Sputnik III on display at a Soviet exhibit in less exciting times. The satellite launched on May 15, 1958, and remained in orbit until April 6, 1960. The Russian spacecraft detected Earth's outer radiation belts among other handy feats.
Walter Sanders/Time Life Pictures/Getty Images
"Man must rise above the Earth -- to the top of the atmosphere and beyond -- for only thus will he fully understand the world in which he lives."
Socrates made this observation centuries before humans successfully placed an object in Earth's orbit. And yet the Greek philosopher seemed to grasp how valuable a view from space might be, even if he didn't know how to achieve it.
Those notions -- about how to get an object "to the top of the atmosphere and beyond" -- would have to wait until Isaac Newton, who published his now-famous cannonball thought experiment in 1729. His thinking went like this: Imagine you place a cannon atop a mountain and fire it horizontally. The cannonball will travel parallel to Earth's surface for a little while but will eventually succumb to gravity and fall to the ground. Now imagine you keep adding gunpowder to the cannon. With the extra explosives, the cannonball will travel farther and farther before it falls. Add just the right amount of powder and impart just the right velocity to the ball, and it will travel completely around the planet, always falling in the gravitational field but never reaching the ground.
In October 1957, the Soviets finally proved Newton correct when they launched Sputnik 1 -- the first artificial satellite to orbit Earth. This kick-started the space race and initiated a long-term love affair with objects designed to travel in circular paths around our planet or other planets in the solar system. Since Sputnik, several nations, led predominantly by the United States, Russia and China, have sent some 2,500 satellites into space [source: National Geographic]. Some of these man-made objects, such as the International Space Station, are massive. Others might fit comfortably in your kitchen breadbox. We see and recognize their use in weather reports, television transmission by DIRECTV and DISH Network, and everyday telephone calls. Even those that escape our notice have become indispensable tools for the military.
Of course, launching and operating satellites leads to problems. Today, with more than 1,000 operational satellites in orbit around Earth, our immediate cosmic neighborhood has become busier than a big city rush hour [source: Cain]. And then there's the discarded equipment, abandoned satellites, pieces of hardware and fragments from explosions or collisions that share the skies with the useful equipment. This orbital debris has accumulated over the years and poses a serious threat to satellites currently circling Earth and to future manned and unmanned launches.
In this article, we'll peer into the guts of a typical satellite and then gaze through its "eyes" to enjoy views of our planet that Socrates and Newton could have barely imagined. But first, let's take a closer look at what, exactly, makes a satellite different from other celestial objects.
What Is a Satellite?
To understand why satellites move this way, we must revisit our friend Newton. Newton proposed that a force -- gravity -- exists between any two objects in the universe. If it weren't for this force, a satellite in motion near a planet would continue in motion at the same speed and in the same direction -- a straight line. This straight-line inertial path of a satellite, however, is balanced by a strong gravitational attraction directed toward the center of the planet.
Sometimes, a satellite's orbit looks like an ellipse, a squashed circle that moves around two points known as foci. The same basic laws of motion apply, except that the planet is located at one of the foci. As a result, the net force applied to the satellite isn't uniform all the way around the orbit, and the speed of the satellite changes constantly. It moves fastest when it's closest to the planet -- a point known as perigee -- and slowest when it's farthest from the planet -- a point known as apogee.
Satellites come in all shapes and sizes and play a variety of roles.
Weather satellites help meteorologists predict the weather or see what's happening at the moment. The Geostationary Operational Environmental Satellite (GOES) is a good example. These satellites generally contain cameras that can return photos of Earth's weather, either from fixed geostationary positions or from polar orbits.
Communications satellites allow telephone and data conversations to be relayed through the satellite. Typical communications satellites include Telstar and Intelsat. The most important feature of a communications satellite is the transponder -- a radio that receives a conversation at one frequency and then amplifies it and retransmits it back to Earth on another frequency. A satellite normally contains hundreds or thousands of transponders. Communications satellites are usually geosynchronous (more on that later).
Broadcast satellites broadcast television signals from one point to another (similar to communications satellites).
