weierstrass substitution proof

\implies on the left hand side (and performing an appropriate variable substitution) Splitting the numerator, and further simplifying: $\frac{1}{b}\int\frac{1}{\sin^2 x}dx-\frac{1}{b}\int\frac{\cos x}{\sin^2 x}dx=\frac{1}{b}\int\csc^2 x\:dx-\frac{1}{b}\int\frac{\cos x}{\sin^2 x}dx$. [1] How to type special characters on your Chromebook To enter a special unicode character using your Chromebook, type Ctrl + Shift + U. S2CID13891212. Thus there exists a polynomial p p such that f p </M. Then we have. Typically, it is rather difficult to prove that the resulting immersion is an embedding (i.e., is 1-1), although there are some interesting cases where this can be done. These inequalities are two o f the most important inequalities in the supject of pro duct polynomials. \\ |Contents| Bernard Bolzano (Stanford Encyclopedia of Philosophy/Winter 2022 Edition) Use the universal trigonometric substitution: \[dx = d\left( {2\arctan t} \right) = \frac{{2dt}}{{1 + {t^2}}}.\], \[{\cos ^2}x = \frac{1}{{1 + {{\tan }^2}x}} = \frac{1}{{1 + {t^2}}},\;\;\;{\sin ^2}x = \frac{{{{\tan }^2}x}}{{1 + {{\tan }^2}x}} = \frac{{{t^2}}}{{1 + {t^2}}}.\], \[t = \tan \frac{x}{2},\;\; \Rightarrow x = 2\arctan t,\;\;\; dx = \frac{{2dt}}{{1 + {t^2}}}.\], \[\int {\frac{{dx}}{{1 + \sin x}}} = \int {\frac{{\frac{{2dt}}{{1 + {t^2}}}}}{{1 + \frac{{2t}}{{1 + {t^2}}}}}} = \int {\frac{{2dt}}{{1 + {t^2} + 2t}}} = \int {\frac{{2dt}}{{{{\left( {t + 1} \right)}^2}}}} = - \frac{2}{{t + 1}} + C = - \frac{2}{{\tan \frac{x}{2} + 1}} + C.\], \[x = \arctan t,\;\; \sin x = \frac{{2t}}{{1 + {t^2}}},\;\; dx = \frac{{2dt}}{{1 + {t^2}}},\], \[I = \int {\frac{{dx}}{{3 - 2\sin x}}} = \int {\frac{{\frac{{2dt}}{{1 + {t^2}}}}}{{3 - 2 \cdot \frac{{2t}}{{1 + {t^2}}}}}} = \int {\frac{{2dt}}{{3 + 3{t^2} - 4t}}} = \int {\frac{{2dt}}{{3\left( {{t^2} - \frac{4}{3}t + 1} \right)}}} = \frac{2}{3}\int {\frac{{dt}}{{{t^2} - \frac{4}{3}t + 1}}} .\], \[{t^2} - \frac{4}{3}t + 1 = {t^2} - \frac{4}{3}t + {\left( {\frac{2}{3}} \right)^2} - {\left( {\frac{2}{3}} \right)^2} + 1 = {\left( {t - \frac{2}{3}} \right)^2} - \frac{4}{9} + 1 = {\left( {t - \frac{2}{3}} \right)^2} + \frac{5}{9} = {\left( {t - \frac{2}{3}} \right)^2} + {\left( {\frac{{\sqrt 5 }}{3}} \right)^2}.\], \[I = \frac{2}{3}\int {\frac{{dt}}{{{{\left( {t - \frac{2}{3}} \right)}^2} + {{\left( {\frac{{\sqrt 5 }}{3}} \right)}^2}}}} = \frac{2}{3}\int {\frac{{du}}{{{u^2} + {{\left( {\frac{{\sqrt 5 }}{3}} \right)}^2}}}} = \frac{2}{3} \cdot \frac{1}{{\frac{{\sqrt 5 }}{3}}}\arctan \frac{u}{{\frac{{\sqrt 5 }}{3}}} + C = \frac{2}{{\sqrt 5 }}\arctan \frac{{3\left( {t - \frac{2}{3}} \right)}}{{\sqrt 5 }} + C = \frac{2}{{\sqrt 5 }}\arctan \frac{{3t - 2}}{{\sqrt 5 }} + C = \frac{2}{{\sqrt 5 }}\arctan \left( {\frac{{3\tan \frac{x}{2} - 2}}{{\sqrt 5 }}} \right) + C.\], \[t = \tan \frac{x}{4},\;\; \Rightarrow d\left( {\frac{x}{2}} \right) = \frac{{2dt}}{{1 + {t^2}}},\;\; \Rightarrow \cos \frac{x}{2} = \frac{{1 - {t^2}}}{{1 + {t^2}}}.\], \[\int {\frac{{dx}}{{1 + \cos \frac{x}{2}}}} = \int {\frac{{d\left( {\frac{x}{2}} \right)}}{{1 + \cos \frac{x}{2}}}} = 2\int {\frac{{\frac{{2dt}}{{1 + {t^2}}}}}{{1 + \frac{{1 - {t^2}}}{{1 + {t^2}}}}}} = 4\int {\frac{{dt}}{{1 + \cancel{t^2} + 1 - \cancel{t^2}}}} = 2\int {dt} = 2t + C = 2\tan \frac{x}{4} + C.