ROUTERA


Gravitation

Class 11th Physics NCERT Exemplar Solution



Mcq I
Question 1.

The earth is an approximate sphere. If the interior contained matter which is not of the same density everywhere, then on the surface of the earth, the acceleration due to gravity
A. will be directed towards the centre but not the same everywhere.

B. will have the same value everywhere but not directed towards the centre.

C. will be same everywhere in magnitude directed towards the centre.

D. cannot be zero at any point.


Answer:

If the interior contained matter is of same density everywhere, then we assume earth approximately as a point mass of mass equal to mass of earth, placed at the centre of earth. In that case, acceleration due to gravity (g) is zero at the centre of the earth. But it can’t be zero at any point on the surface of the earth.


The magnitude and direction of acceleration due to gravity can not be predicted at every point on the surface if the mass density is non - uniformly distributed everywhere. So, options(a), (b) and (c) are incorrect.


Question 2.

As observed from earth, the sun appears to move in an approximate circular orbit. For the motion of another planet like mercury as observed from earth, this would
A. be similarly true.

B. not be true because the force between earth and mercury is not inverse square law.

C. not be true because the major gravitational force on mercury is due to sun.

D. not be true because mercury is influenced by forces other than gravitational forces.


Answer:

All the planets move around the sun in approximate circular orbits dur to gravitational force of attraction between the sun and the planet.



Where,


M1 and M2 are masses of two bodies and r is the distance between them


This gravitational force is inversely proportional to the square of distance between them and hence the planet revolves in circular orbits.


Similarly, Mercury experiences force of gravitational attraction both from the Sun and the Earth. But since the mass of sun is massive, the force due to sun is very large compared to force due to earth.


Therefore, mercury revolves in circular orbit around sun and not around earth.


Question 3.

Different points in earth are at slightly different distances from the sun and hence experience different forces due to gravitation. For a rigid body, we know that if various forces act at various points in it, the resultant motion is as if a net force acts on the c.m. (centre of mass) causing translation and a net torque at the c.m. causing rotation around an axis through the c.m. For the earth - sun system (approximating the earth as a uniform density sphere)
A. the torque is zero.

B. the torque causes the earth to spin.

C. the rigid body result is not applicable since the earth is not even approximately a rigid body.

D. the torque causes the earth to move around the sun.


Answer:

if we consider earth and sun as a system, the earth experiences a centripetal force due to gravitational force of attraction of sun, and thus revolves around the sun in a circular orbit.


We know that,


Torque of any force F about a point is defined as



.(i)


Where,


r⃗ = distance of point of application of force from the point about which torque is to be calculated.


Since earth is symmetrical in shape, the net force due to sun acts on the centre of earth and since gravitational force is along line joining the centre of mass of earth and sun, the angle between r⃗ and F⃗ becomes 0°.


Therefore from eqn.(i)


τ = 0


Question 4.

Satellites orbiting the earth have finite life and sometimes debris of satellites fall to the earth. This is because,
A. the solar cells and batteries in satellites run out.

B. the laws of gravitation predict a trajectory spiralling inwards.

C. of viscous forces causing the speed of satellite and hence height to gradually decrease.

D. of collisions with other satellites.


Answer:

Due to the viscous atmosphere, friction force due to the atmosphere acts on the satellite which reduces its orbital speed and hence the energy of revolution around a planet.


Due to decrease in energy of satellite, its height gradually decreases


Question 5.

Both earth and moon are subject to the gravitational force of the sun. As observed from the sun, the orbit of the moon
A. will be elliptical.

B. will not be strictly elliptical because the total gravitational force on it is not central.

C. is not elliptical but will necessarily be a closed curve.

D. deviates considerably from being elliptical due to influence of planets other than earth.


Answer:

The gravitational force of attraction due to earth on the moon follow the inverse square law due to which the as seen from the earth, the moon revolves around it in circular orbit.


When observed from the sun, moon experiences the gravitational pull due to both, the sun and the moon which results in a net force thus changing the trajectory of moon, and hence it does not revolve in strictly elliptical due to influence of both sun and earth.


Question 6.

