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Darboux's theorem (analysis)

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In mathematics, Darboux's theorem is a theorem in real analysis, named after Jean Gaston Darboux. It states that every function that results from the differentiation of another function has the intermediate value property: the image of an interval is also an interval.

When ƒ is continuously differentiable (ƒ in C()), this is a consequence of the intermediate value theorem. But even when ƒ′ is not continuous, Darboux's theorem places a severe restriction on what it can be.

Darboux's theorem

Let I {\displaystyle I} be a closed interval, f : I R {\displaystyle f\colon I\to \mathbb {R} } be a real-valued differentiable function. Then f {\displaystyle f'} has the intermediate value property: If a {\displaystyle a} and b {\displaystyle b} are points in I {\displaystyle I} with a < b {\displaystyle a<b} , then for every y {\displaystyle y} between f ( a ) {\displaystyle f'(a)} and f ( b ) {\displaystyle f'(b)} , there exists an x {\displaystyle x} in [ a , b ] {\displaystyle } such that f ( x ) = y {\displaystyle f'(x)=y} .

Proofs

Proof 1. The first proof is based on the extreme value theorem.

If y {\displaystyle y} equals f ( a ) {\displaystyle f'(a)} or f ( b ) {\displaystyle f'(b)} , then setting x {\displaystyle x} equal to a {\displaystyle a} or b {\displaystyle b} , respectively, gives the desired result. Now assume that y {\displaystyle y} is strictly between f ( a ) {\displaystyle f'(a)} and f ( b ) {\displaystyle f'(b)} , and in particular that f ( a ) > y > f ( b ) {\displaystyle f'(a)>y>f'(b)} . Let φ : I R {\displaystyle \varphi \colon I\to \mathbb {R} } such that φ ( t ) = f ( t ) y t {\displaystyle \varphi (t)=f(t)-yt} . If it is the case that f ( a ) < y < f ( b ) {\displaystyle f'(a)<y<f'(b)} we adjust our below proof, instead asserting that φ {\displaystyle \varphi } has its minimum on [ a , b ] {\displaystyle } .

Since φ {\displaystyle \varphi } is continuous on the closed interval [ a , b ] {\displaystyle } , the maximum value of φ {\displaystyle \varphi } on [ a , b ] {\displaystyle } is attained at some point in [ a , b ] {\displaystyle } , according to the extreme value theorem.

Because φ ( a ) = f ( a ) y > 0 {\displaystyle \varphi '(a)=f'(a)-y>0} , we know φ {\displaystyle \varphi } cannot attain its maximum value at a {\displaystyle a} . (If it did, then ( φ ( t ) φ ( a ) ) / ( t a ) 0 {\displaystyle (\varphi (t)-\varphi (a))/(t-a)\leq 0} for all t ( a , b ] {\displaystyle t\in (a,b]} , which implies φ ( a ) 0 {\displaystyle \varphi '(a)\leq 0} .)

Likewise, because φ ( b ) = f ( b ) y < 0 {\displaystyle \varphi '(b)=f'(b)-y<0} , we know φ {\displaystyle \varphi } cannot attain its maximum value at b {\displaystyle b} .

Therefore, φ {\displaystyle \varphi } must attain its maximum value at some point x ( a , b ) {\displaystyle x\in (a,b)} . Hence, by Fermat's theorem, φ ( x ) = 0 {\displaystyle \varphi '(x)=0} , i.e. f ( x ) = y {\displaystyle f'(x)=y} .

Proof 2. The second proof is based on combining the mean value theorem and the intermediate value theorem.

Define c = 1 2 ( a + b ) {\displaystyle c={\frac {1}{2}}(a+b)} . For a t c , {\displaystyle a\leq t\leq c,} define α ( t ) = a {\displaystyle \alpha (t)=a} and β ( t ) = 2 t a {\displaystyle \beta (t)=2t-a} . And for c t b , {\displaystyle c\leq t\leq b,} define α ( t ) = 2 t b {\displaystyle \alpha (t)=2t-b} and β ( t ) = b {\displaystyle \beta (t)=b} .

