Enabling efficient pure-NMOS circuits through Adiabatic Complementary Pass-transistor Logic
Enabling efficient pure-NMOS circuits through Adiabatic Complementary Pass-transistor Logic
For many emerging computing technologies, such as wearable and flexible IoT devices, power and energy consumption may be of far greater importance than performance and operating frequency. For some of the novel processes that underpin these technologies, efficient P-type transistors are not yet available and hence pure-NMOS logic is required. In this paper, we show that adiabatic (or reversible) logic provides an attractive solution for such technologies. We investigate the feasibility of applying Adiabatic Complementary Pass-transistor Logic (ACPL) to pure-NMOS implementations and verify through simulation that the energy dissipation of a Carry Look-ahead Adder (CLA) can be reduced to less than 1% of that required by conventional NMOS logic. Furthermore, we propose a novel 2-phase ACPL named ACPL-2, which uses the same clock source as the 4-phase version but reduces the number of transistors of a binary counter by 21% without affecting the overall energy consumption.
Chen, Keyu
854fa139-4391-44ed-85bb-fa638ab2c0f7
Merrett, Geoff
89b3a696-41de-44c3-89aa-b0aa29f54020
Zwolinski, Mark
adfcb8e7-877f-4bd7-9b55-7553b6cb3ea0
Chen, Keyu
854fa139-4391-44ed-85bb-fa638ab2c0f7
Merrett, Geoff
89b3a696-41de-44c3-89aa-b0aa29f54020
Zwolinski, Mark
adfcb8e7-877f-4bd7-9b55-7553b6cb3ea0
Chen, Keyu, Merrett, Geoff and Zwolinski, Mark
(2025)
Enabling efficient pure-NMOS circuits through Adiabatic Complementary Pass-transistor Logic.
23rd IEEE International NEWCAS Conference, , Paris, France.
22 - 25 Jun 2025.
(In Press)
Record type:
Conference or Workshop Item
(Paper)
Abstract
For many emerging computing technologies, such as wearable and flexible IoT devices, power and energy consumption may be of far greater importance than performance and operating frequency. For some of the novel processes that underpin these technologies, efficient P-type transistors are not yet available and hence pure-NMOS logic is required. In this paper, we show that adiabatic (or reversible) logic provides an attractive solution for such technologies. We investigate the feasibility of applying Adiabatic Complementary Pass-transistor Logic (ACPL) to pure-NMOS implementations and verify through simulation that the energy dissipation of a Carry Look-ahead Adder (CLA) can be reduced to less than 1% of that required by conventional NMOS logic. Furthermore, we propose a novel 2-phase ACPL named ACPL-2, which uses the same clock source as the 4-phase version but reduces the number of transistors of a binary counter by 21% without affecting the overall energy consumption.
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Accepted/In Press date: 2025
Venue - Dates:
23rd IEEE International NEWCAS Conference, , Paris, France, 2025-06-22 - 2025-06-25
Identifiers
Local EPrints ID: 501730
URI: http://eprints.soton.ac.uk/id/eprint/501730
PURE UUID: f8933211-50c5-4a8f-8a4e-83c663ccc409
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Date deposited: 09 Jun 2025 17:28
Last modified: 10 Jun 2025 01:42
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Contributors
Author:
Keyu Chen
Author:
Geoff Merrett
Author:
Mark Zwolinski
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