1. Spring period
Question: m = 1 kg and k = 100 N/m. Find T.
Show Solution
Given: m = 1, k = 100.
Formula: T = 2π√(m/k).
Solution: T = 2π√(1/100) = π/5 s.
Final Answer: π/5 s.
If springs, pendulums or oscillations are not clear and you are looking for a Physics Tutor, contact Kumar Sir.Phone: +91-9958461445Email: kumarsirphysics@gmail.com
CLASS 11 PHYSICS
Springs and Pendulums
Spring block systems, spring stiffness, time period, cut springs, series-parallel combinations, simple pendulum, seconds pendulum, effective length, numericals and PYQs.
CBSENEETJEE MainJEE AdvancedIBICSEIGCSEA-Level
1. Spring Block System
A spring block system is the most direct model of SHM. When a block attached to an ideal spring is displaced and released on a smooth horizontal surface, the spring provides restoring force.
Definition and Physical Meaning
If the spring is stretched or compressed by x, the spring force is F = −kx. The negative sign means the force is toward the mean position. The block accelerates back, crosses equilibrium due to inertia, and repeats the motion.
Example: a trolley attached to a spring on a frictionless track oscillates about the natural length position. At mean position speed is maximum; at extremes speed is zero.
Exam trap: the formula assumes ideal spring, no friction and small deformation within elastic limit.
Spring Block System
2. Spring Constant and Stiffness
Spring constant k measures stiffness. Higher spring constant means higher stiffness and a larger restoring force for the same displacement.
F = −kx
If k is large, even a small displacement produces a large restoring force. If k is small, the spring is soft and stretches more easily.
Exam Perspective
For the same mass, a stiffer spring oscillates faster because T = 2π√(m/k). Increasing k decreases T and increases frequency. Students often confuse stiffness with length; after cutting a spring, the smaller piece becomes stiffer.
Memory trick: tight spring, quick swing; soft spring, slow swing.
3. Time Period of Spring
Derivation
For a spring block, F = −kx and Newton's law gives ma = −kx, so a = −(k/m)x. Comparing with SHM form a = −ω2x gives ω = √(k/m).
T = 2π√(m/k)
m is mass attached to the spring and k is spring constant.
Meaning and Mistakes
The time period is independent of amplitude for ideal SHM. It increases with mass and decreases with stiffness.
Common mistake: using T = 2π√(k/m), which is inverted. Always remember heavy mass means longer time, so m must be in numerator.
4. Spring Cut into n Equal Parts
This is a very important NEET/JEE concept. If a spring of spring constant k is cut into n equal parts, each part becomes stiffer.
k' = nk
For one cut part, spring constant becomes n times the original spring constant.
T = 2π√(m/k)
Original spring time period.
T' = 2π√(m/(nk)) = T/√n
New time period using one cut part.
Reason: spring constant is inversely proportional to length for the same material and wire. Shorter spring means greater stiffness.
Spring Cut into n Equal Parts
Example 1
If a spring is cut into 2 equal parts, each part has k' = 2k. New period is T' = T/√2.
Example 2
If a spring is cut into 4 equal parts, each part has k' = 4k. New period is T' = T/2.
Example 3
If a spring is cut into 9 equal parts, each part has k' = 9k. New period is T' = T/3.
5. Springs in Series and Parallel
Series Combination
1/keq = 1/k1 + 1/k2
Series springs become softer. For two identical springs k and k, equivalent spring constant is k/2, so period increases by √2.
Parallel Combination
keq = k1 + k2
Parallel springs become stiffer. For two identical springs, equivalent spring constant is 2k, so period becomes T/√2.
Springs in Series
Springs in Parallel
6. Block Attached to Springs on Both Sides
When a block is connected between two springs and displaced, both springs provide restoring effect in the same direction toward equilibrium.
keff = k1 + k2
The two spring constants add because both springs oppose displacement.
T = 2π√(m/(k1 + k2))
Use this formula for a block attached to springs on both sides.
