Lattice multiplication, also known as the Italian method, Chinese method, Chinese lattice, gelosia multiplication, sieve multiplication, shabakh, diagonally or Venetian squares, is a method of

multiplication Multiplication (often denoted by the cross symbol , by the mid-line dot operator , by juxtaposition, or, on computers, by an asterisk ) is one of the four elementary mathematical operations of arithmetic, with the other ones being additi ...

that uses a

lattice Lattice may refer to: Arts and design * Latticework, an ornamental criss-crossed framework, an arrangement of crossing laths or other thin strips of material * Lattice (music), an organized grid model of pitch ratios * Lattice (pastry), an orna ...

to multiply two multi-digit numbers. It is mathematically identical to the more commonly used

long multiplication A multiplication algorithm is an algorithm (or method) to multiply two numbers. Depending on the size of the numbers, different algorithms are more efficient than others. Efficient multiplication algorithms have existed since the advent of the de ...

algorithm, but it breaks the process into smaller steps, which some practitioners find easier to use. The method had already arisen by medieval times, and has been used for centuries in many different cultures. It is still being taught in certain curricula today.

Method

A grid is drawn up, and each cell is split diagonally. The two

multiplicand Multiplication (often denoted by the cross symbol , by the mid-line dot operator , by juxtaposition, or, on computers, by an asterisk ) is one of the four elementary mathematical operations of arithmetic, with the other ones being additio ...

s of the product to be calculated are written along the top and right side of the lattice, respectively, with one digit per column across the top for the first multiplicand (the number written left to right), and one digit per row down the right side for the second multiplicand (the number written top-down). Then each cell of the lattice is filled in with product of its column and row digit. As an example, consider the multiplication of 58 with 213. After writing the multiplicands on the sides, consider each cell, beginning with the top left cell. In this case, the column digit is 5 and the row digit is 2. Write their product, 10, in the cell, with the digit 1 above the diagonal and the digit 0 below the diagonal (see picture for Step 1). If the simple product lacks a digit in the tens place, simply fill in the tens place with a 0. After all the cells are filled in this manner, the digits in each diagonal are summed, working from the bottom right diagonal to the top left. Each diagonal sum is written where the diagonal ends. If the sum contains more than one digit, the value of the tens place is carried into the next diagonal (see Step 2). Numbers are filled to the left and to the bottom of the grid, and the answer is the numbers read off down (on the left) and across (on the bottom). In the example shown, the result of the multiplication of 58 with 213 is 12354.

Multiplication of decimal fractions

The lattice technique can also be used to multiply

decimal fractions The decimal numeral system (also called the base-ten positional numeral system and denary or decanary) is the standard system for denoting integer and non-integer numbers. It is the extension to non-integer numbers of the Hindu–Arabic numeral ...

. For example, to multiply 5.8 by 2.13, the process is the same as to multiply 58 by 213 as described in the preceding section. To find the position of the decimal point in the final answer, one can draw a vertical line from the decimal point in 5.8, and a horizontal line from the decimal point in 2.13. (See picture for Step 4.) The grid diagonal through the intersection of these two lines then determines the position of the decimal point in the result. In the example shown, the result of the multiplication of 5.8 and 2.13 is 12.354.

History

Though lattice multiplication has been used historically in many cultures, a method called 'Kapat-sandhi' very similar to the lattice method is mentioned in the commentary on 12th century 'Lilavati' a book of Indian mathematics by Bhaskaracharya. It is being researched where it arose first, whether it developed independently within more than one region of the world. The earliest recorded use of lattice multiplication:Jean-Luc Chabert, ed., ''A History of Algorithms: From the Pebble to the Microchip'' (Berlin: Springer, 1999), pp. 21-26. * in Arab mathematics was by

Ibn al-Banna' al-Marrakushi Ibn al‐Bannāʾ al‐Marrākushī ( ar, ابن البناء المراكشي), full name: Abu'l-Abbas Ahmad ibn Muhammad ibn Uthman al-Azdi al-Marrakushi () (29 December 1256 – 31 July 1321), was a Moroccan polymath who was active as a math ...

in his ''Talkhīṣ a‘māl al-ḥisāb'', in the Maghreb in the late 13th century * in European mathematics was by the unknown author of a Latin treatise in England, ''Tractatus de minutis philosophicis et vulgaribus'', c. 1300 * in Chinese mathematics was by Wu Jing in his ''Jiuzhang suanfa bilei daquan'', completed in 1450. The mathematician and educator

David Eugene Smith David Eugene Smith (January 21, 1860 – July 29, 1944) was an American mathematician, educator, and editor. Education and career David Eugene Smith is considered one of the founders of the field of mathematics education. Smith was born in Cortl ...

asserted that lattice multiplication was brought to Italy from the Middle East. This is reinforced by noting that the Arabic term for the method, ''shabakh'', has the same meaning as the Italian term for the method, ''gelosia'', namely, the metal grille or grating (lattice) for a window. It is sometimes erroneously stated that lattice multiplication was described by

Muḥammad ibn Mūsā al-Khwārizmī Muhammad ( ar, مُحَمَّد; 570 – 8 June 632 CE) was an Arab religious, social, and political leader and the founder of Islam. According to Islamic doctrine, he was a prophet divinely inspired to preach and confirm the mono ...

