Page 2 of 2

Re: Problem 317

Posted: Wed Jul 24, 2013 1:51 am
by golfguy37
Okay thanks

Re: Problem 317

Posted: Thu Dec 12, 2013 12:21 am
by muffoosta
Could someone please confirm or deny that the answer lies in this range: <snipped by hk> ?

Re: Problem 317

Posted: Thu Dec 12, 2013 3:05 pm
by muffoosta
So sorry for posting the number, I saw others post incorrect results here so I though it would be ok to ask if I was near the answer at all. But since it was quickly removed by hk, I figured I was on the right track ;)

Re: Problem 317

Posted: Mon Dec 16, 2013 3:16 pm
by oern
Does it actually make sense to give g rounded to two decimal places but require the result with four decimal places? I learned in Physics that one should never have more precision in the result than in the given quantities.

EDIT: And the problem obviously does not mean a "velocity" of 20m/s, but a "speed" (velocity would be a vector, and the vectors of the speeds are definitely not the same).

Re: Problem 317

Posted: Thu Jan 02, 2014 6:54 am
by thundre
oern wrote:Does it actually make sense to give g rounded to two decimal places but require the result with four decimal places? I learned in Physics that one should never have more precision in the result than in the given quantities.
Constants given in math problems are not measured. They are assumed to be exactly true, with perfect precision. Using short ones saves typing. If a constant is not exact, the problem will explicitly say so.

Re: Problem 317

Posted: Fri Jul 14, 2017 9:46 pm
by Alex-82w4
What approximate value of $\pi$ should be used?

Re: Problem 317

Posted: Fri Jul 14, 2017 11:54 pm
by v6ph1
Alex-82w4 wrote: Fri Jul 14, 2017 9:46 pm What approximate value of $\pi$ should be used?
You need 4 decimals in your solution. - So if you append the next digit of pi, the solution should not change at all.

Hint:
If you calculate using float / double: Use always the maximum possible in this format.

Re: Problem 317

Posted: Fri Jul 28, 2017 4:55 pm
by Alex-82w4
I submit many answers but they were not accepted.
So I did approximation of covered area as cylinder with height $h=Ymax=120m$ and radius $r=X_{max}=100m$
$Volume_{cylinder}=\pi*r^2*h$ Volume of cylinder. So the answer can not exceed $3,769,911.1843 m^3$

Could someone PM me to verify my approach to solve the problem?

Thanks,
Alex.

Re: Problem 317

Posted: Fri Jul 28, 2017 10:54 pm
by v6ph1
Your max. height is not correct (it is a little bit higher)

Re: Problem 317

Posted: Sat Jul 29, 2017 12:32 am
by Alex-82w4
formula $h = Y_{max}=H+\frac{V_0^2}{2g}$

exact result is $120.3874m$

Re: Problem 317

Posted: Sat Jul 29, 2017 10:31 pm
by v6ph1
This is my max. height too.

But (I think this is not to much hint) the problem did not describe some kind of cylinder - It's much less than a cylinder

Re: Problem 317

Posted: Sun Jul 30, 2017 1:23 pm
by Alex-82w4
OK. Cylinder is very rough maximum approximation. The real volume is much less than the volume of the cylinder. I agree with you, v6ph1.

My results are still not accepted :(
What angle increment $1^o$ or $0.5^o$ should I use in my calculations?
This is the important question because an answer to it gives volume difference in $79.4676m^3$.

Re: Problem 317

Posted: Tue Aug 01, 2017 9:48 pm
by Alex-82w4
v6ph1 wrote: Fri Jul 14, 2017 11:54 pm
Alex-82w4 wrote: Fri Jul 14, 2017 9:46 pm What approximate value of $\pi$ should be used?
You need 4 decimals in your solution. - So if you append the next digit of pi, the solution should not change at all.
I solved the problem. :)

v6ph1, Your suggestion to use 5 decimals in calculations gives an incorrect result. The difference from the correct answer is $1.5681 m^3$. Rounding $\pi$ to 10 or more decimals and using $\pi$ without rounding gives the correct result.

