# Hookes law

1. ### rons49

2
im having bother writing the conlcusion for hookes law experiment, can any one help or point me in the right direction ????

2. ### dacruick

What is hookes law? Are there limitations of hookes law?

3. ### rons49

2
hooke's law states that spring extension is in direct proportion to the load applied, within the elastic limit of the spring F = KX

F is the force applied to the spring in newtons (N)
k is the spring constant measured in newtons per meter (N/m)
x is the distance the spring is stretched from its equilibrium position in meters (m)

4. ### dacruick

so now relate that definition of hooke's law to your hypothesis and your observations. Mention its limitations.

5. ### ZealScience

380
Analyse the relationship between the conclusion drawn from your data and Hooke's law to verify its validity. Also, is there any anomalies? Do they indicate limitations of Hooke's Law?

6. ### RobinSky

112
I recently finished my first course in mechanics (or maybe I should call it physics course A, however...) but we also talked a bit about Hooke's Law. Unfortunately my teacher wasn't a "real" teacher in physics (actually he was a teacher of Mechanical engineering) and it doesn't look like we learnt the "real" Hooke's law, can anyone explain to me what this is then in simple terms?:

σ = Eε

My teacher told us that this (^) was hooke's law. A quick look on wikipedia shows F=-kx, but also I can find σ = Eε if I scroll down a bit.

I know that sigma is the stress caused on a certain area (like the area of the cable holding up an elevator), E is the elastic modulus of a certain material, and epsilon, umm I don't know the word for it in english but I know what it is. :)

7. ### dacruick

F = -kx is an equation of motion. Your σ = Eε seems to be more of a definition of materials.

8. ### nasu

The σ=Eε is the general Hooke's law. It may be applied to any piece of elastic material, of any shape. In general all terms are tensors. For the simple case of a bar pulled by the ends with a force F , σ is the force per unit cross section area and ε is the relative elongation.
E is a material constant (Young's modulus).

F=-kx applies to a spring or any elastic object. Here k is a constant of the object and not of just the material. Springs made from the same material may have different values of k, depending on size and shape.

9. ### RobinSky

112
Ahhh! Thanks nasu for the good explanation, also I've noticed these "physic" words differ a lot from language to language :b however, big thanks!