6.20. model_grid.nml

This file sets up the grid configuration for the run. It contains seven namelists - JULES_INPUT_GRID, JULES_LATLON, JULES_LAND_FRAC, JULES_MODEL_GRID, JULES_NLSIZES, JULES_SURF_HGT and JULES_Z_LAND

Each run of JULES involves two grids: the input grid and the model grid. The input grid is the grid on which all input data are held. The model grid is the set of points on which the model is run. The model grid is the grid of points that will be processed by JULES, and is a subset of the input grid.

As discussed in General principles, the input grid consists of three pieces of information:

1. Whether the grid is 1D or 2D.

2. The size of each dimension.

3. The name of each dimension in the input file(s).

The latitude, longitude and land fraction of each point are then read in on the full input grid as specified by the namelists. A subset of the input grid to use as the model grid can then be specified in various ways described below (e.g. land points only, all points within certain latitude/longitude bounds).

In most cases, the model grid will be represented internally as a vector of points, even when the input grid is 2D. Numerically, this makes no difference. The only time that the model grid will be 2D is when the input grid is 2D, force_1d_grid = F and the model grid is a contiguous rectangular subsection of the input grid.

6.20.1. JULES_INPUT_GRID namelist members

Warning

The dimension names specified in this namelist will be used for all input files.

JULES_INPUT_GRID::grid_is_1d

Type:

logical

Default:

F

Indicates if the input grid is 1D or 2D.

TRUE

Variables have one grid dimension in the input file(s) - a points dimensions (e.g. a vector of land points with grid dimension “land”).

FALSE

Variables have two grid dimensions in the input file(s) - an x and a y dimension.

Only used when grid_is_1d = TRUE

JULES_INPUT_GRID::grid_dim_name

Type:

character

Default:

“land”

The name of the single grid dimension.

Note

For ASCII files, this can be anything. For NetCDF files, it should the name of the dimension in input file(s).

JULES_INPUT_GRID::npoints

Type:

integer

Permitted:

>= 1

Default:

0

The size of the single grid dimension.

Only used when grid_is_1d = FALSE

JULES_INPUT_GRID::x_dim_name

Type:

character

Default:

“x”

The name of the x dimension (it may, but does not have to, coincide with x_dim_name).

Note

For ASCII files, this can be anything. For NetCDF files, it should be the name of the dimension in the input file(s).

JULES_INPUT_GRID::y_dim_name

Type:

character

Default:

“y”

The name of the y dimension (it may, but does not have to, coincide with y_dim_name).

Note

For ASCII files, this can be anything. For NetCDF files, it should be the name of the dimension in the input file(s).

JULES_INPUT_GRID::nx

Type:

integer

Permitted:

>= 1

Default:

0

The size of the x dimension.

JULES_INPUT_GRID::ny

Type:

integer

Permitted:

>= 1

Default:

0

The size of the y dimension.

JULES_INPUT_GRID::time_dim_name

Type:

character

Default:

“time”

The name of the time dimension in any input files containing time varying data.

Note

For ASCII files, this can be anything. For NetCDF files, it should the name of the dimension in input file(s).

JULES_INPUT_GRID::pft_dim_name

Type:

character

Default:

“pft”

The dimension name used when variables have an additional dimension of size npft.

Note

For ASCII files, this can be anything. For NetCDF files, it should the name of the dimension in input file(s).

JULES_INPUT_GRID::cpft_dim_name

Type:

character

Default:

“cpft”

The dimension name used when variables have an additional dimension of size ncpft.

Note

For ASCII files, this can be anything. For NetCDF files, it should the name of the dimension in input file(s).

JULES_INPUT_GRID::nvg_dim_name

Type:

character

Default:

“nvg”

The dimension name used when variables have an additional dimension of size nnvg.

Note

For ASCII files, this can be anything. For NetCDF files, it should the name of the dimension in input file(s).

JULES_INPUT_GRID::type_dim_name

Type:

character

Default:

“type”

The dimension name used when variables have an additional dimension of size ntype.

Note

For ASCII files, this can be anything. For NetCDF files, it should the name of the dimension in input file(s).

JULES_INPUT_GRID::tile_dim_name

Type:

character

Default:

“tile”

The dimension name used when variables have an additional dimension of size nsurft.

Note

For ASCII files, this can be anything. For NetCDF files, it should the name of the dimension in input file(s).

