The Story of Omar Khayyam

Gabrielle Birchak/ August 6, 2024/ Middle Ages, Post Classical

Interdisciplinary thinking. Sometimes, I can have intellectual revelations by taking my brain into places where it hasn’t been before. And I know there are so many people out there who do the same. For example, when I worked at NASA, I discovered that there were so many people on the lab who were musicians, part-time actors, resolute golfers, sports addicts, foodies and chefs, and more. They enjoyed being creative and immersing themselves in a world that was outside of their occupation. Through these creative outlets, they could find a new focus and make new discoveries within their work in science. And that was exceptionally inspiring to be around. Reminiscing about NASA led me to create this podcast about someone in history who was an exceptional interdisciplinary thinker.

^{By Alireza Javaheri, CC BY 3.0, https://commons.wikimedia.org/w/index.php?curid=55909539}

I note Hypatia’s work on conics in my book. It’s a fascinating subject that lends itself to further understanding algebra and geometry. Its contribution to algebra can be seen through the brilliant work of the Persian mathematician Omar Khayyam. But, like Hypatia, he was more than just a mathematician. Like Hypatia, he was also an astronomer, a philosopher, and a political advisor. Furthermore, he was not just analytical; he was also highly creative and wrote beautiful poetry.

Omar Khayyam was born on May 18, 1048, in Nishapur, a city in northeastern Iran. His full name was Ghiyath al-Din Abu’l‑Fath Umar ibn Ibrahim al-Nisaburi al-Khayyami. Nishapur was a cultural and intellectual hub during Khayyam’s time, providing a rich environment for his education and intellectual growth. Khayyam showed an early aptitude for mathematics and science, which set the stage for his later achievements.

Khayyam’s most significant contributions to mathematics lie in his work on algebra. His pivotal book, “Treatise on Demonstration of Problems of Algebra,” was a landmark text that systematically presented methods for solving cubic equations. Khayyam employed geometric methods, unlike his predecessors, who approached cubic equations algebraically. He used the intersection of conic sections, including parabolas, hyperbolas, and circles, to find solutions to algebraic equations. In the eleventh century, this was an innovative approach ahead of its time. His methodologies laid the groundwork for future developments in algebra and geometry.

For example, Khayyam tackled cubic equations of the form.

x^3+ax=b

He demonstrated that one could find the roots of the cubic equation by intersecting a parabola with a circle. This revolutionary method illustrated Khayyam’s deep understanding of algebra and geometry.

Before Khayyam, solutions to cubic equations were largely unknown. Early mathematicians had developed methods for solving linear equations, quadratic equations, and equations with exponents divisible by two. However, it was still difficult to find general solutions to cubic equations and those equations with exponents divisible by three.

He worked with a few methodologies, some of which include the reduction to a standard form. Khayyam reduced the general cubic equation to simpler forms he could manage with geometric techniques. For instance, he would change the variables of equations to eliminate the quadratic term if it was present.

Another methodology that he used included translating algebraic problems into geometric ones. By looking at the geometry of the equations, like parabolas and circles, he could better understand the algebra behind the geometry. This leads us to his third methodology which was evaluating algebra through the intersection of conics. He realized that the solutions to cubic equations could be found by considering the points of intersection between certain conic sections, such as the intersection between a circle and a parabola.

For example, let’s look at the cubic equation

x^3+6x=20.

Khayyam would rewrite this equation to read

x^3=20-6x

which became a form suitable for geometric interpretation.

He would then look at the intersection of the parabola of equation

y=\frac{x^2}{6}

And the intersection of the circle of equation

y=20-6x.

By finding the points where these two curves intersect, he obtained the solutions to the cubic equation. This was considered groundbreaking for his time.

He was a mathematician whose work exceeded the brilliance of his peers. In addition to his work with cubic equations, HE also contributed to the understanding of the binomial theorem and the concept of combinatorics, which are foundational to modern algebra. His methods and ideas influenced later mathematicians in both the Islamic world and Europe, cementing his place in the history of mathematics.

