Calculus BC

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Nana Liu

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Calculus BC
Calculus BC
6 cards

Cards (19)

Sharp turns on graphs are not differentiable.
Common Mistake: When doing a derivative, I forget that it is a product rule/quotient rule. 
Before doing a derivative right down, what properties need to be done (example: product, quotient, chain rule)
How do I solve this problem: $\frac{dx}{dy}[a^{f(x)} ]$  
$\frac{dx}{dy}[a^{f(x)} ]=$ $ln(a) \cdot a^ {f(x)} \cdot f'(x)$
What is the formula for derivative of inverse?
It is the following :
$g'(x)=$ $\frac{1}{f'(g(x)}$
Most of the time, we want to start at i = 0 or i = 1. It is more traditional to use i = 0 for left or midpoint sums and i = 1 for right sums
How do I solve these types of problems (Consider the sum 5+ (-7)+(-27)+(-55). Which expression is equal to the above sum  
Understand that the number of the top --> # of times you are doing this
A) correct
Let's say you are asked to take the derivative of this $g(x)=$ $\int_{0}^{x^4} cos(x) \,dx$
how would you do it?
Since the integral has a variable in the upper bound you plug in the upper bound and multiply it with the derivative of the variable.
How do you set up a partial decompostion
function = A/(something)+ B/(something)
To find the r value in a geometric series, you divide any term by the term before it. A geometric series with ratio r, diverges if r greater than or equal to 1. If r is in between 0 and 1 then it converges to this $s =$ $\frac{a}{1-r}$
The criteria to use the Integral test is that:
The function has to be positive
The function has to be decreasing
The function has to be continuous
The p-series looks like this : $\sum_{n=1}^{\infty} \frac {1}{n^p}$ where p can only be a positive constant. If p is greater than 1 it converges. If p is between 1 and zero it diverges.
Direct Comparison Test:
What is the limit comparison test? 
An and Bn is greater than 0. If Iimit of the ratio (an/bn) is L a finite and positive number that both series either both converge or diverge