(M-7) Trigonometry--What it is good for?

The basic problem of trigonometry runs somewhat like this:

You stand next to a wide river and need to know the distance across it--say to a tree on the other shore, marked on the drawing here by the letter C (for simplicity, let's ignore the 3rd dimension). How can this be done without actually crossing the river?

The usual prescription is as follows. Stick two poles in the ground at points A and B, and with a tape measure or surveyor's chain measure the distance c between them ("the baseline").

 An old surveyor's tele-
  scope (theodolite).

Then remove the pole at A and replace it with a surveyor's telescope like the one shown here ("theodolite"), having a plate divided into 360 degrees, marking the direction ("azimuth") in which the telescope is pointing. Sighting the telescope, first at the tree and then at pole B, you measure the angle A of the triangle ABC, equal to the difference between the numbers you have read from the azimuth plate.. Replace the pole, take your scope to point B and measure the angle B in the same way.

The length c of the baseline, and the two angles A and B, contain all there is to know about the triangle ABC--enough, for instance, to construct a triangle of the same size and shape on some convenient open field. Trigonometry (trigon = triangle) was originally the art of deriving the missing information by pure calculation. Given enough information to define a triangle, trigonometry lets you calculate its remaining dimensions and angles.

Why triangles? Because they are the basic building blocks from which any shape (with straight boundaries) can be constructed. A square, pentagon or another polygon can be divided into triangles, say by straight lines radiating from one corner to all others.

In mapping a country, surveyors divide it into triangles and mark each corner by a "benchmark", which nowadays is often a round brass plate set into the ground, with a dimple in its center, above which the surveyors place their rods and telescopes (George Washington did this sort of work as a teenager). After measuring a baseline--such as AB in the example of the river--the surveyor would measure (as described here) the angles it formed with lines to some point C, and use trigonometry to calculate the distances AC abd BC. These can serve as baselines for 2 more triangles, each of which provides baselines for two more... and so on, more and more triangles until the entire country is covered by a grid involving only known distances. Later a secondary grid may be added, subdividing the bigger triangles and marking its points with iron stakes, providing additional known distances on which any maps and plans can be based.

One large surveying project of the 1800s was the "Great Trigonometric Survey" of British India. The two largest-ever theodolites were built for the project, monsters with circular scales 36 inches wide, on which settings were read with exceptional accuracy by 5 microscopes. Each in its box weighed half a ton and needed 12 men for carrying it around. Using them, the project covered the country with multiple strings of triangles in the north-south and east-west directions (the areas between the strings were left for later) and it took decades to complete.

In 1843 Andrew Scott Waugh took charge of the project as Surveyor-General, and gave special attention to the Himalaya peaks north of India. Because of clouds and haze, those peaks are only rarely seen from the lowlands, and until 1847 few measured sightings were achieved. Even after they were made, the results had to be laboriously analyzed by "computers" in the survey's offices--not machines, but persons who performed the trigonometric calculations.

The story is told that in 1852 the chief computer, Radanath Sikhdar, came to the director of the survey and told him: "Sir, we have discovered the highest mountain in the world." From a distance of over 100 miles (160 km), the peak was observed from six different stations, and "on no occasion had the observer suspected that he was viewing through his telescope the highest point on Earth." Originally it was designated as "Peak XV" by the survey, but in 1856 Waugh named it after Sir George Everest, his predecessor in the office of chief surveyor. Everest was the one who commisioned and first used those giant theodolites; they are now on display in the Museum of the Survey of India in Dehra Dum.

Nowadays position on Earth can be found pretty accurately using the global positioning system (GPS) of 24 satellites in precise orbits, constantly broadcasting their position. A small hand-held electronic instrument receives their signals and gives one's position within 10-20 meters (even more accurately for the military, the sponsor of the system). A great deal of trigonometry is involved, but it is all done for you by the computer inside your gadget, all you need do is push the proper buttons.

Now that you know a bit about the uses of trigonometry, you are welcome to advance to the actual nitty-gritty.

Note: The details about the discovery of Mt. Everest and the survey of India are from "Who Discovered Mount Everest?" by Parke A. Dickey, Eos (Transactions of the American Geophysical Union), vol 66, p. 697-700, 8 October 1985. The article is reprinted on p. 54-59 of History of Geophysics, Vol. 4, edited by C. Stewart Gillmor, published by the American Geophysical Union, 1990.

Exploring Further:

A site on Mt. Everest and measurements of its height, from the "Horizon" section of "The Washington Post."

A scholarly article about surveys of India (far beyond the story told here, though some overlap exists) can be found here.

About the naming of Mt. Everest.

A teacher's guide for using in the classroom the survey of India and the discovery of Mt. Everest as an introduction to surveying. The attribution of the naming is however incorrect--see preceding item.


Next Stop:   #M-8    How to tell Sines from Cosines



Back to IndexNASA Home PageGoddard Space Flight Center

Author and curator: David P. Stern, u5dps@lepvax.gsfc.nasa.gov
Last updated 25 February 1999.