This document provides a teaching guide for a 7th grade math lesson on sets. It introduces concepts like well-defined sets, subsets, universal sets, and the null set. Students will use Venn diagrams to represent sets and subsets. The lesson defines terms like union and intersection of sets and teaches students to perform set operations and use symbols and notations related to sets.
The document provides instructions for teaching students about measures of central tendency (mean, median, mode) using ungrouped data. It outlines objectives, subject matter, materials, and procedures for the lesson. The teacher's activity is to define and provide examples to calculate the mean, median, and mode. The students' activity is to practice calculating these measures and describing data sets in terms of them. The lesson concludes with an assignment for students to find the mean, median, and mode of additional data sets.
This document provides a lesson on the complement of a set. It begins with an example problem about student populations to introduce the concept. The lesson then defines the complement of a set A as the set of all elements in the universal set U that are not in A. It explains how to find the complement using a Venn diagram and the formula that the cardinality of the complement is equal to the total elements of U minus the elements of A. Several examples are provided to illustrate computing and representing complements of sets using Venn diagrams. The lesson concludes by solving the initial problem about student selection using the complement concept.
The lesson plan aims to teach students about relationships between angles. It defines complementary angles as two angles whose measures sum to 90 degrees, supplementary angles as two angles whose measures sum to 180 degrees, adjacent angles as two angles that share a vertex and side, and vertical angles as two non-adjacent angles formed by two intersecting lines. The lesson involves identifying these relationships in diagrams and adding angle measures. Students will complete an evaluation to assess their understanding of these concepts.
This document provides a teaching guide for a 7th grade math lesson on sets. It introduces concepts like well-defined sets, subsets, universal sets, and the null set. Students will use Venn diagrams to represent sets and subsets. The lesson defines terms like union and intersection of sets and teaches students to perform set operations and represent unions and intersections using Venn diagrams.
This document is a workbook from Esperanza National High School covering sets and number sense for 7th grade mathematics. It includes lessons on defining and describing sets using roster and rule methods, set operations like union, intersection, difference and complement, and problems involving Venn diagrams. It also covers absolute value on the number line. The workbook contains examples and exercises for students to practice these set theory and number sense concepts.
Here is the improved and edited detailed lesson plan with a subject matter SSS Congruence Postulate. I uploaded the old version and now I upload the edited one. you can always download this one..maybe it could help you.
1. The lesson plan is for a math class on factoring the sum and difference of two cubes.
2. Students will do an activity matching cube root terms to images to help understand getting cube roots and the patterns in factoring sums and differences of cubes.
3. The lesson will review getting cube roots, then demonstrate the steps to factor sums and differences of cubes by getting the cube root of each term, forming a binomial, and using the binomial to factor the expression. Students will do examples to practice.
1. The lesson plan discusses relations and functions through classroom activities including a game to demonstrate examples.
2. Key concepts are defined, such as a relation being a set of ordered pairs and a function requiring each domain input to map to only one range output.
3. Examples of both relations that are functions and those that are not are analyzed, with students expected to understand the difference between one-to-one, one-to-many, and many-to-one relations.
Here are the answers:
(a) A B is shown in Set 2. It contains all elements that belong to A or B or both.
(b) A B is shown in Set 3. It contains elements that belong to both A and B.
2. Given sets P = {1, 3, 5, 7, 9} and Q = {2, 4, 6, 8}, find P Q and P Q.
3. Draw a Venn diagram to represent the following sets:
A = {x | x is a prime number less than 10}
B = {x | x is an even number less than 10}
This lesson plan teaches measures of position for ungrouped data. It begins with an activity where students arrange exam scores in order and identify the quartiles. The lesson then defines measures of position like quartiles and deciles, and explains how to find and interpret them using an example of students' math scores. Students practice finding the quartiles of another data set. Finally, an evaluation activity asks students to find and interpret the quartiles of classmates' ages from a table of data.
This lesson plan is for a 9th grade mathematics class on trigonometric ratios of 45-45-90 triangles. The objectives are for students to identify trig ratios in this special triangle, connect the ratios to real life, and find the specific values of the six ratios. To teach this, the teacher will have students play a message relay game in groups, then analyze their observations about the triangle angles and side lengths. Finally, the teacher will discuss properties of 45-45-90 triangles and have students practice finding the six trigonometric ratios of the 45 degree angle. For homework, students must research the 30-60-90 triangle theorem.
DLL Math Grade7 Quarter2 Week5 (Palawan Division).docxTom Quilloy
This document is a daily lesson log for a 7th grade mathematics class. It outlines the objectives, content, learning resources, procedures, and reflection for lessons on multiplying and dividing polynomials over the course of a week. The objectives are for students to multiply monomials using laws of exponents, multiply polynomials using the distributive property and FOIL method, and divide polynomials by monomials and binomials. The content covers patterns and algebra, including algebraic expressions/equations. Learning resources listed include textbooks and materials. The procedures provide examples and practice problems for students to multiply and divide polynomials. The reflection section evaluates student learning and identifies strategies for remediation.
Lesson plan in mathematics 8 (Factoring Perfect Square Trinomial) Rachel Ann
This lesson plan teaches students how to factor perfect square trinomials. It begins with introducing the learning competency and objectives of factoring perfect square trinomials. Examples are provided to demonstrate the steps: getting the square root of the first and last terms and listing them as a sum or difference. Students practice this by factoring examples as a group activity and individually. They summarize the key points and apply the process to new problems, concluding with an assignment to factor additional perfect square trinomials independently.
This document presents a lesson on solving word problems involving sets. It begins by stating the objectives of the lesson which are to apply set operations to word problems, solve word problems using Venn diagrams, and participate in group activities. It then provides examples of word problems involving sets and demonstrates how to analyze them using Venn diagrams and set operations. The document aims to show students how to solve real-world problems involving sets.
This document contains a detailed lesson plan for a 7th grade mathematics class on quadrilaterals. The lesson plan includes the following:
1) Objectives of defining and identifying different types of quadrilaterals, as well as comparing, drawing, and describing them.
2) A variety of activities to engage students in discovering properties of quadrilaterals, including games, group work, and story problems.
3) An evaluation at the end to assess student understanding of quadrilaterals through drawing, defining, and identifying true/false statements about their properties.
4) An assignment for students to work in groups to create a jingle summarizing what they learned about quadrilaterals
The document outlines a lesson plan on ratios and proportions in mathematics. The objectives are for students to define and identify ratios, solve proportions, and understand the real-life applications of ratios and proportions. The lesson plan details the teacher's activities such as reviewing concepts, presenting new material through examples, discussion, and practice problems. It also includes student activities like solving problems and group work. Key concepts covered are defining ratios as comparisons of quantities and proportions as equal ratios. Students learn to set up and solve ratios and proportions, including finding missing terms. The lesson emphasizes applying ratios and proportions to everyday situations like baking.
The lesson plan discusses measures of central tendency for ungrouped data. It defines the three measures - mean, median, and mode. The lesson explains how to calculate each measure through examples and formulas. Students will practice finding the mean, median, and mode of various data sets.
This document outlines a lesson plan on integer operations with the following objectives:
1) Define integers and integer operation rules
2) Solve problems involving integer operations
3) Relate integers to real-world applications
The lesson will include motivation games to introduce integers, group activities with flashcards to practice operations, and a discussion of integer definitions and rules. It will conclude by connecting integers to a real-world video example and giving an evaluation of integer operation problems.
Strategic Intervention Material in Mathematics Grade 7Arlene Callang
This document contains lesson materials on adding integers, including:
- An activity card with examples of using balls to represent integers and add them.
- An assessment card with problems to practice adding integers without visuals.
- An enrichment card with more practice problems, as well as finding missing integers in addition problems.
The materials aim to build students' skills in representing and calculating the addition of integers through visual and numerical problems.
The lesson plan is for a math class on factoring the difference of two squares. It outlines learning objectives, content, materials, and activities. The objectives are for students to factor differences of squares, find square roots, and understand real-world applications. Content includes the skill of factoring expressions and finding square roots. Students will do an activity investigating patterns in products of differences of squares and generalize the relationship. They will learn that to factor such expressions, the factors are the sum and difference of the square roots of the terms. An evaluation and assignment reinforce these skills.
K TO 12 GRADE 7 LEARNING MODULE IN MATHEMATICS (Quarter 3)LiGhT ArOhL
This document provides a lesson plan on solving linear equations and inequalities in one variable algebraically. It begins with reviewing translating between verbal and mathematical phrases and evaluating expressions. The main focus is on introducing and applying the properties of equality, including reflexive, symmetric, transitive, and substitution properties, to solve equations algebraically. Word problems involving equations in one variable are also discussed. The objectives are to identify and apply the properties of equality to find solutions to equations and solve word problems involving one variable equations.
K TO 12 GRADE 4 TEACHER’S GUIDE IN MATHEMATICS (Q1-Q4)LiGhT ArOhL
The document contains multiple repetitions of a paragraph stating that all rights are reserved for the material and that no part can be reproduced or transmitted without permission from the DepEd Central Office. It was published in 2015.
This document introduces special products and factors of polynomials. It discusses how patterns can be used to simplify algebraic expressions and solve geometric problems. Students will learn to identify special products through pattern recognition, find special products of polynomials, and apply these concepts to real-world problems. The goals are to demonstrate understanding of key concepts and solve practice problems accurately using different strategies.
This document provides a lesson plan on solving linear equations and inequalities in one variable algebraically. It begins with reviewing translating between verbal and mathematical phrases and evaluating expressions. The main focus is on introducing and applying the properties of equality, including reflexive, symmetric, transitive, and substitution properties, to solve equations algebraically. Word problems involving equations in one variable are also discussed. The objectives are to identify and apply the properties of equality to find solutions to equations and solve word problems involving one variable equations.
This document discusses hypotheses, which are tentative theories or educated guesses about the real world or a population. A hypothesis aims to explain facts and makes testable predictions about what may happen in certain circumstances. Research hypotheses are created by researchers to speculate about the outcome of an experiment. There are two main kinds of hypotheses: the null hypothesis, which expresses no difference or relationship, and the alternative hypothesis, which is accepted if the null is rejected. When testing a hypothesis, there is a chance of making Type I or Type II errors in rejecting or accepting the null hypothesis.
Waves (Grade 7, Quarter 3) Suggested Guide for DiscussionRachel Espino
A suggested powerpoint presentation guide for discussion for Gr.7 teachers on the characteristics and categories of waves. It also includes a simple quiz (under knowledge category) as an assessment
The document describes a problem where a frog jumps up 3 steps per day and down 2 steps the next day. It asks how many days it will take the frog to reach the top of a 6 step stair. It provides the key information that the frog jumps up 3 steps one day and down 2 the next day, alternating in this pattern until it reaches the top of a 6 step stair.
Teachers Guide 1st Quarter Grade7 for EnglishDon Joven
Good morning, Sir! How may I help you?
Customer: Hi! I would like to inquire about the new book on Philippine folk literature that was
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Assistant: Yes, of course. The book is entitled "Our Living Heritage: A Compilation of Philippine
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This document discusses two summative assessments included in the Lumos tedBook for PARCC math for grade 7. It provides details on the number and types of questions included in each summative assessment, covering domains like ratios, numbers, expressions, geometry, and statistics. Additionally, it notes the tedBook provides online workbooks with over 700 practice questions and detailed explanations to help students prepare.
The document provides an overview of fraction concepts including equivalent fractions, comparing fractions, ordering fractions, fractions in number stories, probability, coordinate points, and operations like addition and subtraction. It includes examples of each concept and provides practice problems for students to work through. The goal is to review key fraction ideas and skills through examples and interactive math problems.
This document provides a teaching guide for a 7th grade math lesson on sets. It includes objectives, notes for teachers, activities, and exercises for students. The lesson introduces concepts like well-defined sets, subsets, the universal set, Venn diagrams, and operations on sets such as union and intersection. Students are asked to group objects, represent sets visually, perform set operations, and determine the number of elements in resulting sets. The teacher is advised to emphasize key definitions and ensure students understand examples and counter-examples.
This document provides an overview of a lesson on ancient Filipino poetry. It discusses how Filipino poetry reflects local customs, traditions, beliefs, and ideals. It presents examples of riddles, proverbs, and folksongs that were popular forms of ancient Filipino poetry. Students are asked to analyze riddles and proverbs and explain the cultural significance and relevance over time of one proverb.
This document contains a summary of key concepts and example problems from a math textbook chapter on exponents, logarithms, and exponential and logarithmic functions. It covers graphing and solving exponential equations/inequalities, properties and applications of logarithms including the Richter scale, modeling population growth and decay using exponential and logarithmic functions, and decibel calculations for sound intensity. Example problems are provided to illustrate concepts like compound interest, advertising models, endangered species populations, and muffler noise reductions.
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This module focuses on becoming a discriminating and analytical learner. It contains a pretest to assess skills like identifying main ideas, distinguishing facts from opinions, and using correct verb forms. The module then covers activities to develop these skills, including choosing word meanings based on context, identifying synonyms, and summarizing a fable about honesty. The goal is to help learners answer whether information will help them make wise decisions.
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The document discusses SAP BusinessObjects Data Services and its role in an SAP landscape. It provides an overview of SAP's enterprise information management solutions including data integration, data quality management, master data management and enterprise data warehousing. It then discusses how Data Services can be used for data integration, data quality, loading SAP BW, extracting from BW, and supporting business processes like data migration and master data management.
This document discusses hypothesis, including its definition, characteristics, types, formulation, and testing. A hypothesis is a tentative assumption made to explain certain facts or observations that can be tested. It should be clear, testable, relate variables, be specific and consistent. The main types are the null, prediction, declarative, and question forms. When testing a hypothesis, the researcher specifies a null hypothesis and alternative, selects a significance level like 5% typically, decides on a distribution, selects samples, computes a test statistic, and compares it to the significance level to either reject or fail to reject the null hypothesis, avoiding type 1 and 2 errors.
This document discusses the formulation, testing, and importance of research hypotheses. It defines a hypothesis as a tentative assumption or predictive statement that can be tested scientifically. The key points covered include: how to properly formulate a hypothesis by ensuring it has conceptual clarity, is testable, and relates independent and dependent variables; the importance of hypotheses in providing direction for research and advancing knowledge; methods for testing hypotheses, including checking logical consistency and agreement with facts; and defining the process of rejecting or modifying a hypothesis based on testing results.
In this presentation we answer the question, "Why do we need hypothesis tests in process improvement?" Then we walk you through a real, live hypothesis test direct from the Bahama Bistro!
You can find the rest of the webinar materials and questions from the webinar here:
https://goleansixsigma.com/webinar-set-run-hypothesis-tests/
The union of sets A and B contains all elements that are in A, in B, or in both. The intersection of sets A and B contains only the elements that are common to both A and B. Venn diagrams can be used to represent the relationships between sets and determine their union and intersection.
Here are the answers:
(a) A B is shown in Set 2. This contains all students who play guitar or piano or both.
(b) A B is shown in Set 4. This contains only students who play both guitar and piano.
