addcan2

Description: Cancellation law for addition. (Contributed by NM, 30-Jul-2004) (Revised by Scott Fenton, 3-Jan-2013)

		Ref	Expression
	Assertion	addcan2	$⊢ (A \in ℂ \land B \in ℂ \land C \in ℂ) \to (A + C = B + C \leftrightarrow A = B)$

Proof

Step	Hyp	Ref	Expression
1		cnegex	$⊢ C \in ℂ \to \exists x \in ℂ C + x = 0$
2	1	3ad2ant3	$⊢ (A \in ℂ \land B \in ℂ \land C \in ℂ) \to \exists x \in ℂ C + x = 0$
3		oveq1	$⊢ A + C = B + C \to A + C + x = B + C + x$
4		simpl1	$⊢ ((A \in ℂ \land B \in ℂ \land C \in ℂ) \land (x \in ℂ \land C + x = 0)) \to A \in ℂ$
5		simpl3	$⊢ ((A \in ℂ \land B \in ℂ \land C \in ℂ) \land (x \in ℂ \land C + x = 0)) \to C \in ℂ$
6		simprl	$⊢ ((A \in ℂ \land B \in ℂ \land C \in ℂ) \land (x \in ℂ \land C + x = 0)) \to x \in ℂ$
7	4 5 6	addassd	$⊢ ((A \in ℂ \land B \in ℂ \land C \in ℂ) \land (x \in ℂ \land C + x = 0)) \to A + C + x = A + C + x$
8		simprr	$⊢ ((A \in ℂ \land B \in ℂ \land C \in ℂ) \land (x \in ℂ \land C + x = 0)) \to C + x = 0$
9	8	oveq2d	$⊢ ((A \in ℂ \land B \in ℂ \land C \in ℂ) \land (x \in ℂ \land C + x = 0)) \to A + C + x = A + 0$
10		addid1	$⊢ A \in ℂ \to A + 0 = A$
11	4 10	syl	$⊢ ((A \in ℂ \land B \in ℂ \land C \in ℂ) \land (x \in ℂ \land C + x = 0)) \to A + 0 = A$
12	7 9 11	3eqtrd	$⊢ ((A \in ℂ \land B \in ℂ \land C \in ℂ) \land (x \in ℂ \land C + x = 0)) \to A + C + x = A$
13		simpl2	$⊢ ((A \in ℂ \land B \in ℂ \land C \in ℂ) \land (x \in ℂ \land C + x = 0)) \to B \in ℂ$
14	13 5 6	addassd	$⊢ ((A \in ℂ \land B \in ℂ \land C \in ℂ) \land (x \in ℂ \land C + x = 0)) \to B + C + x = B + C + x$
15	8	oveq2d	$⊢ ((A \in ℂ \land B \in ℂ \land C \in ℂ) \land (x \in ℂ \land C + x = 0)) \to B + C + x = B + 0$
16		addid1	$⊢ B \in ℂ \to B + 0 = B$
17	13 16	syl	$⊢ ((A \in ℂ \land B \in ℂ \land C \in ℂ) \land (x \in ℂ \land C + x = 0)) \to B + 0 = B$
18	14 15 17	3eqtrd	$⊢ ((A \in ℂ \land B \in ℂ \land C \in ℂ) \land (x \in ℂ \land C + x = 0)) \to B + C + x = B$
19	12 18	eqeq12d	$⊢ ((A \in ℂ \land B \in ℂ \land C \in ℂ) \land (x \in ℂ \land C + x = 0)) \to (A + C + x = B + C + x \leftrightarrow A = B)$
20	3 19	syl5ib	$⊢ ((A \in ℂ \land B \in ℂ \land C \in ℂ) \land (x \in ℂ \land C + x = 0)) \to (A + C = B + C \to A = B)$
21		oveq1	$⊢ A = B \to A + C = B + C$
22	20 21	impbid1	$⊢ ((A \in ℂ \land B \in ℂ \land C \in ℂ) \land (x \in ℂ \land C + x = 0)) \to (A + C = B + C \leftrightarrow A = B)$
23	2 22	rexlimddv	$⊢ (A \in ℂ \land B \in ℂ \land C \in ℂ) \to (A + C = B + C \leftrightarrow A = B)$

Metamath Proof Explorer

Theorem addcan2

Proof