Refraction functions. More...

#include "agenda_class.h"
#include "arts.h"
#include "matpackIV.h"

Functions
void	get_refr_index_1d (Workspace &ws, Numeric &refr_index, Numeric &a_pressure, Numeric &a_temperature, Vector &a_vmr_list, const Agenda &refr_index_agenda, ConstVectorView p_grid, const Numeric &r_geoid, ConstVectorView z_field, ConstVectorView t_field, ConstMatrixView vmr_field, const Numeric &r)
	get_refr_index_1d More...

void	get_refr_index_2d (Workspace &ws, Numeric &refr_index, Numeric &a_pressure, Numeric &a_temperature, Vector &a_vmr_list, const Agenda &refr_index_agenda, ConstVectorView p_grid, ConstVectorView lat_grid, ConstVectorView r_geoid, ConstMatrixView z_field, ConstMatrixView t_field, ConstTensor3View vmr_field, const Numeric &r, const Numeric &lat)
	get_refr_index_2d More...

void	get_refr_index_3d (Workspace &ws, Numeric &refr_index, Numeric &a_pressure, Numeric &a_temperature, Vector &a_vmr_list, const Agenda &refr_index_agenda, ConstVectorView p_grid, ConstVectorView lat_grid, ConstVectorView lon_grid, ConstMatrixView r_geoid, ConstTensor3View z_field, ConstTensor3View t_field, ConstTensor4View vmr_field, const Numeric &r, const Numeric &lat, const Numeric &lon)

void	refr_gradients_1d (Workspace &ws, Numeric &refr_index, Numeric &dndr, Numeric &a_pressure, Numeric &a_temperature, Vector &a_vmr_list, const Agenda &refr_index_agenda, ConstVectorView p_grid, const Numeric &r_geoid, ConstVectorView z_field, ConstVectorView t_field, ConstMatrixView vmr_field, const Numeric &r)
	refr_gradients_1d More...

void	refr_gradients_2d (Workspace &ws, Numeric &refr_index, Numeric &dndr, Numeric &dndlat, Numeric &a_pressure, Numeric &a_temperature, Vector &a_vmr_list, const Agenda &refr_index_agenda, ConstVectorView p_grid, ConstVectorView lat_grid, ConstVectorView r_geoid, ConstMatrixView z_field, ConstMatrixView t_field, ConstTensor3View vmr_field, const Numeric &r, const Numeric &lat)
	refr_gradients_2d More...

void	refr_gradients_3d (Workspace &ws, Numeric &refr_index, Numeric &dndr, Numeric &dndlat, Numeric &dndlon, Numeric &a_pressure, Numeric &a_temperature, Vector &a_vmr_list, const Agenda &refr_index_agenda, ConstVectorView p_grid, ConstVectorView lat_grid, ConstVectorView lon_grid, ConstMatrixView r_geoid, ConstTensor3View z_field, ConstTensor3View t_field, ConstTensor4View vmr_field, const Numeric &r, const Numeric &lat, const Numeric &lon)
	refr_gradients_3d More...

void	refr_index_thayer_1974 (Numeric &refr_index, const Numeric &p, const Numeric &t, const Numeric &h2o_vmr)
	refr_index_thayer_1974 More...

void	refr_index_ir (Numeric &refr_index, const Numeric &p, const Numeric &t)
	refr_index_ir More...

Detailed Description

Refraction functions.

Author: Patrick Eriksson Patri.nosp@m.ck.E.nosp@m.rikss.nosp@m.on@r.nosp@m.ss.ch.nosp@m.alme.nosp@m.rs.se

Date: 2003-01-17

This file contains the definition of the functions in refraction.cc.

Definition in file refraction.h.

Function Documentation

◆ get_refr_index_1d()

void get_refr_index_1d	(	Workspace &	ws,
		Numeric &	refr_index,
		Numeric &	a_pressure,
		Numeric &	a_temperature,
		Vector &	a_vmr_list,
		const Agenda &	refr_index_agenda,
		ConstVectorView	p_grid,
		const Numeric &	r_geoid,
		ConstVectorView	z_field,
		ConstVectorView	t_field,
		ConstMatrixView	vmr_field,
		const Numeric &	r
	)

get_refr_index_1d

Extracts the refractive index for 1D cases.

