∫tan²(x)dx
To solve the integral ∫tan²(x)dx, we can use the trigonometric identity:
tan²(x) = sec²(x) – 1
So, the integral becomes:
∫(sec²(x) – 1)dx
Expanding this, we have:
∫sec²(x)dx – ∫dx
The first integral, ∫sec²(x)dx, can be easily solved by recognizing that it is the derivative of the tangent function:
∫sec²(x)dx = tan(x) + C
The second integral, ∫dx, represents the integral of a constant, which is simply the variable itself:
∫dx = x + C
Putting it all together, the final solution to the integral ∫tan²(x)dx is:
tan(x) – x + C
Where C is the constant of integration
To solve the integral ∫tan²(x)dx, we can use the trigonometric identity:
tan²(x) = sec²(x) – 1
So, the integral becomes:
∫(sec²(x) – 1)dx
Expanding this, we have:
∫sec²(x)dx – ∫dx
The first integral, ∫sec²(x)dx, can be easily solved by recognizing that it is the derivative of the tangent function:
∫sec²(x)dx = tan(x) + C
The second integral, ∫dx, represents the integral of a constant, which is simply the variable itself:
∫dx = x + C
Putting it all together, the final solution to the integral ∫tan²(x)dx is:
tan(x) – x + C
Where C is the constant of integration.
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