A digital long pulse integrator

Author

Broesch, J.D. ; Strait, E.J. ; Snider, R.T. ; Walker, M.L.

Author_Institution

Gen. Atomics, San Diego, CA, USA

Volume

1

fYear

1995

fDate

30 Sep-5 Oct 1995

Firstpage

365

Abstract

A prototype digital integrator with very long integration capabilities has been developed and field tested on an inductive magnetic sensor on the DIII-D tokamak. The integrator is being developed for use on ITER with a pulse length of 1000 s, and has direct applications for other long pulse tokamaks. Inductive magnetic sensors are routinely used on existing tokamaks, are well understood, and are extremely robust, however, they require integration of the signal to determine the magnetic field strength. The next generation of tokamaks, will have pulse lengths of 1000 s or longer, require integrators with drift and noise characteristics compatible with the very long pulse lengths. This paper will discuss the architecture, algorithms, and programming of the long pulse integrator (LPI). Of particular interest are the noise control and the built-in offset correction techniques used in this application

Keywords

circuit noise; fusion reactor instrumentation; fusion reactors; integrating circuits; magnetic sensors; 1000 s; DIII-D tokamak; ITER; built-in offset correction techniques; digital long pulse integrator; drift characteristics; field test; fusion reactor; inductive magnetic sensor; long pulse tokamaks; noise characteristics; noise control; prototype digital integrator; very long integration capabilities; Analog circuits; Integrated circuit measurements; Magnetic noise; Magnetic sensors; Plasmas; Probes; Signal processing; Signal resolution; Tokamaks; Voltage;

fLanguage

English

Publisher

ieee

Conference_Titel

Fusion Engineering, 1995. SOFE '95. Seeking a New Energy Era., 16th IEEE/NPSS Symposium

Conference_Location

Champaign, IL

Print_ISBN

0-7803-2969-4

Type

conf

DOI

10.1109/FUSION.1995.534243

Filename

534243