Pengguna:Kekavigi/bak pasir

Dalam matematika, sebarang himpunan vektor B dalam suatu ruang vektor V disebut basis, jika setiap elemen di V dapat dituliskan sebagai kombinasi linear terhingga yang unik dari elemen-elemen di B. Koefisien-koefisien pada kombinasi linear tersebut disebut sebagai koordinat dari vektor terhadap B. Elemen-elemen dari basis disebut sebagai vektor basis. Basis juga dapat didefinisikan sebagai himpunan B yang elemen-elemennya saling bebas linear dan setiap elemen di V adalah kombinasi linear dari elemen-elemen di B.^[1] Dengan kata lain, basis adalah himpunan merentang (spanning) yang bebas linear.

Suatu ruang vektor dapat memiliki beberapa basis; namun semua basis tersebut akan memiliki jumlah elemen yang sama, yang disebut sebagai dimensi dari ruang vektor. Artikel ini secara umum membahas ruang-ruang vektor berdimensi hingga. Akan tetapi, banyak prinsip yang disampaikan juga berlaku untuk ruang vektor dimensi tak-hingga.

Definisi

Basis untuk ruang vektor ${\displaystyle V}$ (atas medan ${\displaystyle F}$) adalah suatu himpunan bagian ${\displaystyle B\subset V}$ yang memenuhi:

1. Setiap ${\displaystyle \mathbf {v} \in V}$ dapat dituliskan sebagai ${\displaystyle \mathbf {v} =\sum _{i=1}^{k}a_{i}\mathbf {b} _{i}}$ dengan ${\displaystyle k\in \mathbb {N} ,a_{1},\ldots ,a_{k}\in F,\mathbf {b} _{1},\ldots ,\mathbf {b} _{k}\in B}$.
2. Jika ${\displaystyle \mathbf {v} =\sum _{i=1}^{\tilde {k}}{\tilde {a}}_{i}{\tilde {\mathbf {b} }}_{i}}$ representasi lain, maka ${\displaystyle k={\tilde {k}}}$ dan ada suatu permutasi ${\displaystyle \iota :\{1,\ldots ,k\}\to \{1,\ldots ,k\}}$ yang ${\displaystyle a_{i}={\tilde {a}}_{\iota (i)}}$ dan ${\displaystyle \mathbf {b} _{i}={\tilde {\mathbf {b} }}_{\iota (i)}}$.

Sebarang basis ${\displaystyle B}$ dari suatu ruang vektor ${\displaystyle V}$ atas lapangan ${\displaystyle F}$ (seperti bilangan riil ${\displaystyle \mathbb {R} }$ atau bilangan kompleks ${\displaystyle \mathbb {C} }$) adalah suatu subset dari ${\displaystyle V}$ yang saling bebas linear dan merentang ${\displaystyle V}$. Hal ini mengartikan suatu subset ${\displaystyle B}$ dari ${\displaystyle V}$ merupakan basis jika memenuhi dua syarat berikut:

kebebasan linear

Untuk setiap subset terhingga ${\displaystyle \{\mathbf {v} _{1},\dotsc ,\mathbf {v} _{m}\}}$ dari ${\displaystyle B}$, jika ${\displaystyle c_{1}\mathbf {v} _{1}+\cdots +c_{m}\mathbf {v} _{m}=\mathbf {0} }$ untuk suatu ${\displaystyle c_{1},\dotsc ,c_{m}}$ di F, maka ${\displaystyle c_{1}=\cdots =c_{m}=0}$;

merentang linear

Untuk setiap vektor ${\displaystyle \mathbf {v} \in V}$, terdapat ${\displaystyle n}$ skalar ${\displaystyle a_{1},\dotsc ,a_{n}}$ di F dan ${\displaystyle n}$ vektor ${\displaystyle \mathbf {v} _{1},\dotsc ,\mathbf {v} _{n}}$ di B, sehingga ${\displaystyle \mathbf {v} =a_{1}\mathbf {v} _{1}+\cdots +a_{n}\mathbf {v} _{n}}$.

