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Chapter 6: Problem 45

Exer. \(37-46:\) Verify the identity. $$\frac{1}{\cot \alpha-\cot \beta}=\frac{\sin \alpha \sin \beta}{\sin (\beta-\alpha)}$$

Short Answer

Expert verified
The identity is verified.

Step by step solution

01

Simplify the Left Side

The expression on the left side is \( \frac{1}{\cot \alpha - \cot \beta} \). Start by expressing cotangents in terms of sine and cosine: \( \cot \alpha = \frac{\cos \alpha}{\sin \alpha} \) and \( \cot \beta = \frac{\cos \beta}{\sin \beta} \). Thus, \( \cot \alpha - \cot \beta = \frac{\cos \alpha}{\sin \alpha} - \frac{\cos \beta}{\sin \beta} \).
02

Combine the Fractions

Combine \( \frac{\cos \alpha}{\sin \alpha} - \frac{\cos \beta}{\sin \beta} \) into a single fraction: \[ \frac{\cos \alpha \sin \beta - \cos \beta \sin \alpha}{\sin \alpha \sin \beta} \].
03

Simplify Further Using Trigonometric Identities

The numerator \( \cos \alpha \sin \beta - \cos \beta \sin \alpha \) can be simplified using the sine difference identity: \( \cos \alpha \sin \beta - \cos \beta \sin \alpha = \sin(\beta - \alpha) \).
04

Take the Reciprocal

Substitute \( \sin(\beta - \alpha) \) for the numerator in the fraction: \[ \frac{\sin(\beta - \alpha)}{\sin \alpha \sin \beta} \]. Taking the reciprocal, we gain \( \frac{\sin \alpha \sin \beta}{\sin(\beta - \alpha)} \).
05

Compare with the Right Side

The expression is now \( \frac{\sin \alpha \sin \beta}{\sin(\beta - \alpha)} \), which matches the right side of the given identity, confirming the identity is verified.

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Key Concepts

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

Sine Difference Identity
The Sine Difference Identity is a fundamental trigonometric identity that simplifies expressions involving the sine function of the difference of two angles. The formula is given by:
  • \[ \sin(a - b) = \sin a \cos b - \cos a \sin b \]
This identity helps in verifying trigonometric equations and transformations. In the provided exercise, this identity was instrumental in simplifying the numerator \( \cos \alpha \sin \beta - \cos \beta \sin \alpha \). By recognizing this expression as \( \sin(\beta - \alpha) \), we were able to transform the original equation into a simpler form, leading directly to the verification of the identity. Understanding how to use the sine difference identity is crucial for tackling a wide range of trigonometric problems. It showcases how identities can make simplification more manageable and elegant.
Cotangent
The cotangent function is one of the lesser-used trigonometric functions, compared to sine, cosine, and tangent. It is defined as the reciprocal of the tangent function:
  • \[ \cot \theta = \frac{1}{\tan \theta} = \frac{\cos \theta}{\sin \theta} \]
This gives us a unique way to express relationships in trigonometry. In the exercise, we used the definition of cotangent to re-express the difference \( \cot \alpha - \cot \beta \) in terms of sine and cosine. This step was key in reaching a common denominator, which then allowed us to use the sine difference identity. Having a strong grasp of the cotangent’s role as a reciprocal of tangent helps in understanding its relationships with sine and cosine.
Trigonometric Simplification
Trigonometric simplification involves reducing complex trigonometric expressions to simpler forms. This is done using identities and algebraic manipulation. In the solution to the provided exercise, the main simplification process involved rewriting the terms in a way that allowed the identities to be applied efficiently.
  • Transforming \( \cot \alpha - \cot \beta \) into a single fraction was a crucial step.
  • Recognizing the numerator as a sine difference identity further simplified the work.
This process highlights the importance of recognizing patterns and applying identities not just mechanically, but strategically. Simplifying expressions not only confirms identities but also boosts understanding of the connections between trigonometric functions.
Reciprocal Identities
Reciprocal identities are basic trigonometric identities that express the main trigonometric functions as reciprocals of one another. For example:
  • \( \tan \theta = \frac{1}{\cot \theta} \)
  • \( \cot \theta = \frac{1}{\tan \theta} \)
  • \( \sec \theta = \frac{1}{\cos \theta} \)
  • \( \csc \theta = \frac{1}{\sin \theta} \)
These identities are vital in transforming and simplifying expressions involving trigonometric functions. In the exercise, understanding that \( \cot \alpha \) can be expressed as \( \frac{1}{\tan \alpha} \) helped in re-expressing the problem in terms of sine and cosine. This step perpetuates simplification by breaking down complex ratios into more manageable components using basic operations. Reciprocity is a potent tool in the algebra of trigonometry.

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Most popular questions from this chapter

n designing a collector for solar power, an important consideration is the amount of sunlight that is transmitted through the glass into the water being heated. If the angle of incidence \(\theta\) of the sun's rays is measured from a line perpendicular to the surface of the glass, then the fraction \(f(\theta)\) of sunlight reflected off the glass can be approximated by $$f(\theta)=\frac{1}{2}\left(\frac{\sin ^{2} \alpha}{\sin ^{2} \beta}+\frac{\tan ^{2} \alpha}{\tan ^{2} \beta}\right) $$where$$\alpha=\theta-\gamma, \quad \beta=\theta+\gamma, \quad \text { and } \quad \gamma=\sin ^{-1}\left(\frac{\sin \theta}{1.52}\right)$$ Graph \(f\) for \(0<\theta<\pi / 2,\) and estimate \(\theta\) when \(f(\theta)=0.2\)

Write the expression as an algebraic expression in \(x\) for \(x>0\). $$\cos \left(\frac{1}{2} \arccos x\right)$$

Either show that the equation \(i s\) an identity or show that the equation \(is\quad not\) an identity. $$\frac{\tan ^{2} x}{\sec x-1}=\sec x$$

Sketch the graph of the equation. $$y=\frac{1}{2} \sin ^{-1} x$$

Many calculators have viewing sereens that are wider than they are high. The approximate ratio of the height to the width is often \(2: 3 .\) Let the actual height of the calculator screen along the \(y\) -axis be 2 units, the actual width of the calculator screen along the \(x\) -axis be 3 units, and Xscl \(=\mathbf{Y s c}=1 .\) since the line \(y=x\) must pass through the point \((1,1),\) the actual slope \(m_{A}\) of this line on the calcuIator screen is given by $$m_{A}=\frac{\text { actual distance between tick marks on } y \text { -axis }}{\text { actual distance between tick marks on } x \text { -axis }}$$ Using this information, graph \(y=x\) in the given viewing rectangle and predict the actual angle \(\boldsymbol{\theta}\) that the graph makes with the \(x\) -axis on the viewing screen. \([0,3]\) by \([0,2]\)
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