線性代數（來源於英文維基教科書）[編輯]

Linear Algebra 線性代數

An Introduction to Mathematical Discourse 數學話語導論

The book was designed specifically for students who had not previously been exposed to mathematics as mathematicians view it. That is, as a subject whose goal is to rigorously prove theorems starting from clear consistent definitions. This book attempts to build students up from a background where mathematics is simply a tool that provides useful calculations to the point where the students have a grasp of the clear and precise nature of mathematics. A more detailed discussion of the prerequisites and goal of this book is given in the introduction.
這本書是專門為那些以前沒有接觸過數學的學生設計的，因為他們是數學家。也就是說，作為一個目標是從清晰一致的定義開始嚴格證明定理的學科。這本書試圖建立學生從一個背景，數學只是一個工具，提供有用的計算點，學生有一個清晰和精確的數學性質的掌握。引言中對本書的先決條件和目標進行了更詳細的討論。

Table of Contents[編輯]

Template:Algebra

Linear Systems[編輯]

Vector Spaces （Apr 17, 2009）[編輯]

Maps Between Spaces[編輯]

Determinants（Jun 21, 2009）[編輯]

Similarity（Jun 24, 2009）[編輯]

Unitary Transformations[編輯]

Appendix[編輯]

封面[編輯]

符號說明[編輯]

$\mathbb {R}$ , $\mathbb {R} ^{+}$ , $\mathbb {R} ^{n}$	real numbers, reals greater than $0$ , ordered $n$ -tuples of reals
$\mathbb {N}$	natural numbers: $\{0,1,2,\ldots \}$
$\mathbb {C}$	complex numbers
$\{\ldots \,{\big \|}\,\ldots \}$	set of . . . such that . . .
$(a\,..\,b)$ , $[a\,..\,b]$	interval (open or closed) of reals between $a$ and $b$
$\langle \ldots \rangle$	sequence; like a set but order matters
$V,W,U$	vector spaces
${\vec {v}},{\vec {w}}$	vectors
${\vec {0}}$ , ${\vec {0}}_{V}$	zero vector, zero vector of $V$
$B,D$	bases
${\mathcal {E}}_{n}=\langle {\vec {e}}_{1},\,\ldots ,\,{\vec {e}}_{n}\rangle$	standard basis for $\mathbb {R} ^{n}$
${\vec {\beta }},{\vec {\delta }}$	basis vectors
${\rm {Rep}}_{B}({\vec {v}})$	matrix representing the vector
${\mathcal {P}}_{n}$	set of $n$ -th degree polynomials
${\mathcal {M}}_{n\!\times \!m}$	set of $n\!\times \!m$ matrices
$[S]$	span of the set $S$
$M\oplus N$	direct sum of subspaces
$V\cong W$	isomorphic spaces
$h,g$	homomorphisms, linear maps
$H,G$	matrices
$t,s$	transformations; maps from a space to itself
$T,S$	square matrices
${\rm {Rep}}_{B,D}(h)$	matrix representing the map $h$
$h_{i,j}$	matrix entry from row $i$ , column $j$
$\left\|T\right\|$	determinant of the matrix $T$ 矩陣 $T$ 的行列式
${\mathcal {R}}(h),{\mathcal {N}}(h)$	rangespace and nullspace of the map $h$
${\mathcal {R}}_{\infty }(h),{\mathcal {N}}_{\infty }(h)$	generalized rangespace and nullspace

Lower case Greek alphabet
小寫希臘字母[編輯]

${\begin{array}{ll|ll|ll}{\text{name}}&{\text{character}}&{\text{name}}&{\text{character}}&{\text{name}}&{\text{character}}\\\hline {\text{alpha}}&\alpha &{\text{iota}}&\iota &{\text{rho}}&\rho \\{\text{beta}}&\beta &{\text{kappa}}&\kappa &{\text{sigma}}&\sigma \\{\text{gamma}}&\gamma &{\text{lambda}}&\lambda &{\text{tau}}&\tau \\{\text{delta}}&\delta &{\text{mu}}&\mu &{\text{upsilon}}&\upsilon \\{\text{epsilon}}&\epsilon &{\text{nu}}&\nu &{\text{phi}}&\phi \\{\text{zeta}}&\zeta &{\text{xi}}&\xi &{\text{chi}}&\chi \\{\text{eta}}&\eta &{\text{omicron}}&o&{\text{psi}}&\psi \\{\text{theta}}&\theta &{\text{pi}}&\pi &{\text{omega}}&\omega \end{array}}$

About the Cover. This is Cramer's Rule for the system $x_{1}+2x_{2}=6$ , $3x_{1}+x_{2}=8$ . The size of the first box is the determinant shown (the absolute value of the size is the area). The size of the second box is $x_{1}$ times that, and equals the size of the final box. Hence, $x_{1}$ is the final determinant divided by the first determinant.

介紹[編輯]

This book helps students to master the material of a standard undergraduate linear algebra course.

這本書幫助學生掌握標準的本科線性代數課程的材料。

The material is standard in that the topics covered are Gaussian reduction, vector spaces, linear maps, determinants, and eigenvalues and eigenvectors. The audience is also standard: sophomores or juniors, usually with a background of at least one semester of calculus and perhaps with as much as three semesters.

材料是標準的，因為涵蓋的主題是高斯約化，向量空間，線性映射，行列式，特徵值和特徵向量。聽眾也是標準的：大二或大三，通常至少有一個學期的微積分背景，也許有三個學期的時間。

The help that it gives to students comes from taking a developmental approach—this book's presentation emphasizes motivation and naturalness, driven home by a wide variety of examples and extensive, careful, exercises. The developmental approach is what sets this book apart, so some expansion of the term is appropriate here.

它給學生的幫助來自於採取一種發展的方法這本書的介紹強調動機和自然性，由各種各樣的例子和廣泛的，仔細的，練習。發展的方法使這本書與眾不同，所以在這裡對這個術語進行一些擴展是合適的。

Courses in the beginning of most mathematics programs reward students less for understanding the theory and more for correctly applying formulas and algorithms. Later courses ask for mathematical maturity: the ability to follow different types of arguments, a familiarity with the themes that underlay many mathematical investigations like elementary set and function facts, and a capacity for some independent reading and thinking. Linear algebra is an ideal spot to work on the transition between the two kinds of courses. It comes early in a program so that progress made here pays off later, but also comes late enough that students are often majors and minors. The material is coherent, accessible, and elegant. There are a variety of argument styles—proofs by contradiction, if and only if statements, and proofs by induction, for instance—and examples are plentiful.

大多數數學課程開始時的課程對學生的獎勵較少，因為他們理解了理論，而更多的是因為他們正確地應用了公式和算法。以後的課程要求數學成熟：能夠理解不同類型的論據，熟悉許多數學研究的主題，如基本集合和函數事實，以及獨立閱讀和思考的能力。線性代數是研究這兩種課程之間過渡的理想場所。它在一個項目中出現得早，這樣在這裡取得的進步會得到回報，但也會來得太晚，以至於學生通常都是主修生和未成年學生。材料連貫，通俗易懂，優雅大方。用矛盾證明、當且僅當語句證明、歸納證明等多種論證方式，如實例和實例豐富。

So, the aim of this book's exposition is to help students develop from being successful at their present level, in classes where a majority of the members are interested mainly in applications in science or engineering, to being successful at the next level, that of serious students of the subject of mathematics itself.

因此，這本書的目的是幫助學生從目前的水平，在大多數成員主要對科學或工程應用感興趣的課程中取得成功，發展到下一階段的成功，即數學學科本身的嚴肅學生。

Helping students make this transition means taking the mathematics seriously, so all of the results in this book are proved. On the other hand, we cannot assume that students have already arrived, and so in contrast with more abstract texts, we give many examples and they are often quite detailed.

幫助學生完成這一轉變意味着要認真對待數學，因此本書中的所有結果都得到了證明。另一方面，我們不能假設學生已經到了，因此與更抽象的文本相比，我們給出了許多例子，而且往往非常詳細。

In the past, linear algebra texts commonly made this transition abruptly. They began with extensive computations of linear systems, matrix multiplications, and determinants. When the concepts—vector spaces and linear maps—finally appeared, and definitions and proofs started, often the change brought students to a stop. In this book, while we start with a computational topic, linear reduction, from the first we do more than compute. We do linear systems quickly but completely, including the proofs needed to justify what we are computing. Then, with the linear systems work as motivation and at a point where the study of linear combinations seems natural, the second chapter starts with the definition of a real vector space. This occurs by the end of the third week.

在過去，線性代數文本通常會突然進行這種轉換。他們開始廣泛計算線性系統，矩陣乘法和行列式。當概念向量空間和線性映射最終出現，定義和證明開始時，這種變化常常使學生停止。在這本書中，我們從一個計算主題開始，線性化簡，從一開始我們做的不僅僅是計算。我們快速但完整地處理線性系統，包括證明我們正在計算的東西。然後，以線性系統為動力，在研究線性組合似乎很自然的地方，第二章從實向量空間的定義開始。這將在第三周結束時發生。

Another example of our emphasis on motivation and naturalness is that the third chapter on linear maps does not begin with the definition of homomorphism, but with that of isomorphism. That's because this definition is easily motivated by the observation that some spaces are "just like" others. After that, the next section takes the reasonable step of defining homomorphism by isolating the operation-preservation idea. This approach loses mathematical slickness, but it is a good trade because it comes in return for a large gain in sensibility to students.

我們強調動機和自然性的另一個例子是，關於線性映射的第三章沒有從同態的定義開始，而是從同構的定義開始。這是因為這個定義很容易被一些空間「和」其他空間「一樣」的觀察所激發。然後，下一節通過隔離操作保持的思想，採取合理的步驟來定義同態。這種方法失去了數學上的圓滑，但它是一種很好的交易，因為它可以讓學生在情感上得到很大的提高。

One aim of a developmental approach is that students should feel throughout the presentation that they can see how the ideas arise, and perhaps picture themselves doing the same type of work.