Skalar-skalar ${\displaystyle a_{i}}$ disebut koordinat dari vektor ${\displaystyle \mathbf {v} }$ terhadap basis ${\displaystyle B}$, dan berdasarkan sifat pertama, nilai mereka unik (tunggal). Ruang vektor disebut berdimensi hingga jika ruang vektor tersebut memiliki basis dengan total elemen yang berhingga.

Vektor-vektor basis seringkali (dan terkadang harus) perlu memiliki urutan total untuk mempermudah pembahasan. Sebagai contoh, ketika basis digunakan untuk membahas orientasi, atau untuk membahas koefisien-koefisien vektor terhadap suatu basis tanpa perlu merujuk secara eksplisit elemen-elemen dari basis. Istilah basis terurut terkadang digunakan untuk mempertegas bahwa suatu urutan telah dipilih; yang sebenarnya menyebabkan basis bukan lagi sebagai suatu himpunan tak-terurut, melainkan sebagai suatu barisan (atau sejenisnya). Pembahasan lebih lanjut tersedia di bagian Koordinat di bawah.

Contoh

Himpunan ${\displaystyle \mathbb {R} ^{2}}$ dari pasangan terurut bilangan riil adalah suatu ruang vektor dibawah operasi penjumlahan komponen-demi-komponen

dan perkaliandengan ${\displaystyle \lambda }$ adalah sebarang bilangan riil. Contoh basis yang sederhana dari ruang vektor ini adalah himpunan yang berisi vektor ${\displaystyle \mathbf {e} _{1}=(1,\,0)}$ dan ${\displaystyle \mathbf {e} _{2}=(0,\,1)}$. Kedua vektor ini membentuk sebuah basis (yang disebut basis standar) karena sebarang vektor ${\displaystyle \mathbf {v} =(a,\,b)}$ di ${\displaystyle \mathbb {R} ^{2}}$ dapat ditulis secara unik sebagaiSebarang pasangan vektor yang saling bebas linear di ${\displaystyle \mathbb {R} ^{2}}$, seperti ${\displaystyle (1,\,1)}$ dan ${\displaystyle (-1,\,2)}$, juga membentuk sebuah basis untuk ${\displaystyle \mathbb {R} ^{2}}$.

Secara umum, jika ${\displaystyle F}$ berupa lapangan, maka himpunan ${\displaystyle F^{n}}$ yang berisi rangkap-n elemen-elemen dari ${\displaystyle F^{n}}$ adalah sebuah ruang vektor, dibawah operasi penjumlahan dan perkalian yang serupa dengan contoh pembuka tadi. Misalkan

adalah rangkap-n dengan semua komponennya bernilai 0, kecuali komponen ke-i, yang bernilai 1. Himpunan ${\displaystyle \mathbf {e} _{1},\ldots ,\mathbf {e} _{n}}$ membentuk suatu basis (terurut) untuk ${\displaystyle F^{n},}$ yang disebut dengan basis standar dari ${\displaystyle F^{n}.}$

Contoh yang berbeda terlihat pada gelanggang polinomial. Jika ${\displaystyle F}$ berupa lapangan, himpunan ${\displaystyle F[x]}$ dari semua polinomial satu-variabel dengan koefisien-koefisiennya berada di ${\displaystyle F}$, merupakan suatu ruang vektor. Salah satu basis untuk ruang ini adalah basis monomial B, yang berisi semua monomial:

Contoh lain dari basis untuk ruang vektor tersebut adalah polinomial basis Bernstein dan polinomial Chebyshev.

