Linear Dependence, Bases, and Dimension

Arun Ram
Department of Mathematics and Statistics
University of Melbourne
Parkville, VIC 3010 Australia
aram@unimelb.edu.au

Last update: 13 August 2013

Linear Dependence, Bases, and Dimension

Let $R$ be a ring and let $M$ be an $R -module.$ Let $S$ be a subset of $M .$

The submodule generated by $S$ is the smallest submodule of $M$ containing $S;$ i.e. $span (S)$ is a submodule of $M$ such that

(a) $S \subseteq span (S),$

(b) If $N$ is a submodule of $M$ such that $S \subseteq N$ then $span (S) \subseteq N .$
A module $M$ is finitely generated if there is a finite subset $S$ of $M$ such that $span (S) = M .$
A vector space $V$ is finite dimensional if there is a finite subset $S$ of $V$ such that $span (S) = V .$
A linear combination of elements of $S$ is an element $v \in M$ of the form $v = \sum_{s \in S} r_{s} s,$ where $r_{s} \in R$ are such that $r_{s} = 0$ for all but a finite number of $s \in S .$
The set $S$ is linearly independent if it satisfies the condition, $If \sum_{s \in S} r_{s} s = 0, then r_{s} = 0, for all s \in S .$
The set $S$ is linearly dependent if it is not linearly independent.
A basis of $M$ is a set $B \subseteq M$ such that

a) $span (B) = V,$ and

b) $B$ is linearly independent.
A free module is an $R -module$ $M$ that has a basis.

HW: Show that $span (S)$ is the set of linear combinations of elements in $S .$

HW: Let $R$ be a commutative ring. Give an example of a finitely generated $R -module$ $M$ that does not have a basis.

Let $V$ be a vector space over a field $𝔽 .$ Then $V$ has a basis.

Example. Let $R$ be the ring of infinite matrices with rows and columns indexed by $ℤ_{> 0},$ entries in $ℂ,$ and only a finite number of nonzero entries in each row,

R = {(\begin{matrix} a_{11} & a_{12} & a_{13} & \dots \\ a_{21} & a_{22} & a_{23} & \dots \\ a_{31} & a_{32} & ⋱ \\ ⋮ & ⋱ \end{matrix}) | a_{i j} \in ℂ}, and let M = R

be the regular $R -module.$ Let

b_{0} = (\begin{matrix} 1 & 0 & 0 & 0 & \dots \\ 0 & 1 & 0 & 0 & \dots \\ 0 & 0 & 1 & 0 & \dots \\ 0 & 0 & 0 & 1 & \dots \\ ⋮ & ⋱ \end{matrix}), b_{1} = (\begin{matrix} 1 & 0 & 0 & 0 & 0 & \dots \\ 0 & 0 & 1 & 0 & 0 & \dots \\ 0 & 0 & 0 & 0 & 1 & \dots \\ 0 & 0 & 0 & 0 & 0 & \dots \\ ⋮ & ⋮ & ⋱ \end{matrix}), b_{2} = (\begin{matrix} 0 & 1 & 0 & 0 & 0 & 0 & \dots \\ 0 & 0 & 0 & 1 & 0 & 0 & \dots \\ 0 & 0 & 0 & 0 & 0 & 1 & \dots \\ 0 & 0 & 0 & 0 & 0 & 0 & \dots \\ ⋮ & 0 & ⋮ & ⋱ \end{matrix}) .

Then

B_{1} = {b_{0}} and B_{2} = {b_{1}, b_{2}}

are both bases of $M .$

(a)	Let $R$ be a ring and let $M$ be a free $R -module$ with an infinite basis. Any two bases of $M$ have the same number of elements.
(b)	Let $V$ be a vector space over a field $𝔽 .$ Any two bases of $V$ have the same number of elements.
(c)	Let $R$ be a commutative ring and let $M$ be a free $R -module.$ Any two bases of $M$ have the same number of elements.

