1.
Mean value theorem
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This theorem is used to prove statements about a function on an interval starting from local hypotheses about derivatives at points of the interval. More precisely, if a function f is continuous on the closed interval and it is one of the most important results in real analysis. A special case of this theorem was first described by Parameshvara, from the Kerala school of astronomy and mathematics in India, in his commentaries on Govindasvāmi and Bhāskara II. A restricted form of the theorem was proved by Rolle in 1691, the result was what is now known as Rolles theorem, the mean value theorem in its modern form was stated and proved by Cauchy in 1823. Let f, → R be a function on the closed interval, and differentiable on the open interval. Then there exists c in such that f ′ = f − f b − a. The mean value theorem is a generalization of Rolles theorem, which assumes f = f, the mean value theorem is still valid in a slightly more general setting. One only needs to assume that f, → R is continuous on, If finite, that limit equals f ′. An example where this version of the theorem applies is given by the cube root function mapping x → x 13. Note that the theorem, as stated, is if a differentiable function is complex-valued instead of real-valued. For example, define f = e x i for all real x, then f − f =0 =0 while f ′ ≠0 for any real x. Thus the Mean value theorem says that given any chord of a smooth curve, the following proof illustrates this idea. Define g = f − r x, where r is a constant, since f is continuous on and differentiable on, the same is true for g. We now want to choose r so that g satisfies the conditions of Rolles theorem, Assume that f is a continuous, real-valued function, defined on an arbitrary interval I of the real line. If the derivative of f at every point of the interval I exists and is zero. Proof, Assume the derivative of f at every point of the interval I exists and is zero. Let be an open interval in I. By the mean value theorem, there exists a point c in such that 0 = f ′ = f − f b − a, thus, f is constant on the interior of I and thus is constant on I by continuity

2.
Differential calculus
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In mathematics, differential calculus is a subfield of calculus concerned with the study of the rates at which quantities change. It is one of the two divisions of calculus, the other being integral calculus. The primary objects of study in differential calculus are the derivative of a function, related notions such as the differential, the derivative of a function at a chosen input value describes the rate of change of the function near that input value. The process of finding a derivative is called differentiation, geometrically, the derivative at a point is the slope of the tangent line to the graph of the function at that point, provided that the derivative exists and is defined at that point. For a real-valued function of a real variable, the derivative of a function at a point generally determines the best linear approximation to the function at that point. Differential calculus and integral calculus are connected by the theorem of calculus. Differentiation has applications to nearly all quantitative disciplines, for example, in physics, the derivative of the displacement of a moving body with respect to time is the velocity of the body, and the derivative of velocity with respect to time is acceleration. The derivative of the momentum of a body equals the applied to the body. The reaction rate of a reaction is a derivative. In operations research, derivatives determine the most efficient ways to transport materials, derivatives are frequently used to find the maxima and minima of a function. Equations involving derivatives are called differential equations and are fundamental in describing natural phenomena, derivatives and their generalizations appear in many fields of mathematics, such as complex analysis, functional analysis, differential geometry, measure theory, and abstract algebra. Suppose that x and y are real numbers and that y is a function of x and this relationship can be written as y = f. If f is the equation for a line, then there are two real numbers m and b such that y = mx + b. In this slope-intercept form, the m is called the slope and can be determined from the formula, m = change in y change in x = Δ y Δ x. It follows that Δy = m Δx, a general function is not a line, so it does not have a slope. Geometrically, the derivative of f at the point x = a is the slope of the tangent line to the function f at the point a and this is often denoted f ′ in Lagranges notation or dy/dx|x = a in Leibnizs notation. Since the derivative is the slope of the approximation to f at the point a. If every point a in the domain of f has a derivative, for example, if f = x2, then the derivative function f ′ = dy/dx = 2x