September 18[edit]

Is there a non-uniformly continuous bounded real valued function defined on all real numbers? Money is tight (talk) 02:06, 18 September 2011 (UTC)[reply]

Sin(x^2) is an example of such a function. Sławomir Biały (talk) 02:27, 18 September 2011 (UTC)[reply]

Thanks! I have another question. If f is a continuously twice differentiable function on the real line with compact support, is it the fourier transform of some L^1 function? Money is tight (talk) 06:41, 18 September 2011 (UTC)[reply]

Yes. You can estimate the inverse Fourier transform of f by ${\displaystyle C(1+x^{2})^{-1}}$, which is L^1. Sławomir Biały (talk) 11:10, 18 September 2011 (UTC)[reply]

I don't fully understand what you mean. By C do you mean a constant? How and in what sense is the estimation (uniform pointwise L^1 L^2 norm etc.)? Is the inverse transform in L^1? Money is tight (talk) 01:25, 19 September 2011 (UTC)[reply]

This is an apparently simple problem which seems to involve algebra of frustrating complexity. A particle is projected from the top of a cliff of height h metres with a velocity of V m/s into the sea. What is its maximum horizontal range? The equations of motion are

${\displaystyle x=Vt\cos \theta ,\qquad y=-{\frac {g}{2}}t^{2}+Vt\sin \theta +h}$

where θ is the angle of projection and the variable in question. There are two obvious approaches: Find the larger root T of y(t) = 0 and maximise x(T) in terms of θ; or rewrite y as a function of x and maximise the larger root X of y(x) = 0 in terms of θ. Both are very algebra-heavy and I keep getting lost. A craftier approach might be to maximise the roots of y(x) = 0 with product and sum examination rather than actual computation, where

${\displaystyle y(x)={\frac {-g}{2V^{2}\cos ^{2}\theta }}x^{2}+x\tan \theta +h,}$

but that hasn't yielded me much joy. Any advice is appreciated; is there something simpler I'm missing? —Anonymous Dissident^Talk 12:47, 18 September 2011 (UTC)[reply]

The problem is basically an exercise in seeing things through to the end. Solve y=0 for t, keeping the positive root only, and substitute back into x. You then get x as a function of theta, which can be maximized by methods of one variable calculus. Details are in the article Range of a projectile. Sławomir Biały (talk) 12:59, 18 September 2011 (UTC)[reply]

I think the problem can be simplified a bit by noticing that the point of maximum distance would be on the envelope of the parabolas which are the various trajectories. To get the envelope, set (dx/dt)(dy/dθ)=(dx/dθ)(dy/dt) to get an additional equation, I get v=g t sin θ. This can be plugged in to y=0 to get a linear equation for sin θ, and both of these can be plugged into the equation for x to get the maximum distance. Or you can just find the equation of the envelope, which is another parabola, and solve for y=0.--RDBury (talk) 13:54, 18 September 2011 (UTC)[reply]

Slight correction, I should have said "linear equation for sin² θ". Also, since the envelope is a parabola, it has a focus which, interestingly imo, is the location of the cannon.

That's pretty clever. Starting from Anonymous Dissident's equation

${\displaystyle y(x)={\frac {-g}{2V^{2}\cos ^{2}\theta }}x^{2}+x\tan \theta +h,}$

if we make a change of variables ${\displaystyle \tau =\tan \theta }$, this gives the family of parabolas indexed by τ:

${\displaystyle P_{\tau }:\quad y={\frac {-g}{2V^{2}}}(1+\tau ^{2})x^{2}+\tau x+h}$

A point (x,y) is on the envelope if and only if it is on a pair ${\displaystyle P_{\tau },P_{\tau +d\tau }}$ of infinitely near parabolas in the family. So, for such a point,

${\displaystyle 0={\frac {-g}{V^{2}}}\tau d\tau x^{2}+d\tau x\implies x=V^{2}/(g\tau )}$

(the nontrivial zero). Plugging into the equation for y(x) gives

${\displaystyle y(V^{2}/(g\tau ))=h+{\frac {V^{2}(\tau ^{2}-1)}{2g\tau ^{2}}}}$

Solving for y=0 gives

${\displaystyle \tau ={\frac {V}{\sqrt {2gh+V^{2}}}}.}$

So the envelope hits the ground at

${\displaystyle x={\frac {V^{2}}{g\tau }}={\frac {V}{g}}{\sqrt {2gh+V^{2}}}.}$

(This doesn't seem to agree with the answer Range of a projectile gives. I think there must be an error in the article somewhere.) Sławomir Biały (talk) 19:05, 18 September 2011 (UTC)[reply]

