How to Work from Home and Actually be Productive

More companies are realising that allowing their employees to work from home can benefit productivity, save money on office space and parking, reduce absenteeism, and improve morale. If you aspire to become a telecommuter (full- or part-time), learn how you can make working from home work well for you.

 

Break Free from Your Cubicle

One of the biggest advantages to working from home is saving time and eliminating stress. Even if you telecommute only a few days a week, that’s less time you’ll have to spend travelling back and forth, less time in traffic or sitting on a crowded train. Instead, going to the “office” will simply mean rolling out of bed and walking to another room.

Stay Away from the Fridge, the TV, and the Kids

Working from home requires discipline, so don’t create your own distractions. Dedicate a space solely for work, and make sure it’s comfortable, quiet, and clutter-free. Structure your time and take breaks when you need them. If there are children in your house, try to find a space where you can work with the door shut. It might be wise to pack a lunch for yourself each morning, as if you were going to the office. This will help limit mindless snacking during the day. (It also means that you won’t have to stop in the middle of the day to make lunch.) Finally, assess whether you work better with music or without, and plan accordingly.

Get the Tools to Get the Job Done

When it’s time to get down to business, your home office should be equipped with everything you need to be productive. Invest in the right tools, and you’ll get more accomplished in less time.

For instance, a notebook computer gives you the freedom to move from room to room, while Wi-Fi keeps you online wherever you go. A fast processor allows you to run multiple applications with ease, and a roomy keyboard with a comfortable keypad makes typing all day long a breeze. Be sure to have a good lamp and an ergonomic chair, too.

If you’re working on a desktop computer, you might consider replacing your old CRT with an ultra-thin LCD-LED monitor, such as the widescreen Samsung EX2220. It saves space, produces high-quality images, and reduces eye strain. These monitors also use up to 40 percent less power than conventional CRTs, and because they generate less heat, you might save on air conditioning costs as well!

Ideas for Small Spaces

If you’re tight on space, many printers boast compact design yet still deliver essential features, including fast print speed and large paper capacity. If you choose a wireless printer, you can place it almost anywhere in your home. That’s especially helpful if your home office is small, or if you have to share a network with anyone else in your household. Multifunction printers, which can copy, scan and fax, are another space-saving idea.

Smartphones can serve as personal assistants at home, keeping you organised and on track to meet your deadlines. A Samsung Jack with Windows Mobile™ 6.1 lets you access the full Microsoft Office Mobile Suite, so all your appointments and business documents are available at any time. And multiple messaging with Wi-Fi allows you to SMS, MMS, Instant Message, email and video message at high speed, helping you stay connected, no matter where you are.

Protect your phone and yourself

With so much of our lives now existing on our mobile phones, it is essential that we take the necessary steps to protect our privacy. Modern mobile phones are now incorporating innovative security features such as the Mobile Tracker, Fake Call and the Listen-in application to keep you, your content and your phone as safe as possible. 

 

• Print-friendly

One of the real problems of having so much of our lives existing on our mobile phones is that losing a mobile phone, whether it is stolen or simply misplaced, is a real hassle. And it isn’t just the money and time involved in replacing it that’s annoying, it is also an invasion of our privacy. Luckily, help is at hand.

The Mobile Tracker feature found on mobile phones is one of many features that help increase the chances of recovering a lost or stolen phone. Basically, when a new SIM card is used by your phone it automatically generates and sends a message to a pre-designated number with the new SIM card’s mobile phone number. This helps in tracing the new SIM and your mobile phone, which can be a powerful deterrent against thieves.

Other helpful security features include the Fake Call and the Listen-in application. Both are initiated by a double tap button, the Fake Call (as you may guess from the name) makes your mobile phone ring as though someone were calling it. This can be an extremely helpful tool when unsure about your surrounding or just when you wish to avoid a particular person. There are numerous occasions and situations when this feature can lend a hand.

Then there is the Listen-in application. This allows for a pre-designated person to listen-in on your phone calls. This is a very powerful tool. This also works by double-tapping a button during a phone call; at this point your phone will ring another phone unbeknownst to the person you originally called. Like most security features, this is not something you will use often but might it be the difference one day.

And finally, when talking about mobile phone security, being prepared is always the best defence against unfortunate situations. Memory cards, such as Micro SD cards found in the Samsung Tocco and Monte phones, ensure that all your important information is backed up. So, even if you do have your phone stolen or just leave it on a bus seat, all your content, from pictures to email addresses, are kept safe and secure. They really are a must-have accessory for any modern lifestyle.

Handy hints in capturing and protecting your memories

Remembering to bring the camcorder and have it fully charged is just the beginning of capturing and preserving important memories. You really want to look back on important moments in your life and see them as they were, and to do this you will need to practice using a combination of filming techniques and the latest advancements in recording technology.

 

Capture true-to-life images

Nothing can replace quality visuals. From colour reproduction to clarity, they let us relive moments as they really happened and let us connect with them in a much deeper way. For this reason, it is essential that you record using the latest technology like the BSI (Back-side illuminated) CMOS Sensor.

It ensures that images are benefitting from the optimal amount of colour intake. Previous technology, such as the Front-side Illuminated CMOS sensors, captured images with an inferior set-up; a certain amount of colour and light was blocked by the internal wires from being received on the ‘light-receiving’ surface. This failing was overcome with BSI CMOS Sensor, and now the images you capture are true-to-life and exactly as you remembered them.

