|
Sauda,c~oes,
Duas mensagens de uma outra lista editadas
numa
só:
[]'s
Luís
>From: "ndergiades" <ndergiades@yahoo.gr>
>Reply-To: Hyacinthos@yahoogroups.com >To: Hyacinthos@yahoogroups.com >Subject: [EMHL] Re: Perimeter as a function of area and angles >Date: Sun, 14 Apr 2002 12:18:28 -0000 > >Dear Chris and Ignacio, > >[CP] > > Now I have to prove that the equilateral triangle >minimises the perimeter. What tactic do I use for this? >[IL] > >First, prove that of all triangles with equal basis an >heights, the isosceles one have the minimum perimetre (inmediate). > > > >Second, prove that of all isosceles triangles with the same >area, the equilateral one have the minimum perimetre. If you don't >meet another better way, it leads to a one variable optimization >problem. > > >******** >If s = semiperimeter and E = area of ABC >Using Cauchy's AM-GM inequality >we have > >(s-a + s-b + s-c)^3 >= 27(s-a)(s-b)(s-c) or >s^4 >= 27E^2 > >the equality holds only when s-a = s-b = s-c >or when the triangle is equilateral. > >If E is constant then s becomes minimum when >s^4 = 27E^2 or the triangle is equilateral. > >If s is constant then E becomes maximum when >s^4 = 27E^2 or the triangle is equilateral. > >Best regards >Nikos Dergiades > >From: "ndergiades" <ndergiades@yahoo.gr> >Reply-To: Hyacinthos@yahoogroups.com >To: Hyacinthos@yahoogroups.com >Subject: Re: [EMHL] Perimeter as a function of area and angles >Date: Sun, 14 Apr 2002 20:58:57 -0000 > >Dear Antreas, you wrote, > > >This problem and many similar ones are discussed in a good > >monograph (Maxima and Minima [in Greek]) by George A. >Strikis (Rhodos, 1953. 104 pages). > > > >Here are two problems from "Exercises and Problems" section > >(with no solutions): > > > >- Let ABC be an equilateral triangle [of constant side]. > >Find on its incircle a point M such that MA * MB * MC = max > >(p. 102, #23) > > >*** >Let MA = x, MB = y, MC = z then it is known that >using e.g. Stewart's theorem we can prove that >x^2 + y^2 + z^2 = k = constant. >Also it is known that > >3(x^2 + y^2 + z^2) >= (x + y + z)^2 Schwartz inequality >(x^2 + y^2 + z^2)^3 >= 27(xyz)^2 Cauchy inequality >or by multiplication > >(x^2 + y^2 + z^2)^4 >= 9(x + y + z)^2(xyz)^2 or >k^2 >= 3(x + y + z)xyz and hence xyz = max when x + y + z = >min. > >This happens when M is e.g. the intersection of the incircle >and the segment AI ( I = incenter) but I cannot give a proof. > > >- On each side of a right-angled triangle of constant >perimeter we construct a square [outwardly]. > >Which is the minimum of the area of (triangle + three >squares)? (p. 102, #26) > > >***** >Let p be the constant perimeter, and E be the required area >then since a^2 = b^2 + c^2 p = sqrt(b^2 + c^2) + b + c >and E = a^2 + b^2 + c^2 + bc/2 = 2(b^2 + c^2) + bc/2. >We'll prove the inequality p^2 <= kE >where k = (16sqrt(2) + 24 )/ 18 = 2.59 >and the equality when b = c >or that minE = p^2/k > >It is known that 2bc <= b^2 + c^2 and >b + c <= sqrt(2)sqrt(b^2 + c^2) or > >b + c <= (18k - 24)sqrt(b^2 + c^2)/16 or > >2(b + c)sqrt(b^2 + c^2) <= (2k-8)(b^2 + c^2)/8 + (2k - >2)(b^2 + c^2) or > since 2k - 8 < 0 >2(b + c)sqrt(b^2 + c^2) <= (2k-8)bc/4 + (2k - 2)(b^2 + c^2) >or > >(b+c)^2+2(b + c)sqrt(b^2 + c^2)+b^2+c^2 <= 2k(b^2+c^2) + >kbc/2 or > >p^2 <= kE which finishes the proof >because the equality holds only when b = c. > >Best regards >Nikos Dergiades > > > >PS: Another monograph by the same author: > >Convex Regular Polyhedra [in Greek] (Rhodos, 1950. 38 >pages) > > > >Antreas > |