# 1D Number Array Clustering

So let's say I have an array like this:

``````[1,1,2,3,10,11,13,67,71]
``````

Is there a convenient way to partition the array into something like this?

``````[[1,1,2,3],[10,11,13],[67,71]]
``````

I looked through similar questions yet most people suggested using k-means to cluster points, like scipy, which is quite confusing to use for a beginner like me. Also I think that k-means is more suitable for two or more dimensional clustering right? Are there any ways to partition an array of N numbers to many partitions/clustering depending on the numbers?

Some people also suggest rigid range partitioning, but it doesn't always render the results as expected

Don't use multidimensional clustering algorithms for a one-dimensional problem. A single dimension is much more special than you naively think, because you can actually sort it, which makes things a lot easier.

In fact, it is usually not even called clustering, but e.g. segmentation or natural breaks optimization.

You might want to look at Jenks Natural Breaks Optimization and similar statistical methods. Kernel Density Estimation is also a good method to look at, with a strong statistical background. Local minima in density are be good places to split the data into clusters, with statistical reasons to do so. KDE is maybe the most sound method for clustering 1-dimensional data.

With KDE, it again becomes obvious that 1-dimensional data is much more well behaved. In 1D, you have local minima; but in 2D you may have saddle points and such "maybe" splitting points. See this Wikipedia illustration of a saddle point, as how such a point may or may not be appropriate for splitting clusters.

See this answer for an example how to do this in Python (green markers are the cluster modes; red markers a points where the data is cut; the y axis is a log-likelihood of the density):

• Implementation here: macwright.org/2013/02/18/literate-jenks.html Jan 17, 2014 at 23:10
• Could you update your answer with why `meanshift` or `dbscan` may or may not be good approaches to clustering 1D? See scikit-learn.org/stable/modules/clustering.html Mar 4, 2015 at 14:35
• Essentially, both are very naive approximations to Kernel Density Estimation. Mean-Shift is a mode-seeking approach for multivariate KDE, and DBSCAN is using the most primitive KDE (box kernel) to define what is dense and what is not. There is 0 benefit to use them on 1-dimensional data. Mar 4, 2015 at 19:46
• Ckmeans.1d.dp (k-means adapted for dimensional clustering) is worth a look however. See journal.r-project.org/archive/2011-2/… Aug 27, 2016 at 17:28
• @skoush that is a slower k-means variant that yields the global optimum (in 1d only). But if the SSQ k-means objective doesn't solve your problem it does not matter if you find a 0.1% better (by SSQ) k-means solution than with the faster standard algorithm. Aug 27, 2016 at 17:35

This simple algorithm works:

``````points = [0.1, 0.31,  0.32, 0.45, 0.35, 0.40, 0.5 ]

clusters = []
eps = 0.2
points_sorted = sorted(points)
curr_point = points_sorted[0]
curr_cluster = [curr_point]
for point in points_sorted[1:]:
if point <= curr_point + eps:
curr_cluster.append(point)
else:
clusters.append(curr_cluster)
curr_cluster = [point]
curr_point = point
clusters.append(curr_cluster)
print(clusters)
``````

The above example clusters points into a group, such that each element in a group is at most `eps` away from another element in the group. This is like the clustering algorithm `DBSCAN` with `eps=0.2, min_samples=1`. As others noted, 1d data allows you to solve the problem directly, instead of using the bigger guns like `DBSCAN`.

The above algorithm is 10-100x faster for some small datasets with `<1000` elements I tested.

You may look for discretize algorithms. 1D discretization problem is a lot similar to what you are asking. They decide cut-off points, according to frequency, binning strategy etc.

weka uses following algorithms in its , discretization process.

weka.filters.supervised.attribute.Discretize

uses either Fayyad & Irani's MDL method or Kononeko's MDL criterion

weka.filters.unsupervised.attribute.Discretize

uses simple binning

• Hi! The link doesn't seem accessible anymore.. do you have another resource please? Apr 9, 2021 at 12:08

CKwrap is a fast and straightforward k-means clustering function, though a bit light on documentation.