JULES_INPUT_GRID::soil_dim_name

Type:

character

Default:

“soil”

The dimension name used when variables have an additional dimension of size sm_levels.

Note

For ASCII files, this can be anything. For NetCDF files, it should the name of the dimension in input file(s).

JULES_INPUT_GRID::snow_dim_name

Type:

character

Default:

“snow”

The dimension name used when variables have an additional dimension of size nsmax.

Note

For ASCII files, this can be anything. For NetCDF files, it should the name of the dimension in input file(s).

JULES_INPUT_GRID::sclayer_dim_name

Type:

character

Default:

“sclayer”

The dimension name used for the soil biogeochemistry when layered soil is used i.e. l_layeredc = TRUE. When l_layeredc = TRUE the soil biogeochemistry has the same number of layers as the soil hydrology (sm_levels). When l_layeredc = FALSE the soil biogeochemistry represents a single bulk layer. Despite the similar name, this parameter is unrelated to dim_cslayer.

Note

For ASCII files, this can be anything. For NetCDF files, it should the name of the dimension in input file(s).

JULES_INPUT_GRID::scpool_dim_name

Type:

character

Default:

“scpool”

The dimension name used when variables have an additional dimension of size dim_cs1.

Note

For ASCII files, this can be anything. For NetCDF files, it should the name of the dimension in input file(s).

JULES_INPUT_GRID::bedrock_dim_name

Type:

character

Default:

“bedrock”

The dimension name used when variables have an additional dimension of size ns_deep.

Note

For ASCII files, this can be anything. For NetCDF files, it should the name of the dimension in input file(s).

JULES_INPUT_GRID::tracer_dim_name

Type:

character

Default:

“tracer”

The dimension name used when variables have an additional dimension of size ndry_dep_species (e.g. chemical tracers in the atmosphere).

Note

For ASCII files, this can be anything. For NetCDF files, it should the name of the dimension in input file(s).

JULES_INPUT_GRID::bl_level_dim_name

Type:

character

Default:

“bllevel”

The dimension name used when variables have an additional dimension of size bl_levels (e.g. variables on atmospheric boundary layer levels).

Note

For ASCII files, this can be anything. For NetCDF files, it should the name of the dimension in input file(s).

6.20.2. JULES_LATLON namelist members

Members used to determine how gridpoint location variables are set

JULES_LATLON::read_from_dump

Type:

logical

Default:

F

TRUE

Populate variables associated with this namelist from the dump file. All other namelist members are ignored.

FALSE

Use the other namelist members to determine how to populate variables.

JULES_LATLON::l_coord_latlon

Type:

logical

Default:

F

TRUE

The coordinate system used for the model grid is latitude and longitude.

FALSE

The model grid is defined by projection coordinates other than latitude and longitude (e.g. northings and eastings, or a rotated grid).

JULES_LATLON::nvars

Type:

integer

Permitted:

>= 2

Default:

0

The number of location variables that will be provided (see List of grid location properties).

JULES_LATLON::var

Type:

character(nvars)

Default:

None

List of location variable names as recognised by JULES (see List of grid location properties). Names are case sensitive.

Note

For ASCII files, variable names must be in the order they appear in the file.

JULES_LATLON::use_file

Type:

logical(nvars)

Default:

T

For each JULES variable specified in var, this indicates if it should be read from the specified file or whether a constant value is to be used.

TRUE

The variable will be read from the file.

FALSE

The variable will be set to a constant value everywhere using const_val below.

JULES_LATLON::var_name

Type:

character(nvars)

Default:

‘’ (empty string)

For each JULES variable specified in var where use_file = TRUE, this is the name of the variable in the file containing the data.

If the empty string (the default) is given for any variable, then the corresponding value from var is used instead.

This is not used for variables where use_file = FALSE, but a placeholder must still be given in that case.

Note

For ASCII files, this is not used - only the order in the file matters, as described above.

JULES_LATLON::tpl_name

Type:

character(nvars)

Default:

None

For each JULES variable specified in var, this is the string to substitute into the file name in place of the variable name substitution string.

If the file name does not use variable name templating, this is not used.

JULES_LATLON::const_val

Type:

real(nvars)

Default:

None

For each JULES variable specified in var where use_file = FALSE, this is a constant value that the variable will be set to at every point.