Let $R$ be a commutative ring and let $M$ be a free $R -module.$ Let $V$ be a vector space over a field $F .$

The rank of $M$ is the number of elements in a basis of $M .$
The dimension of $V$ is the number of elements in a basis of $V .$

Let $B$ be a set and let $R$ be a ring.

The free module on the set $B$ is the $R -module$ $R^{B} = {\sum_{b \in B} r_{b} b | r_{b} \in R, and all but a finite number of the r_{b} are equal to 0},$ with addition given by $(\sum_{b \in B} r_{b} b) + (\sum_{b \in B} s_{b} b) = \sum_{b \in B} (r_{b} + s_{b}) b,$ and $R -action$ given by $r \sum_{b \in B} r_{b} b = \sum_{b \in B} (r r_{b}) b .$

HW: Let $B$ be a set. Show that $R^{B}$ is a free $R -module$ with basis $B .$

Let $M$ be an $R -module$ and let $B$ be a subset of $M .$

(a)	There is an $R -module$ homomorphism $ϕ : R^{B} \to M$ such that $ϕ (b) = b .$
(b)	$M$ is generated by $B$ if and only if $M$ is a quotient of $R^{B} .$
(c)	$M$ is a free module with basis $B$ if and only if $M ≅ R^{B} .$

Let $B$ and $C$ be sets. Let $R$ be a ring.

A $C \times B$ matrix with entries in $R$ is a collection $F = (F_{c b})$ of elements $F_{c b} \in R$ indexed by the elements of $C \times B$ and such that for each $b \in B$ all but a finite number of the $F_{c b}$ are $0 .$
$M_{C \times B} (R) = {C \times B matrices with entries in R} .$
The sum of two matrices $F_{1}, F_{2} \in M_{C \times B} (R)$ is the matrix $F_{1} + F_{2}$ given by ${(F_{1} + F_{2})}_{c b} = {(F_{1})}_{c b} + {(F_{2})}_{c b}, for all b \in B, c \in C .$
The product of matrices $F_{1} \in M_{D \times C} (R)$ and $F_{2} \in M_{C \times B} (R)$ is the matrix $F_{1} F_{2} \in M_{D \times B} (R)$ given by ${(F_{1} F_{2})}_{d b} = \sum_{c \in C} {(F_{1})}_{d c} {(F_{2})}_{c b}, for all b \in B and d \in D .$

Let $M$ and $N$ be free $R -modules$ with bases $B$ and $C,$ respectively. Let $f : M \to N$ be a homomorphism.

The matrix of $f : M \to N$ with respect to $B$ and $C$ is the matrix $^{\circ} f \in M_{C \times B} (R^{op})$ given by ${(^{\circ} f)}_{c b} = {(f_{c b})}^{op} where f_{c b} \in R are given by f (b) = \sum_{c \in C} f_{c b} c,$ for all $b \in B .$

Let $M$ and $N$ be free $R -modules$ with bases $B$ and $C,$ respectively.

(a)	The function $\begin{matrix} {Hom}_{R} (M, N) & ⟶ & M_{C \times B} (R^{op}) \\ f & ⟼ & ^{\circ} f \end{matrix}$ is an isomorphism of abelian groups.
(b)	The function $\begin{matrix} {End}_{R} (M) & ⟶ & M_{B \times B} (R^{op}) \\ f & ⟼ & ^{\circ} f \end{matrix}$ is a ring isomorphism.

HW: Discuss the difficulties in trying to make the map in Proposition ??? (a) into an $R -modules$ homomorphism, or into an $R^{op} -module$ isomorphism.

Let $M$ be a free module and let $B_{o}$ and $B_{n}$ be bases of $M .$

The change of basis matrix is the matrix $T_{o \to n}$ given by $b \in \sum_{c \in B_{n}} {(T_{o \to n})}_{c b} c, for all b \in B_{o} .$

Let $M$ be a free module with bases $B_{o}$ and $B_{n}$ and let $N$ be a free module with bases $C_{o}$ and $C_{n} .$ Then

{^{\circ} f}_{n} = T_{o \to n} ({^{\circ} f}_{o}) T_{n \to o}

Let $V$ be a vector space. Let $L, S$ be subsets of $V$ such that $L \subseteq S \subseteq$ such that $L$ is linearly independent and $span (S) = V .$ Then there exists a basis $B$ of $V$ such that $L \subseteq B \subseteq S .$

Proof.

