PLEASE NOTE:
This document may contain a number of charts and graphics
that could be problematic for your computer configuration. It is recommended that you use the
"pdf" version for printing this document and the Word or WordPerfect file
for working with or adapting the Course Profile to meet your instructional
needs.
Course Profile
Principles of Mathematics, Grade 9 academic, Catholic
Course Overview
Course Profiles are professional
development materials designed to help teachers implement the new Grade 9
secondary school curriculum. These materials were created by writing
partnerships of school boards and subject associations. The development of
these resources was funded by the Ontario Ministry of Education and Training.
This document reflects the views of the developers and not necessarily those of
the Ministry. Permission is given to reproduce these materials for any purpose
except profit. Teachers are also encouraged to amend, revise, edit, cut, paste,
and otherwise adapt this material for educational purposes.
Any references in this
document to particular commercial resources, learning materials, equipment, or
technology reflect only the opinions of the writers of this sample Course
Profile, and do not reflect any official endorsement by the Ministry of
Education and Training or by the Partnership of School Boards that supported
the production of the document.
©Queen’s Printer for Ontario
Acknowledgements
Lead Board
Ottawa-Carleton Catholic School Board
Sandra Bender, Manager (P1)
Sean
Kelly, Manager (P2)
Department: Mathematics
Course Developer(s):
Arlene Corrigan, Renfrew County Catholic District
School Board
Dominique Levac, Catholic District School Board of
Easterm Ontario
Maureen Vincentine, Algonquin-Lakeshore Catholic
School Board
Linda Sloan, Ottawa Carleton Catholic School Board
Carolyn Boyer, Ottawa Carleton Catholic School Board
Tom Steinke, Ottawa Carleton Catholic School Board
Len St.Clair, Catholic District School Board of
Eastern Ontario
Nora Buckley, Algonquin-Lakeshore Catholic School
Board
Sue Trew, Dufferin-Peel Catholic District School
Board
Brian McCudden, Toronto Catholic District School
Board
Margaret Sinclair, Toronto Catholic District School
Board
David Kurzinger, Toronto Catholic District School
Board
Paul Costa, Toronto Catholic District School Board
Lori Goodfriend, Catholic District School Board of
Eastern Ontario
Catherine Rea, Ottawa Carlton Catholic School Board
Anne Delahunt, Ottawa Carlton Catholic School Board
Development Date:
February/March 1999
Course Revisors:
Revision Date: March/April
1999.
Additional Codes:
Eastern Ontario Catholic
Curriculum Cooperative
Institute for Catholic
Education
Course Overview
Mathematics, Academic, Grade 9
Identifying Information:
|
School: Department: District: Course Title: Principles of Mathematics Grade:
9 Course Type: Academic Ministry Course Code: MPM1D Credit Value: 1.0 |
Course Developer(s): Arlene Corrigan, Dominique Levac, Maureen
Vincentine, Linda Sloan, Carolyn Boyer, Tom Steinke, Len St. Clair, Nora
Buckley, Sue Trew, Brian McCudden, Margaret Sinclair, David Kurzinger, Paul
Costa Development Date: February/March 1999 Course Revisor(s): Revision Date: March/April 1999. |
Description/Rationale
This course enables students to develop generalizations of mathematical ideas and methods through exploration of applications, the effective use of technology, and abstract reasoning. Students will investigate relationships to develop equations of straight lines in analytic geometry, explore relationships between volume and surface area of objects in measurement, and apply extended algebraic skills in problem solving. Students will engage in abstract extensions of core learning that will deepen their mathematical knowledge and enrich their understanding.
How This Course Supports the Ontario Catholic School Graduate Expectations
This course enables students to develop a confident and positive sense of self. Within the setting of a supportive and caring classroom community, the dignity and value of each student is respected and affirmed. Through their personal growth in reason, critical thinking and communication, students come to appreciate their mathematical ability as a God given gift. By sharing their abilities, students contribute to the good of others, in service to the classroom and school community.
Unit Titles (Time and Sequence)
|
Unit 1 |
Exploring Relationships |
20 hours |
|
Unit 2 |
Modelling Linear Relationships |
40 hours |
|
Unit 3 |
Exploring Relationships in Geometry |
35 hours |
|
Unit 4 |
Making Connections |
15 hours |
Unit Organization
Unit #1: Exploring Relationships
Time: 20 Hours
Description:
In this unit, both students and teachers will begin to explore
both linear and non-linear relationships arising from meaningful problems.
Students will develop numeric, graphic and algebraic skills as needed in the
context of the activity. Various forms of assessment are built into all the
activities.
Ontario Catholic
School Graduation Expectations: CGE 3c, 4b, 5a, 7j
Strand(s): Number
Sense and Algebra, Relationships
Overall Expectations:NAV.01, NAV.02, NAV.04, REV.01, REV.02, REV.03.
Specific Expectations:NA1.01, NA1.02, NA1.03, NA1.04, NA1.05, NA1.06, NA2.03, NA2.04, NA2.05, RE1.01, RE1.03, RE1.04, RE1.05, RE1.06, RE1.07, RE2.01, RE2.02, RE2.04, RE2.05, RE2.06, RE3.02, RE3.03, RE3.04.
Unit #2 : Modelling Linear Relationships
Time: 40 Hours
Description:
In this unit, students and teachers will explore numerical, graphical and algebraic models (tables, graphs, equations) of linear relationships arising from meaningful problems. Students will develop numeric, graphic and algebraic skills as needed. Various forms of assessment are built into all the activities.
Ontario Catholic School Graduate Expectations:CGE 2b, 3c, 3e, 4f, 5a, 5g
Strands: Number
Sense and Algebra, Relationships, Analytic Geometry
Overall Expectations:
NAV.01, NAV.03, NAV.04, REV.01, REV.03, AGV.01, AGV.02, AGV.03.
Specific Expectations: NA1.01, NA1.02, NA1.03, NA1.04, NA1.05, NA1.06, NA3.01, NA3.02, NA3.03, NA3.04, NA3.06, NA4.01, NA4.02, NA4.03, RE1.01, RE1.02, RE1.03, RE1.04, RE1.05, RE1.06, RE1.07, RE2.01, RE2.02, RE2.03, RE3.01, RE3.02, RE3.03, RE3.04, AG1.01, AG1.02, AG1.03, AG1.04, AG2.01, AG2.02, AG2.03, AG2.04, AG2.05, AG3.01, AG3.02, AG3.03, AG3.04, AG3.05, AG3.06, AG3.07, AG3.08.
Unit #3:Exploring Relationships in Geometry
Time: 35 Hours
Description:
In this unit, students and teachers will explore and model relationships in measurement and geometry numerically and graphically in the context of optimization problems. This is an extension of the study of non-linear relationships introduced in Unit 1. Students will also explore geometric relationships using dynamic geometry software.
Ontario Catholic
School Graduation Expectations: CGE 2b,
5a, 5b
Strand:Number
Sense and Algebra, Relationships, Analytic Geometry, Measurement and Geometry
Overall
Expectations: NAV.02, NAV.03,
REV.01, REV.02, REV.03, MGV.01, MGV.02, MGV 03.
Specific Expectations:
NA2.01, NA2.02, NA2.03, NA2.04, NA2.05, NA2.06, NA3.01, NA3.02, NA3.03, NA3.04,
NA3.05, NA3.06, RE1.01, RE1.03, RE1.04, RE1.05, RE1.06, RE1.07, RE2.01, RE2.02,
RE2.04, RE2.05, RE3.01, RE3.02, RE3.03, MG1.01, MG1.02, MG1.03, MG1.04, MG2.01,
MG2.02, MG2.03, MG2.04, MG3.01, MG3.02, MG3.03, MG3.04, MG3.05.
Unit #4: Making Connections
Time: 15 Hours
Description:
In this unit, students will engage in a few, large assessment activities. These activities will capture the essence of the grade 9 course. One activity will serve as a culminating assessment task, which will be used in conjunction with a final exam as a final assessment.
Ontario Catholic School Graduation Expectations: CGE 2b, 5a, 5b.
Strand: Number Sense and Algebra, Relationships, Analytic Geometry, Measurement and Geometry
Overall Expectations: NAV.01, REV.01, REV.02, REV.03, AGV.01, AGV.02, AGV.03, MGV.01, MGV.02.
Specific Expectations: NA1.01, NA1.02, NA1.03, NA1.04, NA1.05, NA4.01, RE1.01, RE1.02, RE1.03, RE1.04, RE1.05, RE1.06, RE1.07, RE2.01, RE2.02, RE2.03, RE2.04, RE2.05, RE3.02, RE3.03, RE3.04, AG1.01, AG1.02, AG1.03, AG2.01, AG2.02, AG2.03, AG2.04, AG2.05, AG3.01, AG3.02, AG3.03, AG3.04, AG3.05, AG3.06, AG3.07, AG3.08, MG1.01, MG1.02, MG1.03, MG1.04, MG2.01, MG2.02, MG2.03, MG2.04.
Course Notes
“It is expected that in developing detailed courses of study from this document, teachers will weave together related expectations from different strands ...” (page 5, The Ontario Curriculum, Grades 9 and 10, Mathematics, 1999). This course profile has been constructed with a common theme of relationships that connects all the units. Below is a chart which displays the “weaving”:
|
Strand Unit |
Number Sense and Algebra |
Relationships |
Analytic Geometry |
Measurement and Geometry |
|
1. Exploring Relationships |
3 |
3 |
|
|
|
2. Exploring Linear Relationships |
3 |
3 |
3 |
|
|
3. Exploring Relationships in Geometry |
3 |
3 |
|
3 |
|
4. Making Connections |
3 |
3 |
3 |
3 |
“Skill acquisition is an important part of the program: skills are embedded in the contexts offered by various topics in the mathematics program and should be introduced as they are needed.” (page 4, The Ontario Curriculum, Grades 9 and 10, Mathematics, 1999). Skill development is truly embedded in the activities we have designed.
“The philosophy of the Grade 9 courses is consistent with that of the elementary program and facilitates a seamless transition from elementary school, because it reflects the belief that students learn mathematics effectively when they have initial opportunities to explore through hands-on experiences, followed by careful guidance into an understanding of the abstract mathematics involved.” (page 4, The Ontario Curriculum, Grades 9 and 10, Mathematics, 1999). All the activities give students initial opportunities to explore, through hands-on experiences followed by a thoughtful journey through various, appropriate representations. The bridge to the algebraic representation is one that must by crossed carefully to ensure all students develop a true understanding of this abstract representation. The activities in Unit 2 allow students to initially explore relationships numerically and graphically. The linear regression capabilities of graphing calculators provide a bridge for all students to develop an initial algebraic model. Dynamic Geometry Software is a powerful tool to allow all students to explore the connection between graphical and algebraic models.
Many activities require the use of technology: “The development of sophisticated yet easily used calculators and computers is changing the role of procedure and technique in mathematics. Operations that have been an essential part of a procedures-focused curriculum for decades can now be accomplished quickly and effectively using technology, so that students can now solve problems that were to time consuming to attempt, and can focus underlying concepts. This curriculum integrates appropriate technologies into the learning and doing of mathematics ...” (page 3, The Ontario Curriculum, Grades 9 and 10, Mathematics, 1999).
In the area of assessment it is essential that examples of student work be provided to paint a clearer picture of the meanings of the levels and their descriptors for students, parents, and teachers.
Mathematics, Academic, Grade 9
|
Teaching and Learning Strategies Teaching and learning strategies will include the
following: Hypothesize students will formulate hypotheses associated with
relationships Explore/Investigate through hands-on investigations of relationships Model/Formulate students develop numeric, graphic, algebraic and geometric
models for exploring relationships, dependencies and constraints Transform/Manipulate students will develop numeric, graphic and algebraic
skills as needed in the context of their investigations to allow them to move
within and between representations Infer/Conclude students will re-evaluate their hypotheses in light of
their learning and make inferences to extend their learning Communicate students, individually and in groups, orally and in
writing, communicate the findings of their investigations by defending their
mathematical models and explaining their reasoning |
Assessment Strategies The assessment plan will include the following: Personal
Communication • journals • self/peer assessment • student-teacher conferences Paper and Pencil • tasks • unit tests • final exam • reports Observation • formal
and informal Performance
Assessment • oral presentations • culminating assessment task • written reports Assessment tools
will include: • checklists • rubrics |
Main Resources The following resources are required to support teaching
and learning: Textbooks Student Textbook NCTM Standards Videotapes Life By the Numbers,
PBS, 1998 Computer Software Spreadsheet and Wordprocessor (Corel Suite 8, Microsoft Office) Dynamic Geometry Software (Cabri, Geometer’s SketchPad, TI92) Graphing Software (Graphmatica or
Zap-A-Graph) Websites http://www.ti.com/calc/docs http://www.statcan.ca http://forum.swarthmore.edu/ Technology and
Manipulatives Graphing Calculators (TI82/83/83Plus), Data Collection Devices
(CBR, CBL and scientific probes) Manipulatives |
Mathematics, Academic, Grade 9
Evaluation of Student Achievement
|
Knowledge/Skill Category Weighting Final Examination Focus on: • Knowledge/Understanding • Application/Making Connections
Final Assignment: Culminating Assessment Task Focus on: • Thinking/Inquiry/Problem Solving • Communication Written Reports Focus on: • Thinking/Inquiry/Problem Solving • Communication Oral Presentations Focus on: • Communication Paper and Pencil Tasks Focus on: • Knowledge/Understanding • Application/Making Connections Unit Tests Focus on: • Knowledge/Understanding • Application/Making Connections |
|
Course Grade Weighting Final Examination Culminating Assessment Task Written Reports Oral Presentations Paper and Pencil Tasks Unit Tests Course Grade |
% 15 15 20 10 10 30 ___ 100 |
Coded Expectations: Principles of Mathematics, Academic Grade 9
Number Sense and Algebra
Overall Expectations
NAV.01
• solve multi-step problems requiring numerical answers, using a variety of strategies and tools
NAV.02
• demonstrate understanding of the three basic exponent rules and apply them to simplify expressions
NAV.03
• manipulate first-degree polynomial expressions to solve first-degree equations
NAV.04
• solve problems, using the strategy of algebraic modelling
Specific Expectations
Solving Numerical Problems
NA1.01
• demonstrate facility with critical numerical skills, including mental mathematics, estimation, operations with integers (as necessary for working with equations and analytical geometry), and operations with rational numbers (as necessary in analytic geometry, measurement, and equation solving)
NA1.02
• distinguish between exact and approximate representations of the same quantity and choose appropriately between them in given situations (e.g. use the symbol " instead of 3.14 in determining the effect on volume of a sphere of doubling its diameter; determine the perimeter of a square having an area of 2)
NA1.03
• solve multi-step problems involving applications of percent, ratio, and rate as they arise throughout the course
NA1.04
• use a specific calculator effectively for applications that arise throughout the course
NA1.05
• judge the reasonableness of answers to problems by considering likely results within the situation described in the problem
NA1.06
• judge the reasonableness of answers produced by a calculator, a computer, or pencil and paper, using mental mathematics and estimation
Operating Elements
NA2.01
• elevate numerical expressions involving natural-number exponents with rational-number bases
NA2.02
• substitute into and evaluate algebraic expressions involving exponents, to support other topics of the course (e.g., measurement, analytical geometry)
NA2.03
• determine the meaning of negative exponents and of zero as an exponent from activities involving patterning
NA2.04
• represent very large and very small numbers, using scientific notation
NA2.05
• enter and interpret exponential notation on a scientific calculator, as necessary in calculations involving very large and very small numbers
NA2.06
• determine, from the examination of patterns, the exponent rules for multiplying and dividing monomials and the exponent rule for the power of a power, and apply these rules in expressions involving one and two variables
Manipulating Polynomial Expressions and Solving Equations
NA3.01
• add and subtract polynomials
NA3.02
• multiply a polynomial by a monomial, and factor a polynomial by removing a common factor
NA3.03
• expand and simplify polynomial expressions involving one variable
NA3.04
• solve first-degree equations, including equations with fractional coefficients, using an algebraic method
NA3.05
• calculate in right triangles, using the Pythagorean theorem, as required in topics throughout the course (e.g. measurement)
NA3.06
• rearrange formulas involving variables in the first degree, with and without substitution, as they arise in topics throughout the course (e.g. analytical geometry, measurement)
Using Algebraic Modelling to Solve Problems
NA4.01
• use algebraic modelling as one of several problem-solving strategies in various topics of the course (e.g. relations, measurement, direct and partial variation, Pythagorean theorem, percent)
NA4.02
• compare algebraic modelling with other strategies used for solving the same problem
NA4.03
• communicate solutions
to problems in approximate mathematical forms (e.g., written explanations,
formulas, charts, tables, graphs) and justify the reasoning used in solving the
problems
Relationships
Overall Expectations
REV.01
• determine relationships between two variables by collecting and analysing data
REV.02
• compare the graphs and formulas of linear and non-linear relations
REV.03
• describe the connections between various representations of relations
Specific Expectations
Determining Relationships
RE1.01
• pose problems, identify variables, and formulate hypotheses associated with relationships (Sample problem: If you look through a paper tube at a wall, you can see a region of a certain height on the wall. If you move farther from the wall, the height of that region changes. What is the relationship between the height of the visible region and your distance from the wall? Describe the relationship that you think will occur.)
RE1.02
• demonstrate and understanding of some principles of sampling and surveying (e.g., randomization, representivity, the use of multiple traits) and apply the principles in designing and carrying out experiments to investigate the relationships between variable (Sample problem: What factors might affect the outcome of this experiment? How could you design the experiment to account for them?)
RE1.03
• collect data, using appropriate equipment and/or technology (e.g., measurement tools, graphing calculators, scientific probes, the Internet) (Sample problem: Acquire or construct a paper tube and work with a partner to measure the heights of visible regions at various distances from a wall.);
RE1.04
• Organize and analyse data, using appropriate techniques (e.g., making tables and graphs, calculating measures of central tendency) and technology (e.g., graphing calculators, statistical software, spread-sheets) (Sample problem: Enter the data into a spreadsheet. Decide what analysis would be appropriate to examine the relationship between the variables – a graph, measures of central tendency, ratios)
RE1.05
• describe trends and relationships observed in data, make inferences from data, compare the inferences with hypotheses about the data, and explain the differences between the inferences and the hypotheses (Sample problem: Describe any trend observed in the data. Does a relationship seem to exist? Of what sort? Is the outcome consistent with your original hypotheses? Discuss any outlying pieces of data and provide explanations for them. Suggest a formula relating the height of the visible region to the distance from the wall. How might you vary the experiment to examine other relationships?)
RE1.06
• communicate findings of an experiment clearly and concisely, using appropriate mathematical forms (e.g., written explanations, formulas, charts, tables, graphs), and justify the conclusions reached
RE1.07
• solve and/or
pose problems related to an experiment, using the findings of the experiment
Comparing Linear and Non-linear Relations
RE2.01
• Construct tables of values, graphs, and formulas to represent the linear relations derived from descriptions of realistic situations (e.g., the cost of holding a banquet in a rented hall is $25 per person plus $975 for the hall)
RE2.02
• construct tables of values and scatter plots for linearly related data collected from experiments (e.g., the rebound height of a ball verus the height from which it was dropped) of from secondary sources (e.g., the number of calories in fast food versus the number of grams of fat)
RE2.03
• determine the equation of a line of best fit for a scatter plot, using an informal process (e.g., a process of trial and error on a graphing calculator; calculation of the equation of the line joining two carefully chosen points of the scanner plot)
RE2.04
• construct tables of values and graphs to represent non-linear relations derived from descriptions of realistic situations (Sample problem: A triangular prism has a height of 20 cm and a square base. Represent the relationship between the volume of the prism and the side length of its base, as the side length varies)
RE2.05
• construct tables of values and scatter plots for non-linear related data collected from experiments (e.g., the relationship between height and age) or from secondary sources (e.g., the population of Canada over time); sketch a curve of best fit
RE2.06
• demonstrate an understanding that straight lines represent linear relations and curves represent non-linear relations
Describing Connections Between Representations of Relations
RE3.01
• determine values of a linear relations be using the formula of the relations and by interpolating or extrapolating from the graph of the relation (e.g., if a student earns $5/hr caring for children, determine how long he or she must work to earn $143)
RE3.02
• describe, in written form, a situation that would explain the events illustrated by a given graph or the relationship between two variables (e.g., write a story that matches the events shown in the graph)
RE3.03
• identify, by calculating finite differences in its table of values, whether a relation is linear or non-linear
RE3.04
• describe the
effect on the graph and the formula of a relation of varying the conditions of
a situation they represent (e.g., if a graph showing partial variation
represents the cost of producing a yearbook, describe how the appearance of the
graph changes if the cost per book is altered; describe how it changes if the
fixed costs are altered)
Analytical Geometry
Overall Expectations
AGV.01
• determine, through investigation, the relationships between the form of an equation and the shape of its graph with respect to linearity an non-linearity
AGV.02
• determine, through investigation, the properties of the slope and y-intercept of a linear relation
AGV.03
• solve problems, using the properties of linear relations
Specific Expectations
Investigating the Relationship Between the Equation of a Relation and the Shape of Its Graph
AG1.01
• determine, through investigation, the characteristics that distinguish the equation of a straight line from the equation of non- linear relations (e.g., use graphing soft-ware to obtain the graphs of a variety of linear and non-linear relations from their equations; classify the relations according to the shapes of their graphs; focus on the characteristics of the equations of linear relations and how they differ from the characteristics of the equations of non-linear relations)
AG1.02
• select the equations of straight lines froms given set of equations of linear and non-linear relations
AG1.03
• identify the equation of a line in any of the forms y = mx + b, Ax + By + C = 0, x = a, y = b
AG1.04
• rearrange the equation of a line from the form y = mx + b to the form Ax + By + C = 0, and vice versa
Investigating the Properties of Slope
AG2.01
• determine the slope of a line segment, using various formulas, e.g.,
AG2.02
• identify the slope of a linear relation as representing a constant rate of change
AG2.03
• calculate the finite differences in the table of values of a linear relation and relate the result to the slope of the relation
AG2.04
• identify the geometric significance of m and b in the equation y = mx + b through investigation
AG2.05
• identify
properties of the slopes of line segments (e.g., direction, positive or
negative rate of change, steepness, parallelism, perpendicularity) through
investigations facilitated by graphing technology, where appropriate
Using the Properties of Linear Relations to Solve Problems
AG3.01
• plot points on the xy-plane and use the terminology and notation of the xy-plane correctly
AG3.02
• graph lines by hand, using a variety of techniques (e.g., making a table of values using intercepts, using the slope and y intercept)
AG3.03
• graph lines, using graphing calculators or graphing software
AG3.04
• determine the equation of a line, given information about the line (e.g., the slope and y intercept, the slope and a point, two points, a line parallel to a given line and having the same x intercept as another given line)
AG3.05
