Linearly Independent
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In the theory of
vector space In mathematics and physics, a vector space (also called a linear space) is a set whose elements, often called '' vectors'', may be added together and multiplied ("scaled") by numbers called ''scalars''. Scalars are often real numbers, but can ...
s, a
set Set, The Set, SET or SETS may refer to: Science, technology, and mathematics Mathematics *Set (mathematics), a collection of elements *Category of sets, the category whose objects and morphisms are sets and total functions, respectively Electro ...
of
vector Vector most often refers to: *Euclidean vector, a quantity with a magnitude and a direction *Vector (epidemiology), an agent that carries and transmits an infectious pathogen into another living organism Vector may also refer to: Mathematic ...
s is said to be if there is a nontrivial linear combination of the vectors that equals the zero vector. If no such linear combination exists, then the vectors are said to be . These concepts are central to the definition of
dimension In physics and mathematics, the dimension of a mathematical space (or object) is informally defined as the minimum number of coordinates needed to specify any point within it. Thus, a line has a dimension of one (1D) because only one coord ...
. A vector space can be of finite dimension or infinite dimension depending on the maximum number of linearly independent vectors. The definition of linear dependence and the ability to determine whether a subset of vectors in a vector space is linearly dependent are central to determining the dimension of a vector space.


Definition

A sequence of vectors \mathbf_1, \mathbf_2, \dots, \mathbf_k from a
vector space In mathematics and physics, a vector space (also called a linear space) is a set whose elements, often called '' vectors'', may be added together and multiplied ("scaled") by numbers called ''scalars''. Scalars are often real numbers, but can ...
is said to be ''linearly dependent'', if there exist
scalars Scalar may refer to: * Scalar (mathematics), an element of a field, which is used to define a vector space, usually the field of real numbers * Scalar (physics), a physical quantity that can be described by a single element of a number field such ...
a_1, a_2, \dots, a_k, not all zero, such that :a_1\mathbf_1 + a_2\mathbf_2 + \cdots + a_k\mathbf_k = \mathbf, where \mathbf denotes the zero vector. This implies that at least one of the scalars is nonzero, say a_1\ne 0, and the above equation is able to be written as :\mathbf_1 = \frac\mathbf_2 + \cdots + \frac \mathbf_k, if k>1, and \mathbf_1 = \mathbf if k=1. Thus, a set of vectors is linearly dependent if and only if one of them is zero or a linear combination of the others. A sequence of vectors \mathbf_1, \mathbf_2, \dots, \mathbf_n is said to be ''linearly independent'' if it is not linearly dependent, that is, if the equation :a_1\mathbf_1 + a_2 \mathbf_2 + \cdots + a_n\mathbf_n = \mathbf, can only be satisfied by a_i=0 for i=1,\dots,n. This implies that no vector in the sequence can be represented as a linear combination of the remaining vectors in the sequence. In other words, a sequence of vectors is linearly independent if the only representation of \mathbf 0 as a linear combination of its vectors is the trivial representation in which all the scalars a_i are zero. Even more concisely, a sequence of vectors is linearly independent if and only if \mathbf 0 can be represented as a linear combination of its vectors in a unique way. If a sequence of vectors contains the same vector twice, it is necessarily dependent. The linear dependency of a sequence of vectors does not depend of the order of the terms in the sequence. This allows defining linear independence for a finite set of vectors: A finite set of vectors is ''linearly independent'' if the sequence obtained by ordering them is linearly independent. In other words, one has the following result that is often useful. A sequence of vectors is linearly independent if and only if it does not contain the same vector twice and the set of its vectors is linearly independent.


