scholarly journals Area, Power and Speed Optimized Early Output Majority Voter for Asynchronous TMR Implementation

Electronics ◽  
2021 ◽  
Vol 10 (12) ◽  
pp. 1425
Author(s):  
Padmanabhan Balasubramanian ◽  
Nikos E. Mastorakis
Keyword(s):  
Cycle Time ◽  
Power Dissipation ◽  
Data Communication ◽  
Cmos Technology ◽  
Silicon Area ◽  
Power Cycle ◽  
Data Encoding ◽  
Power Product ◽  
Majority Voter ◽  
Modular Redundancy

This paper presents a new, efficient asynchronous early output majority voter that can be used to effectively realize an asynchronous triple modular redundancy (TMR) implementation. For the input-output mode asynchronous realization, the dual-rail code was used for data encoding and four phase return-to-zero and return-to-one handshake schemes were separately used for data communication. The proposed majority voter requires 62.8% less area and dissipates 37% less power on average compared to the best of the existing asynchronous majority voters while considering both handshake schemes. Importantly, the reductions in area and power are achieved without sacrificing the speed. Example TMR implementations show that the proposed majority voter leads to simultaneous reductions in cycle time, silicon area, and power dissipation. As a result, the proposed majority voter enables improved optimization in figure-of-merits such as area–cycle time product, power–cycle time product, and area–cycle time–power product for TMR implementations utilizing it compared to TMR implementations incorporating other majority voters. The circuits were implemented using a 32/28-nm CMOS technology.

scholarly journals Early Output Quasi-Delay-Insensitive Array Multipliers

Electronics ◽  
2019 ◽  
Vol 8 (4) ◽  
pp. 444 ◽  
Author(s):  
Balasubramanian ◽  
Maskell ◽  
Naayagi ◽  
Mastorakis
Keyword(s):  
Cycle Time ◽  
Arithmetic Operation ◽  
Data Communication ◽  
Digital Signal ◽  
Complementary Metal Oxide Semiconductor ◽  
Cmos Technology ◽  
Data Representation ◽  
Oxide Semiconductor ◽  
Array Multiplier ◽  
Array Multipliers

Multiplication is a widely used arithmetic operation in microprocessing and digital signal processing applications, and multiplication is realized using a multiplier. This article presents the quasi-delay-insensitive (QDI) early output versions of recently reported indicating asynchronous array multipliers. Delay-insensitive dual-rail encoding is used for data representation and processing, and 4-phase return-to-zero (RTZ) and return-to-one (RTO) handshake protocols are used for data communication. Many QDI array multipliers were realized using a 32/28 nm complementary metal oxide semiconductor (CMOS) technology. Compared to the optimum indicating array multiplier, the proposed optimum early output array multiplier achieves a 6.2% reduction in cycle time and a 7.4% reduction in power-cycle time product (PCTP) with respect to RTZ handshaking, and a 7.6% reduction in cycle time and an 8.8% reduction in PCTP with respect to RTO handshaking without an increase in the area. The simulation results also convey that the RTO handshaking is preferable to the RTZ handshaking for the optimum implementation of QDI array multipliers.

scholarly journals Asynchronous quasi delay insensitive majority voters corresponding to quintuple modular redundancy for mission/safety-critical applications

PLoS ONE ◽  
2020 ◽  
Vol 15 (9) ◽  
pp. e0239395
Author(s):  
P. Balasubramanian ◽  
N. E. Mastorakis
Keyword(s):  
Data Communication ◽  
Cmos Process ◽  
Electronic Circuits ◽  
Asynchronous Design ◽  
Multiple Faults ◽  
Safety Critical ◽  
Majority Voter ◽  
Modular Redundancy ◽  
Power And Energy ◽  
Design Style

