How do you find the exact value of #log_3 (-9)#?

2 Answers
Dec 28, 2016

#=2+ik/ln3pi, k = 1, +-3, +-5... ,+-(2n+1)+....#

Explanation:

#log_b x# is complex of unlimited values, if x < 0.#

Here,

#log_3(-9)#

#=log_3(((+-i)^2)(3^2))#, where #i=sqrt(-1)##

#=2(log_3(+- )i+log_3 3)#

#=2(ln(+-i)/ln 3+1)#, using #log_b a = log _c a/log_cb#

#=2(ln(e^(ik/2pi)/ln3 +1), k = +-1, +--3, +- 5+ ...+- (2n+1),+....#

#=2+ik/ln3pi, k = 1, +-3, +- ... ++-(2n+1)+....#,

using # ln e^z =z#

Dec 28, 2016

#log_3 (-9)# is not defined within Real numbers.
As a Complex value I think the answer is
#color(white)("XXX")log_3(-9) =2+pi/ln(3) i#

Explanation:

For Real numbers the #log# function is only defined when its argument is non-negative.
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

For Complex Numbers:

It has been a long time since I've done this kind of thing so could someone check my results.

One of the common results of Euler's Formula: #e^(ix)=cos(x)+i * sin(x)#
is that
#color(white)("XXX")e^(ipi)=-1#
from which it follows that #log_e(-1)=ipi#

Also we will need to remember the "change of base" formula for logarithms:
#color(white)("XXX")log_a(p) = (log_b(p))/(log_b(a))#

....and here we go!

#log_3(-9) = log_3(9 xx (-1))#
#color(white)("XXX")=log_3(9) +log_3(-1)#

#color(white)("XXX")=2 +log_3(-1)#

#color(white)("XXX")=2+ (log_e (-1))/(log_e(3)#

#color(white)("XXX")=2+(ipi)/(log_e(3))#

or using the common notation of #ln(x)# for #log_e(x)#
and separating the #i# factor from the second term:
#color(white)("XXX")=2+pi/ln(3) i#