發展性教學法的一個目的是讓學生在整個演示過程中感覺到他們可以看到想法是如何產生的，也許還能想象自己在做同樣類型的工作。

The clearest example of the developmental approach taken here—and the feature that most recommends this book—is the exercises. A student progresses most while doing the exercises, so they have been selected with great care. Each problem set ranges from simple checks to reasonably involved proofs. Since an instructor usually assigns about a dozen exercises after each lecture, each section ends with about twice that many, thereby providing a selection. There are even a few problems that are challenging puzzles taken from various journals, competitions, or problems collections. (These are marked with a "?" and as part of the fun, the original wording has been retained as much as possible.) In total, the exercises are aimed to both build an ability at, and help students experience the pleasure of, doing mathematics.

最清楚的例子，在這裡採取的發展方法和特點，最推薦這本書是練習。學生在做練習時進步最大，所以他們是經過精心挑選的。每個習題集的範圍從簡單的檢查到合理涉及的證明。由於教師通常在每堂課後布置十幾個練習題，所以每節課結束時的練習數是原來的兩倍，因此提供了一個選擇題。甚至有一些問題是挑戰性的難題從各種雜誌，比賽，或問題收集。（這些標記有「？」總的來說，這些練習的目的是培養學生學習數學的能力，並幫助他們體驗數學的樂趣。

Applications and Computers
應用程序和計算機[編輯]

The point of view taken here, that linear algebra is about vector spaces and linear maps, is not taken to the complete exclusion of others. Applications and the role of the computer are important and vital aspects of the subject. Consequently, each of this book's chapters closes with a few application or computer-related topics. Some are: network flows, the speed and accuracy of computer linear reductions, Leontief Input/Output analysis, dimensional analysis, Markov chains, voting paradoxes, analytic projective geometry, and difference equations.

這裡所採取的觀點，即線性代數是關於向量空間和線性映射的，並不完全排除其他的觀點。計算機的應用和作用是這門學科重要而重要的方面。因此，本書的每一章都以一些應用或計算機相關的主題結束。其中包括：網絡流、計算機線性化簡的速度和精度、Leontief輸入/輸出分析、量綱分析、馬爾可夫鏈、投票悖論、解析射影幾何和差分方程。

These topics are brief enough to be done in a day's class or to be given as independent projects for individuals or small groups. Most simply give the reader a taste of the subject, discuss how linear algebra comes in, point to some further reading, and give a few exercises. In short, these topics invite readers to see for themselves that linear algebra is a tool that a professional must have.

這些主題足夠簡短，可以在一天的課堂上完成，也可以作為個人或小組的獨立項目。最簡單的是讓讀者領略一下這個主題，討論一下線性代數是如何產生的，指出一些進一步的閱讀，並給出一些練習。簡言之，這些主題邀請讀者親眼看到，線性代數是一個專業人士必須具備的工具。

For people reading this book on their own
對於自學這本書的人[編輯]

This book's emphasis on motivation and development make it a good choice for self-study. But, while a professional instructor can judge what pace and topics suit a class, if you are an independent student then perhaps you would find some advice helpful.

這本書對動機和發展的強調使它成為自學的好選擇。但是，雖然專業的教師可以判斷什麼樣的節奏和主題適合一節課，但如果你是一名獨立學生，那麼也許你會發現一些建議是有用的。

Here are two timetables for a semester. The first focuses on core material.

這是一個學期的兩個時間表。第一個重點是核心材料。

week 星期	Monday 禮拜一	Wednesday 禮拜三	Friday 禮拜五
1	One.I.1	One.I.1, 2	One.I.2, 3
2	One.I.3	One.II.1	One.II.2
3	One.III.1, 2	One.III.2	Two.I.1
4	Two.I.2	Two.II	Two.III.1
5	Two.III.1, 2	Two.III.2	Exam
6	Two.III.2, 3	Two.III.3	Three.I.1
7	Three.I.2	Three.II.1	Three.II.2
8	Three.II.2	Three.II.2	Three.III.1
9	Three.III.1	Three.III.2	Three.IV.1, 2
10	Three.IV.2, 3, 4	Three.IV.4	Exam
11	Three.IV.4, Three.V.1	Three.V.1, 2	Four.I.1, 2
12	Four.I.3	Four.II	Four.II
13	Four.III.1	Five.I	Five.II.1
14	Five.II.2	Five.II.3	Review

The second timetable is more ambitious (it supposes that you know One.II, the elements of vectors, usually covered in third semester calculus).

第二個時間表更具雄心（它假設你知道一、二，向量的元素，通常在第三學期微積分中討論）。

week 星期	Monday 禮拜一	Wednesday 禮拜三	Friday 禮拜五
1	One.I.1	One.I.2	One.I.3
2	One.I.3	One.III.1, 2	One.III.2
3	Two.I.1	Two.I.2	Two.II
4	Two.III.1	Two.III.2	Two.III.3
5	Two.III.4	Three.I.1	Exam
6	Three.I.2	Three.II.1	Three.II.2
7	Three.III.1	Three.III.2	Three.IV.1, 2
8	Three.IV.2	Three.IV.3	Three.IV.4
9	Three.V.1	Three.V.2	Three.VI.1
10	Three.VI.2	Four.I.1	Exam
11	Four.I.2	Four.I.3	Four.I.4
12	Four.II	Four.II, Four.III.1	Four.III.2, 3
13	Five.II.1, 2	Five.II.3	Five.III.1
14	Five.III.2	Five.IV.1, 2	Five.IV.2

See the table of contents for the titles of these subsections.

這些小節的標題見目錄。

To help you make time trade-offs, in the table of contents I have marked subsections as optional if some instructors will pass over them in favor of spending more time elsewhere. You might also try picking one or two topics that appeal to you from the end of each chapter. You'll get more from these if you have access to computer software that can do the big calculations.

為了幫助您進行時間權衡，在目錄中，我將子部分標記為可選的，如果有些講師會跳過它們，而將更多的時間花在其他地方。你也可以試着從每一章的結尾選一兩個吸引你的話題。如果你能使用計算機軟件進行大計算，你會從中得到更多。

The most important advice is: do many exercises. The recommended exercises are labeled throughout. (The answers are available.) You should be aware, however, that few inexperienced people can write correct proofs. Try to find a knowledgeable person to work with you on this.

最重要的建議是：多做練習。推薦的練習貫穿始終。（答案是有的）但是你應該知道，沒有經驗的人很少能寫出正確的證明。試着找一個有見識的人和你一起工作。

Finally, if I may, a caution for all students, independent or not: I cannot overemphasize how much the statement that I sometimes hear, "I understand the material, but it's only that I have trouble with the problems" reveals a lack of understanding of what we are up to. Being able to do things with the ideas is their point. The quotes below express this sentiment admirably. They state what I believe is the key to both the beauty and the power of mathematics and the sciences in general, and of linear algebra in particular (I took the liberty of formatting them as poems).

最後，如果可以的話，我要提醒所有的學生，不管他們是否獨立：我不能過分強調我有時聽到的「我理解材料，但只是我對問題有困難」這句話多少暴露了我們對我們正在做的事情缺乏了解。能夠用這些想法做事是他們的重點。下面的引文很好地表達了這種觀點。它們陳述了我認為是數學和科學的美和力量的關鍵，尤其是線性代數（我冒昧地將它們格式化為詩歌）。

I know of no better tactic

than the illustration of exciting principles
by well-chosen particulars.
--Stephen Jay Gould
我知道沒有比這更好的策略了
而不是那些令人興奮的原則
通過精心挑選的細節。
--史蒂芬·傑伊·古爾德

If you really wish to learn

then you must mount the machine
and become acquainted with its tricks
by actual trial.
--Wilbur Wright
如果你真的想學
那你就得裝上機器
熟悉它的技巧
通過實際試驗。
--威爾伯·賴特

Jim Hefferon
Mathematics, Saint Michael's College
Colchester, Vermont USA 05439
http://joshua.smcvt.edu
2006-May-20

吉姆·赫弗倫聖米歇爾學院數學系美國佛蒙特州科爾切斯特市，郵編：05439

2006年5月20日

Author's Note. Inventing a good exercise, one that enlightens as well as tests, is a creative act, and hard work.

作者的筆記。創造一個好的練習，一個啟發和測試，是一個創造性的行為，努力工作。

The inventor deserves recognition. But for some reason texts have traditionally not given attributions for questions. I have changed that here where I was sure of the source. I would greatly appreciate hearing from anyone who can help me to correctly attribute others of the questions.

這位發明家值得肯定。但由於某些原因，文本傳統上沒有給出問題的歸屬。我已經改變了這裡我確定來源的地方。如果有人能幫助我正確回答其他問題，我將不勝感激。

第一章 Linear Systems/線性系統[編輯]

第一節[編輯]

Systems of linear equations are common in science and mathematics. These two examples from high school science (O'Nan 1990) give a sense of how they arise.
線性方程組在科學和數學中很常見。這兩個來自《高中科學》（奧南1990）的例子讓我們了解了它們是如何產生的。

The first example is from Physics. Suppose that we are given three objects, one with a mass known to be 2 kg, and are asked to find the unknown masses. Suppose further that experimentation with a meter stick produces these two balances.
第一個例子來自物理學。假設我們得到三個物體，一個質量已知為2公斤，被要求找出未知質量。進一步假設，使用儀表棒進行試驗可以產生這兩種平衡。

Since the sum of magnitudes of the torques of the clockwise forces equal those of the counter clockwise forces (the torque of an object rotating about a fixed origin is the cross product of the force on it and its position vector relative to the origin; gravitational acceleration is uniform we can divide both sides by it). The two balances give this system of two equations.
由於順時針力的力矩大小之和等於逆時針力的大小（繞固定原點旋轉的物體的力矩是其上的力與其相對於原點的位置矢量的叉積；重力加速度是均勻的，我們可以用它來劃分兩邊）。這兩個天平給出了這個由兩個方程組成的系統。

{\begin{cases}{\begin{array}{rl}40h+15c&=100\\25c&=50+50h\end{array}}\end{cases}}

The second example of a linear system is from Chemistry. We can mix, under controlled conditions, toluene ${\hbox{C}}_{7}{\hbox{H}}_{8}$ and nitric acid ${\hbox{H}}{\hbox{N}}{\hbox{O}}_{3}$ to produce trinitrotoluene ${\hbox{C}}_{7}{\hbox{H}}_{5}{\hbox{O}}_{6}{\hbox{N}}_{3}$ along with the byproduct water (conditions have to be controlled very well, indeed— trinitrotoluene is better known as TNT). In what proportion should those components be mixed? The number of atoms of each element present before the reaction

線性系統的第二個例子來自化學。我們可以在受控制的情況下混合甲苯（C₇H₈）和硝酸（HNO₃）的生產條件三硝基甲苯（C₇H₅O₆N₃）及其副產水（條件必須控制得很好，實際上，三硝基甲苯被稱為TNT）。這些成分應該按多大比例混合？每種元素在反應前存在的原子數

x\,{\rm {C}}_{7}{\rm {H}}_{8}\ +\ y\,{\rm {H}}{\rm {N}}{\rm {O}}_{3}\quad \longrightarrow \quad z\,{\rm {C}}_{7}{\rm {H}}_{5}{\rm {O}}_{6}{\rm {N}}_{3}\ +\ w\,{\rm {H}}_{2}{\rm {O}}

must equal the number present afterward. Applying that principle to the elements C, H, N, and O in turn gives this system.

