There are many lab exercises for upper-level school students and freshman undergraduates to measure the value of the local acceleration due to gravity (g) near Earth's surface. In these exercises, the value of g is usually taken to be constant. The approach is often based on measuring the period of a pendulum that is inversely proportional to the square root of g. Traditional measurements of the period of a simple or inclined pendulum involve use of a stopwatch to measure the time required to complete a number of oscillations, but other more sophisticated measurement techniques for greater accuracy, such as a photogate timing system, measuring the time-dependent tension on the string, or using a stepper motor connected to a conical pendulum have been described. Using video imaging, the mechanics of objects dropped from some height has also been used to determine g. In physics courses where physical principles are applied to Earth problems, however, the goal is usually to measure a change in a potential field, such as Earth's gravitational field, in order to determine anomalous subsurface characteristics. In this paper, we describe an indoor exercise to measure the local change in g resulting from a large anomalous mass near the observation location.
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April 2016
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April 01 2016
Indoor Microgravity Survey
Richard A. Secco;
Richard A. Secco
University of Western Ontario
, London, ON, Canada
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Reynold E. Sukara
Reynold E. Sukara
University of Western Ontario
, London, ON, Canada
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Phys. Teach. 54, 213–215 (2016)
Citation
Richard A. Secco, Reynold E. Sukara; Indoor Microgravity Survey. Phys. Teach. 1 April 2016; 54 (4): 213–215. https://doi.org/10.1119/1.4944359
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