Linear Independence

A set of vectors ∀x,xi∈ℂn: x1x2…xk x x i n x 1 x 2 … x k are linearly independent if none of them can be written as a linear combination of the others.

Definition 1: Linearly Independent

For a given set of vectors, x1x2…xn x 1 x 2 … x n , they are linearly independent if c 1 x1+ c 2 x2+…+ c n xn=0 c 1 x 1 c 2 x 2 … c n x n 0 only when c 1 = c 2 =…= c n =0 c 1 c 2 … c n 0

Example

We are given the following two vectors: x1= 32 x 1 3 2 x2= -6-4 x 2 -6 -4 These are not linearly independent as proven by the following statement, which, by inspection, can be seen to not adhere to the definition of linear independence stated above. x2=-2x1⇒2x1+x2=0 x 2 -2 x 1 2 x 1 x 2 0 Another approach to reveal a vectors independence is by graphing the vectors. Looking at these two vectors geometrically (as in Figure 1), one can again prove that these vectors are not linearly independent.

Figure 1: Graphical representation of two vectors that are not linearly independent.

Figure 2: Graphical representation of two vectors that are linearly independent.

As we have seen in the two above examples, often times the independence of vectors can be easily seen through a graph. However this may not be as easy when we are given three or more vectors. Can you easily tell whether or not these vectors are independent from Figure 3. Probably not, which is why the method used in the above solution becomes important.

Figure 3: Plot of the three vectors. Can be shown that a linear combination exists among the three, and therefore they are not linear independent.

Span

Definition 2: Span

The span of a set of vectors x1x2…xk x 1 x 2 … x k is the set of vectors that can be written as a linear combination of x1x2…xk x 1 x 2 … x k span x1…xk = ∀α, α i ∈ℂn: α 1 x1+ α 2 x2+…+ α k xk span x 1 … x k α α i n α 1 x 1 α 2 x 2 … α k x k

Example

Given the vector x1= 32 x 1 3 2 the span of x1 x 1 is a line.

Example

Given the vectors x1= 32 x 1 3 2 x2= 12 x 2 1 2 the span of these vectors is ℂ2 2 .

Basis

Definition 3: Basis

A basis for ℂn n is a set of vectors that: (1) spans ℂn n and (2) is linearly independent.

Figure 4: Plot of basis for ℂ2 2

If b1…b2 b 1 … b 2 is a basis for ℂn n , then we can express any x∈ℂn x n as a linear combination of the b i b i 's: ∀α, α i ∈ℂ:x= α 1 b1+ α 2 b2+…+ α n bn α α i x α 1 b 1 α 2 b 2 … α n b n

In the two basis examples above, x x is the same vector in both cases, but we can express it in many different ways (we give only two out of many, many possibilities). You can take this even further by extending this idea of a basis to function spaces.