
xMath :: 69 :: Numeration 
xTable of Contents: 
 Introducton
 Numeration
 Quantities
and Symbols
 Quantities in the Decimal
System
 Numerals (Symbols)
 Union of Quantities and Numerals
(Symbols)
 Additional Exercises in Numeration
 The Hundred Board
 The Seguin Boards
 Introduction
to Operations Using the Change Game
 Static Operations in the Decimal
System
 Presentation of Addition:
 Presentation of Subtraction:
 Presentation of Multiplication:
 Presentation of Division:
 Dynamic Operations in the
Decimal System
 Introduction to the Change
Game:
 Presentation of Addition
 Presentation of Subtraction
 Presentation of Multiplication
 Presentation of Division
 Golden
Bead Chains
 Chain of 100
 Chain of 1000
 Hierarchical
Material
 Introduction:
 Presentation:
 Games:
 Introductions
to Other Mathematical Materials
 Stamp Game
 Hierarchical Bead Frames
 Introduction:
 Small Bead Frames
 First Presentation:
 Presentation:
 The History of The Abacus
 Introduction to the materials
 Passage from sensorial to
symbolic representation
 Numeration Based On Position
 Large Bead Frames
 First Presentation
 Numeration According To Position
 Presentation:
 Exercises: Formation of Numbers
 Horizontal Golden Bead Frame
 Introduction
to Memorization
 Addition
 Multiplication
 Subtraction
 Division
 Fractions  COMING SOON
 Decimals  COMING SOON
 PreAlgebra  COMING SOON
[top]

xQuantities and Symbols 
QUANTITIES IN THE DECIMAL SYSTEM
Materials:
...the golden bead materials which consist of:
...one container of loose gold beads representing units
...one box of gold bead bars of ten beads each
...one box of 10 gold bead squares of ten bars (representing
100)
...one box containing 1 gold bead cube of hundred squares (representing
1,000)
...a large tray with a dish or smaller tray, used for transferring
the quantities
Presentation:
Individual Presentation. As a unit bead, and then a ten bar is
placed on the table, the child is asked to identify the quantities.
One hundred and one thousand are presented also. The teacher
gives a three period lesson naming the quantities: unit, ten,
hundred, and thousand. The child is then invited to examine the
materials and their composition. The child may count the ten
beads on the tenbar again. "The hundred is made up of ten
ten bars". The tenbar is placed on top of the square as
the child counts. "The thousand is made up of 10 hundreds".
The hundredsquare is placed next to each section of the cube
as the child counts. The teacher gives the three period lesson
defining the composition of the quantities.
Exercise:
Small Group exercise. The golden bead materials, now including
the wooden hundredsquares and thousandcubes are arranged at
random on a rug (in a basket). Each child takes a tray. The teacher
asks the child to bring a quantity. 'Bring me 3 hundreds' As
each child returns with the quantity, the child identifies it,
and the teacher and child count it together. At first the child
is asked to bring only one hierarchy at a time. Later he will
bring all four at once.
Age: 36
Direct Aim:
...to develop the concept of the hierarchical orders of the decimal
system: units, tens, hundreds, thousands.
...to give the child the relative measurement of the quantities:
bead, bar, square, cube.
Indirect Aim:
...to prepare the child for geometry concepts: point, line, surface
and solid.
NUMERALS (SYMBOLS)
Materials:
decimal system numeral cards:
...19 printed in green
...10, 20...90 printed in blue on doublesized cards
...100, 200...900 printed in red on triplesized cards
...1000, 2000...9000 printed in green on quadruplesized cards
Presentation: 1st Part
Individual Presentation. As the one and the ten cards are placed
on the table, the child reads them. One hundred and one thousand
are presented in a three period lesson. The cards are arranged
as in the diagram. Then the child examines the particular characteristics
of each numeral, its color and the number of zeros.
Games:
1. The cards are turned face down on the table. Without turning
the card face up, the child identifies the numeral indicated
by the teacher. How many zeros does it have? The card is turned
up to control. Another time, the teacher asks the color of each
numeral.
2. 'Magician'. The teacher picks up the four cards arranging
them in a pile weighted to the left. This arrangement is shown
to the child. The cards are stood on end as the top cards slide
into the second position. Where did all the zeros go? They seem
to have disappeared, but they are still there. The cards are
lifted one by one to reveal the zeros. The child performs the
magic trick.
