I'm having a little bit of a conundrum here.

I am formulating the problem as maximizing ${\displaystyle \int _{a}^{b}-xy'\ dt}$ subject to ${\displaystyle \int _{a}^{b}{\sqrt {x'^{2}+y'^{2}}}dt=K}$. If I take the functional derivative of the inside of each integral, multiply the right hand side's functional derivative by a Lagrange multiplier, equate components, and divide the equations, I end up with a tautology. More explicitly, I have ${\displaystyle (y',-x')=-{\frac {\lambda }{{\sqrt {x'^{2}+y'^{2}}}^{3}}}(x''(x'^{2}+y'^{2})-x'x'x''-x'y''y',y''(x'^{2}+y'^{2})-y'x'x''-y'y''y')}$ which gets simplified to ${\displaystyle -y'/x'={\frac {x''y'^{2}-x'y'y''}{y''x'^{2}-y'x'x''}}}$, which is satisfied for all x and y such that the numerator and denominator aren't zero. This leads me to think that one must instead look at where they are zero, which occurs when ${\displaystyle y''x'=y'x''}$. This is satisfied only in the case ${\displaystyle \ln(y')=\ln(x')+C}$ which, however, does not exclude an ellipse.--Jasper Deng (talk) 03:49, 16 December 2019 (UTC)[reply]

I think the problem is you eliminated lambda. You get two equations but they are redundant, so just look at the first equation

${\displaystyle y'=-{\frac {\lambda }{{\sqrt {x'^{2}+y'^{2}}}^{3}}}(x''y'^{2}-x'y''y').}$

Cancel y' and divide by -λ to get

${\displaystyle -{\frac {1}{\lambda }}={\frac {x''y'-x'y''}{{\sqrt {x'^{2}+y'^{2}}}^{3}}},}$

in other words curvature is constant, i.e. the curve is a circle. Btw, for those following along at home, the functional derivative in question is given in Euler–Lagrange equation#Several functions of single variable with single derivative but without the "=0". --RDBury (talk) 07:40, 16 December 2019 (UTC)[reply]

For this,

${\displaystyle \neg (P\land Q)\vdash (\neg P\lor \neg Q)}$

why its reverse direction,

${\displaystyle (\neg P\lor \neg Q)\vdash \neg (P\land Q)}$

is not included? --Ans (talk) 14:02, 16 December 2019 (UTC)[reply]

Possibly it's because that is not a separate law, but rather a result obtained from the second law:

${\displaystyle (\neg P\lor \neg Q)=\neg {\big (}\neg ((\neg P)\lor (\neg Q)){\big )}}$

And by the law of negation of disjunction applied to the part in outermost brackets:

${\displaystyle \vdash \ \ \neg {\big (}\neg (\neg P)\land \neg (\neg Q)){\big )}=\neg (P\land Q)}$

CiaPan (talk) 14:13, 16 December 2019 (UTC)[reply]

In your third step, Are you are using ${\displaystyle A\vdash B}$ to conclude ${\displaystyle \neg A\vdash \neg B}$? RoxAsb (talk) 15:31, 16 December 2019 (UTC)[reply]

@CiaPan:, your last step can imply ${\displaystyle \neg B}$ from ${\displaystyle \neg A}$ if ${\displaystyle A=B}$, but the law of negation of disjunction in sequent notation (in the article) is in the form, ${\displaystyle A\vdash B}$, not the form, ${\displaystyle A=B}$. ${\displaystyle A\vdash B}$ is not sufficient to imply ${\displaystyle \neg B}$ from ${\displaystyle \neg A}$ --Ans (talk) 05:25, 18 December 2019 (UTC)[reply]

If no any other opposed comments, I will add the reverse rules in the article, then. --Ans (talk) 05:49, 18 December 2019 (UTC)[reply]