One of the other benefits of filming with the help of the BSI CMOS Sensor is that it makes filming in the dark more effective. With the improved structure of the sensor, the camera now requires less light to pick up colours, and the results are noticeably better. From shadows to poorly lit rooms, you will enjoy enhanced visuals with richer colours that may have not previously been captured.

So, the benefits of BSI CMOS are quite clear, but they still rely on you capturing decent footage. So, here are a few filming techniques that will hopefully help you capture the best possible footage.

Filming techniques

A few basic filming techniques can ensure that you get more from every frame. There usually isn’t an endless supply of memory, so it is important that you make the most of what you have.

Plan the Shoot

Before you turn the camcorder on, think through what you are trying to achieve. Who will be watching the footage? What will they want to see?

Clean the Lens

Get into the habit of checking your lens for water spots or dust, as this will avoid hours of ruined footage.

Zoom

Try to avoid using the zoom on your camcorder. You are far more likely to see the camera shake when you are heavily zoomed on a particular point. Use the zoom facility between shots to compose your picture.

Frame your shots

Be sure to frame your subject properly. This involves moving closer for good proportions, and don't be afraid to place the subject slightly off-centre to give context.

Hold your shots

A common mistake is to stop recording too soon. Try holding your shot for an extra three seconds. This will allow plenty of time for any post-production. You may insert scene transitions.

Filing system

There is no point in filing anything if you’re not going to save it properly. A good storage system, like an external hard drive, not only ensures that your footage is ordered and secure but makes it easier to access. Often our precious memories remain unwatched because people don’t know where to start looking.

Pack the Tools You Need for Successful Business Travel

Business travel can be stressful. Take the pressure of a big meeting and multiply it by the hassle of travel, and it’s easy to lose your cool. But if you take the time to prepare, and arm yourself with the right tools, you’ll come off looking like a pro. Make a great business impression by following these simple tips.

 

Your Most Important Bag: Your Briefcase

• Bring plenty of business cards—more than you think you’ll need. If the meeting goes well, you may end up with introductions to higher-ups you weren’t even expecting to meet.


• Consider an Optical Disk Drive so you can burn discs on the fly. That way you can update your proposal based on meeting feedback and give clients a revised budget spreadsheet, all before you leave the building. You can also give clients a copy of your presentation to remind them of your key points. Many of today’s super-light notebook computers don’t have a built-in DVD writer, so a sleek peripheral is the way to go. Compatible with both Mac and PCs and available in seven colours, Samsung ODDs integrate seamlessly with your work laptop.


• Bring a new pack of blank DVD-Rs—again, more than you think you’ll need. Once they see how quick and easy it is for you to burn discs, meeting attendees may request additional copies to circulate among colleagues.

Pack Smart to Make a Great First Impression

• Stock your toiletries bag with a complete miniature set of your must-have products, including a designated travel toothbrush. Not only will you get through airport security with less hassle, you won’t have to unpack them when you get home. If your favourite hair product doesn’t come in a trial size, grab a set of inexpensive plastic containers at a drugstore.


• Since your new toiletries set complies with carryon requirements for liquids, you can keep it with you on the plane. Just prior to landing, head to the lavatory to splash some water on your face, use eye drops, and give your teeth a quick brushing.


• Though travelling in sweatpants is best left to the leisure travel set, you still may still want to bring a fresh set of clothes for your arrival. Even if it’s just a neatly folded shirt or blouse to change into in the airport bathroom, you’ll arrive at your meeting looking fresh and wrinkle-free.


• Planning to rent a car? If you have a portable GPS unit or GPS-enabled phone, pre-program your hotel and meeting locations so you’ll arrive stress-free at your destinations.


• Focus on packing light. For instance, two meetings in two cities in two days only require one suit. If you can limit yourself to a single carryon bag, you’ll save time, avoid baggage-check fees, and produce a smaller carbon footprint.

Prepare Yourself for the Main Event

• Spend some time on the plane reviewing the list of potential meeting attendees. They’ll be impressed when you’re able to effortlessly bring their titles and affiliations into the conversation.


• If your travel schedule allows, try to arrive 15 minutes early. Taking a little time to sit quietly after a long morning of travel can do wonders for frayed nerves.


• Just outside the door, remind yourself to stand up straight, take a deep breath, and focus on your goals for the meeting. Then go for it.

Capture an Unforgettable Group Photo

Group photos get taken at some of the most exciting times in life: major family events, sports championships, school graduations. So why are they often some of the most boring pictures found in a photo album? A few easy tips and the right camera can help take your group photos from unremarkable to unforgettable

 

• Print-friendly

A group photo shouldn’t look like a police lineup. It can (and should!) show the personality of the group: the closeness of a family, the camaraderie of a sports team, or the chemistry among a rock band. Choose a camera that helps you get the perfect shot in any conditions. Samsung NX cameras, for example, combine the lightweight body of a compact with many features of a full-size SLR, including interchangeable lenses.

Keep Focus

Group photos can be difficult for an amateur photographer, simply because there are so many points of focus—that is, faces—to capture. Use the NX’s Face Detection mode to perfectly focus and expose up to 10 faces in a single photo.

Remember to Have Fun

You’ll get better results every time if you can make a group of people smile than if you have to tell them to smile. Make some fun props available to help people loosen up: funny hats, feather boas, mustaches-on-a-stick. And promise the children that if they behave themselves for the family photo, you’ll take a few "silly" shots afterward where they can pull funny faces or jump in the air. You never know—one of those shots may turn out to be the keeper!

