This is an Educational blog maintained by SABARISH P, (MSc Physics, MEd, NET), Assistant Professor in Physical Science Education. Contact : pklsabarish@gmail.com

Friday, 8 April 2022

NCERT Text book for BEd Course-Free download

 NCERT Text book for BEd Course-Free download

Posted by

Sabarish P

(MSc Physics, MEd, NET) 
 
Contact: pklsabarish@gmail.com 

Textbook, ‘Basics in Education’, is related to one of the core components of the two-year B. Ed. Programme, introduced by NCERT recently. It aims to help the student- teachers understand and analyse diverse concepts related to education, their premises and contexts. It discusses crucial concepts like the nature and goals of education, the processes of education, different forms of knowledge and the process of knowing, organisation of knowledge in school curriculum, autonomy of the teachers and the learners, and the role of education in inculcating values among children.
The textbook has been written in a self-instructional format, which provides the student-teachers with considerable scope for engaging in the processes of inquiry, critical analysis and intellectual discourse. Each chapter, in addition to the relevant content, carries Learning Checks, Activities, Summary, Review Questions, and References/Further Readings, providing opportunities to the student-teachers to
engage with those concepts. As you go through it, you will see hat the material reflects and propagates inclusiveness too.

I hope that the book will be a meaningful resource
to student-teachers, teachers, teacher-educators and all stakeholders in the schooling systems in our country.

Click here to download NCERT Textbook "Basics in Education"

Famous Quotations about Teachers and Teaching

Quotations about Teachers and Teaching

Prepared by

Sabarish P

(MSc Physics, MEd, NET) 
 
Contact: pklsabarish@gmail.com 

A teacher affects eternity:
he can never tell where his influence stops.
Henry Adams

What nobler employment, or more valuable to the state, than that of the man who instructs the rising generation.
Marcus Tullius Cicero

The important thing is not so much
that every child should be taught,
as that every child should be given the wish to learn.
John Lubbock

Those who educate children well are more to be honored than parents, for these only gave life,
those the art of living well.
Aristotle

What office is there which involves more responsibility, which requires more qualifications, and which ought, therefore, to be more honorable than teaching?
Harriet Martineau

By learning you will teach;
by teaching you will understand.
Latin Proverb

Education is the mother of leadership.
Wendell L. Willkie

Seldom was any knowledge given to keep, but to impart; the grace of this rich jewel is lost in concealment.
Bishop Hall

If you would thoroughly know anything, teach it to others.
Tryon Edwards

We cannot hold a torch to light another's path without brightening our own.
Ben Sweetland

Grammar speaks; dialectics teach us truth; rhetoric gives colouring to our speech; music sings; arithmetic numbers; geometry weighs and measures;
astronomy teaches us to know the stars.
Latin Maxim

To know how to suggest is the great art of teaching.
Henri Frederic Amiel

We learn by teaching.
James Howell

Natural ability is by far the best, but many men have succeeded in winning high renown by skill that is the fruit of teaching.
Pindar

It is the supreme art of the teacher to awaken
joy in creative expression and knowledge.
Albert Einstein

The most effective teacher will always be biased,
for the chief force in teaching is confidence and enthusiasm.
Joyce Cary

Education is the guardian genius of democracy.
It is the only dictator that free men recognize,
and the only ruler that free men require.
Mirabeau Buonaparte Lamar

Whatever you want to teach, be brief.
Horace

To me, education is a leading out of what is already there in the pupil's soul.
Muriel Spark

Nine-tenths of education is encouragement.
Anatole France

The true aim of every one who aspires to be a teacher should be, not to impart his own opinions,
but to kindle minds.
F. W. Robertson

He that teaches us anything which we knew not
before is undoubtedly to be reverenced as a master.
Samuel Johnson

I hear and I forget. I see and I remember.
I do and I understand.
Chinese Proverb

Be careful to leave your sons well
instructed rather than rich,
for the hopes of the instructed are better
than the wealth of the ignorant.
Epictetus

I am indebted to my father for living, but to my teacher for living well.
Alexander of Macedon

To know how to suggest is the great art of teaching. To attain it we must be able to guess what will interest: we must learn to read the childish soul as we might a piece of music. Then, by simply changing the key, we keep up the attraction anil vary the song.
Henri Frederic Amiel

Teaching is not a lost art,
but the regard for it is a lost tradition.
Jacques Barzun

Education is the transmission of civilization.
Will Durant

To teach is to learn twice over.
Joseph Joubert

A schoolmaster should have an atmosphere of awe,
and walk wonderingly, as if he was amazed at being himself.
Newton D. Baker

One good teacher in a lifetime may sometimes
change a delinquent into a solid citizen.
Philip Wylie

A child miseducated is a child lost.
John F. Kennedy

A master can tell you what he expects of you.
A teacher, though, awakens your own expectations.

