| Name | Description |
|---|---|
| Active Constraints | Lists the "from" STK object name and type to which the active constraint belongs. |
| All Constraints | Descriptions of all constraints available for this object and its parent object. |
| Angles | Used to report angle and its time rate of change rate. Angle must be defined in the Vector Geometry Tool. |
| Articulation | Information concerning model articulations for this object. |
| Attitude Quaternions | The attitude quaternion and angular velocity of the vehicle's body axes computed with respect to the vehicle's central body inertial coordinate system. The quaternion components q1, q2, and q3 are the vector components of the quaternion; q4 is the scalar part. The angular velocity is computed as observed from the inertial frame and resolved into inertial components. |
| Attitude Segment Schedule | The list of attitude segments describing the attitude for this object. Each segment is valid over its defined interval. |
| Attitude YPR | The attitude of the vehicle with respect to the vehicle's central body inertial coordinate system, expressed using YPR angles. YPR angles specify attitude using three rotations in sequence: a rotation about the X axis is called roll (R), a rotation about the Y axis is called pitch (P), and a rotation about the Z axis is called yaw (Y). Unlike Euler angles, the rotations are not made about axes defined by an earlier rotation: each rotation is made about the reference system's axes. |
| Available Times | The time intervals over which the object is available to participate in access computations. |
| Axes Choose Axes | Used to report orientation and angular velocity of the selected set of axes relative to a specified reference set of axes. Both sets of axes must be defined in the Vector Geometry Tool. |
| Beta Angle | The Beta Angle is the signed angle of the apparent vector to a central body, relative to the orbital plane. The signed angle is positive when the apparent vector is in the direction of the orbit normal. The orbit normal (which is normal to the orbital plane) is parallel to the orbital angular momentum vector, which is defined as the cross-product of the inertial position and velocity vectors. The light time delay is actually computed between the central body used to compute the beta angle and the vehicle's central body, rather than directly from the object itself. |
| Body Axes Orientation | Selects set of object's body axes to report its orientation and angular velocity relative to reference set of axes. The reference set of axes must be defined in the Vector Geometry Tool. Note that selecting object's body axes is equivalent to selecting object's attitude. |
| Body Axes Orientation YPR 123 | Selects set of object's body axes to report its orientation and angular velocity relative to reference set of axes. The reference set of axes must be defined in the Vector Geometry Tool. Note that selecting object's body axes is equivalent to selecting object's attitude. Uses 123 (or RPY) sequence for YPR angles representation. |
| Body Axes Orientation YPR 132 | Selects set of object's body axes to report its orientation and angular velocity relative to reference set of axes. The reference set of axes must be defined in the Vector Geometry Tool. Note that selecting object's body axes is equivalent to selecting object's attitude. Uses 132 (or RYP) sequence for YPR angles representation. |
| Body Axes Orientation YPR 213 | Selects set of object's body axes to report its orientation and angular velocity relative to reference set of axes. The reference set of axes must be defined in the Vector Geometry Tool. Note that selecting object's body axes is equivalent to selecting object's attitude. Uses 213 (or PRY) sequence for YPR angles representation. |
| Body Axes Orientation YPR 231 | Selects set of object's body axes to report its orientation and angular velocity relative to reference set of axes. The reference set of axes must be defined in the Vector Geometry Tool. Note that selecting object's body axes is equivalent to selecting object's attitude. Uses 231 (or PYR) sequence for YPR angles representation. |
| Body Axes Orientation YPR 312 | Selects set of object's body axes to report its orientation and angular velocity relative to reference set of axes. The reference set of axes must be defined in the Vector Geometry Tool. Note that selecting object's body axes is equivalent to selecting object's attitude. Uses 312 (or YRP) sequence for YPR angles representation. |
| Body Axes Orientation YPR 321 | Selects set of object's body axes to report its orientation and angular velocity relative to reference set of axes. The reference set of axes must be defined in the Vector Geometry Tool. Note that selecting object's body axes is equivalent to selecting object's attitude. Uses 321 (or YPR) sequence for YPR angles representation. |