Infinite case

An infinite set of vectors is ''linearly independent'' if every nonempty finite
subset In mathematics, set ''A'' is a subset of a set ''B'' if all elements of ''A'' are also elements of ''B''; ''B'' is then a superset of ''A''. It is possible for ''A'' and ''B'' to be equal; if they are unequal, then ''A'' is a proper subset of ...
is linearly independent. Conversely, an infinite set of vectors is ''linearly dependent'' if it contains a finite subset that is linearly dependent, or equivalently, if some vector in the set is a linear combination of other vectors in the set. An
indexed family In mathematics, a family, or indexed family, is informally a collection of objects, each associated with an index from some index set. For example, a ''family of real numbers, indexed by the set of integers'' is a collection of real numbers, wher ...
of vectors is ''linearly independent'' if it does not contain the same vector twice, and if the set of its vectors is linearly independent. Otherwise, the family is said ''linearly dependent''. A set of vectors which is linearly independent and spans some vector space, forms a basis for that vector space. For example, the vector space of all
polynomial In mathematics, a polynomial is an expression consisting of indeterminates (also called variables) and coefficients, that involves only the operations of addition, subtraction, multiplication, and positive-integer powers of variables. An exampl ...
s in over the reals has the (infinite) subset as a basis.


Geometric examples

* \vec u and \vec v are independent and define the plane P. * \vec u, \vec v and \vec w are dependent because all three are contained in the same plane. * \vec u and \vec j are dependent because they are parallel to each other. * \vec u , \vec v and \vec k are independent because \vec u and \vec v are independent of each other and \vec k is not a linear combination of them or, equivalently, because they do not belong to a common plane. The three vectors define a three-dimensional space. * The vectors \vec o (null vector, whose components are equal to zero) and \vec k are dependent since \vec o = 0 \vec k


Geographic location

A person describing the location of a certain place might say, "It is 3 miles north and 4 miles east of here." This is sufficient information to describe the location, because the geographic coordinate system may be considered as a 2-dimensional vector space (ignoring altitude and the curvature of the Earth's surface). The person might add, "The place is 5 miles northeast of here." This last statement is ''true'', but it is not necessary to find the location. In this example the "3 miles north" vector and the "4 miles east" vector are linearly independent. That is to say, the north vector cannot be described in terms of the east vector, and vice versa. The third "5 miles northeast" vector is a linear combination of the other two vectors, and it makes the set of vectors ''linearly dependent'', that is, one of the three vectors is unnecessary to define a specific location on a plane. Also note that if altitude is not ignored, it becomes necessary to add a third vector to the linearly independent set. In general, linearly independent vectors are required to describe all locations in -dimensional space.


Evaluating linear independence


The zero vector

If one or more vectors from a given sequence of vectors \mathbf_1, \dots, \mathbf_k is the zero vector \mathbf then the vector \mathbf_1, \dots, \mathbf_k are necessarily linearly dependent (and consequently, they are not linearly independent). To see why, suppose that i is an index (i.e. an element of \) such that \mathbf_i = \mathbf. Then let a_ := 1 (alternatively, letting a_ be equal any other non-zero scalar will also work) and then let all other scalars be 0 (explicitly, this means that for any index j other than i (i.e. for j \neq i), let a_ := 0 so that consequently a_ \mathbf_j = 0 \mathbf_j = \mathbf). Simplifying a_1 \mathbf_1 + \cdots + a_k\mathbf_k gives: :a_1 \mathbf_1 + \cdots + a_k\mathbf_k = \mathbf + \cdots + \mathbf + a_i \mathbf_i + \mathbf + \cdots + \mathbf = a_i \mathbf_i = a_i \mathbf = \mathbf. Because not all scalars are zero (in particular, a_ \neq 0), this proves that the vectors \mathbf_1, \dots, \mathbf_k are linearly dependent. As a consequence, the zero vector can not possibly belong to any collection of vectors that is linearly ''in''dependent. Now consider the special case where the sequence of \mathbf_1, \dots, \mathbf_k has length 1 (i.e. the case where k = 1). A collection of vectors that consists of exactly one vector is linearly dependent if and only if that vector is zero. Explicitly, if \mathbf_1 is any vector then the sequence \mathbf_1 (which is a sequence of length 1) is linearly dependent if and only if alternatively, the collection \mathbf_1 is linearly independent if and only if \mathbf_1 \neq \mathbf.