Learning Guide for Grade 7 Mathematics under the k-12 Curriculum in the Phili...polchan
This is the mathematics Module for Grade 7 pupils under the K-12 Curriculum implemented in the Philippines. This is a Learning Guide for Grade 7 Mathematics.
The document provides information about sets and set operations including:
1) It defines the complement of a set as the elements in the universal set that are not in the given set.
2) It provides examples of finding the complement of sets and using Venn diagrams to represent complements.
3) It solves a word problem about selecting a student who is not a sophomore by finding the complement of the set of sophomores.
The document provides information about sets and operations on sets such as union, intersection, and complement. It includes examples and exercises involving defining sets based on given criteria, finding the elements and cardinality of unions, intersections, and complements of sets, and using Venn diagrams to represent relationships between sets. The key concepts covered are defining sets, unions and intersections of sets, complements of sets, and using Venn diagrams to illustrate set relationships.
The document provides details of a math lesson plan on sets for 7th to 10th grade students. It includes the content standards, objectives, activities, and evaluation. The lesson introduces concepts of sets such as defining sets using roster and rule methods, identifying subsets, and determining if a collection is a well-defined set. Example activities have students grouping objects in pictures into sets and writing the elements of given sets using roster and rule notation. The evaluation assesses students' understanding of set concepts through similar activities of specifying set elements and properties.
This document outlines a daily lesson log for a 7th grade mathematics class. The lesson focuses on sets and the real number system. Specifically, the objectives are for students to describe well-defined sets, subsets, universal sets, and the null set; and to illustrate the union and intersection of sets.
The content of the lesson includes introducing sets, describing the elements and cardinality of sets, and defining subsets, universal sets, and the null set. It then covers the union and intersection of sets, using Venn diagrams to represent these concepts. Examples and activities are provided to help students practice applying these set concepts. Questions are included to check students' understanding and allow the teacher to assess learning.
This document outlines content standards and learning objectives for sets and real numbers in Grade 7 mathematics. It covers key concepts like well-defined sets, subsets, universal sets, null sets, cardinality of sets, union and intersection of sets, and Venn diagrams. Specific objectives include describing these set concepts, finding unions and intersections, and using Venn diagrams to represent relationships between sets. The document provides references and learning resources to support understanding, including textbook pages, websites, and practice exercises. It also includes sample sets, activities, and questions to help teach the relevant concepts and assess student mastery of sets and real numbers.
This document outlines a detailed lesson plan for teaching set operations in math to 7th grade students. The objectives are to identify sets, describe and illustrate different set operations like union, intersection, complement, and difference using examples. Students will perform set operations and use Venn diagrams to represent union and intersection of sets. The lesson begins with an introductory activity to classify pictures of animals into sets of carnivores, herbivores and omnivores. Key concepts of set operations like union, intersection, complement and difference are then explained using examples and Venn diagrams. Students practice identifying sets and performing operations on example sets. The lesson concludes by having students generalize their understanding and apply the concepts through additional exercises
Set 1: A set of fruits with elements of apple, banana, and orange.
Set 2: A set of vehicles with elements of car, truck, and motorcycle.
The student provided an example of two sets - a set of fruits and a set of vehicles. Another student then correctly identified the union and intersection of these two sets. The teacher praised the students for their accurate responses, demonstrating they understood the key concepts of sets, unions, and intersections.
Set 1: A set of fruits with elements of apple, banana, and orange.
Set 2: A set of vehicles with elements of car, truck, and motorcycle.
The student provided an example of two sets - a set of fruits and a set of vehicles. Another student then correctly identified the union and intersection of these two sets. The teacher praised the students for their accurate responses, demonstrating they understood the key concepts of sets, unions, and intersections.
This document introduces key concepts about sets. It defines a set as a well-defined group of objects that share a common characteristic. It discusses subsets and the universal set. Important notations and symbols used to describe sets are explained, including roster notation, verbal descriptions, and set builder notation. Examples are provided to illustrate these concepts and notations. Activities at the end ask the reader to identify well-defined sets, list subsets, provide verbal descriptions of sets, and write sets in different notations.
This document provides a teaching guide for mathematics with 14 units. It explains how to use the guide which includes lesson plans for each unit with objectives, starter activities, main lessons, practice sessions, individual activities and homework. Lesson plans are designed to be completed within 40 minutes and include teaching sets, rational numbers, decimals, exponents, square roots, proportions, profit and loss, algebra, equations, geometry, surface area, volume and data handling. The guide aims to make lessons easy to follow and divide content over the year.
Sets is the first lesson in Mathematics 7. This lesson introduces the basic terms. For more presentations visit me on YouTube. https://www.youtube.com/channel/UCltDbhOXh6r9FyYE52rWzCQ/playlists?shelf_id=18&view_as=subscriber&sort=dd&view=50
Introduction to Sets and Set Operations. The presentation include contents of a KWLH Chart, Essential Questions, and Self-Assessment Questions. With exploration and formative assessments.
The document discusses concepts related to sets including defining sets, subsets, unions and intersections of sets, using Venn diagrams to represent sets and set operations, and applying the concept of sets in other fields of study. It also asks questions about determining whether objects belong to sets, the importance of studying sets, and using sets in everyday experiences.
1) The document is a lesson plan for a mathematics class about sets, Venn diagrams, unions, intersections, and subsets. It includes short reviews, example problems, and activities to reinforce the concepts.
2) Students are divided into teams to complete tasks using meta strips before presenting to the class. Example problems involve finding unions and intersections of sets.
3) An activity surveys students about their sports participation, which is modeled with a Venn diagram to find subsets of students playing each sport alone or in combinations.
This document provides a session guide for teaching sets, elements, and the union of two sets to junior high school students. It includes objectives, subject matter, procedures, and an evaluation. The procedures involve grouping objects by characteristics to introduce sets, defining sets and elements, arranging elements in ascending order, and combining sets using union. Students practice identifying elements of sets, writing sets, and determining the union of multiple sets. The evaluation has students write the union of several sets of numbers and fractions to assess their understanding.
This document provides an overview of basic set concepts and notations. It begins by explaining that a set is a collection of distinct objects, which can be anything. Sets are represented using curly brackets and elements are separated by commas. A set can be finite or infinite depending on the number of elements. There are various relationships between sets such as subsets, supersets, disjoint sets, equivalent sets and more. Set operations like union and intersection are demonstrated using Venn diagrams. The document concludes by providing examples and exercises to solidify understanding of fundamental set concepts.
Similar to Grade 7 teacher's guide (q1&2) (20)
This document is a table of specifications outlining the topics, objectives, number of days, percentage of time allocated, and number and placement of test items for a Grade 10 mathematics class. It details that 17 days or 59% of the class will focus on sequences like arithmetic, geometric, Fibonacci, and harmonic, assessing these topics through 44 test items ranging from numbers 1 to 44. The remaining 12 days or 41% of the class will cover polynomial functions and equations, assessing these through 31 test items numbered 45 to 75. The total class time is 29 days and will include 75 test items.
Romantic art broke from Neoclassical styles by emphasizing emotion and nature. Landscape painting grew as people romantically admired the natural world. Romantic works featured heightened drama, emotion, and sensation through compositions depicting life and death moments and celebrating uncontrolled nature. Paintings focused on evoking emotions while sculptures represented the human world.
Neoclassicism was an artistic movement between 1780-1840 that saw a renewed interest in the styles and forms of Greek and Roman antiquity. Key aspects included portraying Roman history through formal compositions that used diagonals to convey emotion, as well as an emphasis on local color, overall lighting, and classic geometric structures. Neoclassicism reflected classical ideas in society and was inspired by ancient Greece and Rome, drawing from their principles in both decorative and visual arts.
This document discusses two predominant themes in Philippine vocal music: nationalism and love. It summarizes two iconic nationalistic songs, Lupang Hinirang and Marangal na Dalit ng Katagalugan, which played important roles in Philippine history by representing the nation's love of freedom from Spanish rule. It also mentions two representative love songs, Nasaan Ka Irog? and Gaano Ko Ikaw Kamahal?, which express creative artistic expressions of love valued in Philippine culture.
Some of the earliest known sculptures in the Philippines include a low relief engraving from 3000 BCE in Angono, Rizal featuring human and animal figures. A stone figure carved from brain corals called a likha palapat was also recovered from a burial site in Calatagan, Batangas. Additionally, a burial jar found in Palawan features a boat with two men rowing on its lid. Wood carving was an important art form for the mountain region of Cordilleras, where bul-ol figures of gods were carved to serve as guardians for rice granaries and pathways. Muslim communities like the Maranaos also incorporated sculptures like the mythical sarimanok bird into their art and as status symbols
1. The document provides information about measures of position (quartiles, deciles, percentiles) and how to calculate them. It gives an example of finding the first quartile (Q1), second quartile (Q2), and third quartile (Q3) from a data set of students' test scores.
2. Steps for calculating quartiles include arranging the data in order, dividing it into four equal parts, and finding the values that split the data into the 25th, 50th, and 75th percentiles.
3. Interpolation may be needed if the quartile value falls between two data points; this involves calculating the difference between points and multiplying by the decimal portion.
The document defines slope as how steep a straight line is and explains that it is calculated by dividing the change in the vertical axis by the change in the horizontal axis. It provides examples of slopes for different lines and notes that a positive slope means the line is increasing while a negative slope means it is decreasing. It further explains that a horizontal line has a slope of zero, a vertical line has an undefined slope, parallel lines have equal slopes, and perpendicular lines have slopes that are reciprocals of each other. The final section provides an activity for students to determine slopes, intercepts, and trends of functions from graphs.
This document provides information about Hazel Gonzales' teaching philosophy and experience as a student teacher. It discusses her beliefs that learning is measured by attitude as well as intelligence. As a mathematics teacher, she emphasizes understanding over memorization and developing students' reasoning skills through board work and explanations. The document also includes details about her course taught, grading criteria, and methods of providing feedback to students.
Principles of Roods Approach!!!!!!!.pptxibtesaam huma
Principles of Rood’s Approach
Treatment technique used in physiotherapy for neurological patients which aids them to recover and improve quality of life
Facilitatory techniques
Inhibitory techniques
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1. GRADE 7 MATH TEACHING GUIDE
Lesson I: SETS: AN INTRODUCTION
Pre-requisite Concepts: Whole numbers
Objectives:
In this lesson, you are expected to:
1. describe and illustrate
a. well-defined sets;
b. subsets;
c. universal set; and
d. the null set.
2. use Venn Diagrams to represent sets and subsets.
NOTE TO THE TEACHER:
This lesson looks easy to teach but don’t be deceived. The introductory
concepts are always crucial. What differentiates a set from any group is
that a set is well defined. Emphasize this to the students.
You may vary the activity by giving the students a different set of
objects to group. You may make this into a class activity by showing a
poster of objects in front of the class or even make it into a game. The idea
is for them to create their own well-defined groups according to what they
see as common characteristics of elements in a group.
Lesson Proper:
A.
I. Activity
Below are some objects. Group them as you see fit and label each group.
2. Answer the following questions:
a. How many groups are there?
b. Does each object belong to a group?
c. Is there an object that belongs to more than one group? Which one?
NOTE TO THE TEACHER:
You need to follow up on the opening activity hence, the problem
below is important. Ultimately, you want students to apply the concepts of
sets to the set of real numbers.
The groups are called sets for as long as the objects in the group share a
characteristic and are thus, well defined.
Problem: Consider the set consisting of whole numbers from 1 to 200. Let
this be set U. Form smaller sets consisting of elements of U that share a different
characteristic. For example, let E be the set of all even numbers from 1 to 200.
Can you form three more such sets? How many elements are there in each
of these sets? Do any of these sets have any elements in common?
Did you think of a set with no element?
NOTE TO THE TEACHER:
Below are important terms, notations and symbols that students must
remember. From here on, be consistent in your notations as well so as not
to confuse your students. Give plenty of examples and non-examples.
Important Terms to Remember
The following are terms that you must remember from this point on.
1. A set is a well-defined group of objects, called elements that share a common
characteristic. For example, 3 of the objects above belong to the set of head
covering or simply hats (ladies hat, baseball cap, hard hat).
2. Set F is a subset of set A if all elements of F are also elements of A. For
example, the even numbers 2, 4 and 12 all belong to the set of whole numbers.
Therefore, the even numbers 2, 4, and 12 form a subset of the set of whole
numbers. F is a proper subset of A if F does not contain all elements of A.
3. The universal setU is the set that contains all objects under consideration.
4. The null set is an empty set. The null set is a subset of any set.
5. The cardinality of set A is the number of elements contained in A.
Notations and Symbols
In this section, you will learn some of the notations and symbols pertaining to sets.
1. Uppercase letters will be used to name sets, and lowercase letters will be
used to refer to any element of a set. For example, let H be the set of all
objects on page 1 that cover or protect the head. We write
H = {ladies hat, baseball cap, hard hat}
3. This is the listing or roster method of naming the elements of a set.
Another way of writing the elements of a set is with the use of a descriptor. This is
the rule method. For example, H = {x| x covers and protects the head}. This is read
as “the set H contains the element x such that x covers and protects the head.”
2. The symbol or { } will be used to refer to an empty set.
3. If F is a subset of A, then we write . We also say that A contains the set F
and write it as . If F is a proper subset of A, then we write .
4. The cardinality of a set A is written as n(A).
II. Questions to Ponder (Post-Activity Discussion)
NOTE TO THE TEACHER:
It is important for you to go over the answers of your students to the
questions posed in the opening activity in order to process what they have
learned for themselves. Encourage discussions and exchanges in the
class. Do not leave questions unanswered.
Let us answer the questions posed in the opening activity.
1. How many sets are there?
There is the set of head covers (hats), the set of trees, the set of even numbers, and
the set of polyhedra. But, there is also a set of round objects and a set of pointy
objects. There are 6 well-defined sets.
2. Does each object belong to a set? Yes.
3. Is there an object that belongs to more than one set? Which ones are these?
All the hats belong to the set of round objects. The pine trees and two of the
polyhedra belong to the set of pointy objects.
III. Exercises
Do the following exercises. Write your answers on the spaces provided:
1. Give 3 examples of well-defined sets.
Possible answers: The set of all factors of 24, The set of all first year students
in this school, The set of all girls in this class.
2. Name two subsets of the set of whole numbers using both the listing or
roster method and the rule method.
Example:
Listing or Roster Method:
E = {0, 2, 4, 6, 8, ….}
O = {1, 3, 5, 7, …}
Rule Method:
E = {2x | x is a whole number}
O = {2x+1 | x is a whole number}
F A
A F F A
4. 3. Let B = [1, 3, 5, 7, 9}. List all the possible subsets of B.
{ }, {1}, {3}, {5}, {7}, {9}, {1, 3}, {1, 5}, {1, 7}, {1, 9}, {3, 5}, {3, 7}, {3, 9}, {5, 7}, {5,
9}, {7, 9}, {1, 3, 5}, {1, 3, 7}, {1, 3, 9}, {3, 5, 7}, {3, 5, 9}, {5, 7, 9}, {1, 5, 7}, {1, 5, 9},
{1, 7, 9}, {3, 7, 9}, {1, 3, 5, 7}, {1, 3, 5, 9}, {1, 5, 7, 9}, {3, 5, 7, 9}, {1, 3, 7, 9}, {1, 3,
5, 7, 9} – 32 subsets in all.
