∫ calculus

1. The problem is to find the limit of the function as $x$ approaches 1, but the exact function is unclear from the input. 2. To solve a limit problem, we typically use substitutio

1. **State the problem:** We need to find the integral $$\int \frac{x}{x^2 + 1} \, dx.$$\n\n2. **Recall the formula and rules:** When integrating a rational function where the nume

1. The problem asks us to find the interval(s) where the curve $y=f(x)$, defined by $f(x)=\int_0^x \sqrt{1+t^4} \, dt$, is concave down. 2. Recall that the concavity of a function

1. **State the problem:** We need to find the limit $$\lim_{X \to \infty} \left(X - \frac{X}{\sqrt{X^2 + 3}}\right).$$ 2. **Rewrite the expression:** The expression inside the limi

1. **State the problem:** We need to find the integral $$Q = \int (A + BT + CT^2 + DT^3 + ET^4) \, dT$$ where constants are given as: $$A = 4.408$$

1. **State the problem:** We need to evaluate the definite integral $$Q = \int_{673}^{298} \left(A + BT + CT^2 + DT^3 + ET^4\right) d\tau$$ where $A = -118.442$, $B = 1.2856$, $C =

1. **State the problem:** We need to evaluate the definite integral $$Q = \int_{673}^{298} \left(A + BT + CT^2 + DT^3 + ET^4\right) dT$$ where constants are given as: $$A = -118.44

1. **State the problem:** We need to evaluate the definite integral $$Q = \int_{673}^{298} \left(A + BT + CT^2 + DT^3 + ET^4\right) dT$$ where the coefficients are given as: $$A =

1. **State the problem:** We need to evaluate the definite integral $$Q = \int_{398}^{673} (A + BT + CT^2 + DT^3 + ET^4) \, dT$$ where constants are given as: $$A = -118.442, \quad

1. **State the problem:** We need to evaluate the definite integral $$q = \int_6^{32} \sqrt{A + BT + CT^2 + DT^3 + ET^4} \, dT$$ where the constants are given as: $$A = -118.442, \

1. The problem asks us to prove the limit $$\lim_{n \to \infty} \left(2 - \frac{1}{n}\right) = 2.$$\n\n2. The formula for the limit of a sequence $$a_n$$ as $$n$$ approaches infini

1. **State the problem:** We need to evaluate the definite integral $$q = \int_{673}^{398} \left(A + B T + C T^2 + D T^3 + E T^4\right) dT$$ where the constants are given as: $$A =

1. **Problem Statement:** Determine the limits of the function $f(x)$ at the specified points from the graph. 2. **Recall:** The limit $\lim_{x \to a^+} f(x)$ means the value that

1. The problem involves evaluating the integral expression for $Q^{398}_{673} = \int (A + B T + C T^{2} + D T^{3} + E T^{4}) \, dT$ given constants and values. 2. The integral of a

1. The problem involves evaluating the integral expression $$Q^{398}_{673} = \int_{673}^{398} (A + B T + C T^2 + D T^3 + E T^4) \, dT$$ where constants $C$, $D$, and $E$ are given,

1. **Problem 1:** Evaluate $$\lim_{x \to 16} \frac{\sqrt{x} - 4}{\sqrt{\sqrt{x} - 2}}$$ - We notice direct substitution gives $$\frac{4 - 4}{\sqrt{4 - 2}} = \frac{0}{\sqrt{2}} = 0$

1. **State the problem:** Find the value of the function $y = 4 - \frac{2}{x^2}$ at $x = -2$ and determine the equation of the tangent line at this point. 2. **Evaluate the functio

1. **Stating the problem:** Find the equation of the tangent line to a curve at a given point. 2. **Formula used:** The equation of the tangent line to the curve $y=f(x)$ at the po

1. **State the problem:** Find the value of the function $y = 2x(x - 3)^3$ at $x = 2$ and determine the equation of the tangent line at this point. 2. **Evaluate the function at $x

1. **Problem a:** Find the equation of the tangent to the curve $$y=\sqrt{x+1}-a+x=4$$. 2. **Step 1:** Clarify the function. The equation seems ambiguous. Assuming the function is

1. **State the problem:** We need to find the integral $$\int \frac{\cos 2x}{\sin^3 2x} \, dx$$. 2. **Rewrite the integral:** Notice that the integral can be written as $$\int \cos