Find the dimensions of
a. electric field E,
magnetic field B and
magnetic permeability `mu_0`
. The relavant equations are
`F=qE, FqvB, and B=(mu_0I)/(2pi alpha),`
where F is force q is charge, `nu` is speed I is current, and `alpha` is distance.

Find the dimensions of a. electric dipole moment p and b. magnetic dipole moment M. The defining equations are p=q.d and M=IA, whre d is distance, A is area, q is charge and I is current.

Find the dimensions of a/b in the equation. F=asqrtx+bt^(2) where F is force, x is distance and t is time.

Using the formulae ( (vecF)=(vec qv)xx (vec B) and B= (mu_0)i/(2pi r ) ,find the SI units of the magnetic field B and the permeability constant

Find the magnetic field B due to a semicircular wire of radius 10.0 cm carrying a current of 5.0A at its centre of curvature .

A conducting loop in the form of a half circle of r=10cm is placed in a magnetic field as shown. The strength of the magnetic field is given by the relation B=5t^(2)+3t+5 where B is in Tesla and t- the time in seconds. The resistance of the loop is 3Omega . An ideal cell of e.m.f. E = 1.5V is connected to the loop. Calculate the induced e.m.f. and net current in the loop at t = 15 sec.

Find the magnetic field B at the centre of a rectangular loop of length l and width b, carrying a current i.

Show the time period of oscillation when a bar magnet is kept in a uniform magnetic field is T = 2pi sqrt((l)/(p_(m)B)) . In second, where I represents moment of inertia of the bar magnet, p_(m) is the magnetic moment and is the magnetic field.

Find (a) the magnetization I , (b) the magnetic intensity H and © the magnetic field B at the centre of a bar magnet having pole strength 3.6 A m, magnetic length 12cm and cross-sectional are 0.90 cm^2 .