To find the acceleration of a glider moving down a sloping air track, you measure its velocity at two points (?1 and ?2); and the time t it takes between them: v1 = .21 ± 0.05 m/s v2 = .85 ± 0.05 m/s 2 = 0 t = 8.0 ± 0.1 s a. Assuming all uncertainties are independent and random, and acceleration is calculated using a = (v2-v1)/t, what should you report for a and its uncertainty? b. You calculate using an air resistance model that the acceleration should be 0.13 ± 0.01 m/s . Does your measurement agree with this prediction
To find the acceleration of a glider moving down a sloping air track, you measure its...
To find the acceleration of a glider moving down a sloping air track, you measure its velocity at two points (?1 and ?2) and the time it takes between them: ?1 = 0.21 ± 0.05 ?/? ?2 = 0.85 ± 0.05 ?/2 ? = 8.0 ± 0.1 ? a. Assuming all uncertainties are independent and random, and acceleration is calculated using ? = ?2−?1 ? , what should you report for ? and its uncertainty? b. You calculate using...
To find the acceleration of a glider moving down a sloping air track, you measure its velocities (V1 and V2) at two points and the time t it takes between them, as follows: V1=0.21+/- 0.05m/s, V2=0.85 +/- 0.05m/s, t=8.0 +/- 0.1s a) Assuming all uncertainties are independent and random, find the average acceleration, a=(v2-v1)/t , and its uncertainty. b) How well does your result in part (a) agree with your friends theoretical prediction that a=0.13 +/- 0.01m/s^2
A 1.450 kg air-track glider is attached to each end of the track by two coil springs. It takes a horizontal force of 0.500 N to displace the glider to a new equilibrium position, x= 0.270 m. K= 1.85 N/m The glider is now released from rest at x= 0.270 m. Find the maximum x-acceleration of the glider. 3.45×10-1 m/s^2 1. Find the x-coordinate of the glider at time t= 0.730T, where T is the period of the oscillation. 2....
A 0.450 kg air-track glider is attached to each end of the track
by two coil springs. It takes a horizontal force of 0.700 N to
displace the glider to a new equilibrium position, x= 0.270
m.
Find the effective spring constant of the system.
2.59 N/m
You are correct.
Your receipt no. is 160-5399
Previous Tries
The glider is now released from rest at x= 0.270 m. Find the
maximum x-acceleration of the glider.
1.56 m/s^2
You are correct....
A glider with mass m = 0.200 kg sits on a frictionless horizontal air track, connected to a spring with force constant k = 5.20 N/m . You pull on the glider, stretching the spring 0.130 m , and then release it with no initial velocity. The glider begins to move back toward its equilibrium position ( x=0 ). Part A What is the speed of the glider when it returns to x=0 ? Part B What must the initial...
1a- A 140-gram glider on a horizontal, frictionless air track is attached to a fixed ideal spring with force constant 173 N/m. At the instant you make measurements on the glider, it is moving at 88.7 cm/s and is 3.79 cm from its equilibrium point. Use energy conservation to find: (iii) - what is the angular frequency of the oscillations, in rad/s? 1b- A 1.9-kg monkey wrench is pivoted 0.31 m from its center of mass and allowed to swing...
Prelab Assignment 5 - due at the beginning of lab 5 1. Compute the theoretical acceleration A - and its absolute uncertainty, using the following Mm measurements, and give the result in its proper form with uncertainty and unit. Uncertainty equations are given in the lab description.(4) F = 0.295 + 0.001N Force applied by the hanging mass M = 29.9 0.19 hanging mass m 190.4 0.19 glider mass 2. Compute the experimentally observed acceleration and its absolute uncertainty using...
Data Sheet B. Constant Acceleration Measured distance from single leg to double leg of air track L Height of riser block d Spark timer setting 10 Number of time intervals between circled dots Time Δ1 between circled dots ' Angle of nlineplanen Aaron Spark timer Δ4" settingAngle of sparks/s - Circled Dot Elapsed Total Displacements) Between Average Velocity Number Displacement Ar (m) | Even-Numbered | . . ArtM(ms) t (s) x (m) 0 0.4 0.1 0 0 0 O. 1...
Find the x-coordinate of the glider at time t= 0.570T, where T
is the period of the oscillation.
A 0.750 kg air-track glider is attached to each end of the track by two coil springs. It takes a horizontal force of 0.500 N to displace the glider to a new equilibrium position, x= 0.270 m. 000000000 Find the effective spring constant of the system. 1.85 N/m You are correct. Your receipt no. is 149-3397 Previous Tries The glider is now...
I need help for numbers 1 and 3. For number one I
measured the height of the track at angle. One of the heights was
.082m. hypotenuse 1.013m. I did sin^-1(.082/1.013) and got 4.64
degrees. I used a sensor and aquired data for change in v and t as
a glider fell down the track. I calculated the acceleration at that
height and angle as -10.18 m/s^2. final V was 1.48, initial V .687.
final t=.0675, initial t= .1454.
For...