1. Error, their types, their measurements G.P.C. Khunimajra(Mohali)
Presented By:
Anu Bala
G.P.C. Khunimajra(Mohali)

2. What is an error? Some are due to human error… For example,
by not using the equipment correctly
Let’s look at some examples.

3. Human error
Example 1
Professor Messer is trying to measure the length of a piece of wood:
Discuss what he is doing wrong.
How many mistakes can you find? Six?

4. Human error Measuring from 100 end 95.4 is the wrong number
Answers:
Measuring from 100 end
95.4 is the wrong number
‘mm’ is wrong unit (cm)
Hand-held object, wobbling
Gap between object & the rule
End of object not at the end of the rule
Eye is not at the end of the object (parallax)
He is on wrong side of the rule to see scale.
How many did you find?

5. Human error Example 2 Reading a scale:
your eye
Reading a scale:
Discuss the best position to put your eye.

6. Human error 2 is best. 1 and 3 give the wrong readings.
This is called a parallax error.
your eye
It is due to the gap here, between the pointer and the scale.
Should the gap be wide or narrow?

7. Anomalous results
When you are doing your practical work, you may get an odd or inconsistent or ‘anomalous’ reading.
This may be due to a simple mistake in reading a scale.
The best way to identify an anomalous result is to draw a graph.
For example . . .

8. Anomalous results Look at this graph:x
Which result do you think may be anomalous?
A result like this should be taken again, to check it.

9. ERRORS
If we are making physical measurements, there is always error involved. The error is notated by using the delta, Δ, symbol followed by the variable representing the quantity measured.
For example, if we are measuring volume, the error in measuring the volume would be symbolized ΔV.

10. Calculating the Error
A simple way of looking at the error is as the difference between the true value and the approximate value.
i.e:
Error (e) = True value – Approximate value

11. Example:
Find the truncation error for at x= if the first 3 terms in the expansion are retained.
Sol: Error = True value – Approx value

12. TYPE OF ERRORS Static Errors Type of errors Gross error/human Errors
Random Errors
Systematic Errors
Constant Errors
Absolute Errors
Relative Errors
Percentage Errors
Static Errors

13. TYPES OF STATIC ERROR 1) Gross Error
cause by human mistakes in reading/using instruments
may also occur due to incorrect adjustment of the instrument and the computational mistakes
cannot be treated mathematically
cannot eliminate but can minimize
Eg: Improper use of an instrument.
This error can be minimized by taking proper care in reading and recording measurement parameter.
In general, indicating instruments change ambient conditions to some extent when connected into a complete circuit.
Therefore, several readings (at three readings) must be taken to minimize the effect of ambient condition changes.

14. TYPES OF STATIC ERROR (cont)
2) Systematic Error
- due to shortcomings of the instrument (such as
defective or worn parts, ageing or effects of the environment on the instrument)
In general, systematic errors can be subdivided into static and dynamic errors.
Static – caused by limitations of the measuring device or the physical laws governing its behavior.
Dynamic – caused by the instrument not responding very fast enough to follow the changes in a measured variable.

15. TYPES OF STATIC ERROR (cont)
- 3 types of systematic error :-
(i) Instrumental error
(ii) Environmental error
(iii) Observational error

16. TYPES OF STATIC ERROR (cont)
(i) Instrumental error
- inherent while measuring instrument because of their mechanical structure (eg: in a D’Arsonval meter, friction in the bearings of various moving component, irregular spring tension, stretching of spring, etc)
- error can be avoid by:
(a) selecting a suitable instrument for the particular
measurement application
(b) apply correction factor by determining
instrumental error
(c) calibrate the instrument against standard

17. TYPES OF STATIC ERROR (cont)
(ii) Environmental error
- due to external condition effecting the
measurement including surrounding area condition
such as change in temperature, humidity,
barometer pressure, etc
- to avoid the error :-
(a) use air conditioner
(b) sealing certain component in the instruments
(c) use magnetic shields
(iii) Observational error
- introduce by the observer
- most common : parallax error and estimation error (while reading the scale)
- Eg: an observer who tend to hold his head too far to the left, while reading the position of the needle on the scale.

18. TYPES OF STATIC ERROR (cont)
3) Random error
- due to unknown causes, occur when all systematic
error has accounted
- accumulation of small effect, require at high degree of
accuracy
- can be avoid by
(a) increasing number of reading
(b) use statistical means to obtain best approximation
of true value

19. What is systematic error?
Systematic error is caused by any factors that systematically affect measurement of the variable across the sample.
For instance, if there is loud traffic going by just outside of a classroom where students are taking a test, this noise is liable to affect all of the children's scores -- in this case, systematically lowering them.
Unlike random error, systematic errors tend to be consistently either positive or negative -- because of this, systematic error is sometimes considered to be bias in measurement.

