a value of b for which the equations eqalign and x 2 bx 1 0

A value of $$b$$ for which the equations
$$\eqalign{ & {x^2} + bx - 1 = 0 \cr & \,{x^2} + x + b = 0 \cr} $$
have one root in common is

A. $$ - \sqrt 2 $$

B. $$ - i\sqrt 3 $$

C. $$ i\sqrt 5 $$

D. $$ \sqrt 2 $$

Answer : $$ - i\sqrt 3 $$

Solution :
Let $$\alpha $$ be the common root of given equations, then
$$\eqalign{ & {\alpha ^2} + b \alpha - 1 = 0\,\,\,\,\,\,\,\,\,\,\,.....\left( 1 \right) \cr & {\text{and }}\,{\alpha ^2} + \alpha + b = 0\,\,\,\,\,\,\,\,\,\,\,\,.....\left( 2 \right) \cr} $$
Subtracting (2) from (1), we get
$$\eqalign{ & \left( {b - 1} \right)\alpha - \left( {b + 1} \right) = 0 \cr & {\text{or }}\alpha = \frac{{b + 1}}{{b - 1}} \cr} $$
Substituting this value of $$\alpha $$ in equation (1), we get
$$\eqalign{ & {\left( {\frac{{b + 1}}{{b - 1}}} \right)^2} + b\left( {\frac{{b + 1}}{{b - 1}}} \right) - 1 = 0\,\,\,{\text{or}}\,\,{b^3} + 3b = 0 \cr & \Rightarrow \,\,b = 0,i\sqrt 3 , - i\sqrt 3 \cr} $$

Releted MCQ Question on
Algebra >> Quadratic Equation

Releted Question 1

If $$\ell ,m,n$$ are real, $$\ell \ne m,$$ then the roots by the equation: $$\left( {\ell - m} \right){x^2} - 5\left( {\ell + m} \right)x - 2\left( {\ell - m} \right) = 0$$ are

A. Real and equal

B. Complex

C. Real and unequal

D. None of these

View Answer

Releted Question 2

The equation $$x + 2y + 2z = 1{\text{ and }}2x + 4y + 4z = 9{\text{ have}}$$

A. Only one solution

B. Only two solutions

C. Infinite number of solutions

D. None of these

View Answer

Releted Question 3

Let $$a > 0, b > 0$$ and $$c > 0$$ . Then the roots of the equation $$a{x^2} + bx + c = 0$$

A. are real and negative

B. have negative real parts

C. both (A) and (B)

D. none of these

View Answer

Releted Question 4

Both the roots of the equation $$\left( {x - b} \right)\left( {x - c} \right) + \left( {x - a} \right)\left( {x - c} \right) + \left( {x - a} \right)\left( {x - b} \right) = 0$$ are always

A. positive

B. real

C. negative

D. none of these.

View Answer

A value of $$b$$ for which the equations
$$\eqalign{ & {x^2} + bx - 1 = 0 \cr & \,{x^2} + x + b = 0 \cr} $$
have one root in common is

Releted MCQ Question on
Algebra >> Quadratic Equation

If $$\ell ,m,n$$ are real, $$\ell \ne m,$$ then the roots by the equation: $$\left( {\ell - m} \right){x^2} - 5\left( {\ell + m} \right)x - 2\left( {\ell - m} \right) = 0$$ are

The equation $$x + 2y + 2z = 1{\text{ and }}2x + 4y + 4z = 9{\text{ have}}$$

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Both the roots of the equation $$\left( {x - b} \right)\left( {x - c} \right) + \left( {x - a} \right)\left( {x - c} \right) + \left( {x - a} \right)\left( {x - b} \right) = 0$$ are always

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A value of $$b$$ for which the equations $$\eqalign{ & {x^2} + bx - 1 = 0 \cr & \,{x^2} + x + b = 0 \cr} $$ have one root in common is

Releted MCQ Question on Algebra >> Quadratic Equation

If $$\ell ,m,n$$ are real, $$\ell \ne m,$$ then the roots by the equation: $$\left( {\ell - m} \right){x^2} - 5\left( {\ell + m} \right)x - 2\left( {\ell - m} \right) = 0$$ are

The equation $$x + 2y + 2z = 1{\text{ and }}2x + 4y + 4z = 9{\text{ have}}$$

Let $$a > 0, b > 0$$ and $$c > 0$$ . Then the roots of the equation $$a{x^2} + bx + c = 0$$

Both the roots of the equation $$\left( {x - b} \right)\left( {x - c} \right) + \left( {x - a} \right)\left( {x - c} \right) + \left( {x - a} \right)\left( {x - b} \right) = 0$$ are always

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$$\eqalign{ & {x^2} + bx - 1 = 0 \cr & \,{x^2} + x + b = 0 \cr} $$
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