An easy workaround would be to use a 2D-`VectorPlot`

with a dummy variable like this:

```
VectorPlot[
{Cos[t], Sin[t]}, {t, 0, 2 \[Pi]}, {s, -1/2, 1/2},
AspectRatio -> Automatic,
VectorPoints -> {15, 3},
FrameLabel -> {"t", None}
]
```

Or what probably makes more sense is to discretize the curve that you get when you follow the vector while increasing `t`

. This is e.g. useful for Feynman-style Action-integrals in quantum mechanics.

```
Module[
{t, dt = 0.1, vectors, startpoints, startpoint, vector, spv, spvs},
vectors = Table[dt {Cos[t], Sin[t]}, {t, 0, 2 \[Pi], dt}];
startpoints = Accumulate[vectors];
spvs = Transpose[{startpoints, vectors}];
Graphics[Table[Arrow[{spv[[1]], spv[[1]] + spv[[2]]}], {spv, spvs}]]
]
```

onthe line? – Szabolcs Jan 4 '12 at 21:28