IB Chemistry on Uncertainty, Error Analysis, Random and Systematic Error

Measurement

Every measurement – associated with an error
No measurement is 100% precise or accurate.

3 Types of Measurement

Not Precise + Not Accurate

Precise + Accurate

2 Types of Errors
Precise + Not Accurate

Systematic Error

Random Error

Affects accuracy

Affects precision

high systematic
error

Accurate
NOT accurate
low systematic error
NOT precise
High systematic
High random error

Precise
low random error

Not accurate
High systematic error

2 Types of Errors

Random Error

•
•
•
•

Measurement random
Instrument imprecise/uncertainty
Fluctuation reading burette/pipette
Small sample size/trials
Statistical fluctuation of
measurement/reading by
someone/unpredictable

Systematic Error

•
•
•
•
•

VS

Measurement too high/ low
Instrument not calibrated
Faulty apparatus (zero error)
Incorrect measurement
Imperfect instrument
Procedure/method incorrect/predictable

Accurate + Precise
Accuracy
Measurement value close to correct value

VS

Precise
Measurement value close to each other

high random error

2 Types of Errors
Systematic Error
Affects accuracy

•
•
•
•
•
•

Random Error
High random
error

High systematic
error

Measurement too high/ low
Instrument not calibrated
Faulty apparatus (zero error)
Incorrect measurement
Imperfect instrument
Procedure/method incorrect
Predictable

lower

Correct
value

•
•
•
•
•

Measurement random
Instrument imprecise/uncertainty
Fluctuation reading burette/pipette
Small sample size/trials
Statistical fluctuation of
measurement/reading by someone
Unpredictable

Correct
value

lower

higher

Direction error – always one side (higher/lower)

higher

Direction error – always random

Can be reduced

Can be identified/eliminated
Improve measuring
technique

Affects precision

Calibrating equipment
for zero error

Improve expt
design

Using precise
instrument

By repeating more
trials/average

✗

Calorimetry expt
Prevent heat loss
using insulator

Heating expt
Cool down before
weighing

✓

Random and Systematic Error
Measuring circumference using a ruler
Recording measurement using
uncertainty of equipment

Radius, r = (3.0 ±0.2) cm
Treatment of Uncertainty
Multiplying or dividing measured quantities

Circumference  2r

% uncertainty = sum of % uncertainty of individual quantities
Radius, r = (3.0 ±0.2)
%uncertainty radius (%Δr) = 0.2 x 100 = 6.6%
3.0
% uncertainty C = % uncertainty r
% ΔC = % Δr
* Constant, pure/counting number has no uncertainty and sf not taken

Correct value = 20.4
Expt value
= 19 ±6.7%

Circumference  2r
Circumference  2  3.14 3.0  18.8495
0.2
100%  6.6%
3.0
%c  %r
%c  6.6%
Circumference  (18.8495  6.7%)
%r 

AbsoluteC 

6.6
18.8495  1.25
100

Circumference  (18.8495  1.25)
Circumference  (19  1)
%Percentage Error = 6.7%

%Error  (

exp t  correct
) 100%
correct

19  20.4
% Error  (
) 100%  6.7%
20.4

Circumference  (18.8495 6.6%)
% Random Error

%Random Error
6.6%

High random error
Way reduce random error

%Systematic Error
0.1%

Small systematic error
Step/procedure correct

Measuring displacement using a stopwatch

Time, t = (2.25 ±0.01) cm

1 2
Multiplying or dividing measured quantities Displacement, s  gt

2

Time, t = (2.25 ±0.01)
%uncertainty time (%Δt) = 0.01 x 100 = 0.4%
2.25
% uncertainty s = 2 x % uncertainty t
% Δs = 2 x % Δt
* For measurement raised to power of n, multiply % uncertainty by n

Displacement, s 

1 2
gt
2

1
Displacement, s   9.8 x2.25x2.25  24.80
2

0.01
100%  0.4%
2.25
Measurement raised to power of 2,
%s  2  %t
multiply % uncertainty by 2
%s  2  0.4%  0.8%
Displacement  (24.80  0.8%)
%t 

Absolutes 

0.4
 24.80  0.198
100

Expt value
= 24.8 ±0.8%

exp t  correct
%Error  (
) 100%
correct
%Error  (

24.8  23.2
) 100%  0.7%
23.2

Displacement  (24.80  0.8%)
% Random Error

Displacement  (24.80  0.198)
Displacement  (24.8  0.2)

%Random Error 0.8%

% error fall within the % uncertainty (%Random error)
• Little/No systematic error
• Result is reliable but need to reduce random error

