Jump to content

Positives and Negatives


Recommended Posts

It's a Basic Question and therefore should be asked if other things are built upon it.

 

why is a negative times a negative a positive and a negative times a positive a negative and similarily for division?

 

If i missed something basic back in grade 3 please be gentle

thanks,

 

 

A Fool

Link to comment
Share on other sites

Multiplying a number by -1, if you try to imagine it visually, reflects the number about the 0 on the number line.

As you'll know if you've done some geometry, reflecting something about the same point twice, leaves it as it is.

Link to comment
Share on other sites

Hm, thats the first time I've heard it explained that way tree, I like it!

 

An algebraic way of looking at it could go this way:

For a positive*negative, multiplication is defined as addition of one number, summing with itself the number of times as the other number. So (-1)*a = -1 + -1 + -1... a times.

 

For neg*neg here is a proof by contradiction:

assume (-a)*(-b) =/= a*b

then (-a)*(-b) - a*b =/= 0

so (-a)*(-b) + (-a)*b =/= 0

by the distributive law (-a)(-b + b) =/= 0

(-a)(0) = 0 =/= 0 is a contradiction.

 

Therefore (-a)*(-b) = a*b

 

And division works the same way because division is just multiplication by a multiplicative inverse, which has the same sign.

Link to comment
Share on other sites

Here's another proof, not by contradiction.

 

Let [math]a,b,c\in\mathbb{R}[/math].

 

Proposition 1

[math]a+c=b+c[/math] implies [math]a=b[/math].

 

(Actually this could be an "iff" statement, but I don't need the converse to get to what I want.)

 

Proof

[math]a+c=b+c[/math] (by hypothesis)

[math](a+c)+(-c)=(b+c)+(-c)[/math] (add [math]-c[/math] to both sides)

[math]a+(c+(-c))=b+(c+(-c))[/math] (by associativity under addition)

[math]a+0=b+0[/math] (by the additive inverse property)

[math]a=b[/math] (by the additive identity property)

 

Proposition 2

[math]0a=a0=0[/math]

 

Proof

[math]a0+0=a(0+0)[/math] (by the additive identity property)

[math]a0+0=a0+a0[/math] (by the left distributive property)

[math]0=a0[/math] (by proposition 1)

[math]0=0a[/math] (by commutativity under multiplication)

 

Proposition 3

[math](-a)b=-(ab)[/math]

 

Proof

[math]a+(-a)=0[/math] (by the additive inverse property)

[math](a+(-a))b=0b[/math] (multiply both sides by [math]b[/math])

[math]ab+(-a)b=0b[/math] (by the right distributive property)

[math]ab+(-a)b=0[/math] (by proposition 2)

[math](-a)b=(-ab)[/math] (by the additive inverse property)

 

Proposition 4

[math](-a)(-b)=ab[/math]

 

Proof

[math]a+(-a)=0[/math] (by the additive inverse property)

[math](a+(-a))(-b)=0(-b)[/math] (multiply both sides by [math](-b)[/math])

[math]a(-b)+(-a)(-b)=0(-b)[/math] (by the right distributive property)

[math]a(-b)+(-a)(-b)=0[/math] (by proposition 2)

[math]-ab+(-a)(-b)=0[/math] (by proposition 3)

[math](-a)(-b)=ab[/math] (by the additive inverse property)

 

Note: At the end of the proofs for Propositions 3 and 4, I relied on the fact that the additive structure of a field is a group, and that every element in a group has a unique inverse element.

Link to comment
Share on other sites

Here's another proof, not by contradiction.

 

Let [math]a,b,c\in\mathbb{R}[/math].

 

Proposition 1

[math]a+c=b+c[/math] implies [math]a=b[/math].

 

(Actually this could be an "iff" statement, but I don't need the converse to get to what I want.)

 

Proof

[math]a+c=b+c[/math] (by hypothesis)

[math](a+c)+(-c)=(b+c)+(-c)[/math] (add [math]-c[/math] to both sides)

[math]a+(c+(-c))=b+(c+(-c))[/math] (by associativity under addition)

[math]a+0=b+0[/math] (by the additive inverse property)

[math]a=b[/math] (by the additive identity property)

 

Proposition 2

[math]0a=a0=0[/math]

 

Proof

[math]a0+0=a(0+0)[/math] (by the additive identity property)

[math]a0+0=a0+a0[/math] (by the left distributive property)

[math]0=a0[/math] (by proposition 1)

[math]0=0a[/math] (by commutativity under multiplication)

 

Proposition 3

[math](-a)b=-(ab)[/math]

 

Proof

[math]a+(-a)=0[/math] (by the additive inverse property)

[math](a+(-a))b=0b[/math] (multiply both sides by [math]b[/math])

[math]ab+(-a)b=0b[/math] (by the right distributive property)

[math]ab+(-a)b=0[/math] (by proposition 2)

[math](-a)b=(-ab)[/math] (by the additive inverse property)

 

Proposition 4

[math](-a)(-b)=ab[/math]

 

Proof

[math]a+(-a)=0[/math] (by the additive inverse property)

[math](a+(-a))(-b)=0(-b)[/math] (multiply both sides by [math](-b)[/math])

[math]a(-b)+(-a)(-b)=0(-b)[/math] (by the right distributive property)

[math]a(-b)+(-a)(-b)=0[/math] (by proposition 2)

[math]-ab+(-a)(-b)=0[/math] (by proposition 3)

[math](-a)(-b)=ab[/math] (by the additive inverse property)

 

Note: At the end of the proofs for Propositions 3 and 4, I relied on the fact that the additive structure of a field is a group, and that every element in a group has a unique inverse element.

Didn't all of your proofs rely on the converse of proposition 1 at some point?

Link to comment
Share on other sites

Yes, I supposed they do. But I immediately have the converse from the definitions of addition and of equality. If [math]a=b[/math], then I have:

 

[math]a+c=a+c[/math] (tautology)

[math]a+c=b+c[/math] (substitution)

 

So there we have the converse, and everything is now logically closed.

Link to comment
Share on other sites

Multiplying a number by -1, if you try to imagine it visually, reflects the number about the 0 on the number line.

As you'll know if you've done some geometry, reflecting something about the same point twice, leaves it as it is.

 

Great explanation. Now I geddit!

Link to comment
Share on other sites

Yes, I supposed they do. But I immediately have the converse from the definitions of addition and of equality. If [math]a=b[/math], then I have:

 

[math]a+c=a+c[/math] (tautology)

[math]a+c=b+c[/math] (substitution)

 

So there we have the converse, and everything is now logically closed.

Nice!

Link to comment
Share on other sites

  • 2 months later...

Create an account or sign in to comment

You need to be a member in order to leave a comment

Create an account

Sign up for a new account in our community. It's easy!

Register a new account

Sign in

Already have an account? Sign in here.

Sign In Now
×
×
  • Create New...

Important Information

We have placed cookies on your device to help make this website better. You can adjust your cookie settings, otherwise we'll assume you're okay to continue.