Patricia Neal

And one silly quote just for fun....

Never try to teach a pig to sing....it wastes
your time and annoys the pig.
Anonymous


Prepared by

Sabarish P

(MSc Physics, MEd, NET) 
 
Contact: pklsabarish@gmail.com 

History and Philosophy of Science-B.Ed/M.Ed notes

History and Philosophy of Science-B.Ed/M.Ed notes

Prepared by

Sabarish P

(MSc Physics, MEd, NET) 
 
Contact: pklsabarish@gmail.com 

The primitive man picked up a stone and threw it against a wild animal to protect himself. This process developed into the development of tools and weapons. Almost every one of the early mechanical achievements of man, even weaving and tailoring, had already been mastered and excelled by specialised species of animals, birds or even insects. But the use of fire was an art and technique only to be mastered by man.

Primitive man used fire to warm his body on cold nights. Later he learned to heat water in leather buckets by dropping hot stones in to it. Later he found that with a mud coating he could easily place the leather bucket on the fire. And still later he found that the very leather bucket could be dispensed with. This was the beginning of pottery. Later wheeled vehicles, sail boat, emergence of civilizations……..

Such a treatment in the Science classes may invoke ridicule on the part of science students and helplessness on the part of professors of Science. Students may enquire the relevance of studying the history when the latest and most scientific inventions make the past outdated and irrelevant. A study of the past is interesting in itself. But an understanding of the past involves its critical analysis also. Then it yields useful guidelines for the present and future endeavours. (Remember the review of related literature in a PhD work) It is not mere recounting of discoveries and inventions or a chronology of Scientists and their achievements.

Science is a process as well as product. A scientist (one who is earnest in the pursuit of science) should acknowledge this. Rewards are due to any person who is earnest in the process of science. The process is rather more important than the product. There is a good illustration for this fact in the history of Physics. JJ Thomson (Senior) and his son George Thomson received Nobel prizes in 1906 and 1937 respectively for proving two opposite views on the same subject. The former proved that electrons were particles and the later proved that they were like waves.

Searching the history tells us how those ideas germinated, grew, flowered and sometimes wilted. And those who argue that we need to look only at the latest scientific information and need not worry about the earlier theories are treating science as a product.

Let us examine critically the development of Heliocentric theory to know how science emerged, withstanding tough times, sometimes breaking barriers and sometimes hibernating for thousands of years. Near-to-logic explanations started with Claudius Ptolemy (AD 85-165). He was a genius in Mathematics who gave the table of sine values, gave the correct value of π as 3.14167. He had identified the positions of 1022 stars. He arranged the solar system with the earth at the centre and Moon, Mercury, Venus, Sun, Mars, Jupiter and Saturn revolving around it; in that order. Only the moon would move in a simple circle; all the others needed complicated systems of epicycles superimposed on their main orbital cycles. But the wonder was that Ptolemy’s scheme was of course wildly erroneous; yet at the time when it was propounded, it may have been more useful than truth! For what could be more satisfying than the thought that our habitat, this earth, was the centre of the Universe and what could be more natural than that all the heavenly bodies were paying homage to it by revolving around it in circles, which after all where the most perfect and therefore divine of curves?

With these comforting and pleasant dreams the science of astronomy went to sleep for a thousand and five hundred years.

Copernicus (1473-1543) was by profession a physician. His idea was that the universe could be vastly simplified if the Sun rather than the earth were taken as the centre. His new system placed the Sun at the centre of the Universe and ascribed three motions to the earth: a daily spin on its axis, an annual orbit around the Sun and a gyration on the earth’s axis of spin to account for the precession of equinoxes.

He wrote: “To be sure, the majority of the writers agree that earth is at rest, so that they consider it unbelievable and even ridiculous to suppose the contrary…….”

The greatness of Copernicus was that, he for the first time demonstrated and proved that a heliocentric arrangement could produce all the apparent movements in the celestial canopy, which we witness from the earth. But Copernicus also used epicircles and eccentric circles to describe planetary orbits.

