Evaluate the limit #lim_(x rarr 1) sin(pix)/(1-x)#?

4 Answers
May 12, 2017

#lim_(xrarr-1)(sin(pi*x)/(1-x))=pi#

Explanation:

The original expression was in indeterminate form. Since you get #0/0# if you evaluate directly with #x=1#.
Apply the L'Hospital's Rule to solve this problem. How do you use L'hospital's rule to find the limit?
Here are my steps:
#lim_(xrarr1)(sin(pi*x)/(1-x))#
#=lim_(xrarr1)((d/dx*sin(pi*x))/(d/dx*(1-x)))#
#=lim_(xrarr1)((pi*cos(pi*x))/(-1))#
#=lim_(xrarr1)((pi*cos(pi))/(-1))#
#=pi*((-1)/-1)#
#=pi#

May 12, 2017

Answer: #pi#

Explanation:

Find the limit of
#lim_(x->1)(sin(pix))/(x-1)#

Note that this is an indeterminate form: #0//0#. We can use L'Hopital's Rule to solve this equation.

Applying L'Hopital's Rule, we get that
#lim_(x->1)(sin(pix))/(x-1)=lim_(x->1)(d/dx(sin(pix)))/(d/dx(x-1))#
#=lim_(x->1)(picos(pix))/(-1)#
#=lim_(x->1)-picos(pix)#

The limit of a continuous function at a point is just it's value there.

#=lim_(x->1)-picos(pix)=-picos(pi)=pi#

May 12, 2017

# lim_(x rarr 1) sin(pix)/(1-x) = pi#

Explanation:

We want to find the limit:

# L = lim_(x rarr 1) sin(pix)/(1-x) #

Let us make a simple substitution:

Let #\ \ u =pi(1-x)=pi-pix #

Then # pix = pi - u #, and #1-x=u/pi#
As # x rarr 1 => u rarr 0 #

Then the limit becomes:

# L = lim_(u rarr 0) sin(pi-u)/(u/pi) #
# \ \ = lim_(u rarr 0) pi \ {sinpicosu-cospisinu}/u #
# \ \ = pi \ lim_(u rarr 0) {sinpicosu-cospisinu}/u #

Using #sinpi=0# and #cospi=-1# we have:

# L = pi \ lim_(u rarr 0) (sinu)/u #

And an elementary trigonometry calculus limit is that

# lim_(theta rarr 0) (sintheta)/theta = 1 #

Leading to:

# L = pi #

If we look at the graph of the function:
graph{sin(pix)/(1-x) [-4.123, 5.74, -0.818, 4.11]}

We note that at #x=1# the function is continuous (so the limit exists), and has a value slightly above #3# consistence with our analysis.

May 12, 2017

#lim_(x->1) sin(pix)/(1-x)= pi#

Explanation:

The limit:

#lim_(x->1) sin(pix)/(1-x)#

is in the indeterminate form #0/0# so we can solve it using l'Hospital's rule:

#lim_(x->1) sin(pix)/(1-x) = lim_(x->1) (d/dx sin(pix))/(d/dx (1-x)) = lim_(x->1) (picos(pix))/(-1)=pi#

Alternatively it can be resolved algebraically by substituting #t= pi(1-x)#, so that #x=1-t/pi#:

#lim_(x->1) sin(pix)/(1-x) = lim_(t->0) sin(pi(1-t/pi))/(1-(1-t/pi)) = pi lim_(t->0) sin(pi-t)/t #

Using the formula for the sine of the sum of two angles:

#sin(pi-t) = sinpi cos(t) -cospi sin(t) = sin(t)#

then:

#lim_(x->1) sin(pix)/(1-x) = pi lim_(t->0) sint/t = pi #