Designing of an algebraic signature analyzer for mixed-signal systems

Designing of an algebraic signature analyzer for mixed-signal systems and testing

10.32920/ryerson.14651967 ◽

2021 ◽

Author(s):

Muhammad Mohsin Babar

Keyword(s):

Digital Circuits ◽

Interesting Property ◽

Hardware Complexity ◽

Mixed Signal ◽

The Past ◽

Signal Systems ◽

Analog Signals ◽

Algebraic Signature ◽

Signature Analyzer ◽

The Common

While the design of signature analyzers for digital circuits has been well researched in the past, the common design technique of a signature analyzer for mixed-signal systems is based on the rules of an arithmetic finite field. The analyzer does not contain carry propagating circuitry, which improves its performance as well as fault tolerance. The signatures possess the interesting property that if the input analog signal is imprecise within certain bounds (an inherent property of analog signals), then the generated signature is also imprecise within certain bounds. We offer a method to designing an algebraic signature analyzer that can be used for mixed-signal systems testing. The application of this technique to the systems with an arbitrary radix is a challenging task and the devices designed possess high hardware complexity. The proposed technique is simple and applicable to systems of any size and radix. The hardware complexity is low. The technique can also be used in algebraic coding and cryptography.

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Designing of an algebraic signature analyzer for mixed-signal systems and testing

10.32920/ryerson.14651967.v1 ◽

2021 ◽

Author(s):

Muhammad Mohsin Babar

Keyword(s):

Digital Circuits ◽

Interesting Property ◽

Hardware Complexity ◽

Mixed Signal ◽

The Past ◽

Signal Systems ◽

Analog Signals ◽

Algebraic Signature ◽

Signature Analyzer ◽

The Common

While the design of signature analyzers for digital circuits has been well researched in the past, the common design technique of a signature analyzer for mixed-signal systems is based on the rules of an arithmetic finite field. The analyzer does not contain carry propagating circuitry, which improves its performance as well as fault tolerance. The signatures possess the interesting property that if the input analog signal is imprecise within certain bounds (an inherent property of analog signals), then the generated signature is also imprecise within certain bounds. We offer a method to designing an algebraic signature analyzer that can be used for mixed-signal systems testing. The application of this technique to the systems with an arbitrary radix is a challenging task and the devices designed possess high hardware complexity. The proposed technique is simple and applicable to systems of any size and radix. The hardware complexity is low. The technique can also be used in algebraic coding and cryptography.

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On the Use of an Algebraic Signature Analyzer for Mixed-Signal Systems Testing

VLSI Design ◽

10.1155/2014/465907 ◽

2014 ◽

Vol 2014 ◽

pp. 1-8 ◽

Cited By ~ 1

Author(s):

Vadim Geurkov ◽

Lev Kirischian

Keyword(s):

Fault Tolerance ◽

Finite Field ◽

Design Technique ◽

Hardware Complexity ◽

Mixed Signal ◽

Signal Systems ◽

Algebraic Signature ◽

Signature Analyzer ◽

The Common

We propose an approach to design of an algebraic signature analyzer that can be used for mixed-signal systems testing. The analyzer does not contain carry propagating circuitry, which improves its performance as well as fault tolerance. The common design technique of a signature analyzer for mixed-signal systems is based on the rules of an arithmetic finite field. The application of this technique to the systems with an arbitrary radix is a challenging task and the devices designed possess high hardware complexity. The proposed technique is simple and applicable to systems of any size and radix. The hardware complexity is low. The technique can also be used in arithmetic/algebraic coding and cryptography.

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Mixed signal testing system technique with algebraic signature analyzer without carry propagation

10.32920/ryerson.14654679.v1 ◽

2021 ◽

Author(s):

Mohammed Faruque Ahmed

Keyword(s):

Testing System ◽

Signal System ◽

High Complexity ◽

Hardware Complexity ◽

Mixed Signal ◽

Algebraic Signature ◽

Signature Analyzer ◽

System Technique ◽

Algebraic Cryptography ◽

Mixed Signal Testing

Signature Analyzer is an analyzer which is widely used for mixed-signal system testing. But its hardware has high complexity in implementation as the application technique is a system with rules of an arithmetic finite field with arbitrary radix. It’s a challenging task. To avoid this complexity here the project is made based on Algebraic Signature Analyzer that can be used for mixed signal testing and the analyzer doesn’t contain carry propagation circuitry. It improves performance and fault tolerance. This technique is simple and applicable to systems of any size or radix. The hardware complexity is very low compared to the conventional one and can be used in arithmetic/ algebraic cryptography as well as coding

Download Full-text

Mixed signal testing system technique with algebraic signature analyzer without carry propagation

10.32920/ryerson.14654679 ◽

2021 ◽

Author(s):

Mohammed Faruque Ahmed

Keyword(s):

Testing System ◽

Signal System ◽

High Complexity ◽

Hardware Complexity ◽

Mixed Signal ◽

Algebraic Signature ◽

Signature Analyzer ◽

System Technique ◽

Algebraic Cryptography ◽

Mixed Signal Testing

Signature Analyzer is an analyzer which is widely used for mixed-signal system testing. But its hardware has high complexity in implementation as the application technique is a system with rules of an arithmetic finite field with arbitrary radix. It’s a challenging task. To avoid this complexity here the project is made based on Algebraic Signature Analyzer that can be used for mixed signal testing and the analyzer doesn’t contain carry propagation circuitry. It improves performance and fault tolerance. This technique is simple and applicable to systems of any size or radix. The hardware complexity is very low compared to the conventional one and can be used in arithmetic/ algebraic cryptography as well as coding

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Rapid prototyping of algorithmic A/D converters based on FPAA devices

Bulletin of the Polish Academy of Sciences Technical Sciences ◽

10.2478/bpasts-2013-0073 ◽

2013 ◽

Vol 61 (3) ◽

pp. 691-696 ◽

Cited By ~ 4

Author(s):

R. Suszynski ◽

K. Wawryn

Keyword(s):

Rapid Prototyping ◽

Sinusoidal Signal ◽

Digital Converter ◽

Mixed Signal ◽

Analog Digital Converter ◽

Signal Systems ◽

Programmable Analog ◽

Field Programmable ◽

Field Programmable Analog Array

Abstract A rapid prototyping method for designing mixed signal systems has been presented in the paper. The method is based on implementation of the field programmable analog array (FPAA) to configure and reconfigure mixed signal systems. A serial algorithmic analog digital converter has been used as an example. Three converter architectures have been selected and implemented FPAA device. To verify and illustrate converters operation and prototyping capabilities, implemented converters have been excited by a sinusoidal signal. Analog sinusoidal excitations, digital responses and sinusoidal waveforms after reconstruction are presented.

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