Consider a particle P is moving on circle of radius r on X – Y plane with origin O as centre.

The position of the particle at a given instant may be described by angle q, called angular position of the particle, measured in radian. As the particle moves on the path, its angular position (q) changes. The rate of change of angular position is called angular velocity (w) measured in radian per second.

The rate of change of angular velocity is called angular acceleration, measured in rad/s². Thus, the angular acceleration is

RELATION BETWEEN DIFFERENT PARAMETERS OF CIRCULAR MOTION

ü        It is easy to derive the equations of rotational kinematics for the case of constant angular acceleration with fixed axis of rotation. These equations are of the same form as those for one-dimensional translational motion.

w = w₀ +αt                                                             …(i)

Φ = Φ₀ + w₀t + αt²/2                                 …(ii)

w² = w₀² + 2α (Φ- Φ₀)                             …(iii)

Φ= Φ₀ + (w₀ +w)/(2t)                               …(iv)

Here,Φ is the initial angle and w₀ is the initial angular speed.

Illustrations

1.     (a) What is the angular velocity of the minute and hour hands of a clock?

(b) Suppose the clock starts malfunctioning at 7 AM which decelerates the minute hand at the rate of 4p radians/day. How much time would the clock loose by 7 AM next day?

Sol. Angular speed of

minute hand : wmh = 2Π rad/hr

= 48Π rad/day = (Π/1800) rad/sec

hour hand : whh = (Π/6) rad/hr

= 4Π rad/day = (Π/21600) rad/sec

(b)     Assume at t = 0, Φ₀ = 0, when the clock begins to malfunction. Use equation (ii) to get the angle covered by the minute hand in one day.

Hence the minute hand complete 23 revolutions, so the clock losses 1 hour.

]]> http://smartlearnwebtv.com/iitjee/IITJEE/circular-motion/feed/ 0 http://smartlearnwebtv.com/iitjee/IITJEE/motion-of-projectile/ http://smartlearnwebtv.com/iitjee/IITJEE/motion-of-projectile/#comments Tue, 03 Nov 2009 04:54:54 +0000 Prathap http://smartlearnwebtv.com/iitjee/?p=611 To analyze the projectile motion we use the following concept “Resolution of two dimensional motion into two one dimension motion” as discussed earlier. Hence it is easier to analyze the motion of projectile as composed of two simultaneous rectilinear motions which are independent of each other:

along the vertical y-axis with a uniform downward acceleration ‘g’ and

• along the horizontal x-axis with a uniform velocity forward.

Consider a particle projected with an initial velocity u at an angle α with the horizontal x-axis as shown in figure 2.17. Velocity and accelerations can be resolved into two components:

Velocity along x-axis = u_x = u cos α

Acceleration along x-axis a_x = 0

Velocity along y-axis = u_y = u sin α

Acceleration along y-axis a_y = -g

Here we use different equation of motions of one dimension derived earlier to get the different parameters.

v² = v₀² – 2g (y – y₀)                                …(C)

Total Time of flight

When body returns to the same horizontal level, the resultant displacement in vertical y-direction is zero. Use equation B.

Therefore,             0 = (u sin α) t – (½)gt²

or                   t = 2uSinα / g

(as t cannot equal to 0)

Horizontal Range

Horizontal Range (OA)  = Horizontal velocity × Time of flight

=        u cos α × 2u sin α/g

= u² sin 2α/g

=

Maximum Height

At the highest point of the trajectory, vertical component of velocity is zero.

Therefore              0 = (u sin α)² – 2g H_max

or,           H_max = u² sin² α/ 2g

Equation of trajectory

Assuming the point of projection as the origin of co-ordinates and horizontal direction as the x-axis and vertical direction as the y-axis. Let P (x, y) be the position of the particle at instant after t second.

Then x = u cos α.t                and         y = u sin α.t – 1/2 gt²

Eliminating  ‘t’ form the above equations, we get,

y = x tan α – gx²/ 2u² cos² α

This is the equation of trajectory which is a parabola  (y = ax + bx²).

Illustrations

1.      A gun moving at a speed of 30m/sec fires at an angle 300 with a velocity 150m/s relative to the gun. Find the distance between the gun and the projectile when projectile hits the ground . (g = 10 m/sec)

Sol. Vertical component of velocity = 150 sin 300 = 75 m/sec

Horizontal component of velocity relative to gun = 150 cos 300

=                       =   75 √3 m/sec

Horizontal component of velocity relative to ground

=                              = 75 √3 + 30 ≈ 160 m/sec

Time of flight = (2 * 75 )/g = 15 sec

Range of projectile              = 160 × 15 = 2400 m

Distance moved by the gun and projectile = 2400 – 450 = 1950 m.

Consider a particle projected horizontally with a velocity u  from a point O as shown in figure 2.18.

Assuming the point of projection O as the origin of coordinates and horizontal direction as the X-axis and vertical direction as Y-axis. Let P (x, y) be the position of the particle after t seconds.

x = horizontal distance covered in time t = ut. …(1)

y = vertical distance covered in time t  = ½gt² ….(2)

Eliminate t from equations  (1) and (2) then

We get, y = (1/2 ) (g/u²) x²

This is the equation of parabola passing through the origin, with its vertex at the origin O. Hence the trajectory is a parabola.

In the figure 2.1, the position of a point P is specified and

is called the position vector.

• Consider a case in which the position of an object changes with time. Suppose at certain instant ‘t’ the position of an object is x₁ along the x axis and some other instant ‘T’ the position is x ₂ then the displacement Δx is defined as

Δx = x₂ – x₁

• It can be seen in the figure 2.2 where x₁ and x₂ are instantaneous position of the object at time t and T respectively.
• Now consider the motion of a point A with respect to a reference point O. The motion of point A makes its radius vector vary in the general case both in magnitude and in direction as shown in figure 2.3. Suppose the point A travels from point 1 to point 2 in the time interval Δt.

Distance and Displacement

• To understand the difference between distance and displacement, we study the motion of vertical throw of a ball with respect to point O to height h.
• After some time it will come again to the same point O. The displacement of ball is zero but there is some distance traversed by the ball. It’s because distance is a scalar quantity but displacement is a vector quantity.

Speed and Velocity

• Speed is the rate of change of distance without regard to directions. Velocity is the rate at which the position vector of a particle changes with time. Velocity is a vector quantity whereas speed is scalar quantity but both are measured in the same unit m/sec.

Pre-requisite

State of Rest and Motion

• If the position of a particle is changing with respect to its surroundings in a given time interval, we say the particle is in motion and on the other hand if the position particle is not changing with respect to its surroundings, we can say the particle is at rest.

Position

The position of a particle refers to its location in the space at a certain moment. A vector joining the moving particle with the origin can describe the position of that particle at a particular moment.

Displacement

It is the vector joining the initial position of the particle to its final position in a given time interval.

Velocity

The rate of change of position of a moving particle is known as its velocity.

Acceleration

The rate of change of velocity with time is called the acceleration.

Distance and Displacement

• To understand the difference between distance and displacement, we study the motion of vertical throw of a ball with respect to point O to height h.
• After some time it will come again to the same point O. The displacement of ball is zero but there is some distance traversed by the ball. It’s because distance is a scalar quantity but displacement is a vector quantity.

Speed and Velocity

• Speed is the rate of change of distance without regard to directions. Velocity is the rate at which the position vector of a particle changes with time. Velocity is a vector quantity whereas speed is scalar quantity but both are measured in the same unit m/sec.