Presentation: 2nd Part:
The first four numeral cards, just previously presented, are
lain in order. The remaining unit cards are placed in a column
below one, the child being encouraged to read each as he lays
it in position. This continues for the tens (one ten, two tens...),
hundreds (one hundred, two hundred...), and thousands (one thousand,
two thousand...). The three period lesson continues noting color
and number of zeros as well. If the child is familiar with the
names, twenty, thirty..., these may be supplemented. It is important
for the child to realize that twenty (20) is two tens.
Age: 36
Direct Aims:
...to understand the orders of the decimal system.
...to turn the numerals for each of those four orders
Indirect Aim: to understand the importance of zeros
in distinguishing the numerals.
UNION OF QUANTITIES AND
NUMERALS (SYMBOLS)
Materials:
...golden bead materials
...numeral cards 19, 1090, 100900 and 1000
Presentation:
As the teacher lays out the unit beads, the child counts: 'one
unit, two units...nine units.' The teacher goes on: 'If we added
one more unit, we'd have ten units. Ten units make one ten.'
The tens are counted as they are lain out: 'one ten, two tens...
nine tens.' 'If we add one more ten we'd have ten tens. Ten tens
make one hundred.' And so on up tone thousand. Here the rule
of the decimal system is stated: Only nine quantities can remain
loose. When we reach ten, we move to a superior hierarchical
order.
Exercises:
1. The teacher places the numeral cards (as in the diagram) on
one table and the quantities on another. The teacher places one
quantity on a tray. The child finds the corresponding numeral
card and places it on top of the quantity. The teacher controls.
2. The teacher places a numeral card on a tray. The child brings
the corresponding quantity.
Subsequent Presentation:
Group Presentation: The teacher places cards of different orders
on the tray. The child brings the corresponding quantities with
the cards placed on top. The teacher controls and hands the cards
back to the child. When the child has all of the numeral cards,
he does the magic (arranges the cards) and reads the numeral.
The exercise continues omitting one hierarchical order to show
that the place is held by zeros.
Age: 36
Direct Aim:
...to understand the rule of the decimal system: only nine quantities
can remain loose.
...to familiarize the child with the hierarchical orders
...to offer the opportunity to write complete numerals
Indirect Aim:
...to give the understanding that zero occupies the place of
a missing order.
Note: With these and all other activities involving
the golden bead material, the units should remain in the small
tray. This confines the loose beads in a set and makes it easier
for the child to see that he has nine, one more would make ten.
When counting, the beads may be dumped into the palm and counted
back into the tray.
ADDITIONAL EXERCISES IN
NUMERATION
The Hundred Board
ADDITIONAL EXERCISES IN
NUMERATION
The Seguin Boards
Teen Boards
Materials:
...box containing two boards and 9 wooden tablets for 19
...box of ten golden ten bars
...box of 1 each of colored bead bars 19
Presentation:
Individual presentation. The teacher presents the boards side
by side and the tablets ordered in a row. Indicating the first
slot, the child reads the numeral 10 and places a tenbar to
the left of that slot. The teacher then adds a unit bead and
the tablet  1 to make eleven. 'This numeral is eleven: eleven
is ten and one.' This continues through nineteen. When counting
the beads the child counts ' ten, eleven, twelve... ten and two
is twelve.' Three period lesson follows naming the quantities
and in the second period forming them.
If the child questions why the last slot is blank, explain that
in order to make the numeral that comes after nineteen, other
materials are needed.
Age: 36
Aims:
...to clarify understanding of the decimal system (11 means:
1 ten and 1 unit )
...to progress in counting from 10 up to 19
...to learn the names of numbers 1119
ADDITIONAL EXERCISE IN NUMERATION
The Seguin Boards
Ten Boards
Materials:
...box containing two boards with numerals 10, 20, 30....90,
and 9 wooden tablets for 19
...box of 9 gold unit beads
...box of 45 gold tenbars
...1 golden hundred square
Presentation:
Individual presentation. With these materials we will be able
to make the numeral that was missing from the teen boards.
