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A solid is formed by rotating the region bounded by the curve $y = x(x - 1)^2$ and the line $y = 0$ about the y-axis - HSC - SSCE Mathematics Extension 2 - Question 5 - 2006 - Paper 1

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A solid is formed by rotating the region bounded by the curve $y = x(x - 1)^2$ and the line $y = 0$ about the y-axis. Use the method of cylindrical shells to find th... show full transcript

Worked Solution & Example Answer:A solid is formed by rotating the region bounded by the curve $y = x(x - 1)^2$ and the line $y = 0$ about the y-axis - HSC - SSCE Mathematics Extension 2 - Question 5 - 2006 - Paper 1

Step 1

A solid is formed by rotating the region bounded by the curve $y = x(x - 1)^2$ and the line $y = 0$ about the y-axis. Use the method of cylindrical shells to find the volume of this solid.

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Answer

To find the volume of the solid, we apply the method of cylindrical shells:

  1. The formula for the volume using cylindrical shells is given by: V=2πabxf(x)dxV = 2\pi \int_a^b x f(x) \, dx where f(x)=y=x(x1)2f(x) = y = x(x - 1)^2 and the limits of integration are determined from the points where the curve intersects the line y=0y = 0.
  2. We first find the x-intercepts of y=x(x1)2y = x(x - 1)^2:
    • Setting y=0y = 0, we find x=0x = 0 and x=1x = 1 (the points of intersection).
  3. Thus, the volume is: V=2π01x[x(x1)2]dx=2π01(x32x2+x)dxV = 2\pi \int_0^1 x[x(x - 1)^2] \, dx = 2\pi \int_0^1 (x^3 - 2x^2 + x) \, dx
  4. Now, calculating the integral: =2π[x442x33+x22]01=2π(1423+12)= 2\pi \left[ \frac{x^4}{4} - \frac{2x^3}{3} + \frac{x^2}{2} \right]_0^1 = 2\pi \left( \frac{1}{4} - \frac{2}{3} + \frac{1}{2} \right)
  5. Simplifying this expression will yield the volume.

Step 2

(b) (i) Show that $\cos(\alpha + \beta) + \cos(\alpha - \beta) = 2\cos \alpha \cos \beta$.

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Answer

To show this identity:

  1. We can use the cosine angle addition formula: cos(α+β)=cosαcosβsinαsinβ\cos(\alpha + \beta) = \cos \alpha \cos \beta - \sin \alpha \sin \beta cos(αβ)=cosαcosβ+sinαsinβ\cos(\alpha - \beta) = \cos \alpha \cos \beta + \sin \alpha \sin \beta
  2. By adding the two equations: cos(α+β)+cos(αβ)=2cosαcosβ\cos(\alpha + \beta) + \cos(\alpha - \beta) = 2\cos \alpha \cos \beta This proves the identity as required.

Step 3

(b) (ii) Hence, or otherwise, solve the equation $\cos^4 + \cos 2\theta + \cos 3\theta + \cos 4\theta = 0$ for $0 \leq \theta \leq 2\pi$.

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Answer

To solve the equation:

  1. From part (i), we know how to relate angles using cosines. We first apply the identities:
    • Rewrite cos2θ\cos 2\theta, cos3θ\cos 3\theta, and cos4θ\cos 4\theta using double angle formulas.
  2. Substitute:
    • The equation simplifies to a polynomial which can be factored or solved numerically.
  3. The roots can be found in the given interval by testing values or using numerical methods.

Step 4

(c) (i) Resolve the forces on P in the horizontal and vertical directions.

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Answer

To resolve the forces on particle P:

  1. In the horizontal direction, the tension T1T_1 provides a component: T1sinαT_1 \sin \alpha This is the centripetal force due to the motion, equal to mω2rm \omega^2 r.
  2. In the vertical direction, we balance the forces: T1cosα+T2=mgT_1 \cos \alpha + T_2 = mg where T2T_2 is the tension in the second string.

Step 5

(c) (ii) If $T_2=0$, find the value of $\omega$ in terms of $l$, $g$, and $\alpha$.

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Answer

To find ω\omega under the condition that T2=0T_2 = 0:

  1. We start from the vertical force equation: T1cosα=mgT_1 \cos \alpha = mg Thus, we express T1T_1: T1=mgcosαT_1 = \frac{mg}{\cos \alpha}
  2. Using the horizontal component: T1sinα=mω2lT_1 \sin \alpha = m \omega^2 l Substituting for T1T_1: mgsinαcosα=mω2l\frac{mg \sin \alpha}{\cos \alpha} = m \omega^2 l
  3. Simplifying and solving for ω\omega, we get: ω=gtanαl\omega = \sqrt{\frac{g \tan \alpha}{l}}

Step 6

(d) (i) How many different recordings are possible?

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Answer

To find the number of different recordings:

  1. For each of the four games, there are three potential outcomes (Win, Draw, Loss). Thus, 34=813^4 = 81 different outcomes are possible.

Step 7

(d) (ii) Calculate the probability of the result which is recorded as WDLD.

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Answer

To calculate the probability of the result WDLD:

  1. The probability of each outcome is:
    • Win (W): 0.2
    • Draw (D): 0.6
    • Loss (L): 0.2
  2. Thus, the probability of WDLD is: P(WDLD)=P(W)P(D)P(L)P(D)=0.20.60.20.6=0.0144P(WDLD) = P(W) \cdot P(D) \cdot P(L) \cdot P(D) = 0.2 \cdot 0.6 \cdot 0.2 \cdot 0.6 = 0.0144.

Step 8

(d) (iii) What is the probability that the Home team scores more points than the Away team?

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Answer

To find this probability:

  1. The scoring system gives:
    • 1 point for a win, \frac{1}{2} point for a draw, and 0 points for a loss.
  2. Considering all configurations of outcomes, we can calculate the expected scores and compare.
  3. This leads us to a binomial probability distribution, where we can compute individual probabilities and sum accordingly to find the desired probability.

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