一定與反應後存在的原子數相等。根據這個反應中的C、H、N和O元素的守恆。

{\begin{cases}{\begin{array}{rl}7x&=7z\\8x+1y&=5z+2w\\1y&=3z\\3y&=6z+1w\end{array}}\end{cases}}

{\rm {C}}_{7}{\rm {H}}_{8}\ +\

{\rm {H}}{\rm {N}}{\rm {O}}_{3}\quad \longrightarrow \quad

{\rm {C}}_{7}{\rm {H}}_{5}{\rm {O}}_{6}{\rm {N}}_{3}\ +\

{\rm {H}}_{2}{\rm {O}}

To finish each of these examples requires solving a system of equations. In each, the equations involve only the first power of the variables. This chapter shows how to solve any such system.

要完成這些例子中的每一個都需要解一個方程組。在每一個方程中，方程只涉及變量的一次方。本章介紹如何解決任何此類系統。

References[編輯]

O'Nan, Micheal (1990), Linear Algebra (3rd ed.), Harcourt College Pub .

§ 1.1 Gauss' Method 高斯消元法[編輯]

Definition 1.1

A linear equation in variables $x_{1},x_{2},\ldots ,x_{n}$ has the form

未知數 $x_{1},x_{2},\ldots ,x_{n}$ 的一個線性方程組，形如

a_{1}x_{1}+a_{2}x_{2}+a_{3}x_{3}+\cdots +a_{n}x_{n}=d

where the numbers $a_{1},\dots ,a_{n}\in \mathbb {R}$ are the equation's coefficients and $d\in \mathbb {R}$ is the constant. An $n$ -tuple $(s_{1},s_{2},\dots ,s_{n})\in \mathbb {R} ^{n}$ is a solution of, or satisfies, that equation if substituting the numbers $s_{1},\dots ,s_{n}$ for the variables gives a true statement: $a_{1}s_{1}+a_{2}s_{2}+\ldots +a_{n}s_{n}=d$ .

其中 $a_{1},\dots ,a_{n}\in \mathbb {R}$ 是方程的係數， $d\in \mathbb {R}$ 是一個常數項。當一個 $n$ 元數組 $(s_{1},s_{2},\dots ,s_{n})\in \mathbb {R} ^{n}$ 滿足： $a_{1}s_{1}+a_{2}s_{2}+\ldots +a_{n}s_{n}=d$ 成立那麼我們稱這個數組為為方程的一個解。

A system of linear equations

一個線性方程組

{\begin{array}{*{4}{rc}r}a_{1,1}x_{1}&+&a_{1,2}x_{2}&+&\cdots &+&a_{1,n}x_{n}&=&d_{1}\\a_{2,1}x_{1}&+&a_{2,2}x_{2}&+&\cdots &+&a_{2,n}x_{n}&=&d_{2}\\&&&&&&&\vdots \\a_{m,1}x_{1}&+&a_{m,2}x_{2}&+&\cdots &+&a_{m,n}x_{n}&=&d_{m}\end{array}}

has the solution $(s_{1},s_{2},\ldots ,s_{n})$ if that $n$ -tuple is a solution of all of the equations in the system.

當有一個 $n$ 元數組 $(s_{1},s_{2},\dots ,s_{n})\in \mathbb {R} ^{n}$ ，是方程組中每一個方程的解，那麼我們稱這個 $n$ 元數組為方程組的解。

Example 1.2

The ordered pair $(-1,5)$ is a solution of this system.

{\begin{array}{*{2}{rc}r}4x_{1}&+&2x_{2}&=&6\\-x_{1}&+&x_{2}&=&6\end{array}}

In contrast, $(5,-1)$ is not a solution.

Finding the set of all solutions is solving the system. No guesswork or good fortune is needed to solve a linear system. There is an algorithm that always works. The next example introduces that algorithm, called Gauss' method. It transforms the system, step by step, into one with a form that is easily solved.

Example 1.3

To solve this system

{\begin{array}{*{3}{rc}r}&&&&3x_{3}&=&9\\x_{1}&+&5x_{2}&-&2x_{3}&=&2\\{\frac {1}{3}}x_{1}&+&2x_{2}&&&=&3\end{array}}

we repeatedly transform it until it is in a form that is easy to solve.

{\begin{array}{rcl}\quad &{\xrightarrow[{}]{\text{swap row 1 with row 3}}}&{\begin{array}{*{3}{rc}r}{\frac {1}{3}}x_{1}&+&2x_{2}&&&=&3\\x_{1}&+&5x_{2}&-&2x_{3}&=&2\\&&&&3x_{3}&=&9\end{array}}\\&{\xrightarrow[{}]{\text{multiply row 1 by 3}}}&{\begin{array}{*{3}{rc}r}x_{1}&+&6x_{2}&&&=&9\\x_{1}&+&5x_{2}&-&2x_{3}&=&2\\&&&&3x_{3}&=&9\end{array}}\\&{\xrightarrow[{}]{{\text{add }}-1{\text{ times row 1 to row 2}}}}&{\begin{array}{*{3}{rc}r}x_{1}&+&6x_{2}&&&=&9\\&&-x_{2}&-&2x_{3}&=&-7\\&&&&3x_{3}&=&9\end{array}}\end{array}}

The third step is the only nontrivial one. We've mentally multiplied both sides of the first row by $-1$ , mentally added that to the old second row, and written the result in as the new second row.

Now we can find the value of each variable. The bottom equation shows that $x_{3}=3$ . Substituting $3$ for $x_{3}$ in the middle equation shows that $x_{2}=1$ . Substituting those two into the top equation gives that $x_{1}=3$ and so the system has a unique solution: the solution set is $\{\,(3,1,3)\,\}$ .

Most of this subsection and the next one consists of examples of solving linear systems by Gauss' method. We will use it throughout this book. It is fast and easy. But, before we get to those examples, we will first show that this method is also safe in that it never loses solutions or picks up extraneous solutions.

Theorem 1.4 (Gauss' method)

If a linear system is changed to another by one of these operations

an equation is swapped with another
an equation has both sides multiplied by a nonzero constant
an equation is replaced by the sum of itself and a multiple of another

then the two systems have the same set of solutions.

Each of those three operations has a restriction. Multiplying a row by $0$ is not allowed because obviously that can change the solution set of the system. Similarly, adding a multiple of a row to itself is not allowed because adding $-1$ times the row to itself has the effect of multiplying the row by $0$ . Finally, swapping a row with itself is disallowed to make some results in the fourth chapter easier to state and remember (and besides, self-swapping doesn't accomplish anything).

Proof

We will cover the equation swap operation here and save the other two cases for Problem 14.

Consider this swap of row $i$ with row $j$ .

{\begin{array}{*{4}{rc}r}a_{1,1}x_{1}&+&a_{1,2}x_{2}&+&\cdots &&a_{1,n}x_{n}&=&d_{1}\\&&&&&&&\vdots \\a_{i,1}x_{1}&+&a_{i,2}x_{2}&+&\cdots &&a_{i,n}x_{n}&=&d_{i}\\&&&&&&&\vdots \\a_{j,1}x_{1}&+&a_{j,2}x_{2}&+&\cdots &&a_{j,n}x_{n}&=&d_{j}\\&&&&&&&\vdots \\a_{m,1}x_{1}&+&a_{m,2}x_{2}&+&\cdots &&a_{m,n}x_{n}&=&d_{m}\end{array}}{\xrightarrow[{}]{}}{\begin{array}{*{4}{rc}r}a_{1,1}x_{1}&+&a_{1,2}x_{2}&+&\cdots &&a_{1,n}x_{n}&=&d_{1}\\&&&&&&&\vdots \\a_{j,1}x_{1}&+&a_{j,2}x_{2}&+&\cdots &&a_{j,n}x_{n}&=&d_{j}\\&&&&&&&\vdots \\a_{i,1}x_{1}&+&a_{i,2}x_{2}&+&\cdots &&a_{i,n}x_{n}&=&d_{i}\\&&&&&&&\vdots \\a_{m,1}x_{1}&+&a_{m,2}x_{2}&+&\cdots &&a_{m,n}x_{n}&=&d_{m}\end{array}}

The $n$ -tuple $(s_{1},\ldots ,s_{n})$ satisfies the system before the swap if and only if substituting the values, the $s$ 's, for the variables, the $x$ 's, gives true statements: $a_{1,1}s_{1}+a_{1,2}s_{2}+\cdots +a_{1,n}s_{n}=d_{1}$ and ... $a_{i,1}s_{1}+a_{i,2}s_{2}+\cdots +a_{i,n}s_{n}=d_{i}$ and ... $a_{j,1}s_{1}+a_{j,2}s_{2}+\cdots +a_{j,n}s_{n}=d_{j}$ and ... $a_{m,1}s_{1}+a_{m,2}s_{2}+\cdots +a_{m,n}s_{n}=d_{m}$ .

