GP1-1STQ-MODULE-WEEK 1 PDF Philippine Christian University Physics Module

Summary

This is a physics module for undergraduate students at Philippine Christian University. It covers topics like vectors, units, physical quantities, and common errors in physics.

Full Transcript

Philippine Christian University
Sampaloc 1, Dasmariñas City, Cavite 4114
SENIOR HIGH SCHOOL
S.Y. 2024-2025

MODULE IN GENERAL PHYSICS 1(GRADE 12)
QUARTER 1 - WEEK 1 (AUGUST 5-9, 2024)

LESSON 1: VECTORS, UNITS, PHYSICAL QUANTITIES AND COMMON ERRORS

Overview

Physics, being one of the academic disciplines, is commonly known as a branch of science that deals with the
study of matter and its motion—including concepts such as force, energy mass and charge. Sometimes
synonymous with philosophy, chemistry and even certain branches of mathematics and biology during the last
two millennia, physics emerged as a modern science in the 17th century and these disciplines are now generally
distinct, although the boundaries remain difficult to define. Today, physics is a broad and highly developed
subject. Most physicists focus their study on theoretical and experimental research for them to develop new
theories that will lead to the discovery of new phenomena. Despite important discoveries during the last four
centuries, there are a number of open questions in physics, and many areas of active research. Although
physics encompasses a wide variety of phenomena, all competent physicists are familiar with the basic theories
of classical mechanics, electromagnetism, relativity, thermodynamics, and quantum mechanics. Each of these
theories has been tested in numerous experiments and proven to be an accurate model of nature within its
domain of validity.

Schön, N. (2020, October 29). 4 Physics concepts everyone should know. Brainscape Academy. https://www.brainscape.com/academy/physics-concepts-you-should-know/

Disclaimer: This module is adapted and modified from the source materials listed in the references list. This is an
exclusive property of Philippine Christian University-Dasmariñas SHS and is provided only to enrolled students for
their academic use. This module is provided for free by the school through softcopy and/or printed media.
Reproduction of this module without official permission is prohibited.
1
 Course Learning Outcome
Explain the different properties and basic concepts of Kinematics, its measurement, calculations and
interpretation of how it applies in one and two dimensions.
Analyze the effects of different forces in motion such as gravitational, normal, and frictional force to
utilize the free-body diagrams to represent forces and solve problems involving the net force and
acceleration of objects.
Define and explain Newton's Law of Universal Gravitation and how the gravitational force between
two masses governs the motion of celestial bodies.
Apply knowledge and understanding of kinematics and the different laws of motion to systematically
predict resulting motion in different problem-solving activities.
Analyze the properties and behavior of waves including wavelength, frequency, amplitude, and speed
to distinguish between different types of waves (mechanical, electromagnetic, transverse, and
longitudinal) and how it transfers energy.
Illustrate the parts and structure of the different types of waves.
Demonstrate knowledge and comprehension of thermodynamics by citing and giving examples of how
it is observed in real life scenarios.

Lesson Objectives
At the end of this lesson, you are expected to:
Solve measurement problems involving conversion of units, expression of measurements in scientific
notation;
Differentiate accuracy from precision;
Differentiate random errors from systematic errors;
Estimate errors from multiple measurements of a physical quantity using variance;
Differentiate vector and scalar quantities;
Rewrite a vector in component form;
Define physics as a discipline;
Compare and explain the difference between standard and derived units; and
Reflect on their learning on how to interpret and present data.

You may copy and paste the link then enter to the search engine to play video/s:
https://www.youtube.com/watch?v=rcDXQ-5H8mk

Disclaimer: This module is adapted and modified from the source materials listed in the references list. This is an
exclusive property of Philippine Christian University-Dasmariñas SHS and is provided only to enrolled students for
their academic use. This module is provided for free by the school through softcopy and/or printed media.
Reproduction of this module without official permission is prohibited.
2
 Essential Questions:

Why is proper use of instruments
important in measurement?
What are the main differences between
scalar and vector quantities?
How does deeper understanding in speed,
distance, and time affect our perspective
towards the world and our daily lives?

Test Yourself

DIRECTIONS: Fill in the missing boxes to complete the table that shows the different symbols for each units.