4. Answer this question: How many subsets does a set of n elements have?
There are 2n
subsets in all.
B. Venn Diagrams
NOTE TO THE TEACHER:
A lesson on sets will not be complete without using Venn Diagrams.
Note that in this lesson, you are merely introducing the use of these
diagrams to show sets and subsets. The extensive use of the Venn
Diagrams will be introduced in the next lesson, which is on set operations.
The key is for students to be able to verbalize what they see depicted in the
Venn Diagrams.
Sets and subsets may be represented using Venn Diagrams. These are diagrams
that make use of geometric shapes to show relationships between sets.
Consider the Venn diagram below. Let the universal set U be all the elements in sets
A, B, C and D.
Each shape represents a set. Note that although there are no elements shown inside
each shape, we can surmise or guess how the sets are related to each other.Notice
that set B is inside set A. This indicates that all elements in B are contained in A. The
same with set C. Set D, however, is separate from A, B, C. What does it mean?
Exercise
Draw a Venn diagram to show the relationships between the following pairs or
groups of sets:
D
A
C
5. 1. E = {2, 4, 8, 16, 32}
F = {2, 32}
Sample Answer
2. V is the set of all odd numbers
W = {5, 15, 25, 35, 45, 55,….}
Sample Answer
3. R = {x| x is a factor of 24}
S = { }
T = {7, 9, 11}
Sample Answer:
NOTE TO THE TEACHER:
End the lesson with a good summary.
Summary
In this lesson, you learned about sets, subsets, the universal set, the null set, and
the cardinality of the set. You also learned to use the Venn diagram to show
relationships between sets.
E
F
V
W
TR
S
6. Lesson 2.1: Union and Intersection of Sets Time: 1.5 hours
Pre-requisite Concepts: Whole Numbers, definition of sets, Venn diagrams
Objectives:
In this lesson, you are expected to:
1. describe and define
a. union of sets;
b. intersection of sets.
2. perform the set operations
a. union of sets;
b. intersection of sets.
3. use Venn diagrams to represent the union and intersection of sets.
Note to the Teacher:
Below are the opening activities for students. Emphasize that just like
with the whole number, operations are also used on sets. You may
combine two sets or form subsets. Emphasize to students that in counting
the elements of a union of two sets, elements that are common to both sets
are counted only once.
Lesson Proper:
I. Activities
A B
Answer the following questions:
1. Which of the following shows the union of set A and set B? How many
elements are in the union of A and B?
7. 1 2 3
2. Which of the following shows the intersection of set A and set B? How
many elements are there in the intersection of A
and B?
1 2 3
Here’s another activity:
Let
V = { 2x | x , 1 x 4}
W = {x2
| x , -2 x 2}
What elements are found in the intersection of V and W? How many are there? What
elements are found in the union of V and W? How many are there?
Do you remember how to use Venn Diagrams? Based on the diagram below, (1)
determine the elements that belong to both A and B; (2) determine the elements that
belong to A or B or both. How many are there in each set?
8. NOTE TO THE TEACHER:
Below are important terms, notations and symbols that
students must remember. From here on, be consistent in your notations as
well so as not to confuse your students. Give plenty of examples and non-
examples.
Important Terms/Symbols to Remember
The following are terms that you must remember from this point on.
1. Let A and B be sets. The union of sets A and B, denoted by A B, is the
set that contains those elements that are either in A or in B, or in both.
An element x belongs to the union of the sets A and B if and only if x
belongs to A or x belongs to B. This tells us that
A B = {x l x is in A or x is in B}
Venn diagram:
Note to the Teacher:
Explain to the students that in general, the inclusive OR is used in
mathematics. Thus, when we say, “elements belonging to A or B,” includes
the possibility that the elements belong to both. In some instances,
“belonging to both” is explicitly stated when referring to the intersection of
two sets. Advise students that from here onwards, OR is used inclusively.
2. Let A and B be sets. The intersection of sets A and B, denoted by A B, is
the set containing those elements in both A and B.
An element x belongs to the intersection of sets A and B if and only if x
belongs to A and x belongs to B. This tells us that
A B = {x l x is in A and x is in B}
U
A B
A
B
10
2
0
1
1
2
25
3
6
A B
9. Venn diagram:
Sets whose intersection is an empty set are called disjoint sets.
3. The cardinality of the union of two sets is given by the following equation:
n (A ∪ B) = n (A) + n (B) – n (A ∩ B ).
II. Questions to Ponder (Post-Activity Discussion)
NOTE TO THE TEACHER
It is important for you to go over the answers of your students posed
in the opening activities in order to process what they have learned for
themselves. Encourage discussions and exchanges in the class. Do not
leave questions unanswered. Below are the correct answers to the
questions posed in the activities.
Let us answer the questions posed in the opening activity.
1. Which of the following shows the union of set A and set B? Why?
Set 2. This is because it contains all the elements that belong to A or B
or both. There are 8 elements.
2. Which of the following shows the intersection of set A and set B?
Why? Set 3. This is because it contains all elements that are in both A
and B. There are 3 elements.
In the second activity:
V = { 2, 4, 6, 8 }
W = { 0, 1, 4}
Therefore, V W = { 4 } has 1 element and V W = { 0, 1, 2, 4, 6, 8 } has 6
elements. Note that the element { 4 } is counted only once.
On the Venn Diagram: (1) The set that contains elements that belong to both
A and B consists of two elements {1, 12 }; (2) The set that contains elements
that belong to A or B or both consists of 6 elements {1, 10, 12, 20, 25, 36 }.
NOTE TO THE TEACHER:
Always ask for the cardinality of the sets if it is possible to obtain such
number, if only to emphasize that
n (A B) ≠ n (A) + n (B)
U
A B
10. because of the possible intersection of the two sets. In the exercises
below, use every opportunity to emphasize this. Discuss the answers and
make sure students understand the “why” of each answer.
III. Exercises
1. Given sets A and B,
Set A
Students who play the
guitar
Set B
Students who play
the piano
Ethan Molina Mayumi Torres
Chris Clemente Janis Reyes
Angela Dominguez Chris Clemente
Mayumi Torres Ethan Molina
Joanna Cruz Nathan Santos
determine which of the following shows (a) union of sets A and B; and (b)
intersection of sets A and B?
Set 1 Set 2 Set 3 Set 4
Ethan Molina
Chris Clemente
Angela
Dominguez
Mayumi Torres
Joanna Cruz
Mayumi Torres
Ethan Molina
Chris Clemente
Mayumi Torres
Janis Reyes
Chris Clemente
Ethan Molina
Nathan Santos
Ethan Molina
Chris Clemente
Angela
Dominguez
Mayumi Torres
Joanna Cruz
Janis Reyes
Nathan Santos
Answers: (a) Set 4. There are 7 elements in this set. (b) Set 2. There are
3 elements in this set.
2. Do the following exercises. Write your answers on the spaces provided:
A = {0, 1, 2, 3, 4} B = {0, 2, 4, 6, 8} C = {1, 3, 5, 7, 9}
Answers:
Given the sets above, determine the elements and cardinality of:
a. A B = {0, 1, 2, 3, 4, 6, 8}; n (A B) = 7
b. A C = {0, 1, 2, 3, 4, 5, 7, 9}; n (A C) = 8
c. A B C = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9}; n (A B C) = 10
d. A B = {0, 2, 4}; n (A B) = 3
e. B C = Ø; n (B C ) = 0
f. A B C = Ø; n (A B C) = 0
g. (A B) C = {0, 1, 2, 3, 4, 5, 7, 9}; n ((A B) C) = 8
11. NOTE TO THE TEACHER:
In Exercise 2, you may introduce the formula for finding the
cardinality of the union of 3 sets. But, it is also instructive to give students
the chance to discover this on their own. The formula for finding the
cardinality of the union of 3 sets is:
n (A B C) = n (A) + n (B) + n (C) – n (A B) – n (A C) – n
(B C) + n (A B C).
3. Let W = { x | 0 < x < 3 }, Y = { x | x > 2}, and Z = {x | 0 x 4 }.
Determine (a) (W Y) Z; (b) W Y Z.
Answers:
Since at this point students are more familiar with whole numbers and
fractions greater than or equal to 0, use a partial real numberline to show
the elements of these sets.
(a) (W Y) Z = {x | 0 < x 4}
(b) W Y Z = {x | 2 < x < 3}
NOTE TO THE TEACHER:
End with a good summary. Provide more exercises on finding the
union and intersection of sets of numbers.
Summary
In this lesson, you learned about the definition of union and intersection of
sets. You learned also how to use Venn diagrams to represent the unions and the
intersection of sets.
12. Lesson 2.2: Complement of a Set Time: 1.5 hours
Pre-requisite Concepts: sets, universal set, empty set, union and intersection of
sets, cardinality of sets, Venn diagrams
About the Lesson:
The complement of a set is an important concept. There will be times when
one needs to consider the elements not found in a particular set A. You must know
that this is when you need the complement of a set.
Objectives:
In this lesson, you are expected to:
1. describe and define the complement of a set;
2. find the complement of a given set;
3. use Venn diagrams to represent the complement of a set.
NOTE TO THE TEACHER
Review the concept of universal set before introducing this lesson.
Emphasize to the students that there are situations when it is more helpful
to consider the elements found in the universal set that are not part of set
A.
Lesson Proper:
I. Problem
In a population of 8 000 students, 2 100 are Freshmen, 2 000 are
Sophomores, 2 050 are Juniors, and the remaining 1 850 are either in their
fourth or fifth year in university. A student is selected from the 8 000 students
and he/she is not a Sophomore, how many possible choices are there?
Discussion
Definition: The complement of set A, written as A’, is the set of all
elements found in the universal set, U, that are not found in set A. The
cardinality n (A’) is given by
n (A’) = n (U) – n (A) .
Examples:
1. Let U = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9}, and A = {0, 2, 4, 6, 8}.
U
A’
A
13. Then the elements of A’ are the elements from U that are not
found in A.
Therefore, A’ = {1, 3, 5, 7, 9}
2. Let U = {1, 2, 3, 4, 5}, A = {2, 4} and B = {1, 5}. Then,
A’ = {1, 3, 5}
B’ = {2, 3, 4}
A’ B’ = {1, 2, 3, 4, 5} = U
3. Let U = {1, 2, 3, 4, 5, 6, 7, 8}, A = {1, 2, 3, 4} and B = {3, 4, 7, 8}.
Then,
A’ = {5, 6, 7, 8}
B’ = {1, 2, 5, 6}
A’ B’ = {5, 6}
4. Let U = {1, 3, 5, 7, 9}, A = {5, 7, 9} and B = {1, 5, 7, 9}. Then,
A B = {5, 7, 9}
(A B)’ = {1, 3}
5. Let U be the set of whole numbers. If A = {x | x is a whole number
and x > 10}, then
A’ = {x | x is a whole number and 0 x 10}.
The opening problem asks for how many possible choices there are for a
student that was selected and known to be a non-Sophomore. Let U be the set of all
students and n (U) = 8 000. Let A be the set of all Sophomores then n (A) = 2 000.
Set A’ consists of all students in U that are not Sophomores and n (A’) = n (U) – n (A)
= 6 000. Therefore, there are 6000 possible choices for that selected student.
NOTE TO THE TEACHER:
Pay attention to how students identify the elements of the
complement of a set. Teach them that a way to check is to take the union of
a set and its complement. The union is the universal set U. That is, A A’ =
U. Have them recall as well that n (A A’) = n (A) + n (A’) – n (A A’) = n
(A) + n (A’) = n (U) since A A’ = and therefore, n (A A’) = 0.
In the activity below, use Venn diagrams to show how the
different sets relate to each other so that it is easier to identify unions and
intersections of sets and complements of sets or complements or unions
and intersections of sets. Watch as well the language that you use. In
particular, (A B)’ is read as “the complement of the union of A and B”
14. whereas A’ B’ is read as the union of the complement of A and the
complement of B.”
II. Activity
Shown in the table are names of students of a high school class by
sets according to the definition of each set.
A
Like Singing
B
Like Dancing
C
Like Acting
D
Don’t Like Any
Jasper
Faith
Jacky
Miguel
Joel
Charmaine
Leby
Joel
Jezryl
Jacky
Jasper
Ben
Joel
Billy
Ethan
Camille
Tina
After the survey has been completed, find the following sets:
a. U =
b. A B’ =
c. A’ C =
d. (B D)’ =
e. A’ B =
f. A’ D’ =
g. (B C)’ =
The easier way to find the elements of the indicated sets is to use a Venn
diagram showing the relationships of U, sets A, B, C, and D. Set D does not share
any members with A, B, and C. However, these three sets share some members.
The Venn diagram below is the correct picture:
15. A
B
C
Joel
Jacky
Jasper
Ben
Leby
Charmaine
Jezryl
Faith
Miguel
Billy
Ethan
Camille
Tina
U
Now, it is easier to identify the elements of the required sets.
a. U = {Ben, Billy, Camille, Charmaine, Ethan, Faith, Jacky, Jasper,
Jezryl, Joel, Leby, Miguel, Tina}
b. A B’ = {Faith, Miguel, Joel, Jacky, Jasper, Ben, Billy, Ethan,
Camille, Tina}
c. A’ C = {Jasper, Jacky, Joel, Ben, Leby, Charmaine, Jezryl, Billy,
Ethan, Camille, Tina}
d. (B D)’ = {Faith, Miguel, Jacky, Jasper, Ben}
e. A’ B = {Leby, Charmaine, Jezryl}
f. A’ D’ = {Leby, Charmaine, Jezryl, Ben}
g. (B C)’ = {Ben, Billy, Camille, Charmaine, Ethan, Faith, Jacky,
Jasper, Jezryl, Leby, Miguel, Tina}
NOTE TO THE TEACHER
Below are the answers to the exercises. Encourage
discussions among students. Take note of the language they use. It is
important that students say the words or phrases correctly. Whenever
appropriate, use Venn diagrams.
III. Exercises
1. True or False. If your answer is false, give the correct answer.
Let U = the set of the months of the year
X = {March, May, June, July, October}
Y = {January, June, July}
Z = {September, October, November, December}
16. a. Z’ = {January, February, March, April, May, June, July,
August} True
b. X’ Y’ = {June, July} False. X’ Y’ = {February,
April, August, September, November, December}
c. X’ Z’ = {January, February, March, April, May, June,
July, August, September, November, December} True
d. (Y Z)’ = {February, March, April, May} False. (Y
Z)’ = {February, March, April, May, August}.
NOTE TO THE TEACHER
The next exercise is a great opportunity for you to develop students’
reasoning skills. If the complement of A, the complement of B and the
complement of C all contain the element a then a is outside all three sets but
within U. If B’ and C’ both contain b but A’ does not, then A contains b. This
kind of reasoning must be clear to students.