\], \[t = \tan x,\;\; \Rightarrow x = \arctan t,\;\; \Rightarrow dx = \frac{{dt}}{{1 + {t^2}}},\;\; \Rightarrow \cos 2x = \frac{{1 - {t^2}}}{{1 + {t^2}}},\], \[\int {\frac{{dx}}{{1 + \cos 2x}}} = \int {\frac{{\frac{{dt}}{{1 + {t^2}}}}}{{1 + \frac{{1 - {t^2}}}{{1 + {t^2}}}}}} = \int {\frac{{dt}}{{1 + \cancel{t^2} + 1 - \cancel{t^2}}}} = \int {\frac{{dt}}{2}} = \frac{t}{2} + C = \frac{1}{2}\tan x + C.\], \[t = \tan \frac{x}{4},\;\; \Rightarrow x = 4\arctan t,\;\; dx = \frac{{4dt}}{{1 + {t^2}}},\;\; \cos \frac{x}{2} = \frac{{1 - {t^2}}}{{1 + {t^2}}}.\], \[\int {\frac{{dx}}{{4 + 5\cos \frac{x}{2}}}} = \int {\frac{{\frac{{4dt}}{{1 + {t^2}}}}}{{4 + 5 \cdot \frac{{1 - {t^2}}}{{1 + {t^2}}}}}} = \int {\frac{{4dt}}{{4\left( {1 + {t^2}} \right) + 5\left( {1 - {t^2}} \right)}}} = 4\int {\frac{{dt}}{{4 + 4{t^2} + 5 - 5{t^2}}}} = 4\int {\frac{{dt}}{{{3^2} - {t^2}}}} = 4 \cdot \frac{1}{{2 \cdot 3}}\ln \left| {\frac{{3 + t}}{{3 - t}}} \right| + C = \frac{2}{3}\ln \left| {\frac{{3 + \tan \frac{x}{4}}}{{3 - \tan \frac{x}{4}}}} \right| + C.\], \[\int {\frac{{dx}}{{\sin x + \cos x}}} = \int {\frac{{\frac{{2dt}}{{1 + {t^2}}}}}{{\frac{{2t}}{{1 + {t^2}}} + \frac{{1 - {t^2}}}{{1 + {t^2}}}}}} = \int {\frac{{2dt}}{{2t + 1 - {t^2}}}} = 2\int {\frac{{dt}}{{1 - \left( {{t^2} - 2t} \right)}}} = 2\int {\frac{{dt}}{{1 - \left( {{t^2} - 2t + 1 - 1} \right)}}} = 2\int {\frac{{dt}}{{2 - {{\left( {t - 1} \right)}^2}}}} = 2\int {\frac{{d\left( {t - 1} \right)}}{{{{\left( {\sqrt 2 } \right)}^2} - {{\left( {t - 1} \right)}^2}}}} = 2 \cdot \frac{1}{{2\sqrt 2 }}\ln \left| {\frac{{\sqrt 2 + \left( {t - 1} \right)}}{{\sqrt 2 - \left( {t - 1} \right)}}} \right| + C = \frac{1}{{\sqrt 2 }}\ln \left| {\frac{{\sqrt 2 - 1 + \tan \frac{x}{2}}}{{\sqrt 2 + 1 - \tan \frac{x}{2}}}} \right| + C.\], \[t = \tan \frac{x}{2},\;\; \Rightarrow x = 2\arctan t,\;\; dx = \frac{{2dt}}{{1 + {t^2}}},\;\; \sin x = \frac{{2t}}{{1 + {t^2}}},\;\; \cos x = \frac{{1 - {t^2}}}{{1 + {t^2}}}.\], \[\int {\frac{{dx}}{{\sin x + \cos x + 1}}} = \int {\frac{{\frac{{2dt}}{{1 + {t^2}}}}}{{\frac{{2t}}{{1 + {t^2}}} + \frac{{1 - {t^2}}}{{1 + {t^2}}} + 1}}} = \int {\frac{{\frac{{2dt}}{{1 + {t^2}}}}}{{\frac{{2t + 1 - {t^2} + 1 + {t^2}}}{{1 + {t^2}}}}}} = \int {\frac{{2dt}}{{2t + 2}}} = \int {\frac{{dt}}{{t + 1}}} = \ln \left| {t + 1} \right| + C = \ln \left| {\tan \frac{x}{2} + 1} \right| + C.\], \[I = \int {\frac{{dx}}{{\sec x + 1}}} = \int {\frac{{dx}}{{\frac{1}{{\cos x}} + 1}}} = \int {\frac{{\cos xdx}}{{1 + \cos x}}} .\], \[I = \int {\frac{{\cos xdx}}{{1 + \cos x}}} = \int {\frac{{\frac{{1 - {t^2}}}{{1 + {t^2}}} \cdot \frac{{2dt}}{{1 + {t^2}}}}}{{1 + \frac{{1 - {t^2}}}{{1 + {t^2}}}}}} = 2\int {\frac{{\frac{{1 - {t^2}}}{{{{\left( {1 + {t^2}} \right)}^2}}}dt}}{{\frac{{1 + {t^2} + 1 - {t^2}}}{{1 + {t^2}}}}}} = \int {\frac{{1 - {t^2}}}{{1 + {t^2}}}dt} = - \int {\frac{{1 + {t^2} - 2}}{{1 + {t^2}}}dt} = - \int {1dt} + 2\int {\frac{{dt}}{{1 + {t^2}}}} = - t + 2\arctan t + C = - \tan \frac{x}{2} + 2\arctan \left( {\tan \frac{x}{2}} \right) + C = x - \tan \frac{x}{2} + C.\], Trigonometric and Hyperbolic Substitutions. Now we see that $e=\left|\frac ba\right|$, and we can use the eccentric anomaly, Fact: Isomorphic curves over some field $K$ have the same $j$-invariant. Finally, as t goes from 1 to+, the point follows the part of the circle in the second quadrant from (0,1) to(1,0). Assume $\mathrm{char} K \ne 3$ (otherwise the curve is the same as $(X + Y)^3 = 1$). Die Weierstra-Substitution ist eine Methode aus dem mathematischen Teilgebiet der Analysis. Note that $$\frac{1}{a+b\cos(2y)}=\frac{1}{a+b(2\cos^2(y)-1)}=\frac{\sec^2(y)}{2b+(a-b)\sec^2(y)}=\frac{\sec^2(y)}{(a+b)+(a-b)\tan^2(y)}.