Functional Demonstration of a Memristive Arithmetic Logic Unit (MemALU) for In‐Memory Computing

Cheng, Lan; Li, Yi; Yin, Kang-Sheng; Hu, Song; Su, Yi-Sheng; Jin, Miao-Miao; Wang, Zhuorui; Chang, Ting‐Chang; Miao, Xiangshui

doi:10.1002/adfm.201905660

Cited by 62 publications

(54 citation statements)

References 30 publications

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“…Functional demonstration of the arithmetic-logic module, which is the core unit of a computer CPU, is also made possible by the combination of the NAND, OR, AND, and NOR operators with a 4 (bit line, BL) × 3 (word line, WL) PBDTT-BQTPA memristor array 44 , 45 . Figure 5 a, b show the design and memristor array representation of the parallel 1-bit full adder circuit involving only five polymer devices.…”

Section: Resultsmentioning

confidence: 99%

90% yield production of polymer nano-memristor for in-memory computing

et al. 2021

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Polymer memristors with light weight and mechanical flexibility are preeminent candidates for low-power edge computing paradigms. However, the structural inhomogeneity of most polymers usually leads to random resistive switching characteristics, which lowers the production yield and reliability of nanoscale devices. In this contribution, we report that by adopting the two-dimensional conjugation strategy, a record high 90% production yield of polymer memristors has been achieved with miniaturization and low power potentials. By constructing coplanar macromolecules with 2D conjugated thiophene derivatives to enhance the π–π stacking and crystallinity of the thin film, homogeneous switching takes place across the entire polymer layer, with fast responses in 32 ns, D2D variation down to 3.16% ~ 8.29%, production yield approaching 90%, and scalability into 100 nm scale with tiny power consumption of ~ 10−15 J/bit. The polymer memristor array is capable of acting as both the arithmetic-logic element and multiply-accumulate accelerator for neuromorphic computing tasks.

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Section: Resultsmentioning

confidence: 99%

90% yield production of polymer nano-memristor for in-memory computing

et al. 2021

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“…The next step is cascading the gates for computing. Many studies have demonstrated various logic circuits, such as an adder, [34,35,37,40,44,47,49,55,57,[60][61][62][63][64][65][66][67][68][69] multiplier, [37,55,[70][71][72] multiplexer, [73][74][75][76] other combinational logic circuits, [49,[77][78][79] and sequential logic circuits. [29,80,81] These operations can be used to implement image processing, [82] neural networks, [83][84][85] and hyperdimensional computing [43,46,86] in in-memory computing.…”

Section: Competition For Full Adder Executionmentioning

confidence: 99%

Memristive Stateful Logic for Edge Boolean Computers

Kim

Son

Kim

2021

Advanced Intelligent Systems

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Memristive stateful logic enables complete in-memory computing, allowing low-power and low-cost Boolean computing. Its characteristics are consistent with the requirements of edge computing devices, which will occupy a considerable segment in the coming Internet of things (IoT) era. In this review, recent developments in stateful logic technology are intensively explored. The topics include a summary of the evolution of stateful logic gates and their cascading strategies for Boolean computing. Also, array-level data manipulation is discussed, and its role in realizing massive computation inside the memory. Finally, the logic operation error issue is discussed, with feasible solutions.

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“…[6][7][8] Taking consideration of both the conventional silicon memory cells and the newly invented information storage technologies, resistive switching memory (also known as resistive random access memory or RRAM in short) can be rationally marked as the most promising stretchable information storage technology due to the structural simplicity of a resistor and the prodigious range of materials selection, in addition to the performance merits of high speed, low power, and intrinsic nonvolatility. [9][10][11][12][13][14][15] Moreover, the logic-in-memory functionality of resistive switching memory enables data computation directly in the memory array, [16,17] thus holding the great potential to simplify the circuit architecture and reduce the energy consumption of the entire wearable electronic system.…”

Section: Stretchable and Twistable Resistive Switching Memory With Inmentioning

confidence: 99%

Stretchable and Twistable Resistive Switching Memory with Information Storage and Computing Functionalities

Lü

Gao

et al. 2020

Adv Materials Technologies

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High‐performance stretchable and twistable nonvolatile memory devices with logic‐in‐memory functionality are highly desired for the development of future wearable electronics such as smart clothing. However, it is challenging to fabricate these memory devices using rigid functional materials based on conventional film deposition and patterning techniques. Herein, the first intrinsically stretchable and twistable resistive switching memory is reported using spin‐coated poly(dimethyl siloxane) elastomer as the storage medium and printed liquid metal as the electrodes. The memory device is found to exhibit a reliable resistive switching behavior under up to 30% stretching strain and 90° torsional deformation, possessing a large memory window (≈102) and an excellent retention (>104 s). Under 30% strain, stretching–release endurance of >500 cycles as well as excellent data integrity during the dynamic stretching–release process is demonstrated. Beyond data storage, logic‐in‐memory computation prototype represented by a one‐bit full adder is successfully implemented within four operation steps based on three stretched memory cells. This work will be highly valuable in materials and structure design towards the development of high‐performance and multifunctional wearable electronic modules and systems.

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Functional Demonstration of a Memristive Arithmetic Logic Unit (MemALU) for In‐Memory Computing

Cited by 62 publications

References 30 publications

90% yield production of polymer nano-memristor for in-memory computing

90% yield production of polymer nano-memristor for in-memory computing

Memristive Stateful Logic for Edge Boolean Computers

Stretchable and Twistable Resistive Switching Memory with Information Storage and Computing Functionalities

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