Strangely enough the book did not have much of an impact. (It did not even have the distinction of being banned by the church.)

  • Its revolutionary central concept was lost in a maze of mathematical jugglery.

  • In spite of a new model, Copernicus could not improve upon the accuracy of the Ptolemic system.

  • Objections against the heliocentric (which are apparently rational) where not addressed.

  1. Would not all loose objects be flung into space by this whirling sphere?

  2. If the earth moves through space around the sun, why do the stars not change position relative to one another (stellar parallax)?

Tyco Brahe (1546-1601)

He built an observatory in the island of Hveen. He use the ever accurate set of instruments, made remarkably accurate observations every night for 20 years.

He opposed the heliocentric theory of Copernicus. (He thought it contrary to sound Physics as well as clear world of scripture). He was willing to strike a compromise between the Ptolemic system and Copernican theories, by letting the planets revolve around the Sun but insisting that the entire heavens revolve around the earth daily. His main purpose in amassing such accurate observations was to adduce sufficient proof for this pet theory of his.

But it is one of the remarkable ironies of the History that the very same data was used by his assistant and successor Johann Kepler, to banish geocentrism once and for all from astronomic circles and to enthrone the very Copernican System which the master so vehemently distrusted.

Kepler put his laws as 1. the paths of the planets around the sun are ellipses. 2. The planets travel more fast when they are near the sun than when they are away from it. (Planets move so that their radius vectors sweep out equal areas in equal time intervals.) 3. the ratio between the square of the time required by the planet to make a complete revolution around the Sun and the cube of the average distance from the sun is constant for all planets.

Giordano Bruno (1547-1600)

He was a man who contributed more for the development of science by his death, than he probably would have ever achieved by living a long life. He taught in a few French universities and wrote a book “on the infinite Universe and the Worlds”. If Copernicus had displace the earth from the centre of the universe, Bruno displaced the sun also from such an exalted position. In fact he said that there was no centre, for “as the universe is infinite, no body can properly be said to be in the centre of the universe or at the frontier thereof.” Man’s home in space occupied no preferential position.

The doctrine so Bruno struck at the very vitals of the orthodox beliefs; the idea of the infinite world, the identity of the creator and His creation, the insignificance and non uniqueness of man and his habitat, the earth – all this was anathema to the Church. In 1593, he was captured, tried in courts and sentenced to death. Bruno is said to have commented to his judge; “ perhaps you who condemn me are in greater fear than I who am condemned.”

This entire history illustrate that Science is the process of seeking truth. Some people assume that scientists have generated a body of knowledge that is sure to be true for all times. No true scientist (one who is in the earnest pursuit of science) should get ego involved that they refuse to accept new evidence and new ideas. Theories come and go, or at least are modified through time, as old ideas are questioned and new evidences are discovered. In the words of Karl Popper, “Science is a history of corrected mistakes”. Albert Einstein remarked about himself, “That fellow Einstein… every year retracts what he wrote the year before.”

But one should not got to the other extreme view on science – that new ideas and evidences constantly prove the earlier theories totally wrong. In fact the heliocentric theory has changed from Copernicus. Copernicus himself maintained that the orbits of the planets around the sun were perfectly circular. Later after two centuries it was apparent that the orbits are ellipses. In the 20th century we have additionally fond that the exact shapes of ellipses are not constant. (hence the Milankovitch cycles that may have influenced the periodicity of glaciations). However we have not gone back to the idea of an earth centered universe. Instead, we still accept a heliocentric theory – accounted with the modifications with regard to new data.

The structure of science can be compared to the frame work of a building under construction. A frame work of a building consists of foundation, vertical pillars and horizontal beams. The foundation of the frame work is comparable to the broad generalisations and principles of science. The vertical pillars to the theories and horizontal beams to the methods employed in science. The facts are comparable to building materials ie., stone, bricks, concrete etc. in this analogy of ‘house under construction’ vertical pillars and horizontal beams shall get altered but the foundations are strong.

One may say that while the history of science deals with the history of ideas the philosophy of science deals with the logic of ideas. Science is not purely mechanical. The technical details an dobserved data are carefully processed only by an analytical mind to extract inferences. Logicla thinking and reaoning are essential in the process of science. The thinking which the Scientists employ is no different from the thought processes of a person of any other discipline.

