Physics
- Astrophysics
- Astronomy
- Nuclear Physics
- Quantum Physics
Maths
- Matrix Multiplication
- Integration
Integration
Integration is a calculus operation and the inverse operation of differentiation. It finds the area under the function's line on a graph. It turns up a lot throughout physics, much to my chagrin. It may be important but I don't have to like it.
General rules
Integrating a constant
$\int a\,dx=ax+C$
Integrating x
$\int x\,dx=\frac{x^{n+1}}{n+1}+C$
Integrating constant coefficients (ax)
$\int ax\,dx=a\int x\,dx$
Adding/subtracting integrals
$\int u\pm v\,dx=\int u\,dx+\int v\,dx$
Integrating inverse functions
$\int \frac{1}{x}\,dx=\ln{x}+C$
Integrating the natural log (ln)
$\int \ln{x}\,dx= x\ln{x}-x+C$
Integrating exponentials
$\int a^x\,dx=\frac{a^x}{\ln{a}}+C$
Integrating the exponential function
$\int e^x\,dx=e^x+C$
Integrating sin(x)
$\int \sin{x}\,dx=-\cos{x}+C$
Integrating cos(x)
$\int \cos{x}\,dx=\sin{x}+C$
Integrating sec$^2$
$\int \sec^2{x}\,dx=\tan{x}+C$
Reverse Chain Rule/Integration by Substitution
Subsitution is used when functions are nested, much like chain rule. There are three main versions of this method, some of which are for specific situations:
Version 1: Find a complex part of the function of x and let it equal u. Find du/dx, and hence du, which you can substitute into the integral and solve. (Apply u to the limits when definite).
Version 2: $\int f(g(x))g'(x)\,dx=\int f(u)\,dx$. When definite: $\int_{a}^b f(g(x))g'(x)\,dx=\int_{g(a)}^{g(b)} f(u)\,dx$
Version 3: $\int{\frac{1}{ax+b}}\,dx=\frac{1}{a}\ln{|ax+b|}+c$
Integration by Parts
$\int uv'\,dx=uv-\int vu'\,dx$
or equivalently
$\int_{a}^{b}uv'\,dx=[uv]^a_b-\int_{a}^{b}vu'\,dx$
Choose the easiest to integrate part to be v’!
Symbols and Definitions
$\int dx$: Integral w.r.t. $x$.
$u$: function of x ($u(x)$), or, when subsituting, a section of a function of x.
$v$: function of x ($v(x)$)
$a$: constant
$b$: constant
$n$: constant
$C$: constant of integration
$f(x)$: function of x
$f'(x)$: derivative of a function of x ($\frac{\delta f(x)}{\delta x}$)