An Introduction to Various Multiplication Strategies Lynn West Bellevue, NE In partial fulfillment of the requirements for the Master of Arts in Teaching with a Specialization in the Teaching of Middle Level Mathematics in the Department of Mathematics. Jim Lewis, Advisor July 2011
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An Introduction to Various Multiplication Strategies
Lynn West Bellevue, NE
In partial fulfillment of the requirements for the Master of Arts in Teaching with a Specialization in the Teaching of Middle Level Mathematics
in the Department of Mathematics. Jim Lewis, Advisor
July 2011
Multiplication is one of the four basic operations of elementary arithmetic and is
commonly defined as repeated addition. However, while this definition applies to whole number
multiplication, some math researchers argue that it falls short for multiplication of fractions and
other kinds of numbers. These mathematicians prefer to define multiplication as the scaling of
one number by another, or as the process by which the product of two numbers is computed
(Princeton University Wordnet, 2010). Despite the controversy, multiplication, by any definition,
is an essential skill to students preparing for life in the mathematical world of the 21st century. It
is an important tool in solving real-life problems and builds a firm foundation for proportional
reasoning, algebraic thinking, and higher-level math.
The standard algorithm for teaching the multiplication of larger numbers in this country
is known as long multiplication and was originally brought to Europe by the Arabic-speaking
people of Africa. In long multiplication, one multiplies the multiplicand by each digit of the
multiplier and then adds up all the appropriately shifted results. This method requires
memorization of the basic multiplication facts. However, a wide variety of efficient, alternative
algorithms exist. Many students find these methods appealing and easier to navigate, even to the
point of preferring them to the more traditional algorithm.
Finger Multiplication
Some of the oldest methods of multiplication involved finger calculations. One such
method is believed to have come out of Italy and was widely used throughout medieval Europe
(Rouse Ball, 1960 p. 189). The algorithm is fairly simple and can be used to calculate the product
of two single digit numbers between five and nine. In order to use this method, one must
understand that the closed fist represents five, and each raised finger adds one to that value.
Thus, to determine the appropriate number of fingers to be raised on each hand, subtract five
from each factor. For example, to find the product of 8 × 7, use the following steps:
Therefore, 8 × 7 = 56, but why does the algorithm work? Let’s rewrite the preceding process as an algebraic equation substituting x for eight and y for seven: 10[(x - 5) + (y - 5)] + [(10 - x)(10 - y)]
= xy Since all the terms cancel except for x and y, the equation gives the product of x and y.
One advantage of this method is that it does not require memorization of multiplication
facts beyond 5 × 5, so it is an effective tool for students who have not yet mastered the entire
multiplication table. Introducing this algorithm to more advanced students offers them the
opportunity to develop an understanding of the multiplication process and make connections to
prior learning. Using mathematical reasoning to validate the algorithm fosters the development
of conceptual understanding, an important component of proficiency (NCTM, 2000).
Area Model of Multiplication
All students need to be able to make connections between mathematical ideas and
previously learned concepts in order to build new understandings. The area model of
multiplication is an algorithm that uses multiple representations to explain the multiplication
process, and can help students make connections to algebra and algebraic thinking. One can
1. Raise 3 fingers on the left hand; 8 - 5 = 3 2. Raise 2 fingers on the right hand; 7 - 5 = 2 3. Multiply each raised finger by 10; 5 × 10 = 50 4. Multiply the number of fingers in the down position on the left hand by the number of fingers in the down position on the right hand; 2 × 3 = 6 5. Add the two numbers; 50 + 6 = 56
8 × 7
Multiply the number of raised fingers (x-5 and y-5) by ten, and add the product of the fingers in the down position (10-x)(10-y).
represent the multiplication of 14 × 12 as an area problem by drawing a rectangle with height 12
and width 14 on plain paper (or on graph paper to show the intermediate steps or in the case of
multiplication by fractions).
The area model has theoretical limitations and cannot easily be used with irrational
numbers; however, it is an excellent tool in helping students to establish a fundamental
understanding of a variety of basic math concepts. For instance, it can be an effective tool in
helping students to understand the concept of multiplication involving negative numbers. In the
following example, we can represent the multiplication of 14 × 12 as (20 - 6) × (20 - 8):
This model clearly illustrates that the product of a positive number and a negative number is
negative, while the product of two negative numbers must be positive. The area model also
The area model is an application of the distributive property. 14 × 12 = [(10 + 2) × 10] + [(10 + 2) × 4] = (10 × 10) + (2 × 10) + (10 × 4) + (2 × 4) = 100 + 20 + 40 + 8 = 100 + 60 + 6 = 1=
10 × 10 = 100
10 × 4 = 40
2 × 10 = 20
2 × 4 = 8
48
-120
-160
400
highlights the Distributive Property of Multiplication and using expanded notation. By allowing
students to demonstrate graphically that 14 × 12 is the same as 12 × 14, the Commutative
Property of Multiplication can be illustrated as well. In more advanced classes, this algorithm
can be used to assist visual learners with the development of a relational understanding of
polynomial multiplication and factoring.
