Udayadivākara Explained

Udayadivākara (c. 1073 CE) was an Indian astronomer and mathematician who has authored an influential and elaborate commentary, called Sundari, on Laghu-bhāskarīya of Bhāskara I. No personal details about Udayadivākara are known. Since the commentary Sundari takes the year 1073 CE as its epoch, probably the commentary was completed about that year. Sundari has not yet been published and is available only in manuscript form. Some of these manuscripts are preserved in the manuscript depositories in Thiruvananthapuram. According to K. V. Sarma, historian of the astronomy and mathematics of the Kerala school, Udayadivākara probably hailed from Kerala, India.^[1] ^[2]

Historical significance of Sundari

Apart from the fact that Sundari is an elaborate commentary, it has some historical significance. It has quoted extensively from a now lost work by a little known mathematician Jayadeva. The quotations relate to the cakravala method for solving indeterminate integral equations of the form

Nx^2+1=y²

. This shows that the method predates Bhaskara II contrary to generally held beliefs. Another important reference to Jayadeva’s work is the solution of the indeterminate equation of the form

Nx²+C=y²

being positive or negative.^[2]

A problem and its solution

Udayadivākara used his method for solving the equation

Nx²+C=y²

to obtain some particular solutions of a certain algebraic problem. The problem and Udayadivākara's solution to the problem are presented below only to illustrate the techniques used by Indian astronomers for solving algebraic equations.^[2]

Problem

Find positive integers

and

satisfying the following conditions:

\begin{align} x+y&=aprefectsquare,\\ x-y&=aprefectsquare,\\ xy+1&=aprefectsquare. \end{align}

Solution

To solve the problem, Udayadivākara makes a series of apparently arbitrary assumptions all aimed at reducing the problem to one of solving an indeterminate equation of the form

Nx^2+C=y²

Udayadivākara begins by assuming that

xy+1=(2y+1)²

which can be written in the form

x-y=3y+4

. He next assumes that

3y+4=(3z+2)²

which, together with the earlier equation, yields

\begin{align} x&=12z^2+16z+4,\\
y&=3z^2+4z,\\
x+y&=15z^{2+20z+4.
\end{align}}

Now, Udayadivākara puts

15z^2+20z+4=u²

which is then transformed to the equation

(30z+20)²⁼60u^2+160.

This equation is of the form

Nx^2+C=λ²

with

N=60

C=160

and

λ=30z+20

. Using the method for solving the equation

Nx^2+C=y²

, Udayadivākara finds the following solutions

(u=2,λ=20)

(u=18,λ=140)

and

(u=8802,λ=68180)

from which the values of

and

are obtained by back substitution.

Notes and References

Book: K. V. Sarma . A History of the Kerala School of Hindu Astronomy . 1972 . Vishveshvaranand Institute of Sanskrit and Indological Studies, Panjab University, Hoshiarpur . 28 January 2023. 45.
Book: Aditya Kolachana, K. Mahesh and K. Ramasubramanian . Studies in Indian Mathematics and Astronomy Selected Articles of Kripa Shankar Shukla . 2019 . Hindustan Book Agency/Springer . 133-152. (Chapter titled "Ācārya Jayadeva, the mathematician". Originally published in Ganita, Vol. 5, No. 1 (1954), pp. 1–20.)