Scientific satellites, like the Hubble Space Telescope, perform all sorts of scientific missions. They look at everything from sunspots to gamma rays.
Navigational satellites help ships and planes navigate. The most famous are the GPS NAVSTAR satellites.
Rescue satellites respond to radio distress signals (read this page for details).
Earth observation satellites check the planet for changes in everything from temperature to forestation to ice-sheet coverage. The most famous are the Landsat series.
Military satellites are up there, but much of the actual application information remains secret. Applications may include relaying encrypted communication, nuclear monitoring, observing enemy movements, early warning of missile launches, eavesdropping on terrestrial radio links, radar imaging and photography (using what are essentially large telescopes that take pictures of militarily interesting areas).
REFLECTION: SPUTNIK, OCT. 4, 1957
Sputnik's transmissions died along with its battery after only three weeks, but its effects have been felt for decades. As a fifth-grader, I witnessed the stir caused by the launch of Sputnik. News reports showed that many people in the United States were embarrassed to see the Soviet Union achieving a scientific first, as well as frightened that a foreign country had placed something overhead. Soviet rocket development seemed well ahead of the United States' efforts.
The push toward getting an American satellite into space started immediately. American schools and universities were soon stocked with new science books. One side effect that had a direct impact on many students like me was an increase in science homework, giving a personal dimension to the national wake-up call.
– Gary Brown
Newton may have worked through the mental exercise of launching a satellite, but it would take a while before we actually accomplished the feat. One of the early visionaries was sci-fi writer Arthur C. Clarke. In 1945, Clarke suggested that satellites could be placed into orbit so that they moved in the same direction and at the same rate as the spinning Earth. These so-called geostationary satellites, he proposed, could be used for communications.
Many scientists didn't fully embrace Clarke's idea -- until Oct. 4, 1957. That's when the Soviet Union launched Sputnik 1, the first man-made satellite to orbit Earth.Sputnik was a 23-inch (58-centimeter), 184-pound (83-kilogram) metal ball. Although it was a remarkable achievement, Sputnik's contents seem meager by today's standards:
Thermometer
Battery
Radio transmitter -- changed the tone of its beeps to match temperature changes
Nitrogen gas -- pressurized the interior of the satellite
On the outside of Sputnik, four whip antennas transmitted on shortwave frequencies above and below what is today's citizens-band (27 megahertz). Tracking stations on the ground picked up the radio signals and confirmed that the tiny satellite had survived the launch and was successfully tracing a path around our planet. A month later, the Soviets placed a companion craft, Sputnik 2, in orbit. Nestled inside the capsule was a dog by the name of Laika.
In December 1957, desperate to keep up with their Cold War counterparts, American scientists tried to carry a satellite into orbit aboard a Vanguard rocket. Unfortunately, the rocket crashed and burned on the launchpad. Shortly after, on Jan. 31, 1958, the U.S. finally matched the success of the Soviets by using a plan adopted by Wernher von Braun, which called for a U.S. Redstone rocket to propel a satellite -- Explorer 1 -- into Earth's orbit. Explorer 1 carried instrumentation to detect cosmic rays and revealed, in an experiment led by James Van Allen of the University of Iowa, a much lower cosmic ray count than expected. This led to the discovery of two doughnut-shaped zones (eventually named for Van Allen) filled with charged particles trapped by Earth's magnetic field.
Bolstered by these successes, several companies raced to develop and deploy satellites in the 1960s. One of these was Hughes Aircraft and its star engineer Harold Rosen. Rosen led a team that turned Arthur C. Clarke's concept -- a communications satellite positioned in Earth's orbit so it could bounce radio waves from one location to another -- into a feasible design. In 1961, NASA gave Hughes a contract to build the Syncom (synchronous communication) series of satellites. In July 1963, Rosen and his colleagues watched as Syncom 2 soared into space and navigated into a (roughly) geosynchronous orbit. President Kennedy used the new system to have a conversation with the Nigerian prime minister in Africa (you can listen here). This was followed by Syncom 3, which could actually broadcast television.
The age of satellites had begun.