| Cartesian Acceleration | The acceleration of the object as observed from the requested coordinate system, expressed in Cartesian components of that system, as a function of time. The acceleration can be requested in a variety of coordinate systems. The available coordinate systems depend on the object's central body. Nominally, the systems Fixed, Inertial, J2000, TrueOfDate, and MeanOfDate are supported, although some central bodies (notably the Earth and Sun) have more. The following lists the systems available for Earth. |
| Cartesian Position | The position of the object, expressed in Cartesian components, as a function of time. The position can be requested in a variety of coordinate systems. The available coordinate systems depend on the object's central body. Nominally, the systems Fixed, Inertial, J2000, TrueOfDate, and MeanOfDate are supported, although some central bodies (notably the Earth and Sun) have more. The following lists the systems available for Earth. |
| Cartesian Velocity | The velocity of the object as observed from the requested coordinate system, expressed in Cartesian components of that system, as a function of time. The velocity can be requested in a variety of coordinate systems. The available coordinate systems depend on the object's central body. Nominally, the systems Fixed, Inertial, J2000, TrueOfDate, and MeanOfDate are supported, although some central bodies (notably the Earth and Sun) have more. The following lists the systems available for Earth. |
| Classical Elements | Classical osculating orbital elements, sometimes referred to as Keplerian elements. The ephemeris can be requested in a variety of coordinate systems. The available coordinate systems depend on the object's central body. Nominally, the systems Inertial, J2000, TrueOfDate, and MeanOfDate are supported, although some central bodies (notably the Earth and Sun) have more. The following lists the inertial systems available for Earth. |
| Condition Set | Defines a set of conditions for when the elapsed time falls within specified time limits |
| Close Approach Compute Results | Close Approach analysis results summary. |
| Close Approach Definition | Parameter settings for the Close Approach Tool. |
| Close Approach Filter Settings | Filter settings for the Close Approach Tool. |
| CloseApproach | The results produced by using the close approach tool, identifying vehicles that pass within a specified minimum range of the object. Also reports information concerning launch window blackout intervals when that capability is used. |
| CloseApproachByMinRange | The results produced by using the close approach tool, identifying vehicles that pass within a specified minimum range of the object. The data is sorted according to the minimum range. Also reports information concerning launch window blackout intervals when that capability is used. |
| CloseApproachBySSC | The results produced by using the close approach tool, identifying vehicles that pass within a specified minimum range of the object. The data is sorted according to the SSC number of the secondary. Also reports information concerning launch window blackout intervals when that capability is used. |
| Collection of Interval Lists | A time component that produces a collection of related interval lists. |
| Condition | Condition placing bounds on a specific scalar. |
| Crdn Available Times | Time intervals for which a Vector Geometry Tool component for the object is available. |
| Data Provider Detail | Data Provider Detail - hierarchically list the available data providers and all of the included elements |
| Data Provider Summary | Data Provider Summary - a list of all available data providers |
| DeckAccess | Used to report the output from the Deck Access tool. The Deck Access tool allows you to compute access to a set of objects, not currently defined within the STK scenario, from a single object within the scenario. |
| DeckAccess Data | Geometrical data involving the source and target objects of a DeckAccess computation. |
| ECF Attitude Quaternions | The attitude quaternion and angular velocity of the vehicle's body axes computed with respect to the vehicle's central body fixed coordinate system. The quaternion components q1, q2, and q3 are the vector components of the quaternion; q4 is the scalar part. The angular velocity is computed as observed from the fixed frame and resolved into fixed components. |
| Eclipse Definition | The bodies considered when computing eclipse and lighting times. |
| Eclipse Summary | Provides summary information for each eclipse. Note that the Eclipse Summary data provider reports the start and stop times of penumbra which, if umbra exists, occur before and after umbra, respectively. This means that if the Eclipse Summary is generated in cases when it starts in umbra, then the start of penumbra is reported as "No Data" because it occurred prior to the start of reported data. |
