Presentation is loading. Please wait.

Presentation is loading. Please wait.

Errors and Uncertainties in Biology

Published byNicholas O'Donnell Modified over 11 years ago

Similar presentations

Presentation on theme: "Errors and Uncertainties in Biology"— Presentation transcript:

1 Errors and Uncertainties in Biology

2 Accuracy Accuracy indicates how close a measurement is to the accepted value.  For example, we'd expect a balance to read 100 grams if we placed a standard 100 g weight on the balance.  If it does not, then the balance is inaccurate.

3 Precision Precision indicates how close together or how repeatable the results are.  A precise measuring instrument will give very nearly the same result each time it is used. The precision of an instrument reflects the number of significant digits in a reading. TRIAL MASS(g) 1 100.01 100.10 2 100.00 3 99.99 99.88 4 100.02 Average Range ±0.01 ±0.11

4 Precision Precision indicates how close together or how repeatable the results are.  A precise measuring instrument will give very nearly the same result each time it is used. The precision of an instrument reflects the number of significant digits in a reading. More precise Less precise TRIAL MASS(g) 1 100.01 100.10 2 100.00 3 99.99 99.88 4 100.02 Average Range ±0.01 ±0.11

5 Let’s play darts!

6 Let’s play darts!

7 Let’s play darts!

8 Let’s play darts!

9 Accurate? Precise?

10 Precise, but poor accuracy

11 Play again?

12 Play again?

13 Play again?

14 Play again?

15 Play again?

16 Accuracy? Precision?

17 Both accurate and precise

18 One more time!

19 One more time!

20 One more time!

21 One more time!

22 One more time!

23 Well?

24 Poor accuracy and precision

25 Uncertainty in measurement

26 Uncertainty in measurement
An error in a measurement is defined as the difference between the true, or accepted, value of a quantity and its measured value.

27 Uncertainty in measurement
An error in a measurement is defined as the difference between the true, or accepted, value of a quantity and its measured value. In reading any scale the value read is numbers from the scale and one estimated number from the scale and an error of  ½ a division.

28 The Ruler 0.0mm ± 0.5mm 43.4 mm ± 0.5mm Add the uncertainties, therefore 43.4 mm ± 1mm

29 The Balance The balance measures to three decimal places: e.g g. The uncertainty is  g, but once again we have to determine two points, the zero (with no mass on the balance) and the mass of the object to be measured. Therefore the uncertainty is  g

30 Data Collection Whenever you record raw data you must include the uncertainty of the measuring device.

31 Which is more precise? The ruler or the balance?

32 Which is more precise? The ruler or the balance?
The balance has a greater precision than the ruler, it measures to more decimal places and therefore the measurements are closer together.

33 Which is more precise? The ruler or the balance?
The balance has a greater precision than the ruler, it measures to more decimal places and therefore the measurements are closer together. E.g. Balance: g, g, g Ruler: 23.3mm, 23.5mm, 23.6mm

34 Accuracy and Precision
Two students set out to measure the size of a cell that is known to be 100 m in length. Each student takes a number of measurements and they arrive at the following answers:

35 Accuracy and Precision
Two students set out to measure the size of a cell that is known to be 100 m in length. Each student takes a number of measurements and they arrive at the following answers: Student A: 101 m  8 m Student B: 95 m  1 m

36 Accuracy and Precision
Two students set out to measure the size of a cell that is known to be 100 m in length. Each student takes a number of measurements and they arrive at the following answers: Student A: 101 m  8 m Student B: 95 m  1 m Which students measurements are more precise? Which students measurements are more accurate?

37 Accuracy and Precision
Two students set out to measure the size of a cell that is known to be 100 m in length. Each student takes a number of measurements and they arrive at the following answers: Student A: 101 m  8 m Student B: 95 m  1 m Which students measurements are more precise? B Which students measurements are more accurate?

38 Accuracy and Precision
Two students set out to measure the size of a cell that is known to be 100 m in length. Each student takes a number of measurements and they arrive at the following answers: Student A: 101 m  8 m Student B: 95 m  1 m Which students measurements are more precise? B Which students measurements are more accurate? A

39 Types of errors

40 Types of errors There are two types of errors that we are concerned with when looking at our experimental data:

41 Types of errors There are two types of errors that we are concerned with when looking at our experimental data: Systematic errors

42 Types of errors There are two types of errors that we are concerned with when looking at our experimental data: Systematic errors Random errors

43 Systematic errors

44 Systematic errors Result from a defect in an instrument or procedure. E.g. the balance is incorrectly calibrated.

45 Systematic errors Result from a defect in an instrument or procedure. E.g. the balance is incorrectly calibrated. The systematic error is always in one direction. E.g. the incorrectly calibrated balance always gives readings that are too high by 0.1g.

