A clock correct three times a day
up vote
51
down vote
favorite
A stopped clock tells the right time twice a day. How fast must a
clock go for it to be right three times a day?
time
|
show 5 more comments
up vote
51
down vote
favorite
A stopped clock tells the right time twice a day. How fast must a
clock go for it to be right three times a day?
time
1
I'm a bit confused. So, the clock is stopped or it works?
– rhsquared
Nov 22 at 9:22
11
@rhsquared There are two clocks :)
– Anush
Nov 22 at 9:27
1
Could one not argue that a clock that has stopped running at exactly 12.00 o'clock is also correct three times a day? Once at midnight, once at noon and again at midnight. Or, should we count these occurrences at midnight only as ½ ?
– Ideogram
Nov 23 at 6:57
12
A stopped clock will tell the right time three times a day, if it's the day daylight saving ends ...
– Julia Hayward
Nov 23 at 7:50
1
@Ideogram one definitely could argue that, but it's typically better not to. Whenever agreeing on conventions, one must have a purpose in mind; preserving simple addition is usually deemed quite important, so a midnight (00:00) is generally considered to belong to the next day. This results in a period of two days having as many midnights as day one and day two added together. If one counted the moment of midnight belonging to both days, this wouldn't hold.
– Bass
Nov 23 at 11:31
|
show 5 more comments
up vote
51
down vote
favorite
up vote
51
down vote
favorite
A stopped clock tells the right time twice a day. How fast must a
clock go for it to be right three times a day?
time
A stopped clock tells the right time twice a day. How fast must a
clock go for it to be right three times a day?
time
time
asked Nov 22 at 9:14
Anush
892420
892420
1
I'm a bit confused. So, the clock is stopped or it works?
– rhsquared
Nov 22 at 9:22
11
@rhsquared There are two clocks :)
– Anush
Nov 22 at 9:27
1
Could one not argue that a clock that has stopped running at exactly 12.00 o'clock is also correct three times a day? Once at midnight, once at noon and again at midnight. Or, should we count these occurrences at midnight only as ½ ?
– Ideogram
Nov 23 at 6:57
12
A stopped clock will tell the right time three times a day, if it's the day daylight saving ends ...
– Julia Hayward
Nov 23 at 7:50
1
@Ideogram one definitely could argue that, but it's typically better not to. Whenever agreeing on conventions, one must have a purpose in mind; preserving simple addition is usually deemed quite important, so a midnight (00:00) is generally considered to belong to the next day. This results in a period of two days having as many midnights as day one and day two added together. If one counted the moment of midnight belonging to both days, this wouldn't hold.
– Bass
Nov 23 at 11:31
|
show 5 more comments
1
I'm a bit confused. So, the clock is stopped or it works?
– rhsquared
Nov 22 at 9:22
11
@rhsquared There are two clocks :)
– Anush
Nov 22 at 9:27
1
Could one not argue that a clock that has stopped running at exactly 12.00 o'clock is also correct three times a day? Once at midnight, once at noon and again at midnight. Or, should we count these occurrences at midnight only as ½ ?
– Ideogram
Nov 23 at 6:57
12
A stopped clock will tell the right time three times a day, if it's the day daylight saving ends ...
– Julia Hayward
Nov 23 at 7:50
1
@Ideogram one definitely could argue that, but it's typically better not to. Whenever agreeing on conventions, one must have a purpose in mind; preserving simple addition is usually deemed quite important, so a midnight (00:00) is generally considered to belong to the next day. This results in a period of two days having as many midnights as day one and day two added together. If one counted the moment of midnight belonging to both days, this wouldn't hold.
– Bass
Nov 23 at 11:31
1
1
I'm a bit confused. So, the clock is stopped or it works?
– rhsquared
Nov 22 at 9:22
I'm a bit confused. So, the clock is stopped or it works?
– rhsquared
Nov 22 at 9:22
11
11
@rhsquared There are two clocks :)
– Anush
Nov 22 at 9:27
@rhsquared There are two clocks :)
– Anush
Nov 22 at 9:27
1
1
Could one not argue that a clock that has stopped running at exactly 12.00 o'clock is also correct three times a day? Once at midnight, once at noon and again at midnight. Or, should we count these occurrences at midnight only as ½ ?
– Ideogram
Nov 23 at 6:57
Could one not argue that a clock that has stopped running at exactly 12.00 o'clock is also correct three times a day? Once at midnight, once at noon and again at midnight. Or, should we count these occurrences at midnight only as ½ ?
– Ideogram
Nov 23 at 6:57
12
12
A stopped clock will tell the right time three times a day, if it's the day daylight saving ends ...
– Julia Hayward
Nov 23 at 7:50
A stopped clock will tell the right time three times a day, if it's the day daylight saving ends ...
– Julia Hayward
Nov 23 at 7:50
1
1
@Ideogram one definitely could argue that, but it's typically better not to. Whenever agreeing on conventions, one must have a purpose in mind; preserving simple addition is usually deemed quite important, so a midnight (00:00) is generally considered to belong to the next day. This results in a period of two days having as many midnights as day one and day two added together. If one counted the moment of midnight belonging to both days, this wouldn't hold.
– Bass
Nov 23 at 11:31
@Ideogram one definitely could argue that, but it's typically better not to. Whenever agreeing on conventions, one must have a purpose in mind; preserving simple addition is usually deemed quite important, so a midnight (00:00) is generally considered to belong to the next day. This results in a period of two days having as many midnights as day one and day two added together. If one counted the moment of midnight belonging to both days, this wouldn't hold.
– Bass
Nov 23 at 11:31
|
show 5 more comments
12 Answers
12
active
oldest
votes
up vote
59
down vote
accepted
Since a stopped clock already agrees with a correctly running clock twice per day,
let's just add a third time by having the clock run backwards once per day.
So the answer (that requires the smallest clock hand speed) is
half speed backwards.
Since the answer must be symmetrical (as long as the difference in speeds remains the same, it doesn't matter if our clock is getting ahead or behind the correctly running one), we can get the other answer by adding twice the speed difference:
$-0.5 + 2 times (1 - (-0.5)) = 2.5 $ times the regular speed.
1
What’s the general solution for the clock to be correct x times a day?
– Anush
Nov 22 at 23:07
2
@Anush, the accumulated error must come to x full circles per day, and a regular clock runs at 2 full circles per day, so the the speed difference (rate of error accumulation) must be x/2 times the regular speed. So for example, for x=2, the error must accumulate at 1 (the unit is "hours per hour", or "circles per circle"), which gives the solutions of $1 pm 1$ times the regular speed.
– Bass
Nov 23 at 5:13
what happens if x=0?
– JonMark Perry
2 days ago
@JonMarkPerry Well, using the pattern from above, the error accumulation rate must then be exactly 0/2. (Any clock running at exactly the right speed, barring the one obvious exception, is never correct.)
– Bass
2 days ago
@JonMarkPerry If you want a clock to never be correct, just let it run exactly at the correct speed but with a non-zero offset from the correct time.
– zovits
21 hours ago
|
show 2 more comments
up vote
31
down vote
Suppose we have an accurate clock and the fast clock, and that they start off showing the same time.
Over the next period of 24 hours, we want the fast clock to equal the normal clock two more times. So it needs to overtake the real clock twice, and then catch up with it again at exactly the end of those 24 hours for the start of the next 24 hour period. So while the accurate clock goes around twice, the fast clock must go around $2+3=5$ times.
This means that the fast clock goes at $5/2=2.5$ times regular speed.
Here is an alternative method:
Three times a day means every $8$ hours. So in $8$ hours the fast clock must do the same as a regular clock plus one full revolution, i.e. $8+12=20$ hours. It therefore goes at $20/8=2.5$ times the regular speed.
add a comment |
up vote
23
down vote
Alternative method:
The clock is not moving its hands, but is instead moving around the earth through timezones. Each time "moves" around the earth to the west, so the clock travels east to meet them. In order to encounter each time 3 times in a 24-hour period, it has to travel half the distance around the earth. Actual speed would depend on the precise latitude, slower closer to the poles.
The answer to how fast the clock must go:
180 degrees eastward a day, or 7.5 degrees per hour.
New contributor
3
Nice and different.
– Deduplicator
Nov 22 at 16:22
add a comment |
up vote
12
down vote
It should be right three times a day when
its stopped during Daylight Saving Time at 1:00
Reasoning:
During the fall change, clocks move back one hour. If you had the clock set to 1:00, it would be right at 0100 hrs, 0200 hrs (when it switches back to 0100 hrs), then at 1300 hrs (1:00 pm)
add a comment |
up vote
8
down vote
A stopped clock tells the right time twice a day. How fast must a clock go for it to be right three times a day?