a) Only the boards and tenbars are used for now. Pointing to
the first numeral 10, the child is asked to identify it and place
the correct quantity next to it. The child identifies the next
numeral 20 as two tens. We call this twenty. The tenbars are
placed next to twenty, and counted 'ten, twenty.' This continues,
identifying numbers by correct names and counting the tenbars
by 10's. Now we have counted by tens up to ninety. The three
period lesson follows.
b) The tenbars have been returned to their box. Again the child
identifies 10 and brings out one tenbar. After ten is eleven:
the one tablet is placed in the slot and one unit bead is added
'ten, eleven.' This continues up to nineteen. After nineteen
is twenty: Twenty is two tens, so we put away the nine unit beads
and take another tenbar. Both tenbars are moved down by twenty.
This onebyone counting continues up to 99. If we added one
more bead, we'd have 10 units which make another tenbar. Then
we'd have ten tenbars which makes one hundred. After 99 comes
100. The hundred square is placed next to the blank space.
Age: 36
Aims:
...to clarify understanding of the decimal system (11 means 1
ten and 1 unit )
...to count from 1 to 99
...to learn the names of numbers 2099
Note: These materials may be presented any time after
the Union of Quantities and Numerals of the Decimal System.
[top]

xIntroduction to Operations Using the Change Game 
STATIC OPERATIONS IN THE DECIMAL SYSTEM
Materials:
...golden bead materials including wooden hundred squares and
thousand cubes
...large numeral cards
...three sets of small numeral cards
...a box containing symbols for operations +, , x,÷
...small pieces of paper
...a thin rod to be used for the = line
...a soft cloth.
a. Presentation of Addition:
Small Group Presentation. Each of two or three children takes
a tray. The teacher states a different numeral for each and they
find the appropriate small numeral cards and the quantity, placing
the cards on top of the respective quantity. The teacher controls.
The child arranges the cards, places the numeral on the table
and dumps the quantity on the cloth. When all the quantities
are on the cloth, the teacher gathers up the cloth, mixing all
the quantities together. The cloth is opened and the materials
are sorted. The child begins with units counting the quantity
and bringing the large numeral card. When all has been counted,
the child arranges the cards and reads the quantity that the
combination has produced. Pointing to small numeral cards: 'The
children brought these small quantities. When we put them together
we made this large quantity." (indicating the large numeral
cards which is seperated from the addends by the thin rod) 'We
have done addition.'
The numerals are arranged in a column. The plus sign and its
function is presented. The line (which was formed by the thin
rod) is equivalent to the = sign. The teacher reads the problem
(equation) '2,512 plus 1,234 equals 3,746.'
b. Presentation of Subtraction:
Group Presentation: Initially the teacher may play the "Rich
Man, Poor Man" game to demonstrate the concept of "taking
away." The teacher has a large quantity from which several
children take away small quantities until there is nothing left.
The purpose of this game is to make the impression of taking
away and nothing remaining.
The child has an empty tray. The teacher has a large quantity
on his tray. The quantity is counted beginning with the units
and large numeral cards are placed on the quantities. The child
arranges these cards and reads the numeral. Offering the child
some of this large quantity, the teacher chooses some small numeral
cards. The child arranges these cards and reads what shall be
taken away. The teacher counts out this quantity from what is
on the tray, beginning with units. What is left? This quantity
is counted and small numeral cards placed on the quantities,
arranged and read. What remains on the tray is the result of
subtraction. When we take away, we are subtracting. The problem
is set up with the minus sign and read. The large cards tell
us the large quantity; the smaller cards are for the small quantity
that was taken away and the small quantity that remains.
c. Presentation of Multiplication:
Group Presentation: Each child is given a tray and is asked to
get the cards and quantities for a stated number. The teacher
controls each child's tray; the cards are arranged, the numeral
is read and the quantity is placed on the table. As in addition
the quantities are put together, sorted, counted, labeled and
the sum is read. The problem is then set up as in addition with
the plus sign.
Now it is observed that in this 'special' addition, all of the
quantities put together (addends) are the same. This special
addition is called multiplication. Taking one small numeral :
'We can say that we took this quantity three times.' The times
sign is presented and the numeral three is written on a blank
piece of paper. The result has not changed; this is just an easier
way to write the problem.
