Irrational Number – Proving the square root of 2 is an irrational number

Yes. We are to claim the irrationality of sqrt 2.

We will use proof by contradiction.

Assume that sqrt 2 is a rational number. Then by definition of rational numbers, we may write that

sqrt 2 = n / m

where n, m are integers.

Squaring on both sides: (sqrt 2)^2 = (n / m)^2, or

2 = n^2 / m^2

which leads to 2 m^2 = n^2 (*)

Let us show that (*) cannot hold true.

Method 1.

Let m = 2^p K, n = 2^q L, where p, q are integers, K and L are odd integers.

{If either K or L are even numbers, then factor 2 can be extracted iteratively until an odd number (co-factor) is revealed. }

Bringing m, n in the above forms into 2 m^2 = n^2, then:

2 ((2^p) K)^2 = (2^q L)^2

2^{2p+1} K^2 = 2 ^{2q} L^2 (++)

Let us count the number of 2’s on each side. The l.h.s has (2p+1) of factor 2’s (an odd count of 2), and the r.h.s. has (2q) of 2’s (an even count of 2’s). However, it is well established that for any integer, the prime factorization is unique. Therefore, equation (++) cannot holds. Tracing back, we have to revoke the initial assumption

sqrt 2 = n / m

Therefore, number sqrt 2 is not a rational number.

Method 2.

Note in n^2 = 2 m^2, the right hand side is even, so the left side is also even. This implies that n must contain factor 2. Let n = 2 N, then

2 m^2 = (2 N)^2 — > m^2 = 2 N^2

where the new equation m^2 = 2 N^2 implies that number m must contain factor 2. So each of n, m and N contains factor 2.

This process may be applied in an iterative manner, forever. Consequently, both m and n contains an infinite many factors of 2’s. However, this is not possible as either n or m is a finite number.

You got it?

If you got it, you shall be able to prove that sqrt 3 is also irrational (i.e. sqrt 3 cannot be written as the ratio of two integers.) How? Just use the same idea, but this time, you need to count the number of 3’s.

Irrational numbers: what are they and how to justify

Let us start from rational numbers. If one wants to test whether a given number is rational, then he/she will attempt to write it as the ratio of two integers – this is conceptually applicable. To elaborate, if a number is already in this form, of course it is rational. But to claim the opposite is not that straight forward. How would you show that sqrt 2 (or pi) is irrational? There are infinitely many integers, so the ratios of two integers are infinitely many; if you just show an irrational number does not equal to many such ratios numerically, you made little progress in showing it is irrational.

In mathematics, if one is given an approximate value, then it does not make sense to ask whether the given value is rational or not. The reason is, there are infinitely many rational numbers that are so close to an irrational number (more strictly, we can construct a sequence of rational numbers which converge to, or has limit, to be the given irrational number). For example, consider sqrt 2

sqrt 2 = 1.414 213 562 373 .. ..

and the sequence

{1, 1.4, 1.41, 1.414, 1.4142, 1.41421, 1.414213, .. .. .. }

and the sequence

{2, 1.5, 1.42, 1.415, 1.4143, 1.41422, 1.414214, .. .. .. }

Of the above two sequences, each has the limit as sqrt 2 – which implies you cannot isolate an interval on the real axis to claim, all within that interval are irrational numbers. Between two irrational numbers, there are (infinitely) many rational numbers.

To make it meaningful to ask whether a number is irrational, it must be given in an exact form – two of such forms are radical numbers (like sqrt 2), or an expression that involve well known constant(s), e.g. pi + 2, where pi is the ratio (of a circle): DEFINED as the ratio of circumference to diameter. There are three simple rules that we can resort to for deciding whether a number given (in exact form) is irrational or not, as:

(a) The square root of a non perfect-square number is always an irrational number;

Or: if the square root of an integer is not an integer, then it must be an irrational number.

Example: sqrt 2, sqrt 5

(b) An irrational number added to (subtracted from) a rational number, or multiplied by (divided by) a rational number (the multiplier or divisor is not 0), will always result in an irrational number.

Example: sqrt 2 +1, 3 - sqrt 5

(c) If an arithmetic expression (only add/subtract/multiply/division) involves any count of rational numbers but only one irrational, and that irrational is not reduced to zero by a zero multiplier, then the result will always be an irrational number.

