I’m doing my GED and passed that math part but this never came up. I saw it on a meme and am lost. Help!!??
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I am serious, is this implication correct? If so can't I just say :
("1+1=2") ==> ("The earth is round)
Both of these statements are true, but they have no "connection" between eachother, is thr implication still true?
I'm going to rewrite this proof by dividing by all powers of ten and what not.
The proof essentially goes:
$$ \frac{0}{0}=\frac{2\cdot 0}{1\cdot 0}=\frac{2}{1}$$
The problem is in the first line, when you write $\frac{0}{0}$, which is undefined. Of course you could define it, but then it would be equal to every fraction since $$\frac{a}{b}=\frac{c}{d}$$ if $ad=bc$, and if $a=b=0$, then this is always true, since for any $c$ and $d$, $0\cdot d=0\cdot c$.
But then all fractions are equal to each other, so there is only really one fraction: $\frac{0}{0}$. This seems a lot less useful than the system we had before.
You cannot divide any number by $0$! In abstract algebra there are constructed algebraic structures where things similar to "dividing by zero" can be performed (zero divisors).
A new branch of mathematics is the nonstandard analysis in which with numbers which are tending to $0$ can be performed any calculations (these are infinitesimal numbers; it is in the set of hyperreal numbers).
I will give a different answer than the answer I gave in the other thread which tries to appeal to intuition. I am sure your daughter has no problem accepting that $2\times 0 = 0$. Intuitively this is because if you add $2$ to itself zero times, you get zero. Or, to be concrete, if someone gives you two apples zero times, you have zero apples.
For repeatedly adding $2$, talking about collections of apples is a good model. But for repeatedly multiplying by $2$, it isn't necessarily, since you can't multiply apples and apples (at least, not in a way that makes sense to a child). But you can multiply apples by numbers; that is, you can start with $1$ apple, then double the number of apples you have to get $2$ apples, then double the number of apples you have to get $4$ apples, and so forth. In general if you double your apples $n$ times, you have $2^n$ apples.
What happens if you double your apples zero times? Well, that means you haven't started doubling them yet, so you still have $1$ apple. If you want your notation to be consistent, then you should say $2^0 = 1$.
This is a subtly different argument from the argument I gave before. It's intuitive what it means to add different amounts of apples, and it's intuitive what it means to have zero apples. But the twos I am now working with aren't numbers of apples, they're just abstract numbers; in other words, they're unitless, so it's harder to get a grip on them. What $2^n$ really represents above is an endomorphism of the free commutative monoid on an apple, which is much less concrete than an apple.
There is a way to gain intuition here which sort of involves units, but I don't know if you can convince your daughter that it makes sense. One way to interpret $2^n$ is that it is the "size" of an $n$-cube of side length $2$ in dimension $n$. For example, the length of a segment of side length $2$ is $2$, the area of a square of side length $2$ is $4$, and so forth. One way to say this is that $2^n$ is the number of $n$-cubes of side length $1$ that fit into an $n$-cube of side length $2$.
To get a meaningful interpretation of the above when $n = 0$ we need to decide what $0$-dimensional objects are. Well, if $2$-dimensional space is a plane and $1$-dimensional space is a line, then $0$-dimensional space must be... a point. In particular, a $0$-cube, of any side length, is a point, and so exactly one $0$-cube of side length $1$ fits into a $0$-cube of side length $2$. Hence $2^0 = 1$.
(I'm really curious what her response to this argument will be, actually. Could you report back on this?)
How about this: There's always an implicit 1 in the expansion:
$$2^{3} = 2 \cdot 2 \cdot 2 \cdot 1 = 8$$
$$2^{2} = 2 \cdot 2 \cdot 1 = 4$$
$$2^{1} = 2 \cdot 1 = 2 $$
$$2^{0} = 1 = 1 $$