Simple jet model with thermal or kappa-distribution synchrotron emission from Pandya et al. (2016) More...
#include <GyotoJet.h>
Public Types | |
| typedef Gyoto::SmartPointer< Gyoto::SmartPointee > | Subcontractor_t(Gyoto::FactoryMessenger *, std::vector< std::string > const &) |
| A subcontractor builds an object upon order from the Factory. More... | |
Public Member Functions | |
| virtual Property const * | getProperties () const |
| Get list of properties. More... | |
| Jet () | |
| Standard constructor. | |
| Jet (const Jet &) | |
| Copy constructor. | |
| virtual Jet * | clone () const |
| Cloner. | |
| virtual | ~Jet () |
| Destructor. | |
| void | jetOuterOpeningAngle (double ang) |
| double | jetOuterOpeningAngle () const |
| void | jetInnerOpeningAngle (double ang) |
| double | jetInnerOpeningAngle () const |
| void | jetBaseHeight (double hh) |
| double | jetBaseHeight () const |
| void | gammaJet (double gam) |
| double | gammaJet () const |
| void | jetVphiOverVr (double alpha) |
| double | jetVphiOverVr () const |
| double | baseNumberDensity () const |
| double | baseNumberDensity (std::string const &unit) const |
| void | baseNumberDensity (double ne) |
| void | baseNumberDensity (double dens, std::string const &unit) |
| void | baseTemperature (double tt) |
| double | baseTemperature () const |
| void | temperatureSlope (double ss) |
| double | temperatureSlope () const |
| void | magnetizationParameter (double rr) |
| double | magnetizationParameter () const |
| void | kappaIndex (double index) |
| double | kappaIndex () const |
| virtual void | metric (SmartPointer< Metric::Generic >) |
| Set the Metric gg_. | |
| virtual double | operator() (double const coord[4]) |
| Function defining the object interior. More... | |
| virtual void | radiativeQ (double Inu[], double Taunu[], double const nu_em[], size_t nbnu, double dsem, state_t const &coord_ph, double const coord_obj[8]=NULL) const |
| emission and transmission together | |
| virtual void | getVelocity (double const pos[4], double vel[4]) |
| Fluid velocity field. More... | |
| virtual SmartPointer< Metric::Generic > | metric () const |
| Get the Metric gg_. | |
| virtual void | metric (SmartPointer< Metric::Generic >) |
| Set the Metric gg_. | |
| virtual void | safetyValue (double val) |
| Set Standard::safety_value_. | |
| virtual double | safetyValue () const |
| Get Standard::safety_value_. | |
| double | deltaInObj () const |
| Get Generic::delta_inobj_. More... | |
| void | deltaInObj (double val) |
| Set Generic::delta_inobj_. | |
| virtual int | Impact (Gyoto::Photon *ph, size_t index, Astrobj::Properties *data=NULL) |
| Does a photon at these coordinates impact the object? More... | |
| virtual double | operator() (double const data[])=0 |
| The actual function. | |
| virtual double | giveDelta (double coord[8]) |
| Maximum δ inside object. More... | |
| virtual SmartPointer< Metric::Generic > | metric () const |
| Get the Metric gg_. | |
| virtual double | rMax () |
| Get maximal distance from center of coordinate system. More... | |
| virtual double | rMax () const |
| Get maximal distance from center of coordinate system. | |
| virtual double | rMax (std::string const &unit) |
| Get rmax_ is specified unit. More... | |
| virtual double | rMax (std::string const &unit) const |
| Get rmax_ is specified unit. | |
| virtual void | rMax (double val) |
| Set maximal distance from center of coordinate system. More... | |
| virtual void | rMax (double val, std::string const &unit) |
| Set maximal distance from center of coordinate system. More... | |
| virtual double | deltaMax (double coord[8]) |
| Get max step constraint for adaptive integration. More... | |
| const std::string | kind () const |
| Get the kind of the Astrobj (e.g. "Star") | |
| GYOTO_OBJECT_ACCESSORS_UNIT (deltaMaxInsideRMax) | |
| void | opticallyThin (bool flag) |
| Set whether the object is optically thin. More... | |
| bool | opticallyThin () const |
| Query whether object is optically thin. More... | |
| void | showshadow (bool flag) |
| bool | showshadow () const |
| void | redshift (bool flag) |
| bool | redshift () const |
| virtual Gyoto::Quantity_t | getDefaultQuantities () |
