Pregunta
\( \begin{array}{ll}5 & \text { Use compound and double angles to prove that: } \\ 5.1 & \sin 3 x=3 \sin x-4 \sin ^{3} x \\ 5.2 & \cos 3 x=\cos x\left(1-4 \sin ^{2} x\right) \\ 5.3 & \cos 4 x=8 \cos ^{4} x-8 \cos ^{2} x+1 \\ 5.4 & 1-\cos 4 x=2 \sin ^{2} 2 x \\ 5.5 & \sin 4 x=\cos x\left(4 \sin x-8 \sin ^{3}\right) \\ 5.6 & \sin 4 x=4 \sin x \cos ^{3} x-4 \cos x \sin ^{3} x\end{array} \)
Ask by Lambert Stewart. in South Africa
Mar 10,2025
Solución de inteligencia artificial de Upstudy
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Here are the simplified proofs for each identity:
1. **5.1**
\( \sin 3x = 3\sin x - 4\sin^3 x \)
2. **5.2**
\( \cos 3x = \cos x\left(1 - 4\sin^2 x\right) \)
3. **5.3**
\( \cos 4x = 8\cos^4 x - 8\cos^2 x + 1 \)
4. **5.4**
\( 1 - \cos 4x = 2\sin^2 2x \)
5. **5.5**
\( \sin 4x = \cos x\left(4\sin x - 8\sin^3 x\right) \)
6. **5.6**
\( \sin 4x = 4\sin x\cos^3 x - 4\cos x\sin^3 x \)
Each identity is proven using compound and double-angle formulas.
Solución
**5.1 Proof that \( \sin 3x = 3\sin x - 4\sin^3 x \):**
1. Write \( 3x \) as \( 2x + x \):
\[
\sin 3x = \sin(2x + x) = \sin 2x \cos x + \cos 2x \sin x
\]
2. Use the double‐angle identities:
\[
\sin 2x = 2\sin x \cos x,\quad \cos 2x = 1 - 2\sin^2 x
\]
Substitute these:
\[
\sin 3x = (2\sin x \cos x)\cos x + (1-2\sin^2 x)\sin x
\]
3. Simplify:
\[
\sin 3x = 2\sin x \cos^2 x + \sin x - 2\sin^3 x
\]
4. Express \( \cos^2 x \) in terms of \( \sin^2 x \):
\[
\cos^2 x = 1-\sin^2 x
\]
Then,
\[
\sin 3x = 2\sin x(1-\sin^2 x) + \sin x - 2\sin^3 x = 2\sin x - 2\sin^3 x + \sin x - 2\sin^3 x
\]
5. Combine like terms:
\[
\sin 3x = 3\sin x - 4\sin^3 x
\]
---
**5.2 Proof that \( \cos 3x = \cos x\left(1 - 4\sin^2 x\right) \):**
1. Express \( 3x \) as \( 2x + x \):
\[
\cos 3x = \cos(2x + x) = \cos 2x\cos x - \sin 2x\sin x
\]
2. Substitute the double‐angle formulas:
\[
\cos 2x = 1-2\sin^2 x,\quad \sin 2x = 2\sin x\cos x
\]
Then,
\[
\cos 3x = (1-2\sin^2 x)\cos x - (2\sin x\cos x)\sin x
\]
3. Simplify:
\[
\cos 3x = \cos x-2\sin^2 x\cos x-2\sin^2 x\cos x = \cos x - 4\sin^2 x\cos x
\]
4. Factor out \( \cos x \):
\[
\cos 3x = \cos x\left(1-4\sin^2 x\right)
\]
---
**5.3 Proof that \( \cos 4x = 8\cos^4 x - 8\cos^2 x + 1 \):**
1. Write \( 4x \) as \( 2(2x) \):
\[
\cos 4x = 2\cos^2 2x - 1
\]
2. Express \( \cos 2x \) in terms of \( \cos x \):
\[
\cos 2x = 2\cos^2 x - 1
\]
Thus,
\[
\cos^2 2x = (2\cos^2 x - 1)^2 = 4\cos^4 x - 4\cos^2 x + 1
\]
3. Substitute back into the formula for \( \cos4x \):
\[
\cos 4x = 2(4\cos^4 x - 4\cos^2 x + 1) - 1 = 8\cos^4 x - 8\cos^2 x + 2 - 1
\]
4. Simplify to obtain:
\[
\cos 4x = 8\cos^4 x - 8\cos^2 x + 1
\]
---
**5.4 Proof that \( 1-\cos 4x = 2\sin^2 2x \):**
1. Using the result from 5.3:
\[
\cos 4x = 8\cos^4 x - 8\cos^2 x + 1
\]
So,
\[
1 - \cos 4x = 1 - (8\cos^4 x - 8\cos^2 x + 1) = -8\cos^4 x + 8\cos^2 x
\]
2. Factor out \( 8\cos^2 x \):
\[
1 - \cos 4x = 8\cos^2 x(1-\cos^2 x)
\]
3. Recognize that \( 1-\cos^2 x = \sin^2 x \):
\[
1 - \cos 4x = 8\cos^2 x\sin^2 x
\]