Unit Symbol
Meter
Km
gram
Kilogram
Second
C
K
Ampere
mol
Candela

Disclaimer: This module is adapted and modified from the source materials listed in the references list. This is an
exclusive property of Philippine Christian University-Dasmariñas SHS and is provided only to enrolled students for
their academic use. This module is provided for free by the school through softcopy and/or printed media.
Reproduction of this module without official permission is prohibited.
3
 Study These Terms
On this module, you will encounter these important terms:
Measurement - is the determination of size or magnitude of something.
S.I. Unit - or the International System of Units is the modern form of the metric system. It is the only
system of measurement with an official status in nearly every country in the world.
SI base units - are the standard units of measurement defined by the International System of Units (SI)
for the seven base quantities of what is now known as the International System of Quantities

F. (2021, August 25). Understanding base quantities and derived quantities. Blogspot. http://fizik-

fizik.blogspot.com/2009/11/understanding-base-quantities-and.html?m=1
Derived unit- is a SI unit of measurement comprised of a combination of the seven base units.
Conversion of units- is the conversion between different units of measurement for the same quantity,
typically through multiplicative conversion factors.
Rounding-off means- reducing the digits in a number while trying to keep its value similar. However
the result is less accurate, but easier to use.
Random errors- arise from unknown and unpredictable variations in condition.
Systematic errors- are errors which tend to shift all measurements in a systematic way so their mean
value is displaced.

Lesson Proper

What is PHYSICS?
Physics is the branch of science concerned with the nature and properties of non-living matter and
energy that are not dealt with by chemistry or biology, and the fundamental laws of the material universe. As
such, it is a huge and diverse area of study.
In order to make sense of it, scientists have focused their attention on one or two smaller areas of the
discipline. This allows them to become experts in that narrow field, without getting bogged down in the sheer
volume of knowledge that exists regarding the natural world.

THE FIELDS OF PHYSICS

1. Classical Physics
Before the turn of the 19th century, physics concentrated on the study of mechanics, light, sound
and wave motion, heat and thermodynamics, and electromagnetism. Classical physics are fields
that were studied before 1900.
(Optics, Acoustics, Electromagnetics, and Classical mechanics.)

Disclaimer: This module is adapted and modified from the source materials listed in the references list. This is an
exclusive property of Philippine Christian University-Dasmariñas SHS and is provided only to enrolled students for
their academic use. This module is provided for free by the school through softcopy and/or printed media.
Reproduction of this module without official permission is prohibited.
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 2. Modern Physics
Modern physics embraces the atom and its component parts, relativity and the interaction of high
speeds, cosmology and space exploration, and mesoscopic physics, those pieces of the universe
that fall in size between nanometers and micrometers.
(Quantum mechanics, Special relativity and General relativity.)

PHYSICAL QUANTITIES AND UNITS
We define a physical quantity either by specifying how it is measured or by stating how it is calculated
from other measurements. For example, we define distance and time by specifying methods for measuring
them, whereas we define average speed by stating that it is calculated as distance traveled divided by time of
travel.

Measurements of physical quantities are expressed in terms of units, which are standardized values.
For example, the length of a race, which is a physical quantity, can be expressed in units of meters (for sprinters)
or kilometers (for distance runners). Without standardized units, it would be extremely difficult for scientists to
express and compare measured values in a meaningful way.

There are two major systems of units used in the world: SI units (also known as the metric system) and
English units (also known as the customary or imperial system). English units were historically used in nations
once ruled by the British Empire and are still widely used in the United States. Virtually every other country in
the world now uses SI units as the standard; the metric system is also the standard system agreed upon by
scientists and mathematicians. The acronym “SI” is derived from the French Système International.

Fundamental SI Units
Length Mass Time Electric Temperature Amount of Luminosity
Current Substance
meter (m) kilogram (kg) second (s) ampere (A) Kelvin (K) mole (mol) candela (cd)

SI BASE UNIT

SI base units are the standard units of measurement defined by the International System of Units (SI)
for the seven base quantities of what is now known as the International System of Quantities: they are notably
a basic set from which all other SI units can be derived. The units and their physical quantities are the second
for time, the metre/meter for length, the kilogram for mass, the ampere for electric current, the kelvin for
thermodynamic temperature, the mole for amount of substance, and the candela for luminous intensity. The
SI base units are a fundamental part of modern metrology, and thus part of the foundation of modern science
and technology.

