# Middle point of each pair of an numpy.array

I have an array of the form:

`x = np.array([ 1230., 1230., 1227., 1235., 1217., 1153., 1170.])`

and I would like to produce another array where the values are the mean of each pair of values within my original array:

`xm = np.array([ 1230., 1228.5, 1231., 1226., 1185., 1161.5])`

Someone knows the easiest and fast way to do it without using loops?

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Short and sweet:

``````x[:-1] + np.diff(x)/2
``````

That is, take each element of `x` except the last, and add one-half of the difference between it and the subsequent element.

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I posted 9 seconds before you did, though I must admit you gave a better explanation! – moarningsun May 25 '14 at 14:02
I would have posted 9 seconds before you if I had just clicked the button as soon as I had typed the code! :) It's pretty cool that we wrote the exact same solution, meanwhile a couple other people came up with pretty different ideas, and I have to say each one of them has its own special appeal. I still like ours though! – John Zwinck May 25 '14 at 14:04

Even shorter, slightly sweeter:

``````(x[1:] + x[:-1]) / 2
``````

• This is faster:

``````>>> python -m timeit -s "import numpy; x = numpy.random.random(1000000)" "x[:-1] + numpy.diff(x)/2"
100 loops, best of 3: 6.03 msec per loop

>>> python -m timeit -s "import numpy; x = numpy.random.random(1000000)" "(x[1:] + x[:-1]) / 2"
100 loops, best of 3: 4.07 msec per loop
``````
• This is perfectly accurate:

Consider each element in `x[1:] + x[:-1]`. So consider `x₀` and `x₁`, the first and second elements.

`x₀ + x₁` is calculated to perfect precision and then rounded, in accordance to IEEE. It would therefore be the correct answer if that was all that was needed.

`(x₀ + x₁) / 2` is just half of that value. This can almost always be done by reducing the exponent by one, except in two cases:

• `x₀ + x₁` overflows. This will result in an infinity (of either sign). That's not what is wanted, so the calculation will be wrong.

• `x₀ + x₁` underflows. As the size is reduced, rounding will be perfect and thus the calculation will be correct.

In all other cases, the calculation will be correct.

Now consider `x[:-1] + numpy.diff(x) / 2`. This, by inspection of the source, evaluates directly to

``````x[:-1] + (x[1:] - x[:-1]) / 2
``````

and so consider again `x₀` and `x₁`.

`x₁ - x₀` will have severe "problems" with underflow for many values. This will also lose precision with large cancellations. It's not immediately clear that this doesn't matter if the signs are the same, though, as the error effectively cancels out on addition. What does matter is that rounding occurs.

`(x₁ - x₀) / 2` will be no less rounded, but then `x₀ + (x₁ - x₀) / 2` involves another rounding. This means that errors will creep in. Proof:

``````import numpy

wins = draws = losses = 0

for _ in range(100000):
a = numpy.random.random()
b = numpy.random.random() / 0.146

x = (a+b)/2
y = a + (b-a)/2

error_mine   = (a-x) - (x-b)
error_theirs = (a-y) - (y-b)

if x != y:
if abs(error_mine) < abs(error_theirs):
wins += 1
elif abs(error_mine) == abs(error_theirs):
draws += 1
else:
losses += 1
else:
draws += 1

wins / 1000
#>>> 12.44

draws / 1000
#>>> 87.56

losses / 1000
#>>> 0.0
``````

This shows that for the carefully chosen constant of `1.46`, a full 12-13% of answers are wrong with the `diff` variant! As expected, my version is always right.

Now consider underflow. Although my variant has overflow problems, these are much less big a deal than cancellation problems. It should be obvious why the double-rounding from the above logic is very problematic. Proof:

``````...
a = numpy.random.random()
b = -numpy.random.random()
...

wins / 1000
#>>> 25.149

draws / 1000
#>>> 74.851

losses / 1000
#>>> 0.0
``````

Yeah, it gets 25% wrong!

In fact, it doesn't take much pruning to get this up to 50%:

``````...
a = numpy.random.random()
b = -a + numpy.random.random()/256
...

wins / 1000
#>>> 49.188

draws / 1000
#>>> 50.812

losses / 1000
#>>> 0.0
``````

Well, it's not that bad. It's only ever 1 least-significant-bit off as long as the signs are the same, I think.

So there you have it. My answer is the best unless you're finding the average of two values whose sum exceeds `1.7976931348623157e+308` or is smaller than `-1.7976931348623157e+308`.

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It's probably not too relevant in practical applications, but I think this is both slightly faster than @JohnZwinck's answer, and also slightly more prone to loss of precision. – Jaime May 25 '14 at 16:41
@Jaime You're wrong. Mine is faster, but it's also perfectly accurate, whereas the `diff` version is not. I'll add some evidence to the question. – Veedrac May 25 '14 at 17:26
@Jaime Evidence added. – Veedrac May 25 '14 at 18:05
I stand corrected: nice analysis! – Jaime May 26 '14 at 4:16

Try this:

``````midpoints = x[:-1] + np.diff(x)/2
``````

It's pretty easy and should be fast.

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``````>>> x = np.array([ 1230., 1230., 1227., 1235., 1217., 1153., 1170.])

>>> (x+np.concatenate((x[1:], np.array([0]))))/2
array([ 1230. ,  1228.5,  1231. ,  1226. ,  1185. ,  1161.5,   585. ])
``````

now you can just strip the last element, if you want

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