The function interpolates the atmospheric pressure and fields, and calls refr_index_agenda to determine the refractive index for the given point.

The atmosphere is given by its 1D view. That is, the latitude and longitude dimensions are removed from the atmospheric fields. For example, the temperature is given as a vector (the vertical profile).

Parameters

ws	Current Workspace
refr_index	Output: As the WSV with the same name.
a_pressure	Pressure in hPa.
a_temperature	Temperature in K.
a_vmr_list	Vector with VMR values.
refr_index_agenda	As the WSV with the same name.
p_grid	As the WSV with the same name.
r_geoid	As the WSV with the same name.
z_field	The geometric altitude of each pressure level
t_field	The temperature profile.
vmr_field	The VMR profile for each species.
r	The radius of the position of interest.

Author: Patrick Eriksson

Date: 2003-01-16

Definition at line 82 of file refraction.cc.

References gridpos(), interp(), interpweights(), itw2p(), joker, ConstMatrixView::nrows(), ns, refr_index_agendaExecute(), and Vector::resize().

Referenced by ppath_step_refr_1d(), raytrace_1d_linear_euler(), refr_gradients_1d(), and VectorZtanToZaRefr1D().

◆ get_refr_index_2d()

void get_refr_index_2d	(	Workspace &	ws,
		Numeric &	refr_index,
		Numeric &	a_pressure,
		Numeric &	a_temperature,
		Vector &	a_vmr_list,
		const Agenda &	refr_index_agenda,
		ConstVectorView	p_grid,
		ConstVectorView	lat_grid,
		ConstVectorView	r_geoid,
		ConstMatrixView	z_field,
		ConstMatrixView	t_field,
		ConstTensor3View	vmr_field,
		const Numeric &	r,
		const Numeric &	lat
	)

get_refr_index_2d

Extracts the refractive index for 2D cases.

The function interpolates the atmospheric pressure and fields, and calls refr_index_agenda to determine the refractive index for the given point.

The atmosphere is given by its 2D view. That is, the longitude dimension is removed from the atmospheric fields. For example, the temperature is given as a matrix.

Parameters

ws	Current Workspace
refr_index	Output: As the WSV with the same name.
a_pressure	Pressure in hPa.
a_temperature	Temperature in K.
a_vmr_list	Vector with VMR values.
refr_index_agenda	As the WSV with the same name.
p_grid	As the WSV with the same name.
lat_grid	As the WSV with the same name.
r_geoid	As the WSV with the same name.
z_field	The geometric altitude of each pressure level at each latitude.
t_field	The temperature 2D field.
vmr_field	The VMR 2D field for each species.
r	The radius of the position of interest.
lat	The latitude of the position of interest.

Author: Patrick Eriksson

Date: 2003-01-14

Definition at line 162 of file refraction.cc.

References gridpos(), interp(), interpweights(), itw2p(), joker, ConstVectorView::nelem(), ConstTensor3View::npages(), ns, refr_index_agendaExecute(), Vector::resize(), Matrix::resize(), and z_at_lat_2d().

Referenced by refr_gradients_2d().

◆ get_refr_index_3d()

void get_refr_index_3d	(	Workspace &	ws,
		Numeric &	refr_index,
		Numeric &	a_pressure,
		Numeric &	a_temperature,
		Vector &	a_vmr_list,
		const Agenda &	refr_index_agenda,
		ConstVectorView	p_grid,
		ConstVectorView	lat_grid,
		ConstVectorView	lon_grid,
		ConstMatrixView	r_geoid,
		ConstTensor3View	z_field,
		ConstTensor3View	t_field,
		ConstTensor4View	vmr_field,
		const Numeric &	r,
		const Numeric &	lat,
		const Numeric &	lon
	)

get_refr_index_3d

Extracts the refractive index for 3D cases.

The function interpolates the atmospheric pressure and fields, and calls refr_index_agenda to determine the refractive index for the given point.

