Helpl with a few questions (1 Viewer)

mreditor16 · Mar 8, 2015

So, I've started MATH at uni, and they have given us some Qs which 'revises' 3U and 4U content. I am stuck on a few, so any help on these would be much appreciated.

1. At the time of printing, the largest known prime number (found in August 2008) is (2^43112609) - 1

How many digits are in its decimal expansion (hint - think log base 10)

2. By taking cases or otherwise, prove that 1 + x +x^2 + x^3 + x^4 is always positive.

As I go along, I might have a few more, which I will update this post with!

Thanks a lot!

faisalabdul16 · Mar 8, 2015

Provide the cases...

The original question tells you what cases to consider

InteGrand · Mar 8, 2015

mreditor16 said:
So, I've started MATH at uni, and they have given us some Qs which 'revises' 3U and 4U content. I am stuck on a few, so any help on these would be much appreciated.

1. At the time of printing, the largest known prime number (found in August 2008) is (2^43112609) - 1

How many digits are in its decimal expansion (hint - think log base 10)

2. By taking cases or otherwise, prove that 1 + x +x^2 + x^3 + x^4 is always positive.

As I go along, I might have a few more, which I will update this post with!

Thanks a lot!

1. By inspection, the number of digits in the decimal expansion of an integer N > 0 is $\left \lfloor \log _{10}N \right \rfloor +1$ . (e.g. number of digits in 10^3.4421 is 3+1=4 (ignoring the fractional part of the number)).

Therefore, the number of digits in the decimal expansion of $2^{43112609}-1$ is:

$\left \lfloor \log _{10}(2^{43112609}-1) \right \rfloor +1$

$=\left \lfloor \log _{10}(2^{43112609}) \right \rfloor +1$ , since the number of digits in the decimal expansion of $2^{43112609}-1$ equals that of $2^{43112609}$ , since $2^n \neq 10^k$ for positive integers n, k

$=\left \lfloor 43112609\log _{10}(2) \right \rfloor +1$ (log laws)

$=\left \lfloor 12978188.5.... \right \rfloor +1$

$=12978188+1$

$=12978189$ .

mreditor16 · Mar 8, 2015

faisalabdul16 said:
Provide the cases...

The original question tells you what cases to consider

Oh haha yep, forgot to include them.

The cases are x >= 0 , -1 < x < 0 and x<= -1

mreditor16 · Mar 8, 2015

InteGrand said:
1. By inspection, the number of digits in the decimal expansion of an integer N > 0 is $\left \lfloor \log _{10}N \right \rfloor +1$ . (e.g. number of digits in 10^3.4421 is 3+1=4 (ignoring the fractional part of the number)).

Are you expected to pluck that out of nowhere? Like how do you realise that to be your first step?

InteGrand · Mar 8, 2015

mreditor16 said:
So, I've started MATH at uni, and they have given us some Qs which 'revises' 3U and 4U content. I am stuck on a few, so any help on these would be much appreciated.

1. At the time of printing, the largest known prime number (found in August 2008) is (2^43112609) - 1

How many digits are in its decimal expansion (hint - think log base 10)

2. By taking cases or otherwise, prove that 1 + x +x^2 + x^3 + x^4 is always positive.

As I go along, I might have a few more, which I will update this post with!

Thanks a lot!

2. For any $x\geq 0$ , the given polynomial is obviously positive. By the sum of a geometric series, the given polynomial equals $\frac{x^5 - 1}{x-1}$ . Clearly, for any x < 0, this has a negative numerator, and a negative denominator, so the overall fraction (and hence the polynomial) is positive.

Hence the given polynomial is positive for all real x.

InteGrand · Mar 8, 2015

mreditor16 said:
Are you expected to pluck that out of nowhere? Like how do you realise that to be your first step?

Well, when a number equals "10^something", it's like 1, with "something" 0's after it, which is "something +1" digits in base 10. This "something" can be written as $\left \lfloor \text{something} \right \rfloor + \{\text{something}\}$ , where $\{\text{something}\} \in [0,1)$ . So

$10^x=10^{\left \lfloor x \right \rfloor+\{x\}}=10^{\{x\}}\cdot10^{\left \lfloor x \right \rfloor}$ .

