For the first question:
> Simplify down to: sinx(2sinx-1) = 0
> then solve: sinx = 0 and 2sinx-1 = 0 for x
For the second question:
> let (alpha) be one root and (beta) be another root such that (beta) = 2(alpha)
> Thus roots are (alpha) and 2(alpha)
> now (2k+4) = product of roots = (alpha)*2(alpha)= 2(alpha)^2
> Also (k+2) = sum of roots = (alpha) + 2(alpha) = 3(alpha)
> Solve simultaneous equations to solve for k (substitute alpha).
For the third question:
> Recall that differentiation is finding the tangent to the curve
> As f'(x) = 2x +12/x^4 is not continuous you cannot find tangent to the curve for ALL x (ie. x=0).
> :. answer is No; reason because the original function is a non-continuous function
For the fourth question:
> Recall that finding gradient of the tangent at a point is the same as finding the gradient of the curve of which the tangent belongs at that point, (3, 27)
> thus simply differentiate the curve y=3x^2
> Then use the gradient function and substitute for f'(3)
For your fifth question:
|x + 2| can be + or -
ie x+2 > 0
or x+2 < 0
Thus x>-2 or x<-2
When x>-2
x+2 / (x+2)(x-2)
1/(x-2)
When x<-2
(-x-2)/(x+2)(x-2)
-(x+2)/(x+2)(x-2)
-1/(x-2)
:. expression becomes +- 1/(x-2)
I think the fifth one is right but I'm not too sure; I'm not the best with absolute values... sorry :S Also not 100% on the third question... I'm not too sure what "differentiable for all x" means exactly. You can differentiate it and find the gradient function; however you cannot use all x within the gradient function to find the tangent. Thus that is why I think it's not "differentiable" for all x.
Rats; i was too slow
