Spacecraft Event Time: Difference between revisions

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Spacecraft Event Time (SCET) is the spacecraft-local time for events that happen at the spacecraft. SCET is used for command programs that control the timing of spacecraft operations and to identify when specific events occur on the spacecraft relative to Earth time.

SCET versus Earth time

Since signals between the spacecraft and Earth are limited to the speed of light, there is a delay between the time an event happens on the spacecraft (such as the transmission of data taken from an instrument reading) and the time that a signal reporting the event reaches Earth. Similarly, there is a delay between when instructions are sent from Earth and when the spacecraft receives the instructions. The length of delay is related to the distance between the sending and receiving points. Failure to take this delay into account could result in inaccurate data or mistakes in spacecraft control.

Calculating SCET

Determining the Spacecraft Event Time involves taking the time at Earth and adding or subtracting the signal travel time, depending on whether the signal is being sent to or received from the spacecraft. For events transmitted from the spacecraft to Earth, the SCET of an event on the spacecraft can be defined as equal to the ERT (Earth-Received Time) minus the OWLT (One-Way Light Time).^[1] For events transmitted from Earth to the spacecraft, the calculation is TRM (transmission time^[2]) plus OWLT. For example, if a signal were received on Earth at exactly 11:00 UTC from a spacecraft showing that it had just completed a maneuvering thrust, but the spacecraft was four light-hours away from Earth (the distance of the New Horizons spacecraft at one point as it approaches Pluto), the SCET time of the thrust maneuver would have been four hours earlier, at 07:00.

Spacecraft Event Time in UTC is also known as Orbiter UTC, and Earth-received time as Ground UTC.

Spacecraft control

Since it takes time for a radio transmission to reach a spacecraft from Earth, the usual operation of a spacecraft is controlled with an uploaded command script containing SCET markers to ensure a certain timeline of events. Because of the delay between the sending of instructions from Earth and their receipt and execution by the spacecraft, real-time commanding of robotic spacecraft is done rarely: usually only in response to an emergency event, when changes in spacecraft operations must be made as soon as possible. For example, a spacecraft could be instructed to go into safe mode to protect it during a coronal mass ejection (CME) from the Sun.

Presentation format

Spacecraft event times stored in relation to instrument data from spacecraft events (e.g. images) are generally presented in ISO 8601 using one of the following formats:

CCYY-MM-DDTHH:MM:SS.sssZ (preferred format)
CCYY-DDDTHH:MM:SS.sssZ

However, the trailing Z (which indicates that the time is given in UTC) is often assumed/omitted.^[3]

Notes

^ Basics of Space Flight Glossary; JPL/NASA
^ "Synonyms for Transmission Time". Thesaurus.net.
^ Data Standards, PDS/NASA

References

[1] Basics of Space Flight Glossary; JPL/NASA

[2] "Synonyms for Transmission Time". Thesaurus.net.

[3] Data Standards, PDS/NASA

[1]

[2]

[3]

@@ Line 1: / Line 1: @@
-'''Spacecraft Event Time (SCET)''' is the spacecraft-local time for events that happen at the spacecraft.  SCET is used for command programs that control the timing of spacecraft operations and to identify when specific events occur on the spacecraft relative to Earth time.
+{{short description|Spacecraft-local time for events that happen at the spacecraft}}
+'''Spacecraft Event Time''' ('''SCET''') is the spacecraft-local time for events that happen at the spacecraft.  SCET is used for command programs that control the timing of spacecraft operations and to identify when specific events occur on the spacecraft relative to Earth time.
 ==SCET versus Earth time==
@@ Line 7: / Line 8: @@
 ===Calculating SCET===
-Determining the Spacecraft Event Time involves taking the time at Earth and adding or subtracting the signal travel time, depending on whether the signal is being sent to or received from the spacecraft.  For events transmitted from the spacecraft to Earth, the SCET of an event on the spacecraft can be defined as equal to the ERT (Earth-Received Time) minus the OWLT (One-Way Light Time).<ref>Basics of Space Flight Glossary; JPL/NASA</ref>  For events transmitted from Earth to the spacecraft, the calculation is TRM ([http://www.memidex.com/transmission-time transmission time]) plus OWLT.  For example, if a signal were received on Earth at exactly 11:00 UTC from a spacecraft showing that it had just completed a maneuvering thrust, but the spacecraft was four light-hours away from Earth (the distance of the [[New Horizons]] spacecraft at one point as it approaches [[Pluto]]), the SCET time of the thrust maneuver would have been four hours earlier, at 07:00.
+Determining the Spacecraft Event Time involves taking the time at Earth and adding or subtracting the signal travel time, depending on whether the signal is being sent to or received from the spacecraft.  For events transmitted from the spacecraft to Earth, the SCET of an event on the spacecraft can be defined as equal to the ERT (Earth-Received Time) minus the OWLT (One-Way Light Time).<ref>Basics of Space Flight Glossary; JPL/NASA</ref>  For events transmitted from Earth to the spacecraft, the calculation is TRM (transmission time<ref>{{Cite web |title=Synonyms for Transmission Time |url=http://www.thesaurus.net/transmission%20time |website=Thesaurus.net |language=en}}</ref>) plus OWLT.  For example, if a signal were received on Earth at exactly 11:00 UTC from a spacecraft showing that it had just completed a maneuvering thrust, but the spacecraft was four light-hours away from Earth (the distance of the [[New Horizons]] spacecraft at one point as it approaches [[Pluto]]), the SCET time of the thrust maneuver would have been four hours earlier, at 07:00.
 '''Spacecraft Event Time''' in [[Coordinated Universal Time|UTC]] is also known as '''Orbiter UTC''', and Earth-received time as '''Ground UTC'''.
@@ Line 14: / Line 15: @@
 Since it takes time for a radio transmission to reach a spacecraft from [[Earth]], the usual operation of a spacecraft is controlled with an uploaded command script containing SCET markers to ensure a certain timeline of events. Because of the delay between the sending of instructions from Earth and their receipt and execution by the spacecraft, real-time commanding of robotic spacecraft is done rarely: usually only in response to an emergency event, when changes in spacecraft operations must be made as soon as possible.  For example, a spacecraft could be instructed to go into [[Safe mode (spacecraft)|safe mode]] to protect it during a [[Coronal mass ejection|coronal mass ejection (CME)]] from the [[Sun]].
+== Presentation format ==
+{{Main|ISO 8601}}
+Spacecraft event times stored in relation to instrument data from spacecraft events (e.g. images) are generally presented in [[ISO 8601]] using one of the following formats:
+* CCYY-MM-DDTHH:MM:SS.sssZ (preferred format)
+* CCYY-DDDTHH:MM:SS.sssZ
+However, the trailing Z (which indicates that the time is given in [[UTC]]) is often assumed/omitted.<ref>Data Standards, PDS/NASA</ref>
 == Notes ==
@@ Line 20: / Line 29: @@
 == References ==
 * [https://solarsystem.nasa.gov/basics/glossary/#S Basics of Space Flight Glossary, JPL/NASA]
+* [https://pds.nasa.gov/datastandards/pds3/standards/sr/stdref3.7/Chapter07.pdf Data Standards, PDS/NASA]
 {{Portal|Space flight}}
@@ Line 25: / Line 35: @@
 [[Category:Spaceflight concepts]]
 [[Category:Time scales]]
-{{spacecraft-stub}}