The logical mind involved in the process of science raises certain fundamental questions. What is science? How do we explore science? What is the nature of truth? If science is objective, what is the reality pertaining to that objectivity? Is there an objective reality out there, independent of the observer?

Science is a cumulative and endless series of empirical observations which result in the formation of concepts and theories, with both concepts and theories being subject to modification in the light of further empirical observations. Science is both a body of knowledge and the process of acquiring it.” –Frederick Fitzpatrick.

The Aristotelians had believed that the shape of a body determined whether it would sink or float in water. Galileo in a magnificently simple experiment let a ball of wax sink into the bottom of a vessel containing water and then increased its density of the liquid by dissolving in it. When the density reached a critical value, the wax ball rose to the surface.

The best way to filter pseudoscience is Karl Popper’s falsifiability. Popper claims that a scientific statement must be falsifiable. And a valid statement must not yet have been proven false. There are statements that cannot be proven to be true or false. For example if a student says that in the magnet –solenoid experiment, the electricity is produced by a genie, the statement is not scientific because the statement cannot be proven true or false. But if the student says that the solenoid acts as a voltage source by the mere presence of a magnet, the statement can be tested with the help of a galvanometer. The statement made was scientific but as soon as the statement was tested wrong, it became invalid and hence not scientific. Pseudoscience with very little evidence or on the basis that it cannot be disproved claims to be scientific. For example astrology, Feng shui, faith healing, hypnosis etc could not be tested empirically. The argument that the effect of such have not been disproved is no reason to believe it. Nevertheless in order to claim the credibility of science it should prove itself by empirical tests.

Scientific method is the procedure adopted by scientists in their investigation. It is a systematic and orderly method of solving problems. The steps of Scientific Method are

1.Sensing the problem 2. Experimentation 3. collection of Data, Interpretation of Data& Formu8lation of Hypothesis. 4. Establishment of the law 5. Centralisation of the law. 6. application of the law to new situations 7. Predictability 8. Idealisation and Abstraction

. The scientific method has both technical and logical elements. The technical elements include observation, experiment and collection of facts and data. The logical elements include inductive and deductive thinking, analogy, analysis, synthesis, hypothesis formation etc.

Induction may be defined as the operation of ddiscovering and proving general propositions. It is the operation of mind by which we infer that what we know to be true in a particular case or cases will be true in allcases which resemble the former in cer6t5ain assignable respects. It ias attributing truth to a general proposition when particular cases are found to be true. Thus induction is aprocess of inference which proceeds from the known to the unknown. In inductive reasoning conclusions are reached by observing exaples and generalising from the examples to the whole class. If we want to be perfect in inductive inference, we must observe all instances of the pehenomenon. Take an example:

From the given instances,

Rabbit No 1 has lungs

Rabbit No 2 has lungs

Rabbit No 3 has lungs

Rabbit No ‘n’ has lungs

Inference : Every rabbit has lungs.

In this example to be absolutely sure that every rabbit had lungs the researcher would have to have observations on all rabbits presently alive as well as past and future rabbits. This is impossible. Therefore we may rely upon imperfect induction based on incomplete observation.. All inductive inferences are based on two laws

a. the law of uniformity of nature. This means that a phenomenon that takes place in certain circumstances will repeat itself whenever the same circumstances occur. Nature is uniform in her behaviour.

b. the law of causation.- Nothing takes place by sheer chance . Every phenomenon has a cause or set of causes invariably connected to it.

Both these laws have no proof. See the paradox that all scientific inferences based on induction are based on philosophic laws with no proof.

It was the Greek philosopher Aristotle, who perfected the syllogistic method of deductive reasoning (syllogism). 

 Deduction is the process of reasoning that starts from an accepted generalisation and moves towards a conclusion relating to any specific instance . To legitimate syllogism, it is essential that there should be three and no more than three propositions namely the major premise, minor premise and the conclusion.

All men are mortal | Major premise must be true

All kings are men | Argument must be valid

All kings are mortal | Inference follows naturally

One of the major weakness of this method is that it can only deduce the consequences of pre-existing knowledge. It does not probe beyond that which is already known. Also deduction relies on verbal symbols which can be quite ambiguous.

The logical arguments determine the inferences. One has to be very cautious while making interpretations. 