Lattice Multiplication
Lattice multiplication, also known as sieve multiplication or the jalousia (gelosia)
method, dates back to 10th century India and was introduced into Europe by Fibonacci in the 14th
century (Carroll & Porter, 1998). It is algorithmically identical to the traditional long
multiplication method, but breaks the process into smaller steps. For example, to multiply
453 × 25:
Therefore, 453 × 25 = 11,325.
1. Draw a grid that has as many rows and columns as the multiplicand and the multiplier. 2. Draw a diagonal through each box from upper right corner to lower left corner. 3. Write the multipliers across the top and down the right side, lining up the digits with the boxes. 4. Record each partial product as a two-digit number with the tens digit in the upper left triangle and ones digit in the lower right triangle. (If the product does not have a tens digit, record a zero in the tens triangle.) 5. When all multiplications are complete, sum the numbers along the diagonals 6. Carry double digits to the next place, and record the answer.
Multiplication of numbers beyond the single digits relies on three steps: multiplying,
regrouping, and adding. The lattice method does each of these steps separately, so students are
able to focus on the meaning of each part of the process. This method provides students with a
structure for thinking about and recording their work. Lattice multiplication can also easily be
extended to multiply decimal fractions and polynomials.
Line Multiplication Another algorithm that is sometimes introduced to elementary school children is referred
to as line multiplication. This algorithm presents students with a graphic representation of
multiplication and can visually enhance their understanding of the multiplication process.
Suppose you want to multiply 22 × 13:
1. First, draw two sets of vertical lines, two on the left and two on the right, to represent 22 (red lines). Next, draw two sets of horizontal lines, one on the top and three on the bottom, to represent 13 (blue lines).
While some would argue that this algorithm ignores
place value, it is easy to see that the diagonals actually
represent the places that the digits occupy. Therefore,
this multiplication essentially represents:
(20 × 400) + (20 × 50) + (20 × 3)
+ (5 × 400) + (5 × 50) + (5 × 3) = 11,325
As with the traditional long multiplication algorithm, when a multiplication problem calls
for regrouping, digits must be carried to the next place. Consider the multiplication problem 246 × 32. The answer, 6 thousands, 16 hundreds, 26 tens, and 12 ones is correct; however, numbers greater than or equal to 10 must be regrouped to write the answer in its standard form.
This method works because diagonals of intersections of lines serve as placeholders
(ones, 10’s, 100’s, etc.) and the number of points at each intersection represents the product of
the number of lines. This is very similar to an area model of multiplication. When multiplying
two two-digit numbers, as with 22 × 13, note that the problem can be rewritten as
(20 + 2) × (10 + 3).
2. Notice there are four sets of intersecting points (highlighted). To find the product, count up the intersection points in each of the highlighted sets and add diagonally.
Note that the four sets of intersecting points are added diagonally. This serves to collect the points by place value (highlighted).
would be rather cumbersome, for younger students and those who have not yet mastered the
multiplication table, this method offers an opportunity for success with multiplying relatively
large numbers. More advanced students can gain a better understanding of the multiplication
process by investigating the algorithm and justifying the method mathematically.
Circle/Radius Multiplication
Another graphic multiplication algorithm, involves the drawing of concentric circles to
represent the multiplier along with the drawing of radii to represent the multiplicand. For
example, to multiply 3 × 4, first draw three concentric circles to model the multiplier three, and
then add four radii to model the multiplicand four. Then count the number of separate pieces
created within the circle. Since 12 pieces are created, 3 × 4 = 12.
This algorithm is a little more complicated for larger numbers, as the next example shows. In order to calculate 21 × 34:
1. Draw two concentric circles to represent the two in the tens place of the multiplier (21), and duplicate the circles once for each digit in the multiplicand.
Therefore: 21 × 34 = 714
This method works because the circles representing the
digits in the multiplier are duplicated once for each digit in the
multiplicand. This, in essence, allows for multiplication of each
digit in the multiplier by each digit in the multiplicand. The
diagonal lines serve to separate the digits into the appropriate
place value.
2. Draw a single circle to represent the one in the ones place of the multiplier; and also duplicate these circles once for each digit in the multiplicand. 3. To multiply by 34, draw three radii in the two circles on the left. 4. Then draw four radii in the two remaining circles. 5. Draw diagonal lines between the circles as shown, count the number of pieces in each section, and add diagonally .