This is not used for variables where use_file = TRUE, but a placeholder must still be given in that case.

JULES_LATLON::file

Type:

character

Default:

None

The file to read ancillary properties from.

If use_file is FALSE for every variable, this will not be used.

This file name can use variable name templating.

6.20.2.1. List of grid location properties

The following table summarises ancillary fields that give the location and related characteristics of each point on the grid, specified from an ancillary file if use_file = TRUE.

Name	Description
latitude	Latitude of each point. Always required.
longitude	Longitude of each point. Always required. Values in the range -180 to 360 are allowed.
projection_x_coord	Values of the projection coordinate in the x direction. This is only required if l_coord_latlon = FALSE. Note that these can have any valid unit.
projection_y_coord	Values of the projection coordinate in the y direction. This is only required if l_coord_latlon = FALSE. Note that these can have any valid unit.
grid_area	The area of each gridbox (m:sup`2`) This is only requred if irrigation is being modelled with l_water_resources = TRUE and l_water_irrigation = TRUE.

Examples of how to specify the model domain using through this namelist are provided at the end of this section.

6.20.3. JULES_LAND_FRAC namelist members

Land fraction is the fraction of each gridbox that is land. Currently, JULES considers any gridbox with land fraction > 0 to be 100% land, and all others to be 100% sea (or sea-ice). Land fraction data can be used to select only land points from the full input grid (see below).

Warning

When the input grid consists of a single location (1D and npoints = 1 or 2D and nx = ny = 1), that single location is assumed to be 100% land.

For any input grid with more than a single location, the following are used:

JULES_LAND_FRAC::file

Type:

character

Default:

None

The name of the file to read land fraction data from.

JULES_LAND_FRAC::land_frac_name

Type:

character

Default:

‘land_fraction’

The name of the variable containing the land fraction data.

In the file, the variable must have no levels dimensions and no time dimension.

6.20.4. JULES_MODEL_GRID namelist members

Members of this namelist are used to select the points to be modelled from the input grid. This can be done in various ways (see the Examples of grid setups).

JULES_MODEL_GRID::land_only

Type:

logical

Default:

T

TRUE

Model land points only (from the points that are selected with other options).

FALSE

Model all selected points.

If use_subgrid = FALSE (see below), the land points will be extracted from the full input grid.

If use_subgrid = TRUE, then the subgrid extraction takes place first, and the land points will be extracted from the specified subgrid.

JULES_MODEL_GRID::force_1d_grid

Type:

logical

Default:

F

TRUE

Force the model grid to be 1D, even if it would otherwise have been 2D.

FALSE

The model grid takes its default shape.

JULES_MODEL_GRID::use_subgrid

Type:

logical

Default:

F

TRUE

The model grid is a subset of the full input grid, specified using some valid combination of the options below.

FALSE

The model grid is the full input grid.

Only used if use_subgrid = TRUE

JULES_MODEL_GRID::l_bounds

Type:

logical

Default:

None

TRUE

Subset of points to model will be selected using bounds for the coordinates variables.

FALSE

Subset of points to model will be selected using a list of coordinate pairs for each point.

If l_coord_latlon = TRUE, the coordinates used here are latitude and longitude.

If l_coord_latlon = FALSE, the coordinates used here are the values stored in the variables projection_x_coord and projection_y_coord.

Only used if l_bounds = TRUE

JULES_MODEL_GRID::y_bounds

Type:

real(2)

Default:

None

The lower and upper bounds (in that order) for the y coordinate used to select points. Assuming that the coordinate is latitude (see l_coord_latlon) the model grid will comprise the points where y_bounds(1) <= latitude <= y_bounds(2).

JULES_MODEL_GRID::x_bounds

Type:

real(2)

Default:

None

The lower and upper bounds (in that order) for the x coordinate used to select points. Assuming that the coordinate is longitude (see l_coord_latlon) the model grid will comprise the points where x_bounds(1) <= longitude <= x_bounds(2).

If the x coordinate is longitude, the values of x_bounds should lie in the range [-180, 360]. A special case is that in which the desired subgrid straddles the edge of a global input grid. For example, if the input grid has longitudes in [0, 360] and a domain of 20 degrees of longitude centred on 0degE is required, this should be indicated using xbounds=-10,10 (not xbounds=360,370 because values > 360 are not recognised). In this case the JULES code recognises the cyclic nature of longitude and correctly picks up points in both hemispheres, even though -10degE is outwith the longitude values in the input grid.