Let $𝒞$ be the set of linearly independent subsets $L \subseteq C \subseteq S,$ partially ordered by inclusion. Let $B$ be a maximal element of $𝒞 .$

To show: $B$ is a basis of $V .$

To show:

(a)	$span (B) = V .$
(b)	$B$ is linearly independent.

(a) Suppose that $span (B) \neq V .$ Let $s \in S$ such that $s \notin span (B) .$ Then $L \subseteq (B \cup {s}) \subseteq S,$ and if there is a linear combination

ξ_{s} s + \sum_{b \in B} ξ_{b} b = 0, with ξ_{s} \neq 0, then s = ξ_{s}^{- 1} (\sum_{b \in B} ξ_{b} b) \in span (B) .

Since $s \notin span (B),$ $ξ_{s} = 0,$ but then since $B$ is linearly independent $ξ_{b} = 0$ for all $b \in B .$ So $B \cup {s}$ is linearly independent. This is a contradiction to the maximality of $B .$ So $span (B) = V .$

(b) $B$ is linearly independent by definition.

$□$

Let $R$ be a ring and let $M$ be a free $R -module.$ If $M$ has an infinite basis, or $R$ is a field, or $R$ is a commutative ring, then any two bases of $M$ have the same number of elements.

Proof.

(a) Let $B$ be an infinite basis of $M .$ Let $C$ be a basis of $M .$ Define $r_{c b} \in R$ for $c \in C,$ $b \in B,$ by

b = \sum_{c \in C} r_{c b} c and let S_{b} = {c \in C | r_{c b} \neq 0},

for each $b \in B .$ Then each $S_{b}$ is a finite subset of $C$ and $C \subseteq ⋃_{b \in B} S_{b}$ since $C$ is a minimal spanning set. So $Card (C) \leq ℵ_{0} Card (B) = Card (B) .$ The same argument shows that $Card (B) \leq ℵ_{0} Card (C) .$ So $Card (B) = Card (C) .$

(b) By part (a) we may assume that $V$ has a finite basis $B .$ Let $C$ be another basis of $B .$ Let $b \in B .$ Then there is an element $c \in C$ such that $c \notin span (B - {b}) .$ Then $B_{1} = (B - {b}) \cup {c}$ is a basis with the same cardinality as $B .$ By repeating this process, we can create a basis $B'$ of $V$ which contains all the elements of $C$ and which has the same cardinality as $C .$ Thus $Card (B) \geq Card (C) .$ A similar argument with $C$ in place of $B$ give that $Card (B) \leq Card (C) .$

(c) The case when $Card (B)$ is infinite is covered by part (a). We will show that if $B$ is a basis of $M$ then $\overline{B} = {b + 𝔪 M | b \in B}$ is a basis of $M / 𝔪 M$ as a vector space over $R / 𝔪 .$ Then the result will follow from part (b). Let

\sum_{i} {\overline{r}}_{i} {\overline{b}}_{i} = 0

where ${\overline{r}}_{i} \in R / 𝔪$ and ${\overline{b}}_{i} \in M / 𝔪 M .$ Then

0 = \sum_{i} {\overline{r}}_{i} {\overline{b}}_{i} = \sum_{i} (r_{i} + 𝔪) (b_{i} + 𝔪 M) = (\sum_{i} r_{i} b_{i}) + 𝔪 M .

So $\sum_{i} r_{i} b_{i} \in 𝔪 M .$ So there are elements $ℓ_{j} \in 𝔪,$ $m_{j} \in M$ and elements $c_{j_{k}} \in R$ such that

\sum_{i} r_{i} b_{i} = ℓ_{1} m_{1} + \dots ℓ_{s} m_{s} = \sum_{j} ℓ_{j} \sum_{k} c_{j_{k}} b_{k} = \sum_{j, k} ℓ_{j} m_{j_{k}} b_{k} .

