Evaluate \(\int e^{(a+i b) x} d x\) and take real and imaginary parts to show that: $$\int e^{a x} \cos b x d x=\frac{e^{a x}(a \cos b x+b \sin b x)}{a^{2}+b^{2}}$$

Complex integration involves integrating functions that have complex numbers. Complex numbers include both real and imaginary parts, written as \(a + ib\), where \(a\) is the real part and \(ib\) represents the imaginary part. An integral like \(\int e^{(a+ib)x} dx\) combines these real and imaginary components.
To approach this, we first break down the exponential function using the properties of exponents: \(e^{(a+ib)x} = e^{ax} \times e^{ibx}\). Then, we use the basic rule for integrating exponentials: \(\int e^{cx} dx = \frac{e^{cx}}{c} + C\). Here, \(c = a + ib\).
Next, we simplify the fraction \(\frac{1}{a+ib}\) by multiplying by the conjugate: \(\frac{a-ib}{(a+ib)(a-ib)} = \frac{a-ib}{a^2+b^2}\). This helps us separate the real and imaginary parts more easily.

Euler's formula is a key tool in complex analysis. It states that \(e^{i\theta} = \cos \theta + i \sin \theta\). This formula allows us to express complex exponentials in terms of sine and cosine, which are easier to handle. When applying Euler's formula to our integral, we get: \(e^{(a+ib)x} = e^{ax} \times (\cos(bx) + i \sin(bx))\).
In this case, substituting back into our integral, we can more easily recognize the real and imaginary components. This simplification helps to directly identify the real part required in the problem statement.
With Euler's formula, we split our complex function such that we can apply real number operations to solve them.

To solve the integral involving complex numbers, it's crucial to separate the expression into its real and imaginary parts. Using Euler's formula, we can represent the integral result as: \(\frac{e^{ax}(a\cos(bx) + ai\sin(bx) - ib\cos(bx) - b\sin(bx))}{a^2+b^2} + C\).
By grouping the real parts together and the imaginary parts together, we identify the real component: \(\frac{e^{ax}(a \cos bx + b \sin bx)}{a^2 + b^2}\).
This method highlights how understanding each part of a complex function leads to determining the final real and imaginary components.