MoneyBox/DensityAnalysis
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| − | Density Analysis of australian coinage |
+ | {{TOCright}} |
| − | + | ...a Density Analysis of australian coinage |
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ie, how much value of a given coin can you fit inside, say, 1litre of space? |
ie, how much value of a given coin can you fit inside, say, 1litre of space? |
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;$2: 20.5mm, 3mm |
;$2: 20.5mm, 3mm |
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| + | == How to calculate == |
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| − | === 20c === |
+ | There are three estimates easily possible. |
| + | # Count of coins for maximum displacement within our 1litre limit (1litre divided by volume per coin) |
||
| + | # Same as before, but assume coins are square with edge length equal to diameter. Simulates stacks arranged in a grid |
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| + | # Same as before, but assume coins are hexagonal and stacked in a hex lattice. (is this the most efficient possible in a 3d space?) |
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| − | I've not caclulated this out, but from experience, $40 of 20c coins will fill a 1litre container nicely. |
+ | In the real world, coins are unlikely to be stacked neatly, but with repeated shaking should form themselves into dense stacks. Thus I'd expect a real-world result somewhere between the 'squared' and 'hexed' results. |
| + | |||
| + | ;Volume of coin: (pi*r^2) * thickness |
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| + | ;Volume of squared coin: d^2 * thickness |
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| + | ;Volume of hexed coin: ((sqrt(3)*d^2)/2) * thickness |
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| + | |||
| + | === 5c === |
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| + | |||
| + | ==== real coins ==== |
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| + | * 1.55*pi*9.705^2 = 145.99*pi = 458.638 cubic mm |
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| + | * This gives us 2180 coins to occupy 1litre of space. |
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| + | |||
| + | ==== Squared coins ==== |
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| + | * 19.41^2 * 1.55 = 583.96 cubicmm |
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| + | * This gives us now only 1712 coins. |
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| + | |||
| + | ==== Hexed coins ==== |
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| + | * ((sqrt(3)*19.42^2)/2)*1.55 = 506.245 cubic mm |
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| + | * This now gives us 1975 coins. |
||
| + | |||
| + | ==== Conclusion ==== |
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| + | In the real world, you might get around 1800 5c coins into your 1litre container - or approx $90 |
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=== 10c === |
=== 10c === |
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| − | The volume of a cylinder is determined as it's circular cross sectional area multiplied by it's height. Area is pi*(r^2). |
+ | ==== real coins ==== |
| − | So, for a 10c coin, the volume is 1.98*pi*(11.8^2)=pi*275.7 which is roughly 866.12 cubic mm |
+ | * 1.98*pi*(11.8^2)= pi*275.7 = 866.12 cubic mm |
| + | * This gives us 1154 coins to occupy 1litre of space. |
||
| + | |||
| + | ==== Squared coins ==== |
||
| + | * 23.6^2*1.98 = 1102.8 cubic mm. |
||
| + | * This now gives us only 906 coins |
||
| + | |||
| + | ==== Hexed coins ==== |
||
| + | * ((sqrt(3)*23.6^2)/2)*1.98 = 955.036 cubic mm |
||
| + | * This gives us 1047 coins into our million cubic millimetre volume. |
||
| + | |||
| + | ==== Conclusion ==== |
||
| + | In the real world, you can probably get about 950 10c coins into a 1litre container - or $95. |
||
| + | |||
| + | In actual testing, I achieved 940 coins - or, $94! :) |
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| + | |||
| + | === 20c === |
||
| + | |||
| + | ==== real coins ==== |
||
| + | * 2.52*pi*(14.26^2)= pi*512.436 = 1609.86 cubic mm |
||
| + | * This gives us 621 coins to occupy 1litre of space. |
||
| + | |||
| + | ==== Squared coins ==== |
||
| + | * 28.52^2*2.52 = 2049.744 cubic mm. |
||
| + | * This now gives us only 487 coins |
||
| + | |||