 

Prepared by

Sabarish P

(MSc Physics, MEd, NET) 
 
Contact: pklsabarish@gmail.com 

 


DIGITAL LESSON PLAN-Model

 DIGITAL LESSON PLAN-Model

Prepared by

Sabarish P

(MSc Physics, MEd, NET) 
 
Contact: pklsabarish@gmail.com  
 
 

DIGITAL LESSON PLAN

Subject: Science / Physics

Topic: Properties of light

Grade Level: 5-8

It is designed to take for one period of 45 minutes

Instructional Objectives

After this lesson, students should be able to:

Identify that Light rays travels in a straight line.

Understand the phenomenon of reflection of light.

Understand the angle of incidence and angle of reflection of light.

Explain the difference between angle of incidence and angle of reflection.

Know the Law of reflection.

Identify various situations in life where reflection of light occurs.

Teaching learning plan

Teaching Aids

Presentation, data book, note book etc..

Introduction

Teacher shows some pictures and asks the students to provide feedback.

(Presentation that can be used) (Link of presentation)

Activity 1

Students are provided with the video and they are asked to write what they observe? (Link of video)

Activity 2

Students are provided with the video and they are asked to write what they observe?

Students are asked to write their findings

Activity3

Law of reflection (animation) http://www.physicsclassroom.com/mmedia/optics/lr.gif

When a ray of light strikes a plane mirror, the light ray reflects off the mirror. Reflection involves a change in direction of the light ray. The convention used to express the direction of a light ray is to indicate the angle which the light ray makes with a normal line drawn to the surface of the mirror. The angle of incidence is the angle between this normal line and the incident ray; the angle of reflection is the angle between this normal line and the reflected ray. According to the law of reflection, the angle of incidence equals the angle of reflection. These concepts are illustrated in the animation below.

Curiosity corner

The speed of light! This is 300,000km/s in space.

Assessment

1. Consider the diagram below. Which one of the angles (A, B, C, or D) is the angle of incidence? ______ Which one of the angles is the angle of reflection? ______

 

 

Ans :Angle B is the angle of incidence (angle between the incident ray and the normal). Angle C is the angle of reflection (angle between the reflected ray and the normal).

2. A ray of light is incident towards a plane mirror at an angle of 30-degrees with the mirror surface. What will be the angle of reflection?

Ans: The angle of reflection is 60 degrees. (Note that the angle of incidence is not 30 degrees; it is 60 degrees since the angle of incidence is measured between the incident ray and the normal.)

3. Perhaps you have observed the image of the sun in the windows of distant buildings near the time that the sun is rising or setting. However, the image of the sun is not seen in the windows of distant building during midday. Use the diagram below to explain, drawing appropriate light rays on the diagram.

 

Ans: A ray of light drawn from the sun's position at 7 pm to the distant window reflects off the window and travel to the observer's eye. On the other hand, a ray of light drawn from the 1 pm sun position to the window will reflect and travel to the ground, never making it to the distant observer's eye. 

4. A ray of light is approaching a set of three mirrors as shown in the diagram. The light ray is approaching the first mirror at an angle of 45-degrees with the mirror surface. Trace the path of the light ray as it bounces off the mirror. Continue tracing the ray until it finally exits from the mirror system. How many times will the ray reflect before it finally exits?

 

Ans: The light reflects twice before it finally exits the system. Draw a normal at the point of incidence to the first mirror; measure the angle of incidence (45 degrees); then draw a reflected ray at 45 degrees from the normal. Repeat the process for the second mirror.


Prepared by

Sabarish P

(MSc Physics, MEd, NET) 
 
Contact: pklsabarish@gmail.com 

Thursday, 7 April 2022

UNIT 5- LANGUAGE ACROSS THE CURRICULUM-Linguistic hazards in pedagogic decision making-Developing Proficiency in Written Comprehension and Production - Part 5-BEd notes

 

UNIT 5- LANGUAGE ACROSS THE CURRICULUM-Developing Proficiency in Written Comprehension and Production - Part 5-BEd notes

Prepared by

Sabarish P

(MSc Physics, MEd, NET) 
 
Contact: pklsabarish@gmail.com 

Contents

Linguistic hazards in pedagogic decision making-remedial programmes for teachers from different disciplines

 

Linguistic hazards in pedagogic decision making

  • In India, language and literacy are generally seen as the concern of only the language teachers.

  • However, no matter what the subject, teaching cannot take place in a language free environment.

  • Assumptions about the language and literacy background of students influence classroom interactions, pedagogical decisions and the nature of students’ learning.