Get In on the Action

Sometimes—especially in family photos—the photographer also belongs in the picture. Certain NX models (like the NX200) have a programmable self-timer that can be set to fire the shutter after any interval between 2 and 30 seconds, allowing for greater flexibility than cameras with only a few preset choices. Decide beforehand where you belong in the lineup so you’re not rushing to squeeze into the arrangement.

Set the Scene

Select from different Scene modes to choose the one that best matches your setting. For instance, choose Beach to mitigate the effects of bright sunlight reflecting off sand, which might otherwise cause underexposure. Also consider adding a polarizing filter to increase colour saturation and to remove reflections from shiny surfaces such as water.

Light It Up

If you have a choice, take your photo in the morning or late afternoon when sunlight is softer and less direct. If you do have to shoot during midday, try a few shots with the flash turned on, even if you’re outside, as it can help tone down harsh shadows and increase colour saturation.

Finish Smart

Use Smart Filters to add creative effects after the shoot. Turn your photo into a sketch, add moody lighting, or give it a goofy fisheye effect.

Group Photo Wrangling

Trying to capture a group of squirmy children? Use your camera’s Burst Mode to capture up to 30 photos per second—odds are that at least one of the photos will capture the entire crew at their best.

Creative Arrangements

When posing your subjects, don’t just line them up. Arrange them at different levels and heights. Use a tree or stone wall if outdoors, or the back of a sofa or the stairs if at home. Even something as simple as different heights of seating can help. Use a mix of low chairs, bar stools, and standing.

Rise Above

If there’s a safe spot to elevate yourself (a stepladder, a jungle gym, the back of a truck), a vantage point looking down on your photo subjects can be an interesting angle, especially for big groups—more faces, fewer bodies. As a bonus, having your subjects looking up will minimise any double chins in the group.

Catch the Outtakes

Take candid photos and even shoot HD movies with the NX’s video feature while the group is gathering, arranging, and then breaking up. Children especially can be at their most charming when they think the camera isn’t looking.

Don’t miss capturing a once-in-a-lifetime group photo because of a lack of ideas or camera features. With a little inspiration and the right equipment, it’s easy to make a memory that no one in the group will ever forget.

Point and Shoot or Interchangeable Lens?

When deciding which type of camera is best for you, it’s no longer necessary to decide which camera is “good”. Advanced optical technology has ensured that all digital cameras will take great photos, and then some.

 

In Pursuit of Perfect Pictures

Consider what you'll be shooting (for instance, family vs. sports), the purpose of the pictures (website postings vs. printed photographs), and so on. Then ask yourself, what fits your lifestyle and how creative do you want to be? Can I carry a larger camera with lenses around or do I need to keep it simple? Do I want or need to override the camera’s exposure settings?

Point and Shoot: Versatile, Easy to Use, Fits in Your Pocket

If sheer ease of use is what you're seeking, then point-and-shoot cameras are models of simplicity. Point and shoots are ideal for the absolute beginner, or for the amateur who wants to take casual party pictures. A good point-and-shoot camera will offer a decent zoom for close-ups and have similar capabilities to an interchangeable lens camera— like manual override of a few settings that affect the image quality. But if you're looking to take quick, quality pictures, these cameras will be just fine.

Yet point and shoot cameras can also appeal to experts as well—those who like to capture "the decisive moment." Because it's an agile, easily portable camera, with no need for elaborate technical adjustments or additional equipment, even world-class photographers keep a point-and-shoot camera handy for when they require a "lean and mean" approach to photo-taking.

Point and Shoot: Dual LCD Screens

The innovative DualView Camera is designed for self portraits and couple shots. It gets you out from behind the camera and into the picture. This camera has two screens that help you frame up shots—a 1.5" front LCD screen for self portraits and a rear LCD touch screen with easy access your photo library.

In addition to having two screens, the DualView ST600 has a 27mm wide angle lens. The 5x optical zoom gives you a wider shooting range from a shorter distance so you get more of your subject in the image and have greater flexibility than most cameras with a built-in zoom.

Point and Shoot: Wireless

The SH100 with its jumbo 14.2 megapixel sensor is Wi-Fi capability, allowing you to email and post pictures directly from Wi-Fi hotspots. Upload directly onto Facebook, Picasa or YouTube at the touch of a button and share your moments with friends and family almost instantly. Have easy access to your smartphone too using the SH100’s Remote Viewfinder functionality, enabling remote previews and control of zoom, flash, resolution and more.

Point and Shoot: Long Zoom

Long optical zoom cameras allow you to focus in on your target with precision and maximum pixels. With a shorter zoom, you are forced to crop later, which is time-consuming and crops precious pixels out of the image.

Interchangeable Lens

The NX System is designed to be like a traditional DSLR i.e. allowing interchangeable lenses, but is engineered to be compact through the elimination of a traditional optical viewfinder and mirror box.

Large Apertures

A quality lens should let you shoot at larger apertures to allow more light in needed to freeze a scene while providing little distortion. Do you tend to shoot in low light or need edge to edge sharpness, then look at a lens with a large aperture (FStop) such as the 30mm NX Pancake Lens. Lenses such as these that also use an aspherical element in its optical design, improve sharpness and keep distortion at a minimum.