It must travel at
on average approximately 45–50mph, twice per day
Here's how:
Our clock is broken and has the time pointed at 4 o'clock. It starts in the city of Gary, Indiana, USA (EST, UTC-5).
At 4am, our clock will be correct for the first time.
At 4pm, our clock will be correct for the second time. Then we hop in our car with the clock.
Using the I-90 E we can head westward to reach Chicago, Illinois in about 40 minutes (see Google Maps for the journey). 4pm is an off-peak time so travel ought to be fairly smooth. By the time we're in Chicago, we're in CST, UST-6, and the local time is about 3:40pm with good timing. Once it reaches 4pm again, our clock's been right for the third time today.
Our job well done, we drive back to our home in Gary, Indiana and return our clock to where we kept it.
add a comment |
up vote
4
down vote
The clock needs to be moving at
2.5 times normal speed
Reasoning:
If you were to graph the stationary clock and normal time, then you would have a flat line, and 2 diagonal lines - these would cross at 2 points, which are the times where the clock is "correct".
Since we cannot change normal time (barring DST or timezones) we need to increase the slope on the stopped (henceforth "wrong") clock until it intersects normal time thrice.
This cannot happen until the Wrong Clock is moving at least as fast as the Correct Clock. At 1:1 the clock is either always right or always wrong. At 2:1 the clock will be "correct" at 12 hour intervals (e.g. Midnight, Noon and Midnight, or twice per day)
As soon as your Wrong Clock is moving slightly faster than 2:1 then your "correct" periods will also be slightly more frequent than every 12 hours - or 3 times some days, and 2 times all the rest.
To be right 3 times every day, you need to be right every 8 hours - which is a ratio of 5:2, or 2.5 time normal speed
add a comment |
up vote
1
down vote
So if we are talking about an analog clock then it will come to same position three times a day if hours become 36 and to cover 36 hours in the routine 24 hours 1 second should become 1.5 second. $1.5*3600*24=129600$ seconds and since $36*3600=129600$ So speed of clock will increase so that 1 second will become equal to 1.5 second.
New contributor
Which are the hours it would be correct?
– Anush
Nov 22 at 21:49
add a comment |
up vote
1
down vote
An analog clock with a second hand that jumps instantaneously every second is right 86400 times a day, so it's also right 3 times a day.
1
The same argument for digital clocks
– gota
Nov 23 at 17:16
add a comment |
up vote
1
down vote
There is a slight ambiguity/lack of precision in the question wording which (in my interpretation) means there isn't a definitive answer as other answers suggest.
Up front, my answer is:
A clock that is more than 2 times faster and less than or equal to 3 times faster than a perfect clock, can be observed to be correct 3 times in one day
First I'd like to introduce a concept that makes the rest of this answer easier to explain
Suppose I have a perfect clock, that is accurate and on time. Suppose I also have a broken clock that I position so it shows a time one minute before the current time on the perfect clock, and then I move the minute hand of the broken clock so it shows a time one minute after the perfect clock. At some point during that motion, the broken clock was showing a time that was accurate. It occurred just (infinitesimally) prior to the exact moment the broken clock time moved past the perfect clock time.
Hence, when a clock is faulty (running fast) and it "overtakes" a perfect clock, for the briefest of moments the time the faulty clock is observed to be perfectly accurate.
We must hence work out how fast a clock must run to overtake a perfect clock 3 times in a 24 hour period
- If a faulty clock runs twice as fast as perfect clock, and we set them going both showing 12:00, they are in sync. This is the first time they are in sync. Let's also say it's Monday
- 6 hours after we started, the faulty fast clock is back at the start position, but the perfect clock is only half way round
- 12 hours after we started, the faulty fast clock will overtake the perfect clock and it's the second time it has happened
- 24 hours after we started, the fast clock again overtakes the perfect clock. It does so on the exact stroke of midnight but this means it's a new day (i.e. it's now Tuesday)
- Our fast clock only overtook the perfect clock twice - at the outset, and at noon
This means...
... 2 times normal speed isn't enough to get the fast clock to overtake the perfect clock 3 times
However, if a clock runs...
... just fractionally faster than 2 times normal speed, then it will overtake a perfect clock 3 times in one day. If we have a clock that is a double speed plus one second faster (i.e. it counts (86400 * 2) + 1 seconds in a single day) then from being synced to a perfect clock on midnight monday (first overtake) it will overtake the perfect clock at around 11:59:59.5 (half a second to noon) and again at around 23:59:59 (just before it becomes Tuesday)
Now, I initially started the fast clock at the same time as the perfect clock, meaning they were on an overtake from the start. What if I put the fast clock at the maximum disadvantage? If I start the fast clock at one second ahead of the perfect clock it's at a considerable disadvantage in the race and has a huge amount of catching up to do before it will register the same time as the perfect clock.
With a perfect clock at midnight and a faulty clock at midnight+1 second with a running rate of 3 times faster, the faulty clock will first catch up at 1 second past 6am, again at 1 second past noon, thirdly at 1 second past 6pm and the next time it registers the same time is at 1 second past midnight on the following day. If the fast clock goes any faster, 4 overtakes will occur in the day
Hence the answer given above..
But before I finish:
A Special Note
2.5 times is a special speed factor; it's the only speed factor where the faulty fast clock will overtake (=show the correct time) three times a day, day in day out without being manipulated further. Any speed factor slower than this will, after some variable number of days depending on the speed factor, result in a clock that has too much catching up to do at the start of the day and won't run fast enough to overtake the perfect clock 3 times in the day. How often these "can't overtake 3 times" days occur is a function of how slow the clock is. Values near 2x or 3x speed will take a long time to get back to a state where they can have a "3 overtakes" day. Values near 2.5x speed will have many days in a row where they perform 3 overtakes, only occasionally dipping to a 2-overtake day
The question didn't call for every day (for the rest of the clock's life) being a 3-overtake day, only that a faulty clock should show the correct time 3 times in a day, hence why I feel the answer has to be..
..a range
add a comment |
up vote
0
down vote
Assumption 1: The regular 12 hour clock-face.
Assumption 2: Fast here does not mean an offset but that the clock is actually running at a higher speed.
It should rotate at 60 (false) hours per day (instead of 24 hours per
day).
Assuming we start at 00:00 on day 1 (actual time) and set the false clock at 00:00 and switch it ON. -- FIRST TIME it is RIGHT
By the time it is 08:00 (AM actual time) which 1/3 of the day past, the false time would show as 08:00 too as it would finish 1/3 of 60 hours which is 20 hours or 12 hours false time (one complete rotation from 00:00) + 8 hours and it would point to 08:00 on the clock. -- SECOND TIME it is RIGHT
By the time it is 04:00 (PM actual time) which 2/3 of the day past, the false time would show as 04:00 too as it would finish 2/3 of 60 hours which is 40 hours or 36 hours false time (3 complete rotations from 00:00) + 4 hours and it would point to 04:00 on the clock. -- THIRD TIME it is RIGHT
Using the same math, it would be RIGHT again at 00:00 (FIRST TIME of next day) and so on.
New contributor
add a comment |
up vote
-1
down vote
Answer:
It must move 3 seconds for every 2 seconds that pass, so 1.5 times as fast as a normal clock.
Reason:
In a 24 hour period, 36 hours will have transpired on this faster clock, meaning it will have made 3 rotations within the day. At some point in each of those rotations, the correct time will have been passed, meaning it is right 3 times a day.
3
You may want to check your premise: Using your example, if the clock shows the correct time at Midnight, it will not show the correct time again until the following Midnight...
– Chronocidal
Nov 22 at 9:38
@Chronocidal dang u right, i think my brain was working on a fast clock vs a stopped clock lol
– AHKieran
Nov 22 at 9:54
You did manage to fool at least 2 more people though ;)
– Geliormth
Nov 22 at 11:45
add a comment |
up vote
-2
down vote
The speed has to be
-1 so the clock will be at the same spot at 00, 06 and 18
New contributor
Welcome to Puzzling SE. Could you add more explanation to what you mean by a speed of -1? Also if you'd like to learn more about this site and earn your first badge, check out the tour at this link: puzzling.stackexchange.com/tour
– gabbo1092
Nov 22 at 14:27
2
This would be right at 12 too, wouldn't it?
– jafe
Nov 22 at 14:27
add a comment |
protected by JonMark Perry Nov 24 at 7:37
Thank you for your interest in this question.
Because it has attracted low-quality or spam answers that had to be removed, posting an answer now requires 10 reputation on this site (the association bonus does not count).
Would you like to answer one of these unanswered questions instead?