Exam trap: this is not series. The block feels restoring force from both sides, so effective stiffness is sum.
Block Between Two Springs
7. Simple Pendulum
Definition and Physical Meaning
A simple pendulum consists of a small heavy bob suspended by a light, inextensible string from a fixed support. For small angular displacement, its motion is approximately SHM.
The restoring component is due to gravity. When the bob is displaced, a component of weight acts tangentially toward the mean position.
Trap: large-angle pendulum is not exactly SHM because sin θ is not equal to θ.
Simple Pendulum
8. Time Period of Pendulum
T = 2π√(L/g)
L is effective length of pendulum and g is acceleration due to gravity.
For small angles, the restoring torque is proportional to angular displacement. This makes the pendulum approximately SHM.
Important Points
- Time period does not depend on mass of bob.
- Time period does not depend on small amplitude.
- Increasing length increases time period.
- Increasing g decreases time period.
Common mistake: using mass in pendulum period formula. Mass is absent.
9. Seconds Pendulum
Definition
A seconds pendulum has time period 2 seconds. It takes 1 second to go from one extreme to the other and 2 seconds for a complete oscillation.
T = 2 s
Near Earth's surface, its length is approximately 1 m because T = 2π√(L/g).
Seconds Pendulum
10. Effective Length
Effective length is the distance from the point of suspension to the centre of gravity of the bob.
L = distance from support to centre of bob
For a spherical bob, effective length is string length plus radius of bob if string length is measured up to the top of the bob.
Exam trap: do not use only string length unless it is clearly given as effective length.
Effective Length
11. Applications
Clocks
Pendulum clocks use nearly constant period for small amplitude oscillations. Temperature changes can alter length and affect timekeeping.
Vehicle Suspension
Springs in vehicles store and release energy, reducing shocks. Stiffer springs give higher natural frequency.
Seismometers
Spring-mass systems help detect ground vibrations. Understanding natural frequency prevents wrong readings.
Measuring g
Using T = 2π√(L/g), a pendulum experiment can estimate local gravitational acceleration.
Engineering Design
Machines use springs to control vibration and avoid resonance at operating frequencies.
Exam Use
Spring and pendulum formulas appear in CBSE derivations, NEET direct questions and JEE combination problems.
Need Help With Springs or Pendulums?
If springs, pendulums or oscillations are not clear and you are looking for a Physics Tutor, contact Kumar Sir.
Formula Sheet
T = 2π√(m/k)
Spring block period.
ω = √(k/m)
Spring angular frequency.
k' = nk
Spring cut into n equal parts.
T' = T/√n
Using one cut part.
1/keq = 1/k1 + 1/k2
Series springs.
keq = k1 + k2
Parallel or both-side springs.
T = 2π√(m/(k1 + k2))
Block attached between two springs.
T = 2π√(L/g)
Simple pendulum period.
T = 2 s
Seconds pendulum.
12. 40 Solved Numericals
2. Angular frequency
Question: k = 200 N/m, m = 2 kg. Find ω.
Show Solution
Given: k = 200, m = 2.
Formula: ω = √(k/m).
Solution: ω = √100 = 10 rad/s.
Final Answer: 10 rad/s.
3. Effect of mass
Question: Mass is made 4 times. What happens to spring period?
Show Solution
Given: m' = 4m.
Formula: T ∝ √m.
Solution: T' = 2T.
Final Answer: Period doubles.
4. Effect of stiffness
Question: k becomes 4k. What happens to T?
Show Solution
Given: k' = 4k.
Formula: T ∝ 1/√k.
Solution: T' = T/2.
Final Answer: Period halves.
5. Cut into 4 parts
Question: A spring is cut into 4 equal parts. Find k' for each part.
Show Solution
Given: n = 4.
Formula: k' = nk.
Solution: k' = 4k.
Final Answer: 4k.
6. Period of cut spring
Question: Original period is 6 s. Spring is cut into 9 parts and one part is used. Find new T.
