1
JEE Main 2023 (Online) 31st January Morning Shift
+4
-1

The number of real roots of the equation $$\sqrt{x^{2}-4 x+3}+\sqrt{x^{2}-9}=\sqrt{4 x^{2}-14 x+6}$$, is :

A
0
B
1
C
3
D
2
2
JEE Main 2023 (Online) 29th January Morning Shift
+4
-1

Let $$\lambda \ne 0$$ be a real number. Let $$\alpha,\beta$$ be the roots of the equation $$14{x^2} - 31x + 3\lambda = 0$$ and $$\alpha,\gamma$$ be the roots of the equation $$35{x^2} - 53x + 4\lambda = 0$$. Then $${{3\alpha } \over \beta }$$ and $${{4\alpha } \over \gamma }$$ are the roots of the equation

A
$$7{x^2} - 245x + 250 = 0$$
B
$$49{x^2} - 245x + 250 = 0$$
C
$$49{x^2} + 245x + 250 = 0$$
D
$$7{x^2} + 245x - 250 = 0$$
3
JEE Main 2023 (Online) 24th January Evening Shift
+4
-1

The number of real solutions of the equation $$3\left( {{x^2} + {1 \over {{x^2}}}} \right) - 2\left( {x + {1 \over x}} \right) + 5 = 0$$, is

A
3
B
4
C
0
D
2
4
JEE Main 2023 (Online) 24th January Morning Shift
+4
-1

The equation $${x^2} - 4x + [x] + 3 = x[x]$$, where $$[x]$$ denotes the greatest integer function, has :

A
exactly two solutions in ($$-\infty,\infty$$)
B
no solution
C
a unique solution in ($$-\infty,\infty$$)
D
a unique solution in ($$-\infty,1$$)
EXAM MAP
Medical
NEET