12 Answers
12
active
oldest
votes
12 Answers
12
active
oldest
votes
active
oldest
votes
active
oldest
votes
up vote
59
down vote
accepted
Since a stopped clock already agrees with a correctly running clock twice per day,
let's just add a third time by having the clock run backwards once per day.
So the answer (that requires the smallest clock hand speed) is
half speed backwards.
Since the answer must be symmetrical (as long as the difference in speeds remains the same, it doesn't matter if our clock is getting ahead or behind the correctly running one), we can get the other answer by adding twice the speed difference:
$-0.5 + 2 times (1 - (-0.5)) = 2.5 $ times the regular speed.
1
What’s the general solution for the clock to be correct x times a day?
– Anush
Nov 22 at 23:07
2
@Anush, the accumulated error must come to x full circles per day, and a regular clock runs at 2 full circles per day, so the the speed difference (rate of error accumulation) must be x/2 times the regular speed. So for example, for x=2, the error must accumulate at 1 (the unit is "hours per hour", or "circles per circle"), which gives the solutions of $1 pm 1$ times the regular speed.
– Bass
Nov 23 at 5:13
what happens if x=0?
– JonMark Perry
2 days ago
@JonMarkPerry Well, using the pattern from above, the error accumulation rate must then be exactly 0/2. (Any clock running at exactly the right speed, barring the one obvious exception, is never correct.)
– Bass
2 days ago
@JonMarkPerry If you want a clock to never be correct, just let it run exactly at the correct speed but with a non-zero offset from the correct time.
– zovits
21 hours ago
|
show 2 more comments
up vote
59
down vote
accepted
Since a stopped clock already agrees with a correctly running clock twice per day,
let's just add a third time by having the clock run backwards once per day.
So the answer (that requires the smallest clock hand speed) is
half speed backwards.
Since the answer must be symmetrical (as long as the difference in speeds remains the same, it doesn't matter if our clock is getting ahead or behind the correctly running one), we can get the other answer by adding twice the speed difference:
$-0.5 + 2 times (1 - (-0.5)) = 2.5 $ times the regular speed.
1
What’s the general solution for the clock to be correct x times a day?
– Anush
Nov 22 at 23:07
2
@Anush, the accumulated error must come to x full circles per day, and a regular clock runs at 2 full circles per day, so the the speed difference (rate of error accumulation) must be x/2 times the regular speed. So for example, for x=2, the error must accumulate at 1 (the unit is "hours per hour", or "circles per circle"), which gives the solutions of $1 pm 1$ times the regular speed.
– Bass
Nov 23 at 5:13
what happens if x=0?
– JonMark Perry
2 days ago
@JonMarkPerry Well, using the pattern from above, the error accumulation rate must then be exactly 0/2. (Any clock running at exactly the right speed, barring the one obvious exception, is never correct.)
– Bass
2 days ago
@JonMarkPerry If you want a clock to never be correct, just let it run exactly at the correct speed but with a non-zero offset from the correct time.
– zovits
21 hours ago
|
show 2 more comments
up vote
59
down vote
accepted
up vote
59
down vote
accepted
Since a stopped clock already agrees with a correctly running clock twice per day,
let's just add a third time by having the clock run backwards once per day.
So the answer (that requires the smallest clock hand speed) is
half speed backwards.
Since the answer must be symmetrical (as long as the difference in speeds remains the same, it doesn't matter if our clock is getting ahead or behind the correctly running one), we can get the other answer by adding twice the speed difference:
$-0.5 + 2 times (1 - (-0.5)) = 2.5 $ times the regular speed.
Since a stopped clock already agrees with a correctly running clock twice per day,
let's just add a third time by having the clock run backwards once per day.
So the answer (that requires the smallest clock hand speed) is
half speed backwards.
Since the answer must be symmetrical (as long as the difference in speeds remains the same, it doesn't matter if our clock is getting ahead or behind the correctly running one), we can get the other answer by adding twice the speed difference:
$-0.5 + 2 times (1 - (-0.5)) = 2.5 $ times the regular speed.
edited Nov 22 at 16:28
answered Nov 22 at 11:37
Bass
26.4k465166
26.4k465166
1
What’s the general solution for the clock to be correct x times a day?
– Anush
Nov 22 at 23:07
2
@Anush, the accumulated error must come to x full circles per day, and a regular clock runs at 2 full circles per day, so the the speed difference (rate of error accumulation) must be x/2 times the regular speed. So for example, for x=2, the error must accumulate at 1 (the unit is "hours per hour", or "circles per circle"), which gives the solutions of $1 pm 1$ times the regular speed.
– Bass
Nov 23 at 5:13
what happens if x=0?
– JonMark Perry
2 days ago
@JonMarkPerry Well, using the pattern from above, the error accumulation rate must then be exactly 0/2. (Any clock running at exactly the right speed, barring the one obvious exception, is never correct.)
– Bass
2 days ago
@JonMarkPerry If you want a clock to never be correct, just let it run exactly at the correct speed but with a non-zero offset from the correct time.
– zovits
21 hours ago
|
show 2 more comments
1
What’s the general solution for the clock to be correct x times a day?
– Anush
Nov 22 at 23:07
2
@Anush, the accumulated error must come to x full circles per day, and a regular clock runs at 2 full circles per day, so the the speed difference (rate of error accumulation) must be x/2 times the regular speed. So for example, for x=2, the error must accumulate at 1 (the unit is "hours per hour", or "circles per circle"), which gives the solutions of $1 pm 1$ times the regular speed.
– Bass
Nov 23 at 5:13
what happens if x=0?
– JonMark Perry
2 days ago
@JonMarkPerry Well, using the pattern from above, the error accumulation rate must then be exactly 0/2. (Any clock running at exactly the right speed, barring the one obvious exception, is never correct.)
– Bass
2 days ago
@JonMarkPerry If you want a clock to never be correct, just let it run exactly at the correct speed but with a non-zero offset from the correct time.
– zovits
21 hours ago
1
1
What’s the general solution for the clock to be correct x times a day?
– Anush
Nov 22 at 23:07
What’s the general solution for the clock to be correct x times a day?
– Anush
Nov 22 at 23:07
2
2
@Anush, the accumulated error must come to x full circles per day, and a regular clock runs at 2 full circles per day, so the the speed difference (rate of error accumulation) must be x/2 times the regular speed. So for example, for x=2, the error must accumulate at 1 (the unit is "hours per hour", or "circles per circle"), which gives the solutions of $1 pm 1$ times the regular speed.
– Bass
Nov 23 at 5:13
@Anush, the accumulated error must come to x full circles per day, and a regular clock runs at 2 full circles per day, so the the speed difference (rate of error accumulation) must be x/2 times the regular speed. So for example, for x=2, the error must accumulate at 1 (the unit is "hours per hour", or "circles per circle"), which gives the solutions of $1 pm 1$ times the regular speed.
– Bass
Nov 23 at 5:13
what happens if x=0?
– JonMark Perry
2 days ago
what happens if x=0?
– JonMark Perry
2 days ago
@JonMarkPerry Well, using the pattern from above, the error accumulation rate must then be exactly 0/2. (Any clock running at exactly the right speed, barring the one obvious exception, is never correct.)
– Bass
2 days ago
@JonMarkPerry Well, using the pattern from above, the error accumulation rate must then be exactly 0/2. (Any clock running at exactly the right speed, barring the one obvious exception, is never correct.)
– Bass
2 days ago
@JonMarkPerry If you want a clock to never be correct, just let it run exactly at the correct speed but with a non-zero offset from the correct time.
– zovits
21 hours ago
@JonMarkPerry If you want a clock to never be correct, just let it run exactly at the correct speed but with a non-zero offset from the correct time.
– zovits
21 hours ago
|
show 2 more comments
up vote
31
down vote
Suppose we have an accurate clock and the fast clock, and that they start off showing the same time.
Over the next period of 24 hours, we want the fast clock to equal the normal clock two more times. So it needs to overtake the real clock twice, and then catch up with it again at exactly the end of those 24 hours for the start of the next 24 hour period. So while the accurate clock goes around twice, the fast clock must go around $2+3=5$ times.
This means that the fast clock goes at $5/2=2.5$ times regular speed.
Here is an alternative method:
Three times a day means every $8$ hours. So in $8$ hours the fast clock must do the same as a regular clock plus one full revolution, i.e. $8+12=20$ hours. It therefore goes at $20/8=2.5$ times the regular speed.
add a comment |
up vote
31
down vote
Suppose we have an accurate clock and the fast clock, and that they start off showing the same time.
Over the next period of 24 hours, we want the fast clock to equal the normal clock two more times. So it needs to overtake the real clock twice, and then catch up with it again at exactly the end of those 24 hours for the start of the next 24 hour period. So while the accurate clock goes around twice, the fast clock must go around $2+3=5$ times.