| Which quantities to compute if know was requested. More... | |
| virtual void | setParameters (FactoryMessenger *fmp) |
| Main loop in Subcontractor_t function. More... | |
| virtual void | processHitQuantities (Photon *ph, state_t const &coord_ph_hit, double const *coord_obj_hit, double dt, Astrobj::Properties *data) const |
| Fills Astrobj::Properties. More... | |
| virtual void | processHitQuantities (Photon *ph, double *coord_ph_hit, double *coord_obj_hit, double dt, Astrobj::Properties *data) const =delete |
| virtual double | emission (double nu_em, double dsem, state_t const &coord_ph, double const coord_obj[8]=NULL) const |
| Specific intensity Iν More... | |
| virtual double | emission (double nu_em, double dsem, double coord_ph[8], double coord_obj[8]=NULL) const =delete |
| Obsolete, update your code;. | |
| virtual void | emission (double Inu[], double const nu_em[], size_t nbnu, double dsem, state_t const &coord_ph, double const coord_obj[8]=NULL) const |
| Specific intensity Iν for several values of νem More... | |
| virtual void | emission (double Inu[], double nu_em[], size_t nbnu, double dsem, double coord_ph[8], double coord_obj[8]=NULL) const =delete |
| Obsolete, update your code. | |
| virtual void | radiativeQ (double Inu[], double Taunu[], double nu_em[], size_t nbnu, double dsem, double coord_ph[8], double coord_obj[8]=NULL) const =delete |
| virtual void | radiativeQ (double *Inu, double *Qnu, double *Unu, double *Vnu, double *alphaInu, double *alphaQnu, double *alphaUnu, double *alphaVnu, double *rQnu, double *rUnu, double *rVnu, double const *nuem, size_t nbnu, double dsem, state_t const &cph, double const *co) const |
| virtual double | integrateEmission (double nu1, double nu2, double dsem, state_t const &c_ph, double const c_obj[8]=NULL) const |
| ∫ν1ν2 Iν dν (or jν) More... | |
| virtual double | integrateEmission (double nu1, double nu2, double dsem, double c_ph[8], double c_obj[8]=NULL) const =delete |
| Obsolete, update your code. | |
| virtual void | integrateEmission (double *I, double const *boundaries, size_t const *chaninds, size_t nbnu, double dsem, state_t const &cph, double const *co) const |
| ∫ν1ν2 Iν dν (or jν) More... | |
| virtual void | integrateEmission (double *I, double const *boundaries, size_t const *chaninds, size_t nbnu, double dsem, double *cph, double *co) const =delete |
| Obsolete, update your code. | |
| virtual double | transmission (double nuem, double dsem, state_t const &coord_ph, double const coord_obj[8]) const |
| Transmission: exp( αν * dsem ) More... | |
| virtual double | transmission (double nuem, double dsem, state_t const &coord) const =delete |
| Obsolete, update your code. | |
| virtual double | transmission (double nuem, double dsem, double coord[8]) const =delete |
| Obsolete, update your code. | |
| void | incRefCount () |
| Increment the reference counter. Warning: Don't mess with the counter. | |
| int | decRefCount () |
| Decrement the reference counter and return current value. Warning: Don't mess with the counter. | |
| int | getRefCount () |
| Get the current number of references. | |
| virtual bool | isThreadSafe () const |
| Whether this class is thread-safe. More... | |
| void | set (Property const &p, Value val) |
| Set Value of a Property. | |
| void | set (Property const &p, Value val, std::string const &unit) |
| Set Value (expressed in unit) of a Property. | |
| void | set (std::string const &pname, Value val) |
| Set Value of a Property. | |
| void | set (std::string const &pname, Value val, std::string const &unit) |
| Set Value (expressed in unit) of a Property. | |
| Value | get (Property const &p) const |
| Get Value of a Property. | |
| Value | get (std::string const &pname) const |
| Get Value of a Property. | |
| Value | get (Property const &p, std::string const &unit) const |
| Get Value of a Property, converted to unit. | |
| Value | get (std::string const &pname, std::string const &unit) const |
| Get Value of a Property, converted to unit. | |
| Property const * | property (std::string const pname) const |
| Find property by name. More... | |
| virtual void | fillProperty (Gyoto::FactoryMessenger *fmp, Property const &p) const |
