df-assa

Description: Definition of an associative algebra. An associative algebra is a set equipped with a left-module structure on a (commutative) ring, coupled with a multiplicative internal operation on the vectors of the module that is associative and distributive for the additive structure of the left-module (so giving the vectors a ring structure) and that is also bilinear under the scalar product. (Contributed by Mario Carneiro, 29-Dec-2014)

		Ref	Expression
	Assertion	df-assa	$⊢ AssAlg = \{w \in (LMod \cap Ring) \| \underset{˙}{[} Scalar (w) / f \underset{˙}{]} (f \in CRing \land \forall r \in {Base}_{f} \forall x \in {Base}_{w} \forall y \in {Base}_{w} \underset{˙}{[} \cdot_{w} / s \underset{˙}{]} \underset{˙}{[} \cdot_{w} / t \underset{˙}{]} ((r s x) t y = r s (x t y) \land x t (r s y) = r s (x t y)))\}$

Detailed syntax breakdown

Step	Hyp	Ref	Expression
0		casa	$class AssAlg$
1		vw	$setvar w$
2		clmod	$class LMod$
3		crg	$class Ring$
4	2 3	cin	$class (LMod \cap Ring)$
5		csca	$class Scalar$
6	1	cv	$setvar w$
7	6 5	cfv	$class Scalar (w)$
8		vf	$setvar f$
9	8	cv	$setvar f$
10		ccrg	$class CRing$
11	9 10	wcel	$wff f \in CRing$
12		vr	$setvar r$
13		cbs	$class Base$
14	9 13	cfv	$class {Base}_{f}$
15		vx	$setvar x$
16	6 13	cfv	$class {Base}_{w}$
17		vy	$setvar y$
18		cvsca	$class \cdot_{𝑠}$
19	6 18	cfv	$class \cdot_{w}$
20		vs	$setvar s$
21		cmulr	$class \cdot_{𝑟}$
22	6 21	cfv	$class \cdot_{w}$
23		vt	$setvar t$
24	12	cv	$setvar r$
25	20	cv	$setvar s$
26	15	cv	$setvar x$
27	24 26 25	co	$class (r s x)$
28	23	cv	$setvar t$
29	17	cv	$setvar y$
30	27 29 28	co	$class ((r s x) t y)$
31	26 29 28	co	$class (x t y)$
32	24 31 25	co	$class (r s (x t y))$
33	30 32	wceq	$wff (r s x) t y = r s (x t y)$
34	24 29 25	co	$class (r s y)$
35	26 34 28	co	$class (x t (r s y))$
36	35 32	wceq	$wff x t (r s y) = r s (x t y)$
37	33 36	wa	$wff ((r s x) t y = r s (x t y) \land x t (r s y) = r s (x t y))$
38	37 23 22	wsbc	$wff \underset{˙}{[} \cdot_{w} / t \underset{˙}{]} ((r s x) t y = r s (x t y) \land x t (r s y) = r s (x t y))$
39	38 20 19	wsbc	$wff \underset{˙}{[} \cdot_{w} / s \underset{˙}{]} \underset{˙}{[} \cdot_{w} / t \underset{˙}{]} ((r s x) t y = r s (x t y) \land x t (r s y) = r s (x t y))$
40	39 17 16	wral	$wff \forall y \in {Base}_{w} \underset{˙}{[} \cdot_{w} / s \underset{˙}{]} \underset{˙}{[} \cdot_{w} / t \underset{˙}{]} ((r s x) t y = r s (x t y) \land x t (r s y) = r s (x t y))$
41	40 15 16	wral	$wff \forall x \in {Base}_{w} \forall y \in {Base}_{w} \underset{˙}{[} \cdot_{w} / s \underset{˙}{]} \underset{˙}{[} \cdot_{w} / t \underset{˙}{]} ((r s x) t y = r s (x t y) \land x t (r s y) = r s (x t y))$
42	41 12 14	wral	$wff \forall r \in {Base}_{f} \forall x \in {Base}_{w} \forall y \in {Base}_{w} \underset{˙}{[} \cdot_{w} / s \underset{˙}{]} \underset{˙}{[} \cdot_{w} / t \underset{˙}{]} ((r s x) t y = r s (x t y) \land x t (r s y) = r s (x t y))$
43	11 42	wa	$wff (f \in CRing \land \forall r \in {Base}_{f} \forall x \in {Base}_{w} \forall y \in {Base}_{w} \underset{˙}{[} \cdot_{w} / s \underset{˙}{]} \underset{˙}{[} \cdot_{w} / t \underset{˙}{]} ((r s x) t y = r s (x t y) \land x t (r s y) = r s (x t y)))$
44	43 8 7	wsbc	$wff \underset{˙}{[} Scalar (w) / f \underset{˙}{]} (f \in CRing \land \forall r \in {Base}_{f} \forall x \in {Base}_{w} \forall y \in {Base}_{w} \underset{˙}{[} \cdot_{w} / s \underset{˙}{]} \underset{˙}{[} \cdot_{w} / t \underset{˙}{]} ((r s x) t y = r s (x t y) \land x t (r s y) = r s (x t y)))$
45	44 1 4	crab	$class \{w \in (LMod \cap Ring) \| \underset{˙}{[} Scalar (w) / f \underset{˙}{]} (f \in CRing \land \forall r \in {Base}_{f} \forall x \in {Base}_{w} \forall y \in {Base}_{w} \underset{˙}{[} \cdot_{w} / s \underset{˙}{]} \underset{˙}{[} \cdot_{w} / t \underset{˙}{]} ((r s x) t y = r s (x t y) \land x t (r s y) = r s (x t y)))\}$
46	0 45	wceq	$wff AssAlg = \{w \in (LMod \cap Ring) \| \underset{˙}{[} Scalar (w) / f \underset{˙}{]} (f \in CRing \land \forall r \in {Base}_{f} \forall x \in {Base}_{w} \forall y \in {Base}_{w} \underset{˙}{[} \cdot_{w} / s \underset{˙}{]} \underset{˙}{[} \cdot_{w} / t \underset{˙}{]} ((r s x) t y = r s (x t y) \land x t (r s y) = r s (x t y)))\}$

Metamath Proof Explorer

Definition df-assa

Detailed syntax breakdown