This means that the fast clock goes at $5/2=2.5$ times regular speed.
Here is an alternative method:
Three times a day means every $8$ hours. So in $8$ hours the fast clock must do the same as a regular clock plus one full revolution, i.e. $8+12=20$ hours. It therefore goes at $20/8=2.5$ times the regular speed.
add a comment |
up vote
31
down vote
up vote
31
down vote
Suppose we have an accurate clock and the fast clock, and that they start off showing the same time.
Over the next period of 24 hours, we want the fast clock to equal the normal clock two more times. So it needs to overtake the real clock twice, and then catch up with it again at exactly the end of those 24 hours for the start of the next 24 hour period. So while the accurate clock goes around twice, the fast clock must go around $2+3=5$ times.
This means that the fast clock goes at $5/2=2.5$ times regular speed.
Here is an alternative method:
Three times a day means every $8$ hours. So in $8$ hours the fast clock must do the same as a regular clock plus one full revolution, i.e. $8+12=20$ hours. It therefore goes at $20/8=2.5$ times the regular speed.
Suppose we have an accurate clock and the fast clock, and that they start off showing the same time.
Over the next period of 24 hours, we want the fast clock to equal the normal clock two more times. So it needs to overtake the real clock twice, and then catch up with it again at exactly the end of those 24 hours for the start of the next 24 hour period. So while the accurate clock goes around twice, the fast clock must go around $2+3=5$ times.
This means that the fast clock goes at $5/2=2.5$ times regular speed.
Here is an alternative method:
Three times a day means every $8$ hours. So in $8$ hours the fast clock must do the same as a regular clock plus one full revolution, i.e. $8+12=20$ hours. It therefore goes at $20/8=2.5$ times the regular speed.
edited Nov 22 at 9:58
answered Nov 22 at 9:51
Jaap Scherphuis
14.2k12463
14.2k12463
add a comment |
add a comment |
up vote
23
down vote
Alternative method:
The clock is not moving its hands, but is instead moving around the earth through timezones. Each time "moves" around the earth to the west, so the clock travels east to meet them. In order to encounter each time 3 times in a 24-hour period, it has to travel half the distance around the earth. Actual speed would depend on the precise latitude, slower closer to the poles.
The answer to how fast the clock must go:
180 degrees eastward a day, or 7.5 degrees per hour.
New contributor
3
Nice and different.
– Deduplicator
Nov 22 at 16:22
add a comment |
up vote
23
down vote
Alternative method:
The clock is not moving its hands, but is instead moving around the earth through timezones. Each time "moves" around the earth to the west, so the clock travels east to meet them. In order to encounter each time 3 times in a 24-hour period, it has to travel half the distance around the earth. Actual speed would depend on the precise latitude, slower closer to the poles.
The answer to how fast the clock must go:
180 degrees eastward a day, or 7.5 degrees per hour.
New contributor
3
Nice and different.
– Deduplicator
Nov 22 at 16:22
add a comment |
up vote
23
down vote
up vote
23
down vote
Alternative method:
The clock is not moving its hands, but is instead moving around the earth through timezones. Each time "moves" around the earth to the west, so the clock travels east to meet them. In order to encounter each time 3 times in a 24-hour period, it has to travel half the distance around the earth. Actual speed would depend on the precise latitude, slower closer to the poles.
The answer to how fast the clock must go:
180 degrees eastward a day, or 7.5 degrees per hour.
New contributor
Alternative method:
The clock is not moving its hands, but is instead moving around the earth through timezones. Each time "moves" around the earth to the west, so the clock travels east to meet them. In order to encounter each time 3 times in a 24-hour period, it has to travel half the distance around the earth. Actual speed would depend on the precise latitude, slower closer to the poles.
The answer to how fast the clock must go:
180 degrees eastward a day, or 7.5 degrees per hour.
New contributor
edited Nov 22 at 16:33
New contributor
answered Nov 22 at 15:29
Grollo
3315
3315
New contributor
New contributor
3
Nice and different.
– Deduplicator
Nov 22 at 16:22
add a comment |
3
Nice and different.
– Deduplicator
Nov 22 at 16:22
3
3
Nice and different.
– Deduplicator
Nov 22 at 16:22
Nice and different.
– Deduplicator
Nov 22 at 16:22
add a comment |
up vote
12
down vote
It should be right three times a day when
its stopped during Daylight Saving Time at 1:00
Reasoning:
During the fall change, clocks move back one hour. If you had the clock set to 1:00, it would be right at 0100 hrs, 0200 hrs (when it switches back to 0100 hrs), then at 1300 hrs (1:00 pm)
add a comment |
up vote
12
down vote
It should be right three times a day when
its stopped during Daylight Saving Time at 1:00
Reasoning:
During the fall change, clocks move back one hour. If you had the clock set to 1:00, it would be right at 0100 hrs, 0200 hrs (when it switches back to 0100 hrs), then at 1300 hrs (1:00 pm)
add a comment |
up vote
12
down vote
up vote
12
down vote
It should be right three times a day when
its stopped during Daylight Saving Time at 1:00
Reasoning:
During the fall change, clocks move back one hour. If you had the clock set to 1:00, it would be right at 0100 hrs, 0200 hrs (when it switches back to 0100 hrs), then at 1300 hrs (1:00 pm)
It should be right three times a day when
its stopped during Daylight Saving Time at 1:00
Reasoning:
During the fall change, clocks move back one hour. If you had the clock set to 1:00, it would be right at 0100 hrs, 0200 hrs (when it switches back to 0100 hrs), then at 1300 hrs (1:00 pm)
answered Nov 22 at 17:44
Canadian Luke
23219
23219
add a comment |
add a comment |
up vote
8
down vote
A stopped clock tells the right time twice a day. How fast must a clock go for it to be right three times a day?
It must travel at
on average approximately 45–50mph, twice per day
Here's how:
Our clock is broken and has the time pointed at 4 o'clock. It starts in the city of Gary, Indiana, USA (EST, UTC-5).
At 4am, our clock will be correct for the first time.
At 4pm, our clock will be correct for the second time. Then we hop in our car with the clock.
Using the I-90 E we can head westward to reach Chicago, Illinois in about 40 minutes (see Google Maps for the journey). 4pm is an off-peak time so travel ought to be fairly smooth. By the time we're in Chicago, we're in CST, UST-6, and the local time is about 3:40pm with good timing. Once it reaches 4pm again, our clock's been right for the third time today.
Our job well done, we drive back to our home in Gary, Indiana and return our clock to where we kept it.
add a comment |
up vote
8
down vote
A stopped clock tells the right time twice a day. How fast must a clock go for it to be right three times a day?
It must travel at
on average approximately 45–50mph, twice per day
Here's how:
Our clock is broken and has the time pointed at 4 o'clock. It starts in the city of Gary, Indiana, USA (EST, UTC-5).
At 4am, our clock will be correct for the first time.
At 4pm, our clock will be correct for the second time. Then we hop in our car with the clock.
Using the I-90 E we can head westward to reach Chicago, Illinois in about 40 minutes (see Google Maps for the journey). 4pm is an off-peak time so travel ought to be fairly smooth. By the time we're in Chicago, we're in CST, UST-6, and the local time is about 3:40pm with good timing. Once it reaches 4pm again, our clock's been right for the third time today.
Our job well done, we drive back to our home in Gary, Indiana and return our clock to where we kept it.
add a comment |
up vote
8
down vote
up vote
8
down vote
A stopped clock tells the right time twice a day. How fast must a clock go for it to be right three times a day?
It must travel at
on average approximately 45–50mph, twice per day
Here's how:
Our clock is broken and has the time pointed at 4 o'clock. It starts in the city of Gary, Indiana, USA (EST, UTC-5).
At 4am, our clock will be correct for the first time.
At 4pm, our clock will be correct for the second time. Then we hop in our car with the clock.
Using the I-90 E we can head westward to reach Chicago, Illinois in about 40 minutes (see Google Maps for the journey). 4pm is an off-peak time so travel ought to be fairly smooth. By the time we're in Chicago, we're in CST, UST-6, and the local time is about 3:40pm with good timing. Once it reaches 4pm again, our clock's been right for the third time today.
Our job well done, we drive back to our home in Gary, Indiana and return our clock to where we kept it.
A stopped clock tells the right time twice a day. How fast must a clock go for it to be right three times a day?
It must travel at
on average approximately 45–50mph, twice per day
Here's how:
Our clock is broken and has the time pointed at 4 o'clock. It starts in the city of Gary, Indiana, USA (EST, UTC-5).