Disclaimer: This module is adapted and modified from the source materials listed in the references list. This is an
exclusive property of Philippine Christian University-Dasmariñas SHS and is provided only to enrolled students for
their academic use. This module is provided for free by the school through softcopy and/or printed media.
Reproduction of this module without official permission is prohibited.
5
 SI DERIVED UNIT
Other quantities, called derived quantities, are defined in terms of the seven base quantities via
a system of quantity equations. The SI derived units for these derived quantities are obtained from these
equations and the seven SI base units.

SI DERIVED UNIT
area square meter m2
volume cubic meter m3
speed, velocity meter per second m/s
acceleration meter per second squared m/s2
wave number reciprocal meter m-1
mass density kilogram per cubic meter kg/m3
specific volume cubic meter per kilogram m3/kg
current density ampere per square meter A/m2
magnetic field strength ampere per meter A/m
amount-of-substance mole per cubic meter mol/m3
concentration
luminance candela per square meter cd/m2
mass fraction kilogram per kilogram, which kg/kg = 1
may be represented by the
number 1

ACCURACY AND PRECISION
Accuracy is the degree of closeness between a measured value and true value. Accuracy depends on
using good techniques and highly accurate tools.

Precision is the representation of measurement of a single property in the same way of at least three
trials giving a way of judging how close to each other the repeated values. It depends on accuracy of the
instruments.

Let us visualize what accuracy and precision are:

https://danielmiessler.com/blog/difference-precision-accuracy/

Disclaimer: This module is adapted and modified from the source materials listed in the references list. This is an
exclusive property of Philippine Christian University-Dasmariñas SHS and is provided only to enrolled students for
their academic use. This module is provided for free by the school through softcopy and/or printed media.
Reproduction of this module without official permission is prohibited.
6
 CONVERSION OF UNITS
Conversion of units is the conversion between different units of measurement for the same quantity,
typically through multiplicative conversion factors. Converting between units can be done through the use of
conversion factors or specific conversion formulas.

Math - Metric Conversion Trick. (n.d.). BlogSpot-Strong Armor. Retrieved August 25, 2021,
from https://strongarmor.blogspot.com/2012/06/fun-with-metric-conversions.html
Can you still remember this method of conversion? Yes this is the easiest way to convert metric units
but now let us discuss the proper conversion factors for each unit of measurements.

Physics / Aug. 15 – Aug. 19. (2016, August 18). Discovery School Grade 12.
https://grade12ds.wordpress.com/2016/08/15/physics-aug-15-aug-19/

Disclaimer: This module is adapted and modified from the source materials listed in the references list. This is an
exclusive property of Philippine Christian University-Dasmariñas SHS and is provided only to enrolled students for
their academic use. This module is provided for free by the school through softcopy and/or printed media.
Reproduction of this module without official permission is prohibited.
7
 This might seem like a lot of numbers and units, so how do we really use this conversion factors in converting
units? Here’s an example!

8-2 Converting Metric Units Warm Up Warm Up Lesson Presentation Lesson Presentation Problem of the Day Problem of the Day
Lesson Quizzes Lesson Quizzes. (n.d.). Slide Player. Retrieved August 25, 2021, from https://slideplayer.com/slide/10879116/

LET’S PRACTICE!
Directions: Convert the following using the different conversion factors given on the table above. Good
luck!
Convert the following:

1. 322,543 cm=______km

2. 9,000g=______oz

3. 15ft=______cm

Disclaimer: This module is adapted and modified from the source materials listed in the references list. This is an
exclusive property of Philippine Christian University-Dasmariñas SHS and is provided only to enrolled students for
their academic use. This module is provided for free by the school through softcopy and/or printed media.
Reproduction of this module without official permission is prohibited.
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 Rounding means reducing the digits in a number while trying to keep its value similar. However the
result is less accurate, but easier to use.
Below are some rules/steps to round numbers
1. Decide which is the last digit to keep

Retrieved from: https://content.byui.edu/file/b8b83119-9acc-4a7b-bc84-efacf9043998/1/Math-1-3-4.html

2. If the next digit is less than five meaning round down, then leave it the same.
3. But if the next digit is five and above meaning round up increase the next digit by 1.
Examples:
Round off the following to the nearest hundredths (two decimal places):
1. ) 3.45346543
2. ) 453.2434
3. ) 5.6785

1.) 3.45 - As the next digit is 3 which is less than 5 hence round down.
2.) 453.24 - As the next digit is 3 which is less than 5 hence round down.
3.) 5.68 -As the next digit is 8 which is more than 5 hence round up.

