Jade Mirror of the Four Unknowns

Template:Short description Template:Italic title

Jade Mirror of the Four Unknowns,^[1] Siyuan yujian (Template:Zh), also referred to as Jade Mirror of the Four Origins,^[2] is a 1303 mathematical monograph by Yuan dynasty mathematician Zhu Shijie.^[3] Zhu advanced Chinese algebra with this Magnum opus.

The book consists of an introduction and three books, with a total of 288 problems. The first four problems in the introduction illustrate his method of the four unknowns. He showed how to convert a problem stated verbally into a system of polynomial equations (up to the 14th order), by using up to four unknowns: 天 Heaven, 地 Earth, 人 Man, 物 Matter, and then how to reduce the system to a single polynomial equation in one unknown by successive elimination of unknowns. He then solved the high-order equation by Southern Song dynasty mathematician Qin Jiushao's "Ling long kai fang" method published in Shùshū Jiǔzhāng (“Mathematical Treatise in Nine Sections”) in 1247 (more than 570 years before English mathematician William Horner's method using synthetic division). To do this, he makes use of the Pascal triangle, which he labels as the diagram of an ancient method first discovered by Jia Xian before 1050.

Zhu also solved square and cube roots problems by solving quadratic and cubic equations, and added to the understanding of series and progressions, classifying them according to the coefficients of the Pascal triangle. He also showed how to solve systems of linear equations by reducing the matrix of their coefficients to diagonal form. His methods predate Blaise Pascal, William Horner, and modern matrix methods by many centuries. The preface of the book describes how Zhu travelled around China for 20 years as a teacher of mathematics.

Jade Mirror of the Four Unknowns consists of four books, with 24 classes and 288 problems, in which 232 problems deal with Tian yuan shu, 36 problems deal with variable of two variables, 13 problems of three variables, and 7 problems of four variables.

The four quantities are x, y, z, w can be presented with the following diagram

Template:Counting rodx

yTemplate:Counting rod Template:Counting rod太Template:Counting rodw

Template:Counting rodz

The square of which is:

This section deals with Tian yuan shu or problems of one unknown.

Question: Given the product of huangfan and zhi ji equals to 24 paces, and the sum of vertical and hypotenuse equals to 9 paces, what is the value of the base?

Answer: 3 paces

Set up unitary tian as the base( that is let the base be the unknown quantity x)

Since the product of huangfang and zhi ji = 24

in which

huangfan is defined as：${\displaystyle (a+b-c)}$^[4]

zhi ji：${\displaystyle ab}$

therefore ${\displaystyle (a+b-c)ab=24}$

Further, the sum of vertical and hypotenuse is

${\displaystyle b+c=9}$

Set up the unknown unitary tian as the vertical

${\displaystyle x=a}$

We obtain the following equation

Template:Rod numbers （${\displaystyle x^5-9x^4-81x^3+729x^2=3888}$）

Template:Counting rod 太

Template:Rod numbers

Template:Rod numbers

Template:Counting rod

Template:Counting rod

Solve it and obtain x=3

Template:Rod numbers太 Unitary

Template:Rod numbers

Template:Rod numbers

Template:Rod numbers

equation: ${\displaystyle -2y^2-x{y}^2+2xy+2x^{2}y+x^3=0}$;

from the given

Template:Rod numbers太

Template:Rod numbers

Template:Rod numbers

Template:Rod numbers

equation: ${\displaystyle 2y^2-x{y}^2+2xy+x^3=0}$;

we get:

太

Template:Counting rod

Template:Counting rod

${\displaystyle 8x+4x^2=0}$

and

太

Template:Counting rod

Template:Counting rod

Template:Counting rod

${\displaystyle 2x^2+x^3=0}$

by method of elimination, we obtain a quadratic equation

Template:Counting rod

Template:Counting rod

Template:Counting rod

${\displaystyle x^2-2x-8=0}$

solution: ${\displaystyle x=4}$.

Template for solution of problem of three unknowns

Zhu Shijie explained the method of elimination in detail. His example has been quoted frequently in scientific literature.^[5][6][7]

Set up three equations as follows

Template:Counting rod太Template:Counting rod

Template:Counting rod

Template:Rod numbers

${\displaystyle -y-z-y^{2}x-x+xyz=0}$ .... I

Template:Rod numbers

Template:Counting rod

Template:Counting rod

${\displaystyle -y-z+x-x^2+xz=0}$.....II

Template:Rod numbers太Template:Rod numbers

Template:Counting rod

Template:Counting rod

${\displaystyle y^2-z^2+x^2=0;}$....III

Elimination of unknown between II and III

by manipulation of exchange of variables

We obtain

Template:Counting rod Template:Rod numbers太

Template:Rod numbers

Template:Rod numbers

${\displaystyle -x-2x^2+y+y^2+xy-x{y}^2+x^{2}y}$ ...IV

and

Template:Rod numbers太

Template:Rod numbers

Template:Rod numbers

${\displaystyle -2x-2x^2+2y-2y^2+y^3+4xy-2x{y}^2+x{y}^2}$.... V

Elimination of unknown between IV and V we obtain a 3rd order equation

${\displaystyle x^4-6x^3+4x^2+6x-5=0}$

Template:Counting rod

Template:Counting rod

Template:Counting rod

Template:Counting rod

Template:Counting rod

Solve to this 3rd order equation to obtain ${\displaystyle x=5}$;

Change back the variables

We obtain the hypothenus =5 paces

This section deals with simultaneous equations of four unknowns.

