SO I realise the question I am asking here is large and complex.

### A potential solution to variences in sizes of

In all of my searching through statistical forums and posts I haven't come across a scientifically sound method of taking into account the type of data that I am encountering, but I have thought up a (novel?) potential solutions to account perfectly (in my mind) for large and small datasets within the same model.

The proposed method involves using a genetic algorithm to alter two numbers defining a relationship between the size of the dataset making up an `implied strike`

rate and the
percentage of the `implied strike`

to be used, with the target of the model to maximise the homology of the number `1`

in two columns of the following csv. (ultra simplified
but hopefully demonstrates the principle)

### Example data

```
Date,PupilName,Unique class,Achieved rank,x,y,x/y,Average xy
12/12/2012,PupilName1,UniqueClass1,1,3000,9610,0.312174818,0.08527
12/12/2012,PupilName2,UniqueClass1,2,300,961,0.312174818,0.08527
12/12/2012,PupilName3,UniqueClass1,3,1,3,0.333333333,0.08527
13/12/2012,PupilName1,UniqueClass2,1,2,3,0.666666667,0.08527
13/12/2012,PupilName2,UniqueClass2,2,0,1,0,0.08527
13/12/2012,PupilName3,UniqueClass2,3,0,5,0,0.08527
13/12/2012,PupilName4,UniqueClass2,4,0,2,0,0.08527
13/12/2012,PupilName5,UniqueClass2,5,0,17,0,0.08527
14/12/2012,PupilName1,UniqueClass3,1,1,2,0.5,0.08527
14/12/2012,PupilName2,UniqueClass3,2,0,1,0,0.08527
14/12/2012,PupilName3,UniqueClass3,3,0,5,0,0.08527
14/12/2012,PupilName4,UniqueClass3,4,0,6,0,0.08527
14/12/2012,PupilName5,UniqueClass3,5,0,12,0,0.08527
15/12/2012,PupilName1,UniqueClass4,1,0,0,0,0.08527
15/12/2012,PupilName2,UniqueClass4,2,1,25,0.04,0.08527
15/12/2012,PupilName3,UniqueClass4,3,1,29,0.034482759,0.08527
15/12/2012,PupilName4,UniqueClass4,4,1,38,0.026315789,0.08527
16/12/2012,PupilName1,UniqueClass5,1,12,24,0.5,0.08527
16/12/2012,PupilName2,UniqueClass5,2,1,2,0.5,0.08527
16/12/2012,PupilName3,UniqueClass5,3,13,59,0.220338983,0.08527
16/12/2012,PupilName4,UniqueClass5,4,28,359,0.077994429,0.08527
16/12/2012,PupilName5,UniqueClass5,5,0,0,0,0.08527
17/12/2012,PupilName1,UniqueClass6,1,0,0,0,0.08527
17/12/2012,PupilName2,UniqueClass6,2,2,200,0.01,0.08527
17/12/2012,PupilName3,UniqueClass6,3,2,254,0.007874016,0.08527
17/12/2012,PupilName4,UniqueClass6,4,2,278,0.007194245,0.08527
17/12/2012,PupilName5,UniqueClass6,5,1,279,0.003584229,0.08527
```

So I have created a tiny model dataset, which contains some good examples of where my current methods fall short and how I feel a genetic algorithm can be used to fix this. If we look in the dataset above it contains 6 unique classes the ultimate objective of the algorithm is to create as high as possible correspondence between a rank of an adjusted `x/y`

and the `achieved rank`

in column 3 (zero based referencing.) In `uniqueclass1`

we have two identical `x/y`

values, now these are comparatively large `x/y`

values if you compare with the average (note the average isn't calculated from this dataset) but it would be common sense to expect that the 3000/9610 is more significant and therefore more likely to have an `achieved rank`

of `1`

than the 300/961. So what I want to do is make an `adjusted x/y`

to overcome these differences in dataset sizes using a logarithmic growth relationship defined by the equation:

`adjusted xy = ((1-exp(-y*α)) * x/y)) + ((1-(1-exp(-y*α)))*Average xy)`

Where `α`

is the only dynamic number

If I can explain my logic a little and open myself up to (hopefully) constructive criticsm. This graph below shows is an exponential growth relationship between size of the data set and the % of x/y contributing to the adjusted x/y. Essentially what the above equation says is as the dataset gets larger the percentage of the original `x/y`

used in the `adjusted x/y`

gets larger. Whatever percentage is left is made up by the average xy. Could hypothetically be 75% `x/y`

and 25% `average xy`

for 300/961 and 95%/5% for 3000/9610 creating an adjusted x/y which clearly demonstrates

For help with understanding the lowering of `α`

would produce the following relationship where by a larger dataset would be requred to achieve the same "% of xy contributed"

Conversly increasing `α`

would produce the following relationship where by a smaller dataset would be requred to achieve the same "% of xy contributed"

So I have explained my logic. I am also open to code snippets to help me overcome the problem. I have plans to make a multitude of genetic/evolutionary algorithms in the future and could really use a working example to pick apart and play with in order to help my understanding of how to utilise such abilities of python. If additional detail is required or further clarification about the problem or methods please do ask, I really want to be able to solve this problem and future problems of this nature.

So after much discussion about the methods available to overcome the problem presented here I have come to the conclusion that he best method would be a genetic algorithm to iterate α in order to maximise the homology/correspondance between a rank of an adjusted x/y and the achieved rank in column 3. It would be greatly greatly appreciated if anyone be able to help in that department?

### So to clarify, this post is no longer a discussion about methodology

I am hoping someone can help me produce a genetic algorithm to maximise the homology between the results of the equation

`adjusted xy = ((1-exp(-y*α)) * x/y)) + ((1-(1-exp(-y*α)))*Average xy)`

Where `adjusted xy`

applies to each row of the csv. Maximising homology could be achieved by minimising the difference between the rank of the `adjusted xy`

(where the rank is by each `Unique class`

only) and `Achieved rank.`

Minimising this value would maximise the homology and essentially solve the problem presented to me of different size datasets. If any more information is required please ask, I check this post about 20 times a day at the moment so should reply rather promptly. Many thanks SMNALLY.