Sifat-sifat

Banyak sifat dari basis terhingga merupakan hasil dari lema pertukaran Steinitz, yang menyatakan bahwa, untuk sebarang ruang vektor ${\displaystyle V}$, dan sebarang penetapan himpunan merentang ${\displaystyle S}$ dan himpunan bebas linear ${\displaystyle L}$ berisi ${\displaystyle n}$ elemen dari ${\displaystyle V}$, ${\displaystyle n}$ elemen dari ${\displaystyle S}$ dapat dipilih sedemikian rupa untuk ditukar dengan elemen-elemen di ${\displaystyle L}$ sehingga menghasilkan suatu himpunan merentang yang: mengandung ${\displaystyle L}$, elemen-elemen yang lainnya berada di ${\displaystyle S}$, dan memiliki jumlah elemen yang sama dengan ${\displaystyle S}$. Sebagian besar sifat yang dihasilkan dari lema tersebut masih berlaku ketika tidak ada himpunan merentang yang terhingga, namun pembuktian untuk keadaan ini memerlukan aksioma pemilihan atau suatu bentuk yang lebih lemahnya, seperti lema ultrafilter.

Jika ${\displaystyle V}$ adalah ruang vektor atas lapangan ${\displaystyle F}$, maka:

• Untuk sebarang subset bebas linear ${\displaystyle L}$ dari sebarang himpunan merentang ${\displaystyle S\subseteq V}$, terdapat suatu basis ${\displaystyle B}$ sehingga
  $${\displaystyle L\subseteq B\subseteq S.}$$

  
• ${\displaystyle V}$ memiliki basis (hal ini dapat dihasilkan dari sifat sebelumnya dengan memilih ${\displaystyle L}$ sebagai himpunan kosong, dan ${\displaystyle S=V}$).
• Setiap basis dari ${\displaystyle V}$ memiliki kardinalitas yang sama, yang disebut dengan dimensi dari ${\displaystyle V}$. Pernyataan ini dikenal sebagai teorema dimensi.
• Sebarang himpunan pembangkit ${\displaystyle S}$ adalah basis dari ${\displaystyle V}$ jika dan hanya jika itu bersifat minimal, artinya, ${\displaystyle S}$ bukan subset wajar (proper subset) dari sebarang himpunan yang bebas linear.

Jika ${\displaystyle V}$ adalah ruang vektor berdimensi ${\displaystyle n}$, suatu subset berisi ${\displaystyle n}$ elemen dari ${\displaystyle V}$ merupakan basis dari ${\displaystyle V}$ jika dan hanya jika:

• Subset tersebut bebas linear;
• Subset tersebut himpunan merentang dari ${\displaystyle V}$.

Koordinat

Misalkan ${\displaystyle V}$ adalah ruang vektor berdimensi ${\displaystyle n}$ (hingga) atas lapangan ${\displaystyle F}$, dan

adalah basis dari ${\displaystyle V}$. Berdasarkan definisi dari basis, setiap ${\displaystyle \mathbf {v} }$ di ${\displaystyle V}$ dapat ditulis secara unik sebagaidengan koefisien-koefisien ${\displaystyle \lambda _{1},\ldots ,\lambda _{n}}$ adalah skalar (yaitu, elemen-elemen dari ${\displaystyle F}$), yang disebut sebagai koordinat dari ${\displaystyle \mathbf {v} }$ atas ${\displaystyle B}$. Akan tetapi, pembahasan terkait himpunan koefisien akan menghilangkan hubungan antara koefisien-koefisien dari elemen-elemen basis, dan beberapa vektor berbeda dapat memiliki himpunan koefisien yang sama. Sebagai contoh, vektor ${\displaystyle 3\mathbf {b} _{1}+2\mathbf {b} _{2}}$ dan ${\displaystyle 2\mathbf {b} _{1}+3\mathbf {b} _{2}}$ yang berbeda memiliki himpunan koefisien ${\displaystyle \{2,\,3\}}$ yang sama. Oleh karena itu, konsep basis terurut umum digunakan untuk mempermudah pembahasan. Hal ini dilakukan dengan mengindeks elemen-elemen basis menggunakan bilangan asli. Koordinat dari vektor juga diindeks dengan cara yang sama, sehingga vektor dapat dikarakterisasi seutuhnya dari barisan koordinat mereka.