Positive aspects of this method are that it can be used without knowledge of the
multiplication table, it may appeal to visual learners, and it offers students another approach for
multiplying, thus providing a deeper understanding of the multiplication process. However,
drawing circles and radii to calculate products becomes more and more difficult as the size of the
factors increases. Therefore, this algorithm could be introduced to students as one of several
methods for multiplication, but they should not rely on this method alone.
Paper Strip Multiplication
Another way to perform the operation of multiplication involves writing the numbers to
be multiplied on strips of paper, manipulating the order of the digits in one of the factors, and
performing a series of one-digit multiplications. This alternative algorithm may appeal to hands-
on learners. To multiply 432 × 628 using this method:
1. First, write each factor on a strip of paper, reversing the order of the digits in one of the numbers (432 234). 2. Place the strips of paper so that the inverted factor is above and to the right of the other factor. 3. Align the new first digit of the top number with the last digit of the bottom number, multiply, regroup the double digits, and write the product underneath.
4. Slide the bottom strip to right until the next set of digits line up, multiply the digits that are aligned, regroup the double digits, and write the sum underneath.
5. Continue sliding the bottom strip to the right, multiplying the aligned digits, regrouping the double digits, and writing the sum below the strips until all multiplications have been performed.
But, how does reversing the order of the digits along with multiplying and adding pairs of
numerals lead to the correct solution? Let's consider more closely what is actually happening as
we carry out the steps of this algorithm. First, consider multiplying 432 × 628 using the
traditional long multiplication algorithm.
6. Therefore, 432 × 628 = 271,296.
When the two methods are written side-by-side, it becomes apparent that they are
actually the same algorithm with the multiplication steps carried out in a different order for each
method. Because multiplication and addition are commutative, the order in which the steps are
carried out makes no difference to the final product.
Egyptian Multiplication
Evidence of mathematical computation, including multiplication, dates back to about
2000 BC (O’Connor & Robertson, 2011). Ancient Egyptian, Greek, Babylonian, Indian, and
Chinese civilizations are all credited with having methods for multiplying numbers. One of the
earliest documented forms of multiplication dates back to Ancient Egypt and does not require
memorization of the entire multiplication tables as it relies solely on the abilities to add and
multiply by two. The following example of multiplying 46 × 28 illustrates the Egyptian
multiplication process.
1. First, make two columns of numbers, starting with 1 in the left column and one
of the two factors (usually the greatest) in the right column.
2. Begin the process of decomposing the second factor into powers of 2 by doubling the
numbers in both columns until the number in the left column represents the greatest power of 2 less than or equal to the second factor.
3. Decompose the second factor into powers of 2.
4. Add the numbers in the right column that correspond to the powers of 2 indicated in Step 3.
1 46 2 92 4 184 8 368 16 736
The numbers in the left column represent powers of 2. While the numbers on the right represent 46 × these powers of 2. The greatest power of 2 ≤ 28 is 16.
The largest power of 2 less than or equal to 28 is 16. 28 - 16 = 12 The largest power of 2 less than or equal to 12 is 8. 12 - 8 = 4 The largest power of 2 less than or equal to 4 is 4. Thus, 28 is the sum of the powers of 2: 16 + 8 + 4.
1 46 2 92 4 184 8 368 16 736 28 1288
184 + 368 + 736 = 1288 Therefore: 46 × 28 = 1288
It is important to know why this method works. The algorithm is based on the distributive
property of multiplication over addition and the ability to rewrite a product as a sum of powers of
two. Since the numbers in the left hand column represent powers of two, the table can be
modified as follows:
While the Egyptian multiplication method involves more steps than the long
multiplication algorithm, its key advantage is users only need to know multiplication facts for
two. It can also be used as a form of scaffolding for students who have not yet mastered all of
their basic facts. This Algorithm could also be introduced in the classroom as a means of leading
students into a discussion of the meaning of multiplication, the process, and why it works. For
example, students could compare this multiplication method to the more traditional long
multiplication method and then explain how both procedures lead to the correct answer.
Introducing students to multiple algorithms also promotes conceptual understanding, and
according to noted mathematics scholar Laping Ma (1999), “when a problem is solved in
multiple ways, it serves as a tie connecting several pieces of mathematical knowledge” (p. 112).
Russian Peasant Multiplication
A variation of this Egyptian algorithm has also been linked to the peasants of early
Russia and is still in use in some areas today (Bogomolny 2011). This method involves a process
of halving and doubling, which reduces one factor to powers of two and uses the distributive
property of multiplication over addition to calculate a product. As with the Egyptian method, the
process begins by arranging numbers in two columns. The following example of multiplying
46 × 28 illustrates the Russian peasant multiplication process.
