Rafael Bombelli

Last updated April 25, 2024

Rafael Bombelli (baptised on 20 January 1526; died 1572)^{[lower-alpha 1]}^[1]^[2] was an Italian mathematician. Born in Bologna, he is the author of a treatise on algebra and is a central figure in the understanding of imaginary numbers.

Life

Rafael Bombelli was baptised on 20 January 1526^[3] in Bologna, Papal States. He was born to Antonio Mazzoli, a wool merchant, and Diamante Scudieri, a tailor's daughter. The Mazzoli family was once quite powerful in Bologna. When Pope Julius II came to power, in 1506, he exiled the ruling family, the Bentivoglios. The Bentivoglio family attempted to retake Bologna in 1508, but failed. Rafael's grandfather participated in the coup attempt, and was captured and executed. Later, Antonio was able to return to Bologna, having changed his surname to Bombelli to escape the reputation of the Mazzoli family. Rafael was the oldest of six children. Rafael received no college education, but was instead taught by an engineer-architect by the name of Pier Francesco Clementi.

Bombelli felt that none of the works on algebra by the leading mathematicians of his day provided a careful and thorough exposition of the subject. Instead of another convoluted treatise that only mathematicians could comprehend, Rafael decided to write a book on algebra that could be understood by anyone. His text would be self-contained and easily read by those without higher education.

Bombelli died in 1572 in Rome.

Bombelli's Algebra

In the book that was published in 1572, entitled Algebra, Bombelli gave a comprehensive account of the algebra known at the time. He was the first European to write down the way of performing computations with negative numbers. The following is an excerpt from the text:

"Plus times plus makes plus
Minus times minus makes plus
Plus times minus makes minus
Minus times plus makes minus
Plus 8 times plus 8 makes plus 64
Minus 5 times minus 6 makes plus 30
Minus 4 times plus 5 makes minus 20
Plus 5 times minus 4 makes minus 20"

As was intended, Bombelli used simple language as can be seen above so that anybody could understand it. But at the same time, he was thorough.

Notation

Bombelli introduced, for the first time in a printed text (in Book II of his Algebra), a form of index notation in which the equation
$x^{3}=6x+40$
appeared as
1U3 a. 6U1 p. 40.^[4]
in which he wrote the U3 as a raised bowl-shape (like the curved part of the capital letter U) with the number 3 above it. Full symbolic notation was developed shortly thereafter by the French mathematician François Viète.

Complex numbers

Perhaps more importantly than his work with algebra, however, the book also includes Bombelli's monumental contributions to complex number theory. Before he writes about complex numbers, he points out that they occur in solutions of equations of the form $x^{3}=ax+b,$ given that $(a/3)^{3}>(b/2)^{2},$ which is another way of stating that the discriminant of the cubic is negative. The solution of this kind of equation requires taking the cube root of the sum of one number and the square root of some negative number.

Before Bombelli delves into using imaginary numbers practically, he goes into a detailed explanation of the properties of complex numbers. Right away, he makes it clear that the rules of arithmetic for imaginary numbers are not the same as for real numbers. This was a big accomplishment, as even numerous subsequent mathematicians were extremely confused on the topic.

Bombelli avoided confusion by giving a special name to square roots of negative numbers, instead of just trying to deal with them as regular radicals like other mathematicians did. This made it clear that these numbers were neither positive nor negative. This kind of system avoids the confusion that Euler encountered. Bombelli called the imaginary number i "plus of minus" and used "minus of minus" for -i.

Bombelli had the foresight to see that imaginary numbers were crucial and necessary to solving quartic and cubic equations. At the time, people cared about complex numbers only as tools to solve practical equations. As such, Bombelli was able to get solutions using Scipione del Ferro's rule, even in casus irreducibilis, where other mathematicians such as Cardano had given up.