Example: pi + 2, 2 pi -1, {8/5} sqrt 3 - {1/2}, 1/ (3 pi -2)

If we are given a number that is not directly in any of the forms (i) (ii) (iii), then to use these rules, we will have to do some work: try simplifying the given expression while keeping the exact value.

Rule (a) shall be extended (as we shall consider the cubic root, fourth power root etc.) as: for a power root of n-th exponent (n is any integer), if the radicand is not a perfect n-th power number, then the result of this power root must be an irrational number. For example, root{4}{8} is an irrational number (since 8 is not a perfect 4-th power number).

To appreciate those rules, let us attempt the question below. Of the following numbers, which is a rational number, and which is an irrational number?

(i) (root{22}{22})^2, (ii) 2 (root{3}{13}) + {1/2} (root{6}{169}), (iii) 2/ (sqrt 9 + 6), (iv) (root{3}{10}) (4/5)^{4/3}

If you forget the definition of fraction exponent, you may want to quickly review for it. The key to the above question is: among the four numbers listed as (i) (ii) (iii) (iv):

  • (i) (ii) are irrational numbers: (ii) = {5/2} (root{3}{13}), (i) = root{11}{22};
  • (iii) (iv) are rational numbers: (iii) = {2/9}, (iv) = {8/5} .

Suppose an expression results in a rational number. Only a slight change will bring it to an irrational number. For example, 2/ (sqrt 10 + 6) is an irrational number (since the square root of 10 is irrational, which adds to 6 to get a sum, then take reciprocal and then double). See how similar the form is to the given form (iii) !

In the next post, for the first rule — rule (a) — an example (sqrt 2) will be shown strictly as an irrational number (we not only know that rule, but also try to understand why the rule stands true).

Meanwhile, we note the constant pi is defined as a ratio (checking up the definition – if you want), and we say it is an irrational number. Why so? Find the explanation in the next post.

Proof: Diameter is the shortest curve that bisects circular area

The picture below actually shows the proof.

The goal is to show the red line (which is supposed to bisect circular area) is longer than the diameter AB’.
We see it from:

Length of red curve AB is greater than: AE + EB = AE + EB’

which is certainly longer than AB.

Just one more minute. Let’s review the construction-proof process.

Connect the two endpoints A, B of the curve by a line segment. Draw diameter CD // AB.

Take O (the midpoint of CD), then passing A and O we get another diameter AB’.

The two arguments needed for completing proof are:

(1) Red line must have at least one intersection with diameter CD; (think like this: if the red line resides completely at only one side, then there is no point that it can evenly divide the circular area) Suppose the intersection is at point E;

(2) B and B’ are symmetric to the diameter CD therefore EB = EB’ (think on why? using the property of circles and parallel lines)

Now the rest of the proof is straight forward.

Complete Numbers in Fraction Equations

The formula on our face page of “amazing numbers” is rather interesting:
1 – (1 ⁄ 28) = (1 ⁄ 2) + (1 ⁄ 4) + (1 ⁄ 7) + (1 ⁄ 14)

The point of interest is that: if you look at all divisors of 28: they are 1,2,4,7,14,28; with the exception of 28 which is itself, all divisors have appeared in this formula, and they appear in the form of so-called “unit fraction”, where numerator is 1. So (1 ⁄ 2), (1 ⁄ 4), etc. are all unit fractions.

Indeed, we present a fraction equation to make it a bit unusual, but there is a low-pitch but straightforward ways to present number 28. We have that:
28 = 1 + 2 + 4 + 7 + 14
To get to the earlier fraction form, just divide every term by the number 28.

The smallest complete number is 6 (=1+2+3), 28 is the 2nd complete number, and after that, you will not see a complete number until 496. So complete numbers are rare among all positive whole numbers.

Complete numbers 6 also has a nice fraction form, as:
1 – (1⁄6) = (1⁄2) + (1⁄3)

3D objects with 3 views from top, front and side

For a 3D objects, given three views to you: one from top, one from front, and one from side, can you imagine what the original 3D objects looks like?

The question is not posed to a mechanic engineer, it would be trivial in that case. The question is raised to get a junior middle student to think a bit.

For a cylinder one of the three views is a circle, and the other two views are rectangles. For a cone one of the views is a circle, and the other two views are triangles. What if the three views given are a circle, a rectangle and a triangle? Can you figure out the original shape?