Measuring period using a ruler

Length, I = (1.25 ±0.05) m


L
g
1.25
T  2
 2.24
9. 8
T  2

0.05
100%  4%
1.25
1
power
%T   %l Measurement raised to by 1/2 of 1/2,
multiply % uncertainty
2
%T  2%
%l 

T  2

L
g

Length, I = (1.25 ±0.05)
%uncertainty length (%ΔI) = 0.05 x 100 = 4%
1.25
% uncertainty T = ½ x % uncertainty l
% ΔT = ½ x % ΔI
* For measurement raised to power of n, multiply % uncertainty by n


T  (2.24  2%)
AbsoluteT 

2
 2.24  0.044
100

T  (2.24  0.044)
T  (2.24  0.04)

Expt value
= 2.24 ±2%


%Error  (

exp t  correct
) 100%
correct

%Error  (

2.24  2.15
) 100%  4.2%
2.15

T  (2.24  2%)

% Random Error

%Random Error = 2%

%Systematic Error = 2.2%

% error fall outside> than % uncertainty (%Random error)
• Random error cannot account for % error
• Systematic error occur – way to reduce systematic error

Measuring Area using ruler

Length, I = (4.52 ±0.02) cm
Height, h = (2.0 ±0.2)cm3

Area, A  Length, l  height, h

Length, l = (4.52 ±0.02)
%uncertainty length (%Δl) = 0.02 x 100 = 0.442%
4.52
Height, h = (2.0 ±0.2)
%uncertainty height (%Δh) = 0.2 x 100 = 10%
2.0
% uncertainty A = % uncertainty length + % uncertainty height
% ΔA =
% ΔI
+
%Δh


Area  4.52 2.0  9.04
0.02
100%  0.442%
4.52
0.2
%h 
100%  10%
2.0
%A  %l  %h
%A  0.442%  10%  10.442%
Area  (9.04  10%)
%l 

AbsoluteA 

10
 9.04  0.9
100

Area  (9.0  0.9)
%Percentage Error = 9%

Expt value
= 24.8 ±0.87%

%Error  (

Area, A  Length, l  height, h

exp t  correct
) 100%
correct

24.8  22.7
%Error  (
) 100%  9%
22.7

Area  (9.04  10%)
% Random Error

%Random Error = 10%
• Result is reliable – need to reduce random error
Reduce random error – HUGE (10%) – use precise instrument vernier calipers

Vernier caliper

Measuring moles using
dropper and volumetric flask
Conc, c
= (2.00 ±0.02) cm
Volume, v = (2.0 ±0.1)dm3

Mole, n  Conc, c Volume, v
Mole  2.00 2.0  4.00
0.02
100%  1%
2.00
0.1
%v 
100%  5%
2.0
%n  %c  %v
%c 

Multiplying or dividing measured quantity Mole, n  Conc Vol
% uncertainty = sum of % uncertainty of individual quantity
Conc, c = (2.00 ±0.02)
%uncertainty conc (%Δc) = 0.02 x 100 = 1%
2.00
Volume, v = (2.0 ±0.1)
%uncertainty volume (%Δv) = 0.1 x 100 = 5%
2.0
% uncertainty n = % uncertainty conc + % uncertainty volume
% Δn =
% Δc
+
%Δv

Dropper, volumetric
flask

%n  1%  5%  6%
Mole  (4.00  6%)
Absoluten 

Mole  (4.00  0.24)

6
 4.00  0.24
100

Mole  (4.0  0.2)

Expt value
= 4.00 ±6%

exp t  correct
%Error  (
) 100%
correct
% Error  (

4  3.63
) 100%  10%
3.63
Mole  (4.00  6%)
% Random Error

%Random Error = 6%

%Systematic Error = 4%

• Systematic error occur – improve on method/steps used.
Ways to reduce error

Random error (6%)
More precise instrument -pipette

Systematic error (4%)
Calibration of instrument


Density, D 

Measuring density using mass
and measuring cylinder

Mass, m = (482.63 ±1)g
Volume, v = (258 ±5)cm3

Density, D 

Mass
Volume

482.63
 1.870658
258

1
100%  0.21%
482.63
5
%V 
100%  1.93%
258
%D  %m  %V
%m 

Mass
Multiplying or dividing measured quantities Density, D  Volume
Mass, m = (482.63 ±1)
%uncertainty mass (%Δm) = 1
x 100 = 0.21%
482.63
Volume, V = (258 ±5)
%uncertainty vol (%ΔV) = 5 x 100 = 1.93%
258
% uncertainty density = % uncertainty mass + % uncertainty volume
% ΔD =
% Δm
+
%ΔV