$$ Hence $$\int \frac{dx}{a+b\cos(x)}=\int \frac{\sec^2(y)}{(a+b)+(a-b)\tan^2(y)} \, dy.$$ Now conclude with the substitution $t=\tan(y).$, Kepler found the substitution when he was trying to solve the equation As I'll show in a moment, this substitution leads to, $ = Your Mobile number and Email id will not be published. 1 Site design / logo 2023 Stack Exchange Inc; user contributions licensed under CC BY-SA. Integration by substitution to find the arc length of an ellipse in polar form. Weierstrass, Karl (1915) [1875]. in his 1768 integral calculus textbook,[3] and Adrien-Marie Legendre described the general method in 1817. Let M = ||f|| exists as f is a continuous function on a compact set [0, 1]. \begin{align} Weierstrass Theorem - an overview | ScienceDirect Topics {\textstyle t=\tan {\tfrac {x}{2}}} PDF Techniques of Integration - Northeastern University . So to get $\nu(t)$, you need to solve the integral Let \(K$ denote the field we are working in. The Weierstrass approximation theorem. Then Kepler's first law, the law of trajectory, is Instead of Prohorov's theorem, we prove here a bare-hands substitute for the special case S = R. When doing so, it is convenient to have the following notion of convergence of distribution functions. It is sometimes misattributed as the Weierstrass substitution. Integration of rational functions by partial fractions 26 5.1. has a flex x 2 t sin In the case = 0, we get the well-known perturbation theory for the sine-Gordon equation. Syntax; Advanced Search; New. of this paper: http://www.westga.edu/~faucette/research/Miracle.pdf. x In trigonometry, tangent half-angle formulas relate the tangent of half of an angle to trigonometric functions of the entire angle. &=\text{ln}|\text{tan}(x/2)|-\frac{\text{tan}^2(x/2)}{2} + C. He also derived a short elementary proof of Stone Weierstrass theorem. at {\displaystyle \operatorname {artanh} } Newton potential for Neumann problem on unit disk. x Weierstrass Trig Substitution Proof - Mathematics Stack Exchange = 2 \end{align} = 20 (1): 124135. Integrate $\int \frac{\sin{2x}}{\sin{x}+\cos^2{x}}dx$, Find the indefinite integral $\int \frac{25}{(3\cos(x)+4\sin(x))^2} dx$. MathWorld. Complex Analysis - Exam. How can Kepler know calculus before Newton/Leibniz were born ? d Bestimmung des Integrals ". \end{align*} Browse other questions tagged, Start here for a quick overview of the site, Detailed answers to any questions you might have, Discuss the workings and policies of this site. : Thus, dx=21+t2dt. $j = c_4^3 / \Delta$ for $\Delta \ne 0$. Then we can find polynomials pn(x) such that every pn converges uniformly to x on [a,b]. Example 3. As x varies, the point (cos x . , rearranging, and taking the square roots yields. weierstrass substitution proof. The Weierstrass Function Math 104 Proof of Theorem. 