Units and Measurement Notes PDF

Summary

These notes provide an overview of units and measurements, including fundamental and derived quantities, different systems of units (e.g., cgs, fps, mks, SI), and practical units. The advantages of the SI system are also described along with a discussion of significant figures.

Full Transcript

UNITS AND MEASUREMENT
PHYSICAL QUANTITIES
All those quantities that can be measured directly or indirectly are called
physical quantities.
FUNDAMENTAL QUANTITIES
Physical quantities that can be treated as independent of other physical
quantities are called fundamental quantities.
DERIVED QUANTITIES
Physical quantities whose defining operations are based on other physical
quantities are called derived quantities.
MEASUREMENT
Comparing an unknown physical quantity with a known quantity of the
same type is called Measurement.
Unit
Standard quantity used to compare the unknown physical quantity is called
its unit.
Eg: meter (m), centimeter (cm), gram (g) etc.
System of units
A complete set of units which is used to measure all kinds of fundamental
and derived quantities is called a system of units
Example:
cgs - centimetre, gram and second.
fps - foot, pound and second.
mks - metre, kilogram and second.
SI - International System of Units

SI System

In SI, there are seven base units. All other units are called derived units.

Seven fundamental units are:

Quantity Unit Symbol
Length metre m
Mass kilogram kg
Time second s
Temperature kelvin K
Amount of substance mole mol

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 Electric current ampere A
Luminous intensity candela cd

Besides the seven base units, there are two more
units that are defined:

(a) plane angle dθ as the ratio of length of arc ds
to the radius r. The unit for plane angle is
radian. (rad)

One radian is defined as the plane angle
subtended at the centre of a circle by an arc
equal in length to the radius of the circle

(b) solid angle dΩ as the ratio of the intercepted area dA of the spherical
surface, described about the apex O as the centre, to the square of its
radius r. The unit for the solid angle is steradian with the symbol sr.

One steradian is defined as the solid angle subtended at the centre of a
sphere by a surface of the sphere equal in area to that of a square,
having each side equal to the radius of the sphere.

Units that can be expressed in terms of fundamental units are called derived
units.

Eg: Unit of speed (m/s)
Unit of volume (m3)

ADVANTAGES OF SI SYSTEM

(i) SI is a coherent system of units. All derived units can be obtained
by simple multiplication or division of fundamental units without
introducing any numerical factor.

(ii) SI is a rational system of units. It uses only one unit for a given
physical quantity. For example, all forms of energy are measured in
joule. On the other hand, in mks system, the mechanical energy is
measured in joule, heat energy in calorie and electrical energy in
watt hour.

(iii) SI is a metric system. The multiples and submultiples of SI units
can be expressed as powers of 10.

(iv) SI is an absolute system of units. It does not use gravitational
units. The use of 'g' is not required.

(v) SI is an internationally accepted system of units.
Some common practical units

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 (i) Fermi. It is the small practical unit of distance used for measuring
nuclear sizes. It is also called femtometre.
1 fermi = 1 fm = 10-15 m

(ii) Angstrom. It is used to express wavelength of light.
1 angstrom = 1À = 10-10 m

(iii) Nanometre. It is also used for expressing wavelength of light.
1 nanometre = 1 nm = 10-9 m

(iv) Micron. It is the unit of distance defined as micrometre.
1 micron = 1µm = 10-6 m

Practical units used for measuring large distances:

(i) Light year. It is the distance travelled by light in vacuum in one year.

1 light year = Speed of light in vacuum x 1 year

= 3 x 108ms-1 x 365.25 x 24 x 60x 60 s
:: 1 light year = 1 ly = 9.467 x 1015 m

(ii) Astronomical unit. It is defined as the mean distance of the earth from
the sun.

1 astronomical unit = 1 AU = 1.496 x 1011 m

(iii) Parsec (parallactic second). It is the largest practical unit of distance
used in astronomy. It is defined as the distance at which an arc of
length 1 astronomical unit subtends an angle of 1 second of arc.