Telephoto Zoom

Point and Shoot or Interchangeable Lens

Shooting sports outdoors and need to be close? A telephoto zoom lens such as The T50200IB 50-200mm gives the versatility to pull back for images such as portraits, but zoom into the field to capture the action. This lens also incorporates ED glass in its optical design minimising colour distortion typical in telephoto lenses.

In addition, shooting modes that permit the manual choice of shutter speeds (Shutter Priority AE) or aperture (Aperture Priority AE) unleash your creativity by allowing you to choose how movement is captured and the range of focus within your scene. Just like a Point and Shoot however, you can also shoot in Auto for ease of use.

Memory and Sharing

When shopping for cameras, make sure that your camera uses a standard memory size such as SD or MicroSD (like SD, but smaller). Some cameras use proprietary memory card formats, which will be harder to find and more costly to purchase. There are multiple ways to clear memory and transport photos: move the SD card from the camera to a computer or printer; use cables to connect the camera to the computer directly; or ideally, use Wi-Fi to send images to your computer or email directly to friends and family.

Good luck with your purchase!

Get Better Sports Photos With the Right Camera

Action shots put your camera—and your photography skills—to the test. Capturing fast action requires carefully chosen equipment, plenty of practice, and sometimes a little luck. Here are some tips for getting better results, whether you’re a rookie photographer or a seasoned pro.

Your phone’s camera might be fine for casual shots of friends, but ever try using it to capture your son’s game-winning goal? That red blur at the edge of the shot may or may not be him. Whether you choose a powerful-yet-simple SMART camera or the sophisticated NX series, Samsung cameras make it easy to capture all the excitement of sporting events.


Match Your Camera to Your Skills and Needs




You won’t get great sports photos if your camera is too complicated for your current abilities—or if it can’t produce the level of detail you want. Choose the right type of camera by considering how close you want to get and how detailed you want your images to be.



Clear close-ups. Any modern camera can get you closer to the action. But the ability to zoom in doesn’t mean much if it results in blurry motion shots. Samsung’s capable but simple WB150F SMART camera has an 18x optical zoom that can get you much closer to the action without sacrificing image quality. It’s perfect if you’re sitting rinkside and want to catch the smile on your ice-skating daughter’s face for your Facebook page.


Power zoom. The WB850F SMART camera is even more powerful, taking you from the cheap seats to the heart of the action. The camera is easy to use, but its 21x optical zoom and 16.2-megapixel CMOS sensor bring intimate details dramatically close. Now you can capture that fall-away jumper at the opposite end of the court.


Pinpoint accuracy. For the highest level of quality, the NX camera system uses interchangeable lenses, letting you choose the level of closeness you want. A 50-200mm telephoto lens, for example, lets you choose from a wide range of focal lengths for the highest-quality close-up shots. Capture not just the action, but also the nuances of emotion on your favorite player’s face. The NX system also provides the fastest shutter speeds, enabling you to take rapid-fire shots and capture even the hardest slap shot.


Video options. Sometimes a still photo doesn’t tell the full story. Many of today’s best still cameras also offer a high-quality video option. The Samsung WB850F and NX cameras record Full HD video, while the WB150F shoots 720p HD. And now you don’t have to choose between video and still shots. The Dual Capture feature of the WB850F lets you snap 10-megapixel still pictures even while recording Full HD video, so you don’t have to sacrifice your scrapbook memories when you’re shooting live action.
Elevate Your Game

As with any sport, the perfect equipment won’t turn you into a star performer overnight. Here are three fundamental tips to help you step up your game.




Location matters. If you’re not an expert, it’s difficult to capture the essence of an event from afar. The better you can see what you’re shooting with the naked eye, the more control you’ll have over the composition of your shots. That’s true even if you have a powerful zoom like the WB850F’s or an advanced telephoto lens. So make sure you’re as close to the action as you can be (short of walking onto the field, of course).


Know the game. When you can anticipate who’s getting the ball next, you’ll have a much better chance of zeroing in on a key moment. If you don’t know the teams or the rules of the game, you may have a hard time staying a step ahead of the action. Familiarise yourself with the sport and, if possible, the players.


Practice, practice, practice. As with free throws or a topspin backhand, there’s no substitute for repetition. Don’t worry about the quality of every shot: Samsung cameras have plenty of storage space. Wi-Fi capabilities and the Auto Backup feature enable the WB150F and WB850F to automatically store copies of your shots to a hard drive or to the cloud. The NX20 also has Wi-Fi for easy backup of your best shots, wherever you are.


After you’ve chosen the right equipment and started taking lots of action shots, you might find yourself discouraged by your initial results. That’s the point at which many would-be sports photographers throw in the towel. But if you’re patient with yourself and keep practicing, you’ll soon be turning split seconds into lasting memories.

How Does the Internet Work?

Introduction

How does the Internet work? Good question! The Internet's growth has become explosive and it seems impossible to escape the bombardment of www.com's seen constantly on television, heard on radio, and seen in magazines. Because the Internet has become such a large part of our lives, a good understanding is needed to use this new tool most effectively.

This whitepaper explains the underlying infrastructure and technologies that make the Internet work. It does not go into great depth, but covers enough of each area to give a basic understanding of the concepts involved. For any unanswered questions, a list of resources is provided at the end of the paper. Any comments, suggestions, questions, etc. are encouraged and may be directed to the author at the email address given above.

Where to Begin? Internet Addresses

Because the Internet is a global network of computers each computer connected to the Internet must have a unique address. Internet addresses are in the form nnn.nnn.nnn.nnn where nnn must be a number from 0 - 255. This address is known as an IP address. (IP stands for Internet Protocol; more on this later.)