| Eclipse Times | Generates a listing of all eclipse events. Eclipsing events are start and end of periods of partial lighting (penumbra) and periods of zero lighting (umbra). |
| Ephemeris Diff | The relative ephemeris of the assigned object with respect to the primary object, expressed in Cartesian components, as a function of time. The relative velocity vector is computed as observed in the requested coordinate system, and expressed in components of that frame. The relative ephemeris can be requested in a variety of coordinate systems. The available coordinate systems depend on the object's central body. Nominally, the systems Fixed, Inertial, J2000, TrueOfDate, and MeanOfDate are supported, although some central bodies (notably the Earth and Sun) have more. The following lists the systems available for Earth. |
| Euler Angles | The attitude of the vehicle (i.e., the rotation between the vehicle's body axes and the vehicle' central body's inertial frame) expressed using Euler angles. Euler angles use a sequence of three rotations starting from a reference coordinate frame. The rotations are performed in succession: each rotation is relative to the frame resulting from any previous rotations. The sequence of three rotations is indicated by a integer sequence where the X axis is 1, Y axis is 2, and Z axis is 3. For example, a 313 sequence uses Z, then the new X, and then finally the newest Z axis. |
| Flight Attitude | Attitude of the body axes, expressed using standard aeronautical terms. |
| Gravity Model | The name of the gravity model that is currently in use by the propagator. It includes the values of the standard gravitational parameter mu, and the J2 term in the gravity field. |
| Ground Ellipse Definition | Ground Ellipse Definition. |
| Ground Range | The ground range and altitude of the vehicle over time. |
| Heading | Heading information relative to the object's central body fixed coordinate system. |
| Interval | A time component that produces a single interval of time. |
| Interval List | A time component that produces an ordered list of time intervals. |
| LLA State | The ephemeris of the object, expressed in LLA elements, as a function of time. The coordinate system is the Fixed frame of the object's central body. |
| LLR State | The ephemeris of the object, expressed in LLR elements, as a function of time. The ephemeris can be requested in a variety of coordinate systems. The available coordinate systems depend on the object's central body. Nominally, the systems Fixed, Inertial, J2000, TrueOfDate, and MeanOfDate are supported, although some central bodies (notably the Earth and Sun) have more. The following lists the systems available for Earth. |
| Launch Clear Intervals | The time intervals for which a launch produced no close approaches within the specified range threshold. |
| Launch Window Definition | Parameter settings for the Launch Window Tool. |
| LaunchBlackout | Launch window blackout time intervals determined by the close approach tool. Only valid if the launch window capability has been used. During a launch window blackout interval, the vehicle will have a close approach with some secondary vehicle if it were to be launched during that interval. |
| LaunchBlackout By Launch | The Launch Blackout report results, sorted by primary launch object. |
| LaunchWindow | The results produced by using the launch window tool, identifying vehicles that pass within a specified minimum range of the object. |
| LaunchWindowByLaunch | The Launch Window report results, sorted by primary launch object. |
| LaunchWindowByLaunchID | The Launch Window report results, sorted by primary launch SSC. |
| LaunchWindowByLaunchName | The Launch Window report results, sorted by primary launch name. |
| LaunchWindowByMinRange | The Launch Window report results, sorted by minimum range. |
| LaunchWindowBySSC | The Launch Window report results, sorted by secondary SSC. |
| Lighting AER | Angle and range data describing the apparent position vector of the Sun relative to the selected object. |
| Lighting Times | Generates a listing of all lighting events. Lighting events are start and end of periods of full lighting (sunlight), partial lighting (penumbra) and periods of zero lighting (umbra). Note that the Lighting Times data provider reports all computed penumbra intervals, which means that if umbra exists, then two penumbra intervals, each with its own start and stop times, is reported--one before and one after the umbra interval. So, if lighting times that start in umbra are generated, then the first reported penumbra interval corresponds to the times that follow after the first umbra, and the penumbra interval prior to the first umbra is not reported. |
