Experiment to determine acceleration due to gravity using a mass-spring system by measuring oscillation time, extension, and applying SHM relations.
Apparatus
The experiment requires a helical spring of known spring constant (K), an iron stand with a clamp, slotted weights, and a stopwatch for timing oscillations. All equipment should be properly aligned before beginning the procedure.
Observations and Calculations
| No.of abs | Oscillating mass ‘M’ gms | Time for 10 vibrations | Time period T=t/20 | Extension Produced Weights in gms ‘a’ cm | ||
| 1 sec | 2 sec | Mean ‘t’ sec | ||||
| 1 2 3 |
20 40 60 | 20 20 20 | ||||
Mean value of ‘g’=………………………cm/s
Procedure
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First, suspend the helical spring from the clamp of the iron stand and attach a hanger to its lower end.
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Load the hanger with different weights and observe the corresponding extension on the attached scale.
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Next, slightly pull the hanger downward to start the oscillation and record the time for 20 vibrations.
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Repeat this measurement twice and take the mean value of the time.
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Therefore, calculate the acceleration due to gravity (g) using the formula:
g = 4π² (a / T²)
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Perform the same steps for different weights to get several readings.
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Finally, compute the mean value of g from all observations to ensure accuracy.
Formula Used
g=4π2aT2g = 4π² \frac{a}{T²}
Where:
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g = acceleration due to gravity
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a = extension produced
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T = time period of oscillation
Inference
The experiment verifies that the acceleration due to gravity can be determined using a mass-spring system performing simple harmonic motion. The calculated values of g remain nearly constant for all readings, confirming the accuracy of Hooke’s Law and SHM principles.
Precautions
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Make sure the spring is elastic and free from kinks.
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The table and stand must remain stable during oscillations.
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Start the stopwatch precisely when the oscillation begins.
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Avoid overloading the spring to stay within the elastic limit.
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Repeat readings to minimize human and mechanical errors.
Viva Voce
Q1. What is meant by restoring force?
A: The restoring force brings a vibrating system back toward its mean position.
Q2. What are the factors responsible for oscillatory motion?
A: The main factors are restoring force and inertia.
Q3. What is Simple Harmonic Motion (SHM)?
A: It is the motion in which acceleration is directly proportional to displacement and always directed toward the mean position.
Q4. What is the spring constant?
A: The ratio of the applied force to the extension produced in the spring, i.e., k = F/x.
Q5. Define elastic limit.
A: The maximum limit of stress after which a material stops obeying Hooke’s Law.
Q6. State Hooke’s Law.
A: Within the elastic limit, the force applied to a spring is directly proportional to its extension.
Q7. What is a helical spring?
A: A spring coiled in the shape of a helix is called a helical spring.
Q8. What type of energy is stored in a stretched spring?
A: Elastic potential energy.
Q9. Define stress and strain.
A:
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Stress: Force per unit area acting on a body.
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Strain: Ratio of change in length to the original length.
Q10. What are the characteristics of SHM?
A:
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Acceleration ∝ displacement from the mean position.
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It is always directed toward the mean position.
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Total energy remains constant during motion.
Q11. How is “g” calculated using a mass-spring system?
A: Measure the extension (x) and time period (T) of oscillation, then apply the formula:
g=4π2aT2g = 4π² \frac{a}{T²}