17.5. Inverse Variation
▪ Exploration:
The two functions
- y = x and y = 1/x
look somewhat alike. (a) Can you predict, for each, what happens to y as x gets larger? (b) What happens to y for each as x gets very large? (c) What happens to y for each as x gets very small?
Try this. Graph the two functions in the same viewing window, for x = 0 to 3. Does your graph bear out your predictions?
For the bar in tension, Fig. 17-17, the stress σ is equal to the applied force P divided by the cross-sectional area a of the bar, or 
. What happens mathematically to the stress as a increases? As a gets very small? Does the mathematics agree with what you know about the stress in a bar?
Figure 17.17. A bar in tension.
When we say that "y varies inversely as x" or that "y is inversely proportional to x," we mean that x and y are related by the following equation, where, as before, k is a constant of proportionality:
The equation y = k/x can also be written as
- y = kx−1
that is, a power function with a negative exponent. Another form is obtained by multiplying both sides of y = k/x by x, getting
- xy = k
Each of these three forms indicate inverse variation. Inverse variation problems are solved by the ...
Get Technical Mathematics, Sixth Edition now with the O’Reilly learning platform.
O’Reilly members experience books, live events, courses curated by job role, and more from O’Reilly and nearly 200 top publishers.
