a question regarding irrational numbers

MattcAnderson · 2020-07-18, 07:15

Hi again all,

Please look at the following conjecture.
Note that in mathematics, conjecture means 'probably true'.

Conjecture about irrational numbers

Let k be an arbitrary chosen counting number.

Consider S = sqrt(a0) + sqrt(a1) + ... + sqrt(ak).

Where a0, a1, ... , ak are square free positive integers.

Conjecture that S is therefore irrational.

This might be an open question.

For what its worth
Matt

retina · 2020-07-18, 07:36

Quote:

Originally Posted by MattcAnderson

Let k be an arbitrary chosen counting number.

Consider S = sqrt(a0) + sqrt(a1) + ... + sqrt(ak).

Where a0, a1, ... , ak are square free positive integers.

Conjecture that S is therefore irrational.

I choose k = 0

MattcAnderson · 2020-07-18, 07:58

k=0 is an excellent choice.
From the rational root theorem, we have that the square root of any positive integer that is not itself a perfect square, is irrational.

Consider an example with k=1.
Let S1 = sqrt(2) + sqrt(3)
I am pretty sure that S1 is irrational. However, I do not know how to prove this.

Regards,
Matt

Batalov · 2020-07-18, 08:14

Quote:

Originally Posted by MattcAnderson

Let S1 = sqrt(2) + sqrt(3)
I am pretty sure that S1 is irrational. However, I do not know how to prove this.

Did you try to google for an answer?

retina · 2020-07-18, 08:42

Quote:

Originally Posted by MattcAnderson

k=0 is an excellent choice.
From the rational root theorem, we have that the square root of any positive integer that is not itself a perfect square, is irrational.

For k = 0: S = sqrt(0) = 0

Or do I misunderstand?

MattcAnderson · 2020-07-18, 09:04

A google search of
"Is square root of 2 plus square root of 3 rational"
helped me find a webpage at proofsfromthebook.com

The restriction on the a_i is that the numbers are Positive and not squares.

So zero is not allowed in this conjecture.

The various a_i must be in the set {2,3,5,6,7,8,10, …}

Regards,
Matt

LaurV · 2020-07-18, 09:31

There is a recent Mathologer video about this. Quite nice to watch, actually (don't look to his eyes!

)

Dr Sardonicus · 2020-07-18, 11:47

Since 1 is the only squarefree positive integer that is also a square, you could specify that a_i is squarefree, and a_i > 1 for every i from 0 to k.

Assertion: If no non-empty product of the a_i is a square, then the numbers 1, sqrt(a₀), sqrt(a₁), ... sqrt(a_k) are linearly independent over Q (field of rational numbers). [This assertion implies your result.]

Sketch of proof:

Let p₁, p₂, ..., p_r be distinct prime numbers such that a_i divides the product p₁p₂...p_r for i = 0 to k.

The extension K = Q(sqrt(p₁), sqrt(p₂), ... sqrt(p_r)) is of degree 2^r over Q.

For each subset s of S = {1, 2, ...r} let P_s be the product of the primes p_i, i in s. Then there are 2^r products P_s. These products include 1 (empty product) and all the a_i. Every element of K can be expressed as a Q-linear combination of these 2^r products. They are, therefore, a Q-basis for K, hence linearly independent over Q. Thus any non-empty subset is also linearly independent over Q.

kriesel · 2020-07-18, 16:19

Quote:

Originally Posted by retina

For k = 0: S = sqrt(0) = 0

Or do I misunderstand?

I took his description to be sum of k terms.
The sum of 0 terms would be 0.
S=sum over 0 to k of sqrt(k). Depending on whether you test before or after summing, you get 1 or 0 terms. But 0 as a term may be as disqualified as 1.
k=0 would seem to be excluded by "counting number".

MattcAnderson · 2020-07-20, 03:53

I learned something.
The mathologger video about irrationals was helpful.
Wolfram Alpha has a command called MinimumPolynomial().
You input an expression, which can have square roots, and it will give you the monic polynomial with minimal degree, that has a root that is the argument in the command. This with the integer root theorem shows the irrationality of the expression
S = sqrt(a0) + sqrt(a1) + … + sqrt(ak)
and require all ai >2, and integer and not a perfect square.