In a requirement consisting of statements and-ed together we can rearrange the order of the statements, so that this requirement is met if and only if $a_{1,1}s_{1}+a_{1,2}s_{2}+\cdots +a_{1,n}s_{n}=d_{1}$ and ... $a_{j,1}s_{1}+a_{j,2}s_{2}+\cdots +a_{j,n}s_{n}=d_{j}$ and ... $a_{i,1}s_{1}+a_{i,2}s_{2}+\cdots +a_{i,n}s_{n}=d_{i}$ and ... $a_{m,1}s_{1}+a_{m,2}s_{2}+\cdots +a_{m,n}s_{n}=d_{m}$ . This is exactly the requirement that $(s_{1},\ldots ,s_{n})$ solves the system after the row swap.

Definition 1.5

The three operations from Theorem 1.4 are the elementary reduction operations, or row operations, or Gaussian operations. They are swapping, multiplying by a scalar or rescaling, and pivoting.

When writing out the calculations, we will abbreviate "row $i$ " by " $\rho _{i}$ ". For instance, we will denote a pivot operation by $k\rho _{i}+\rho _{j}$ , with the row that is changed written second. We will also, to save writing, often list pivot steps together when they use the same $\rho _{i}$ .

Example 1.6

A typical use of Gauss' method is to solve this system.

{\begin{array}{*{3}{rc}r}x&+&y&&&=&0\\2x&-&y&+&3z&=&3\\x&-&2y&-&z&=&3\end{array}}

The first transformation of the system involves using the first row to eliminate the $x$ in the second row and the $x$ in the third. To get rid of the second row's $2x$ , we multiply the entire first row by $-2$ , add that to the second row, and write the result in as the new second row. To get rid of the third row's $x$ , we multiply the first row by $-1$ , add that to the third row, and write the result in as the new third row.

{\begin{array}{rcl}&{\xrightarrow[{-\rho _{1}+\rho _{3}}]{-2\rho _{1}+\rho _{2}}}&{\begin{array}{*{3}{rc}r}x&+&y&&&=&0\\&&-3y&+&3z&=&3\\&&-3y&-&z&=&3\end{array}}\end{array}}

(Note that the two $\rho _{1}$ steps $-2\rho _{1}+\rho _{2}$ and $-\rho _{1}+\rho _{3}$ are written as one operation.) In this second system, the last two equations involve only two unknowns. To finish we transform the second system into a third system, where the last equation involves only one unknown. This transformation uses the second row to eliminate $y$ from the third row.

{\begin{array}{rcl}&{\xrightarrow[{}]{-\rho _{2}+\rho _{3}}}&{\begin{array}{*{3}{rc}r}x&+&y&&&=&0\\&&-3y&+&3z&=&3\\&&&&-4z&=&0\end{array}}\end{array}}

Now we are set up for the solution. The third row shows that $z=0$ . Substitute that back into the second row to get $y=-1$ , and then substitute back into the first row to get $x=1$ .

Example 1.7

For the Physics problem from the start of this chapter, Gauss' method gives this.

{\begin{array}{rcl}{\begin{array}{*{2}{rc}r}40h&+&15c&=&100\\-50h&+&25c&=&50\end{array}}&{\xrightarrow[{}]{5/4\rho _{1}+\rho _{2}}}&{\begin{array}{*{2}{rc}r}40h&+&15c&=&100\\&&(175/4)c&=&175\end{array}}\end{array}}

So $c=4$ , and back-substitution gives that $h=1$ . (The Chemistry problem is solved later.)

Example 1.8

The reduction

{\begin{array}{rcl}{\begin{array}{*{3}{rc}r}x&+&y&+&z&=&9\\2x&+&4y&-&3z&=&1\\3x&+&6y&-&5z&=&0\end{array}}&{\xrightarrow[{-3\rho _{1}+\rho _{3}}]{-2\rho _{1}+\rho _{2}}}&{\begin{array}{*{3}{rc}r}x&+&y&+&z&=&9\\&&2y&-&5z&=&-17\\&&3y&-&8z&=&-27\end{array}}\\&{\xrightarrow[{}]{-(3/2)\rho _{2}+\rho _{3}}}&{\begin{array}{*{3}{rc}r}x&+&y&+&z&=&9\\&&2y&-&5z&=&-17\\&&&&-(1/2)z&=&-(3/2)\end{array}}\end{array}}

shows that $z=3$ , $y=-1$ , and $x=7$ .

As these examples illustrate, Gauss' method uses the elementary reduction operations to set up back-substitution.

Definition 1.9

In each row, the first variable with a nonzero coefficient is the row's leading variable. A system is in echelon form if each leading variable is to the right of the leading variable in the row above it (except for the leading variable in the first row).

Example 1.10

The only operation needed in the examples above is pivoting. Here is a linear system that requires the operation of swapping equations. After the first pivot

{\begin{array}{rcl}{\begin{array}{*{4}{rc}r}x&-&y&&&&&=&0\\2x&-&2y&+&z&+&2w&=&4\\&&y&&&+&w&=&0\\&&&&2z&+&w&=&5\end{array}}&{\xrightarrow[{}]{-2\rho _{1}+\rho _{2}}}&{\begin{array}{*{4}{rc}r}x&-&y&&&&&=&0\\&&&&z&+&2w&=&4\\&&y&&&+&w&=&0\\&&&&2z&+&w&=&5\end{array}}\end{array}}

the second equation has no leading $y$ . To get one, we look lower down in the system for a row that has a leading $y$ and swap it in.

{\begin{array}{rcl}&{\xrightarrow[{}]{\rho _{2}\leftrightarrow \rho _{3}}}&{\begin{array}{*{4}{rc}r}x&-&y&&&&&=&0\\&&y&&&+&w&=&0\\&&&&z&+&2w&=&4\\&&&&2z&+&w&=&5\end{array}}\end{array}}

(Had there been more than one row below the second with a leading $y$ then we could have swapped in any one.) The rest of Gauss' method goes as before.

{\begin{array}{rcl}&{\xrightarrow[{}]{-2\rho _{3}+\rho _{4}}}&{\begin{array}{*{4}{rc}r}x&-&y&&&&&=&0\\&&y&&&+&w&=&0\\&&&&z&+&2w&=&4\\&&&&&&-3w&=&-3\end{array}}\end{array}}

Back-substitution gives $w=1$ , $z=2$ , $y=-1$ , and $x=-1$ .

Strictly speaking, the operation of rescaling rows is not needed to solve linear systems. We have included it because we will use it later in this chapter as part of a variation on Gauss' method, the Gauss-Jordan method.

All of the systems seen so far have the same number of equations as unknowns. All of them have a solution, and for all of them there is only one solution. We finish this subsection by seeing for contrast some other things that can happen.

Example 1.11

Linear systems need not have the same number of equations as unknowns. This system

{\begin{array}{*{2}{rc}r}x&+&3y&=&1\\2x&+&y&=&-3\\2x&+&2y&=&-2\end{array}}

has more equations than variables. Gauss' method helps us understand this system also, since this

{\begin{array}{rcl}&{\xrightarrow[{-2\rho _{1}+\rho _{3}}]{-2\rho _{1}+\rho _{2}}}&{\begin{array}{*{2}{rc}r}x&+&3y&=&1\\&&-5y&=&-5\\&&-4y&=&-4\end{array}}\end{array}}

shows that one of the equations is redundant. Echelon form

{\begin{array}{rcl}&{\xrightarrow[{}]{-(4/5)\rho _{2}+\rho _{3}}}&{\begin{array}{*{2}{rc}r}x&+&3y&=&1\\&&-5y&=&-5\\&&0&=&0\end{array}}\end{array}}

gives $y=1$ and $x=-2$ . The " $0=0$ " is derived from the redundancy.

That example's system has more equations than variables. Gauss' method is also useful on systems with more variables than equations. Many examples are in the next subsection.

Another way that linear systems can differ from the examples shown earlier is that some linear systems do not have a unique solution. This can happen in two ways.

The first is that it can fail to have any solution at all.

Example 1.12

Contrast the system in the last example with this one.

{\begin{array}{rcl}{\begin{array}{*{2}{rc}r}x&+&3y&=&1\\2x&+&y&=&-3\\2x&+&2y&=&0\end{array}}&{\xrightarrow[{-2\rho _{1}+\rho _{3}}]{-2\rho _{1}+\rho _{2}}}&{\begin{array}{*{2}{rc}r}x&+&3y&=&1\\&&-5y&=&-5\\&&-4y&=&-2\end{array}}\end{array}}

Here the system is inconsistent: no pair of numbers satisfies all of the equations simultaneously. Echelon form makes this inconsistency obvious.

{\begin{array}{rcl}&{\xrightarrow[{}]{-(4/5)\rho _{2}+\rho _{3}}}&{\begin{array}{*{2}{rc}r}x&+&3y&=&1\\&&-5y&=&-5\\&&0&=&2\end{array}}\end{array}}

The solution set is empty.

Example 1.13

The prior system has more equations than unknowns, but that is not what causes the inconsistency— Example 1.11 has more equations than unknowns and yet is consistent. Nor is having more equations than unknowns sufficient for inconsistency, as is illustrated by this inconsistent system with the same number of equations as unknowns.

{\begin{array}{rcl}{\begin{array}{*{2}{rc}r}x&+&2y&=&8\\2x&+&4y&=&8\end{array}}&{\xrightarrow[{}]{-2\rho _{1}+\rho _{2}}}&{\begin{array}{*{2}{rc}r}x&+&2y&=&8\\&&0&=&-8\end{array}}\end{array}}

The other way that a linear system can fail to have a unique solution is to have many solutions.

Example 1.14

In this system

{\begin{array}{*{2}{rc}r}x&+&y&=&4\\2x&+&2y&=&8\end{array}}

any pair of numbers satisfying the first equation automatically satisfies the second. The solution set $\{(x,y)\,{\big |}\,x+y=4\}$ is infinite; some of its members are $(0,4)$ , $(-1,5)$ , and $(2.5,1.5)$ . The result of applying Gauss' method here contrasts with the prior example because we do not get a contradictory equation.