| Mixed Spherical Elements | The position and velocity of the object, expressed in mixed spherical elements, as a function of time. The position is expressed using LLA elements, with respect to the vehicle's central body fixed coordinate system -- the requested coordinate system is immaterial. The velocity of the object is computed as observed from the requested coordinate system. The ephemeris can be requested in a variety of coordinate systems. The available coordinate systems depend on the object's central body. Nominally, the systems Fixed, Inertial, J2000, TrueOfDate, and MeanOfDate are supported, although some central bodies (notably the Earth and Sun) have more. The following lists the systems available for Earth. |
| Model Area | The area of the object's 3D graphics model, as viewed from a given view direction, as computed by the Area Tool. |
| Model LOD 0 Articulations | The model's articulation values used for display with a level of detail of 0 (high resolution). This data provider always includes time, but the rest of its content varies depending on the model. |
| Model LOD 1 Articulations | The model's articulation values used for display with a level of detail of 1 (low resolution). This data provider always includes time, but the rest of its content varies depending on the model. |
| Moon AER | Angle and range data describing the apparent position vector of the Moon relative to the selected object. |
| Moon Vector | The apparent position of the Moon with respect to the object, expressed in Cartesian components, as a function of time. The light time delay is actually computed between the Moon and the object's central body, rather than directly from the object itself. The apparent position can be requested in a variety of coordinate systems. The available coordinate systems depend on the object's central body. Nominally, the systems Fixed, Inertial, J2000, TrueOfDate, and MeanOfDate are supported, although some central bodies (notably the Earth and Sun) have more. The following lists the systems available for Earth. |
| Parameter Set Attitude | The Attitude parameter set defines orientation of one set of Axes from VGT relative to another. This parameter includes the following sub-sets: Quaternion, Euler, DCM and AngleAxis. Quaternion includes four quaternion elements Q1, Q2, Q3, Q4. Euler includes all 12 sequences where within each there are three angles A, B, C. DCM includes all nine elements of the direction cosine matrix; e.g., XX, XY, etc. AngleAxis includes X, Y, Z components of the unit axis of rotation and RotationAngle. |
| Parameter Set Cartographic Trajectory | Cartographic Trajectory Parameter Set contains calculations that relate a specified point to the selected central body shape. This parameter set contains the following sub-sets: Cartesian, Centric and Detic. Cartesian includes X, Y, Z and Radius. Centric includes LLR with Latitude, Longitude and Radius, and SubPoint with Cartesian elements. Detic includes several LLA with Latitude, Longitude, Altitude, SurfaceNormal with Cartesian elements without Radius, and SubPoint with Cartesian elements. It also includes Terrain and MSL both with LLA and SubPoint subsets of their own. |
| Parameter Set Orbit | The Orbit parameter set defines orbital element sets for a Point from VGT orbiting the specified Central Body in the specified coordinate System. Element sets include: Cartesian, Classical, Delaunay, Spherical and Equinoctial (Posigrade and Retrograde). |
| Parameter Set Trajectory | The Trajectory parameter set defines the position of a specified Point from VGT with respect to the reference System. This parameter set includes the following sub-sets: Cartesian, Cylindrical and Spherical. Cartesian includes X, Y, Z and Radius. Cylindrical includes Azimuth, Height, Radius. Spherical includes Azimuth, Elevation, CoElevation, and Radius. |
| Planes Choose System | Used to report the selected plane and its velocity in a specified reference coordinate system. Both plane and coordinate system must be defined in the Vector Geometry Tool. |
| Planes(Fixed) | Used to report the selected plane and its velocity in the object's central body fixed coordinate system. The plane must be defined in the Vector Geometry Tool. |
| Planes(ICRF) | Used to report the selected plane and its velocity in the object's central body ICRF coordinate system. The plane must be defined in the Vector Geometry Tool. |
| Planes(Inertial) | Used to report the selected plane and its velocity in the object's central body inertial coordinate system. The plane must be defined in the Vector Geometry Tool. |
| Planes(J2000) | Used to report the selected plane and its velocity in the object's central body J2000 coordinate system. The plane must be defined in the Vector Geometry Tool. |
