I'd like to find a fast way to update a sum of squared residuals, when I know that only a small fraction of the terms are changing. Let me describe the problem in more detail.

I have N data points from noisy step-function data.

```
N = 100000
realStepList = [200, 500, 900]
x = np.zeros(N)
for realStep in realStepList:
x[realStep:] += 1
x+=np.random.randn(len(x))*0.1 #Add noise
```

I'd like to calculate the sum of squared residuals for this data and an arbitrary list of step locations. Here is how I do this.

```
a = [0, 250, 550, N]
def Q(x, a):
q = np.sum([np.sum((x[ai:af] - i)**2) for i, (ai,af) in enumerate(zip(a[:-1],a[1:]))])
return q
```

`a`

is my list of potential steps. It's easier to use a list that always has `0`

as the first element and `N`

as the last element.

This is relatively slow, since it is a sum over `N`

squares. However, I realized that if I change `a`

by a relatively small amount, most of these `N`

terms will remain unchanged, which means I don't have to compute them again.

So let's say I have already computed `Q(x,a)`

as above. I now have another list

`b = [aa + dd for aa, dd in zip(a, d)]`

where `d`

is the difference between the two lists. Rather than calculating `Q(x,b)`

as above (another sum over `N`

elements), I want to find

`deltaQ(x, a, d)`

such that

`Q(x, b) = Q(x,a) + deltaQ(x, a, d)`

I have written such a function, but it is slow and sloppy. In fact, it is *slower* than `Q`

!

```
def deltaQ(x, a, d):
z = np.zeros(len(x))
J = np.zeros(len(x))
s = 0
for j, [dd, aa] in enumerate(zip(d, a[1:-1])):
if dd >= 0:
z[aa:aa+dd] += 1
s += sum(x[aa:aa+dd])
if dd < 0:
z[aa+dd:aa] += -1
s += -sum(x[aa+dd:aa])
J[aa:] += 1
dq = 2*s - sum((J**2 - (J-z)**2))
return dq
```

The idea is to identify all the points in `x`

which will be affected. For example, if the original list was `a = [0, 5, 10]`

and `b = [0, 7, 10]`

, then only the terms corresponding to `x[5:7]`

will change in the sum. I keep track of this with the list `z`

. I then calculate the change based on this.

I don't think I'm the first person in the world to have this problem. So my question is:

Is there a fast way to calculate the *difference* in the sum of squared residuals, since this will often be a sum many fewer elements than recalculating the new sum from scratch?

`b = [aa + dd for zip(a, d)]`

is not valid syntax.`a`

stay the same when making those small changes? In other words, do only the values change or also the number of steps? Also, can you give an example of`d`

?findthe true step locations. If you are, I can help you with that too :)1more comment