Computer and its various parts.

The word computer refers to an object that can accept some input and produce some output. In fact, the human brain itself is a sophisticated computer, and scientists are learning more about how it works with each passing year. Our most common use of the word computer, though, is to describe an electronic device containing a microprocessor.

A microprocessor is a small electronic device that can carry out complex calculations in the blink of an eye. You can find microprocessors in many devices you use each day, such as cars, refrigerators and televisions. The most recognized device with a microprocessor is the personal computer, or PC. In fact, the concept of a computer has become nearly synonymous with the term PC.

When you hear PC, you probably envision an enclosed device with an attached video screen, keyboard and some type of a pointing device, like a mouse or touchpad. You might also envision different forms of PCs, such as desktop computers, towers and laptops. The term PC has been associated with certain brands, such as Intel processors or Microsoft operating systems. In this article, though, we define a PC as a more general computing device with these characteristics:

• designed for use by one person at a time

• runs an operating system to interface between the user and the microprocessor

• has certain common internal components described in this article, like a CPU and RAM

• runs software applications designed for specific work or play activities

• allows for adding and removing hardware or software as needed

PCs trace their history back to the 1970s when a man named Ed Roberts began to sell computer kits based on a microprocessor chip designed by Intel. Roberts called his computer the Altair 8800 and sold the unassembled kits for $395. Popular Electronics ran a story about the kit in its January 1975 issue, and to the surprise of just about everyone, the kits became an instant hit. Thus, the era of the personal computer began [sources: Cerruzi, Lasar].

While the Altair 8800 was the first real personal computer, it was the release of the Apple II a couple of years later that signaled the start of the PC as a sought-after home appliance. The Apple II, from inventors Steve Jobs and Steve Wozniak, proved that there was a demand for computers in homes and schools. Soon after, long-established computer companies like IBM and Texas Instruments jumped into the PC market, and new brands like Commodore and Atari jumped into the game.

In this article, we'll look inside the PC to find out about its parts and what they do. We'll also check out the basic software used to boot and run a PC. Then, we'll cover mobile PCs and examine the future for PC technology.

Core PC Components

To see how a PC works, let's start with the pieces that come together to make up the machine. The following are the components common to PCs in the order they're typically assembled:

Case -- If you're using a laptop, the computer case includes keyboard and screen. For desktop PCs, the case is typically some type of box with lights, vents, and places for attaching cables. The size of the case can vary from small tabletop units to tall towers. A larger case doesn't always imply a more powerful computer; it's what's inside that counts. PC builders design or select a case based on the type of motherboard that should fit inside.

Motherboard -- The primary circuit board inside your PC is its motherboard. All components, inside and out, connect through the motherboard in some way. The other components listed on this page are removable and, thus, replaceable without replacing the motherboard. Several important components, though, are attached directly to the motherboard. These include the complementary metal-oxide semiconductor (CMOS), which stores some information, such as the system clock, when the computer is powered down. Motherboards come in different sizes and standards, the most common as of this writing being ATX and MicroATX. From there, motherboards vary by the type of removable components they're designed to handle internally and what ports are available for attaching external devices.

Power supply -- Other than its CMOS, which is powered by a replaceable CMOS battery on the motherboard, every component in your PC relies on its power supply. The power supply connects to some type of power source, whether that's a battery in the case of mobile computers, or a power outlet in the case of desktop PCs. In a desktop PC, you can see the power supply mounted inside the case with a power cable connection on the outside and a handful of attached cables inside. Some of these cables connect directly to the motherboard while others connect to other components like drives and fans.

Central processing unit (CPU) -- The CPU, often just called the processor, is the component that contains the microprocessor. That microprocessor is the heart of all the PC's operations, and the performance of both hardware and software rely on the processor's performance. Intel and AMD are the largest CPU manufacturers for PCs, though you'll find others on the market, too. The two common CPU architectures are 32-bit and 64-bit, and you'll find that certain software relies on this architecture distinction.

