Vector Inverse is Negative Vector
Theorem
Let $F$ be a field whose zero is $0_F$ and whose unity is $1_F$.
Let $\struct {\mathbf V, +, \circ}_F$ be a vector space over $F$, as defined by the vector space axioms.
Then:
- $\forall \mathbf v \in \mathbf V: -\mathbf v = -1_F \circ \mathbf v$
Proof
| \(\ds \mathbf v + \paren {-1_F \circ \mathbf v}\) | \(=\) | \(\ds \paren {1_F \circ \mathbf v} + \paren {-1_F \circ \mathbf v}\) | Field Axiom $\text M3$: Identity for Product | |||||||||||
| \(\ds \) | \(=\) | \(\ds \paren {1_F + \paren {- 1_F} } \circ \mathbf v\) | Vector Space Axiom $(\text V 5)$: Distributivity over Scalar Addition | |||||||||||
| \(\ds \) | \(=\) | \(\ds 0_F \circ \mathbf v\) | Field Axiom $\text A4$: Inverses for Addition | |||||||||||
| \(\ds \) | \(=\) | \(\ds \mathbf 0\) | Vector Scaled by Zero is Zero Vector |
so $-1_F \circ \mathbf v$ is an additive inverse of $\mathbf v$.
From Additive Inverse in Vector Space is Unique:
- $-1_F \circ \mathbf v = -\mathbf v$
$\blacksquare$
Sources
- 1965: Claude Berge and A. Ghouila-Houri: Programming, Games and Transportation Networks ... (previous) ... (next): $1$. Preliminary ideas; sets, vector spaces: $1.2$. Vector Spaces
- 1969: C.R.J. Clapham: Introduction to Abstract Algebra ... (previous) ... (next): Chapter $7$: Vector Spaces: $\S 32$. Definition of a Vector Space: Theorem $64 \ \text{(v)}$