In our solar system, the inter - planetary region has chunks of matter (much smaller in size compared to planets) called asteroids. They
A. will not move around the sun since they have very small masses compared to sun.

B. will move in an irregular way because of their small masses and will drift away into outer space.

C. will move around the sun in closed orbits but not obey Kepler’s laws.

D. will move in orbits like planets and obey Kepler’s laws.


Answer:

Like any other planet, asteroids also follow Kepler’s law and move in elliptical orbits around planet due to the central gravitational force acting on them.


small mass of asteroid does not escape the gravitational force due to sun because of large mass of sun and hence, (a) is incorrect. Since gravitational force follow inverse square law, the asteroid will move in circular or elliptical orbits and (b) is incorrect option


Question 7.

Choose the wrong option.
A. Inertial mass is a measure of difficulty of accelerating a body by an external force whereas the gravitational mass is relevant in determining the gravitational force on it by an external mass.

B. That the gravitational mass and inertial mass are equal is an experimental result.

C. That the acceleration due to gravity on earth is the same for all bodies is due to the equality of gravitational mass and inertial mass.

D. Gravitational mass of a particle like proton can depend on the presence of neighbouring heavy objects but the inertial mass cannot.


Answer:

Inertial mass:


The mass of an object A can be defined as the mass of the object obtained by measuring their accelerations under equal forces taking mass of B to be 1kg. This is known as inertial mass.


Gravitational mass:


The gravitational force exerted by a massive body on an object is proportional to the mass of the object. If FA and FB are the forces of attraction on the two objects due to the earth


and


Thus



If B is a standard unit mass, by measuring gravitational Force we can obtain the mass of object A which is known as gravitational mass.


By several experiments, it has been concluded that the inertial and gravitational mass are identical.


Therefore, gravitational mass of proton is equal to its inertial mass and is independent of the presence of neighbouring objects.


Question 8.

Particles of masses 2M, m and M are respectively at points A, B and C with AB = 1/2 (BC). m is much - much smaller than M and at time t = 0, they are all at rest (Fig. 8.1). At subsequent times before any collision takes place:



A. m will remain at rest.

B. m will move towards M.

C. m will move towards 2M.

D. m will have oscillatory motion


Answer:

We know that gravitational force between two masses separated by a distance r is given by



Now,


Force due to 2M at A on B =


towards A


Force due to M at C on B =


towards C


Therefore, net force on B




Towards A


Therefore, m will move towards A


Therefore (c) is the correct option



Mcq Ii
Question 1.

Which of the following options are correct?
A. Acceleration due to gravity decreases with increasing altitude.

B. Acceleration due to gravity increases with increasing depth (assume the earth to be a sphere of uniform density).

C. Acceleration due to gravity increases with increasing latitude.

D. Acceleration due to gravity is independent of the mass of the earth.


Answer:

When a particle is placed on the surface of the earth, then the acceleration due to gravity is given by


…(i)


Now when the particle is at a height h form the surface then new acceleration becomes


…..(ii)


From eqn. (i) and (ii)



Therefore, acceleration due to gravity decreases with increasing altitude


Now, if a body of mass m is placed on the point whose angle of latitude is ϕ then acceleration due to gravity is given by



Where,


ω = angular velocity of earth


R = radius of earth


As the latitude increases, ϕ increases and cosϕ decreases, thus increasing the value of g


Therefore, (a) and (c) are correct option


Question 2.

If the law of gravitation, instead of being inverse - square law, becomes an inverse - cube law -
A. planets will not have elliptic orbits.

B. circular orbits of planets is not possible.

C. projectile motion of a stone thrown by hand on the surface of the earth will be approximately parabolic.

D. there will be no gravitational force inside a spherical shell of uniform density.


Answer:

we know that, for planet to follow elliptical orbit



But if law of gravitation follows inverse cube law, then for a planet of mass m, the gravitational force experienced due to sun is given by



Orbital speed



The time period of revolution of planet is then given by



Which does not follow Kepler’s law. Hence, the planet will not revolve in either elliptical or circular orbit.


The new acceleration due to gravity can be given as



Since g’ is constant, hence path followed by the projectile will be approximately parabolic when thrown.


