How do you find an expression for #sin(x)# in terms of #e^(ix)# and #e^(ix)#?

3 Answers
Jun 4, 2018

#sinx = (e^(ix) - e^(-ix))/(2i)#

Explanation:

Start from the MacLaurin series of the exponential function:

#e^x = sum_(n=0)^oo x^n/(n!)#

so:

#e^(ix) = sum_(n=0)^oo (ix)^n/(n!) = sum_(n=0)^oo i^nx^n/(n!) #

Separate now the terms for #n# even and #n# odd, and let #n=2k# in the first case, #n= 2k+1# in the second:

#e^(ix) = sum_(k=0)^oo i^(2k) x^(2k)/((2k)!) + sum_(k=0)^oo i^(2k+1)x^(2k+1)/((2k+1)!) #

Note now that:

#i^(2k) = (i^2)^k = (-1)^k#

#i^(2k+1) = i*i^(2k) = i*(-1)^k#

so:

#e^(ix) = sum_(k=0)^oo (-1)^k x^(2k)/((2k)!) + isum_(k=0)^oo (-1)^k x^(2k+1)/((2k+1)!) #

and we can recognize the MacLaurin expansions of #cosx# and #sinx#:

#e^(ix) = cosx +i sinx#

which is Euler's formula.

Considering that #cosx# is an even function and #sinx# and odd function then we have:

#e^(-ix) = cos(-x) + i sin(-x) = cosx-i sinx#

then:

#e^(ix) - e^(-ix) = 2i sinx#

and finally:

#sinx = (e^(ix) - e^(-ix))/(2i)#

Jun 4, 2018

Other approach to problem. See below

Explanation:

We know that #e^(ix)=cosx+isinx# (Euler)

Similarly, #e^(-ix)=cos(-x)+isin(-x)#

But we know that #cos(-x)=cosx# and #sin(-x)=-sinx#

Then we have

#e^(ix)=cosx+isinx#
#e^(-ix)=cosx-isinx#

Adding both identities

#e^(ix)+e^(-ix)=2cosx# and finally #cosx=(e^(ix)+e^(-ix))/2#

Subtarcting both, we have

#e^(ix)-e^(-ix)=2isinx# and then #sinx=(e^(ix)-e^(-ix))/(2i)#

Jun 4, 2018

Compare the Maclaurin series of #sinx# and #e^x# and construct the relation from that:
#sinx=1/(2i)(e^(ix)-e^(-ix))#

Explanation:

I assume the final formula in the question should read #e^(-ix)#?

Compare the Maclaurin series of #sinx# and #e^x# and construct the relation from that. We'll take as given the series for these functions. Deriving these is a pleasure in itself, one easily found elsewhere on the web, e.g.
http://blogs.ubc.ca/infiniteseriesmodule/units/unit-3-power-series/taylor-series/maclaurin-expansion-of-sinx/
http://www.songho.ca/math/taylor/taylor_exp.html
Note that both of these series are convergent over the whole range of #x#.

#sinx=x-(x^3)/(3!)+(x^5)/(5!)-...+(-1)^nx^(2n+1)/((2n+1)!)+...#
#e^x=1+x+x^2/(2!)+x^3/(3!)+...+x^n/(n!)+...#

We can immediately see that the terms in the sine series are very similar to those in the exponential series - they're the same size where they exist, but often have the opposite sign, and half of them are missing.

Recalling that the powers of #i# change in a periodic four-step pattern that has two successive plus signs and two successive minus signs, we wonder if changing #x# to #ix# in the exponential series might help our sign problem. We substitute:

#e^(ix)=1+ix+(ix)^2/(2!)+(ix)^3/(3!)+...+(ix)^n/(n!)+...#
which becomes
#e^(ix)=1+ix-x^2/(2!)-ix^3/(3!)+x^4/(4!)+...+(ix)^n/(n!)+...#

To remove every second term, we combine it with the series for #e^(-ix)#:
#e^(-ix)=1+(-ix)+(-ix)^2/(2!)+(-ix)^3/(3!)+...+(-ix)^n/(n!)+...#
which becomes (be careful combining minus signs and #i^2#s!)
#e^(-ix)=1-ix-x^2/(2!)-ix^3/(3!)+x^4/(2!)-...+(-ix)^n/(n!)+...#

When we take the difference of these series term by term, we get closer to what we want (NB taking the sum of them gives us a relation for #cosx# instead - give it a try). Note that the terms of even powers of #x# are identical in the two series, so their difference is 0.

#e^(ix)-e^(-ix)=2ix-2ix^3/(3!)+2ix^5/(5!)-...+2i(-1)^nx^(2n+1)/((2n+1)!)+...#

which is just the series above for #sinx# multiplied by #2i#. So we have our desired relation:

#sinx=1/(2i)(e^(ix)-e^(-ix))#

Compare at this point the hyperbolic functions, which you may have been introduced to already. In particular, note the definition of #sinhx# ("hyperbolic sine"; "sinh" is pronounced in one of several ways - "shine", "sinch", etc.):

#sinhx=1/2(e^x-e^(-x))#

The hyperbolic functions are a set of functions closely related to the trig functions via these formulae. As you progress with differential equations, you'll encounter situations where a simple change of sign to a coefficient makes the difference between finding trig function and hyperbolic function solutions. The relation between the two sets of functions is an important one.