| Output a single Property to XML. More... | |
| virtual void | fillElement (Gyoto::FactoryMessenger *fmp) const |
| Fill the XML element for this Object. More... | |
| virtual int | setParameter (std::string name, std::string content, std::string unit) |
| Set parameter by name. More... | |
| virtual void | setParameter (Gyoto::Property const &p, std::string const &name, std::string const &content, std::string const &unit) |
| Set parameter by Property (and name) More... | |
| std::string | describeProperty (Gyoto::Property const &p) const |
| Format desrciption for a property. More... | |
| void | help () const |
| Print (to stdout) some help on this class. More... | |
Public Attributes | |
| GYOTO_OBJECT_THREAD_SAFETY | |
Static Public Attributes | |
| static GYOTO_OBJECT Property const | properties [] |
Protected Member Functions | |
| virtual void | tell (Gyoto::Hook::Teller *msg) |
| This is how a Teller tells. More... | |
Protected Attributes | |
| double | critical_value_ |
| See operator()(double const coord[4]) | |
| double | safety_value_ |
| See operator()(double const coord[4]) | |
| double | delta_inobj_ |
| Constant value of the integration step inside object, in units of the compact object's mass M. | |
| SmartPointer< Gyoto::Metric::Generic > | gg_ |
| The Metric in this end of the Universe. | |
| double | rmax_ |
| Maximum distance to the center of the coordinate system [geometrical units]. More... | |
| double | deltamaxinsidermax_ |
| Maximum Photon integration step inside rmax_ [geometrical units]. More... | |
| bool | flag_radtransf_ |
| 1 if radiative transfer inside Astrobj, else 0 | |
| int | shadow_ |
| 1 to highlight the shadow region in the image | |
| int | noredshift_ |
| 1 to impose redshift factor g = 1 | |
| std::string | kind_ |
| The "kind" that is output in the XML entity. More... | |
| std::vector< std::string > | plugins_ |
| The plug-ins that needs to be loaded to access this instance's class. More... | |
Private Attributes | |
| SmartPointer< Spectrum::KappaDistributionSynchrotron > | spectrumKappaSynch_ |
| SmartPointer< Spectrum::ThermalSynchrotron > | spectrumThermalSynch_ |
| double | jetOuterOpeningAngle_ |
| Jet outer opening angle (rad) | |
| double | jetInnerOpeningAngle_ |
| Jet inner opening angle (rad) | |
| double | jetBaseHeight_ |
| Height of the base of the jet (z value, M units) | |
| double | gammaJet_ |
| Constant Lorentz factor in jet. | |
| double | jetVphiOverVr_ |
| this is (r*Vphi/Vr) where V is the jet velocity measured by the ZAMO | |
| double | baseNumberDensity_cgs_ |
| electron nb density at jet base (cgs) | |
| double | baseTemperature_ |
| electron temperature at jet base (K) | |
| double | temperatureSlope_ |
| electron temperature z^temperatureSlope_ | |
| double | magnetizationParameter_ |
| Pmagn/(ne mp c2) | |
Friends | |
| class | Gyoto::SmartPointer< Gyoto::Astrobj::Jet > |
Detailed Description
Simple jet model with thermal or kappa-distribution synchrotron emission from Pandya et al. (2016)
This class implements a jet defined as the volume contained between the two conical surfaces defined by angles jetInnerOpeningAngle_ and jetOuterOpeningAngle_, with apex located on the black hole rotation axis at altitude jetBaseHeight_ in units of M.
The Lorentz factor is assumed constant at gammaJet_. The electron number density at the base of the jet is baseNumberDensity_cgs_, its z-evolution is dedictated by mass conservation. The electron temperature is baseTemperature_, its z-evolution is assumed to follow a power law z^temperatureSlope_. The magnetic field amplitude is defined by the magnetization parameter, magnetizationParameter_.
The jet emits synchrotron radiation, assuming that the electrons follow a thermal or kappa distribution, ie the smooth gluing of a thermal distribution at low electron Lorentz factor, to a power-law distribution at high electron Lorentz factor. This distribution, as well as the resulting emission and absorption coefficients are taken from: Pandya et al., ApJ, 822, 34 (2016), section 5.3.3
Member Typedef Documentation
◆ Subcontractor_t
|
inherited |
A subcontractor builds an object upon order from the Factory.