Note: After this initial presentation, the child no longer
sets up the addition problem first.
d. Presentation of Division:
Group Presentation: The children are seated in a circle. One
child is asked to pick up the large numeral cards for the stated
quantity, and he brings the golden bead material. 'This large
quantity must be distributed to each of these other children
equally. 'Starting with the thousands, one thousand for you,
one thousand for you, another thousand for, another thousand
for you'... until all of the quantity has been distributed. The
children who received count their quantity to be sure that everyone
received the same amount. One child is asked to get the small
numeral cards. It is emphasized that each child received this
amount. When we distribute equally to many others, we divide.
The division problem is set up, using a small piece of paper
for the divisor, and it is read. The result of division is what
one child receives.
Exercises:
After each problem has been demonstrated and set up with numeral
cards and symbols, the child may write this in his notebook,
preferably on paper with columns and in colors for the hierarchical
orders.
After all of the operations have been presented, it is important
for the child to understand the function of each operation. 'What
is addition?... putting together...etc.
Age: 37
Control of Error: The teacher checks the quantities
counted.
Aims:
...to realize the concept of addition (putting together), subtraction
(taking away), multiplication (adding the same number many times),
and division (distributing equally)
DYNAMIC OPERATIONS IN THE
DECIMAL SYSTEM
Materials:
...golden bead material
...large and small numeral cards
...symbol cards for the operations
...problem cards for each operation
a. Introduction to the Change
Game:
Individual Presentation. A large quantity is placed on the tray
and the child is invited to count it. Beginning with units, the
child counts, but is stopped at 10. Ten units cannot remain loose;
they must be changed for a tenbar. The ten beads are traded
for one tenbar from the bank. The child continues counting units
and placing the correct large numeral cards on the try. So on
to thousands. The cards are arranged and read. The child does
many exercises.
Aim: to exchange equal quantities of different hierarchies
to reinforce the rule: only 9 units can remain loose
to reinforce knowledge of the composition of each hierarchy (ten
tens=100)
b. Presentation of Addition:
The teacher reads a task card. The child performs each command
as it is read. The teacher controls.
c. Presentation of Subtraction:
The teacher reads a task card. The child performs each command
as it is read. The teacher controls.
The teacher presents the thousand cube (golden bead) and wants
to take away 1 unit. This may be symbolized with the large and
small numeral cards for emphasis. How can this be done? The thousand
is changed to 10 hundreds. Now can we take away one unit? Not
yet. So on until one unit can be taken away. The remaining quantity
is counted and represented with small cards.
Aim: to realize that one unit revolutionizes a large quantity.
d. Presentation of Multiplication:
As for addition task cards are prepared.
e. Presentation of Division:
Group Presentation. As with static division the child sets about
distributing. When he finds that he doesn't have enough for one
hierarchy to go around, he must exchange for a lesser hierarchy.
When there is a remainder, the corresponding small numeral cards
are brought and placed after a small card with the initial r
to the right of the result (quotient)
Age: 47
Aim:
...to further understand the concept of addition, subtraction,
multiplication, and division
[top]

xGolden Bead Chains 
CHAIN OF ONE HUNDRED
Materials:
...a chain formed of 10 tenbars
...a hundred square
...an envelope containing: 9 units arrows 19 in green, 9 tens
arrows 1090 in blue, a red hundred arrow
Presentation:
The chain is folded like a fan to resemble a hundred square.
Do you recognize this? It looks like 100. We prove that it is
100 by placing the hundred square on or beside the folded chain.
The chain is stretched out to its full length. How many tens
are there in this hundred square? How many tens are in this chain?
The square and the chain are exactly equal.
The child begins counting the beads placing the corresponding
arrows by the bead. At 10, he begins counting by tens to 100.
The red hundreds arrow and the hundred square are placed by the
last bead.
Exercise:
1) The unit arrows are removed and the tens arrows are turned
over. The child counts by 10's to 100, and then backwards by
10's.
2) The teacher asks the child to indicate a number on the chain.
Then pointing to a bead, asks, 'What is this?'