{\begin{array}{rcl}&{\xrightarrow[{}]{-2\rho _{1}+\rho _{2}}}&{\begin{array}{*{2}{rc}r}x&+&y&=&4\\&&0&=&0\end{array}}\end{array}}

Don't be fooled by the " $0=0$ " equation in that example. It is not the signal that a system has many solutions.

Example 1.15

The absence of a " $0=0$ " does not keep a system from having many different solutions. This system is in echelon form

{\begin{array}{*{3}{rc}r}x&+&y&+&z&=&0\\&&y&+&z&=&0\end{array}}

has no " $0=0$ ", and yet has infinitely many solutions. (For instance, each of these is a solution: $(0,1,-1)$ , $(0,1/2,-1/2)$ , $(0,0,0)$ , and $(0,-\pi ,\pi )$ . There are infinitely many solutions because any triple whose first component is $0$ and whose second component is the negative of the third is a solution.)

Nor does the presence of a " $0=0$ " mean that the system must have many solutions. Example 1.11 shows that. So does this system, which does not have many solutions— in fact it has none— despite that when it is brought to echelon form it has a " $0=0$ " row.

{\begin{array}{rcl}{\begin{array}{*{3}{rc}r}2x&&&-&2z&=&6\\&&y&+&z&=&1\\2x&+&y&-&z&=&7\\&&3y&+&3z&=&0\end{array}}&{\xrightarrow[{}]{-\rho _{1}+\rho _{3}}}&{\begin{array}{*{3}{rc}r}2x&&&-&2z&=&6\\&&y&+&z&=&1\\&&y&+&z&=&1\\&&3y&+&3z&=&0\end{array}}\\&{\xrightarrow[{-3\rho _{2}+\rho _{4}}]{-\rho _{2}+\rho _{3}}}&{\begin{array}{*{3}{rc}r}2x&&&-&2z&=&6\\&&y&+&z&=&1\\&&&&0&=&0\\&&&&0&=&-3\end{array}}\end{array}}

We will finish this subsection with a summary of what we've seen so far about Gauss' method.

Gauss' method uses the three row operations to set a system up for back substitution. If any step shows a contradictory equation then we can stop with the conclusion that the system has no solutions. If we reach echelon form without a contradictory equation, and each variable is a leading variable in its row, then the system has a unique solution and we find it by back substitution. Finally, if we reach echelon form without a contradictory equation, and there is not a unique solution (at least one variable is not a leading variable) then the system has many solutions.

The next subsection deals with the third case— we will see how to describe the solution set of a system with many solutions.

Exercises[編輯]

Template:Linear Algebra/Book 2/Recommended

Problem 1

Use Gauss' method to find the unique solution for each system.

${\begin{array}{*{2}{rc}r}2x&+&3y&=&13\\x&-&y&=&-1\end{array}}$
${\begin{array}{*{3}{rc}r}x&&&-&z&=&0\\3x&+&y&&&=&1\\-x&+&y&+&z&=&4\end{array}}$

Template:Linear Algebra/Book 2/Recommended

Problem 2

Use Gauss' method to solve each system or conclude "many solutions" or "no solutions".

${\begin{array}{*{2}{rc}r}2x&+&2y&=&5\\x&-&4y&=&0\end{array}}$
${\begin{array}{*{2}{rc}r}-x&+&y&=&1\\x&+&y&=&2\end{array}}$
${\begin{array}{*{3}{rc}r}x&-&3y&+&z&=&1\\x&+&y&+&2z&=&14\end{array}}$
${\begin{array}{*{2}{rc}r}-x&-&y&=&1\\-3x&-&3y&=&2\end{array}}$
${\begin{array}{*{3}{rc}r}&&4y&+&z&=&20\\2x&-&2y&+&z&=&0\\x&&&+&z&=&5\\x&+&y&-&z&=&10\end{array}}$
${\begin{array}{*{4}{rc}r}2x&&&+&z&+&w&=&5\\&&y&&&-&w&=&-1\\3x&&&-&z&-&w&=&0\\4x&+&y&+&2z&+&w&=&9\end{array}}$

Template:Linear Algebra/Book 2/Recommended

Problem 3

There are methods for solving linear systems other than Gauss' method. One often taught in high school is to solve one of the equations for a variable, then substitute the resulting expression into other equations. That step is repeated until there is an equation with only one variable. From that, the first number in the solution is derived, and then back-substitution can be done. This method takes longer than Gauss' method, since it involves more arithmetic operations, and is also more likely to lead to errors. To illustrate how it can lead to wrong conclusions, we will use the system

{\begin{array}{*{2}{rc}r}x&+&3y&=&1\\2x&+&y&=&-3\\2x&+&2y&=&0\end{array}}

from Example 1.12.

Solve the first equation for $x$ and substitute that expression into the second equation. Find the resulting $y$ .
Again solve the first equation for $x$ , but this time substitute that expression into the third equation. Find this $y$ .

What extra step must a user of this method take to avoid erroneously concluding a system has a solution?

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Problem 4

For which values of $k$ are there no solutions, many solutions, or a unique solution to this system?

{\begin{array}{*{2}{rc}r}x&-&y&=&1\\3x&-&3y&=&k\end{array}}

Template:Linear Algebra/Book 2/Recommended

Problem 5

This system is not linear, in some sense,

{\begin{array}{*{3}{rc}r}2\sin \alpha &-&\cos \beta &+&3\tan \gamma &=&3\\4\sin \alpha &+&2\cos \beta &-&2\tan \gamma &=&10\\6\sin \alpha &-&3\cos \beta &+&\tan \gamma &=&9\end{array}}

and yet we can nonetheless apply Gauss' method. Do so. Does the system have a solution?

Template:Linear Algebra/Book 2/Recommended

Problem 6

What conditions must the constants, the $b$ 's, satisfy so that each of these systems has a solution? Hint. Apply Gauss' method and see what happens to the right side (Anton 1987).

${\begin{array}{*{2}{rc}r}x&-&3y&=&b_{1}\\3x&+&y&=&b_{2}\\x&+&7y&=&b_{3}\\2x&+&4y&=&b_{4}\end{array}}$
${\begin{array}{*{3}{rc}r}x_{1}&+&2x_{2}&+&3x_{3}&=&b_{1}\\2x_{1}&+&5x_{2}&+&3x_{3}&=&b_{2}\\x_{1}&&&+&8x_{3}&=&b_{3}\end{array}}$

Problem 7

True or false: a system with more unknowns than equations has at least one solution. (As always, to say "true" you must prove it, while to say "false" you must produce a counterexample.)

Problem 8

Must any Chemistry problem like the one that starts this subsection— a balance the reaction problem— have infinitely many solutions?

Template:Linear Algebra/Book 2/Recommended

Problem 9

Find the coefficients $a$ , $b$ , and $c$ so that the graph of $f(x)=ax^{2}+bx+c$ passes through the points $(1,2)$ , $(-1,6)$ , and $(2,3)$ .

Problem 10

Gauss' method works by combining the equations in a system to make new equations.

Can the equation $3x-2y=5$ be derived, by a sequence of Gaussian reduction steps, from the equations in this system?
${\begin{array}{*{2}{rc}r}x&+&y&=&1\\4x&-&y&=&6\end{array}}$
Can the equation $5x-3y=2$ be derived, by a sequence of Gaussian reduction steps, from the equations in this system?
${\begin{array}{*{2}{rc}r}2x&+&2y&=&5\\3x&+&y&=&4\end{array}}$
Can the equation $6x-9y+5z=-2$ be derived, by a sequence of Gaussian reduction steps, from the equations in the system?
${\begin{array}{*{3}{rc}r}2x&+&y&-&z&=&4\\6x&-&3y&+&z&=&5\end{array}}$

Problem 11

Prove that, where $a,b,\ldots ,e$ are real numbers and $a\neq 0$ , if

ax+by=c

has the same solution set as

ax+dy=e

then they are the same equation. What if $a=0$ ?

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Problem 12

Show that if $ad-bc\neq 0$ then

{\begin{array}{*{2}{rc}r}ax&+&by&=&j\\cx&+&dy&=&k\end{array}}

has a unique solution.

Template:Linear Algebra/Book 2/Recommended

Problem 13

In the system

{\begin{array}{*{2}{rc}r}ax&+&by&=&c\\dx&+&ey&=&f\end{array}}

each of the equations describes a line in the $xy$ -plane. By geometrical reasoning, show that there are three possibilities: there is a unique solution, there is no solution, and there are infinitely many solutions.

Problem 14

Finish the proof of Theorem 1.4.

Problem 15

Is there a two-unknowns linear system whose solution set is all of $\mathbb {R} ^{2}$ ?

Template:Linear Algebra/Book 2/Recommended

Problem 16

Are any of the operations used in Gauss' method redundant? That is, can any of the operations be synthesized from the others?

Problem 17

Prove that each operation of Gauss' method is reversible. That is, show that if two systems are related by a row operation $S_{1}\rightarrow S_{2}$ then there is a row operation to go back $S_{2}\rightarrow S_{1}$ .

? Problem 18

A box holding pennies, nickels and dimes contains thirteen coins with a total value of $83$ cents. How many coins of each type are in the box? (Anton 1987)

? Problem 19

Four positive integers are given. Select any three of the integers, find their arithmetic average, and add this result to the fourth integer. Thus the numbers 29, 23, 21, and 17 are obtained. One of the original integers is:

19
21
23
29
17

(Salkind 1975, 1955 problem 38)

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? Problem 20

Laugh at this: ${\mbox{AHAHA}}+{\mbox{TEHE}}={\mbox{TEHAW}}$ . It resulted from substituting a code letter for each digit of a simple example in addition, and it is required to identify the letters and prove the solution unique (Ransom & Gupta 1935).

