Bungee Drop

''Cow A Bungee redirects here. For Egg Drop events, see Naked Egg Drop and Rotor Egg Drop.''

Bungee Drop is a Division C event for the 2015 season. The object is to drop a mass attached to an elastic cord from a given height and to get the mass as close to the ground without letting it touch the ground.

Objective
The object is to drop a mass attached to an elastic cord from a given height and to get the mass as close to the ground without letting it touch the ground. The heights for the two drops can be anywhere from two to five meters (Regionals/States) or ten meters (Nationals), with the same height for both drops (different from 2014 rules). After all devices are impounded impound, both the drop height and object mass will be announced. These weights will be anywhere from 50 to 300 grams and will be placed in a 500-591 mL plastic bottle.

General Advice
Read the event description carefully! The cord can be made from any materials, but the bottom meter must pass the 'elasticity' test. With the 2015 rules for elasticity tests, only the bottom meter of the device needs to be stretch, so the remainder of the cord can be unelastic string. While all sorts of materials can be used to make the cord elastic, ranging from metal springs to Slinkys to elastic or rubber bands, some will be more reliable and will work better.

Practicing


The most important task to be done is calibration. Constructing a device may not be as difficult for Bungee Drop as it is for other events, but practice is key. Since elastic cords are not necessarily consistent in elasticity throughout, it is important to practice with multiple drop heights.

Creating a more reliable testing apparatus will allow you to have better data points to rely on at the competition. A typical bungee testing-device utilizes a soda bottle with mass contained in it and a clamp to hold the cord in place. It is recommended to also have a controlled method of releasing the bottle so that trials are systematic. For an example of a testing apparatus, see the image to the right.

Calibration this year promises to be more complicated than it has been in past years. If, say, you start calibration with a height of 3.00 meters, you can't only find one mark to make on our bungee for that height - you must make a mark for that height with 25 grams, for that height with 50 grams, etc. Getting the same degree of precision as was possible in past years will now, theoretically, take more the time (assuming you calibrate for, say 15 heights, and 15 masses). Of course, the real solution will to be to find a pattern - a formula. With a formula, you can simply input a mass and a height to know how long your cord should be.

A Mathematical Approach
There are many different ways one can tackle the Bungee Drop problem. However, if you want to compete nationally, there really is one approach that trumps all. Math. Math can never break down. 1+1 will never suddenly equal 3 the day before the competition. Math lets you determine the intervals in between. Math is love, math is life.

Partially Elastic Bungee Equations

 * Please note: I strongly discourage the usage of partially elastic bungee cords, and instead deeply advocate fully elastic cords, mainly because partially elastic cords deviate from Hooke's law very easily due to higher strain at higher drop heights, while fully elastic bungees retain low strain. However, this section will remain as a reference section for the fully elastic bungees. Furthermore, the fully elastic equation was derived based off the partially elastic equation, so many principles need to be understood here before tackling the fully elastic bungee equations. Finally, if you really want to use the partially elastic equation, here you go.

This the follow equations (courtesy of Joseph Liba (forum name: joiemoie) of Acton-Boxborough Regional High), use basic physics equations to create the ideal bungee equation.

Requirements:
 * Your bungee cord has an elastic portion and a non-elastic portion.
 * Graphing Calculator

x1 = the length of unstretched bungee x2 = how long the bungee stretches m = mass of bottle g = acceleration due to gravity (9.8) p = mass of bungee per unit length (which is not negligible) Use the first equation, $$k=\frac{gx_1^2p+2x_1x_2p+4x_1m+4x_2m}{2x_2^2}$$ to calculate the "k" constant. To make things faster, be sure use an equation that allows you simply input x₁, x₂, and D, where D is not the drop height, but rather distance traveled. A simple way to calculate D is just to get the drop height and subtract how far off the ground it was. I would suggest running as few trials as you can to determine "k".

Don't use the equation f=kx because it doesn't consider the fact that the bungee cord whips down and has a mass of its own.