Random-access memory (RAM) -- Even the fastest processor needs a buffer to store information while it's being processed. The RAM is to the CPU as a countertop is to a cook: It serves as the place where the ingredients and tools you're working with wait until you need to pick up and use them. Both a fast CPU and an ample amount of RAM are necessary for a speedy PC. Each PC has a maximum amount of RAM it can handle, and slots on the motherboard indicate the type of RAM the PC requires.

Drives -- A drive is a device intended to store data when it's not in use. A hard drive or solid state drive stores a PC's operating system and software, which we'll look at more closely later. This category also includes optical drives such as those used for reading and writing CD, DVD and Blu-ray media. A drive connects to the motherboard based on the type of drive controller technology it uses, including the older IDE standard and the newer SATA standard.

Cooling devices -- The more your computer processes, the more heat it generates. The CPU and other components can handle a certain amount of heat. However, if a PC isn't cooled properly, it can overheat, causing costly damage to its components and circuitry. Fans are the most common device used to cool a PC. In addition, the CPU is covered by a metallic block called a heat sink, which draws heat away from the CPU. Some serious computer users, such as gamers, sometimes have more expensive heat management solutions, like a water-cooled system, designed to deal with more intense cooling demands.

Cables -- All the components we've mentioned so far are connected by some combination of cables. These cables are designed to carry data, power or both. PCs should be constructed so that the cables fold neatly within the case and do not block air flow throughout it.

A PC is typically much more than these core components. Next, we'll look at the ports and peripherals that let you interact with the computer and how you can add even more components using expansion slots.

BP Apparatus

Sphygmomanometers

What is blood pressure?

Blood pressure is the force exerted by the blood on blood vessel walls. Today, it's measured in millimeters of mercury, units that refer to the height to which a column of mercury is raised by an equivalent pressure.

Recording blood pressure leads to the discovery of hypertension

Although physiologists who studied animals knew about the phenomenon of blood pressure in the 1700s, it was many years before physicians figured out how to measure it in humans. As soon as doctors had an accurate device and a simple procedure for measuring blood pressure, it became a normal part of a medical exam. Physicians could detect and monitor blood pressure over time, and they soon discovered hypertension, or chronic high blood pressure, a widespread and life-threatening condition.

Unfortunately, doctors had few options for treating hypertension and little understanding of its causes. Sometimes kidney disease was associated with hypertension, but in most cases, no cause could be identified.

This 1863 sphygmograph was an early attempt to measure blood pressure that proved to be cumbersome and inaccurate. A spring pressed one end of a lever onto the wrist, compressing an artery. The lever rose and fell with each pulse wave. A recording device traced the movements on smoked paper.

This 1898 sphygmomanometer had a cuff that was too narrow. Later models with wider cuffs gave more accurate readings.

This 1901 model had a wide cuff, but doctors used their fingers to detect arterial blood flow as they watched for changes in pressure.

	In 1905, Russian surgeon Nikolai Korotkoff developed the modern technique of using a stethoscope to listen for the sounds of blood flowing through the artery. His method proved to be extremely accurate and led to the discovery of hypertension.

1920 mercury sphygmomanometer, the "Pilling Midget"

How to take a blood pressure reading, based on Korotkoff sounds

A modern sphygmomanometer

1. Place cuff snugly around the middle of the upper arm.
2. Place the bell of your stethoscope over the pulse point just below the cuff.
3. Pump up the cuff until it's tight enough to stop blood flow.
4. Slowly deflate the cuff and listen.
5. Note the pressure reading when you hear the first faint sounds—that means some blood has started to pass through the vessels under the cuff. This is the maximum, or systolic, pressure.
6. When all sounds stop, note the pressure reading again. Now blood is flowing freely. This is the minimum, or diastolic, pressure.
7. Record the blood pressure as systolic over diastolic.