### Your first segment of code defines a classifier on `1d`

data.

`X`

represents the feature vectors.

```
[0] is the feature vector of the first data example
[1] is the feature vector of the second data example
....
[[0],[1],[2],[3]] is a list of all data examples,
each example has only 1 feature.
```

`y`

represents the labels.

Below graph shows the idea:

- Green nodes are data with label 0
- Red nodes are data with label 1
- Grey nodes are data with unknown labels.

print(neigh.predict([[1.1]]))

This is asking the classifier to predict a label for `x=1.1`

.

```
print(neigh.predict_proba([[0.9]]))
```

This is asking the classifier to give membership probability estimate for each label.

Since both grey nodes located closer to the green, below outputs make sense.

```
[0] # green label
[[ 0.66666667 0.33333333]] # green label has greater probability
```

### The second segment of code actually has good instructions on `scikit-learn`

:

In the following example, we construct a NeighborsClassifier class from an array representing our data set and ask who’s the closest point to [1,1,1]

>>> samples = [[0., 0., 0.], [0., .5, 0.], [1., 1., .5]]
>>> from sklearn.neighbors import NearestNeighbors
>>> neigh = NearestNeighbors(n_neighbors=1)
>>> neigh.fit(samples)
NearestNeighbors(algorithm='auto', leaf_size=30, ...)
>>> print(neigh.kneighbors([1., 1., 1.]))
(array([[ 0.5]]), array([[2]]...))

There is no target value here because this is only a `NearestNeighbors`

class, it's not a classifier, hence no labels are needed.

### For your own problem:

Since you need a classifier, you should resort to `KNeighborsClassifier`

if you want to use `KNN`

approach. You might want to construct your feature vector `X`

and label `y`

as below:

```
X = [ [h1, e1, s1],
[h2, e2, s2],
...
]
y = [label1, label2, ..., ]
```