void gfrfov_c ( ConstSpiceChar * inst,
ConstSpiceDouble raydir [3],
ConstSpiceChar * rframe,
ConstSpiceChar * abcorr,
ConstSpiceChar * obsrvr,
SpiceDouble step,
SpiceCell * cnfine,
SpiceCell * result )
Determine time intervals when a specified ray intersects the
space bounded by the field-of-view (FOV) of a specified
instrument.
CK
FRAMES
GF
KERNEL
NAIF_IDS
PCK
SPK
TIME
WINDOWS
EVENT
FOV
GEOMETRY
INSTRUMENT
SEARCH
WINDOW
VARIABLE I/O DESCRIPTION
--------------- --- ------------------------------------------------
SPICE_GF_MARGIN P Minimum complement of FOV cone angle.
SPICE_GF_CNVTOL P Convergence tolerance.
SPICE_GF_MAXVRT P Maximum number of FOV boundary vertices.
inst I Name of the instrument.
raydir I Ray's direction vector.
rframe I Reference frame of ray's direction vector.
abcorr I Aberration correction flag.
obsrvr I Name of the observing body.
step I Step size in seconds for finding FOV events.
cnfine I-O SPICE window to which the search is restricted.
result O SPICE window containing results.
inst indicates the name of an instrument, such as a
spacecraft-mounted framing camera, the field of view
(FOV) of which is to be used for an target intersection
search: the direction from the observer to a target
is represented by a ray, and times when the specified
ray intersects the region of space bounded by the FOV
are sought.
The position of the instrument designated by `inst' is
considered to coincide with that of the ephemeris
object designated by the input argument `obsrvr' (see
description below).
`inst' must have a corresponding NAIF ID and a frame
defined, as is normally done in a frame kernel. It
must also have an associated reference frame and a FOV
shape, boresight and boundary vertices (or reference
vector and reference angles) defined, as is usually
done in an instrument kernel.
See the header of the CSPICE routine getfov_c for a
description of the required parameters associated with
an instrument.
raydir is the direction vector associated with a ray
representing a target. The ray emanates from the
location of the ephemeris object designated by the
input argument `obsrvr' and is expressed relative to the
reference frame designated by `rframe' (see descriptions
below).
rframe is the name of the reference frame associated with
the input ray's direction vector `raydir'.
Since light time corrections are not supported for
rays, the orientation of the frame is always evaluated
at the epoch associated with the observer, as opposed
to the epoch associated with the light-time corrected
position of the frame center.
Case and leading or trailing blanks bracketing a
non-blank frame name are not significant in the string
`rframe'.
abcorr indicates the aberration corrections to be applied
when computing the ray's direction.
The supported aberration correction options are
"NONE" No correction.
"S" Stellar aberration correction,
reception case.
"XS" Stellar aberration correction,
transmission case.
For detailed information, see the geometry finder
required reading, gf.req.
Case, leading and trailing blanks are not significant
in the string `abcorr'.
obsrvr is the name of the body from which the target
represented by `raydir' is observed. The instrument
designated by `inst' is treated as if it were co-located
with the observer.
step is the step size to be used in the search. `step' must
be shorter than any interval, within the confinement
window, over which the specified condition is met. In
other words, `step' must be shorter than the shortest
visibility event that the user wishes to detect. `step'
also must be shorter than the minimum duration
separating any two visibility events. However, `step'
must not be *too* short, or the search will take an
unreasonable amount of time.
The choice of `step' affects the completeness but not
the precision of solutions found by this routine; the
precision is controlled by the convergence tolerance.
See the discussion of the parameter SPICE_GF_CNVTOL for
details.
`step' has units of seconds.
cnfine is a SPICE window that confines the time period over
which the specified search is conducted. `cnfine' may
consist of a single interval or a collection of
intervals.
The endpoints of the time intervals comprising `cnfine'
are interpreted as seconds past J2000 TDB.
See the Examples section below for a code example
that shows how to create a confinement window.
cnfine is the input confinement window, updated if necessary
so the control area of its data array indicates the
window's size and cardinality. The window data are
unchanged.
result is a SPICE window representing the set of time
intervals, within the confinement period, when the
input ray is "visible"; that is, when the ray is
contained in the space bounded by the specified
instrument's field of view.