Electronic circuits and systems employed in mission- and safety-critical applications such as space, aerospace, nuclear plants etc. tend to suffer from multiple faults due to radiation and other harsh external phenomena. To overcome single or multiple faults from affecting electronic circuits and systems, progressive module redundancy (PMR) has been suggested as a potential solution that recommends the use of different levels of redundancy for the vulnerable portions of a circuit or system depending upon their criticality. According to PMR, triple modular redundancy (TMR) can be used where a single fault is likely to occur and should be masked, and quintuple modular redundancy (QMR) can be used where double faults are likely to occur and should be masked. In this article, we present asynchronous QDI majority voter designs for QMR and state which are preferable from cycle time (i.e., speed), area, power, and energy perspectives. Towards this, we implemented example QMR circuits in a robust QDI asynchronous design style by employing a delay insensitive dual rail code for data encoding and adopting four-phase handshake protocols for data communication. Based on physical implementations using a 32/28nm CMOS process, we find that our proposed QMR majority voter achieves improved optimization in speed and energy.

scholarly journals Majority and Minority Voted Redundancy Scheme for Safety-Critical Applications with Error/No-Error Signaling Logic

Electronics ◽  
2018 ◽  
Vol 7 (11) ◽  
pp. 272 ◽  
Author(s):  
Padmanabhan Balasubramanian ◽  
Douglas Maskell ◽  
Nikos Mastorakis
Keyword(s):  
Critical Path ◽  
Cmos Technology ◽  
Path Delay ◽  
Silicon Area ◽  
Multiple Faults ◽  
Design Metrics ◽  
Safety Critical ◽  
Critical Path Delay ◽  
Function Blocks ◽  
Modular Redundancy

In the era of nanoelectronics, multiple faults or failures of function blocks are likely to occur. To withstand these, higher levels of redundancy are suggested to be employed in at least the sensitive portions of a circuit or system. In this context, the N-modular redundancy (NMR) scheme may be used to guard against the multiple faults or failures of function blocks. However, the NMR scheme would exacerbate the weight, cost, and design metrics to implement higher-order redundancy. Hence, as an alternative to the NMR, the majority and minority voted redundancy (MMR) scheme was proposed recently. However, the proposal was restricted to the basic implementation with no provision for indicating the correct or the incorrect operation of the MMR. Hence in this work, we present the MMR scheme with the error/no-error signaling logic (ESL). Example NMR circuits without and with the ESL (NMRESL), and example MMR circuits without and with the proposed ESL (MMRESL) were implemented to achieve similar degrees of fault tolerance using a 32/28-nm CMOS technology. The results show that, on average, the proposed MMRESL circuits have 18.9% less critical path delay, dissipate 64.8% less power, and require 49.5% less silicon area compared to their counterpart NMRESL circuits.

Towards the Design of Cost-efficient Generic Register Using Quantum-dot Cellular Automata

2020 ◽  
Vol 10 (4) ◽  
pp. 534-547
Author(s):  
Chiradeep Mukherjee ◽  
Saradindu Panda ◽  
Asish K. Mukhopadhyay ◽  
Bansibadan Maji
Keyword(s):  
Cellular Automata ◽  
Quantum Dot ◽  
Power Dissipation ◽  
Cmos Technology ◽  
Oxide Semiconductor ◽  
Digital Data ◽  
Design Parameters ◽  
Flip Flop ◽  
Quantum Dot Cellular Automata ◽  
Cost Efficient

Background: The advancement of VLSI in the application of emerging nanotechnology explores quantum-dot cellular automata (QCA) which has got wide acceptance owing to its ultra-high operating speed, extremely low power dissipation with a considerable reduction in feature size. The QCA architectures are emerging as a potential alternative to the conventional complementary metal oxide semiconductor (CMOS) technology. Experimental: Since the register unit has a crucial role in digital data transfer between the electronic devices, such study leading to the design of cost-efficient and highly reliable QCA register is expected to be a prudent area of research. A thorough survey on the existing literature shows that the generic models of Serial-in Serial Out (SISO), Serial-in-Parallel-Out (SIPO), Parallel-In- Serial-Out (PISO) and Parallel-in-Parallel-Out (PIPO) registers are inadequate in terms of design parameters like effective area, delay, O-Cost, Costα, etc. Results: This work introduces a layered T gate for the design of the D flip flop (LTD unit), which can be broadly used in SISO, SIPO, PISO, and PIPO register designs. For detection and reporting of high susceptible errors and defects at the nanoscale, the reliability and defect tolerant analysis of LTD unit are also carried out in this work. The QCA design metrics for the general register layouts using LTD unit is modeled. Conclusion: Moreover, the cost metrics for the proposed LTD layouts are thoroughly studied to check the functional complexity, fabrication difficulty and irreversible power dissipation of QCA register layouts.

