在古代，奧運選手都是憑借肌肉力量、體力和速度去贏得令人垂涎的橄欖枝編織而成的桂冠。正如顧拜旦所說，兩千年以來人們都在慶祝這種“運動信仰”。但是，自顧拜旦開始對體育進行研究從而促使他組織一種全新的奧運之后的一百年里，奧運會始終都與運動、科學相結合，將科研、技術和運動融為一體，使每四年一次的體育盛會提升到了令人無法想象的高度。

In ancient times Olympic athletes relied on raw strength, sinew and speed to earn a coveted olive wreath. For two millennia they celebrated the "religion of sport", as French educator Pierre de Coubertin put it.

In the hundred years since Baron de Coubertin's studies of physical exercise led him to marshal a new Olympic Movement, the Games have increasingly embraced the science of sport. This is a union of research, technology and athletics that has elevated the quadrennial festival to unimagined heights.

Throughout the modern Olympic Games, technology has been a partner with pageantry and prowess. Two of the first three Olympiads were relegated exhibition status as part of the World's Fair, a showplace for new technology and science. By 1912, Olympic athletes benefited from electronic timing, while spectators got their first taste of public-address systems.

High-speed film for assessing performance debuted in 1928, and both radio and television were still experimental when first used in the Games. In 1964, satellites broadcasted the Olympics worldwide, and the international audience reached 1 billion eight years later.

From microchips on marathon runner's shoes to ultrasensitive touch pads in the pool, there's a 007 trove of gadgetry behind the Games to help separate the Olympic medal-winners from the also-rans.

One of the freestyle relay swimmers in Swiss swimming team was proved by an equipment to have jumped off the starting block a tenth of a second before his teammate touched the wall. Swimming touch pads were first used in competition at the 1987 Commonwealth Games in Brisbane, Australia. Sensors embedded inside the starting block record when a swimmer leaves, and an ultrathin plastic touch pad on the wall under the water can calculate within hundredths of a second when the swimmer lands. The touch pads are specially ridged to ensure the swimmer's fingertip, not the force of the water the swimmer is displacing, trips the sensor. Cameras that take 100 pictures a second, aimed on the touch pads and starting blocks, back up the touch system.

The cameras used in track and field are the most sensitive. The extremely fast cameras, which take 1000 images per second, shoot only the first 8 millimeters of the finish line. As the runners cross, the cameras capture their bodies in a series of thousands of minuscule bits, first photographing the tips of the toe, then the finger then the tips of the nose, with resolution so fine it can pick up the hair on runners' bodies. All those thousands of pictures are then electronically pieced together to reproduce a photo finish. That's why the runners' bodies look distorted in official finish line recordings, because the picture is not an actual picture but a visual recreation of matter crossing a point in time. The same technology is used in rowing, flat water canoe and kayaking, and cycling events.

When marathon runners traced the historic steps of Philippides from the coastal city of Marathon to the 1896 Olympic stadium, they had microchips tied to the laces of their distance and speed.

Bicyclists use a transponder clipped to a spoke on their front wheel to record their finish time. It sends signals from the bike to antennae along the route so judges can confirm who is in first.


（Foreign and Domestic Olympic Stories ）