7.3: The Bolzano-Weierstrass Theorem - Mathematics LibreTexts assume the statement is false). \end{align} The method is known as the Weierstrass substitution. It only takes a minute to sign up. (c) Finally, use part b and the substitution y = f(x) to obtain the formula for R b a f(x)dx. . In other words, if f is a continuous real-valued function on [a, b] and if any > 0 is given, then there exist a polynomial P on [a, b] such that |f(x) P(x)| < , for every x in [a, b]. as follows: Using the double-angle formulas, introducing denominators equal to one thanks to the Pythagorean theorem, and then dividing numerators and denominators by f p < / M. We also know that 1 0 p(x)f (x) dx = 0. Thus, Let N M/(22), then for n N, we have. The German mathematician Karl Weierstrauss (18151897) noticed that the substitution t = tan(x/2) will convert any rational function of sin x and cos x into an ordinary rational function. the sum of the first n odds is n square proof by induction. cornell application graduate; conflict of nations: world war 3 unblocked; stone's throw farm shelbyville, ky; words to describe a supermodel; navy board schedule fy22 Die Weierstra-Substitution (auch unter Halbwinkelmethode bekannt) ist eine Methode aus dem mathematischen Teilgebiet der Analysis. that is, |f(x) f()| 2M [(x )/ ]2 + /2 x [0, 1]. We've added a "Necessary cookies only" option to the cookie consent popup, $\displaystyle\int_{0}^{2\pi}\frac{1}{a+ \cos\theta}\,d\theta$. or the $X$ term). Weierstrass theorem - Encyclopedia of Mathematics goes only once around the circle as t goes from to+, and never reaches the point(1,0), which is approached as a limit as t approaches. = = To subscribe to this RSS feed, copy and paste this URL into your RSS reader. Changing $u = t - \frac{2}{3},$ $du = dt$ gives the final answer: Make the universal trigonometric substitution: we can easily find the integral:we can easily find the integral: To simplify the integral, we use the Weierstrass substitution: As in the previous examples, we will use the universal trigonometric substitution: Since $\sin x = {\frac{{2t}}{{1 + {t^2}}}},$ $\cos x = {\frac{{1 - {t^2}}}{{1 + {t^2}}}},$ we can write: Making the ${\tan \frac{x}{2}}$ substitution, we have, Then the integral in $t-$terms is written as. 195200. Using Bezouts Theorem, it can be shown that every irreducible cubic In Ceccarelli, Marco (ed.). The tangent half-angle substitution parametrizes the unit circle centered at (0, 0). and Stack Exchange network consists of 181 Q&A communities including Stack Overflow, the largest, most trusted online community for developers to learn, share their knowledge, and build their careers. Moreover, since the partial sums are continuous (as nite sums of continuous functions), their uniform limit fis also continuous. A theorem obtained and originally formulated by K. Weierstrass in 1860 as a preparation lemma, used in the proofs of the existence and analytic nature of the implicit function of a complex variable defined by an equation $ f( z, w) = 0 $ whose left-hand side is a holomorphic function of two complex variables. \end{aligned} Tangent line to a function graph. one gets, Finally, since The technique of Weierstrass Substitution is also known as tangent half-angle substitution. {\displaystyle t,} The essence of this theorem is that no matter how much complicated the function f is given, we can always find a polynomial that is as close to f as we desire. Retrieved 2020-04-01. 