Math, asked by Yogesha4365, 1 year ago

Q11. Prove that any quadratic equation has maximum two roots .

Answers

Answered by Yuichiro13
0
Hey

∆ You can just Assume to the contrary that the Quadratic has more than 2 roots and by factor theorem, Contradict it !

∆ For no roots, I think you can use the Argument that every Equation that is defined and one to one or many to one or one to many, doesn't matter ! has got a Representation on the Cartesian Plane and by the Density Property of Real Numbers, there has two be at least some intersections due to two Concave - Convex Curves
Answered by Anonymous
93

\bold{\large{\underline{\underline{\sf{StEp\:by\:stEp\:explanation:}}}}}

To prove:

\sf\green{\implies x = \dfrac{-b\pm\sqrt{b^{2}-4ac}}{2a}}

Proof:

We will start with the the standard form of a quadratic equation,

\bold\green{\implies ax^{2}+bx+c=0}

Now, divide both sides of the equation by 'a' so you can complete the square,

\sf{\implies x^{2}+\dfrac{b}{a}x+\dfrac{c}{a}=\dfrac{0}{a}}

\sf{\implies x^{2}+\dfrac{b}{a}x+\dfrac{c}{a}=0}

Now, Subtract c/a from both sides.

\sf{\implies x^{2}+\dfrac{b}{a}x+\dfrac{c}{a}-\dfrac{c}{a}=0-\dfrac{c}{a}}

\tt{\implies x^{2}+\dfrac{b}{a}x=-\dfrac{c}{a}}

Now, by completing the square method.

The coefficient of the second term is b/a . Divide this coefficient by 2 and square the result to get (b/2a)², add (b/2a)² to both sides:

\sf{\implies x^{2}+\dfrac{b}{a}x+\Bigg(\dfrac{b}{2a}\Bigg)^{2}=-\dfrac{c}{a}+\Bigg(\dfrac{b}{2a}\Bigg)^{2}}

Since the left side of the equation right above is a perfect square, you can factor the left side by using the coefficient of the first term (x) and the base of the last term(b/2a).

Then, square the right side to get (b²)/(4a²).

\sf{\implies \Bigg(x+\dfrac{b}{2a}\Bigg)^{2}=-\dfrac{c}{a}+\dfrac{b^{2}}{4a^{2}}}

Get the same denominator on the right side:

\sf{\implies \Bigg(x+\dfrac{b}{2a}\Bigg)^{2} =-\dfrac{4ac}{4a^{2}}+\dfrac{b^{2}}{4a^{2}}}

\sf{\implies \Bigg(x+\dfrac{b}{2a}\Bigg)^{2} =\dfrac{b^{2}-4ac}{4a^{2}}}

Now, take the square root of each side,

\sf{\implies \sqrt{\bigg(x+\dfrac{b}{2a}\bigg)^{2}}=\sqrt{\dfrac{b^{2}-4ac}{4a^{2}}}}

Now, Simplify the left side,

\sf{\implies x+\dfrac{b}{2a}=\pm\sqrt{\dfrac{b^{2}-4ac}{4a^{2}}}}

\sf{\implies x+\dfrac{b}{2a}=\pm\dfrac{\sqrt{b^{2}-4ac}}{\sqrt{4a^{2}}}}

Rewrite the right sides,

\sf{\implies x+\dfrac{b}{2a}=\pm\dfrac{\sqrt{b^{2}-4ac}}{2a}}

Now, Subtract b/2a from both sides,

\sf{\implies x+\dfrac{b}{2a}-\dfrac{b}{2a}=-\dfrac{b}{2a}\pm \dfrac{\sqrt{b^{2}-4ac}}{2a}}

Adding the numerator and keeping the same denominator, we get the quadratic formula,

\sf{\implies x = \dfrac{-b\pm\sqrt{b^{2}-4ac}}{2a}}

_________________(HENCE PROVED) .

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