Question 3.

If the mass of sun were ten times smaller and gravitational constant G were ten times larger in magnitudes -
A. walking on ground would become more difficult.

B. the acceleration due to gravity on earth will not change.

C. raindrops will fall much faster.

D. airplanes will have to travel much faster.


Answer:

Given:


New gravitational constant G’ = 10G


Ms’ = Ms/10


Gravitational field due to earth is given by



Force on the man due to sun



Where r = distance between centre of sun and man


Since r≫R the effect due to sun can be neglected and the gravity pull will increase. Due to it, walking on the ground can be difficult


As the acceleration due to gravity g increases, the raindrops fall much faster than usual


Also, airplanes will have to travel much faster to overcome the increased gravitational pull of the earth


Question 4.

If the sun and the planets carried huge amounts of opposite charges,
A. all three of Kepler’s laws would still be valid.

B. only the third law will be valid.

C. the second law will not change.

D. the first law will still be valid.


Answer:

If the sun and the planets carried huge amounts of opposite charges then the electrostatic force of attraction will act between the sun and the planets.


We know that electrostatic or columbic force follows inverse square law and thus both the gravitational and electrostatic force will add up in nature and the net force will also follow inverse square law.


Therefore, since both the forces are of same nature, the Kepler’s law will still be valid


Question 5.

There have been suggestions that the value of the gravitational constant G becomes smaller when considered over very large time period (in billions of years) in the future. If that happens, for our earth,
A. nothing will change.

B. we will become hotter after billions of years.

C. we will be going around but not strictly in closed orbits.

D. after sufficiently long time we will leave the solar system.


Answer:

We know that gravitational force between the earth and the sun is given by



Where


G = Gravitational constant


Me and Ms are mass of earth and sun respectively


Due to this force the earth revolves around the sun in circular orbits.


If the value of G decreases with time and the gravitational force between sun and earth starts decreasing and the trajectory of earth will change and hence not going around in strictly closed orbits.


As the gravitational pull of sun becomes weaker the radius of revolution of earth will gradually increase over time and after sufficiently long time, we will leave the solar system


Question 6.

Supposing Newton’s law of gravitation for gravitation forces F1 and F2 between two masses m1 and m2 at positions r1 and r2 read F1 = - F2 = GM02 r where M0 is a constant of dimension of mass, r12 = r1 – r2 and n is a number. In such a case,
A. the acceleration due to gravity on earth will be different for different objects.

B. none of the three laws of Kepler will be valid.

C. only the third law will become invalid.

D. for n negative, an object lighter than water will sink in water.


Answer:

Given:



Where


= constant


For calculating acceleration due to gravity let


M1 = Mass of earth = M


M2 = mass of object


= radius of earth = R


Then magnitude of force between the object and earth is given by



Which can be said as



Where K is a constant


Therefore, acceleration due to gravity can be calculated as



Which depends on mass and hence different for different objects


Therefore (a) is the correct option


since this force follows inverse square law, hence Kepler’s first two are valid but since g is no longer constant, therefore Kepler’s third law (Law of periods) does not remain valid


therefore (c) is the correct option


when n is negative than force is given by



Where a = - n


Therefore, force is inversely proportional to mass of body, hence an object lighter than water will experience more force than water and therefore will sink in water


Therefore (a), (c) and (d) are the correct options


Question 7.

Which of the following are true?
A. A polar satellite goes around the earth’s pole in north south direction.

B. A geostationary satellite goes around the earth in east - west direction.

C. A geostationary satellite goes around the earth in west - east direction.

D. A polar satellite goes around the earth in east - west direction.


Answer:

Geostationary satellites are the satellites which revolve in a circular orbit around the earth in the equatorial plane with time period equal to the time period of rotation of earth = 24 hours. Hence the geostationary satellite appears fixed from any point on the earth.


Hence the geostationary satellite revolves with same speed and sense as of earth which is west - east direction.


Another kind of satellites known as polar satellites are low altitude of satellites which go around the poles of the earth in north - south direction. Its time period is 100 minutes.



Question 8.