%D  0.21%  1.93%  2.1%
Density  (1.87  2.1%)
AbsoluteD 

2.1
1.87  0.04
100

Density  (1.87  0.04)


Expt value
= 1.87 ±2.1%
%Random Error = 2.1%

exp t  correct
%Error  (
) 100%
correct
1.87  1.78
%Error  (
) 100%  5%
1.78


• Systematic error occurs


Density  (1.87  2.1%)
Random error (6%)
Precise instrument
mass balance

% Random Error
Precise balance

Use different method like
displacement can
Displacement can

Measuring Enthalpy change using calorimeter/thermometer

Mass water = (2.00 ±0.02)g
ΔTemp
= (2.0 ±0.4) C
Multiplying or dividing measured quantities Enthalpy, H
Mass, m = (2.00 ±0.02)
%uncertainty mass (%Δm) = 0.02 x 100 = 1%
2.00
ΔTemp = (2.0 ±0.4)
%uncertainty temp (%ΔT) = 0.4 x 100 = 20%
2.0
% uncertainty H = % uncertainty mass + % uncertainty temp
% ΔH =
% Δm
+
%ΔT

 m  c  T

Enthalpy, H  2.00 4.18 2.0  16.72
0.02
100%  1%
2.00
0.4
%T 
100%  20%
2.0
%H  %m  %T
%m 

%H  1%  20%  21%
Enthalpy  (16.72  21%)
AbsoluteH 

21
16.72  3.51
100

Enthalpy  (16.72  3.51)
Enthalpy  (17  4)



Expt value
= 16.72 ±21%

%Error  (

Enthalpy, H  m  c  T

exp t  correct
) 100%
correct

%Random Error =21%

16.72  33.44
% Error  (
) 100%  50%
33.44
Enthalpy  (16.72  21%)


• Systematic error occurs – reduce this error

Random error (21%)
Precise Temp sensor

% Random Error

Temp sensor

Reduce heat loss
using styrofoam cup

Measuring speed change using stopwatch
G = (20 ± 0.5)
H = (16 ± 0.5)
Z = (106 ± 1.0)

Speed, s 

✔

Addition
add absolute uncertainty

Speed, s 

G+H = (36 ± 1)
Z = (106 ± 1.0)

(G  H )
Z

(G + H) = (36 ±1)
%uncertainty (G+H) (%ΔG+H) = 1 x 100 = 2.77%
36
Z = (106 ±1.0)
%uncertainty Z (%Δz) = 1.0 x 100 = 0.94%
106
%uncertainty s = %uncertainty(G+H) + %uncertainty(Z)
% Δs = % Δ(G+H)
+
%Δz

(G  H )
Z

(20  16)
 0.339
106
1.0
%(G  H ) 
100%  2.77%
36
1.0
%Z 
100%  0.94%
106
Speed, s 

%S  %(G  H )  %Z
%S  2.77%  0.94%  3.7%

Speed, s  (0.339  3.7%)
AbsoluteS 

*Adding or subtracting- Max absolute uncertainty is the SUM of individual uncertainties


3.7
 0.339  0.012
100

Speed, s  (0.339  0.012)

Expt value
= 0.339 ±3.7%

%Error  (

%Error  (

exp t  correct
) 100%
correct

%Random Error = 3.7%

• Result is reliable – need to reduce random error

0.339  0.330
) 100%  3%
0.330


Speed  (0.339  3.7%)
Random error (3.7%)
Precise time sensor
% Random Error

precise time sensor

No systematic error
Steps/method are reliable.

Volt, v = (2.0 ± 0.2)
Current, I = ( 3.0 ± 0.6)
Temp, t = (4.52 ± 0.02)


Energy, E 

0.02
 100%  0.442%
4.52
0 .6
% I 
 100%  20%
3 .0
0.2
% v 
 100%  10%
2.0
1
%E  %t  2  % I   %v
2
% t 

tI2
v1/ 2

% uncertainty = sum of % uncertainty of individual quantity
Time, t = (4.52 ±0.02)
%uncertainty temp (%Δt) = 0.02 x 100 = 0.442%
4.52
Current, I = (3.0 ±0.6)
%uncertainty current (%ΔI) = 0.6 x 100 = 20%
3.0
Volt, v = (2.0±0.2)
%uncertainty volt (%Δv) = 0.2 x 100 = 10%
2.0
% ΔE = %Δt + 2 x %ΔI + ½ x %ΔV