Here's the proof. The solution range is $3,769,911.1843m^3$ $10^7$ (see this post) plus 4 decimal digits. Therefore, we have $10^{11}$ range of significant digits. $\pi$ range is $10^1$. So a result will be not be affected if we round to $\log_{10}{(10^{11}/10^1)} = \log_{10}{10^{10}} = 10$ digits.

Re: Problem 317

Posted: Wed Aug 02, 2017 2:20 am
by jaap
Alex-82w4 wrote: Tue Aug 01, 2017 9:48 pm
v6ph1 wrote: Fri Jul 14, 2017 11:54 pm
Alex-82w4 wrote: Fri Jul 14, 2017 9:46 pm What approximate value of $\pi$ should be used?
You need 4 decimals in your solution. - So if you append the next digit of pi, the solution should not change at all.
I solved the problem. :)

v6ph1, Your suggestion to use 5 decimals in calculations gives an incorrect result.
I think you misunderstood v6ph1, though the post was somewhat ambiguous. I think the intended suggestion was to use as many decimals in the value of pi as you need such that adding an extra decimal does not change the four decimals in the calculated answer.

Re: Problem 317

Posted: Wed Aug 02, 2017 12:14 pm
by Alex-82w4
Hi japp,
My initial question in the forum "Clarifications on Project Euler Problems" was
What approximate value of $\pi$ should be used?
The answer must be a number, for example $3.14$. v6ph1's initial answer was
You need 4 decimals in your solution. - So if you append the next digit of pi, the solution should not change at all.
This is a general answer that can be applied to any constant, for example $e$.
jaap, here's your comment
I think the intended suggestion was to use as many decimals in the value of pi as you need such that adding an extra decimal does not change the four decimals in the calculated answer.
The 317 problem can be solved by using scientific calculator. It may not have enough decimals of $\pi$. It may lead to an incorrect result.

Therefore, the value of $\pi$ must be stated in the problem description the same way it stated for $g$.

Thank you for understanding.
Regards,
Alex.

P.S. I suggest to moderators that problem 317 wording has to be updated by adding value of $\pi$ constant.

Re: Problem 317

Posted: Wed Aug 02, 2017 8:01 pm
by v6ph1
My intention was to calculate with as many decimals as possible/needed.
And this could be checked if the next digit of pi would not change the result.

Suggesting a specific precise approximation will gave the others too much hints.

The wording should not change as constants like pi and e have an exactly defined value.

Re: Problem 317

Posted: Thu Aug 03, 2017 11:43 am
by DJohn
Alex-82w4 wrote: Wed Aug 02, 2017 12:14 pm Therefore, the value of $\pi$ must be stated in the problem description the same way it stated for $g$.
The problem is asking for the value you'd get by calculating the volume exactly, then rounding it to four decimal places. It doesn't mention $\pi$ at all. Any method of finding that rounded value is acceptable. You might use the exact value of $\pi$, some approximation, or not use $\pi$ at all.

Whichever method you use, you'll need to satisfy yourself that it gives the same result as rounding the exact volume. If you decide to use an approximation to $\pi$, finding a suitable approximation is up to you.

$g$ is a different matter. In the real world, it's a physical value that must be measured. The value you get will depend on the time and place of measurement, the equipment used, and the care and skill of the person taking the measurement. To ensure that everyone solving this problem gets the same answer, we all need to be using the same value. So that has to be given in the problem.

Re: Problem 317

Posted: Thu Aug 03, 2017 11:57 am
by Alex-82w4
v6ph1 wrote: Wed Aug 02, 2017 8:01 pm Suggesting a specific precise approximation will gave the others too much hints.
v6ph1, I understand your answer now, not to give the others to much hints. :)

Re: Problem 317

Posted: Sat Aug 17, 2019 11:14 pm
by RishadanPort
Can someone confirm to me, that the Max X distance, is ~<removed by moderator>, at t = ~xxx,
with Theta = ~xxx radians
?

Re: Problem 317

Posted: Mon Mar 08, 2021 10:35 pm
by gaufowl
I'm sure I've done this correctly, especially after reading old comments on here. I think I have a precision problem, could someone help me troubleshoot by checking that the 6 decimals after the 4 decimals asked for in the problem statement are 170668? In other words, the solution looks something like X.abcd170668.

Edit: nevermind, I had a mistake copying a number towards the end from my calculator to paper. Solved.