Age: 36
Aims:
...to represent one hundred in a line
...to learn numeration from 1100
...to count forwards and backwards by 10, s from 1100
CHAIN OF ONE THOUSAND
Materials:
...a chain of 100 tenbars with a ring after every 100 beads
...an envelope containing: 9 green units arrows, 9 blue tens
arrows 1090, 9 red hundreds arrows, and 1 green thousands arrow
...10 hundred squares
...1 thousand cube
Presentation:
The chain is stretched out to show the difference between this
chain and the chain of 100. It is folded like a fan to resemble
hundred squares. It is proven that there are ten hundreds in
this chain by placing the hundred squares on top of each section.
The hundred squares are then stacked up to prove that this chain
is equal to the cube. After this correspondence has been firmly
established, the child begins counting, first by units, matching
the arrows, then by tens, and lastly by 100's. At each hundred
the child places a hundred square. At 900 the child counts by
10's again to 990. The child counts by units from 990 to 1000.
We place another hundred square here, but now we have 10 hundreds.
Ten hundreds make one thousand, so we can put the cube here instead.
Exercise:
1) The child counts by 100's to 100, forwards and backwards from
1 to 1000, with the arrows overturned
2) The teacher asks the child to point to a number on the chain.
Then pointing to a bead, the teacher asks, 'What is this?'
Age: 36
Direct Aim:
...to count forwards and backwards by 10, s and 100's to 1000
Indirect Aim:
...to prepare for learning the powers of numbers
[top]

xHierarchical Material 
INTRODUCTION
These materials are the geometric
representation of the quantities from one unit to one millionthe
powers of ten; 100 to 106 Having reached one million the child
will easily imagine the succeeding hierarchies.
Materials:
...the wooden materials made of light wood to facilitate movement,
in relative proportions:
...1  green cube  .5cm
...10  blue rod with green lines .5 x .5 x 5cm
...100  red square with blue lines .5 x 5 x 5cm
...1000  green cube with red lines 5cm
...10,000  blue rod with green lines 5 x 5 x 50cm
...100,000  red square with blue lines 5 x 50 x 50cm
...1,000,000  green cube with red lines 50cm
...numeral cards 1; 10; 100; 1,000; 10,000; 100,000; 1,000,000
all on white backing with numerals printed in black
...a ruler or stick or an expensive laser pen
Presentation:
The materials should be laid out in a row as they are presented,
from right to left. Isolate the unit cube and identify it. This
is one. If I had ten of these little cubes and placed them end
to end, I would have this rod. This is ten. Place the cube along
the side of the rod to count the ten sections. If I had 10 of
these tens, I would get one hundredthis square. Count the sections
of the square using the rod. Place the three pieces on the table
in a row, and place the ruler on top. These all have the same
height. Identify the three pieces again  1, 10, 100, unit, ten,
hundred. They are numbers of the simple class. Set the stick
aside.
Isolate the thousand cube. This is still a unit, but it is a
unit of the thousands. Compare its color and shape to the unit
cube. Present the ten and hundred as before. Place the stick
on top to see that they are all the same height. They are 1,
10, 100 but of thousands.
Present the million cube. This is still a unit, but it is a unit
of millions. Imagine the ten of millions. It would be as long
as ten of these side by side. Imagine also the hundred, which
would be made of ten of these tens. These would make up the class
of millions.
Review the first period giving the names of the classes and the
names 1, 10, 100 for the cube, rod, square, to show how these
three orders are repeated in each class. The dominant figure
of each class is the cube for it gives us the name of the class.
Compare these materials to the concepts of point, line, surface
and solidwhich is only a point of the next line. The point is
represented bigger each time. Even the Earth, as big as it is,
is just a tiny point in space. Three period lesson
Give the child the symbols
to match by placing on top of the material. Identify for the
child the symbols of 10,000 · 100,000 · and 1,000,000.
Notice that the comma corresponds to a change in hierarchical
class.
Games:
Distribute the cards to a group of children and they place the
cards on the appropriate material. Give each child a piece of
material and he finds the right card.
Ask the child to identify a piece of material, the class to which
it belongs, the reason for the color of the lines, of what it
is composed. In this way the child will be able to form definitions
in his own words. Emphasize that the superior hierarchy is always
formed of 10 of the preceding hierarchy.
The child draws the material in his notebook or cuts and pastes
the pieces using a different scale of measurement. The cube is
drawn as a threedimensional image.
