Let a, b, c be real numbers, a != 0. If ...

Let `a, b, c` be real numbers, `a != 0.` If `alpha` is a zero of `a^2 x^2+bx+c=0, beta` is the zero of `a^2x^2-bx-c=0 and 0 , alpha < beta` then prove that the equation `a^2x^2+2bx+2c=0` has a root `gamma` that always satisfies `alpha < gamma < beta.`

Similar Questions

Explore conceptually related problems

If alpha,beta are the roots of ax^(2)+bx+c=0 then those of ax^(2)+2bx+4c=0 are

Let a, b, c be real numbers with a = 0 and let alpha,beta be the roots of the equation ax^2 + bx + C = 0 . Express the roots of a^3x^2 + abcx + c^3 = 0 in terms of alpha,beta

Let a,b,c be real numbers with a!=0 and let alpha,beta be the roots of the equation ax^(2)+bx+c=0. Express the roots of a^(3)x^(2)+abcx+c^(3)=0 in terms of alpha,beta.

Let a,b,c be real numbers with ane0 and let alpha,beta be the roots of the equation ax^2+bx+c=0 . Express the roots of a^2cx^2+(b^3-3abc)x+ac^2=0 in terms of alpha,beta .

Let a,b,c be real numbers with a =0 and let alpha,beta be the roots of the equation ax^(2)+bx+C=0. Express the roots of a^(3)x^(2)+abcx+c^(3)=0 in terms of alpha,beta

If alpha an beta are roots of ax^(2)+bx+c=0 the value for lim_(xto alpha)(1+ax^(2)+bx+c)^(2//x-alpha) is

Let `a, b, c` be real numbers, `a != 0.` If `alpha` is a zero of `a^2 x^2+bx+c=0, beta` is the zero of `a^2x^2-bx-c=0 and 0 , alpha < beta` then prove that the equation `a^2x^2+2bx+2c=0` has a root `gamma` that always satisfies `alpha < gamma < beta.`

Similar Questions

Recommended Questions