Optimal Operation of Cryogenic Calorimeters Through Deep Reinforcement Learning

G. Angloher; S. Banik; G. Benato; A. Bento; A. Bertolini; R. Breier; C. Bucci; J. Burkhart; L. Canonica; A. D’Addabbo; S. Di Lorenzo; L. Einfalt; A. Erb; F. v. Feilitzsch; S. Fichtinger; D. Fuchs; A. Garai; V. M. Ghete; P. Gorla; P. V. Guillaumon; S. Gupta; D. Hauff; M. Ješkovský; J. Jochum; M. Kaznacheeva; A. Kinast; S. Kuckuk; H. Kluck; H. Kraus; A. Langenkämper; M. Mancuso; L. Marini; B. Mauri; L. Meyer; V. Mokina; K. Niedermayer; M. Olmi; T. Ortmann; C. Pagliarone; L. Pattavina; F. Petricca; W. Potzel; P. Povinec; F. Pröbst; F. Pucci; F. Reindl; J. Rothe; K. Schäffner; J. Schieck; S. Schönert; C. Schwertner; M. Stahlberg; L. Stodolsky; C. Strandhagen; R. Strauss; I. Usherov; F. Wagner; V. Wagner; M. Willers; V. Zema; C. Heitzinger; W. Waltenberger

doi:10.1007/s41781-024-00119-y

Optimal Operation of Cryogenic Calorimeters Through Deep Reinforcement Learning

G. Angloher, S. Banik, G. Benato, A. Bento, A. Bertolini, R. Breier, C. Bucci, J. Burkhart, L. Canonica, A. D’Addabbo, S. Di Lorenzo, L. Einfalt, A. Erb, F. v. Feilitzsch, S. Fichtinger, D. Fuchs, A. Garai, V. M. Ghete, P. Gorla, P. V. GuillaumonS. Gupta, D. Hauff, M. Ješkovský, J. Jochum, M. Kaznacheeva, A. Kinast, S. Kuckuk, H. Kluck, H. Kraus, A. Langenkämper, M. Mancuso, L. Marini, B. Mauri, L. Meyer, V. Mokina, K. Niedermayer, M. Olmi, T. Ortmann, C. Pagliarone, L. Pattavina, F. Petricca, W. Potzel, P. Povinec, F. Pröbst, F. Pucci, F. Reindl, J. Rothe, K. Schäffner, J. Schieck, S. Schönert, C. Schwertner, M. Stahlberg, L. Stodolsky, C. Strandhagen, R. Strauss, I. Usherov, F. Wagner, V. Wagner, M. Willers, V. Zema, C. Heitzinger, W. Waltenberger

Lehrstuhl für Experimentelle Astroteilchenphysik

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

Abstract

Cryogenic phonon detectors with transition-edge sensors achieve the best sensitivity to sub-GeV/c² dark matter interactions with nuclei in current direct detection experiments. In such devices, the temperature of the thermometer and the bias current in its readout circuit need careful optimization to achieve optimal detector performance. This task is not trivial and is typically done manually by an expert. In our work, we automated the procedure with reinforcement learning in two settings. First, we trained on a simulation of the response of three Cryogenic Rare Event Search with Superconducting Thermometers (CRESST) detectors used as a virtual reinforcement learning environment. Second, we trained live on the same detectors operated in the CRESST underground setup. In both cases, we were able to optimize a standard detector as fast and with comparable results as human experts. Our method enables the tuning of large-scale cryogenic detector setups with minimal manual interventions.

Originalsprache	Englisch
Aufsatznummer	10
Fachzeitschrift	Computing and Software for Big Science
Jahrgang	8
Ausgabenummer	1
DOIs	https://doi.org/10.1007/s41781-024-00119-y
Publikationsstatus	Veröffentlicht - Dez. 2024

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10.1007/s41781-024-00119-y

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Angloher, G., Banik, S., Benato, G., Bento, A., Bertolini, A., Breier, R., Bucci, C., Burkhart, J., Canonica, L., D’Addabbo, A., Di Lorenzo, S., Einfalt, L., Erb, A., v. Feilitzsch, F., Fichtinger, S., Fuchs, D., Garai, A., Ghete, V. M., Gorla, P., ... Waltenberger, W. (2024). Optimal Operation of Cryogenic Calorimeters Through Deep Reinforcement Learning. Computing and Software for Big Science, 8(1), Artikel 10. https://doi.org/10.1007/s41781-024-00119-y