20. Systematic errors
These errors cause readings to be shifted one way (or the other) from the true reading.
Your results will be systematically wrong.
Let’s look at some examples . . .

21. Systematic errors Example 1 Suppose you are measuring with a ruler:
If the ruler is wrongly calibrated, or if it expands,
then all the readings will be too low (or all too high):

22. Systematic errors Example 2 If you have a parallax error:
with your eye always too high
then you will get a systematic error
All your readings will be too high.

23. Systematic errors A particular type of systematic error
is called a zero error.
Here are some examples . . .

24. Zero errors Example 3 A spring balance: Over a period of time,
the spring may weaken,
and so the pointer
does not point to zero:
What effect does this have on all the readings?

25. Zero errors Example 4 Look at this top-pan balance:
It has a zero error.
There is nothing on it, but it is not reading zero.
What effect do you think this will have on all the readings?

26. Zero errors Example 5 Look at this ammeter:
If you used it like this, what effect would it have on your results?

27. Zero errors Example 6 Look at this voltmeter:
What is the first thing to do?
Use a screwdriver here to adjust the pointer.

28. Zero errors Example 7 Look at this ammeter: What can you say?
Is it a zero error?
Or is it parallax?

29. Zero error, Parallax error
Example 8
Look at this ammeter:
It has a mirror behind the pointer, near the scale.
What is it for?
How can you use it to stop parallax error?
When the image of the pointer in the mirror is hidden by the pointer itself, then you are looking at 90o, with no parallax.

30. What is random error?
Caused by any factors that randomly affect measurement of the variable across the sample.
Each person’s mood can inflate or deflate their performance on any occasion. In a particular testing, some children may be in a good mood and others may be depressed. Mood may artificially inflate the scores for some children and artificially deflate the scores for others.
Random error does not have consistent effects across the entire sample. If we could see all the random errors in a distribution, the sum would be zero.
The important property of random error is that it adds variability to the data but does not affect average performance for the group.

31. Random Errors
Random errors are “not inherent to the measuring process”. 
Frequently they are introduced by external factors that cause a scattering of the measured data.
When the scattering is distributed equally about the true value, the error can be mitigated somewhat by making multiple measurements and averaging the data. 
Vibration in mechanical devices produces random errors.
  In electronic devices, noise produces random errors.   

32. Random errors These may be due to human error, a faulty technique,
or faulty equipment.
To reduce the error,
take a lot of readings,
and then calculate the average (mean).

33. Constant Error
When the results of observation are in error by the same amount, the error is said to be a constant error. e.g. if a scale of 15 cm actually measures 14.8 cm. Then it is measuring 0.2 cm more in every observation. This type of error will be same in all measurements done by the scale.

34. Another types of Error Three other ways of defining the error are:
Absolute error
Relative error
Percentage error

35. Calculation the Absolute Error
ea = |True value – Approximate value|

36. Calculating the Error Absolute error:
ea = |True value – Approximate value|
Relative error is defined as:

37. Absolute Error
The difference between the measured value and the true value is referred to as the absolute error. Assume that analysis of an iron ore by some method gave 11.1% while the true value was 12.1%, the absolute error is:
11.1% % = -1.0%

38. Relative Error
The relative error is the percentage of the absolute error to the true value. For the argument above we can calculate the relative error as:
Relative error = (absolute error/true value)x100%
= (-1.0/12.1)x100% = -8.3%

39. Relative Accuracy
The percentage of the quotient of observed result to the true value is called relative accuracy.
Relative accuracy = (observed value/true value)x100%
For the abovementioned example:
Relative accuracy = (11.1/12.1)x100% = 91.7%

40. Calculating the Error
Percentage error is defined as:

41. Examples
Suppose is used as an approx to . Find the absolute, relative and percentage errors.

42. Examples
Suppose is used as an approx to . Find the absolute, relative and percentage errors.

43. Examples
Suppose is used as an approx to . Find the absolute, relative and percentage errors.

44. Example:
True value = 122 mm
expected value = 120 mm
Then:
a. absolute error = True value - expected value absolute error = 122 mm – 120 mm = 2 mm  Ans
b. relative error = absolute error / expected value relative error = 2 mm / 120 mm =  0.017  Ans Note: relative error has no units.
c. percent error = relative error · 100%
percent error = · 100% =  1.7 %  Ans

45. Classification of Error
The following are general classifications for errors:
For consumer purposes, 5-10% error is acceptable
For engineering purposes, 1% error is acceptable
For scientific purposes, 0.1% error is acceptable