The centre of mass of an extended body on the surface of the earth and its centre of gravity
A. are always at the same point for any size of the body.

B. are always at the same point only for spherical bodies.

C. can never be at the same point.

D. is close to each other for objects, say of sizes less than 100 m.

E. both can change if the object is taken deep inside the earth.


Answer:

Centre of mass of any object is described as mean position of mass in the object. Many objects with uniform shape and mass distribution have their centre of masses at their centre


Whereas centre of gravity of the object is the point where the gravity is assumed to act i.e. when the object is suspended from a fixed point, the torque of gravity about the point is zero.


Centre of mass and centre of gravity are not same points for an extended body with large dimensions due to different mass distribution. But if the size of the body is less and the gravitational field is uniform, then the centre of gravity and centre of mass are nearly at the same point.



Vsa
Question 1.

Molecules in air in the atmosphere are attracted by gravitational force of the earth. Explain why all of them do not fall into the earth just like an apple falling from a tree.


Answer:

In the case of apple falling from the tree, the mass of the apple is very large as compared to the air molecules underneath the apple. Thus, the vertical motion of apple dominates and due to gravitational force, it falls towards the earth.


Whereas an air molecule is surrounded by many air molecules having relatively equal mass. also due to random thermal motion of molecules their velocity is not directed downwards. Therefore, the air molecules do not fall towards earth. The density of air molecules close to the surface of earth is greater than other due to the gravitational force.



Question 2.

Give one example each of central force and non - central force.


Answer:

Central force:


Central force is a force which always directed at a fixed point either away or towards it and its magnitude depends upon the distance of body from the centre


Example: Gravitational force of attraction


Non - central force:


Non - central force is not directed towards or away from a fixed point.


Example: Magnetic force on a current carrying loop



Question 3.

Draw areal velocity versus time graph for mars.


Answer:

According to Kepler’s second law, the line between the sun and the planet sweeps equal area in equal interval of time, i.e.



Where is the areal velocity of any planet and K is any constant


Therefore, areal velocity remains constant and is independent of time. The graph between areal velocity versus time for mars is as shown




Question 4.

What is the direction of areal velocity of the earth around the sun?


Answer:

We know that the areal velocity of earth around the sun is given by


….(i)


Where


L⃗ = angular momentum of earth about sun


mass of earth


Now, angular momentum of earth around the sun is given by


…. (ii)


Where


v⃗ = velocity of earth


r⃗ = position vector of earth w.r.t sun


from eqn.(i) and (ii) we have,



Therefore, direction of areal velocity is perpendicular to the plane containing velocity vector and position vector.



Therefore, areal velocity of earth is normal to the plane containing earth and the sun



Question 5.

How is the gravitational force between two - point masses affected when they are dipped in water keeping the separation between them the same?


Answer:

The gravitational force between two - point masses is given by



Where, andare masses and r is the distance between them respectively & G is the universal gravitational constant.


This gravitational force is independent of the medium in which masses are placed since the value of G is a universal constant and independent of medium and the masses also remains unaffected.


Therefore, the gravitational force between the two - point masses when they are dipped in water keeping the separation between them same remains same when put in vacuum.



Question 6.

Is it possible for a body to have inertia but no weight?


Answer:

Yes, a body can have inertia but no weight. Inertia of a body is related to mass. Whereas weight of body is defined as



Where


M = mass of body


g = acceleration due to gravity


therefore, weight of the object can be zero when the acceleration due to gravity becomes zero.


Since we know that at the centre of earth, the value of acceleration due to gravity is zero and hence the weight of the object is zero at the centre, but it remains mass(inertia) remains constant.



Question 7.

We can shield a charge from electric fields by putting it inside a hollow conductor. Can we shield a body from the gravitational influence of nearby matter by putting it inside a hollow sphere or by some other means?


Answer:

Gravitational field between two bodies, unlike electric fields, does not depend upon the nature of the medium between the two bodies, therefore a body cannot be shielded by the influence of nearby matter by putting it inside a hollow sphere.



Question 8.

An astronaut inside a small spaceship orbiting around the earth cannot detect gravity. If the space station orbiting around the earth has a large size, can he hope to detect gravity?