Linear dependence and independence of two vectors

This example considers the special case where there are exactly two vector \mathbf and \mathbf from some real or complex vector space. The vectors \mathbf and \mathbf are linearly dependent
if and only if In logic and related fields such as mathematics and philosophy, "if and only if" (shortened as "iff") is a biconditional logical connective between statements, where either both statements are true or both are false. The connective is bic ...
at least one of the following is true: # \mathbf is a scalar multiple of \mathbf (explicitly, this means that there exists a scalar c such that \mathbf = c \mathbf) or # \mathbf is a scalar multiple of \mathbf (explicitly, this means that there exists a scalar c such that \mathbf = c \mathbf). If \mathbf = \mathbf then by setting c := 0 we have c \mathbf = 0 \mathbf = \mathbf = \mathbf (this equality holds no matter what the value of \mathbf is), which shows that (1) is true in this particular case. Similarly, if \mathbf = \mathbf then (2) is true because \mathbf = 0 \mathbf. If \mathbf = \mathbf (for instance, if they are both equal to the zero vector \mathbf) then ''both'' (1) and (2) are true (by using c := 1 for both). If \mathbf = c \mathbf then \mathbf \neq \mathbf is only possible if c \neq 0 ''and'' \mathbf \neq \mathbf; in this case, it is possible to multiply both sides by \frac to conclude \mathbf = \frac \mathbf. This shows that if \mathbf \neq \mathbf and \mathbf \neq \mathbf then (1) is true if and only if (2) is true; that is, in this particular case either both (1) and (2) are true (and the vectors are linearly dependent) or else both (1) and (2) are false (and the vectors are linearly ''in''dependent). If \mathbf = c \mathbf but instead \mathbf = \mathbf then at least one of c and \mathbf must be zero. Moreover, if exactly one of \mathbf and \mathbf is \mathbf (while the other is non-zero) then exactly one of (1) and (2) is true (with the other being false). The vectors \mathbf and \mathbf are linearly ''in''dependent if and only if \mathbf is not a scalar multiple of \mathbf ''and'' \mathbf is not a scalar multiple of \mathbf.


Vectors in R2

Three vectors: Consider the set of vectors \mathbf_1 = (1, 1), \mathbf_2 = (-3, 2), and \mathbf_3 = (2, 4), then the condition for linear dependence seeks a set of non-zero scalars, such that :a_1 \begin 1\\1\end + a_2 \begin -3\\2\end + a_3 \begin 2\\4\end =\begin 0\\0\end, or :\begin 1 & -3 & 2 \\ 1 & 2 & 4 \end\begin a_1\\ a_2 \\ a_3 \end= \begin 0\\0\end. Row reduce this matrix equation by subtracting the first row from the second to obtain, :\begin 1 & -3 & 2 \\ 0 & 5 & 2 \end\begin a_1\\ a_2 \\ a_3 \end= \begin 0\\0\end. Continue the row reduction by (i) dividing the second row by 5, and then (ii) multiplying by 3 and adding to the first row, that is :\begin 1 & 0 & 16/5 \\ 0 & 1 & 2/5 \end\begin a_1\\ a_2 \\ a_3 \end= \begin 0\\0\end. Rearranging this equation allows us to obtain :\begin 1 & 0 \\ 0 & 1 \end\begin a_1\\ a_2 \end= \begin a_1\\ a_2 \end=-a_3\begin 16/5\\2/5\end. which shows that non-zero ''a''''i'' exist such that \mathbf_3 = (2, 4) can be defined in terms of \mathbf_1 = (1, 1) and \mathbf_2 = (-3, 2). Thus, the three vectors are linearly dependent. Two vectors: Now consider the linear dependence of the two vectors \mathbf_1 = (1, 1) and \mathbf_2 = (-3, 2), and check, :a_1 \begin 1\\1\end + a_2 \begin -3\\2\end =\begin 0\\0\end, or :\begin 1 & -3 \\ 1 & 2 \end\begin a_1\\ a_2 \end= \begin 0\\0\end. The same row reduction presented above yields, :\begin 1 & 0 \\ 0 & 1 \end\begin a_1\\ a_2 \end= \begin 0\\0\end. This shows that a_i = 0, which means that the vectors ''v''1 = (1, 1) and ''v''2 = (−3, 2) are linearly independent.