| Pointing Covariance (Projection) | Projection of the equal probability density ellipsoid defined by the pointing covariance matrix onto the plane perpendicular to the mean pointing direction. The data requires position covariance to be defined for the object and/or its target. |
| Points Choose Plane | Used to report projection of the selected point and its velocity on a specified reference plane. Both point and plane must be defined in the Vector Geometry Tool. |
| Points Choose System | Used to report the selected point and its velocity in a specified reference coordinate system. Both point and coordinate system must be defined in the Vector Geometry Tool. |
| Points(Fixed) | Used to report the selected point and its velocity in the object's central body fixed coordinate system. The point must be defined in the Vector Geometry Tool. |
| Points(ICRF) | Used to report the selected point and its velocity in the object's central body ICRF coordinate system. The point must be defined in the Vector Geometry Tool. |
| Points(Inertial) | Used to report the selected point and its velocity in the object's central body inertial coordinate system. The point must be defined in the Vector Geometry Tool. |
| Points(J2000) | Used to report the selected point and its velocity in the object's central body J2000 coordinate system. The point must be defined in the Vector Geometry Tool. |
| Position Covariance | Reports data about position covariance matrix including orientation of its principal axes relative to selected set of axes. Any set of axes defined in the Vector Geometry Tool is available for use, including user defined sets. The data requires position covariance to be defined for the object. Note: This data provider does not support interpolation of the position/velocity covariance matrices. Output is limited to the times of the stored ephemeris points. |
| Position Covariance Choose Axes | Reports data about position covariance matrix including orientation of its principal axes relative to selected set of axes and dimensions of the associated sigma scaled equal probability density ellipsoid. Any set of axes defined in the Vector Geometry Tool is available for use, including user defined sets. The data requires position covariance to be defined for the object. |
| Position Covariance CrossSection | Cross-section of the equal probability density ellipsoid defined by the position covariance matrix with the specified plane. Any plane defined in the Vector Geometry Tool is available for use, including user defined planes. The data requires position covariance to be defined for the object. |
| Position Covariance CrossSection Choose Plane | Cross-section of the equal probability density ellipsoid defined by the position covariance matrix with the specified plane. Any plane defined in the Vector Geometry Tool is available for use, including user defined planes. The data requires position covariance to be defined for the object. |
| Position Covariance CrossSection Impact | Position Covariance CrossSection Impact computes cross-section of the position covariance ellipsoid in a plane perpendicular to the object's CBF velocity at the stop time (impact time). The resulting ellipse is projected futher along the CBF velocity which makes up an elliptical cylinder. The cylinder's intersection with the local horizontal plane makes the final ellipse which is reported by this data provider. |
| SEET GCR Differential Flux by Energy | Computes the Galactic Cosmic Radiation (GCR) differential flux with respect to particle energy. The data items available for this data provider depend on the GCR model, atomic number, and potentially other GCR model dependent parameters. |
| SEET GCR Differential Fluence by Energy | Computes the Galactic Cosmic Radiation (GCR) fluence as an differential fluence with respect to particle energy. The data items available for this data provider depend on the GCR model, atomic number, sample time period, and potentially other GCR model dependent parameters. |
| Position Covariance Projection | Projection of the equal probability density ellipsoid defined by the position covariance matrix onto the specified plane. Any plane defined in the Vector Geometry Tool is available for use, including user defined planes. The data requires position covariance to be defined for the object. |
| Position Covariance Projection Choose Plane | Projection of the equal probability density ellipsoid defined by the position covariance matrix onto the specified plane. Any plane defined in the Vector Geometry Tool is available for use, including user defined planes. The data requires position covariance to be defined for the object. |
| Propagator Inputs | Parameters used by the specified propagator to propagate the vehicle. |
