robsimmons/gist:2cf90e7f86e42819dd5965010f530c47

## gistfile1.txt
#### First proof I wrote ####
Given ~A & ~B
[ Suppose A | B
  [ Suppose A
    ~A          # By conjunction elimination left with (2)
    F ]         # By negation elimination with (5) and (4)
  [ Suppose B
    ~B          # By conjunction elimination right with (2)
    F ]         # By negation elimination with (8) and (7)
  F ]           # By disjunction elimination with (3), (4-6), (7-9)
~(A | B)        # By negation introduction with (3-10)


#### Better matching the structure given in quiz ####
Given ~A & ~B
~A              # By conjunction elimination left with (16)
~B              # By conjunction elimination right with (16)
[ Suppose A | B
  [ Suppose A
    F ]         # By negation elimination with (17) and (20)
  [ Suppose B
    F ]         # By negation elimination with (18) and (22)
  F ]           # By disjunction elimination with (19), (20-21), (22-23)
~(A | B)        # By negation introduction with (19-24)


#### Even better matching the structure given in quiz ####
Given ~A & ~B
~A              # By conjunction elimination left with (30)
~B              # By conjunction elimination right with (30)
[ Suppose A | B
  [ Suppose A
    F           # By negation elimination with (31) and (34)
    ~(A | B) ]  # By falsehood elimination with (35)
  [ Suppose B
    F           # By negation elimination with (32) and (37)
    ~(A | B) ]  # By falsehood elimination with (38)
  ~(A | B)      # By disjunction elimination (proof by cases) with (33), (34-36), (37-39)
  F ]           # By negation elimination with (40), (33)
~(A | B)        # By negation introduction with (33-41)


Rules for system:
# Implication introduction: from [A ... B], derive A => B
# Implication elimination (modus ponens): from A => B and A, derive B
# Conjunction introduction: from A and B, derive A & B
# Conjunction elimination left: from A & B, derive A
# Conjunction elimination right: from A & B, derive B
# Disjunction introduction left: from A, derive A | B
# Disjunction introduction right: from B, derive A | B
# Disjunction elimination (proof by cases): from A | B, [A ... C], and [B ... C], derive C
# Truth introduction: derive T
# Falsehood elimination: from F, derive A
# Negation introduction: from [A ... F], derive ~A
# Negation elimination: from ~A and A, derive F

Note: it's pretty common to say that negation is just literally A => F.
If you do that, negation introduction/elimination rules are literally
just the implication introduction/elimination rules.

These rules suffice for intuitionstic logic.
There are several interderivable rules for classical logic.
Any *one* of these rules suffices to make the system classical and prove the rest.
# Double negation elimination: from ~~A, derive A
# Proof by contradiction: from [~A ... F], derive A
# Assume the opposite: from [~A ... A], derive A
# Law of the excluded middle: derive ~A | A
	#### First proof I wrote ####
	Given ~A & ~B
	[ Suppose A \| B
	[ Suppose A
	~A # By conjunction elimination left with (2)
	F ] # By negation elimination with (5) and (4)
	[ Suppose B
	~B # By conjunction elimination right with (2)
	F ] # By negation elimination with (8) and (7)
	F ] # By disjunction elimination with (3), (4-6), (7-9)
	~(A \| B) # By negation introduction with (3-10)



	#### Better matching the structure given in quiz ####
	Given ~A & ~B
	~A # By conjunction elimination left with (16)
	~B # By conjunction elimination right with (16)
	[ Suppose A \| B
	[ Suppose A
	F ] # By negation elimination with (17) and (20)
	[ Suppose B
	F ] # By negation elimination with (18) and (22)
	F ] # By disjunction elimination with (19), (20-21), (22-23)
	~(A \| B) # By negation introduction with (19-24)



	#### Even better matching the structure given in quiz ####
	Given ~A & ~B
	~A # By conjunction elimination left with (30)
	~B # By conjunction elimination right with (30)
	[ Suppose A \| B
	[ Suppose A
	F # By negation elimination with (31) and (34)
	~(A \| B) ] # By falsehood elimination with (35)
	[ Suppose B
	F # By negation elimination with (32) and (37)
	~(A \| B) ] # By falsehood elimination with (38)
	~(A \| B) # By disjunction elimination (proof by cases) with (33), (34-36), (37-39)
	F ] # By negation elimination with (40), (33)
	~(A \| B) # By negation introduction with (33-41)



	Rules for system:
	# Implication introduction: from [A ... B], derive A => B
	# Implication elimination (modus ponens): from A => B and A, derive B
	# Conjunction introduction: from A and B, derive A & B
	# Conjunction elimination left: from A & B, derive A
	# Conjunction elimination right: from A & B, derive B
	# Disjunction introduction left: from A, derive A \| B
	# Disjunction introduction right: from B, derive A \| B
	# Disjunction elimination (proof by cases): from A \| B, [A ... C], and [B ... C], derive C
	# Truth introduction: derive T
	# Falsehood elimination: from F, derive A
	# Negation introduction: from [A ... F], derive ~A
	# Negation elimination: from ~A and A, derive F

	Note: it's pretty common to say that negation is just literally A => F.
	If you do that, negation introduction/elimination rules are literally
	just the implication introduction/elimination rules.

	These rules suffice for intuitionstic logic.
	There are several interderivable rules for classical logic.
	Any one of these rules suffices to make the system classical and prove the rest.
	# Double negation elimination: from ~~A, derive A
	# Proof by contradiction: from [~A ... F], derive A
	# Assume the opposite: from [~A ... A], derive A
	# Law of the excluded middle: derive ~A \| A