Transcript Measurement and units summary powerpoint

Skills for Physics
SI Units
Over the centuries many different units for measuring
physical quantities have been developed.
For example...
Lengths can be measured in chains, fathoms, furlongs,
yards, feet, rods and microns.
SI Units
The metric system was established by the French
Academy of Science at the time of the French
Revolution (1789–1815).
This system includes units such as the metre, litre and
kilogram.
Countries of the British Empire adopted the British
Imperial system of the mile, gallon and pound.
SI Units
Having separate systems made it harder for scientists to
communicate and compare data. It also made it harder
for merchants to trade goods.
In 1960 an international comittee set standard units for
fundamental physical quantities.
These were called the Système Internationale d’Unites
(in French). We know them as the SI units.
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Base Units
Mass
The kilogram was originally defined as the mass of 1 L
of water at 4°C.
Since 1897 the measurement standard for the
kilogram has been a cylindrical block of platinum–
iridium alloy kept at the International Bureau of
Weights and Measures in France.
Australia has a copy of this at the CSIRO Division of
Applied Physics in Sydney. At times it is returned to
France to ensure that the mass remains accurate.
Length
The metre was originally defined in 1792 as one tenmillionth of the distance from the equator to the North
Pole.
In 1983, to give a more accurate value, the metre was
redefined as the distance that light in a vacuum travels
in 1/299 792 458 second.
This can be reproduced all over the world, as light travels
at a constant speed in a vacuum.
Time
Until 1960, one second was defined as 1/60 of 1/60 of
1/24 of an average day in 1900. Unfortunately the Earth’s
rotation on its axis not quite uniform.
In 1967 one second was defined as the time required
for a caesium-133 atom to undergo 9 162 631 770
vibrations.
Derived Units
Derived units are defined in terms of the base SI units.
For example...
 Velocity has unit m s-1
 Force has unit kg m s-2
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Derived Units
Negative Indices
Derived units are often expressed with negative indices.
For example, the unit of speed is usually expressed as m
s−1 rather than m/s because...
1
1
s
s
The unit of pressure, newtons per square metre, or
N/m2, is written as N m−2 because...
1
2

m
m2
Prefixes
Some SI units are too large or small for measuring some
quantities.
For example, consider measuring...
 the thickness of a human hair in metres
 the age of the Earth in seconds
The prefixes used in front of SI units allow you to use
more appropriate units such as millimetres or kilometres
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Prefixes
Correct use of symbols
 Uppercase letters are not used for the names of
quantities (eg: newton).
 Uppercase letters are only used for symbols that are
named after people (eg: N).
 The one exception to this is the litre (L).
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Correct use of symbols
 For a derived unit which is the product of two other
units the unit symbols are separated by a dot or a space
(eg: N m or N.m)
 Units involving the division of other units can be
shown as a fraction or a negative index (eg: m/s or ms-1)
 Prefixes should not be separated by a space.
What is wrong with these: ms-2, k m/h, µM, Nm
Practice questions
For these questions you will need to refer to...
 the table of SI units on page 563
 the table of derived units on page 564
 the table of prefixes on page 566
1. Write the full name for the following units
a. dm
b. mA
c. nJ
d. µg
2. Express each of the following quantities in SI base units
a. 1500 mA
b. 250 GW (note 1W = 1 J s-1)
velocity
c. 150 µs
d. 12 dm
acceleration 
time
3. What is the SI unit for acceleration if
Accuracy and Precision
Often the terms accuracy and precision are used
interchangeably, however they are not the same thing
and the difference between them is important in
Physics.
Accurate measurements are, on average, a good
representation of the actual value.
Precise measurements have very little variation
between consecutive readings.
Accuracy and Precision
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Accuracy and Precision
The precision of a instrument determines the
uncertainty in a measurement.
The uncertainty (sometimes called error) is generally
one half of the finest scale division on the measuring
instrument.
Examples...
Significant figures
When we take a measurement the number of significant
figures we write down reflects the uncertainty of the
measuring device.
Examples...
5.5 m
16.5 cm
16.25 cm
Significant figures
Significant figures and decimal places are two different
things.
To determine the number of significant figures in a value
follow these rules...

Zeros between other numbers are significant eg: 1001

Zeros before other numbers are not significant eg: 0.01

For zeros after other numbers...

To the right of the decimal point they are significant eg: 0.10

To the left of the decimal point they are significant unless
stated otherwise eg: 8000
Significant figures
Practice questions
1.
Round the following to...
i) 1 decimal place
ii) 2 decimal places
a) 7.953
b) 12.076
c) 0.083
d) 100.999
e) 33.333
f) 6.12059
2. Round each of the following numbers to the number of
significant figures shown in the brackets.
a) 4.397 (1)
b) 758.92 (1) c) 1200.56 (2)
d) 3.5009 (3)
e) 0.0762 (2) f) 19.0583 (4)
3. How many significant figures are there in the following...
a) 100.029
b) 9.250
c) 0.029
Significant figures
4. Round the following to the number of decimal places
shown in the brackets.
a) 9.259 (2)
b) 12.076(1)
c) 0.083(0)
5. Round each of the following numbers to the number of
significant figures shown in the brackets.
a) 2700.397 (1) b) 257.83 (3) c) 2.15007 (2)
6. Evaluate the following to the correct numbers of
significant figures.
a) The area of a circle with a radius of 10.0 cm
b) The volume of milk left in a 1 L carton after 300 ml has
been removed.
Scientific notation
To make it clear how many significant figures there are
in a value scientists use scientific notation.
In scientific notation values are written as a number
between 0 and 10, then multiplied by a power of 10.
Example:
0.054 = 5.4 × 10-2
245.7 = 2.457 × 102
Note that scientific notation, standard notation and
standard form all have the same meaning.
Scientific notation
Practice questions
1. Express the following quantities in scientific
notation:
(a) the radius of the Earth, 637 000 m
(b) the speed of light in a vacuum, 300 000 000 m s−1
(c) the diameter of a typical atom, 0.000 000 000 3 m
2. The speed of light in a vacuum is 2.9979 × 108 ms-1 ,
write this without using scientific notation.