The endpoints of the time intervals comprising `result'
are interpreted as seconds past J2000 TDB.
If `result' is non-empty on input, its contents
will be discarded before gfrfov_c conducts its
search.
All parameters described here are declared in the header file
SpiceGF.h. See that file for parameter values.
SPICE_GF_CNVTOL
is the convergence tolerance used for finding endpoints
of the intervals comprising the result window.
SPICE_GF_CNVTOL is used to determine when binary searches
for roots should terminate: when a root is bracketed
within an interval of length SPICE_GF_CNVTOL, the root is
considered to have been found.
The accuracy, as opposed to precision, of roots found
by this routine depends on the accuracy of the input
data. In most cases, the accuracy of solutions will be
inferior to their precision.
SPICE_GF_MAXVRT
is the maximum number of vertices that may be used
to define the boundary of the specified instrument's
field of view.
SPICE_GF_MARGIN
is a small positive number used to constrain the
orientation of the boundary vectors of polygonal
FOVs. Such FOVs must satisfy the following constraints:
1) The boundary vectors must be contained within
a right circular cone of angular radius less
than than (pi/2) - SPICE_GF_MARGIN radians; in other
words, there must be a vector A such that all
boundary vectors have angular separation from
A of less than (pi/2)-SPICE_GF_MARGIN radians.
2) There must be a pair of boundary vectors U, V
such that all other boundary vectors lie in the
same half space bounded by the plane containing U
and V. Furthermore, all other boundary vectors
must have orthogonal projections onto a specific
plane normal to this plane (the normal plane
contains the angle bisector defined by U and V)
such that the projections have angular separation
of at least 2*SPICE_GF_MARGIN radians from the
plane spanned by U and V.
1) In order for this routine to produce correct results,
the step size must be appropriate for the problem at hand.
Step sizes that are too large may cause this routine to miss
roots; step sizes that are too small may cause this routine
to run unacceptably slowly and in some cases, find spurious
roots.
This routine does not diagnose invalid step sizes, except
that if the step size is non-positive, the error
SPICE(INVALIDSTEPSIZE) will be signaled.
2) Due to numerical errors, in particular,
- Truncation error in time values
- Finite tolerance value
- Errors in computed geometric quantities
it is *normal* for the condition of interest to not always be
satisfied near the endpoints of the intervals comprising the
result window.
The result window may need to be contracted slightly by the
caller to achieve desired results. The SPICE window routine
WNCOND can be used to contract the result window.
3) If the observer's name cannot be mapped to an ID code, the
error SPICE(IDCODENOTFOUND) is signaled.
4) If the aberration correction flag calls for light time
correction, the error SPICE(INVALIDOPTION) is signaled.
5) If the ray's direction vector is zero, the error
SPICE(ZEROVECTOR) is signaled.
6) If the instrument name `inst' does not have corresponding NAIF
ID code, the error will be diagnosed by a routine in the call
tree of this routine.
7) If the FOV parameters of the instrument are not present in
the kernel pool, the error will be be diagnosed by routines
in the call tree of this routine.
8) If the FOV boundary has more than SPICE_GF_MAXVRT vertices, the error
will be be diagnosed by routines in the call tree of this
routine.
9) If the instrument FOV is polygonal, and this routine cannot
find a ray R emanating from the FOV vertex such that maximum
angular separation of R and any FOV boundary vector is within
the limit (pi/2)-SPICE_GF_MARGIN radians, the error will be diagnosed
by a routine in the call tree of this routine. If the FOV
is any other shape, the same error check will be applied with
the instrument boresight vector serving the role of R.
10) If the loaded kernels provide insufficient data to compute a
requested state vector, the error will be diagnosed by a
routine in the call tree of this routine.
11) If an error occurs while reading an SPK or other kernel file,
the error will be diagnosed by a routine in the call tree
of this routine.
12) If the output SPICE window `result' has insufficient capacity
to contain the number of intervals on which the specified
visibility condition is met, the error will be diagnosed
by a routine in the call tree of this routine. If the result
window has size less than 2, the error SPICE(WINDOWTOOSMALL)
will be signaled by this routine.
13) If any input string argument pointer is null, the error
SPICE(NULLPOINTER) will be signaled.
