Trie fields make range queries faster by precomputing certain range results and storing them as a single record in the index. For clarity, my example will use integers in base ten. The same concept applies to all trie types. This includes dates, since a date can be represented as the number of seconds since, say, 1970.

Let's say we index the number `12345678`

. We can tokenize this into the following tokens.

```
12345678
123456xx
1234xxxx
12xxxxxx
```

The `12345678`

token represents the actual integer value. The tokens with the `x`

digits represent ranges. `123456xx`

represents the range `12345600`

to `12345699`

, and matches all the documents that contain a token in that range.

Notice how in each token on the list has successively more `x`

digits. This is controlled by the precision step. In my example, you could say that I was using a precision step of 2, since I trim 2 digits to create each extra token. If I were to use a precision step of 3, I would get these tokens.

```
12345678
12345xxx
12xxxxxx
```

A precision step of 4:

```
12345678
1234xxxx
```

A precision step of 1:

```
12345678
1234567x
123456xx
12345xxx
1234xxxx
123xxxxx
12xxxxxx
1xxxxxxx
```

It's easy to see how a smaller precision step results in more tokens and increases the size of the index. However, it also speeds up range queries.

Without the trie field, if I wanted to query a range from 1250 to 1275, Lucene would have to fetch 25 entries (`1250`

, `1251`

, `1252`

, ..., `1275`

) and combine search results. With a trie field (and precision step of 1), we could get away with fetching 8 entries (`125x`

, `126x`

, `1270`

, `1271`

, `1272`

, `1273`

, `1274`

, `1275`

), because `125x`

is a precomputed aggregation of `1250`

- `1259`

. If I were to use a precision step larger than 1, the query would go back to fetching all 25 individual entries.

**Note:** In reality, the precision step refers to the number of bits trimmed for each token. If you were to write your numbers in hexadecimal, a precision step of 4 would trim one hex digit for each token. A precision step of 8 would trim two hex digits.