The picture below illustrates two computers connected to the Internet; your computer with IP address 1.2.3.4 and another computer with IP address 5.6.7.8. The Internet is represented as an abstract object in-between. (As this paper progresses, the Internet portion of Diagram 1 will be explained and redrawn several times as the details of the Internet are exposed.)

Diagram 1

 

If you connect to the Internet through an Internet Service Provider (ISP), you are usually assigned a temporary IP address for the duration of your dial-in session. If you connect to the Internet from a local area network (LAN) your computer might have a permanent IP address or it might obtain a temporary one from a DHCP (Dynamic Host Configuration Protocol) server. In any case, if you are connected to the Internet, your computer has a unique IP address.

Check It Out - The Ping Program

If you're using Microsoft Windows or a flavor of Unix and have a connection to the Internet, there is a handy program to see if a computer on the Internet is alive. It's called ping, probably after the sound made by older submarine sonar systems.1 If you are using Windows, start a command prompt window. If you're using a flavor of Unix, get to a command prompt. Type ping www.yahoo.com. The ping program will send a 'ping' (actually an ICMP (Internet Control Message Protocol) echo request message) to the named computer. The pinged computer will respond with a reply. The ping program will count the time expired until the reply comes back (if it does). Also, if you enter a domain name (i.e. www.yahoo.com) instead of an IP address, ping will resolve the domain name and display the computer's IP address. More on domain names and address resolution later.

Protocol Stacks and Packets

So your computer is connected to the Internet and has a unique address. How does it 'talk' to other computers connected to the Internet? An example should serve here: Let's say your IP address is 1.2.3.4 and you want to send a message to the computer 5.6.7.8. The message you want to send is "Hello computer 5.6.7.8!". Obviously, the message must be transmitted over whatever kind of wire connects your computer to the Internet. Let's say you've dialed into your ISP from home and the message must be transmitted over the phone line. Therefore the message must be translated from alphabetic text into electronic signals, transmitted over the Internet, then translated back into alphabetic text. How is this accomplished? Through the use of a protocol stack. Every computer needs one to communicate on the Internet and it is usually built into the computer's operating system (i.e. Windows, Unix, etc.). The protocol stack used on the Internet is referred to as the TCP/IP protocol stack because of the two major communication protocols used. The TCP/IP stack looks like this: 

Protocol Layer	Comments
Application Protocols Layer	Protocols specific to applications such as WWW, e-mail, FTP, etc.
Transmission Control Protocol Layer	TCP directs packets to a specific application on a computer using a port number.
Internet Protocol Layer	IP directs packets to a specific computer using an IP address.
Hardware Layer	Converts binary packet data to network signals and back. (E.g. ethernet network card, modem for phone lines, etc.)

If we were to follow the path that the message "Hello computer 5.6.7.8!" took from our computer to the computer with IP address 5.6.7.8, it would happen something like this: 

Diagram 2

 

1. The message would start at the top of the protocol stack on your computer and work it's way downward.
2. If the message to be sent is long, each stack layer that the message passes through may break the message up into smaller chunks of data. This is because data sent over the Internet (and most computer networks) are sent in manageable chunks. On the Internet, these chunks of data are known as packets.
3. The packets would go through the Application Layer and continue to the TCP layer. Each packet is assigned a port number. Ports will be explained later, but suffice to say that many programs may be using the TCP/IP stack and sending messages. We need to know which program on the destination computer needs to receive the message because it will be listening on a specific port.
4. After going through the TCP layer, the packets proceed to the IP layer. This is where each packet receives it's destination address, 5.6.7.8.
5. Now that our message packets have a port number and an IP address, they are ready to be sent over the Internet. The hardware layer takes care of turning our packets containing the alphabetic text of our message into electronic signals and transmitting them over the phone line.
6. On the other end of the phone line your ISP has a direct connection to the Internet. The ISPs routerexamines the destination address in each packet and determines where to send it. Often, the packet's next stop is another router. More on routers and Internet infrastructure later.
7. Eventually, the packets reach computer 5.6.7.8. Here, the packets start at the bottom of the destination computer's TCP/IP stack and work upwards.
8. As the packets go upwards through the stack, all routing data that the sending computer's stack added (such as IP address and port number) is stripped from the packets.
9. When the data reaches the top of the stack, the packets have been re-assembled into their original form, "Hello computer 5.6.7.8!"

Networking Infrastructure

So now you know how packets travel from one computer to another over the Internet. But what's in-between? What actually makes up the Internet? Let's look at another diagram: 

Diagram 3

 

Here we see Diagram 1 redrawn with more detail. The physical connection through the phone network to the Internet Service Provider might have been easy to guess, but beyond that might bear some explanation.

The ISP maintains a pool of modems for their dial-in customers. This is managed by some form of computer (usually a dedicated one) which controls data flow from the modem pool to a backbone or dedicated line router. This setup may be referred to as a port server, as it 'serves' access to the network. Billing and usage information is usually collected here as well.

After your packets traverse the phone network and your ISP's local equipment, they are routed onto the ISP's backbone or a backbone the ISP buys bandwidth from. From here the packets will usually journey through several routers and over several backbones, dedicated lines, and other networks until they find their destination, the computer with address 5.6.7.8. But wouldn't it would be nice if we knew the exact route our packets were taking over the Internet? As it turns out, there is a way...

