Presentation is loading. Please wait.

Presentation is loading. Please wait.

Welcome to Regents Physics! Mrs. Patterson Course Introduction.

Published byAlan Stanley Fitzgerald Modified over 8 years ago

Similar presentations

Presentation on theme: "Welcome to Regents Physics! Mrs. Patterson Course Introduction."— Presentation transcript:

1

2 Welcome to Regents Physics! Mrs. Patterson Course Introduction

3 What is Physics? Physics is the study of the physical or natural world. It is the most basic science… The study of motion, forces, energy, matter, heat, sound, light, waves, and the composition of matter.

4 What will we investigate? There are 5 basic units in physics: -Mechanics -Energy and Work -Electricity and Magnetism -Waves -Modern Physics

5 Success Skills Conceptual (Why does this happen?) Problem Solving Data Analysis Lab design and Reporting Self-guidance Observation

6 SI (System International) Base Units: Fundamental units (also called base units) Length = meter (m) Mass = kilogram (kg) Time = seconds (s) A base unit is independent of other units.

7 Derived Units: Derived Units are combinations of fundamental units. Examples: Meters per second (m/s) used to measure _______? Kilogram * meter squared per second (kg*m 2 /s) is used to measure energy (the joule).

8 Common Prefixes Look at your reference tables – front page, bottom left corner, “Prefixes for Powers of 10” Example: 1 ns = 1 x 10 -9 s 1 nm = 1 x 10 -9 m We can make conversion factors!

9 Practice: How many seconds are in 1 picosecond? Answer: 1 ps = 1 x 10 -12 s What if we turn the question around? How many picoseconds are in one second? Answer: (1 ps/ 1x10 -12 s) = (1x10 12 ps/s)

10 Getting Conversion Factors from Prefix Table We often need to change from one unit to another… we can do this using conversion factors. Here’s the key…Units are treated as mathematical factors, and can be divided out.

11 Let’s do it! Let’s convert 365 meters to km. ________ Why can’t I just move the decimal place? You can, but only if you are going from one metric unit to another. What if you need to convert a derived unit, like km/hr to m/s?

12 Factor-Label method a.k.a Dimensional Analysis FLM is a technique used to convert from one unit to another using appropriate conversion factors.

13 Let’s do it! Let’s convert 100 km/hr to m/s.

14 Precision Precision is the degree of exactness to which the measurement of a quantity can be reproduced. Precision is linked to significant figures: Significant figures includes all known digits plus one estimated digit.

15 Accuracy Accuracy is the extent to which a measured value agrees with the standard or accepted value. Accuracy is measured using percent error. % error = measured value – accepted value x 100 accepted value precision and accuracy

16 The Four Sig Fig Rules:

17 Rule #1: Non-zero digits are always significant. Example: How many sig figs in 2.735 m? Answer: Four sig figs

18 Rule #2: Zeros between two other significant digits are significant. Example: How many sig figs in the value 202.03 kg? Answer: 5 sig figs

19 Rule #3: All final zeros after the decimal point are significant. Examples: - 0.002 kg has one sig fig - 0.020 kg has two sig figs - 0.200 kg has three sig figs

20 Rule #4: Zeros used solely for spacing the decimal point are not significant (unless a decimal point is present) Examples: - 63400 s has 3 sig figs - 63400. has 5 sig figs

21 Try these examples: 1) 47.90 _____6) 50.0 ____ 2) 235.45 _____7) 0.0204 ____ 3) 1000 _____8) 1.30000 ____ 4) 0.0008 _____9) 12.004 ____ 5) 70. _____10) 500.009 ____

22 Adding and Subtracting with Significant Figures The Rule: Perform the operation, then round off to the least precise value involved. Examples:412.57 + 35 = ________ 23.941 – 12.79 = ________ 1309.75 – 1000 = ________

23 Multiplying and Dividing with Significant Figures The Rule: Perform the operation, then round off the answer to the same number of significant figures and the factor with the fewest sig figs. Examples:24.0 x 30.00 = _______ 45.79/2 = _______100./4.0 = _______ 100./3 = _______7652 x.0040 = _______

24 Scientific Notation Numbers expressed as: M x 10 n Where: ”M” is the “mantissa”, a number between 1 and 10. The mantissa must contain the correct number of sig figs. “n” is the exponent, an integer

25 Let’s Practice Express 0.0000578 in scientific notation. ________________ Express 2900 in scientific notation. ________________ Express 5.409 x 10 7 as an integer. _______________ Express 8.92 x 10 -5 as an integer. ________________

26 One more thing… Use your calculator to perform the following calculation: (3.45 x 10 12 kg) x (4.3 x 10 -2 m/s) Express your answer with the correct number of significant figures, and with the correct units. ____________________

27 “Order of Magnitude” “Order of Magnitude” is the power of 10 closest to a numerical quantity’s actual value.Powers videopowers demoPowers videopowers demo Examples:powers demopowers demo 1693 kg has an order of magnitude of 10 3 kg. 8534 kg has an order of magnitude of 10 4 kg.

28 Estimating Some questions will pop up from time to time such as: How tall is a door? Or how thick is a piece of paper? The choices will force you to put all answers in one unit that makes sense. Let’s practice:

29 How tall is a physics student? a.1 x 10 -2 kmc. 1 x 10 2 m b.1 x 10 2 cmd. 1 x 10 4 mm The answer is “b”. This may seem a little strange, but we are estimating here. If we put all the answers into meters, we see choice “a” is 10 m, “b” is 1 m, “c” is 100 m, and “d” is 10 m. Although most students are closer to 2 m, the only logical choice is “b”.

Download ppt "Welcome to Regents Physics! Mrs. Patterson Course Introduction."

Similar presentations

Homework Answers m/s m g/L cm3

Homework Answers m/s m g/L cm3
Chapter 2 – Scientific Measurement

Chapter 2 – Scientific Measurement
SECTION 2-3. Objectives 1. Distinguish between accuracy and precision 2. Determine the number of significant figures in measurements 3. Perform mathematical.

SECTION 2-3. Objectives 1. Distinguish between accuracy and precision 2. Determine the number of significant figures in measurements 3. Perform mathematical.
Unit 1 Part 2: Measurement

Unit 1 Part 2: Measurement
Uncertainty in Measurements

Uncertainty in Measurements
The Fundamental Tools Of Science. Units Some fundamental measurements in all of science: Length Time Mass Many others are combinations of these: Energy,

The Fundamental Tools Of Science. Units Some fundamental measurements in all of science: Length Time Mass Many others are combinations of these: Energy,
Measurements and Calculations Chapter 2. Units of Measurement Measurements involve NUMBER and UNIT Represent a quantity: has magnitude, size, or amount.

Measurements and Calculations Chapter 2. Units of Measurement Measurements involve NUMBER and UNIT Represent a quantity: has magnitude, size, or amount.
Significant Figures.  All measurements are inaccurate  Precision of measuring device  Human error  Faulty technique.

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

Scientific Measurement
1.2 Measurement in Experiments

1.2 Measurement in Experiments
Measurements and Calculations

Measurements and Calculations
Using and Expressing Measurements

Using and Expressing Measurements
Units and Standards. In science, numbers aren’t just numbers. They need a unit. We use standards for this unit. A standard is: a basis for comparison.

Units and Standards. In science, numbers aren’t just numbers. They need a unit. We use standards for this unit. A standard is: a basis for comparison.
1.2 Measurements and Uncertainties. 1.2.1 State the fundamental units in the SI system In science, numbers aren’t just numbers. They need a unit. We use.

1.2 Measurements and Uncertainties State the fundamental units in the SI system In science, numbers aren’t just numbers. They need a unit. We use.
Data analysis (chapter 2) SI units and the metric system ▫Base units  Time (sec)  Length (m)  Mass (kg)  Temperature (Kelvin)  Derived base units.

Data analysis (chapter 2) SI units and the metric system ▫Base units  Time (sec)  Length (m)  Mass (kg)  Temperature (Kelvin)  Derived base units.
1-1 What is Physics?  What does Physics mean? Physics is from the Greek root physik (science of nature) and Latin physica (natural science).  It’s.

1-1 What is Physics?  What does Physics mean? "Physics" is from the Greek root physik (science of nature) and Latin physica (natural science).  It’s.
Accuracy, Precision, Signficant Digits and Scientific Notation.

Accuracy, Precision, Signficant Digits and Scientific Notation.
SCIENTIFIC MEASUREMENT  CHEM IH: CHAPTER 3. What is Scientific Notation?  Scientific notation is a way of expressing really big numbers or really small.

SCIENTIFIC MEASUREMENT  CHEM IH: CHAPTER 3. What is Scientific Notation?  Scientific notation is a way of expressing really big numbers or really small.
IN THE CHEMISTRY SECTION OF YOUR NOTEBOOK, TAKE CORNELL STYLE NOTES OVER THE INFORMATION PRESENTED IN THE FOLLOWING SLIDES. Measurements in Chemistry Aug.

IN THE CHEMISTRY SECTION OF YOUR NOTEBOOK, TAKE CORNELL STYLE NOTES OVER THE INFORMATION PRESENTED IN THE FOLLOWING SLIDES. Measurements in Chemistry Aug.
Unit 2. Measurement This lesson is 8 days long.

Unit 2. Measurement This lesson is 8 days long.

Similar presentations

Ads by Google