What does the graph of a^(x^x) look like and what are its applications?

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Discussion Overview

The discussion revolves around the function a^(x^x), exploring its graph, potential applications, and differentiation. Participants express curiosity about the behavior of this function and its steepness compared to standard exponential functions.

Discussion Character

  • Exploratory
  • Mathematical reasoning
  • Conceptual clarification

Main Points Raised

  • Oscar questions the nature of the graph for the function a^(x^x) and its practical applications.
  • Another participant suggests that the graph would resemble a standard exponential graph but be significantly steeper.
  • Oscar attempts to differentiate the function, starting with y = e^(x^x) and expresses uncertainty about the differentiation process.
  • There is a discussion about the correct application of the chain rule in differentiation, with various participants contributing to the differentiation steps.
  • One participant humorously notes a preference for studying y = e^(x^(x^x)), highlighting its rapid growth and providing specific values for x.

Areas of Agreement / Disagreement

Participants generally agree that the function a^(x^x) is steep and resembles exponential growth, but there is no consensus on its practical applications or the exact nature of its graph. Differentiation steps are debated, indicating some uncertainty in the mathematical process.

Contextual Notes

There are unresolved aspects regarding the differentiation of the function, including assumptions about logarithmic bases and the application of differentiation rules. The discussion also touches on the rapid growth of related functions without establishing formal conclusions.

2^Oscar
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Hey guys,

I was wondering about what a graph would look like where the power to a did not increase at a linear rate i.e

a^(x^x)

Is there such a recognised function as this? If so does it have any practical applications and what does the graph look like?

Thanks,

Oscar
 
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Hey 2Oscar! :smile:
2^Oscar said:
I was wondering about what a graph would look like where the power to a did not increase at a linear rate i.e

a^(x^x)

Is there such a recognised function as this? If so does it have any practical applications and what does the graph look like?

Never seen anything like it!

I'd be very surprised if it does have any practical applications.

Its graph would be like ax, only very much steeper. :smile:

Why don't you try working out its derivative? :wink:
 


I'm unsure on how to differentiate a^x tbh... but i think i can do it for e^x...

so y= e^(x^x)

dy/dx = x2e^(x^x)?


My graphical calculator goes weird when i try to draw it lol... but i can see why it would be like a normal exponential graph just steeper.

Thanks,

Oscar
 
2^Oscar said:
so y= e^(x^x)

dy/dx = x2e^(x^x)?

No …

e^(xx) = e^(exlogx),

so it's not x2, but d/dx(exlogx), = … ? :smile:

(and a^(xx) = e^(xxloga) wink:)
 


sorry if I am misunderstanding... is the log to the base e?

If so then d/dx(e^xlogx) = (xlogx)e^(xlogx)?

Or perhaps d/dx(e^xlogx) = e^x2?

Sorry if i sound daft... not too familiar with this stuff :S


Thanks,

Oscar
 
No, use the chain rule …

d/dx(exlogx) = exlogx d/dx(xlogx) :smile:

(use the X2 tag just above the reply box :wink:)
 


so xlogx differentiates to 1+logx?

so (1+logx)exlogx?
 
2^Oscar said:
so xlogx differentiates to 1+logx?

so (1+logx)exlogx?

Yup! :biggrin:
 


Oh wow so the end differentiation is (1+logx)exlogxex^x?


Thanks so much for your help :D

Oscar
 
  • #10
You can simplify it a bit more …

(1+logx)xxex^x :wink:
 
  • #11


2^Oscar said:
Hey guys,

I was wondering about what a graph would look like where the power to a did not increase at a linear rate i.e

a^(x^x)

Usually when you look into powers that increase at a rate rather than linear, you try quadratic, not exponential :-p

While I don't think it applies to anything, I'm more curious to dedicate my life studying:

[tex]y=e^{x^{x^x}}[/tex]

There is growing interest in the field of BS-mathematics :wink:

If you haven't noticed yet, it grows pretty fast.

[tex]x=1 ~ y=e[/tex]
[tex]x=1.5 ~ y=8[/tex]
[tex]x=2 ~ y=9,000,000[/tex]
[tex]x=2.3 ~ y>googol[/tex]
 

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