? Problem 21

The Wohascum County Board of Commissioners, which has 20 members, recently had to elect a President. There were three candidates ( $A$ , $B$ , and $C$ ); on each ballot the three candidates were to be listed in order of preference, with no abstentions. It was found that 11 members, a majority, preferred $A$ over $B$ (thus the other 9 preferred $B$ over $A$ ). Similarly, it was found that 12 members preferred $C$ over $A$ . Given these results, it was suggested that $B$ should withdraw, to enable a runoff election between $A$ and $C$ . However, $B$ protested, and it was then found that 14 members preferred $B$ over $C$ ! The Board has not yet recovered from the resulting confusion. Given that every possible order of $A$ , $B$ , $C$ appeared on at least one ballot, how many members voted for $B$ as their first choice (Gilbert, Krusemeyer & Larson 1993, Problem number 2)?

? Problem 22

"This system of $n$ linear equations with $n$ unknowns," said the Great Mathematician, "has a curious property."

"Good heavens!" said the Poor Nut, "What is it?"

"Note," said the Great Mathematician, "that the constants are in arithmetic progression."

"It's all so clear when you explain it!" said the Poor Nut. "Do you mean like $6x+9y=12$ and $15x+18y=21$ ?"

"Quite so," said the Great Mathematician, pulling out his bassoon. "Indeed, even larger systems can be solved regardless of their progression. Can you find their solution?"

"Good heavens!" cried the Poor Nut, "I am baffled."

Are you? (Dudley, Lebow & Rothman 1963)

§ 1.2 Describing the Solution Set 解集的表示[編輯]

A linear system with a unique solution has a solution set with one element. A linear system with no solution has a solution set that is empty. In these cases the solution set is easy to describe. Solution sets are a challenge to describe only when they contain many elements.

Example 2.1

This system has many solutions because in echelon form

{\begin{array}{rcl}{\begin{array}{*{3}{rc}r}2x&&&+&z&=&3\\x&-&y&-&z&=&1\\3x&-&y&&&=&4\end{array}}&{\xrightarrow[{-\left({\frac {3}{2}}\right)\rho _{1}+\rho _{3}}]{-\left({\frac {1}{2}}\right)\rho _{1}+\rho _{2}}}&{\begin{array}{*{3}{rc}r}2x&&&+&z&=&3\\&&-y&-&\left({\frac {3}{2}}\right)z&=&-{\frac {1}{2}}\\&&-y&-&\left({\frac {3}{2}}\right)z&=&-{\frac {1}{2}}\end{array}}\\[3em]&{\xrightarrow[{}]{-\rho _{2}+\rho _{3}}}&{\begin{array}{*{3}{rc}r}2x&&&+&z&=&3\\&&-y&-&\left({\frac {3}{2}}\right)z&=&-{\frac {1}{2}}\\&&&&0&=&0\end{array}}\end{array}}

not all of the variables are leading variables. The Gauss' method theorem showed that a triple satisfies the first system if and only if it satisfies the third. Thus, the solution set ${\Big \{}(x,y,z){\Big |}2x+z=3{\text{ and }}x-y-z=1{\text{ and }}3x-y=4{\Big \}}$ can also be described as $\left\{(x,y,z){\Big |}2x+z=3{\text{ and }}-y-{\frac {3z}{2}}=-{\frac {1}{2}}\right\}$ . However, this second description is not much of an improvement. It has two equations instead of three, but it still involves some hard-to-understand interaction among the variables.

To get a description that is free of any such interaction, we take the variable that does not lead any equation, $z$ , and use it to describe the variables that do lead, $x$ and $y$ . The second equation gives $y={\frac {1}{2}}-{\frac {3}{2}}z$ and the first equation gives $x={\frac {3}{2}}-{\frac {1}{2}}z$ . Thus, the solution set can be described as $\left\{(x,y,z)=\left({\frac {3}{2}}-{\frac {1}{2}}z,{\frac {1}{2}}-{\frac {3}{2}}z,z\right){\Big |}z\in \mathbb {R} \right\}$ . For instance, $\left({\frac {1}{2}},-{\frac {5}{2}},2\right)$ is a solution because taking $z=2$ gives a first component of ${\frac {1}{2}}$ and a second component of $-{\frac {5}{2}}$ .

The advantage of this description over the ones above is that the only variable appearing, $z$ , is unrestricted — it can be any real number.

Definition 2.2

The non-leading variables in an echelon-form linear system are free variables.

In the echelon form system derived in the above example, $x$ and $y$ are leading variables and $z$ is free.

Example 2.3

A linear system can end with more than one variable free. This row reduction

{\begin{array}{rcl}{\begin{array}{*{4}{rc}r}x&+&y&+&z&-&w&=&1\\&&y&-&z&+&w&=&-1\\3x&&&+&6z&-&6w&=&6\\&&-y&+&z&-&w&=&1\end{array}}&{\xrightarrow[{}]{-3\rho _{1}+\rho _{3}}}&{\begin{array}{*{4}{rc}r}x&+&y&+&z&-&w&=&1\\&&y&-&z&+&w&=&-1\\&&-3y&+&3z&-&3w&=&3\\&&-y&+&z&-&w&=&1\end{array}}\\[3em]&{\xrightarrow[{\rho _{2}+\rho _{4}}]{3\rho _{2}+\rho _{3}}}&{\begin{array}{*{4}{rc}r}x&+&y&+&z&-&w&=&1\\&&y&-&z&+&w&=&-1\\&&&&&&0&=&0\\&&&&&&0&=&0\end{array}}\end{array}}

ends with $x$ and $y$ leading, and with both $z$ and $w$ free. To get the description that we prefer we will start at the bottom. We first express $y$ in terms of the free variables $z$ and $w$ with $y=-1+z-w$ . Next, moving up to the top equation, substituting for $y$ in the first equation $x+(-1+z-w)+z-w=1$ and solving for $x$ yields $x=2-2z+2w$ . Thus, the solution set is ${\Big \{}(2-2z+2w,-1+z-w,z,w){\Big |}z,w\in \mathbb {R} {\Big \}}$ .

We prefer this description because the only variables that appear, $z$ and $w$ , are unrestricted. This makes the job of deciding which four-tuples are system solutions into an easy one. For instance, taking $z=1$ and $w=2$ gives the solution $(4,-2,1,2)$ . In contrast, $(3,-2,1,2)$ is not a solution, since the first component of any solution must be $2$ minus twice the third component plus twice the fourth.

Example 2.4

After this reduction

{\begin{array}{rcl}{\begin{array}{*{4}{rc}r}2x&-&2y&&&&&=&0\\&&&&z&+&3w&=&2\\3x&-&3y&&&&&=&0\\x&-&y&+&2z&+&6w&=&4\end{array}}&{\xrightarrow[{-({\frac {1}{2}})\rho _{1}+\rho _{4}}]{-({\frac {3}{2}})\rho _{1}+\rho _{3}}}&{\begin{array}{*{4}{rc}r}2x&-&2y&&&&&=&0\\&&&&z&+&3w&=&2\\&&&&&&0&=&0\\&&&&2z&+&6w&=&4\end{array}}\\[3em]&{\xrightarrow[{}]{-2\rho _{2}+\rho _{4}}}&{\begin{array}{*{4}{rc}r}2x&-&2y&&&&&=&0\\&&&&z&+&3w&=&2\\&&&&&&0&=&0\\&&&&&&0&=&0\end{array}}\end{array}}

$x,z$ lead, $y,w$ are free. The solution set is ${\Big \{}(y,y,2-3w,w){\Big |}y,w\in \mathbb {R} {\Big \}}$ . For instance, $(1,1,2,0)$ satisfies the system — take $y=1$ and $w=0$ . The four-tuple $(1,0,5,4)$ is not a solution since its first coordinate does not equal its second.

We refer to a variable used to describe a family of solutions as a parameter and we say that the set above is parametrized with $y$ and $w$ . (The terms "parameter" and "free variable" do not mean the same thing. Above, $y$ and $w$ are free because in the echelon form system they do not lead any row. They are parameters because they are used in the solution set description. We could have instead parametrized with $y$ and $z$ by rewriting the second equation as $w={\frac {2}{3}}-{\frac {1}{3}}z$ . In that case, the free variables are still $y$ and $w$ , but the parameters are $y$ and $z$ . Notice that we could not have parametrized with $x$ and $y$ , so there is sometimes a restriction on the choice of parameters. The terms "parameter" and "free" are related because, as we shall show later in this chapter, the solution set of a system can always be parametrized with the free variables. Consequently, we shall parametrize all of our descriptions in this way.)

Example 2.5

This is another system with infinitely many solutions.

{\begin{array}{rcl}{\begin{array}{*{4}{rc}r}x&+&2y&&&&&=&1\\2x&&&+&z&&&=&2\\3x&+&2y&+&z&-&w&=&4\end{array}}&{\xrightarrow[{-3\rho _{1}+\rho _{3}}]{-2\rho _{1}+\rho _{2}}}&{\begin{array}{*{4}{rc}r}x&+&2y&&&&&=&1\\&&-4y&+&z&&&=&0\\&&-4y&+&z&-&w&=&1\end{array}}\\[3em]&{\xrightarrow[{}]{-\rho _{2}+\rho _{3}}}&{\begin{array}{*{4}{rc}r}x&+&2y&&&&&=&1\\&&-4y&+&z&&&=&0\\&&&&&&-w&=&1\end{array}}\end{array}}

The leading variables are $x,y,w$ . The variable $z$ is free. (Notice here that, although there are infinitely many solutions, the value of one of the variables is fixed — $w=-1$ .) Write $w$ in terms of $z$ with $w=-1+0z$ . Then $y={\frac {1}{4}}z$ . To express $x$ in terms of $z$ , substitute for $y$ into the first equation to get $x=1-{\frac {1}{2}}z$ . The solution set is $\left\{\left(1-{\frac {1}{2}}z,{\frac {1}{4}}z,z,-1\right){\Bigg |}z\in \mathbb {R} \right\}$ .

We finish this subsection by developing the notation for linear systems and their solution sets that we shall use in the rest of this book.

Definition 2.6

An $m\times n$ matrix is a rectangular array of numbers with $m$ rows and $n$ columns. Each number in the matrix is an entry.