Done.

MattcAnderson · 2020-07-20, 05:09

oops, I meant to allow 2 for any ai with 1>= i >= k

Also, a related conjecture is

Let S2 = q + sqrt(r).
where q is any rational number and r is and integer and not a square and greater than one.

show that S2 is irrational.

Regards,
Matt

2020-07-18, 07:15	#1
MattcAnderson "Matthew Anderson" Dec 2010 Oregon, USA 2⁵×5² Posts	a question regarding irrational numbers Hi again all, Please look at the following conjecture. Note that in mathematics, conjecture means 'probably true'. Conjecture about irrational numbers Let k be an arbitrary chosen counting number. Consider S = sqrt(a0) + sqrt(a1) + ... + sqrt(ak). Where a0, a1, ... , ak are square free positive integers. Conjecture that S is therefore irrational. This might be an open question. For what its worth Matt

2020-07-18, 09:04	#6
MattcAnderson "Matthew Anderson" Dec 2010 Oregon, USA 320₁₆ Posts	A google search of "Is square root of 2 plus square root of 3 rational" helped me find a webpage at proofsfromthebook.com The restriction on the a_i is that the numbers are Positive and not squares. So zero is not allowed in this conjecture. The various a_i must be in the set {2,3,5,6,7,8,10, …} Regards, Matt Last fiddled with by MattcAnderson on 2020-07-18 at 09:06 Reason: added some set notation for clarity

2020-07-18, 11:47	#8
Dr Sardonicus Feb 2017 Nowhere 1223₁₆ Posts	Since 1 is the only squarefree positive integer that is also a square, you could specify that a_i is squarefree, and a_i > 1 for every i from 0 to k. Assertion: If no non-empty product of the a_i is a square, then the numbers 1, sqrt(a₀), sqrt(a₁), ... sqrt(a_k) are linearly independent over Q (field of rational numbers). [This assertion implies your result.] Sketch of proof: Let p₁, p₂, ..., p_r be distinct prime numbers such that a_i divides the product p₁p₂...p_r for i = 0 to k. The extension K = Q(sqrt(p₁), sqrt(p₂), ... sqrt(p_r)) is of degree 2^r over Q. For each subset s of S = {1, 2, ...r} let P_s be the product of the primes p_i, i in s. Then there are 2^r products P_s. These products include 1 (empty product) and all the a_i. Every element of K can be expressed as a Q-linear combination of these 2^r products. They are, therefore, a Q-basis for K, hence linearly independent over Q. Thus any non-empty subset is also linearly independent over Q. Last fiddled with by Dr Sardonicus on 2020-07-18 at 11:49 Reason: xifnix ostpy

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2020-07-18, 07:58	#3
MattcAnderson "Matthew Anderson" Dec 2010 Oregon, USA 2⁵·5² Posts	k=0 is an excellent choice. From the rational root theorem, we have that the square root of any positive integer that is not itself a perfect square, is irrational. Consider an example with k=1. Let S1 = sqrt(2) + sqrt(3) I am pretty sure that S1 is irrational. However, I do not know how to prove this. Regards, Matt

2020-07-18, 09:31	#7
LaurV Romulan Interpreter Jun 2011 Thailand 22613₈ Posts	There is a recent Mathologer video about this. Quite nice to watch, actually (don't look to his eyes! )

2020-07-20, 03:53	#10
MattcAnderson "Matthew Anderson" Dec 2010 Oregon, USA 2⁵·5² Posts	I learned something. The mathologger video about irrationals was helpful. Wolfram Alpha has a command called MinimumPolynomial(). You input an expression, which can have square roots, and it will give you the monic polynomial with minimal degree, that has a root that is the argument in the command. This with the integer root theorem shows the irrationality of the expression S = sqrt(a0) + sqrt(a1) + … + sqrt(ak) and require all ai >2, and integer and not a perfect square. Done.

2020-07-20, 05:09	#11
MattcAnderson "Matthew Anderson" Dec 2010 Oregon, USA 320₁₆ Posts	oops, I meant to allow 2 for any ai with 1>= i >= k Also, a related conjecture is Let S2 = q + sqrt(r). where q is any rational number and r is and integer and not a square and greater than one. show that S2 is irrational. Regards, Matt