Observing Windows [Windows]

4.4 Observing Windows [Windows]

The observability of solar system targets is often constrained by various geometrical conditions (e.g. satellites observed at greatest elongation from their parent planet), or the desirability of coordinated observations (e.g. the observation of a planetary system at the same time as a spacecraft encounter with the system). The Window field is provided to allow the proposer to define geometric and timing constraints. The proposer should specify any constraints necessary to achieve the scientific objectives of the program. However, care should be taken in specifying constraints, since they can render the observations difficult or impossible to schedule.

In general, “windows” which define when the target is visible to HST need not be explicitly identified, since these windows will be calculated by the STScI. Windows in this category include:

•	Times when the target is not occulted by the Earth.

•	Times when the target is not too close to the Sun, Moon, or the bright Earth limb.

•	If the target is a planetary satellite, the times when it is not occulted by any other object in the planetary system.

•	If the target is a surface feature on a body, the times when the feature is within the field of view of the HST (i.e. the feature is on that part of the body “facing” HST).

If you require other specific conditions to be satisfied (e.g. to observe when a satellite is near elongation, to observe when the central meridian longitude lies in a particular range, etc.), then these conditions must be specified in the Window field. However, the proposer must recognize that proposer-supplied windows might not overlap with the “visibility” windows defined above (calculated by STScI), in which case the observation cannot be scheduled. Note that atmospheric drag and other effects make it difficult to predict the exact position of the HST in its orbit far in advance. This leads to uncertainty in the exact timing of the “visibility” windows more than two or three months in advance.

The various keywords used to define windows are given in the following table and described in detail below.

Table 4.11: Keywords for Observing Windows
SEP	angular separation of two bodies as viewed from a third body
RANGE	distance between two bodies in AU
A_VEL	angular velocity in arcsec/sec
R_VEL	radial velocity of one body relative to another in km/sec
SIZE	angular diameter of one body as seen from another in arc-sec
PHASE	phase of one body as seen from another
OCC	when two bodies overlap as viewed from a third body
TRANSIT	when one body crosses another as viewed from a third body
ECL	when one body is in the shadow of another body
CML	central meridian longitude
OLG	orbital longitude

Table 4.12: Operators for Observing Windows
LT	short for less than
GT	short for greater than
MAX	short for local maximum (i.e. inflection point). Accompanied by a non-zero tolerance value.
MIN	short for local minimum (i.e. inflection point). Accompanied by a non-zero tolerance value.
NOT	logical complement. May be used to specify when a condition does not exist. Each of the above keywords may be preceded by the NOT operator.

The operator NOT, if present, should precede the keyword for the solar system target observing window, as in these examples:

NOT SEP OF IO JUPITER FROM EARTH GT 10

NOT RANGE JUPITER EARTH GT 10

NOT A_VEL IO RELATIVE JUPITER FROM EARTH GT 10