From http://www.intmath.com/integration/5-trapezoidal-rule.php
Area≈21(y0+y1)Δx+21(y1+y2)Δx+21(y2+y3)Δx+
Area≈Δx(2y0+y1+y2+y3+…+2yn) for uniform grid
The trapezoidal rule finds the area. To get the average
value, you will need to divide the area by b-a which is the
the difference between the final and initial x values.
Wednesday, October 29, 2014
Friday, October 24, 2014
Inverse of a straight line
The straight line graphs shown below are inverses of one another.
Given the invertible function f(x), we determine the inverse by:
- replacing every x with y and y with x;
Monday, October 20, 2014
Moving left and right, speeding up or slowing down?
From Khan Academy
Let's deal with moving left and right to start.
Let's deal with moving left and right to start.
The particle is moving to the right when its velocity is positively valued; that is, when v(t)>0.
The particle is moving to the left when its velocity is negatively valued; that is, when v(t)<0.
Now we consider when the particle is speeding up and slowing down.
The particle is speeding up for those times when the product of its velocity and its acceleration is greater than zero. Therefore we want
v(t)⋅a(t)>0.
For this condition to be satisfied, we want those times when v(t) and a(t) are both positively valued or both negatively valued.
In contrast, he particle is slowing down for those times when the product of the velocity and the acceleration is less than zero. Therefore we want
v(t)⋅a(t)<0.
Friday, October 10, 2014
The fundamental theorem of calculus
The Fundamental Theorem of Calculus
Suppose f is continuous on [a,b].
1) If y=∫xaf(t)dt , then dydx=f(x).
2) ∫baf(t)dt=F(b)−F(a) , where F is an antiderivative of f.
The theorem can be applied in many instances. One of which is as shown, for finding a function that increases or is concaved upwards.
The function F is increasing on the interval(s) where its derivative f is positive in value.
The function F is concave up on the interval(s) where its derivative f is increasing.
The Fundamental Theorem of Calculus
Suppose f is continuous on [a,b].
1) If y=∫xaf(t)dt , then dydx=f(x).
2) ∫baf(t)dt=F(b)−F(a) , where F is an antiderivative of f.
The theorem can be applied in many instances. One of which is as shown, for finding a function that increases or is concaved upwards.
The function F is increasing on the interval(s) where its derivative f is positive in value.
The function F is concave up on the interval(s) where its derivative f is increasing.
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