1. Create a column beneath each of the factors. 2. Repeatedly halve the number in the left hand column, dropping any remainder, until one is reached. 3. Repeatedly multiply numbers in the right hand column by two. 4. Cross off the rows that have an even number in the left hand column. 5. Add the remaining numbers in the right hand column to find the product.
The justification for this algorithm is almost identical to the rationalization for the
Egyptian method; however, let's look at it from a slightly different point of view. The fact that
both of these procedures are dependent on multiplication/division by two, suggests that they are
founded in the binary system. First, obtain the binary representation of 46 by following the
subsequent procedure:
1. List the powers of two in a “base two table” from right to left starting at 20, and increase the exponent by one for each power.
2. Find the greatest power of two that fits into 46. Since 32 fits into 46, write a one
for the leftmost binary digit. Subtract 32 from 46, which leaves 14.
3. Find the greatest power of two that fits into 14. Because 16 does not fit into 14, write a zero for the second binary digit.
4. Since eight fits into 14, write a one for the third binary digit. Subtract eight from 14, which leaves six.
5. Find the greatest power of two that fits into six. Since four fits into six, write a
one for the fourth binary digit. Subtract four from six, which leaves two.
6. Find the greatest power of two that fits into two. Since two (a power of two) fits into two (the working decimal number), write one for the next binary digit and subtract two from two, which leaves zero.
7. Since no additional powers of two will fit into zero, write zero for the remaining
Next, add two columns to the original table; the first shows the exponent of two that gives the number and the second represents the binary digits of 46 written in reverse order.
Because the binary digit represents the remainder in division by powers of two, one corresponds
to odd numbers in the column under 46 and zero corresponds to even numbers, thus only the
rows with odd numbers will contribute to the multiplication. One corresponds to the odd
numbers in the first column and zero corresponds to the even numbers in the first column. Thus
only the columns with odd numbers in the first row will contribute to the multiplication.
Adding two additional columns clearly illustrates the relationship between this algorithm and the binary system: 46 = 1011102 = (1 × 25) + (0 × 24) + (1 × 23) + (1 × 22) + (1 × 21) + (0 × 20) = 32 + 8 + 4 + 2
Vedic Multiplication
Vedic mathematics has its roots in the Vedas, which are ancient Indian texts first written
in Sanskrit and thought to have originated around 2000 BC. Spiritual leader and mathematician,
Sri Bharati Krsna Tirthaji reconstructed 16 sutras, or fundamental principles, derived from these
ancient texts. The sutras, along with 13 sub-sutras, are the basis for the Vedic mathematics
system (Nataraj & Thomas, 2006). Vedic multiplication is an efficient and simple form of mental
calculation. For example to multiply 24 × 32 using the vertically and crosswise sutra:
This algorithm could be introduced in the classroom as a tool to support mental
multiplication. When problems require multiple steps, solving them can become tedious,
and students can easily make mistakes. Middle school and high school students would
1. Multiply vertically on the right to find the units digit. 2. Multiply crosswise and add: (2 × 2) + (4 × 3) = 16. This gives the tens digit of the answer. (Notice that the one must be carried to the hundreds place.)
3. Multiply vertically on the left, and add the amount carried to find the hundreds digit. Therefore, 24 × 32 = 768.
especially appreciate this simple short cut to finding products, and they may even find the
ability to calculate mentally, empowering.
Let's take a deeper look at how this algorithm works. First of all, use the
Distributive Property of Multiplication to rewrite the same problem:
Notice how the highlighted portion of the problem corresponds to the vertical and crosswise algorithm. This algorithm is based on the Distributive Property of Multiplication. Writing the factors in
columns, along with adding the intermediary place holders between the first and last digit of the
answer, assigns each digit the correct place value.
To multiply larger numbers, one follows the same basic steps adding two more sets of
crosswise multiplication using the following pattern:
For example, to multiply 123 × 456 multiply and add as shown, regrouping values greater than 9
in the last step.
Therefore, 123 × 456 = 56088.
Conclusion
Multiplication is a basic mathematical skill, and understanding the process and its many
applications is of fundamental importance to the future success of today’s students. Education
has grown beyond the point where all students were expected to learn in the same way and by the
same instructional methods. Contemporary educators must be prepared to meet the widely varied
and individual educational needs of each of the students that enter the classroom. Research has
shown that when children are introduced to a variety of problem solving methods and strategies,
they become more flexible and resourceful in their problem solving abilities (NCTM, 2000). As
students gain knowledge of the history of the development of mathematical ideas, they are more
likely to view mathematics as a discipline that continues to evolve as people look for faster and
more efficient means of calculation in the quest to solve increasingly complicated problems.
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