tiggerfamilytre
hammer of the underworld
- Joined
- Oct 8, 2004
- Messages
- 18
- Gender
- Male
- HSC
- 2005
My teacher couldn't do this, and I don't know where to begin. How do I simplify i to the i?
-
Looking for HSC notes and resources? Check out our Notes & Resources page
How do I simplify i to the i? (1 Viewer)
- Thread starter tiggerfamilytre
- Start date
Slidey
But pieces of what?
- Joined
- Jun 12, 2004
- Messages
- 6,600
- Gender
- Male
- HSC
- 2005
http://mathforum.org/library/drmath/view/53907.html
The critical line of that link is:
i^i = e^[0 + i^2 pi/2+ i^2 2kpi] = e^[- pi/2 - 2kpi]
That is: i^i has many values
The critical line of that link is:
i^i = e^[0 + i^2 pi/2+ i^2 2kpi] = e^[- pi/2 - 2kpi]
That is: i^i has many values
Last edited:
Trev
stix
wtf?!
ohh this thing, isnt this eulers theorem or something? i asked my math teacher bout this he didnt kno wat it was and he did 4u for hsc lol i just remember it got him thinking about pi and how pi is rational or something (i forget)
ohh this thing, isnt this eulers theorem or something? i asked my math teacher bout this he didnt kno wat it was and he did 4u for hsc lol i just remember it got him thinking about pi and how pi is rational or something (i forget)
Last edited:
Trev
stix
haha that site "I have been playing around with this equation and have
found some disturbing things." mmmmmyes disturbing mathematics
found some disturbing things." mmmmmyes disturbing mathematics
Trev
stix
eh? u tripper i sed i asked my math teacher (if he could prove it)shannonm said:
I was reffering to tiggerfamilytre's post not yours.
trev if your maths teacher doesnt know eulers formula he shouldnt be teaching (or was he reffering to the complex number 'i' when he said he didnt know what it was?)
edit-slidey beat me to it but the point remains
trev if your maths teacher doesnt know eulers formula he shouldnt be teaching (or was he reffering to the complex number 'i' when he said he didnt know what it was?)
edit-slidey beat me to it but the point remains
Trev
stix
he doesnt kno eulers thorem i think, i kno he cant prove it coz i remember that much
Captain pi
Member
Di Bona? I think he would know.Trev said:
Trev
stix
i asked him, aaages ago if he could prove it and he didnt kno how to, he probly knows tho. this arv he was goin on about how rosie is the iron chef and he is the guest chef or something, coz he never beats rosie lol
with a few quick changes.....shannonm said:
e^(ix) = cosx + isinx
when x = 5pi/2,
e^(i.5pi/2) = i (cos term = 0, sin term = i(1))
so i^i = e^(-5pi/2)
see i^i is actually e^(-5pi/2)!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!1
All right,
I don't think this result is especially trivial. Be nice to your maths teachers, when you haven't done complex analysis for years its easy to forget little tricks like these.
Basically to understand this question you just have to know Euler's formula
e^ix = cosx + isinx
so i = e^(i*(4k+1)Pi/2)
because we need cosx=0 and sinx=1 which is true at Pi/2,5Pi/2,...
Now you need to accept that the complex exponential function follows the same rules as the real exponential function ie (e^x)^y = e^(xy). There should be a proof of this somewhere on the net.
then
i^i
= e^(i^2*(4k+1)Pi/2)
= e^(-(4k+1)Pi/2)
= e^(-Pi/2-2kPi)
So the result is right but there is some subtlety involved. To see that you need to prove a result about the complex exponential consider the same proof using cisx notation
i^i
= (cos(4k+1)Pi/2 + isin(4k+1)Pi/2)^i
and it definitely isn't obvious how to proceed. The e^z notation is used to make clear the properties of the complex exponential function.
I don't think this result is especially trivial. Be nice to your maths teachers, when you haven't done complex analysis for years its easy to forget little tricks like these.
Basically to understand this question you just have to know Euler's formula
e^ix = cosx + isinx
so i = e^(i*(4k+1)Pi/2)
because we need cosx=0 and sinx=1 which is true at Pi/2,5Pi/2,...
