ACCESS– Summer 2014
Elastic and Inelastic Collisions - Numerical Integration
Gernot LaicherUniversity of Utah - Department of Physics & Astronomy
Newton’s second law
…..or in a more general form
Momentum
m=constant “original” form of Newton’s second law.
Re-arrange Newton’s second law
“A net Force Fnet applied for an infinitesimally small time interval dt results in a change of momentum dp.”
Net force applied over a time interval (tf-ti)
“Impulse” or “Impulse Integral” I
Newton’s second law :
“Impulse = Change of Momentum”.
Example:
A golf ball (m=46g) is struck by a club which applies a constant force of 200N for a time period of 1/100 of a second. What is the impulse on the golf ball? If the ball is at rest initially, how fast will it be after it has been hit?
Change in momentum equals impulse
Conservation of Momentum:
For a “closed system” (no external forces applied to the system) the total linear momentum of the system is conserved. (The sum of all the individual momenta of the pieces that make up the “system” remains constant.)
To approach a system with no applied external force, we can consider two gliders on an air track and just look at the linear momentum in the horizontal direction.
Demo: One glider is initially at rest; both gliders have equal mass.
Before the collision:
Total momentum:
V1i V2i = 0
After the collision:
Total momentum:
V2f = V1i V1f = 0
Mechanical energy of the system before and after the collision:
Mechanical energy was conserved
” Totally elastic collision”
Before the collision:
After the collision:
V2i = 0 V1i
Vf = ½ V1i
Mechanical energy of the system:
Half the mechanical energy “lost” in collision (converted to heat) Inelastic collision
Numerical Integration
In general, applied forces are not constant during collision:
Impulse = “Area” under the force-time curve (the integral).
In lab activity: Force sensors Computer
Measurement not continuous - taken in discrete time intervals.
Estimate time integral with “numerical integration”.
Assume force remains constant over each time interval. Then calculate the sum of the rectangular areas (width ti and height Fi).
(Here, ti = t because we sample in equal time intervals.)
Alternative method: “Trapezoidal Rule”.
Partition area under the function into n intervals (widths δx). Label start of each partition as x0, x1, x2, x3, ... xn.
f(x)
Width of intervals
x xo x1 x2 x3 x4 x5 x6 x7 x8 x9
x
More partitions smaller time intervals Connect with straight lines f(xi) and f(xi+1) Area approximated by sum of n trapezoid areas.
w=width of trapezoid (= δx)
c = length of the leg1= f(xi)
d = length of leg 2 = f(xi+1)
Area Ai of ith trapezoid
Total area Atotal
Example Using Trapezoidal Rule:
Integrate f(x) = x4 for 1 ≤ x ≤ 3 with n = 8.
The width δx of each partition is:
x0 = 1.00 f(x0) = (1.00)4 = 1.0000
x1 = 1.25 f(x1) = (1.25)4 = 2.4414 (Rounding to 4 decimal places)
x2 = 1.50 f(x2) = (1.50)4 = 5.0625
x3 = 1.75 f(x3) = (1.75)4 = 9.3789
x4 = 2.00 f(x4) = (2.00)4 = 16.0000
x5 = 2.25 f(x5) = (2.25)4 = 25.6289
x6 = 2.50 f(x5) = (2.50)4 = 39.0625
x7 = 2.75 f(x7) = (2.75)4 = 57.1914
x8 = 3.00 f(x8) = (3.00)4 = 81.0000
Compared to exact result:
(Numerical integration within 1% of exact result)