Design and implementation of the IMS A110 image and signal processor

S. R. Barraclough; M. Sotheran; K. Burgin; A. P. Wise; A. Vadher; W. P. Robbins; R. M. Forsyth

Design and implementation of the IMS A110 image and signal processor

S. R. Barraclough, M. Sotheran, K. Burgin, A. P. Wise, A. Vadher, W. P. Robbins, R. M. Forsyth

Electrical and Computer Engineering

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3 Scopus citations

Abstract

The IMS A110 provides a solution to many real-time image- and signal-processing problems by supporting techniques such as 1-D/2-D convolution/correlation, statistical/histogram data collection and nonlinear data transformation. It is a cascadable, software configurable single-chip digital signal-processing device that operates at 20 MHz with a data throughput of 420 MOPS (million operations per second), and consists of three programmable length shift registers, a configurable 21-stage multiply-accumulate array (MAC), a postprocessing unit (PPU) and a microprocessor interface. The chip is fabricated in a single-level-metal 1.2-μm polysilicide CMOS process and contains around 375K transistors on a 9.6-mm × 8.1-mm die, which translates to a site density of 4.1 transistors/mil² (excluding the pad ring). The authors present an overview of the A110 architecture and highlight the key design techniques used to implement the multiply accumulate array.

Original language	English (US)
Pages (from-to)	24.5/1-4
Journal	Proceedings of the Custom Integrated Circuits Conference
State	Published - May 1 1989
Event	Proceedings of the IEEE 1989 Custom Integrated Circuits Conference - San Diego, CA, SA Duration: May 15 1989 → May 18 1989

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title = "Design and implementation of the IMS A110 image and signal processor",

abstract = "The IMS A110 provides a solution to many real-time image- and signal-processing problems by supporting techniques such as 1-D/2-D convolution/correlation, statistical/histogram data collection and nonlinear data transformation. It is a cascadable, software configurable single-chip digital signal-processing device that operates at 20 MHz with a data throughput of 420 MOPS (million operations per second), and consists of three programmable length shift registers, a configurable 21-stage multiply-accumulate array (MAC), a postprocessing unit (PPU) and a microprocessor interface. The chip is fabricated in a single-level-metal 1.2-μm polysilicide CMOS process and contains around 375K transistors on a 9.6-mm × 8.1-mm die, which translates to a site density of 4.1 transistors/mil2 (excluding the pad ring). The authors present an overview of the A110 architecture and highlight the key design techniques used to implement the multiply accumulate array.",

author = "Barraclough, {S. R.} and M. Sotheran and K. Burgin and Wise, {A. P.} and A. Vadher and Robbins, {W. P.} and Forsyth, {R. M.}",

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AU - Barraclough, S. R.

AU - Sotheran, M.

AU - Burgin, K.

AU - Wise, A. P.

AU - Vadher, A.

AU - Robbins, W. P.

AU - Forsyth, R. M.

PY - 1989/5/1

Y1 - 1989/5/1

N2 - The IMS A110 provides a solution to many real-time image- and signal-processing problems by supporting techniques such as 1-D/2-D convolution/correlation, statistical/histogram data collection and nonlinear data transformation. It is a cascadable, software configurable single-chip digital signal-processing device that operates at 20 MHz with a data throughput of 420 MOPS (million operations per second), and consists of three programmable length shift registers, a configurable 21-stage multiply-accumulate array (MAC), a postprocessing unit (PPU) and a microprocessor interface. The chip is fabricated in a single-level-metal 1.2-μm polysilicide CMOS process and contains around 375K transistors on a 9.6-mm × 8.1-mm die, which translates to a site density of 4.1 transistors/mil2 (excluding the pad ring). The authors present an overview of the A110 architecture and highlight the key design techniques used to implement the multiply accumulate array.

AB - The IMS A110 provides a solution to many real-time image- and signal-processing problems by supporting techniques such as 1-D/2-D convolution/correlation, statistical/histogram data collection and nonlinear data transformation. It is a cascadable, software configurable single-chip digital signal-processing device that operates at 20 MHz with a data throughput of 420 MOPS (million operations per second), and consists of three programmable length shift registers, a configurable 21-stage multiply-accumulate array (MAC), a postprocessing unit (PPU) and a microprocessor interface. The chip is fabricated in a single-level-metal 1.2-μm polysilicide CMOS process and contains around 375K transistors on a 9.6-mm × 8.1-mm die, which translates to a site density of 4.1 transistors/mil2 (excluding the pad ring). The authors present an overview of the A110 architecture and highlight the key design techniques used to implement the multiply accumulate array.

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SN - 0886-5930

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T2 - Proceedings of the IEEE 1989 Custom Integrated Circuits Conference

Y2 - 15 May 1989 through 18 May 1989

ER -

Design and implementation of the IMS A110 image and signal processor

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