Clustering

Clustering seeks to group data into clusters based on their properties and then allow us to predict which cluster a new member belongs.

import numpy as np
import matplotlib.pyplot as plt

We’ll use a dataset generator that is part of scikit-learn called make_moons. This generates data that falls into 2 different sets with a shape that looks like half-moons.

from sklearn import datasets

def generate_data():
    xvec, val = datasets.make_moons(200, noise=0.2)

    # encode the output to be 2 elements
    x = []
    v = []
    for xv, vv in zip(xvec, val):
        x.append(np.array(xv))
        v.append(vv)

    return np.array(x), np.array(v)

x, v = generate_data()

Let’s look at a point and it’s value

print(f"x = {x[0]}, value = {v[0]}")

x = [0.7827843  0.72758715], value = 0

Now let’s plot the data

def plot_data(x, v):
    xpt = [q[0] for q in x]
    ypt = [q[1] for q in x]

    fig, ax = plt.subplots()
    ax.scatter(xpt, ypt, s=40, c=v, cmap="viridis")
    ax.set_aspect("equal")
    return fig

fig = plot_data(x, v)

We want to partition this domain into 2 regions, such that when we come in with a new point, we know which group it belongs to.

First we setup and train our network

from keras.models import Sequential
from keras.layers import Dense, Dropout, Activation, Input
from keras.optimizers import RMSprop

2025-05-15 11:29:44.228110: I external/local_xla/xla/tsl/cuda/cudart_stub.cc:32] Could not find cuda drivers on your machine, GPU will not be used.
2025-05-15 11:29:44.231161: I external/local_xla/xla/tsl/cuda/cudart_stub.cc:32] Could not find cuda drivers on your machine, GPU will not be used.
2025-05-15 11:29:44.239506: E external/local_xla/xla/stream_executor/cuda/cuda_fft.cc:467] Unable to register cuFFT factory: Attempting to register factory for plugin cuFFT when one has already been registered
WARNING: All log messages before absl::InitializeLog() is called are written to STDERR
E0000 00:00:1747308584.253119    3473 cuda_dnn.cc:8579] Unable to register cuDNN factory: Attempting to register factory for plugin cuDNN when one has already been registered
E0000 00:00:1747308584.257202    3473 cuda_blas.cc:1407] Unable to register cuBLAS factory: Attempting to register factory for plugin cuBLAS when one has already been registered
W0000 00:00:1747308584.268577    3473 computation_placer.cc:177] computation placer already registered. Please check linkage and avoid linking the same target more than once.
W0000 00:00:1747308584.268587    3473 computation_placer.cc:177] computation placer already registered. Please check linkage and avoid linking the same target more than once.
W0000 00:00:1747308584.268588    3473 computation_placer.cc:177] computation placer already registered. Please check linkage and avoid linking the same target more than once.
W0000 00:00:1747308584.268590    3473 computation_placer.cc:177] computation placer already registered. Please check linkage and avoid linking the same target more than once.
2025-05-15 11:29:44.272752: I tensorflow/core/platform/cpu_feature_guard.cc:210] This TensorFlow binary is optimized to use available CPU instructions in performance-critical operations.
To enable the following instructions: AVX2 FMA, in other operations, rebuild TensorFlow with the appropriate compiler flags.

model = Sequential()
model.add(Input(shape=(2,)))
model.add(Dense(50, activation="relu"))
model.add(Dense(20, activation="relu"))
model.add(Dense(1, activation="sigmoid"))

2025-05-15 11:29:46.066809: E external/local_xla/xla/stream_executor/cuda/cuda_platform.cc:51] failed call to cuInit: INTERNAL: CUDA error: Failed call to cuInit: UNKNOWN ERROR (303)

rms = RMSprop()
model.compile(loss='binary_crossentropy',
              optimizer=rms, metrics=['accuracy'])

model.summary()

Model: "sequential"