SCIENTIFIC NOTATION
Other form of writing large or small (decimal) numbers using the base ten or exponential form.
Below are the rules in expressing number in scientific notation.
1. The decimal point should always be placed after the first non-zero digit.
2. If the decimal travels from right to left, the exponent of ten will be positive.
3. If the decimal point travels from left to right, the exponent of ten will be negative.
The exponent must be a non-zero integer, that means it can be either positive or negative. The absolute
value of the coefficient is greater than or equal to 1 but it should be less than 10. Coefficients can be positive
or negative numbers including whole and decimal numbers.
Examples:
1.) 224.9
2.) 0.000034
3.) 65000000

1.) 2.25 × 102
2.) 3.40 × 10−5
3.) 6.50 × 107

Disclaimer: This module is adapted and modified from the source materials listed in the references list. This is an
exclusive property of Philippine Christian University-Dasmariñas SHS and is provided only to enrolled students for
their academic use. This module is provided for free by the school through softcopy and/or printed media.
Reproduction of this module without official permission is prohibited.
9
 RANDOM ERRORS & SYSTEMATIC ERRORS
Random errors arise from unknown and unpredictable variations in condition.
For example, a student is observing a pendulum and the time taken to complete 10 oscillations is 20.0s.
1st 2nd 3rd 4th 5th
experiment experiment experiment experiment experiment
Time taken for 10 oscillation 20.1 20.0 19.8 19.9 20.2
Error +0.1 0.0 -0.2 -0.1 +0.2

Random error has non-consistent size of error and is unpredictable.

Sources of Random Errors:
1. Human limitations
2. Lack of sensitivity of the instrument
3. Wrong technique of measurement.

This type of error can be reduced by:
1. Taking repeat readings
2. Find the average value of the reading
20.1+20.0+19.8+19.9+20.0=100/5=20.0s
The average of the readings for the oscillations of the pendulum is = 20.0s

Systematic errors are errors which tend to shift all measurements in a systematic way so their mean
value is displaced.
The measurement obtained is deviated consistently either too high or too low from the actual value.
Systematic errors can be compensated if the errors are known.

For example, you are weighing ingredients for baking.

Flour Baking powder Sugar Cocoa powder
Actual weight 2.5kg 1.0kg 0.5kg 1.5kg
Reading from the 3.0kg 1.5kg 1.0kg 2.0kg
scale
Errors 0.5kg 0.5kg 0.5kg 0.5kg

The errors from all the ingredients are the same, they are all 0.5kg.

Sources of Systematic Errors:
1. Incorrect calibration of measuring instrument
2. Consistently improper use of equipment
How to overcome:
1. Conducting experiment with care
2. Repeat the experiment by using different instruments

Disclaimer: This module is adapted and modified from the source materials listed in the references list. This is an
exclusive property of Philippine Christian University-Dasmariñas SHS and is provided only to enrolled students for
their academic use. This module is provided for free by the school through softcopy and/or printed media.
Reproduction of this module without official permission is prohibited.
10
 GRAPHICAL REPRESENTATION
Graphical Representation is a way of analysing numerical data. It exhibits the relation between data,
ideas, information and concepts in a diagram. It is easy to understand and it is one of the most important
learning strategies. It always depends on the type of information in a particular domain. There are different
types of graphical representation. Some of them are as follows:
Line Graphs – Line graph or the linear graph is used to display the continuous data and it is useful for predicting
future events over time.
Bar Graphs – Bar Graph is used to display the category of data and it compares the data using solid
bars to represent the quantities.
Histograms – The graph that uses bars to represent the frequency of numerical data that are organised
into intervals. Since all the intervals are equal and continuous, all the bars have the same width.
Line Plot – It shows the frequency of data on a given number line. ‘ x ‘ is placed above a number line
each time when that data occurs again.
Frequency Table – The table shows the number of pieces of data that falls within the given interval.
Circle Graph – Also known as the pie chart that shows the relationships of the parts of the whole. The
circle is considered with 100% and the categories occupied is represented with that specific percentage
like 15%, 56%, etc.
Stem and Leaf Plot – In the stem and leaf plot, the data are organised from least value to the greatest
value. The digits of the least place values from the leaves and the next place value digit forms the
stems.
Box and Whisker Plot – The plot diagram summarises the data by dividing into four parts. Box and
whisker show the range (spread) and the middle ( median) of the data.