4. Now, use the double-angle identity for sine:
\[
\sin 2x = 2\sin x\cos x \quad \Longrightarrow \quad \sin^2 2x = 4\sin^2 x\cos^2 x
\]
5. Substitute to match the expression:
\[
8\cos^2 x\sin^2 x = 2\bigl(4\sin^2 x\cos^2 x\bigr) = 2\sin^2 2x
\]
Thus,
\[
1-\cos 4x = 2\sin^2 2x
\]
---
**5.5 Proof that \( \sin 4x = \cos x\left(4\sin x - 8\sin^3 x\right) \):**
1. Start with the double-angle expansion for \( \sin 4x \):
\[
\sin 4x = 2\sin 2x \cos 2x
\]
2. Write \( \sin 2x \) and \( \cos 2x \) in terms of \( \sin x \) and \( \cos x \):
\[
\sin 2x = 2\sin x\cos x,\quad \cos 2x = 1-2\sin^2 x
\]
3. Substitute these into the formula:
\[
\sin 4x = 2\,(2\sin x\cos x)\,(1-2\sin^2 x)= 4\sin x\cos x\,(1-2\sin^2 x)
\]
4. Distribute \( 4\sin x\cos x \):
\[
\sin 4x = 4\sin x\cos x - 8\sin^3 x\cos x
\]
5. Factor out \( \cos x \):
\[
\sin 4x = \cos x\left(4\sin x-8\sin^3 x\right)
\]
---
**5.6 Proof that \( \sin 4x = 4\sin x\cos^3 x - 4\cos x\sin^3 x \):**
1. Begin with the expression from 5.5:
\[
\sin 4x = 4\sin x\cos x - 8\sin^3 x\cos x
\]
2. Alternatively, express \( \sin 4x \) using the sine addition formula for \( 2x+2x \):
\[
\sin 4x = \sin(2x+2x) = \sin 2x\cos 2x + \cos 2x\sin 2x = 2\sin 2x \cos 2x
\]
3. Substitute the double-angle identities:
\[
\sin 2x = 2\sin x\cos x,\quad \cos 2x = 2\cos^2 x - 1
\]
Then,
\[
\sin 4x = 2\,(2\sin x\cos x)(2\cos^2 x-1) = 4\sin x\cos x(2\cos^2 x-1)
\]
4. Expand the product:
\[
\sin 4x = 8\sin x\cos^3 x - 4\sin x\cos x
\]
5. Factor \( 4\sin x\cos x \) from the original forms:
\[
\sin 4x = 4\sin x\cos x\left(2\cos^2 x - 1\right)
\]
6. Express \( 2\cos^2 x-1 \) in a form that highlights a difference:
\[
2\cos^2 x - 1 = (\cos^2 x - \sin^2 x)
\]
(using the identity \( \cos^2 x - \sin^2 x = 2\cos^2 x-1 \))
7. Thus, we have:
\[
\sin 4x = 4\sin x\cos x(\cos^2 x - \sin^2 x)
\]
8. Now, distribute to write the expression as:
\[
\sin 4x = 4\sin x\cos^3 x - 4\sin x\cos x\sin^2 x
\]
9. Recognize that \( \sin x\cos x\sin^2 x = \cos x\sin^3 x \), so:
\[
\sin 4x = 4\sin x\cos^3 x - 4\cos x\sin^3 x
\]
Each of the identities is now proven using compound and double angle formulas.
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Simplifique esta solución Extra Insights
To understand these trigonometric identities better, let’s dive into the magic behind them! The identity \( \sin 3x = 3 \sin x - 4 \sin^3 x \) can be derived using the angle addition formula \( \sin(a + b) \). By expressing \( \sin 3x \) as \( \sin(2x + x) \) and applying the formulas repeatedly, you can see how these polynomial forms pop up! The expression for \( \cos 4x = 8 \cos^4 x - 8 \cos^2 x + 1 \) is another classic example of utilizing double angles. By starting with \( \cos 2x = 2\cos^2 x - 1 \) and substituting it twice, you arrive at a beautifully simplified polynomial equation. Each time we wield the double-angle or triple-angle identities, we reveal a deeper understanding of the circular waveforms we see in trigonometry!
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