Matrices are usually named by upper case roman letters, e.g. $A$ . Each entry is denoted by the corresponding lower-case letter, e.g. $a_{i,j}$ is the number in row $i$ and column $j$ of the array. For instance,

A={\begin{pmatrix}1&2.2&5\\3&4&-7\end{pmatrix}}

has two rows and three columns, and so is a $2\times 3$ matrix. (Read that "two-by-three"; the number of rows is always stated first.) The entry in the second row and first column is $a_{2,1}=3$ . Note that the order of the subscripts matters: $a_{1,2}\neq a_{2,1}$ since $a_{1,2}=2.2$ . (The parentheses around the array are a typographic device so that when two matrices are side by side we can tell where one ends and the other starts.)

Matrices occur throughout this book. We shall use ${\mathcal {M}}_{n\times m}$ to denote the collection of $n\times m$ matrices.

Example 2.7

We can abbreviate this linear system

{\begin{array}{*{3}{rc}r}x&+&2y&&&=&4\\&&y&-&z&=&0\\x&&&+&2z&=&4\end{array}}

with this matrix.

\left({\begin{array}{ccc|c}1&2&0&4\\0&1&-1&0\\1&0&2&4\end{array}}\right)

The vertical bar just reminds a reader of the difference between the coefficients on the systems's left hand side and the constants on the right. When a bar is used to divide a matrix into parts, we call it an augmented matrix. In this notation, Gauss' method goes this way.

\left({\begin{array}{ccc|c}1&2&0&4\\0&1&-1&0\\1&0&2&4\end{array}}\right){\xrightarrow[{}]{-\rho _{1}+\rho _{3}}}\left({\begin{array}{ccc|c}1&2&0&4\\0&1&-1&0\\0&-2&2&0\end{array}}\right){\xrightarrow[{}]{2\rho _{2}+\rho _{3}}}\left({\begin{array}{ccc|c}1&2&0&4\\0&1&-1&0\\0&0&0&0\end{array}}\right)

The second row stands for $y-z=0$ and the first row stands for $x+2y=4$ so the solution set is ${\Big \{}(4-2z,z,z){\Big |}z\in \mathbb {R} {\Big \}}$ . One advantage of the new notation is that the clerical load of Gauss' method — the copying of variables, the writing of $+$ 's and $=$ 's, etc. — is lighter.

We will also use the array notation to clarify the descriptions of solution sets. A description like $\{(2-2z+2w,-1+z-w,z,w){\big |}z,w\in \mathbb {R} \}$ from Example 2.3 is hard to read. We will rewrite it to group all the constants together, all the coefficients of $z$ together, and all the coefficients of $w$ together. We will write them vertically, in one-column wide matrices.

\left\{{\begin{pmatrix}2\\-1\\0\\0\end{pmatrix}}+{\begin{pmatrix}-2\\1\\1\\0\end{pmatrix}}z+{\begin{pmatrix}2\\-1\\0\\1\end{pmatrix}}w{\Bigg |}z,w\in \mathbb {R} \right\}

For instance, the top line says that $x=2-2z+2w$ . The next section gives a geometric interpretation that will help us picture the solution sets when they are written in this way.

Definition 2.8

A vector (or column vector) is a matrix with a single column. A matrix with a single row is a row vector. The entries of a vector are its components.

Vectors are an exception to the convention of representing matrices with capital roman letters. We use lower-case roman or greek letters overlined with an arrow: ${\vec {a}},{\vec {b}}$ ... or ${\vec {\alpha }},{\vec {\beta }}$ ... (boldface is also common: $\mathbf {a}$ or ${\boldsymbol {\alpha }}$ ). For instance, this is a column vector with a third component of $7$ .

{\vec {v}}={\begin{pmatrix}1\\3\\7\end{pmatrix}}

Definition 2.9

The linear equation $a_{1}x_{1}+\cdots +a_{n}x_{n}=d$ with unknowns $x_{1},\ldots \,,x_{n}$ is satisfied by

{\vec {s}}={\begin{pmatrix}s_{1}\\\vdots \\s_{n}\end{pmatrix}}

if $a_{1}s_{1}+\cdots +a_{n}s_{n}=d$ . A vector satisfies a linear system if it satisfies each equation in the system.

The style of description of solution sets that we use involves adding the vectors, and also multiplying them by real numbers, such as the $z$ and $w$ . We need to define these operations.

Definition 2.10

The vector sum of ${\vec {u}}$ and ${\vec {v}}$ is this.

{\vec {u}}+{\vec {v}}={\begin{pmatrix}u_{1}\\\vdots \\u_{n}\end{pmatrix}}+{\begin{pmatrix}v_{1}\\\vdots \\v_{n}\end{pmatrix}}={\begin{pmatrix}u_{1}+v_{1}\\\vdots \\u_{n}+v_{n}\end{pmatrix}}

In general, two matrices with the same number of rows and the same number of columns add in this way, entry-by-entry.

Definition 2.11

The scalar multiplication of the real number $r$ and the vector ${\vec {v}}$ is this.

r\cdot {\vec {v}}=r\cdot {\begin{pmatrix}v_{1}\\\vdots \\v_{n}\end{pmatrix}}={\begin{pmatrix}rv_{1}\\\vdots \\rv_{n}\end{pmatrix}}

In general, any matrix is multiplied by a real number in this entry-by-entry way.

Scalar multiplication can be written in either order: $r\cdot {\vec {v}}$ or ${\vec {v}}\cdot r$ , or without the " $\cdot$ " symbol: $r{\vec {v}}$ . (Do not refer to scalar multiplication as "scalar product" because that name is used for a different operation.)

Example 2.12

{\begin{pmatrix}2\\3\\1\end{pmatrix}}+{\begin{pmatrix}3\\-1\\4\end{pmatrix}}={\begin{pmatrix}2+3\\3-1\\1+4\end{pmatrix}}={\begin{pmatrix}5\\2\\5\end{pmatrix}}\qquad 7\cdot {\begin{pmatrix}1\\4\\-1\\-3\end{pmatrix}}={\begin{pmatrix}7\\28\\-7\\-21\end{pmatrix}}

Notice that the definitions of vector addition and scalar multiplication agree where they overlap, for instance, ${\vec {v}}+{\vec {v}}=2{\vec {v}}$ .

With the notation defined, we can now solve systems in the way that we will use throughout this book.

Example 2.13

This system

{\begin{array}{*{5}{rc}r}2x&+&y&&&-&w&&&=&4\\&&y&&&+&w&+&u&=&4\\x&&&-&z&+&2w&&&=&0\end{array}}

reduces in this way.

{\begin{array}{rcl}\left({\begin{array}{ccccc|c}2&1&0&-1&0&4\\0&1&0&1&1&4\\1&0&-1&2&0&0\end{array}}\right)&{\xrightarrow[{}]{-\left({\frac {1}{2}}\right)\rho _{1}+\rho _{3}}}&\left({\begin{array}{ccccc|c}2&1&0&-1&0&4\\0&1&0&1&1&4\\0&-{\frac {1}{2}}&-1&{\frac {5}{2}}&0&-2\end{array}}\right)\\[3em]&{\xrightarrow[{}]{\left({\frac {1}{2}}\right)\rho _{2}+\rho _{3}}}&\left({\begin{array}{ccccc|c}2&1&0&-1&0&4\\0&1&0&1&1&4\\0&0&-1&3&{\frac {1}{2}}&0\end{array}}\right)\end{array}}

The solution set is $\left\{(w+{\frac {1}{2}}u,4-w-u,3w+{\frac {1}{2}}u,w,u){\Bigg |}w,u\in \mathbb {R} \right\}$ . We write that in vector form.

\left\{{\begin{pmatrix}x\\y\\z\\w\\u\end{pmatrix}}={\begin{pmatrix}0\\4\\0\\0\\0\end{pmatrix}}+{\begin{pmatrix}1\\-1\\3\\1\\0\end{pmatrix}}w+{\begin{pmatrix}{\frac {1}{2}}\\-1\\{\frac {1}{2}}\\0\\1\end{pmatrix}}u{\Bigg |}w,u\in \mathbb {R} \right\}

Note again how well vector notation sets off the coefficients of each parameter. For instance, the third row of the vector form shows plainly that if $u$ is held fixed then $z$ increases three times as fast as $w$ .

That format also shows plainly that there are infinitely many solutions. For example, we can fix $u$ as $0$ , let $w$ range over the real numbers, and consider the first component $x$ . We get infinitely many first components and hence infinitely many solutions.

Another thing shown plainly is that setting both $w,u$ to 0 gives that this

{\begin{pmatrix}x\\y\\z\\w\\u\end{pmatrix}}={\begin{pmatrix}0\\4\\0\\0\\0\end{pmatrix}}

is a particular solution of the linear system.

Example 2.14

In the same way, this system

{\begin{array}{*{3}{rc}r}x&-&y&+&z&=&1\\3x&&&+&z&=&3\\5x&-&2y&+&3z&=&5\end{array}}

reduces

\left({\begin{array}{ccc|c}1&-1&1&1\\3&0&1&3\\5&-2&3&5\end{array}}\right){\xrightarrow[{-5\rho _{1}+\rho _{3}}]{-3\rho _{1}+\rho _{2}}}\left({\begin{array}{ccc|c}1&-1&1&1\\0&3&-2&0\\0&3&-2&0\end{array}}\right){\xrightarrow[{}]{-\rho _{2}+\rho _{3}}}\left({\begin{array}{ccc|c}1&-1&1&1\\0&3&-2&0\\0&0&0&0\end{array}}\right)

to a one-parameter solution set.

\left\{{\begin{pmatrix}1\\0\\0\end{pmatrix}}+{\begin{pmatrix}-{\frac {1}{3}}\\{\frac {2}{3}}\\1\end{pmatrix}}z{\Bigg |}z\in \mathbb {R} \right\}

Before the exercises, we pause to point out some things that we have yet to do.

The first two subsections have been on the mechanics of Gauss' method. Except for one result, Theorem 1.4— without which developing the method doesn't make sense since it says that the method gives the right answers— we have not stopped to consider any of the interesting questions that arise.