Vectors in R4

In order to determine if the three vectors in \mathbb^4, :\mathbf_1= \begin1\\4\\2\\-3\end, \mathbf_2=\begin7\\10\\-4\\-1\end, \mathbf_3=\begin-2\\1\\5\\-4\end. are linearly dependent, form the matrix equation, :\begin1&7&-2\\4& 10& 1\\2&-4&5\\-3&-1&-4\end\begin a_1\\ a_2 \\ a_3 \end = \begin0\\0\\0\\0\end. Row reduce this equation to obtain, :\begin 1& 7 & -2 \\ 0& -18& 9\\ 0 & 0 & 0\\ 0& 0& 0\end \begin a_1\\ a_2 \\ a_3 \end = \begin0\\0\\0\\0\end. Rearrange to solve for v3 and obtain, :\begin 1& 7 \\ 0& -18 \end \begin a_1\\ a_2 \end = -a_3\begin-2\\9\end. This equation is easily solved to define non-zero ''a''i, :a_1 = -3 a_3 /2, a_2 = a_3/2, where a_3 can be chosen arbitrarily. Thus, the vectors \mathbf_1, \mathbf_2, and \mathbf_3 are linearly dependent.


Alternative method using determinants

An alternative method relies on the fact that n vectors in \mathbb^n are linearly independent
if and only if In logic and related fields such as mathematics and philosophy, "if and only if" (shortened as "iff") is a biconditional logical connective between statements, where either both statements are true or both are false. The connective is bic ...
the
determinant In mathematics, the determinant is a scalar value that is a function of the entries of a square matrix. It characterizes some properties of the matrix and the linear map represented by the matrix. In particular, the determinant is nonzero if and ...
of the
matrix Matrix most commonly refers to: * ''The Matrix'' (franchise), an American media franchise ** ''The Matrix'', a 1999 science-fiction action film ** "The Matrix", a fictional setting, a virtual reality environment, within ''The Matrix'' (franchis ...
formed by taking the vectors as its columns is non-zero. In this case, the matrix formed by the vectors is :A = \begin1&-3\\1&2\end . We may write a linear combination of the columns as :A \Lambda = \begin1&-3\\1&2\end \begin\lambda_1 \\ \lambda_2 \end . We are interested in whether for some nonzero vector Λ. This depends on the determinant of A, which is :\det A = 1\cdot2 - 1\cdot(-3) = 5 \ne 0. Since the
determinant In mathematics, the determinant is a scalar value that is a function of the entries of a square matrix. It characterizes some properties of the matrix and the linear map represented by the matrix. In particular, the determinant is nonzero if and ...
is non-zero, the vectors (1, 1) and (-3, 2) are linearly independent. Otherwise, suppose we have m vectors of n coordinates, with m < n. Then ''A'' is an ''m''×''n'' matrix and Λ is a column vector with m entries, and we are again interested in ''A''Λ = 0. As we saw previously, this is equivalent to a list of n equations. Consider the first m rows of A, the first m equations; any solution of the full list of equations must also be true of the reduced list. In fact, if is any list of m rows, then the equation must be true for those rows. :A_ \Lambda = \mathbf . Furthermore, the reverse is true. That is, we can test whether the m vectors are linearly dependent by testing whether :\det A_ = 0 for all possible lists of m rows. (In case m = n, this requires only one determinant, as above. If m > n, then it is a theorem that the vectors must be linearly dependent.) This fact is valuable for theory; in practical calculations more efficient methods are available.


More vectors than dimensions

If there are more vectors than dimensions, the vectors are linearly dependent. This is illustrated in the example above of three vectors in \R^2.


Natural basis vectors

Let V = \R^n and consider the following elements in V, known as the natural basis vectors: :\begin \mathbf_1 & = & (1,0,0,\ldots,0) \\ \mathbf_2 & = & (0,1,0,\ldots,0) \\ & \vdots \\ \mathbf_n & = & (0,0,0,\ldots,1).\end Then \mathbf_1, \mathbf_2, \ldots, \mathbf_n are linearly independent.