| SEET GCR Integral Fluence by Energy | Computes the Galactic Cosmic Radiation (GCR) fluence as an integrated distribution with respect to particle energy. The data items available for this data provider depend on the GCR model, atomic number, sample time period, and potentially other GCR model dependent parameters. |
| SEET GCR Integral Flux by Energy | Computes the Galactic Cosmic Radiation (GCR) flux as an integrated distribution with respect to particle energy. The data items available for this data provider depend on the GCR model, atomic number, and potentially other GCR model dependent parameters. |
| Position Covariance Projection Impact | Position Covariance Projection Impact computes projection of the position covariance ellipsoid onto a plane perpendicular to the object's CBF velocity at the stop time (impact time). The resulting ellipse is projected futher along the CBF velocity which makes up an elliptical cylinder. The cylinder's intersection with the local horizontal plane makes the final ellipse which is reported by this data provider. |
| SEET GCR Model | Parameter settings for the object's Galactic Cosmic Radiation (GCR) model. |
| Position Covariance in Axes | Reports data about position covariance matrix including orientation of its principal axes relative to selected set of axes and dimensions of the associated sigma scaled equal probability density ellipsoid. Any set of axes defined in the Vector Geometry Tool is available for use, including user defined sets. The data requires position covariance to be defined for the object. Note: This data provider does not support interpolation of the position/velocity covariance matrices. Output is limited to the times of the stored ephemeris points. |
| Relative Motion | The relative ephemeris of the assigned object with respect to the primary object, expressed in Cartesian components, as a function of time. The relative ephemeris is computed with respect to two rotating frames, the RIC (Radial, In-Track, Cross-Track) frame and the NTC (Normal, Tangential, and Cross-Track) frames, that are defined using the primary's ephemeris. Cross-track refers to the direction perpendicular to the position and inertial velocity; in-track refers to the direction perpendicular to both the radial and cross-track (positive in the direction of motion); tangential refers to the direction along the velocity vector; and normal refers to the direction perpendicular to the velocity and cross-track directions (positive outward along radial). |
| SEET Debris Flux | Computes the total debris flux of all particulates. The debris model is valid only for near-circular orbits at altitudes between roughly 300 km and 2250 km. Because the model was created using averages over long time periods (e.g., many months or a few years), it is not appropriate to output a flux value at any given time - there really is no information in different evaluations of the model over short time spans. Hence, the debris flux is evaluated at just 1 sample per requested time interval, at the midpoint of the interval. Valid for vehicles whose central body is earth. |
| SEET Magnetic Conjugacy | Computes the time intervals when the vehicle is magnetically conjugate with a target object. The user must specify the target object and the maximum separation angle between their respective field lines that will indicate conjugacy. The smaller the separation is made, the closer the field lines containing the vehicle and the target object must be. Valid for vehicles whose central body is earth. |
| SEET Magnetic Coordinates | Computes the vehicle's position and velocity in the requested coordinate system, as a function of time. Valid for vehicles whose central body is earth. |
| SEET Magnetic Field | Computes the geomagnetic field and various parameters associated with the geomagnetic field. Valid for vehicles whose central body is earth. |
| SEET Magnetic Field Model | Description of the parameter settings for the vehicle's Magnetic Field model. |
| SEET Meteor Flux | Computes the total meteoroid flux of all particulates, at the given time. Valid for vehicles whose central body is earth. |
| SEET Particle Distribution Fluence | Computes the fluence (i.e., the flux integrated over time) for the distribution of mass particles that are used to model meteoroid and debris particulates. Valid for vehicles whose central body is earth. |
| SEET Particle Fluence | Computes the total fluence (i.e., the total flux of all particulates integrated over time). Valid for vehicles whose central body is earth. |
| SEET Particle Flux Model | Parameter settings for the vehicle's Particle Flux model. |