scholarly journals Low Power Robust Early Output Asynchronous Block Carry Lookahead Adder with Redundant Carry Logic

Electronics ◽  
2018 ◽  
Vol 7 (10) ◽  
pp. 243 ◽  
Author(s):  
Padmanabhan Balasubramanian ◽  
Douglas Maskell ◽  
Nikos Mastorakis
Keyword(s):  
Low Power ◽  
Digital Signal Processor ◽  
Digital Signal ◽  
Complementary Metal Oxide Semiconductor ◽  
Low Power Design ◽  
Cmos Technology ◽  
General Purpose ◽  
Metal Oxide Semiconductor ◽  
Oxide Semiconductor ◽  
Power Cycle

Adder is an important datapath unit of a general-purpose microprocessor or a digital signal processor. In the nanoelectronics era, the design of an adder that is modular and which can withstand variations in process, voltage and temperature are of interest. In this context, this article presents a new robust early output asynchronous block carry lookahead adder (BCLA) with redundant carry logic (BCLARC) that has a reduced power-cycle time product (PCTP) and is a low power design. The proposed asynchronous BCLARC is implemented using the delay-insensitive dual-rail code and adheres to the 4-phase return-to-zero (RTZ) and the 4-phase return-to-one (RTO) handshaking. Many existing asynchronous ripple-carry adders (RCAs), carry lookahead adders (CLAs) and carry select adders (CSLAs) were implemented alongside to perform a comparison based on a 32/28 nm complementary metal-oxide-semiconductor (CMOS) technology. The 32-bit addition was considered for an example. For implementation using the delay-insensitive dual-rail code and subject to the 4-phase RTZ handshaking (4-phase RTO handshaking), the proposed BCLARC which is robust and of early output type achieves: (i) 8% (5.7%) reduction in PCTP compared to the optimum RCA, (ii) 14.9% (15.5%) reduction in PCTP compared to the optimum BCLARC, and (iii) 26% (25.5%) reduction in PCTP compared to the optimum CSLA.

scholarly journals Reduction of Power Dissipation in Dynamic BiCMOS Logic Gates by Transistor Reordering

VLSI Design ◽  
2002 ◽  
Vol 15 (2) ◽  
pp. 547-553
Author(s):  
S. M. Rezaul Hasan ◽  
Yufridin Wahab
Keyword(s):  
Power Dissipation ◽  
Figure Of Merit ◽  
Low Voltage ◽  
Logic Gates ◽  
Base Layer ◽  
Cmos Process ◽  
Silicon Area ◽  
Dynamic Power ◽  
Analog Cmos ◽  
Power Delay Product

This paper explores the deterministic transistor reordering in low-voltage dynamic BiCMOS logic gates, for reducing the dynamic power dissipation. The constraints of load driving (discharging) capability and NPN turn-on delay for MOSFET reordered structures has been carefully considered. Simulations shows significant reduction in the dynamic power dissipation for the transistor reordered BiCMOS structures. The power-delay product figure-of-merit is found to be significantly enhanced without any associated silicon-area penalty. In order to experimentally verify the reduction in power dissipation, original and reordered structures were fabricated using the MOSIS 2 μm N-well analog CMOS process which has a P-base layer for bipolar NPN option. Measured results shows a 20% reduction in the power dissipation for the transistor reordered structure, which is in close agreement with the simulation.

scholarly journals A Flux Controlled Memristor using 90nm Technology

2021 ◽  
pp. 1-6
Author(s):  
B.T. Krishna ◽  
◽  
Shaik. mohaseena Salma ◽  
Keyword(s):  
Power Supply ◽  
Power Dissipation ◽  
Power Efficiency ◽  
Current Mode ◽  
Cmos Technology ◽  
Theoretical Simulation ◽  
Transconductance Amplifier ◽  
Higher Power ◽  
Static Power ◽  
A Current