Misalkan, seperti biasa, ${\displaystyle F^{n}}$ adalah himpunan rangkap-n dari elemen-elemen di ${\displaystyle F}$). Himpunan ini adalah ruang vektor-${\displaystyle F}$, dengan operasi penjumlahan dan perkalian skalar-nya dilakukan secara komponen-demi-komponen. Pemetaan

adalah suatu isomorfisme linear dari ruang vektor ${\displaystyle F^{n}}$ pada (onto) ${\displaystyle V}$. Dalam kata lain, ${\displaystyle F^{n}}$ adalah ruang koordinat dari ${\displaystyle V}$, dan rangkap-n ${\displaystyle \varphi ^{-1}(\mathbf {v} )}$ adalah vektor koordinat dari ${\displaystyle \mathbf {v} }$. Secara khusus, invers bayangan dari ${\displaystyle \mathbf {b} _{i}}$ oleh ${\displaystyle \varphi }$ adalah vektor ${\displaystyle \mathbf {e} _{i}}$, yang setiap komponennya bernilai 0, kecuali komponen ke-i yang bernilai 1. Himpunan ${\displaystyle \mathbf {e} _{i}}$ membentuk suatu basis terurut bagi ${\displaystyle F^{n}}$, yang disebut dengan basis standar atau basis kanonik.

Perubahan basis

Let V be a vector space of dimension n over a field F. Given two (ordered) bases ${\displaystyle B_{\text{old}}=(\mathbf {v} _{1},\ldots ,\mathbf {v} _{n})}$ and ${\displaystyle B_{\text{new}}=(\mathbf {w} _{1},\ldots ,\mathbf {w} _{n})}$ of V, it is often useful to express the coordinates of a vector x with respect to ${\displaystyle B_{\mathrm {old} }}$ in terms of the coordinates with respect to ${\displaystyle B_{\mathrm {new} }.}$ This can be done by the change-of-basis formula, that is described below. The subscripts "old" and "new" have been chosen because it is customary to refer to ${\displaystyle B_{\mathrm {old} }}$ and ${\displaystyle B_{\mathrm {new} }}$ as the old basis and the new basis, respectively. It is useful to describe the old coordinates in terms of the new ones, because, in general, one has expressions involving the old coordinates, and if one wants to obtain equivalent expressions in terms of the new coordinates; this is obtained by replacing the old coordinates by their expressions in terms of the new coordinates.

---

Maka V jadilah terang dan pagi~ ruang vektor berdimensi n di atas bidang F. Diberikan dua pangkalan (order) ${\displaystyle B_{\mathrm {old} }=(v_{1},\ldots ,v_{n})}$ dan ${\displaystyle B_{\mathrm {new} }=(w_{1},\ldots ,w_{n})}$ dari V, sering kali berguna untuk menyatakan koordinat vektor x sehubungan dengan ${\displaystyle B_{\mathrm {old} }}$ dalam hal koordinat sehubungan dengan ${\displaystyle B_{\mathrm {new} }.}$ Ini dapat dilakukan dengan rumus perubahan-basis , yang dijelaskan di bawah ini. Subskrip "lama" dan "baru" telah dipilih karena biasa digunakan untuk merujuk ${\displaystyle B_{\mathrm {old} }}$ dan ${\displaystyle B_{\mathrm {new} }}$ sebagai dasar lama dan dasar baru . Ini berguna untuk menggambarkan koordinat lama dengan yang baru, karena, secara umum, seseorang memiliki ekspresi yang melibatkan koordinat lama, dan jika seseorang ingin mendapatkan ekspresi yang setara dalam hal koordinat baru; ini diperoleh dengan mengganti koordinat lama dengan ekspresi mereka dalam bentuk koordinat baru.