┏━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━┳━━━━━━━━━━━━━━━━━━━━━━━━┳━━━━━━━━━━━━━━━┓
┃ Layer (type)                    ┃ Output Shape           ┃       Param # ┃
┡━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━━╇━━━━━━━━━━━━━━━━━━━━━━━━╇━━━━━━━━━━━━━━━┩
│ dense (Dense)                   │ (None, 50)             │           150 │
├─────────────────────────────────┼────────────────────────┼───────────────┤
│ dense_1 (Dense)                 │ (None, 20)             │         1,020 │
├─────────────────────────────────┼────────────────────────┼───────────────┤
│ dense_2 (Dense)                 │ (None, 1)              │            21 │
└─────────────────────────────────┴────────────────────────┴───────────────┘

 Total params: 1,191 (4.65 KB)

 Trainable params: 1,191 (4.65 KB)

 Non-trainable params: 0 (0.00 B)

We seem to need a lot of epochs here to get a good result

epochs = 100
results = model.fit(x, v, batch_size=50, epochs=epochs, verbose=2)

Epoch 1/100

4/4 - 1s - 147ms/step - accuracy: 0.7450 - loss: 0.6313

Epoch 2/100

4/4 - 0s - 6ms/step - accuracy: 0.8650 - loss: 0.5835

Epoch 3/100

4/4 - 0s - 6ms/step - accuracy: 0.8700 - loss: 0.5510

Epoch 4/100

4/4 - 0s - 6ms/step - accuracy: 0.8700 - loss: 0.5253

Epoch 5/100

4/4 - 0s - 6ms/step - accuracy: 0.8600 - loss: 0.5018

Epoch 6/100

4/4 - 0s - 6ms/step - accuracy: 0.8500 - loss: 0.4807

Epoch 7/100

4/4 - 0s - 6ms/step - accuracy: 0.8550 - loss: 0.4612

Epoch 8/100

4/4 - 0s - 6ms/step - accuracy: 0.8500 - loss: 0.4424

Epoch 9/100

4/4 - 0s - 6ms/step - accuracy: 0.8500 - loss: 0.4250

Epoch 10/100

4/4 - 0s - 6ms/step - accuracy: 0.8500 - loss: 0.4073

Epoch 11/100

4/4 - 0s - 6ms/step - accuracy: 0.8550 - loss: 0.3904

Epoch 12/100

4/4 - 0s - 6ms/step - accuracy: 0.8500 - loss: 0.3751

Epoch 13/100

4/4 - 0s - 6ms/step - accuracy: 0.8500 - loss: 0.3618

Epoch 14/100

4/4 - 0s - 6ms/step - accuracy: 0.8500 - loss: 0.3501

Epoch 15/100

4/4 - 0s - 6ms/step - accuracy: 0.8500 - loss: 0.3393

Epoch 16/100

4/4 - 0s - 6ms/step - accuracy: 0.8550 - loss: 0.3303

Epoch 17/100

4/4 - 0s - 6ms/step - accuracy: 0.8500 - loss: 0.3231

Epoch 18/100

4/4 - 0s - 6ms/step - accuracy: 0.8650 - loss: 0.3141

Epoch 19/100

4/4 - 0s - 6ms/step - accuracy: 0.8600 - loss: 0.3078

Epoch 20/100

4/4 - 0s - 6ms/step - accuracy: 0.8700 - loss: 0.3015

Epoch 21/100

4/4 - 0s - 6ms/step - accuracy: 0.8700 - loss: 0.2961

Epoch 22/100

4/4 - 0s - 6ms/step - accuracy: 0.8650 - loss: 0.2918

Epoch 23/100

4/4 - 0s - 6ms/step - accuracy: 0.8700 - loss: 0.2861

Epoch 24/100

4/4 - 0s - 6ms/step - accuracy: 0.8650 - loss: 0.2817

Epoch 25/100

4/4 - 0s - 6ms/step - accuracy: 0.8700 - loss: 0.2782

Epoch 26/100

4/4 - 0s - 6ms/step - accuracy: 0.8700 - loss: 0.2740

Epoch 27/100

4/4 - 0s - 6ms/step - accuracy: 0.8700 - loss: 0.2703

Epoch 28/100

4/4 - 0s - 6ms/step - accuracy: 0.8700 - loss: 0.2678

Epoch 29/100

4/4 - 0s - 6ms/step - accuracy: 0.8650 - loss: 0.2643

Epoch 30/100

4/4 - 0s - 6ms/step - accuracy: 0.8750 - loss: 0.2612

Epoch 31/100

4/4 - 0s - 6ms/step - accuracy: 0.8750 - loss: 0.2577

Epoch 32/100

