Find the general solution of each of the following differential equations. \(\left(1-x^{2}\right) d y-\left(x y+2 x \sqrt{1-x^{2}}\right) d x=0\)

When dealing with first-order differential equations, recognizing exact equations is crucial. Exact differential equations are those where we can find a function whose differential equals the given equation. In mathematical terms, an equation of the form M(x, y)dx + N(x, y)dy = 0 is exact if it meets the condition: \ \(\frac{\partial M}{\partial y} = \frac{\partial N}{\partial x}\). This means that the mixed partial derivatives of some potential function \varphi(x, y) are equal.
To verify if the given equation is exact, as shown in the step-by-step solution, calculate the partial derivatives \(\frac{\partial M}{\partial y}\) and \(\frac{\partial N}{\partial x}\). If they are equal, the equation is exact, otherwise, it is not. If not exact, like in the example, we need an integrating factor to proceed.

When a differential equation isn’t exact, we can sometimes make it exact by multiplying through by an integrating factor. The integrating factor is typically a function that, when multiplied by the entire equation, turns it into an exact differential equation. Determining the integrating factor can be trickier, but in the case of functions that are primarily a function of \(x\) or \(y\), we can sometimes guess it.
For the equation \(-(xy + 2x\sqrt{1 - x^2})dx + (1 - x^2)dy = 0\), an integrating factor was guessed as \(\mu(x) = \frac{1}{1 - x^2}\). When applying \(\mu(x)\), every term in the equation gets multiplied by it. The goal is to turn the equation into an exact form where the partial derivatives match. Always verify by recalculating the partial derivatives after applying the integrating factor.

Partial derivatives lie at the heart of understanding and solving exact differential equations. The partial derivative of a function with respect to one variable is its derivative while holding the other variable constant. In our context, you need to calculate \(\frac{\partial M}{\partial y}\) and \(\frac{\partial N}{\partial x}\) to check the exactness.
For the exactness test in our exercise: calculate \(\frac{\partial M}{\partial y} = -x\) and \(\frac{\partial N}{\partial x} = -2x\). Because these are not equal, the given equation isn’t initially exact. Understanding how to compute these partial derivatives correctly is fundamental, and it's essential for identifying whether an equation is exact, or determining how to alter it to make it exact.

Integration techniques help solve the differential equation once it is exact (or made exact through an integrating factor). Integration involves finding the antiderivative or integral of a function which effectively reverses differentiation.
In the step-by-step solution provided, integrating both sides of the simplified equation involves specific techniques. For instance, integrating \(dy\) with respect to \(y\) straightforwardly gives \(y\). However, integrating the right side, \(\int \frac{xy + 2x\sqrt{1 - x^2}}{x^2 - 1} dx\) could require substitution or breaking down the expression into simpler parts.
When dealing with complex integrals, use substitution to simplify the variable involvement. For example, setting a new variable like \(u = 1 - x^2\) can transform an unwieldy integral into a more manageable form, easing the integration process.
The result of integrating both sides provides the general solution, which includes a constant \(C\), acknowledging the indefinite nature of the integrals involved.