*Surdorum quadraticorum arithmetica* (Arithmetic of Square Roots) is a work by the mathematician and fencing master Ludolph Van Ceulen (1540–1610), which was translated into Latin by his student Willebrord Snell (1580–1626). It was published after the death of Van Ceulen, along with Snell’s modification and Latin translation *De Circulo* of Van Ceulen’s *Vanden Circkel*, which was published in 1596. Images from the 1594 Dutch original *Vanden Circkel* are available on *Convergence*. Images from *De Circulo* are available on *Convergence* here and here. The last two images in the first link above for *De Circulo* are actually from *Surdorum quadraticorum arithmetica*, which was bound together with *De Circulo*.

The opening page of *Surdorum quadraticorum arithmetica* is below.

Chapter 2 is about the addition of “simple irrational numbers”, that is square roots which when simplified have a common square root factor, such as \(5\sqrt{3}\) and \(2\sqrt{3}\). However Van Ceulen does not simplify irrational square roots like we do today; for example he uses \(\sqrt{75}\) rather than \(5\sqrt{3}\). Below are images of pages 4 and 5 showing several examples of his method for adding these simple irrational numbers.

Van Ceulen’s method for adding this type of square roots is to add together the sum of the radicands with the square root of the product of the radicands multiplied by 4. The solution is the square root of this sum. His example on page 4 is to find the sum \(\sqrt{75} + \sqrt{12}\). Notice \(75+12=87\) and \(75\times 12=900\). Then the square root of \(900\times 4= 3600\) is \(60\), and \(60+87=147\). So \(\sqrt{75} + \sqrt{12}=\sqrt{147}\). Additional examples are then given on page 5, pictured above.

Upon closer inspection of the addition examples, one notices that, if simplified, they are all of the form \(a\sqrt{c} + b\sqrt{c}=(a+b)\sqrt{c}\), where \(a, b, c\) are all positive integers. So, using Van Ceulen’s non-simplified notation, the sum is of the form \(\sqrt{a^2c} + \sqrt{b^2c}\). Four times the product of the radicands is then \(4a^2b^2c^2\) which is the square of \(2abc\). Adding \(2abc\) to the sum of the original radicands yields \(a^2c + 2abc + b^2c = (a+b)^2c\). Thus, his method produces the desired sum for this special case of irrationals, \(a\sqrt{c} + b\sqrt{c}=\sqrt{a^2c} + \sqrt{b^2c}= \sqrt{a^2c + 2abc + b^2c} = \sqrt{(a+b)^2c}=(a+b)\sqrt{c}\).

Below on page 85, is a figure of the Pythagorean Theorem applied to a 5–12–13 right triangle.

A complete digital scan of *Surdorum quadraticorum arithmetica* is available in the Linda Hall Library Digital Collections, starting after the scan of *De Circulo*, which is 54 pages long. The books are bound together and assigned the call number QA33 .C481 1619.

*Images in this article are courtesy of the Linda Hall Library of Science, Engineering & Technology and used with permission. The images may be downloaded and used for the purposes of research, teaching, and private study, provided the Linda Hall Library of Science, Engineering & Technology is credited as the source. For other uses, check out the LHL **Image Rights and Reproductions** policy.*