v0_1

In the given circuit V_(0_1) " and " V_(0_2) are -

Having gone through a plank of thickness h, a bullet changed its velocity from v_(0) to v_(1) . Find the time of motion of the bullet on the plank, assuming the resistance force to be proportional to the square of the velocity.

Prove that x = x_0 + v_0 t + 1/2 at^(2) .

Ressult 1 If V_(0) is the value of an article at a certain time and R% per annum is the rate of depreciation then the value V_(n) at the end of n years is given by V_(n)=V_(0)(1-(R)/(1000^(n))

The electric potential V(z, y,z) for a planar charge distribution is given by: V(x, y, z)={(0,,"for "x lt -d),(-V_(0)(1+x/d)^(2),,"for "-d le x le 0),(-V_(0)(1+2x/d),,"for "0 le x lt d),(-3V_(0),,"for " x gt d):} where -V_(0) is the potential at the origin and d is a distance. Graph of electric field as a function of position is given as

A particle of mass m, moving in a circle of radius R, has a velocity v=v_(0)(1-e^(-gamma t)) The power delivered to tha particle by the force at t=0 is

A spherical shell is heated. The Volume changes according to the equation V_theta= V_0(1+gamma_theta) . Does the volume refer to the volume encloded by the shell or the volume of the marerial making up the shell?

Based on the data given for half cell (M^(x+n)+ , M^(x+) || Pt % of reduced form 50 20 Potential (V) 0.1, 0.112 the value of n is: