new for the 2014 the key to curriculum national success in ks3 mathematics · the key to success in...

The key to success in KS3 mathematics

www.pearsonschools.co.uk/progresswithKS3maths

Confidence • Fluency • Problem-solving • Progression

Why nurturing confidence raises achievement

The thinking behind

10 key principles of

NEW for the 2014 National Curriculum

2 3

An innovative structure for Each Unit is organised as follows:

Master Strengthen

The thinking behind In preparing our new KS3 Maths course, leading mathematics education researchers and Key Stage 3 teachers across a range of schools:

l closely examined the new National Curriculum for Mathematics (including Key Stage 2)l appraised the best performing countries in mathematics l reviewed some recent and most commonly cited research papers in mathematics education*l audited the most respected and well-used mathematics resources, both print and digital.

As a result we’ve developed a brand-new approach to Key Stage 3 Mathematics, designed to nurture confidence and raise achievement.

The 10 Key Principles of l Fluencyl Problem-solvingl Mathematical Reasoningl Progressionl Reflection

l Multiplicative Reasoningl Modellingl Concrete–Pictorial–Abstract (CPA)l Relevancel Linking

This guide explains each of these principles in more detail, describing how they raise confidence and raise achievement and how they appear throughout the course.

Each Unit is supported by a range of learning materials designed to promote confidence, by encouraging students to visualise concepts, discuss their understanding and reflect on their learning.

How this structure nurtures confidence and raises achievementl Students who do not master the topic in the first few lessons do not carry on regardless.

Instead, they have the opportunity to revisit key concepts, explained in a different way, and at a slower pace.

l Students who do master the topic in the first few lessons do not simply do more of the same. Instead, they are challenged by increasing the breadth and depth of their understanding.

Why nurturing confidence raises achievementNurture students’ confidence so that they can work independently, take risks and persevere, and they will experience success. If students do believe they are no good at mathematics, they are likely to give up before they have really tried. That’s why research shows a strong link between confidence and achievement in mathematics. And that’s why nurturing confidence is at the heart of our new Key Stage 3 Mathematics course.

Test CheckExtend

1 Students are helped to master fundamental knowledge and skills over a series of lessons.

2 Before moving on with the rest of the Unit, they check their understanding in a short formative assessment, and give an indication of their confidence level.

3 They decide on their personalised route through the rest of the Unit:

• In areas where they have yet to develop a solid understanding and/or they do not feel confident, they can choose to strengthen their learning;

• In areas where they performed well in the assessment and also feel confident, they can choose to extend their learning.

4 Finally, students do a test to determine their progression across the Unit.

*Full list of research references available at: www.pearsonschools.co.uk/progresswithKS3Maths

4 5

FluencyWhen certain mathematics facts are so familiar that their recall or use is automatic, this is called fluency.

How fluency nurtures confidence and raises achievementPsychologists believe we only have a limited amount of ‘brain power’ to apply to mathematics learning and problem-solving at any one time. This means that if we can rely on the speedy retrieval of known facts to help us, we have spare brain power to confidently engage in the trickier elements of a problem. For this reason, good mathematical fluency is known to enhance students’ mathematics achievement.*

This is also why ‘developing fluency’ is now a key feature of the new National Curriculum for Mathematics and plays an important part in progressing to GCSE Mathematics.

How fluency appears in

Lessons begin with questions for students to develop their mathematical fluency in the facts and skills they will soon be using.

Students also have the opportunity to practise their fluency in questions that require them to use previously learnt knowledge.

Taken from: KS3 Maths ActiveCourse

Front-of-class teaching resources for building and embedding fluency, which students consolidate through online homework.

There is also teacher support on how to build fluency in each lesson in the teacher planning materials.

*Full list of research references available at: www.pearsonschools.co.uk/progresswithKS3Maths *Full list of research references available at: www.pearsonschools.co.uk/progresswithKS3Maths

Problem-solving When decisions have to be made about the steps to take to tackle a mathematical task, this is called mathematics problem-solving.

How problem-solving nurtures confidence and raises achievementThere is strong evidence to suggest that when students are taught strategies for mathematics problem-solving they become increasingly willing to ‘have a go’ and persevere at tasks. This is because as they experience success, they gain confidence in their ability, and so become ever-more willing to tackle unfamiliar problems using such strategies. As a result, these students are better equipped to succeed in tests and exams and consequently in future study and employment. This is why mathematics problem-solving is central to the curriculum of high-performing jurisdictions.*

‘Problem-solving’ is now a key feature of the new National Curriculum for Mathematics and plays an important part in progressing to GCSE Mathematics.

How problem-solving appears in

Lessons not only include problem-solving tasks, but also offer strategy hints, like ‘draw a diagram’, ‘try working backwards’, or ‘first of all use easier numbers’. Once students have met a range of these strategies, hints are removed and students are simply asked to tackle the problem, choosing a strategy for themselves.

The Online homework practice and support resources offer plenty of problem-solving practice, with each question having an interactive worked example that breaks the problem down into simple steps.

Problem-solving isn’t just ‘questions in contexts’.

Taken from: KS3 Maths Progress Student Book Theta 1


6 7*Full list of research references available at: www.pearsonschools.co.uk/progresswithKS3Maths *Full list of research references available at: www.pearsonschools.co.uk/progresswithKS3Maths

Mathematical reasoningWhen describing why mathematical knowledge, skills or methods are used, this is called mathematical reasoning.

How reasoning nurtures confidence and raises achievementStudents may be able to state what they know and show what they can do in mathematics, but it is not until they can reason why, that they truly demonstrate their understanding. Only then can they describe why they chose a particular approach, why that approach may be better than another, and why their final solution made sense. In essence, only then can they be confident in their answers. Therefore, it is no surprise that research shows a strong relationship between students’ reasoning ability and their mathematical achievement.*

As a result, ‘reasoning mathematically’ is now a key feature of the new National Curriculum for Mathematics and plays an important part in progressing to GCSE Mathematics.

How reasoning mathematically appears in

Through the course, lessons often include prompts that encourage students to explain their reasoning. Sometimes these appear at the end of a problem. At other times, these appear as a statement for discussion, where students are asked to give a reason why the statement is correct or incorrect.


Progression When the order of mathematics teaching is carefully planned and mathematical understanding is carefully scaffolded, this secures progression in students’ learning through KS3 and on to KS4 and beyond.

How progression nurtures confidence and raises achievementSuccess in mathematics is dependent on offering students just the ‘right’ amount of challenge, at just the ‘right’ moment. This means ensuring all the necessary prior knowledge, skills and understanding are in place, and gradually building to enable students to progress.

Research suggests that when students are made explicitly aware of this progression, not just topic-by-topic, but lesson-by-lesson, then their confidence and performance improve.*

How progression appears in

Students follow a Pi (lower ability), Theta (middle ability) or Delta (higher ability) route. Within each route, we have worked with teachers to achieve the best possible order for teaching topics, as well as the most appropriate progression routes through the Units themselves (mastering first, then choosing to strengthen or extend).

There is smooth progression in lessons, both in the introduction of new concepts, the comprehensive coverage of fluency, problem-solving and reasoning and the pace of the questions.

Interactive front-of-class teaching resources provide adaptive multiple-choice exercises – an innovative classroom test that adapts to the students’ success and provides harder questions when they are ready.

Progression is measured and tracked by ability and by level of confidence through online homework and practice.



Multiplicative reasoningWhen deliberately using multiplication (or division) to compare quantities and work out the value of one based on the values of others, this is called multiplicative reasoning.

How multiplicative reasoning nurtures confidence and raises achievementKnowing if, when and why relationships are multiplicative is essential to the understanding of many Key Stage 3 concepts, among them ratio, proportion, percentages, area, volume, sequences and functions. This is why ‘multiplicative reasoning’ is now a key feature of the new National Curriculum for Mathematics and plays an important part in progressing to GCSE Mathematics.

Research shows that students gain confidence in multiplicative reasoning when they actually see multiplicative connections illustrated in diagrams, such as bar models. This, in turn, deepens their understanding of what is happening to one quantity as the other changes. Therefore, it helps them choose the correct calculations to do to solve problems in mathematical and real-world contexts.*

How multiplicative reasoning appears in

Lessons addressing concepts dependent on multiplicative reasoning include pictorial representations to support students’ understanding.

Typically multiplicative relations will be illustrated in bar models or tables, or on number lines or graphs in the Student Books and in the ActiveLearn Digital Service.



Reflection (Metacognition)When thinking about the processes and mental strategies involved when doing mathematics, this is called reflection or metacognition.

How reflection nurtures confidence and raises achievementAs they do mathematics, if students reflect on what they are doing, how they are doing it, and why they are taking a particular course of action, then they gain valuable insights into the way that they learn. If, afterwards, they are also encouraged to consider the understanding they gained, what they found easy or difficult, the mistakes that they made, and the merits of different approaches, they can confidently adjust how they do things in the future. Research demonstrates that students who regularly reflect in this manner demonstrate greater perseverance and success at solving mathematics problems.*

How reflection appears in

Lessons and Units end with Reflect questions that ask students to examine their thinking and understanding, emphasising the important role of reflection in learning mathematics.

Adaptive multiple choice quizzes in the front-of-class teaching resources provide an innovative in-class resource enabling teachers to capture students’ confidence levels. The quizzes ask students to reflect on their level of certainty when giving an answer: are they ‘just guessing’, ‘feeling doubtful’ or ‘confident’? This gives much greater insight into students’ results at the end of each quiz.


The online homework allows students to log their confidence level for each question, and also feed back any problems they have to the teacher through the interactive workspace or comments field.

Guidance is given to teachers on using reflection in the classroom for each lesson, in the teacher planning material.


ModellingWhen an attempt is made to understand and describe a real-world situation in mathematical terms, this is called mathematical modelling.

How modelling nurtures confidence and raises achievementGive students opportunities to model and they begin to understand how mathematics can provide insights into important real-world situations. This is known to have a motivational effect. There is also evidence that modelling deepens students’ understanding of the concepts they bring to bear in devising, testing and evaluating a model. As well as improving their performance in mathematics, this also improves how they do in maths-related fields, such as STEM and finance, beyond school.*

Therefore, ‘modelling realistic situations’ is now a key feature of the new National Curriculum for Mathematics and plays an important part in progressing to GCSE Mathematics.

How modelling appears in

Lessons include problems labelled ‘modelling’, often drawn from STEM or finance. These mostly ask students to test a model in some simple way and then give reasons for whether it is a good model or not.

Concrete–Pictorial–Abstract (CPA)When students learn mathematics with objects, then pictures, followed by notation, this is called a concrete-pictorial-abstract (CPA) approach.

How CPA nurtures confidence and raises achievementSometimes students may start with the concrete manipulation of objects (be they blocks, sticks, dice); at other times they may begin with pictorial representations (whether moving animations, diagrams, charts, graphs, or bar models). They can then move onto abstract ideas expressed in symbols, numbers and letters.

Bar models are rectangular bars that have been proven to help students visualise problems:

CPA is a common approach to teaching mathematics in high-performing jurisdictions, and research shows that it gives students the time and space for conceptual understanding to develop and confidence to grow.*

How CPA appears in

The Pi (lower ability) route leads wherever possible with concrete representations of problems.

In the Theta (middle ability) route, the emphasis is more on pictorial representations, with students encouraged towards abstract understanding.

Then, in the Delta (higher ability) route, the focus is on abstract representations of mathematics, supported by some pictorial ideas.

The CPA approach is supported by front-of-class teaching resources including hundreds of videos and digital animations to help students visualise mathematical concepts.

A series of teacher videos provide lesson ideas for the new and trickier National Curriculum topics, with the ideas arranged along concrete-pictorial-abstract progression.

Question: Pen and Dave hire a limousine together at a cost of £287.Pen pays 6 times more than Dave.How much does Dave pay?

Taken from KS3 Maths Progress Student Book Theta 1

Answer:

Dave pays £287 ÷ 7 = £41

£287Pen Dave


12 13

LinkingWhen the connections between concepts within mathematics, or with other subjects, are realised, this is called linking.

How linking nurtures confidence and raises achievementStudents often perceive mathematics as a series of discrete topics and concepts. However, research shows that when students recognise the links between two concepts, their understanding of both of them deepens. This is because they have the opportunity to reinforce concepts previously mastered, and to use them again but in new contexts. Then, as their confidence in mathematics increases, research shows students become more willing to apply mathematical knowledge and skills in other subjects, such as science and geography.*

How linking appears in

Lessons begin with Warm-up questions where students are often asked to demonstrate their knowledge or skills in related concepts.

Progression through the whole course, is predicated on the idea of linking topics and concepts. Questions are structured to encourage students to use and apply prior knowledge and understanding as an integral part of their learning. The progression structure for KS3 Maths Progress was developed in conjunction with a group of teachers from around the country, reviewers and our Series Editors.

Throughout lessons, links are made to previously mastered topics, as well as contexts drawn from other subjects. Every lesson also has a list of cross-topic and subject links.



*Full list of research references available at: www.pearsonschools.co.uk/progresswithKS3Maths *Full list of research references available at: www.pearsonschools.co.uk/progresswithKS3Maths

RelevanceWhen mathematics is used and applied in the real world, then its relevance is demonstrated.

How relevance nurtures confidence and raises achievementThe purpose of learning mathematics becomes clear to students when they are faced with ‘real’ (rather than contrived) problems that they can relate to, such as:

How many toilets are needed at the Glastonbury Festival?

Is it cheaper to buy an iPad in the UK, France or the USA?

How can you scale a small painting to make it street art on the side of a building?

Research demonstrates that making students aware of the need for mathematics in these sorts of real-life situations increases motivation. At the same time, it gives everyone an opportunity to access mathematical problem-solving, and so increases confidence.*

How relevance appears in

Lessons start with a real-life problem for students to Explore, ‘loosely’ at first, then fully at the end of the lesson (having learned the necessary mathematical knowledge and skills). This shows students how much they have learnt and how it may be useful.

Lessons are also dotted with further questions labelled ‘real’, which use teen-friendly, STEM or financial contexts.

At appropriate points, whole lessons related to STEM or Finance are integrated in the course. These deliver learning objectives through a single theme each time, and are fully supported in the front-of-class teaching resources and teacher planning materials.



Progress with confidence

Our innovative Key Stage 3 Maths course embeds evidence-based approaches throughout our trusted suite of digital and print resources, to create confident and numerate students able to progress to KS4 and beyond.

Smooth progression to GCSE Inline with the 2014 National Curriculum and the new Edexcel GCSE (9-1) Mathematics specfication both our KS3 and GCSE courses have a strong evidence-based approach to fluency, problem-solving, reasoning and building confidence.

Pedagogy at the heart – Our new course is built around a pedagogy based on leading mathematics educational research and best practice from teachers in the UK. The result is an innovative learning structure based around 10 key principles designed to nurture confidence and raise achievement.

Nurturing confidence to raise achievement - Our course promotes confidence by encouraging students to understand and reflect on their learning.

Stretch, challenge and support – Differentiated materials catering for students of all abilities.

Learning beyond the classroom – Focussing on breaking barriers to independent learning, online homework is linked to every lesson to offer students extra practice, and a chance to reflect on their learning with our confidence-checker. Powerful reporting tools can be used to track student progression and confidence levels.

Tried and tested front-of-class support – Our enhanced online service makes the Student Books available for display on your whiteboard along with an extensive range of videos and animations, to help your class progress their conceptual understanding at the right speed.

Easy to plan, teach and assess – Our comprehensive lesson plans provide teacher support for the pedagogy and link to front-of-class resources and homework activities. Assessment materials support monitoring progression throughout the course.

Practice to progress – An extensive range of practice across topics and abilities. Student Books, write-in Progression Workbooks and online homework, ensure there is plenty of practice available in a variety of formats to suit both classroom and independent learning.

Request a free Evaluation pack at:

www.pearsonschools.co.uk/progresswithKS3Maths

Discover now!

Series EditorsDr Naomi NormanKatherine Pate

U05

9b

Pearson Ltd is committed to reducing its impact on the environment by using responsibly sourced and recycled paper.

Pearson 11-19 Mathematics for Progression aims to create a new generation of numerate and confident young people who feel well equipped to progress through their Mathematics studies and beyond.

The courses that build into Pearson’s 11-19 Mathematics for Progression framework embed a deep and broad understanding of mathematics. They promote a can-do philosophy that prepares students in mathematical fluency, reasoning and problem-solving as well as specific key stage or qualification learning and teaching needs. These core principles - created to consistently track, build upon and promote progression - are delivered in the secondary Mathematics services at Pearson through evidence-based and best practice approaches.

Discover now!

Request a free Evaluation Pack at: www.pearsonschools.co.uk/progresswithKS3Maths

Progress with confidence

Our innovative Key Stage 3 Maths course embeds a modern pedagogical approach

around our trusted suite of digital and print resources, to create confident and numerate

students ready to progress further.

new for the 2014 the key to curriculum national success in ks3 mathematics · the key to success in...

Documents