The Global Positioning System (GPS) uses satellites to support navigation on Earth. One GPS satellite is in a circular orbit at a height $h$ above the surface of the Earth. The Earth has mass $M$ and radius $R$. Show that the angular speed $\omega$ of the satellite is given by $$\omega = \frac{GM}{(R+h)^{3/2}}$$ Calculate the orbital period of the satellite when $h$ equals $2.02 \times 10^{7} \, m$. Figure 3 shows the orbital plane of the satellite inclined at an angle to the equator. $X$, $Y$ and $Z$ are locations on the Earth. $X$ is at the North Pole, $Y$ is on a high mountain and $Z$ is on the equator. The satellite is to be launched from one of the locations. State and explain which launch site $X$, $Y$ or $Z$ minimizes the amount of fuel required to send the satellite into its orbit. The satellite has a mass of 1630 kg. Calculate the gravitational potential energy of the satellite when in the orbit in Question 02.2. A different satellite is in a higher circular orbit. Explain how the linear speed of this satellite compares with the linear speed of the satellite in Question 02.1.

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The Global Positioning System (GPS) uses satellites to support navigation on Earth - AQA - A-Level Physics - Question 2 - 2021 - Paper 2

Question 2

The Global Positioning System (GPS) uses satellites to support navigation on Earth. One GPS satellite is in a circular orbit at a height $h$ above the surface of th... show full transcript

Worked Solution & Example Answer:The Global Positioning System (GPS) uses satellites to support navigation on Earth - AQA - A-Level Physics - Question 2 - 2021 - Paper 2

Step 1

Show that the angular speed $\omega$ of the satellite is given by $\omega = \frac{GM}{(R+h)^{3/2}}$

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Answer

To derive the angular speed, we start with the gravitational force acting on the satellite, which provides the necessary centripetal force for circular motion:

$F = \frac{GMm}{(R+h)^{2}} = m\frac{v^{2}}{(R+h)}$

Here, $F$ is the gravitational force, $M$ is the mass of Earth, $m$ is the mass of the satellite, $R$ is the radius of the Earth, $h$ is the height above the surface, and $v$ is the orbital speed of the satellite.

Cancelling $m$ , we rearrange to find:

$\frac{v^{2}}{(R+h)} = \frac{GM}{(R+h)^{2}}$

Multiplying through by $(R+h)$ gives:

$v^{2} = \frac{GM}{(R+h)}$

The angular velocity $\omega$ is related to the tangential speed $v$ by:

$\omega = \frac{v}{(R+h)}$

Substituting for $v$ , we have:

$\omega = \frac{\sqrt{\frac{GM}{(R+h)}}}{(R+h)} = \frac{GM}{(R+h)^{3/2}}$

Step 2

Calculate the orbital period of the satellite when $h$ equals $2.02 \times 10^{7} \, m$

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Answer

To calculate the orbital period $T$ , we use:

$T = \frac{2\pi}{\omega}$

Substituting our expression for $\omega$ :

$T = \frac{2\pi (R+h)^{3/2}}{\sqrt{GM}}$

Plugging in the values:

$R = 6.371 \times 10^{6} \, m$
$h = 2.02 \times 10^{7} \, m$
$G = 6.674 \times 10^{-11} \, m^{3}kg^{-1}s^{-2}$
$M = 5.972 \times 10^{24} \, kg$

Calculating:

$h = 2.02 \times 10^{7} + 6.371 \times 10^{6} = 2.6571 \times 10^{7} \, m$

Then substituting values to compute $T$ .

Step 3

State and explain which launch site $X$, $Y$ or $Z$ minimizes the amount of fuel required to send the satellite into its orbit.

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Answer

The optimal launch site is $Z$ , which is on the equator. Launching from the equator allows the satellite to take advantage of the Earth's rotational speed, reducing the amount of fuel needed to achieve orbit. Launching from higher latitudes, like $X$ at the North Pole, requires additional fuel to achieve the necessary speed and trajectory.

Step 4

Calculate the gravitational potential energy of the satellite when in the orbit in Question 02.2.

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Answer

The gravitational potential energy $U$ is given by:

$U = -\frac{GMm}{R+h}$

Using the values:

$G = 6.674 \times 10^{-11} \, m^{3}kg^{-1}s^{-2}$
$M = 5.972 \times 10^{24} \, kg$
$m = 1630 \, kg$
$R + h = 2.6571 \times 10^{7} \, m$

Substituting these into the equation gives:

$U = -\frac{6.674 \times 10^{-11} \cdot 5.972 \times 10^{24} \cdot 1630}{2.6571 \times 10^{7}}$

Now compute value for $U$ .

Step 5

Explain how the linear speed of this satellite compares with the linear speed of the satellite in Question 02.1.

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Answer

In a higher orbit, the linear speed of the satellite is smaller. The orbital speed $v$ depends on the radius of the orbit as given by:

$v = \sqrt{\frac{GM}{R+h}}$

As $R+h$ increases for a satellite in a higher orbit, the linear speed decreases, leading to a slower orbital motion compared to the satellite in Question 02.1.

The Global Positioning System (GPS) uses satellites to support navigation on Earth - AQA - A-Level Physics - Question 2 - 2021 - Paper 2

Worked Solution & Example Answer:The Global Positioning System (GPS) uses satellites to support navigation on Earth - AQA - A-Level Physics - Question 2 - 2021 - Paper 2

Show that the angular speed $\omega$ of the satellite is given by $\omega = \frac{GM}{(R+h)^{3/2}}$

Calculate the orbital period of the satellite when $h$ equals $2.02 \times 10^{7} \, m$

State and explain which launch site $X$, $Y$ or $Z$ minimizes the amount of fuel required to send the satellite into its orbit.

Calculate the gravitational potential energy of the satellite when in the orbit in Question 02.2.

Explain how the linear speed of this satellite compares with the linear speed of the satellite in Question 02.1.

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