LINEAR FITTING
The very most straightforward case of a single scalar predictor variable x and a single scalar response
variable y is known as simple linear regression. The equation for this regression is represented by;
y=a+bx
The expansion to multiple and vector-valued predictor variables is known as multiple linear regression,
also known as multivariable linear regression. The equation for this regression is represented by;
Y = a+bX
Almost all real-world regression patterns include multiple predictors, and basic explanations of linear
regression are often explained in terms of the multiple regression form. Note that, though, in these cases, the
dependent variable y is yet a scalar.

Disclaimer: This module is adapted and modified from the source materials listed in the references list. This is an
exclusive property of Philippine Christian University-Dasmariñas SHS and is provided only to enrolled students for
their academic use. This module is provided for free by the school through softcopy and/or printed media.
Reproduction of this module without official permission is prohibited.
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 Summary

Physics is a branch of science that deals with energy and matter. Physics are divided into two
fields, namely, Classical and Modern Physics. Classical hysics are fields of physics that was studied before
1900, while modern physics are the studies and discoveries published and theorized after 1900.

Mathematical calculations and formulations in physics are quantified using Scalar and Vector
Quantities. Scalar quantities are quantities that only have magnitude. Speed and Distance are examples
of scalar quantity. Vector quantities are quantities that possess both magnitude and direction. Velocity
and Displacement are the examples of vector quantities. These quantities are also classified by their units
of measurement to determine the properties of the said quantities. There are two units of measurement
that are commonly used in physics, these are the English System and Metric System.

Upon usage of incorrect mathematical approaches in experiments, the outcome will lead to
errors. When dealing with scientific experiments, there are two possible type of error that can occur.
These errors are called Random Errors and Systematic Errors.

Disclaimer: This module is adapted and modified from the source materials listed in the references list. This is an
exclusive property of Philippine Christian University-Dasmariñas SHS and is provided only to enrolled students for
their academic use. This module is provided for free by the school through softcopy and/or printed media.
Reproduction of this module without official permission is prohibited.
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 Activity # 1 (Written Work 1)
NAME: STRAND & SECTION:
DATE/WEEK NO.: SCORE: / 55

I. Rounding Off Numbers
DIRECTIONS: Complete the table below by rounding the numbers to the required values. Read and
answer carefully. (10 points)
Given Nearest Round-Off Form
1 473,483,441.55 Ten Thousands
2 3,420.336 Tenths
3 123,456,789.10 Hundred Thousands
4 44,654,778.95862651 Millionths
5 15.245504 Ten Thousandths
6 127.777 Tens
7 299,792,458,562.995 Ten Billions
8 999,999,999 Thousands
9 621,311,299 Hundreds
10 27,489.99 Thousands

II. Scientific Notation
DIRECTIONS: Complete the table below by writing the correct scientific notation form of the given
values.
Given Scientific Notation
1 0.00000000000000000069
2 7559831054.00
3 35498796.99
4 0.00000249953
5 0.00930000523
6 33529.33
7 0.000000239
8 2356.4
9 0.008820000001
10 29979245826478

III. Conversion of Units
DIRECTIONS: Convert the following as indicated. Show your solutions and cancellation of units.

1.) 5m= ______________________yd. Solution:
=_______________________ft.

Disclaimer: This module is adapted and modified from the source materials listed in the references list. This is an
exclusive property of Philippine Christian University-Dasmariñas SHS and is provided only to enrolled students for
their academic use. This module is provided for free by the school through softcopy and/or printed media.
Reproduction of this module without official permission is prohibited.
13
 2.) 3.5 tons =_________________kg. Solution:
=_________________g.