Check It Out - The Traceroute Program

If you're using Microsoft Windows or a flavor of Unix and have a connection to the Internet, here is another handy Internet program. This one is called traceroute and it shows the path your packets are taking to a given Internet destination. Like ping, you must use traceroute from a command prompt. In Windows, use tracert www.yahoo.com. From a Unix prompt, typetraceroute www.yahoo.com. Like ping, you may also enter IP addresses instead of domain names. Traceroute will print out a list of all the routers, computers, and any other Internet entities that your packets must travel through to get to their destination.

If you use traceroute, you'll notice that your packets must travel through many things to get to their destination. Most have long names such as sjc2-core1-h2-0-0.atlas.digex.net and fddi0-0.br4.SJC.globalcenter.net. These are Internet routers that decide where to send your packets. Several routers are shown in Diagram 3, but only a few. Diagram 3 is meant to show a simple network structure. The Internet is much more complex.

Internet Infrastructure

The Internet backbone is made up of many large networks which interconnect with each other. These large networks are known as Network Service Providers or NSPs. Some of the large NSPs are UUNet, CerfNet, IBM, BBN Planet, SprintNet, PSINet, as well as others. These networks peer with each other to exchange packet traffic. Each NSP is required to connect to three Network Access Points or NAPs. At the NAPs, packet traffic may jump from one NSP's backbone to another NSP's backbone. NSPs also interconnect at Metropolitan Area Exchanges or MAEs. MAEs serve the same purpose as the NAPs but are privately owned. NAPs were the original Internet interconnect points. Both NAPs and MAEs are referred to as Internet Exchange Points or IXs. NSPs also sell bandwidth to smaller networks, such as ISPs and smaller bandwidth providers. Below is a picture showing this hierarchical infrastructure. 

Diagram 4

 

This is not a true representation of an actual piece of the Internet. Diagram 4 is only meant to demonstrate how the NSPs could interconnect with each other and smaller ISPs. None of the physical network components are shown in Diagram 4 as they are in Diagram 3. This is because a single NSP's backbone infrastructure is a complex drawing by itself. Most NSPs publish maps of their network infrastructure on their web sites and can be found easily. To draw an actual map of the Internet would be nearly impossible due to it's size, complexity, and ever changing structure.

The Internet Routing Hierarchy

So how do packets find their way across the Internet? Does every computer connected to the Internet know where the other computers are? Do packets simply get 'broadcast' to every computer on the Internet? The answer to both the preceding questions is 'no'. No computer knows where any of the other computers are, and packets do not get sent to every computer. The information used to get packets to their destinations are contained in routing tables kept by each router connected to the Internet.

Routers are packet switches. A router is usually connected between networks to route packets between them. Each router knows about it's sub-networks and which IP addresses they use. The router usually doesn't know what IP addresses are 'above' it. Examine Diagram 5 below. The black boxes connecting the backbones are routers. The larger NSP backbones at the top are connected at a NAP. Under them are several sub-networks, and under them, more sub-networks. At the bottom are two local area networks with computers attached. 

Diagram 5

 

When a packet arrives at a router, the router examines the IP address put there by the IP protocol layer on the originating computer. The router checks it's routing table. If the network containing the IP address is found, the packet is sent to that network. If the network containing the IP address is not found, then the router sends the packet on a default route, usually up the backbone hierarchy to the next router. Hopefully the next router will know where to send the packet. If it does not, again the packet is routed upwards until it reaches a NSP backbone. The routers connected to the NSP backbones hold the largest routing tables and here the packet will be routed to the correct backbone, where it will begin its journey 'downward' through smaller and smaller networks until it finds it's destination.

Domain Names and Address Resolution

But what if you don't know the IP address of the computer you want to connect to? What if the you need to access a web server referred to as www.anothercomputer.com? How does your web browser know where on the Internet this computer lives? The answer to all these questions is the Domain Name Service or DNS. The DNS is a distributed database which keeps track of computer's names and their corresponding IP addresses on the Internet.

Many computers connected to the Internet host part of the DNS database and the software that allows others to access it. These computers are known as DNS servers. No DNS server contains the entire database; they only contain a subset of it. If a DNS server does not contain the domain name requested by another computer, the DNS server re-directs the requesting computer to another DNS server. 

Diagram 6

 

The Domain Name Service is structured as a hierarchy similar to the IP routing hierarchy. The computer requesting a name resolution will be re-directed 'up' the hierarchy until a DNS server is found that can resolve the domain name in the request. Figure 6 illustrates a portion of the hierarchy. At the top of the tree are the domain roots. Some of the older, more common domains are seen near the top. What is not shown are the multitude of DNS servers around the world which form the rest of the hierarchy.

When an Internet connection is setup (e.g. for a LAN or Dial-Up Networking in Windows), one primary and one or more secondary DNS servers are usually specified as part of the installation. This way, any Internet applications that need domain name resolution will be able to function correctly. For example, when you enter a web address into your web browser, the browser first connects to your primary DNS server. After obtaining the IP address for the domain name you entered, the browser then connects to the target computer and requests the web page you wanted.