Biasanya, vektor basis baru diberikan oleh koordinatnya di atas basis lama, yaitu

${\displaystyle w_{j}=\sum _{i=1}^{n}a_{i,j}v_{i}.}$

If ${\displaystyle (x_{1},\ldots ,x_{n})}$ and ${\displaystyle (y_{1},\ldots ,y_{n})}$ are the coordinates of a vector x over the old and the new basis respectively, the change-of-basis formula is

${\displaystyle x_{i}=\sum _{j=1}^{n}a_{i,j}y_{j},}$

for i = 1, ..., n.

Rumus ini dapat ditulis secara ringkas dalam notasi matriks. Misalkan A adalah matriks dari ${\displaystyle a_{i,j},}$ dan

${\displaystyle X={\begin{pmatrix}x_{1}\\\vdots \\x_{n}\end{pmatrix}}\quad }$ dan ${\displaystyle \quad Y={\begin{pmatrix}y_{1}\\\vdots \\y_{n}\end{pmatrix}}}$

jadilah vektor kolom dari koordinat v di basis lama dan basis baru, maka rumus untuk mengubah koordinat adalah

${\displaystyle X=AY.}$

Rumusnya dapat dibuktikan dengan mempertimbangkan dekomposisi vektor x pada dua basa: satu memiliki

${\displaystyle x=\sum _{i=1}^{n}x_{i}v_{i},}$

dan

${\displaystyle {\begin{aligned}x&=\sum _{j=1}^{n}y_{j}w_{j}\\&=\sum _{j=1}^{n}y_{j}\sum _{i=1}^{n}a_{i,j}v_{i}\\&=\sum _{i=1}^{n}\left(\sum _{j=1}^{n}a_{i,j}y_{j}\right)v_{i}.\end{aligned}}}$

Rumus perubahan basis kemudian dari keunikan dekomposisi vektor atas basis, di sini ${\displaystyle B_{\mathrm {old} };}$ adalah

${\displaystyle x_{i}=\sum _{j=1}^{n}a_{i,j}y_{j},}$

untuk i = 1, ..., n.

Change of basis

Typically, the new basis vectors are given by their coordinates over the old basis, that is,

If ${\displaystyle (x_{1},\ldots ,x_{n})}$ and ${\displaystyle (y_{1},\ldots ,y_{n})}$ are the coordinates of a vector x over the old and the new basis respectively, the change-of-basis formula isfor i = 1, ..., n.

This formula may be concisely written in matrix notation. Let A be the matrix of the ${\displaystyle a_{i,j}}$, and

be the column vectors of the coordinates of v in the old and the new basis respectively, then the formula for changing coordinates isThe formula can be proven by considering the decomposition of the vector x on the two bases: one hasandThe change-of-basis formula results then from the uniqueness of the decomposition of a vector over a basis, here ${\displaystyle B_{\text{old}}}$; that isfor i = 1, ..., n.

Related notions

Free module

If one replaces the field occurring in the definition of a vector space by a ring, one gets the definition of a module. For modules, linear independence and spanning sets are defined exactly as for vector spaces, although "generating set" is more commonly used than that of "spanning set".

Like for vector spaces, a basis of a module is a linearly independent subset that is also a generating set. A major difference with the theory of vector spaces is that not every module has a basis. A module that has a basis is called a free module. Free modules play a fundamental role in module theory, as they may be used for describing the structure of non-free modules through free resolutions.

A module over the integers is exactly the same thing as an abelian group. Thus a free module over the integers is also a free abelian group. Free abelian groups have specific properties that are not shared by modules over other rings. Specifically, every subgroup of a free abelian group is a free abelian group, and, if G is a subgroup of a finitely generated free abelian group H (that is an abelian group that has a finite basis), then there is a basis ${\displaystyle \mathbf {e} _{1},\ldots ,\mathbf {e} _{n}}$ of H and an integer 0 ≤ k ≤ n such that ${\displaystyle a_{1}\mathbf {e} _{1},\ldots ,a_{k}\mathbf {e} _{k}}$ is a basis of G, for some nonzero integers ${\displaystyle a_{1},\ldots ,a_{k}}$. For details, see Free abelian group § Subgroups.

