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CLP-4 Vector Calculus

Section A.4 Table of Integrals

Throughout this table, \(a\) and \(b\) are given constants, independent of \(x\) and \(C\) is an arbitrary constant.
\(f(x)\) \(F(x)=\int f(x)\ \dee{x}\)
\(af(x)+bg(x)\) \(a\int f(x)\ \dee{x}+b\int g(x)\ \dee{x}\ +\ C\)
\(f(x)+g(x)\) \(\int f(x)\ \dee{x}+\int g(x)\ \dee{x}\ +\ C\)
\(f(x)-g(x)\) \(\int f(x)\ \dee{x}-\int g(x)\ \dee{x}\ +\ C\)
\(af(x)\) \(a\int f(x)\ \dee{x}\ +\ C\)
\(u(x)v'(x)\) \(u(x)v(x)-\int u'(x)v(x)\ \dee{x}\ +\ C\)
\(f\big(y(x)\big)y'(x)\) \(F\big(y(x)\big)\hbox{ where }F(y)=\int f(y)\ \dee{y}\)
\(a\) \(ax+C\)
\(x^a\) \(\frac{x^{a+1}}{a+1}+C\hbox{ if }a\ne-1\)
\(\frac{1}{x}\) \(\ln|x|+C\)
\(g(x)^ag'(x)\) \(\frac{g(x)^{a+1}}{a+1}+C\hbox{ if }a\ne -1\)
\(f(x)\) \(F(x)=\int f(x)\ \dee{x}\)
\(\sin x\) \(-\cos x+C\)
\(g'(x)\sin g(x)\) \(-\cos g(x)+C\)
\(\cos x\) \(\sin x+C\)
\(\tan x\) \(\ln|\sec x|+C\)
\(\csc x\) \(\ln |\csc x-\cot x|+C\)
\(\sec x\) \(\ln |\sec x+\tan x|+C\)
\(\cot x\) \(\ln|\sin x|+C\)
\(\sec^2 x\) \(\tan x+C\)
\(\csc^2 x\) \(-\cot x+C\)
\(\sec x\tan x\) \(\sec x+C\)
\(\csc x\cot x\) \(-\csc x+C\)
\(f(x)\) \(F(x)=\int f(x)\ \dee{x}\)
\(e^x\) \(e^x+C\)
\(e^{g(x)}g'(x)\) \(e^{g(x)}+C\)
\(e^{ax}\) \(\frac{1}{a}\ e^{ax}+C\)
\(a^x\) \(\frac{1}{\ln a}\ a^x+C\)
\(\ln x\) \(x\ln x -x+C\)
\(\frac{1}{\sqrt{1-x^2}}\) \(\arcsin x+C\)
\(\frac{g'(x)}{\sqrt{1-g(x)^2}}\) \(\arcsin g(x)+C\)
\(\frac{1}{\sqrt{a^2-x^2}}\) \(\arcsin \frac{x}{a}+C\)
\(\frac{1}{1+x^2}\) \(\arctan x+C\)
\(\frac{g'(x)}{1+g(x)^2}\) \(\arctan g(x)+C\)
\(\frac{1}{a^2+x^2}\) \(\frac{1}{a}\arctan \frac{x}{a}+C\)
\(\frac{1}{x\sqrt{x^2-1}}\) \(\arcsec x+C\hbox{ for }x \gt 1\)