5.2 Substitution The general substitution formula states that f0(g(x))g0(x)dx = f(g(x))+C . Integrating $I=\int^{\pi}_0\frac{x}{1-\cos{\beta}\sin{x}}dx$ without Weierstrass Substitution. \int{\frac{dx}{1+\text{sin}x}}&=\int{\frac{1}{1+2u/(1+u^{2})}\frac{2}{1+u^2}du} \\ The Bolzano-Weierstrass Theorem is at the foundation of many results in analysis. Now, fix [0, 1]. A point on (the right branch of) a hyperbola is given by(cosh , sinh ). Definition of Bernstein Polynomial: If f is a real valued function defined on [0, 1], then for n N, the nth Bernstein Polynomial of f is defined as, Proof: To prove the theorem on closed intervals [a,b], without loss of generality we can take the closed interval as [0, 1]. Furthermore, each of the lines (except the vertical line) intersects the unit circle in exactly two points, one of which is P. This determines a function from points on the unit circle to slopes. Let E C ( X) be a closed subalgebra in C ( X ): 1 E . Your Mobile number and Email id will not be published. {\textstyle u=\csc x-\cot x,} \int{\frac{dx}{\text{sin}x+\text{tan}x}}&=\int{\frac{1}{\frac{2u}{1+u^2}+\frac{2u}{1-u^2}}\frac{2}{1+u^2}du} \\ One can play an entirely analogous game with the hyperbolic functions. Proof by contradiction - key takeaways. = brian kim, cpa clearvalue tax net worth . x This is the one-dimensional stereographic projection of the unit circle parametrized by angle measure onto the real line. G Among these formulas are the following: From these one can derive identities expressing the sine, cosine, and tangent as functions of tangents of half-angles: Using double-angle formulae and the Pythagorean identity 2.4: The Bolazno-Weierstrass Theorem - Mathematics LibreTexts Instead of a closed bounded set Rp, we consider a compact space X and an algebra C ( X) of continuous real-valued functions on X. $$r=\frac{a(1-e^2)}{1+e\cos\nu}$$ Instead of + and , we have only one , at both ends of the real line. Proof of Weierstrass Approximation Theorem . By clicking Accept all cookies, you agree Stack Exchange can store cookies on your device and disclose information in accordance with our Cookie Policy. Elliptic Curves - The Weierstrass Form - Stanford University $$\begin{align}\int\frac{dx}{a+b\cos x}&=\frac1a\int\frac{d\nu}{1+e\cos\nu}=\frac12\frac1{\sqrt{1-e^2}}\int dE\\ Published by at 29, 2022. &=\int{\frac{2(1-u^{2})}{2u}du} \\ artanh {\displaystyle t,} PDF Chapter 2 The Weierstrass Preparation Theorem and applications - Queen's U By similarity of triangles. importance had been made. Karl Weierstrass, in full Karl Theodor Wilhelm Weierstrass, (born Oct. 31, 1815, Ostenfelde, Bavaria [Germany]died Feb. 19, 1897, Berlin), German mathematician, one of the founders of the modern theory of functions. Evaluate the integral \[\int {\frac{{dx}}{{1 + \sin x}}}.\], Evaluate the integral \[\int {\frac{{dx}}{{3 - 2\sin x}}}.\], Calculate the integral \[\int {\frac{{dx}}{{1 + \cos \frac{x}{2}}}}.\], Evaluate the integral \[\int {\frac{{dx}}{{1 + \cos 2x}}}.\], Compute the integral \[\int {\frac{{dx}}{{4 + 5\cos \frac{x}{2}}}}.\], Find the integral \[\int {\frac{{dx}}{{\sin x + \cos x}}}.\], Find the integral \[\int {\frac{{dx}}{{\sin x + \cos x + 1}}}.\], Evaluate \[\int {\frac{{dx}}{{\sec x + 1}}}.\]. When $a,b=1$ we can just multiply the numerator and denominator by $1-\cos x$ and that solves the problem nicely. 1 2 t Instead of + and , we have only one , at both ends of the real line. 2. As x varies, the point (cosx,sinx) winds repeatedly around the unit circle centered at(0,0). Draw the unit circle, and let P be the point (1, 0). , 193. Hoelder functions. (1) F(x) = R x2 1 tdt. \begin{align*} Substitute methods had to be invented to . The reason it is so powerful is that with Algebraic integrands you have numerous standard techniques for finding the AntiDerivative . . er. csc Weierstrass Substitution is also referred to as