1© Manhattan Press (H.K.) Ltd. Measurements and errors Precision and accuracy Significant figures cientific notation S cientific notation Measurements.

Slides:

Advertisements

Similar presentations

Chapter 2 – Scientific Measurement

Advertisements

Measurements Length Volume Temperature Mass 1.Will learn to use different measuring instrument 2.Will learn that the smaller the unit increment, the more.

Measuring Devices:. MEASURING MASS There are various types of laboratory balances. The triple beam beam balance you use may look somewhat different from.

Measuring Instruments

Significant Figures Every measurement has a limit on its accuracy based on the properties of the instrument used. we must indicate the precision of the.

 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.

Introduction to experimental errors

Physics and Measurements.

Ch. 3.1 – Measurements and Their Uncertainty

Measurements: Every measurement has UNITS.

SIGNIFICANT figures Two types of numbers: exact and inexact. Exact numbers are obtained by counting or by definitions – a dozen of wine, hundred cents.

Scientific Measurement

Topic 11: Measurement and Data Processing

IB Chemistry Chapter 11, Measurement & Data Processing Mr. Pruett

Making Measurements and Using Numbers The guide to lab calculations.

Chapter 2 Data Handling.

Unit 1: Measurements Measurement of Length.

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.

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

Lesson Starter Look at the specifications for electronic balances. How do the instruments vary in precision? Discuss using a beaker to measure volume versus.

Chapter 2 Measurement & Problem Solving. Uncertainty There is a certain amount of doubt in every measurement – It is important to know the uncertainty.

The Scientific Method 1. Using and Expressing Measurements Scientific notation is written as a number between 1 and 10 multiplied by 10 raised to a power.

Uncertainty and error Distinguish between precision and accuracy Accuracy is how close to the “correct” value Precision is being able to.

Physics and Physical Measurement The Realm of physics Measurement and uncertainties.

Error Analysis Significant Figures and Error Propagation.

1 Parts of a Measurement 1.The value (numerical portion) 2.The unit (describes what units) 3.The name of substance being measured EX: 1 teaspoon salt 2.

Honors Chemistry I. Uncertainty in Measurement A digit that must be estimated is called uncertain. A measurement always has some degree of uncertainty.

Significant Figures. What is a significant figure? There are 2 kinds of numbers: 1. Exact : Known with certainty. Example: the number of students in this.

Calibration vs. Precision If a balance is accurate, it should read 0 when nothing is on it. The process for making sure a balance or any equipment is accurate.

Ch.2 Measurements and Calculations

1.07 Accuracy and Precision

Measurements and Errors. Task: Find a textbook And measure it It doesn’t matter which textbook. It should have a length, a width and a height. Use the.

Measuring and Significant Digits. Parallax Error Parallax is the apparent shift in position of an object caused by the observer’s movement relative to.

Scientific Measurement Ch. 3. Scientific Notation 3-1.

WEEEK 3 MEASURING INSTRUMENTS. MEASUREMENT OF TIME All day to day activities involve the idea of time. To measure time instruments are needed. In the.

Uncertainty and Error in Measurement (IB text - Ch 11) (If reviewing this slide in the senior year, there is also uncertainty information in the AP text.

Measurement. Physics  A branch of science that involves the study of the physical world: energy, matter, and how they are related.

Significant Figures. Accuracy vs. Precision Percentage Error.

Significant Figures When using calculators we must determine the correct answer. Calculators are ignorant boxes of switches and don’t know the correct.

Significant Figures Chemistry 10 Chemistry 10 Significant figures: the number of digits in an experimentally derived number that give useful information.

Significant Digits. l Significant figures are extremely important when reporting a numerical value. l The number of significant figures used indicates.

Accuracy vs Precision Accuracy: how close a set of measurements is to the actual value. Precision: how close a set of measurements are to one another.

1© Manhattan Press (H.K.) Ltd. Graphical methods in physics Graph plotting Different types of graphs.

Preview Lesson Starter Objectives Accuracy and Precision Significant Figures Scientific Notation Using Sample Problems Direct Proportions Inverse Proportions.

Measurement Unit Unit Description: In this unit we will focus on the mathematical tools we use in science, especially chemistry – the metric system and.

CfE Advanced Higher Physics

Measuring Instruments Ruler 1 A ruler is used to measure lengths from a few cm up to 1 m. A metre rule has an accuracy of 0.1 cm (i.e. 1 mm).

Chemistry Chapter 2D Uncertainty in Measurement. Uncertainty  Represents how well a measurement was made  Science is ‘peer reviewed’  We don’t just.

What is a reading? It is the single determination of the value of an unknown quantity It is the actual reading taken in an experiment.

 An understanding of uncertainty is an important pre-requisite for students in an introductory physics course to fully comprehend scientific measurement.

