====== 4. Spring constant from extension and period ======
[[https://colab.research.google.com/drive/1tD3YzjG3QRVFyrV-L1ccF84yx7QW4eYf?usp=sharing|Google Colab example]]



===== - Introduction =====
Spring constant is a property of a spring; its value $k$ should be a constant. You will calculate $k$ using two different methods: first, using the extension $l$ caused by a hanging mass $m$ and second, using the period $T$ for a given hanging mass $m$.

{{:courses:phy101l:spring.png?nolink|}}

When a mass $m$ is hung from an unstretched spring, it is extended by a length $x=l$ because of the gravitational pull of the earth on the mass. The spring exerts a restoring force $F$ on the mass opposite to its gravitational force $mg$. According to Hooke's law

$$ F \propto -l \Rightarrow F = -kl $$

where $k$ is the spring constant. Replacing $F=-mg$ we get $-mg = -kl $ and

$$ k = g\frac{m}{l}. $$

$$ l = \frac{g}{k}m + 0 $$

For the second method, you will use the relation between period and mass

$$ T = 2\pi \sqrt{\frac{m}{k'}} $$

which leads to 

$$ k' = 4\pi^2 \frac{m}{T^2}. $$

$$ T^2 = \frac{4\pi^2}{k'} m + 0 $$

The values $k$ and $k'$ should be very similar because they are both the spring constant of the same spring.

===== - Method and data =====

^ Mass $m$ [g] ^ Extension $l$ [cm] ^ Time for 10 oscillations $t$ [s] ^
| 100 |  |  |
| 150 |  |  |
| 200 |  |  |
| 250 |  |  |
| 300 |  |  |

===== - Spring constant from extension =====

===== - Spring constant from period =====

===== - Discussion and conclusion =====
  - Why are $k$ and $k'$ different?
  - Which one is greater, $\delta k$ or $\delta k'$? Why?
  - In which method we have higher fitting error?