At 4am, our clock will be correct for the first time.
At 4pm, our clock will be correct for the second time. Then we hop in our car with the clock.
Using the I-90 E we can head westward to reach Chicago, Illinois in about 40 minutes (see Google Maps for the journey). 4pm is an off-peak time so travel ought to be fairly smooth. By the time we're in Chicago, we're in CST, UST-6, and the local time is about 3:40pm with good timing. Once it reaches 4pm again, our clock's been right for the third time today.
Our job well done, we drive back to our home in Gary, Indiana and return our clock to where we kept it.
answered Nov 22 at 16:05
doppelgreener
296212
296212
add a comment |
add a comment |
up vote
4
down vote
The clock needs to be moving at
2.5 times normal speed
Reasoning:
If you were to graph the stationary clock and normal time, then you would have a flat line, and 2 diagonal lines - these would cross at 2 points, which are the times where the clock is "correct".
Since we cannot change normal time (barring DST or timezones) we need to increase the slope on the stopped (henceforth "wrong") clock until it intersects normal time thrice.
This cannot happen until the Wrong Clock is moving at least as fast as the Correct Clock. At 1:1 the clock is either always right or always wrong. At 2:1 the clock will be "correct" at 12 hour intervals (e.g. Midnight, Noon and Midnight, or twice per day)
As soon as your Wrong Clock is moving slightly faster than 2:1 then your "correct" periods will also be slightly more frequent than every 12 hours - or 3 times some days, and 2 times all the rest.
To be right 3 times every day, you need to be right every 8 hours - which is a ratio of 5:2, or 2.5 time normal speed
add a comment |
up vote
4
down vote
The clock needs to be moving at
2.5 times normal speed
Reasoning:
If you were to graph the stationary clock and normal time, then you would have a flat line, and 2 diagonal lines - these would cross at 2 points, which are the times where the clock is "correct".
Since we cannot change normal time (barring DST or timezones) we need to increase the slope on the stopped (henceforth "wrong") clock until it intersects normal time thrice.
This cannot happen until the Wrong Clock is moving at least as fast as the Correct Clock. At 1:1 the clock is either always right or always wrong. At 2:1 the clock will be "correct" at 12 hour intervals (e.g. Midnight, Noon and Midnight, or twice per day)
As soon as your Wrong Clock is moving slightly faster than 2:1 then your "correct" periods will also be slightly more frequent than every 12 hours - or 3 times some days, and 2 times all the rest.
To be right 3 times every day, you need to be right every 8 hours - which is a ratio of 5:2, or 2.5 time normal speed
add a comment |
up vote
4
down vote
up vote
4
down vote
The clock needs to be moving at
2.5 times normal speed
Reasoning:
If you were to graph the stationary clock and normal time, then you would have a flat line, and 2 diagonal lines - these would cross at 2 points, which are the times where the clock is "correct".
Since we cannot change normal time (barring DST or timezones) we need to increase the slope on the stopped (henceforth "wrong") clock until it intersects normal time thrice.
This cannot happen until the Wrong Clock is moving at least as fast as the Correct Clock. At 1:1 the clock is either always right or always wrong. At 2:1 the clock will be "correct" at 12 hour intervals (e.g. Midnight, Noon and Midnight, or twice per day)
As soon as your Wrong Clock is moving slightly faster than 2:1 then your "correct" periods will also be slightly more frequent than every 12 hours - or 3 times some days, and 2 times all the rest.
To be right 3 times every day, you need to be right every 8 hours - which is a ratio of 5:2, or 2.5 time normal speed
The clock needs to be moving at
2.5 times normal speed
Reasoning:
If you were to graph the stationary clock and normal time, then you would have a flat line, and 2 diagonal lines - these would cross at 2 points, which are the times where the clock is "correct".
Since we cannot change normal time (barring DST or timezones) we need to increase the slope on the stopped (henceforth "wrong") clock until it intersects normal time thrice.
This cannot happen until the Wrong Clock is moving at least as fast as the Correct Clock. At 1:1 the clock is either always right or always wrong. At 2:1 the clock will be "correct" at 12 hour intervals (e.g. Midnight, Noon and Midnight, or twice per day)
As soon as your Wrong Clock is moving slightly faster than 2:1 then your "correct" periods will also be slightly more frequent than every 12 hours - or 3 times some days, and 2 times all the rest.
To be right 3 times every day, you need to be right every 8 hours - which is a ratio of 5:2, or 2.5 time normal speed
answered Nov 22 at 10:01
Chronocidal
674111
674111
add a comment |
add a comment |
up vote
1
down vote
So if we are talking about an analog clock then it will come to same position three times a day if hours become 36 and to cover 36 hours in the routine 24 hours 1 second should become 1.5 second. $1.5*3600*24=129600$ seconds and since $36*3600=129600$ So speed of clock will increase so that 1 second will become equal to 1.5 second.
New contributor
Which are the hours it would be correct?
– Anush
Nov 22 at 21:49
add a comment |
up vote
1
down vote
So if we are talking about an analog clock then it will come to same position three times a day if hours become 36 and to cover 36 hours in the routine 24 hours 1 second should become 1.5 second. $1.5*3600*24=129600$ seconds and since $36*3600=129600$ So speed of clock will increase so that 1 second will become equal to 1.5 second.
New contributor
Which are the hours it would be correct?
– Anush
Nov 22 at 21:49
add a comment |
up vote
1
down vote
up vote
1
down vote
So if we are talking about an analog clock then it will come to same position three times a day if hours become 36 and to cover 36 hours in the routine 24 hours 1 second should become 1.5 second. $1.5*3600*24=129600$ seconds and since $36*3600=129600$ So speed of clock will increase so that 1 second will become equal to 1.5 second.
New contributor
So if we are talking about an analog clock then it will come to same position three times a day if hours become 36 and to cover 36 hours in the routine 24 hours 1 second should become 1.5 second. $1.5*3600*24=129600$ seconds and since $36*3600=129600$ So speed of clock will increase so that 1 second will become equal to 1.5 second.
New contributor
edited Nov 22 at 20:08
gabbo1092
4,581735
4,581735
New contributor
answered Nov 22 at 19:43
Ihtisham Ali Farooq
384
384
New contributor
New contributor
Which are the hours it would be correct?
– Anush
Nov 22 at 21:49
add a comment |
Which are the hours it would be correct?
– Anush
Nov 22 at 21:49
Which are the hours it would be correct?
– Anush
Nov 22 at 21:49
Which are the hours it would be correct?
– Anush
Nov 22 at 21:49
add a comment |
up vote
1
down vote
An analog clock with a second hand that jumps instantaneously every second is right 86400 times a day, so it's also right 3 times a day.
1
The same argument for digital clocks
– gota
Nov 23 at 17:16
add a comment |
up vote
1
down vote
An analog clock with a second hand that jumps instantaneously every second is right 86400 times a day, so it's also right 3 times a day.
1
The same argument for digital clocks
– gota
Nov 23 at 17:16
add a comment |
up vote
1
down vote
up vote
1
down vote
An analog clock with a second hand that jumps instantaneously every second is right 86400 times a day, so it's also right 3 times a day.
An analog clock with a second hand that jumps instantaneously every second is right 86400 times a day, so it's also right 3 times a day.
answered Nov 23 at 12:36
Peter
177110
177110
1
The same argument for digital clocks
– gota
Nov 23 at 17:16
add a comment |
1
The same argument for digital clocks
– gota
Nov 23 at 17:16
1
1
The same argument for digital clocks
– gota
Nov 23 at 17:16
The same argument for digital clocks
– gota
Nov 23 at 17:16
add a comment |
up vote
1
down vote
There is a slight ambiguity/lack of precision in the question wording which (in my interpretation) means there isn't a definitive answer as other answers suggest.
Up front, my answer is:
A clock that is more than 2 times faster and less than or equal to 3 times faster than a perfect clock, can be observed to be correct 3 times in one day
First I'd like to introduce a concept that makes the rest of this answer easier to explain
Suppose I have a perfect clock, that is accurate and on time. Suppose I also have a broken clock that I position so it shows a time one minute before the current time on the perfect clock, and then I move the minute hand of the broken clock so it shows a time one minute after the perfect clock. At some point during that motion, the broken clock was showing a time that was accurate. It occurred just (infinitesimally) prior to the exact moment the broken clock time moved past the perfect clock time.
Hence, when a clock is faulty (running fast) and it "overtakes" a perfect clock, for the briefest of moments the time the faulty clock is observed to be perfectly accurate.
