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.
Just because a device works does not mean it is accurate. It must be CALIBRATED. Calibrate: (1) mark an instrument with a standard scale of readings. (2) correlate the readings of an instrument with those of a standard in order to check the instrument's accuracy.
Kitchen microwaves baffle Australian space scientistsbaffle
Mr. Sapone, do I round this? All Measurements in Science have Error associated with them. 1) Systematic 2) Random 3) Screw-Ups (e.g. parallax) Calculators result in errors since they assume all numbers are known. Measured Number: the length of a desk. Known Number: the number of desks in this room. All Measurements in Science have Error associated with them. 1) Systematic 2) Random 3) Screw-Ups (e.g. parallax) Calculators result in errors since they assume all numbers are known. Measured Number: the length of a desk. Known Number: the number of desks in this room × 10 9 years ± 1% 4.54 ± 0.05 billion years Age of the Earth via Radiometric Dating Uncertainty % Uncertainty
Suppose I ask you to measure the volume of a rectangular solid in cm 3 with a ruler and you come up with the following dimensions. 2.74cm 2.23cm 2.68cm 2.74cm x 2.23cm x2.68cm = cm 3 Your three measurements have three significant figures but your result has five. Your measurements are only given to a hundredth of a centimeter cubed but your answer has the precision of a thousandth of a centimeter cubed, How can this be? A measurement cannot be more accurate than your measuring devices!
Reading a Meter Stick / Ruler
One Uncertain Digit 17.6 ml Certain Numbers Uncertain Digit We know for certain the water lies between 17 and 18ml.
You should report one uncertain Digit
What is the length? We can see the markings between cm We can’t see the markings between the.6-.7 We must guess between the.6 and.7 mark We record 1.67 cm as our measurement The last digit 7 is estimated...stop there
Report these measurements!
Sigfig Rules: 1.ALL non-zero numbers (1,2,3,4,5,6,7,8,9) are ALWAYS significant 2.ALL zeroes between non-zero numbers are ALWAYS significant. 3. ALL zeroes which are SIMULTANEOUSLY to the right of the decimal point AND at the end of the number are ALWAYS significant. 4. ALL zeroes which are to the left of a written decimal point and are in a number ≥ 10 are ALWAYS significant. Sometimes writing the number in scientific notation helps determine the number of significant digits. Number# of SigFigsRule(s) 48, ,000,
Sigfig Rules: 1.ALL non-zero numbers (1,2,3,4,5,6,7,8,9) are ALWAYS significant 2.ALL zeroes between non-zero numbers are ALWAYS significant. 3. ALL zeroes which are SIMULTANEOUSLY to the right of the decimal point AND at the end of the number are ALWAYS significant. 4. ALL zeroes which are to the left of a written decimal point and are in a number ≥ 10 are ALWAYS significant. Sometimes writing the number in scientific notation helps determine the number of significant digits. Number# of SigFigsRule(s) 48, ,2, , , ,2,3,4 3,000, ,3,4
Sig Fig Arithmetic Products and Quotients When multiplying or dividing measured numbers, the answer cannot have more significant figures than the term with the least number of significant figures. Example: Calculator: 25.2 x = Corrected Answer: 64.1 Addition and Subtraction In addition and subtraction the number of decimal places is what is important. The answer cannot have more decimal places than the term with the least number. Example: Calculator: = Corrected Answer: SigFig Problems = Calculator: Answer: = Calculator: Answer: 2.5 x 3.42 Calculator: Answer: 3.10 x Calculator: Answer: (4.52 x 10¯ 4 ) ÷ (3.980 x 10¯ 6 ) Calculator: Answer: The number of tables in this room times the width of my desk: Calculator: Answer:
Sig Fig Arithmetic Products and Quotients When multiplying or dividing measured numbers, the answer cannot have more significant figures than the term with the least number of significant figures. Example: Calculator: 25.2 x = Corrected Answer: 64.1 Addition and Subtraction In addition and subtraction the number of decimal places is what is important. The answer cannot have more decimal places than the term with the least number. Example: Calculator: = Corrected Answer: SigFig Problems = Calculator: Answer: = Calculator: Answer: 2.5 x 3.42 Calculator: Answer: 3.10 x Calculator: Answer: (4.52 x 10¯ 4 ) ÷ (3.980 x 10¯ 6 ) Calculator: Answer: The number of tables in this room times the width of my desk: Calculator: Answer:
Statistical Analysis In science there is no such thing as a perfect measurement. ALL MEASUREMENTS HAVE ERROR. Any result given without a consideration of error is useless! Standard Deviation is a measure of how spread out numbers are. Its symbol is σ (the Greek letter sigma) The formula is easy: it is the square root of the Variance divided by the mean minus one. The variance is the average of the squared differences from the Mean.
Standard Deviation Curve
The average height for adult men in the United States is about 70 inches, with a standard deviation of around 3 inches. 68% have a height within 3 inches of the mean (67– 73 inches) 95% have a height within 6 inches of the mean (64– 76 inches
Standard Deviation (sample) 1.Calculate the mean or average of each data set. To do this, add up all the numbers in a data set and divide by the total number of pieces of data. 2.Get the deviance of each piece of data by subtracting the mean from each number. 3. Square each of the deviations. 4.Add up all of the squared deviations. 5.Divide this number by one less than the number of items in the data set. 6.Calculate the square root of the resulting value. This is the sample standard deviation. x i are individual values u is the mean n is total number of data points
Standard Deviation Problem Show in Excel
Percent Error How to Calculate it. ERROR!
Error = Measured Value – Accepted Value Science references list the density of aluminum as being 2.7g/cm 3. Suppose you perform an experiment and your results show aluminum having a density of 2.8g/cm 3 Aluminum 2.7g/cm 3 Aluminum 2.8g/cm 3 Accepted Measured Error = 2.8g/cm 3 – 2.7g/cm 3 = 0.1g/cm 3 Error can be positive or negative but sometimes it isn’t very useful!
If you have a 10ft long table (accepted value) and your results state it is 5ft long (measured value) your error is 5ft. Goal line to Goal line, a football field is 300 feet (known value). If you measure its length and come up with 290ft your error is 10ft. Even though the first measurement was off by only 5ft, the second measurement which is off by 10ft is much better. In terms of percentages, the first measurement was off by 50% of the value whereas the second was only off by 3.3%. Error is 5ft out of 10 Error is 10ft but out of 300ft You can have an error of a million miles if you were measuring the distance to the sun but it would only be a 1-2% error because the sun is 93 million miles away!
Aluminum has an accepted value of 2.7g/cm 3.Suppose you perform an experiment and your results show aluminum as having a density of 2.8g/cm 3. What is your percent error? Get a difference. Compare to Accepted value. Multiply by 100.
A student measured the temperature of boiling water and got an experimental reading of 97.5°C. Calculate the % error. Get a difference. Compare to Accepted value. Multiply by 100.