${\displaystyle \{\begin{array}{c}-2y+x+z=0\\ -y^{2}x+4y+2x-x^2+4z+xz=0\\ x^2+y^2-z^2=0\\ 2y-w+2x=0\end{array}}$

Successive elimination of unknowns to get

Template:Rod numbers ${\displaystyle 4x^2-7x-686=0}$

Template:Counting rod

Template:Counting rod

Solve this and obtain 14 paces

There are 18 problems in this section.

Problem 18

Obtain a tenth order polynomial equation:

${\displaystyle 16x^{10}-64x^9+160x^8-384x^7+512x^6-544x^5+456x^4+126x^3+3x^2-4x-177162=0}$

The root of which is x = 3, multiply by 4, getting 12. That is the final answer.

There are 18 problems in this section

There are 9 problems in this section

There are 6 problems in this section

There are 7 problems in this section

There are 13 problems in this section

There are eight problems in this section

Problem 1

Template:Blockquote

Let tian yuan unitary as half of the length, we obtain a 4th order equation

${\displaystyle x^4+480x^3-270000x^2+15552000x+1866240000=0}$^[8]

solve it and obtain Template:Mvar=240 paces, hence length =2x= 480 paces=1 li and 120 paces.

Similarity, let tian yuan unitary(x) equals to half of width

we get the equation:

${\displaystyle x^4+360x^3-270000x^2+20736000x+1866240000=0}$^[9]

Solve it to obtain Template:Mvar=180 paces, length =360 paces =one li.

Problem 7

Identical to The depth of a ravine (using hence-forward cross-bars) in Haidao Suanjing.

Problem 8

Identical to The depth of a transparent pool in Haidao Suanjing.

Problem No 5 is the earliest 4th order interpolation formula in the world

men summoned :${\displaystyle na+\frac{1}{2!}n(n-1)b+\frac{1}{3!}n(n-1)(n-2)c+\frac{1}{4!}n(n-1)(n-2)(n-3)d}$^[10]

In which

• Template:Mvar=1st order difference
• Template:Mvar=2nd order difference
• Template:Mvar=3rd order difference
• Template:Mvar=4th order difference

This section contains 20 problems dealing with triangular piles, rectangular piles

Problem 1

Find the sum of triangular pile

${\displaystyle 1+3+6+10+...+\frac{1}{2}n(n+1)}$

and value of the fruit pile is:

${\displaystyle v=2+9+24+50+90+147+224+\cdots +\frac{1}{2}n(n+1{)}^2}$

Zhu Shijie use Tian yuan shu to solve this problem by letting x=n

and obtained the formular

${\displaystyle v=\frac{1}{2\cdot 3\cdot 4}(3x+5)x(x+1)(x+2)}$

From given condition ${\displaystyle v=1320}$, hence

${\displaystyle 3x^4+14x^3+21x^2+10x-31680=0}$^[11]

Solve it to obtain ${\displaystyle x=n=9}$.

Therefore,

${\displaystyle v=2+9+24+50+90+147+224+324+450=1320}$。

Six problems of four unknowns.

Question 2

Yield a set of equations in four unknowns: .^[12]

${\displaystyle \{\begin{array}{c}-3y^2+8y-8x+8z=0\\ 4y^2-8xy+3x^2-8yz+6xz+3z^2=0\\ y^2+x^2-z^2=0\\ 2y+4x+2z-w=0\end{array}}$

Template:Reflist Sources Template:Refbegin

• Jade Mirror of the Four Unknowns, tr. into English by Professor Chen Zhaixin, Former Head of Mathematics Department, Yenching University (in 1925), Translated into modern Chinese by Guo Shuchun, Volume I & II, Library of Chinese Classics, Chinese-English, Liaoning Education Press 2006 Template:Isbn https://www.scribd.com/document/357204551/Siyuan-yujian-2, https://www.scribd.com/document/357204728/Siyuan-yujian-1
• Collected Works in the History of Sciences by Li Yan and Qian Baocong, Volume 1 《李俨钱宝琮科学史全集》 第一卷 钱宝琮 《中国算学史 上编》
• Zhu Shijie Siyuan yujian Book 1–4, Annotated by Qin Dynasty mathematician Luo Shilin, Commercial Press
• J. Hoe, Les systèmes d'équations polynômes dans le Siyuan yujian (1303), Institut des Hautes Études Chinoises, Paris, 1977
• J. Hoe, A study of the fourteenth-century manual on polynomial equations "The jade mirror of the four unknowns" by Zhu Shijie, Mingming Bookroom, P.O. Box 29-316, Christchurch, New Zealand, 2007

Template:Refend