(Baghdad, c. 825) or by

Fibonacci Fibonacci (; also , ; – ), also known as Leonardo Bonacci, Leonardo of Pisa, or Leonardo Bigollo Pisano ('Leonardo the Traveller from Pisa'), was an Italian mathematician from the Republic of Pisa, considered to be "the most talented Western ...

in his ''

Liber Abaci ''Liber Abaci'' (also spelled as ''Liber Abbaci''; "The Book of Calculation") is a historic 1202 Latin manuscript on arithmetic by Leonardo of Pisa, posthumously known as Fibonacci. ''Liber Abaci'' was among the first Western books to describe ...

'' (Italy, 1202, 1228). In fact, however, no use of lattice multiplication by either of these two authors has been found. In Chapter 3 of his ''

'',

does describe a related technique of multiplication by what he termed ''quadrilatero in forma scacherii'' (“rectangle in the form of a chessboard”). In this technique, the square cells are not subdivided diagonally; only the lowest-order digit is written in each cell, while any higher-order digit must be remembered or recorded elsewhere and then "carried" to be added to the next cell. This is in contrast to lattice multiplication, a distinctive feature of which is that each cell of the rectangle has its own correct place for the carry digit; this also implies that the cells can be filled in any order desired. Swetz compares and contrasts multiplication by ''gelosia'' (lattice), by ''scacherii'' (chessboard), and other tableau methods. Other notable historical uses of lattice multiplication include: *

Jamshīd al-Kāshī Ghiyāth al-Dīn Jamshīd Masʿūd al-Kāshī (or al-Kāshānī) ( fa, غیاث الدین جمشید کاشانی ''Ghiyās-ud-dīn Jamshīd Kāshānī'') (c. 1380 Kashan, Iran – 22 June 1429 Samarkand, Transoxania) was a Persian astronomer a ...

’s ''Miftāḥ al-ḥisāb'' (Samarqand, 1427), in which the numerals used are sexagesimal (base 60), and the grid is turned 45 degrees to a “diamond” orientation * the ''Arte dell’Abbaco'', an anonymous text published in the Venetian dialect in 1478, often called the

Treviso Arithmetic The ''Treviso Arithmetic'', or ''Arte dell'Abbaco'', is an anonymous textbook in commercial arithmetic written in vernacular Venetian language, Venetian and published in Treviso, Italy, in 1478. The author explains the motivation for writing thi ...

because it was printed in Treviso, just inland from Venice, Italy *

Luca Pacioli Fra Luca Bartolomeo de Pacioli (sometimes ''Paccioli'' or ''Paciolo''; 1447 – 19 June 1517) was an Italian mathematician, Franciscan friar, collaborator with Leonardo da Vinci, and an early contributor to the field now known as accounting ...

’s ''

Summa de arithmetica ' (''Summary of arithmetic, geometry, proportions and proportionality'') is a book on mathematics written by Luca Pacioli and first published in 1494. It contains a comprehensive summary of Renaissance mathematics, including practical arithmeti ...

'' (Venice, 1494) * the Indian astronomer Gaṇeśa's commentary on

Bhāskara II Bhāskara II (c. 1114–1185), also known as Bhāskarāchārya ("Bhāskara, the teacher"), and as Bhāskara II to avoid confusion with Bhāskara I, was an Indian mathematician and astronomer. From verses, in his main work, Siddhānta Shiroman ...

’s '' Lilāvati'' (16th century).

Derivations

Derivations of this method also appeared in the 16th century works ''Umdet-ul Hisab'' by Ottoman-Bosnian polymath

Matrakçı Nasuh Nasuh bin Karagöz bin Abdullah el-Visokavi el-Bosnavî, commonly known as Matrakçı Nasuh (; ) for his competence in the combat sport of '' Matrak'' which was invented by himself, (also known as ''Nasuh el-Silâhî'', ''Nasuh the Swordsman'', ...

's triangular version of the multiplication technique is seen in the example showing 155 x 525 on the right, and explained in the example showing 236 x 175 on the left figure.{{Cite journal, url=https://tamu.academia.edu/SencerCorlu/Papers/471488/The_Ottoman_Palace_School_Enderun_and_the_Man_with_Multiple_Talents_Matrakci_Nasuh, title = Corlu, M. S., Burlbaw, L. M., Capraro, R. M., Han, S., & Çorlu, M. A. (2010). The Ottoman palace school and the man with multiple talents, Matrakçı Nasuh. Journal of the Korea Society of Mathematical Education Series D: Research in Mathematical Education, 14(1), 19–31, journal = D-수학교육연구, date = January 2010, last1 = Capraro, first1 = Robert matraki2

The same principle described by

underlay the later development of the calculating rods known as

Napier's bones Napier's bones is a manually-operated calculating device created by John Napier of Merchiston, Scotland for the calculation of products and quotients of numbers. The method was based on lattice multiplication, and also called ''rabdology'', a wor ...

(Scotland, 1617) and

Genaille–Lucas rulers Genaille–Lucas rulers (also known as Genaille's rods) are an arithmetic tool invented by Henri Genaille, a French railway engineer, in 1891. The device is a variant of Napier's bones. By representing the carry graphically, the user can read ...

(France, late 1800s).

References

Multiplication

Method

Multiplication of decimal fractions

History

Derivations

See also

References