the Tangent Half Angle Method. Tangent half-angle substitution - Wikipedia For a proof of Prohorov's theorem, which is beyond the scope of these notes, see [Dud89, Theorem 11.5.4]. $\int \frac{dx}{\sin^3{x}}$ possible with universal substitution? cosx=cos2(x2)-sin2(x2)=(11+t2)2-(t1+t2)2=11+t2-t21+t2=1-t21+t2. I saw somewhere on Math Stack that there was a way of finding integrals in the form $$\int \frac{dx}{a+b \cos x}$$ without using Weierstrass substitution, which is the usual technique. (d) Use what you have proven to evaluate R e 1 lnxdx. . With or without the absolute value bars these formulas do not apply when both the numerator and denominator on the right-hand side are zero. Derivative of the inverse function. {\textstyle \csc x-\cot x} Try to generalize Additional Problem 2. Then the integral is written as. Finally, since t=tan(x2), solving for x yields that x=2arctant. The steps for a proof by contradiction are: Step 1: Take the statement, and assume that the contrary is true (i.e. $\qquad$. Tangent half-angle substitution - Wikiwand Weierstrass Function. Weisstein, Eric W. (2011). 2 PDF Calculus MATH 172-Fall 2017 Lecture Notes - Texas A&M University , . By eliminating phi between the directly above and the initial definition of &=\int{(\frac{1}{u}-u)du} \\ A simple calculation shows that on [0, 1], the maximum of z z2 is . 1. {\textstyle \csc x-\cot x=\tan {\tfrac {x}{2}}\colon }. {\displaystyle t} x Let f: [a,b] R be a real valued continuous function. tan PDF The Weierstrass Function - University of California, Berkeley csc pp. . p Is a PhD visitor considered as a visiting scholar. = \text{sin}x&=\frac{2u}{1+u^2} \\ The editors were, apart from Jan Berg and Eduard Winter, Friedrich Kambartel, Jaromir Loul, Edgar Morscher and . Following this path, we are able to obtain a system of differential equations that shows the amplitude and phase modulation of the approximate solution. Alternatives for evaluating $ \int \frac { 1 } { 5 + 4 \cos x} \ dx $ ?? The orbiting body has moved up to $Q^{\prime}$ at height The Bernstein Polynomial is used to approximate f on [0, 1]. PDF Math 1B: Calculus Worksheets - University of California, Berkeley . Weierstrass' preparation theorem. Categories . Polynomial functions are simple functions that even computers can easily process, hence the Weierstrass Approximation theorem has great practical as well as theoretical utility. and the integral reads Using \implies &\bbox[4pt, border:1.25pt solid #000000]{d\theta = \frac{2\,dt}{1 + t^{2}}} Some sources call these results the tangent-of-half-angle formulae . 2 Check it: Weierstrass Substitution : r/calculus - reddit cos An irreducibe cubic with a flex can be affinely a 2 &=\int{\frac{2du}{1+2u+u^2}} \\ All Categories; Metaphysics and Epistemology $\text{cos}\theta=\frac{BC}{AB}=\frac{1-u^2}{1+u^2}$. t Alternatively, first evaluate the indefinite integral, then apply the boundary values. It is just the Chain Rule, written in terms of integration via the undamenFtal Theorem of Calculus. {\textstyle t=\tan {\tfrac {x}{2}}} In integral calculus, the tangent half-angle substitution is a change of variables used for evaluating integrals, which converts a rational function of trigonometric functions of x {\\textstyle x} into an ordinary rational function of t {\\textstyle t} by setting t = tan x 2 {\\textstyle t=\\tan {\\tfrac {x}{2}}} .
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