Difference between revisions of "The Planck mission WiP"
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Planck is a space telescope of the European Space Agency designed to answer key cosmological questions. | Planck is a space telescope of the European Space Agency designed to answer key cosmological questions. | ||
− | Its main goal is to determine the geometry and content of the Universe, and | + | Its main goal is to determine the geometry and content of the Universe, and to distinguish between specific theories describing the birth and evolution of the Universe. To achieve this ambitious objective, it observed the [http://pdg.lbl.gov/2013/reviews/rpp2013-rev-cosmic-microwave-background.pdf cosmic microwave background radiation] (CMB), emitted about 14 billion years ago, around 380,000 years after the Big Bang. The CMB permeates the Universe and is observed to have a blackbody spectrum with a temperature of about 2.7 K. Small deviations from isotropy encode a wealth of information on the properties of the Universe in its infancy. The objective of Planck is to measure these properties with an unprecedented accuracy and level of detail. |
− | [[file:Planck_Logos.jpg|thumb|300px|The Planck collaboration institutes.]] | + | [[file:Planck_Logos.jpg|thumb|300px|The Planck collaboration institutes and agencies.]] |
As with all ESA scientific missions, Planck was developed in a partnership with the | As with all ESA scientific missions, Planck was developed in a partnership with the | ||
− | European scientific community. [[Planck Collaboration|Two consortia of scientific institutes]], each led by a Principal | + | European scientific community. [[Planck Collaboration|Two consortia of scientific institutes]] (supported by several funding agencies), |
− | Investigator, developed and delivered to ESA | + | each led by a Principal Investigator, developed and delivered to ESA an instrument designed specifically for |
Planck. Each of these instruments targets a specific number of wavelength bands within the | Planck. Each of these instruments targets a specific number of wavelength bands within the | ||
− | range | + | range where the CMB is observable. Together, the two instruments are capable of collecting |
− | data of | + | data of sufficient quality to measure the CMB signal and distinguish it from other confusing |
− | sources. A large telescope | + | sources. A large telescope collected the light from the sky and delivered it to the instruments |
for measurement and analysis. The reflectors of the Planck telescope were developed and | for measurement and analysis. The reflectors of the Planck telescope were developed and | ||
− | delivered to ESA by a Danish consortium of institutes. | + | delivered to ESA by a Danish consortium of institutes. NASA also contributed significantly to Planck. |
− | ESA retains overall management of the project, | + | ESA retains overall management of the project, including the responsibility to develop and procure the spacecraft, integrate |
− | the instruments into the spacecraft, and | + | the instruments into the spacecraft, and launch and operate it. Planck was launched on May 14th 2009 on an Ariane 5 rocket, |
− | Space Observatory. After launch, they were both | + | together with the Herschel Space Observatory. After launch, they were both |
− | placed into orbits around the | + | placed into orbits around the second Lagrange point of the Sun-Earth system, located about 1.5 million km from the Earth. From that far |
vantage point, Planck swept the sky regularly in large swaths, and covered it fully | vantage point, Planck swept the sky regularly in large swaths, and covered it fully | ||
− | about | + | about five times for the HFI and eight times for the LFI. |
Each of the two instrument consortia operated their respective instrument and processed | Each of the two instrument consortia operated their respective instrument and processed | ||
− | all the data into usable scientific products. At | + | all the data into usable scientific products. At specific intervals the consortia delivered the data products to ESA, which archives them |
and distributes them to the community. | and distributes them to the community. | ||
− | The last command to the Planck satellite was sent on the | + | The last command to the Planck satellite was sent on the 23 October 2013, marking the end of operations. |
− | [[file:PlanckMissionTimelineV2.png|thumb|480px| | + | [[file:PlanckMissionTimelineV2.png|thumb|480px|Timeline of the Planck operations and archiving.]] |