Various classes need to provide a subcontractor to be able to instantiate themselves upon order from the Factory. A subcontractor is a function (often a static member function) which accepts a pointer to a FactoryMessenger as unique parameter, communicates with the Factory using this messenger to read an XML description of the object to build, and returns this objet. SmartPointee::Subcontractor_t* is just generic enough a typedef to cast to and from other subcontractor types: Astrobj::Subcontractor_t, Metric::Subcontractor_t, Spectrum::Subcontractor_t. A subcontractor needs to be registered using the relevant Register() function: Astrobj::Register(), Metric::Register(), Spectrum::Register().
Member Function Documentation
◆ deltaInObj()
|
inherited |
Get Generic::delta_inobj_.
Get the constant integration step inside the astrobj
- Returns
- delta_inobj_ in geometrical units
◆ deltaMax()
|
virtualinherited |
Get max step constraint for adaptive integration.
- Parameters
-
[in] coord position
- Returns
- max step to find this object reliably
Reimplemented in Gyoto::Astrobj::Complex.
◆ describeProperty()
|
inherited |
Format desrciption for a property.
Returns a string containing the name(s) and type of the property, as well as whether it supports unit.
◆ emission() [1/2]
|
virtualinherited |
Specific intensity Iν
Called by the default implementation for processHitQuantities().
emission() computes the intensity Iν emitted by the small volume of length dsem, in the emitter's frame. It should take self-absorption along dsem into account.
Reminder :
- intensity = Iν [J m^-2 s^-1 ster^-1 Hz^-1];
- invariant intensity = Iν/ν3, which has the same value in any frame;
- emission coefficient = jν [J m^-3 s^-1 ster^-1 Hz^-1] , defined by dIν = jν*ds, where ds is the distance travelled by the photon inside the object;
- invariant emission coef = jν/ν2, which has the same value in any frame.
The equation used for radiative transfer (without absorption) is:
d(Iν/ν3)/dλ = (jν/ν2) [*]
where λ is the integration parameter along the null geodesic.
NB: Let us consider a particular observer, with ν being the frequency measured by this observer, and ds being the proper distance (as measured by the observer) that the photon travels as it moves from λ to λ+dλ along its geodesic. Then it can be shown that:
dλ = ds/ν
This shows that Eq. [*] is homogeneous.
The default implementation returns 1. if optically thick and dsem if optically thin. It allows for a quick implementation of your object for visualization purposes.
- Parameters
-
nu_em Frequency at emission [Hz] dsem length over which to integrate inside the object [geometrical units] coord_ph Photon coordinate coord_obj Emitter coordinate at current photon position
Reimplemented in Gyoto::Astrobj::Python::ThinDisk, Gyoto::Astrobj::Python::Standard, Gyoto::Astrobj::PatternDisk, Gyoto::Astrobj::UniformSphere, Gyoto::Astrobj::XillverReflection, Gyoto::Astrobj::DirectionalDisk, Gyoto::Astrobj::Torus, Gyoto::Astrobj::NeutronStarModelAtmosphere, Gyoto::Astrobj::DynamicalDisk3D, Gyoto::Astrobj::PageThorneDisk, Gyoto::Astrobj::InflateStar, Gyoto::Astrobj::ThinDiskGridIntensity, Gyoto::Astrobj::DynamicalDisk, Gyoto::Astrobj::PatternDiskBB, Gyoto::Astrobj::ThinDiskPL, Gyoto::Astrobj::EquatorialHotSpot, Gyoto::Astrobj::ThinDiskProfile, Gyoto::Astrobj::DynamicalDiskBolometric, Gyoto::Astrobj::NeutronStarAnalyticEmission, and Gyoto::Astrobj::ThinDiskIronLine.
◆ emission() [2/2]
|
virtualinherited |
Specific intensity Iν for several values of νem
Called by the default implementation for processHitQuantities().
emission() computes the intensity Iν emitted by the small volume of length dsem. It should take self-absorption along dsem into account.
Same as emission(double nu_em, double dsem, double coord_ph[8], double coord_obj[8]=NULL) const looping on several values of nu_em.
- Parameters
-
Inu[nbnu] Output (must be set to a previously allocated array of doubles) nu_em[nbnu] Frequencies at emission nbnu Size of Inu[] and nu_em[] dsem Length over which to integrate inside the object coord_ph Photon coordinate coord_obj Emitter coordinate at current photon position
- Returns
- Iν or dIν [W m-2 sr-2]
Reimplemented in Gyoto::Astrobj::Python::ThinDisk, and Gyoto::Astrobj::Python::Standard.
