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The Pendulum — Time a Swing and Weigh Gravity
Martin

བཟོས་མཁན

Martin

2. སྤྱི་ཟླ་བདུན་པ 2026NO

The Pendulum — Time a Swing and Weigh Gravity

A hands-on school project: tie a weight to a string, time its swing, and discover that a pendulum keeps perfect time — its period depends only on length and gravity, never on the weight. Measure it yourself with a stopwatch, then a Python cell checks your numbers against the 350-year-old formula and even lets you weigh gravity from your own readings.
འགོ་བཙུགས
30 minutes

ལམ་སྟོན

1

The lamp that kept time

Around 1602 the young Galileo watched a lamp swinging in Pisa cathedral and timed it against his pulse. Whether it swung wide or narrow, each swing took the same time. That discovery — isochronism — is what makes a pendulum a clock, and you are about to measure it yourself.
2

Build your pendulum

Tie a small heavy weight (a steel nut, a ball bearing, or a fishing weight) to the end of a piece of string, and hang it from a fixed point like a doorframe or a clamp so it can swing freely. Measure the length of the string from the pivot to the middle of the weight with a tape measure and write it down — call it L.

གོམ་པ་འདིའི་རྫས་རིགས:

Cotton Kitchen StringCotton Kitchen String1 piece
Ball BearingBall Bearing1 piece

ལག་ཆས་དགོས་མཁོ:

Measuring Tape 3mMeasuring Tape 3m
3

Time twenty swings

Pull the weight to one side by a small angle (about 10-15 degrees — small swings work best) and let go. With a stopwatch, time how long TWENTY complete back-and-forth swings take, then divide by 20 to get the time of one swing (the period). Timing 20 and dividing makes your result far more accurate than timing just one. Do it two or three times and average. Then change the string length and measure again.

ལག་ཆས་དགོས་མཁོ:

StopwatchStopwatch
4

Check your period against the formula

Loading Jupyter Notebook...

ལག་ཆས་དགོས་མཁོ:

Desktop ComputerDesktop Computer
CalculatorCalculator
5

Compendium: everything the swing is hiding

A few things your experiment reveals. (1) The bob's MASS does not matter — a heavy and a light bob of the same length keep identical time, because gravity pulls harder on the heavy one but also has more mass to move, and the two effects cancel. (2) The period grows with the square ROOT of the length: to make a pendulum swing twice as slowly you must make it four times as long — which is why a tall grandfather clock ticks once per second with a bob about a metre down. (3) Isochronism (equal times) only holds for SMALL swings; past about 20 degrees the period slowly lengthens, which is why pendulum clocks keep their swing narrow. (4) Because a pendulum's tick depends on gravity, the very same swing measures how strong gravity is, runs the pendulum clock that timed the world for 300 years, reveals the Earth's rotation in Foucault's giant pendulum, and detects earthquakes in a seismometer.

རྫས་རིགས

2

ལག་ཆས་དགོས་མཁོ

4

You can swap these in

Can't get one of the materials? Swap it for an equivalent — these work just as well.

འབྲེལ་ཡོད་བིལུ་པིརིན་ཊི

བིལུ་པིརིན་ཊི་འདི་ཚུ་ཐབས་ལམ་དང་རྫས་རིགས། སྤྱི་ཆོས་བགོ་བཤའ་བྱེད

CC0 སྤྱི་དབང

བིལུ་པིརིན་ཊི་འདི་CC0 འོག་བཀྲམས་ཡོད། ཁྱེད་རང་གིས་ཆོག་མཆན་མ་བཞེས་པར་ཕབ་ལེན་དང་བཟོ་བཅོས། བགོ་བཤའ། དགོས་མཁོ་གང་ལའང་བཀོལ་སྤྱོད་བྱས་ཆོག

བཟོ་མཁན་ལ་རྒྱབ་སྐྱོར་བྱེད་པའི་ཆེད་ཁོང་ཚོའི་བིལུ་པིརིན་ཊི་བརྒྱུད་ཐོན་སྐྱེད་ཉོ། བཟོ་མཁན་གྱིས བཟོ་མཁན་གྱི་ཁེ་ཕོགས ཚོང་པས་གཏན་འཁེལ་བྱས་པ། ཡང་ན་བིལུ་པིརིན་ཊི་འདིའི་པར་གསར་བཟོས་ཏེ་ཁྱེད་རང་གི་བིལུ་པིརིན་ཊི་ནང་མཐུད་སྦྲེལ་བྱས་ཏེ་ཡོང་སྒོ་བགོ་བཤའ་བྱེད།

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