Determining DfT Hardware by VHDL-AMS Fault Simulation for Biological Micro-Electronic Fluidic Arrays

H.G. Kerkhoff; X. Zhang; H. Liu; A. Richardson; P. Nouet; F. Azais

Determining DfT Hardware by VHDL-AMS Fault Simulation for Biological Micro-Electronic Fluidic Arrays

H.G. Kerkhoff, X. Zhang, H. Liu, A. Richardson, P. Nouet, F. Azais

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

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Abstract

The interest of microelectronic fluidic arrays for biomedical applications, like DNA determination, is rapidly increasing. In order to evaluate these systems in terms of required Design-for-Test structures, fault simulations in both fluidic and electronic domains are necessary. VHDL-AMS can be used successfully in this case. This paper shows a highly testable architecture of a DNA Bio-Sensing array, its basic sensing concept, fluidic modeling and sensitivity analysis. The overall VHDL-AMS fault simulation of the system is show

Original language	English
Title of host publication	Overview of the workshops ProRISC-SAFE, November 17-18, 2005, Veldhoven, the Netherlands
Place of Publication	Utrecht, The Netherlands
Publisher	STW
Pages	378-382
Number of pages	5
ISBN (Print)	90-73461-50-2
Publication status	Published - 2005
Event	16th Workshop on Circuits, Systems and Signal Processing, ProRISC 2005 - Veldhoven, Netherlands Duration: 17 Nov 2005 → 18 Nov 2005 Conference number: 16

Workshop

Workshop	16th Workshop on Circuits, Systems and Signal Processing, ProRISC 2005
Country	Netherlands
City	Veldhoven
Period	17/11/05 → 18/11/05

Keywords

EC Grant Agreement nr.: FP6/507255

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title = "Determining DfT Hardware by VHDL-AMS Fault Simulation for Biological Micro-Electronic Fluidic Arrays",

abstract = "The interest of microelectronic fluidic arrays for biomedical applications, like DNA determination, is rapidly increasing. In order to evaluate these systems in terms of required Design-for-Test structures, fault simulations in both fluidic and electronic domains are necessary. VHDL-AMS can be used successfully in this case. This paper shows a highly testable architecture of a DNA Bio-Sensing array, its basic sensing concept, fluidic modeling and sensitivity analysis. The overall VHDL-AMS fault simulation of the system is show",

keywords = "EC Grant Agreement nr.: FP6/507255",

author = "H.G. Kerkhoff and X. Zhang and H. Liu and A. Richardson and P. Nouet and F. Azais",

note = "Sponsored by the CEC, in FP6 NoE DfMM: PATENT; 16th Workshop on Circuits, Systems and Signal Processing, ProRISC 2005 ; Conference date: 17-11-2005 Through 18-11-2005",

year = "2005",

language = "English",

isbn = "90-73461-50-2",

pages = "378--382",

booktitle = "Overview of the workshops ProRISC-SAFE, November 17-18, 2005, Veldhoven, the Netherlands",

publisher = "STW",

}

Kerkhoff, HG, Zhang, X, Liu, H, Richardson, A, Nouet, P & Azais, F 2005, Determining DfT Hardware by VHDL-AMS Fault Simulation for Biological Micro-Electronic Fluidic Arrays. in Overview of the workshops ProRISC-SAFE, November 17-18, 2005, Veldhoven, the Netherlands. STW, Utrecht, The Netherlands, pp. 378-382, 16th Workshop on Circuits, Systems and Signal Processing, ProRISC 2005, Veldhoven, Netherlands, 17/11/05.

Determining DfT Hardware by VHDL-AMS Fault Simulation for Biological Micro-Electronic Fluidic Arrays. / Kerkhoff, H.G.; Zhang, X.; Liu, H.; Richardson, A.; Nouet, P.; Azais, F.

Overview of the workshops ProRISC-SAFE, November 17-18, 2005, Veldhoven, the Netherlands. Utrecht, The Netherlands : STW, 2005. p. 378-382.

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

TY - GEN

T1 - Determining DfT Hardware by VHDL-AMS Fault Simulation for Biological Micro-Electronic Fluidic Arrays

AU - Kerkhoff, H.G.

AU - Zhang, X.

AU - Liu, H.

AU - Richardson, A.

AU - Nouet, P.

AU - Azais, F.

N1 - Conference code: 16

PY - 2005

Y1 - 2005

N2 - The interest of microelectronic fluidic arrays for biomedical applications, like DNA determination, is rapidly increasing. In order to evaluate these systems in terms of required Design-for-Test structures, fault simulations in both fluidic and electronic domains are necessary. VHDL-AMS can be used successfully in this case. This paper shows a highly testable architecture of a DNA Bio-Sensing array, its basic sensing concept, fluidic modeling and sensitivity analysis. The overall VHDL-AMS fault simulation of the system is show

AB - The interest of microelectronic fluidic arrays for biomedical applications, like DNA determination, is rapidly increasing. In order to evaluate these systems in terms of required Design-for-Test structures, fault simulations in both fluidic and electronic domains are necessary. VHDL-AMS can be used successfully in this case. This paper shows a highly testable architecture of a DNA Bio-Sensing array, its basic sensing concept, fluidic modeling and sensitivity analysis. The overall VHDL-AMS fault simulation of the system is show

KW - EC Grant Agreement nr.: FP6/507255

M3 - Conference contribution

SN - 90-73461-50-2

SP - 378

EP - 382

BT - Overview of the workshops ProRISC-SAFE, November 17-18, 2005, Veldhoven, the Netherlands

PB - STW

CY - Utrecht, The Netherlands

T2 - 16th Workshop on Circuits, Systems and Signal Processing, ProRISC 2005

Y2 - 17 November 2005 through 18 November 2005

ER -

Determining DfT Hardware by VHDL-AMS Fault Simulation for Biological Micro-Electronic Fluidic Arrays

Abstract

Workshop

Keywords

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