I have two vectors, a and b. See attached.
a is the signal and is a probability.
b is the absolute percentage change the next period.
Signalt <- seq(0, 1, 0.05)
I would like to find the maximum absolute return occuring within each intermediate 5%-tile (
Signalt) of the a vector. So if it is
0.01, 0.02, 0.03, 0.06 0.07
then it should calculate the maximum return between
0.01 and 0.02, 0.01 and 0.03, 0.02 and 0.03.
Then move on to
0.06 and 0.07 do it over etc.
Output would then be combined in a matrix or table when the entire sequence has run.
It should follow the index from vector a and b.
i is an index that is updated by one every time that
a crosses into a new percentile.
t(i) is the bucket associated with the
a is the probability vector which has length tao. This vector should be analyzed in its 5% tiles, with the maximum intermediate absolute return being the output. The price change of next period is the vector
b. This would be represented by P in the equation below.
m are indexes.
Every time Signal moves from one 5% tile to another, we compute the largest absolute return that occurs between any two intermediate buckets, until Signal moves to another 5% tile. For example, suppose that Signal moves into the 85th percentile and 4 volume buckets later moves into the 90th percentile. We would then calculate absolute returns between buckets 1 and 2, 1 and 3, 1 and 4, 2 and 3, 2 and 4, 3 and 4. We are interested in the maximum absolute return. We would then calculate the max return in the following percentile bucket, move on to the next, which could be an 85th percentile and so on. So we let i be an index that is updated by 1 every time that Signal moves from one percentile into another, and τ(i) the bucket associated with the ith cross.
This is the equation I am using. The notation might vary slightly.
Now my question is how to go about this. Perhaps someone has an intuitive solution to this. I hope my question is clear.
"a","b" 0,0.013013698630137 0,0.0013522650439487 0,0.00135409614082593 0,0.00203389830508471 0.27804813511593,0.00135317997293627 0.300237801284318,0 0.495965075167796,0.00405405405405412 0.523741892051237,0.000672947510094168 0.558753750296458,0.00202020202020203 0.665762829019002,0.000672043010752743 0.493106479913899,0.000671591672263272 0.344592579573497,0.000672043010752854 0.336263897823707,0.00201748486886366 0.35884763774257,0.00536912751677865 0.23662807979007,0.00133511348464632 0.212636893966841,0.00267379679144386 0.362212830513403,0.000666666666666593 0.319216408413927,0.00333555703802535 0.277670854167344,0 0.310143323100971,0 0.374104373036218,0.00267737617135211 0.190943075221511,0.00268456375838921 0.165770070508112,0.00200803212851386 0.240310208616952,0.00133600534402145 0.212418038918236,0.00200133422281523 0.204282022136019,0.00200534759358306 0.363725074298064,0.000667111407605114 0.451807761954326,0.000666666666666593 0.369296011692801,0.000666222518321047 0.37503495989363,0.0026666666666666 0.323386355686901,0.00132978723404265 0.189216171830472,0.00266311584553924 0.185252052821193,0.00199203187250996 0.174882909380997,0.000662690523525522 0.149291525540782,0.00132625994694946 0.196824215268048,0.00264900662251666 0.164611993131396,0.000660501981505912 0.125470998266484,0.00132187706543285 0.179999532586703,0.00264026402640272 0.368749638521621,0.000658327847267826 0.427799340926225,0