Thus, for t ( a , b ) {\displaystyle t\in (a,b)} we have a α ( t ) < β ( t ) b {\displaystyle a\leq \alpha (t)<\beta (t)\leq b} . Now, define g ( t ) = ( f β ) ( t ) ( f α ) ( t ) β ( t ) α ( t ) {\displaystyle g(t)={\frac {(f\circ \beta )(t)-(f\circ \alpha )(t)}{\beta (t)-\alpha (t)}}} with a < t < b {\displaystyle a<t<b} . g {\displaystyle \,g} is continuous in ( a , b ) {\displaystyle (a,b)} .

Furthermore, g ( t ) f ( a ) {\displaystyle g(t)\rightarrow {f}'(a)} when t a {\displaystyle t\rightarrow a} and g ( t ) f ( b ) {\displaystyle g(t)\rightarrow {f}'(b)} when t b {\displaystyle t\rightarrow b} ; therefore, from the Intermediate Value Theorem, if y ( f ( a ) , f ( b ) ) {\displaystyle y\in ({f}'(a),{f}'(b))} then, there exists t 0 ( a , b ) {\displaystyle t_{0}\in (a,b)} such that g ( t 0 ) = y {\displaystyle g(t_{0})=y} . Let's fix t 0 {\displaystyle t_{0}} .

From the Mean Value Theorem, there exists a point x ( α ( t 0 ) , β ( t 0 ) ) {\displaystyle x\in (\alpha (t_{0}),\beta (t_{0}))} such that f ( x ) = g ( t 0 ) {\displaystyle {f}'(x)=g(t_{0})} . Hence, f ( x ) = y {\displaystyle {f}'(x)=y} .

Darboux function

A Darboux function is a real-valued function ƒ which has the "intermediate value property": for any two values a and b in the domain of ƒ, and any y between ƒ(a) and ƒ(b), there is some c between a and b with ƒ(c) = y. By the intermediate value theorem, every continuous function on a real interval is a Darboux function. Darboux's contribution was to show that there are discontinuous Darboux functions.

Every discontinuity of a Darboux function is essential, that is, at any point of discontinuity, at least one of the left hand and right hand limits does not exist.

An example of a Darboux function that is discontinuous at one point is the topologist's sine curve function:

x { sin ( 1 / x ) for  x 0 , 0 for  x = 0. {\displaystyle x\mapsto {\begin{cases}\sin(1/x)&{\text{for }}x\neq 0,\\0&{\text{for }}x=0.\end{cases}}}

By Darboux's theorem, the derivative of any differentiable function is a Darboux function. In particular, the derivative of the function x x 2 sin ( 1 / x ) {\displaystyle x\mapsto x^{2}\sin(1/x)} is a Darboux function even though it is not continuous at one point.

An example of a Darboux function that is nowhere continuous is the Conway base 13 function.

Darboux functions are a quite general class of functions. It turns out that any real-valued function ƒ on the real line can be written as the sum of two Darboux functions. This implies in particular that the class of Darboux functions is not closed under addition.

A strongly Darboux function is one for which the image of every (non-empty) open interval is the whole real line. The Conway base 13 function is again an example.

Notes

  1. ^ Apostol, Tom M.: Mathematical Analysis: A Modern Approach to Advanced Calculus, 2nd edition, Addison-Wesley Longman, Inc. (1974), page 112.
  2. ^ Olsen, Lars: A New Proof of Darboux's Theorem, Vol. 111, No. 8 (Oct., 2004) (pp. 713–715), The American Mathematical Monthly
  3. Rudin, Walter: Principles of Mathematical Analysis, 3rd edition, MacGraw-Hill, Inc. (1976), page 108
  4. ^ Ciesielski, Krzysztof (1997). Set theory for the working mathematician. London Mathematical Society Student Texts. Vol. 39. Cambridge: Cambridge University Press. pp. 106–111. ISBN 0-521-59441-3. Zbl 0938.03067.
  5. Bruckner, Andrew M: Differentiation of real functions, 2 ed, page 6, American Mathematical Society, 1994

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