46 Systematic errors Result from a defect in an instrument or procedure. E.g. the balance is incorrectly calibrated. The systematic error is always in one direction. E.g. the incorrectly calibrated balance always gives readings that are too high by 0.1g. Comparison to standard samples can help overcome systematic errors. E.g. use a standard of known mass on the balance.

47 Systematic errors Systematic errors affect the accuracy of the readings.

48 Random errors

49 Random errors Result from random fluctuations in procedures and measuring devices.

50 Random errors Result from random fluctuations in procedures and measuring devices. Because this error is random in nature it can be too high or too low than the actual value.

51 Random errors Result from random fluctuations in procedures and measuring devices. Because this error is random in nature it can be too high or too low than the actual value. Random errors can be reduced by taking the average of several replicate measurements.

52 Random errors An average of the measurements will be more accurate, closer to the actual value.

53 Random errors average An average of the measurements will be more accurate, closer to the actual value.

Download ppt "Errors and Uncertainties in Biology"

Similar presentations

Errors and uncertainties in chemistry internal assessment

Errors and uncertainties in chemistry internal assessment
Measurements and Their Uncertainty 3.1

Measurements and Their Uncertainty 3.1
Uncertainty and Significant Figures

Uncertainty and Significant Figures
Experimental Measurements and their Uncertainties

Experimental Measurements and their Uncertainties
US Customary Measurement System. The U S Customary System System of measurement used in the United States Similar to the British Imperial System of Measurement,

US Customary Measurement System. The U S Customary System System of measurement used in the United States Similar to the British Imperial System of Measurement,
 When we count we use exact numbers  If we count people we have exactly 4 people  There is no uncertainty about this number of people.  Measurements.

 When we count we use exact numbers  If we count people we have exactly 4 people  There is no uncertainty about this number of people.  Measurements.
Errors and Uncertainties in Biology Accuracy Accuracy indicates how close a measurement is to the accepted value. For example, we'd expect a balance.

Errors and Uncertainties in Biology Accuracy Accuracy indicates how close a measurement is to the accepted value. For example, we'd expect a balance.
Uncertainty/Error in Measurment

Uncertainty/Error in Measurment
1 Determining Mass Mass is a direct measurement of the amount of matter in a sample.

1 Determining Mass Mass is a direct measurement of the amount of matter in a sample.
Using Scientific Measurements.

Using Scientific Measurements.
Ch. 3.1 – Measurements and Their Uncertainty

Ch. 3.1 – Measurements and Their Uncertainty
Objectives The student will be able to: ● Distinguish between accuracy and precision ● Use significant figures in measurements and calculations.

Objectives The student will be able to: ● Distinguish between accuracy and precision ● Use significant figures in measurements and calculations.
Topic 11: Measurement and Data Processing

Topic 11: Measurement and Data Processing
Errors and Uncertainties © Christopher Talbot and Cesar Reyes 2008

Errors and Uncertainties © Christopher Talbot and Cesar Reyes 2008
Reliability of Measurements

Reliability of Measurements
Chapter 2 Data Handling.

Chapter 2 Data Handling.
Uncertainty in Measurement Professor Bob Kaplan University Department of Science 1.

Uncertainty in Measurement Professor Bob Kaplan University Department of Science 1.
The ± 1 second is called the absolute uncertainty Every measurement has an uncertainty or error. e.g. time = 5 seconds ± 1 second There are three main.

The ± 1 second is called the absolute uncertainty Every measurement has an uncertainty or error. e.g. time = 5 seconds ± 1 second There are three main.
Uncertainty and Error (11.1)  error in a measurement refers to the degree of fluctuation in a measurement  types systematic error ○ measurements are.

Uncertainty and Error (11.1)  error in a measurement refers to the degree of fluctuation in a measurement  types systematic error ○ measurements are.
Accuracy: The closeness of a measurement to the true or actual value

Accuracy: The closeness of a measurement to the true or actual value

Similar presentations

Ads by Google