Physics 1000 Lecture Notes 001/002 PDF

Summary

These lecture notes cover basic concepts in physics, focusing on physical standards and units. The material explores the fundamental principles and concepts related to units and their use in measurements. There are homework questions included.

Full Transcript

Physics 1000 –
001/002
Introduction – Physical Standards and Units
 Individual Lecture Sequence
Review previous homework/exam

New material

Read chapter to reinforce lecture

Homework (Blackboard)
What is Physics?
 What is Physics?
Physics is the study of the physical world
 What is Physics?
Physics is the study of the physical world

This is done by finding patterns, and attempting to predict future behavior
 Scientific Laws
When enough experiments have become universally accepted within the
scientific community, it becomes known as a law
Scientific law, physical law, and law of nature are all used interchangeably
Even long-held laws can be disproven if new evidence is presented
Experimental results can never prove an idea, they can only disprove it

A scientific law must be testable
It must make predictions that can be tested and possibly disproven
 Physical Standards and Units
When measuring something (distance, time), it helps to have a common frame of reference

Units are standards we agree on in order to measure other things consistently

Different systems use different units for measuring the same quantity
For example, the meter and the foot both measure distance

This class will primarily use SI units
Le Système International d’Unités, or International System of Units
As units get more complex in physics, the US system becomes harder to use
 Area Unit Comparison (US/SI)
Area is a distance multiplied by another distance
Acre
Traditionally defined as the area of one chain (66 feet) by one furlong (10 chains)
66’ x 660’ = 39600 square feet

Square kilometer
One kilometer by one kilometer
1000 meters by 1000 meters
1,000,000 square meters
 Units
Quantity Unit (SI) Unit (US) SI to US US to SI
Length Meter (m) Foot (ft) Multiply by 3.281 Divide by 3.281
Mass Kilogram (kg) Pound (lb) Multiply by 2.205 Divide by 2.205
Time Second (s) Second (s)
Force Newton (N) Pound force (lbf) Divide by 4.448 Multiply by 4.448
Energy Joule (J) Foot-pound (ft*lb) Divide by 1.356 Multiply by 1.356
Current Ampere (A) Ampere (A)
Temperature Kelvin (K) Degree Fahrenheit (°F)
 Metric Prefixes
Prefix Symbol Short Form Value Common Name
peta- P 10^15 1,000,000,000,000,000 quadrillion
tera- T 10^12 1,000,000,000,000 trillion
giga- G 10^9 1,000,000,000 billion
mega- M 10^6 1,000,000 million
kilo- h 10^3 1,000 thousand
10^0 1 one
centi- c 10^-2 0.01 hundredth
milli- m 10^-3 0.001 thousandth
micro- μ 10^-6 0.000 001 millionth
nano- n 10^-9 0.000 000 001 billionth
pico- p 10^-12 0.000 000 000 001 trillionth
femto- f 10^-15 0.000 000 000 000 001 quadrillionth
 Scientific Notation
A way to express very large (or very small) numbers conveniently
Written as , where n is an integer and
400 becomes
1024 becomes
80,000,000,000 becomes
0.000000006 becomes

Order of magnitude is a concept used to discuss the scale of numbers in
relation to one another
Two numbers are "within an order of magnitude" of each other if their ratio is between
1/10 and 10
3,000,000 (and 30 () are 5 orders of magnitude apart
 Homework

Read Chapter 1
Questions: 3, 5, 9, 10, 18, 19, 23, 26, 27, 29