In calculus, and especially multivariable calculus, the mean of a function is loosely defined as the average value of the function over its domain. In one variable, the mean of a function f(x) over the interval (a,b) is defined by:[1]

Recall that a defining property of the average value of finitely many numbers is that . In other words, is the constant value which when added to itself times equals the result of adding the terms . By analogy, a defining property of the average value of a function over the interval is that

In other words, is the constant value which when integrated over equals the result of integrating over . But the integral of a constant is just

See also the first mean value theorem for integration, which guarantees that if is continuous then there exists a point such that

The point is called the mean value of on . So we write and rearrange the preceding equation to get the above definition.

In several variables, the mean over a relatively compact domain U in a Euclidean space is defined by

This generalizes the arithmetic mean. On the other hand, it is also possible to generalize the geometric mean to functions by defining the geometric mean of f to be

More generally, in measure theory and probability theory, either sort of mean plays an important role. In this context, Jensen's inequality places sharp estimates on the relationship between these two different notions of the mean of a function.

There is also a harmonic average of functions and a quadratic average (or root mean square) of functions.

See also

References

  1. Dougherty, Bradley (2016). "ON THE AVERAGE OF A FUNCTION AND THE MEAN VALUE THEOREM FOR INTEGRALS". Pi Mu Epsilon Journal. 14 (4): 251–254. ISSN 0031-952X. Retrieved 11 January 2023.
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