A flux-controlled memristor using complementary metal–oxide–(CMOS) structure is presented in this study. The proposed circuit provides higher power efficiency, less static power dissipation, lesser area, and can also reduce the power supply by using CMOS 90nm technology. The circuit is implemented based on the use of a second-generation current conveyor circuit (CCII) and operational transconductance amplifier (OTA) with few passive elements. The proposed circuit uses a current-mode approach which improves the high frequency performance. The reduction of a power supply is a crucial aspect to decrease the power consumption in VLSI. An offered emulator in this proposed circuit is made to operate incremental and decremental configurations well up to 26.3 MHZ in cadence virtuoso platform gpdk using 90nm CMOS technology. proposed memristor circuit has very little static power dissipation when operating with ±1V supply. Transient analysis, memductance analysis, and dc analysis simulations are verified practically with the Experimental demonstration by using ideal memristor made up of ICs AD844AN and CA3080, using multisim which exhibits theoretical simulation are verified and discussed.

scholarly journals Approximate Adder: Lower-Part or Adder

2020 ◽  
Vol 9 (7) ◽  
pp. 1176-1180
Keyword(s):  
Real Time ◽  
Power Dissipation ◽  
High Performance ◽  
Building Blocks ◽  
Cmos Technology ◽  
Approximate Computing ◽  
Computing Technique ◽  
Ripple Carry Adder ◽  
Real Time Applications ◽  
Dsp Systems

High-performance VLSI systems are essential in real-time applications, in order to increase the performance of the VLSI systems, an approximate computing technique is followed where the performance of the circuit is enhanced by trading off it with a slight loss in the accuracy. These approximate circuits are used in error-tolerant applications, where output need not be accurate. This paper concentrates mainly on approximate adders, as they are major building blocks of DSP systems. The analysis of the Lower-part OR Adder for 4-bit addition and comparison of it with the precise adder i.e., Ripple Carry Adder using the mentor graphics tool in 90 nm CMOS technology are presented in this paper. Our experimental results show that there is 17%-70% savings in power dissipation, 4%-32% saving in the area, and 19%-84% savings in time due to approximate adder. As the LOA-2 and LOA-3 are performing optimally these two adders can be used for error-tolerant applications and based on the requirement LOA-2 or LOA-3 can be selected.

scholarly journals Design of a Novel CMOS Voltage Divider

2021 ◽  
Author(s):  
Darshil Patel
Keyword(s):  
Power Dissipation ◽  
Voltage Divider ◽  
Cmos Technology ◽  
Voltage Sensing ◽  
Steady Current ◽  
Current Consumption ◽  
Linear Voltage

Passive linear voltage dividers are an essential part of the voltage sensing and detecting circuits. In this paper, a novel voltage divider is designed in 180nm CMOS technology and is validated with LTSpice simulations. The proposed circuit features very low steady current consumption and as a result, very little power dissipation around 200-300pW.

scholarly journals Design of area-efficient GHz range current mode frequency synthesizer using standard CMOS technology

2019 ◽  
Vol 70 (4) ◽  
pp. 323-328
Author(s):  
Dan-Dan Zheng ◽  
Yu-Bin Li ◽  
Chang-Qi Wang ◽  
Kai Huang ◽  
Xiao-Peng Yu
Keyword(s):  
Frequency Synthesizer ◽  
Frequency Tuning ◽  
Supply Voltage ◽  
Current Mode ◽  
Cmos Technology ◽  
Mode Frequency ◽  
Loop Filter ◽  
Silicon Area ◽  
Power Efficient ◽  
A Current

Abstract In this paper, an area and power efficient current mode frequency synthesizer for system-on-chip (SoC) is proposed. A current-mode transformer loop filter suitable for low supply voltage is implemented to remove the need of a large capacitor in the loop filter, and a current controlled oscillator with additional voltage based frequency tuning mechanism is designed with an active inductor. The proposed design is further integrated with a fully programmable frequency divider to maintain a good balance among output frequency operating range, power consumption as well as silicon area. A test chip is implemented in a standard 0.13 µm CMOS technology, measurement result demonstrates that the proposed design has a working range from 916 MHz to 1.1 l GHz and occupies a silicon area of 0.25 mm2 while consuming 8.4 mW from a 1.2 V supply.

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