Show Solution
Given: T = 6 s, n = 9.
Formula: T' = T/√n.
Solution: T' = 6/3 = 2 s.
Final Answer: 2 s.
7. Cut into 2 parts
Question: Original period is T. One half spring is used. Find new period.
Show Solution
Given: n = 2.
Formula: T' = T/√n.
Solution: T' = T/√2.
Final Answer: T/√2.
8. Cut into 3 parts
Question: k = 60 N/m. Spring is cut into 3 equal parts. Find each k'.
Show Solution
Given: k = 60, n = 3.
Formula: k' = nk.
Solution: k' = 180 N/m.
Final Answer: 180 N/m.
9. Series identical springs
Question: Two springs each k are in series. Find keq.
Show Solution
Given: k and k in series.
Formula: 1/keq = 1/k + 1/k.
Solution: keq = k/2.
Final Answer: k/2.
10. Parallel identical springs
Question: Two springs each k are in parallel. Find keq.
Show Solution
Given: k and k in parallel.
Formula: keq = k + k.
Solution: keq = 2k.
Final Answer: 2k.
11. Series numerical
Question: k1 = 100 N/m, k2 = 100 N/m in series, m = 2 kg. Find T.
Show Solution
Given: keq = 50 N/m, m = 2.
Formula: T = 2π√(m/keq).
Solution: T = 2π√(2/50) = 2π/5 s.
Final Answer: 2π/5 s.
12. Parallel numerical
Question: k1 = 100, k2 = 300 N/m, m = 1 kg. Find T.
Show Solution
Given: keq = 400 N/m.
Formula: T = 2π√(m/keq).
Solution: T = 2π√(1/400) = π/10 s.
Final Answer: π/10 s.
13. Both side springs
Question: k1 = 50, k2 = 150 N/m, m = 2 kg. Find T.
Show Solution
Given: keff = 200, m = 2.
Formula: T = 2π√(m/(k1 + k2)).
Solution: T = 2π√(2/200) = π/5 s.
Final Answer: π/5 s.
14. Pendulum period
Question: L = 1 m, g = π2 m/s2. Find T.
Show Solution
Given: L = 1, g = π².
Formula: T = 2π√(L/g).
Solution: T = 2π√(1/π²) = 2 s.
Final Answer: 2 s.
15. Seconds pendulum length
Question: T = 2 s and g = π². Find L.
Show Solution
Given: T = 2, g = π².
Formula: T = 2π√(L/g).
Solution: 2 = 2π√(L/π²), so L = 1 m.
Final Answer: 1 m.
16. Length quadrupled
Question: Pendulum length becomes 4L. What happens to T?
Show Solution
Given: L' = 4L.
Formula: T ∝ √L.
Solution: T' = 2T.
Final Answer: Doubles.
17. g becomes g/4
Question: If g becomes g/4, what happens to T?
Show Solution
Given: g' = g/4.
Formula: T ∝ 1/√g.
Solution: T' = 2T.
Final Answer: Doubles.
18. Find g
Question: L = 1 m, T = 2 s. Find g.
Show Solution
Given: L = 1, T = 2.
Formula: g = 4π²L/T².
Solution: g = 4π²/4 = π² m/s².
Final Answer: π² m/s².
19. Effective length
Question: String length to top of spherical bob is 0.9 m and bob radius is 0.1 m. Find effective length.
Show Solution
Given: string to top = 0.9 m, radius = 0.1 m.
Formula: L = string length + radius.
Solution: L = 1.0 m.
Final Answer: 1.0 m.
20. Pendulum period from effective length
Question: L = 0.25 m, g = π². Find T.
Show Solution
Given: L = 0.25, g = π².
Formula: T = 2π√(L/g).
Solution: T = 2π√(0.25/π²) = 1 s.
Final Answer: 1 s.
21. Mass independence
Question: Pendulum bob mass is doubled. What happens to T?
Show Solution
Given: mass changes.
