Using two 1s, try to come up with the most consecutive positive integers.
Allowed operations:
Addition
Subtraction
Multiplication
Division
Concatenation
Square Root
Radical
Factorial
Floor and Ceiling Functions
Decimal Point
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6$\begingroup$ Isn't there a conjecture that with only factorial, square root and floor, and starting with any single number >1, you can form all positive integers? If so, this seems like one that could go on for ever... $\endgroup$– Gareth McCaughan ♦Commented Jan 23, 2017 at 3:52
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$\begingroup$ @GarethMcCaughan It'd have to be $>2$, because $2!=2$, floor decreases and square root makes closer to 1. $\endgroup$– boboquackCommented Jan 23, 2017 at 4:34
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$\begingroup$ @GarethMcCaughan ... and floor yields an integer. $\endgroup$– Rosie FCommented Jan 23, 2017 at 7:04
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$\begingroup$ Oops, yes, I meant >2. $\endgroup$– Gareth McCaughan ♦Commented Jan 23, 2017 at 10:04
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1$\begingroup$ Do you happen to recall the name of this conjecture? $\endgroup$– greenturtle3141Commented Jan 24, 2017 at 0:48
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1 Answer
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6
Let's try (feel free to add on or correct, this is community wiki):
$1=1\times1$
$2=1+1$
$3=\left\lfloor\sqrt{11}\right\rfloor$
$4=\left\lceil\sqrt{11}\right\rceil$
$5=\left\lfloor\sqrt{\sqrt{\left(\left\lfloor\sqrt{11}\right\rfloor!\right)!}}\right\rfloor$
$6=\left\lfloor\sqrt{11}\right\rfloor!$
$7=\left\lceil\sqrt{\sqrt{11}!}!\right\rceil$
$8=\left\lfloor\sqrt{\sqrt{\sqrt{11!}}}\right\rfloor$
$9=\left\lfloor\sqrt{11}!\right\rfloor$
$10=\left\lceil\sqrt{11}!\right\rceil$
$11=11$
$12=\left\lceil\sqrt{\sqrt{\sqrt{\sqrt{\sqrt{\left\lceil\sqrt{\sqrt{\sqrt{\sqrt{(\left\lceil\sqrt{11}\space\right\rceil!)!}}}}\right\rceil!}}}}}\right\rceil$
$13=\left\lceil\sqrt{\sqrt{\sqrt{\left\lceil\sqrt{\sqrt{\sqrt{\sqrt{\sqrt{\left\lceil\sqrt{\sqrt{\sqrt{\sqrt{(\left\lceil\sqrt{11}\space\right\rceil!)!}}}}\right\rceil!}}}}}\right\rceil}}}\right\rceil$
$14=\sqrt{\sqrt{\left\lfloor\sqrt{\sqrt{\left\lceil\sqrt{\sqrt{\sqrt{(1\div(.1))!}}}\right\rceil!}}\right\rfloor!}}$
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1$\begingroup$ I found a way for 12 but it's just a hassle to write it down. We can go all the way to infinity without much problem. $\endgroup$ Commented Jan 23, 2017 at 6:05
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2$\begingroup$ @humn I simplified my 10 as well as the 7 and 9. Looks much better now. But I guess 11 is a good number to stop this... I am not going any higher lol. $\endgroup$ Commented Jan 23, 2017 at 6:17
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2$\begingroup$ Anyone want to write a program for this...? $\endgroup$ Commented Jan 23, 2017 at 6:19
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1$\begingroup$ This is turning into a ridiculous open-ended mathematics exercise. It seems likely that given an unlimited number of factorials, square roots, floor and ceilings, you could express the values of all positive integers. $\endgroup$ Commented Jan 23, 2017 at 13:46