I have noticed experimentally that:
$$\int_{0}^{1} \frac{\color{red}{x}}{x^4+2x^3+2x^2-2x+1} dx=\color{blue}{\frac{\pi}{8}},\tag{1}$$
$$\int_{0}^{1} \frac{\color{red}{1-x^2}}{x^4+2x^3+2x^2-2x+1} dx=\color{blue}{\frac{\pi}{4}},\tag{2}$$
$$\int_{0}^{1} \frac{\color{red}{1+x-x^2}}{x^4+2x^3+2x^2-2x+1} dx=\color{blue}{\frac{3\pi}{8}}.\tag{3}$$
So slight variations in the numerator *always* seem to produce something like $n\pi$, where $n$ is a rational number.
At [MathSE][1] I have asked what the exact relationship is between $n$ and the integrand, to which Quanto  has responded with a general formula:
$$\int_{0}^{1} \frac{ax^2 +b x + c}{x^4+2x^3+2x^2-2x+1} dx
=\frac\pi8(c+b-a)+\frac\pi{3\sqrt3}(a+c).\tag{4}$$
However, is it necessary for the denominator to remain fixed? Not really. The following integral is formula (34) in this list of [$\pi$ formulas][2]:
$$\int_{0}^{1} \frac{\color{red}{16x-16}}{x^4-2x^3+4x-4}\,dx=\color{blue}{\pi}.\tag{5}$$
Notice that the denominator is different. But again, a slight variation in the denominator and it *still* produces something like $n\pi$:
$$\int_{0}^{1} \frac{\color{red}{x^2-x-1}}{x^4-2x^3+4x-4}\,dx=\color{blue}{\frac{3\pi}{16}}.\tag{6}$$
The fact that the denominator is not the same suggests that a further generalization is possible.

Here is my question: **is it possible to characterize the integrand $\frac{P(x)}{Q(x)}$ in such a way that by simple inspection we can say $I=n\pi$? Or in other words, what should be the relationship between the coefficients of the numerator and the denominator for the integral to yield $n\pi$?**

  [1]: https://math.stackexchange.com/questions/4736889/a-curious-family-of-integrals-that-give-pi
  [2]: https://mathworld.wolfram.com/PiFormulas.html