3.) 12 in = ______________________ft. Solution:
=______________________cm.

4.) 33x106 sec =___________________min. Solution:
=___________________hr.

5.) 43Km =______________________m Solution:
=______________________cm

Supplemental Readings and Materials

vector | Definition, Physics, & Facts. (n.d.). Encyclopedia Britannica. Retrieved August 25, 2021, from
https://www.britannica.com/science/vector-physics

Math - Metric Conversion Trick. (n.d.). BlogSpot-Strong Armor. Retrieved August 25, 2021, from
https://strongarmor.blogspot.com/2012/06/fun-with-metric-conversions.html

Learning Resources

Caintic, H. (2017). General Physics 1 for Senior High School. C & E Publishing, Inc.
Sayson, L., Navalta, C. (2015). Physics 1 Workbook. Mindshapers Co., Inc.
8-2 Converting Metric Units Warm Up Warm Up Lesson Presentation Lesson Presentation Problem of the Day
Problem of the Day Lesson Quizzes Lesson Quizzes. (n.d.). Slide Player. Retrieved August 25, 2021,
from https://slideplayer.com/slide/10879116/

Essentials of the SI: Base & derived units. (n.d.). THE NIST REFERENCE ON CONSTANTS, UNITS AND UNCERTAINTY.
Retrieved August 25, 2021, from https://physics.nist.gov/cuu/Units/units.html

Disclaimer: This module is adapted and modified from the source materials listed in the references list. This is an
exclusive property of Philippine Christian University-Dasmariñas SHS and is provided only to enrolled students for
their academic use. This module is provided for free by the school through softcopy and/or printed media.
Reproduction of this module without official permission is prohibited.
14
 F. (2021, August 25). Understanding base quantities and derived quantities. Blogspot. http://fizik-
fizik.blogspot.com/2009/11/understanding-base-quantities-and.html?m=1

Learn About Different Types of Physics. (n.d.). ThoughtCo. Retrieved August 25, 2021, from
https://www.thoughtco.com/what-are-the-fields-of-physics-2699068

Physical Quantities and Units | Physics. (n.d.). Lumen. Retrieved August 25, 2021, from
https://courses.lumenlearning.com/physics/chapter/1-2-physical-quantities-and-units/

Physics / Aug. 15 – Aug. 19. (2016, August 18). Discovery School Grade 12.
https://grade12ds.wordpress.com/2016/08/15/physics-aug-15-aug-19/

what is motion in physics? The concept of displacement and distance. (2021, January 22). Downlaod Physics App
- The Best Physics App 2021. https://towardbrightspark.info/what-is-motion-in-physics-the-
concept-of-displacement-and-distance/

Wikipedia contributors. (2021, August 24). SI base unit. Wikipedia. https://en.wikipedia.org/wiki/SI_base_unit
Vector Addition. (n.d.). The Physics Classroom. Retrieved August 31, 2021, from
https://www.physicsclassroom.com/class/vectors/Lesson-1/Vector-Addition

Admin. (2021, May 4). Graphical Representation - Types, Rules, Principles and Merits. BYJUS. Retrieved July
20,2024 from https://byjus.com/maths/graphical-representation/

Admin. (2020, August 13). Linear Regression-Equation, Formula and Properties. BYJUS. Retrieved July 20, 2024
from https://byjus.com/maths/linear-regression/

Prepared by: Checked By: Noted By:

Eleze Abraham P. Ambrad, LPT. Angela A. Zarcilla, LPT. Maria Beatriz B. Sico, MM
Subject Lead Teacher – Principal
Marie Elaine B. Caparas, MAEd, LPT. Science 12

John Karlo C. Narvaez, LPT.

Robin C. Padon, LPT.

Vanessa C. Pedro
Subject Teacher/s

Disclaimer: This module is adapted and modified from the source materials listed in the references list. This is an
exclusive property of Philippine Christian University-Dasmariñas SHS and is provided only to enrolled students for
their academic use. This module is provided for free by the school through softcopy and/or printed media.
Reproduction of this module without official permission is prohibited.
15