  • Thus, it is important to understand their language background and know how oral and written language can be used in the classroom to ensure optimal learning of the subject area.

  • Student-teachers will need to be familiar with theoretical issues, and to develop competence in analysing current school practices and coming up with appropriate alternatives.

  • Teachers’ pedagogical decision making is a complex process. In the teaching and learning process, a pedagogical decision making involves intuitive, analytical and deliberative decisions.

  • Pedagogical decision making is the essence of teachers’ professional practice.

  • Pedagogical decision making refers to the process of thinking and reasoning that constitutes the basis and justification for choosing among available alternative, based on considerations, that is hoped will bring about effective and meaningful learning for the learners.

  • Teachers make multitude of decisions during the course of their teaching a lesson.

  • The quality of decisions that determines the quality of the teaching and learning process.

  • Decisions can be of various kinds, they can be technical, common sense or pedagogical.

  • Most teachers are apt at making common sense decisions. A curriculum that provides structure and guidelines may enable a teacher to make technical decisions.

  • The process of teaching and learning is basically pedagogical. Hence, it is only proper that the teacher is able to make pedagogical decision and not merely common sense and technical decisions.

  • Pedagogical decision making is a developmental process and embedded in actual pedagogical practice.

  • Pedagogical decision making can be viewed through theoretical understanding of teacher knowledge or a more practice oriented conception of knowledge that evolves through a growing understanding of the epistemology of practice.

  • Teachers need to be able to make pedagogical decisions on their own. They have to be thinking individuals who are flexible, creative, accommodating and are willing to accept students’ active, and event dominant, role in the teaching and learning processes in their classrooms.

  • Pedagogical decisions are recurring positive relationship between student learning and teachers’ flexibility, creativity, and adaptability.

  • Successful teachers tend to be those who are able to use a range of teaching strategies and who use a range of interaction styles, rather than a single, rigid approach.

  • Teachers’ abilities to structure materials, ask higher-order questions, use student ideas, and probe student comments have also been found to be important variables in what students learn.

  • Teachers don’t merely deliver the curriculum. They develop, define it and reinterpret it too. It is what teachers think, what teachers believe and what teachers do at the level of the classroom that ultimately shape the kind of learning that young people get.

Remedial programmes for teachers from different disciplines

  • Apart from various learning difficulties, pupils may have different abilities and styles of learning. Some are better in visual learning while others are more competent in audio learning. Certain pupils have to learn through sense of touch or practical experiences.

  • Remedial teachers should design diversified teaching activities and adopt various teaching methods to help students develop their potential and remove the obstacles in learning. 

  • Each pupil is different in terms of learning ability, academic standards, classroom learning and academic performance, and each has his own in learning.

  • By adapting school curricula and teaching strategies, teachers can provide learning activities and practical experiences to students according to their abilities and needs.

  • Teachers can also design individualised educational programmes with intensive remedial support to help pupils consolidate their basic knowledge in different subjects, master the learning methods, strengthen their confidence and enhance the effectiveness of learning.

  • Throughout the teaching process, teachers should provide systematic training to develop pupils' generic skills, including interpersonal relationship, communication, problem-solving, self-management, self-learning, independent thinking, creativity and the use of information technology.

  • Such training can lay the foundation for pupils' life-long learning, help them develop positive attitudes and values, as well as prepare them for future studies and career.

  • Before preparing for their lessons, remedial teachers should identify pupils' diverse learning needs as soon as possible so that they may design appropriate teaching plans to facilitate pupils' effective learning.

  • Since pupils have different characteristics in learning, teachers must devise different learning activities with the same teaching objective to develop pupils' varied abilities and skills in problem solving.

  • It is more effective for teachers to adopt a series of relevant and simple teaching activities than assigning one long teaching activity since pupils may acquire the required knowledge and skills through diversified activities.

  • Remedial teachers should specifically design meaningful learning situations, language environments, games or activities so as to provide personal learning experiences for pupils and stimulate their interest and initiative in learning.

  • Teachers should give concrete examples before proceeding to abstract concepts by way of simple and easy steps at a pace in line with the learning abilities of students.

  • Teachers may teach new concepts from different perspectives by various approaches so that pupils can grasp the ideas through meaningful and repeated illustrations.

  • Teachers should encourage pupils' active participation by more frequent use of teaching aids, games and activities.

  • Teacher can also make use of information technology and all the teaching resources available to help pupils understand the main points.