We must hence work out how fast a clock must run to overtake a perfect clock 3 times in a 24 hour period
- If a faulty clock runs twice as fast as perfect clock, and we set them going both showing 12:00, they are in sync. This is the first time they are in sync. Let's also say it's Monday
- 6 hours after we started, the faulty fast clock is back at the start position, but the perfect clock is only half way round
- 12 hours after we started, the faulty fast clock will overtake the perfect clock and it's the second time it has happened
- 24 hours after we started, the fast clock again overtakes the perfect clock. It does so on the exact stroke of midnight but this means it's a new day (i.e. it's now Tuesday)
- Our fast clock only overtook the perfect clock twice - at the outset, and at noon
This means...
... 2 times normal speed isn't enough to get the fast clock to overtake the perfect clock 3 times
However, if a clock runs...
... just fractionally faster than 2 times normal speed, then it will overtake a perfect clock 3 times in one day. If we have a clock that is a double speed plus one second faster (i.e. it counts (86400 * 2) + 1 seconds in a single day) then from being synced to a perfect clock on midnight monday (first overtake) it will overtake the perfect clock at around 11:59:59.5 (half a second to noon) and again at around 23:59:59 (just before it becomes Tuesday)
Now, I initially started the fast clock at the same time as the perfect clock, meaning they were on an overtake from the start. What if I put the fast clock at the maximum disadvantage? If I start the fast clock at one second ahead of the perfect clock it's at a considerable disadvantage in the race and has a huge amount of catching up to do before it will register the same time as the perfect clock.
With a perfect clock at midnight and a faulty clock at midnight+1 second with a running rate of 3 times faster, the faulty clock will first catch up at 1 second past 6am, again at 1 second past noon, thirdly at 1 second past 6pm and the next time it registers the same time is at 1 second past midnight on the following day. If the fast clock goes any faster, 4 overtakes will occur in the day
Hence the answer given above..
But before I finish:
A Special Note
2.5 times is a special speed factor; it's the only speed factor where the faulty fast clock will overtake (=show the correct time) three times a day, day in day out without being manipulated further. Any speed factor slower than this will, after some variable number of days depending on the speed factor, result in a clock that has too much catching up to do at the start of the day and won't run fast enough to overtake the perfect clock 3 times in the day. How often these "can't overtake 3 times" days occur is a function of how slow the clock is. Values near 2x or 3x speed will take a long time to get back to a state where they can have a "3 overtakes" day. Values near 2.5x speed will have many days in a row where they perform 3 overtakes, only occasionally dipping to a 2-overtake day
The question didn't call for every day (for the rest of the clock's life) being a 3-overtake day, only that a faulty clock should show the correct time 3 times in a day, hence why I feel the answer has to be..
..a range
add a comment |
up vote
1
down vote
There is a slight ambiguity/lack of precision in the question wording which (in my interpretation) means there isn't a definitive answer as other answers suggest.
Up front, my answer is:
A clock that is more than 2 times faster and less than or equal to 3 times faster than a perfect clock, can be observed to be correct 3 times in one day
First I'd like to introduce a concept that makes the rest of this answer easier to explain
Suppose I have a perfect clock, that is accurate and on time. Suppose I also have a broken clock that I position so it shows a time one minute before the current time on the perfect clock, and then I move the minute hand of the broken clock so it shows a time one minute after the perfect clock. At some point during that motion, the broken clock was showing a time that was accurate. It occurred just (infinitesimally) prior to the exact moment the broken clock time moved past the perfect clock time.
Hence, when a clock is faulty (running fast) and it "overtakes" a perfect clock, for the briefest of moments the time the faulty clock is observed to be perfectly accurate.
We must hence work out how fast a clock must run to overtake a perfect clock 3 times in a 24 hour period
- If a faulty clock runs twice as fast as perfect clock, and we set them going both showing 12:00, they are in sync. This is the first time they are in sync. Let's also say it's Monday
- 6 hours after we started, the faulty fast clock is back at the start position, but the perfect clock is only half way round
- 12 hours after we started, the faulty fast clock will overtake the perfect clock and it's the second time it has happened
- 24 hours after we started, the fast clock again overtakes the perfect clock. It does so on the exact stroke of midnight but this means it's a new day (i.e. it's now Tuesday)
- Our fast clock only overtook the perfect clock twice - at the outset, and at noon
This means...
... 2 times normal speed isn't enough to get the fast clock to overtake the perfect clock 3 times
However, if a clock runs...
... just fractionally faster than 2 times normal speed, then it will overtake a perfect clock 3 times in one day. If we have a clock that is a double speed plus one second faster (i.e. it counts (86400 * 2) + 1 seconds in a single day) then from being synced to a perfect clock on midnight monday (first overtake) it will overtake the perfect clock at around 11:59:59.5 (half a second to noon) and again at around 23:59:59 (just before it becomes Tuesday)
Now, I initially started the fast clock at the same time as the perfect clock, meaning they were on an overtake from the start. What if I put the fast clock at the maximum disadvantage? If I start the fast clock at one second ahead of the perfect clock it's at a considerable disadvantage in the race and has a huge amount of catching up to do before it will register the same time as the perfect clock.
With a perfect clock at midnight and a faulty clock at midnight+1 second with a running rate of 3 times faster, the faulty clock will first catch up at 1 second past 6am, again at 1 second past noon, thirdly at 1 second past 6pm and the next time it registers the same time is at 1 second past midnight on the following day. If the fast clock goes any faster, 4 overtakes will occur in the day
Hence the answer given above..
But before I finish:
A Special Note
2.5 times is a special speed factor; it's the only speed factor where the faulty fast clock will overtake (=show the correct time) three times a day, day in day out without being manipulated further. Any speed factor slower than this will, after some variable number of days depending on the speed factor, result in a clock that has too much catching up to do at the start of the day and won't run fast enough to overtake the perfect clock 3 times in the day. How often these "can't overtake 3 times" days occur is a function of how slow the clock is. Values near 2x or 3x speed will take a long time to get back to a state where they can have a "3 overtakes" day. Values near 2.5x speed will have many days in a row where they perform 3 overtakes, only occasionally dipping to a 2-overtake day
The question didn't call for every day (for the rest of the clock's life) being a 3-overtake day, only that a faulty clock should show the correct time 3 times in a day, hence why I feel the answer has to be..
..a range
add a comment |
up vote
1
down vote
up vote
1
down vote
There is a slight ambiguity/lack of precision in the question wording which (in my interpretation) means there isn't a definitive answer as other answers suggest.
Up front, my answer is:
A clock that is more than 2 times faster and less than or equal to 3 times faster than a perfect clock, can be observed to be correct 3 times in one day
First I'd like to introduce a concept that makes the rest of this answer easier to explain
Suppose I have a perfect clock, that is accurate and on time. Suppose I also have a broken clock that I position so it shows a time one minute before the current time on the perfect clock, and then I move the minute hand of the broken clock so it shows a time one minute after the perfect clock. At some point during that motion, the broken clock was showing a time that was accurate. It occurred just (infinitesimally) prior to the exact moment the broken clock time moved past the perfect clock time.
Hence, when a clock is faulty (running fast) and it "overtakes" a perfect clock, for the briefest of moments the time the faulty clock is observed to be perfectly accurate.
We must hence work out how fast a clock must run to overtake a perfect clock 3 times in a 24 hour period
- If a faulty clock runs twice as fast as perfect clock, and we set them going both showing 12:00, they are in sync. This is the first time they are in sync. Let's also say it's Monday
- 6 hours after we started, the faulty fast clock is back at the start position, but the perfect clock is only half way round
- 12 hours after we started, the faulty fast clock will overtake the perfect clock and it's the second time it has happened
- 24 hours after we started, the fast clock again overtakes the perfect clock. It does so on the exact stroke of midnight but this means it's a new day (i.e. it's now Tuesday)
- Our fast clock only overtook the perfect clock twice - at the outset, and at noon
This means...
... 2 times normal speed isn't enough to get the fast clock to overtake the perfect clock 3 times
However, if a clock runs...
... just fractionally faster than 2 times normal speed, then it will overtake a perfect clock 3 times in one day. If we have a clock that is a double speed plus one second faster (i.e. it counts (86400 * 2) + 1 seconds in a single day) then from being synced to a perfect clock on midnight monday (first overtake) it will overtake the perfect clock at around 11:59:59.5 (half a second to noon) and again at around 23:59:59 (just before it becomes Tuesday)
Now, I initially started the fast clock at the same time as the perfect clock, meaning they were on an overtake from the start. What if I put the fast clock at the maximum disadvantage? If I start the fast clock at one second ahead of the perfect clock it's at a considerable disadvantage in the race and has a huge amount of catching up to do before it will register the same time as the perfect clock.