Analysis

In the context of infinite-dimensional vector spaces over the real or complex numbers, the term Hamel basis (named after Georg Hamel^[2]) or algebraic basis can be used to refer to a basis as defined in this article. This is to make a distinction with other notions of "basis" that exist when infinite-dimensional vector spaces are endowed with extra structure. The most important alternatives are orthogonal bases on Hilbert spaces, Schauder bases, and Markushevich bases on normed linear spaces. In the case of the real numbers R viewed as a vector space over the field Q of rational numbers, Hamel bases are uncountable, and have specifically the cardinality of the continuum, which is the cardinal number ${\displaystyle 2^{\aleph _{0}}}$, where ${\displaystyle \aleph _{0}}$ (aleph-nought) is the smallest infinite cardinal, the cardinal of the integers.

The common feature of the other notions is that they permit the taking of infinite linear combinations of the basis vectors in order to generate the space. This, of course, requires that infinite sums are meaningfully defined on these spaces, as is the case for topological vector spaces – a large class of vector spaces including e.g. Hilbert spaces, Banach spaces, or Fréchet spaces.

The preference of other types of bases for infinite-dimensional spaces is justified by the fact that the Hamel basis becomes "too big" in Banach spaces: If X is an infinite-dimensional normed vector space that is complete (i.e. X is a Banach space), then any Hamel basis of X is necessarily uncountable. This is a consequence of the Baire category theorem. The completeness as well as infinite dimension are crucial assumptions in the previous claim. Indeed, finite-dimensional spaces have by definition finite bases and there are infinite-dimensional (non-complete) normed spaces that have countable Hamel bases. Consider ${\displaystyle c_{00}}$, the space of the sequences ${\displaystyle x=(x_{n})}$ of real numbers that have only finitely many non-zero elements, with the norm ${\textstyle \|x\|=\sup _{n}|x_{n}|}$. Its standard basis, consisting of the sequences having only one non-zero element, which is equal to 1, is a countable Hamel basis.

Example

In the study of Fourier series, one learns that the functions {1} ∪ { sin(nx), cos(nx) : n = 1, 2, 3, ... } are an "orthogonal basis" of the (real or complex) vector space of all (real or complex valued) functions on the interval [0, 2π] that are square-integrable on this interval, i.e., functions f satisfying

The functions {1} ∪ { sin(nx), cos(nx) : n = 1, 2, 3, ... } are linearly independent, and every function f that is square-integrable on [0, 2π] is an "infinite linear combination" of them, in the sense thatfor suitable (real or complex) coefficients a_k, b_k. But many^[3] square-integrable functions cannot be represented as finite linear combinations of these basis functions, which therefore do not comprise a Hamel basis. Every Hamel basis of this space is much bigger than this merely countably infinite set of functions. Hamel bases of spaces of this kind are typically not useful, whereas orthonormal bases of these spaces are essential in Fourier analysis.

Geometry

The geometric notions of an affine space, projective space, convex set, and cone have related notions of basis.^[4] An affine basis for an n-dimensional affine space is ${\displaystyle n+1}$ points in general linear position. A projective basis is ${\displaystyle n+2}$ points in general position, in a projective space of dimension n. A convex basis of a polytope is the set of the vertices of its convex hull. A cone basis^[5] consists of one point by edge of a polygonal cone. See also a Hilbert basis (linear programming).