Answer:

An astronaut in a small spaceship around earth is always in freefall and is constantly under the influence of gravitational force of earth and since the spaceship is small its gravitational force on the astronaut is very small as compared to earth, therefore the astronaut cannot detect gravity. If the spaceship is large enough to produce a comparable gravitational force against earth’s gravitational force the astronaut will then detect gravity.



Question 9.

The gravitational force between a hollow spherical shell (of radius R and uniform density) and a point mass is F. Show the nature of F vs r graph where r is the distance of the point from the centre of the hollow spherical shell of uniform density.


Answer:

Given:


Radius of hollow shell = R


Distance of point mass from centre of hollow shell = r


Let the mass of the spherical shell be M and the point mass be m. Then the force between the shell and the point mass is given by,



When point mass is positioned such that it is inside the hollow sphere i.e. 0<r<R, the force is zero as the mass of the hollow sphere is distributed on its surface. When the mass is positioned such that r≤R, the force will be,




Therefore, the graph will be as follows



Question 10.

Out of aphelion and perihelion, where is the speed of the earth more and why?


Answer:

Aphelion is the positon of earth from where it has the greatest distance from the sun and perihelion is the position from where it has the shortest distance. Now since the angular momentum of earth about the sun is conserved then we have:


Where m is the mass of the earth, rap is the earth - sun distance at the aphelion and rpe is the earth - sun distance at the perihelion.




Since rap > rpe, vpe > vap, therefore the velocity at the perihelion is greater than the velocity at the aphelion.



Question 11.

What is the angle between the equatorial plane and the orbital plane of

(a) Polar satellite?

(b) Geostationary satellite?


Answer:

The orbital plane of a satellite is the plane in which it revolves around the earth. The equatorial plane of earth is the plane which contains the equator.


(a) For a polar satellite, the satellite revolves from north to south and therefore its orbital plane is at 90° to the equatorial plane


(b) For a geostationary satellite whose position with respect to a place on earth is constant i.e. it revolves in the direction of the rotation of earth, the orbital plane is at 0° to the equatorial plane.




Sa
Question 1.

Mean solar day is the time interval between two successive noon when sun passes through zenith point (meridian). Sidereal day is the time interval between two successive transit of a distant star through the zenith point (meridian). By drawing appropriate diagram showing earth’s spin and orbital motion, show that mean solar day is four minutes longer than the sidereal day. In other words, distant stars would rise 4 minutes early every successive day.

(Hint: you may assume circular orbit for the earth).


Answer:


A day on earth is measured in terms of rotation of earth on its axis with respect to the sun called the mean solar day. When the day is measured with respect to a distant sun, it is called a sidereal day.


Let us look at the given figure, let the sun and distant star’s location be pointed by the long arrow at day 1, where they are directly in line with zenith of the observer on earth. When the earth rotates by 360° the arrow of the distant star points in the same direction along the zenith. However, the sun’s arrow is at an angle from the zenith. Thus, for the sun to be at the zenith in line with the observer, the earth needs to rotate an additional angle. Since the earth moves by 1° around the sun in a day, this additional angle is 1°. Now 360° is equal to 24 hours on earth or 1440 minutes, therefore



Therefore, the distant star will always rise 4 minutes earlier than the sun.



Question 2.

Two identical heavy spheres are separated by a distance 10 times their radius. Will an object placed at the midpoint of the line joining their centres be in stable equilibrium or unstable equilibrium? Give reason for your answer.


Answer:

Given:


Distance between centres of spheres = 10 x radius


Let the mass of the two spheres be M and their radii be R. Then, the distance between the two will be 10R. let an object of mass m be placed at the midpoint of the line joining the centres of the spheres. Then the force acting on the object due to the two spheres F1 and F2 will be,



Therefore, the forces are equal and in opposite directions and therefore the mass is in stable equilibrium.


However, if the mass were to be displaced by say a distance x from the midpoint towards the sphere 2, the forces acting on the object would be




Therefore, F2’ > F1’ and therefore the net force acting on the mass will not be zero and equal to (F2’ - F1’) towards the sphere 2 and the object would be in unstable equilibrium.