Linear independence of functions

Let V be the
vector space In mathematics and physics, a vector space (also called a linear space) is a set whose elements, often called '' vectors'', may be added together and multiplied ("scaled") by numbers called ''scalars''. Scalars are often real numbers, but can ...
of all differentiable
function Function or functionality may refer to: Computing * Function key, a type of key on computer keyboards * Function model, a structured representation of processes in a system * Function object or functor or functionoid, a concept of object-oriente ...
s of a real variable t. Then the functions e^t and e^ in V are linearly independent.


Proof

Suppose a and b are two real numbers such that :ae ^ t + be ^ = 0 Take the first derivative of the above equation: :ae ^ t + 2be ^ = 0 for values of t. We need to show that a = 0 and b = 0. In order to do this, we subtract the first equation from the second, giving be^ = 0. Since e^ is not zero for some t, b=0. It follows that a = 0 too. Therefore, according to the definition of linear independence, e^ and e^ are linearly independent.


Space of linear dependencies

A linear dependency or
linear relation In linear algebra, a linear relation, or simply relation, between elements of a vector space or a module is a linear equation that has these elements as a solution. More precisely, if e_1,\dots,e_n are elements of a (left) module over a ring ...
among vectors is a
tuple In mathematics, a tuple is a finite ordered list (sequence) of elements. An -tuple is a sequence (or ordered list) of elements, where is a non-negative integer. There is only one 0-tuple, referred to as ''the empty tuple''. An -tuple is defi ...
with
scalar Scalar may refer to: *Scalar (mathematics), an element of a field, which is used to define a vector space, usually the field of real numbers * Scalar (physics), a physical quantity that can be described by a single element of a number field such ...
components such that :a_1 \mathbf_1 + \cdots + a_n \mathbf_n= \mathbf. If such a linear dependence exists with at least a nonzero component, then the vectors are linearly dependent. Linear dependencies among form a vector space. If the vectors are expressed by their coordinates, then the linear dependencies are the solutions of a homogeneous system of linear equations, with the coordinates of the vectors as coefficients. A basis of the vector space of linear dependencies can therefore be computed by
Gaussian elimination In mathematics, Gaussian elimination, also known as row reduction, is an algorithm for solving systems of linear equations. It consists of a sequence of operations performed on the corresponding matrix of coefficients. This method can also be used ...
.


Generalizations


Affine independence

A set of vectors is said to be affinely dependent if at least one of the vectors in the set can be defined as an
affine combination In mathematics, an affine combination of is a linear combination : \sum_^ = \alpha_ x_ + \alpha_ x_ + \cdots +\alpha_ x_, such that :\sum_^ =1. Here, can be elements ( vectors) of a vector space over a field , and the coefficients \alpha_ ...
of the others. Otherwise, the set is called affinely independent. Any affine combination is a linear combination; therefore every affinely dependent set is linearly dependent. Conversely, every linearly independent set is affinely independent. Consider a set of m vectors \mathbf_1, \ldots, \mathbf_m of size n each, and consider the set of m augmented vectors \left(\left begin 1 \\ \mathbf_1\end\right \ldots, \left begin1 \\ \mathbf_m\end\rightright) of size n + 1 each. The original vectors are affinely independent if and only if the augmented vectors are linearly independent.


Linearly independent vector subspaces

Two vector subspaces M and N of a vector space X are said to be if M \cap N = \. More generally, a collection M_1, \ldots, M_d of subspaces of X are said to be if M_i \cap \sum_ M_k = \ for every index i, where \sum_ M_k = \Big\ = \operatorname \bigcup_ M_k. The vector space X is said to be a of M_1, \ldots, M_d if these subspaces are linearly independent and M_1 + \cdots + M_d = X.


See also

*


References

*


External links

*
Linearly Dependent Functions
at WolframMathWorld.

on Linear Independence.
Introduction to Linear Independence
at KhanAcademy. {{Matrix classes Abstract algebra Linear algebra Articles containing proofs