How many different units of length can you think of?
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Transcript of How many different units of length can you think of?
How many different units of
length can you think
of?
Units of length?Light year, parsec, AU, mile, furlong, fathom, yard, feet, inches, Angstroms, nautical miles, cubits, cm, mm, km, μm, nm
The SI system of units
There are seven fundamental base units which are clearly defined and on which all other derived units are based:
You need to know these, but not their definitions.
The metre
• This is the unit of distance. It is the distance traveled by light in a vacuum in a time of 1/299792458 seconds.
The second
• This is the unit of time. A second is the duration of 9192631770 full oscillations of the electromagnetic radiation emitted in a transition between two hyperfine energy levels in the ground state of a caesium-133 atom.
The ampere
• This is the unit of electrical current. It is defined as that current which, when flowing in two parallel conductors 1 m apart, produces a force of 2 x 10-7 N on a length of 1 m of the conductors.
Note that the Coulomb is NOT a base unit.
The kelvin
• This is the unit of temperature. It is 1/273.16 of the thermodynamic temperature of the triple point of water.
The mole
• One mole of a substance contains as many molecules as there are atoms in 12 g of carbon-12. This special number of molecules is called Avogadro’s number and equals 6.02 x 1023.
The candela (not used in IB)
• This is the unit of luminous intensity. It is the intensity of a source of frequency 5.40 x 1014 Hz emitting 1/683 W per steradian.
The kilogram
• This is the unit of mass. It is the mass of a certain quantity of a platinum-iridium alloy kept at the Bureau International des Poids et Mesures in France.
THE kilogram!
SI Base UnitsQuantity Unit
distance metre
time second
current ampere
temperature kelvin
quantity of substance mole
luminous intensity candela
mass kilogram
Can you copy this please?
Note: No Newton or Coulomb
Derived units
Other physical quantities have units that are combinations of the fundamental units.
Speed = distance/time = m.s-1
Acceleration = m.s-2
Force = mass x acceleration = kg.m.s-2 (called a Newton)
(note in IB we write m.s-1 rather than m/s)
Some important derived units (learn these!)
1 N = kg.m.s-2 (F = ma)
1 J = kg.m2.s-2 (W = Force x distance)
1 W = kg.m2.s-3 (Power = energy/time)
Guess what
Prefixes
It is sometimes useful to express units that are related to the basic ones by powers of ten
Prefixes
Power Prefix Symbol Power Prefix Symbol
10-18 atto a 101 deka da
10-15 femto f 102 hecto h
10-12 pico p 103 kilo k
10-9 nano n 106 mega M
10-6 micro μ 109 giga G
10-3 milli m 1012 tera T
10-2 centi c 1015 peta P
10-1 deci d 1018 exa E
Prefixes
Power Prefix Symbol Power Prefix Symbol
10-18 atto a 101 deka da
10-15 femto f 102 hecto h
10-12 pico p 103 kilo k
10-9 nano n 106 mega M
10-6 micro μ 109 giga G
10-3 milli m 1012 tera T
10-2 centi c 1015 peta P
10-1 deci d 1018 exa E
Don’t worry!
These will all be in the
formula book you
have for the exam.
Examples
3.3 mA = 3.3 x 10-3 A
545 nm = 545 x 10-9 m = 5.45 x 10-7 m
2.34 MW = 2.34 x 106 W
Checking equations
If an equation is correct, the units on one side should equal the units on another. We can use base units to help us check.
Checking equations
For example, the period of a pendulum is given by
T = 2π l where l is the length in metres g and g is the acceleration due to gravity.
In units m = s2 = s m.s-2
Let’s try some questions for a change
Tsokos Page 6
Questions 15, 16, 18, 20, 21, 24, 26, 29.
Can you finish
these for Monday 11/9/12 please?
Let’s do some measuring!
Do the measurements
yourselves, but leave space in your table of results to record the measurements of 4
other people from the group
Errors/Uncertainties
Errors/Uncertainties
In EVERY measurement (as opposed to simply counting) there is an uncertainty in the measurement.
This is sometimes determined by the apparatus you're using, sometimes by the nature of the measurement itself.
Estimating uncertainty
As Physicists we need to have an idea
of the size of the uncertainty in each
measurement
The intelligent ones are
always the cutest.
Individual measurements
When using an analogue scale, the uncertainty is plus or minus half the smallest scale division. (in a best case scenario!)
4.20 ± 0.05 cm
Individual measurements
When using an analogue scale, the uncertainty is plus or minus half the smallest scale division. (in a best case scenario!) 22.0 ± 0.5 V
Individual measurements
When using a digital scale, the uncertainty is plus or minus the smallest unit shown.
19.16 ± 0.01 V
Repeated measurements
When we take repeated measurements and find an average, we can find the uncertainty by finding the difference between the highest and lowest measurement and divide by two.
Repeated measurements - Example
Pascal measured the length of 5 supposedly identical tables. He got the following results; 1560 mm, 1565 mm, 1558 mm, 1567 mm , 1558 mm
Average value = 1563 mm
Uncertainty = (1567 – 1558)/2 = 4.5 mm
Length of table = 1563 ± 5 mm
This means the actual length is anywhere between 1558 and 1568 mm
Average of the differences
• Imagine you got the following results for resistance (in Ohms)
• 13.2, 14.2, 12.3, 15.2, 13.1, 12.2.
