The document provides the syllabus for Cambridge IGCSE Mathematics examinations in June and November
2014, outlining the aims and assessment objectives of the syllabus, curriculum content, coursework guidance
for centers, coursework assessment criteria, and additional appendices on topics such as assessment at a
glance and schools in England, Wales and Northern Ireland.
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- Definition of Angles
- Parts of Angles
- Protractor
- Kinds of Angles
- Measuring Angles
The Assignment on the last slide is for them to have a background on the next lesson.
The document discusses dividing integers and their rules:
- There are four rules for dividing integers based on the signs of the numbers: two positives or negatives give a positive, opposite signs give a negative.
- Examples are provided to demonstrate applying the rules.
- The mean, or average, of a data set is calculated by summing the values and dividing by the number of values.
- Order of operations must be followed when evaluating expressions.
Cartesian Coordinate Plane - Mathematics 8Carlo Luna
This document explains the Cartesian coordinate plane. It describes how the plane is divided into four quadrants by the x and y axes which intersect at the origin. It provides examples of plotting points using ordered pairs with coordinates (x,y). The document also notes that Rene Descartes developed this system by combining algebra and geometry. It includes an activity for students to physically position themselves on the x and y axes to learn the coordinate system.
This document provides examples of factorizing algebraic expressions by finding the highest common factor (HCF) of the terms. It shows expressions being factorized, such as 2a+6 being written as 2(a+3), and 8m+12 being written as 4(2m+3). The document explains that algebraic expressions can sometimes be written as the HCF multiplied by grouped terms in parentheses. It provides steps for finding the factors of each term and the HCF to factorize expressions like 9jk+4k as k(9j+4).
1) The document discusses various forms of equations for lines, including slope-intercept form, standard form, and point-slope form. It provides definitions and examples of writing equations of lines given the slope and y-intercept or given two points on the line.
2) Key concepts covered include writing the equation of a line given its slope m and y-intercept b using slope-intercept form y=mx+b, or given slope m and a point (x1,y1) using point-slope form y-y1=m(x-x1).
3) Examples are provided for writing equations of lines using slope-intercept form when given slope and y-intercept, and using point-
The document discusses linear equations in two variables. It defines a linear equation as one that can be written in the standard form Ax + By = C, where A, B, and C are real numbers and A and B cannot both be zero. Examples are provided of determining if equations are linear and identifying the A, B, and C components if they are linear. The document also discusses using ordered pairs as solutions to linear equations and finding multiple solutions to a given linear equation.
The document discusses basic rules of algebra. It recaps terms like algebraic expressions and equations from the previous class. It then explains that the rules of addition and subtraction of algebraic terms are similar to numerical addition and subtraction, but the terms must be "like" terms, meaning they have the same variables. Unlike terms, with different variables, cannot be added or subtracted. It provides several examples to illustrate how to combine like terms through addition and subtraction.
This preview may not appear the same on the actual version of the PPT slides.
Some formats may change due to font and size settings available on the audience's device.
To get/buy a soft copy, please send a request to queenyedda@gmail.com
Inclusions of the file attachment:
* Fonts used
* Soft copy of the WHOLE ppt slides with effects
ACCEPTING COMMISSIONED POWERPOINT SLIDES
ACCEPTING COMMISSIONED POWERPOINT SLIDES
ACCEPTING COMMISSIONED POWERPOINT SLIDES
EMAIL queenyedda@gmail.com
- - - - - - - - - - - - -
- Definition of Angles
- Parts of Angles
- Protractor
- Kinds of Angles
- Measuring Angles
The Assignment on the last slide is for them to have a background on the next lesson.
The document discusses dividing integers and their rules:
- There are four rules for dividing integers based on the signs of the numbers: two positives or negatives give a positive, opposite signs give a negative.
- Examples are provided to demonstrate applying the rules.
- The mean, or average, of a data set is calculated by summing the values and dividing by the number of values.
- Order of operations must be followed when evaluating expressions.
Cartesian Coordinate Plane - Mathematics 8Carlo Luna
This document explains the Cartesian coordinate plane. It describes how the plane is divided into four quadrants by the x and y axes which intersect at the origin. It provides examples of plotting points using ordered pairs with coordinates (x,y). The document also notes that Rene Descartes developed this system by combining algebra and geometry. It includes an activity for students to physically position themselves on the x and y axes to learn the coordinate system.
This document provides examples of factorizing algebraic expressions by finding the highest common factor (HCF) of the terms. It shows expressions being factorized, such as 2a+6 being written as 2(a+3), and 8m+12 being written as 4(2m+3). The document explains that algebraic expressions can sometimes be written as the HCF multiplied by grouped terms in parentheses. It provides steps for finding the factors of each term and the HCF to factorize expressions like 9jk+4k as k(9j+4).
1) The document discusses various forms of equations for lines, including slope-intercept form, standard form, and point-slope form. It provides definitions and examples of writing equations of lines given the slope and y-intercept or given two points on the line.
2) Key concepts covered include writing the equation of a line given its slope m and y-intercept b using slope-intercept form y=mx+b, or given slope m and a point (x1,y1) using point-slope form y-y1=m(x-x1).
3) Examples are provided for writing equations of lines using slope-intercept form when given slope and y-intercept, and using point-
The document discusses linear equations in two variables. It defines a linear equation as one that can be written in the standard form Ax + By = C, where A, B, and C are real numbers and A and B cannot both be zero. Examples are provided of determining if equations are linear and identifying the A, B, and C components if they are linear. The document also discusses using ordered pairs as solutions to linear equations and finding multiple solutions to a given linear equation.
The document discusses basic rules of algebra. It recaps terms like algebraic expressions and equations from the previous class. It then explains that the rules of addition and subtraction of algebraic terms are similar to numerical addition and subtraction, but the terms must be "like" terms, meaning they have the same variables. Unlike terms, with different variables, cannot be added or subtracted. It provides several examples to illustrate how to combine like terms through addition and subtraction.
This document defines and describes different types of angles:
1) Adjacent angles share a common vertex and side. Vertically opposite angles are formed when two lines intersect and are equal.
2) Complementary angles have a sum of 90 degrees. Supplementary angles have a sum of 180 degrees.
3) A linear pair is two adjacent supplementary angles.
4) A transversal intersects two or more lines. It forms corresponding, alternate, and interior angles that follow specific properties.
Presentation on introducing whole numberVivek Kumar
The document defines and discusses properties of whole numbers. Whole numbers include all positive integers from 0 to infinity, and are represented by W. They include natural numbers and counting numbers. Key properties of whole numbers are that they are closed under addition and multiplication, follow the associative property, commutative property, and distributive property. Operations on whole numbers include addition, subtraction, multiplication, and division.
This document provides information about the Cartesian plane (or Cartesian coordinate system) including:
- It specifies each point uniquely using a pair of numerical coordinates that represent the distance from the point to two fixed perpendicular axes.
- Rene Descartes invented the Cartesian coordinate system to plot ordered pairs (x,y) on a plane with perpendicular x and y axes intersecting at the origin (0,0).
- The x-coordinate represents the horizontal axis and the y-coordinate represents the vertical axis. Ordered pairs written as (x, y) locate a point by moving left/right along the x-axis and up/down along the y-axis from the origin.
This document discusses how to solve equations and inequalities. It covers topics such as: balancing equations, combining like terms, expanding brackets, rearranging formulas to change the subject, representing inequalities on number lines, and solving one-step and two-step inequalities. Examples are provided to demonstrate each concept and practice problems are included for readers to try.
A net is an unfolded 3D shape laid out flat that makes it easy to see how many faces the shape has. The document shows different nets including cubes with 11 possible nets, cuboids with 54 possible nets, cylinders formed from two different nets, cones, square-based pyramids, triangular-based pyramids made of four triangles, and prisms which are made up of two base shapes along with rectangles, where the number of rectangles equals the number of sides of the base shape. An example net of a pentagonal prism is provided which has two pentagons and five rectangles.
This document provides definitions and examples related to circles and tangents. It defines key terms like radius, diameter, chord, secant, and tangent. Examples demonstrate identifying these segments and determining if lines are tangent to circles. Theorems are presented about properties of tangents, such as tangents being perpendicular to radii and two tangents from the same exterior point being congruent. Proofs of theorems are also provided. Exercises apply these concepts, like using properties of tangents to find missing values.
The document discusses the rectangular coordinate system and plotting points on a Cartesian plane. It begins by stating the objectives of understanding the rectangular coordinate system, plotting points, and completing tasks cooperatively. Classroom policies for discussions are outlined. A motivation activity called the "Row-Column Game" is described to call on students by row and column to answer questions about a seating chart. Concepts of the rectangular coordinate system like quadrants, axes, and ordered pairs are analyzed. The history of the system developed by René Descartes is provided. Examples are given to illustrate plotting points and connecting the rectangular coordinate system to real-life and other subjects. An assignment requires students to plot locations on a Cartesian plane and connect the points to form an object
Chapter 1 addition and subtraction of whole numbersrey castro
This document summarizes key concepts about addition and subtraction of whole numbers from a mathematics textbook. It explains addition as the combining of collections of objects, and subtraction as determining the remainder when part of a total is removed. The key processes of addition and subtraction are described step-by-step with examples. Properties of addition like commutativity and associativity are also explained with examples.
This document discusses simplifying complex rational expressions, which have numerators or denominators containing fractions. It provides two methods for simplification:
1) Multiplying the numerator and denominator by the lowest common denominator to clear fractions. Examples and steps are shown.
2) Dividing the numerator by the denominator after collecting like terms. An example problem is worked through to demonstrate the process. Objectives and learning outcomes are stated to guide readers.
* GSCE, IGCSE, IB, PSAT, and AISL - Exam Style Questions which covers all the related concepts required for students to unravel any International Exam Style Approximation and Estimation Questions [Upper and Lower Bound]
* Learner will be able to say authoritatively that:
I can solve any given Rounding Questions:
Estimate numbers using rounding, decimal places and significant figures. ...To estimate means to make a rough guess or calculation. To round means to simplify a known number by scaling it slightly up or down. Rounding is a type of estimating. Both methods can help you make educated approximations and can be used in everyday life for tasks related to money, time or distance.
While accurate estimates are the basis of sound project planning, there are many techniques used as project management best practices in estimation as - Analogous estimation, Parametric estimation, Delphi method, 3 Point Estimate, Expert Judgement, Published Data Estimates, Vendor Bid Analysis, Reserve Analysis, Bottom
I understand and can apply Upper and Lower Bound concepts in all fields of studies:
Upper and lower bounds are useful to find best case running time and worst case running time of an algorithm. In general lower bound means the best case running time and upper bound means the worst case running time…
To write the equation of a line in slope-intercept form (y=mx+b) given the slope (m) and y-intercept (b):
1) Identify the y-intercept as the y-value when x=0
2) Plug the slope (m) and y-intercept (b) into the slope-intercept equation
3) To write the equation when given two points, use the point-slope formula: y-y1=m(x-x1), where m is the slope calculated from the two points.
This document defines and provides examples of first degree equations, which are equations where the highest exponent of any variable is 1. All linear equations are first degree. An example first degree equation is 3x + 5 = 6. To identify a first degree equation, one checks which options have the highest exponent being 1. The option 8x - y = 3 is a first degree equation, while the others are not.
The document discusses integers and absolute value. It defines integers as positive or negative whole numbers, and provides examples of where integers are used in daily life like money, temperature, and years. It introduces positive and negative integers on a number line. The document explains how to write integers in real-life situations, graph integers on a number line, compare and order integers. It defines absolute value as the distance from zero on the number line and always being positive. It provides examples of evaluating absolute value expressions and using absolute value in real world contexts like eyeglass prescriptions.
1) A surd is a number whose square root is not a whole number. Common surds include √2, √3, √5.
2) Surds can be simplified by breaking numbers into factors where one is a perfect square.
3) Surds can be added, subtracted, multiplied, or divided following specific rules such as having the same basic form or multiplying by conjugates.
- The gradient or slope represents how steep a slope is, with uphill slopes being positive and downhill slopes being negative.
- The gradient is measured by the rise over the run, where rise is the vertical change in distance and run is the horizontal change in distance between two points.
- To find the gradient between two points, you create a right triangle between the points and calculate the rise as the vertical leg and the run as the horizontal leg, then plug those values into the formula: Gradient = Rise/Run.
The document provides objectives and examples for adding and subtracting polynomials. The objectives are to: 1) Add polynomials 2) Subtract polynomials 3) Solve problems involving adding and subtracting polynomials. Examples are provided to demonstrate representing quantities with tiles, adding polynomials by grouping like terms, and subtracting polynomials using the keep, change, change process.
This document discusses simplifying algebraic expressions through combining like terms, multiplying like terms, and evaluating expressions by substituting values for variables. It covers adding, subtracting, multiplying, and dividing terms. Examples are provided to demonstrate simplifying expressions with numbers and variables as well as evaluating expressions by replacing variables with values. Order of operations and dividing terms are also explained.
This document defines and classifies different types of polygons. It discusses simple vs complex polygons, concave vs convex polygons, and regular vs irregular polygons based on their geometric properties. It also provides names for polygons based on the number of sides, such as triangle, quadrilateral, pentagon, etc. up to polygons with 20 or more sides using Greek and Latin prefixes and suffixes.
- Integers include whole numbers and their opposites on the number line including zero. Positive numbers are greater than zero, while negative numbers are less than zero.
- Integers can be compared and ordered on a number line, with numbers to the left being less than those to the right. Their absolute values represent distances from zero.
- Integers are used to represent real-world concepts like temperature, elevation, and financial amounts, with positive integers for gains and negative for losses or amounts owed.
The document discusses adding polynomials. It provides examples of adding the polynomials of two students, Sam and Ted, who combined different fruits they each brought. It defines similar and dissimilar terms in polynomials and provides examples of adding various polynomial terms. The key steps in adding polynomials are identified as: 1) Identifying similar terms, 2) Grouping similar terms, and 3) Adding the similar terms by applying rules of adding integers. Real-life applications of adding polynomials are also discussed.
The document is a syllabus for Cambridge IGCSE Mathematics. It outlines the changes made to the syllabus for 2015, including some deleted content, clarification of existing content, and addition of new content. It provides an overview of the course, including the aims and objectives, syllabus content, assessment structure, and support available for teachers. The key information is that the syllabus has been updated for 2015 with some content removed, content clarified, and new content added related to topics like compound interest, exponential growth/decay, and graphing exponential functions.
12 13 igcse int'l math extended (y1,2) topic overviewRoss
The document provides an overview of the curriculum for International Mathematics Extended at IGCSE levels for Year 1 and Year 2. It lists the main units covered each year including the topics within each unit, recommended resources, and number of lessons. The units cover areas of algebra, number, geometry, probability, statistics, coordinate geometry, and trigonometry.
This document defines and describes different types of angles:
1) Adjacent angles share a common vertex and side. Vertically opposite angles are formed when two lines intersect and are equal.
2) Complementary angles have a sum of 90 degrees. Supplementary angles have a sum of 180 degrees.
3) A linear pair is two adjacent supplementary angles.
4) A transversal intersects two or more lines. It forms corresponding, alternate, and interior angles that follow specific properties.
Presentation on introducing whole numberVivek Kumar
The document defines and discusses properties of whole numbers. Whole numbers include all positive integers from 0 to infinity, and are represented by W. They include natural numbers and counting numbers. Key properties of whole numbers are that they are closed under addition and multiplication, follow the associative property, commutative property, and distributive property. Operations on whole numbers include addition, subtraction, multiplication, and division.
This document provides information about the Cartesian plane (or Cartesian coordinate system) including:
- It specifies each point uniquely using a pair of numerical coordinates that represent the distance from the point to two fixed perpendicular axes.
- Rene Descartes invented the Cartesian coordinate system to plot ordered pairs (x,y) on a plane with perpendicular x and y axes intersecting at the origin (0,0).
- The x-coordinate represents the horizontal axis and the y-coordinate represents the vertical axis. Ordered pairs written as (x, y) locate a point by moving left/right along the x-axis and up/down along the y-axis from the origin.
This document discusses how to solve equations and inequalities. It covers topics such as: balancing equations, combining like terms, expanding brackets, rearranging formulas to change the subject, representing inequalities on number lines, and solving one-step and two-step inequalities. Examples are provided to demonstrate each concept and practice problems are included for readers to try.
A net is an unfolded 3D shape laid out flat that makes it easy to see how many faces the shape has. The document shows different nets including cubes with 11 possible nets, cuboids with 54 possible nets, cylinders formed from two different nets, cones, square-based pyramids, triangular-based pyramids made of four triangles, and prisms which are made up of two base shapes along with rectangles, where the number of rectangles equals the number of sides of the base shape. An example net of a pentagonal prism is provided which has two pentagons and five rectangles.
This document provides definitions and examples related to circles and tangents. It defines key terms like radius, diameter, chord, secant, and tangent. Examples demonstrate identifying these segments and determining if lines are tangent to circles. Theorems are presented about properties of tangents, such as tangents being perpendicular to radii and two tangents from the same exterior point being congruent. Proofs of theorems are also provided. Exercises apply these concepts, like using properties of tangents to find missing values.
The document discusses the rectangular coordinate system and plotting points on a Cartesian plane. It begins by stating the objectives of understanding the rectangular coordinate system, plotting points, and completing tasks cooperatively. Classroom policies for discussions are outlined. A motivation activity called the "Row-Column Game" is described to call on students by row and column to answer questions about a seating chart. Concepts of the rectangular coordinate system like quadrants, axes, and ordered pairs are analyzed. The history of the system developed by René Descartes is provided. Examples are given to illustrate plotting points and connecting the rectangular coordinate system to real-life and other subjects. An assignment requires students to plot locations on a Cartesian plane and connect the points to form an object
Chapter 1 addition and subtraction of whole numbersrey castro
This document summarizes key concepts about addition and subtraction of whole numbers from a mathematics textbook. It explains addition as the combining of collections of objects, and subtraction as determining the remainder when part of a total is removed. The key processes of addition and subtraction are described step-by-step with examples. Properties of addition like commutativity and associativity are also explained with examples.
This document discusses simplifying complex rational expressions, which have numerators or denominators containing fractions. It provides two methods for simplification:
1) Multiplying the numerator and denominator by the lowest common denominator to clear fractions. Examples and steps are shown.
2) Dividing the numerator by the denominator after collecting like terms. An example problem is worked through to demonstrate the process. Objectives and learning outcomes are stated to guide readers.
* GSCE, IGCSE, IB, PSAT, and AISL - Exam Style Questions which covers all the related concepts required for students to unravel any International Exam Style Approximation and Estimation Questions [Upper and Lower Bound]
* Learner will be able to say authoritatively that:
I can solve any given Rounding Questions:
Estimate numbers using rounding, decimal places and significant figures. ...To estimate means to make a rough guess or calculation. To round means to simplify a known number by scaling it slightly up or down. Rounding is a type of estimating. Both methods can help you make educated approximations and can be used in everyday life for tasks related to money, time or distance.
While accurate estimates are the basis of sound project planning, there are many techniques used as project management best practices in estimation as - Analogous estimation, Parametric estimation, Delphi method, 3 Point Estimate, Expert Judgement, Published Data Estimates, Vendor Bid Analysis, Reserve Analysis, Bottom
I understand and can apply Upper and Lower Bound concepts in all fields of studies:
Upper and lower bounds are useful to find best case running time and worst case running time of an algorithm. In general lower bound means the best case running time and upper bound means the worst case running time…
To write the equation of a line in slope-intercept form (y=mx+b) given the slope (m) and y-intercept (b):
1) Identify the y-intercept as the y-value when x=0
2) Plug the slope (m) and y-intercept (b) into the slope-intercept equation
3) To write the equation when given two points, use the point-slope formula: y-y1=m(x-x1), where m is the slope calculated from the two points.
This document defines and provides examples of first degree equations, which are equations where the highest exponent of any variable is 1. All linear equations are first degree. An example first degree equation is 3x + 5 = 6. To identify a first degree equation, one checks which options have the highest exponent being 1. The option 8x - y = 3 is a first degree equation, while the others are not.
The document discusses integers and absolute value. It defines integers as positive or negative whole numbers, and provides examples of where integers are used in daily life like money, temperature, and years. It introduces positive and negative integers on a number line. The document explains how to write integers in real-life situations, graph integers on a number line, compare and order integers. It defines absolute value as the distance from zero on the number line and always being positive. It provides examples of evaluating absolute value expressions and using absolute value in real world contexts like eyeglass prescriptions.
1) A surd is a number whose square root is not a whole number. Common surds include √2, √3, √5.
2) Surds can be simplified by breaking numbers into factors where one is a perfect square.
3) Surds can be added, subtracted, multiplied, or divided following specific rules such as having the same basic form or multiplying by conjugates.
- The gradient or slope represents how steep a slope is, with uphill slopes being positive and downhill slopes being negative.
- The gradient is measured by the rise over the run, where rise is the vertical change in distance and run is the horizontal change in distance between two points.
- To find the gradient between two points, you create a right triangle between the points and calculate the rise as the vertical leg and the run as the horizontal leg, then plug those values into the formula: Gradient = Rise/Run.
The document provides objectives and examples for adding and subtracting polynomials. The objectives are to: 1) Add polynomials 2) Subtract polynomials 3) Solve problems involving adding and subtracting polynomials. Examples are provided to demonstrate representing quantities with tiles, adding polynomials by grouping like terms, and subtracting polynomials using the keep, change, change process.
This document discusses simplifying algebraic expressions through combining like terms, multiplying like terms, and evaluating expressions by substituting values for variables. It covers adding, subtracting, multiplying, and dividing terms. Examples are provided to demonstrate simplifying expressions with numbers and variables as well as evaluating expressions by replacing variables with values. Order of operations and dividing terms are also explained.
This document defines and classifies different types of polygons. It discusses simple vs complex polygons, concave vs convex polygons, and regular vs irregular polygons based on their geometric properties. It also provides names for polygons based on the number of sides, such as triangle, quadrilateral, pentagon, etc. up to polygons with 20 or more sides using Greek and Latin prefixes and suffixes.
- Integers include whole numbers and their opposites on the number line including zero. Positive numbers are greater than zero, while negative numbers are less than zero.
- Integers can be compared and ordered on a number line, with numbers to the left being less than those to the right. Their absolute values represent distances from zero.
- Integers are used to represent real-world concepts like temperature, elevation, and financial amounts, with positive integers for gains and negative for losses or amounts owed.
The document discusses adding polynomials. It provides examples of adding the polynomials of two students, Sam and Ted, who combined different fruits they each brought. It defines similar and dissimilar terms in polynomials and provides examples of adding various polynomial terms. The key steps in adding polynomials are identified as: 1) Identifying similar terms, 2) Grouping similar terms, and 3) Adding the similar terms by applying rules of adding integers. Real-life applications of adding polynomials are also discussed.
The document is a syllabus for Cambridge IGCSE Mathematics. It outlines the changes made to the syllabus for 2015, including some deleted content, clarification of existing content, and addition of new content. It provides an overview of the course, including the aims and objectives, syllabus content, assessment structure, and support available for teachers. The key information is that the syllabus has been updated for 2015 with some content removed, content clarified, and new content added related to topics like compound interest, exponential growth/decay, and graphing exponential functions.
12 13 igcse int'l math extended (y1,2) topic overviewRoss
The document provides an overview of the curriculum for International Mathematics Extended at IGCSE levels for Year 1 and Year 2. It lists the main units covered each year including the topics within each unit, recommended resources, and number of lessons. The units cover areas of algebra, number, geometry, probability, statistics, coordinate geometry, and trigonometry.
The document provides definitions and formulas for key project management terms related to scheduling, cost, earned value management, and forecasting. It defines acronyms like AC, BAC, CPI, CV, EAC, ETC, EV, FV, PERT, PV, SPI, SV, and formulas to calculate values for schedule performance, cost performance, variance, estimates, and more. Formulas include calculations for earned value, cost and schedule variances, estimate at completion, estimate to complete, present and future values, PERT estimates, return on invested capital, and standard deviation.
This document provides a syllabus for Cambridge IGCSE Mathematics. It outlines the aims of the curriculum, which are to develop students' mathematical knowledge, skills, and understanding in a way that provides enjoyment and confidence. It describes the assessment objectives of mathematical techniques and applying techniques to solve problems. It provides an assessment overview including exam paper formats, weightings, and grades available. Finally, it details the curriculum content covering topics like number, algebra, space/shape, and statistics/probability for both the core and extended curriculums.
1) A set is a collection of clearly defined elements that can be listed, described by their properties, or represented using a Venn diagram.
2) A null set has no elements, while an equal set contains elements that are the same as another set.
3) A subset contains all the elements of another set, while a proper subset contains some but not all elements of another set.
Wjec gcse exam prep higher paper unit 2Emma Sinclair
The document provides guidance for students taking the WJEC GCSE Higher Tier English exam. It explains that Paper Two will assess writing skills through two non-fiction writing tasks worth 20 marks each. Students will have one hour to complete both tasks and should spend around 30 minutes on each. The tasks will require students to write texts such as letters, articles, or reports for a specific audience and purpose. Students will be assessed on their ability to communicate clearly and engage the reader, organize their writing cohesively, and use accurate grammar and punctuation. The document provides tips on planning, structuring responses, and using language techniques to achieve a high grade.
The document provides revision materials for the Cambridge IGCSE Paper 2 exam, including:
- Checklists to help identify strengths and weaknesses in answering each type of question;
- Sample questions and responses to use for practice;
- Advice on developing strategic approaches to different questions. It focuses on three main question types: genre transformation, analyzing an author's use of language, and summarizing multiple passages. Students are encouraged to use the checklists and practice questions to strengthen their skills in areas they find most challenging.
This document provides notes on various mathematics topics for the IGCSE including: decimals and standard form, accuracy and error, powers and roots, ratio and proportion, and trigonometry. It includes examples and practice problems for each topic. The notes are intended to help with revision for IGCSE mathematics question papers and assessments.
The document provides guidance on approaching and answering the writing questions in Section B of an exam. It discusses the structure and requirements of the shorter and longer writing tasks, including time limits, number of ideas to plan, and how writing will be assessed. It also provides tips on writing techniques to use, such as varying sentence structure, using engaging vocabulary, and crafting powerful openings and closings. Sample marking schemes are included to demonstrate how responses will be evaluated on content and writing skills.
This document provides an overview of functions from chapter 1 of an additional mathematics module. It defines key terms like domain, codomain, range, and discusses different types of relations including one-to-one, many-to-one, and many-to-many. It also covers function notation, evaluating functions, composite functions, and provides examples of calculating images and objects of functions. The chapter aims to introduce students to the fundamental concepts of functions through definitions, diagrams, and practice exercises.
This document is the syllabus for Cambridge IGCSE Chemistry. It outlines the aims, assessment objectives, scheme of assessment, and curriculum content for the qualification. Some key points:
- The syllabus aims to provide students with knowledge and understanding of chemistry, as well as scientific skills. It prepares students for further study in sciences or science-related fields.
- Students are assessed on their knowledge and understanding, handling of information and problem solving, and experimental skills. The scheme of assessment includes multiple choice, structured questions, and practical papers.
- Students take Paper 1, 2 or 3, and one of Papers 4, 5 or 6. Paper 1 is multiple choice, Papers 2 and 3 test theoretical knowledge
This document is the syllabus for Cambridge IGCSE Biology. It outlines the aims, assessment objectives, scheme of assessment, curriculum content, and practical assessment requirements for the qualification. The key points are:
- The aims are to provide a worthwhile education in biology and develop scientific skills.
- Assessment objectives cover knowledge and understanding, handling information, and experimental skills.
- All candidates take Papers 1, 2 or 3, and either Paper 4, 5 or 6 to assess different objectives.
- The curriculum content and practical skills requirements are defined for teachers and learners.
The document is a syllabus for the Cambridge IGCSE Biology exam. It outlines the course content, assessment structure, and other details about the exam. Students can take either the core curriculum exam, aimed at grades D-G, or the extended curriculum exam, aimed at grades A*-C. All students must complete three papers: a multiple choice paper, a core or extended theory paper, and either a practical coursework paper, a practical exam, or an alternative paper.
This document is the syllabus for Cambridge IGCSE Chemistry. It outlines the aims of the syllabus, which are to provide students with an educational experience in experimental and practical science, and to enable students to gain understanding and knowledge to become informed citizens and prepare for further study. It also describes the three assessment objectives for the syllabus: knowledge with understanding, handling information and problem solving, and experimental skills and investigations. The syllabus content is divided into core and extended curriculum and includes topics such as atomic structure, chemical bonding, stoichiometry, acids and bases, the periodic table and organic chemistry. The assessment overview indicates that students take a multiple choice paper, a core or extended theory paper, and either a coursework,
This document provides information about the Cambridge IGCSE Mathematics syllabus and examinations for 2015. Key points include:
- The syllabus has been updated and restructured, with some content deleted or clarified.
- Candidates can follow either the Core or Extended curriculum. Those aiming for grades A* to C should follow the Extended curriculum.
- The examinations consist of two compulsory papers for all candidates, plus an additional two papers depending on whether a candidate follows the Core or Extended curriculum.
- The aims of the syllabus are to develop candidates' mathematical knowledge and skills through practical application and problem solving.
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1. SYLLABUS
Cambridge IGCSE®
Mathematics
Cambridge International Certificate*
0580
For examination in June and November 2014
Cambridge IGCSE®
Mathematics (with Coursework)
0581
For examination in June and November 2014
*This syllabus is accredited for use in England, Wales and Northern Ireland as a Cambridge International
Level 1/Level 2 Certificate.
3. Contents
1. Introduction ..................................................................................................................... 2
1.1
1.2
1.3
1.4
1.5
1.6
Why choose Cambridge?
Why choose Cambridge IGCSE?
Why choose Cambridge IGCSE Mathematics?
Cambridge International Certificate of Education (ICE)
Schools in England, Wales and Northern Ireland
How can I find out more?
2. Assessment at a glance .................................................................................................. 5
3. Syllabus aims and assessment ....................................................................................... 7
3.1 Syllabus aims
3.2 Assessment objectives and their weighting in the exam papers
4. Curriculum content........................................................................................................ 10
4.1 Grade descriptions
5. Coursework: guidance for centres ................................................................................ 20
5.1
5.2
5.3
5.4
Procedure
Selection of Coursework assignments
Suggested topics for Coursework assignments
Controlled elements
6. Coursework assessment criteria ................................................................................... 23
6.1 Scheme of assessment for Coursework assignments
6.2 Moderation
7. Appendix A ................................................................................................................... 29
8. Appendix B: Additional information ............................................................................... 33
9. Appendix C: Additional information – Cambridge International Level 1/Level 2
Certificates.................................................................................................................... 35
4. Introduction
1.
Introduction
1.1
Why choose Cambridge?
University of Cambridge International Examinations is the world’s largest provider of international education
programmes and qualifications for 5 to 19 year olds. We are part of the University of Cambridge, trusted for
excellence in education. Our qualifications are recognised by the world’s universities and employers.
Recognition
Every year, thousands of learners gain the Cambridge qualifications they need to enter the world’s
universities.
Cambridge IGCSE® (International General Certificate of Secondary Education) is internationally
recognised by schools, universities and employers as equivalent to UK GCSE. Learn more at
www.cie.org.uk/recognition
Excellence in education
We understand education. We work with over 9000 schools in over 160 countries who offer our
programmes and qualifications. Understanding learners’ needs around the world means listening carefully
to our community of schools, and we are pleased that 98% of Cambridge schools say they would
recommend us to other schools.
Our mission is to provide excellence in education, and our vision is that Cambridge learners become
confident, responsible, innovative and engaged.
Cambridge programmes and qualifications help Cambridge learners to become:
•
confident in working with information and ideas – their own and those of others
•
responsible for themselves, responsive to and respectful of others
•
innovative and equipped for new and future challenges
•
engaged intellectually and socially, ready to make a difference.
Support in the classroom
We provide a world-class support service for Cambridge teachers and exams officers. We offer a
wide range of teacher materials to Cambridge schools, plus teacher training (online and face-to-face),
expert advice and learner-support materials. Exams officers can trust in reliable, efficient administration
of exams entry and excellent, personal support from our customer services. Learn more at
www.cie.org.uk/teachers
Not-for-profit, part of the University of Cambridge
We are a part of Cambridge Assessment, a department of the University of Cambridge and a not-for-profit
organisation.
We invest constantly in research and development to improve our programmes and qualifications.
2
Cambridge IGCSE Mathematics 0580/0581
5. Introduction
1.2 Why choose Cambridge IGCSE?
Cambridge IGCSE helps your school improve learners’ performance. Learners develop not only knowledge
and understanding, but also skills in creative thinking, enquiry and problem solving, helping them to perform
well and prepare for the next stage of their education.
Cambridge IGCSE is the world’s most popular international curriculum for 14 to 16 year olds, leading to
globally recognised and valued Cambridge IGCSE qualifications. It is part of the Cambridge Secondary 2
stage.
Schools worldwide have helped develop Cambridge IGCSE, which provides an excellent preparation for
Cambridge International AS and A Levels, Cambridge Pre-U, Cambridge AICE (Advanced International
Certificate of Education) and other education programmes, such as the US Advanced Placement Program
and the International Baccalaureate Diploma. Cambridge IGCSE incorporates the best in international
education for learners at this level. It develops in line with changing needs, and we update and extend it
regularly.
1.3 Why choose Cambridge IGCSE Mathematics?
Cambridge IGCSE Mathematics is accepted by universities and employers as proof of mathematical
knowledge and understanding. Successful Cambridge IGCSE Mathematics candidates gain lifelong skills,
including:
•
the development of their mathematical knowledge;
•
confidence by developing a feel for numbers, patterns and relationships;
•
an ability to consider and solve problems and present and interpret results;
•
communication and reason using mathematical concepts;
•
a solid foundation for further study.
Cambridge IGCSE Mathematics is structured with a Coursework option and is ideal for candidates of
all abilities. There are a number of mathematics syllabuses at both Cambridge IGCSE and Cambridge
International AS & A Level offered by Cambridge – further information is available on the Cambridge website
at www.cie.org.uk
1.4 Cambridge International Certificate of Education (ICE)
Cambridge ICE is the group award of Cambridge IGCSE. It gives schools the opportunity to benefit
from offering a broad and balanced curriculum by recognising the achievements of learners who pass
examinations in at least seven subjects. Learners draw subjects from five subject groups, including two
languages, and one subject from each of the other subject groups. The seventh subject can be taken from
any of the five subject groups.
Mathematics falls into Group IV, Mathematics.
Learn more about Cambridge IGCSE and Cambridge ICE at www.cie.org.uk/cambridgesecondary2
Cambridge IGCSE Mathematics 0580/0581
3
6. Introduction
1.5 Schools in England, Wales and Northern Ireland
This Cambridge IGCSE is approved for regulation in England, Wales and Northern Ireland. It appears
on the Register of Regulated Qualifications http://register.ofqual.gov.uk as a Cambridge International
Level 1/Level 2 Certificate. There is more information for schools in England, Wales and Northern Ireland in
Appendix C to this syllabus.
School and college performance tables
Cambridge IGCSEs which are approved by Ofqual are eligible for inclusion in school and college
performance tables.
For up-to-date information on the performance tables, including the list of qualifications which
count towards the English Baccalaureate, please go to the Department for Education website
(www.education.gov.uk/performancetables). All approved Cambridge IGCSEs are listed as Cambridge
International Level 1/Level 2 Certificates.
1.6 How can I find out more?
If you are already a Cambridge school
You can make entries for this qualification through your usual channels. If you have any questions, please
contact us at international@cie.org.uk
If you are not yet a Cambridge school
Learn about the benefits of becoming a Cambridge school at www.cie.org.uk/startcambridge.
Email us at international@cie.org.uk to find out how your organisation can become a Cambridge school.
4
Cambridge IGCSE Mathematics 0580/0581
7. Assessment at a glance
2.
Assessment at a glance
Syllabus 0580 (without coursework)1
Core curriculum
Grades available: C–G
Paper 1
Extended curriculum
Grades available: A*–E
1 hour
Paper 2
1½ hours
Short-answer questions.
Short-answer questions.
Candidates should answer each question.
Candidates should answer each question.
Weighting: 35%
Weighting: 35%
Paper 3
2 hours
Paper 4
2½ hours
Structured questions.
Structured questions.
Candidates should answer each question.
Candidates should answer each question.
Weighting: 65%
Weighting: 65%
Syllabus 0581 (with coursework)
Core curriculum
Grades available: C–G
Paper 1
Extended curriculum
Grades available: A*–E
1 hour
Paper 2
1½ hours
Short-answer questions.
Short-answer questions.
Candidates should answer each question.
Candidates should answer each question.
Weighting: 30%
Weighting: 30%
Paper 3
2 hours
Paper 4
2½ hours
Structured questions.
Structured questions.
Candidates should answer each question.
Candidates should answer each question.
Weighting: 50%
Weighting: 50%
Paper 5
Paper 6
Coursework.
Coursework.
Weighting: 20%
Weighting: 20%
† Candidates who enter for the accredited version of this syllabus may only enter for Mathematics (without
coursework)
Cambridge IGCSE Mathematics 0580/0581
5
8. Assessment at a glance
•
Candidates should have an electronic calculator for all papers. Algebraic or graphical calculators are not
permitted. Three significant figures will be required in answers except where otherwise stated.
•
Candidates should use the value of π from their calculators if their calculator provides this. Otherwise,
they should use the value of 3.142 given on the front page of the question paper only.
•
Tracing paper may be used as an additional material for each of the written papers.
•
For syllabus 0581, the Coursework components (papers 5 and 6) will be assessed by the teacher using
the criteria given in this syllabus. The work will then be externally moderated by Cambridge. Teachers
may not undertake school-based assessment of Coursework without the written approval of Cambridge.
This will only be given to teachers who satisfy Cambridge requirements concerning moderation and
who have undertaken special training in assessment before entering candidates. Cambridge offers
schools in-service training via the Coursework Training Handbook.
•
For 0581, a candidate’s Coursework grade cannot lower his or her overall result. Candidates entered for
Syllabus 0581 are graded first on Components 1+3+5 or 2+4+6 and then graded again on Components
1+3 or 2+4. If the grade achieved on the aggregate of the two written papers alone is higher then this
replaces the result achieved when the Coursework component is included. In effect, no candidate is
penalised for taking the Coursework component.
Availability
This syllabus is examined in the May/June examination series and the October/November examination
series.
0580 is available to private candidates. 0581 is not available to private candidates.
Combining this with other syllabuses
Candidates can combine these syllabuses in an examination series with any other Cambridge syllabus,
except:
•
syllabuses with the same title at the same level
•
0607 Cambridge IGCSE International Mathematics
Please note that Cambridge IGCSE, Cambridge International Level 1/Level 2 Certificates and Cambridge
O Level syllabuses are at the same level.
6
Cambridge IGCSE Mathematics 0580/0581
9. Syllabus aims and assessment
3.
Syllabus aims and assessment
3.1 Syllabus aims
The aims of the curriculum are the same for all candidates. The aims are set out below and describe the
educational purposes of a course in Mathematics for the Cambridge IGCSE examination. They are not listed
in order of priority.
The aims are to enable candidates to:
1. develop their mathematical knowledge and oral, written and practical skills in a way which encourages
confidence and provides satisfaction and enjoyment;
2. read mathematics, and write and talk about the subject in a variety of ways;
3. develop a feel for number, carry out calculations and understand the significance of the results obtained;
4. apply mathematics in everyday situations and develop an understanding of the part which mathematics
plays in the world around them;
5. solve problems, present the solutions clearly, check and interpret the results;
6. develop an understanding of mathematical principles;
7. recognise when and how a situation may be represented mathematically, identify and interpret relevant
factors and, where necessary, select an appropriate mathematical method to solve the problem;
8. use mathematics as a means of communication with emphasis on the use of clear expression;
9. develop an ability to apply mathematics in other subjects, particularly science and technology;
10. develop the abilities to reason logically, to classify, to generalise and to prove;
11. appreciate patterns and relationships in mathematics;
12. produce and appreciate imaginative and creative work arising from mathematical ideas;
13. develop their mathematical abilities by considering problems and conducting individual and co-operative
enquiry and experiment, including extended pieces of work of a practical and investigative kind;
14. appreciate the interdependence of different branches of mathematics;
15. acquire a foundation appropriate to their further study of mathematics and of other disciplines.
Cambridge IGCSE Mathematics 0580/0581
7
10. Syllabus aims and assessment
3.2 Assessment objectives and their weighting in the exam papers
The two assessment objectives in Mathematics are:
A Mathematical techniques
B
Applying mathematical techniques to solve problems
A description of each assessment objective follows.
A
Mathematical techniques
Candidates should be able to:
1. organise, interpret and present information accurately in written, tabular, graphical and diagrammatic
forms;
2. perform calculations by suitable methods;
3. use an electronic calculator and also perform some straightforward calculations without a calculator;
4. understand systems of measurement in everyday use and make use of them in the solution of
problems;
5. estimate, approximate and work to degrees of accuracy appropriate to the context and convert between
equivalent numerical forms;
6. use mathematical and other instruments to measure and to draw to an acceptable degree of accuracy;
7. interpret, transform and make appropriate use of mathematical statements expressed in words or
symbols;
8. recognise and use spatial relationships in two and three dimensions, particularly in solving problems;
9. recall, apply and interpret mathematical knowledge in the context of everyday situations.
B
Applying mathematical techniques to solve problems
In questions which are set in context and/or which require a sequence of steps to solve, candidates should
be able to:
10. make logical deductions from given mathematical data;
11. recognise patterns and structures in a variety of situations, and form generalisations;
12. respond to a problem relating to a relatively unstructured situation by translating it into an appropriately
structured form;
13. analyse a problem, select a suitable strategy and apply an appropriate technique to obtain its solution;
14. apply combinations of mathematical skills and techniques in problem solving;
15. set out mathematical work, including the solution of problems, in a logical and clear form using
appropriate symbols and terminology.
8
Cambridge IGCSE Mathematics 0580/0581
11. Syllabus aims and assessment
Weighting of assessment objectives
The relationship between the assessment objectives and the scheme of assessment is set out in the tables
below.
Paper 1
(marks)
B: Applying mathematical techniques to
solve problems
Paper 3
(marks)
Paper 4
(marks)
42–48
A: Mathematical techniques
Paper 2
(marks)
28–35
78–88
52–65
8–14
35–42
16–26
65–78
Core assessment
Extended assessment
A: Mathematical techniques
75–85%
40–50%
B: Applying mathematical techniques to
solve problems
15–25%
50–60%
The relationship between the main topic areas of Mathematics and the assessment is set out in the table
below.
Number
Algebra
Space &
shape
Statistics
&
probability
Core (Papers 1 & 3)
30–35%
20–25%
30–35%
10–15%
Extended (Papers 2 & 4)
15–20%
35-40%
30–35%
10–15%
Cambridge IGCSE Mathematics 0580/0581
9
12. Curriculum content
4.
Curriculum content
Candidates may follow either the Core curriculum only or the Extended curriculum which involves
both the Core and Supplement. Candidates aiming for Grades A*–C should follow the Extended
Curriculum.
Centres are reminded that the study of mathematics offers opportunities for the use of ICT, particularly
spreadsheets and graph-drawing packages. For example, spreadsheets may be used in the work on
Percentages (section 11), Personal and household finance (section 15), Algebraic formulae (section 20),
Statistics (section 33), etc. Graph-drawing packages may be used in the work on Graphs in practical
situations (section 17), Graphs of functions (section 18), Statistics (section 33), etc. It is important to note
that use or knowledge of ICT will not be assessed in the examination papers.
Centres are also reminded that, although use of an electronic calculator is permitted on all examination
papers, candidates should develop a full range of mental and non-calculator skills during the course of study.
Questions demonstrating the mastery of such skills may be asked in the examination.
As well as demonstrating skill in the following techniques, candidates will be expected to apply them in the
solution of problems.
1. Number, set notation and language
Core
Identify and use natural numbers, integers
(positive, negative and zero), prime numbers,
square numbers, common factors and common
multiples, rational and irrational numbers
(e.g. π , 2 ), real numbers; continue a given
number sequence; recognise patterns in
sequences and relationships between different
sequences, generalise to simple algebraic
statements (including expressions for the nth term)
relating to such sequences.
Supplement
Use language, notation and Venn diagrams to
describe sets and represent relationships between
sets as follows:
Definition of sets, e.g.
A = {x: x is a natural number}
B = {(x,y): y = mx + c}
C = {x: a Y x Y b}
D = {a, b, c, …}
Notation
Number of elements in set A
n(A)
“…is an element of…”
∈
“…is not an element of…”
∉
Complement of set A
A’
The empty set
∅
Universal set
A is a subset of B
A is a proper subset of B
A⊈B
A is not a proper subset of B
A⊄B
Union of A and B
A∪B
Intersection of A and B
Cambridge IGCSE Mathematics 0580/0581
A⊂B
A is not a subset of B
10
A⊆B
A∩B
13. Curriculum content
2. Squares and cubes
Core
Calculate squares, square roots, cubes and cube
roots of numbers.
3. Directed numbers
Core
Use directed numbers in practical situations
(e.g. temperature change, flood levels).
4. Vulgar and decimal fractions and percentages
Core
Use the language and notation of simple vulgar and
decimal fractions and percentages in appropriate
contexts; recognise equivalence and convert
between these forms.
5. Ordering
Core
Order quantities by magnitude and demonstrate
familiarity with the symbols =, Œ, K, I, [ , Y
6. Standard form
Core
Use the standard form A × 10n where n is a
positive or negative integer, and 1 Y A I=10
7. The four rules
Core
Use the four rules for calculations with whole
numbers, decimal fractions and vulgar (and mixed)
fractions, including correct ordering of operations
and use of brackets.
8. Estimation
Core
Make estimates of numbers, quantities and
lengths, give approximations to specified numbers
of significant figures and decimal places and round
off answers to reasonable accuracy in the context
of a given problem.
9. Limits of accuracy
Core
Give appropriate upper and lower bounds for
data given to a specified accuracy (e.g. measured
lengths).
Supplement
Obtain appropriate upper and lower bounds to
solutions of simple problems (e.g. the calculation of
the perimeter or the area of a rectangle) given data
to a specified accuracy.
Cambridge IGCSE Mathematics 0580/0581
11
14. Curriculum content
10. Ratio, proportion, rate
Core
Demonstrate an understanding of the elementary
ideas and notation of ratio, direct and inverse
proportion and common measures of rate; divide
a quantity in a given ratio; use scales in practical
situations; calculate average speed.
Supplement
Express direct and inverse variation in algebraic
terms and use this form of expression to find
unknown quantities; increase and decrease a
quantity by a given ratio.
11. Percentages
Core
Calculate a given percentage of a quantity; express
one quantity as a percentage of another; calculate
percentage increase or decrease.
12. Use of an electronic calculator
Core
Use an electronic calculator efficiently; apply
appropriate checks of accuracy.
13. Measures
Core
Use current units of mass, length, area, volume
and capacity in practical situations and express
quantities in terms of larger or smaller units.
14. Time
Core
Calculate times in terms of the 24-hour and
12-hour clock; read clocks, dials and timetables.
15. Money
Core
Calculate using money and convert from one
currency to another.
16. Personal and household finance
Core
Use given data to solve problems on personal
and household finance involving earnings, simple
interest and compound interest (knowledge
of compound interest formula is not required),
discount, profit and loss; extract data from tables
and charts.
12
Cambridge IGCSE Mathematics 0580/0581
Supplement
Carry out calculations involving reverse
percentages, e.g. finding the cost price given the
selling price and the percentage profit.
15. Curriculum content
17. Graphs in practical situations
Core
Demonstrate familiarity with Cartesian co-ordinates
in two dimensions, interpret and use graphs in
practical situations including travel graphs and
conversion graphs, draw graphs from given data.
Supplement
Apply the idea of rate of change to easy kinematics
involving distance-time and speed-time graphs,
acceleration and deceleration; calculate distance
travelled as area under a linear speed-time graph.
18. Graphs of functions
Core
Construct tables of values for functions of the form
ax + b, ±x 2 + ax + b, a/x (x Œ 0) where a and b are
integral constants; draw and interpret such graphs;
find the gradient of a straight line graph; solve
linear and quadratic equations approximately by
graphical methods.
Supplement
Construct tables of values and draw graphs for
functions of the form axn where a is a rational
constant and n = –2, –1, 0, 1, 2, 3 and simple sums
of not more than three of these and for functions of
the form ax where a is a positive integer; estimate
gradients of curves by drawing tangents; solve
associated equations approximately by graphical
methods.
19. Straight line graphs
Core
Interpret and obtain the equation of a straight
line graph in the form y = mx + c; determine the
equation of a straight line parallel to a given line.
Supplement
Calculate the gradient of a straight line from the
co-ordinates of two points on it; calculate the
length and the co-ordinates of the midpoint of a
straight line segment from the co-ordinates of its
end points.
20. Algebraic representation and formulae
Core
Use letters to express generalised numbers and
express basic arithmetic processes algebraically,
substitute numbers for words and letters in
formulae; transform simple formulae; construct
simple expressions and set up simple equations.
Supplement
Construct and transform more complicated
formulae and equations.
21. Algebraic manipulation
Core
Manipulate directed numbers; use brackets and
extract common factors.
Supplement
Expand products of algebraic expressions;
factorise where possible expressions of the form
ax + bx + kay + kby, a 2x 2 – b 2y 2; a 2 + 2ab + b 2;
ax 2 + bx + c
manipulate algebraic fractions, e.g.
2x
3
−
(
3 x −5
2
),
3a
4
×
5ab
3
,
x
3
+
x −4
2
,
3a 9a
1
2
−
,
+
4
10 x − 2 x − 3
factorise and simplify expressions such as
2
x - 2x
2
x - 5x + 6
Cambridge IGCSE Mathematics 0580/0581
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16. Curriculum content
22. Functions
Supplement
Use function notation, e.g. f(x) = 3x – 5,
f: x a 3x – 5 to describe simple functions, and
the notation f–1(x) to describe their inverses; form
composite functions as defined by gf(x) = g(f(x))
23. Indices
Core
Use and interpret positive, negative and zero
indices.
Supplement
Use and interpret fractional indices, e.g. solve
32x = 2
24. Solutions of equations and inequalities
Core
Solve simple linear equations in one unknown;
solve simultaneous linear equations in two
unknowns.
Supplement
Solve quadratic equations by factorisation,
completing the square or by use of the formula;
solve simple linear inequalities.
25. Linear programming
Supplement
Represent inequalities graphically and use this
representation in the solution of simple linear
programming problems (the conventions of using
broken lines for strict inequalities and shading
unwanted regions will be expected).
26. Geometrical terms and relationships
Core
Use and interpret the geometrical terms: point,
line, parallel, bearing, right angle, acute, obtuse and
reflex angles, perpendicular, similarity, congruence;
use and interpret vocabulary of triangles,
quadrilaterals, circles, polygons and simple solid
figures including nets.
27. Geometrical constructions
Core
Measure lines and angles; construct a triangle
given the three sides using ruler and pair
of compasses only; construct other simple
geometrical figures from given data using
protractors and set squares as necessary;
construct angle bisectors and perpendicular
bisectors using straight edges and pair of
compasses only; read and make scale drawings.
14
Cambridge IGCSE Mathematics 0580/0581
Supplement
Use the relationships between areas of similar
triangles, with corresponding results for similar
figures and extension to volumes and surface areas
of similar solids.
17. Curriculum content
28. Symmetry
Core
Recognise rotational and line symmetry (including
order of rotational symmetry) in two dimensions
and properties of triangles, quadrilaterals and
circles directly related to their symmetries.
Supplement
Recognise symmetry properties of the prism
(including cylinder) and the pyramid (including
cone); use the following symmetry properties of
circles:
(a) equal chords are equidistant from the centre
(b) the perpendicular bisector of a chord passes
through the centre
(c) tangents from an external point are equal in
length.
29. Angle properties
Core
Calculate unknown angles using the following
geometrical properties:
Supplement
Use in addition the following geometrical
properties:
(a) angles at a point
(a) angle properties of irregular polygons
(b) angles at a point on a straight line and
intersecting straight lines
(b) angle at the centre of a circle is twice the angle
at the circumference
(c) angles formed within parallel lines
(c) angles in the same segment are equal
(d) angle properties of triangles and quadrilaterals
(d) angles in opposite segments are
supplementary; cyclic quadrilaterals.
(e) angle properties of regular polygons
(f) angle in a semi-circle
(g) angle between tangent and radius of a circle.
30. Locus
Core
Use the following loci and the method of
intersecting loci for sets of points in two
dimensions:
(a) which are at a given distance from a given point
(b) which are at a given distance from a given
straight line
(c) which are equidistant from two given points
(d) which are equidistant from two given
intersecting straight lines.
31. Mensuration
Core
Carry out calculations involving the perimeter and
area of a rectangle and triangle, the circumference
and area of a circle, the area of a parallelogram and
a trapezium, the volume of a cuboid, prism and
cylinder and the surface area of a cuboid and a
cylinder.
Supplement
Solve problems involving the arc length and sector
area as fractions of the circumference and area of
a circle, the surface area and volume of a sphere,
pyramid and cone (given formulae for the sphere,
pyramid and cone).
Cambridge IGCSE Mathematics 0580/0581
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18. Curriculum content
32. Trigonometry
Core
Interpret and use three-figure bearings measured
clockwise from the North (i.e. 000°–360°);
apply Pythagoras’ theorem and the sine, cosine
and tangent ratios for acute angles to the
calculation of a side or of an angle of a right-angled
triangle (angles will be quoted in, and answers
required in, degrees and decimals to one decimal
place).
Supplement
Solve trigonometrical problems in two dimensions
involving angles of elevation and depression;
extend sine and cosine values to angles between
90° and 180°; solve problems using the sine and
cosine rules for any triangle and the formula area of
1
triangle = 2 ab sin C, solve simple trigonometrical
problems in three dimensions including angle
between a line and a plane.
33. Statistics
Core
Collect, classify and tabulate statistical data; read,
interpret and draw simple inferences from tables
and statistical diagrams; construct and use bar
charts, pie charts, pictograms, simple frequency
distributions, histograms with equal intervals and
scatter diagrams (including drawing a line of best
fit by eye); understand what is meant by positive,
negative and zero correlation; calculate the mean,
median and mode for individual and discrete data
and distinguish between the purposes for which
they are used; calculate the range.
Supplement
Construct and read histograms with equal and
unequal intervals (areas proportional to frequencies
and vertical axis labelled 'frequency density');
construct and use cumulative frequency diagrams;
estimate and interpret the median, percentiles,
quartiles and inter-quartile range; calculate an
estimate of the mean for grouped and continuous
data; identify the modal class from a grouped
frequency distribution.
34. Probability
Core
Calculate the probability of a single event as either
a fraction or a decimal (not a ratio); understand and
use the probability scale from 0 to 1; understand
that: the probability of an event occurring = 1 – the
probability of the event not occurring; understand
probability in practice, e.g. relative frequency.
Supplement
Calculate the probability of simple combined
events, using possibility diagrams and tree
diagrams where appropriate (in possibility diagrams
outcomes will be represented by points on a grid
and in tree diagrams outcomes will be written at
the end of branches and probabilities by the side of
the branches).
35. Vectors in two dimensions
Core
Describe a translation by using a vector
x
represented by e.g. , AB or a;
y
add and subtract vectors; multiply a vector by a
scalar.
Supplement
Calculate the magnitude of a vector
x2 + y 2 .
x
as
y
(Vectors will be printed as AB or a and their
magnitudes denoted by modulus signs, e.g. AB
or a. In their answers to questions candidates are
expected to indicate a in some definite way, e.g. by
an arrow or by underlining, thus AB or a)
Represent vectors by directed line segments; use
the sum and difference of two vectors to express
given vectors in terms of two coplanar vectors; use
position vectors
16
Cambridge IGCSE Mathematics 0580/0581
19. Curriculum content
36. Matrices
Supplement
Display information in the form of a matrix of
any order; calculate the sum and product (where
appropriate) of two matrices; calculate the product
of a matrix and a scalar quantity; use the algebra of
2 × 2 matrices including the zero and identity 2 × 2
matrices; calculate the determinant and inverse A –1
of a non-singular matrix A
37. Transformations
Core
Reflect simple plane figures in horizontal or
vertical lines; rotate simple plane figures about
the origin, vertices or midpoints of edges of
the figures, through multiples of 90°; construct
given translations and enlargements of simple
plane figures; recognise and describe reflections,
rotations, translations and enlargements.
Supplement
Use the following transformations of the plane:
reflection (M); rotation (R); translation (T);
enlargement (E); shear (H); stretch (S) and their
combinations (if M(a) = b and R(b) = c the notation
RM(a) = c will be used; invariants under these
transformations may be assumed.)
Identify and give precise descriptions of
transformations connecting given figures; describe
transformations using co-ordinates and matrices
(singular matrices are excluded).
Cambridge IGCSE Mathematics 0580/0581
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20. Curriculum content
4.1 Grade descriptions
Grade Descriptions are provided to give a general indication of the standards of achievement likely to have
been shown by candidates awarded particular grades. The grade awarded will depend in practice upon the
extent to which the candidate has met the assessment objectives overall. Shortcomings in some aspects
of a candidate’s performance in the examination may be balanced by a better performance in others.
Grade F
At this level, candidates are expected to identify and obtain necessary information. They would be expected
to recognise if their results to problems are sensible. An understanding of simple situations should enable
candidates to describe them, using symbols, words and diagrams. They draw simple, basic conclusions with
explanations where appropriate.
•
With an understanding of place value, candidates should be able to perform the four rules on positive
integers and decimal fractions (one operation only) using a calculator where necessary. They should be
able to convert between fractions, decimals and percentages for the purpose of comparing quantities
between 0 and 1 in a variety of forms, and reduce a fraction to its simplest form. Candidates should
appreciate the idea of direct proportion and the solution of simple problems involving ratio should be
expected. Basic knowledge of percentage is needed to apply to simple problems involving percentage
parts of quantities. They need to understand and apply metric units of length, mass and capacity,
together with conversion between units in these areas of measure. The ability to recognise and continue
a straightforward pattern in sequences and understand the terms multiples, factors and squares is
needed as a foundation to higher grade levels of applications in the areas of number and algebra.
•
At this level, the algebra is very basic involving the construction of simple algebraic expressions,
substituting numbers for letters and evaluating simple formulae. Candidates should appreciate how a
simple linear equation can represent a practical situation and be able to solve such equations.
•
Knowledge of names and recognition of simple plane figures and common solids is basic to an
understanding of shape and space. This will be applied to the perimeter and area of a rectangle and
other rectilinear shapes. The skill of using geometrical instruments, ruler, protractor and compasses is
required for applying to measuring lengths and angles and drawing a triangle given three sides.
•
Candidates should be familiar with reading data from a variety of sources and be able to extract data
from them, in particular timetables. The tabulation of the data is expected in order to form frequency
tables and draw a bar chart. They will need the skill of plotting given points on a graph and reading a
travel graph. From a set of numbers they should be able to calculate the mean.
Grade C
At this level, candidates are expected to show some insight into the mathematical structures of problems,
which enables them to justify generalisations, arguments or solutions. Mathematical presentation and
stages of derivations should be more extensive in order to generate fuller solutions. They should appreciate
the difference between mathematical explanation and experimental evidence.
•
18
Candidates should now apply the four rules of number to positive and negative integers, fractions
and decimal fractions, in order to solve problems. Percentage should be extended to problems
involving calculating one quantity as a percentage of another and its application to percentage change.
Calculations would now involve several operations and allow candidates to demonstrate fluent and
efficient use of calculators, as well as giving reasonable approximations. The relationship between
decimal and standard form of a number should be appreciated and applied to positive and negative
powers of 10. They should be familiar with the differences between simple and compound interest and
apply this to calculating both.
Cambridge IGCSE Mathematics 0580/0581
21. Curriculum content
•
Candidates now need to extend their basic knowledge of sequences to recognise, and in simple cases
formulate, rules for generating a pattern or sequence. While extending the level of difficulty of solving
linear equations by involving appropriate algebraic manipulation, candidates are also expected to solve
simple simultaneous equations in two unknowns. Work with formulae extends into harder substitution
and evaluating the remaining term, as well as transforming simple formulae. The knowledge of basic
algebra is extended to the use of brackets and common factor factorisation. On graph work candidates
should be able to plot points from given values and use them to draw and interpret graphs in practical
situations, including travel and conversion graphs and algebraic graphs of linear and quadratic functions.
•
Candidates are expected to extend perimeter and area beyond rectilinear shapes to circles. They are
expected to appreciate and use area and volume units in relation to finding the volume and surface
area of a prism and cylinder. The basic construction work, with appropriate geometrical instruments,
should now be extended and applied to accurate scale diagrams to solve a two-dimensional problem.
Pythagoras theorem and trigonometry of right-angled triangles should be understood and applied
to solving, by calculation, problems in a variety of contexts. The calculation of angles in a variety
of geometrical figures, including polygons and to some extent circles should be expected from
straightforward diagrams.
•
Candidates should be able to use a frequency table to construct a pie chart. They need to understand
and construct a scatter diagram and apply this to a judgement of the correlation existing between two
quantities.
Grade A
At this level, candidates should make clear, concise and accurate statements, demonstrating ease and
confidence in the use of symbolic forms and accuracy or arithmetic manipulation. They should apply the
mathematics they know in familiar and unfamiliar contexts.
•
Candidates are expected to apply their knowledge of rounding to determining the bounds of intervals,
which may follow calculations of, for example, areas. They should understand and use direct and
inverse proportion. A further understanding of percentages should be evident by relating percentage
change to change to a multiplying factor and vice versa, e.g. multiplication by 1.03 results in a 3%
increase.
•
Knowledge of the four rules for fractions should be applied to the simplification of algebraic fractions.
Building on their knowledge of algebraic manipulation candidates should be able to manipulate linear,
simultaneous and quadratic equations. They should be able to use positive, negative and fractional
indices in both numerical and algebraic work, and interpret the description of a situation in terms of
algebraic formulae and equations. Their knowledge of graphs of algebraic functions should be extended
to the intersections and gradients of these graphs.
•
The basic knowledge of scale factors should be extended to two and three dimensions and applied to
calculating lengths, areas and volumes between actual values and scale models. The basic right-handed
trigonometry knowledge should be applied to three-dimensional situations as well as being extended to
an understanding of and solving problems on non-right angled triangles.
•
At this level, candidates should be able to process data, discriminating between necessary and
redundant information. The basic work on graphs in practical situations should be extended to making
quantitative and qualitative deductions from distance/time and speed/time graphs.
Cambridge IGCSE Mathematics 0580/0581
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22. Coursework: guidance for centres
5.
Coursework: guidance for centres
The Coursework component provides candidates with an additional opportunity to show their ability in
Mathematics. This opportunity relates to all abilities covered by the Assessment Objectives, but especially
to the last five, where an extended piece of work can demonstrate ability more fully than an answer to a
written question.
Coursework should aid development of the ability
•
to solve problems,
•
to use mathematics in a practical way,
•
to work independently,
•
to apply mathematics across the curriculum,
and if suitable assignments are selected, it should enhance interest in, and enjoyment of, the subject.
Coursework assignments should form an integral part of both Cambridge IGCSE Mathematics courses:
whether some of this Coursework should be submitted for assessment (syllabus 0581), or not (syllabus
0580), is a matter for the teacher and the candidate to decide. A candidate’s Coursework grade cannot
lower his or her overall result.
5.1 Procedure
(a) Candidates should submit one Coursework assignment.
(b) Coursework can be undertaken in class, or in the candidate’s own time. If the latter, the teacher must
be convinced that the piece is the candidate’s own unaided work, and must sign a statement to that
effect (see also Section 5.4 Controlled Elements).
(c) A good Coursework assignment is normally between 8 and 15 sides of A4 paper in length. These
figures are only for guidance; some projects may need to be longer in order to present all the findings
properly, and some investigations might be shorter although all steps should be shown.
(d) The time spent on a Coursework assignment will vary, according to the candidate. As a rough guide,
between 10 and 20 hours is reasonable.
20
Cambridge IGCSE Mathematics 0580/0581
23. Coursework: guidance for centres
5.2 Selection of Coursework assignments
(a) The topics for the Coursework assignments may be selected by the teacher, or (with guidance) by the
candidates themselves.
(b) Since individual input is essential for high marks, candidates should work on different topics. However,
it is possible for the whole class to work on the same topic, provided that account is taken of this in the
final assessment.
(c) Teachers should ensure that each topic corresponds to the ability of the candidate concerned. Topics
should not restrict the candidate and should enable them to show evidence of attainment at the highest
level of which they are capable. However, topics should not be chosen which are clearly beyond the
candidate’s ability.
(d) The degree of open-endedness of each topic is at the discretion of the teacher. However, each topic
selected should be capable of extension, or development beyond any routine solution, so as to give full
rein to the more imaginative candidate.
(e) The principal consideration in selecting a topic should be the potential for mathematical activity. With
that proviso, originality of topics should be encouraged.
(f) Some candidates may wish to use a computer at various stages of their Coursework assignment. This
should be encouraged, but they must realise that work will be assessed on personal input, and not what
the computer does for them. Software sources should be acknowledged.
5.3 Suggested topics for Coursework assignments
Good mathematical assignments can be carried out in many different areas. It is an advantage if a suitable
area can be found which matches the candidate’s own interests.
Some suggestions for Coursework assignments are:
A mathematical investigation
There are many good investigations available from various sources: books, the Internet, etc. The
objective is to obtain a mathematical generalisation for a given situation.
At the highest level, candidates should consider a complex problem which involves the co-ordination of
three features or variables.
An application of mathematics
Packaging – how can four tennis balls be packaged so that the least area of card is used?
Designing a swimming pool
Statistical analysis of a survey conducted by the candidate
Simulation games
Surveying – taking measurements and producing a scale drawing or model
At the highest level, candidates should consider a complex problem which involves mathematics at grade A.
(See the section on grade descriptions.)
Teachers should discuss assignments with the candidates to ensure that they have understood what is
required and know how to start. Thereafter, teachers should only give hints if the candidate is completely
stuck.
Computer software packages may be used to enhance presentation, perform repetitive calculations or draw
graphs.
Cambridge IGCSE Mathematics 0580/0581
21
24. Coursework: guidance for centres
5.4 Controlled elements
(a) The controlled element is included to assist the teacher in checking
(i) the authenticity of the candidate’s work,
(ii) the extent of the candidate’s learning of Mathematics, and its retention,
(iii) the depth of understanding of the Mathematics involved,
(iv) the ability to apply the learning to a different situation.
(b) The element must be carried out individually by the candidates under controlled conditions, but may
take any appropriate form, provided that the results are available for moderation, e.g.
a timed or untimed written test,
an oral exchange between the candidate and the teacher,
a parallel investigation or piece of work,
a parallel piece of practical work, or practical test including a record of the results,
a written summary or account.
22
Cambridge IGCSE Mathematics 0580/0581
25. Coursework assessment criteria
6.
Coursework assessment criteria
6.1 Scheme of assessment for Coursework assignments
(a) The whole range of marks is available at each level. The five classifications each have a maximum
of 4 marks, awarded on a five-point scale, 0, 1, 2, 3, 4. For Coursework as a whole, including the
controlled element, a maximum of 20 marks is available. Participating schools should use the forms at
the back of the syllabus on which to enter these marks.
(b) Assignments are part of the learning process for the candidates, and it is expected that they will receive
help and advice from their teachers. The marks awarded must reflect the personal contributions of the
candidates, including the extent to which they use the advice they receive in the development of the
assignments.
(c) The way in which the accuracy marks are allocated will vary from one assignment to another.
Numerical accuracy, accuracy of manipulation in algebra, accuracy in the use of instruments, care in
the construction of graphs and use of the correct units in measuring, are all aspects which may need
consideration in particular assignments.
(d) If a candidate changes his or her level of entry during the course, Coursework already completed
and assessed by the teacher will have to be reassessed according to the new entry option before
moderation. A candidate being re-entered at the higher level (Extended curriculum) must be given the
opportunity to extend any assignment already completed before it is re-assessed.
(e) The use of ICT is to be encouraged; however, teachers should not give credit to candidates for the
skills needed to use a computer software package. For example, if data is displayed graphically by
a spreadsheet, then credit may be given for selecting the most appropriate graph to draw and for its
interpretation.
(f) Further information about the assessment of Coursework is given in the Coursework Training Handbook
and at training sessions.
The following tables contain detailed criteria for the award of marks from 0 to 4 under the five categories
of assessment (overall design and strategy, mathematical content, accuracy, clarity of argument and
presentation, controlled element). For the Coursework component as a whole, a maximum of 20 marks is
available.
Cambridge IGCSE Mathematics 0580/0581
23
26. Coursework assessment criteria
Overall design and strategy
Assessment Criteria
Much help has been received.
No apparent attempt has been made to plan the work
Core
Extended
0
0
1
0
2
1
3
2
4
3
4
4
Help has been received from the teacher, the peer group or a
prescriptive worksheet.
Little independent work has been done.
Some attempt has been made to solve the problem, but only at a
simple level.
The work is poorly organised, showing little overall plan.
Some help has been received from the teacher or the peer group.
A strategy has been outlined and an attempt made to follow it.
A routine approach, with little evidence of the candidate's own
ideas being used.
The work has been satisfactorily carried out, with some evidence
of forward planning.
Appropriate techniques have been used; although some of these
may have been suggested by others, the development and use of
them is the candidate’s own.
The work is well planned and organised.
The candidate has worked independently, devising and using
techniques appropriate to the task.
The candidate is aware of the wider implications of the task and
has attempted to extend it. The outcome of the task is clearly
explained.
The work is methodical and follows a flexible strategy to cope with
unforeseen problems.
The candidate has worked independently, the only assistance
received being from reference books or by asking questions arising
from the candidate’s own ideas.
The problem is solved, with generalisations where appropriate.
The task has been extended and the candidate has demonstrated
the wider implications.
24
Cambridge IGCSE Mathematics 0580/0581
27. Coursework assessment criteria
Mathematical content
Assessment Criteria
Core
0
The work is very largely descriptive or pictorial.
A few concepts and methods relevant to the task have been
employed, but in a superficial and repetitive manner.
A sufficient range of mathematical concepts which meet the basic
needs of the task has been employed.
More advanced mathematical methods may have been attempted,
but not necessarily appropriately or successfully.
The concepts and methods usually associated with the task have
been used, and the candidate has shown competence in using
them.
The candidate has used a wide range of Core syllabus mathematics
competently and relevantly, plus some mathematics from beyond
the Core syllabus.
0
1
Little or no evidence of any mathematical activity.
Extended
0
2
1
3
2
4
3
4
4
The candidate has developed the topic mathematically beyond the
usual and obvious. Mathematical explanations are concise.
A substantial amount of work, involving a wide range of
mathematical ideas and methods of Extended level standard or
beyond.
The candidate has employed, relevantly, some concepts and
methods not usually associated with the task in hand.
Some mathematical originality has been shown.
Cambridge IGCSE Mathematics 0580/0581
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28. Coursework assessment criteria
Accuracy
N.B. The mark for Accuracy should not normally exceed the mark for Mathematical Content.
Assessment Criteria
Very few calculations have been carried out, and errors have been
made in these.
Core
Extended
0
0
1
0
2
1
3
2
4
3 or 4*
Diagrams and tables are poor and mostly inaccurate.
Either
correct work on limited mathematical content
or
calculations performed on a range of Core syllabus
topics with some errors.
Diagrams and tables are adequate, but units are often omitted or
incorrect.
Calculations have been performed on all Core syllabus topics
relevant to the task, with only occasional slips.
Diagrams are neat and accurate, but routine; and tables contain
information with few errors.
The candidate has shown some idea of the appropriate degree of
accuracy for the data used.
Units are used correctly.
All the measurements and calculations associated with the task
have been completed accurately.
The candidate has shown an understanding of magnitude and
degree of accuracy when making measurements or performing
calculations.
Accurate diagrams are included, which support the written work.
Careful, accurate and relevant work throughout. This includes,
where appropriate, computation, manipulation, construction and
measurement with correct units.
Accurate diagrams are included which positively enhance the work,
and support the development of the argument.
The degree of accuracy is always correct and appropriate.
*According to the mark for mathematical content.
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Cambridge IGCSE Mathematics 0580/0581
29. Coursework assessment criteria
Clarity of argument and presentation
Assessment Criteria
Core
0
0
1
Haphazard organisation of work, which is difficult to follow. A
series of disconnected short pieces of work. Little or no attempt
to summarise the results.
Extended
0
2
1
3
2
4
3
4
4
Poorly presented work, lacking logical development.
Undue emphasis is given to minor aspects of the task, whilst
important aspects are not given adequate attention.
The work is presented in the order in which it happened to be
completed; no attempt is made to re-organise it into a logical order.
Adequate presentation which can be followed with some effort.
A reasonable summary of the work completed is given, though
with some lack of clarity and/or faults of emphasis.
The candidate has made some attempt to organise the work into a
logical order.
A satisfactory standard of presentation has been achieved.
The work has been arranged in a logical order.
Adequate justification has been given for any generalisations made.
The summary is clear, but the candidate has found some difficulty
in linking the various different parts of the task together.
The presentation is clear, using written, diagrammatic and graphical
methods as and when appropriate.
Conclusions and generalisations are supported by reasoned
statements which refer back to results obtained in the main body
of the work.
Disparate parts of the task have been brought together in a
competent summary.
The work is clearly expressed and easy to follow.
Mathematical and written language has been used to present the
argument; good use has been made of symbolic, graphical and
diagrammatic evidence in support.
The summary is clear and concise, with reference to the original
aims; there are also good suggestions of ways in which the work
might be extended, or applied in other areas.
Cambridge IGCSE Mathematics 0580/0581
27
30. Coursework assessment criteria
Controlled element
Assessment Criteria
Core
Extended
0
0
1
0
2
1
3
2
4
3 or 4*
Little or no evidence of understanding the problem.
Unable to communicate any sense of having learned something by
undertaking the original task.
Able to reproduce a few of the basic skills associated with the task,
but needs considerable prompting to get beyond this.
Can answer most of the questions correctly in a straightforward
test on the project.
Can answer questions about the problem and the methods used in
its solution.
Can discuss or write about the problem, in some detail.
Shows competence in the mathematical methods used in the work.
Little or no evidence of having thought about possible extensions to
the work or the application of methods to different situations.
Can talk or write fluently about the problem and its solution.
Has ideas for the extension of the problem, and the applicability of
the methods used in its solution to different situations.
*Dependent on the complexity of the problem and the quality of the ideas.
6.2 Moderation
Internal Moderation
When several teachers in a Centre are involved in internal assessments, arrangements must be made within
the Centre for all candidates to be assessed to a common standard. It is essential that within each Centre
the marks for each skill assigned within different teaching groups (e.g. different classes) are moderated
internally for the whole Centre entry. The Centre assessments will then be subject to external moderation.
External Moderation
External moderation of internal assessment is carried out by Cambridge. Centres must submit candidates’
internally assessed marks to Cambridge. The deadlines and methods for submitting internally assessed
marks are in the Cambridge Administrative Guide available on our website.
Once Cambridge has received the marks, Cambridge will select a sample of candidates whose work should
be submitted for external moderation. Cambridge will communicate the list of candidates to the Centre,
and the Centre should despatch the Coursework of these candidates to Cambridge immediately. Individual
Candidate Record Cards and Coursework Assessment Summary Forms (copies of which may be found at
the back of this syllabus booklet) must be enclosed with the Coursework.
Further information about external moderation may be found in the Cambridge Handbook and the
Cambridge Administrative Guide.
28
Cambridge IGCSE Mathematics 0580/0581
31. MATHEMATICS
Individual Candidate Record Card
IGCSE 2014
Please read the instructions printed overleaf and the General Coursework Regulations before completing this form.
Centre Number
Centre Name
June/November
Candidate Number
Candidate Name
Teaching Group/Set
2
0
1
4
Title(s) of piece(s) of work:
Classification of Assessment
Use space below for Teacher’s comments
(max 4)
Mathematical content
(max 4)
Accuracy
(max 4)
Clarity of argument and presentation
(max 4)
Controlled element
(max 4)
TOTAL
Mark to be transferred to Coursework Assessment Summary Form
(max 20)
WMS329
0581/05&06/CW/S/14
Appendix A
Cambridge IGCSE Mathematics 0580/0581
Overall design and strategy
Mark awarded
29
32. Cambridge IGCSE Mathematics 0580/0581
Appendix A
30
INSTRUCTIONS FOR COMPLETING INDIVIDUAL CANDIDATE RECORD CARDS
1. Complete the information at the head of the form.
2. Mark the item of Coursework for each candidate according to instructions given in the Syllabus and Training Handbook.
3. Enter marks and total marks in the appropriate spaces. Complete any other sections of the form required.
4. The column for teachers’ comments is to assist Cambridge’s moderation process and should include a reference to the marks awarded.
Comments drawing attention to particular features of the work are especially valuable to the Moderator.
5. Ensure that the addition of marks is independently checked.
6. It is essential that the marks of candidates from different teaching groups within each Centre are moderated internally. This means
that the marks awarded to all candidates within a Centre must be brought to a common standard by the teacher responsible for co-ordinating
the internal assessment (i.e. the internal moderator), and a single valid and reliable set of marks should be produced which reflects the relative
attainment of all the candidates in the Coursework component at the Centre.
7. Transfer the marks to the Coursework Assessment Summary Form in accordance with the instructions given on that document.
8. Retain all Individual Candidate Record Cards and Coursework which will be required for external moderation. Further detailed instructions
about external moderation will be sent in late March of the year of the June Examination and in early October of the year of the November
examination. See also the instructions on the Coursework Assessment Summary Form.
Note: These Record Cards are to be used by teachers only for candidates who have undertaken Coursework as part of their Cambridge IGCSE.
0581/05&06/CW/I/14
33. MATHEMATICS
Coursework Assessment Summary Form
IGCSE 2014
Please read the instructions printed overleaf and the General Coursework Regulations before completing this form.
Centre Number
Candidate
Number
Candidate Name
Centre Name
June/November
Teaching
Group/
Set
Title(s) of piece(s) of work
2
Total
Mark
(max 20)
Signature
Signature
4
Internally
Moderated
Mark
(max 20)
Date
Name of internal moderator
1
Date
WMS330
0581/05&06/CW/S/14
Appendix A
Cambridge IGCSE Mathematics 0580/0581
Name of teacher completing this form
0
31
34. Cambridge IGCSE Mathematics 0580/0581
Appendix A
32
A.
INSTRUCTIONS FOR COMPLETING COURSEWORK ASSESSMENT SUMMARY FORMS
1. Complete the information at the head of the form.
2. List the candidates in an order which will allow ease of transfer of information to a computer-printed Coursework mark sheet MS1 at a later stage
(i.e. in candidate index number order, where this is known; see item B.1 below). Show the teaching group or set for each candidate. The initials of
the teacher may be used to indicate group or set.
3. Transfer each candidate’s marks from his or her Individual Candidate Record Card to this form as follows:
(a) Where there are columns for individual skills or assignments, enter the marks initially awarded (i.e. before internal moderation took place).
(b) In the column headed ‘Total Mark’, enter the total mark awarded before internal moderation took place.
(c) In the column headed ‘Internally Moderated Mark’, enter the total mark awarded after internal moderation took place.
4. Both the teacher completing the form and the internal moderator (or moderators) should check the form and complete and sign the bottom portion.
B.
PROCEDURES FOR EXTERNAL MODERATION
1. University of Cambridge International Examinations sends a computer-printed Coursework mark sheet MS1 to each centre (in late March for the
June examination and in early October for the November examination) showing the names and index numbers of each candidate. Transfer the total
internally moderated mark for each candidate from the Coursework Assessment Summary Form to the computer-printed Coursework mark sheet
MS1.
2. The top copy of the computer-printed Coursework mark sheet MS1 must be despatched in the specially provided envelope to arrive as soon as
possible at Cambridge but no later than 30 April for the June examination and 31 October for the November examination.
3. Cambridge will select a list of candidates whose work is required for external moderation. As soon as this list is received, send the candidates’
work with the corresponding Individual Candidate Record Cards, this summary form and the second copy of the computer-printed mark sheet(s)
(MS1), to Cambridge. Indicate the candidates who are in the sample by means of an asterisk (*) against the candidates’ names overleaf.
4. Cambridge reserves the right to ask for further samples of Coursework.
5. If the Coursework involves three-dimensional work then clear photographs should be submitted in place of the actual models.
0581/05&06/CW/S/14
35. Appendix B: Additional information
8.
Appendix B: Additional information
Guided learning hours
Cambridge IGCSE syllabuses are designed on the assumption that candidates have about 130 guided
learning hours per subject over the duration of the course. (‘Guided learning hours’ include direct teaching
and any other supervised or directed study time. They do not include private study by the candidate.)
However, this figure is for guidance only, and the number of hours required may vary according to local
curricular practice and the candidates’ prior experience of the subject.
Recommended prior learning
We recommend that candidates who are beginning this course should have previously studied an
appropriate lower secondary Mathematics programme.
Progression
Cambridge IGCSE Certificates are general qualifications that enable candidates to progress either directly to
employment, or to proceed to further qualifications.
Candidates who are awarded grades C to A* in Cambridge IGCSE Extended tier Mathematics are well
prepared to follow courses leading to Cambridge International AS and A Level Mathematics, or the
equivalent.
Component codes
Because of local variations, in some cases component codes will be different in instructions about making
entries for examinations and timetables from those printed in this syllabus, but the component names will
be unchanged to make identification straightforward.
Grading and reporting
Cambridge IGCSE results are shown by one of the grades A*, A, B, C, D, E, F or G indicating the standard
achieved, Grade A* being the highest and Grade G the lowest. ‘Ungraded’ indicates that the candidate’s
performance fell short of the standard required for Grade G. ‘Ungraded’ will be reported on the statement
of results but not on the certificate.
Percentage uniform marks are also provided on each candidate’s statement of results to supplement their
grade for a syllabus. They are determined in this way:
•
A candidate who obtains…
… the minimum mark necessary for a Grade A* obtains a percentage uniform mark of 90%.
… the minimum mark necessary for a Grade A obtains a percentage uniform mark of 80%.
… the minimum mark necessary for a Grade B obtains a percentage uniform mark of 70%.
… the minimum mark necessary for a Grade C obtains a percentage uniform mark of 60%.
… the minimum mark necessary for a Grade D obtains a percentage uniform mark of 50%.
… the minimum mark necessary for a Grade E obtains a percentage uniform mark of 40%.
… the minimum mark necessary for a Grade F obtains a percentage uniform mark of 30%.
Cambridge IGCSE Mathematics 0580/0581
33
36. Appendix B: Additional information
… the minimum mark necessary for a Grade G obtains a percentage uniform mark of 20%.
… no marks receives a percentage uniform mark of 0%.
Candidates whose mark is none of the above receive a percentage mark in between those stated, according
to the position of their mark in relation to the grade ‘thresholds’ (i.e. the minimum mark for obtaining a
grade). For example, a candidate whose mark is halfway between the minimum for a Grade C and the
minimum for a Grade D (and whose grade is therefore D) receives a percentage uniform mark of 55%.
The percentage uniform mark is stated at syllabus level only. It is not the same as the ‘raw’ mark obtained
by the candidate, since it depends on the position of the grade thresholds (which may vary from one series
to another and from one subject to another) and it has been turned into a percentage.
Access
Reasonable adjustments are made for disabled candidates in order to enable them to access the
assessments and to demonstrate what they know and what they can do. For this reason, very few
candidates will have a complete barrier to the assessment. Information on reasonable adjustments is found
in the Cambridge Handbook which can be downloaded from the website www.cie.org.uk
Candidates who are unable to access part of the assessment, even after exploring all possibilities through
reasonable adjustments, may still be able to receive an award based on the parts of the assessment they
have taken.
Support and resources
Copies of syllabuses, the most recent question papers and Principal Examiners’ reports for teachers are on
the Syllabus and Support Materials CD-ROM, which we send to all Cambridge International Schools. They
are also on our public website – go to www.cie.org.uk/igcse. Click the Subjects tab and choose your
subject. For resources, click ‘Resource List’.
You can use the ‘Filter by’ list to show all resources or only resources categorised as ‘Endorsed by
Cambridge’. Endorsed resources are written to align closely with the syllabus they support. They have
been through a detailed quality-assurance process. As new resources are published, we review them
against the syllabus and publish their details on the relevant resource list section of the website.
Additional syllabus-specific support is available from our secure Teacher Support website
http://teachers.cie.org.uk which is available to teachers at registered Cambridge schools. It provides past
question papers and examiner reports on previous examinations, as well as any extra resources such as
schemes of work or examples of candidate responses. You can also find a range of subject communities on
the Teacher Support website, where Cambridge teachers can share their own materials and join discussion
groups.
34
Cambridge IGCSE Mathematics 0580/0581
37. Appendix C: Additional information – Cambridge International Level 1/Level 2 Certificates
9.
Appendix C: Additional information – Cambridge
International Level 1/Level 2 Certificates
Prior learning
Candidates in England who are beginning this course should normally have followed the Key Stage 3
programme of study within the National Curriculum for England.
Other candidates beginning this course should have achieved an equivalent level of general education.
NQF Level
This qualification is approved by Ofqual, the regulatory authority for England, as part of the National
Qualifications Framework as a Cambridge International Level 1/Level 2 Certificate.
Candidates who gain grades G to D will have achieved an award at Level 1 of the National Qualifications
Framework.
Candidates who gain grades C to A* will have achieved an award at Level 2 of the National Qualifications
Framework.
Progression
Cambridge International Level 1/Level 2 Certificates are general qualifications that enable candidates to
progress either directly to employment, or to proceed to further qualifications.
This syllabus provides a foundation for further study at Levels 2 and 3 in the National Qualifications
Framework, including GCSE, Cambridge International AS and A Level GCE, and Cambridge Pre-U
qualifications.
Candidates who are awarded grades C to A* are well prepared to follow courses leading to Level 3 AS and
A Level GCE Mathematics, Cambridge Pre-U Mathematics, IB Mathematics or the Cambridge International
AS and A Level Mathematics.
Guided learning hours
The number of guided learning hours required for this course is 130.
Guided learning hours are used to calculate the funding for courses in state schools in England, Wales
and Northern Ireland. Outside England, Wales and Northern Ireland, the number of guided learning hours
should not be equated to the total number of hours required by candidates to follow the course as the
definition makes assumptions about prior learning and does not include some types of learning time.
Overlapping qualifications
Centres in England, Wales and Northern Ireland should be aware that every syllabus is assigned to a
national classification code indicating the subject area to which it belongs. Candidates who enter for more
than one qualification with the same classification code will have only one grade (the highest) counted for
the purpose of the school and college performance tables. Candidates should seek advice from their school
on prohibited combinations.
Cambridge IGCSE Mathematics 0580/0581
35
38. Appendix C: Additional information – Cambridge International Level 1/Level 2 Certificates
Spiritual, ethical, social, legislative, economic and cultural issues
Spiritual: There is the opportunity for candidates to appreciate the concept of truth in a mathematical
context and to gain an insight into how patterns and symmetries rely on underlying mathematical principles.
Moral: Candidates are required to develop logical reasoning, thereby strengthening their abilities to make
sound decisions and assess consequences; they will also appreciate the importance of persistence in
problem solving.
Ethical: Candidates have the opportunity to develop an appreciation of when teamwork is appropriate and
valuable, but also to understand the need to protect the integrity of individual achievement.
Social: There is the opportunity for candidates to work together productively on complex tasks and to
appreciate that different members of a team have different skills to offer.
Cultural: Candidates are required to apply mathematics to everyday situations, thereby appreciating its
central importance to modern culture; by understanding that many different cultures have contributed to
the development of mathematics and that the language of mathematics is universal, candidates have the
opportunity to appreciate the inclusive nature of mathematics.
Sustainable development, health and safety considerations and international
developments
This syllabus offers opportunities to develop ideas on sustainable development and environmental issues
and the international dimension.
•
Sustainable development and environmental issues
Issues can be raised and addressed by questions set in context (e.g. pie charts; bar charts; optimising
resources).
•
The International dimension
Questions are set using varied international contexts (maps; currencies; journeys) and with cultural
sensitivity.
Avoidance of bias
Cambridge has taken great care in the preparation of this syllabus and assessment materials to avoid bias of
any kind.
Language
This syllabus and the associated assessment materials are available in English only.
Access
Reasonable adjustments are made for disabled candidates in order to enable them to access the
assessments and to demonstrate what they know and what they can do. For this reason, very few
candidates will have a complete barrier to the assessment. Information on reasonable adjustments is found
in the Cambridge Handbook which can be downloaded from the website www.cie.org.uk
Candidates who are unable to access part of the assessment, even after exploring all possibilities through
reasonable adjustments, may still be able to receive an award based on the parts of the assessment they
have taken.
36
Cambridge IGCSE Mathematics 0580/0581
39. Appendix C: Additional information – Cambridge International Level 1/Level 2 Certificates
Key Skills
The development of the Key Skills of application of number, communication, and information technology, along
with the wider Key Skills of improving your own learning and performance, working with others and problem
solving can enhance teaching and learning strategies and motivate students towards learning independently.
This syllabus will provide opportunities to develop the key skills of
•
application of number
•
communication
•
information technology
•
improving own learning and performance
•
working with others
•
problem solving.
The separately certificated Key Skills qualification recognises achievement in
•
application of number
•
communication
•
information technology.
Further information on Key Skills can be found on the Ofqual website (www.ofqual.gov.uk).
Support and resources
Copies of syllabuses, the most recent question papers and Principal Examiners’ reports for teachers are on
the Syllabus and Support Materials CD-ROM, which we send to all Cambridge International Schools. They
are also on our public website – go to www.cie.org.uk/igcse. Click the Subjects tab and choose your
subject. For resources, click ‘Resource List’.
You can use the ‘Filter by’ list to show all resources or only resources categorised as ‘Endorsed by
Cambridge’. Endorsed resources are written to align closely with the syllabus they support. They have
been through a detailed quality-assurance process. As new resources are published, we review them
against the syllabus and publish their details on the relevant resource list section of the website.
Additional syllabus-specific support is available from our secure Teacher Support website
http://teachers.cie.org.uk which is available to teachers at registered Cambridge schools. It provides past
question papers and examiner reports on previous examinations, as well as any extra resources such as
schemes of work or examples of candidate responses. You can also find a range of subject communities on
the Teacher Support website, where Cambridge teachers can share their own materials and join discussion
groups.
Cambridge IGCSE Mathematics 0580/0581
37