CALENDAR REFORM

In addition to his work with mathematics, he did significant work on calendar reform. Over the past 2000 years, if not more, there have been various calendar reforms. I discussed this in my season one podcast about Leap Year. In 46 BCE, Julius Caesar and his brilliant sidekick Sosigenes realized a three-month seasonal discrepancy in their calendar. And so, he commissioned Sosigenes to develop the Julian calendar. In the same podcast, I also mention the Gregorian calendar and how that was implemented by Pope Gregory in October 1582.

^{By Rashid al-Din — ‘Jami’ al-Tawarikh’ of Rashid al-Din, Public Domain, https://commons.wikimedia.org/w/index.php?curid=52179490}

However, in that podcast, I failed to mention the developments made in Persia and Iran on the calendar reform implemented by Sultan Malik Shah I of the Seljuk Empire. Five hundred years earlier than the Gregorian calendar, in 1074 the Sultan invited Khayyam to Isfahan to reform the calendar. The goal was to create a more accurate calendar to better predict the solar year and improve agricultural planning.

Khayyam, along with a team of astronomers, developed the Jalali calendar. The Jalali Calendar, introduced in 1079, was remarkably precise. It calculated the length of the year as 365.24219858156 days, which is only slightly different from the modern value of 365.242190 days. This level of accuracy was unmatched at the time and remained so until the introduction of the Gregorian calendar in 1582.

The Jalali calendar’s precision stemmed from Khayyam’s deep understanding of astronomy and his meticulous observational methods. He and his team extensively used observational data to refine their calculations, ensuring the calendar’s accuracy over extended periods. The Jalali calendar is still used in Iran today, a testament to Khayyam’s enduring legacy.

POLITICS

Khayyam’s contributions were not limited to mathematics and astronomy. He was also deeply involved in the political life of his time. He served as an advisor to Sultan Malik Shah I and later to his successor, Sultan Sanjar. His role as a court advisor allowed him to influence decisions on various matters, including scientific and educational policies.

Despite his involvement in politics, Khayyam remained dedicated to his intellectual pursuits. He navigated the complexities of court life while continuing his research and writing. This dual role as a scholar and political advisor highlights Khayyam’s versatility and ability to thrive in different spheres.

In addition to his mathematical and political contributions, Khayyam is also known in the West for his poetry. His collection of quatrains, known as the Rubaiyat, has been translated into many languages and continues to captivate readers with its themes of love, mortality, and the pursuit of knowledge.

Here’s an excerpt from one of his most famous quatrains, translated by Edward FitzGerald:

“The Moving Finger writes; and, having writ,
Moves on: nor all thy Piety nor Wit
Shall lure it back to cancel half a Line,
Nor all thy Tears wash out a Word of it.”
Omar Khayyam

These lines reflect Khayyam’s philosophical outlook on life and the inevitable passage of time. His poetry often contemplates the transient nature of existence and the importance of living in the moment. The Rubaiyat’s themes resonate with readers across cultures and eras, highlighting Khayyam’s universal appeal.

Khayyam’s work in mathematics, astronomy, and poetry intersected in fascinating ways. His mathematical precision informed his astronomical observations, which, in turn, influenced his philosophical musings in poetry. This interplay of disciplines is a hallmark of Khayyam’s genius and underscores his comprehensive approach to knowledge.

Khayyam’s contributions to mathematics and astronomy were groundbreaking, yet he remained humble and dedicated to the pursuit of truth. His ability to bridge different fields of study and his profound insights into the human condition make him a timeless figure in the history of science and literature.

Omar Khayyam was a polymath whose work transcended the boundaries of mathematics, astronomy, and poetry. His solutions to cubic equations and his calendar reform were pioneering achievements that left an indelible mark on the history of science. His poetry, with its philosophical depth and lyrical beauty, continues to inspire readers worldwide.

^{By The original uploader was Atilin at French Wikipedia. — Transferred from fr.wikipedia to Commons by Bloody-libu using CommonsHelper., CC BY-SA 3.0, https://commons.wikimedia.org/w/index.php?curid=16492805}

Khayyam’s legacy is a testament to the power of interdisciplinary thinking and the enduring quest for knowledge. He reminds us that the pursuit of truth through mathematics, astronomy, or poetry is a universal endeavor that transcends time and place.

Until next time, carpe diem! — Gabrielle