## Example Usage

pip install ckwrap

``````import ckwrap

nums= np.array([1,1,2,3,10,11,13,67,71])
km = ckwrap.ckmeans(nums,3)

print(km.labels)
# [0 0 0 0 1 1 1 2 2]

buckets = [[],[],[]]
for i in range(len(nums)):
buckets[km.labels[i]].append(nums[i])
print(buckets)
# [[1, 1, 2, 3], [10, 11, 13], [67, 71]]
exit()
``````

I expect the authors intended you to make use of the nd array functionality rather than create a list of lists.

other measures:

``````km.centers
km.k
km.sizes
km.totss
km.betweenss
km.withinss
``````

• Any idea how I get the index of the `km.centers` in the input dataset? Aug 4, 2021 at 18:31
• km.centers[0] corresponds to the first element in the input dataset. Aug 30, 2021 at 15:05

I have recently authored a new hierarchical clustering algorithm specifically for 1D data. I think it would be suitable to the case in your question. It is called `hlust1d` and it is written in `R`. It is available under this link.

The algorithm addresses @Anony-Mousse's concern: it takes advantages of the particular structure of 1D data and runs in O(n*log n) time. This is much faster than general-purpose hierarchical clustering algorithms.

To segment your data into 3 bins (clusters) as you require in your question, you could run the following code

``````library(hclust1d)
dendrogram <- hclust1d(c(1, 1, 2, 3, 10, 11, 13, 67, 71))
plot(dendrogram)
``````

Now, having a look at the dendrogram tree one can see that cutting at the height of aprox. 10 results in the segmentation required.

``````cutree(dendrogram, h=10)
# 1  1  2  3 10 11 13 67 71
# 1  1  1  1  2  2  2  3  3
``````

The clustering is hierarchical, meaning that what you get is a hierarchy of clusters (a dendrogram) and it is up to you to decide, which number of clusters fits your particular data best. It is both an advantage (flexibility) and disadvantage (you have to decide something) of this method. For instance, another good cut of the dendrogram, as can be seen on a plot, is located somewhere between the heights of 20 and 60, resulting in two clusters:

``````cutree(dendrogram, h=20)
# 1  1  2  3 10 11 13 67 71
# 1  1  1  1  1  1  1  2  2
``````

For more complex data, you could also experiment with other linkage functions using the `method` argument, like this:

``````dendrogram <- hclust1d(c(1, 1, 2, 3, 10, 11, 13, 67, 71), method="ward.D2")
``````

Generally, Ward linkage method would give you a clustering similar to K-Means (the loss function in both methods is the same with Ward hierarchical clustering being a greedy implementation) but the hierarchical clustering let's you decide what is an appropriate number of clusters with a dendrogram in front of you, while you have to provide that number for K-Means up front.

The list of all supported linkage methods can be read with a use of

``````> supported_methods()
# [1] "complete"    "average"     "centroid"    "true_median" "median"      "mcquitty"    "ward.D"      "ward.D2"     "single"
``````

Late response and just for the record. You can partition a 1D array using Ckmeans.1d.dp.

This method guarantees optimality and it is O(n^2), where n is the num of observations. The implementation is in C++ and there is a wrapper in R.

When you have 1-dimensional data, sort it, and look for the largest gaps

I only added that gaps need to be relatively large

``````import numpy as np
from scipy.signal import argrelextrema
# lst = [1,1,5,6,1,5,10,22,23,23,50,51,51,52,100,112,130,500,512,600,12000,12230]
lst = [1,1,2,3,10,11,13,67,71]
lst.sort()
diff = [lst[i] - lst[i-1] for i in range(1, len(lst))]
rel_diff = [diff[i]/lst[i] for i in range(len(diff))]
arg = argrelextrema(np.array(rel_diff), np.greater)[0]
last = 0
for x in arg:
print(f'{last}:{x + 1} {lst[last:x + 1]}')
last = x + 1
print(f'{last}: {lst[last:]}')
``````

output:

``````0:2 [1, 1]
2:4 [2, 3]
4:7 [10, 11, 13]
7: [67, 71]
``````
• I prefer iterations over list elements to indexes (e.g. `[y-x for x, y in zip(lst[:-1], lst[1:])]`), but algorithmically a very pragmatic answer. In particular, the complexity is the same as for sort, so `O(n log(n))`. Mar 28, 2023 at 10:30