With a perfect clock at midnight and a faulty clock at midnight+1 second with a running rate of 3 times faster, the faulty clock will first catch up at 1 second past 6am, again at 1 second past noon, thirdly at 1 second past 6pm and the next time it registers the same time is at 1 second past midnight on the following day. If the fast clock goes any faster, 4 overtakes will occur in the day
Hence the answer given above..
But before I finish:
A Special Note
2.5 times is a special speed factor; it's the only speed factor where the faulty fast clock will overtake (=show the correct time) three times a day, day in day out without being manipulated further. Any speed factor slower than this will, after some variable number of days depending on the speed factor, result in a clock that has too much catching up to do at the start of the day and won't run fast enough to overtake the perfect clock 3 times in the day. How often these "can't overtake 3 times" days occur is a function of how slow the clock is. Values near 2x or 3x speed will take a long time to get back to a state where they can have a "3 overtakes" day. Values near 2.5x speed will have many days in a row where they perform 3 overtakes, only occasionally dipping to a 2-overtake day
The question didn't call for every day (for the rest of the clock's life) being a 3-overtake day, only that a faulty clock should show the correct time 3 times in a day, hence why I feel the answer has to be..
..a range
There is a slight ambiguity/lack of precision in the question wording which (in my interpretation) means there isn't a definitive answer as other answers suggest.
Up front, my answer is:
A clock that is more than 2 times faster and less than or equal to 3 times faster than a perfect clock, can be observed to be correct 3 times in one day
First I'd like to introduce a concept that makes the rest of this answer easier to explain
Suppose I have a perfect clock, that is accurate and on time. Suppose I also have a broken clock that I position so it shows a time one minute before the current time on the perfect clock, and then I move the minute hand of the broken clock so it shows a time one minute after the perfect clock. At some point during that motion, the broken clock was showing a time that was accurate. It occurred just (infinitesimally) prior to the exact moment the broken clock time moved past the perfect clock time.
Hence, when a clock is faulty (running fast) and it "overtakes" a perfect clock, for the briefest of moments the time the faulty clock is observed to be perfectly accurate.
We must hence work out how fast a clock must run to overtake a perfect clock 3 times in a 24 hour period
- If a faulty clock runs twice as fast as perfect clock, and we set them going both showing 12:00, they are in sync. This is the first time they are in sync. Let's also say it's Monday
- 6 hours after we started, the faulty fast clock is back at the start position, but the perfect clock is only half way round
- 12 hours after we started, the faulty fast clock will overtake the perfect clock and it's the second time it has happened
- 24 hours after we started, the fast clock again overtakes the perfect clock. It does so on the exact stroke of midnight but this means it's a new day (i.e. it's now Tuesday)
- Our fast clock only overtook the perfect clock twice - at the outset, and at noon
This means...
... 2 times normal speed isn't enough to get the fast clock to overtake the perfect clock 3 times
However, if a clock runs...
... just fractionally faster than 2 times normal speed, then it will overtake a perfect clock 3 times in one day. If we have a clock that is a double speed plus one second faster (i.e. it counts (86400 * 2) + 1 seconds in a single day) then from being synced to a perfect clock on midnight monday (first overtake) it will overtake the perfect clock at around 11:59:59.5 (half a second to noon) and again at around 23:59:59 (just before it becomes Tuesday)
Now, I initially started the fast clock at the same time as the perfect clock, meaning they were on an overtake from the start. What if I put the fast clock at the maximum disadvantage? If I start the fast clock at one second ahead of the perfect clock it's at a considerable disadvantage in the race and has a huge amount of catching up to do before it will register the same time as the perfect clock.
With a perfect clock at midnight and a faulty clock at midnight+1 second with a running rate of 3 times faster, the faulty clock will first catch up at 1 second past 6am, again at 1 second past noon, thirdly at 1 second past 6pm and the next time it registers the same time is at 1 second past midnight on the following day. If the fast clock goes any faster, 4 overtakes will occur in the day
Hence the answer given above..
But before I finish:
A Special Note
2.5 times is a special speed factor; it's the only speed factor where the faulty fast clock will overtake (=show the correct time) three times a day, day in day out without being manipulated further. Any speed factor slower than this will, after some variable number of days depending on the speed factor, result in a clock that has too much catching up to do at the start of the day and won't run fast enough to overtake the perfect clock 3 times in the day. How often these "can't overtake 3 times" days occur is a function of how slow the clock is. Values near 2x or 3x speed will take a long time to get back to a state where they can have a "3 overtakes" day. Values near 2.5x speed will have many days in a row where they perform 3 overtakes, only occasionally dipping to a 2-overtake day
The question didn't call for every day (for the rest of the clock's life) being a 3-overtake day, only that a faulty clock should show the correct time 3 times in a day, hence why I feel the answer has to be..
..a range
edited yesterday
answered 2 days ago
Caius Jard
847154
847154
add a comment |
add a comment |
up vote
0
down vote
Assumption 1: The regular 12 hour clock-face.
Assumption 2: Fast here does not mean an offset but that the clock is actually running at a higher speed.
It should rotate at 60 (false) hours per day (instead of 24 hours per
day).
Assuming we start at 00:00 on day 1 (actual time) and set the false clock at 00:00 and switch it ON. -- FIRST TIME it is RIGHT
By the time it is 08:00 (AM actual time) which 1/3 of the day past, the false time would show as 08:00 too as it would finish 1/3 of 60 hours which is 20 hours or 12 hours false time (one complete rotation from 00:00) + 8 hours and it would point to 08:00 on the clock. -- SECOND TIME it is RIGHT
By the time it is 04:00 (PM actual time) which 2/3 of the day past, the false time would show as 04:00 too as it would finish 2/3 of 60 hours which is 40 hours or 36 hours false time (3 complete rotations from 00:00) + 4 hours and it would point to 04:00 on the clock. -- THIRD TIME it is RIGHT
Using the same math, it would be RIGHT again at 00:00 (FIRST TIME of next day) and so on.
New contributor
add a comment |
up vote
0
down vote
Assumption 1: The regular 12 hour clock-face.
Assumption 2: Fast here does not mean an offset but that the clock is actually running at a higher speed.
It should rotate at 60 (false) hours per day (instead of 24 hours per
day).
Assuming we start at 00:00 on day 1 (actual time) and set the false clock at 00:00 and switch it ON. -- FIRST TIME it is RIGHT
By the time it is 08:00 (AM actual time) which 1/3 of the day past, the false time would show as 08:00 too as it would finish 1/3 of 60 hours which is 20 hours or 12 hours false time (one complete rotation from 00:00) + 8 hours and it would point to 08:00 on the clock. -- SECOND TIME it is RIGHT
By the time it is 04:00 (PM actual time) which 2/3 of the day past, the false time would show as 04:00 too as it would finish 2/3 of 60 hours which is 40 hours or 36 hours false time (3 complete rotations from 00:00) + 4 hours and it would point to 04:00 on the clock. -- THIRD TIME it is RIGHT
Using the same math, it would be RIGHT again at 00:00 (FIRST TIME of next day) and so on.
New contributor
add a comment |
up vote
0
down vote
up vote
0
down vote
Assumption 1: The regular 12 hour clock-face.
Assumption 2: Fast here does not mean an offset but that the clock is actually running at a higher speed.
It should rotate at 60 (false) hours per day (instead of 24 hours per
day).
Assuming we start at 00:00 on day 1 (actual time) and set the false clock at 00:00 and switch it ON. -- FIRST TIME it is RIGHT
By the time it is 08:00 (AM actual time) which 1/3 of the day past, the false time would show as 08:00 too as it would finish 1/3 of 60 hours which is 20 hours or 12 hours false time (one complete rotation from 00:00) + 8 hours and it would point to 08:00 on the clock. -- SECOND TIME it is RIGHT
By the time it is 04:00 (PM actual time) which 2/3 of the day past, the false time would show as 04:00 too as it would finish 2/3 of 60 hours which is 40 hours or 36 hours false time (3 complete rotations from 00:00) + 4 hours and it would point to 04:00 on the clock. -- THIRD TIME it is RIGHT
Using the same math, it would be RIGHT again at 00:00 (FIRST TIME of next day) and so on.
New contributor
Assumption 1: The regular 12 hour clock-face.
Assumption 2: Fast here does not mean an offset but that the clock is actually running at a higher speed.
It should rotate at 60 (false) hours per day (instead of 24 hours per
day).
