Dimensional Analysis and Units

1. Introduction

Dimensional analysis is a mathematical technique used to analyze the relationships between different physical quantities by identifying their fundamental dimensions. It is widely used in physics, engineering, and applied mathematics.

2. Units and Dimensions

• Physical Quantities: Quantities used to describe physical phenomena (e.g., length, mass, time, etc.).
• Fundamental Quantities:
  • Length: [L]
  • Mass: [M]
  • Time: [T]
  • Electric Current: [I]
  • Temperature: [Θ]
  • Amount of Substance: [N]
  • Luminous Intensity: [J]
• Derived Quantities: Expressed in terms of fundamental quantities (e.g., velocity [LT^-1], force [MLT^-2]).
• Units: Standardized measurements of physical quantities.
  • SI Units:
    • Length: meter (m)
    • Mass: kilogram (kg)
    • Time: second (s)
    • Electric Current: ampere (A)
    • Temperature: kelvin (K)
    • Amount of Substance: mole (mol)
    • Luminous Intensity: candela (cd)

3. Dimensional Formula

The expression that shows how a physical quantity is related to the fundamental dimensions is called its dimensional formula.

• Velocity: [L][T]^-1
• Force: [M][L][T]^-2
• Energy: [M][L]²[T]^-2

4. Principle of Homogeneity of Dimensions

This principle states that:

• In any valid physical equation, the dimensions of all terms on both sides of the equation must be the same.
• Used to:
  1. Verify the correctness of equations.
  2. Derive relationships between quantities.

5. Applications of Dimensional Analysis

• Checking the correctness of equations: Use the dimensional formula for all terms in the equation and ensure the dimensions are consistent on both sides.
• Deriving relationships between physical quantities: Assume a relationship and substitute dimensional formulas to find exponents.
• Converting units: Example: Convert speed from m/s to km/h.

  1 m/s = 3.6 km/h

• Estimation of orders of magnitude: Quickly estimate approximate values or trends using dominant terms.

6. Limitations of Dimensional Analysis

• Does not provide numerical constants (e.g., π, e, k).
• Cannot distinguish between dimensionless quantities.
• Cannot determine functions (e.g., trigonometric, logarithmic) in equations.
• Limited to algebraic relationships; does not work for non-dimensionalized equations.

7. Examples

• Verify Equation of Motion: v = u + at
  • Dimensions of v, u: [L][T]^-1
  • Dimensions of at: [L][T]^-1
  • Both sides have the same dimensions; equation is correct.
• Derive Formula for Period of a Pendulum:
  • Period (T) depends on length (l) and gravitational acceleration (g).
  • Assume T = k * l^a g^b.
  • Substitute dimensions: [T] = [L]^a[L][T]^-2b.
  • Solve for a and b: a = 1/2, b = -1/2.
  • Final relation: T ∝ √(l/g).

8. Frequently Used Dimensional Quantities

Quantity	Dimensional Formula
Speed/Velocity	[L][T]-1
Acceleration	[L][T]-2
Force	[M][L][T]-2
Energy	[M][L]2[T]-2
Power	[M][L]2[T]-3
Pressure	[M][L]-1[T]-2
Charge	[I][T]
Electric Field	[M][L][T]-3[I]-1

9. Tips for Dimensional Analysis

• Memorize fundamental dimensions and derived unit dimensions.
• Break down complex units into base dimensions.
• Apply the principle of homogeneity consistently.

Related Links

An Introduction to Mechanics by D. Kleppner & R. Kolenkow