Random basis

For a probability distribution in Rⁿ with a probability density function, such as the equidistribution in an n-dimensional ball with respect to Lebesgue measure, it can be shown that n randomly and independently chosen vectors will form a basis with probability one, which is due to the fact that n linearly dependent vectors x₁, ..., x_n in Rⁿ should satisfy the equation det[x₁ ⋯ x_n] = 0 (zero determinant of the matrix with columns x_i), and the set of zeros of a non-trivial polynomial has zero measure. This observation has led to techniques for approximating random bases.^[6][7]

It is difficult to check numerically the linear dependence or exact orthogonality. Therefore, the notion of ε-orthogonality is used. For spaces with inner product, x is ε-orthogonal to y if ${\displaystyle \left|\left\langle x,y\right\rangle \right|/\left(\left\|x\right\|\left\|y\right\|\right)<\varepsilon }$ (that is, cosine of the angle between x and y is less than ε).

In high dimensions, two independent random vectors are with high probability almost orthogonal, and the number of independent random vectors, which all are with given high probability pairwise almost orthogonal, grows exponentially with dimension. More precisely, consider equidistribution in n-dimensional ball. Choose N independent random vectors from a ball (they are independent and identically distributed). Let θ be a small positive number. Then for

$${\displaystyle N\leq {\exp }{\bigl (}{\tfrac {1}{4}}\varepsilon ^{2}n{\bigr )}{\sqrt {-\ln(1-\theta )}}}$$

(Eq. 1)

N random vectors are all pairwise ε-orthogonal with probability 1 − θ.^[7] This N growth exponentially with dimension n and ${\displaystyle N\gg n}$ for sufficiently big n. This property of random bases is a manifestation of the so-called measure concentration phenomenon.^[8]

The figure (right) illustrates distribution of lengths N of pairwise almost orthogonal chains of vectors that are independently randomly sampled from the n-dimensional cube [−1, 1]ⁿ as a function of dimension, n. A point is first randomly selected in the cube. The second point is randomly chosen in the same cube. If the angle between the vectors was within π/2 ± 0.037π/2 then the vector was retained. At the next step a new vector is generated in the same hypercube, and its angles with the previously generated vectors are evaluated. If these angles are within π/2 ± 0.037π/2 then the vector is retained. The process is repeated until the chain of almost orthogonality breaks, and the number of such pairwise almost orthogonal vectors (length of the chain) is recorded. For each n, 20 pairwise almost orthogonal chains were constructed numerically for each dimension. Distribution of the length of these chains is presented.

Proof that every vector space has a basis

Let V be any vector space over some field F. Let X be the set of all linearly independent subsets of V.

The set X is nonempty since the empty set is an independent subset of V, and it is partially ordered by inclusion, which is denoted, as usual, by ⊆.

Let Y be a subset of X that is totally ordered by ⊆, and let L_Y be the union of all the elements of Y (which are themselves certain subsets of V).

Since (Y, ⊆) is totally ordered, every finite subset of L_Y is a subset of an element of Y, which is a linearly independent subset of V, and hence L_Y is linearly independent. Thus L_Y is an element of X. Therefore, L_Y is an upper bound for Y in (X, ⊆): it is an element of X, that contains every element of Y.

As X is nonempty, and every totally ordered subset of (X, ⊆) has an upper bound in X, Zorn's lemma asserts that X has a maximal element. In other words, there exists some element L_max of X satisfying the condition that whenever L_max ⊆ L for some element L of X, then L = L_max.

It remains to prove that L_max is a basis of V. Since L_max belongs to X, we already know that L_max is a linearly independent subset of V.

If there were some vector w of V that is not in the span of L_max, then w would not be an element of L_max either. Let L_w = L_max ∪ {w}. This set is an element of X, that is, it is a linearly independent subset of V (because w is not in the span of L_max, and L_max is independent). As L_max ⊆ L_w, and L_max ≠ L_w (because L_w contains the vector w that is not contained in L_max), this contradicts the maximality of L_max. Thus this shows that L_max spans V.

Hence L_max is linearly independent and spans V. It is thus a basis of V, and this proves that every vector space has a basis.

This proof relies on Zorn's lemma, which is equivalent to the axiom of choice. Conversely, it has been proved that if every vector space has a basis, then the axiom of choice is true.^[9] Thus the two assertions are equivalent.