Age: 7 years
[top]

xIntroduction to Other Mathematical Materials 
STAMP GAME
Materials:
...wooden stamps of four types:
...green unit stamps printed with the numeral 1,
...blue tens stamps printed with the numeral 10,
...red hundred stamps printed with the numeral 100, and
...green thousand stamps printed with the numeral 1000
...box with three compartments each containing 9 skittles and
one counter in the hierarchic colors;
...four small plates
Presentation:
One of each stamp is presented and identified, lain in correct
orderunits t the far right; thousands to the left. The teacher
forms a number laying out the stamps in a straight column for
each hierarchy. 'Can you read this to me?' Now the child reads
a number from a slip of paper and forms the number with the stamps.
After the child has done many exercises of this type, he will
be ready to go on to operations.
HIERARCHICAL BEAD FRAMES
INTRODUCTION
In this work, which follows
memorization, the child encounters a new difficulty. He must
identify quickly the value of each digit of a number as it is
indicated by the place the digit occupies. The child considers
the position of the digits in a number, and determines the value
of each digit according to this position.
The decimal system material: the bead1, bar10, square100,
and cube1000, represented constant values, values which did
not change when the position of the material changed. On the
bead frames beads of the same size represent the various quantities,
thus eliminating the sensorial element of size. The quantities
are symbolically represented on the bead frame aided by the hierarchic
colors and the relative positions of the frame.
These hierarchic colors have been encountered before in the decimal
system material numeral cards and the stamp game. On the frame
one blue bead represents ten (unit) beads of the previous hierarchy
and onetenth of a (hundred) bead of the next superior hierarchy.
SMALL BEAD FRAMES
First Presentation:
Materials:
...small bead frame, corresponding form
...a golden unit bead, 10bar, 100square, 1000cube
...2 green beads (from the unit division board)
Presentation:
Introduce the child to the concept of hierarchy with an analogy:
i.e. the social organization differentiates one person from the
next. The same thing happens in the beads, These 4 beads could
be units of the simple class or units of the thousands depending
on their position.
These three colors, green, blue, and red are repeated in each
class in the same sequence. Only their position will differentiate
them.
Isolate two green loose beads. How many are there? 2 On the frame
isolate one unit and one thousand bead. Here I also have two
green beads, but I can't call them just '2 green beads.' The
one at the top has the value of one; the bead on the lower wire
has the value of 1000. The position makes the difference.
The absolute value is the value of the unit independent of its
position (the number of beads on the wire). The relative value
is the value of a digit when its relative position is taken into
consideration.
The History of The Abacus
Relate the story of the abacus: A bead frame like this is used
by children all over to learn to count. It is a very, very old
instrument, that was used by the Chinese as far back as 500 BC.
They called it 'swanpan'. The Japanese caught on to the idea,
but they called it 'soroban.' The Russians learned about it
and began to use it in their country, calling it 'sciot', which
means calculator. Around 1812 there were French prisoners in
Russia who learned about the abacus. When he was released he
brought the idea back to France. This knowledge spread rapidly
around Europe and to America.
Studies have shown that this design originated long, long ago.
People made little grooves in the sand and placed little pebbles
into the grooves. Each groove was like one of our wires, and
the pebbles were like our beads.
Introduction to the materials
Our bead frame has four wires; the first three are equal distances
from one another, and between the third and fourth there is a
greater distance. This space separates the simple class from
the class of thousands. On the right side we see these two classes
indicated by two different colors. There are ten beads on each
wire. The number on the left side of the frame indicate the value
of each bead on that wire. Here it says 1, so each bead has the
value of one... and so on to 1000.
On this form the same situation is repeated. Turn the bead frame
on its side to demonstrate the corresponding colors, names of
classes, and the space to divide the classes, which has been
replaced by a comma.
Passage from sensorial to
symbolic representation
Isolate the golden bead, and ask the child to identify its value;
one unit. Isolate one green unit bead on the right side of the
frame. This green bead is also one unit. Each bead on this row
is a unit.
Isolate the tenbar, and ask the child to identify its value;
ten. This blue bead also has the value of ten. Each one of the
beads on this row is worth ten units. Continue in the same way
with the square and the cube.
By means of the three period lesson: have the child match the
corresponding quantities, i.e. Give me 100. The child gives the
square. Now show me 100 on the frame, or pointing to a particular
bead: What is this? The child names it and gets the corresponding
golden bead material.