== Early operations and transfer to orbit == | == Early operations and transfer to orbit == | ||
Line 41: | Line 41: | ||
axis within 1.6 % of prediction), on a trajectory towards | axis within 1.6 % of prediction), on a trajectory towards | ||
the second Lagrangian point of the Earth-Sun system (L2). The orbit describes a Lissajous trajectory | the second Lagrangian point of the Earth-Sun system (L2). The orbit describes a Lissajous trajectory | ||
− | around L2 with a | + | around L2 with a roughly six month period that avoids crossing |
− | the Earth penumbra for at least | + | the Earth penumbra for at least four years. |
− | [[file:HerschelPlanckLaunch.jpg|thumb|200px| | + | [[file:HerschelPlanckLaunch.jpg|thumb|200px|Herschel and Planck spacecraft in the launch vehicle configuration.]] |
− | [[file:PLANCK_HERSCHEL_LAUNCH.jpg|thumb|200px| | + | [[file:PLANCK_HERSCHEL_LAUNCH.jpg|thumb|200px|Herschel and Planck launch by an Ariane 5 ECA rocket in May 2009.]] |
After release from the rocket, three large manoeuvres were | After release from the rocket, three large manoeuvres were | ||
carried out to place Planck in its intended final orbit. | carried out to place Planck in its intended final orbit. | ||
Once in its final orbit, very small manoeuvres were required at approximately | Once in its final orbit, very small manoeuvres were required at approximately | ||
− | monthly intervals (1 | + | monthly intervals (1 m/s per year) to keep Planck |
from drifting away from its intended path around L2. The attitude | from drifting away from its intended path around L2. The attitude | ||
− | manoeuvres required to follow the scanning strategy | + | manoeuvres required to follow the scanning strategy need |
− | about 2.6 | + | about 2.6 m/s per year. Overall, the excellent performance |
− | of launch and orbit manoeuvres | + | of launch and orbit manoeuvres led to a large amount of fuel remaining on board at end of mission operations. |
Planck started cooling down radiatively shortly after launch. | Planck started cooling down radiatively shortly after launch. | ||
Line 72: | Line 72: | ||
The first period of operations focussed on commissioning activities, | The first period of operations focussed on commissioning activities, | ||
i.e., functional check-out procedures of all sub-systems and | i.e., functional check-out procedures of all sub-systems and | ||
− | instruments of the Planck spacecraft in preparation for running | + | instruments of the Planck spacecraft, in preparation for running |
science operations related to calibration and performance verification | science operations related to calibration and performance verification | ||
of the payload. Planning for commissioning operations | of the payload. Planning for commissioning operations | ||
Line 98: | Line 98: | ||
planned activities, it was concluded that the two instruments were fully tuned and ready for routine | planned activities, it was concluded that the two instruments were fully tuned and ready for routine | ||
operations. No further parameter tuning was expected | operations. No further parameter tuning was expected | ||
− | to be needed, except for the sorption cooler, which | + | to be needed, except for the sorption cooler, which required |
a weekly change in operational parameters. | a weekly change in operational parameters. | ||
The scientific performance parameters of both instruments | The scientific performance parameters of both instruments | ||
− | + | were in most respects as had been measured on the ground before | |
launch. The only significant exception was that, due to | launch. The only significant exception was that, due to | ||
the high level of Galactic cosmic rays, the bolometers of HFI | the high level of Galactic cosmic rays, the bolometers of HFI | ||
were detecting a higher number of glitches than expected, | were detecting a higher number of glitches than expected, | ||
− | causing a modest ( | + | causing a modest (about 10%) increase of systematic effects on |
− | their noise | + | their noise levels. The satellite did not introduce any major systematic effects |
into the science data. In particular, the telemetry transponder | into the science data. In particular, the telemetry transponder | ||
did not result in radio-frequency interference, which implies | did not result in radio-frequency interference, which implies | ||
− | that the data acquired during visibility periods is | + | that the data acquired during visibility periods is usable for |