| SEET Radiation Accumulated Dose | Computes the radiation dose as it accumulates over time for the requested time interval(s), using the step size to perform the numerical integration of dose rate with time. The data items available for this data provider depend on the shielding thicknesses in use. For each thickness, there will be data items for Electron dose, Electron-Bremsstrahlung dose, Proton dose, and Combined dose. Valid for vehicles whose central body is earth. |
| SEET Radiation Accumulated Dose By Thickness | Computes the radiation dose as it accumulates over time for the requested time interval(s), using the step size to perform the numerical integration of dose rate with time. The report is divided into subsections, where each subsection corresponds to a different shielding thickness. Valid for vehicles whose central body is earth. |
| SEET Radiation Average Dose Rate | Computes the average radiation dose rate. The data items available for this data provider depend on the shielding thicknesses in use. For each thickness, there will be data items for Model, Electron dose, Electron-Bremsstrahlung dose, Proton dose, and Combined dose. Valid for vehicles whose central body is earth. |
| SEET Radiation Average Dose Rate By Thickness | Computes the average radiation dose rate for each shielding thickness. The report is divided into subsections, where each subsection corresponds to a different shielding thickness. Valid for vehicles whose central body is earth. |
| SEET Radiation Dose Depth | Computes the radiation dose over the requested time interval(s), using the step size to perform the numerical integration of dose rate with time. Valid for vehicles whose central body is earth. |
| SEET Radiation Dose Rate | Computes the radiation dose rate. The data items available for this data provider depend on the shielding thicknesses in use. For each thickness, there will be data items for Model, Electron dose, Electron-Bremsstrahlung dose, Proton dose, and Combined dose. Valid for vehicles whose central body is earth. |
| SEET Radiation Dose Rate By Thickness | Computes the radiation dose rate for each shielding thickness. The report is divided into subsections, where each subsection corresponds to a different shielding thickness. Valid for vehicles whose central body is earth. |
| SEET Radiation Flux | Computes the radiation flux at each electron and proton energy level. The energy levels are determined by the computational mode. There will be data items for electrons and protons at each of their respective energy levels. Valid when using NASA or CRRES models. Valid for vehicles whose central body is earth. |
| SEET Radiation Flux by Energy | Computes the radiation flux at each electron and proton energy level. The energy levels are determined by the computational mode. The report is divided into subsections, where each subsection corresponds to a different constituent and energy level. Valid when using NASA or CRRES models. Valid for vehicles whose central body is earth. |
| SEET Radiation Integral Flux | Computes the integral radiation flux at each electron and proton energy level. The energy levels are determined by the computational mode. There will be data items for electrons and protons at each of their respective energy levels. Valid when using NASA or CRRES models. Valid for vehicles whose central body is earth. |
| SEET Radiation Integral Flux by Energy | Computes the integral radiation flux at each electron and proton energy level. The energy levels are determined by the computational mode. The report is divided into subsections, where each subsection corresponds to a different constituent and energy level. Valid when using NASA or CRRES models. Valid for vehicles whose central body is earth. |
| SEET Radiation Model | Parameter settings for the vehicle's Radiation model. |
| SEET SAA Contour Settings | Parameter settings for the vehicle's SAA (South Atlantic Anomaly) contour. |
| SEET SAA Crossing Times | Computes the SAA (South Atlantic Anomaly) transit times for the vehicle for the channel and flux level specified by the vehicle's SAA contour settings. Valid for vehicles whose central body is earth. |
| SEET SEP Energy by Fluence | The fluence value for the energy in the selected model based on the specified probability. |
| SEET SEP Fluence by Probability per Energy | A distribution of fluence and probablities for each energy level in the selected model. |
| SEET SAA Flux Intensity | Computes the flux intensity within the SAA (South Atlantic Anomaly). Valid for vehicles whose central body is earth. |
| SEET SEP Model | Parameter settings for the object's Solar Energetic Particle (SEP) model. |
| SEET Vehicle Temperature | Computes the vehicle temperature considering incident sunlight heating, earth albedo, earth thermal radiation, and internal dissipation. |
| SEET Vehicle Temperature Model | Parameter settings for the vehicle's Temperature model. |
| Scalar Calculations | Calculation component that produces scalar time-varying calculations. |
