An FPGA-based system for generalised electron devices testing
An FPGA-based system for generalised electron devices testing
Electronic systems are becoming more and more ubiquitous as our world digitises. Simultaneously, even basic components are experiencing a wave of improvements with new transistors, memristors, voltage/current references, data converters, etc, being designed every year by hundreds of R &D groups world-wide. To date, the workhorse for testing all these designs has been a suite of lab instruments including oscilloscopes and signal generators, to mention the most popular. However, as components become more complex and pin numbers soar, the need for more parallel and versatile testing tools also becomes more pressing. In this work, we describe and benchmark an FPGA system developed that addresses this need. This general purpose testing system features a 64-channel source- meter unit, and 2× banks of 32 digital pins for digital I/O. We demonstrate that this bench-top system can obtain 170 pA current noise floor, 40 ns pulse delivery at ±13.5 V and 12 mA maximum current drive/channel. We then showcase the instrument’s use in performing a selection of three characteristic measurement tasks: (a) current–voltage characterisation of a diode and a transistor, (b) fully parallel read-out of a memristor crossbar array and (c) an integral non-linearity test on a DAC. This work introduces a down-scaled electronics laboratory packaged in a single instrument which provides a shift towards more affordable, reliable, compact and multi-functional instrumentation for emerging electronic technologies .
Electronics, Electrons
13912
Foster, Patrick
7cd3d58b-231c-4986-868f-2c2cd55327dc
Huang, Jinqi
de5be89e-1542-4658-9d67-6757f7075c01
Stathopoulos, Spyros
98d12f06-ad01-4708-be19-a97282968ee6
Serb, Alexantrou
30f5ec26-f51d-42b3-85fd-0325a27a792c
Prodromakis, Themistoklis
d58c9c10-9d25-4d22-b155-06c8437acfbf
Papavassiliou, Christos
86fe7042-20a3-47a9-9430-2bdb6c260303
17 August 2022
Foster, Patrick
7cd3d58b-231c-4986-868f-2c2cd55327dc
Huang, Jinqi
de5be89e-1542-4658-9d67-6757f7075c01
Stathopoulos, Spyros
98d12f06-ad01-4708-be19-a97282968ee6
Serb, Alexantrou
30f5ec26-f51d-42b3-85fd-0325a27a792c
Prodromakis, Themistoklis
d58c9c10-9d25-4d22-b155-06c8437acfbf
Papavassiliou, Christos
86fe7042-20a3-47a9-9430-2bdb6c260303
Foster, Patrick, Huang, Jinqi, Stathopoulos, Spyros, Serb, Alexantrou, Prodromakis, Themistoklis and Papavassiliou, Christos
(2022)
An FPGA-based system for generalised electron devices testing.
Scientific Reports, 12 (1), , [13912].
(doi:10.1038/s41598-022-18100-3).
Abstract
Electronic systems are becoming more and more ubiquitous as our world digitises. Simultaneously, even basic components are experiencing a wave of improvements with new transistors, memristors, voltage/current references, data converters, etc, being designed every year by hundreds of R &D groups world-wide. To date, the workhorse for testing all these designs has been a suite of lab instruments including oscilloscopes and signal generators, to mention the most popular. However, as components become more complex and pin numbers soar, the need for more parallel and versatile testing tools also becomes more pressing. In this work, we describe and benchmark an FPGA system developed that addresses this need. This general purpose testing system features a 64-channel source- meter unit, and 2× banks of 32 digital pins for digital I/O. We demonstrate that this bench-top system can obtain 170 pA current noise floor, 40 ns pulse delivery at ±13.5 V and 12 mA maximum current drive/channel. We then showcase the instrument’s use in performing a selection of three characteristic measurement tasks: (a) current–voltage characterisation of a diode and a transistor, (b) fully parallel read-out of a memristor crossbar array and (c) an integral non-linearity test on a DAC. This work introduces a down-scaled electronics laboratory packaged in a single instrument which provides a shift towards more affordable, reliable, compact and multi-functional instrumentation for emerging electronic technologies .
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ArC_Neuro_SR_Paper_5
- Accepted Manuscript
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Foster_et_al-2022-Scientific_Reports
- Version of Record
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Accepted/In Press date: 5 August 2022
Published date: 17 August 2022
Additional Information:
© 2022. The Author(s).
Keywords:
Electronics, Electrons
Identifiers
Local EPrints ID: 468744
URI: http://eprints.soton.ac.uk/id/eprint/468744
ISSN: 2045-2322
PURE UUID: 24b1eda6-aef1-49c2-abab-bd9d654dcc03
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Date deposited: 24 Aug 2022 16:38
Last modified: 16 Mar 2024 21:38
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Contributors
Author:
Patrick Foster
Author:
Jinqi Huang
Author:
Spyros Stathopoulos
Author:
Alexantrou Serb
Author:
Themistoklis Prodromakis
Author:
Christos Papavassiliou
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