science. | science. | ||
Line 127: | Line 127: | ||
== Routine operations phase == | == Routine operations phase == | ||
− | The routine operations phase of Planck is | + | The routine operations phase of Planck is characterized by continuous |
and stable scanning of the sky and data acquisition by | and stable scanning of the sky and data acquisition by | ||
− | LFI and HFI. It started with the FLS on 13 August | + | LFI and HFI. It started with the FLS on 13 August 2009. |
− | The Planck satellite | + | The Planck satellite generated (and stored on-board) data |
− | continuously at the following typical rates: 21 kilobit | + | continuously at the following typical rates: 21 kilobit/s (kbps) |
of house-keeping (HK) data from all on-board sources, 44 kbps | of house-keeping (HK) data from all on-board sources, 44 kbps | ||
of LFI science data and 72 kbps of HFI science data. The data | of LFI science data and 72 kbps of HFI science data. The data | ||
− | + | were brought to ground in a daily pass of approximately 3 h duration. | |
− | Besides the data downloads, the passes also | + | Besides the data downloads, the passes also acquired realtime |
HK and a 20 min period of real-time science (used to monitor | HK and a 20 min period of real-time science (used to monitor | ||
− | instrument performance during the pass). Planck | + | instrument performance during the pass). Planck utilized the |
two ESA deep-space ground stations in New Norcia (Australia) | two ESA deep-space ground stations in New Norcia (Australia) | ||
and Cebreros (Spain). Scheduling of the daily | and Cebreros (Spain). Scheduling of the daily | ||
− | telecommunication period | + | telecommunication period was quite stable, with small perturbations |
due to the need to coordinate the use of the antenna with | due to the need to coordinate the use of the antenna with | ||
other ESA satellites (in particular Herschel). | other ESA satellites (in particular Herschel). | ||
− | At the ground station the telemetry | + | At the ground station the telemetry was received by redundant |
− | chains of front-end/back-end equipment. The data | + | chains of front-end/back-end equipment. The data flowed to the |
mission operations control centre (MOC) located at ESOC in | mission operations control centre (MOC) located at ESOC in | ||
− | Darmstadt (Germany), where | + | Darmstadt (Germany), where they were processed by redundant mission |
control software (MCS) installations and made available to | control software (MCS) installations and made available to | ||
the science ground segment. To reduce bandwidth requirements | the science ground segment. To reduce bandwidth requirements | ||
between the station and ESOC only one set of science telemetry | between the station and ESOC only one set of science telemetry | ||
− | + | was usually transferred. Software was run post-pass to check the | |
− | completeness of the data. This software check | + | completeness of the data. This software check was also used to |
− | build a catalogue of data completeness, which | + | build a catalogue of data completeness, which was used by the science |
ground segment to control its own data transfer process. | ground segment to control its own data transfer process. | ||
− | Where gaps | + | Where gaps were detected, attempts to fill them were made as an |
offline activity (normally next working day), the first step being | offline activity (normally next working day), the first step being | ||
to attempt to reflow the relevant data from station. Early in | to attempt to reflow the relevant data from station. Early in | ||
the mission these gaps were more frequent, with some hundreds | the mission these gaps were more frequent, with some hundreds | ||
of packets affected per week (impact on data return of order | of packets affected per week (impact on data return of order | ||
− | 50 ppm) due principally to a combination of software problems | + | 50 ppm), due principally to a combination of software problems |
with the data ingestion and distribution in the MCS, and imperfect | with the data ingestion and distribution in the MCS, and imperfect | ||
behaviour of the software gap check. Software updates implemented | behaviour of the software gap check. Software updates implemented | ||
− | during the mission | + | during the mission improved the situation, such |
− | that gaps | + | that gaps became much rarer, with a total impact on data return well |
below 1 ppm. | below 1 ppm. | ||