| + | ==== Hexed coins ==== |
||
| + | * ((sqrt(3)*28.52^2)/2)*2.52 = 1775.13 cubic mm |
||
| + | * This gives us 563 coins into our million cubic millimetre volume. |
||
| + | |||
| + | ==== Conclusion ==== |
||
| + | In the real world, you might get around 500 20c coins into your 1litre container - or $100 |
||
| + | |||
| + | * In an actual test, I had 442 coins - or $88.40 |
||
| + | (some $1 stacks had $1.20, so the actual number is closer to $89 |
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| + | * In a second jar, I had 469 coins - or $93.80 |
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| + | |||
| + | Clearly, internal stacking can have more than a 5% different in value! |
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| + | (my stacking method tends to have been 'shake and repeat' until it seems to work... |
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| + | |||
| + | |||
| + | === 50c === |
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| + | Aussie 50c coins are |
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| + | * huge |
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| + | * not round |
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| + | Due to the second of these, I've never bothered to do the math. Maybe one day I'll have a jar full and I can give real-world results however! :) |
||
| + | |||
| + | ...Real world test got it to $185! |
||
| + | |||
| + | |||
| + | === $1 === |
||
| + | |||
| + | ==== real coins ==== |
||
| + | * 2.8*pi*(12.5^2)= pi*437.5 = 1374.45 cubic mm |
||
| + | * This gives us 727 coins to occupy 1litre of space. |
||
| + | |||
| + | ==== Squared coins ==== |
||
| + | * 25^2*2.8 = 1750 cubic mm. |
||
| + | * This now gives us only 571 coins |
||
| + | |||
| + | ==== Hexed coins ==== |
||
| + | * ((sqrt(3)*25^2)/2)*2.8 = 1515.54 cubic mm |
||
| + | * This gives us 659 coins into our million cubic millimetre volume. |
||
| + | |||
| + | ==== Conclusion ==== |
||
| + | In the real world, you're gonna be looking at around 600 coins. I'm not gonna even pretend I need to work out the dollar value here. |
||
| + | |||
| + | |||
| + | === $2 === |
||
| + | |||
| + | ==== real coins ==== |
||
| + | * 3*pi*(10.25^2)= pi*315.19 = 990.19 cubic mm |
||
| + | * This gives us 1009 coins to occupy 1litre of space. |
||
| − | So, it will take 1154 10c coins will occupy the volume of a litre. That's a theoretical maximum of course, and for a real-world litre container, there will be spaces between the coins. |
+ | ==== Squared coins ==== |
| + | * 20.5^2*3 = 1260.75 cubic mm. |
||
| + | * This now gives us only 793 coins |
||
| − | So, let's assume coins stacked in piles, and those stacks arranged in a grid. ie, as if the coins were square rather than round. In this case, each coin takes up the volume of 23.6^2*1.98 = 1102.8 cubic mm. |
+ | ==== Hexed coins ==== |
| + | * ((sqrt(3)*20.5^2)/2)*3 = 1091.84 cubic mm |
||
| + | * This gives us 915 coins into our million cubic millimetre volume. |
||
| − | With out 1million cubic mm litre, we can fit 906 coins in via this method. |
+ | ==== Conclusion ==== |
| + | * You're probably looking at the 800-850 coins mark if you're lucky, or $1600+ :) |
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| − | In the real world, coins even dumped in randomly, will arrange themselves much more efficiently than this method, but the math to work it out would be quite horrible, and would need to know the container shape. If we worked out the volume according to piles arranged in a honeycomb, then that would probably get us much closer. |
||
| − | Conclusion: You can probably get about 1000 10c coins into a 1litre container - or $100 |
+ | === Links === |
| + | * http://www.drking.worldonline.co.uk/hexagons/misc/area.html |
||
Latest revision as of 21:54, 20 December 2012
|
...a Density Analysis of australian coinage ie, how much value of a given coin can you fit inside, say, 1litre of space?
So what are we dealing with:
- 1litre = 1000cm^3 of volume = 1,000,000 cubic mm
Australian coin sizes: (see: http://www.worldmints.com/ccoin_ram.asp) (note that diameter is the specified, but thickness is the maximum legal allowed)
- 5c
- diameter: 19.41mm, thickness: 1.55mm
- 10c
- 23.6mm, 1.98mm
- 20c
- 28.52mm, 2.52mm
- 50c
- 31.51mm (across flats), 2.8mm
- $1
- 25mm, 2.8mm
- $2
- 20.5mm, 3mm
[edit] How to calculate
There are three estimates easily possible.