Parameters

ws	Current Workspace
refr_index	Output: As the WSV with the same name.
a_pressure	Pressure in hPa.
a_temperature	Temperature in K.
a_vmr_list	Vector with VMR values.
refr_index_agenda	As the WSV with the same name.
p_grid	As the WSV with the same name.
lat_grid	As the WSV with the same name.
lon_grid	As the WSV with the same name.
r_geoid	As the WSV with the same name.
z_field	As the WSV with the same name.
t_field	As the WSV with the same name.
vmr_field	As the WSV with the same name.
r	The radius of the position of interest.
lat	The latitude of the position of interest.
lon	The longitude of the position of interest.

Author: Patrick Eriksson

Date: 2003-01-17

Definition at line 256 of file refraction.cc.

References gridpos(), interp(), interpweights(), itw2p(), joker, ConstTensor4View::nbooks(), ConstVectorView::nelem(), ns, refr_index_agendaExecute(), Vector::resize(), Matrix::resize(), and z_at_latlon().

Referenced by refr_gradients_3d().

◆ refr_gradients_1d()

void refr_gradients_1d	(	Workspace &	ws,
		Numeric &	refr_index,
		Numeric &	dndr,
		Numeric &	a_pressure,
		Numeric &	a_temperature,
		Vector &	a_vmr_list,
		const Agenda &	refr_index_agenda,
		ConstVectorView	p_grid,
		const Numeric &	r_geoid,
		ConstVectorView	z_field,
		ConstVectorView	t_field,
		ConstMatrixView	vmr_field,
		const Numeric &	r
	)

refr_gradients_1d

Determines the refractive index, and the radial gradient.

The gradient is calculated in pure numerical way. That is, the refractive index is calculated for slightly shifted radius and the difference to the refractive index at the given point determines the gradient.

The atmosphere is given by its 1D view. That is, the latitude and longitude dimensions are removed from the atmospheric fields. For example, the temperature is given as a vector.

Parameters

ws	Current Workspace
refr_index	Output: As the WSV with the same name.
dndr	Output: Radial gradient of refractive index.
a_pressure	Pressure in hPa.
a_temperature	Temperature in K.
a_vmr_list	Vector with VMR values.
refr_index_agenda	As the WSV with the same name.
p_grid	As the WSV with the same name.
r_geoid	As the WSV with the same name.
z_field	The geometric altitude of each pressure level at each latitude.
t_field	The temperature 2D field.
vmr_field	The VMR 2D field for each species.
r	The radius of the position of interest.

Author: Patrick Eriksson

Date: 2003-01-20

Definition at line 359 of file refraction.cc.

References get_refr_index_1d().

◆ refr_gradients_2d()

void refr_gradients_2d	(	Workspace &	ws,
		Numeric &	refr_index,
		Numeric &	dndr,
		Numeric &	dndlat,
		Numeric &	a_pressure,
		Numeric &	a_temperature,
		Vector &	a_vmr_list,
		const Agenda &	refr_index_agenda,
		ConstVectorView	p_grid,
		ConstVectorView	lat_grid,
		ConstVectorView	r_geoid,
		ConstMatrixView	z_field,
		ConstMatrixView	t_field,
		ConstTensor3View	vmr_field,
		const Numeric &	r,
		const Numeric &	lat
	)

refr_gradients_2d

Determines the refractive index, and its gradients, for the given position.

The gradients are calculated in pure numerical way. That is, the refractive index is calculated for slightly shifted radius or latitude and the difference to the refractive index at the given point determines the gradient.

The latitude gradient is scaled with the radius to obtain the same unit ([1/m]) for both gradients. That is, the returned value is the change of the refractive index for a movement of 1m in the latitude direction.

The atmosphere is given by its 2D view. That is, the longitude dimension is removed from the atmospheric fields. For example, the temperature is given as a matrix.

Parameters

ws	Current Workspace
refr_index	Output: As the WSV with the same name.
dndr	Output: Radial gradient of refractive index.
dndlat	Output: Latitude gradient of refractive index.
a_pressure	Pressure in hPa.
a_temperature	Temperature in K.
a_vmr_list	Vector with VMR values.
refr_index_agenda	As the WSV with the same name.
p_grid	As the WSV with the same name.
lat_grid	As the WSV with the same name.
r_geoid	As the WSV with the same name.
z_field	The geometric altitude of each pressure level at each latitude.
t_field	The temperature 2D field.
vmr_field	The VMR 2D field for each species.
r	The radius of the position of interest.
lat	The latitude of the position of interest.