Uncertainty2 Types of Uncertainties Random Uncertainties: result from the randomness of measuring instruments. They can be dealt with by making repeated.

Measurements and their Uncertainty

Physical Quantities, Units and Measurement T H E M E O N E : M E A S U R E M E N T C h a p t e r Physical Quantities A physical quantity is one that.

Uncertainty and error in measurement

Uncertainty in Measurement How would you measure 9 ml most precisely? What is the volume being measured here? What is the uncertainty measurement? For.

Measurements and Units Chemistry is a quantitative science – How much of this blue powder do I have? – How long is this test tube? – How much liquid does.

Numbers are central to Science

STUDY GUIDE: Page 11 - Q7 Page 12 - Q , 15 TEXT BOOK:

Learning Targets I can use correct numbers of significant figures and units in both measurements and calculations. I can accurately measure mass and volume.

Numbers are central to Science

Physics and Physical Measurement

Numbers are central to Science

Accuracy and Precision

Sensitivity, Accuracy And Range Of An Instrument

Errors and Uncertainties

Graphing with Uncertainties

Errors and Uncertainties

Section 2.3 Uncertainty in Data

Measuring Instruments

Mechanics Measurement

Presentation transcript:

1© Manhattan Press (H.K.) Ltd. Measurements and errors Precision and accuracy Significant figures cientific notation S cientific notation Measurements Types of errors Combination of errors

2 © Manhattan Press (H.K.) Ltd. Measurements and errors Reading: single determination of the value of an unknown quantity actual reading taken during an experiment Measurement and errors (SB p. 13) Measurement: final result of the analysis of a series of readings

3 © Manhattan Press (H.K.) Ltd. Precision and accuracy Precision: indicates the agreement among repeated measurements Measurement and errors (SB p. 13) take readings repeatedly calculate mean ( ) deviation (d) = measure the precision: by the mean deviation

4 © Manhattan Press (H.K.) Ltd. Precision and accuracy Improvement: e.g. Use a hand lens when reading the scale of a meter Use a plane mirror behind the pointer Read the scale when the pointer is directly on top of its image Measurement and errors (SB p. 14)

5 © Manhattan Press (H.K.) Ltd. Accuracy Measurement and errors (SB p. 14) Precision and accuracy A measurement is said to be accurate if it is close to the actual value. Accuracy: Indicates how correct the result is

6 © Manhattan Press (H.K.) Ltd. Accuracy Measurement and errors (SB p. 14) Precision and accuracy e.g. 1. Using a metre rule Length recorded = 34.7 cm length accurate to 0.1 cm 34.7  0.1 cm

7 © Manhattan Press (H.K.) Ltd. Accuracy Measurement and errors (SB p. 14) Precision and accuracy 2. Using a micrometre screw gauge Length recorded = 3.62 mm  mm maximum possible error Fractional error =

8 © Manhattan Press (H.K.) Ltd. Accuracy Measurement and errors (SB p. 14) Precision and accuracy 3. Percentage error Smaller the percentage error, higher the accuracy Go to More to Know 4 More to Know 4 Go to Common Error

9 © Manhattan Press (H.K.) Ltd. (a) Most significant digit: the leftmost non-zero digit (b) Least significant digit: the rightmost non-zero digit for the number without decimal point, or the rightmost digit (including zero) for the number with decimal point Significant figures: No. of digits except for zeros at the beginning Measurement and errors (SB p. 15) Significant figures

10 © Manhattan Press (H.K.) Ltd. (a) ruler of smallest division 0.1 cm Length = cm is not consistent Length = 8.1  0.1 cm Significant figures: consistent with the accuracy of the measurement Measurement and errors (SB p. 15) Significant figures

11 © Manhattan Press (H.K.) Ltd. (b) Mass of X = kg (3 sig. fig.) Mass of Y = kg (3 sig. fig.) Combined weight mg = ( ) ×9.8 = ×9.8 = N Combined weight = 4.2 N (2 sig. fig.) Measurement and errors (SB p. 15) Significant figures g (2 sig. fig.)

12 © Manhattan Press (H.K.) Ltd. No. of significant figures = no. of significant figures in the quantity which has the least no. of significant figures Measurement and errors (SB p. 16) Significant figures

13 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 16) Significant figures No. of significant figures reflects a measurement’s order of accuracy e.g. Length of classroom = 8 m (1 sig. fig.) Actual measured length = 7.5 m to 8.5 m

14 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 16) Significant figures e.g. Length of classroom = 8.0 m (2 sig. fig.) Actual measured length = 7.95 m to 8.05 m

15 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 16) Scientific notation Scientific notation: represent extremely large or extremely small numbers e.g (up to 1, 2 or 3 sig. fig?) 8.00 x 10 5 (3 sig. fig)