Only used if l_bounds = FALSE

JULES_MODEL_GRID::npoints

Type:

integer

Permitted:

>= 1

Default:

0

The number of points to model.

JULES_MODEL_GRID::points_file

Type:

character

Default:

None

The name of the file containing the coordinates for each point.

If l_coord_latlon = TRUE, the coordinates used here are latitude and longitude. Each line in the file should contain the latitude and longitude (in that order) for a point.

If l_coord_latlon = FALSE, the coordinates used here are the values stored in the variables projection_x_coord and projection_y_coord. Each line in the file should contain the value for projection_y_coord and projection_x_coord (in that order; note this is y then x) for a point.

An error is raised and the run terminates if any coordinate pair does not match to a location in the input grid.

6.20.5. JULES_NLSIZES namelist members

This namelist is used to set the number of levels in the boundary layer.

JULES_NLSIZES::bl_levels

Type:

integer

Default:

1

Number of boundary layer levels. This is only used if atmospheric deposition is selected (l_deposition = TRUE) in which case it is used to set the size of input fields.

6.20.6. JULES_SURF_HGT namelist members

This namelist sets the elevation of each surface tile. Elevations can either be relative to the gridbox mean or have constant elevation bands above sea-level.

If tile elevations are set relative to the gridbox mean, then the gridbox mean elevation is not required. The gridbox mean elevation is implicit in the near-surface meteorological data that are provided (higher locations will tend to be colder, have lower pressure, etc.). The elevation of each tile is used to alter the values of the air temperature and humidity (and possibly downwelling longwave, see l_elev_lw_down) over that tile relative to the surface.

If any tile uses absolute heights (i.e. l_elev_absolute_height has at least one element that is .true.), then the gridbox mean elevation must also be supplied. This is read in from the optional JULES_Z_LAND namelist which is described below. The model calculates elevations relative to the gridbox mean by taking the difference between the absolute elevation and the gridbox mean.

If any tile uses absolute heights, then tile heights are set constant across a domain, regardless of whether each tile’s height is specified as a relative offset or absolute. This makes it simple to set zero-offset heights for tiles that should not be considered in the elevation bands. It is no longer possible to have spatially varying tile heights if this option is used.

JULES_SURF_HGT::zero_height

Type:

logical

Default:

T

Switch used to simplify the initialisation of tile elevation.

Note

If l_aggregate = TRUE, this switch is also set to TRUE.

TRUE

Set all surface tile elevations to zero. This is a very common configuration.

FALSE

Set surface tile heights using specified data.

Only used if zero_height = FALSE

JULES_SURF_HGT::l_elev_absolute_height

Type:

logical(nsurft)

Default:

F

TRUE

Heights of surface tiles are absolute values above sea-level. If this option is used, then the elevation of the forcing data must also be provided (see JULES_Z_LAND namelist below).

FALSE

Surface tile heights are relative to the gridbox mean.

JULES_SURF_HGT::use_file

Type:

logical

Default:

T

This indicates if surface tile heights relative to the gridbox mean should be read from a specified file or namelist.

TRUE

The variable will be read from a file if the input grid consists of more than location.

FALSE

The variable will be read from a namelist if the input grid is for a single location.

Only used if use_file = TRUE

JULES_SURF_HGT::file

Type:

character

Default:

None

The name of the file containing surface tile heights relative to the gridbox mean.

JULES_SURF_HGT::surf_hgt_name

Type:

character

Default:

‘surf_hgt’

The name of the variable containing surface tile heights relative to the gridbox mean. In the file, the variable must have a single levels dimension of size nsurft called tile_dim_name.

Only used if use_file = FALSE

JULES_SURF_HGT::surf_hgt_io

Type:

real(nsurft)

Default:

None

Surface tile heights relative to the gridbox mean for a single location.

6.20.7. JULES_Z_LAND namelist members

This is an optional namelist and only used if any surface tile has l_elev_absolute_height = TRUE. The namelist sets values for the elevation bands and reads the elevation of the forcing data.

JULES_Z_LAND::surf_hgt_band

Type:

real(nsurft)

Default:

None

Spatially invariant elevation bands for each surface tile. These may be relative to the gridbox mean or absolute elevations above sea-level depending on l_elev_absolute_height.