− | Redump of data from the spacecraft | + | Redump of data from the spacecraft was attempted when there |
− | + | had been losses in the space link. This was only necessary | |
− | on very few occasions. In each case the spacecraft redump | + | on very few occasions. In each case the spacecraft redump |
successfully recovered all the data. | successfully recovered all the data. | ||
All the data downloaded from the satellite, and processed | All the data downloaded from the satellite, and processed | ||
− | products such as filtered attitude information, | + | products such as filtered attitude information, were made available |
each day for retrieval from the MOC by the LFI and HFI | each day for retrieval from the MOC by the LFI and HFI | ||
− | + | data processing centres (DPCs). | |
− | The scanning strategy | + | The scanning strategy was the following: the spin axis follows a cycloidal path on the sky by step-wise displacements of 2 arcmin |
approximately every 50 min. The dwell time (i.e., the duration of | approximately every 50 min. The dwell time (i.e., the duration of | ||
− | stable data acquisition at each pointing) | + | stable data acquisition at each pointing) varied sinusoidally |
− | by a factor of | + | by a factor of approximately 2. |
− | Planck’s scanning strategy | + | Planck’s scanning strategy resulted |
in significantly inhomogeneous depth of integration time | in significantly inhomogeneous depth of integration time | ||
− | across the sky; the areas near the ecliptic poles | + | across the sky; the areas near the ecliptic poles were observed |
with greater depth than all others. | with greater depth than all others. | ||
The scanning strategy for the second year of Routine | The scanning strategy for the second year of Routine | ||
Operations was exactly the same as for the | Operations was exactly the same as for the | ||
− | first year, except that all pointings | + | first year, except that all pointings were shifted by 1 arcmin along |
the cross-scanning direction, in order to provide finer sky sampling | the cross-scanning direction, in order to provide finer sky sampling | ||
for the highest frequency detectors when combining two | for the highest frequency detectors when combining two | ||
years of observations. | years of observations. | ||
− | The remaining two years of operations including | + | The remaining two years of operations, including Surveys 6 to 8 of the LFI-only phase, made use of a change in the cycloid phase of 90 degrees in order to spread out scanning directions over the sky. |
Orbit maintenance manoeuvres were carried out at approximately | Orbit maintenance manoeuvres were carried out at approximately | ||
Line 203: | Line 203: | ||
pre-planned pointings to be carried out. | pre-planned pointings to be carried out. | ||
− | While the Planck detectors | + | While the Planck detectors were scanning the sky, they also naturally |
− | + | observed celestial calibrators. The main objects used for this | |
− | purpose | + | purpose were the Crab Nebula, and the bright planets Mars, Jupiter, and Saturn. |
==Major operational milestones== | ==Major operational milestones== | ||
Line 212: | Line 212: | ||
time of 13:12 UT, on an Ariane 5 ECA rocket of Arianespace. | time of 13:12 UT, on an Ariane 5 ECA rocket of Arianespace. | ||
− | On 13 August 2009, Planck started its first all sky survey after successfully concluding its commissioning phase. | + | On 13 August 2009, Planck started its first all-sky survey after successfully concluding its commissioning phase. |
− | On 14 January 2012, Planck’s HFI completed its survey of the early Universe after running out of coolant as expected. Able to work at | + | On 14 January 2012, Planck’s HFI completed its survey of the early Universe after running out of coolant as expected. Able to work at higher temperatures, the LFI continued surveying the sky until 3 October 2013. |
On 4 October 2013 Planck ended its routine operations, after executing its last observation of the Crab Nebula, and started its decommissioning activities. | On 4 October 2013 Planck ended its routine operations, after executing its last observation of the Crab Nebula, and started its decommissioning activities. | ||
− | On 19 October 2013, the sorption cooler and the two instruments (LFI | + | On 19 October 2013, the sorption cooler and the two instruments (LFI and HFI) were switched off. |
The final command to the Planck satellite was sent on 23 October 2013, marking the end of operations. | The final command to the Planck satellite was sent on 23 October 2013, marking the end of operations. | ||
Line 224: | Line 224: | ||
==Contingencies== | ==Contingencies== | ||
− | The main unplanned events included the following | + | The main unplanned events included the following. |
− | * Very minor deviations from the scanning law | + | * Very minor deviations from the scanning law included occasional (on the average about once every two months) under-performance of the 1-N thrusters used for regular manoeuvres, which implied that the corresponding pointings were not at the intended locations. These deviations had typical amplitudes of 30 arcsec, and had no significant impact on the coverage map. |
* The thruster heaters were unintentionally turned off between 31 August and 16 September 2009 (the so-called “catbed” event). | * The thruster heaters were unintentionally turned off between 31 August and 16 September 2009 (the so-called “catbed” event). | ||
Line 234: | Line 234: | ||
* As planned, the RF transmitter was initially turned on and off every day in synchrony with the daily visibility window, in order to reduce potential interference by the transmitter on the scientific data. The induced daily temperature variation had a measurable effect throughout the satellite. An important effect was on the temperature of the 4He-JT cooler compressors, which caused variations of the levels of the interference lines that they induce on the bolometer data (Planck HFI Core Team 2011a). Therefore the RF transmitter was left permanently on starting from 25 January 2010 (257 days after launch), which made a noticeable improvement on the daily temperature variations. | * As planned, the RF transmitter was initially turned on and off every day in synchrony with the daily visibility window, in order to reduce potential interference by the transmitter on the scientific data. The induced daily temperature variation had a measurable effect throughout the satellite. An important effect was on the temperature of the 4He-JT cooler compressors, which caused variations of the levels of the interference lines that they induce on the bolometer data (Planck HFI Core Team 2011a). Therefore the RF transmitter was left permanently on starting from 25 January 2010 (257 days after launch), which made a noticeable improvement on the daily temperature variations. | ||
− | * During the coverage period, the operational star tracker switched autonomously to the redundant unit on two occasions (11 January 2010 and 26 February 2010); the nominal star tracker was restored a short period later (3.37 and 12.75 h, respectively) by manual power-cycling. Although the science data taken during this period have normal quality, they have not been used because the redundant star tracker’s performance is not fully | + | * During the coverage period, the operational star tracker switched autonomously to the redundant unit on two occasions (11 January 2010 and 26 February 2010); the nominal star tracker was restored a short period later (3.37 and 12.75 h, respectively) by manual power-cycling. Although the science data taken during this period have normal quality, they have not been used, because the redundant star tracker’s performance is not fully characterized. |
− | For more information, see {{BibCite|planck2011-1-1}}. For a complete list of operational events, including contigencies, see the [[Planck operational state history | POSH]]. | + | For more information, see {{BibCite|planck2011-1-1}}. For a complete list of operational events, including contigencies, see the [[Planck operational state history | POSH]] (Planck operational state history). |
==For more information== | ==For more information== |
Latest revision as of 18:59, 14 October 2014
Contents
Introduction[edit]
Planck is a space telescope of the European Space Agency designed to answer key cosmological questions. Its main goal is to determine the geometry and content of the Universe, and to distinguish between specific theories describing the birth and evolution of the Universe. To achieve this ambitious objective, it observed the cosmic microwave background radiation (CMB), emitted about 14 billion years ago, around 380,000 years after the Big Bang. The CMB permeates the Universe and is observed to have a blackbody spectrum with a temperature of about 2.7 K. Small deviations from isotropy encode a wealth of information on the properties of the Universe in its infancy. The objective of Planck is to measure these properties with an unprecedented accuracy and level of detail.
As with all ESA scientific missions, Planck was developed in a partnership with the European scientific community. Two consortia of scientific institutes (supported by several funding agencies), each led by a Principal Investigator, developed and delivered to ESA an instrument designed specifically for Planck. Each of these instruments targets a specific number of wavelength bands within the range where the CMB is observable. Together, the two instruments are capable of collecting data of sufficient quality to measure the CMB signal and distinguish it from other confusing sources. A large telescope collected the light from the sky and delivered it to the instruments for measurement and analysis. The reflectors of the Planck telescope were developed and delivered to ESA by a Danish consortium of institutes. NASA also contributed significantly to Planck. ESA retains overall management of the project, including the responsibility to develop and procure the spacecraft, integrate the instruments into the spacecraft, and launch and operate it. Planck was launched on May 14th 2009 on an Ariane 5 rocket, together with the Herschel Space Observatory. After launch, they were both placed into orbits around the second Lagrange point of the Sun-Earth system, located about 1.5 million km from the Earth. From that far vantage point, Planck swept the sky regularly in large swaths, and covered it fully about five times for the HFI and eight times for the LFI. Each of the two instrument consortia operated their respective instrument and processed all the data into usable scientific products. At specific intervals the consortia delivered the data products to ESA, which archives them and distributes them to the community.
The last command to the Planck satellite was sent on the 23 October 2013, marking the end of operations.
Early operations and transfer to orbit[edit]
Planck was launched from the Centre Spatial Guyanais in Kourou (French Guyana) on 14 May 2009 at its nominal lift-off time of 13:12 UT, on an Ariane 5 ECA rocket of Arianespace. ESA’s Herschel observatory was launched on the same rocket. At 13:37:55 UT, Herschel was released from the rocket at an altitude of 1200 km; Planck followed suit at 13:40:25UT. The separation attitudes of both satellites were within 0.1 deg. of prediction. The Ariane rocket placed Planck with excellent accuracy (semimajor axis within 1.6 % of prediction), on a trajectory towards the second Lagrangian point of the Earth-Sun system (L2). The orbit describes a Lissajous trajectory around L2 with a roughly six month period that avoids crossing the Earth penumbra for at least four years.
After release from the rocket, three large manoeuvres were carried out to place Planck in its intended final orbit. Once in its final orbit, very small manoeuvres were required at approximately monthly intervals (1 m/s per year) to keep Planck from drifting away from its intended path around L2. The attitude manoeuvres required to follow the scanning strategy need about 2.6 m/s per year. Overall, the excellent performance of launch and orbit manoeuvres led to a large amount of fuel remaining on board at end of mission operations.
Planck started cooling down radiatively shortly after launch. Heaters were activated to hold the focal plane at 250 K, which was reached around 5 h after launch. The valve opening the exhaust piping of the dilution cooler was activated at 03:30 UT, and the 4He-JT cooler compressors were turned on at low stroke at 05:20 UT. After these essential operations were completed, on the second day after launch, the focal plane temperature was allowed to descend to 170 K for out-gassing and decontamination of the telescope and focal plane.
Commissioning and initial science operations[edit]
Commissioning[edit]
The first period of operations focussed on commissioning activities, i.e., functional check-out procedures of all sub-systems and instruments of the Planck spacecraft, in preparation for running science operations related to calibration and performance verification of the payload. Planning for commissioning operations was driven by the telescope decontamination period of 2 weeks and the subsequent cryogenic cool-down of the payload and instruments. The overall duration of the cool-down was approximately 2 months, including the decontamination period. The commissioning activities were executed very smoothly and all sub-systems were found to be in good health. The commissioning activities were formally completed at the time when the HFI bolometer stage reached its target temperature of 100 mK, on 3 July 2009 at 01:00 UT. At this time all the critical resource budgets (power, fuel, lifetime, etc.) were found to contain very significant margins with respect to the original specification.
Calibration and performance verification[edit]
Calibration and performance verification (CPV) activities started during the cool-down period and continued until the end of August 2009. On completion of all the planned activities, it was concluded that the two instruments were fully tuned and ready for routine operations. No further parameter tuning was expected to be needed, except for the sorption cooler, which required a weekly change in operational parameters. The scientific performance parameters of both instruments were in most respects as had been measured on the ground before launch. The only significant exception was that, due to the high level of Galactic cosmic rays, the bolometers of HFI were detecting a higher number of glitches than expected, causing a modest (about 10%) increase of systematic effects on their noise levels. The satellite did not introduce any major systematic effects into the science data. In particular, the telemetry transponder did not result in radio-frequency interference, which implies that the data acquired during visibility periods is usable for science.