Precision and Accuracy
The same thing?
Precision
A man’s height was measured several times using a laser device. All the measurements were very similar and the height was found to be
184.34 ± 0.01 cm
This is a precise result (high number of significant figures, small range of measurements)
AccuracyHeight of man = 184.34 ± 0.01cm
This is a precise result, but not accurate (near the “real value”) because the man still had his shoes on.
Accuracy
The man then took his shoes off and his height was measured using a ruler to the nearest centimetre.
Height = 182 ± 1 cm
This is accurate (near the real value) but not precise (only 3 significant figures)
Precise and accurate
The man’s height was then measured without his socks on using the laser device.
Height = 182.23 ± 0.01 cm
This is precise (high number of significant figures) AND accurate (near the real value)
Precision and Accuracy
• Precise – High number of significent figures. Repeated measurements are similar
• Accurate – Near to the “real” value
Random errors/uncertainties
Some measurements do vary randomly. Some are bigger than the actual/real value, some are smaller. This is called a random uncertainty. Finding an average can produce a more reliable result in this case.
Systematic/zero errors
Sometimes all measurements are bigger or smaller than they should be by the same amount. This is called a systematic error/uncertainty.
(An error which is identical for each reading )
Systematic/zero errors
This is normally caused by not measuring from zero. For example when you all measured Mr Porter’s height without taking his shoes off!
For this reason they are also known as zero errors/uncertainties. Finding an average doesn’t help.
Systematic/zero errors
Systematic errors are sometimes hard to identify and eradicate.
UncertaintiesIn the example with the table, we found the length of the table to be 1563 ± 5 mm
We say the absolute uncertainty is 5 mm
The fractional uncertainty is 5/1563 = 0.003
The percentage uncertainty is 5/1563 x 100 = 0.3%
UncertaintiesIf the average height of students at BSW is 1.23 ± 0.01 m
We say the absolute uncertainty is 0.01 m
The fractional uncertainty is 0.01/1.23 = 0.008
The percentage uncertainty is 0.01/1.23 x 100 = 0.8%
Let’s try some questions.
Let’s read!Pages 7 to 10 of Hamper/Ord ‘SL
Physics’
Combining uncertainties
When we find the volume of a block, we have to multiply the length by the width by the height.
Because each measurement has an uncertainty, the uncertainty increases when we multiply the measurements together.
Combining uncertainties
When multiplying (or dividing) quantities, to find the resultant uncertainty we have to add the percentage (or fractibnal) uncertainties of the quantities we are multiplying.
Combining uncertainties
Example: A block has a length of 10.0 ± 0.1 cm, width 5.0 ± 0.1 cm and height 6.0 ± 0.1 cm.
Volume = 10.0 x 5.0 x 6.0 = 300 cm3
% uncertainty in length = 0.1/10 x 100 = 1%% uncertainty in width = 0.1/5 x 100 = 2 %% uncertainty in height = 0.1/6 x 100 = 1.7 %
Uncertainty in volume = 1% + 2% + 1.7% = 4.7%
(4.7% of 300 = 14)
Volume = 300 ± 14 cm3
This means the actual volume could be anywhere between 286 and 314 cm3
Combining uncertainties
When adding (or subtracting) quantities, to find the resultant uncertainty we have to add the absolute uncertainties of the quantities we are multiplying.
Combining uncertainties
One basketball player has a height of 196 ± 1 cm and the other has a height of 152 ± 1 cm. What is the difference in their heights?
Difference = 44 ± 2 cm
Who’s going to win?
New York TimesLatest opinion poll
Bush 48%
Gore 52%
Gore will win!
Uncertainty = ± 5%
Who’s going to win?
New York TimesLatest opinion poll
Bush 48%
Gore 52%
Gore will win!
Uncertainty = ± 5%
Who’s going to win?
New York TimesLatest opinion poll
Bush 48%
Gore 52%
Gore will win!
Uncertainty = ± 5%
Uncertainty = ± 5%
Who’s going to win
Bush = 48 ± 5 % = between 43 and 53 %
Gore = 52 ± 5 % = between 47 and 57 %
We can’t say!
(If the uncertainty is greater than the difference)
Let’s try some more questions!
Error bars
• X = 0.6 ± 0.1
• Y = 0.5 ± 0.1
Gradients
Minimum gradient
Maximum gradient
y = mx + c
Hooke’s law
• F = kx
Hooke’s law
• F = kx
F (N)
x (m)
Kinetic energy
• Ek = ½mv2
y = mx + c
• Ek = ½mv2
Ek (J)
V2 (m2.s-2)
Period of a pendulum
T = 2π l g
Period of a pendulum
T = 2π l g
T (s)
l½ (m½)
Period of a pendulum
T = 2π l g
T2 (s)
l (m)
Let’s try an investigation
Can you read the sheets that Mr Porter is giving you?
Data collection and processing
• Heading, Units, Uncertainties
• Decimal places consistent between data and also with uncertainties
• Repeated measurements
• Averages (with uncertainties)
• Graph(s) with units and labels
• Lines of best fit – maximum and minimum gradients if possible/required
Homework
• Complete „Oscillating Mass” investigation.
• Due Monday 26th September