Rectilinear motion (application) 18

Questions and their answers are presented here in the module text format as if it were an extension of the treatment of the topic. The idea is to provide a verbose explanation, detailing the application of theory.

Solution presented is, therefore, treated as the part of the understanding process  not merely a Q/A session.

The emphasis is to enforce ideas and concepts, which can not be completely absorbed unless they are put to real time situation.

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1.17.1 Representative problems and their solutions

We discuss problems, which highlight certain aspects of rectilinear motion. The questions are categorized in terms of the characterizing features of the subject matter :

• Interpretation of position - time plot

• Interpretation of displacement - time plot

• Displacement

• Average velocity

1.17.1.1 Position vector Example 1.34

Problem : Two boys (P and Q) walk to their respective school from their homes in the morning on a particular day. Their motions are plotted on a position  time graph for the day as shown. If all schools and homes are situated by the side of a straight road, then answer the followings :

Motion of two boys

Figure 1.127: Position  time plot of a rectilinear motion.

1. Which of the two resides closer to the school?

2. Which of the two starts earlier for the school?

3. Which of the two walks faster?

4. Which of the two reaches the school earlier?

5. Which of the two overtakes other during walk?

Solution : In order to answer questions, we complete the drawing with vertical and horizontal lines as shown here. Now,

Motion of two boys

Figure 1.128: Position  time plot of a rectilinear motion.

1: Which of the two resides closer to the school?

We can answer this question by knowing the displacements. The total displacements here are OC by P and OD by Q. From gure, OC < OD. Hence, P resides closer to the school.

2: Which of the two starts earlier for the school?

The start times are point O for P and A for Q on the time axis. Hence, P starts earlier for school.

3: Which of the two walks faster?

The speed is given by the slope of the plot. Slope of the motion of P is smaller than that of Q.

Hence, Q walks faster.

4: Which of the two reaches the school earlier?

Both boys reach school at the time given by point B on time axis. Hence, they reach school at the same time.

5: Which of the two overtakes other during walk?

The plots intersect at a point E. They are at the same location at this time instant. Since, speed of B is greater, he overtakes A.

1.17.1.2 Interpretation of displacement - time plot Example 1.35

Problem : A displacement  time plot in one dimension is as shown. Find the ratio of velocities represented by two straight lines.

Displacement-time plot

Figure 1.129: There two segments of dierent velocities.

Solution : The slope of displacement  time plot is equal to velocity. Let v1 and v2 be the velocities in two segments, then magnitudes of velocities in two segments are :

| v1| = tan60 ^◦ = √ 3

| v2| = tan30 ^◦ = ^√1₃

We note that velocity in the rst segment is positive, whereas velocity in the second segment is negative. Hence, the required ratio of two velocities is :

v₁ v2 = −

√3

√1 3

= − 3

1.17.1.3 Displacement Example 1.36

Problem : The displacement x of a particle moving in one dimension is related to time t as :

t = √ x + 3

where t is in seconds and x is in meters. Find the displacement of the particle when its velocity is zero.

Solution : We need to nd x when velocity is zero. In order to nd this, we require to have an expression for velocity. This, in turn, requires an expression of displacement in terms of time.

The given expression of time, therefore, is required to be re-arranged :

√x = t − 3 Squaring both sides, we have :

⇒ x = ( t − 3 )² = t² − 6t + 9

Now, we obtain the required expression of velocity in one dimension by dierentiating the above relation with respect to time,

v = ^dx_dt = 2t − 6 According to question,

v = 2t − 6 = 0 t = 3 s

Putting this value of time in the expression of displacement, we have : x = 3² − 6 x 3 + 9 = 0

1.17.1.4 Average velocity Example 1.37

Problem : A particle moving in a straight line covers 1/3rd of the distance with a velocity 4 m/s. The remaining part of the linear distance is covered with velocities 2 m/s and 6 m/s for equal times. What is the average velocity during the total motion?

Solution : The average velocity is ratio of displacement and time. In one dimensional unidirectional motion, distance and displacement are same. As such, average velocity is ratio of total distance and time.

Let the total distance be x. Now, we need to nd total time in order to nd the average velocity. Let " t1", " t2" and " t2" be the time periods of the motion in three parts of the motion as given in the question. Considering the rst part of the motion,

Unidirectional motion

Figure 1.130: The particle covers segments of the motion with dierent average velocities.

t1 = ^x_v¹

1 = ^x3₄ = ₁₂^x

For the second part of the motion, the particle covers the remaining distance at two dierent velocities for equal time,  t2 ,

x − ^x₃ = v₂ x t₂ + v₃ x t₂

The discussion of dierent attributes of motion in previous modules has led us to the study of motion from the point of view of a general consideration to a simplied consideration such as uniform or rectilinear motion.

The time is now ripe to recapitulate and highlight important results - particularly where distinctions are to be made.

For convenience, we shall refer general motion as the one that involves non-linear, two/ three dimensional motion. The simplied motion, on the other hand, shall refer motion that involves one dimensional, rectilinear and uniform motion.

Consideration of scalar quantities like distance and speed are same for general as well as simplied

cases. We need to score similarities or dierences for vector quantities to complete our understanding up to this point. It is relevant here to point out that most of these aspects have already been dealt in detail in previous modules. As such, we shall limit our discussion on main points/ results and shall generally not use

gures and details.

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