JULES_Z_LAND::use_file

Type:

logical

Default:

T

This indicates if the elevation of the forcing data should be read from a file or from a namelist.

TRUE

The variable will be read from a file if the input grid consists of more than location.

FALSE

The variable will be read from a namelist if the input grid is for a single location.

Used if use_file = TRUE

JULES_Z_LAND::file

Type:

character

Default:

None

The name of the file containing the elevation of the forcing data.

JULES_Z_LAND::z_land_name

Type:

character

Default:

‘z_land’

The name of the variable containing the elevation of the forcing data. In the file, the variable must have no level dimensions and no time dimensions.

Used if use_file = FALSE

JULES_Z_LAND::z_land_io

Type:

real

Default:

None

Elevation of the forcing data for a single location.

6.20.7.1. Example

The following gives an example of how you would set up the namelists to use elevation bands above sea-level.

&JULES_SURF_HGT

  zero_height            = .false.,

  # No elevation correction to surface tiles 1 to 6, use elevation bands for surface tiles 7 to 9
  l_elev_absolute_height = 6*.false., 3*.true.,

/

&JULES_Z_LAND

  # Set values for the elevation bands.
  surf_hgt_band          = 6*0.0, 1000.0, 2000.0, 3000.0,

  # Read the WFDEI forcing data elevation from a file
  use_file               = .true.,
  file                   = 'WFDEI-elevation.nc',
  z_land_name            = 'elevation'

/

6.20.8. Examples of grid setups

6.20.8.1. A single location

&JULES_INPUT_GRID
  nx = 1,
  ny = 1
/

&JULES_LATLON
  l_coord_latlon = T
  nvars     = 2,
  var       = 'latitude','longitude',
  use_file  = .false., .false.,
  const_val = 52.168, 5.744
/

&JULES_LAND_FRAC /

&JULES_MODEL_GRID /

&JULES_SURF_HGT
  zero_height = T
/

JULES_INPUT_GRID

The default value of grid_is_1d, FALSE, is used. This means the user has to specify the extents, nx and ny, of the input grid. Since all the input data is ASCII, no dimension names are required.

JULES_LATLON

The latitude and longitude of the single location are specified directly in the namelist. nvars = 2 indicates that the two mandatory variables will be provided, and var = ‘latitude’,’longitude’ confirms that these are the latitude and longitude. use_file = .false. indicates that the values will be read from the namelist (not from another file) and the values are provided after const_val.

JULES_LAND_FRAC

The land fraction at the single location is assumed to be 100%, so nothing is required.

JULES_MODEL_GRID

Use default options to select the model grid (i.e. land points only from the full input grid). In this case, this leaves the single location as the model grid.

6.20.8.2. Examples of gridded runs

All the examples in this section assume gridded NetCDF data.

6.20.8.2.1. Specifying a 1D input grid

In this example, input files contain data on a vector of land points. The land points dimension is called “land”. The time dimension for time-varying variables is called “time”. The default dimension names are used for all additional dimensions (e.g. pft, tile).

&JULES_INPUT_GRID
  grid_is_1D = T,

  npoints = 15238,
  grid_dim_name = "land",

  time_dim_name = "time"
/

6.20.8.2.2. Specifying a 2D input grid

In this example, input files contain data on a 2D latitude/longitude grid. The x dimension is called “lon” and the y dimension is called “lat”. The time dimension for time-varying variables is called “time”. Variables with an extra tiles dimension use the dimension name “pseudo” for that dimension. All other additional dimensions use their default names.

&JULES_INPUT_GRID
  grid_is_1D = F,

  nx = 96,
  ny = 56,

  x_dim_name = "lon",
  y_dim_name = "lat",

  tile_dim_name = "pseudo",

  time_dim_name = "time"
/

6.20.8.2.3. Specifying a subgrid using a given range of latitude and longitude

This can be used with either a 1D or 2D input grid.

&JULES_LATLON
  l_coord_latlon = T,
  nvars     = 2,
  var       = 'latitude','longitude',
  use_file  = .true., .true.,
  file      = 'lat_lon.nc',
/

&JULES_LAND_FRAC
  file = 'land_mask.nc',

  land_frac_name = 'land_frac'
/

&JULES_MODEL_GRID
  land_only = F,

  use_subgrid = T,

  l_bounds = T,

  y_bounds = 55.0  57.0,
  x_bounds = -5.0  -3.0
/

This setup reads latitude, longitude and land fraction for each gridbox in the full input grid (1D or 2D) from the named variables in the specified files.

