The principle of homogeneity of dimensions states that the dimensions of all the terms in a physical expression should be the same.
For example, in the physical expression v2 = u2 + 2as, the dimensions of v2 , u2 and 2 as are the same and equal to [L2 T-2 ].
(i) To convert a physical quantity from one system of units to another:
This is based on the fact that the product of the numerical values (n) and its corresponding unit (u) is a constant, i.e, = constant,n1 [u1] = constant
(or) n1 [u1] = n2 [u2].
Consider a physical quantity which has dimension ‘a’ in mass, ‘b’ in length and ‘c’ in time. If the fundamental units in one system are M1, L1 and T1 and the other system are M2, L2 and T2 respectively, then we can write,
We have thus converted the numerical value of physical quantity from one system of units into the other system.
Example: Convert 76 cm of mercury pressure into Nm-2 using the method of dimensions.
Solution: In cgs system 76 cm of mercury pressure = 76 × 13.6 × 980 dyne cm-2
The dimensional formula of pressure P is [ML-1T-2]
(ii) To check the dimensional correctness of a given physical equation:
Example: The equation \(\frac{1}{2}mv^2\) = mgh can be checked by using this method as follows.
Solution: Dimensional formula for
Dimensional formula for
Both sides are dimensionally the same, hence the equations \(\frac{1}{2} mv^2 = mgh\) is dimensionally correct
(iii) To establish the relation among various physical quantities:
Example: An expression for the time period T of a simple pendulum can be obtained by using this method as follows.
Let true period T depend upon
(i) mass m of the bob
(ii) length l of the pendulum and
(iii) acceleration due to gravity g at the place where the pendulum is suspended. Let the constant involved is K = 2π.
Solution:
Here k is the dimensionless constant. Rewriting the above equation with dimensions.
Comparing the powers of M, L and T on both sides,
a – 0, b + c = 0, -2c = 1
Solving for a, b and c a = 0, b = 1/2, and c = -1/2
From the above equation
