The nearest neighbour code in Iris, sadly, currently loads the data to identify the indexes needed. I've submitted a trivial pull request (made complex by testing) to fix this (https://github.com/SciTools/iris/pull/707) which you could try using to work with this sized dataset.

I'm going to work with a cube from the sample data:

```
import iris
cube = iris.load_cube(iris.sample_data_path('air_temp.pp'))
```

And I can check whether there is data loaded with the following function:

```
def cube_data_is_loaded(cube):
# A None data manger means the data is loaded...
return cube._data_manager is None
```

So:

```
>>> print cube_data_is_loaded(cube)
False
```

Basically, the interface (http://scitools.org.uk/iris/docs/latest/iris/iris/analysis/interpolate.html#iris.analysis.interpolate.extract_nearest_neighbour) for nearest neighbour allows you to do a point extraction:

```
from iris.analysis.interpolate import extract_nearest_neighbour
smaller_cube = extract_nearest_neighbour(cube,
(('longitude', -180), ('latitude', 1.5)))
>>> print smaller_cube
air_temperature / (K) (scalar cube)
Scalar coordinates:
forecast_period: 6477 hours
forecast_reference_time: 1998-03-01 03:00:00
latitude: 2.50002 degrees
longitude: 180.0 degrees
pressure: 1000.0 hPa
time: 1996-12-01 00:00:00
Attributes:
STASH: m01s16i203
source: Data from Met Office Unified Model
Cell methods:
mean: time
```

Notice how the extraction has actually picked the nearest latitude value to my requested point. One thing that is really important is to note that this function really doesn't handle wrapping if your longitude coordinate is not circular:

```
cube.coord('longitude').circular = False
smaller_cube = extract_nearest_neighbour(cube,
(('longitude', -180), ('latitude', 1.5)))
cube.coord('longitude').circular = True
>>> print smaller_cube
air_temperature / (K) (scalar cube)
Scalar coordinates:
forecast_period: 6477 hours
forecast_reference_time: 1998-03-01 03:00:00
latitude: 2.50002 degrees
longitude: 0.0 degrees
pressure: 1000.0 hPa
time: 1996-12-01 00:00:00, bound=(1994-12-01 00:00:00, 1998-12-01 00:00:00)
Attributes:
STASH: m01s16i203
source: Data from Met Office Unified Model
Cell methods:
mean: time
```

Notice how the longitude range in the original cube (0-360) now means that the nearest value to -180 is actually 0.

There is also a function to do a trajectory extraction (http://scitools.org.uk/iris/docs/latest/iris/iris/analysis/trajectory.html?highlight=trajectory#iris.analysis.trajectory.interpolate):

```
smaller_traj = interpolate(cube,
(('longitude', [-180, -180]), ('latitude', [1.5, 3.5])),
'nearest')
>>> print smaller_traj
air_temperature / (K) (*ANONYMOUS*: 2)
Auxiliary coordinates:
latitude x
longitude x
Scalar coordinates:
forecast_period: 6477 hours
forecast_reference_time: 1998-03-01 03:00:00
pressure: 1000.0 hPa
time: 1996-12-01 00:00:00, bound=(1994-12-01 00:00:00, 1998-12-01 00:00:00)
Attributes:
STASH: m01s16i203
source: Data from Met Office Unified Model
Cell methods:
mean: time
```

Finally, notice how the original cube's data has not been loaded throughout (using my branch), and indeed, the data from smaller_cube has also been deferred:

```
>>> print cube_data_is_loaded(cube)
False
>>> print cube_data_is_loaded(smaller_cube)
False
```

For the trajectory, in general, deferred loading is not possible, but it is worth noting that when using NetCDF the indices are being passed right through to the underlying NetCDF library so that at no point is the entire array in memory.

HTH!

P.S. I'm not aware of any spline interpolation algorithms which work with Iris yet, though there *is* a similar interface to do linear interpolation, should that be of interest.