Question 3.

Show the nature of the following graph for a satellite orbiting the earth.

(a) KE vs orbital radius R

(b) PE vs orbital radius R

(c) TE vs orbital radius R.


Answer:

Given


Radius of satellite’s orbit = R


(a) Let the mass of earth be M and the mass of the satellite be m. Then the orbital velocity of the satellite will be



then, the kinetic energy of the satellite will be



(b) the potential energy of the satellite is given by



(c) the total energy of the satellite is given by





Therefore, the curves are as follows



Question 4.

Shown are several curves (Fig. 8.2). Explain with reason, which ones amongst them can be possible trajectories traced by a projectile (neglect air friction).

(a)

(b)

(c)

(d)

(e)

(f)


Answer:

The trajectory traced by a projectile under the action of gravitational force will always be a conic section. When the distance thrown is small compared to the radius of the earth then the projectile follows a parabolic trajectory as demonstrated by the so - called projectile motion in the analysis of newton’s equations of motion. However, when the distance is comparable to the earth’s radius the trajectory is an ellipse according to Kepler’s laws. Therefore, the correct trajectory is (c)



Question 5.

An object of mass m is raised from the surface of the earth to a height equal to the radius of the earth, that is, taken from a distance R to 2R from the centre of the earth. What is the gain in its potential energy?


Answer:

Given:


Mass of the object = m


Radius of earth = R


Initial height of the object from earth’s centre = R


Final height of the object from earth’s centre = 2R


Let the mass of earth be M. We know that the gravitational potential energy of an object is given by,



Where r is the distance between the object and centre of earth. When the object is at its initial position it is at a distance of R from the centre of the earth. Then its potential energy,



When the object is raised to a height 2R, then the potential energy is given by,



Now the gain in gravitational potential energy is given by





Question 6.

A mass m is placed at P a distance h along the normal through the centre O of a thin circular ring of mass M and radius r (Fig. 8.3).



If the mass is removed further away such that OP becomes 2h, by what factor the force of gravitation will decrease, if h = r?


Answer:

Given:


Mass of the ring = M


Layout of the ring = r


Mass of the object = m


Initial distance of the object h = r


Final distance of the object 2h = 2r


To find the gravitational force on the object of mass m due to the ring let us consider an elemental mass on the ring of mass dM. The force due to this elemental mass is then,




where x is the distance of the object from the elemental mass m and



Now at the point P the force dF can be resolved into a vertical component and a horizontal component. If we consider two elemental masses diametrically opposite to each other, then the vertical component due to the two forces cancel each other as they are equal and opposite and the horizontal forces add up. Therefore, we only need to consider the horizontal component of the forces, therefore the net force on the object,



Now from the triangle OPA in the figure we have,



therefore,




When h = r



When h = 2h = 2r




Therefore, the force decreases by a factor of .




La
Question 1.

A star like the sun has several bodies moving around it at different distances. Consider that all of them are moving in circular orbits. Let r be the distance of the body from the centre of the star and let its linear velocity be v, angular velocity ω, kinetic energy K, gravitational potential energy U, total energy E and angular momentum l. As the radius r of the orbit increases, determine which of the above quantities increase and which ones decrease.


Answer:

Given:


Radius of the orbit of planets = r


Let the mass of the sun be M and the planet be m.


(a) The force on an object revolving around the star is given by




Therefore, linear velocity v is inversely proportional to square root of r and hence when r increases, v decreases.


(b) The angular velocity ω is given by




Therefore, when r increases, ω decreases.


(c) The kinetic energy K is given by,




Therefore, as r increases, K decreases.


(d) The potential energy U is given by,




Therefore, as r increases U becomes less negative or increases.


(e) The total energy E is given by,




Therefore, as r increases E becomes less negative or increases.


(f) The angular momentum L is given by,




Therefore, as r increases, L increases.



Question 2.

Six point masses of mass m each are at the vertices of a regular hexagon of side l. Calculate the force on any of the masses.


Answer:

Given


Side of hexagon = l


The force on the masses will be the resultant of the forces of all the other masses. Let the masses be m each. Now the distance AC is given by the parallelogram law i.e.