Catatan kaki

Referensi

Referensi umum

• Blass, Andreas (1984), "Existence of bases implies the axiom of choice" (PDF), Axiomatic set theory, Contemporary Mathematics volume 31, Providence, R.I.: American Mathematical Society, hlm. 31–33, ISBN 978-0-8218-5026-8, MR 0763890 
• Brown, William A. (1991), Matrices and vector spaces, New York: M. Dekker, ISBN 978-0-8247-8419-5 
• Lang, Serge (1987), Linear algebra, Berlin, New York: Springer-Verlag, ISBN 978-0-387-96412-6 

Referensi sejarah

• Banach, Stefan (1922), "Sur les opérations dans les ensembles abstraits et leur application aux équations intégrales (On operations in abstract sets and their application to integral equations)" (PDF), Fundamenta Mathematicae (dalam bahasa Prancis), 3: 133–181, doi:10.4064/fm-3-1-133-181, ISSN 0016-2736 
• Bolzano, Bernard (1804), Betrachtungen über einige Gegenstände der Elementargeometrie (Considerations of some aspects of elementary geometry) (dalam bahasa Jerman) 
• Bourbaki, Nicolas (1969), Éléments d'histoire des mathématiques (Elements of history of mathematics) (dalam bahasa Prancis), Paris: Hermann 
• Dorier, Jean-Luc (1995), "A general outline of the genesis of vector space theory", Historia Mathematica, 22 (3): 227–261, doi:10.1006/hmat.1995.1024 , MR 1347828 
• Fourier, Jean Baptiste Joseph (1822), Théorie analytique de la chaleur (dalam bahasa Prancis), Chez Firmin Didot, père et fils 
• Grassmann, Hermann (1844), Die Lineale Ausdehnungslehre - Ein neuer Zweig der Mathematik (dalam bahasa Jerman) , reprint: Hermann Grassmann. Translated by Lloyd C. Kannenberg. (2000), Extension Theory, Kannenberg, L.C., Providence, R.I.: American Mathematical Society, ISBN 978-0-8218-2031-5 
• Hamel, Georg (1905), "Eine Basis aller Zahlen und die unstetigen Lösungen der Funktionalgleichung f(x+y)=f(x)+f(y)", Mathematische Annalen (dalam bahasa Jerman), Leipzig, 60 (3): 459–462, doi:10.1007/BF01457624  Parameter |s2cid= yang tidak diketahui akan diabaikan (bantuan)
• Hamilton, William Rowan (1853), Lectures on Quaternions, Royal Irish Academy 
• Möbius, August Ferdinand (1827), Der Barycentrische Calcul : ein neues Hülfsmittel zur analytischen Behandlung der Geometrie (Barycentric calculus: a new utility for an analytic treatment of geometry) (dalam bahasa Jerman), diarsipkan dari versi asli tanggal 2009-04-12  Parameter |url-status= yang tidak diketahui akan diabaikan (bantuan)
• Moore, Gregory H. (1995), "The axiomatization of linear algebra: 1875–1940", Historia Mathematica, 22 (3): 262–303, doi:10.1006/hmat.1995.1025  
• Peano, Giuseppe (1888), Calcolo Geometrico secondo l'Ausdehnungslehre di H. Grassmann preceduto dalle Operazioni della Logica Deduttiva (dalam bahasa Italia), Turin 

Pranala luar

• Video pembelajaran dari Khan Academy (bahasa Inggris)
  • Introduction to bases of subspaces
  • Proof that any subspace basis has same number of elements
• "Linear combinations, span, and basis vectors". Essence of linear algebra. August 6, 2016. Diarsipkan dari versi asli tanggal 2021-11-17 – via YouTube.  Parameter |url-status= yang tidak diketahui akan diabaikan (bantuan)
• Hazewinkel, Michiel, ed. (2001) [1994], "Basis", Encyclopedia of Mathematics, Springer Science+Business Media B.V. / Kluwer Academic Publishers, ISBN 978-1-55608-010-4