• communicate solutions to multi-step problems in established mathematical form, with clear reasons given for the steps taken
AG3.06
• describe the meaning of the slope and y intercept for a linear relation arising from a realistic situation, interpolate and extrapolate from the graph and the equation of the relation, and identify and explain any restrictions on the variables in the relation
AG3.07
• describe a situation that would be modelled by a given linear equation
AG3.08
• determine the
point of intersection of two linear relations, by hand for simple examples, and
using graphing calculators or graphing software for more complex examples; interpret
the intersection point in the context of an application
Measurement and Geometry
Overall Expectations
MGV.01
• determine the optimal values of various measurements through investigations facilitated, where appropriate, by the use of concrete materials, diagrams, and calculators or computer software
MGV.02
• solve problems involving the surface area and the volume of three-dimensional objects
MGV.03
• formulate conjectures and generalizations about geometric relationships involving two-dimensional figures, through investigations facilitated by dynamic geometry software, where appropriate
Specific Expectations
Investigating the Optimal Value of Measurements
MG1.01
• identify, through investigation, the effect of varying the dimensions of a rectangular prism or cylinder on the volume or surface area of the object
MG1.02
• identify, through investigation, the relationships between the volume and surface area of a given rectangular prism cylinder
MG1.03
• explain the significance of optimal surface area or volume in various applications (e.g., packaging; the relationship between surface area and heat loss)
MG1.04
• pose and solve a problem involving the relationship between the perimeter and the area of a figure when one of the measures is fixed
Solving Problems Involving Surface Area and Volume
MG2.01
• solve simple problems, using the formulas for the surface area and the volume of prisms, pyramids, cylinders, cones and spheres
MG2.02
• solve multi-step problems involving the volume and the surface area of prisms, cylinders, pyramids, comes, and spheres
MG2.03
• judge the reasonableness of answers to measurement problems by considering likely results within the situation described in the problem
MG2.04
• judge the reasonableness of answers produced by a calculator, a computer, or pencil and paper, using mental mathematics and estimation
Investigating Geometric Relationships
MG3.01
• illustrate and explain the properties of the interior and exterior angles of triangles and quadrilaterals, and of angles related to parallel lines
MG3.02
• determine the properties of angle bisectors, medians, and altitudes in various types of triangles through investigation
MG3.03
• determine the properties of the sides and the diagonals of polygons (e.g., the diagonals in quaddrilaterals, the diagonals of regular pentagons, the figure that results from joining the midpoints of sides of quadrilaterals) through investigation
MG3.04
• pose questions about geometric relationships, test them, and communicate the findings, using appropriate language and mathmatical forms (e.g., written explanations, diagrams, formulas, tables
MG3.04
• confirm a statement about the relationship between geometric properties by illustrating the statement with examples, or deny the statement on the basis of a counter-example (e.g., confirm or deny the following statement: If a quadrilateral has perpendicular diagonals, then it is a square)
Ontario Catholic School Graduate Expectations
The graduate is expected to be:
A Discerning Believer Formed in the Catholic Faith Community who
CGE1a -illustrates a basic understanding of the saving story of our Christian faith;
CGE1b -participates in the sacramental life of the church and demonstrates an understanding of the centrality of the Eucharist to our Catholic story;
CGE1c -actively reflects on God’s Word as communicated through the Hebrew and Christian scriptures;
CGE1d -develops attitudes and values founded on Catholic social teaching and acts to promote social responsibility, human solidarity and the common good;
CGE1e -speaks the language
of life... “recognizing that life is an unearned gift and that a person
entrusted with life does not own it but that one is called to protect and
cherish it.” (Witnesses to Faith)
CGE1f -seeks intimacy with God and celebrates communion with God, others and creation through prayer and worship;
CGE1g -understands that one’s purpose or call in life comes from God and strives to discern and live out this call throughout life’s journey;
CGE1h -respects the faith
traditions, world religions and the life-journeys of all people of good will;
CGE1i -integrates faith with life;
CGE1j -recognizes that “sin, human weakness, conflict and forgiveness are part of the human journey” and that the cross, the ultimate sign of forgiveness is at the heart of redemption. (Witnesses to Faith)
An Effective Communicator who
CGE2a -listens actively and critically to understand and learn in light of gospel values;
CGE2b -reads, understands and uses written materials effectively;
CGE2c -presents information and ideas clearly and honestly and with sensitivity to others;
CGE2d -writes and speaks fluently one or both of Canada’s official languages;
CGE2e -uses and integrates the Catholic faith tradition, in the
critical analysis of the arts, media, technology and information systems to
enhance the quality of life.