| Shadow LLA | The location of the object's shadow on the object's central body surface, produced by the Sun at its apparent position as computed at the object's location. Note that the shadow point is defined as the intersection on the object's central body the line emanating from the center of the apparent Sun toward the object. Thus, the effects of the finite size of the Sun are ignored. In addition, no light time delay is computed for the light travelling between the object and the intersection point. |
| Solar Intensity | Percent of the solar disc visible, along with lighting condition and name of obscuring central body. |
| Solar Specular Point | The solar specular reflection point is the point on the object's central body surface where the reflected light of the Sun about the surface normal reaches the object. Light time delay effects are considered on both legs: from the Sun to the point on the surface and from the surface to the object itself. There may be times where there the specular point does not exist. |
| Spherical Elements | The position and velocity of the object, expressed in spherical elements, as a function of time. The velocity of the object is computed as observed from the requested coordinate system. The ephemeris can be requested in a variety of coordinate systems. The available coordinate systems depend on the object's central body. Nominally, the systems Fixed, Inertial, J2000, TrueOfDate, and MeanOfDate are supported, although some central bodies (notably the Earth and Sun) have more. The following lists the systems available for Earth. |
| Sun Vector | The apparent position of the Sun with respect to the object, expressed in Cartesian components, as a function of time. The light time delay is actually computed between the Sun and the object's central body, rather than directly from the object itself. The apparent position can be requested in a variety of coordinate systems. The available coordinate systems depend on the object's central body. Nominally, the systems Fixed, Inertial, J2000, TrueOfDate, and MeanOfDate are supported, although some central bodies (notably the Earth and Sun) have more. The following lists the systems available for Earth. |
| Swath Points | The location of the horizon on the central body surface, as viewed from the object. For the Ground Elevation Envelope or Vehicle Half Angle Envelope swath types, the left/right swath point may not exist. If it does not, the point being reported at that time uses the Ground Elevation or Vehicle Half Angle swath setting as appropriate. |
| Time Array | A time component that produces intervals of time within which there are ordered arrays of times. |
| Time Instant | A time component that produces a single moment in time. |
| User Supplied Data | Values of custom data associated with the object. |
| Vector Choose Axes | Used to report the selected vector and its derivative in a specified reference set of axes. Both vector and axes must be defined in the Vector Geometry Tool. |
| Vector Choose Plane | Used to report projection of the selected vector and its derivative on a specified reference plane. Both vector and plane must be defined in the Vector Geometry Tool. |
| Vectors(Body) | Used to report the selected vector and its derivative in the object's body axes. The vector must be defined in the Vector Geometry Tool. |
| Vectors(Fixed) | Used to report the selected vector and its derivative in the object's central body fixed axes. The vector must be defined in the Vector Geometry Tool. |
| Vectors(Fixed_VVLH) | Used to report the selected vector and its derivative in the object's VVLH(CBF) axes. The vector must be defined in the Vector Geometry Tool. |
| Vectors(ICRF) | Used to report the selected vector and its derivative in ICRF axes. The vector must be defined in the Vector Geometry Tool. |
| Vectors(Inertial) | Used to report the selected vector and its derivative in the object's central body inertial axes. The vector must be defined in the Vector Geometry Tool. |
| Vectors(J2000) | Used to report the selected vector and its derivative in J2000 axes. The vector must be defined in the Vector Geometry Tool. |
| Vectors(LVLH) | Used to report the selected vector and its derivative in the object's LVLH axes. The vector must be defined in the Vector Geometry Tool. |
| Vectors(VNC) | Used to report the selected vector and its derivative in the object's VNC axes. The vector must be defined in the Vector Geometry Tool. |
| Vectors(VVLH(CBF)) | Used to report the selected vector and its derivative in the object's VVLH(CBF) axes. The vector must be defined in the Vector Geometry Tool. |
| Vectors(VVLH) | Used to report the selected vector and its derivative in the object's VVLH(CBI) axes. The vector must be defined in the Vector Geometry Tool. |
STK Programming Interface 11.0.1