasing a bunch of dedicated routers for each

discipline you want to learn.

7) Cisco 1912 or 1924 Switch with Enterprise Software $109.99. This is a good low cost switch. The only drawback is it is a 10 MB switch except for the two 100 MB uplink ports. Not a big deal since you have 10 MB routers.

Cisco 2912 or 2924 Switch with Enterprise Software $249.99. This switch will run all the current commands needed for the test and is a full 100 MB switch.

And should you desire to sell your lab after you complete your certification, you can either negotiate a price with the vendor who sold it to you, or you can sell it yourself on ebay. It’s my experience that 95% of candidates who earn their CCNA go on to pursue their CCNP within one year, though, so don’t sell it too quickly.

In the end, you spend only a few hundred dollars, and you gain invaluable experience and knowledge that will help you both in your certification quest and your job performance. Having worked my way from the CCNA to the CCIE, I can tell you that you will learn much more from actually configuring and cabling your own equipment than you ever will from any simulation of the real thing.