Home Topics in Analysis Analysis Elementary Linear Algebra Linear Algebra Analysis of Functions of Many Variables Linear Algebra and Analysis Complex Analysis Calculus of One And Many Variables Engineering Math One Variable Advanced Calculus Interrogation of Hiroshi Oshima

4 CHAPTER 1. SOME PREREQUISITE TOPICS

The theorem will be proved if this last expression is less than1√

2n+3. This happens if

and only if (1√

2n+3

)2

=1

2n+3>

2n+1

(2n+2)2

which occurs if and only if (2n+2)2 > (2n+3)(2n+1) and this is clearly true which maybe seen from expanding both sides. This proves the inequality.

Lets review the process just used. If S is the set of integers at least as large as 1 for whichthe formula holds, the first step was to show 1 ∈ S and then that whenever n ∈ S, it followsn+ 1 ∈ S. Therefore, by the principle of mathematical induction, S contains [1,∞)∩Z,all positive integers. In doing an inductive proof of this sort, the set S is normally notmentioned. One just verifies the steps above. First show the thing is true for some a ∈ Zand then verify that whenever it is true for m it follows it is also true for m+1. When thishas been done, the theorem has been proved for all m≥ a.

1.3 The Complex NumbersRecall that a real number is a point on the real number line. Just as a real number should beconsidered as a point on the line, a complex number is considered a point in the plane whichcan be identified in the usual way using the Cartesian coordinates of the point. Thus (a,b)identifies a point whose x coordinate is a and whose y coordinate is b. In dealing with com-plex numbers, such a point is written as a+ ib. For example, in the following picture, I havegraphed the point 3+2i. You see it corresponds to the point in the plane whose coordinatesare (3,2) .

•3+2iMultiplication and addition are defined in the most obvious way sub-ject to the convention that i2 =−1. Thus,

(a+ ib)+(c+ id) = (a+ c)+ i(b+d)

and

(a+ ib)(c+ id) = ac+ iad + ibc+ i2bd

= (ac−bd)+ i(bc+ad) .

Every non zero complex number a + ib, with a2 + b2 ΜΈ= 0, has a unique multiplicativeinverse.

1a+ ib

=a− ib

a2 +b2 =a

a2 +b2 − ib

a2 +b2 .

You should prove the following theorem.

Theorem 1.3.1 The complex numbers with multiplication and addition defined as aboveform a field satisfying all the field axioms. These are the following list of properties.

1. x+ y = y+ x, (commutative law for addition)

2. x+0 = x, (additive identity).

3. For each x ∈ R, there exists −x ∈ R such that x+(−x) = 0, (existence of additiveinverse).