Some of the makers of action games make great animations and may include a story line. Stories always attract us. Tell a story and everybody will listen. The action games on computers use this very well to produce games that can take your breath away thinking of the imagination and artistry applied by the maker.

Adventures, space fights, planes colliding in mid air, think of any action and you will find it used in a game. Most of these games are free online. Action games give great thrill and despite called for teenagers they are for the family to enjoy them together. Action games test the response of the player and sharpen the judgment. Such games are not pure fun. They can help as training tools if used properly.

Other free online games that are currently becoming very popular are- Arcade Games, Board Games, Card Games, Casino Games, Strategy Games, Sports Games, Shooting Games and, Puzzle Games. Most of the online games are free. Look for a good website and play the games. They are a fabulous way of enjoyment. As I said in the heading these games can become addictive. Take small doses and life will be a joy.

Sooner or later your company could become the victim of a natural disaster, or something much more common like a lightning storm or downed power lines.

Just because your company may be a small business doesn’t mean it’s immune to data disasters. If a small business does not have a good and tested disaster recovery plan in place when disaster hits they may never fully recuperate and it may even cause them to go out of business. Sometimes even a data recovery service is unable to be of any help.

Following are some questions that should be answered in order to give you some idea of what you need to do to that will help you if you do have a data disaster situation.

Do you know where your company’s most important data files are located?

Are these files being backed up and by what means?

How often do you run these data backups and are they verified and tested?

Do you have automated controls that correctly and on a consistent basis do the backups?

Do your data backup tapes go off-site and how often?

Do you have some kind of security against tampering or theft of your data backups?

Do you keep your servers, routers, hubs, and phone system controllers in locked areas to keep them more secure?

Does just anyone have access to your servers and your other technology assets or do you limit access to at least two, but no more than four people?

Do you run a locally securable operating system, such as Microsoft Windows 2000 Professional, Microsoft Windows XP, or Microsoft Windows NT Workstation 4,on the company’s desktop PCs and notebooks?

Do you have any confidential data stored locally on any desktop PCs or notebooks? Are any of these systems running an inherently in-secure operating system, such as Microsoft Windows 9x or Microsoft Windows Me?

Do you prevent unauthorized boot-ups or tampering with BIOS configuration settings by using power-on passwords?

On your desktop PCs and notebooks, how are main updates, service packs and releases kept current?

The bottom line is that you can’t plan when a data disaster may strike but taking a few steps beforehand may help with your company’s survival in the days and weeks following a disaster.

O E2 5.1.1.1 [110/20] via 172.34.34.3, 00:33:21, Ethernet0

6.0.0.0/32 is subnetted, 1 subnets

O E2 6.1.1.1 [110/20] via 172.34.34.3, 00:33:21, Ethernet0

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

O E2 172.12.21.0/30 [110/20] via 172.34.34.3, 00:33:32,
Ethernet0

O E2 7.1.1.1 [110/20] via 172.34.34.3, 00:33:21, Ethernet0

15.0.0.0/24 is subnetted, 1 subnets

O E2 15.1.1.0 [110/20] via 172.34.34.3, 00:33:32, Ethernet0

E2 is the default route type for routes learned via redistribution. The key with E2 routes is that the cost of these routes reflects only the cost of the path from the ASBR to the final destination; the cost of the path from R4 to R1 is not reflected in this cost. (Remember that OSPF’s metric for a path is referred to as “cost”.)
In this example, we want the cost of the routes to reflect the entire path, not just the path between the ASBR and the destination network. To do so, the routes must be redistributed into OSPF as E1 routes on the ASBR, as shown here.
R1#conf t

Enter configuration commands, one per line. End with CNTL/Z.

R1(config)#router ospf 1

R1(config-router)#redistribute rip subnets metric-type 1

Now on R4, the routes appear as E1 routes and have a larger metric, since the entire path cost is now reflected in the routing table.
O E1 5.1.1.1 [110/94] via 172.34.34.3, 00:33:21, Ethernet0

6.0.0.0/32 is subnetted, 1 subnets

O E1 6.1.1.1 [110/100] via 172.34.34.3, 00:33:21, Ethernet0

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

O E1 172.12.21.0/30 [110/94] via 172.34.34.3, 00:33:32, Ethernet0

O E1 7.1.1.1 [110/94] via 172.34.34.3, 00:33:21, Ethernet0

15.0.0.0/24 is subnetted, 1 subnets

O E1 15.1.1.0 [110/94] via 172.34.34.3, 00:33:32, Ethernet0

Knowing the difference between E1 and E2 routes is vital for CCNP exam success, as well as fully understanding a production router’s routing table. Good luck in your studies!

Trying to explain how an antenna works in simple English is not an easy task as there are a lot of technical specifications that need to be explained. But a general understanding is possible without getting into tech speak that would make Einstein cringe.

In order for an antenna to work it has to radiate. Your antenna, whether TV or radio has what is called free electrons running through it. It is these free electrons that vibrate. The question becomes, how do these free electrons vibrate and what causes them to vibrate?

Well, in real life it takes an electric field to move an electron. If you take an isolated straight dipole, the power comes from the combined fields of all the charged particles, both positive and negative, in the antenna. We’ll call this field the antenna’s coulomb field.

In addition to this field, the antenna exhibits a magnetic field that is the sum of the magnetic fields of all the free moving electrons. The antenna also has a dynamic electric field that is the vector sum of the dynamic electric fields of all the free electrons. What we can do is separate the electric field of the antenna at any point in space into two components. One of the components will be in phase with the total magnetic field and the other will be 90 degrees out of phase. The in-phase component is the radiation field of the antenna and the out of phase component is the induction field. At the antenna, both fields are parallel to the metal surface.

What happens is that the coulomb field and the induction field fall off much more quickly than the radiation field as the distance increases from the antenna. When you reach distances greater than a few wavelengths from the antenna, you have what is called the antenna’s far field. This field is pure radiation. As you get closer to the antenna you have what is called the antenna’s near field. This field is a mixture of radiation, coulomb, and induction fields. Still with us? Great, we’re getting to the good part.

What ultimately happens with all these fields that makes it so that your TV or radio picks up signals through your antenna is this. The free electrons moving through your antenna are moving at their maximum speed. The right hand half of your antenna accumulates electrons. The left hand half of your antenna is where the electrons depart and leave an excess of charged ions. The coulomb field produces an imbalance and opposes the electrons’ rightward motion. The electrons then stop, coast for a bit and then head back towards the left. After they reach maximum speed they then stop and process is repeated, now heading back to the right. The result is a vibration of free electrons that heats the metal and in turn generates electromagnetic waves.

And that, in as simple English as possible, is how your antenna works.