Units and Measurement PDF

Summary

This document covers the fundamental concepts of units and measurements in physics, including the International System of Units (SI). It details the measurement of length, mass, and time, and discusses accuracy, precision, and errors in measurements.

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CHAPTER TWO

UNITS AND MEASUREMENT

2.1 INTRODUCTION
Measurement of any physical quantity involves comparison
with a certain basic, arbitrarily chosen, internationally
2.1 Introduction accepted reference standard called unit. The result of a
measurement of a physical quantity is expressed by a
2.2 The international system of
number (or numerical measure) accompanied by a unit.
units
Although the number of physical quantities appears to be
2.3 Measurement of length very large, we need only a limited number of units for
2.4 Measurement of mass expressing all the physical quantities, since they are inter-
2.5 Measurement of time related with one another. The units for the fundamental or
2.6 Accuracy, precision of base quantities are called fundamental or base units. The
instruments and errors in units of all other physical quantities can be expressed as
measurement combinations of the base units. Such units obtained for the
2.7 Significant figures derived quantities are called derived units. A complete set
2.8 Dimensions of physical of these units, both the base units and derived units, is
quantities known as the system of units.
2.9 Dimensional formulae and 2.2 THE INTERNATIONAL SYSTEM OF UNITS
dimensional equations In earlier time scientists of different countries were using
2.10 Dimensional analysis and its different systems of units for measurement. Three such
applications systems, the CGS, the FPS (or British) system and the MKS
Summary system were in use extensively till recently.
Exercises The base units for length, mass and time in these systems
Additional exercises were as follows :
In CGS system they were centimetre, gram and second
respectively.
In FPS system they were foot, pound and second
respectively.
In MKS system they were metre, kilogram and second
respectively.
The system of units which is at present internationally
accepted for measurement is the Système Internationale
d’ Unites (French for International System of Units),
abbreviated as SI. The SI, with standard scheme of symbols,
units and abbreviations, was developed and recommended
by General Conference on Weights and Measures in 1971 for
UNITS AND MEASUREMENT 17

international usage in scientific, technical,
industrial and commercial work. Because SI
units used decimal system, conversions within
the system are quite simple and convenient. We
shall follow the SI units in this book.
In SI, there are seven base units as given in
(a)
Table 2.1. Besides the seven base units, there
are two more units that are defined for (a) plane
angle dθ as the ratio of length of arc ds to the
radius r and (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, as shown in Fig. 2.1(a)
and (b) respectively. The unit for plane angle is
radian with the symbol rad and the unit for the (b)
solid angle is steradian with the symbol sr. Both Fig. 2.1 Description of (a) plane angle dθ and
these are dimensionless quantities. (b) solid angle dΩ.

Table 2.1 SI Base Quantities and Units*
Base SI Units
quantity Name Symbol Definition
Length metre m The metre is the length of the path travelled by light in vacuum
during a time interval of 1/299,792,458 of a second. (1983)
Mass kilogram kg The kilogram is equal to the mass of the international prototype
of the kilogram (a platinum-iridium alloy cylinder) kept at
international Bureau of Weights and Measures, at Sevres, near
Paris, France. (1889)
Time second s The second is the duration of 9,192,631,770 periods of the
radiation corresponding to the transition between the two
hyperfine levels of the ground state of the cesium-133 atom.
(1967)
Electric ampere A The ampere is that constant current which, if maintained in
current two straight parallel conductors of infinite length, of negligible
circular cross-section, and placed 1 metre apart in vacuum,
would produce between these conductors a force equal to 2×10–7
newton per metre of length. (1948)
Thermo kelvin K The kelvin, is the fraction 1/273.16 of the thermodynamic
dynamic temperature of the triple point of water. (1967)
Temperature
Amount of mole mol The mole is the amount of substance of a system, which contains
substance as many elementary entities as there are atoms in 0.012
kilogram of carbon - 12. (1971)
Luminous candela cd The candela is the luminous intensity, in a given
intensity direction, of a source that emits monochromatic radiation of
frequency 540×1012 hertz and that has a radiant intensity in
that direction of 1/683 watt per steradian. (1979)

* The values mentioned here need not be remembered or asked in a test. They are given here only to indicate the
extent of accuracy to which they are measured. With progress in technology, the measuring techniques get
improved leading to measurements with greater precision. The definitions of base units are revised to keep up
with this progress.
18 PHYSICS

Table 2.2 Some units retained for general use (Though outside SI)

Note that when mole is used, the elementary 2.3.1 Measurement of Large Distances
entities must be specified. These entities Large distances such as the distance of a planet
may be atoms, molecules, ions, electrons,
or a star from the earth cannot be measured
other particles or specified groups of such
directly with a metre scale. An important method
particles.
in such cases is the parallax method.
We employ units for some physical quantities
that can be derived from the seven base units When you hold a pencil in front of you against
(Appendix A 6). Some derived units in terms of some specific point on the background (a wall)
the SI base units are given in (Appendix A 6.1). and look at the pencil first through your left eye
Some SI derived units are given special names A (closing the right eye) and then look at the
(Appendix A 6.2 ) and some derived SI units make pencil through your right eye B (closing the left
use of these units with special names and the eye), you would notice that the position of the
seven base units (Appendix A 6.3). These are pencil seems to change with respect to the point
given in Appendix A 6.2 and A 6.3 for your ready on the wall. This is called parallax. The
reference. Other units retained for general use distance between the two points of observation
are given in Table 2.2. is called the basis. In this example, the basis is
Common SI prefixes and symbols for multiples the distance between the eyes.
and sub-multiples are given in Appendix A2. To measure the distance D of a far away
General guidelines for using symbols for physical planet S by the parallax method, we observe it
quantities, chemical elements and nuclides are from two different positions (observatories) A and
given in Appendix A7 and those for SI units and B on the Earth, separated by distance AB = b
some other units are given in Appendix A8 for at the same time as shown in Fig. 2.2. We
your guidance and ready reference. measure the angle between the two directions
2.3 MEASUREMENT OF LENGTH along which the planet is viewed at these two
You are already familiar with some direct methods points. The ∠ASB in Fig. 2.2 represented by
for the measurement of length. For example, a symbol θ is called the parallax angle or
metre scale is used for lengths from 10–3 m to 102 parallactic angle.
m. A vernier callipers is used for lengths to an b
accuracy of 10 –4 m. A screw gauge and a As the planet is very far away,