4/4 - 0s - 6ms/step - accuracy: 0.8750 - loss: 0.2545

Epoch 33/100

4/4 - 0s - 6ms/step - accuracy: 0.8750 - loss: 0.2515

Epoch 34/100

4/4 - 0s - 6ms/step - accuracy: 0.8750 - loss: 0.2496

Epoch 35/100

4/4 - 0s - 6ms/step - accuracy: 0.8750 - loss: 0.2458

Epoch 36/100

4/4 - 0s - 6ms/step - accuracy: 0.8750 - loss: 0.2444

Epoch 37/100

4/4 - 0s - 6ms/step - accuracy: 0.8800 - loss: 0.2417

Epoch 38/100

4/4 - 0s - 6ms/step - accuracy: 0.8800 - loss: 0.2398

Epoch 39/100

4/4 - 0s - 6ms/step - accuracy: 0.8750 - loss: 0.2363

Epoch 40/100

4/4 - 0s - 6ms/step - accuracy: 0.8750 - loss: 0.2349

Epoch 41/100

4/4 - 0s - 6ms/step - accuracy: 0.8750 - loss: 0.2327

Epoch 42/100

4/4 - 0s - 6ms/step - accuracy: 0.8850 - loss: 0.2293

Epoch 43/100

4/4 - 0s - 6ms/step - accuracy: 0.8950 - loss: 0.2272

Epoch 44/100

4/4 - 0s - 6ms/step - accuracy: 0.8950 - loss: 0.2254

Epoch 45/100

4/4 - 0s - 6ms/step - accuracy: 0.8900 - loss: 0.2241

Epoch 46/100

4/4 - 0s - 6ms/step - accuracy: 0.8950 - loss: 0.2207

Epoch 47/100

4/4 - 0s - 6ms/step - accuracy: 0.8950 - loss: 0.2191

Epoch 48/100

4/4 - 0s - 6ms/step - accuracy: 0.9000 - loss: 0.2172

Epoch 49/100

4/4 - 0s - 6ms/step - accuracy: 0.8950 - loss: 0.2157

Epoch 50/100

4/4 - 0s - 6ms/step - accuracy: 0.9000 - loss: 0.2130

Epoch 51/100

4/4 - 0s - 6ms/step - accuracy: 0.9050 - loss: 0.2108

Epoch 52/100

4/4 - 0s - 6ms/step - accuracy: 0.9050 - loss: 0.2099

Epoch 53/100

4/4 - 0s - 6ms/step - accuracy: 0.9000 - loss: 0.2069

Epoch 54/100

4/4 - 0s - 6ms/step - accuracy: 0.9050 - loss: 0.2067

Epoch 55/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.2037

Epoch 56/100

4/4 - 0s - 6ms/step - accuracy: 0.9050 - loss: 0.2034

Epoch 57/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.2029

Epoch 58/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.1989

Epoch 59/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.1976

Epoch 60/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.1963

Epoch 61/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.1962

Epoch 62/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.1936

Epoch 63/100

4/4 - 0s - 6ms/step - accuracy: 0.9050 - loss: 0.1932

Epoch 64/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.1916

Epoch 65/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.1904

Epoch 66/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.1875

Epoch 67/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.1870

Epoch 68/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.1881

Epoch 69/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.1846

Epoch 70/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.1837

Epoch 71/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.1811

Epoch 72/100

4/4 - 0s - 6ms/step - accuracy: 0.9050 - loss: 0.1808

Epoch 73/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.1787

Epoch 74/100

4/4 - 0s - 6ms/step - accuracy: 0.9000 - loss: 0.1801

Epoch 75/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.1761

Epoch 76/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.1738

