Significant Figures Mr. Nelson – 2008. Uncertainty The pin is ½ way between the smallest lines on the ruler – what do we do? We have to IMAGINE that there.

Slides:

Advertisements

Similar presentations

Significant Figures Mr. Nelson – 2010.

Advertisements

1.2 Measurements in Experiments

UNIT: Chemistry and Measurement

Ch. 3.1 – Measurements and Their Uncertainty

Uncertainty in Measurements

Measurements: Every measurement has UNITS.

SIGNIFICANT FIGURES.

Significant Figures There are two kinds of numbers in the world: Exact

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

Significant Figures.  All measurements are inaccurate  Precision of measuring device  Human error  Faulty technique.

Significant (Measured) Digits Measuring with Precision.

“A man with a watch knows what time it is. A man with two watches is never sure” (Unknown)

Precision and Accuracy Uncertainty in Measurements.

IB Chem I Uncertainty in Measurement Significant Figures.

Uncertainty in Measurement Professor Bob Kaplan University Department of Science 1.

Using and Expressing Measurements

Chapter 1.5 Uncertainty in Measurement. Exact Numbers Values that are known exactly Numbers obtained from counting The number 1 in conversions Exactly.

Section 2.3 Measurement Reliability. Accuracy Term used with uncertainties Measure of how closely individual measurements agree with the correct or true.

Uncertainty in Measurements: Using Significant Figures & Scientific Notation Unit 1 Scientific Processes Steinbrink.

MEASUREMENTS. What is the difference between these two measurement rulers? Should we record the same number for each scale reading?

Working with Significant Figures. Exact Numbers Some numbers are exact, either because: We count them (there are 14 elephants) By definition (1 inch =

Uncertainty in Measurements and Significant Figures Group 4 Period 1.

A measured value Number and unit Example 6 ft.. Accuracy How close you measure or hit a true value or target.

SIGNIFICANT FIGURES. ACCURACY VS. PRECISION  In labs, we are concerned by how “correct” our measurements are  They can be accurate and precise  Accurate:

How many significant figures?

Measurement book reference p Accuracy  The accuracy of the measurement refers to how close the measured value is to the true or accepted value.

The Importance of measurement Scientific Notation.

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

Chapter 5, Part 2 Measurements and Calculations. 5.4 Uncertainty in Measurement Reported data- the last unit is uncertain; it has been estimated. Uncertainty.

Significant Figures Chemistry. Exact vs approximate There are 2 kinds of numbers: 1.Exact: the amount of money in your account. Known with certainty.

Unit 1 Chapter 2. Common SI Units SI System is set-up so it is easy to move from one unit to another.

Uncertainty in Measurement Accuracy, Precision, Error and Significant Figures.

Significant Figures. Accuracy vs. Precision Percentage Error.

Uncertainty in Measurement

Bellringer 9 / 9 / 2009 Rephrase the following quotation in your own words “There is nothing so far removed from us to be beyond our reach, or so far hidden.

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

Accuracy and Precision Accuracy and Precision A MEASURE of your SUCCESS!

V. Limits of Measurement 1. Accuracy and Precision.

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

V. Limits of Measurement 1. Accuracy and Precision.

All measurements are subject to uncertainties. All instruments used are influenced by external circumstances, and the accuracy of a measurement may be.

1 Significant Figures (Sig Figs) Quantity includes all known digits plus one estimated digit = last digit of # Indicates precision 500 vs

Significant Figures and Scientific Notation. Physics 11 In both physics 11 and physics 12, we use significant figures in our calculations. On tests, assignments,

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

Significant Digits or Significant Figures. WHY??? The number of significant figures in a measurement is equal to the number of digits that are known with.

Significant Figures.

Significant Figures Chemistry I. Significant Figures The numbers reported in a measurement are limited by the measuring tool Significant figures in a.

 1. Nonzero integers. Nonzero integers always count as significant figures. For example, the number 1457 has four nonzero integers, all of which count.

Section 5.2 Uncertainty in Measurement and Significant Figures 1.To learn how uncertainty in a measurement arises 2.To learn to indicate a measurement’s.

Significant Figures When we take measurements or make calculations, we do so with a certain precision. This precision is determined by the instrument we.

How big is the beetle? Measure between the head and the tail!

Objectives To learn how uncertainty in a measurement arises

BELLWORK 9/13/16 1 Tm = 1012 m 1mm = 10-3 m 1Mm = 106 m

Significant Digits or Significant Figures

Measurement Schmeasurement

Measurement Schmeasurement

BELLWORK 9/01/17 Complete #’s 1, 12, 22, and 34 in the new Virginia Bellwork Packet.