- Count of coins for maximum displacement within our 1litre limit (1litre divided by volume per coin)
- Same as before, but assume coins are square with edge length equal to diameter. Simulates stacks arranged in a grid
- Same as before, but assume coins are hexagonal and stacked in a hex lattice. (is this the most efficient possible in a 3d space?)
In the real world, coins are unlikely to be stacked neatly, but with repeated shaking should form themselves into dense stacks. Thus I'd expect a real-world result somewhere between the 'squared' and 'hexed' results.
- Volume of coin
- (pi*r^2) * thickness
- Volume of squared coin
- d^2 * thickness
- Volume of hexed coin
- ((sqrt(3)*d^2)/2) * thickness
[edit] 5c
[edit] real coins
- 1.55*pi*9.705^2 = 145.99*pi = 458.638 cubic mm
- This gives us 2180 coins to occupy 1litre of space.
[edit] Squared coins
- 19.41^2 * 1.55 = 583.96 cubicmm
- This gives us now only 1712 coins.
[edit] Hexed coins
- ((sqrt(3)*19.42^2)/2)*1.55 = 506.245 cubic mm
- This now gives us 1975 coins.
[edit] Conclusion
In the real world, you might get around 1800 5c coins into your 1litre container - or approx $90
[edit] 10c
[edit] real coins
- 1.98*pi*(11.8^2)= pi*275.7 = 866.12 cubic mm
- This gives us 1154 coins to occupy 1litre of space.
[edit] Squared coins
- 23.6^2*1.98 = 1102.8 cubic mm.
- This now gives us only 906 coins
[edit] Hexed coins
- ((sqrt(3)*23.6^2)/2)*1.98 = 955.036 cubic mm
- This gives us 1047 coins into our million cubic millimetre volume.
[edit] Conclusion
In the real world, you can probably get about 950 10c coins into a 1litre container - or $95.
In actual testing, I achieved 940 coins - or, $94! :)
[edit] 20c
[edit] real coins
- 2.52*pi*(14.26^2)= pi*512.436 = 1609.86 cubic mm
- This gives us 621 coins to occupy 1litre of space.
[edit] Squared coins
- 28.52^2*2.52 = 2049.744 cubic mm.
- This now gives us only 487 coins
[edit] Hexed coins
- ((sqrt(3)*28.52^2)/2)*2.52 = 1775.13 cubic mm
- This gives us 563 coins into our million cubic millimetre volume.
[edit] Conclusion
In the real world, you might get around 500 20c coins into your 1litre container - or $100
- In an actual test, I had 442 coins - or $88.40
(some $1 stacks had $1.20, so the actual number is closer to $89
- In a second jar, I had 469 coins - or $93.80
Clearly, internal stacking can have more than a 5% different in value! (my stacking method tends to have been 'shake and repeat' until it seems to work...
[edit] 50c
Aussie 50c coins are
- huge
- not round
Due to the second of these, I've never bothered to do the math. Maybe one day I'll have a jar full and I can give real-world results however! :)
...Real world test got it to $185!
[edit] $1
[edit] real coins
- 2.8*pi*(12.5^2)= pi*437.5 = 1374.45 cubic mm
- This gives us 727 coins to occupy 1litre of space.
[edit] Squared coins
- 25^2*2.8 = 1750 cubic mm.
- This now gives us only 571 coins
[edit] Hexed coins
- ((sqrt(3)*25^2)/2)*2.8 = 1515.54 cubic mm
- This gives us 659 coins into our million cubic millimetre volume.
[edit] Conclusion
In the real world, you're gonna be looking at around 600 coins. I'm not gonna even pretend I need to work out the dollar value here.
[edit] $2
[edit] real coins
- 3*pi*(10.25^2)= pi*315.19 = 990.19 cubic mm
- This gives us 1009 coins to occupy 1litre of space.
[edit] Squared coins
- 20.5^2*3 = 1260.75 cubic mm.
- This now gives us only 793 coins
[edit] Hexed coins
- ((sqrt(3)*20.5^2)/2)*3 = 1091.84 cubic mm
- This gives us 915 coins into our million cubic millimetre volume.
[edit] Conclusion
- You're probably looking at the 800-850 coins mark if you're lucky, or $1600+ :)
