Math Is Fun Forum

  Discussion about math, puzzles, games and fun.   Useful symbols: ÷ × ½ √ ∞ ≠ ≤ ≥ ≈ ⇒ ± ∈ Δ θ ∴ ∑ ∫ • π ƒ -¹ ² ³ °

You are not logged in.

Pages: 1

#1 2008-04-26 02:28:55

Janiffer
Member
Registered: 2008-04-26
Posts: 12

onto and one to one

hey... Suppose a linear transformation T is defined by a 4x3 matrix, can T be onto?

Offline

#2 2008-04-26 08:25:33

mikau
Member
Registered: 2005-08-22
Posts: 1,504

Re: onto and one to one

I think you were trying to ask... can T be one to one?

One to one, after a quick googling, means injective. That means if your mapping is from V to W and v and u are both elements of V, then

in otherwords, if the input values are unequal, then the output values are unequal, and vice versa. This is what one to one means. The more formal term for this type of mapping is 'injective'

Assume the mapping is injective.
suppose we consider the natural basis elements of V


In order to be injective, we have that

must all be unique. However, we know that these are all values in a 3 dimensional vector space, and therefore they cannot be linearly independent. This means that there is one value which can be expressed as a linear combination of the others. Suppose, after a suitable relabeling of indexes,  that T(v[sub]4[/sub]) is this value. We have then, for some scalers

that

applying the properties of a linear transformation, this means 

since T is injective, we must have that


we know that because, if they weren't equal, then the mapping of each would be unequal.

BUT 


implies that the basis elements of the 4 dimensional vector space, are linearly dependant. Since they are a basis, we have a contradiction.

Therefore, the mapping cannot be injective, or 'one to one'.

Last edited by mikau (2008-04-26 08:38:30)

A logarithm is just a misspelled algorithm.

Offline

#3 2008-04-26 11:16:11

JaneFairfax
Member
Registered: 2007-02-23
Posts: 6,868

Re: onto and one to one

Mikau, you didn’t answered the actual question: Can T be onto (i.e. surjective)? In any case, your analysis is wrong: T is a mapping from

to
, not the other way round.

There do indeed exist injective linear transformations defined by 4×3 matrices. For example

is injective. The transformation matrix is

Now try and prove that no linear mapping from

to
can be surjective.

Offline

#4 2008-04-26 11:35:21

mathsyperson
Moderator
Registered: 2005-06-22
Posts: 4,900

Re: onto and one to one

I think you could define a surjective map with a 4x3 matrix as long as the domain and codomain were appropriate. Say,

, for example.

(I'm not sure if that one actually works, but something like it would.)

Why did the vector cross the road?
It wanted to be normal.

Offline

#5 2008-04-26 12:04:40

JaneFairfax
Member
Registered: 2007-02-23
Posts: 6,868

Re: onto and one to one

I think not! shame

Definition: If V and W are vector spaces over the same field, a mapping T:VW is called a linear transformation iff for all vectors u, v in V and all scalars a, b, T(au+bv) = aT(u)+bT(v).

The image of V under the linear transformation T, T(V), is a subspace of W.

Theorem: dim(T(V)) ≤ dim(V).

Proof. Let dim(V) = n and suppose w[sub]1[/sub], …, w[sub]n[/sub], w[sub]n+1[/sub] are n+1 vectors in T(V). Then there are vectors v[sub]1[/sub], …, v[sub]n[/sub], v[sub]n+1[/sub] in V such that T(v[sub]i[/sub]) = w[sub]i[/sub], i = 1, …, n+1. Since the v[sub]i[/sub]’s are linearly dependent, one of them is a linear combination of the others, say v[sub]n+1[/sub]. It follows that w[sub]n+1[/sub] = T(v[sub]n+1[/sub]) is a linear combination of the other w[sub]i[/sub]’s; hence the w[sub]i[/sub]’s are linearly dependent. So any set of n+1 vectors in T(V) are linearly dependent; therefore dim(T(V)) < n+1.

By the way,

is not a vector space.

Last edited by JaneFairfax (2008-04-26 12:43:38)

Offline

#6 2008-04-26 12:26:05

JaneFairfax
Member
Registered: 2007-02-23
Posts: 6,868

Re: onto and one to one

Here is the answer to Janiffer’s question in less abstract verbiage.

shame

Offline

#7 2008-04-26 12:28:09

Janiffer
Member
Registered: 2008-04-26
Posts: 12

Re: onto and one to one

Thanks a lot guys;))

Offline

#8 2008-04-26 23:01:44

mathsyperson
Moderator
Registered: 2005-06-22
Posts: 4,900

Re: onto and one to one

Oh, I didn't realise linear transformations were restricted to being on vector spaces.
In that case, what about:

Why did the vector cross the road?
It wanted to be normal.

Offline

#9 2008-04-26 23:35:33

JaneFairfax
Member
Registered: 2007-02-23
Posts: 6,868

Re: onto and one to one

Yup, that’s a linear transformation. If V and W are nontrivial vector spaces (i.e. not {0}) there are always at least two linear transformations between them: the identity map, and the one that maps everything in V to 0[sub]W[/sub].

Offline

#10 2008-05-28 23:35:30

mikau
Member
Registered: 2005-08-22
Posts: 1,504

Re: onto and one to one

JaneFairfax wrote:

Mikau, you didn’t answered the actual question: Can T be onto (i.e. surjective)? In any case, your analysis is wrong: T is a mapping from

to
, not the other way round.

wow! I didn't even see this until just now.

argh! Row major format, of course! *face slap* silly me!

but I've never heard the term 'onto' to mean surjective. Thats weird!

A logarithm is just a misspelled algorithm.

Offline

Pages: 1

Board footer

Powered by FluxBB