Multiplication table
In mathematics, a multiplication table (sometimes, less formally, a times table) is a mathematical table used to define a multiplication operation for an algebraic system.
The decimal multiplication table was traditionally taught as an essential part of elementary arithmetic around the world, as it lays the foundation for arithmetic operations with baseten numbers. Many educators believe it is necessary to memorize the table up to 9 × 9.^{[1]}
HistoryEdit
The oldest known multiplication tables were used by the Babylonians about 4000 years ago.^{[2]} However, they used a base of 60.^{[2]} The oldest known tables using a base of 10 are the Chinese decimal multiplication table on bamboo strips dating to about 305 BC, during China's Warring States period.^{[2]}
The multiplication table is sometimes attributed to the ancient Greek mathematician Pythagoras (570–495 BC). It is also called the Table of Pythagoras in many languages (for example French, Italian and Russian), sometimes in English.^{[4]} The GrecoRoman mathematician Nichomachus (60–120 AD), a follower of Neopythagoreanism, included a multiplication table in his Introduction to Arithmetic, whereas the oldest surviving Greek multiplication table is on a wax tablet dated to the 1st century AD and currently housed in the British Museum.^{[5]}
In 493 AD, Victorius of Aquitaine wrote a 98column multiplication table which gave (in Roman numerals) the product of every number from 2 to 50 times and the rows were "a list of numbers starting with one thousand, descending by hundreds to one hundred, then descending by tens to ten, then by ones to one, and then the fractions down to 1/144."^{[6]}
In his 1820 book The Philosophy of Arithmetic,^{[7]} mathematician John Leslie published a multiplication table up to 99 × 99, which allows numbers to be multiplied in pairs of digits at a time. Leslie also recommended that young pupils memorize the multiplication table up to 50 × 50. The illustration below shows a table up to 12 × 12, which is a size commonly used in schools.
×  0  1  2  3  4  5  6  7  8  9  10  11  12 

0  0  0  0  0  0  0  0  0  0  0  0  0  0 
1  0  1  2  3  4  5  6  7  8  9  10  11  12 
2  0  2  4  6  8  10  12  14  16  18  20  22  24 
3  0  3  6  9  12  15  18  21  24  27  30  33  36 
4  0  4  8  12  16  20  24  28  32  36  40  44  48 
5  0  5  10  15  20  25  30  35  40  45  50  55  60 
6  0  6  12  18  24  30  36  42  48  54  60  66  72 
7  0  7  14  21  28  35  42  49  56  63  70  77  84 
8  0  8  16  24  32  40  48  56  64  72  80  88  96 
9  0  9  18  27  36  45  54  63  72  81  90  99  108 
10  0  10  20  30  40  50  60  70  80  90  100  110  120 
11  0  11  22  33  44  55  66  77  88  99  110  121  132 
12  0  12  24  36  48  60  72  84  96  108  120  132  144 
The traditional rote learning of multiplication was based on memorization of columns in the table, in a form like
1 × 10 = 10
2 × 10 = 20
3 × 10 = 30
4 × 10 = 40
5 × 10 = 50
6 × 10 = 60
7 × 10 = 70
8 × 10 = 80
9 × 10 = 90
This form of writing the multiplication table in columns with complete number sentences is still used in some countries, such as Bosnia and Herzegovina,^{[citation needed]} instead of the modern grid above.
Patterns in the tablesEdit
There is a pattern in the multiplication table that can help people to memorize the table more easily. It uses the figures below:
→  →  
↑  1  2  3  ↓  ↑  2  4  ↓  