Ok now that you solved for k, use the solve function on your graphing calculator so solve for x_1 $$D=x_1+\frac{\sqrt{g(x_1^2gp^2+2x_1^2kp+4x_1gmp+8x_1km+4gm^2)}+x_1gp+2gm}{2k}$$

x_1 is how long you should measure out your bungee

Entirely Elastic Bungee Equations
Please refer to the previous section, except instead of k, we will be using lamda "λ". λ is Young's Modulus of elasticity. λ is a constant. The reason we use λ instead of k compared to the previous section is because in the previous section, we assume that the length of the elastic portion is constant. However, with a bungee that is entirely elastic, the length of the elastic portion is always changing. And the higher up the bungee you go, the more elastic the part under it will be. I mean, think about it logically, too. If you try to stretch a tiny piece of rubber, it's really hard, but if you try to stretch a long piece, it's much easier. λ takes into account the length and the k value at that particular length.

Once again, x1 = length of bungee you're measuring out, x2 is the amount it stretches, D is the distance from floor to bottom of bottle, m is mass, and g is acceleration due to gravity (9.8), and p is the mass of bungee per meter. Also please remember to use metric. All units are in meters, kilograms, seconds.

All we gotta do is experimentally calculate the λ. $$\lambda=\frac{x_1g(x_1^2p+2x_1x_2p+4x_1m+4x_2m)}{2x_2^2}$$

Keep in mind, λ may not be perfect either, at which point you'll have to find λ as a function of f(x2) as I mentioned in an earlier section.

Cool. You have λ. To solve for x_1, get a graphing calculator and use the solve function on

$$D=x_1+\frac{x_1+x_1^2gp}{(2\lambda)}+\frac{x_1gm}{\lambda}-\frac{x_1\sqrt{g(g(x_1p+2m)^{2}+2\lambda(x_1p+4m))}}{2\lambda}$$

Also, adjust the equation if λ is a function of x2.

Full Elastic vs. Partially Elastic
So now the question is: should you use a fully elastic or partially elastic bungee? What are the pros and cons of both?

Full Elastic: + Slower drop so that the camera is more likely to catch it if it gets close to the ground (one time at a regionals tournament the guy was recording the drops with his iphone that had a 30fps camera and sometimes the bungee dropped so fast that even though it went really close to the ground, the frame only caught the times when it was about 6cm from the ground) + The strain is guaranteed to be roughly constant throughout all drop heights and hooke's law will not break. + Bungee stretches out slower over time, allowing you to do more trials - Can be hard to measure out the x1 if using rubber bands - I haven't tested it yet. - Very good chance that hooke's law will break given high distances. Partially elastic: + Deriving the equation was easier lol + You can use a measuring tape as the non-elastic portion to account for bungee that stretches out over time. -Drops faster so the camera might not catch it

Materials
The 2015 rules allow students to use any materials as long as they pass the 'elasticity' test. While this does give a lot of freedom in deciding how to make your device, obviously some work better than others.

Competition Tips

 * At the competition, always be more cautious for new drop heights. Adjust the cord so that it is slightly shorter than you would expect.


 * If the two drop heights are the same, you can adjust the cord for the second drop depending on how close the first drop was.


 * If you use graphs to determine a formula, consider adding error bars to your graph so you can predict how careful you should be.


 * Some event supervisors will not disclose how close each of your drops was, so consider having your partner stand near the surface to observe how close each drop is.


 * The rules permit students to verify the mass of the bottle on their own. Since scales will vary in accuracy, consider using your own scale to measure the mass so that it fits with your data.

Scoring
The goal, as before, is to get the device to drop as close as possible to the floor below, without touching. The team with the lowest score for the sum of the two drops from the ground, wins. However, if one drop hits the surface, a team will be ranked below (Tier 2) all teams that have no touches, and if a team has two touches, it will be ranked below (Tier 3) all teams that had one or no touches.

Tiebreakers are broken in the following order: 1. Single best overall drop; 2. Cord with the greatest elasticity.

Resources

 * bernard's 2015 SSSS [[Media:Bernard's Bungee Drop Notes.pdf|Bungee Drop Notes]]
 * [[Media:Bungee Drop.pptx|Supervisor Preparation PowerPoint]]