# Formulation

Here's how I would formulate the problem. Let the items in your (potentially infinite) sequence be `i=1,2,...`

. Suppose you want to take approximately `0 < z < 1`

of the items from your sequence, to generate a sparser sequence. Let `x(i)`

represent whether we include item `i`

in the sparser sequence we generate.

For any window of `n`

consecutive items (where you pick `n >= 1`

), you want the *expected* number of items to be `z*n`

, but with the possibility for some *variance* from that expectation. For this you could use a (truncated) binomial distribution (link) with mean `z*n`

and standard deviation `d`

(where you pick `d > 0`

). (It's truncated on the right because it would be impossible for you to pick more than `n`

items when there are only `n`

to consider! You could also truncate it on the left to say "I always want *at least* `m`

items out of every `n`

, where `m`

is much less than `z*n`

, but I'll assume you skip that.)

Now, you can determine the probability you should include the item `i`

in the sparser sequence you are generating based on whether you have included each of the `n-1`

preceding items `i-1,i-2,...,i-(n-1)`

:

```
A = P( x(i) = 1 | x(i - j), 1 <= j < n )
```

# What does this all mean?

The way this is formulated, you pick three numbers:

`0 < z < 1`

- In your question, you have specified
`z`

to be 10% - i.e., `z = 0.1`

`n >= 1`

and `d > 0`

- Think of
`n`

as a window size
- Think of
`d`

as the amount of deviation from a regular sampling towards a more noisy sampling pattern
`n = 1`

means "include every item `i`

with probability `z`

, independently of whether other items are included in the sparser sequence
`n = 100, d = 0.0001`

means "except in extremely rare cases, include `10`

out of each consecutive `100`

items in the sparser sequence"
- if you make
`d`

extremely small, you're basically saying "choose every `1/z`

th item, in a regular pattern"

`n = 100, d = 5`

means "include roughly `5`

to `15`

out of each consecutive `100`

items in the sparser sequence"