Prove a few theorems about vector spaces using the axioms

In summary, the axioms of vector spaces are a set of rules that define the properties of vector spaces, including closure under addition and scalar multiplication, associativity, commutativity, existence of an additive identity and inverse, and distributivity. These axioms can be used to prove various properties of vector spaces, such as closure under addition and the existence of an additive identity. Additionally, using axioms to prove theorems about vector spaces ensures the validity and applicability of these conclusions to all vector spaces.
  • #1
ataraxia
1
0
Hey guys,

I need to prove a few theorems about vector spaces using the axioms.

a) Prove: if -v = v, then v = 0

b) Prove: (-r)v = -(rv)

c) Prove: r(-v) = -(rv)

d) Prove: v - (-w) = v + w

where r is a scalar and v, w are vectors.
 
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  • #2
really, you need to do those yourself.
 

1. What are the axioms of vector spaces?

The axioms of vector spaces are a set of rules that define the properties of vector spaces. These include closure under addition and scalar multiplication, associativity, commutativity, existence of an additive identity and inverse, and distributivity.

2. How do you prove closure under addition in a vector space?

Closure under addition can be proven by showing that the sum of any two vectors in the space is also a vector in the space. This can be done by applying the axioms of vector spaces, such as associativity and commutativity, to the addition of the two vectors.

3. Can you give an example of proving the existence of an additive identity in a vector space?

Yes, in a vector space V, the zero vector, denoted as 0, is the additive identity. This means that for any vector v in V, v + 0 = v. This can be proven by using the axioms of vector spaces, specifically the existence of an additive inverse. Since v + (-v) = 0, we can conclude that 0 is the additive identity.

4. How do you prove the distributivity of scalar multiplication over vector addition in a vector space?

The distributivity property states that for any scalar c and vectors v and w in a vector space V, c(v + w) = cv + cw. This can be proven by using the axioms of vector spaces, specifically associativity and distributivity of scalar multiplication over scalar addition. By applying these axioms, we can show that c(v + w) = cv + cw, thus proving the distributivity property.

5. What is the significance of proving theorems about vector spaces using axioms?

Proving theorems about vector spaces using axioms is important because it allows us to establish a solid foundation for the properties and behaviors of vector spaces. By using the axioms as the basis for our proofs, we can ensure that our conclusions are valid and applicable to all vector spaces, regardless of their specific characteristics or dimensions.

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