2. Place the elements in their respective sets in the diagram below based
on the following elements assigned to each set:
U
A
B
C
a
b
c
d
e
f
g
h
i j
17. U = {a, b, c, d, e, f, g, h, i, j}
A’ = {a, c, d, e, g, j}
B’ = {a, b, d, e, h, i}
C’ = {a, b, c, f, h, i, j}
NOTE TO THE TEACHER:
In Exercise 3, there are many possible answers. Ask students to
show all their work. This is a good opportunity for them to argue and justify
their answers. Engage them in meaningful discussions. Encourage them to
explain their work. Help them decide which diagrams are correct.
3. Draw a Venn diagram to show the relationships between sets U, X, Y,
and Z, given the following information.
U, the universal set contains set X, set Y, and set Z.
X Y Z = U
Z is the complement of X.
Y’ includes some elements of X and the set Z
U
March May
June
July
October
X
Y
January
September
November
December
Z
February
April
August
18. NOTE TO THE TEACHER
End with a good summary.
Summary
In this lesson, you learned about the complement of a given set. You learned
how to describe and define the complement of a set, and how it relates to the
universal set, U, and the given set.
X
Z
Y
U
19. Lesson 3: Problems Involving Sets Time: 1 hour
Prerequisite Concepts: Operations on Sets and Venn Diagrams
Objectives:
In this lesson, you are expected to:
1. solve word problems involving sets with the use of Venn diagrams
2. apply set operations to solve a variety of word problems.
NOTE TO THE TEACHER
This is an important lesson. Do not skip it. This lesson reinforces
what students learned about sets, set operations and the Venn diagram in
solving problems.
Lesson Proper:
I. Activity
Try solving the following problem:
In a class of 40 students, 17 have ridden an airplane, 28 have ridden a
boat, 10 have ridden a train, 12 have ridden both an airplane and a
boat, 3 have ridden a train only, and 4 have ridden an airplane only.
Some students in the class have not ridden any of the three modes of
transportation and an equal number have taken all three.
a. How many students have used all three modes of transportation?
b. How many students have taken only the boat?
NOTE TO THE TEACHER
Allow students to write their own solutions. Allow them to discuss
and argue. In the end, you have to know how to steer them to the correct
solution.
II. Questions/Points to Ponder (Post-Activity Discussion)
Venn diagrams can be used to solve word problems involving union and
intersection of sets. Here are some worked out examples:
1. A group of 25 high school students was asked whether they use either
Facebook or Twitter or both. Fifteen of these students use Facebook, and
twelve use Twitter.
a. How many use Facebook only?
b. How many use Twitter only?
c. How many use both social networking sites?
Solution:
Let S1 = set of students who use Facebook only
S2 = set of students who use both social networking sites
S3 = set of students who use Twitter only
20. The Venn diagram is shown below
Finding the elements in each region:
The number of elements in each region is shown below
2. A group of 50 students went on a tour to Palawan. Out of the 50 students,
24 joined the trip to Coron; 18 went to Tubbataha Reef; 20 visited El Nido;
12 made a trip to Coron and Tubbataha Reef; 15 saw Tubbataha Reef and
El Nido; 11 made a trip to Coron and El Nido, and 10 saw the three tourist
spots.
a. How many of the students went to Coron only?
b. How many of the students went to Tubbataha Reef only?
c. How many joined the El Nido trip only?
d. How many did not go to any of the tourist spots?
Solution:
To solve this problem, let
P1 = students who saw the three tourist spots
P2 = those who visited Coron only
P3 = those who saw Tubbataha Reef only
n(S1) + n( S2) + n(S3) = 25
n(S1) + n( S2) = 15
______________________
n(S3) = 10
But n( S2) + n(S3) = 12
________________
n( S2) = 2
n(S1) + n( S2) + n(S3) = 25
n( S2) + n(S3) = 12
_______________________
n(S1) = 13
Facebook Twitter
S1 S3
S2
U
Facebook Twitter
13 2 10
21. P4 = those who joined the El Nido trip only
P5 = those who visited Coron and Tubbataha Reef only
P6 = those who joined the Tubbataha Reef and El Nido trip
only
P7 = those who saw Coron and El Nido only
P8 = those who did not see any of the three tourist spots
Draw the Venn diagram as shown below and identify the region where the
students went.
Determine the elements in each region starting from P1.
P1 consists of students who went to all three tourist spots. Thus, n(P1) = 10.
P1 P5 consists of students who visited Coron and Tubbataha Reef but this
set includes those who also went to El Nido. Therefore, n(P5) = 12 – 10 =
2 students visited Coron and Tubbatha Reef only.
P1 P6 consists of students who went to El Nido and Tubbataha Reef but
this set includes those who also went to Coron. Therefore, n(P6) = 15 –
10 = 5 students visited El Nido and Tubbataha Reef only.
P1 P7 consists of students who went to Coron and El Nido but this set
includes those who also went to Tubbataha Reef. Therefore, n(P7) = 11 –
10 = 1 student visited Coron and El Nido only.
From here, it follows that
n(P2) = 24 – n(P1) – n(P5) – n(P7) = 24 – 10 – 2 – 1 = 11 students
visited Coron only.
n(P3) = 18 – n(P1) – n(P5) – n(P6) = 18 – 10 – 2 – 5 = 1 student visited
Tubbataha Reef only
n(P4) = 20 – n(P1) – n(P6) – n(P7) = 20 – 10 – 5 – 1 = 4 students
visited Coron and El Nido only.
Therefore
n(P8) = 50 – n(P1) – n(P2) – n(P3) – n(P4) – n(P5) – n(P6) – n(P7) = 16
students did not visit any of the three spots.
The number of elements is shown below.
Coron El Nido
P8 Tubbataha Reef
P5 P1
P6
P3
P2
P7 P4
22. Now, what about the opening problem? Solution to the Opening Problem
(Activity):
Can you explain the numbers?
III. Exercises
Do the following exercises. Represent the sets and draw a Venn diagram
when needed.
1. If A is a set, give two subsets of A. Answer: and A
2. (a) If and are finite sets and , what can you say about the
cardinalities of the two sets?
(b) If the cardinality of is less than the cardinality of , does it follow
that ?
Answer: (a) ; (b) No. Example:
3. If A and B have the same cardinality, does it follow that A = B? Explain.
Answer: Not necessarily. Example, A = {1, 2, 3} and B = {4, 8, 9}.
4. If and . Does it follow that ? Illustrate your reasoning
using a Venn diagram. Answer: Yes.
148
A B
3
4
21
4
4
T
Coron El Nido
16 Tubbataha Reef
11
1 4
2 10
5
1
NOTE TO THE TEACHER
Discuss the solution thoroughly and clarify all questions your
students might have. Emphasize the notation for the cardinality of a
set.
23. 5. Among the 70 kids in Barangay Magana, 53 like eating in Jollibee, while
42 like eating in McDonalds. How many like eating both in Jollibee and
McDonalds? In Jollibee only? In McDonalds only?
Solution:
Let n(M1) = kids who like Jollibee only
n(M2) = kids who like both Jollibee and McDonalds
n(M3) = kids who like McDonalds only
Draw the Venn diagram
Find the elements in each region
n(M1) + n(M2) + n(M3) = 70
n(M1) + n(M2) = 53
_______________________
n(M3) = 17
But n(M2) + n(M3) = 42
_______________________
n(M2) = 25
n(M1) + n(M2) + n(M3) = 70
n(M2) + n(M3) = 42
_______________________
n(M1) = 28
Check using Venn diagram
Jollibee McDonalds
M1 M2 M3
A B
C
24. 6. The following diagram shows how all the First Year students of
Maningning High School go to school.
a. How many students ride in a car, jeep and the MRT in going to
school? 15
b. How many students ride both in a car and a jeep? 34
c. How many students ride both in a car and the MRT? 35
d. How many students ride both in a jeep and the MRT? 32
e. How many students go to school
in a car only? 55 in a jeep only? 76
in the MRT only? 67 walking? 100
f. How many First Year students of Maningning High School are
there in all? 269
7. The blood-typing system is based on the presence of proteins called
antigens in the blood. A person with antigen A has blood type A. A person
with antigen B has blood type B, and a person with both antigens A and B
has blood type AB. If no antigen is present, the blood type is O. Draw a
Venn diagram representing the ABO System of blood typing.
A protein that coats the red blood cells of some persons was discovered
in 1940. A person with this protein is classified as Rh positive (Rh+), and
a person whose blood cells lack this protein is Rh negative (Rh–). Draw a
Walking 100 Jeep
Car
MRT
Facebook Twitter
28 25 17
19
55 15
76
17
20
67
25. Venn diagram illustrating all the blood types in the ABO System with the
corresponding Rh classifications.
Summary
In this lesson, you were able to apply what you have learned about sets, the
use of a Venn diagram, and set operations in solving word problems.
NOTE TO THE TEACHER
The second problem is quite
complex. Adding the 3rd set Rh
captures the system without
altering the original diagram in the
first problem.
A
B
Rh
A+
A–
B+
AB+
O+
B–AB–
O–
A BAB
O
26. Lesson 4.1: Fundamental Operations on Integers: Addition of Integers
Time: 1 hour
Pre-requisite Concepts: Whole numbers, Exponents, Concept of Integers
Objectives:
In this lesson, you are expected to:
1. add integers using different approaches;
2. solve word problems involving addition of integers.
NOTE TO THE TEACHER
This lesson is a review and deepening of the concept of addition of
integers. Keep in mind that the definitions for the operations on integers
must retain the properties of the same operations on whole numbers or
fractions. In this sense, the operations are merely extended to cover a
bigger set of numbers. We present here two models for addition that are
used to represent addition of whole numbers.
Lesson Proper:
I. Activity
Study the following examples:
A. Addition Using Number Line
1. Use the number line to find the sum of 6 & 5.
On the number line, start with point 6 and count 5 units to the right. At what
point on the number line does it stop ?
It stops at point 11; hence, 6 + 5 = 11.
2. Find the sum of 7 and (-3) .
On the number line, start from 7 and count 3 units going to the left since the
sign of 3 is negative.
At which point does it stop?
It stops at point 4; hence, (-3) + (7) = 4.
After the 2 examples, can you now try the next two problems?
a. (-5) + (-4) b. (-8) + (5)
27. NOTE TO THE TEACHER
More examples may be given to emphasize an interpretation of the
negative sign as a direction to the left of the number line.
We now have the following generalization:
Adding a positive integer to means moving along the real line a distance of
units to the right from . Adding a negative integer – to means moving along the
real line a distance of units to the left from .
NOTE TO THE TEACHER
Other objects might be used in this next activity. Signed tiles could be
algebra tiles or counters with different colors on each side. Bottle caps are
easily obtained and will be very good visual and hands-on materials.
B. Addition Using Signed Tiles
This is another device that can be used to represent integers.The tile
represents integer 1, the tile represents -1, and the flexible + - represents
0.
Recall that a number and its negative cancel each other under the operation of
addition. This means
In general, .
NOTE TO THE TEACHER
Get the students to model the above equations using signed tiles or
colored counters.
Examples:
1. 4 + 5 ------
hence, 4 + 5 = 9
2. 5 + (-3) -----
hence,
+
-
28. 3.
hence
Now, try these:
1. (-5) + (-11)
2. (6) + (-9)
Solution:
1. (–5) + (–11)
hence, (–5) + (–11) = –16.
2. (6) + (–9)
hence, (6) + (–9) = –3.
If colored counters (disks) or bottle caps are used, one side of the counter denotes
“positive,” while the other side denotes “negative.” For example, with counters having
black and red sides, black denotes “positive,” while red denotes “negative.” For this
module, we will use white instead of red to denote negative.
Examples:
1. The configurations below represent
Keeping in mind that a black disk and a white disk cancel each other, take out
pairs consisting of a black and a white disk until there are no more pairs left.
29. This tells us that
2. Give a colored-counter representation of
Therefore,
The signed tiles model gives us a very useful procedure for adding large integers
having different signs.
Examples:
1.
Since 63 is bigger than 25, break up 63 into 25 and 38.
Hence
2.
II. Questions/ Points to Ponder
Using the above model, we summarize the procedure for adding integers as follows:
1. If the integers have the same sign, just add the positive equivalents of the
integers and attach the common sign to the result.
a. 27 + 30 = + (/27/ + /30/)
= + ( /57/ )
= + 57
b. (-20) + (-15) = - (/20/ + /15/)
= - ( 20 + 15 )
= - ( 35 )
= - 35
30. 2. If the integers have different signs, get the difference of the positive
equivalents of the integers and attach the sign of the larger number to the
result.
a. (38) + (-20)
Get the difference between 38 and 20: 18
Since 38 is greater than 20, the sign of the sum is positive.
Hence
b.
Get the difference between 42 and 16: 26
Since 42 is greater than 16, the sum will have a negative sign.
Hence
NOTE TO THE TEACHER
Provide more examples as needed.
If there are more than two addends in the problem, the first step to do is to combine
addends with the same signs and then get the difference of their sums.
Examples:
1.
2.
III. Exercises
A. Who was the first English mathematician who first used the modern
symbol of equality in 1557?
(To get the answer, compute the sums of the given exercises below.
Write the letter of the problem corresponding to the answer found in
each box at the bottom).
A 25 + 95 C. (30) + (-20) R 65 + 75
B 38 + (-15) D. (110) + (-75) O (-120) + (-35)
O 45 + (-20) T. (16) + (-38) R (165) + (-85)
R (-65) + (-20) R (-65) + (-40) E 47 + 98
E (78) + (-15) E (-75) + (20)
Answer: ROBERT RECORDE
31. B. Addthe following:
1. (18) + (-11) + (3)
2. (-9) + (-19) + (-6)
3. (-4) + (25) + (-15)
4. (50) + (-13) + (-12)
5. (-100) + (48) + (49)
Answers:
1. 10 2. –34 3. 6 4. 25 5. –3
C. Solve the following problems:
1. Mrs. Reyes charged P3,752.00 worth of groceries on her credit
card. Find her balance after she made a payment of P2,530.00.
Answer: PhP1,222.00
2. In a game, Team Azcals lost 5 yards in one play but gained 7 yards
in the next play. What was the actual yardage gain of the
team?Answer: (-5) + 7 = 2 yards
3. A vendor gained P50.00 on the first day; lost P28.00 on the second
day, and gained P49.00 on the third day. How much profit did the
vendor gain in 3 days?Answer: 50 + (-28) + 49 = 71. Profit is
PhP71.00
4. Ronnie had PhP2280 in his checking account at the beginning of
the month. He wrote checks for PhP450, P1200, and PhP900. He
then made a deposit of PhP1000. If at any time during the month
the account is overdrawn, a PhP300 service charge is deducted.
What was Ronnie’s balance at the end of the month?
Answer: 2 280 + (-450) + (-1 200) + (-900) = -270
(-270) + (-300) + 1 000 = 430
Balance is PhP430.00
NOTE TO THE TEACHER
Summarize the two models used in this lesson. It is always good to
keep these models in mind, but make sure that students learn to let go of
these models and should be able to add integers eventually even without
these models.
Summary
In this lesson, you learned how to add integers using two different methods.
The number line model is practical for small integers. For larger integers, the signed
tiles model is a more useful tool.