Assuming we start at 00:00 on day 1 (actual time) and set the false clock at 00:00 and switch it ON. -- FIRST TIME it is RIGHT
By the time it is 08:00 (AM actual time) which 1/3 of the day past, the false time would show as 08:00 too as it would finish 1/3 of 60 hours which is 20 hours or 12 hours false time (one complete rotation from 00:00) + 8 hours and it would point to 08:00 on the clock. -- SECOND TIME it is RIGHT
By the time it is 04:00 (PM actual time) which 2/3 of the day past, the false time would show as 04:00 too as it would finish 2/3 of 60 hours which is 40 hours or 36 hours false time (3 complete rotations from 00:00) + 4 hours and it would point to 04:00 on the clock. -- THIRD TIME it is RIGHT
Using the same math, it would be RIGHT again at 00:00 (FIRST TIME of next day) and so on.
New contributor
edited Nov 22 at 17:02
New contributor
answered Nov 22 at 12:38
alwayslearning
24517
24517
New contributor
New contributor
add a comment |
add a comment |
up vote
-1
down vote
Answer:
It must move 3 seconds for every 2 seconds that pass, so 1.5 times as fast as a normal clock.
Reason:
In a 24 hour period, 36 hours will have transpired on this faster clock, meaning it will have made 3 rotations within the day. At some point in each of those rotations, the correct time will have been passed, meaning it is right 3 times a day.
3
You may want to check your premise: Using your example, if the clock shows the correct time at Midnight, it will not show the correct time again until the following Midnight...
– Chronocidal
Nov 22 at 9:38
@Chronocidal dang u right, i think my brain was working on a fast clock vs a stopped clock lol
– AHKieran
Nov 22 at 9:54
You did manage to fool at least 2 more people though ;)
– Geliormth
Nov 22 at 11:45
add a comment |
up vote
-1
down vote
Answer:
It must move 3 seconds for every 2 seconds that pass, so 1.5 times as fast as a normal clock.
Reason:
In a 24 hour period, 36 hours will have transpired on this faster clock, meaning it will have made 3 rotations within the day. At some point in each of those rotations, the correct time will have been passed, meaning it is right 3 times a day.
3
You may want to check your premise: Using your example, if the clock shows the correct time at Midnight, it will not show the correct time again until the following Midnight...
– Chronocidal
Nov 22 at 9:38
@Chronocidal dang u right, i think my brain was working on a fast clock vs a stopped clock lol
– AHKieran
Nov 22 at 9:54
You did manage to fool at least 2 more people though ;)
– Geliormth
Nov 22 at 11:45
add a comment |
up vote
-1
down vote
up vote
-1
down vote
Answer:
It must move 3 seconds for every 2 seconds that pass, so 1.5 times as fast as a normal clock.
Reason:
In a 24 hour period, 36 hours will have transpired on this faster clock, meaning it will have made 3 rotations within the day. At some point in each of those rotations, the correct time will have been passed, meaning it is right 3 times a day.
Answer:
It must move 3 seconds for every 2 seconds that pass, so 1.5 times as fast as a normal clock.
Reason:
In a 24 hour period, 36 hours will have transpired on this faster clock, meaning it will have made 3 rotations within the day. At some point in each of those rotations, the correct time will have been passed, meaning it is right 3 times a day.
answered Nov 22 at 9:18
AHKieran
3,638632
3,638632
3
You may want to check your premise: Using your example, if the clock shows the correct time at Midnight, it will not show the correct time again until the following Midnight...
– Chronocidal
Nov 22 at 9:38
@Chronocidal dang u right, i think my brain was working on a fast clock vs a stopped clock lol
– AHKieran
Nov 22 at 9:54
You did manage to fool at least 2 more people though ;)
– Geliormth
Nov 22 at 11:45
add a comment |
3
You may want to check your premise: Using your example, if the clock shows the correct time at Midnight, it will not show the correct time again until the following Midnight...
– Chronocidal
Nov 22 at 9:38
@Chronocidal dang u right, i think my brain was working on a fast clock vs a stopped clock lol
– AHKieran
Nov 22 at 9:54
You did manage to fool at least 2 more people though ;)
– Geliormth
Nov 22 at 11:45
3
3
You may want to check your premise: Using your example, if the clock shows the correct time at Midnight, it will not show the correct time again until the following Midnight...
– Chronocidal
Nov 22 at 9:38
You may want to check your premise: Using your example, if the clock shows the correct time at Midnight, it will not show the correct time again until the following Midnight...
– Chronocidal
Nov 22 at 9:38
@Chronocidal dang u right, i think my brain was working on a fast clock vs a stopped clock lol
– AHKieran
Nov 22 at 9:54
@Chronocidal dang u right, i think my brain was working on a fast clock vs a stopped clock lol
– AHKieran
Nov 22 at 9:54
You did manage to fool at least 2 more people though ;)
– Geliormth
Nov 22 at 11:45
You did manage to fool at least 2 more people though ;)
– Geliormth
Nov 22 at 11:45
add a comment |
up vote
-2
down vote
The speed has to be
-1 so the clock will be at the same spot at 00, 06 and 18
New contributor
Welcome to Puzzling SE. Could you add more explanation to what you mean by a speed of -1? Also if you'd like to learn more about this site and earn your first badge, check out the tour at this link: puzzling.stackexchange.com/tour
– gabbo1092
Nov 22 at 14:27
2
This would be right at 12 too, wouldn't it?
– jafe
Nov 22 at 14:27
add a comment |
up vote
-2
down vote
The speed has to be
-1 so the clock will be at the same spot at 00, 06 and 18
New contributor
Welcome to Puzzling SE. Could you add more explanation to what you mean by a speed of -1? Also if you'd like to learn more about this site and earn your first badge, check out the tour at this link: puzzling.stackexchange.com/tour
– gabbo1092
Nov 22 at 14:27
2
This would be right at 12 too, wouldn't it?
– jafe
Nov 22 at 14:27
add a comment |
up vote
-2
down vote
up vote
-2
down vote
The speed has to be
-1 so the clock will be at the same spot at 00, 06 and 18
New contributor
The speed has to be
-1 so the clock will be at the same spot at 00, 06 and 18
New contributor
edited Nov 22 at 14:25
gabbo1092
4,581735
4,581735
New contributor
answered Nov 22 at 14:21
user54121
1
1
New contributor
New contributor
Welcome to Puzzling SE. Could you add more explanation to what you mean by a speed of -1? Also if you'd like to learn more about this site and earn your first badge, check out the tour at this link: puzzling.stackexchange.com/tour
– gabbo1092
Nov 22 at 14:27
2
This would be right at 12 too, wouldn't it?
– jafe
Nov 22 at 14:27
add a comment |
Welcome to Puzzling SE. Could you add more explanation to what you mean by a speed of -1? Also if you'd like to learn more about this site and earn your first badge, check out the tour at this link: puzzling.stackexchange.com/tour
– gabbo1092
Nov 22 at 14:27
2
This would be right at 12 too, wouldn't it?
– jafe
Nov 22 at 14:27
Welcome to Puzzling SE. Could you add more explanation to what you mean by a speed of -1? Also if you'd like to learn more about this site and earn your first badge, check out the tour at this link: puzzling.stackexchange.com/tour
– gabbo1092
Nov 22 at 14:27
Welcome to Puzzling SE. Could you add more explanation to what you mean by a speed of -1? Also if you'd like to learn more about this site and earn your first badge, check out the tour at this link: puzzling.stackexchange.com/tour
– gabbo1092
Nov 22 at 14:27
2
2
This would be right at 12 too, wouldn't it?
– jafe
Nov 22 at 14:27
This would be right at 12 too, wouldn't it?
– jafe
Nov 22 at 14:27
add a comment |
protected by JonMark Perry Nov 24 at 7:37
Thank you for your interest in this question.
Because it has attracted low-quality or spam answers that had to be removed, posting an answer now requires 10 reputation on this site (the association bonus does not count).
Would you like to answer one of these unanswered questions instead?
1
I'm a bit confused. So, the clock is stopped or it works?
– rhsquared
Nov 22 at 9:22
11
@rhsquared There are two clocks :)
– Anush
Nov 22 at 9:27
1
Could one not argue that a clock that has stopped running at exactly 12.00 o'clock is also correct three times a day? Once at midnight, once at noon and again at midnight. Or, should we count these occurrences at midnight only as ½ ?
– Ideogram
Nov 23 at 6:57
12
A stopped clock will tell the right time three times a day, if it's the day daylight saving ends ...
– Julia Hayward
Nov 23 at 7:50
1
@Ideogram one definitely could argue that, but it's typically better not to. Whenever agreeing on conventions, one must have a purpose in mind; preserving simple addition is usually deemed quite important, so a midnight (00:00) is generally considered to belong to the next day. This results in a period of two days having as many midnights as day one and day two added together. If one counted the moment of midnight belonging to both days, this wouldn't hold.
– Bass
Nov 23 at 11:31