Now you need to accept that the complex exponential function follows the same rules as the real exponential function ie (e^x)^y = e^(xy). There should be a proof of this somewhere on the net.
then
i^i
= e^(i^2*(4k+1)Pi/2)
= e^(-(4k+1)Pi/2)
= e^(-Pi/2-2kPi)
So the result is right but there is some subtlety involved. To see that you need to prove a result about the complex exponential consider the same proof using cisx notation
i^i
= (cos(4k+1)Pi/2 + isin(4k+1)Pi/2)^i
and it definitely isn't obvious how to proceed. The e^z notation is used to make clear the properties of the complex exponential function.
Last edited:
CrashOveride
Active Member
Slide Rule said:
Will Hunting
Member
Is it peculiar that I've spent a term plumbing the depths of Complex Numbers and have never heard of a Euler's theorum. I've been using a couple of Patel's publications as references and the said theorum has failed to present itself as yet. Please shed some light on this.
Slidey
But pieces of what?
- Joined
- Jun 12, 2004
- Messages
- 6,600
- Gender
- Male
- HSC
- 2005
It was removed from the syllabus ages ago, I think.
Basically, r.e^(i.@)=r.cis@
Very useful - you tend to use the exponential form in complex analysis - which is analysis (calculus) of complex numbers.
Somebody who's actually done complex analysis (martin?) might be able to shed some more light. It'll be 3 or so years before I can take it.
Basically, r.e^(i.@)=r.cis@
Very useful - you tend to use the exponential form in complex analysis - which is analysis (calculus) of complex numbers.
Somebody who's actually done complex analysis (martin?) might be able to shed some more light. It'll be 3 or so years before I can take it.
Arkad
Member
Basically thats what you get taught in first year uni for complex no. questions.Slide Rule said:
To be perfectly clear, none of the following is relevant in the NSW 4U maths course.
In first year uni we only did a week or two of complex numbers but Euler's formula was used a lot. I wondered why we didn't learn it in high school. I guess its difficult to give an honest proof and its very difficult to just accept it.
The standard proof uses Taylor series (infinite series that add together to give sin, cos or exponential functions) but there is another proof that uses differentiation and integration. All you have to accept is that you can differentiate and integrate complex functions as if i is a constant.
Here it is (ripped shamelessly from wikipedia)
Define the complex number z such that
z=cos x + i*sin x
Differentiating z with respect to x:
dz/dx=-sin x + i*cos x
Using the fact that i^2 = -1:
dz/dx=i^2*sin x + i*cos x=i*(cos x + i*sin x)=z*i
Separating variables and integrating both sides:
integral(1/z)dz=integral(i)dx
ln z=xi + C
where C is the constant of integration. To finish the proof we have to argue that it is zero. This is easily done by substituting x = 0.
lnz = C
But z is just equal to:
z = cosx + i*sinx = cos0 + i*sin0 = 1
thus
ln1 = C
C = 0
So now we just exponentiate
lnz = xi
e^lnz = e^xi
z = e^xi
e^xi = cosx + isinx
In first year uni we only did a week or two of complex numbers but Euler's formula was used a lot. I wondered why we didn't learn it in high school. I guess its difficult to give an honest proof and its very difficult to just accept it.
The standard proof uses Taylor series (infinite series that add together to give sin, cos or exponential functions) but there is another proof that uses differentiation and integration. All you have to accept is that you can differentiate and integrate complex functions as if i is a constant.
Here it is (ripped shamelessly from wikipedia)
Define the complex number z such that
z=cos x + i*sin x
Differentiating z with respect to x:
dz/dx=-sin x + i*cos x
Using the fact that i^2 = -1:
dz/dx=i^2*sin x + i*cos x=i*(cos x + i*sin x)=z*i
Separating variables and integrating both sides:
integral(1/z)dz=integral(i)dx
ln z=xi + C
where C is the constant of integration. To finish the proof we have to argue that it is zero. This is easily done by substituting x = 0.
lnz = C
But z is just equal to:
z = cosx + i*sinx = cos0 + i*sin0 = 1
thus
ln1 = C
C = 0
So now we just exponentiate
lnz = xi
e^lnz = e^xi
z = e^xi
e^xi = cosx + isinx