14) If any input string argument other than `tframe' is empty, the
error SPICE(EMPTYSTRING) will be signaled.
Appropriate SPICE kernels must be loaded by the calling program
before this routine is called.
The following data are required:
- SPK data: ephemeris data for the observer for the period
defined by the confinement window `cnfine' must be loaded.
If aberration corrections are used, the state of the
observer relative to the solar system barycenter must be
calculable from the available ephemeris data. Typically
ephemeris data are made available by loading one or more SPK
files via furnsh_c.
- Data defining the reference frame associated with the
instrument designated by `inst' must be available in the kernel
pool. Additionally the name `inst' must be associated with an
ID code. Normally these data are made available by loading a
frame kernel via furnsh_c.
- IK data: the kernel pool must contain data such that
the CSPICE routine getfov_c may be called to obtain
parameters for `inst'. Normally such data are provided by
an IK via furnsh_c.
The following data may be required:
- CK data: if the instrument frame is fixed to a spacecraft,
at least one CK file will be needed to permit transformation
of vectors between that frame and the J2000 frame.
- SCLK data: if a CK file is needed, an associated SCLK
kernel is required to enable conversion between encoded SCLK
(used to time-tag CK data) and barycentric dynamical time
(TDB).
- Since the input ray direction may be expressed in any
frame, FKs, CKs, SCLK kernels, PCKs, and SPKs may be
required to map the direction to the J2000 frame.
Kernel data are normally loaded once per program run, NOT every
time this routine is called.
This routine determines a set of one or more time intervals when
the specified ray in contained within the field of view of a
specified instrument. We'll use the term "visibility event" to
designate such an appearance. The set of time intervals resulting
from the search is returned as a SPICE window.
This routine provides a simpler, but less flexible, interface
than does the CSPICE routine gffove_c for conducting searches for
visibility events. Applications that require support for progress
reporting, interrupt handling, non-default step or refinement
functions, or non-default convergence tolerance should call
gffove_c rather than this routine.
Below we discuss in greater detail aspects of this routine's
solution process that are relevant to correct and efficient use
of this routine in user applications.
The Search Process
==================
The search for visibility events is treated as a search for state
transitions: times are sought when the state of the ray
changes from "not visible" to "visible" or vice versa.
Step Size
=========
Each interval of the confinement window is searched as follows:
first, the input step size is used to determine the time
separation at which the visibility state will be sampled.
Starting at the left endpoint of an interval, samples will be
taken at each step. If a state change is detected, a root has
been bracketed; at that point, the "root"--the time at which the
state change occurs---is found by a refinement process, for
example, via binary search.
Note that the optimal choice of step size depends on the lengths
of the intervals over which the visibility state is constant:
the step size should be shorter than the shortest visibility event
duration and the shortest period between visibility events, within
the confinement window.
Having some knowledge of the relative geometry of the ray and
observer can be a valuable aid in picking a reasonable step size.
In general, the user can compensate for lack of such knowledge by
picking a very short step size; the cost is increased computation
time.
Note that the step size is not related to the precision with which
the endpoints of the intervals of the result window are computed.
That precision level is controlled by the convergence tolerance.
Convergence Tolerance
=====================
Once a root has been bracketed, a refinement process is used to
narrow down the time interval within which the root must lie.
This refinement process terminates when the location of the root
has been determined to within an error margin called the
"convergence tolerance." The convergence tolerance used by this
routine is set via the parameter SPICE_GF_CNVTOL.
The value of SPICE_GF_CNVTOL is set to a "tight" value so that the
tolerance doesn't become the limiting factor in the accuracy of
solutions found by this routine. In general the accuracy of input
data will be the limiting factor.
To use a different tolerance value, a lower-level GF routine such
as gffove_c must be called. Making the tolerance tighter than
SPICE_GF_CNVTOL is unlikely to be useful, since the results are unlikely
to be more accurate. Making the tolerance looser will speed up
searches somewhat, since a few convergence steps will be omitted.
However, in most cases, the step size is likely to have a much
greater effect on processing time than would the convergence
tolerance.
The Confinement Window
======================
The simplest use of the confinement window is to specify a time
interval within which a solution is sought. However, the confinement
window can, in some cases, be used to make searches more efficient.
