Question

Perform the indicated integrations. $$ \int \frac{2 x d x}{\sqrt{1-x^{4}}} $$

Short answer

The integral is complex and typically requires special functions or numerical methods to fully solve.

Step-by-step solution

Identify Integration Technique

Observe the integral \( \int \frac{2x \, dx}{\sqrt{1 - x^4}} \). Notice that a substitution method is appropriate due to the non-trivial expression \(1 - x^4\) under the square root in the denominator. This expression suggests a potential trigonometric substitution or another suitable transformation to simplify the integrand.

Choose a Trigonometric Substitution

To simplify \( \sqrt{1 - x^4} \), choose the substitution \( x^2 = \sin(\theta) \), implying \( x = \sqrt{\sin(\theta)} \). Differentiating both sides gives \( 2x \, dx = \cos(\theta) \sqrt{\sin(\theta)} \, d\theta \). The integral becomes \( \int \frac{\cos(\theta) \sqrt{\sin(\theta)} \, d\theta}{\sqrt{1-\sin^2(\theta)}} \). The expression \( \sqrt{1-\sin^2(\theta)} \) simplifies to \( \cos(\theta) \).

Simplify the Expression

Simplify the integral using the identity \( \sqrt{1-\sin^2(\theta)} = \cos(\theta) \). Substitute this into the integral to get \( \int \frac{\cos(\theta) \sqrt{\sin(\theta)} \, d\theta}{\cos(\theta)} \), which simplifies to \( \int \sqrt{\sin(\theta)} \, d\theta \).

Evaluate the Simplified Integral

Now, the task is to integrate \( \sqrt{\sin(\theta)} \, d\theta \). Utilizing suitable integration techniques or tables, the integral evaluates to an expression involving the incomplete beta function or can be expressed for particular forms using known results.

Substitute Back to Original Variable

Once the integral is evaluated according to the complexity of the approach, substitute back using the relation \( x^2 = \sin(\theta) \), leading to the solution to the original integral in terms of \( x \). Since we arrived at an advanced integration that generally requires comprehensive solutions, the precise evaluation would depend on fine calculus techniques or numerical estimation.

Key concepts

Trigonometric Substitution

Trigonometric substitution is a clever technique for simplifying integrals, especially when involving square roots. Consider the integral \( \int \frac{2x \, dx}{\sqrt{1 - x^4}} \). The form \( \sqrt{1 - x^4} \) hints that a substitution can simplify the expression. By using trigonometric identities to replace complex algebraic expressions with trigonometric functions, we transform difficult integrals into more manageable ones.

In this problem, substituting \( x^2 = \sin(\theta) \) transforms the problem. Differentiating gives \( 2x \, dx = \cos(\theta) \sqrt{\sin(\theta)} \, d\theta \). This substitution effectively changes the variable and setup to more easily integrate the expression.

• Substitution Method: Simplifies expressions by replacing variables with trigonometric identities.
• Identity Used: \( \sqrt{1 - x^4} \to \cos(\theta) \).

By doing this, we've transformed the complicated original integral into a simpler form: \( \int \sqrt{\sin(\theta)} \, d\theta \).

Square Root Integration

Integrating expressions that involve square roots often requires special techniques or substitutions to simplify the process. In the integral \( \int \frac{2x \, dx}{\sqrt{1-x^4}} \), simplifying the square root expression \( \sqrt{1-x^4} \) is a key step. This is where trigonometric substitution plays a role to handle such integrals.

To reach a solvable form, rewrite the integral using substitution like \( x^2 = \sin(\theta) \). This step turns \( \sqrt{1-x^4} \) into a trigonometric identity, such as \( \cos(\theta) \), which is much easier to handle when integrating.

• Challenges: Direct square root integration can be complex without substitution.
• Simplification: Trigonometric identities simplify root expressions.

This technique results in a new expression, \( \int \sqrt{\sin(\theta)} \, d\theta \), which is generally easier to integrate than the original square root form.

Incomplete Beta Function

The incomplete beta function is a special mathematical function that can appear when dealing with advanced integrals. After the trigonometric substitution and simplification in the given integral problem, integrating \( \int \sqrt{\sin(\theta)} \, d\theta \) can lead to expressions involving the incomplete beta function.

The incomplete beta function is defined as \[B_x(a, b) = \int_0^x t^{a-1}(1-t)^{b-1} \, dt\]for parameters \( a \) and \( b \), and \( t \) being the integration variable. In contexts like these integrals, it helps express the results of complex integration problems that are not easily solvable by elementary functions.

• Utility: Expresses complex integral solutions.
• Parameters: Involves variables and values from transformed integrals.

Knowing when and how to use such functions can greatly simplify the process of evaluating integrals in calculus, particularly when standard techniques do not suffice.