Math Toolkit ACCURACY, PRECISION & ERROR.

Section 3-2 Uncertainty in Measurements

Science and Measurement

Measurement book reference p

BELLWORK 9/2/15 How does a scientist reduce the frequency of human error and minimize a lack of accuracy? A. Take repeated measurements B. Use the same.

Section 2.3 Uncertainty in Data

Uncertainty and Significant Figures

Uncertainty and Significant Figures

Accuracy vs. Precision & Significant Figures

Accuracy and Precision

Significant Figures.

Uncertainty and Significant Figures

Significant Figures (Sig figs)

Presentation transcript:

Significant Figures Mr. Nelson – 2008

Uncertainty The pin is ½ way between the smallest lines on the ruler – what do we do? We have to IMAGINE that there are 10 more spaces between those smallest lines and ESTIMATE We can see it is between the 2.8 and 2.9 mark, but… We can estimate visually that it is probably around 2.85 cm

Uncertainty We can estimate visually that it is probably around 2.85 cm This is just a visual estimation though – that last number is uncertain – it could just as easily be 2.84 or 2.86 cm!! Note that the first two numbers in that measurement are always the same – just the last number, the estimated number, is uncertain

Rules for uncertainty When making a measurement, record all numbers that are known, plus ONE uncertain digit. These numbers (all certain numbers + 1 uncertain number) are called significant figures

Significant Figures It is important to know the degree of uncertainty in the final result in science Any final result is only as certain as the least precise measuring device There are rules to follow when figuring out sig figs

Sig Fig Rules ****Nonzero integers are always significant Example: 1457 has four nonzero integers and four significant figures When 0’s are between sig. figs., 0’s are always significant Example: 101 has 3 sig. fig. and has 5 sig. fig 2. When the measurement is a whole number ending with 0’s, the 0’s are never significant Example: 210 has 2 sig. figs. and 71,000,000 also has 2 sig. figs

3. When the measurement is less than a whole number, the 0’s between the decimal and other significant numbers are never significant (they are place holders). Example:.0021 has 2 sig. fig. and has 3 sig. fig. 4. When the measurement is less than a whole number and the 0’s fall after the other significant numbers, the 0’s are always significant Example:.310 has 3 sig. fig. and.3400 has 4 sig. fig

5. When the measurement is less than a whole and there is a 0 to the left of the decimal, the 0 is not significant. Example: 0.02 has only 1 sig. fig. and has 3 sig. fig. 6. When the measurement is a whole number but ends with 0’s to the right of the decimal, the 0’s are significant. Example: 20.0 has 3 sig. fig., has 8 sig. fig.

Example Problems Give the # of significant figures in each measurement: 1. A sample of orange juice contains g of vitamin C 2. A forensic chemist in a crime lab weighs a single hair and records its mass as g 3. The distance between two points is found to be 5.030x10 3 ft.

Rounding Rules 1. If the number you want to “round off” is less than 5, then the preceding digit stays the same 2. If that number is more than 5, round the preceding number UP. 3. ALWAYS wait till the end to round off numbers – don’t round as you go or your # might be off!

Sig Figs in Calculations 1. For multiplication and division: the number of sig figs in your answer is the same as the SMALLEST number of sig figs (total) in the problem (this is the limiting measurement). Example: 4.56 x 1.4 =  how do we do sig figs? Example: x 1.0 x 100 = ?

2. For addition or subtraction: the limiting number is the one with the smallest number of decimal places. Example: = ? Example: – 0.1 = ? Note: for multiplication & division, sig figs are counted. For addition & subtraction, the decimal places are counted.

Precision vs. Accuracy Accuracy is telling the truth... Precision is telling the same story over and over again. Accuracy: the degree of conformity with “the truth”

Precision & accuracy, cont’d. Precision: the quality, uniformity, or reproducibility of a measurement. Note that this has nothing to do with how “true” the result is, just whether or not you can repeat it exactly.

Precision vs. Accuracy, cont’d. Accuracy with precision: the person shooting these arrows has performed both accurately (on the bull’s eye) and precisely (over and over)

Precision vs. Accuracy, cont’d. Precision with blunder – because all of your other results are accurate and precise, it is easy to see the “bad” data and toss it out. Accuracy with blunder – although this is accurate, it is not as precise – it may be easier to overlook the error