To check the child's comprehension, isolate one unit bead and
one thousand bead. These two beads are both green: do they have
the same value? Why?
SMALL BEAD FRAMES
Numeration Based On Position
Materials:
...small bead frame
...form for each child
Presentation:
Moving one unit bead to the right, the teacher counts one and
writes the digit on the form. The numeration continues: move
a bead, say the number, write it down. As the tenth unit
bead is moved forward: I change these ten units for one ten bead
forward. Write the digit 1 on the blue line. Move another ten
bead forward 2 tens and write a 2 in the column. The numeration
continues in this way up to 90, changing 10 tens for 100. Finally
the numeration ends at 1000. This is controlled by 28 lines on
the form.
At the end fill in all of the zeros to bring into focus the passage
from one hierarchy to the next by the placement of one more zero
each time.
This work recalls the concept of changing from one hierarchy
to another from the decimal system operations. This activity
helps the child to fix the places which correspond to each hierarchy.
Activities: Formation of Numbers
1) The teacher forms a number on the frame. The child reads it.
2) The child reads a number from prepared cards and forms it
on the frame.
3) The child forms any number on the frame, reads it and records
it on the left side of the form used earlier for the presentation.
Note: Each time the child forms a number he will
recall the formation 10.
Aim: familiarization with the
bead frame
knowledge of the passage between hierarchies
LARGE BEAD FRAMES
First Presentation
Materials:
...large bead frame, bearing the same characteristics as the
small frame:
...space and change of frame color to separate the classes,
...10 beads of respective hierarchic colors on each row.
...wooden hierarchic materials
Presentation:
Slide one green bead to the right and isolate the unit cube.
This green bead has the same value as this cube. What was the
value of this cube? ..unit of what class? the simple class. Every
green bead on this row has the value of one unit. In the same
way identify each row of beads using the hierarchic materials.
Exercise:
Isolate a bead and ask the child to identify the equivalent material
and ask the child to isolate the corresponding bead.
LARGE BEAD FRAMES
Numeration According To Position
Materials:
...large bead frame
...corresponding long form with 55 lines
Presentation:
Move one unit bead to the right, count one and write the digit
1 in the first space of the form. Continue counting and writing.
When the tenth unit bead is moved forward, 'we know that 10 units
make 1 ten.' The units are moved back and one ten is moved forward.
Write '1' in the tens column (without a zero) Continue in this
way up to 1 million; the form will be filled up. Go back and
add the zeros. Notice the passage from one hierarchy to the next
as indicated by the zeros. Note that the commas correspond to
the spaces between classes.
Exercises;Formation of Numbers:
1) The teacher forms a number on the bead frame. The child reads
the number and writes it on the form.
2) The teacher writes a number on a piece of paper and the child
reads it, forms it on the frame and writes it on the form.
3) The child creates a number on the frame and writes it on the
form. The child performs addition, subtraction and multiplication
(with a onedigit multiplier) on this frame. This larger frame
permits the child to work with larger numbers.
HORIZONTAL GOLDEN BEAD FRAME
Materials: the frame which lies flat on the
table.
It is less sensorial in that
hierarchic colors and spaces between the classes have been eliminated
(note: the black lines are drawn on the board beneath the wires;
they will indicate where to begin the multiplication when multiplying
by units, tens, hundreds or thousands.). All of the previous
operations can be done with this material, but we will do the
most interesting  multiplication with a twodigit multiplier.
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xIntroduction to Memorization 
Memorization is the key that will
allow the child to continue in his development of the mathematical
mind. Memorization can be defined as conservation in the memory
along with the ability to recall experience and impressions.
Oftentimes the exercises of memorization are boring to the child
because the same thing is repeated over and over until he remembers.
In order for our goals to be achieved, we must find ways to make
memorization attractive and interesting.
Memorization must be taught
along with the decimal system materials. The child has realized
the concept of the decimal system: that only nine units can remain
loose, and he has understood the function of each operation.
Now we must learn to calculate. As soon as the child has memorized
all of the possible combinations of 19, he will be able to calculate
any complex addition. In order to enter the world of mathematics,
the child must be given the opportunity to memorize.
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