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Sayma : an arbitrary waveform generator for scientific experiments in ion traps

100%

Kulik P. , Kasprowicz G. , Harty T. , Bourdeauducq S. , Jördens R. , Allcock D. , Nadlinger D. , Britton J. W.

tom Vol. 64, Nr 8

65--68

Sayma is an advanced hardware solution designed for scien tific experiments in the field of quantum physics, particularly those involving ion traps. It is a part of Sinara, an open-sour ce ecosystem developed by a collaboration between M-Labs, Warsaw University of Technology (WUT), US Army Research Laboratory (ARL), the University of Oxford, the University of Maryland, and NIST. Sayma provides a high-quality, modular, and flexible platform for generating arbitrary waveforms in ion trap experiments. This article provides an overview of Sayma, its features, and its components: the Sayma AMC (Advanced Mezzanine Card) and Sayma RTM (Rear Transition Module).

Sayma to zaawansowane rozwiązanie sprzętowe przeznaczo ne do eksperymentów naukowych z zakresu fizyki kwantowej, w szczególności z wykorzystaniem pułapek jonowych. Jest częścią Sinara, ekosystemu open-source opracowanego we współpracy między M-Labs, Politechniką Warszawską (PW), US Army Research Laboratory (ARL), Uniwersytetem Oksfordz kim, Uniwersytetem Maryland i NIST. Sayma zapewnia wysokiej jakości, modułową i elastyczną platformę do generowania do wolnych przebiegów w eksperymentach z pułapkami jonowymi. Ten artykuł zawiera opis systemu Sayma, jego funkcji i kom ponentów: Sayma AMC (Advanced Mezzanine Card) i Sayma RTM (Rear Transition Module).

A new methodology for designing and development of complex systems for high energy physics

75%

Makowski D.

tom Vol. 7, nr 4

123--132

The paper describes a new methodology that allows to design scalable complex control and data acquisition systems taking into consideration the additional, non-functional requirements of High-Energy Physics (HEP). Electronic systems applied in HEP often operate in difficult conditions. Access to such devices is difficult or even impossible. The HEP systems require high availability, serviceability and upgradeability. The operating conditions of these systems are even more difficult than for telecommunication devices. Therefore, a different methodology should be applied than for classical telecommunication systems, when designing electronics used in high-energy physics applications. Electronic systems also need a suitable hardware platform that not only assures high availability, simplifies maintenance and servicing but also allows to use mixed analogue-digital signals. The author made an attempt to develop a new methodology suitable for designing of complex data acquisition and control systems of HEP. The Low Level RF (LLRF) system of European Free Electron Laser (EXFEL) and Image Acquisition System (IAS) prototype developed for International Thermonuclear Experimental Reactor (ITER) tokamak are presented as examples of complex electronic systems that were designed according to the proposed methodology.