An indefinite integral represents the family of all antiderivatives of a function. The result includes a constant of integration \(C\).

\[\int f(x)\,dx = F(x) + C\]

\[\int x^n\,dx = \frac{x^{n+1}}{n+1} + C\]

\[\int ax^n\,dx = a \cdot \frac{x^{n+1}}{n+1} + C\]

• Constant: \(\int k\,dx = kx + C\)
• Linear: \(\int x\,dx = \frac{x^2}{2} + C\)
• Square: \(\int x^2\,dx = \frac{x^3}{3} + C\)
• Negative power: \(\int x^{-2}\,dx = -x^{-1} + C = -\frac{1}{x} + C\)

\[\int kf(x)\,dx = k\int f(x)\,dx\]

\[\int [f(x) \pm g(x)]\,dx = \int f(x)\,dx \pm \int g(x)\,dx\]

\[\int \sin x\,dx = -\cos x + C\]

\[\int \cos x\,dx = \sin x + C\]

\[\int \sec^2 x\,dx = \tan x + C\]

\[\int e^x\,dx = e^x + C\]

\[\int \frac{1}{x}\,dx = \ln|x| + C\]

For \(f(ax + b)\), divide by the coefficient of \(x\)

\[\int (ax + b)^n\,dx = \frac{(ax + b)^{n+1}}{a(n+1)} + C\]

\[\int \sin(ax + b)\,dx = -\frac{1}{a}\cos(ax + b) + C\]

\[\int \cos(ax + b)\,dx = \frac{1}{a}\sin(ax + b) + C\]

\[\int e^{ax + b}\,dx = \frac{1}{a}e^{ax + b} + C\]

\[\int \frac{1}{ax + b}\,dx = \frac{1}{a}\ln|ax + b| + C\]

\[\int_a^b f(x)\,dx = F(b) - F(a)\]

\[\int_a^b f(x)\,dx = \left[F(x)\right]_a^b\]

• No constant \(C\) needed for definite integrals
• \(\int_a^a f(x)\,dx = 0\) (same limits)
• \(\int_a^b f(x)\,dx = -\int_b^a f(x)\,dx\) (swap limits)
• \(\int_a^b f(x)\,dx + \int_b^c f(x)\,dx = \int_a^c f(x)\,dx\) (split intervals)

\[\text{Area} = \int_a^b f(x)\,dx\]

\[\text{Area} = -\int_a^b f(x)\,dx = \int_a^b |f(x)|\,dx\]

Split at x-intercepts and calculate each region separately, taking absolute values

\[\text{Area} = \int_a^b [f(x) - g(x)]\,dx\]

1. Find intersection points to determine limits
2. Identify which function is above the other
3. Integrate (upper - lower)
4. If curves cross, split into regions

1. Choose substitution \(u = g(x)\)
2. Find \(\frac{du}{dx}\), then \(dx = \frac{du}{du/dx}\)
3. Substitute into integral
4. Integrate with respect to \(u\)
5. Substitute back to express in terms of \(x\)

• Change limits: when \(x = a\), find \(u = g(a)\); when \(x = b\), find \(u = g(b)\)
• No need to substitute back
• Integrate directly with new limits

\[\int u\,dv = uv - \int v\,du\]

\[\int u(x)v'(x)\,dx = u(x)v(x) - \int u'(x)v(x)\,dx\]

Priority for \(u\) (first that appears):
Logarithmic → Inverse trig → Algebraic → Trigonometric → Exponential

\[V = \pi\int_a^b [f(x)]^2\,dx\]

\[V = \pi\int_c^d [g(y)]^2\,dy\]

Rotate a 2D area 360° around an axis to create a 3D solid. The volume is calculated by summing infinite circular disk cross-sections.

\[v(t) = \int a(t)\,dt\]

\[s(t) = \int v(t)\,dt\]

\[\text{Distance} = \int_{t_1}^{t_2} |v(t)|\,dt\]

• Acceleration \(\xrightarrow{\text{integrate}}\) Velocity \(\xrightarrow{\text{integrate}}\) Displacement
• Displacement \(\xrightarrow{\text{differentiate}}\) Velocity \(\xrightarrow{\text{differentiate}}\) Acceleration