As a first step, you should use a NumPy array to store your data instead of a Python list.

As you correctly observe, a Python float uses double precision internally, and the double-precision *value* underlying a Python float can be represented in 8 bytes. But on a 64-bit machine, with the CPython reference implementation of Python, a Python `float`

*object* takes a full 24 bytes of memory: 8 bytes for the underlying double-precision value, 8 bytes for a pointer to the object type, and 8 bytes for a reference count (used for garbage collection). There's no equivalent of Java's "primitive" types or .NET's "value" types in Python - everything is boxed. That makes the language semantics simpler, but means that objects tend to be fatter.

Now if we're creating a Python *list* of `float`

objects, there's the added overhead of the list itself: one 8-byte object pointer per Python `float`

(still assuming a 64-bit machine here). So in general, a list of `n`

Python `float`

objects is going to cost you over `32n`

bytes of memory. On a 32-bit machine, things are a little better, but not much: our `float`

objects are going to take 16 bytes each, and with the list pointers we'll be using `20n`

bytes of memory for a list of `float`

s of length `n`

. (Caveat: this analysis doesn't quite work in the case that your list refers to the *same* Python `float`

object from multiple list indices, but that's not a particularly common case.)

In contrast, a NumPy array of `n`

double-precision floats (using NumPy's `float64`

dtype) stores its data in "packed" format in a single data block of `8n`

bytes, so allowing for the array metadata the total memory requirement will be a little over `8n`

bytes.

Conclusion: just by switching from a Python list to a NumPy array you'll reduce your memory needs by about a factor of 4. If that's still not enough, then it might make sense to consider reducing precision from double to single precision (NumPy's `float32`

dtype), if that's consistent with your accuracy needs. NumPy's `float16`

datatype takes only 2 bytes per float, but records only about 3 decimal digits of precision; I suspect that it's going to be close to useless for the application you describe.