%E  

tI2
Energy, E  1/ 2
v
4.52(3.0) 2
Energy, E 
 28.638
2.01/ 2

0.02
0.6
1 0.2
100%    2  100%     100%   45%
4.52
3.0
2 2.0

Energy, E  (28.638  45%)
AbsoluteE 

Energy, E  (29  13)

45
 28.638  13
100


Expt value
= 28.638 ±45%

%Error  (

exp t  correct
) 100%
correct

%Random Error = 45%

• Systematic error occur – small compared to random error

28.638  19.092
%Error  (
) 100%  50%
19.092

Energy, E  (28.638  45%)
% Random Error


Reduce random error – HUGE (45%)
Precise instrument.
Temp sensor

Expt on enthalpy change of displacement between Zinc and copper sulphate
25 ml (1M) (0.025mole) CuSO4 solution added to cup. Initial Temp, T1 taken. Excess zinc powder was added.
Final Temp T2 was taken. Calculate ΔH for reaction.

Treatment of uncertainty

Adding or subtracting
Max absolute uncertainty is the SUM of individual uncertainties

Addition/Subtraction/Multiply/Divide

Multiplying or dividing
Max %uncertainty is the SUM of individual %uncertainties
Addition/Subtraction
Add absolute uncertainty

Initial mass beaker, M1
= (20.00 ±0.01) g
Final mass beaker + CuSO4 M2 = (45.00 ±0.01)g
Mass CuSO4 m = (M2 –M1)
Absolute uncertainty, Δm = (0.01 + 0.01) = 0.02

Initial Temp, T1 = (20.0 ±0.2)C
Final Temp, T2 = (70.6 ±0.2)C
Diff Temp ΔT = (T2 –T1)
Absolute uncertainty, ΔT = (0.2 + 0.2) = 0.4

Enthalpy, H = (M2-M1) x c x (T2-T1)
Enthalpy, H  m  c  T

Multiplication
Add % uncertainty

Enthalpy, H  25.00  4.18  50.6  5.29
Mass CuSO4 m = (45.00 –20.00) = 25.00
Absolute uncertainty, Δm = (0.01 + 0.01) = 0.02
Mass CuSO4 m = (25.00 ±0.02)g

Mass CuSO4 m = (25.00 ±0.02)g

Diff Temp ΔT = (70.6 –20.0) = 50.6
Absolute uncertainty, ΔT = (0.2 + 0.2) = 0.4
Diff Temp, ΔT = (50.6 ±0.4)

ΔTemp = (50.6 ±0.4) C

Multiplying or dividing measured quantities Enthalpy, H  m  c  T
Mass, m = (25.00 ±0.02)
%uncertainty mass (%Δm) = 0.02 x 100 = 0.08%
25.00
ΔTemp = (50.6 ±0.4)
%uncertainty temp (%ΔT) = 0.4 x 100 = 0.8%
50.6
% uncertainty H = % uncertainty mass + % uncertainty temp
% ΔH =
% Δm
+
%ΔT

0.025moleCuSO4  5.29

1moleCuSO4  5.29 

1
 212
0.025

0.02
 100%  0.08%
25.00
0.4
%T 
100%  0.8%
50.6
%H  %m  %T
%m 

%H  0.08%  0.8%  0.88%
Enthalpy  (212  0.88%)
AbsoluteH 

Enthalpy  (212  1.8)
Enthalpy  (212  2)

0.88
 212  1.86
100
Continue  next slide

Measuring Enthalpy change using calorimeter/thermometer

Enthalpy = (212 ± 0.88%)


Mass CuSO4 = (25.00 ±0.02)g
ΔTemp
= (50.6 ±0.4) C



Correct value = 250
Expt value
= 212 ±0.8%
%Random Error =0.88%

%Error  (
% Error  (

exp t  correct
) 100%
correct


• Small random error cannot account for % error
• Systematic error occurs – reduce this error

212  250
) 100%  15%
250


Enthalpy  (212  0.88%)
% Random Error

Reduce heat loss
use styrofoam cup

Extrapolate to higher temp
(Temp correction)

Small random error
Equipments OK

Systematic error (14.2%)

Stir the solution to
distribute heat

stirrer

•
•
•
•

Assumption wrong
Heat capacity cup is significant
Specific heat capacity CuSO4 is not 4.18
Thermometer has measurable heat capacity
Density solution not 1.00g/dm3

✗

IB Chemistry on Uncertainty, Error Analysis, Random and Systematic Error

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