LINK: Back to Contents
Monday, October 4, 2010
Monday, September 13, 2010
Thursday, August 26, 2010
Wednesday, August 25, 2010
Sunday, August 15, 2010
Sunday, April 25, 2010
AP Calculus HINTS
LINK: Back to Contents
1) You only need to get about 1/2 the questions
correct to pass with a "3".
2) With "Multiple Choice Questions", try to
eliminate one or more options and then
you can guess from the others. In guessing,
pick the one that looks the most like the
whole group of options.
3) With the "Show your Work Questions",
you must LABEL all graphs and number
lines that you use ( f or f ' or f " ).
4) If you use the Graphing Calculator to
find the Area, then be sure to write down
the DEFINITE INTEGRAL on the paper.
correct to pass with a "3".
2) With "Multiple Choice Questions", try to
eliminate one or more options and then
you can guess from the others. In guessing,
pick the one that looks the most like the
whole group of options.
3) With the "Show your Work Questions",
you must LABEL all graphs and number
lines that you use ( f or f ' or f " ).
4) If you use the Graphing Calculator to
find the Area, then be sure to write down
the DEFINITE INTEGRAL on the paper.
Friday, April 9, 2010
Symmetry of Functions / Graphs
LINK: Back to Contents
Three examples of how to
determine what type of
symmetry exists:
With Respect To - w.r.t.
Wednesday, March 10, 2010
Wednesday, March 3, 2010
How to find THE DERIVATIVE
Suppose a driver is on a highway with mile markers.
And also suppose that we would be able to know
the mile position that paired up with the elapsed
time on the highway.
For example:
after 1 hour the mile marker was 111
at 2 hours the marker was 171
at 1.1 hours the marker was 117
Moving into the world of Math:
( 1, 111 )
( 1.1, 117 )
( 2, 171 )
What y value would you assume
went with x = 0 ?
( 0, __?__ )
How about y = 51?
What assumption are you making?
(The speed was a constant 60 mph.)
*********************************************
Given a function f(x)
Suppose you want to know the INSTANTANEOUS
RATE OF CHANGE in the function at a particular
value of x. Let's say when x = a.
This is called the DERIVATIVE of f(x) @ x=a.
f ' (a) = ?
If f(x) is a LINEAR FUNCTION, then the slope
of the line gives the RATE OF CHANGE of y with
respect to a change in x. This ratio (Delta y)/ (Delta x)
is the constant m in the form
y = m x + b
You can check my blog for more on SLOPE!
In general, the SLOPE OF THE TANGENT
LINE TO THE CURVE at the particular value
of x ( x = a ) gives the INSTANTANEOUS
RATE OF CHANGE at this point.
In CALCULUS we look at the AVERAGE RATE
OF CHANGE to find the INSTANTANEOUS.
The AVERAGE RATE OF CHANGE is found by picking
two points on the curve and finding the slope
of the SECANT LINE that passes thru them.
Suppose we are looking for the SLOPE of the TANGENT
LINE (INSTANTANEOUS RATE OF CHANGE)
at the point on the curve where x=a. Let's call it point P.
Using one point on the curve as P ( a , f(a) )
We choose a point very close to P calling it Q.
Q can and should be allowed to be on either side of P.
After we find the SECANT SLOPE we make point Q
get very close to point P. As this happens we look for
the limit of these SECANT SLOPES.
LINK: Back to Contents
And also suppose that we would be able to know
the mile position that paired up with the elapsed
time on the highway.
For example:
after 1 hour the mile marker was 111
at 2 hours the marker was 171
at 1.1 hours the marker was 117
Moving into the world of Math:
( 1, 111 )
( 1.1, 117 )
( 2, 171 )
What y value would you assume
went with x = 0 ?
( 0, __?__ )
How about y = 51?
What assumption are you making?
(The speed was a constant 60 mph.)
*********************************************
Given a function f(x)
Suppose you want to know the INSTANTANEOUS
RATE OF CHANGE in the function at a particular
value of x. Let's say when x = a.
This is called the DERIVATIVE of f(x) @ x=a.
f ' (a) = ?
If f(x) is a LINEAR FUNCTION, then the slope
of the line gives the RATE OF CHANGE of y with
respect to a change in x. This ratio (Delta y)/ (Delta x)
is the constant m in the form
y = m x + b
You can check my blog for more on SLOPE!
In general, the SLOPE OF THE TANGENT
LINE TO THE CURVE at the particular value
of x ( x = a ) gives the INSTANTANEOUS
RATE OF CHANGE at this point.
In CALCULUS we look at the AVERAGE RATE
OF CHANGE to find the INSTANTANEOUS.
The AVERAGE RATE OF CHANGE is found by picking
two points on the curve and finding the slope
of the SECANT LINE that passes thru them.
Suppose we are looking for the SLOPE of the TANGENT
LINE (INSTANTANEOUS RATE OF CHANGE)
at the point on the curve where x=a. Let's call it point P.
Using one point on the curve as P ( a , f(a) )
We choose a point very close to P calling it Q.
Q can and should be allowed to be on either side of P.
After we find the SECANT SLOPE we make point Q
get very close to point P. As this happens we look for
the limit of these SECANT SLOPES.
LINK: Back to Contents
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