16 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 16) Measurements 1. Metre rule Maximum possible error = Half the smallest division =  =  0.05 cm

17 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 17) Measurements e.g. At “8 cm” mark, reading = 8.00  0.05 cm 7.95 cm – 8.05 cm 1. the first reading from “0 cm” 2. the second reading from “8 cm” Length = 8.00  0.1 cm Maximum possible error 2 reading errors

18 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 17) Measurements 2. Vernier caliper external diameter internal diameter depth of container

19 © Manhattan Press (H.K.) Ltd. 2. Vernier caliper Maximum possible error = Half the smallest division =  =  0.05 mm Measurement and errors (SB p. 17) Measurements

20 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 18) Measurements e.g cm to 1.40 cm The 7 th mark is exactly opposite a mark on the main scale. Reading = cm Reading =  cm Go to More to Know 5 More to Know 5

21 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 18) Measurements 3. Micrometre screw gauge Measure outer dimension of object up to accuracy of at least 0.01 mm

22 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 18) Measurements Length of division in main scale = 0.5 mm Each smallest division = = 0.01 mm Maximum possible error = Half the smallest division =  =  mm

23 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 19) Measurements e.g. Reading =  mm Go to More to Know 6 More to Know 6

24 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 19) Measurements 4. Computer data-logging system Data collection and storage for data processing later Interface Sensor

25 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 20) Types of errors 1. Systematic errors Systematic errors are errors in the measurement of physical quantities due to instruments, faults in the surrounding conditions or mistakes made by the observer. An experiment with small systematic error is said to be accurate.

26 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 21) Types of errors Sources of systematic error (a) Zero errors reading on instrument is not zero when it is not used Go to More to Know 7 More to Know 7

27 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 21) Types of errors (b) Personal errors of the observer From physical constrains or limitation of an individual (reaction time)

28 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 21) Types of errors (c) Errors due to instruments e.g. (i) A watch which is fast (ii) An ammeter which is used under different conditions from which it had have calibrated

29 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 21) Types of errors (d) Errors due to wrong assumption e.g. acceleration due to gravity (g) is assumed to be 9.81 m s -2 Systematic errors cannot be reduced by repeating measurements using the same method, same instrument and by the same observer.

30 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 22) Types of errors Systematic errors can reduced by taking measurements carefully, or varying conditions of measurements. More accurate Less accurate

31 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 22) Types of errors 2. Random errors Random errors are errors in a measurement made by the observer or person who takes the measurement. An experiment with small random error is said to be precise.

32 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 22) Types of errors Sources (a) Due to parallax Go to More to Know 8 More to Know 8

33 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 23) Types of errors (b) Due to temperature change Go to More to Know 9 More to Know 9 More preciseLess precise

34 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 23) Combination of errors 1. Addition or subtraction (a)If U = x + y  U =  (  x +  y) (b)If V = x - y  V =  (  x +  y)  x,  y are errors Go to Example 3 Example 3

35 © Manhattan Press (H.K.) Ltd. 2. Product If U = xyz Measurement and errors (SB p. 24) Combination of errors  x,  y,  z are errors Go to Example 4 Example 4

36 © Manhattan Press (H.K.) Ltd. 3. Quotient If U = Measurement and errors (SB p. 25) Combination of errors Go to Example 5 Example 5

37 © Manhattan Press (H.K.) Ltd. Measurement and errors (SB p. 26) Combination of errors 4. Constant power If U = x p (p is constant)

38 © Manhattan Press (H.K.) Ltd. 5. General case If U = (c, p, q, r are constant) Measurement and errors (SB p. 26) Combination of errors Go to Example 6 Example 6 Go to Example 7 Example 7

39 © Manhattan Press (H.K.) Ltd. End

40 © Manhattan Press (H.K.) Ltd. Maximum possible error If a metre rule is graduated in mm, the maximum possible error of a measurement is equal to the half of the smallest division (0.05 cm or 0.5 mm). Why should the maximum possible error of the measurement of the metal rod be 0.1 cm? For details, please refer to the Section D of Metre rule. Return to Text Measurement and errors (SB p. 14)

41 © Manhattan Press (H.K.) Ltd. A common zero error arises from using a metre rule from one end, which may be worn. It is a better practice to use the centre of the rule, instead of measuring from one end. Return to Text Measurement and errors (SB p. 15)

42 © Manhattan Press (H.K.) Ltd. Most vernier calipers will read zero when the jaws are closed, without an object in place. However, as a result of misuse or wear, the instrument may not read zero. In these cases, a zero reading error must be added or subtracted. The maximum possible error becomes ± 0.05 mm × 2 = ± 0.1 mm. Return to Text Measurement and errors (SB p. 18)

43 © Manhattan Press (H.K.) Ltd. Choice of measuring instrument When we choose a measuring instrument, we should consider: 1. its convenience to be used, 2. its precision, and 3. the range of the reading we need. Return to Text Measurement and errors (SB p. 19)

