as the product of length, breadth and height, or three lengths. Hence the dimensions of volume are [L] × [L] × [L] = [L] = [L ]. As the volume is independent of mass and time, it is said to possess zero dimension in mass [M°], zero dimension in time [T°] and three dimensions in length. Similarly, force, as the product of mass and acceleration, can be expressed as Force = mass × acceleration = mass × (length)/(time) The dimensions of force are [M] [L]/[T] = [M L T – ].
Thus, the force has one dimension in mass, one dimension in length, and – dimensions in time. The dimensions in all other base quantities are zero. Note that in this type of representation, the magnitudes are not considered. It is the quality of the type of the physical quantity that enters.
Thus, a change in velocity, initial velocity, average velocity, final velocity, and speed are all equivalent in this context. Since all these quantities can be expressed as length/time, their dimensions are [L]/[T] or [L T – ]. . DIMENSIONAL FORMULAE AND DIMENSIONAL E Q UATIONS The expression which shows how and which of the base quantities represent the dimensions of a physical quantity is called the dimensional formula of the given physical quantity.
For example, the dimensional formula of the volume is [M° L T°], and that of speed or velocity is [M° L T - ]. Similarly, [M° L T – ] is the dimensional formula of acceleration and [M L – T°] that of mass density. An equation obtained by equating a physical quantity with its dimensional formula is called the dimensional equation of the physical quantity. Thus, the dimensional equations are the equations, which represent the dimensions of a physical quantity in terms of the base quantities.
For example, the dimensional equations of volume [ V ], speed [ v ], force [ F ] and mass density [ ρ ] may be expressed as [ V ] = [M L T ] [ v ] =