32. Lesson 4.2: Fundamental Operation on Integers:Subtraction of Integers
Time: 1 hour
Prerequisite Concepts: Whole numbers, Exponents, Concept of Integers, Addition
of Integers
About the Lesson: This lesson focuses on the subtraction of integers using
different approaches. It is a review of what the students learned in Grade 6.
Objectives:
In this lesson, you are expected to:
1. subtract integers using
a. number line
b. signed tiles
2. solve problems involving subtraction of integers.
NOTE TO THE TEACHER
This lesson is a continuation of lesson 4.1 in a sense that mastery of
the law of signs in addition of integers makes subtraction easy for the
learners. Emphasis must be given on how the law of signs in addition is
connected to that of subtraction.
Lesson Proper:
I. Activity
Study the material below.
1. Subtraction as the reverse operation of addition.
Recall how subtraction is defined. We have previously defined subtraction as
the reverse operation of addition. This means that when we ask “what is 5
minus 2?”, we are also asking “what number do we add to 2 in order to get
5?” Using this definition of subtraction, we can deduce how subtraction is
done using the number line.
a. Suppose you want to compute . You ask “What number must be
added to 3 to get ?”
To get from 3 to , you need to move 7 units to the left. This is
equivalent to adding to 3. Hence in order to get , must be
added to 3. Therefore,
b. Compute
33. What number must be added to to get ?
To go from to , move 4 units to the right, or equivalently, add 4.
Therefore,
2. Subtraction as the addition of the negative
Subtraction is also defined as the addition of the negative of the number. For
example, . Keeping in mind that and are negatives of
each other, we can also have . Hence the examples above
can be solved as follows:
This definition of subtraction allows the conversion of a subtraction problem
to an addition problem.
NOTE TO THE TEACHER
You need to follow up on the opening activity, hence the problem
below is important to reinforce what was discussed.
Problem:
Subtract (-45) from 39 using the two definitions of subtraction.
Can you draw your number line?Where do you start numbering it to make the
line shorter?
Solution:
1.
What number must be added to in order to obtain 39?
34. 2.
II. Questions/Points to Ponder
Rule in Subtracting Integers
In subtracting integers, add the negative of the subtrahend to the minuend,
NOTE TO THE TEACHER
Give more examples as needed. The next section relies on the use
of colored counters or signed tiles. Study the material so that you will be
able to guide your students in understanding the use of these tiles
correctly.
Using signed tiles or colored counters
Signed tiles or colored counters can also be used to model subtraction of integers. In
this model, the concept of subtraction as “taking away” is utilized.
Examples:
1. means take away 6 from 10. Hence
2.
35. 3.
4.
Hence
The last two examples above illustrate the definition of subtraction as the addition of
the negative.
Since there are not enough counters from which to take
away 9, we add 9 black counters and 9 white counters.
Remember that these added counters are equivalent to zero.
We now take
away 9 black
counters.
Notice that this configuration is the
same configuration for .
We proceed with the addition and
obtain the answer
36. III. Exercices
A. What is the name of the 4th highest mountain in the world?
(Decode the answer by finding the difference of the following subtraction
problems. Write the letter to the answer corresponding to the item in the box
provided below:
O Subtract (-33) from 99
L Subtract (-30) from 49
H 18 less than (-77)
E Subtract (-99) from 0
T How much is 0 decreased by (-11)?
S (-42) – (-34) – (-9) - 18
79 -95 132 11 -17 99
Answer: LHOTSE
B. Mental Math
Give the difference:
1. 53 -25 6. 25 - 43
2. (-6) - 123 7. (-30) - (-20)
3. (-4) - (-9) 8. (-19) - 2
4. 6 - 15 9. 30 –(-9)
5. 16 - (-20) 10. (-19) - (-15)
C. Solve the following problems:
1. Maan deposited P53,400.00 in her account and withdrew P19,650.00 after
a week. How much of her money was left in the bank?
Answer: PhP33,750.00
2. Two trains start at the same station at the same time. Train A travels
92km/h, while train B travels 82km/h. If the two trains travel in opposite
directions, how far apart will they be after an hour? If the two trains travel
in the same direction, how far apart will they be in two hours?
Answer: 92 - (-82) = 174 km apart
2×92-2×82 = 20 km apart
3. During the Christmas season, the student gov’t association was able to
solicit 2 356 grocery items and distribute 2 198 grocery items to one
barangay. If this group decides to distribute 1 201 grocery items to the
next barangay, how many more grocery items do they need to solicit?
Answer: 2 356 – 2 198 = 158 left after the first barangay
1 201 – 158 = 1 043 needed for the second barangay
Answers:
1. 28 2. –129 3. 5 4. –9 5. 36
6. –18 7. –10 8. –21 9. 39 10. –4
37. NOTE TO THE TEACHER
To end, emphasize the new ideas that this lesson discussed,
particularly the new concepts of subtraction and how these concepts allow
the conversion of subtraction problems to addition problems.
Summary
In this lesson, you learned how to subtract integers by reversing the process
of addition, and by converting subtraction to addition using the negative of the
subtrahend.
38. Lesson 4.3: Fundamental Operations on Integers: Multiplication of Integers
Time: 1 hour
Prerequisite Concepts: Operations on whole numbers, addition and subtraction of
integers
About the Lesson: This is the third lesson on operations on integers. The intent of
the lesson is to deepen what students have learned in Grade 6, by
expounding on the meaning of multiplication of integers.
Objective:
In this lesson; you are expected to:
1. multiply integers
2. apply multiplication of integers in solving problems.
NOTE TO THE TEACHER
The repeated addition model for multiplication can be extended to
multiplication of two integers in which one of the factors is positive.
However, for products in which both factors are negative, repeated addition
does not have any meaning. Hence multiplication of integers will be
discussed in two parts: the first part looks into products with at least one
positive factor, while the second studies the product of two negative
integers.
Lesson Proper:
I. Activity
Answer the following question.
How do we define multiplication?
We learned that with whole numbers, multiplication is repeated addition. For
example, means three groups of 4. Or, putting it into a real context, 3 cars
with 4 passengers each, how many passenger in all? Thus
But, if there are 4 cars with 3 passengers each, in counting the total number of
passengers, the equation is . We can say then that
and
We extend this definition to multiplication of a negative integer by a positive integer.
Consider the situation when a boy loses P6 for 3 consecutive days.His total loss for
three days is
. Hence, we could have
39. II. Questions/Points to Ponder
The following examples illustrate further how integers are multiplied.
Example 1. Multiply : 5 ×(-2)
However,
5 × (-2) = (-2) × (5)
Therefore:
(-2) × (5)= (-2) + (-2) + (-2) + (-2) + (-2) = -10
The result shows that the product of a negative multiplier and a positive multiplicand
is a negative integer.
Generalization: Multiplying unlike signs
We know that adding negative numbers means adding their positive equivalents
and attaching the negative sign to the result, then
for any positive integers and .
We know that any whole number multiplied by 0 gives 0. Is this true for any integer
as well? The answer is YES. In fact, any number multiplied by 0 gives 0. This is
known as the Zero Property.
FOR THE TEACHER: PROOF OF THE ZERO PROPERTY
Since 1 is the identity for multiplication, for any integer a, a×1=a.
The identity for addition is 0, so a×1=a×(1+0)=a .
By the distributive law, a×(1+0)=a×1+a×0=a.
Hence a+a×0=a.
Now 0 is the only number which does not change a on addition.
Therefore a×0=0.
What do we get when we multiply two negative integers?
Example 2. Multiply: (-8) × (-3)
We know that .
Therefore,
(Distributive Law)
( and are additive inverses)
(Zero Property)
The only number which when added to gives 0 is the additive
inverse of . Therefore, is the additive inverse of 24,
or
The result shows that the product of two negative integers is a positive integer.
40. NOTE TO THE TEACHER
The above argument can be generalized to obtain the product (-a)×(-
b). The proof may be presented to more advanced students.It is important
to note that the definition of the product of two negative integers is not
based on the same model as the product of whole numbers (i.e., repeated
addition). The basis for the definition of the product of two negative
numbers is the preservation of the properties or axioms of whole number
operations (distributive law, identity and inverse property).
Generalization: Multiplying Two Negative Integers
If and are positive integers, then .
Rules in Multiplying Integers:
In multiplying integers, find the product of their positive equivalents.
1. If the integers have the same signs, their product is positive.
2. If the integers have different signs, their product is negative.
III. Exercises
A. Find the product of the following:
1. (5)(12)
2. (-8)(4)
3. (-5)(3)(2)
4. (-7)(4)(-2)
5. (3)(8)(-2)
6. (9)(-8)(-9)
7. (-9)(-4)(-6)
MATH DILEMMA
B. How can a person fairly divide 10 apples among 8 children so that each
child has the same share?
To solve the dilemma, match the letter in Column II with the number that
corresponds to the numbers in Column I.
Column I Column II
1. (6)(-12) C 270
2. (-13)(-13) P -72
3. (19)(-17) E 300
4. (-15)(29) K -323
5. (165)(0) A -435
6. (-18)(-15) M 0
7. (-15)(-20) L 16
8. (-5)(-5)(-5) J -125
9. (-2)(-2)(-2)(-2) U 169
10. (4)(6)(8) I 192
Answers:
1. 60 2. –32 3. –30 4. 56
5. –48 6. 648 7. –216
41. C. Problem Solving
1. Jof has twenty P5 coins in her coin purse. If her niece took 5 of
the coins, how much has been taken away?
Answer: PhP25
2. Mark can type 45 words per minute, how many words can Mark
type in 30 minutes?
Answer: 1 350 words
3. Give an arithmetic equation which will solve the following
a. The messenger came and delivered 6 checks worth
PhP50 each. Are you richer or poorer? By how much?
b. The messenger came and took away 3 checks worth
PhP120 each. Are you richer or poorer? By how much?
c. The messenger came and delivered 12 bills for PhP86
each. Are you richer or poorer? By how much?
d. The messenger came and took away 15 bills for PhP72
each. Are you richer or poorer? By how much?
Answers:
a. Richer by PhP300
b. Poorer by PhP360
c. Poorer by PhP1,032
d. Richer by PhP1,080
NOTE TO THE TEACHER
Give additional problems and drills, if only to reinforce the rules for
multiplying integers. Summarize by emphasizing as well the different types
of problems given in this lesson.
Summary
This lesson emphasized the meaning of multiplication to set the rules for
multiplying integers. To multiply integers, first find the product of their positive
equivalents. If the integers have the same signs, their product is positive. If the
integers have different signs, their product is negative.
Answer: MAKE APPLE JUICE
_____
5
_____
4
_____
3
_____
7
_____
4
_____
1
_____
1
_____
9
_____
7
_____
8
_____
2
_____
10
_____
6
_____
7
42. Lesson 4.4: Fundamental Operations on Integers: Division of Integers
Time: 1 hour
Prerequisite Concepts: Addition and subtraction of Integers, Multiplication of
Integers
Objective:
In this lesson you are expected to:
1. find the quotient of two integers
2. solve problems involving division of integers.
NOTE TO THE TEACHER
This is a short lesson because the sign rules for division of integers
are the same as with the multiplication of integers. Division is to be
understood as the reverse operation of multiplication, hence making the
rules the same with respect to the sign of the quotient.
Lesson Proper:
I. Activity
Answer the following questions:
What is (-51) ÷ (-3)?
What is (-51) ÷ 3?
What is 51 ÷ (-3)?
What are the rules in dividing integers?
II. Questions/Points to Ponder
We have learned that Subtraction is the inverse operation of Addition,
In the same manner, Division is the inverse operation of Multiplication.
Example 1.Find the quotient of (-51) and (-3)
Solution:
Since division is the inverse of multiplication, determine what number
multiplied by (-3) produces (-51).
If we ignore the signs for the meantime, we know that
We also know that in order to get a negative product, the factors must
have different signs. Hence
Therefore
(-51) ÷ (-3) = 17
Example 2. What is
Solution:
Hence
Therefore
NOTE TO THE TEACHER
This exercise
emphasizes the need to
remember the sign rules for
dividing integers.
43. Example 3.Show why 273 ÷ (–21) = –13.
Solution: (-13) × (-21) = 57
Therefore, 273 ÷ (–21) = –13
NOTE TO THE TEACHER
It is important to give more examples to students. Always, ask
students to explain or justify their answers.
Generalization
The quotient of two integers with the same signs is a positive integer, and the
quotient of two integers having unlike signs is a negative integer.However,
division by zero is not possible.
NOTE TO THE TEACHER
Since we introduced division as the reverse operation of
multiplication, it is now easy to show why division by 0 is not possible.
What is (-10) ÷ 0? Because division is the reverse of multiplication, we
must find a number such that when multiplied by 0 gives -10. But, there is
no such number. In fact, no number can be divided by 0 for the same
reason.
When several operations have to be performed, the GEMDAS rule applies.
Example 4. Perform the indicated operations
1.
2.
3.
Solution:
1.
2.
3.
III. Exercises:
A. Compute the following
1.
2.
3.
4.
5.
B. What was the original name for the butterfly?
To find the answer, find the quotient of each of the following. Then
write the letter of the problems in the box corresponding to the quotient.
Answers:
1. –1 2. –73 3. 26 4. –4 5. 8
44. Answer: Flutterby
C. Solvethe following problems:
1. Vergara’s store earned P8,750 a week, How much is her average
earning in a day? Answer: PhP1,250.00 (8750 ÷ 7 = 1250)
2. Russ worked in a factory and earned P7,875.00 for 15 days. How
much is his earning in a day? Answer: PhP525.00 (7875 ÷ 15 =
525)
3. There are 336 oranges in 12 baskets. How many oranges are there in
3 baskets? Answer: 84 oranges (336 ÷ 12 × 3 = 84)
4. A teacher has to divide 280 pieces of graphing paper equally among
his 35 students. How many pieces of graphing paper will each student
recieve? Answer: 8 (280 ÷ 35 = 8)
5. A father has 976 sq meters lot; he has to divide it among his 4
children. What is the share of each child? Answer: 244 sq meters
(976 ÷ 4 = 244)
D. Complete the three-by-three magic square (that is, the sums of the numbers
in each row, in each column and in each of the diagonals are the same) using
the numbers -10, -7, -4, -3, 0, 3, 4, 7, 10. What is the sum for each row,
column, and diagonal line?
9 37 -15 -8 -8 28 -16 12 -48
R (-352) ÷
22
L(128) ÷ -
16
(168) ÷ 6E(144) ÷ -3
(108) ÷ 9B
(-315) ÷ (-
35)
(-147) ÷ 7T F
(-120) ÷ 8U
T (-444) ÷ (-12)
Y
45. Answer: The sum of all the numbers is 0. Hence each
column/row/diagonal will have a sum of . Put 0 in the
middle square. Put each number and its negative on either side of
0. A possible solution is
7 10 3
–4 0 4
–3 –10 –7
Summary
Division is the reverse operation of multiplication. Using this definition, it is
easy to see that the quotient of two integers with the same signs is a positive integer,
and the quotient of two integers having unlike signs is a negative integer.