First-Light Survey[edit]
The First Light Survey (FLS) was the last major activity planned before the start of routine surveying of the sky. It was conceived as a two-week period during which Planck would be fully tuned up and operated as if it was in its routine phase. This stable period could have resulted in the identification of further tuning activities required to optimise the performance of Planck in the long-duration surveys to come. The FLS was conducted between 13 and 27 August, and in fact led to the conclusion that the Planck payload was operating stably and optimally, and required no further tuning of its instruments. Therefore the period of the FLS was accepted as a valid part of the first Planck survey.
Routine operations phase[edit]
The routine operations phase of Planck is characterized by continuous and stable scanning of the sky and data acquisition by LFI and HFI. It started with the FLS on 13 August 2009.
The Planck satellite generated (and stored on-board) data continuously at the following typical rates: 21 kilobit/s (kbps) of house-keeping (HK) data from all on-board sources, 44 kbps of LFI science data and 72 kbps of HFI science data. The data were brought to ground in a daily pass of approximately 3 h duration. Besides the data downloads, the passes also acquired realtime HK and a 20 min period of real-time science (used to monitor instrument performance during the pass). Planck utilized the two ESA deep-space ground stations in New Norcia (Australia) and Cebreros (Spain). Scheduling of the daily telecommunication period was quite stable, with small perturbations due to the need to coordinate the use of the antenna with other ESA satellites (in particular Herschel). At the ground station the telemetry was received by redundant chains of front-end/back-end equipment. The data flowed to the mission operations control centre (MOC) located at ESOC in Darmstadt (Germany), where they were processed by redundant mission control software (MCS) installations and made available to the science ground segment. To reduce bandwidth requirements between the station and ESOC only one set of science telemetry was usually transferred. Software was run post-pass to check the completeness of the data. This software check was also used to build a catalogue of data completeness, which was used by the science ground segment to control its own data transfer process. Where gaps were detected, attempts to fill them were made as an offline activity (normally next working day), the first step being to attempt to reflow the relevant data from station. Early in the mission these gaps were more frequent, with some hundreds of packets affected per week (impact on data return of order 50 ppm), due principally to a combination of software problems with the data ingestion and distribution in the MCS, and imperfect behaviour of the software gap check. Software updates implemented during the mission improved the situation, such that gaps became much rarer, with a total impact on data return well below 1 ppm. Redump of data from the spacecraft was attempted when there had been losses in the space link. This was only necessary on very few occasions. In each case the spacecraft redump successfully recovered all the data.
All the data downloaded from the satellite, and processed products such as filtered attitude information, were made available each day for retrieval from the MOC by the LFI and HFI data processing centres (DPCs).
The scanning strategy was the following: the spin axis follows a cycloidal path on the sky by step-wise displacements of 2 arcmin approximately every 50 min. The dwell time (i.e., the duration of stable data acquisition at each pointing) varied sinusoidally by a factor of approximately 2. Planck’s scanning strategy resulted in significantly inhomogeneous depth of integration time across the sky; the areas near the ecliptic poles were observed with greater depth than all others.
The scanning strategy for the second year of Routine Operations was exactly the same as for the first year, except that all pointings were shifted by 1 arcmin along the cross-scanning direction, in order to provide finer sky sampling for the highest frequency detectors when combining two years of observations.
The remaining two years of operations, including Surveys 6 to 8 of the LFI-only phase, made use of a change in the cycloid phase of 90 degrees in order to spread out scanning directions over the sky.
Orbit maintenance manoeuvres were carried out at approximately monthly intervals. Although the manoeuvres only required a few minutes, preparations, post-manoeuvre mass properties calibration, and re-entry into scientific slewing mode increased the overhead to several hours. The manoeuvres were carried out without disturbing the path of the spin axis from its nominal scanning law. The dwell times of pointings before and after the execution of the manoeuvre were reduced to allow all pre-planned pointings to be carried out.