Check It Out - Disable DNS in Windows

If you're using Windows 95/NT and access the Internet, you may view your DNS server(s) and even disable them. If you use Dial-Up Networking:  Open your Dial-Up Networking window (which can be found in Windows Explorer under your CD-ROM drive and above Network Neighborhood). Right click on your Internet connection and click Properties. Near the bottom of the connection properties window press the TCP/IP Settings... button. If you have a permanent connection to the Internet:  Right click on Network Neighborhood and click Properties. Click TCP/IP Properties. Select the DNS Configuration tab at the top. You should now be looking at your DNS servers' IP addresses. Here you may disable DNS or set your DNS servers to 0.0.0.0. (Write down your DNS servers' IP addresses first. You will probably have to restart Windows as well.) Now enter an address into your web browser. The browser won't be able to resolve the domain name and you will probably get a nasty dialog box explaining that a DNS server couldn't be found. However, if you enter the corresponding IP address instead of the domain name, the browser will be able to retrieve the desired web page. (Use ping to get the IP address prior to disabling DNS.) Other Microsoft operating systems are similar.

Internet Protocols Revisited

As hinted to earlier in the section about protocol stacks, one may surmise that there are many protocols that are used on the Internet. This is true; there are many communication protocols required for the Internet to function. These include the TCP and IP protocols, routing protocols, medium access control protocols, application level protocols, etc. The following sections describe some of the more important and commonly used protocols on the Internet. Higher level protocols are discussed first, followed by lower level protocols.

Application Protocols: HTTP and the World Wide Web

One of the most commonly used services on the Internet is the World Wide Web (WWW). The application protocol that makes the web work is Hypertext Transfer Protocol or HTTP. Do not confuse this with the Hypertext Markup Language (HTML). HTML is the language used to write web pages. HTTP is the protocol that web browsers and web servers use to communicate with each other over the Internet. It is an application level protocol because it sits on top of the TCP layer in the protocol stack and is used by specific applications to talk to one another. In this case the applications are web browsers and web servers.

HTTP is a connectionless text based protocol. Clients (web browsers) send requests to web servers for web elements such as web pages and images. After the request is serviced by a server, the connection between client and server across the Internet is disconnected. A new connection must be made for each request. Most protocols are connection oriented. This means that the two computers communicating with each other keep the connection open over the Internet. HTTP does not however. Before an HTTP request can be made by a client, a new connection must be made to the server.

When you type a URL into a web browser, this is what happens:

1. If the URL contains a domain name, the browser first connects to a domain name server and retrieves the corresponding IP address for the web server.
2. The web browser connects to the web server and sends an HTTP request (via the protocol stack) for the desired web page.
3. The web server receives the request and checks for the desired page. If the page exists, the web server sends it. If the server cannot find the requested page, it will send an HTTP 404 error message. (404 means 'Page Not Found' as anyone who has surfed the web probably knows.)
4. The web browser receives the page back and the connection is closed.
5. The browser then parses through the page and looks for other page elements it needs to complete the web page. These usually include images, applets, etc.
6. For each element needed, the browser makes additional connections and HTTP requests to the server for each element.
7. When the browser has finished loading all images, applets, etc. the page will be completely loaded in the browser window.

Check It Out - Use Your Telnet Client to Retrieve a Web Page Using HTTP

Telnet is a remote terminal service used on the Internet. It's use has declined lately, but it is a very useful tool to study the Internet. In Windows find the default telnet program. It may be located in the Windows directory named telnet.exe. When opened, pull down the Terminal menu and select Preferences. In the preferences window, check Local Echo. (This is so you can see your HTTP request when you type it.) Now pull down the Connection menu and select Remote System. Enter www.google.com for the Host Name and 80 for the Port. (Web servers usually listen on port 80 by default.) Press Connect. Now type GET / HTTP/1.0 and press Enter twice. This is a simple HTTP request to a web server for it's root page. You should see a web page flash by and then a dialog box should pop up to tell you the connection was lost. If you'd like to save the retrieved page, turn on logging in the Telnet program. You may then browse through the web page and see the HTML that was used to write it.

Most Internet protocols are specified by Internet documents known as a Request For Comments or RFCs. RFCs may be found at several locations on the Internet. See the Resources section below for appropriate URL's. HTTP version 1.0 is specified by RFC 1945.

Application Protocols: SMTP and Electronic Mail

Another commonly used Internet service is electronic mail. E-mail uses an application level protocol calledSimple Mail Transfer Protocol or SMTP. SMTP is also a text based protocol, but unlike HTTP, SMTP is connection oriented. SMTP is also more complicated than HTTP. There are many more commands and considerations in SMTP than there are in HTTP.

When you open your mail client to read your e-mail, this is what typically happens:

1. The mail client (Netscape Mail, Lotus Notes, Microsoft Outlook, etc.) opens a connection to it's default mail server. The mail server's IP address or domain name is typically setup when the mail client is installed.
2. The mail server will always transmit the first message to identify itself.
3. The client will send an SMTP HELO command to which the server will respond with a 250 OK message.
4. Depending on whether the client is checking mail, sending mail, etc. the appropriate SMTP commands will be sent to the server, which will respond accordingly.
5. This request/response transaction will continue until the client sends an SMTP QUIT command. The server will then say goodbye and the connection will be closed.

A simple 'conversation' between an SMTP client and SMTP server is shown below. R: denotes messages sent by the server (receiver) and S: denotes messages sent by the client (sender).

      This SMTP example shows mail sent by Smith at host USC-ISIF, to
      Jones, Green, and Brown at host BBN-UNIX.  Here we assume that
      host USC-ISIF contacts host BBN-UNIX directly.  The mail is
      accepted for Jones and Brown.  Green does not have a mailbox at
      host BBN-UNIX.