46. Range of Uncertainty
Range of uncertainty is reported as a nominal value plus or minus an amount called the tolerance. Reported value: 120 mm ±1 mm = 119 mm to 121 mm
tolerance
nominal value
range of uncertainty

47. Range of Uncertainty
Range of uncertainty is also reported as a nominal value plus or min Range of uncertainty is reported as a nominal value plus or minus an amount called the tolerance us an percent tolerance.
Reported value 120 mm ±2% = mm to mm
Note: 2% of 120 = 2.4, = 117.6, = 122.4
tolerance
nominal value
range of uncertainty

48. PERFORMANCE CHARACTERISTICS
Accuracy – the degree of exactness (closeness) of measurement compared to the expected (desired) value.
Resolution – the smallest change in a measurement variable to which an instrument will respond.
Precision – a measure of consistency or repeatability of measurement, i.e successive reading do not differ.
Sensitivity – ratio of change in the output (response) of instrument to a change of input or measured variable.
Expected value – the design value or the most probable value that expect to obtain.
Error – the deviation of the true value from the desired value. 48

49. Precision – Target 1
Measurement precision must be interpreted in light of measurement accuracy.  Let’s use a target practice example:
The best situation, the shots are tightly clustered (high precision) on the center circle (high accuracy).

50. Precision – Target 2
Measurement precision must be interpreted in light of measurement accuracy.  Let’s use a target practice example:
The next situation, shots are near the center (high accuracy), but not tightly clustered (low precision).  

51. Precision – Target 3
Measurement precision must be interpreted in light of measurement accuracy.  Let’s use a target practice example:
In the next situation, a tight cluster (high precision) is far off center (low accuracy).

52. Precision – Target 4
Measurement precision must be interpreted in light of measurement accuracy.  Let’s use a target practice example:
Finally, widely scattered shots (low precision) appear away from the center (low accuracy).

53. Precision - Comparison
Which is the best and which is worst?
Most Insidious
Why?
Best
Worst

54. Example Given expected voltage value across a resistor is 80V.
The measurement is 79V. Calculate,
The absolute error
The % of error
The relative accuracy
The % of accuracy

55. Solution (Example) Given that , expected value = 80V
measurement value = 79V
i. Absolute error, e = = 80V – 79V = 1V
ii. % error = = = 1.25%
iii. Relative accuracy, =
iv. % accuracy, a = A x 100% = x 100% = %

56. Example From the value in table 1.1 calculate Table 1.1
the precision of 6th measurement?
Solution
the average of measurement value
the 6th reading Precision = No Xn 1 98 2
101 3
102 4 97 5 6
100 7
103 8 9
106 10 99

57. LIMITING ERROR
The accuracy of measuring instrument is guaranteed within a certain percentage (%) of full scale reading
E.g manufacturer may specify the instrument to be accurate at 2 % with full scale deflection
For reading less than full scale, the limiting error increases

58. LIMITING ERROR (cont) Example
Given a 600 V voltmeter with accuracy 2% full scale.
Calculate limiting error when the instrument is used to measure a voltage of 250V?
Solution
The magnitude of limiting error, 0.02 x 600 = 12V
Therefore, the limiting error for 250V = 12/250 x 100 = 4.8%

59. LIMITING ERROR (cont) Example
Given for certain measurement, a limiting error for voltmeter at 70V is 2.143% and a limiting error for ammeter at 80mA is 2.813%. Determine the limiting error of the power.
Solution
The limiting error for the power = 2.143% %
= 4.956%

60. Example
What is the relative error in the approximation X = 2.0 to x = 1.98?
Solution
Relative error = = = (to 5d.p.) X x 2
1.98 - 1 - 1

61. In summary Human errors can be due to faulty technique.
Parallax errors can be avoided.
Anomalous results can be seen on a graph.
Random errors can be reduced by taking many readings, and then calculating the average (mean).
Systematic errors, including zero errors, will cause all your results to be wrong.

62. THE END

63. Scientists and engineers express measurement quality using,
SWTJC STEM – ENGR 1201
Quality Factors
Accuracy "refers to how close the reported value comes to the true value“
Precision "refers to the clustering of a group of measurements“
Scientists and engineers express measurement quality using,
Content Goal 13

64. Errors in measurement can be classified in two types:
SWTJC STEM – ENGR 1201
Error Types
Errors in measurement can be classified in two types:
1. Systematic Errors results from a measurement that is inherently wrong Random Errors results from the effect of external factors.
Content Goal 13

65. ABSOLUTE, RELATIVE, AND PERCENT ERROR
The actual error from the true value is called the absolute error.
The relative error is the absolute error divided by total quantity. In the case of volume,
The percentage error is the relative error multiplied by 100.