Relative velocity in one dimension (Page 4/4)

Physics for k-12

Page 4 / 4

Relative velocity

This technique is a very useful tool for consideration of relative motion in two dimensions.

Direction of relative velocities

For a pair of two moving objects moving uniformly, there are two values of relative velocity corresponding to two reference frames. The values differ only in sign – not in magnitude. This is clear from the example here.

Problem : Two cars start moving away from each other with speeds 1 m/s and 2 m/s along a straight road. What are relative velocities ? Discuss the significance of their sign.

Solution : Let the cars be denoted by subscripts “1” and “2”. Let us also consider that the direction $v_{2}$ is the positive reference direction, then relative velocities are :

Relative velocity

$\begin{array}{l} \Rightarrow v_{12} = v_{1} - v_{2} = - 1 - 2 = - 3 m / s \\ \Rightarrow v_{21} = v_{2} - v_{1} = 2 - (- 1) = 3 m / s \end{array}$

The sign attached to relative velocity indicates the direction of relative velocity with respect to reference direction. The directions of relative velocity are different, depending on the reference object.

However, two relative velocities with different directions mean same physical situation. Let us read the negative value first. It means that car 1 moves away from car 2 at a speed of 3 m/s in the direction opposite to that of car 2. This is exactly the physical situation. Now for positive value of relative velocity, the value reads as car 2 moves from car 1 in the direction of its own velocity. This also is exactly the physical situation. There is no contradiction as far as physical interpretation is concerned. Importantly, the magnitude of approach – whatever be the sign of relative velocity – is same.

Relative velocity

Got questions? Get instant answers now!

Relative velocity .vs. difference in velocities

It is very important to understand that relative velocity refers to two moving bodies – not a single body. Also that relative velocity is a different concept than the concept of "difference of two velocities", which may pertain to the same or different objects. The difference in velocities represents difference of “final” velocity and “initial” velocity and is independent of any order of subscript. In the case of relative velocity, the order of subscripts are important. The expression for two concepts viz relative velocity and difference in velocities may look similar, but they are different concepts.

Relative acceleration

We had restricted out discussion up to this point for objects, which moved with constant velocity. The question, now, is whether we can extend the concept of relative velocity to acceleration as well. The answer is yes. We can attach similar meaning to most of the quantities - scalar and vector both. It all depends on attaching physical meaning to the relative concept with respect to a particular quantity. For example, we measure potential energy (a scalar quantity) with respect to an assumed datum.

Extending concept of relative velocity to acceleration is done with the restriction that measurements of individual accelerations are made from the same reference.

If two objects are moving with different accelerations in one dimension, then the relative acceleration is equal to the net acceleration following the same working relation as that for relative velocity. For example, let us consider than an object designated as "1" moves with acceleration " $a_{1}$ " and the other object designated as "2" moves with acceleration " $a_{2}$ " along a straight line. Then, relative acceleration of "1" with respect to "2" is given by :

$\begin{array}{l} \Rightarrow a_{12} = a_{1} - a_{2} \end{array}$

Similarly,relative acceleration of "2" with respect to "1" is given by :

$\begin{array}{l} \Rightarrow a_{21} = a_{2} - a_{1} \end{array}$

Worked out problems

Relative motion

Problem : Two trains are running on parallel straight tracks in the same direction. The train, moving with the speed of 30 m/s overtakes the train ahead, which is moving with the speed of 20 m/s. If the train lengths are 200 m each, then find the time elapsed and the ground distance covered by the trains during overtake.

Solution : First train, moving with the speed of 30 m/s overtakes the second train, moving with the speed of 20 m/s. The relative speed with which first train overtakes the second train,

$\begin{array}{l} v_{12} = v_{1} - v_{2} = 30 - 20 = 10 m/s. \end{array}$

The figure here shows the initial situation, when faster train begins to overtake and the final situation, when faster train goes past the slower train. The total distance to be covered is equal to the sum of each length of the trains (L1 + L2) i.e. 200 + 200 = 400 m. Thus, time taken to overtake is :

The total relative distance

The total relative distance to cover during overtake is equal to the sum of lengths of each train.

$\begin{array}{l} t = \frac{400}{10} = 40 s. \end{array}$

In this time interval, the two trains cover the ground distance given by:

$\begin{array}{l} s = 30 x 40 + 20 x 40 = 1200 + 800 = 2000 m. \end{array}$

Got questions? Get instant answers now!

In the question given in the example, if the trains travel in the opposite direction, then find the time elapsed and the ground distance covered by the trains during the period in which they cross each other.

$\begin{array}{l} v_{12} = v_{1} - v_{2} = 30 - (- 20) = 50 m/s. \end{array}$

The total distance to be covered is equal to the sum of each length of the trains i.e. 200 + 200 = 400 m. Thus, time taken to overtake is :

$\begin{array}{l} t = \frac{400}{50} = 8 s. \end{array}$

Now, in this time interval, the two trains cover the ground distance given by:

$\begin{array}{l} s = 30 x 8 + 20 x 8 = 240 + 160 = 400 m. \end{array}$

In this case, we find that the sum of the lengths of the trains is equal to the ground distance covered by the trains, while crossing each other.

Got questions? Get instant answers now!

Check your understanding

Check the module titled Relative velocity in one dimension (Check your understanding) to test your understanding of the topics covered in this module.

<< Chapter < Page Page > Chapter >>

Read also:

Get Jobilize Job Search Mobile App in your pocket Now!

100% Free Mobile Applications
Receive real-time job alerts and never miss the right job again

Source: OpenStax, Physics for k-12. OpenStax CNX. Sep 07, 2009 Download for free at http://cnx.org/content/col10322/1.175

Google Play and the Google Play logo are trademarks of Google Inc.

Notification Switch

Would you like to follow the 'Physics for k-12' conversation and receive update notifications?

Ask

	6 Microbiology Midterm Practice By Madison Christian Start Test
	7 Psychology MCQ 2010 Final Exam By John Gabrieli Start Exam
©flickr: eLife	Mycobacterial Infections (Mandell 8th Ch 251-254) By Cath Yu Start Quiz
	2011 Dynamics CRM By Danielrosenberger Start Quiz
	3 AP 03 Cellular Level of Organization MCQ By OpenStax Start Quiz
	3 Psychology MCQ 2009 2 Exam By John Gabrieli Start Exam
©flickr: Jonathan	Power By Megan Earhart Start Quiz
	26 AP 26 Fluid, Electrolyte, Acid-Base Balance MCQ By OpenStax Start Quiz
©flickr:	Health Reviewer MCQ By Edgar Delgado Start Quiz
	18 AP Key Terms 18 Cardiovascular System Blood By OpenStax Start Key Terms