◆ fillElement()
|
virtualinherited |
Fill the XML element for this Object.
The base implementation simply calls fillProperty() for each Property defined for the Object.
Derived classes should avoid overriding fillElement(). It may make sense occasionally, e.g. to make sure that the metric is output first.
To customize how a given Property is rendered, it is better to override fillProperty().
If this method is overridden, the implementation should in general call fillElement() on the direct base.
Reimplemented in Gyoto::Scenery, Gyoto::Spectrometer::Complex, Gyoto::Astrobj::Complex, and Gyoto::Metric::Complex.
◆ fillProperty()
|
virtualinherited |
Output a single Property to XML.
The base implementation decides what to do based on the p.type. The format matches how setParameters() an setParameter() would interpret the XML descition.
Overriding this method should be avoided, but makes sense in some cases (for instance Screen::fillProperty() selects a different unit for Distance based on its magnitude, so that stellar sizes are expressed in solar radii while smaller sizes can be expressed in meters and larger sizes in parsecs).
Overriding implementation should fall-back on calling the implementation in the direct parent class:
Reimplemented in Gyoto::Screen, Gyoto::Scenery, Gyoto::Astrobj::Star, Gyoto::Spectrometer::Uniform, Gyoto::Astrobj::PolishDoughnut, Gyoto::Astrobj::Disk3D, Gyoto::Astrobj::PatternDisk, Gyoto::Astrobj::DirectionalDisk, Gyoto::Astrobj::DynamicalDisk, Gyoto::Astrobj::EquatorialHotSpot, Gyoto::Astrobj::XillverReflection, Gyoto::Metric::Shift, and Gyoto::Astrobj::NeutronStarModelAtmosphere.
◆ getDefaultQuantities()
|
virtualinherited |
Which quantities to compute if know was requested.
Return a Gyoto::Quantity_t suitable as input to Gyoto::Scenery::setRequestedQuantities() to set de default quantities to compute for this object. The default of these defaults GYOTO_QUANTITY_INTENSITY.
Reimplemented in Gyoto::Astrobj::PageThorneDisk.
◆ getProperties()
|
virtual |
Get list of properties.
This method is declared automatically by the GYOTO_OBJECT macro and defined automatically by the GYOTO_PROPERTY_END macro.
Reimplemented from Gyoto::Astrobj::Standard.
◆ getVelocity()
|
virtual |
Fluid velocity field.
Fill vel with the 4-vector velocity of the fluid at 4-position pos.
- Parameters
-
[in] pos 4-position at which to compute velocity; [out] vel 4-velocity at pos.
Implements Gyoto::Astrobj::Standard.
◆ giveDelta()
|
virtualinherited |
Maximum δ inside object.
Gives the requested integration step δt (in coordinate time t) between two neighbooring points along a portion of geodesic inside an astrobj; the current implementation only considers a constant delta, equal to Standard::deltaInobj()
- Parameters
-
coord input coordinate at which δt is given
Reimplemented in Gyoto::Astrobj::Python::Standard.
◆ help()
|
inherited |
Print (to stdout) some help on this class.
Describe all properties that this instance supports.
◆ Impact()
|
virtualinherited |
Does a photon at these coordinates impact the object?
Impact() checks whether a Photon impacts the object between two integration steps of the photon's trajectory (those two steps are photon->getCoord(index, coord1) and photon->getCoord(index+1, coord2)). Impact returns 1 if the photon impacts the object between these two steps, else 0. In many cases of geometrically thick obects, the implementation Astrobj::Standard::Impact() will be fine.
Impact will call Generic::processHitQuantities() (which is virtual and may be re-implemented) to compute observable properties on demand: if the data pointer is non-NULL, the object will look in it for pointers to properties which apply to its kind. If a pointer to a property known to this object is present, then the property is computed and store at the pointed-to address. For instance, all objects know the "intensity" property. If data->intensity != NULL, the instensity is computed and stored in *data->intensity.
If data is non-NULL and only in this case, processHitQuantities() will also call ph->transmit() to update the transmissions of the Photon (see Photon::transmit(size_t, double)). This must not be done if data is NULL (see Astrobj::Complex::Impact() for an explanation).
