3 --graphing

Rules for Calculating with
Significant Figures

Rules for Rounding in Calculations

Rules for Rounding in
Calculations

Objectives
• Interpret data in tables and graphs, and
recognize equations that summarize data.

• Distinguish between conventions for
abbreviating units and quantities.

• Use dimensional analysis to check the
validity of equations.

• Perform order-of-magnitude calculations.

Mathematics and Physics

• Tables, graphs, and equations can make data
easier to understand.

• For example, consider an experiment to test
Galileo’s hypothesis that all objects fall at the
same rate in the absence of air resistance.
– In this experiment, a table-tennis ball and a golf ball are dropped
in a vacuum.
– The results are recorded as a set of numbers corresponding to
the times of the fall and the distance each ball falls.
– A convenient way to organize the data is to form a table, as
shown on the next slide.

Data from Dropped-Ball
Experiment

A clear trend can be seen in the data. The more time that
passes after each ball is dropped, the farther the ball falls.

Graph from Dropped-Ball
Experiment
One method for analyzing the data is to construct a
graph of the distance the balls have fallen versus the
elapsed time since they were released.

The shape of the
graph provides
information about
the relationship
between time and
distance.

Physics Equations
• Physicists use equations to describe measured or
predicted relationships between physical quantities.

• Variables and other specific quantities are abbreviated
with letters that are boldfaced or italicized.

• Units are abbreviated with regular letters, sometimes
called roman letters.

• Two tools for evaluating physics equations are
dimensional analysis and order-of-magnitude
estimates.

Equation from Dropped-Ball
Experiment
• We can use the following equation to describe the relationship
between the variables in the dropped-ball experiment:
(change in position in meters) = 4.9 × (time in seconds)2
• With symbols, the word equation above can be written as follows :
∆y = 4.9(∆t)2
• The Greek letter ∆ (delta) means “change in.” The abbreviation
∆y indicates the vertical change in a ball’s position from its
starting point, and ∆t indicates the time elapsed.

• This equation allows you to reproduce the graph and make
predictions about the change in position for any time.

Standardized Test Prep
Chapter 1
Multiple Choice
1. What area of physics deals with the
subjects
of heat and temperature?
A. mechanics
B. thermodynamics
C. electrodynamics
D. quantum mechanics

Chapter 1
Multiple Choice, continued

2. What area of physics deals with the
behavior of
subatomic particles?
F. mechanics
G. thermodynamics
H. electrodynamics
J. quantum mechanics

Chapter 1
3. What term describes a set of particles or
interacting components considered to be
a distinct physical entity for the purpose of
study?
A. system
B. model
C. hypothesis
D. controlled experiment

Chapter 1
4. What is the SI base unit for length?
F. inch
G. foot
H. meter
J. kilometer

Chapter 1
Short Response
13. Determine the number of significant
figures
in each of the following measurements.
A. 0.0057 kg
B. 5.70 g
C. 6070 m
D. 6.070 × 103 m

Chapter 1
Short Response
13. Determine the number of significant
figures
in each of the following measurements.
A. 0.0057 kg
B. 5.70 g
C. 6070 m
D. 6.070 × 103 m

Answers:
A. 2; B. 3; C. 3; D. 4

Chapter 1
Short Response, continued
14. Calculate the following sum, and
express the answer in meters. Follow the
rules for significant figures.

(25.873 km) + (1024 m) + (3.0 × 102 cm)

Chapter 1
Short Response, continued
14. Calculate the following sum, and
express the answer in meters. Follow the
rules for significant figures.

(25.873 km) + (1024 m) + (3.0 × 102 cm)

Answer: 26 897 m

3 --graphing

More Related Content

What's hot (19)

Similar to 3 --graphing (20)

Recently uploaded (20)

3 --graphing