Formula: T = 2π√(L/g).
Solution: mass is absent.
Final Answer: No change.
22. Frequency of spring
Question: k = 400 N/m, m = 1 kg. Find f.
Show Solution
Given: ω = √400 = 20 rad/s.
Formula: f = ω/(2π).
Solution: f = 10/π Hz.
Final Answer: 10/π Hz.
23. Three identical series springs
Question: Three identical springs k are in series. Find period compared to one spring.
Show Solution
Given: keq = k/3.
Formula: T ∝ 1/√k.
Solution: T' = √3 T.
Final Answer: √3 times.
24. Three identical parallel springs
Question: Three identical springs k are in parallel. Find period compared to one spring.
Show Solution
Given: keq = 3k.
Formula: T ∝ 1/√k.
Solution: T' = T/√3.
Final Answer: T/√3.
25. Cut and mass changed
Question: Spring cut into 4 parts and mass becomes 4m. One part is used. Find new period compared to original.
Show Solution
Given: k' = 4k, m' = 4m.
Formula: T' = 2π√(m'/k').
Solution: T' = 2π√(4m/4k) = T.
Final Answer: No change.
26. Both side identical springs
Question: A block between two identical springs k has period?
Show Solution
Given: keff = 2k.
Formula: T = 2π√(m/2k).
Solution: substitute effective stiffness.
Final Answer: 2π√(m/2k).
27. Extension force
Question: k = 50 N/m, x = 0.2 m. Find restoring force magnitude.
Show Solution
Given: k = 50, x = 0.2.
Formula: F = kx.
Solution: F = 10 N.
Final Answer: 10 N toward mean.
28. Static extension method
Question: A mass stretches spring by y at equilibrium. Find period.
Show Solution
Given: mg = ky.
Formula: T = 2π√(m/k).
Solution: m/k = y/g.
Final Answer: T = 2π√(y/g).
29. Static extension numerical
Question: Static extension is 0.25 m. Take g = π². Find T.
Show Solution
Given: y = 0.25, g = π².
Formula: T = 2π√(y/g).
Solution: T = 2π√(0.25/π²) = 1 s.
Final Answer: 1 s.
30. Series unequal springs
Question: k1 = 100, k2 = 300 N/m. Find series keq.
Show Solution
Given: two springs in series.
Formula: keq = k1k2/(k1 + k2).
Solution: keq = 30000/400 = 75 N/m.
Final Answer: 75 N/m.
31. Seconds pendulum half swing
Question: Seconds pendulum takes how much time from one extreme to other?
Show Solution
Given: T = 2 s.
Formula: extreme to opposite extreme = T/2.
Solution: time = 1 s.
Final Answer: 1 s.
32. Pendulum on Moon
Question: g decreases. What happens to pendulum period?
Show Solution
Given: lower g.
Formula: T ∝ 1/√g.
Solution: T increases.
Final Answer: Period increases.
33. Clock slow or fast
Question: Pendulum length increases. Clock runs?
Show Solution
Given: L increases.
Formula: T ∝ √L.
Solution: T increases, fewer oscillations per time.
Final Answer: Clock runs slow.
34. Pendulum length for T = 4 s
Question: If g = π², find L for T = 4 s.
Show Solution
Given: T = 4, g = π².
Formula: L = gT²/(4π²).
Solution: L = π² × 16/(4π²) = 4 m.
Final Answer: 4 m.
35. Spring period from frequency
Question: Spring frequency is 5 Hz. Find period.
Show Solution
Given: f = 5 Hz.
Formula: T = 1/f.
Solution: T = 0.2 s.
Final Answer: 0.2 s.
36. Find mass
Question: k = 100 N/m, T = 2π/5 s. Find m.
Show Solution
Given: k = 100, T = 2π/5.
Formula: T = 2π√(m/k).
Solution: √(m/100) = 1/5, so m = 4 kg.
Final Answer: 4 kg.