SIGNIFICANT FIGURES

Every measurement involves errors. Thus, the result of measurement should
be reported in a way that
indicates the precision of measurement. Normally, the reported result of
measurement is a number that includes all digits in the number that are
known reliably plus the first digit that is uncertain. The reliable digits plus
the first uncertain digit are known as significant digits or significant figures.

Rules to find the number of significant figures

All the non-zero digits are significant.
All the zeros between two non-zero digits are significant, no matter
where the decimal point is, if at all.
If the number is less than 1, the zero(s) on the right of decimal point
but to the left of the first non-zero digit are not significant.

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 The terminal or trailing zero(s) in a number without a decimal point
are not significant.
The trailing zero(s) in a number with a decimal point are significant.

DIMENSIONS OF PHYSICAL QUANTITIES

The dimensions of a physical quantity are the powers (or exponents) to
which the base quantities are raised to represent that quantity.

For example, the volume occupied by an object is expressed as the product
of length, breadth and height, or three lengths. Hence the dimensions of
volume are [L] × [L] × [L] = [L]3 = [L3]

Dimensions of base quantities

Physical Quantity Dimension
Length [L]
Mass [M]
Time [T]
Temperature [K]
Electric current [A]
Luminous intensity [cd]
Amount of substance [mol]

An equation obtained by equating a physical quantity with its dimensional
formula is called the dimensional equation

For example, the dimensional equations of volume [V], speed [v], force [F]
and mass density [𝜌] may be expressed as

Principle of homogeneity of dimensions

Two physical quantities may be added together of subtracted from one
another if they have the same dimensions. This principle is called the
principle of homogeneity of dimensions.

DIMENSIONAL ANALYSIS AND ITS APPLICATIONS

1) Checking the Dimensional Consistency of Equations

An equation is dimensionally correct if the dimension of each term of the left
side of the equation is equal to the dimension each term on the right side.

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Example:

Check the dimensional consistency of the equation ½ mv2 = mgh

Solution:
Dimension of m = [M]
v = [LT-1]
g = [LT-2]
h = [L]

Substituting the dimensions in the equation

[M] [LT-1]2 = [M] [LT-2] [L]

[ML2T-2] = [ML2T-2]

Dimension on left side of the equation is equal to the dimension on the right
side. So, the equation is dimensionally correct.

A dimensionally correct equation need not be an exact (correct) equation,
but a dimensionally wrong (incorrect) or inconsistent equation must be
wrong.

2) Deducing Relation among the Physical Quantities

The method of dimensions can sometimes be used to deduce relation among
the physical quantities. For this we should know the dependence of the
physical quantity on other quantities.

Example:

The period of oscillation of the simple pendulum depends on its length (l),
mass of the bob (m) and acceleration due to gravity (g). Derive the expression
for its time period using method of dimensions.

Solution:
The dependence of time period T on the quantities l, g and m as a product
may be written as :

T = klxgymz………..(1)

Where k is a dimensionless constant and x,y and z are the exponents.

By considering the dimension on both sides

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On equating the dimension on both sides

So that x = ½ , y = -½ , z = 0.

Substituting the exponents in equation (1)

T = k l ½ g -½

!
T = k ""
Note that value of constant k can not be obtained by the method of
dimensions.

The value of k = 2π

!
T = 2π ""

LIMITATIONS OF DIMENSIONAL ANALYSIS

1. The method does not give any information about the dimensionless
constant K.
2. It fails when a physical quantity depends on more than three physical
quantities.
3. It fails when a physical quantity (e.g., s= ut + ½ at2) is the sum or
difference of two or more quantities.
4. It fails to derive relationships which involve trigonometric, logarithmic
or exponential functions.
5. Sometimes, it is difficult to identify the factors on which the physical
quantity depends.

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