46. Lesson 5: Properties of the Operations on Integers Time: 1.5 hours
Prerequisite Concepts: Addition, Subtraction, Multiplication and Division of
Integers
Objectives
In this lesson, you are expected to:
1. state and illustrate the different properties of the operations on
integers
a. closure d. distributive
b. commutative e. identitiy
c. associative f. inverse
2. rewrite given expressions according to the given property.
NOTE TO THE TEACHER:
Operations on integers are some of the difficult topics in elementary
algebra, and one of the least mastered skills of students based on
research. The different activities presented in this lesson will hopefully
give the students a tool for creating their own procedures in solving
equations involving operations on integers. These are the basic rules of
our system of algebra and they will be used in all succeeding
mathematics. It is very important that students understand how to apply
each property when solving math problems.
In activities 1 and 2, try to test the students’ ability to give
corresponding meaning to the different words exhibited and later on
relate said terms to the lesson. In addition, students can show some
creativity in activity 2.
Lesson Proper:
I. A. Activity 1: Try to reflect on these . . .
1. Give at least 5 words synonymous to the word “property”.
Activity 2: PICTIONARY GAME: DRAW AND TELL!
47. The following questions will be answered as you go along to the next activity.
What properties of real numbers were shown in the Pictionary Game?
Give one example and explain.
How are said properties seen in real life?
NOTE TO THE TEACHER
Activity 3 gives a visual presentation of the properties.
Activity 3: SHOW AND TELL!
Determine what kind of property of real numbers is illustrated in the following
images:
A. Fill in the blanks with the correct numerical values of the motorbike and bicycle
riders.
_______ _______
If a represents the number of motorbike riders and b represents the
number of bicycle riders, show the mathematical statement in a the
diagram below.
_______ + _______ = _______ + _______
Expected Answer: a + b = b + a
Guide Questions:
What operation is used in illustrating the diagram? Addition
What happened to the terms in both sides of the equation? The terms
were interchanged.
Based on the previous activity, what property is applied?
+
48. Commutative Property of Addition: For integers a, b, a + b = b + a
If the operation is replaced by multiplication, will the same property be
applicable? Give an example to prove your answer.
2 • 3 = 3 • 2
6 = 6
Commutative Property of Multiplication: For integers a, b, ab = ba
Define the property.
Commutative Property
Changing the order of two numbers that are either being added or
multiplied does not change the result.
Give a real life situation in which the commutative property can be
applied.
An example is preparing fruit juices - even if you put the powder first
before the water or vice versa, the product will still be the same. It’s
still the same fruit juice.
Test the property on subtraction and division operations by using simple
examples. What did you discover?
Commutative property is not applicable to subtraction and division as
shown in the following examples:
6 – 2 = 2 – 6 6 ÷ 2 = 2 ÷ 6
4 ≠ -4 3 ≠
B. Fill in the blanks with the correct numerical values of the set of cellphones,
ipods, and laptops.
_______ _______ _______
+ +
equals
+ +
49. If a represents the number of cellphones, b represents the ipods, and c
represents the laptops, show the mathematical statement in the diagram below.
(_______ + _______ ) +_______ = _______ + (_______ + _______ )
Expected Answer: (a + b) + c = a + (b + c)
Guide Questions:
What operation is used in illustrating the diagram? Addition
What happened to the groupings of the given sets that correspond to both
sides of the equation? The groupings were changed.
Based on the previous activity, what property is applied?
Associative Property of Addition
For integers a, b and c, (a + b) + c = a + (b + c)
If the operation is replaced by multiplication, will the same property be
applicable? Give an example to prove your answer.
(2 • 3) • 5 = 3 • (2 • 5)
6 • 5 = 3 • 10
30 = 30
Associative Property of Multiplication
For integers a, b and c, (a• b)c = a(b• c)
Define the property.
Associative Property
Changing the grouping of numbers that are either being added or
multiplied does not change its value.
Give a real life situation wherein associative property can be applied.
An example is preparing instant coffee – even if you combine coffee
and creamer then sugar or coffee and sugar then creamer the result
will be the same – 3-in-1coffee.
Test the property on subtraction and division operations by using simple
examples. What did you discover?
Associative property is not applicable to subtraction and division as
shown in the following examples:
(6 – 2) – 1 = 6 – (2 – 1) (12 ÷ 2) ÷ 2 = 12 ÷ (2 ÷
2)
4 – 1 = 6 – 1 6 ÷ 2 = 12 ÷ 1
3 ≠ 5 3 ≠12
50. C. Fill in the blanks with the correct numerical values of the set of oranges and
the set of strawberries.
_______ _______
_______ _______
If a represents the multiplier in front, b represents the set of oranges and
c represents the set of strawberries, show the mathematical statement in
the diagram below.
_______ (_______+_______) = ______ • _______ + _______• ______
Answer: a(b + c) = ab + ac
Guide Questions:
Based on the previous activity, what property is applied in the images
presented?
Distributive Property
For any integers a, b, c, a(b + c) = ab + ac
For any integers a, b, c, a(b - c) = ab - ac
Define the property.
Distributive Property
When two numbers have been added / subtracted and
then multiplied by a factor, the result will be the same
+2 ×
equals
+2 ×
51. when each number is multiplied by the factor and the
products are then added / subtracted.
In the said property can we add/subtract the numbers inside the
parentheses and then multiply or perform multiplication first and then
addition/subtraction? Give an example to prove your answer.
In the example, we can either add or subtract the numbers inside the
parentheses first and then multiply the result; or, we can multiply
each term separately and then add/ subtract the two products
together. The answer is the same in both cases as shown below.
Give a real life situation where the distributive property can be applied.
Your mother gave you four 5-peso coins and your grandmother gave
you four 20-peso bills. You now have PhP20 worth of 5-peso coins
and PhP80 worth of 20-peso bill. You also have four sets of PhP25
each consisting of a 5-peso coin and a 20-peso bill.
D. Fill in the blanks with the correct numerical representation of the given
illustration.
_______ _______ _______
Answer: a + 0 = a
Guide Questions:
Based on the previous activity, what property is applied in the images
presented?
Identity Property for Addition
a + 0 = a
-2(4 + 3) = (-2 • 4) + (-2 • 3)
-2(7) = (-8) + (-6)
-14 = -14
or
-2(4 + 3) = -2(7)
-2(7) = -14
-14 = -14
52. What is the result if you add something represented by any number to
nothing represented by zero? The result is the non-zero number.
What do you call zero “0” in this case? Zero, “0” is the additive identity.
Define the property.
Identity Property for Addition states that 0 is the additive identity, that
is, the sum of any number and 0 is the given number.
Is there a number multiplied to any number that will result to that same
number? Give examples.
Yes, the number is 1.
Examples: 1•2=2 1•3=2 1•4=2
What property is illustrated? Define.
Identity Property for Multiplication says that 1 is the Multiplicative
Identity
- the product of any number and 1 is the given number, a 1 = a.
What do you call one “1” in this case?
One, “1” is the multiplicative identity
E. Give the correct mathematical statement of the given illustrations. To do this,
refer to the guide questions below.
Guide Questions:
How many cabbages are there in the crate? 14 cabbages
PUT IN
PLUS
REMOVE
E
53. Using integers, represent “put in 14 cabbages” and “remove 14
cabbages”? What will be the result if you add these representations?
(+14) + (-14) = 0
Based on the previous activity, what property is applied in the images
presented?
Inverse Property for Addition
a + (-a)= 0
What is the result if you add something to its negative? The result is
always zero.
What do you call the opposite of a number in terms of sign? What is the
opposite of a number represented by a?
Additive Inverse. The additive inverse of the number a is –a.
Define the property.
Inverse Property for Addition
- states that the sum of any number and its additive inverse or its
negative, is zero.
What do you mean by reciprocal, and what is the other term used for it?
The reciprocal is 1 divided by that number or the fraction
a
1
, where a
represents the number.
The reciprocal of a number is also known as its multiplicative
inverse.
If you multiply a number say 5 by its multiplicative inverse , what is the
result? 5 • = 1
What property is illustrated? Define this property.
Inverse Property for Multiplication
- states that the product of any number and its multiplicative
inverse or reciprocal, is 1.
For any number a, the multiplicative inverse is
a
1
.
Important Terms to Remember
The following are terms that you must remember from this point on.
1. Closure Property
Two integers that are added and multiplied remain as integers. The set of
integers is closed under addition and multiplication.
2. Commutative Property
Changing the order of two numbers that are either added or multiplied
does not change the value.
3. Associative Property
Changing the grouping of numbers that are either added or multiplied
does not change its value.
4. Distributive Property
54. When two numbers are added / subtracted and then multiplied by a
factor, the result is the same when each number is multiplied by the factor
and the products are then added / subtracted.
5. Identity Property
Additive Identity
- states that the sum of any number and 0 is the given number. Zero,
“0” is the additive identity.
Multiplicative Identity
- states that the product of any number and 1 is the given number, a • 1
= a. One, “1” is the multiplicative identity.
6. Inverse Property
In Addition
- states that the sum of any number and its additive inverse, is zero.
The additive inverse of the number a is –a.
In Multiplication
- states that the product of any number and its multiplicative inverse or
reciprocal, is 1.The multiplicative inverse of the number a is
a
1
.
Notations and Symbols
In this segment, you will learn some of the notations and symbols pertaining to
properties of real number applied in the operations of integers.
Closure Property under addition and
multiplication
a, b I, then a+b I,
a • b I
Commutative property of addition
a + b = b + a
Commutative property of multiplication
ab = ba
Associative property of addition
(a + b) + c = a + (b + c)
Associative property of multiplication
(ab) c = a (bc)
Distributive property
a(b + c) = ab + ac
Additive identity property
a + 0 = a
Multiplicative identity property
a • 1 = a
Multiplicative inverse property • = 1
Additive inverse property
a + (-a) = 0
55. NOTE TO THE TEACHER:
It is important for you to examine and discuss the responses of your
students to the questions posed in every activity and exercise in order to
practice what they have learned for themselves. Remember application as
part of the learning process is essential to find out whether the learners
gained knowledge of the concept or not. It is also appropriate to encourage
brainstorming, dialogues and arguments in class. After the exchanges, see
to it that all questions are resolved.
III. Exercises
A. Complete the Table: Which property of real number justifies each
statement?
B. Rewrite the following expressions using the given property.
1. 12a – 5a Distributive Property (12-5)a
2. (7a)b Associative Property 7 (ab)
3. 8 + 5 Commutative Property 5 + 8
4. -4(1) Identity Property -4
5. 25 + (-25) Inverse Property 0
C. Fill in the blanks and determine what properties were used to solve the
equations.
1. 5 x ( -2 + 2) = 0 Additive Inverse, Zero Property
2. -4 + 4 = 0 Additive Inverse
3. -6 + 0 = -6 Additive Identity
4. (-14 + 14) + 7 = 7 Additive Inverse, Additive Identity
5. 7 x (0 + 7) = 49 Additive Identity
Given Property
1. 0 + (-3) = -3 Additive Identity Property
2. 2(3 - 5) = 2(3) - 2(5) Distributive Property
3. (- 6) + (-7) = (-7) + (-6) Commutative Property
4. 1 x (-9) = -9 Multiplicative Identity Property
5. -4 x - = 1 Multiplicative Inverse Property
6. 2 x (3 x 7) = (2 x 3) x 7 Associative Property
7. 10 + (-10) = 0 Additive Inverse Property
8. 2(5) = 5(2) Commutative Property
9. 1 x (- ) = - Multiplicative Identity Property
10. (-3)(4 + 9) = (-3)(4) + (-
3)(9)
Distributive Property
56. NOTE TO THE TEACHER
Try to give more of the type of exercises in Exercise C. Combine
properties so that you can test how well your students have understood
the lesson.
Summary
The lesson on the properties or real numbers explains how numbers or
values are arranged or related in an equation. It further clarifies that no matter
how these numbers are arranged and what processes are used, the
composition of the equation and the final answer is still the same. Our society
is much like these equations - composed of different numbers and operations,
different people with varied personalities, perspectives and experiences. We
can choose to look at the differences and forever highlight our advantage or
superiority over the others. Or we can focus on the commonality among people
and altogether work for the common good. A peaceful society and harmonious
relationship start with recognizing, appreciating and fully maximizing the
positive traits that we, as a people, have in common.
57. Lesson 6: Rational Numbers in the Number Line
Time: 1 hour
Prerequisite Concepts: Subsets of Real Numbers, Integers
Objective:
In this lesson, you, the students, are expected to
1. define rational numbers;
2. illustrate rational numbers on the number line;
3. arrange rational numbers on the number line.
NOTE TO THE TEACHER:
Ask students to recall the relationship of the set of rational numbers to
the set of integers and the set of non-integers (Lesson 4). This lesson gives
students a challenge in their numerical estimation skills. How accurately can
they locate rational numbers between two integers, perhaps, or between any
two numbers?
Lesson Proper
I. Activity
Determine whether the following numbers are rational numbers or not.
- 2, ,
1
11
, 43
, 16 , -1.89,
Now, try to locate them on the real number line below by plotting:
II. Questions to Ponder
Consider the following examples and answer the questions that follow:
a. 7 ÷ 2 = 3 ½ ,
b. (-25) ÷ 4 = -6 ¼
c. (-6) ÷ (-12) = ½
1. Are quotients integers? Not all the time. Consider 10
7 .
2. What kind of numbers are they? Quotients are rational numbers.
3. Can you represent them on a number line? Yes. Rational numbers are
real numbers and therefore, they are found in the real number line.
0-1-2-3 1 2 3 4
NOTE TO THE TEACHER:
Give as many rational numbers as class time can allow. Give them in
different forms: integers, fractions, mixed numbers, decimals, repeating
decimals, etc.
58. Recall what rational numbers are...
3 ½, -6 ¼, ½, are rational numbers. The word rational is derived from the word
“ratio” which means quotient. Rational numbers are numbers which can be written as
a quotient of two integers, where b ≠ 0.
The following are more examples of rational numbers:
5 = 5
1 0.06 = 6
100 1.3 =
From the example, we can see that an integer is also a rational number and
therefore, integers are a subset of rational numbers. Why is that?
Let’s check on your work earlier. Among the numbers given, - 2, ,
1
11
, 43
, 16 , -
1.89, the numbers and 43
are the only ones that are not rational numbers.
Neither can be expressed as a quotient of two integers. However, we can express
the remaining ones as a quotient of two intergers:
2 2
1 , 16 4 4
1 , 1.89
189
100
Of course,
1
11
is already a quotient by itself.
We can locate rational numbers on the real number line.
Example 1. Locate ½ on the number line.
a. Since 0 < ½ < 1, plot 0 and 1 on the number line.
b. Get the midpoint of the segment from 0 to 1. The midpoint now corresponds to
½
Example 2. Locate 1.75 on the number line.
a. The number 1.75 can be written as 7
4 and, 1 < 7
4 < 2. Divide the segment from
0 to 2 into 8 equal parts.
b. The 7th mark from 0 is the point 1.75.
1.7510 2
10 2
0 1
½
0 1
59. Example 3. Locate the point on the number line.
Note that -2 < < -1. Dividing the segment from -2 to 0 into 6 equal parts, it is
easy to plot . The number is the 5th mark from 0 to the left.
