Dear student,
Here is the answer of your question. I hope the following paragraphs will clear your concept about unit and dimension.
Numbers are meaningless for the physicist without the correct use of units . It makes no sense to say "the distance from my house to school is two", unless we follow that statement with "miles" or "kilometers", or whichever unit makes the statement true. We will distinguish between dimension, the abstract quality of a measurement without scale
(ie., length), and unit, the quality of a number which specifies a previously agreed upon scale (ie., meters). While dimensional arguments are of primary importance in understanding the qualitative behavior of systems, the use of units are necessary for the predictions we seek.
The four fundamental dimensions are length, time, mass and electric charge . These qualities of numbers are fundamentally different, and make up the building blocks for all of our studies. We perceive three spatial dimensions of length, upon which we build dimensions of area and volume (notice the different use of the word dimension). Area and volume have "composite dimension", by which we mean that more than one factor of a fundamental dimension appears (area = length squared, volume = length cubed). Time, likewise, will often appear in higher powers in a composite dimension. Consider the rate of change of speed: "my car can accelerate at 6 miles per hour per second":
6 miles / hour / sec = 6 miles / (hour sec).
Dimensions: Dimensions of a physical quantity are,the powers to which the fundamental units are raised to get one unit of the physical quantity.
The fundamental quantities are expressed with following symbols while writing dimensional formulas of derived physical quantities.
Mass →[M] ; Length→[L]; Time→[T]; Electric current →[I] ; Thermodynamic temperature →[K] ;Intensity of light →[cd] ; Quantity of matter →[mol] .
Dimensional Formula: Dimensional formula of a derived physical quantity is the
“expression showing powers to which different fundamental units are raised”.
Ex : Dimensional formula of Force F →[ ]
Dimensional equation :When the dimensional formula of a physical quantity is expressed in the form of an equation by writing the physical quantity on the left hand side and the dimensional formula on the right hand side,then the resultant equation is called Dimensional equation.
Ex: Dimensional equation of Energy is E = [ ] .

Question : How can you derive Dimensional formula of a derived physical quantity.
Ans : We can derive dimensional formula of any derived physical quantity in two ways i) Using the formula of the physical quantity : Ex: let us derive dimensional formula of
Force .
Force F→ma ; substitute the dimensional formula of mass m →[M] ; acceleration
→[ ] we get F → [M][ ]; F →[
] . ii) Using the units of the derived physical quantity . Ex: let us derive the dimensional formula of momentum.
Unit of Momentum ( p ) → [ ] ; kg is unit of mass → [M] ; is unit of length → [L] ; sec is the unit of time →[T]
Substitute these dimensional formulas in above equation we get p →[
].
Quantities having no units, can not possess dimensions : Trigonometric ratios, logarithmic functions, exponential functions, coefficient of friction, strain, poisson’s ratio, specific gravity, refractive index, Relative permittivity, Relative permeability. All these quantities neither possess units nor dimensional formulas.
• Quantities having units, but no dimensions : Plane angle,angular displacement, solid angle.These physical quantities possess units but they does not possess dimensional formulas.
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Quantities having both units & dimensions : The following quantities are examples of such quantities.
Area, Volume,Density, Speed, Velocity, Acceleration, Force, Energy etc.
Principle of Homogeneity of dimensions : The term on both sides of a dimensional equation should have same dimensions.This is called principle of Homogeneity of dimensions. (or) Every term on both sides of a dimensional equation should have same dimensions.This is called principle of homogeneity of dimensions.
Uses of Dimensional equations : dimensional equations are used i) to convert units from one system to another, ii)to check the correctness of the dimensional equations iii)to derive the expressions connecting different physical quantities..

Limitations of dimensional method : The limitations of dimensional metthod,s are i)The value of dimensionless constants can not be calculated using dimensional methods, ii) We can not analyze the equations containing trigonometrical, exponential and logarithmic functions using method of dimensions. iii)If a physical quantity is sum or difference of two or more than two physical quantities, such physical quantities can not be derived with dimensional methods, iv)If any equation having dimensional constants like, G, R etc can not be derived using dimensional methods, v)If any equations is involving more than three fundamental quantities in it, such expressions can not be derived using dimensional methods.
Regards