THE PICSAT PROJECT. Mathias Nowak, PhD student LESIA/Observatoire de Paris

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THE PICSAT PROJECT Mathias Nowak, PhD student LESIA/Observatoire de Paris mathias.nowak@obspm.fr

THE PICSAT PROJECT - A 3-unit CubeSat, ~4 kg, ~6 W - Dedidacted to the observation of Beta Pictoris - LESIA (Paris Observatory) is responsible for the payload and AIT - To be launched in Q2 2017

BETA PICTORIS Image: ESO Digitized Sky Survey, DSS2-red, 2 x 2 field

BETA PICTORIS mag = 3.86 (V band) Spectral type: A6V (main sequence white star) A very young star: 10 to 20 Myr Image: ESO Digitized Sky Survey, DSS2-red, 2 x 2 field

BETA PICTORIS mag = 3.86 (V band) Spectral type: A6V (main sequence white star) A very young star: 10 to 20 Myr Coordinates: RA 05h 47min 17s Dec -51 03 59 (visible only from the Southern hemisphere; hidden by the Sun during summer) Image: ESO Digitized Sky Survey, DSS2-red, 2 x 2 field

WHY BETA PICTORIS? - Circumstellar disk discovered in 1984 - Later identified as a debris disk (second stage in the evolutionary track) - Secondary disk identified with the Hubble Telescope

WHY BETA PICTORIS? Presence of a planet (Beta Pic b), discovered in 2009

WHY BETA PICTORIS? Presence of a planet (Beta Pic b), discovered in 2009 CO emission line deprojected assuming circular motion (Dent at al. 2014)

WHY BETA PICTORIS? Presence of a planet (Beta Pic b), discovered in 2009 Gas + dust + debris + planetesimals + a formed planet: The PERFECT target to test planet formation models! CO emission line deprojected assuming circular motion (Dent at al. 2014)

WHY DO WE DEVELOP PICSAT? Because of this (Lecavelier et al. 1995):

WHY DO WE DEVELOP PICSAT? Because of this (Lecavelier et al. 1995): a transitting object seen in 1981

WHY DO WE DEVELOP PICSAT? Because of this (Lecavelier et al. 1995): a transitting object seen in 1981 Recent observations strongly suggest that Beta Pic b is the transitting body Next transit : between June 2017 and September 2018

WHY DO WE DEVELOP PICSAT? Main objective of PICSAT: constant monitoring of the photometry of Beta Pic, at ~100 ppm/hour accuracy to detect the transit -> Determine the radius of the planet -> Characterize the Hill Sphere -> Inohomogeneities in the disk

WHY DO WE DEVELOP PICSAT? Main objective of PICSAT: constant monitoring of the photometry of Beta Pic, at ~100 ppm/hour accuracy to detect the transit -> Determine the radius of the planet -> Characterize the Hill Sphere -> Inohomogeneities in the disk Why not use existing facilities? - The transit is expected between June 2017 and September 2018 - It is a 10 h event 1 - Beta Pic CANNOT be observed from ground in summer 2 - Unrealistic to request one year of 24/7 observing time on a fewmeter ground or space telescope in the hope of detecting a 10 hr event! A dedicated space mission is required but the timeframe is very short!

PICSAT IN A NUTSHELL: Overview Solar panels on all sides + 4 deployable units) UHF/VHF antennas Star tracker OBC unit (and power generation, communication, data handling, etc.) (1.5 kg, 3 W) ADCS unit (0.5 kg, 2 W) 5 cm telescope Payload unit (1.5 kg, 2 W) (also contains the Star Tracker)

PICSAT IN A NUTSHELL: The Payload Two-axis piezo actuator (space qualified) +/- 250 microns = +/- 0.1 degrees CEDRAT XY400M Electronic board Off-axis parabola (30 deg) Real diameter: 50 mm Effective diameter: 35 mm Focal length: 135 mm (f/d=2.70) Avalanche photodiode (photon counting detector) IDQUANTIQUE ID101

PICSAT IN A NUTSHELL: ADCS and fine pointing - Light is collected by a single-mode fiber (3 micron diameter in the focal plane) - Required injection stability: 5% @ 100 Hz - Fine positionning of the fiber (0.5 micron required!) 1 arcsec pointing precision required!

PICSAT IN A NUTSHELL: ADCS and fine pointing - Light is collected by a single-mode fiber (3 micron diameter in the focal plane) - Required injection stability: 5% @ 100 Hz - Fine positionning of the fiber (0.5 micron required!) 1 arcsec pointing precision required! First stage: ADCS coarse pointing iadcs 100.60: (Hyperion Technologies) - 3 reaction wheels - Gyroscopes - 3 magneto-torquers - Magnetometer - StarTracker 30 arcsec accuracy (datasheet)

PICSAT IN A NUTSHELL: ADCS and fine pointing - Light is collected by a single-mode fiber (3 micron diameter in the focal plane) - Required injection stability: 5% @ 100 Hz - Fine positionning of the fiber (0.5 micron required!) 1 arcsec pointing precision required! First stage: ADCS coarse pointing iadcs 100.60: (Hyperion Technologies) - 3 reaction wheels - Gyroscopes - 3 magneto-torquers - Magnetometer - StarTracker 30 arcsec accuracy (datasheet) Second stage: Payload fine pointing - Photometric measurements (1000 Hz) - 3-axis gyroscope - Data fusion is made through an Extended Kalman Filter Accuracy: < 1 arcsec (simulations)

PICSAT IN A NUTSHELL: OBC, data handling Power: GomSpace EPS with battery board P31us (4x2600 mah) ~ 6 W generated with deployable panels

PICSAT IN A NUTSHELL: OBC, data handling Power: GomSpace EPS with battery board P31us (4x2600 mah) ~ 6 W generated with deployable panels Communications: ISIS TRXVU VHF/UHF Transceiver ISIS AntS Deployable Antenna System (1 Mbyte/day downlink; 0.1 Mbyte/day uplink)

PICSAT IN A NUTSHELL: OBC, data handling Power: GomSpace EPS with battery board P31us (4x2600 mah) ~ 6 W generated with deployable panels Communications: ISIS TRXVU VHF/UHF Transceiver ISIS AntS Deployable Antenna System (1 Mbyte/day downlink; 0.1 Mbyte/day uplink) On-board computer: ISIS OBC 400 MHz ARM9 processor (will be used for some in-flight data processing)

PICSAT IN A NUTSHELL: Noise budget Source Assumption Error level Resulting error (ppm/h) Photon noise N=80x10 4 N 60 e/s Readout noise 0 0 0 Dark current N=10 3 e/s N 0.1 Sky background N=150 e/s N 0.2 Thermal stability 0.01 K 0.4 % per K 40 Voltage stability 100 uv 20 % per Volt 20 Pointing stability 100 Hz 5 % 83 TOTAL : 111 ppm/h

CONCLUSION: current status - For its objective, PicSat must be launched in Q2 2017 - Engineering model is currently being built in Meudon (structure, ADCS, OBC already delivered) - Payload telescope has been designed and is now being built - A first version of the electronic board has been tested in vibrations, thermal vacuum (radiation testing to come), and the second version will be delivered in July - Payload algorithm and data reduction/processing are being developed (will be tested on a dedicated testbench this summer) - Flight software also under development

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