While the Planck detectors were scanning the sky, they also naturally observed celestial calibrators. The main objects used for this purpose were the Crab Nebula, and the bright planets Mars, Jupiter, and Saturn.
Major operational milestones[edit]
Planck was launched from the Centre Spatial Guyanais in Kourou (French Guyana) on 14 May 2009 at its nominal lift-off time of 13:12 UT, on an Ariane 5 ECA rocket of Arianespace.
On 13 August 2009, Planck started its first all-sky survey after successfully concluding its commissioning phase.
On 14 January 2012, Planck’s HFI completed its survey of the early Universe after running out of coolant as expected. Able to work at higher temperatures, the LFI continued surveying the sky until 3 October 2013.
On 4 October 2013 Planck ended its routine operations, after executing its last observation of the Crab Nebula, and started its decommissioning activities.
On 19 October 2013, the sorption cooler and the two instruments (LFI and HFI) were switched off.
The final command to the Planck satellite was sent on 23 October 2013, marking the end of operations.
Contingencies[edit]
The main unplanned events included the following.
- Very minor deviations from the scanning law included occasional (on the average about once every two months) under-performance of the 1-N thrusters used for regular manoeuvres, which implied that the corresponding pointings were not at the intended locations. These deviations had typical amplitudes of 30 arcsec, and had no significant impact on the coverage map.
- The thruster heaters were unintentionally turned off between 31 August and 16 September 2009 (the so-called “catbed” event).
- An operator error in the upload of the on-board command timeline led to an interruption of the normal sequence of manoeuvres and therefore to Planck pointing to the same location on the sky for a period of 29 h between 20 and 21 November 2009 (“the day Planck stood still”). Observations of the nominal scanning pattern resumed on 22 November, and on 23 November a recovery operation was applied to survey the previously missed area. During the recovery period the duration of pointing was decreased to allow the nominal law to be caught up with. As a side effect, the RF transmitter was left on for longer than 24 h, which had a significant thermal impact on the warm part of the satellite.
- As planned, the RF transmitter was initially turned on and off every day in synchrony with the daily visibility window, in order to reduce potential interference by the transmitter on the scientific data. The induced daily temperature variation had a measurable effect throughout the satellite. An important effect was on the temperature of the 4He-JT cooler compressors, which caused variations of the levels of the interference lines that they induce on the bolometer data (Planck HFI Core Team 2011a). Therefore the RF transmitter was left permanently on starting from 25 January 2010 (257 days after launch), which made a noticeable improvement on the daily temperature variations.
- During the coverage period, the operational star tracker switched autonomously to the redundant unit on two occasions (11 January 2010 and 26 February 2010); the nominal star tracker was restored a short period later (3.37 and 12.75 h, respectively) by manual power-cycling. Although the science data taken during this period have normal quality, they have not been used, because the redundant star tracker’s performance is not fully characterized.
For more information, see [1]. For a complete list of operational events, including contigencies, see the POSH (Planck operational state history).
For more information[edit]
A complete overview of the Planck mission and its science programme can be found in the Blue Book.
More details on the Planck mission performance can be found in [1], .
A complete list of Planck publications can be found here.
References[edit]
- ↑ 1.01.1 Planck early results. I. The Planck mission, Planck Collaboration I, A&A, 536, A1, (2011).
Cosmic Microwave background
European Space Agency
(Planck) High Frequency Instrument
(Planck) Low Frequency Instrument
Calibration and Performance Verification
House Keeping
[ESA's] Mission Operation Center [Darmstadt, Germany]
European Space Operations Centre (Darmstadt)
[LFI meaning]: absolute calibration refers to the 0th order calibration for each channel, 1 single number, while the relative calibration refers to the component of the calibration that varies pointing period by pointing period.