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Chapter 2: Problem 1

Find the derivative of the function. $$ f(x)=4 \cos x-2 x+1 $$

Short Answer

Expert verified
The derivative of the function \(f(x) = 4\cos x - 2x + 1\) is \(f'(x) = -4\sin x - 2\).

Step by step solution

01

Identify the individual terms of the function

The given function f(x) can be represented as a sum/difference of three separate terms: \(f(x) = \) (4 * cos(x)) - (2 * x) + 1
02

Differentiate each term

According to the sum/difference rule, the derivative of a sum/difference of functions is the sum/difference of their derivatives. We will now differentiate each term: 1. Differentiate 4 * cos(x): Apply both the constant rule and the derivative of cos(x): \( \frac{d}{dx}(4\cos x)= 4\frac{d}{dx}\cos x \) The derivative of cos(x) is - sin(x): \( \frac{d}{dx}(4\cos x)= 4(-\sin x)= -4\sin x \) 2. Differentiate 2 * x: Apply the constant rule and the derivative of x: \( \frac{d}{dx}(2x)= 2\frac{d}{dx}(x) \) The derivative of x is 1: \( \frac{d}{dx}(2x)= 2(1)= 2 \) 3. Differentiate 1: Since 1 is a constant, its derivative will be 0: \( \frac{d}{dx}(1) = 0 \)
03

Combine the derivatives to obtain the final solution

Now, we will put together the derivatives of each term to find the derivative of f(x): \(f'(x) = -4\sin x - 2 + 0 \) Simplifying the expression, we get: \(f'(x) = -4\sin x - 2 \) The derivative of the function f(x) = 4 * cos(x) - 2x + 1 is \(f'(x) = -4\sin x - 2\).

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Key Concepts

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

Sum/Difference Rule
Derivative calculations often begin by breaking down complex functions into simpler parts. The sum/difference rule is particularly useful for this purpose. When you have a function formed by the sum or difference of several terms, such as \(f(x) = 4\cos x - 2x + 1\), you can differentiate each component separately.

Here's why this is beneficial:
  • It simplifies complex expressions into manageable pieces.
  • Allows for the use of specific derivative rules for each term.
  • Ensures clarity and accuracy in calculating derivatives.
In our example, we separated the terms as \(4 \cos x\), \(-2x\), and \(1\). We then applied the sum/difference rule, which states: if \(f(x) = u(x) + v(x)\) or \(f(x) = u(x) - v(x)\), then \(f'(x) = u'(x) + v'(x)\) or \(f'(x) = u'(x) - v'(x)\). This approach makes the derivative much easier to compute.
Constant Rule
The constant rule is a straightforward yet essential tool in calculus. It helps when differentiating terms that involve constants. Essentially, if you have a constant multiplied by a function, the derivative of the product is the constant multiplied by the derivative of the function itself.

To understand this better, consider the term \(2x\). Applying the constant rule, the derivative \(d/dx\) of \(2x\) is simply \(2\times d/dx(x)\). And we know the derivative of \(x\) is \(1\). Therefore:
  • Calculate derivative of \(x\): \(d/dx(x) = 1\)
  • Apply constant: \(2 \times 1 = 2\)
Similarly, for a constant term like \(1\), the derivative is \(0\) because constants do not change. Always remember that multiplying by a constant simplifies the differentiation process.
Trigonometric Derivatives
Trigonometric derivatives are crucial for understanding and working with functions involving trigonometric identities, such as sine, cosine, and tangent. They have specific established rules for differentiation.

In our equation, we encountered the term \(\cos x\). The derivative of \(\cos x\) is \(-\sin x\). Using this rule, we differentiate \(4\cos x\) by applying both the trigonometric derivative and the constant rule, resulting in:
  • Differentiate \(\cos x\): \(d/dx(\cos x) = -\sin x\)
  • Multiply by the constant: \(4(-\sin x) = -4\sin x\)
Understanding these trigonometric derivatives allows you to solve a wide range of calculations involving periodic and oscillating functions. Each trigonometric function has its own specific derivative, which helps simplify various mathematical problems.

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Most popular questions from this chapter

A 20 -ft ladder leaning against a wall begins to slide. How fast is the angle between the ladder and the wall changing at the instant of time when the bottom of the ladder is \(12 \mathrm{ft}\) from the wall and sliding away from the wall at the rate of \(5 \mathrm{ft} / \mathrm{sec} ?\)

Forecasting Commodity Crops Government economists in a certain country have determined that the demand equation for soybeans is given by $$ p=f(x)=\frac{55}{2 x^{2}+1} $$ where the unit price \(p\) is expressed in dollars per bushel and \(x\), the quantity demanded per year, is measured in billions of bushels. The economists are forecasting a harvest of \(2.2\) billion bushels for the year, with a possible error of \(10 \%\) in their forecast. Determine the corresponding error in the predicted price per bushel of soybeans.

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Two curves are said to be orthogonal if their tangent lines are perpendicular at each point of intersection of the curves. In Exercises \(89-92\), show that the curves with the given equations are orthogonal. $$ x^{2}+3 y^{2}=4, \quad y=x^{3} $$

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