Go back to the opening activity. You were asked to locate the rational numbers and
plot them on the real number line. Before doing that, it is useful to arrange them in
order from least to greatest. To do this, express all numbers in the same form –-
either as similar fractions or as decimals. Because integers are easy to locate, they
need not take any other form. It is easy to see that
- 2 < -1.89 <
1
11
< 16
Can you explain why?
Therefore, plotting them by approximating their location gives
III. Exercises
1. Locate and plot the following on a number line (use only one number line).
a.
10
3
e. -0.01
b. 2.07 f. 7
1
9
c.
2
5
g. 0
d. 12 h.
1
6
2. Name 10 rational numbers that are greater than -1 but less than 1, and
arrange them from least to greatest on the real number line?
Examples are:
1
10
,
3
10
,
1
2
,
1
5
,
1
100
, 0,
1
8
,
2
11
,
8
37
,
9
10
12
2
0
-2 -1 0
NOTE TO THE TEACHER:
You are given a number line
to work on. Plot the numbers
on this number line to serve as
your answer key.
60. 3. Name one rational number x that satisfies the descriptions below:
a. 10 x 9,
Possible answers:
x
46
5
,
48
5
, 9.75, 9
8
9
, 9.99
b.
1
10
x
1
2
Possible answers:
x
46
5
,
48
5
, 9.75, 9
8
9
, 9.99
c. 3 x
Possible answers:
x 3.1, 3.01, 3.001, 3.12
d.
1
4
x
1
3
Possible answers:
x
13
50
, 0.27, 0.28,
299
1000
,
3
10
e.
1
8
x
1
9
Possible answers:
x
3
25
, 0.124,
17
144
, 0.112
NOTE TO THE TEACHER:
End this lesson with a summary as well as a preview of what students are
expected to learn about rational numbers, their properties, operations and
uses.
Summary
In this lesson, you learned more about what rational numbers are and where
they can be found in the real number line. By changing all rational numbers to
equivalent forms, it is easy to arrange them in order, from least to greatest or vice
versa.
NOTE TO THE TEACHER:
In this exercise, you may
allow students to use the
calculator to check that their
choice of x is within the
range given. You may, as
always also encourage them
to use mental computation
strategies if calculators are
not readily available. The
important thing is that
students have a way of
checking their answers and
will not only rely on you to
give the correct answers.
61. Lesson 7: Forms of Rational Numbers and Addition and Subtraction of
Rational Numbers
Time: 2 hours
Prerequisite Concepts: definition of rational numbers, subsets of real numbers,
fractions, decimals
Objectives:
In this lesson, you are expected to:
1. express rational numbers from fraction form to decimal form (terminating
and repeating and non-terminating) and vice versa;
2. add and subtract rational numbers;
3. solve problems involving addition and subtraction of rational numbers.
NOTE TO THE TEACHER:
The first part of this module is a lesson on changing rational numbers
from one form to another, paying particular attention to changing rational
numbers in non-terminating and repeating decimal form to fraction form. It
is assumed that students know decimal fractions and how to operate on
fractions and decimals.
Lesson Proper:
A. Forms of Rational Numbers
I. Activity
1. Change the following rational numbers in fraction form or mixed number form
to decimal form:
a.
1
4
= -0.25 d.
5
2
= 2.5
b.
3
10
= 0.3 e.
17
10
= -1.7
c. 3
5
100
= 3.05 f. 2
1
5
= -2.2
2. Change the following rational numbers in decimal form to fraction form.
a. 1.8 =
9
5
d. -0.001 =
1000
1
b. - 3.5 =
7
2
e. 10.999 =
1000
10999
c. -2.2 =
11
5
f. 0.11 =
1
9
NOTE TO THE TEACHER:
NOTE TO THE TEACHER:
These should be treated as review exercises. There is no need to spend too
much time on reviewing the concepts and algorithms involved here.
62. The discussion that follows assumes that students remember why
certain fractions are easily converted to decimals. It is not so easy to
change fractions to decimals if they are not decimal fractions. Be aware of
the fact that this is the time when the concept of a fraction becomes very
different. The fraction that students remember as indicating a part of a
whole or of a set is now a number (rational) whose parts (numerator and
denominator) can be treated separately and can even be divided! This is a
major shift in concept, and students have to be prepared to understand
how these concepts are consistent with what they have learned from
elementary level mathematics.
II. Discussion
Non-decimal Fractions
There is no doubt that most of the above exercises were easy for you. This is
because all except item 2f are what we call decimal fractions. These numbers are all
parts of powers of 10. For example,
1
4
=
25
100
which is easily convertible to a
decimal form, 0.25. Likewise, the number -3.5 = 3
5
10
35
10
.
What do you do when the rational number is not a decimal fraction? How do
you convert from one form to the other?
Remember that a rational number is a quotient of 2 integers. To change a
rational number in fraction form, you need only to divide the numerator by the
denominator.
Consider the number
1
8
. The smallest power of 10 that is divisible by 8 is
1000. But,
1
8
means you are dividing 1 whole unit into 8 equal parts. Therefore,
divide 1 whole unit first into 1 000 equal parts, and then take
1
8
of the thousandths
part. That is equal to
1000
125
or 0.125.
Example: Change
1
16
,
9
11
, and
1
3
to their decimal forms.
The smallest power of 10 that is divisible by 16 is 10,000. Divide 1 whole unit
into 10,000 equal parts and take
1
16
of the ten thousandths part. That is equal to
625
10000
or 0.625. You can obtain the same value if you perform the long division
1 16.
63. Do the same for
9
11
. Perform the long division 9 11, and you should obtain
0.81. Therefore,
9
11
= 0.81. Also,
1
3
0.3. Note that both
9
11
and
1
3
are non-
terminating but repeating decimals.
To change rational numbers in decimal forms, express the decimal part of the
numbers as a fractional part of a power of 10. For example, -2.713 can be changed
initially to 2
713
1000
and then changed to
2173
1000
.
What about non-terminating but repeating decimal forms? How can they be
changed to fraction form? Study the following examples:
Example 1: Change 0.2 to its fraction form.
Solution: Let
r 0.222...
10r 2.222...
Then subtract the first equation from the second equation and obtain
9r 2.0
r
2
9
Therefore, 0.2 =
2
9
.
Example 2. Change 1.35 to its fraction form.
Solution: Let
r 1.353535...
100r 135.353535...
Then subtract the first equation from the second equation and obtain
99r 134
r
134
99
1
35
99
Therefore, 1.35 =
135
99
.
NOTE TO THE TEACHER:
Now that students are clear about how to change rational numbers from
one form to another, they can proceed to learning how to add and subtract
them. Students will soon realize that these skills are the same skills that
they have learned in elementary mathematics.
Since there is only 1 repeated digit,
multiply the first equation by 10.
Since there are 2 repeated digits,
multiply the first equation by 100. In
general, if there are n repeated digits,
multiply the first equation by 10n
.
64. B. Addition and Subtraction of Rational Numbers in Fraction Form
I. Activity
Recall that we added and subtracted whole numbers by using the number line
or by using objects in a set.
Using linear or area models, find the sum or difference.
a. = _____ c. = _____
b. = _____ d. = _____
Without using models, how will you get the sum or difference?
Consider the following examples:
1.
2.
3.
4.
5.
6.
Answer the following questions:
1. Is the common denominator always the same as one of the denominators of the
given fractions?
2. Is the common denominator always the greater of the two denominators?
3. What is the least common denominator of the fractions in each example?
4. Is the resulting sum or difference the same when a pair of dissimilar fractions is
replaced by any pair of similar fractions?
Problem: Copy and complete the fraction magic square. The sum in each
row, column, and diagonal must be 2.
» What are the values of a, b, c, d and e? a =
1
6
, b =
4
3
, c =
4
15
, d =
13
30
, e =
7
6
1
/2
7
/5
1
/3 c
d e 2
/5
a b
65. NOTE TO THE TEACHER:
The following pointers are not new to students at this level. However,
if they had not mastered how to add and subtract fractions and decimals
well, this is the time for them to do so.
Important things to remember
To Add or Subtract Fraction
With the same denominator,
If a, b and c denote integers, and b ≠ 0, then
and
With different denominators, , where b ≠ 0 and d ≠ 0
If the fractions to be added or subtracted are dissimilar
» Rename the fractions to make them similar whose denominator is the least
common multiple of b and d.
» Add or subtract the numerators of the resulting fractions.
» Write the result as a fraction whose numerator is the sum or difference of the
numerators, and whose denominator is the least common multiple of b and d.
Examples:
To Add: To Subtract:
a. a.
b. b.
LCM/LCD of 5 and 4 is 20
NOTE TO THE TEACHER:
Below are the answers to the activity. Make sure that students clearly
understand the answers to all the questions and the concepts behind each
question.
II. Questions to Ponder (Post –Activity Discussion)
Let us answer the questions posed in activity.
You were asked to find the sum or difference of the given fractions.
a. = c. =
b. = d. =
Without using the models, how would you get the sum or difference?
You would have to apply the rule for adding or subtracting similar fractions.
66. 1. Is the common denominator always the same as one of the denominators of the
given fractions?
Not always. Consider
2
5
3
4
. Their least common denominator is 20 not 5 or 4.
2. Is the common denominator always the greater of the two denominators?
Not always. The least common denominator is always greater than or equal to one of
the two denominators and it may not be the greater of the two denominators.
3. What is the least common denominator of the fractions in each example?
(1) 6 ( 2) 21 ( 3) 15 (4) 35 (5) 12 (6) 60
4. Is the resulting sum or difference the same as when a pair of dissimilar fractions
is replaced by any pair of similar fractions?
Yes, for as long as the replacement fractions are equivalent to the original fractions.
NOTE TO THE TEACHER:
Answers in simplest form or lowest terms could mean both mixed
numbers with the fractional part in simplest form or an improper fraction
whose numerator and denominator have no common factor except 1. Both
are acceptable as simplest forms.
III. Exercises
Do the following exercises.
a. Perform the indicated operations and express your answer in simplest
form.
1. =
2
3
9. =
25
36
2. =
13
5
10. =
67
18
3
13
18
3. =
11
10
1
1
10
11. =
5
12
4. =
1
6
12. =
72
11
6
6
11
5. 2 =
7
4
13. =
9
8
6. =
239
28
8
15
28
14. =
11
18
7. = 9
11
12
15. =
87
8
10
7
8
8. = 6
3
7
67. b. Give the number asked for.
1. What is three more than three and one-fourth? 6
1
4
2. Subtract from the sum of . What is the result?
263
30
8
23
30
3. Increase the sum of . What is the result? 12
4. Decrease . What is the result?
647
40
16
7
40
5. What is ?
423
35
12
3
35
c. Solve each problem.
1. Michelle and Corazon are comparing their heights. If Michelle’s height is 120
cm and Corazon’s height is 96 cm. What is the difference in their heights?
Answer: 24
5
12
cm
2. Angel bought meters of silk, meters of satin and meters of velvet. How
many meters of cloth did she buy? Answer: 18
13
20
m
3. Arah needs kg of meat to serve 55 guests. If she has kg of chicken, a
kg of pork, and kg of beef, is there enough meat for 55 guests? Answer: Yes,
she has enough. She has a total of 10
1
2
kilos.
4. Mr. Tan has liters of gasoline in his car. He wants to travel far so he added
16 liters more. How many liters of gasoline is in the tank? Answer: 29
9
10
liters
NOTE TO THE TEACHER:
Note that the language here is crucial. Students need to translate the
English phrases to the correct mathematical phrase or equation.
NOTE TO THE TEACHER:
You should give more exercises if needed. You, the teacher should
probably use the calculator to avoid computing mistakes.
68. 5. After boiling, the liters of water is reduced to 9 liters. How much water has
evaporated? Answer: 8
1
12
liters
NOTE TO THE TEACHER:
The last portion of this module is on the addition and subtraction of
rational numbers in decimal form. This is mainly a review. Emphasize that
they are not just working on decimal numbers, but also with rational
numbers. Emphasize that these decimal numbers are a result of the
numerator divided by the denominator of a quotient of two integers.
C. Addition and Subtraction of Rational Numbers in Decimal Form
There are 2 ways of adding or subtracting decimals.
1. Express the decimal numbers in fractions then add or subtract as
described earlier.
Example:
Add: 2.3 + 7.21 Subtract:: 9.6 – 3.25
(2 + 7) + (9 – 3) +
9 + = or 9.51 6 + = or 6.35
2. Arrange the decimal numbers in a column such that the decimal points are
aligned, then add or subtract as with whole numbers.
Example:
Add: 2.3 + 7.21 Subtract: 9.6- 3.25
2.3 9.6
+ 7.21 - 3.25
9.51 6.35
Exercises:
1. Perform the indicated operation.
1) 1 902 + 21.36 + 8.7 = 1 932.06 6) 700 – 678.891 =
21.109
2) 45.08 + 9.2 + 30.545 = 84.825 7) 7.3 – 5.182 = 2.118
69. 3) 900 + 676.34 + 78.003 = 1 654.343 8) 51.005 – 21.4591 =
29.5459
4) 0.77 + 0.9768 + 0.05301 = 1.79981 9) (2.45 + 7.89) – 4.56 =
5.78
5) 5.44 – 4.97 = 0.47 10) (10 – 5.891) + 7.99 =
12.099
2. Solve the following problems:
a. Helen had P7,500 for shopping money. When she got home, she had
P132.75 in her pocket. How much did she spend for shopping?
P7,367.25
b. Ken contributed P69.25, while John and Hanna gave P56.25 each for
their gift to Teacher Daisy. How much were they able to gather
altogether? P181.75
c. Ryan said, “I’m thinking of a number N. If I subtract 10.34 from N, the
difference is 1.34.” What is Ryan’s number? 11.68
d. Agnes said, “I’m thinking of a number N. If I increase my number by
56.2, the sum is 14.62.” What is Agnes number? –41.58
e. Kim ran the 100-meter race in 135.46 seconds. Tyron ran faster by
15.7 seconds. What is Tyron’s time for the 100-meter dash? 119.76
NOTE TO THE TEACHER:
The summary is important especially because this is a long module.
This lesson provided students with plenty of exercises to help them master
addition and subtraction of rational numbers.
SUMMARY
This lesson began with some activities and instruction on how to change
rational numbers from one form to another and proceeded to discuss addition and
subtraction of rational numbers. The exercises given were not purely computational.
There were thought questions and problem solving activities that helped in
deepening one’s understanding of rational numbers.
70. Lesson 8: Multiplication and Division of Rational Numbers
Time: 2 hours
Prerequisite Concepts: addition and subtraction of rational numbers, expressing
rational numbers in different forms
Objectives:
In this lesson, you are expected to:
1. multiply rational numbers;
2. Divide rational numbers;
3. solve problems involving multiplication and division of rational numbers.
NOTE TO THE TEACHER:
This lesson reinforces what students learned in elementary
mathematics. It starts with the visualization of the multiplication and
division of rational numbers using the area model. Use different, yet
appropriate shapes when illustrating using the area model. The opening
activity encourages the students to use a model or drawing to help them
solve the problem. Although, some students will insist they know the
answer, it is a whole different skill to teach them to visualize using the area
model.