37. Find k from period
Question: m = 2 kg, T = π s. Find k.
Show Solution
Given: m = 2, T = π.
Formula: T = 2π√(m/k).
Solution: 1/2 = √(2/k), so k = 8 N/m.
Final Answer: 8 N/m.
38. Cut part with k value
Question: Original k = 40 N/m. Cut into 5 parts. Mass 2 kg attached to one part. Find ω.
Show Solution
Given: k' = 5k = 200 N/m, m = 2.
Formula: ω = √(k'/m).
Solution: ω = √100 = 10 rad/s.
Final Answer: 10 rad/s.
39. Both side unequal
Question: k1 = k, k2 = 3k. Find period.
Show Solution
Given: keff = 4k.
Formula: T = 2π√(m/keff).
Solution: T = 2π√(m/4k) = π√(m/k).
Final Answer: π√(m/k).
40. Compare spring and pendulum
Question: Spring block has T = 2π√(m/k). Pendulum has same period. Find L.
Show Solution
Given: 2π√(L/g) = 2π√(m/k).
Formula: equate square roots.
Solution: L/g = m/k, so L = mg/k.
Final Answer: L = mg/k.
13. 50 PYQs and Exam Questions
1. State time period of spring block.
Write the formula.
Show Answer
T = 2π√(m/k).
2. What is spring constant?
Define stiffness.
Show Answer
Spring constant is restoring force per unit displacement. Higher k means greater stiffness.
3. Does spring period depend on amplitude?
Ideal spring.
Show Answer
No, for ideal SHM.
4. State pendulum time period.
Small oscillations.
Show Answer
T = 2π√(L/g).
5. What is effective length?
For pendulum.
Show Answer
Distance from point of suspension to centre of gravity of bob.
6. Spring cut into n parts.
What is k'?
Show Answer
Each part has k' = nk.
7. Spring cut into n parts.
What is T' for one part?
Show Answer
T' = T/√n.
8. Two springs in parallel.
Equivalent k?
Show Answer
keq = k1 + k2.
9. Two springs in series.
Equivalent k?
Show Answer
1/keq = 1/k1 + 1/k2.
10. Both-side springs.
Effective k?
Show Answer
keff = k1 + k2.
11. If k is quadrupled, T becomes?
Same mass.
Show Answer
T becomes T/2.
12. If mass is quadrupled, T becomes?
Same spring.
Show Answer
T becomes 2T.
13. Seconds pendulum period?
Definition.
Show Answer
2 seconds.
14. Seconds pendulum length near Earth?
Approximate.
Show Answer
Approximately 1 m.
15. Does pendulum period depend on bob mass?
Small oscillations.
Show Answer
No.
16. Why small-angle condition?
Pendulum SHM.
Show Answer
Because sin θ ≈ θ only for small angles, giving restoring torque proportional to displacement.
17. Cut spring and stiffness.
Why does k increase?
Show Answer
For same spring material, k is inversely proportional to length; shorter part is stiffer.
18. Block between springs formula.
Write T.
Show Answer
T = 2π√(m/(k1 + k2)).
19. Static extension formula.
Vertical spring period.
Show Answer
T = 2π√(y/g), where y is static extension.
20. Parallel springs effect.
Soft or stiff?
Show Answer
Stiffer; equivalent k increases.
21. Explain restoring force in spring.
Conceptual.
Show Answer
It acts opposite to displacement and pulls/pushes block toward equilibrium.
22. Explain pendulum restoring force.
Conceptual.
Show Answer
The tangential component of weight acts toward the mean position.
23. Give use of seconds pendulum.
Application.
Show Answer
It is used in timekeeping and pendulum clocks.
24. What happens if pendulum length increases?
Period effect.
Show Answer
Time period increases.
25. How to reduce timing error in pendulum lab?
Practical.
Show Answer
Measure time for many oscillations and divide by number of oscillations.
26. What is one oscillation?
Pendulum.
Show Answer
Motion from one extreme to the other and back to original extreme.