Epoch 77/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.1738

Epoch 78/100

4/4 - 0s - 6ms/step - accuracy: 0.9050 - loss: 0.1729

Epoch 79/100

4/4 - 0s - 6ms/step - accuracy: 0.9200 - loss: 0.1704

Epoch 80/100

4/4 - 0s - 6ms/step - accuracy: 0.9150 - loss: 0.1704

Epoch 81/100

4/4 - 0s - 6ms/step - accuracy: 0.9100 - loss: 0.1704

Epoch 82/100

4/4 - 0s - 6ms/step - accuracy: 0.9200 - loss: 0.1667

Epoch 83/100

4/4 - 0s - 6ms/step - accuracy: 0.9200 - loss: 0.1647

Epoch 84/100

4/4 - 0s - 6ms/step - accuracy: 0.9250 - loss: 0.1632

Epoch 85/100

4/4 - 0s - 6ms/step - accuracy: 0.9200 - loss: 0.1621

Epoch 86/100

4/4 - 0s - 6ms/step - accuracy: 0.9200 - loss: 0.1618

Epoch 87/100

4/4 - 0s - 6ms/step - accuracy: 0.9250 - loss: 0.1622

Epoch 88/100

4/4 - 0s - 6ms/step - accuracy: 0.9200 - loss: 0.1580

Epoch 89/100

4/4 - 0s - 6ms/step - accuracy: 0.9300 - loss: 0.1568

Epoch 90/100

4/4 - 0s - 6ms/step - accuracy: 0.9200 - loss: 0.1548

Epoch 91/100

4/4 - 0s - 6ms/step - accuracy: 0.9200 - loss: 0.1549

Epoch 92/100

4/4 - 0s - 6ms/step - accuracy: 0.9300 - loss: 0.1553

Epoch 93/100

4/4 - 0s - 6ms/step - accuracy: 0.9300 - loss: 0.1506

Epoch 94/100

4/4 - 0s - 6ms/step - accuracy: 0.9300 - loss: 0.1501

Epoch 95/100

4/4 - 0s - 6ms/step - accuracy: 0.9300 - loss: 0.1494

Epoch 96/100

4/4 - 0s - 6ms/step - accuracy: 0.9350 - loss: 0.1496

Epoch 97/100

4/4 - 0s - 6ms/step - accuracy: 0.9350 - loss: 0.1462

Epoch 98/100

4/4 - 0s - 6ms/step - accuracy: 0.9350 - loss: 0.1440

Epoch 99/100

4/4 - 0s - 6ms/step - accuracy: 0.9300 - loss: 0.1439

Epoch 100/100

4/4 - 0s - 6ms/step - accuracy: 0.9300 - loss: 0.1423

score = model.evaluate(x, v, verbose=0)
print(f"score = {score[0]}")
print(f"accuracy = {score[1]}")

score = 0.13965898752212524
accuracy = 0.9350000023841858

Let’s look at a prediction. We need to feed in a single point as an array of shape (N, 2), where N is the number of points

res = model.predict(np.array([[-2, 2]]))
res

1/1 ━━━━━━━━━━━━━━━━━━━━ 0s 30ms/step


1/1 ━━━━━━━━━━━━━━━━━━━━ 0s 40ms/step

array([[6.0088795e-10]], dtype=float32)

We see that we get a floating point number. We will need to convert this to 0 or 1 by rounding.

Let’s plot the partitioning

M = 128
N = 128

xmin = -1.75
xmax = 2.5
ymin = -1.25
ymax = 1.75

xpt = np.linspace(xmin, xmax, M)
ypt = np.linspace(ymin, ymax, N)

To make the prediction go faster, we want to feed in a vector of these points, of the form:

[[xpt[0], ypt[0]],
 [xpt[1], ypt[1]],
 ...
]

We can see that this packs them into the vector

pairs = np.array(np.meshgrid(xpt, ypt)).T.reshape(-1, 2)
pairs[0]

array([-1.75, -1.25])

Now we do the prediction. We will get a vector out, which we reshape to match the original domain.

res = model.predict(pairs, verbose=0)
res.shape = (M, N)

Finally, round to 0 or 1

domain = np.where(res > 0.5, 1, 0)

and we can plot the data

fig, ax = plt.subplots()
ax.imshow(domain.T, origin="lower",
          extent=[xmin, xmax, ymin, ymax], alpha=0.25)
xpt = [q[0] for q in x]
ypt = [q[1] for q in x]

ax.scatter(xpt, ypt, s=40, c=v, cmap="viridis")

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