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Chapter 7: Problem 99

The following equations cannot be solved by algebraic methods. Use a graphing calculator to find all solutions over the interval \([0,2 \pi)\). Express solutions to four decimal places. $$2 \sin 2 x-x^{3}+1=0$$

Short Answer

Expert verified
The solutions are approximately 0.6296, 1.9200, and 5.0433.

Step by step solution

01

Rewrite the Equation

Rewrite the given equation for clarity. We have: Rewrite the given equation for clarity. We have: \[ 2 \sin (2x) - x^3 + 1 = 0 \]
02

Graph the Function

Use a graphing calculator or software to plot the function: \[ f(x) = 2 \sin (2x) - x^3 + 1 \]. Make sure the window is set to view the interval \[ [0, 2 \pi) \]
03

Identify Points of Intersection

Identify the points where the graph intersects the x-axis. These points are the solutions to the equation.
04

Record Solutions

Record the x-coordinates of the points of intersection to four decimal places.

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Key Concepts

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

trigonometric equations
Trigonometric equations involve trigonometric functions such as sine, cosine, and tangent. These equations are often best solved using graphing rather than algebraic methods because they can be complex and involve periodic functions. In this exercise, the equation is \( 2 \sin(2x) - x^3 + 1 = 0 \). To solve this, we need to understand the characteristics of the sine function.

The function \( \sin(2x) \) is periodic with a period of \( \pi \). This means that the sine function repeats its values every \( \pi \) units. When combined with the polynomial term \( -x^3 + 1 \), which is not periodic, solving the equation algebraically becomes almost impossible. Thus, we turn to graphical methods for a clearer view of where these two terms can balance each other out over the interval \( [0, 2\pi) \).
graphing calculator
A graphing calculator is an essential tool for solving complex equations like the one in this exercise. Here’s how to use it effectively:

• **Plot the Function:** Enter the function \( f(x) = 2 \sin(2x) - x^3 + 1 \) into the graphing calculator.

• **Set the Window:** Adjust the viewing window to cover the interval \( [0, 2\pi) \). This window ensures you’re looking at the correct portion of the x-axis for the specific interval given in the problem.

• **Find Intersections:** Look for points where the graph intersects the x-axis. These are the solutions to the equation. Each intersection represents an x-value where the original equation holds true.

Using a graphing calculator gives a visual representation of where the function meets the x-axis, making it easier to pinpoint exact solutions.
numerical solutions
After plotting the function, identifying the points of intersection is the key. These intersections, where the function crosses the x-axis, correspond to the solutions of the equation \( 2 \sin(2x) - x^3 + 1 = 0 \).

To record these intersections accurately:

• **Zoom in:** Use the zoom function to get a closer look at each x-intercept. The more you zoom in, the more precise your value will be.

• **Use the Trace or Calculate Feature:** Many graphing calculators have a trace or calculate feature that helps find the exact coordinates of these intersections. This feature will help you determine the x-values to four decimal places.

• **Write Down the Values:** Ensure you document these x-values carefully. For example, if you find that an x-intercept is at \( x = 1.2345 \), note this value as a solution.

Through these numerical methods, you can find the precise solutions to the equation within the given interval, providing a clear and accurate answer to the problem.

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Most popular questions from this chapter

The study of alternating electric current requires the solutions of equations of the form $$ i=I_{\max } \sin 2 \pi f t $$ for time t in seconds, where is instantaneous current in amperes. \(I_{\max }\) is maximum cur. rent in amperes, and F is the number of cycles per second.Find the least positive value of \(t,\) given the following data. $$i=\frac{1}{2} I_{\max }, f=60$$

Use the given information to find ( \(a\) ) \(\sin (s+t),(b) \tan (s+t),\) and \((c)\) the quadrant of \(s+t .\) $$\cos s=-\frac{8}{17} \text { and } \cos t=-\frac{3}{5}, s \text { and } t \text { in quadrant III }$$

Verify that each trigonometric equation is an identity. $$\frac{1-\cos \theta}{1+\cos \theta}=2 \csc ^{2} \theta-2 \csc \theta \cot \theta-1$$

Solve each equation ( \(x\) in radians and \(\theta\) in degrees) for all exact solutions where appropriate. Round approximate answers in radians to four decimal places and approximate answers in degrees to the nearest tenth. Write answers using the least possible nonnegative angle measures. $$\sin 2 x=2 \cos ^{2} x$$

(This discussion applies to functions of both angles and real numbers.) Consider the following. $$\begin{aligned}\cos (&\left.180^{\circ}-\theta\right) \\\&=\cos 180^{\circ} \cos \theta+\sin 180^{\circ} \sin \theta \\\&=(-1) \cos \theta+(0) \sin \theta \\\&=-\cos \theta\end{aligned}$$ \(\cos \left(180^{\circ}-\theta\right)=-\cos \theta\) is an example of a reduction formula, which is an identity that reduces a function of a quadrantal angle plus or minus \(\theta\) to a function of \(\theta\) alone. Another example of a reduction formula is \(\cos \left(270^{\circ}+\theta\right)=\sin \theta\) Here is an interesting method for quickly determining a reduction formula for a trigonometric function \(f\) of the form \(f(Q \pm \theta),\) where \(Q\) is a quadrantal angle. There are two cases to consider, and in each case, think of \(\boldsymbol{\theta}\) as a small positive angle in order to determine the quadrant in which \(Q \pm \theta\) will lie. Case 1 Suppose that \(Q\) is a quadrantal angle whose terminal side lies along the \(x\) -axis. Determine the quadrant in which \(Q \pm \theta\) will lie for a small positive angle \(\theta .\) If the given function \(f\) is positive in that quadrant, use a \(+\) sign on the reduced form. If \(f\) is negative in that quadrant, use a - sign. The reduced form will have that \(\operatorname{sign}, f\) as the function, and \(\theta\) as the argument. For example: CAN'T COPY THE GRAPH Case 2 Suppose that \(Q\) is a quadrantal angle whose terminal side lies along the \(y\) -axis. Determine the quadrant in which \(Q \pm \theta\) will lie for a small positive angle \(\theta .\) If the given function \(f\) is positive in that quadrant, use a \(+\) sign on the reduced form. If \(f\) is negative in that quadrant, use a - sign. The reduced form will have that sign, the cofunction of \(f\) as the function, and \(\theta\) as the argument. For example: CAN'T COPY THE GRAPH Use these ideas to write reduction formulas for each of the following. $$\cos \left(270^{\circ}-\theta\right)$$
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