Since $B$ is linearly independent

r_{k} = \sum_{j} ℓ_{j} c_{j_{k}} \in 𝔪, for each k .

So ${\overline{r}}_{k} = 0$ for each $k .$ So $\overline{B}$ is linearly independent.

$□$

Let $M$ and $N$ be free $R -modules$ with bases $B$ and $C,$ respectively.

(a)	The function $\begin{matrix} {Hom}_{R} (M, N) & ⟶ & M_{B \times C} (R^{op}) \\ f & ⟼ & ^{\circ} f \end{matrix}$ is a bijection.
(b)	The function $\begin{matrix} {End}_{R} (M) & ⟶ & M_{B \times B} (R^{op}) \\ f & ⟼ & ^{\circ} f \end{matrix}$ is a ring isomorphism.

Proof.

(b) In fact we shall show that if $M,$ $N$ and $P$ are free modules with bases $B,$ $C$ and $D$ respectively and if $f_{1} \in {Hom}_{R} (M, N)$ and $f_{2} \in {Hom}_{R} (N, P)$ then $^{\circ} (f_{1} f_{2}) = {^{\circ} f}_{1} {^{\circ} f}_{2} .$

f_{1} (f_{2} (b)) = \sum_{c \in C} {(f_{2})}_{c b} c f_{1} (c) = \sum_{c \in C} \sum_{d \in D} {(f_{2})}_{c b} {(f_{1})}_{d c} d = \sum_{d \in D} (\sum_{c \in C} {(f_{2})}_{c b} {(f_{1})}_{d c}) d .

{(^{\circ} (f_{1} f_{2}))}_{d b} = {(\sum_{c \in C} {(f_{2})}_{c b} {(f_{1})}_{d c})}^{op} = \sum_{c \in C} {(f_{1})}_{d c}^{op} {(f_{2})}_{c b}^{op} = \sum_{c \in C} {({^{\circ} f}_{1})}_{d c} {({^{\circ} f}_{2})}_{c b} = {({^{\circ} f}_{1} {^{\circ} f}_{2})}_{d b}

$□$

HW: Discuss the difficulties in trying to make the map in Proposition ??? (a) into an $R -modules$ homomorphism, or into an $R^{op} -module$ isomorphism.

Let $M$ be a free module and let $B = {b_{i}}$ and $B' = {b_{j}^{'}}$ be bases of $M .$

The change of basis matrix $P (B', B)$ is the matrix given by $b_{i} = \sum_{j} P {(B, B')}_{i j} b_{j}^{'}, for all b_{i} \in B .$

HW: Let $M$ be an $R -module$ and let $S \subseteq M$ be a subset of $M .$ Show that $span (S)$ exists and is unique by showing that $span (S)$ is the intersection of all of the submodules that contain $S .$

HW: Let M be an $R -module.$ Show that

span (S) = {\sum_{m \in S} r_{m} m | r_{m} = 0 for all but a finite number of m \in S} .

HW: Let $M$ be an $R -module.$ Show that a subset $S \subseteq M$ is linearly independent if and only if $S$ satisfies the following property:
If $r_{m} \in R$ such that $r_{m} = 0$ for all but a finite number of $m \in M$ and $\sum_{m \in S} r_{m} m = 0$ then $r_{m} = 0$ for all $m \in M .$

HW: Let $V$ be a vector space over a field $F .$ Show that if $v \in V$ and ${v_{1}, v_{2}, \dots, v_{n}}$ is a basis of $V$ then there exist unique $c_{i} \in F$ such that $v = c_{1} v_{1} + c_{2} v_{2} + \dots + c_{n} v_{n} .$

HW: Give an example of a finitely generated module over a commutative ring that does not have a basis.

HW: Give an example of a ring $R$ and a finitely generated module over $R$ that has two different finite bases with different numbers of elements.

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(a)	$S \subseteq span (S),$
(b)	If $N$ is a submodule of $M$ such that $S \subseteq N$ then $span (S) \subseteq N .$