A Reflective and Creative Thinker who
CGE3a -recognizes there is more grace in our world than sin and that hope is essential in facing all challenges;
CGE3b -creates, adapts, evaluates new ideas in light of the common good;
CGE3c -thinks reflectively and creatively to evaluate situations
and solve problems;
CGE3d -makes decisions in light of gospel values with an informed moral conscience;
CGE3e -adopts a holistic approach to life by integrating learning from various subject areas and experience;
CGE3f -examines, evaluates and applies knowledge of interdependent systems (physical, political, ethical, socio-economic and ecological) for the development of a just and compassionate society.
A Self-Directed, Responsible,
Life Long Learner who
CGE4a -demonstrates a confident and positive sense of self and respect for the dignity and welfare of others;
CGE4b -demonstrates flexibility and adaptability;
CGE4c -takes initiative and demonstrates Christian leadership;
CGE4d -responds to, manages and constructively influences change in
a discerning manner;
CGE4e -sets appropriate goals and priorities in school, work and personal life;
CGE4f -applies effective communication, decision-making, problem-solving, time and resource management skills;
CGE4g -examines and reflects on one’s personal values, abilities
and aspirations influencing life’s choices and opportunities;
CGE4h -participates in leisure and fitness activities for a
balanced and healthy lifestyle.
A Collaborative Contributor who
CGE5a -works effectively as an interdependent team member;
CGE5b -thinks critically about the meaning and purpose of work;
CGE5c -develops one’s God-given potential and makes a meaningful
contribution to society;
CGE5d -finds meaning, dignity, fulfillment and vocation in work which contributes to the common good;
CGE5e -respects the rights, responsibilities and contributions of
self and others;
CGE5f -exercises Christian leadership in the achievement of individual and group goals;
CGE5g -achieves excellence, originality, and integrity in one’s own
work and supports these qualities in the work of others;
CGE5h -applies skills for employability, self-employment and
entrepreneurship relative to Christian vocation.
A Caring Family Member who
CGE6a -relates to family members in a loving, compassionate and respectful manner;
CGE6b -recognizes human intimacy and sexuality as God given gifts, to be used as the creator intended;
CGE6c -values and honours the important role of the family in
society;
CGE6d -values and nurtures opportunities for family prayer;
CGE6e -ministers to the family, school, parish, and wider community through service.
A Responsible Citizen who
CGE7a -acts morally and legally as a person formed in Catholic traditions;
CGE7b -accepts accountability for one’s own actions;
CGE7c -seeks and grants forgiveness;
CGE7d -promotes the sacredness of life;
CGE7e -witnesses Catholic social teaching by promoting equality, democracy, and solidarity for a just, peaceful and compassionate society;
CGE7f -respects and affirms the diversity and interdependence of the world’s peoples and cultures;
CGE7g -respects and understands the history, cultural heritage and pluralism of today’s contemporary society;
CGE7h -exercises the rights and responsibilities of Canadian citizenship;
CGE7i -respects the environment and uses resources wisely;
CGE7j -contributes to the common good.
Continue to Unit 1 | Back to
Course Profiles main menu