In-flight diagnostics in LISA pathfinder

A. Lobo; M. Nofrarias; J. Ramos-Castro; J. Sanjuan; A. Conchillo; J. A. Ortega; X. Xirgu; H. Araujo; C. Boatella; M. Chmeissani; C. Grimani; C. Puigdengoles; P. Wass; E. García-berro; S. García; L. M. Martínez; G. Montero

doi:10.1063/1.2405094

In-flight diagnostics in LISA pathfinder

A. Lobo^*
, M. Nofrarias
, J. Ramos-Castro
, J. Sanjuan
, A. Conchillo
, J. A. Ortega
, X. Xirgu
, H. Araujo
, C. Boatella
, M. Chmeissani
, C. Grimani
, C. Puigdengoles
, P. Wass
, E. García-berro
, S. García
, L. M. Martínez
, G. Montero

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

6 Citations (Scopus)

Abstract

LISA PathFinder (LPF) will be flown with the objective to test in space key technologies for LISA. However its sensitivity goals are, for good reason, one order of magnitude less than those which LISA will have to meet, both in drag-free and optical metrology requirements, and in the observation frequency band. While the expected success of LPF will of course be of itself a major step forward to LISA, one might not forget that a further improvement by an order of magnitude in performance will still be needed. Clues for the last leap are to be derived from proper disentanglement of the various sources of noise which contribute to the total noise, as measured in flight during the PathFinder mission. This paper describes the principles, workings and requirements of one of the key tools to serve the above objective: the diagnostics subsystem. This consists in sets of temperature, magnetic field, and particle counter sensors, together with generators of controlled thermal and magnetic perturbations. At least during the commissioning phase, the latter will be used to identify feed-through coefficients between diagnostics sensor readings and associated actual noise contributions. A brief progress report of the current state of development of the diagnostics subsystem will be given as well.

Original language	English
Pages (from-to)	522-528
Number of pages	7
Journal	AIP Conference Proceedings
Volume	873
DOIs	https://doi.org/10.1063/1.2405094
Publication status	Published - 2006
Externally published	Yes

Keywords

Diagnostics
Gravity waves
LISA
LISA pathfinder

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10.1063/1.2405094

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@article{c23871fb2f63420ba3ab86ae131950b0,

title = "In-flight diagnostics in LISA pathfinder",

abstract = "LISA PathFinder (LPF) will be flown with the objective to test in space key technologies for LISA. However its sensitivity goals are, for good reason, one order of magnitude less than those which LISA will have to meet, both in drag-free and optical metrology requirements, and in the observation frequency band. While the expected success of LPF will of course be of itself a major step forward to LISA, one might not forget that a further improvement by an order of magnitude in performance will still be needed. Clues for the last leap are to be derived from proper disentanglement of the various sources of noise which contribute to the total noise, as measured in flight during the PathFinder mission. This paper describes the principles, workings and requirements of one of the key tools to serve the above objective: the diagnostics subsystem. This consists in sets of temperature, magnetic field, and particle counter sensors, together with generators of controlled thermal and magnetic perturbations. At least during the commissioning phase, the latter will be used to identify feed-through coefficients between diagnostics sensor readings and associated actual noise contributions. A brief progress report of the current state of development of the diagnostics subsystem will be given as well.",

keywords = "Diagnostics, Gravity waves, LISA, LISA pathfinder",

author = "A. Lobo and M. Nofrarias and J. Ramos-Castro and J. Sanjuan and A. Conchillo and Ortega, \{J. A.\} and X. Xirgu and H. Araujo and C. Boatella and M. Chmeissani and C. Grimani and C. Puigdengoles and P. Wass and E. Garc{\'i}a-berro and S. Garc{\'i}a and Mart{\'i}nez, \{L. M.\} and G. Montero",

year = "2006",

doi = "10.1063/1.2405094",

language = "English",

volume = "873",

pages = "522--528",

journal = "AIP Conference Proceedings",

issn = "0094-243X",

publisher = "American Institute of Physics",

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TY - JOUR

T1 - In-flight diagnostics in LISA pathfinder

AU - Lobo, A.

AU - Nofrarias, M.

AU - Ramos-Castro, J.

AU - Sanjuan, J.

AU - Conchillo, A.

AU - Ortega, J. A.

AU - Xirgu, X.

AU - Araujo, H.

AU - Boatella, C.

AU - Chmeissani, M.

AU - Grimani, C.

AU - Puigdengoles, C.

AU - Wass, P.

AU - García-berro, E.

AU - García, S.

AU - Martínez, L. M.

AU - Montero, G.

PY - 2006

Y1 - 2006

N2 - LISA PathFinder (LPF) will be flown with the objective to test in space key technologies for LISA. However its sensitivity goals are, for good reason, one order of magnitude less than those which LISA will have to meet, both in drag-free and optical metrology requirements, and in the observation frequency band. While the expected success of LPF will of course be of itself a major step forward to LISA, one might not forget that a further improvement by an order of magnitude in performance will still be needed. Clues for the last leap are to be derived from proper disentanglement of the various sources of noise which contribute to the total noise, as measured in flight during the PathFinder mission. This paper describes the principles, workings and requirements of one of the key tools to serve the above objective: the diagnostics subsystem. This consists in sets of temperature, magnetic field, and particle counter sensors, together with generators of controlled thermal and magnetic perturbations. At least during the commissioning phase, the latter will be used to identify feed-through coefficients between diagnostics sensor readings and associated actual noise contributions. A brief progress report of the current state of development of the diagnostics subsystem will be given as well.

AB - LISA PathFinder (LPF) will be flown with the objective to test in space key technologies for LISA. However its sensitivity goals are, for good reason, one order of magnitude less than those which LISA will have to meet, both in drag-free and optical metrology requirements, and in the observation frequency band. While the expected success of LPF will of course be of itself a major step forward to LISA, one might not forget that a further improvement by an order of magnitude in performance will still be needed. Clues for the last leap are to be derived from proper disentanglement of the various sources of noise which contribute to the total noise, as measured in flight during the PathFinder mission. This paper describes the principles, workings and requirements of one of the key tools to serve the above objective: the diagnostics subsystem. This consists in sets of temperature, magnetic field, and particle counter sensors, together with generators of controlled thermal and magnetic perturbations. At least during the commissioning phase, the latter will be used to identify feed-through coefficients between diagnostics sensor readings and associated actual noise contributions. A brief progress report of the current state of development of the diagnostics subsystem will be given as well.

KW - Diagnostics

KW - Gravity waves

KW - LISA

KW - LISA pathfinder

UR - https://www.scopus.com/pages/publications/33845621085

U2 - 10.1063/1.2405094

DO - 10.1063/1.2405094

M3 - Article

AN - SCOPUS:33845621085

SN - 0094-243X

VL - 873

SP - 522

EP - 528

JO - AIP Conference Proceedings

JF - AIP Conference Proceedings

ER -

In-flight diagnostics in LISA pathfinder

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Keywords

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