      -------------------------------------------------------------

         R: 220 BBN-UNIX.ARPA Simple Mail Transfer Service Ready
         S: HELO USC-ISIF.ARPA
         R: 250 BBN-UNIX.ARPA

         S: MAIL FROM:<Smith@USC-ISIF.ARPA>
         R: 250 OK

         S: RCPT TO:<Jones@BBN-UNIX.ARPA>
         R: 250 OK

         S: RCPT TO:<Green@BBN-UNIX.ARPA>
         R: 550 No such user here

         S: RCPT TO:<Brown@BBN-UNIX.ARPA>
         R: 250 OK

         S: DATA
         R: 354 Start mail input; end with <CRLF>.<CRLF>
         S: Blah blah blah...
         S: ...etc. etc. etc.
         S: .
         R: 250 OK

         S: QUIT
         R: 221 BBN-UNIX.ARPA Service closing transmission channel

This SMTP transaction is taken from RFC 821, which specifies SMTP.

Transmission Control Protocol

Under the application layer in the protocol stack is the TCP layer. When applications open a connection to another computer on the Internet, the messages they send (using a specific application layer protocol) get passed down the stack to the TCP layer. TCP is responsible for routing application protocols to the correct application on the destination computer. To accomplish this, port numbers are used. Ports can be thought of as separate channels on each computer. For example, you can surf the web while reading e-mail. This is because these two applications (the web browser and the mail client) used different port numbers. When a packet arrives at a computer and makes its way up the protocol stack, the TCP layer decides which application receives the packet based on a port number.

TCP works like this:

• When the TCP layer receives the application layer protocol data from above, it segments it into manageable 'chunks' and then adds a TCP header with specific TCP information to each 'chunk'. The information contained in the TCP header includes the port number of the application the data needs to be sent to.
• When the TCP layer receives a packet from the IP layer below it, the TCP layer strips the TCP header data from the packet, does some data reconstruction if necessary, and then sends the data to the correct application using the port number taken from the TCP header.

This is how TCP routes the data moving through the protocol stack to the correct application.

TCP is not a textual protocol. TCP is a connection-oriented, reliable, byte stream service. Connection-oriented means that two applications using TCP must first establish a connection before exchanging data. TCP is reliable because for each packet received, an acknowledgement is sent to the sender to confirm the delivery. TCP also includes a checksum in it's header for error-checking the received data. The TCP header looks like this:

Diagram 7

 

Notice that there is no place for an IP address in the TCP header. This is because TCP doesn't know anything about IP addresses. TCP's job is to get application level data from application to application reliably. The task of getting data from computer to computer is the job of IP.

Check It Out - Well Known Internet Port Numbers

Listed below are the port numbers for some of the more commonly used Internet services. FTP 20/21 Telnet 23 SMTP 25 HTTP 80 Quake III Arena 27960

Internet Protocol

Unlike TCP, IP is an unreliable, connectionless protocol. IP doesn't care whether a packet gets to it's destination or not. Nor does IP know about connections and port numbers. IP's job is too send and route packets to other computers. IP packets are independent entities and may arrive out of order or not at all. It is TCP's job to make sure packets arrive and are in the correct order. About the only thing IP has in common with TCP is the way it receives data and adds it's own IP header information to the TCP data. The IP header looks like this: 

Diagram 8

 

Above we see the IP addresses of the sending and receiving computers in the IP header. Below is what a packet looks like after passing through the application layer, TCP layer, and IP layer. The application layer data is segmented in the TCP layer, the TCP header is added, the packet continues to the IP layer, the IP header is added, and then the packet is transmitted across the Internet. 

Diagram 9

 

Wrap Up

Now you know how the Internet works. But how long will it stay this way? The version of IP currently used on the Internet (version 4) only allows 2³² addresses. Eventually there won't be any free IP addresses left. Surprised? Don't worry. IP version 6 is being tested right now on a research backbone by a consortium of research institutions and corporations. And after that? Who knows. The Internet has come a long way since it's inception as a Defense Department research project. No one really knows what the Internet will become. One thing is sure, however. The Internet will unite the world like no other mechanism ever has. The Information Age is in full stride and I am glad to be a part of it.

Rus Shuler, 1998 
Updates made 2002

Resources

Below are some interesting links associated with some of the topics discussed. (I hope they all still work. All open in new window.)

http://www.ietf.org is the home page of the Internet Engineering Task Force. This body is greatly responsible for the development of Internet protocols and the like.

http://www.internic.org is the organization responsible for administering domain names.

http://www.faqs.org/rfcs/rfcsearch.html is an excellent RFC search engine useful for finding any RFC.

http://navigators.com/isp.html is Russ Haynal's ISP Page. This is a great site with links to most NSPs and their backbone infrastructure maps.

http://www.investintech.com/content/historyinternet/ is A Brief Guide to the History of the Internet, sent by Kendra.

Bibliography

The following books are excellent resources and helped greatly in the writing of this paper. I believe Stevens' book is the best TCP/IP reference ever and can be considered the bible of the Internet. Sheldon's book covers a much wider scope and contains a vast amount of networking information.

• TCP/IP Illustrated, Volume 1, The Protocols. 
  W. Richard Stevens. 
  Addison-Wesley, Reading, Massachusetts. 1994.
• Encyclopedia of Networking. 
  Tom Sheldon. 
  Osbourne McGraw-Hill, New York. 1998.