Due to symmetry we have AC = AE =



Now, for AD we have



Now the force on mass at A due to b is



Also



The force on mass A due to C is



Also due to symmetry, we have



The force on mass at A due to mass at D is



Now, the forces Fae and Fac make equal angles with the direction AD viz. 30°, and therefore by parallelogram law of vector addition their resultant is along AD and therefore the magnitude of the resultant,




Similarly, Fab and Faf also make equal angles with AD viz. 60° and therefore they are also along AD and




Therefore, the net force on mass at A will be






Question 3.

A satellite is to be placed in equatorial geostationary orbit around earth for communication.

(a) Calculate height of such a satellite.

(b) Find out the minimum number of satellites that are needed to cover entire earth so that at least one satellites is visible from any point on the equator.

[M = 6 × 1024 kg, R = 6400 km, T = 24h, G = 6.67 × 10 - 11 SI units]


Answer:

(a) For a geostationary satellite, the centripetal force must equal the gravitational force. Let the mass of earth be M and the satellite be m, then



Where r is the radius of the orbit of the satellite and ω is its angular velocity



where T is the time period of revolution, then



Now the height h of the satellite from the surface of the earth,



where R is the radius of earth.


For a geostationary satellite, the time period is 24 hours or 86400 seconds,




(b) A geostationary satellite is visible form the equator in the region shown in the figure having an angle 2θ,



Now from the figure we have





Now 2θ = 162.58, therefore to cover the earth with such satellites so that from any point on the equator a satellite can be seen,



Therefore, we need a minimum of 3 satellites.



Question 4.

Earth’s orbit is an ellipse with eccentricity 0.0167. Thus, earth’s distance from the sun and speed as it moves around the sun varies from day to day. This means that the length of the solar day is not constant through the year. Assume that earth’s spin axis is normal to its orbital plane and find out the length of the shortest and the longest day. A day should be taken from noon to noon. Does this explain variation of length of the day during the year?


Answer:

Given


The eccentricity of earth’s orbit e = 0.0167


Let the earth - sun distance at the aphelion and perihelion be ra and rp respectively, and the angular velocity at those points be ωa and ωp. Now since the angular momentum of the earth is conserved we have




Now, from the ellipse we have



Where a is the semi - major axis of the ellipse




Since e = 0.0167



Now let the mean angular velocity of earth corresponding to the mean solar day be ω, then



And since the mean angular velocity is the geometric mean of the two, we have



Now we know that the mean solar day corresponds to 1° on the orbit of earth. A mean solar day has 24 h for which the earth rotates 361°. Thus for aphelion the earth rotates 361.034° and hence the time for the day is 24 hours and 8.1 seconds, and the for the perihelion the earth rotates 359.96° and the time is 23 hours and 52 seconds. Thus the longest day is 8.1 seconds long and the shortest day is 8 seconds shorter. However, the variation of length of day in the year is not explained by this phenomenon as the total time of the day still remains around 24 hours, while the amount of time the sun is visible changes.



Question 5.

A satellite is in an elliptic orbit around the earth with aphelion of 6R and perihelion of 2 R where R = 6400 km is the radius of the earth. Find eccentricity of the orbit. Find the velocity of the satellite at apogee and perigee. What should be done if this satellite has to be transferred to a circular orbit of radius 6R?

[G = 6.67 × 10 - 11 SI units and M = 6 × 1024 kg]


Answer:

Given


Radius of earth = R = 6400 km


Aphelion earth - satellite distance ra = 6R


Perihelion earth - satellite distance rp = 2R


We know for an ellipse




Where e is the eccentricity of the ellipse, and the semi major axis.




Now, the angular momentum of the satellite is conserved we then, we have



Where m is the mass of satellite and vp and va are the velocities at the perigee and apogee respectively



Now from conservation of energy at the apogee and perigee



Where K and U are the kinetic and gravitational potential energy of the satellite



Where M is the mass of earth. Using the relation between vp and va above we have



Putting the values of rp and ra we have




To transfer the satellite to a circular orbit of radius 6R the satellite’s velocity has to be maintained at a value of