Lesson Proper
A. Models for the Multiplication and Division
I. Activity:
Make a model or a drawing to show the following:
1. A pizza is divided into 10 equal slices. Kim ate of of the pizza. What
part of the whole pizza did Kim eat?
2. Miriam made 8 chicken sandwiches for some street children. She cut up
each sandwich into 4 triangular pieces. If a child can only take a piece, how
many children can she feed?
Can you make a model or a drawing to help you solve these problems?
A model that we can use to illustrate multiplication and division of rational numbers is
the area model.
What is
1
4
1
3
? Suppose we have one bar of chocolate represent 1 unit.
Divide the bar first into 4 equal parts vertically. One part of it is
1
4
71. Then, divide each fourth into 3 equal parts, this time horizontally to make the
divisions easy to see. One part of the horizontal division is
1
3
.
There will be 12 equal-sized pieces and one piece is
1
12
. But, that one piece
is
1
3
of
1
4
, which we know from elementary mathematics to mean
1
3
1
4
.
NOTE TO THE TEACHER
The area model is also used in visualizing division of rational
numbers in fraction form. This can be helpful for some students. For
others, the model may not be easily understandable. But, do not give up. It
is a matter of getting used to the model. In fact, this is a good way to help
them use a non-algorithmic approach to dividing rational numbers in
fraction form: by using the idea that division is the reverse of
multiplication.
What about a model for division of rational numbers?
Take the division problem:
4
5
1
2
. One unit is divided into 5 equal parts and 4
of them are shaded.
Each of the 4 parts now will be cut up in halves
Since there are 2 divisions per part (i.e. 1
5 ) and there are 4 of them (i.e. 4
5 ), then
there will be 8 pieces out of 5 original pieces or
4
5
1
2
8
5
.
1
3
1
4
1
12
72. NOTE TO THE TEACHER
The solution to the problem
4
5
1
2
can be easily checked using the area
model as well. Ask the students, what is
1
2
8
5
. The answer can be
obtained using the area model
1
2
8
5
=
4
5
NOTE TO THE TEACHER:
It is important for you to go over the answers of your students to the
questions posed in the opening activity in order to process what they have
learned for themselves. Encourage discussions and exchanges in class.
Do not leave questions unanswered.
II. Questions to Ponder (Post-Activity Discussion)
Let us answer the questions posed in the opening activity.
1. A pizza is divided into 10 equal slices. Kim ate of of the pizza. What part
of the whole pizza did Kim eat?
½
3/5
NOTE TO THE TEACHER
The area model works for multiplication of rational numbers because the
operation is binary, meaning it is an operation done on two elements. The
area model allows for at most “shading” or “slicing” in two directions.
// // //
3
5
1
2
3
10
Kim ate
3
10
of the whole pizza.
73. 2. Miriam made 8 chicken sandwiches for some street children. She cut up
each sandwich into 4 triangular pieces. If a child can only take a piece, how
many children can she feed?
The equation is 8 1
4 32. Since there are 4 fourths in one sandwich, there
will be 4 x 8 = 32 triangular pieces and hence, 32 children can be fed.
How then can you multiply or divide rational numbers without using models or
drawings?
NOTE TO THE TEACHER:
Below are important rules or procedures that the students must
remember. From here on, be consistent in your rules so that your students
will not be confused. Give plenty of examples.
Important Rules to Remember
The following are rules that you must remember. From here on, the symbols to be
used for multiplication are any of the following: , x, , or x.
1. To multiply rational numbers in fraction form, simply multiply the numerators and
multiply the denominators.
In symbol, where: b and d are NOT equal to zero, ( b ≠ 0; d ≠
0 )
2. To divide rational numbers in fraction form, you take the reciprocal of the second
fraction (called the divisor) and multiply it by the first fraction.
74. In symbol, where: b, c, and d are NOT equal to
zero.
Example:
Multiply the following and write your answer in simplest form
a.
b.
Divide:
=
III. Exercises.
Do the following exercises. Write your answer on the spaces provided:
1. Find the products. Express in lowest terms (i.e. the numerator and
denominators do not have a common factor except 1). Mixed numbers are
acceptable as well:
a. =
5
9
f. =
51
2
25
1
2
b. 7 =
14
3
4
2
3
g. =
1
10
c. =
2
25
h. =
1
36
d. =
325
9
36
1
9
i. =
4
9
e. =
5
12
j. =
3
10
The easiest way to solve for this number is
to change mixed numbers to an improper
fraction and then multiply it. Or use prime
factors or the greatest common factor, as
part of the multiplication process.
Take the reciprocal of , which is then multiply it
with the first fraction. Using prime factors, it is easy
to see that 2 can be factored out of the numerator then
cancelled out with the denominator, leaving 4 and 3
as the remaining factors in the numerator and 11 as
the remaining factors in the denominator.
75. B. Divide:
1. 20 = 30 6. =
10
9
1
1
9
2. =
5
9
7. =
79
12
6
7
12
3. =
7
40
8. =
7
6
1
1
6
4. =
69
80
9. =
10
33
5. =
9
2
4
1
2
10. = 6
C. Solve the following:
1. Julie spent hours doing her assignment. Ken did his assignment for
times as many hours as Julie did. How many hours did Ken spend doing his
assignment?
35
6
5
5
6
hours
2. How many thirds are there in six-fifths?
18
5
3
3
5
3. Hanna donated of her monthly allowance to the Iligan survivors. If her
monthly allowance is P3,500, how much did she donate? P1,400.00
4. The enrolment for this school year is 2 340. If are sophomores and are
seniors, how many are freshmen or juniors? 1 365 students are freshmen or
juniors
5. At the end of the day, a store had 2/5 of a cake leftover. The four employees
each took home the same amount of leftover cake. How much of the cake
did each employee take home?
1
10
of the cake.
B. Multiplication and Division of Rational Numbers in Decimal Form
NOTE TO THE TEACHER
The emphasis here is on what to do with the decimal point when
multiplying or dividing rational numbers in decimal form. Do not get stuck
on the rules. Give a deeper explanation. Consider:
6.1 0.08 6
1
10
8
100
488
1000
0.488
76. The decimal places indicate the powers of 10 used in the denominators,
hence the rule for determining where to place the decimal point in the
product.
This unit will draw upon your previous knowledge of multiplication and
division of whole numbers. Recall the strategies that you learned and developed
when working with whole numbers.
Activity:
1. Give students several examples of multiplication sentences with the answers
given. Place the decimal point in an incorrect spot and ask students to
explain why the decimal place should not be placed there and explain
where it should be placed and why.
Example:
215.2 x 3.2 = 68.864
2. Five students ordered buko pie, and the total cost is P135.75. How much did
each student have to pay if they shared the cost equally?
Questions and Points to Ponder:
1. In multiplying rational numbers in decimal form, note the importance of
knowing where to place the decimal point in a product of two decimal
numbers. Do you notice a pattern? Take the sum of the decimal places in
each of the multiplicand and the multiplier and that is the number of places in
the product.
2. In dividing rational numbers in decimal form, how do you determine where to
place the decimal point in the quotient? The number of decimal places in the
quotient depends on the number of decimal places in the divisor and the
dividend.
NOTE TO THE TEACHER
Answer to the Questions and Points to Ponder is to be elaborated when
you discuss the rules below.
Rules in Multiplying Rational Numbers in Decimal Form
1. Arrange the numbers in a vertical column.
2. Multiply the numbers, as if you are multiplying whole numbers.
3. Starting from the rightmost end of the product, move the decimal point to the
left the same number of places as the sum of the decimal places in the
multiplicand and the multiplier.
Rules in Dividing Rational Numbers in Decimal Form
1. If the divisor is a whole number, divide the dividend by the divisor applying the
rules of a whole number. The position of the decimal point is the same as that
in the dividend.
2. If the divisor is not a whole number, make the divisor a whole number by
moving the decimal point in the divisor to the rightmost end, making the
number seem like a whole number.
77. 3. Move the decimal point in the dividend to the right the same number of places
as the decimal point was moved to make the divisor a whole number.
4. Lastly divide the new dividend by the new divisor.
Exercises:
A. Perform the indicated operation
1. 3.5 ÷ 2 = 1.75 6. 27.3 x 2.5 = 68.25
2. 78 x 0.4 = 31.2 7. 9.7 x 4.1 = 39.77
3. 9.6 x 13 = 124.8 8. 3.415 ÷ 2.5 = 1.366
4. 3.24 ÷ 0.5 = 6.48 9. 53.61 x 1.02 = 54.6822
5. 1.248 ÷ 0.024 = 52 10. 1948.324 ÷ 5.96 = 326.9
B. Finds the numbers that when multiplied give the products shown.
1. . 3. . 5. .
x_______ x______ x___________
1 0 . 6 2 1 . 6 2 1 . 9 8
2. . 4. .
x _______ x _______
1 6 . 8 9 . 5
NOTE TO THE TEACHER
Give a good summary to this lesson emphasizing how this lesson was
meant to deepen their understanding of rational numbers and develop better
their skills in multiplying and dividing rational numbers.
Summary
In this lesson, you learned to use the area model to illustrate multiplication
and division of rational numbers. You also learned the rules for multiplying and
dividing rational numbers in both the fraction and decimal forms. You solved
problems involving multiplication and division of rational numbers.
Answers: (1) 5.3 x 2 ; (2) 8.4 x 2 or 5.6 x 3; (3) 5.4 x 4; (4) 3.5 x 3; (5) 3.14 x 7
NOTE TO THE TEACHER: These are only some of the possible pairs. Be
open to accept or consider other pairs of numbers.
78. Lesson 9: Properties of the Operations on Rational Numbers
Time: 1 hour
Pre-requisite Concepts: Operations on rational numbers
Objectives:
In this lesson, you are expected to
1. Describe and illustrate the different properties of the operations on
rational numbers.
2. Apply the properties in performing operations on rational numbers.
NOTE TO THE TEACHER:
Generally, rational numbers appear difficult among students. The
following activity should be fun and could help your students realize the
importance of the properties of operations on rational numbers.
Lesson Proper:
I. Activity
Pick a Pair
2
14
3
5
0 1
13
40
13
12
1
3
3
20
From the box above, pick the correct rational number to be placed in the spaces
provided to make the equation true.
1. [
2
14
] = 6. [
13
12
]
2. [
2
14
] + 7. = [
1
3
]
3. = 0 [0] 8. 2
5
___
3
4
3
20
[
1
2 ]
4. 1 x [ ] = 9. = _____ [ 3
20 ]
5. + [0] = 10. = [
13
40
]
Answer the following questions:
1. What is the missing number in item 1?
2. How do you compare the answers in items 1 and 2?
3. What about item 3? What is the missing number?
79. 4. In item 4, what number did you multiply with 1 to get ?
5. What number should be added to in item 5 to get the same
number?
6. What is the missing number in items 6 and 7?
7. What can you say about the grouping in items 6 and 7?
8. What do you think are the answers in items 8 and 9?
9. What operation did you apply in item 10?
NOTE TO THE TEACHER
The follow-up problem below could make the points raised in the
previous activity clearer.
Problem:
Consider the given expressions:
a.
b. =
* Are the two expressions equal? If yes, state the property illustrated. Yes,
the expressions in item (a) are equal and so are the expressions in item (b). This is
due to the Commutative Property of Addition and of Multiplication. The Commutative
Property allows you to change the order of the addends or factors and the resulting
sum or product, respectively, will not change.
NOTE TO THE TEACHER
Discuss among your students the following properties. These
properties make adding and multiplying of rational numbers easier to do.
PROPERTIES OF RATIONAL NUMBERS (ADDITION & MULTIPLICATION)
1. CLOSURE PROPERTY: For any two defined rational numbers. ,
their sum and product is also rational.
For example:
a. =
b.
2. COMMUTATIVE PROPERTY: For any two defined rational numbers
,
i. =
ii. =
80. For example:
a.
b.
3. ASSOCIATIVE PROPERTY: For any three defined rational numbers
i.
ii.
For example:
a.
b.
4. DISTRIBUTIVE PROPERTY of multiplication over addition for rational
numbers.
If are any defined rational numbers, then
For example:
5. DISTRIBUTIVE PROPERTY of multiplication over subtraction for rational
numbers.
If are any defined rational numbers, then
For example:
6. IDENTITY PROPERTY
Addition: Adding 0 to a number will not change the identity or value of that
number.
+ 0 =
For example:
81. Multiplication: Multiplying a number by 1 will not change the identity or value
of that number.
For example:
7. ZERO PROPERTY OF MULTIPLICATION: Any number multiplied by zero
equals 0, i. e.
For example:
II. Question to Ponder (Post-Activity Discussion)
NOTE TO THE TEACHER
Answer each question in the opening Activity thoroughly and discuss the
concepts clearly. Allow students to express their ideas, their doubts and
their questions. At this stage, they should really be able to verbalize what
they understand or do not understand so that can properly address any
misconceptions they have. Give additional examples, if necessary.
Let us answer the questions posed in the opening activity.
1. What is the missing number in item1? »
2. How do you compare the answers in items 1 and 2? » The answer is
the same, the order of the numbers is not important.
3. What about item 3? What is the missing number? » The missing
number is 0. When you multiply a number with zero the product is
zero.
4. In item 4, what number did you multiply with 1 to get ? » When
you multiply a number by one the answer is the same.
5. What number should be added to in item 5 to get the same number?
» 0, When you add zero to any number, the value of the number does
not change.
6. What do you think is the missing number in items 6 and 7?»
7. What can you say about the grouping in items 6 and 7? » The
groupings are different but they do not affect the sum.
8. What do you think are the answers in items 8 and 9? » The answer is
the same in both items, .
9. What operation did you apply in item 10? » The Distributive Property
of Multiplication over Addition
82. III. Exercises:
Do the following exercises. Write your answer in the spaces provided.
A. State the property that justifies each of the following statements.
1.
Commutative Property
2. 1 x =
Identity Property for Multiplication
3.
Distributive Property of Multiplication over Addition
4.
Associative Property
5. 2
7
1
5
2
3 1 2
7
1
5
2
3
Identity Property for Multiplication
6.
Identity Property for Addition
7.
1
2
5
6
4
3
Closure Property
8. =
Commutative Property
9.
1
4
Distributive Property of Multiplication over Subtraction
10.
2
15
5
7 0 0
Zero Property for Multiplication
B. Find the value of N in each expression
1. N + N = 0
2. = N =
6
7
3. = + N =
12
30
83. 4. 0 + N = N =
6. N = N =
1
6
7. N =
8
23
8. = N N =
8
9
NOTE TO THE TEACHER
You might want to add more exercises. When you are sure that your
students have mastered the properties, do not forget to end your lesson
with a summary.
Summary
This lesson is about the properties of operations on rational numbers. The
properties are useful because they simplify computations of rational numbers. These
properties are true under the operations addition and multiplication. Note that for the
Distributive Property of Multiplication over Subtraction, subtraction is considered part
of addition. Think of subtraction as the addition of a negative rational number.