4  5  6  
7  8  9  6  8  
←  ←  
0  5  0  
Figure 1: Odd  Figure 2: Even 
Figure 1 is used for multiples of 1, 3, 7, and 9. Figure 2 is used for the multiples of 2, 4, 6, and 8. These patterns can be used to memorize the multiples of any number from 0 to 10, except 5. As you would start on the number you are multiplying, when you multiply by 0, you stay on 0 (0 is external and so the arrows have no effect on 0, otherwise 0 is used as a link to create a perpetual cycle). The pattern also works with multiples of 10, by starting at 1 and simply adding 0, giving you 10, then just apply every number in the pattern to the "tens" unit as you would normally do as usual to the "ones" unit.
For example, to recall all the multiples of 7:
 Look at the 7 in the first picture and follow the arrow.
 The next number in the direction of the arrow is 4. So think of the next number after 7 that ends with 4, which is 14.
 The next number in the direction of the arrow is 1. So think of the next number after 14 that ends with 1, which is 21.
 After coming to the top of this column, start with the bottom of the next column, and travel in the same direction. The number is 8. So think of the next number after 21 that ends with 8, which is 28.
 Proceed in the same way until the last number, 3, corresponding to 63.
 Next, use the 0 at the bottom. It corresponds to 70.
 Then, start again with the 7. This time it will correspond to 77.
 Continue like this.
Multiplication by 6 to 10Edit
Multiplying two whole numbers, each from 6 to 10 can be achieved using fingers and thumbs as follows:
 Number the fingers and thumbs from 10 to 6, then 6 to 10 from left to right, as in the figure.
 Bend the finger or thumb on each hand corresponding to each number, and all the fingers between them.
 The number of bent fingers or thumbs gives the tens digit.
 To the above is added the product of the unbent fingers or thumbs on the left and right sides.
Multiplication by 9Edit
Multiplying 9 with a whole number from 1 to 10 can also be achieved as follows:
 Number the fingers and thumbs from 1 to 10 from left to right.
 Bend the finger or thumb corresponding to the number.
 The number of fingers or thumb to the left of the bend gives the tens digit (if none, the digit is zero).
 The number of fingers or thumb to the right of the bend gives the units digit (if none, the digit is zero).
In abstract algebraEdit
Tables can also define binary operations on groups, fields, rings, and other algebraic systems. In such contexts they can be called Cayley tables. Here are the addition and multiplication tables for the finite field Z_{5}.
For every natural number n, there are also addition and multiplication tables for the ring Z_{n}.


Chinese multiplication tableEdit
The Chinese multiplication table consists of eightyone sentences with four or five Chinese characters per sentence, making it easy for children to learn by heart. A shorter version of the table consists of only fortyfive sentences, as terms such as "nine eights beget seventytwo" are identical to "eight nines beget seventytwo" so there is no need to learn them twice. A minimum version by removing all "one" sentences, consists of only thirtysix sentences, which is most commonly used in schools in China. It's often in this order: 2x2=4, 2x3=6, ..., 2x8=16, 2x9=18, 3x3, 3x4, ..., 3x9, 4x4, ..., 4x9, 5x5,...,9x9
Warring States decimal multiplication bamboo slipsEdit
A bundle of 21 bamboo slips dated 305 BC in the Warring States period in the Tsinghua Bamboo Slips (清华简) collection is the world's earliest known example of a decimal multiplication table.^{[8]}
Standardsbased mathematics reform in the USEdit
In 1989, the National Council of Teachers of Mathematics (NCTM) developed new standards which were based on the belief that all students should learn higherorder thinking skills, which recommended reduced emphasis on the teaching of traditional methods that relied on rote memorization, such as multiplication tables. Widely adopted texts such as Investigations in Numbers, Data, and Space (widely known as TERC after its producer, Technical Education Research Centers) omitted aids such as multiplication tables in early editions. NCTM made it clear in their 2006 Focal Points that basic mathematics facts must be learned, though there is no consensus on whether rote memorization is the best method.
See alsoEdit
 Division table
 Chinese multiplication table
 Vedic square
 IBM 1620, an early computer that used tables stored in memory to perform addition and multiplication
ReferencesEdit
 ^ Trivett, John (1980), "The Multiplication Table: To Be Memorized or Mastered!", For the Learning of Mathematics, 1 (1): 21–25, JSTOR 40247697.
 ^ ^{a} ^{b} ^{c} Jane Qiu (January 7, 2014). "Ancient times table hidden in Chinese bamboo strips". Nature News. doi:10.1038/nature.2014.14482.
 ^ Wikisource:Page:Popular Science Monthly Volume 26.djvu/467
 ^ for example in An Elementary Treatise on Arithmetic by John Farrar
 ^ David E. Smith (1958), History of Mathematics, Volume I: General Survey of the History of Elementary Mathematics. New York: Dover Publications (a reprint of the 1951 publication), ISBN 0486204294, pp. 58, 129.
 ^ David W. Maher and John F. Makowski. "Literary evidence for Roman arithmetic with fractions". Classical Philology, 96/4 (October 2001), p. 383.
 ^ Leslie, John (1820). The Philosophy of Arithmetic; Exhibiting a Progressive View of the Theory and Practice of Calculation, with Tables for the Multiplication of Numbers as Far as One Thousand. Edinburgh: Abernethy & Walker.
 ^ Nature article The 2,300yearold matrix is the world's oldest decimal multiplication table