Ultralow power compressor circuits implementation with different logic styles
Nowadays, with the increasing use of the portable electronic devices, the ultralow power CMOS circuit design becomes a vital issue. Methods and techniques are developed to achieve the low power consumption for digital system successfully. One of the aggressive approaches is to operate transistors of...
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sg-ntu-dr.10356-687092023-07-04T15:04:43Z Ultralow power compressor circuits implementation with different logic styles Zhang, Yuxiang Lau Kim Teen School of Electrical and Electronic Engineering DRNTU::Engineering::Electrical and electronic engineering Nowadays, with the increasing use of the portable electronic devices, the ultralow power CMOS circuit design becomes a vital issue. Methods and techniques are developed to achieve the low power consumption for digital system successfully. One of the aggressive approaches is to operate transistors of the digital logic circuit in the sub-threshold or near-threshold region, which is proposed to be an effective way to reduce the power consumption in the digital circuit design. In this project, by employing this technique, several kinds of compressor circuits with ultralow power consumption will be designed and analyzed. However, when the circuits are operating in the near-threshold region, it will experience the speed penalty. As a result, the power-delay production (PDP) will be calculated to get the best trade off between the delay and power consumption for the digital circuits. At the first stage, it will focus on the compressor structures and functionality, including 3-2 compressor, 4-2 compressor and 5-2 compressor. These compressor circuits will be designed in three logic styles — the static circuits, the pass transistor circuits and clock-delayed (CD) domino circuits. Subsequently, the circuit blocks in the different logic design styles will be implemented by the optimized circuits of XOR and MUX sub-blocks. At the second stage, different voltage level and frequency level of input signal will be simulated in each compressor circuit, and all the simulation results will be presented and analyzed in these three aspects — propagation delay, power consumption and power-delay production (PDP) to evaluate the performance of the compressors. In the third stage, the comparison of two different kinds of CD domino circuits would be conducted to obtain the most power-delay efficient circuit architecture. Master of Science (Electronics) 2016-05-31T02:33:45Z 2016-05-31T02:33:45Z 2016 Thesis http://hdl.handle.net/10356/68709 en 129 p. application/pdf |
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DRNTU::Engineering::Electrical and electronic engineering Zhang, Yuxiang Ultralow power compressor circuits implementation with different logic styles |
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Nowadays, with the increasing use of the portable electronic devices, the ultralow power CMOS circuit design becomes a vital issue. Methods and techniques are developed to achieve the low power consumption for digital system successfully. One of the aggressive approaches is to operate transistors of the digital logic circuit in the sub-threshold or near-threshold region, which is proposed to be an effective way to reduce the power consumption in the digital circuit design. In this project, by employing this technique, several kinds of compressor circuits with ultralow power consumption will be designed and analyzed. However, when the circuits are operating in the near-threshold region, it will experience the speed penalty. As a result, the power-delay production (PDP) will be calculated to get the
best trade off between the delay and power consumption for the digital circuits. At the first stage, it will focus on the compressor structures and functionality, including 3-2 compressor, 4-2 compressor and 5-2 compressor. These compressor circuits will be designed in three logic styles — the static circuits, the pass transistor circuits and clock-delayed (CD) domino circuits. Subsequently, the circuit blocks in the different logic design styles will be implemented by the optimized circuits of XOR and MUX sub-blocks. At the second stage, different voltage level and frequency level of input signal will be simulated in each compressor circuit, and all the simulation results will be presented and analyzed in these three aspects — propagation delay, power consumption and power-delay production (PDP) to evaluate the performance of the compressors. In the third stage, the comparison of two different kinds of CD domino circuits would be conducted to obtain the most power-delay efficient circuit architecture. |
| author2 |
Lau Kim Teen |
| author_facet |
Lau Kim Teen Zhang, Yuxiang |
| format |
Theses and Dissertations |
| author |
Zhang, Yuxiang |
| author_sort |
Zhang, Yuxiang |
| title |
Ultralow power compressor circuits implementation with different logic styles |
| title_short |
Ultralow power compressor circuits implementation with different logic styles |
| title_full |
Ultralow power compressor circuits implementation with different logic styles |
| title_fullStr |
Ultralow power compressor circuits implementation with different logic styles |
| title_full_unstemmed |
Ultralow power compressor circuits implementation with different logic styles |
| title_sort |
ultralow power compressor circuits implementation with different logic styles |
| publishDate |
2016 |
| url |
http://hdl.handle.net/10356/68709 |
| _version_ |
1772827914742530048 |