This is a common misunderstanding of vowpal wabbit.

*One cannot compare batch learning with online learning.*

vowpal wabbit is not a batch learner. It is an online learner. Online learners learn by looking at examples one at a time and *slightly* adjusting the weights of the model as they go.

There are advantages and disadvantages to online learning. The downside is that convergence to the final model is slow/gradual. The learner doesn't do a "perfect" job at extracting information from each example, because the process is iterative. Convergence on a final result is deliberately restrained/slow. This can make online learners appear weak on tiny data-sets like the above.

There are several upsides though:

- Online learners don't need to load the full data into memory (they work by examining one example at a time and adjusting the model based on the real-time observed per-example loss) so they can scale easily to billions of examples. A 2011 paper by 4 Yahoo! researchers describes how vowpal wabbit was used to learn from a tera (10^12) feature data-set in 1 hour on 1k nodes. Users regularly use
`vw`

to learn from billions of examples data-sets on their desktops and laptops.
- Online learning is adaptive and can track changes in conditions over time, so it can learn from non-stationary data, like learning against an adaptive adversary.
- Learning introspection: one can observe loss convergence rates while training and identify specific issues, and even gain significant insights from specific data-set examples or features.
- Online learners can learn in an incremental fashion so users can intermix labeled and unlabeled examples to keep learning while predicting at the same time.
- The estimated error, even during training, is always "out-of-sample" which is a good estimate of the test error. There's no need to split the data into train and test subsets or perform N-way cross-validation. The next (yet unseen) example is always used as a hold-out. This is a tremendous advantage over batch methods from the operational aspect. It greatly simplifies the typical machine-learning process. In addition, as long as you don't run multiple-passes over the data, it serves as a great over-fitting avoidance mechanism.

Online learners are very sensitive to example order. The worst possible order for an online learner is when classes are clustered together (all, or almost all, `-1`

s appear first, followed by all `1`

s) like the example above does. So the first thing to do to get better results from an online learner like vowpal wabbit, is to uniformly shuffle the `1`

s and `-1`

s (or simply order by time, as the examples typically appear in real-life).

OK now what?

*Q: Is there any way to produce a reasonable model in the sense that it gives reasonable predictions on small data when using an online learner?*

*A: Yes, there is!*

You can emulate what a batch learner does more closely, by taking two simple steps:

*Uniformly shuffle* `1`

and `-1`

examples.
- Run
*multiple passes* over the data to give the learner a chance to converge

Caveat: if you run multiple passes until error goes to 0, there's a danger of over-fitting. The online learner has perfectly learned your examples, but it may not generalize well to unseen data.

The second issue here is that the predictions `vw`

gives are not logistic-function transformed (this is unfortunate). They are akin to standard deviations from the middle point (truncated at [-50, 50]). You need to pipe the predictions via `utl/logistic`

(in the source tree) to get signed probabilities. Note that these signed probabilities are in the range [-1, +1] rather than [0, 1]. You may use `logistic -0`

instead of `logistic`

to map them to a [0, 1] range.

So given the above, here's a recipe that should give you more expected results:

```
# Train:
vw train.vw -c --passes 1000 -f model.vw --loss_function logistic --holdout_off
# Predict on train set (just as a sanity check) using the just generated model:
vw -t -i model.vw train.vw -p /dev/stdout | logistic | sort -tP -n -k 2
```

Giving this more expected result on your data-set:

```
-0.95674145247658 P1
-0.930208359811439 P2
-0.888329575506748 P3
-0.823617739247262 P4
-0.726830630992614 P5
-0.405323815830325 P6
0.0618902961794472 P7
0.298575998150221 P8
0.503468453150847 P9
0.663996516371277 P10
0.715480084449868 P11
0.780212725426778 P12
```

You could make the results more/less polarized (closer to `1`

on the older ages and closer to `-1`

on the younger) by increasing/decreasing the number of passes. You may also be interested in the following options for training:

```
--max_prediction <arg> sets the max prediction to <arg>
--min_prediction <arg> sets the min prediction to <arg>
-l <arg> set learning rate to <arg>
```

For example, by increasing the learning rate from the default `0.5`

to a large number (e.g. `10`

) you can force `vw`

to converge much faster when training on small data-sets thus requiring less passes to get there.

*Update*

As of mid 2014, `vw`

no longer requires the external `logistic`

utility to map predictions back to [0,1] range. A new `--link logistic`

option maps predictions to the logistic function [0, 1] range. Similarly `--link glf1`

maps predictions to a generalized logistic function [-1, 1] range.