Length v/s Temperature graph of A & B is given below. Find the relation between `alpha_(A)` & `alpha_(B)`.

The relation between alpha and beta of a transistor is

Two composite rods made by A & B and C & B materials as shown. When we increase the temperature DeltaT , relation between final lengths of rod becomes L_(1)ltL_(2) . Find the relation between alpha_(A) and alpha_(C) .

The relationship between alpha and beta is given by

A uniform L shaped rod of mass 3 m is hinged at point O. length OB is two times the length OA. It is in equilibrium. Find (a). Relation between alpha and beta (b). Net hinge force.

A cubical block of co-efficient of linear expansion alpha_s is submerged partially inside a liquid of co-efficient of volume expansion gamma_l . On increasing the temperature of the system by DeltaT , the height of the cube inside the liquid remains unchanged. Find the relation between alpha_s and gamma_l .

The velocity-displacement graph of a particle is shown in Fig . (a) Write the relation between (v) and (x). (b) Obtain the relation between acceleration and displacement and plot it . . . .

The length of two metallic rods at temperatures theta are L_(A) and L_(B) and their linear coefficient of expansion are alpha_(A) and alpha_(B) respectively. If the difference in their lengths is to remian constant at any temperature then

Two different wires having lengths L_(1) and L_(2) and respective temperature coefficient of linear expansion alpha_(1) and alpha_(2) are joined end - to - end . Then the effective temperature coefficient of linear expansion is :

The variation of lengths of two moles rods A and B with change in temperature is shown in figure . The ratio of (alpha_(a))/(alpha_(B)) is :-

Coefficient of linear expnsion of material of resistor is alpha . Its temperature coefficient of resistivity and resistance are alpha_(p) and alpha_(R) respectively , the correct relation is .