Impact() may not extend the ph Worldline. The only two dates that are guaranteed to be defined are at indices index and index+1.
- Parameters
-
ph Gyoto::Photon aimed at the object; index Index of the last photon step; data Pointer to a structure to hold the observables at impact.
- Returns
- 1 if impact, 0 if not.
Implements Gyoto::Astrobj::Generic.
Reimplemented in Gyoto::Astrobj::PolishDoughnut, Gyoto::Astrobj::Plasmoid, and Gyoto::Astrobj::InflateStar.
◆ integrateEmission() [1/2]
|
virtualinherited |
∫ν1ν2 Iν dν (or jν)
Compute the integral of emission() from ν1 to ν2. The default implementation is a numerical integrator which works well enough and is reasonably fast if emission() is a smooth function (i.e. no emission or absorption lines). If possible, it is wise to implement an analytical solution. It is used by processHitQuantities to compute the "BinSpectrum" quantity which is the most physical: it is the only quantity that can be actually measured directly by a real-life instrument.
Reimplemented in Gyoto::Astrobj::Python::ThinDisk, Gyoto::Astrobj::Python::Standard, and Gyoto::Astrobj::Torus.
◆ integrateEmission() [2/2]
|
virtualinherited |
∫ν1ν2 Iν dν (or jν)
Like double integrateEmission(double nu1, double nu2, double dsem, double c_ph[8], double c_obj[8]) const for each Spectrometer channel.
Reimplemented in Gyoto::Astrobj::Python::ThinDisk, Gyoto::Astrobj::Python::Standard, and Gyoto::Astrobj::PolishDoughnut.
◆ isThreadSafe()
|
virtualinherited |
Whether this class is thread-safe.
Return True if this object is thread-safe, i.e. if an instance and its clone can be used in parallel threads (in the context of Scenery::raytrace()). Known objects which are not thread-safe include Lorene metrics and everything from the Python plug-in.
The default implementation considers that the class itself is thread safe and recurses into the declared properties to check whether they are safe too. Classes that abide to the Object/Property paradigm and are themselves thread-safe have nothing special to do.
Objects that clone children in their copy constructor that are not declared as properties must take these children into account.
Classes that are never thread-safe must declare it. It acn be easily done using GYOTO_OBJECT_THREAD_SAFETY in the class declaration and GYOTO_PROPERTY_THREAD_UNSAFE in the class definition.
◆ operator()()
|
virtual |
Function defining the object interior.
A potential, distance, or whatever function such that operator()(double const coord[4]) < Standard::critical_value_ if and only if coord is inside the object. This function is used by the default implmenetation of Impact(). If Impact() is overloaded, it is not necessary to overload operator()(double coord[4]). The default implementation throws an error.
Implements Gyoto::Astrobj::Standard.
◆ opticallyThin() [1/2]
|
inherited |
Set whether the object is optically thin.
Set flag indicating that radiative transfer should be integrated, i.e. the object is to be considered optically thin.
- Parameters
-
flag 1 if optically thin, 0 if optically thick.
◆ opticallyThin() [2/2]
|
inherited |
Query whether object is optically thin.
◆ processHitQuantities()
|
virtualinherited |
Fills Astrobj::Properties.
processHitQuantities fills the requested data in Impact. To use it, you need to call it in the Impact() method for your object in case of hit. It will fill Redshift, Intensity, Spectrum, BinSpectrum and update the Photon's transmission by calling Photon::transmit(), only if data==NULL.
You can overload it for your Astrobj. The generic implementation calls emission(), integrateEmission() and transmission() below.
Reimplemented in Gyoto::Astrobj::PageThorneDisk, Gyoto::Astrobj::ThinDiskProfile, and Gyoto::Astrobj::DynamicalDiskBolometric.
◆ property()
|
inherited |
◆ rMax() [1/4]
|
virtualinherited |
Get maximal distance from center of coordinate system.
Get maximal distance from center of coordinate system at which a Photon may hit the object.
Child classes may use the rmax_ member to cache this value, if its current value is DBL_MAX.
It can also be set using rMax().
- Returns
- rmax_ in geometrical units
Reimplemented in Gyoto::Astrobj::Star, Gyoto::Astrobj::Torus, Gyoto::Astrobj::Complex, and Gyoto::Astrobj::FixedStar.
◆ rMax() [2/4]
|
virtualinherited |
Get rmax_ is specified unit.
