Prove that any three tangents to a parabola whose slopes are in harmonic progression enclose slopes are in harmonic progression enclose a traingle of constant area .

Prove that any three tangents to a parabola whose slopes are in harmonic progression enclose a triangle of constant area.

Prove that the semi-latus rectum of the parabola 'y^2 = 4ax' is the harmonic mean between the segments of any focal chord of the parabola.

Prove that the slope of tangent at any point of the curve y=6x?^(3)+15x+10 can not 12. x in R .

Tangents are drawn to the parabola y^2=4x at the point P which is the upper end of latusrectum . Area enclosed by the tangent line at, P,X axis and the parabola is

Three simple harmonic waves , identical in frequency n and amplitude A moving in the same direction are superimposed in air in such a way , that the first , second and the third wave have the phase angles phi , phi + ( pi//2) and (phi + pi) , respectively at a given point P in the superposition Then as the waves progress , the superposition will result in

An ideal gas enclosed in a cylindrical container supports a freely moving piston of mass M . The piston and the cylinder have equal cross-sectional area A . When the piston is in equilibrium, the volume of the gas is V_(0) and its pressure is P_(0) . The piston is slightly displaced from the equilibrium position and released. Assuming that the system is completely isolated from its surrounding, the piston executes a simple harmonic motion with frequency

Find the area enclosed by the parabola (y-2)^2 = x -1 , x -axis and the tangent to the parabola at (2,3) points is …….Sq. units