@article{226195e34554434784676b418469be69,

title = "Optimal Operation of Cryogenic Calorimeters Through Deep Reinforcement Learning",

abstract = "Cryogenic phonon detectors with transition-edge sensors achieve the best sensitivity to sub-GeV/c2 dark matter interactions with nuclei in current direct detection experiments. In such devices, the temperature of the thermometer and the bias current in its readout circuit need careful optimization to achieve optimal detector performance. This task is not trivial and is typically done manually by an expert. In our work, we automated the procedure with reinforcement learning in two settings. First, we trained on a simulation of the response of three Cryogenic Rare Event Search with Superconducting Thermometers (CRESST) detectors used as a virtual reinforcement learning environment. Second, we trained live on the same detectors operated in the CRESST underground setup. In both cases, we were able to optimize a standard detector as fast and with comparable results as human experts. Our method enables the tuning of large-scale cryogenic detector setups with minimal manual interventions.",

keywords = "Cryogenic calorimeter, Dark matter, Reinforcement learning, Transition-edge sensor",

author = "G. Angloher and S. Banik and G. Benato and A. Bento and A. Bertolini and R. Breier and C. Bucci and J. Burkhart and L. Canonica and A. D{\textquoteright}Addabbo and {Di Lorenzo}, S. and L. Einfalt and A. Erb and {v. Feilitzsch}, F. and S. Fichtinger and D. Fuchs and A. Garai and Ghete, {V. M.} and P. Gorla and Guillaumon, {P. V.} and S. Gupta and D. Hauff and M. Je{\v s}kovsk{\'y} and J. Jochum and M. Kaznacheeva and A. Kinast and S. Kuckuk and H. Kluck and H. Kraus and A. Langenk{\"a}mper and M. Mancuso and L. Marini and B. Mauri and L. Meyer and V. Mokina and K. Niedermayer and M. Olmi and T. Ortmann and C. Pagliarone and L. Pattavina and F. Petricca and W. Potzel and P. Povinec and F. Pr{\"o}bst and F. Pucci and F. Reindl and J. Rothe and K. Sch{\"a}ffner and J. Schieck and S. Sch{\"o}nert and C. Schwertner and M. Stahlberg and L. Stodolsky and C. Strandhagen and R. Strauss and I. Usherov and F. Wagner and V. Wagner and M. Willers and V. Zema and C. Heitzinger and W. Waltenberger",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2024.",

year = "2024",

month = dec,

doi = "10.1007/s41781-024-00119-y",

language = "English",

volume = "8",

journal = "Computing and Software for Big Science",

issn = "2510-2044",

publisher = "Springer Nature",

number = "1",

}

Angloher, G, Banik, S, Benato, G, Bento, A, Bertolini, A, Breier, R, Bucci, C, Burkhart, J, Canonica, L, D’Addabbo, A, Di Lorenzo, S, Einfalt, L, Erb, A, v. Feilitzsch, F, Fichtinger, S, Fuchs, D, Garai, A, Ghete, VM, Gorla, P, Guillaumon, PV, Gupta, S, Hauff, D, Ješkovský, M, Jochum, J, Kaznacheeva, M, Kinast, A, Kuckuk, S, Kluck, H, Kraus, H, Langenkämper, A, Mancuso, M, Marini, L, Mauri, B, Meyer, L, Mokina, V, Niedermayer, K, Olmi, M, Ortmann, T, Pagliarone, C, Pattavina, L, Petricca, F, Potzel, W, Povinec, P, Pröbst, F, Pucci, F, Reindl, F, Rothe, J, Schäffner, K, Schieck, J, Schönert, S, Schwertner, C, Stahlberg, M, Stodolsky, L, Strandhagen, C, Strauss, R, Usherov, I, Wagner, F, Wagner, V, Willers, M, Zema, V, Heitzinger, C & Waltenberger, W 2024, 'Optimal Operation of Cryogenic Calorimeters Through Deep Reinforcement Learning', Computing and Software for Big Science, Jg. 8, Nr. 1, 10. https://doi.org/10.1007/s41781-024-00119-y

TY - JOUR

T1 - Optimal Operation of Cryogenic Calorimeters Through Deep Reinforcement Learning

AU - Angloher, G.