Author: Patrick Eriksson

Date: 2003-01-14

Definition at line 430 of file refraction.cc.

References DEG2RAD, and get_refr_index_2d().

Referenced by raytrace_2d_linear_euler().

◆ refr_gradients_3d()

void refr_gradients_3d	(	Workspace &	ws,
		Numeric &	refr_index,
		Numeric &	dndr,
		Numeric &	dndlat,
		Numeric &	dndlon,
		Numeric &	a_pressure,
		Numeric &	a_temperature,
		Vector &	a_vmr_list,
		const Agenda &	refr_index_agenda,
		ConstVectorView	p_grid,
		ConstVectorView	lat_grid,
		ConstVectorView	lon_grid,
		ConstMatrixView	r_geoid,
		ConstTensor3View	z_field,
		ConstTensor3View	t_field,
		ConstTensor4View	vmr_field,
		const Numeric &	r,
		const Numeric &	lat,
		const Numeric &	lon
	)

refr_gradients_3d

Determines the refractive index, and its gradients, for the given position.

The gradients are calculated in pure numerical way. That is, the refractive index is calculated for slightly shifted radius, latitude or longitude and the difference to the refractive index at the given point determines the gradient.

The latitude and longitude gradients are scaled with the (effective) radius to obtain the same unit ([1/m]) for all gradients. That is, the returned values are the change of the refractive index for a movement of 1m in the latitude or longitude direction.

Parameters

ws	Current Workspace
refr_index	Output: As the WSV with the same name.
dndr	Output: Radial gradient of refractive index.
dndlat	Output: Latitude gradient of refractive index.
dndlon	Output: Longitude gradient of refractive index.
a_pressure	Pressure in hPa.
a_temperature	Temperature in K.
a_vmr_list	Vector with VMR values.
refr_index_agenda	As the WSV with the same name.
p_grid	As the WSV with the same name.
lat_grid	As the WSV with the same name.
lon_grid	As the WSV with the same name.
r_geoid	As the WSV with the same name.
z_field	As the WSV with the same name.
t_field	As the WSV with the same name.
vmr_field	As the WSV with the same name.
r	The radius of the position of interest.
lat	The latitude of the position of interest.
lon	The longitude of the position of interest.

Author: Patrick Eriksson

Date: 2003-01-17

Definition at line 511 of file refraction.cc.

References DEG2RAD, and get_refr_index_3d().

Referenced by raytrace_3d_linear_euler().

◆ refr_index_ir()

void refr_index_ir	(	Numeric &	refr_index,
		const Numeric &	p,
		const Numeric &	t
	)

refr_index_ir

Calculation of refractive index for the infrared frequency band. The function uses a definition from Michael H�pfner, Forschungszentrum Karlsruhe.

Author: Mattias Ekstr�m

Date: 2003-05-15

Definition at line 602 of file refraction.cc.

Referenced by refr_indexIR().

◆ refr_index_thayer_1974()

void refr_index_thayer_1974	(	Numeric &	refr_index,
		const Numeric &	p,
		const Numeric &	t,
		const Numeric &	h2o_vmr
	)

refr_index_thayer_1974

Calculation of microwave refractive index following Thayer 1974.

Calculates the microwave refractive index due to gases in the Earth's atmosphere. The refractivity of dry air and water vapour is summed. All other gases has a negligible contribution.

The parameterisation of Thayer (Radio Science, 9, 803-807, 1974) is used. See also Eq. 3 and 5 of Solheim et al. (JGR, 104, pp. 9664).

Author: Patrick Eriksson

Date: 2002-11-13

Definition at line 581 of file refraction.cc.

Referenced by refr_indexThayer().

Functions

Detailed Description

Function Documentation

◆ get_refr_index_1d()

◆ get_refr_index_2d()

◆ get_refr_index_3d()

◆ refr_gradients_1d()

◆ refr_gradients_2d()

◆ refr_gradients_3d()

◆ refr_index_ir()

◆ refr_index_thayer_1974()