An algebraic approach, which may be what was requested, is this. A characteristic length is ${\displaystyle L}$ defined by ${\displaystyle V^{2}=Lg}$. Introducing the dimensionless variable ${\displaystyle z}$, and the dimensionless height ${\displaystyle b}$, by substituting ${\displaystyle x=Lz}$ and ${\displaystyle h=Lb}$ and ${\displaystyle y=0}$ into Anonymous Dissident's equation, gives

${\displaystyle 0={\frac {-g(Lz)^{2}}{2Lg\cos ^{2}\theta }}+Lz\,\tan \theta +Lb.}$

Dividing by ${\displaystyle L}$, and multiplying by ${\displaystyle 2\cos ^{2}\theta }$ gives the simpler equation

${\displaystyle 0=-z^{2}+2\,z\,\sin \theta \cos \theta +2\,b\,\cos ^{2}\theta .}$

This is further simplified by the trigonometric identities for the double angle ${\displaystyle \alpha =2\,\theta }$

${\displaystyle 0=-z^{2}+z\,\sin \alpha +b\,\cos \alpha +b.}$

Another equation is obtained by differentiation,

${\displaystyle 0=-2z\,dz+\sin \alpha \,dz+z\,\cos \alpha \,d\alpha -b\,\sin \alpha \,d\alpha .}$

When ${\displaystyle z}$ is maximum the differential ${\displaystyle dz}$ is zero even if ${\displaystyle d\alpha }$ is not. So

${\displaystyle 0=z\,\cos \alpha -b\,\sin \alpha .}$

Define ${\displaystyle C=\cos \alpha }$ and ${\displaystyle S=\sin \alpha .}$ Then the system of equations is completely algebraic

${\displaystyle 0=-z^{2}+zS+bC+b=zC-bS=C^{2}+S^{2}-1\,.}$

It remains to eliminate ${\displaystyle C}$ and ${\displaystyle S}$ to get an algebraic equation in ${\displaystyle z}$ alone. Bo Jacoby (talk) 02:20, 19 September 2011 (UTC).[reply]

In order to avoid making sign errors while manipulating polynomials I temporarily use the name ${\displaystyle m}$ to signify ${\displaystyle -1}$. So ${\displaystyle m+1=0}$ and ${\displaystyle m^{2}=1}$. The minus sign ${\displaystyle -}$ is then not used.

The three polynomials

${\displaystyle P_{1}=mz^{2}+zS+bC+b}$

${\displaystyle P_{2}=zC+mbS}$

${\displaystyle P_{3}=C^{2}+S^{2}+m}$

all evaluate to zero for the wanted values of the variables ${\displaystyle z,C,S}$ and the known values of the constants ${\displaystyle b,m}$. By construction the following polynomials also evaluate to zero.

${\displaystyle P_{4}=(zC+bS)P_{2}+b^{2}P_{3}=(z^{2}+b^{2})C^{2}+mb^{2}}$

${\displaystyle P_{5}=(mz^{2}+mzS+bC+b)P_{1}+z^{2}P_{3}}$

${\displaystyle =(mz^{2}+mzS+bC+b)(mz^{2}+zS+bC+b)+z^{2}(C^{2}+S^{2}+m)}$

${\displaystyle =(mz^{2}+bC+b)^{2}+mz^{2}S^{2}+z^{2}C^{2}+z^{2}S^{2}+z^{2}m}$

${\displaystyle =(mz^{2}+bC+b)^{2}+z^{2}C^{2}+z^{2}m}$

${\displaystyle =b^{2}C^{2}+(mz^{2}+b)^{2}+2bC(mz^{2}+b)+z^{2}C^{2}+z^{2}m}$

${\displaystyle =(z^{2}+b^{2})C^{2}+2b(mz^{2}+b)C+(mz^{2}+b)^{2}+z^{2}m}$

Here ${\displaystyle S}$ has been eliminated. Substitute ${\displaystyle w=z^{2}}$.

${\displaystyle P_{4}=(w+b^{2})C^{2}+mb^{2}}$

${\displaystyle p_{5}=(w+b^{2})C^{2}+2b(mw+b)C+(mw+b)^{2}+mw}$

Now eliminate ${\displaystyle C^{2}}$ from the equations ${\displaystyle 0=P_{4}=P_{5}}$.

${\displaystyle P_{6}=mP_{4}+P_{5}}$

${\displaystyle =m((w+b^{2})C^{2}+mb^{2})+(w+b^{2})C^{2}+2b(mw+b)C+(mw+b)^{2}+mw}$

${\displaystyle =b^{2}+2b(mw+b)C+(mw+b)^{2}+mw}$

${\displaystyle =2b(mw+b)C+w^{2}+m(2b+1)w+2b^{2}}$

Now eliminate ${\displaystyle C}$ from the equations ${\displaystyle 0=P_{4}=P_{6}}$.

The above calculation is unfinished. I have deleted some errors. Bo Jacoby (talk) 05:12, 23 September 2011 (UTC) .[reply]