  • Pupils with learning difficulties are less competent in understanding written language. Therefore, remedial teachers should give pupils short and clear instructions to avoid confusion.

  • Teachers must explain clearly the arrangement of each learning activity. If necessary, they may ask pupils to repeat the steps of activities so that every pupil may understand the instructions.

  • At the course of teaching, teachers should always sum up the main points in teaching and write the key phrases on the board to enhance pupils' audio and visual memories.

  • Teachers can guide their pupils to link up the knowledge they learn from class with their life experiences so as to enhance the effectiveness of learning.

  • Besides, guiding pupils to repeat the main points in verbal or written form is also an effective way of learning.

  • Suffering from frequent frustrations in their work, pupils with learning difficulties may gradually lose their interest in learning. Therefore, teachers should adapt the curriculum to meet the needs of pupils.

  • Teachers can design interesting activities coupled with reward scheme to stimulate pupils' interest.

  • It is most important to help pupils overcome their learning difficulties so that they may gain a sense of achievement and recover their confidence and interest in learning.

  • Pupils with learning difficulties usually lack self-confidence and are more passive in class. They seldom ask questions or express their views. Remedial teachers should patiently encourage active participation in class. Pleasurable learning experiences may help enhance pupils' interest in learning.

  • Teaching should not only focus on the transmission of knowledge. It is also important to see that pupils are benefited from the entire learning process.

  • Teachers should provide ample opportunities in class for pupils to practise and think what they have learnt, and allow them to solve problems by different means.

  • Teachers should also carefully observe the performances of pupils and give them appropriate assistance, feedback and encouragement so as to help them acquire the learning skills, solve their problems and understand their own capability, thus enhancing self-confidence and improving their learning skills.

  • Pupils may encounter different problems in their studies, therefore, teachers should carefully observe the learning process of individual pupils in class.

  • Whenever necessary, teachers should provide individualised remedial teaching before and after class, during recess or lunchtime, so that they can remove their learning obstacles as soon as possible.

  • When marking assignments, teachers should take note of the common errors of pupils and deliver the correct concepts and knowledge to them promptly.

  • Remedial teachers should adapt the curriculum to accommodate the learning characteristics and abilities of pupils. They should set some teaching objectives which are easy to achieve to ensure that pupils may acquire the knowledge as desired after the completion of each module.

  • Teaching should not be directed by textbooks which should not be taken as the school curriculum. There is no need to cover all the contents in the textbooks as well.

  • Schools can classify the teaching content into core and non-core learning aspects according to the teaching objectives and pupils abilities.

  • Core learning aspects require in-depth studies and application whereas materials in the non-core or advanced learning aspects may be streamlined or appropriately selected for teaching.

  • Teachers are encouraged to adopt recommendations on cross-curricular teaching by linking up related teaching areas flexibly so that more time can be spared for effective activities and learning.

  • Teachers should make good use of all teaching materials. For example, they may select and use the materials in textbooks to meet the teaching objectives, or compile their own supplementary teaching materials. They may also design materials of different standards.

  • Materials from the internet, newspapers, magazines and references provided by the Education Department may help teachers design interesting and enjoyable activities to enhance pupils’effectiveness of learning.

  • Schools should formulate clear policies on homework which should be reviewed regularly. The assignments should be targeted at the teaching objectives and serve the purposes of learning.

  • Schools should choose these exercise books carefully and make appropriate adjustments to the category, quantity and quality of homework.

  • Teachers should take note of the following points when designing homework for pupils:

      • the homework should have clear objectives and can accommodate the level and needs of pupils;

      • the form and contents of homework should be of a great variety so as to develop pupils’ creativity, self-learning and collaborative skills;

      • the homework should match the content taught in class;

      • teachers should give simple and clear instruction;

      • assign appropriate amount of homework each day;

      • ineffective and mechanical drills should be avoided; and

      • teachers should make good use of the homework as a tool for evaluation and feedback to enhance the motivation and effectiveness of learning.

  • Remedial teachers must keep in close contact with other teachers. They are encouraged to discuss or share their experiences with others to find out ways to improve pupils’ learning and behaviour.

  • Remedial teachers should also liaise with other related professionals to seek for professional support with a view to helping pupils solve their problems.

     

    Prepared by

    Sabarish P

    (MSc Physics, MEd, NET) 
     
    Contact: pklsabarish@gmail.com