Sometimes it's possible to do an efficient search to reduce the size
of the time period over which a relatively slow search of interest
must be performed. For an example, see the program CASCADE in the GF
Example Programs chapter of the GF Required Reading, gf.req.
The numerical results shown for these examples may differ across
platforms. The results depend on the SPICE kernels used as
input, the compiler and supporting libraries, and the machine
specific arithmetic implementation.
1) This example is an extension of example #1 in the
header of
gftfov_c
The problem statement for that example is
Search for times when Saturn's satellite Phoebe is within the
FOV of the Cassini narrow angle camera (CASSINI_ISS_NAC). To
simplify the problem, restrict the search to a short time
period where continuous Cassini bus attitude data are
available.
Use a step size of 10 seconds to reduce chances of missing
short visibility events.
Here we search the same confinement window for times when a
selected background star is visible. We use the FOV of the
Cassini ISS wide angle camera (CASSINI_ISS_WAC) to enhance the
probability of viewing the star.
The star we'll use has catalog number 6000 in the Hipparcos
Catalog. The star's J2000 right ascension and declination, proper
motion, and parallax are taken from that catalog.
Use the meta-kernel from the gftfov_c example:
KPL/MK
File name: gftfov_ex1.tm
This meta-kernel is intended to support operation of SPICE
example programs. The kernels shown here should not be
assumed to contain adequate or correct versions of data
required by SPICE-based user applications.
In order for an application to use this meta-kernel, the
kernels referenced here must be present in the user's
current working directory.
The names and contents of the kernels referenced
by this meta-kernel are as follows:
File name Contents
--------- --------
naif0009.tls Leapseconds
cpck05Mar2004.tpc Satellite orientation and
radii
981005_PLTEPH-DE405S.bsp Planetary ephemeris
020514_SE_SAT105.bsp Satellite ephemeris
030201AP_SK_SM546_T45.bsp Spacecraft ephemeris
cas_v37.tf Cassini FK
04135_04171pc_psiv2.bc Cassini bus CK
cas00084.tsc Cassini SCLK kernel
cas_iss_v09.ti Cassini IK
\begindata
KERNELS_TO_LOAD = ( 'naif0009.tls',
'cpck05Mar2004.tpc',
'981005_PLTEPH-DE405S.bsp',
'020514_SE_SAT105.bsp',
'030201AP_SK_SM546_T45.bsp',
'cas_v37.tf',
'04135_04171pc_psiv2.bc',
'cas00084.tsc',
'cas_iss_v09.ti' )
\begintext
Example code begins here.
#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include "SpiceUsr.h"
#include "SpiceZmc.h"
int main()
{
/.
PROGRAM EX1
./
/.
Local constants
./
#define AU 149597870.693
#define META "gftfov_ex1.tm"
#define TIMFMT "YYYY-MON-DD HR:MN:SC.######::TDB (TDB)"
#define TIMLEN 41
#define MAXWIN 10000
/.
Local variables
./
SPICEDOUBLE_CELL ( cnfine, MAXWIN );
SPICEDOUBLE_CELL ( result, MAXWIN );
SpiceChar * abcorr;
SpiceChar * inst;
SpiceChar * obsrvr;
SpiceChar * rframe;
SpiceChar timstr [2][ TIMLEN ];
SpiceDouble dec;
SpiceDouble dec_deg;
SpiceDouble dec_deg_0;
SpiceDouble dec_epoch;
SpiceDouble dec_pm;
SpiceDouble dtdec;
SpiceDouble dtra;
SpiceDouble endpt [2];
SpiceDouble et0;
SpiceDouble et1;
SpiceDouble lt;
SpiceDouble parallax;
SpiceDouble parallax_deg;
SpiceDouble pos [3];
SpiceDouble ra;
SpiceDouble ra_deg;
SpiceDouble ra_deg_0;
SpiceDouble ra_epoch;
SpiceDouble ra_pm;
SpiceDouble raydir [3];
SpiceDouble stardist;
SpiceDouble starpos [3];
SpiceDouble stepsz;
SpiceDouble t;
SpiceInt catno;
SpiceInt i;
SpiceInt j;
SpiceInt n;
/.