27. Derive spring angular frequency.
State result.
Show Answer
ma = −kx gives a = −(k/m)x, so ω = √(k/m).
28. Derive pendulum period condition.
Small angle.
Show Answer
For small θ, restoring acceleration is proportional to displacement, giving T = 2π√(L/g).
29. Assertion: A cut spring is stiffer. Reason: spring constant is inversely proportional to length.
Evaluate.
Show Answer
Both are true and reason explains assertion.
30. Assertion: Pendulum period depends on mass. Reason: heavier bob has larger weight.
Evaluate.
Show Answer
Assertion is false. Reason is true but not relevant; mass cancels in pendulum motion.
31. Higher k means higher stiffness.
True or false?
Show Answer
True.
32. Series springs become stiffer.
True or false?
Show Answer
False; series springs become softer.
33. Parallel springs become stiffer.
True or false?
Show Answer
True.
34. Seconds pendulum has period 1 s.
True or false?
Show Answer
False; its period is 2 s.
35. Why does both-side spring k add?
Explain.
Show Answer
Both springs exert restoring forces toward equilibrium, so total restoring force is −(k1 + k2)x.
36. Why is pendulum not exact SHM at large angle?
Explain.
Show Answer
Because restoring term contains sin θ, not θ; proportionality fails for large θ.
37. Why does softer spring have larger period?
Explain.
Show Answer
Smaller k gives weaker restoring force and smaller acceleration, so oscillation is slower.
38. Why does longer pendulum have larger period?
Explain.
Show Answer
Longer pendulum has smaller angular acceleration for same angular displacement, so it oscillates slower.
39. Spring cut into 16 parts.
New period with one part?
Show Answer
T' = T/4.
40. Four identical springs parallel.
New period compared to one spring?
Show Answer
T' = T/2.
41. Four identical springs series.
New period compared to one spring?
Show Answer
T' = 2T.
42. Pendulum clock taken to lower g.
Fast or slow?
Show Answer
It runs slow because period increases.
43. A vehicle uses stiff springs.
What happens to natural frequency?
Show Answer
Natural frequency increases because ω = √(k/m).
44. A pendulum bob is replaced by heavier bob.
What happens to period?
Show Answer
No change for small oscillations.
45. A spring is cut shorter.
What happens to stiffness?
Show Answer
Stiffness increases.
46. Two side springs pull block back.
Equivalent spring constant?
Show Answer
k1 + k2.
47. Spring F-x graph slope?
Meaning.
Show Answer
Slope magnitude is spring constant k.
48. Pendulum period vs √L graph?
Shape.
Show Answer
Straight line because T ∝ √L.
49. Spring period vs √m graph?
Shape.
Show Answer
Straight line because T ∝ √m.
50. Spring period vs 1/√k graph?
Shape.
Show Answer
Straight line because T ∝ 1/√k.
14. Quick Revision Notes
Spring Block
- F = −kx
- ω = √(k/m)
- T = 2π√(m/k)
- Higher k means higher stiffness.
Cut Spring
- Cut into n equal parts.
- Each part: k' = nk.
- Using one part: T' = T/√n.
- Shorter spring is stiffer.
Combinations
- Series: reciprocal formula.
- Parallel: k values add.
- Both-side springs: keff = k1 + k2.
Pendulum
- T = 2π√(L/g)
- Valid for small angles.
- Mass independent.
- Seconds pendulum: T = 2 s.
Exam Tips
- Check whether springs are series, parallel or both-side.
- Use effective length, not always string length.
- For cut spring, never write k/n.
Last Day Notes
- Heavy mass: larger spring period.
- Stiffer spring: smaller period.
- Longer pendulum: larger period.
- Lower g: larger pendulum period.
If springs, pendulums or oscillations are not clear and you are looking for a Physics Tutor, contact Kumar Sir.
Phone: +91-9958461445 Email: kumarsirphysics@gmail.com Website: https://kumarphysicsclasses.com