The Rasnik 3-point optical alignment system

M. Beker; G. Bobbink; B. Bouwens; N. Deelen; P. Duinker; J. van Eldik; N. de Gaay Fortman; R. van der Geer; Harry van der Graaf; H. Groenstege; R. Hart; K. Hashemi; J. van Heijningen; M. Kea; J. Koopstra; X. Leijtens; F. Linde; J.A. Paradiso; H. Tolsma; M. Woudstra

doi:10.1088/1748-0221/14/08/P08010

The Rasnik 3-point optical alignment system

M. Beker
, G. Bobbink
, B. Bouwens
, N. Deelen
, P. Duinker
, J. van Eldik
, N. de Gaay Fortman
, R. van der Geer
, Harry van der Graaf (Corresponding author)
, H. Groenstege
, R. Hart
, K. Hashemi
, J. van Heijningen
, M. Kea
, J. Koopstra
, X. Leijtens
, F. Linde
, J.A. Paradiso
, H. Tolsma
, M. Woudstra

Onderzoeksoutput: Bijdrage aan tijdschrift › Tijdschriftartikel › Academic › peer review

12 Citaten (Scopus)

Samenvatting

The Rasnik alignment system was developed initially in 1983 for the monitoring of the alignment of the muon chambers of the L3 Muon Spectrometer at CERN. Since then, the development has continued as new opto-electronic components become available. Rasnik systems are 3-point optical displacement monitors and their precision ranges from below nanometers to several micrometers, depending on the design and requirements of the systems. A result, expressed in the range/precision ratio of 2 × 106, is presented. According to the calculations of the Cram&aposer-Rao limit, and by means of MonteCarlo simulations, a typical Rasnik image should have enough information to reach deep sub-nanometer precision. This paper is an overview of the technological developments and achievements since Rasnik was applied in high energy physics experiments.

Originele taal-2	Engels
Artikelnummer	P08010
Aantal pagina's	46
Tijdschrift	Journal of Instrumentation
Volume	14
Nummer van het tijdschrift	8
DOI's	https://doi.org/10.1088/1748-0221/14/08/P08010
Status	Gepubliceerd - 8 aug. 2019

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Beker, M., Bobbink, G., Bouwens, B., Deelen, N., Duinker, P., van Eldik, J., de Gaay Fortman, N., van der Geer, R., van der Graaf, H., Groenstege, H., Hart, R., Hashemi, K., van Heijningen, J., Kea, M., Koopstra, J., Leijtens, X., Linde, F., Paradiso, J. A., Tolsma, H., & Woudstra, M. (2019). The Rasnik 3-point optical alignment system. Journal of Instrumentation, 14(8), Artikel P08010. https://doi.org/10.1088/1748-0221/14/08/P08010

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title = "The Rasnik 3-point optical alignment system",

abstract = "The Rasnik alignment system was developed initially in 1983 for the monitoring of the alignment of the muon chambers of the L3 Muon Spectrometer at CERN. Since then, the development has continued as new opto-electronic components become available. Rasnik systems are 3-point optical displacement monitors and their precision ranges from below nanometers to several micrometers, depending on the design and requirements of the systems. A result, expressed in the range/precision ratio of 2 × 106, is presented. According to the calculations of the Cram\&aposer-Rao limit, and by means of MonteCarlo simulations, a typical Rasnik image should have enough information to reach deep sub-nanometer precision. This paper is an overview of the technological developments and achievements since Rasnik was applied in high energy physics experiments.",

keywords = "Detector alignment and calibration methods (lasers, sources, particle-beams), Overall mechanics design (support structures and materials, vibration analysis etc)",

author = "M. Beker and G. Bobbink and B. Bouwens and N. Deelen and P. Duinker and \{van Eldik\}, J. and \{de Gaay Fortman\}, N. and \{van der Geer\}, R. and \{van der Graaf\}, Harry and H. Groenstege and R. Hart and K. Hashemi and \{van Heijningen\}, J. and M. Kea and J. Koopstra and X. Leijtens and F. Linde and J.A. Paradiso and H. Tolsma and M. Woudstra",

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doi = "10.1088/1748-0221/14/08/P08010",

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Beker, M, Bobbink, G, Bouwens, B, Deelen, N, Duinker, P, van Eldik, J, de Gaay Fortman, N, van der Geer, R, van der Graaf, H, Groenstege, H, Hart, R, Hashemi, K, van Heijningen, J, Kea, M, Koopstra, J, Leijtens, X, Linde, F, Paradiso, JA, Tolsma, H & Woudstra, M 2019, 'The Rasnik 3-point optical alignment system', Journal of Instrumentation, vol. 14, nr. 8, P08010. https://doi.org/10.1088/1748-0221/14/08/P08010

TY - JOUR

T1 - The Rasnik 3-point optical alignment system

AU - Beker, M.

AU - Bobbink, G.

AU - Bouwens, B.

AU - Deelen, N.

AU - Duinker, P.

AU - van Eldik, J.

AU - de Gaay Fortman, N.

AU - van der Geer, R.

AU - van der Graaf, Harry

AU - Groenstege, H.

AU - Hart, R.

AU - Hashemi, K.

AU - van Heijningen, J.

AU - Kea, M.

AU - Koopstra, J.

AU - Leijtens, X.

AU - Linde, F.

AU - Paradiso, J.A.

AU - Tolsma, H.

AU - Woudstra, M.

PY - 2019/8/8

Y1 - 2019/8/8

N2 - The Rasnik alignment system was developed initially in 1983 for the monitoring of the alignment of the muon chambers of the L3 Muon Spectrometer at CERN. Since then, the development has continued as new opto-electronic components become available. Rasnik systems are 3-point optical displacement monitors and their precision ranges from below nanometers to several micrometers, depending on the design and requirements of the systems. A result, expressed in the range/precision ratio of 2 × 106, is presented. According to the calculations of the Cram&aposer-Rao limit, and by means of MonteCarlo simulations, a typical Rasnik image should have enough information to reach deep sub-nanometer precision. This paper is an overview of the technological developments and achievements since Rasnik was applied in high energy physics experiments.

AB - The Rasnik alignment system was developed initially in 1983 for the monitoring of the alignment of the muon chambers of the L3 Muon Spectrometer at CERN. Since then, the development has continued as new opto-electronic components become available. Rasnik systems are 3-point optical displacement monitors and their precision ranges from below nanometers to several micrometers, depending on the design and requirements of the systems. A result, expressed in the range/precision ratio of 2 × 106, is presented. According to the calculations of the Cram&aposer-Rao limit, and by means of MonteCarlo simulations, a typical Rasnik image should have enough information to reach deep sub-nanometer precision. This paper is an overview of the technological developments and achievements since Rasnik was applied in high energy physics experiments.

KW - Detector alignment and calibration methods (lasers, sources, particle-beams)

KW - Overall mechanics design (support structures and materials, vibration analysis etc)

UR - https://www.scopus.com/pages/publications/85072713285

U2 - 10.1088/1748-0221/14/08/P08010

DO - 10.1088/1748-0221/14/08/P08010

M3 - Article

SN - 1748-0221

VL - 14

JO - Journal of Instrumentation

JF - Journal of Instrumentation

IS - 8

M1 - P08010

ER -

The Rasnik 3-point optical alignment system

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