Call rMax() and convert result to unit.
- Parameters
-
unit string
- Returns
- double rmax converted to unit
◆ rMax() [3/4]
|
virtualinherited |
◆ rMax() [4/4]
|
virtualinherited |
Set maximal distance from center of coordinate system.
Call Generic::rMax(double val) after converting val from unit to geometrical units.
- Parameters
-
val rmax_ expressed in unit "unit"; unit string...
◆ setParameter() [1/2]
|
virtualinherited |
Set parameter by name.
This function is used when parsing an XML description, if no Property of this name is found. Overriding implementation should fall-back on calling the direct's parent implementation:
- Parameters
-
name XML name of the parameter (XML entity). This may have a path component, e.g. "Astrobj::Radius", in which case a property named "Astrobj" will be sought in the current object, and setParameter will be called recusrively on this Astrobj with Radius as name. content string representation of the value unit string representation of the unit
- Returns
- 0 if this parameter is known, 1 if it is not.
Reimplemented in Gyoto::Astrobj::Star, Gyoto::Metric::RotStar3_1, Gyoto::Metric::KerrKS, and Gyoto::Astrobj::EquatorialHotSpot.
◆ setParameter() [2/2]
|
virtualinherited |
Set parameter by Property (and name)
This function is used when parsing an XML description, if Property (p) of this name is found (i.e. either p.name or p.name_false is equal to name). Implementation should fall-back on calling the direct's parent implementation:
- Parameters
-
p Property that matches name (p.name == name or p.name_false == name) name XML name of the parameter (XML entity) content string representation of the value unit string representation of the unit
Reimplemented in Gyoto::Astrobj::PolishDoughnut.
◆ setParameters()
|
virtualinherited |
Main loop in Subcontractor_t function.
The Subcontractor_t function for each Astrobj kind should look somewhat like this (templated as Gyoto::Astrobj::Subcontractor<MyKind>):
Each object kind should implement setParameter(string name, string content, string unit) to interpret the individual XML elements. setParameters() can be overloaded in case the specific Astrobj class needs low level access to the FactoryMessenger. See UniformSphere::setParameters().
Reimplemented from Gyoto::Object.
Reimplemented in Gyoto::Astrobj::Star, Gyoto::Astrobj::Complex, Gyoto::Astrobj::OscilTorus, and Gyoto::Astrobj::EquatorialHotSpot.
◆ tell()
|
protectedvirtualinherited |
This is how a Teller tells.
A teller will basically call listener->tell(this).
- Parameters
-
msg Teller* the Teller who is telling... Useful if the Listener listens to several Tellers.
Reimplemented in Gyoto::Worldline, Gyoto::Astrobj::PolishDoughnut, Gyoto::Astrobj::XillverReflection, Gyoto::Astrobj::PageThorneDisk, Gyoto::Spectrometer::Complex, Gyoto::Astrobj::OscilTorus, and Gyoto::Metric::Shift.
◆ transmission()
|
virtualinherited |
Transmission: exp( αν * dsem )
transmission() computes the transmission of this fluid element or 0 if optically thick. The default implementation returns 1. (no attenuation) if optically thin, 0. if optically thick.
- Parameters
-
nuem frequency in the fluid's frame coord Photon coordinate dsem geometrical length in geometrical units
Reimplemented in Gyoto::Astrobj::PatternDisk, and Gyoto::Astrobj::DynamicalDisk3D.
Member Data Documentation
◆ deltamaxinsidermax_
|
protectedinherited |
Maximum Photon integration step inside rmax_ [geometrical units].
Maximum step for Photon integation when inside the sphere of radius rmax_.
deltamaxinsidermax_ is in geometrical units.
◆ kind_
|
protectedinherited |
The "kind" that is output in the XML entity.
E.g. for an Astrobj, fillElement() will ensure
is written.
◆ plugins_
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protectedinherited |
The plug-ins that needs to be loaded to access this instance's class.
E.g. for an Astrobj, fillElement() will ensure
is written.
◆ rmax_
|
protectedinherited |
Maximum distance to the center of the coordinate system [geometrical units].
Maximum distance from the center of the coordinate system at which a photon may hit the object. Child classes may compute a decent value for rmax_ at any time if rmax_ is DBL_MAX. External classes (Photons in particular) must use rMax() to access this information.
rmax_ is in geometrical units.
The documentation for this class was generated from the following file:
