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  • In 1798, at the age of 21, Carl Friedrich Gauss wrote a classic book called the Disquisitiones

  • Arithmeticae. Here he laid out the modern idea of modular arithmetic. This technique

  • takes the group of integers, partitions them into a finite number of sets, and then treats

  • each set as a new type of number. Modular arithmetic has proven to be so useful, it’s

  • natural to try to adapt this technique to other areas. In group theory, this can been

  • done using normal subgroups and quotient groups.

  • To motivate the idea of a normal subgroup and a quotient group, let’s first look at

  • a concrete example. Let’s begin by looking at the integers mod

  • 5. Here, we will divide the integers into 5 sets,

  • depending on the remainder you get when you divide the number by 5.

  • The first set will be all the integers with a remainder of 0 when you divide by 5. In

  • other words, all the multiples of 5 - positive, negative, and zero.

  • The next set is the integers with a remainder of 1 when you divide by 5.

  • We continue this process: those with a remainder of twothreeand fourWe can now

  • stop, because these are the only possible remainders you can get.

  • Here’s the critical observation: if you pick any number with a remainder of 1, and

  • add it to any number with a remainder of 2, you will always get an integer with a remainder

  • of 3… Similarly, if you pick any number from the

  • 2 set, and add it to any number from the 4 set, you will always get a number in the 1

  • set... This always happens. If you pick any number

  • from one set, and add it to any number from a second set, the sum will always be in the

  • same, third set.

  • [4] These five sets are called congruence classes, and if we treat the sets as if they

  • were numbers, then we have a group with five elements: the integers mod 5. It’s very

  • good practice to check that these 5 “meta numbersdo indeed form a group under addition.

  • For instance, the set of the multiples of five act as the identity element, and each

  • set has an inverse. By the way, whenever two integers “A” and “B” are in the same

  • congruence class, we write it like this. We say this aloud as “A is congruent to B mod

  • N”, and all this means is that “A” and “B” have the same remainder when you divide

  • by N.

  • Let’s take another look at the integers mod 5 using the language of group theory.

  • To start, we have the group of integers “Z” under addition.

  • This group has an infinite number of subgroups, but well look at the subgroup of the multiples

  • of 5, which well write as “5-Z.” Graphically, let’s represent the group of

  • integers by a rectangle, and the subgroup “5-Z” as a smaller rectangle inside of

  • it. Every integer in this subgroup has a remainder

  • of 0 when you divide by 5. The number 1 is not in the subgroup, and if

  • you add 1 to every number in the subgroup, you get a new set -- the set of integers with

  • a remainder of 1 when you divide by 5. Well denote this set by 1 + 5Z.

  • We call this set a “cosetand it’s NOT a subgroup. It’s not closed under addition,

  • doesn’t have inverses, and does not contain the identity element. It’s not even close

  • to being a group. This coset does not overlap with the subgroup

  • 5-Z, since every number in the coset has a remainder of 1 when you divide by 5, and every

  • number in the subgroup has a remainder of 0 when you divide by 5.

  • We can continue this process by picking a number not already inside a rectangle, like

  • 2, and then making a new coset: 2 + 5Z. Continuing this process we get the cosets

  • 3 + 5Z… and then 4 + 5Z... At this point, the original group is now completely

  • covered by one subgroup 5Z, and 4 cosets. By the way, you can also think of the subgroup

  • as a coset: 0 + 5Z.

  • We used the subgroup 5-Z to partition the group Z into cosets. Because the cosets form

  • a group, we call 5-Z a NORMAL SUBGROUP. And the group of cosets is called a QUOTIENT GROUP,

  • and it’s written like this. This name is very descriptive, since we are using a subgroup

  • to divide the group into cosets. And when you divide one thing by another, you get a

  • quotient. But the critical insight in this process was the observation that you can treat

  • these cosets as elements in a new group: a coset group, if you will.

  • For example, if you add the coset 1 + 5Z to the coset 3 + 5Z you get the coset 4 + 5Z.

  • The way you add these two cosets is to add all the numbers in the first coset with all

  • the numbers in the second coset. The resulting set turns out to be exactly the coset

  • 4 + 5Z.

  • I’d like to point out one more thing. In the example weve discussed, we started

  • out with a group Z, then took a subgroup 5Z -- which is called a normal subgroup -- and

  • used these two to create a quotient group out of the cosets. The quotient group is NOT

  • a subgroup of Z. It’s an entirely different group.

  • Let’s now begin the process of generalizing this technique to an arbitrary group. Suppose

  • we have a group G, and a subgroup N. Here, we will use multiplicative notation for the

  • group G. Like before, we can use N to generate a collection of non-overlapping cosets. Remember,

  • N is a subgroup, while the other cosets are simply sets. Here is the big question: do

  • the cosets always form a group? The answer is NO. If the cosets do not form a group,

  • we do NOT call N a normal subgroup, and we CANNOT make a quotient group. Let’s now

  • see what properties N must have in order for the cosets to be a group.

  • Let’s assume N divides G into T different cosets.

  • Since G may not be abelian, we need to be careful: left cosets and rights cosets may

  • be different, so well go ahead and work with left cosets.

  • Now, every left coset is of the form g-N for some element ‘g’ in the group.

  • Let’s pick two different cosets: X-N and Y-N.

  • Since N is a subgroup, it contains the identity element ‘E’.

  • This means X times E (which equals X) is in the first coset, and Y times E (which equals

  • Y) is in the second coset. So if the cosets behave like a group, X times

  • Y must be in the product of the two cosets. In other words, X-N times Y-N should equal

  • XY-N. If this is true, then the product of any element

  • in the first coset with any element in the second coset should be in the coset XY-N.

  • Let’s see when this happens. Pick an arbitrary element in the first coset,

  • call it X-times-N1. And then pick an element from the second coset,

  • Y-times-N2. If we multiply these together we get X-N1

  • ✕ Y-N2. If this is in the coset XY-N, then their product

  • must be XY-times-N3 for some N3. Were now going to tinker with this equation

  • to get a simpler expression. We can simplify this by multiplying on the

  • left hand side by the inverse of X and cancelling. Next, multiply on the left by Y-inverse and

  • cancel on the right. This gives us Y-inverse ✕ N1 ✕ Y ✕ N2

  • EQUALS N3. Finally, multiply this on the right by N2-inverse.

  • Since N is a subgroup, the product on the right is also in N.

  • So we end up with Y-inverse ✕ N1 ✕ Y is an element of N.

  • In fact, if you look at the set Y-inverse ✕ N ✕ Y you get N.

  • One way to do this is to show each side is a subset of the other. We just showed the

  • left hand side is a subset of N, and it’s a very good exercise to show that the right

  • hand side is a subset of the left.

  • So to summarize, if the product of the two cosets X-N and Y-N is well defined, then it

  • must be true that Y-inverse ✕ N ✕ Y equals N. We call the left hand side a conjugate.

  • Now that we have a group operation, we can check that the cosets form a group.

  • The identity element is just the subgroup N, which you can also think of as the coset

  • E-N. We see this is the identity because E-N times

  • G-N equals (E✕G) N which equals G-N. And for each coset G-N the inverse is G-inverse-N,

  • because if you multiply these two cosets together, you get (G✕G-inverse) N which equals E-N,

  • or simply N, which is the identity element.

  • We just saw that if N is a subgroup of G and the cosets behave like a group, then it must

  • be true that the set Y-inverse TIMES N times Y must equal N for any Y. But with a clever

  • trick, we can show the converse is true as well. That is, if the conjugate of N always

  • equals N, then the cosets form a group. Let’s see why.

  • Suppose Y-inverse ✕ N ✕ Y equals N for any element Y.

  • Well use this fact to show that the cosets form a group.

  • To begin, pick two cosets X-N and Y-N. Let’s multiply two arbitrary elements from

  • these cosets: X-N1 and Y-N2. Here’s the clever trick: Y ✕ Y-inverse

  • equals the identity element E. Multiplying by E has no effect, so let’s

  • insert Y ✕ Y-inverse right after X. In the middle of this expression is Y-inverse

  • ✕ N1 ✕ Y. But from our assumption, we know this must

  • be an element of the subgroup N, call it N3. So this expression equals X times Y times

  • N3 times N2. But N3 times N2 is also in N, call it N4.

  • So the expression further simplifies to X ✕ Y ✕ N4 which is an element of the coset

  • X-Y-N. This means the product of the cosets X-N and

  • Y-N is the coset X-Y-N. The cosets do form a group.

  • What weve just shown is that if N is a subgroup of G, then the cosets behave like

  • a group precisely when Y-inverse TIMES N TIMES Y equals N for any element Y in the group.

  • When this is true, we call N a “normal subgroupof G, and we write it like this. The group

  • of cosets is called a “factor group,” and it’s written like thisIn the factor

  • group, the subgroup N is the identity element, and the inverse of X-N is X-inverse-N.

  • Every group G has two subgroups: the identity element and the entire group G. It turns out

  • these are technically normal subgroups, but they aren’t very interesting. If a group

  • has no other normal subgroups than these two, then we call G a SIMPLE GROUP. A simple group

  • does not have any factor groups, and they are the building blocks of other groups, much

  • like prime numbers are the building blocks of the integers.

  • Normal subgroups and quotient groups are among the most useful devices in abstract algebra.

  • In separate videos, well show how normal subgroups determine what kinds of homomorphisms

  • are possible from a group G to other groups. And for finite groups, you can find a chain

  • of normal subgroups called a “composition serieswhich acts as a kind ofprime

  • factorizationof the group. Normal subgroups can even be used to study fields; youll

  • learn about this technique in Galois Theory.

  • Here’s a good exercise. Try to find a normal subgroup of the symmetric group S3. This group

  • has only 6 elements, so you should be able to check everything by hand. Be sure to help

  • each other out in the comments below, and remember,

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In 1798, at the age of 21, Carl Friedrich Gauss wrote a classic book called the Disquisitiones

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正規小群と商群(別名因子群) - 抽象代数学 (Normal Subgroups and Quotient Groups (aka Factor Groups) - Abstract Algebra)

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    林宜悉 に公開 2021 年 01 月 14 日
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