1) is quite easy:

```
want <- c("storesize", "sales_per_sqft", "sales_per_visits", "tothhsinta")
Kmeans(stores_standard[, want], 20, iter.max = 1000, nstart = 1,
method = c("euclidean"))
```

For 2)

```
## a 2-dimensional example from ?Kmeans
x <- rbind(matrix(rnorm(100, sd = 0.3), ncol = 2),
matrix(rnorm(100, mean = 1, sd = 0.3), ncol = 2))
colnames(x) <- c("x", "y")
cl <- Kmeans(x, 2)
```

Now look at `cl`

:

```
R> str(cl)
List of 4
$ cluster : int [1:100] 2 2 2 2 2 2 2 2 2 2 ...
$ centers : num [1:2, 1:2] 1.0245 -0.017 1.0346 0.0375
..- attr(*, "dimnames")=List of 2
.. ..$ : chr [1:2] "1" "2"
.. ..$ : chr [1:2] "x" "y"
$ withinss: num [1:2] 0.00847 0.22549
$ size : int [1:2] 50 50
- attr(*, "class")= chr "kmeans"
```

The `cluster`

component of the list contains the assigned cluster ID. These are in the same order as the samples in the input data. If you want to assign the `cluster`

component as a column in the input data we'd then do:

```
R> x <- cbind(x, Cluster = cl$cluster)
R> head(x)
x y Cluster
[1,] -0.24251497 0.532012889 2
[2,] 0.10957740 0.225168920 2
[3,] -0.35563544 -0.428798979 2
[4,] -0.41251306 0.529953489 2
[5,] -0.61212001 -0.003443993 2
[6,] 0.04435213 0.086595025 2
```

For your data do:

```
stores_standard <- cbind(stores_standard, Cluster = kmeans_object$cluster)
```

As for 3, that doesn't appear possible with `kmeans()`

in standard R nor `Kmeans()`

in package **amap**.

k-means is an iterative algorithm trying to optimise the partitioning of your objects intokclusters by minimising an objective function (say within cluster sums of squares). You can think of the objective function being a hilly landscape, for any point in the landscape (a single partition ofnsamples intokclusters) you have an altitude (the value of the objective function). Upon which, the`Kmeans()`

function always wants to walk downhill. If you only tell`Kmeans()`

how many clusters you want to find it starts from an random assignment of samples to clusters or... – Gavin Simpson Jul 19 '12 at 7:42ksamples to act as the current cluster centres.`Kmeans()`

then optimises that starting configuration/partition but it may get stuck in a little valley of the objective function landscape (can only walk downhill remember); this is alocal optimum. A much better solution may be just over a small rise, in the next valley; aglobaloptimum. Hence the solution to which the algorithm converges may be dependent upon the starting configuration.`nstart`

controls how many random initial configurations`Kmeans()`

will try out, returning the best of the`nstart`

runs. – Gavin Simpson Jul 19 '12 at 7:45`set.seed()`

you were probably finding lots of locally optimal but not globally optimal solutions to the clustering problem. That with several repeated runs with`nstart = 100`

anddifferent seeds youdoget the same configuration/solution indicates to me that you have found a global, consistent solution to the clustering problem you posed. Does that help? – Gavin Simpson Jul 19 '12 at 7:47