44 © Manhattan Press (H.K.) Ltd. Zero reading error and zero error Zero reading error is due to the limitation of measuring device at the “0” mark and is equal to the half of the smallest division of the device. Zero error of the device is due to the deviation from “0” value at the “0” mark. Return to Text Measurement and errors (SB p. 21)

45 © Manhattan Press (H.K.) Ltd. 1. Reading can be taken with great precision but not accurate if there is a systematic error. 2. Reading can be accurate but not precise when there is a random error. Return to Text Measurement and errors (SB p. 22)

46 © Manhattan Press (H.K.) Ltd. Random errors can be reduced by repeated measurements while systematic errors cannot. Return to Text Measurement and errors (SB p. 23)

47 © Manhattan Press (H.K.) Ltd. Q: Q: The internal diameter d 1 and the external diameter d 2 of a metal tube are d 1 = 45 ± 1 mm and d 2 = 60 ± 2 mm. What is the maximum percentage error in the total thickness of the tube when it is pressed together? Solution Measurement and errors (SB p. 24)

48 © Manhattan Press (H.K.) Ltd. Solution: Return to Text Thickness of the tube (t) = d 2 – d 1 = 60 – 45 = 15 mm Error in t (δt) = ±(δd 2 + δd 1 ) = ±2 + 1 = ±3 mm ∴ Thickness of the tube = 15 ± 3 mm ∴ Maximum percentage error in t : = 20% Measurement and errors (SB p. 24)

49 © Manhattan Press (H.K.) Ltd. Q: Q:The dimensions of a box are recorded as follows: Length ( ) = 5.0 ± 0.2 cm Width (b) = 4.0 ± 0.1 cm Height (h) = 8.0 ± 0.2 cm What is the maximum percentage error in the volume of the box? Solution Measurement and errors (SB p. 24)

50 © Manhattan Press (H.K.) Ltd. Solution: Return to Text Volume of box ( V ) = bh = 5.0  4.0  8.0 = 160 cm 3  Maximum percentage error in V: =  9% Measurement and errors (SB p. 25)

51 © Manhattan Press (H.K.) Ltd. Q: Q:The mass of a metal block is 11.5 ± 0.5 kg and its volume is ± 20 cm 3. How would you express the density of the metal? Solution Measurement and errors (SB p. 25)

52 © Manhattan Press (H.K.) Ltd. Solution: Return to Text Density (  ) Maximum fractional error in  : =  0.07 x kg cm -3 Density of metal (  ) = (1.15  0.07) x kg cm -3 Note: The error is calculated to only one sig. fig. Measurement and errors (SB p. 25)

53 © Manhattan Press (H.K.) Ltd. Q: Q:In an experiment, the external diameter D and internal diameter d of a metal tube were found to be 64 ± 2 mm and 47 ± 1 mm respectively. What is the maximum percentage error in the cross-sectional area of the metal tube as shown in the figure? Solution Measurement and errors (SB p. 26)

54 © Manhattan Press (H.K.) Ltd. Solution: Return to Text Area of the shaded region (A) Maximum error in (D + d): δ(D + d) = δD + δd = = 3 mm Maximum error in (D – d): δ(D – d) = δD + δd = = 3 mm Maximum percentage error in the cross-sectional area: Measurement and errors (SB p. 26)

55 © Manhattan Press (H.K.) Ltd. Q: Q:(a) Explain the principle of vernier calipers. (b) The figure shows a steel vernier caliper which was used to measure the diameter of a cylinder. What is the reading for the diameter? (c) Assuming that the zero reading is correct, what is the percentage error in this measurement? (d) Calculate the percentage error in the cross- sectional area of the cylinder. Solution Measurement and errors (SB p. 27)

56 © Manhattan Press (H.K.) Ltd. Solution: (a) Vernier calipers consist of two scales. 1. The main scale has 1.0 cm divided into 10 equal divisions. Size of each division = 0.10 cm 2. The vernier scale has the length of 10 divisions adding up to 0.9 cm. Size of each division = 0.09 cm  Difference in size of one division on the main scale and one division on the vernier scale is: (0.10 – 0.09) cm = 0.01 cm In the figure above, the distance between the 1.2 cm mark on the main scale and the 0 mark on the vernier scale is 3  0.01 = 0.03 cm.  The vernier reading is 1.23 cm. Measurement and errors (SB p. 27)

57 © Manhattan Press (H.K.) Ltd. Solution (cont’d) : Return to Text (b) From the figure, diameter of the cylinder (d) = 2.53 cm (c) Error in d (δd) = cm ∴ Percentage error: (d) Cross-sectional area (A) = ∴ Percentage error: Measurement and errors (SB p. 27)