Incidence matrix of a simple graph #
This file defines the unoriented incidence matrix of a simple graph.
Main definitions #
SimpleGraph.incMatrix
:G.incMatrix R
is the incidence matrix ofG
over the ringR
.
Main results #
SimpleGraph.incMatrix_mul_transpose_diag
: The diagonal entries of the product ofG.incMatrix R
and its transpose are the degrees of the vertices.SimpleGraph.incMatrix_mul_transpose
: Gives a complete description of the product ofG.incMatrix R
and its transpose; the diagonal is the degrees of each vertex, and the off-diagonals are 1 or 0 depending on whether or not the vertices are adjacent.SimpleGraph.incMatrix_transpose_mul_diag
: The diagonal entries of the product of the transpose ofG.incMatrix R
andG.inc_matrix R
are2
or0
depending on whether or not the unordered pair is an edge ofG
.
Implementation notes #
The usual definition of an incidence matrix has one row per vertex and one column per edge.
However, this definition has columns indexed by all of Sym2 α
, where α
is the vertex type.
This appears not to change the theory, and for simple graphs it has the nice effect that every
incidence matrix for each SimpleGraph α
has the same type.
TODO #
- Define the oriented incidence matrices for oriented graphs.
- Define the graph Laplacian of a simple graph using the oriented incidence matrix from an arbitrary orientation of a simple graph.
noncomputable def
SimpleGraph.incMatrix
(R : Type u_1)
{α : Type u_2}
(G : SimpleGraph α)
[Zero R]
[One R]
:
G.incMatrix R
is the α × Sym2 α
matrix whose (a, e)
-entry is 1
if e
is incident to
a
and 0
otherwise.
Equations
- SimpleGraph.incMatrix R G a = (G.incidenceSet a).indicator 1
Instances For
theorem
SimpleGraph.incMatrix_apply
{R : Type u_1}
{α : Type u_2}
(G : SimpleGraph α)
[Zero R]
[One R]
{a : α}
{e : Sym2 α}
:
SimpleGraph.incMatrix R G a e = (G.incidenceSet a).indicator 1 e
theorem
SimpleGraph.incMatrix_apply'
{R : Type u_1}
{α : Type u_2}
(G : SimpleGraph α)
[Zero R]
[One R]
[DecidableEq α]
[DecidableRel G.Adj]
{a : α}
{e : Sym2 α}
:
SimpleGraph.incMatrix R G a e = if e ∈ G.incidenceSet a then 1 else 0
Entries of the incidence matrix can be computed given additional decidable instances.
theorem
SimpleGraph.incMatrix_apply_mul_incMatrix_apply
{R : Type u_1}
{α : Type u_2}
(G : SimpleGraph α)
[MulZeroOneClass R]
{a : α}
{b : α}
{e : Sym2 α}
:
SimpleGraph.incMatrix R G a e * SimpleGraph.incMatrix R G b e = (G.incidenceSet a ∩ G.incidenceSet b).indicator 1 e
theorem
SimpleGraph.incMatrix_apply_mul_incMatrix_apply_of_not_adj
{R : Type u_1}
{α : Type u_2}
(G : SimpleGraph α)
[MulZeroOneClass R]
{a : α}
{b : α}
{e : Sym2 α}
(hab : a ≠ b)
(h : ¬G.Adj a b)
:
SimpleGraph.incMatrix R G a e * SimpleGraph.incMatrix R G b e = 0
theorem
SimpleGraph.incMatrix_of_not_mem_incidenceSet
{R : Type u_1}
{α : Type u_2}
(G : SimpleGraph α)
[MulZeroOneClass R]
{a : α}
{e : Sym2 α}
(h : e ∉ G.incidenceSet a)
:
SimpleGraph.incMatrix R G a e = 0
theorem
SimpleGraph.incMatrix_of_mem_incidenceSet
{R : Type u_1}
{α : Type u_2}
(G : SimpleGraph α)
[MulZeroOneClass R]
{a : α}
{e : Sym2 α}
(h : e ∈ G.incidenceSet a)
:
SimpleGraph.incMatrix R G a e = 1
theorem
SimpleGraph.incMatrix_apply_eq_zero_iff
{R : Type u_1}
{α : Type u_2}
(G : SimpleGraph α)
[MulZeroOneClass R]
{a : α}
{e : Sym2 α}
[Nontrivial R]
:
SimpleGraph.incMatrix R G a e = 0 ↔ e ∉ G.incidenceSet a
theorem
SimpleGraph.incMatrix_apply_eq_one_iff
{R : Type u_1}
{α : Type u_2}
(G : SimpleGraph α)
[MulZeroOneClass R]
{a : α}
{e : Sym2 α}
[Nontrivial R]
:
SimpleGraph.incMatrix R G a e = 1 ↔ e ∈ G.incidenceSet a
theorem
SimpleGraph.sum_incMatrix_apply
{R : Type u_1}
{α : Type u_2}
(G : SimpleGraph α)
[Fintype (Sym2 α)]
[NonAssocSemiring R]
{a : α}
[Fintype ↑(G.neighborSet a)]
:
∑ e : Sym2 α, SimpleGraph.incMatrix R G a e = ↑(G.degree a)
theorem
SimpleGraph.incMatrix_mul_transpose_diag
{R : Type u_1}
{α : Type u_2}
(G : SimpleGraph α)
[Fintype (Sym2 α)]
[NonAssocSemiring R]
{a : α}
[Fintype ↑(G.neighborSet a)]
:
(SimpleGraph.incMatrix R G * (SimpleGraph.incMatrix R G).transpose) a a = ↑(G.degree a)
theorem
SimpleGraph.sum_incMatrix_apply_of_mem_edgeSet
{R : Type u_1}
{α : Type u_2}
(G : SimpleGraph α)
[NonAssocSemiring R]
{e : Sym2 α}
[Fintype α]
:
e ∈ G.edgeSet → ∑ a : α, SimpleGraph.incMatrix R G a e = 2
theorem
SimpleGraph.sum_incMatrix_apply_of_not_mem_edgeSet
{R : Type u_1}
{α : Type u_2}
(G : SimpleGraph α)
[NonAssocSemiring R]
{e : Sym2 α}
[Fintype α]
(h : e ∉ G.edgeSet)
:
∑ a : α, SimpleGraph.incMatrix R G a e = 0
theorem
SimpleGraph.incMatrix_transpose_mul_diag
{R : Type u_1}
{α : Type u_2}
(G : SimpleGraph α)
[NonAssocSemiring R]
{e : Sym2 α}
[Fintype α]
[Decidable (e ∈ G.edgeSet)]
:
((SimpleGraph.incMatrix R G).transpose * SimpleGraph.incMatrix R G) e e = if e ∈ G.edgeSet then 2 else 0
theorem
SimpleGraph.incMatrix_mul_transpose_apply_of_adj
{R : Type u_1}
{α : Type u_2}
(G : SimpleGraph α)
[Fintype (Sym2 α)]
[Semiring R]
{a : α}
{b : α}
(h : G.Adj a b)
:
(SimpleGraph.incMatrix R G * (SimpleGraph.incMatrix R G).transpose) a b = 1
theorem
SimpleGraph.incMatrix_mul_transpose
{R : Type u_1}
{α : Type u_2}
(G : SimpleGraph α)
[Fintype (Sym2 α)]
[Semiring R]
[(a : α) → Fintype ↑(G.neighborSet a)]
[DecidableEq α]
[DecidableRel G.Adj]
:
SimpleGraph.incMatrix R G * (SimpleGraph.incMatrix R G).transpose = fun (a b : α) =>
if a = b then ↑(G.degree a) else if G.Adj a b then 1 else 0