For example, can we always describe solution sets as above, with a particular solution vector added to an unrestricted linear combination of some other vectors? The solution sets we described with unrestricted parameters were easily seen to have infinitely many solutions so an answer to this question could tell us something about the size of solution sets. An answer to that question could also help us picture the solution sets, in $\mathbb {R} ^{2}$ , or in $\mathbb {R} ^{3}$ , etc.

Many questions arise from the observation that Gauss' method can be done in more than one way (for instance, when swapping rows, we may have a choice of which row to swap with). Theorem 1.4 says that we must get the same solution set no matter how we proceed, but if we do Gauss' method in two different ways must we get the same number of free variables both times, so that any two solution set descriptions have the same number of parameters? Must those be the same variables (e.g., is it impossible to solve a problem one way and get $y$ and $w$ free or solve it another way and get $y$ and $z$ free)?

In the rest of this chapter we answer these questions. The answer to each is "yes". The first question is answered in the last subsection of this section. In the second section we give a geometric description of solution sets. In the final section of this chapter we tackle the last set of questions. Consequently, by the end of the first chapter we will not only have a solid grounding in the practice of Gauss' method, we will also have a solid grounding in the theory. We will be sure of what can and cannot happen in a reduction.

Exercises[編輯]

Template:Linear Algebra/Book 2/Recommended

Problem 1

Find the indicated entry of the matrix, if it is defined.

A={\begin{pmatrix}1&3&1\\2&-1&4\end{pmatrix}}

$a_{2,1}$
$a_{1,2}$
$a_{2,2}$
$a_{3,1}$

Template:Linear Algebra/Book 2/Recommended

Problem 2

Give the size of each matrix.

${\begin{pmatrix}1&0&4\\2&1&5\end{pmatrix}}$
${\begin{pmatrix}1&1\\-1&1\\3&-1\end{pmatrix}}$
${\begin{pmatrix}5&10\\10&5\end{pmatrix}}$

Template:Linear Algebra/Book 2/Recommended

Problem 3

Do the indicated vector operation, if it is defined.

${\begin{pmatrix}2\\1\\1\end{pmatrix}}+{\begin{pmatrix}3\\0\\4\end{pmatrix}}$
$5{\begin{pmatrix}4\\-1\end{pmatrix}}$
${\begin{pmatrix}1\\5\\1\end{pmatrix}}-{\begin{pmatrix}3\\1\\1\end{pmatrix}}$
$7{\begin{pmatrix}2\\1\end{pmatrix}}+9{\begin{pmatrix}3\\5\end{pmatrix}}$
${\begin{pmatrix}1\\2\end{pmatrix}}+{\begin{pmatrix}1\\2\\3\end{pmatrix}}$
$6{\begin{pmatrix}3\\1\\1\end{pmatrix}}-4{\begin{pmatrix}2\\0\\3\end{pmatrix}}+2{\begin{pmatrix}1\\1\\5\end{pmatrix}}$

Template:Linear Algebra/Book 2/Recommended

Problem 4

Solve each system using matrix notation. Express the solution using vectors.

${\begin{array}{*{2}{rc}r}3x&+&6y&=&18\\x&+&2y&=&6\end{array}}$
${\begin{array}{*{2}{rc}r}x&+&y&=&1\\x&-&y&=&-1\end{array}}$
${\begin{array}{*{3}{rc}r}x_{1}&&&+&x_{3}&=&4\\x_{1}&-&x_{2}&+&2x_{3}&=&5\\4x_{1}&-&x_{2}&+&5x_{3}&=&17\end{array}}$
${\begin{array}{*{3}{rc}r}2a&+&b&-&c&=&2\\2a&&&+&c&=&3\\a&-&b&&&=&0\end{array}}$
${\begin{array}{*{4}{rc}r}x&+&2y&-&z&&&=&3\\2x&+&y&&&+&w&=&4\\x&-&y&+&z&+&w&=&1\end{array}}$
${\begin{array}{*{4}{rc}r}x&&&+&z&+&w&=&4\\2x&+&y&&&-&w&=&2\\3x&+&y&+&z&&&=&7\end{array}}$

Template:Linear Algebra/Book 2/Recommended

Problem 5

Solve each system using matrix notation. Give each solution set in vector notation.

${\begin{array}{*{3}{rc}r}2x&+&y&-&z&=&1\\4x&-&y&&&=&3\end{array}}$
${\begin{array}{*{4}{rc}r}x&&&-&z&&&=&1\\&&y&+&2z&-&w&=&3\\x&+&2y&+&3z&-&w&=&7\end{array}}$
${\begin{array}{*{4}{rc}r}x&-&y&+&z&&&=&0\\&&y&&&+&w&=&0\\3x&-&2y&+&3z&+&w&=&0\\&&-y&&&-&w&=&0\end{array}}$
${\begin{array}{*{5}{rc}r}a&+&2b&+&3c&+&d&-&e&=&1\\3a&-&b&+&c&+&d&+&e&=&3\end{array}}$

Template:Linear Algebra/Book 2/Recommended

Problem 6

The vector is in the set. What value of the parameters produces that vector?

${\begin{pmatrix}5\\-5\end{pmatrix}}$ , $\{{\begin{pmatrix}1\\-1\end{pmatrix}}k\,{\big |}\,k\in \mathbb {R} \}$
${\begin{pmatrix}-1\\2\\1\end{pmatrix}}$ , $\{{\begin{pmatrix}-2\\1\\0\end{pmatrix}}i+{\begin{pmatrix}3\\0\\1\end{pmatrix}}j\,{\big |}\,i,j\in \mathbb {R} \}$
${\begin{pmatrix}0\\-4\\2\end{pmatrix}}$ , $\{{\begin{pmatrix}1\\1\\0\end{pmatrix}}m+{\begin{pmatrix}2\\0\\1\end{pmatrix}}n\,{\big |}\,m,n\in \mathbb {R} \}$

Problem 7

Decide if the vector is in the set.

${\begin{pmatrix}3\\-1\end{pmatrix}}$ , $\{{\begin{pmatrix}-6\\2\end{pmatrix}}k\,{\big |}\,k\in \mathbb {R} \}$
${\begin{pmatrix}5\\4\end{pmatrix}}$ , $\{{\begin{pmatrix}5\\-4\end{pmatrix}}j\,{\big |}\,j\in \mathbb {R} \}$
${\begin{pmatrix}2\\1\\-1\end{pmatrix}}$ , $\{{\begin{pmatrix}0\\3\\-7\end{pmatrix}}+{\begin{pmatrix}1\\-1\\3\end{pmatrix}}r\,{\big |}\,r\in \mathbb {R} \}$
${\begin{pmatrix}1\\0\\1\end{pmatrix}}$ , $\{{\begin{pmatrix}2\\0\\1\end{pmatrix}}j+{\begin{pmatrix}-3\\-1\\1\end{pmatrix}}k\,{\big |}\,j,k\in \mathbb {R} \}$

Problem 8

Parametrize the solution set of this one-equation system.

x_{1}+x_{2}+\cdots +x_{n}=0

Template:Linear Algebra/Book 2/Recommended

Problem 9

Apply Gauss' method to the left-hand side to solve
${\begin{array}{*{4}{rc}r}x&+&2y&&&-&w&=&a\\2x&&&+&z&&&=&b\\x&+&y&&&+&2w&=&c\end{array}}$
for $x$ , $y$ , $z$ , and $w$ , in terms of the constants $a$ , $b$ , and $c$ . Note that $w$ will be a free variable.
Use your answer from the prior part to solve this.
${\begin{array}{*{4}{rc}r}x&+&2y&&&-&w&=&3\\2x&&&+&z&&&=&1\\x&+&y&&&+&2w&=&-2\end{array}}$

Template:Linear Algebra/Book 2/Recommended

Problem 10

Why is the comma needed in the notation " $a_{i,j}$ " for matrix entries?

Template:Linear Algebra/Book 2/Recommended

Problem 11

Give the $4\!\times \!4$ matrix whose $i,j$ -th entry is

$i+j$ ;
$-1$ to the $i+j$ power.

Problem 12

For any matrix $A$ , the transpose of $A$ , written ${{A}^{\rm {trans}}}$ , is the matrix whose columns are the rows of $A$ . Find the transpose of each of these.

${\begin{pmatrix}1&2&3\\4&5&6\end{pmatrix}}$
${\begin{pmatrix}2&-3\\1&1\end{pmatrix}}$
${\begin{pmatrix}5&10\\10&5\end{pmatrix}}$
${\begin{pmatrix}1\\1\\0\end{pmatrix}}$

Template:Linear Algebra/Book 2/Recommended

Problem 13

Describe all functions $f(x)=ax^{2}+bx+c$ such that $f(1)=2$ and $f(-1)=6$ .
Describe all functions $f(x)=ax^{2}+bx+c$ such that $f(1)=2$ .

Problem 14

Show that any set of five points from the plane $\mathbb {R} ^{2}$ lie on a common conic section, that is, they all satisfy some equation of the form $ax^{2}+by^{2}+cxy+dx+ey+f=0$ where some of $a,\,\ldots \,,f$ are nonzero.

Problem 15

Make up a four equations/four unknowns system having

a one-parameter solution set;
a two-parameter solution set;
a three-parameter solution set.

? Problem 16

Solve the system of equations.
${\begin{array}{*{2}{rc}r}ax&+&y&=&a^{2}\\x&+&ay&=&1\end{array}}$
For what values of $a$ does the system fail to have solutions, and for what values of $a$ are there infinitely many solutions?
Answer the above question for the system.
${\begin{array}{*{2}{rc}r}ax&+&y&=&a^{3}\\x&+&ay&=&1\end{array}}$

(USSR Olympiad #174)

? Problem 17

In air a gold-surfaced sphere weighs $7588$ grams. It is known that it may contain one or more of the metals aluminum, copper, silver, or lead. When weighed successively under standard conditions in water, benzene, alcohol, and glycerine its respective weights are $6588$ , $6688$ , $6778$ , and $6328$ grams. How much, if any, of the forenamed metals does it contain if the specific gravities of the designated substances are taken to be as follows?