AU - Banik, S.

AU - Benato, G.

AU - Bento, A.

AU - Bertolini, A.

AU - Breier, R.

AU - Bucci, C.

AU - Burkhart, J.

AU - Canonica, L.

AU - D’Addabbo, A.

AU - Di Lorenzo, S.

AU - Einfalt, L.

AU - Erb, A.

AU - v. Feilitzsch, F.

AU - Fichtinger, S.

AU - Fuchs, D.

AU - Garai, A.

AU - Ghete, V. M.

AU - Gorla, P.

AU - Guillaumon, P. V.

AU - Gupta, S.

AU - Hauff, D.

AU - Ješkovský, M.

AU - Jochum, J.

AU - Kaznacheeva, M.

AU - Kinast, A.

AU - Kuckuk, S.

AU - Kluck, H.

AU - Kraus, H.

AU - Langenkämper, A.

AU - Mancuso, M.

AU - Marini, L.

AU - Mauri, B.

AU - Meyer, L.

AU - Mokina, V.

AU - Niedermayer, K.

AU - Olmi, M.

AU - Ortmann, T.

AU - Pagliarone, C.

AU - Pattavina, L.

AU - Petricca, F.

AU - Potzel, W.

AU - Povinec, P.

AU - Pröbst, F.

AU - Pucci, F.

AU - Reindl, F.

AU - Rothe, J.

AU - Schäffner, K.

AU - Schieck, J.

AU - Schönert, S.

AU - Schwertner, C.

AU - Stahlberg, M.

AU - Stodolsky, L.

AU - Strandhagen, C.

AU - Strauss, R.

AU - Usherov, I.

AU - Wagner, F.

AU - Wagner, V.

AU - Willers, M.

AU - Zema, V.

AU - Heitzinger, C.

AU - Waltenberger, W.

PY - 2024/12

Y1 - 2024/12

N2 - Cryogenic phonon detectors with transition-edge sensors achieve the best sensitivity to sub-GeV/c2 dark matter interactions with nuclei in current direct detection experiments. In such devices, the temperature of the thermometer and the bias current in its readout circuit need careful optimization to achieve optimal detector performance. This task is not trivial and is typically done manually by an expert. In our work, we automated the procedure with reinforcement learning in two settings. First, we trained on a simulation of the response of three Cryogenic Rare Event Search with Superconducting Thermometers (CRESST) detectors used as a virtual reinforcement learning environment. Second, we trained live on the same detectors operated in the CRESST underground setup. In both cases, we were able to optimize a standard detector as fast and with comparable results as human experts. Our method enables the tuning of large-scale cryogenic detector setups with minimal manual interventions.

AB - Cryogenic phonon detectors with transition-edge sensors achieve the best sensitivity to sub-GeV/c2 dark matter interactions with nuclei in current direct detection experiments. In such devices, the temperature of the thermometer and the bias current in its readout circuit need careful optimization to achieve optimal detector performance. This task is not trivial and is typically done manually by an expert. In our work, we automated the procedure with reinforcement learning in two settings. First, we trained on a simulation of the response of three Cryogenic Rare Event Search with Superconducting Thermometers (CRESST) detectors used as a virtual reinforcement learning environment. Second, we trained live on the same detectors operated in the CRESST underground setup. In both cases, we were able to optimize a standard detector as fast and with comparable results as human experts. Our method enables the tuning of large-scale cryogenic detector setups with minimal manual interventions.

KW - Cryogenic calorimeter

KW - Dark matter

KW - Reinforcement learning

KW - Transition-edge sensor

UR - http://www.scopus.com/inward/record.url?scp=85194045234&partnerID=8YFLogxK

U2 - 10.1007/s41781-024-00119-y

DO - 10.1007/s41781-024-00119-y

M3 - Article

AN - SCOPUS:85194045234

SN - 2510-2044

VL - 8

JO - Computing and Software for Big Science

JF - Computing and Software for Big Science

IS - 1

M1 - 10

ER -

Optimal Operation of Cryogenic Calorimeters Through Deep Reinforcement Learning

Abstract

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