Load kernels.
./
furnsh_c ( META );
/.
Insert search time interval bounds into the
confinement window.
./
str2et_c ( "2004 JUN 11 06:30:00 TDB", &et0 );
str2et_c ( "2004 JUN 11 12:00:00 TDB", &et1 );
wninsd_c ( et0, et1, &cnfine );
/.
Initialize inputs for the search.
./
inst = "CASSINI_ISS_WAC";
/.
Create a unit direction vector pointing from observer to star.
We'll assume the direction is constant during the confinement
window, and we'll use et0 as the epoch at which to compute the
direction from the spacecraft to the star.
The data below are for the star with catalog number 6000
in the Hipparcos catalog. Angular units are degrees; epochs
have units of Julian years and have a reference epoch of J1950.
The reference frame is J2000.
./
catno = 6000;
parallax_deg = 0.000001056;
ra_deg_0 = 19.290789927;
ra_pm = -0.000000720;
ra_epoch = 41.2000;
dec_deg_0 = 2.015271007;
dec_pm = 0.000001814;
dec_epoch = 41.1300;
rframe = "J2000";
/.
Correct the star's direction for proper motion.
The argument t represents et0 as Julian years past J1950.
./
t = et0/jyear_c() + ( j2000_c()- j1950_c() )/365.25;
dtra = t - ra_epoch;
dtdec = t - dec_epoch;
ra_deg = ra_deg_0 + dtra * ra_pm;
dec_deg = dec_deg_0 + dtdec * dec_pm;
ra = ra_deg * rpd_c();
dec = dec_deg * rpd_c();
radrec_c ( 1.0, ra, dec, starpos );
/.
Correct star position for parallax applicable at
the Cassini orbiter's position. (The parallax effect
is negligible in this case; we're simply demonstrating
the computation.)
./
parallax = parallax_deg * rpd_c();
stardist = AU / tan(parallax);
/.
Scale the star's direction vector by its distance from
the solar system barycenter. Subtract off the position
of the spacecraft relative to the solar system barycenter;
the result is the ray's direction vector.
./
vscl_c ( stardist, starpos, starpos );
spkpos_c ( "cassini", et0, "J2000", "NONE",
"solar system barycenter", pos, < );
vsub_c ( starpos, pos, raydir );
/.
Correct the star direction for stellar aberration when
we conduct the search.
./
abcorr = "S";
obsrvr = "CASSINI";
stepsz = 10.0;
printf ( "\n"
" Instrument: %s\n"
" Star's catalog number: %d\n"
"\n",
inst,
(int)catno );
/.
Perform the search.
./
gfrfov_c ( inst, raydir, rframe, abcorr,
obsrvr, stepsz, &cnfine, &result );
n = wncard_c ( &result );
if ( n == 0 )
{
printf ( "No FOV intersection found.\n" );
}
else
{
printf ( " Visibility start time Stop time\n" );
for ( i = 0; i < n; i++ )
{
wnfetd_c ( &result, i, endpt, endpt+1 );
for ( j = 0; j < 2; j++ )
{
timout_c ( endpt[j], TIMFMT, TIMLEN, timstr[j] );
}
printf ( " %s %s\n",
timstr[0],
timstr[1] );
}
}
printf ( "\n" );
return ( 0 );
}
When this program was executed on a PC/Linux/gcc platform, the
output was:
Instrument: CASSINI_ISS_WAC
Star's catalog number: 6000
Visibility start time Stop time
2004-JUN-11 06:30:00.000000 (TDB) 2004-JUN-11 12:00:00.000000 (TDB)
The star is visible throughout the confinement window.
The kernel files to be used by gfrfov_c must be loaded (normally via
the CSPICE routine furnsh_c) before gfrfov_c is called.
None.
N.J. Bachman (JPL)
L.S. Elson (JPL)
E.D. Wright (JPL)
-CSPICE Version 1.0.1, 12-JUL-2016 (EDW)
Edit to example program to use "%d" with explicit casts
to int for printing SpiceInts with printf.
-CSPICE Version 1.0.0, 12-FEB-2009 (NJB) (LSE) (EDW)
GF ray in instrument FOV search
Link to routine gfrfov_c source file gfrfov_c.c
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