QCM : LOGARITHMIC LIMITS AND DERIVATIVES — 8 questions

Explication

The derivative of the product of two functions is given by the product rule, which states that (uv)' = u'v + uv'. This rule specifically describes how to differentiate a product of functions, making it the correct answer.

Explication

The primitive of the function $rac{u'}{u}$, where $u$ is differentiable and non-zero, is $ ext{ln}|u| + C$. This is a standard result in calculus, derived from the chain rule for the logarithm function.

Explication

The limit of ln x as x approaches zero from the right is -∞, which helps in analyzing the behavior of functions involving logarithms near zero, especially in limits and asymptotic analysis.

Explication

The limit of $ ext{ln } x$ as $x o + ext{infinity}$ was established during the development of calculus in the late 17th century, when mathematicians like Newton and Leibniz formalized the properties of logarithms and limits.

Explication

Both limits involve the logarithm function approaching unbounded values at boundary points, with $ ext{ln} x o -inite$ as $x o 0^+$ and $ ext{ln} x o +inite$ as $x o +inite$. They are similar in that both are unbounded, but differ in the direction of divergence.

Explication

Leonhard Euler is credited with formalizing the properties of the natural logarithm, including its primitive function and its relation to derivatives of ratios like u'/u. His work in the 18th century established these foundational concepts in calculus.

Explication

When $U(x)$ approaches zero from the right, $ ext{ln}(U(x))$ tends to negative infinity. This is because the natural logarithm function tends to $- ext{infinity}$ as its argument approaches zero from the positive side, reflecting the unbounded decrease of the logarithm near zero.

Explication

As x approaches infinity, \\text{ln}(x^2 + 1) behaves like \\text{ln}(x^2) = 2\\text{ln} x, which grows slower than x. Therefore, the ratio \\frac{ ext{ln}(x^2 + 1)}{x} tends to 0, applying the limit laws and properties of logarithms.