Dick said:You should start by not connecting all of the steps in your problem with an '=' sign. Do a simple example first. y=x^2. ln(y)=ln(x^2)=2*ln(x). Now differentiate. y'/y=2/x. So y'=2y/x=2x^2/x=2x. That's true. Now note that y and ln(y) are not equal. Nor is y=(ln(y))'. Take the log of both sides, then solve for y'.
Dick said:Put parentheses around your denominators, ok? I.e. write y'/y = 2/x + 6x/(x^2-1) + 4/(x+1). But, yes, it's right so far. Now I think you just need to try and simplify it.
Dick said:y'= 2x (x^2 - 1)^3 (x+1)^4 + 6x^3 (x^2 - 1)^2 (x+1)^4 + 4 x^2 (x^2 - 1)^3 (x+1)^3 is also right. Take out the common factors and try and simplify what's left.
Dick said:The point is that your answer is already right. There's nothing wrong with what you did. But you said "Still I am not having the result." I assume that means you haven't simplified it enough to get the form of the answer you want. Is that right? In that case, that's where it's going. You can immediately factor out the highest power of each factor in your expression. That would be x*(x^2-1)^2*(x+1)^3. Then try and factor what's left. What is the answer you are looking for anyway?
Jimmy84 said:The answer I am looking for is 2x(x+1)^6 (x-1)^2 (6x^2 -2x -1)
Dick said:Ok, that's the same as your answer in a different form. Notice (x^2-1)=(x-1)*(x+1). Just combine and factor.
Jimmy84 said:Let me see, I still don't get the result. From
2x (x^2 - 1)^3 (x+1)^4 + 6x^3 (x^2 - 1)^2 (x+1)^4 + 4 x^2 (x^2 - 1)^3 (x+1)^3
(x^2-1)^3 = (x-1)^1.5 (x+1)^1.5 ?
So by adding all the (x^2 - 1) terms I get (x-1)^4 (x+1)^4
Plus the other (x+1) terms in the answer (x+1)^11 + (x+1)^4 = (x+1)^15 ?
Logarithmic differentiation is a method used to differentiate functions that involve both exponential and non-exponential terms. It involves taking the natural logarithm of both sides of an equation and then using the rules of logarithms to simplify the expression before differentiating.
Logarithmic differentiation is often used when differentiating functions that involve products, quotients, or powers of functions that cannot be easily differentiated using the standard rules of differentiation. It is also useful in simplifying complicated expressions before differentiating.
Logarithmic differentiation is different from other differentiation methods because it allows us to differentiate functions that involve both exponential and non-exponential terms. It also allows us to simplify complicated expressions before differentiating, making the process easier and more efficient.
The steps involved in logarithmic differentiation are as follows:
Logarithmic differentiation can be used for most functions, but it is most useful for functions that involve exponential and non-exponential terms. It may not be necessary for simpler functions that can be easily differentiated using the standard rules of differentiation.