I want to add a histogram contour to my scatterplot (where colors are already taken up), to show the e.g. 50th percentile of the data since there are a lot of points and some of them overlap (and it's not sightly to look at if they're plotted smaller)
@user2305193 I think you are complicating your plot too much. It is “one plot = one story”, not “one plot = all my data”. A plot is about communicating your finding to your audience, not about demonstrating how much work you did to make that finding. What story do you want to convey with this plot? Plot just the stuff that you need to express that story. The simpler the plot, the easier it is for your audience to read the plot and understand your story.
Yeah, no I understand, and intuitively I think I would respond the same if I re-read my question. It's more like I have two axis in a scatterplot and I want to visualize and quantify the spread of all the dots in x and y. It's not a substantial difference, so I want to gauge if it's worth it to even visualize (my gut feeling would be 'no'). Can be done in many easy (easier?) ways but I was wondering if I can add this for clarity to the readers
just because dots are also overlapping - it's more transparent if you show the distribution. To this end I considered the histogram in a scatterhist or scatterhistogram like fashion
(the difference is significant but small)
thanks for answers
!
I don't really care about 3d, it was just the easiest way for me to think about a median or 95% contour line in a scatter plot
I'd say that if you plot contours for various density levels, you should leave out the scatter plot. The two represent the same information. Pick the one form that shows the aspects of the data you want to show.
A 3D histogram is useless IMO. You can show a surface plot of an estimated density function if the shape of the function is more important than the values themselves, or the exact location of the maximum, etc. If those aspects are more important than the shape, use a contour plot. If the correlation between the two axes is most important, use a scatter plot.
And remember that if you want to show multiple aspects of a data set, you can always have multiple plots. You don't need to put everything on top of each other into the same plot.
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@AndrasDeak I always find it funny to see this one being used - it reminds me of all the video games where everything that is supposed to look futuristic is hexagonal:)
@AndrasDeak With a Numpy array A, the function call np.sum(A) and the method invocation A.sum() seem to do the same. Is there some subtle difference? Which is preferred (faster, better style, ...)?
@LuisMendo exact same as far as I know. I prefer the method lookup. Might be marginally faster but doesn't matter. If you use JIT accelerators np.sum might work better.
Not sure about ndarray subclasses, I don't use those.
Thanks. I've also noticed that A.sort(axis=0)changes the original array bound to the name A (if that's correct terminology), whereas A.sum(axis=0)doesn't. Why is that? @AndrasDeak
@AndrasDeak So, using functions on an array never changes the array, whereas using methods on the array sometimes changes it (A. sort) and sometimes doesn't (A.sum). Is that correct?
And if so, isn't that a mess? You have to memorize what methods change the array and what methods don't?
If you allow me to make a recommendation: I much prefer using pytorch over numpy - I guess they learned some lessons from numpy and avoided making the same mistakes:)
But that only makes sense if you don't have to rely on other libraries that only work with numpy.
Damn, hexbin is nice! The hexagonal grid is a more efficient sampling than the square grid, you need fewer samples to get the same resolution. And it looks cool. But it's annoying to work with.
@LuisMendo This is typical with object-oriented code though. It happens everywhere. And actually it also happens with imperative languages that have pass-by-reference. You always need to look up whether the arguments are being changed or not. This is why I like MATLAB so much (before the handle class shit was introduced): no pass-by-reference means inputs are never changed, the function call tells you exactly what is going to happen.
@flawr Yeah, functional programming makes sense in that it has no state, and therefore pass-by-reference is meaningless. I should try Haskell some time, just haven't had a reason to (I'd need a project to implement in Haskell, rather than just reading a book about it).
Still, I didn't say I don't like pass-by-reference, it leads to efficient programming. A state is often necessary, and being able to modify that state without copying it first is really nice.
@CrisLuengo I'm ok with having both pass-by-reference and pass-by-value as long as there is a rule (or some differentiated syntax) for telling when each of them applies. But if a method can either change the array or produce a new array with the same syntax that's confusing, I think
Yes, I probably have been spoiled by almost 25 years of Matlab programming :-)
@LuisMendo Arrays themselves are a very thin wrapper around a chunk of malloced memory. A view is a different wrapper over the same chunk of memory (or a subset of it)
arr.data is the memory an array's data sits on. arr.base tells you the original array into which the array is a view. For an array that owns its data (i.e. is not a view) arr.base is None.
While for python lists lst[:] is a (shallow) copy, for a numpy array arr[:] is a trivial view
@LuisMendo nah, views are clear once you understand what they're about. But numpy arrays are very much not python lists. Think of arithmetic for instance, or bool(lst).
In [16]: arr = np.arange(10)
...: brr = arr[2::]
In [17]: arr.data
Out[17]: <memory at 0x7f10547b4ac0>
In [18]: brr.data
Out[18]: <memory at 0x7f107403b7c0>
In [19]: arr.base is None
Out[19]: True
In [20]: brr.base is arr
Out[20]: True
And a bunch of things in numpy give you views. One key thing about basic indexing and fancy (aka. advanced) indexing is this: slices as indices are basic indexing and give you views. Array-likes as indices are fancy indexing and give you copies. And the distinction is clear if you consider that any slice into a memory can be described by strides, whereas a general array-valued index can't be represented by just strides.
And by strides we mean "the number of steps to jump on the underlying chunk of memory with each dimension of the array"
In [28]: arr = np.arange(10)
...: brr = arr[::2] # every other element: double the strides
In [29]: arr.strides, brr.strides
Out[29]: ((8,), (16,))
Absolutely, numpy is a whole new world compare to native python.
@LuisMendo yeah, you have to keep track of that. You normally avoid using multiple views at the same time, because you don't want to mutate your arrays inadvertently. Just call .copy() to get a new array that owns its data.
These are important concepts, and they make a lot of sense even though they might seem overwhelming at first. The concept of the view is fundamental for efficient programming, and is the one thing that MATLAB is really missing.
@LuisMendo For example, notice how in MATLAB subsref and subsasgn are different functions, that mostly implement the same functionality? The one copies data out of the array, the other copies it into the array. If you have views, these two would be the exact same function, creating an array into its input. a(1:3:end) just returns the view, whereas a(1:3:end) = 0 fills the view with zeros.
@AndrasDeak Yeah, I would have liked to be able to use the colon in function calls as well. A('foo',4:7). Instead you need to do A('foo',slice(4,7)).
@LuisMendo The a(1:3:end) part (in my examples above) can be interpreted identically in both cases (OK, so Python doesn't do this, but DIPlib does). The = 0 is a second action, that takes the result of a(1:3:end) as one of its inputs.
@CrisLuengo I don't see why it should be special-cased then. Just make 4:7 a synonym for slice(4, 7). Then again it would more often be useful to make it mean range(4, 7) but that's out of the question.
I'm not sure I follow. I expected 4:7 to be a synonym for slice(4,7) always, but this is only true within an indexing expression. func(4:7) is illegal, arr[4:7] calls __getitem__ with slice(4,7) as one of the arguments.
@CrisLuengo yes, that's why it can only mean slice. My point, however, is that It might be nice to have a standalone range object with the same syntax. Same as how 1:5 is a range in MATLAB.
Right, that makes sense. A lot of these ideas about how stuff should work are developed over time by experience, but it's hard to change how the language works. This is, I guess, why there are so many different languages. :)
@CrisLuengo that's why I don't let dumb machines touch my typing. I insist on my own typos.
@CrisLuengo and some mistakes are bad enough that they do change them. And then after more than a decade we still see people scrambling for python 2 support :'(