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Chapter 3: Problem 8

Find the derivative of the following functions. $$f(t)=t^{11}$$

Short Answer

Expert verified
Answer: The derivative of the function $$f(t)=t^{11}$$ is $$11t^{10}$$.

Step by step solution

01

Identify the exponent in the given function

In the given function, the exponent is 11. So, our n value is 11.
02

Apply the power rule

Now, using the power rule, we'll find the derivative of the given function: $$\frac{d}{dt}t^{11} = 11 \cdot t^{11-1}$$
03

Simplify the expression

Simplify the expression to get the final derivative: $$\frac{d}{dt}t^{11} = 11 \cdot t^{10}$$ So, the derivative of the function $$f(t)=t^{11}$$ is $$11t^{10}$$.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Power Rule
The Power Rule is a fundamental theorem in calculus that greatly simplifies the process of differentiation, especially when dealing with polynomial functions. When you have a function in the form of \( f(x) = x^n \), where \( n \) is a constant exponent, the Power Rule enables you to easily find its derivative. To apply the Power Rule, follow this simple formula:
  • Identify the exponent \( n \) in your function.
  • Multiply the entire term by this exponent.
  • Subtract one from the exponent to find the new exponent.
  • Your derivative will then be \( nx^{n-1} \).
For example, if you have \( f(t) = t^{11} \), by applying the Power Rule, the derivative becomes \( 11t^{10} \). This process turns a complex-looking term into a manageable expression that gives us the slope at any point \( t \) along the function curve.
Exponentiation
Exponentiation is a mathematical operation involving two numbers, the base and the exponent. In polynomial functions like \( f(t) = t^{11} \), exponentiation describes raising the base \( t \) to the power of \( 11 \), represented as \( t^{11} \). Here’s what each part means:
  • The base \( t \) represents the number that is multiplied by itself.
  • The exponent 11 signifies how many times the base is used as a factor in multiplication.
As a simple example, \( t^3 = t \times t \times t \). In our original exercise, \( t^{11} \) means multiplying \( t \) by itself 11 times. This concept is crucial for employing the Power Rule, as the derivative heavily depends on manipulating this exponent. Thus, understanding how exponentiation works allows you to apply the Power Rule efficiently in calculus.
Differentiation
Differentiation is a key concept in calculus, primarily used to find the derivative of a function. A derivative represents the rate at which a function is changing at any given point and is fundamental in understanding the behavior of functions. When differentiating a function like \( f(t) = t^{11} \), the goal is to determine \( \frac{d}{dt}t^{11} \). This process involves applying established rules such as the Power Rule to simplify the function into a derivative. Differentiation has crucial applications across many fields including physics, engineering, and economics, as it provides insights into the slope of a curve, optimization problems, and rates of change. By mastering the technique of differentiation, you can solve complex problems and better understand how different mathematical functions behave and transform.

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Most popular questions from this chapter

Orthogonal trajectories Two curves are orthogonal to each other if their tangent lines are perpendicular at each point of intersection (recall that two lines are perpendicular to each other if their slopes are negative reciprocals). A family of curves forms orthogonal trajectories with another family of curves if each curve in one family is orthogonal to each curve in the other family. For example, the parabolas \(y=c x^{2}\) form orthogonal trajectories with the family of ellipses \(x^{2}+2 y^{2}=k,\) where \(c\) and \(k\) are constants (see figure). Find \(d y / d x\) for each equation of the following pairs. Use the derivatives to explain why the families of curves form orthogonal trajectories. \(y=c x^{2} ; x^{2}+2 y^{2}=k,\) where \(c\) and \(k\) are constants

A spring hangs from the ceiling at equilibrium with a mass attached to its end. Suppose you pull downward on the mass and release it 10 inches below its equilibrium position with an upward push. The distance \(x\) (in inches) of the mass from its equilibrium position after \(t\) seconds is given by the function \(x(t)=10 \sin t-10 \cos t,\) where \(x\) is positive when the mass is above the equilibrium position. a. Graph and interpret this function. b. Find \(\frac{d x}{d t}\) and interpret the meaning of this derivative. c. At what times is the velocity of the mass zero? d. The function given here is a model for the motion of an object on a spring. In what ways is this model unrealistic?

Complete the following steps. a. Find equations of all lines tangent to the curve at the given value of \(x\). b. Graph the tangent lines on the given graph. \(4 x^{3}=y^{2}(4-x) ; x=2\) (cissoid of Diocles)

A cylindrical tank is full at time \(t=0\) when a valve in the bottom of the tank is opened. By Torricelli's Law, the volume of water in the tank after \(t\) hours is \(V=100(200-t)^{2}\), measured in cubic meters. a. Graph the volume function. What is the volume of water in the tank before the valve is opened? b. How long does it take the tank to empty? c. Find the rate at which water flows from the tank and plot the flow rate function. d. At what time is the magnitude of the flow rate a minimum? A maximum?

One of the Leibniz Rules One of several Leibniz Rules in calculus deals with higher-order derivatives of products. Let \((f g)^{(n)}\) denote the \(n\) th derivative of the product \(f g,\) for \(n \geq 1\) a. Prove that \((f g)^{(2)}=f^{\prime \prime} g+2 f^{\prime} g^{\prime}+f g^{\prime \prime}\) b. Prove that, in general, $$(f g)^{(n)}=\sum_{k=0}^{n}\left(\begin{array}{l} n \\ k \end{array}\right) f^{(k)} g^{(n-k)}$$ where \(\left(\begin{array}{l}n \\ k\end{array}\right)=\frac{n !}{k !(n-k) !}\) are the binomial coefficients. c. Compare the result of (b) to the expansion of \((a+b)^{n}\)
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