Quick Handout for Time, Speed and Distance problems

TIME, SPEED AND DISTANCE - Part 1

Time, Speed and Distance problems typically appear in GMAT as word problems. While the chapter is simple enough to understand (There is just one formula effectively – Distance = Speed * Time ) the different contexts (Elevators, escalators, boats, trains and what not) actually make the job quite challenging for a test taker. More importantly, common sense and linking the problems with real world understanding helps the most rather than trying to memorize formulae.

There have been some very good TSD materials posted by Narenn (https://gmatclub.com/forum/time-speed-and-distance-simplified-150163.html) and a few others, so I won’t repeat them here. However, I want to particularly highlight on a few additional sections that might be tested in the exam – particularly in difficult 700+ level problems. Hope you’ll find it useful.

Frame of Reference (External vs. Internal)

A frame of reference is nothing but the point of observation. An external frame of reference typically means an observer is standing outside the moving bodies (E.g. An observer on a platform), an internal frame of reference means the observer is inside the moving bodies (E.g. a passenger inside a train). There is a ton of material available on this forum on external frame of reference (Train crossing a man/pole/platform/another train etc. So, I’d limit this discussion to internal reference frame alone.

Situation 1 – Stationary Object inside a moving body

Sample problem: A train traveling at a speed of 36 kmph and having a length of 100 metres crosses a platform 300 metres long. How long would Andy, a passenger on-board the train would take to cross the platform?

The key for these questions is to understand that we’re now looking at the problem from Andy’s perspective, who is a passenger on the train. So, we are no longer interested in the train’s time taken to cross the platform. Thus, to solve this problem, a simple way would be to consider as though Andy, a point object (And hence Length = 0) is traveling at a speed of 36 kmph and crossing the platform. Hence time taken would be 300/36*(5/18) = 30 seconds. Note that we ignored the length of the train because we are only interested in the time Andy took to cross the platform and not the train.

Situation 2 – Moving Object inside a moving body

Sample problem: A train traveling at a speed of 36 kmph and having a length of 100 metres crosses a platform 300 metres long. Andy, a passenger on board the train is standing in the last compartment and starts moving towards the engine at a speed of 18 kmph. How long would he take to cross the platform?
Many of you might think that two bodies moving in same direction, so relative speed is V1 – V2. You’d be wrong to think so in this question, because here we are referring to an internal frame of reference. Applying common sense would tell you that by the time Andy crosses the platform, he would have advanced some distance towards the engine and hence would take less time to cross the platform. So, to obtain a lesser time, we must add the speeds – V1+ V2. Hence the answer in this case would be 300/(36+18)*(5/18) = 20 seconds.

It would be similar if Andy was moving from the Engine towards the rear end of the train, with the only change -> the relative velocity would be V1 – V2.

Escalator Fundamentals

Escalators are another classic example of problems involving internal frame of reference. Since we covered the fundamentals above, test your understanding by trying the two problems below.

Sample Problem: R and S are walking on an escalator. R walked down the descending escalator and took 40 steps to reach the escalator base. S started from the escalator base at a speed twice that of R and started walking towards the top and reached the top at the same time as R reached the base. How many steps more than R did S cover when they crossed each other? Assume that the elevator moves 1 step/second.

(A) 10
(B) 20
(C) 30
(D) 40
(E) 50

Answer: (B)

2. A woman walked down a descending escalator in a mall at a certain speed and took 10 steps to reach the base. As soon as she reached the base she remembered that she left her purse in a shop upstairs and started rushing to the floor above at a speed 5 times her speed earlier. This time she covered 25 steps to reach the top. How many steps does the elevator have?

(A) 10
(B) 15
(C) 20
(D) 25
(E) 30

Answer: (C)

Average Speed

Again, average speed has been discussed aplenty in different forums, so I’m just going to summarize the result here. Whenever the distance travelled can be classified as m parts of the distance travelled at a velocity p and n parts of the distance travelled at q then the average speed of the journey can be classified as (m+n)pq/(mq+np).
Here’s an interesting problem to test your understanding of average speed.

IR Two Parts Analysis Question on TSD

A dog, standing at a hilltop starts descending down the slope and meets his owner who starts his upward journey from the hill-base at the same time the dog starts. The dog meets the owner, goes back to the top, comes back again to meet the owner and repeats this till the owner reaches the hill top. The owner’s up-hill speed is 6 m/sec, dog’s downhill speed is 15 m/sec, uphill speed is 9 m/sec. The hill slope is 720 metre.

Find the following:
i) The total distance travelled by the dog.
ii) The time taken by the dog for downward journey.

Answer choices
i)
A. 900 m
B. 1050 m
C. 1200 m
D. 1350 m
E. 1500 m

Answer: (D)

ii)
A. 30 sec
B. 45 sec
C. 60 sec
D. 75 sec
E. 90 sec

Answer: (B)

Relative Speed

There is a particular type of problem in TSD where many of us often gets stumped. At the first look the questions seems to provide inadequate information, but in fact the details are cleverly disguised. There is no special formula except D = S * T which makes the job even more frustrating. Here is a couple of examples of such problems. Typically, we are asked to find distance in most such questions, but they could be tweaked differently too. Te key for such problems is to assume some variables D and T and construct 2 equations. We then need to make use of the following facts depending on the question to construct the equations.

1. When Distance is constant - Time is inversely proportional to speed
2. When Time is constant - Distance is directly proportional to Speed
3. When Speed is constant - Distance is directly proportional to Time

Here are two frustrating problems Give it a try and I shall discuss the solutions in my subsequent post.

1. Two buses A and B leave cities P and Q at equal speeds from cities P and Q and travel at equal speeds. They meet at a point R after 2 hours and continue further to reach cities Q and P. Next day, Bus A starts 36 minutes early, and bus B starts 24 minutes late and they meet at a point S such that RS = 24 km. Find the distance between the cities P and Q.

A. 96 km
B. 144 km
C. 160 km
D. 184 km
E. 192 km

Answer: (E)

2. Two buses P and Q start from cities A and B towards each other. They meet at a distance of 22 km from City B, cross each other to reach city B and A and turn back. During the second time they meet at a distance of 10 km from City A. Find the distance between cities A and B.

A. 24 km
B. 56 km
C. 60 km
D. 72 km
E. 84 km

Answer: (B)

I plan to add some more content on circular tracks, relay races and clocks. Do let me know if you find the post useful. That would help me stay motivated to add further contents

P.S. – I shall post the answers to the questions after a few days. In the meantime, it would be good to see some attempts and analyses. I shall try pitching in from time to time