In JULES_MODEL_GRID, use_subgrid indicates that a subset of the input grid will be selected as the model grid. l_bounds then indicates that latitude and longitude bounds will be used to select the subgrid. land_only = FALSE means that sea and sea-ice points will remain in the model grid if any are selected. The model grid will then be a vector containing the selected points (those that fall within the latitude/longitude bounds), even if those points could be used to form a rectangular region.

6.20.8.2.4. Specifying a subgrid using a given range of projection coordinates (not latitude and longitude)

This can be used with either a 1D or 2D input grid.

&JULES_LATLON
  l_coord_latlon = F,
  nvars     = 4,
  var       = 'latitude','longitude','projection_x_coord','projection_y_coord'
  use_file  = .true., .true., .true., .true.,
  file      = 'lat_lon.nc',
/

&JULES_LAND_FRAC
  file = 'land_mask.nc',

  land_frac_name = 'land_frac'
/

&JULES_MODEL_GRID
  land_only = F,

  use_subgrid = T,

  l_bounds = T,

  y_bounds = 500.0  40500.0,
  x_bounds = 25500.0 55500.0
/

In this setup l_coord_latlon = FALSE indicates that data will be read from a grid that is not defined by latitude and longitude - rather it uses other projection coordinates such as the northings and eastings of the Ordnance Survey (British) National Grid (BNG) OSGB36. The projection coordinates are read via the variables projection_x_coord and projection_y_coord. Note that the latitude and longitude of each point is also read in; JULES includes these in output files for reference, and they can also be required by the science code (e.g. for solar zenith angle).

In JULES_MODEL_GRID, use_subgrid indicates that a subset of the input grid will be selected as the model grid. l_bounds then indicates that bounding values of the projection coordinates will be used to select the subgrid. land_only = FALSE means that sea and sea-ice points will remain in the model grid if any are selected. The model grid will then be a vector containing the selected points (those that fall within the latitude/longitude bounds), even if those points could be used to form a rectangular region.

6.20.8.2.5. Specifying a subgrid using a list of points

This can be used with either a 1D or 2D input grid.

&JULES_LATLON
  l_coord_latlon = T,
  nvars     = 2,
  var       = 'latitude','longitude',
  use_file  = .true., .true.,
  file      = 'lat_lon.nc',
/

&JULES_LAND_FRAC
  file = 'land_mask.nc',

  land_frac_name = 'land_frac'
/

&JULES_MODEL_GRID
  use_subgrid = T,

  l_bounds = F,

  npoints = 4,
  points_file = 'points.txt'
/

This setup reads latitude, longitude and land fraction for each gridbox in the full input grid (1D or 2D) from the named variables in the specified files.

In JULES_MODEL_GRID, use_subgrid indicates that a subset of the input grid will be selected as the model grid. l_bounds then indicates that a list of latitudes and longitudes will be used to select the subgrid. land_only is not given, meaning it takes its default value, TRUE. This means that any sea or sea-ice points specified in the list of points will be discarded. The model grid will then be a vector containing the selected points (those with the given latitude/longitude).

Assuming that the input grid is a 1 degree grid and the latitude and longitude are given at the centre of the gridbox, points.txt should look like the following:

55.5  -4.5
55.5  -3.5
56.5  -4.5
56.5  -3.5

6.20.8.2.6. The only configuration that yields a 2D model grid

&JULES_INPUT_GRID
  grid_is_1d = F,

  nx = 96,
  ny = 56,

  # ...
/

&JULES_LATLON
  # <specified from file>
/

&JULES_LAND_FRAC
  # <specified from file>
/

&JULES_MODEL_GRID
  land_only = F
/

In general, the only configuration that yields a 2D model grid is:

• 2D input grid

• The model grid is the full input grid, including any non-land points

If the input grid is a 2D region where every point is land (i.e. not the whole globe), then land_only = TRUE would also yield a 2D model grid. If any options are set that mean some points from the input grid are not modeled, the model grid will be a vector of points. Computationally, this makes no difference.