In his book, Bombelli explains complex arithmetic as follows:

"Plus by plus of minus, makes plus of minus.
Minus by plus of minus, makes minus of minus.
Plus by minus of minus, makes minus of minus.
Minus by minus of minus, makes plus of minus.
Plus of minus by plus of minus, makes minus.
Plus of minus by minus of minus, makes plus.
Minus of minus by plus of minus, makes plus.
Minus of minus by minus of minus makes minus."

After dealing with the multiplication of real and imaginary numbers, Bombelli goes on to talk about the rules of addition and subtraction. He is careful to point out that real parts add to real parts, and imaginary parts add to imaginary parts.

Reputation

Bombelli is generally regarded as the inventor of complex numbers, as no one before him had made rules for dealing with such numbers, and no one believed that working with imaginary numbers would have useful results. Upon reading Bombelli's Algebra, Leibniz praised Bombelli as an ". . . outstanding master of the analytical art." Crossley writes in his book, "Thus we have an engineer, Bombelli, making practical use of complex numbers perhaps because they gave him useful results, while Cardan found the square roots of negative numbers useless. Bombelli is the first to give a treatment of any complex numbers. . . It is remarkable how thorough he is in his presentation of the laws of calculation of complex numbers. . ."^[5]

In honor of his accomplishments, a Moon crater was named Bombelli.

Bombelli's method of calculating square roots

Bombelli used a method related to continued fractions to calculate square roots. He did not yet have the concept of a continued fraction, and below is the algorithm of a later version given by Pietro Cataldi (1613).^[6]

The method for finding ${\sqrt {n}}$ begins with $n=(a\pm r)^{2}=a^{2}\pm 2ar+r^{2}\$ with $0<r<1\$ , from which it can be shown that $r={\frac {|n-a^{2}|}{2a\pm r}}$ . Repeated substitution of the expression on the right hand side for $r$ into itself yields a continued fraction

a\pm {\frac {|n-a^{2}|}{2a\pm {\frac {|n-a^{2}|}{2a\pm {\frac {|n-a^{2}|}{2a\pm \cdots }}}}}}

for the root but Bombelli is more concerned with better approximations for $r$ . The value chosen for $a$ is either of the whole numbers whose squares $n$ lies between. The method gives the following convergents for ${\sqrt {13}}\$ while the actual value is 3.605551275... :

3{\frac {2}{3}},\ 3{\frac {3}{5}},\ 3{\frac {20}{33}},\ 3{\frac {66}{109}},\ 3{\frac {109}{180}},\ 3{\frac {720}{1189}},\ \cdots

The last convergent equals 3.605550883... . Bombelli's method should be compared with formulas and results used by Heros and Archimedes. The result ${\frac {265}{153}}<{\sqrt {3}}<{\frac {1351}{780}}$ used by Archimedes in his determination of the value of $\pi$ can be found by using 1 and 0 for the initial values of $r$ .

Related Research Articles

In mathematics, a complex number is an element of a number system that extends the real numbers with a specific element denoted $i$ , called the imaginary unit and satisfying the equation $; every complex number can be expressed in the form, where a and b are real numbers. Because no real number satisfies the above equation, i was called an imaginary number by René Descartes. For the complex number, a is called the real part, and b is called the imaginary part . The set of complex numbers is denoted by either of the symbols or C . Despite the historical nomenclature, "imaginary" complex numbers have a mathematical existence as firm as that of the real numbers, and they are fundamental tools in the scientific description of the natural world.$

<span class="mw-page-title-main">Exponential function</span> Mathematical function, denoted exp(x) or e^x

The exponential function is a mathematical function denoted by $or . Unless otherwise specified, the term generally refers to the positive-valued function of a real variable, although it can be extended to the complex numbers or generalized to other mathematical objects like matrices or Lie algebras. The exponential function originated from the operation of taking powers of a number, but various modern definitions allow it to be rigorously extended to all real arguments, including irrational numbers. Its ubiquitous occurrence in pure and applied mathematics led mathematician Walter Rudin to consider the exponential function to be "the most important function in mathematics".$

An imaginary number is a real number multiplied by the imaginary unit $i$ , which is defined by its property $i 2 = -1$ . The square of an imaginary number $bi$ is $- b 2$ . For example, $5 i$ is an imaginary number, and its square is $-25$ . The number zero is considered to be both real and imaginary.

