The depth of water, in metres, at a certain point in a harbour varies with the tide and can be modelled by a function of the form $$f(t) = a + b \, cos \, ct$$ where $t$ is the time in hours from the first high tide on a particular Saturday and $a$, $b$, and $c$ are constants. (Note: $ct$ is expressed in radians.) On that Saturday, the following were noted: - The depth of the water in the harbour at high tide was 5-5 m - The depth of the water in the harbour at low tide was 1.7 m - High tide occurred at 02:00 and again at 14:34. (a) Use the information you are given to add, as accurately as you can, labelled and scaled axes to the diagram below to show the graph of $f$ over a portion of that Saturday. The point $P$ should represent the depth of the water in the harbour at high tide on that Saturday morning. (b) (i) Find the value of $a$ and the value of $b$. (ii) Show that $c = 0.5$, correct to 1 decimal place. (c) Use the equation $$f(t) = a + b \, cos \, ct$$ to find the times on that Saturday afternoon when the depth of the water in the harbour was exactly 5.2 m. Give each answer correct to the nearest minute.

Leaving Cert Mathematics Trigonometry: The depth of water, in metres, a

The depth of water, in metres, at a certain point in a harbour varies with the tide and can be modelled by a function of the form $$f(t) = a + b \, cos \, ct$$ where $t$ is the time in hours from the first high tide on a particular Saturday and $a$, $b$, and $c$ are constants - Leaving Cert Mathematics - Question 9 - 2017

Question 9

$The-depth-of-water,-in-metres,-at-a-certain-point-in-a-harbour-varies-with-the-tide-and-can-be-modelled-by-a-function-of-the-form--$$f(t)-=-a-+-b-\,-cos-\,-ct$$--where-$t$-is-the-time-in-hours-from-the-first-high-tide-on-a-particular-Saturday-and-$a$,-$b$,-and-$c$-are-constants-Leaving Cert Mathematics-Question 9-2017.png$

The depth of water, in metres, at a certain point in a harbour varies with the tide and can be modelled by a function of the form $$f(t) = a + b \, cos \, ct$$ whe... show full transcript

Worked Solution & Example Answer:The depth of water, in metres, at a certain point in a harbour varies with the tide and can be modelled by a function of the form $$f(t) = a + b \, cos \, ct$$ where $t$ is the time in hours from the first high tide on a particular Saturday and $a$, $b$, and $c$ are constants - Leaving Cert Mathematics - Question 9 - 2017

Step 1

Find the value of a and the value of b.

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Answer

To find the values of $a$ and $b$ , we can use the given information about high and low tides:

At high tide: $f(t) = a + b$ Given that high tide is 5.5 m, we can write: $a + b = 5.5$
At low tide: $f(t) = a - b$ Given that low tide is 1.7 m, we write: $a - b = 1.7$

Now we have the set of equations:

$a + b = 5.5$
$a - b = 1.7$

Solving these equations, we add them: $2a = 7.2 \implies a = 3.6$

Substituting $a$ back into the first equation: $3.6 + b = 5.5 \implies b = 1.9$

Thus, $a = 3.6$ and $b = 1.9$ .

Step 2

Show that c = 0.5, correct to 1 decimal place.

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Answer

To find the value of $c$ , we first need the period of the tide:

From the information:

High tide occurs at 02:00 and again at 14:34, which is 12 hours and 34 minutes later.
- Converting minutes, $34 \text{ minutes} = \frac{34}{60} \text{ hours} \approx 0.5667$ .
- So, $12 \frac{34}{60} \text{ hours} = 12.5667 \text{ hours}$ .

The period $T$ of the function is given by: $T = \frac{2\pi}{c}$ .

Using the calculated period, we find: $c = \frac{2\pi}{T} = \frac{2\pi}{12.5667} \approx 0.5$ ,

which is correct to 1 decimal place.

Step 3

Use the equation f(t) = a + b cos ct to find the times when the depth was 5.2 m.

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Answer

Using the equation $f(t) = a + b \cos ct$

we can substitute the known values:

depth = 5.2 m,
$5.2 = 3.6 + 1.9 \cos(0.5t)$ .

Rearranging gives: $1.9 \cos(0.5t) = 5.2 - 3.6$
$1.9 \cos(0.5t) = 1.6$

Dividing both sides by 1.9 leads to: $\cos(0.5t) = \frac{1.6}{1.9} \approx 0.8421$ .

Taking the inverse cosine yields: $0.5t = \cos^{-1}(0.8421) \approx 0.579$
thus, $t \approx \frac{0.579}{0.5} \approx 1.158 \text{ hours}$ .

We then solve for the other angle in the cosine function: $0.5t = 2\pi - 0.579$ leading to another solution.

Finally:

Converting 1.158 hours: $1.158 \text{ hours} \approx 1 \text{ hour and } 9 \text{ minutes}.$

Calculating for the times:

The first time: 14:34 + 1:09 = 15:43
The second time: Calculate accordingly to find each answer, giving the final times correct to the nearest minute.

Find the value of a and the value of b.

Show that c = 0.5, correct to 1 decimal place.

Use the equation f(t) = a + b cos ct to find the times when the depth was 5.2 m.

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