Clearly, it's the $10^{\left \lfloor x \right \rfloor}$ that controls the number of digits, which will then be $\left \lfloor x \right \rfloor+1$ as mentioned earlier. (The $10^{\{x\}}\in [1,10)$ controls what those digits are.)

And this "something" is just $\log _{10} N$ , since $N = 10^{\log_{10}N}$

mreditor16 · Mar 8, 2015

Got one more question:

I keep getting 0.863163549....

but the answers say 0.5

:/

InteGrand · Mar 8, 2015

mreditor16 said:
Got one more question:

I keep getting 0.863163549....

but the answers say 0.5

:/

I guess the answers are wrong, it should be what you got $\left ( \frac{1}{2-\cos(1)}\right )$ .

Maybe when the answers were written, they forgot they asked for $g^\prime (1)$ and thought they'd asked for $g^\prime (0)$ , which would be 0.5.

Edit: wait, I might be wrong

Edit 2: Yeah, it's 0.5.

enigma_1 · Mar 8, 2015

faisalabdul16 said:
Provide the cases...

The original question tells you what cases to consider

welcome back

mreditor16 · Mar 8, 2015

InteGrand said:
I guess the answers are wrong, it should be what you got $\left ( \frac{1}{2-\cos(1)}\right )$ .

Maybe when the answers were written, they forgot they asked for $g^\prime (1)$ and thought they'd asked for $g^\prime (0)$ , which would be 0.5.

Edit: wait, I might be wrong

Edit 2: Yeah, it's 0.5.

Wait how, and I got 1 / (2 - sin(1)) keeping in mind radians mode.

InteGrand · Mar 8, 2015

(0,1) lies on the graph of f(x), so the corresponding point on the graph of g(x) is (1,0), and at this point, the slope is the reciprocal of that on (0,1) of f(x), which is $\frac{1}{2}$ .

InteGrand · Mar 8, 2015

mreditor16 said:
Wait how, and I got 1 / (2 - sin(1)) keeping in mind radians mode.

Sorry, I meant sin (typo)

InteGrand · Mar 8, 2015

So if $f:A\to B$ and $g:B \to A$ are inverse functions, and $f(a)=b\Leftrightarrow g(b)=a$ , then $f^\prime (a)=\frac{1}{g^\prime (b)}$ , provided $g^\prime (b) \neq 0$ .

mreditor16 · Mar 8, 2015

InteGrand said:
(0,1) lies on the graph of f(x), so the corresponding point on the graph of g(x) is (1,0), and at this point, the slope is the reciprocal of that on (0,1) of f(x), which is $\frac{1}{2}$ .

ohhhh, I got an expression for derivative of g(x) in previous post, but subbed in x=1 instead of y=0 oops thanks

mreditor16 · Mar 8, 2015

Can anyone help me with part c)?

buriza · Mar 8, 2015

mreditor16 said:
Can anyone help me with part c)?

Sy123 said:
$\\ $Re-arrange the inequality in part$ \ (b) \ $to get$ \ \ \frac{1}{e} < \frac{k^k}{(1+k)^k}< \frac{k+1}{k} \frac{1}{e}\\ \\ $This inequality is true for$ \ k=1,2,\dots,n \ $so, substitute each possible value of$ \ k \ $in and then multiply all inequalities side by side, i.e.$ \\ \\ \prod_{k=1}^n \frac{1}{e} < \prod_{k=1}^n \frac{k^k}{(1+k)^k} < \prod_{k=1}^n \frac{k+1}{k} \frac{1}{e} \\ \\ \Rightarrow \ \frac{1}{e^n} < \frac{1^1}{2^1}\cdot \frac{2^2}{3^2} \cdot \frac{3^3}{4^3} \dots \frac{n^n}{(1+n)^n} < \frac{2}{1} \cdot \frac{3}{2} \cdot \dots \frac{n+1}{n} \frac{1}{e^n} \\ \\ \Rightarrow \ \frac{1}{e^n} < \frac{n!}{(1+n)^n} < \frac{n+1}{e^n} \\ \\ \Rightarrow \ \frac{(1+n)^n}{e^n} < n! < \frac{(1+n)^{1+n}}{e^n}$

Reposting from the other thread.

mreditor16 · Mar 8, 2015

buriza said:
Reposting from the other thread.

Thanks Buriza!

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