<span class="mw-page-title-main">Number</span> Used to count, measure, and label

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In mathematics, the quaternion number system extends the complex numbers. Quaternions were first described by the Irish mathematician William Rowan Hamilton in 1843 and applied to mechanics in three-dimensional space. The algebra of quaternions is often denoted by $H$ , or in blackboard bold by $Quaternions are not a field, because multiplication of quaternions is not, in general, commutative. Quaternions provide a definition of the quotient of two vectors in a three-dimensional space. Quaternions are generally represented in the form$

<span class="mw-page-title-main">Imaginary unit</span> Principal square root of −1

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In algebra, the theory of equations is the study of algebraic equations, which are equations defined by a polynomial. The main problem of the theory of equations was to know when an algebraic equation has an algebraic solution. This problem was completely solved in 1830 by Évariste Galois, by introducing what is now called Galois theory.

William Rowan Hamilton invented quaternions, a mathematical entity in 1843. This article describes Hamilton's original treatment of quaternions, using his notation and terms. Hamilton's treatment is more geometric than the modern approach, which emphasizes quaternions' algebraic properties. Mathematically, quaternions discussed differ from the modern definition only by the terminology which is used.

A mathematical constant is a key number whose value is fixed by an unambiguous definition, often referred to by a special symbol, or by mathematicians' names to facilitate using it across multiple mathematical problems. Constants arise in many areas of mathematics, with constants such as $e$ and $π$ occurring in such diverse contexts as geometry, number theory, statistics, and calculus.

References

Footnotes

↑ Dates follow the Julian calendar. The Gregorian calendar was adopted in Italy in 1582 (4 October 1582 was followed by 15 October 1582).

Citations

↑ "The Gregorian calendar".
↑ Crossley 1987, p. 95.
↑ "Rafael Bombelli". www.gavagai.de. Archived from the original on 19 November 2003.
↑ Stedall, Jacqueline Anne (2000). A large discourse concerning algebra: John Wallis's 1685 Treatise of algebra (Thesis). The Open University Press.
↑ Crossley 1987.
↑ Bombelli_algebra

Sources

Morris Kline, Mathematical Thought from Ancient to Modern Times, 1972, Oxford University Press, New York, ISBN 0-19-501496-0
David Eugene Smith, A Source Book in Mathematics, 1959, Dover Publications, New York, ISBN 0-486-64690-4
Crossley, John N. (1987). The emergence of number. Singapore: World Scientific. doi:10.1142/0462. ISBN 978-9971-5-0413-7.
Daniel J. Curtin, et al., Rafael Bombelli's L'Algebra, 1996,

https://www.people.iup.edu/gsstoudt/history/bombelli/bombelli.pdf

External links

L'Algebra, Libri I, II, III, IV e V, original Italian texts.
O'Connor, John J.; Robertson, Edmund F., "Rafael Bombelli", MacTutor History of Mathematics Archive , University of St Andrews
Background

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[1] Dates follow the Julian calendar. The Gregorian calendar was adopted in Italy in 1582 (4 October 1582 was followed by 15 October 1582).

[2] "The Gregorian calendar".

[FOOTNOTECrossley198795-3] Crossley 1987, p. 95.

[4] "Rafael Bombelli". www.gavagai.de. Archived from the original on 19 November 2003.

[Stedall-5] Stedall, Jacqueline Anne (2000). A large discourse concerning algebra: John Wallis's 1685 Treatise of algebra (Thesis). The Open University Press.

[FOOTNOTECrossley1987-6] Crossley 1987.

[7] Bombelli_algebra

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