Design of a Nine-Transistor/Two-Magnetic-Tunnel-Junction-Cell-Based Low-Energy Nonvolatile Ternary Content-Addressable Memory

Matsunaga, Satoru; Katsumata, Akitoshi; Natsui, Masanori; Endoh, Tetsuo; Ohno, Hideo; Hanyu, Takahiro

doi:10.1143/jjap.51.02bm06

Cited by 18 publications

(8 citation statements)

References 22 publications

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“…For performance comparisons, a conventional 9T-2MTJ cell based TCAM is designed, based on the word structure shown in Fig. 6, where R P is 2 kΩ and R AP is 4 kΩ used in [9]. The two TCAMs are simulated using HSPICE at the supply voltage of 1.0V and the temperature of 25 degrees Celsius.…”

Section: B Simulation Resultsmentioning

confidence: 99%

“…The search delay time is 920 ps that is 28% larger than that without a soft error as the resistance value of 2R AP +R P is closer to the threshold than the original value of 3R AP . Table I shows performance comparisons with the conventional TCAM [9]. The conventional TCAM is designed for the same size of the proposed TCAM and simulated for performance comparisons.…”

Section: B Simulation Resultsmentioning

confidence: 99%

“…The MTJ device stores one-bit information as a resistance value [7] and has recently been exploited for nonvolatile memories (MRAM) and TCAMs [8], [9]. The stored bit is quite robust against direct particle strikes [10], but might be flipped by a current pulse signal generated at peripheral transistors due to particle strikes [11].…”

Section: Introductionmentioning

confidence: 99%

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Design of a soft-error tolerant 9-transistor/6-magnetic-tunnel-junction hybrid cell based nonvolatile TCAM

Onizawa

Matsunaga

Hanyu

2014

2014 IEEE 12th International New Circuits and Systems Conference (NEWCAS)

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This paper introduces a soft-error tolerant ternary content-addressable memory (TCAM) cell based on a transistor/magnetic-tunnel-junction (MTJ) hybrid structure. The MTJ device stores one-bit information as a resistance value and is often used for non-volatile memories. In the proposed nine-transistor (9T)/six-MTJ (6MTJ) cell, one-bit information is redundantly represented using three MTJs to mask a one-bit error per cell that might be occurred due to particle strikes. Thanks to the stackability of the MTJ device over a CMOS layer, there is no area overhead due to the redundancy compared to a conventional 9T-2MTJ cell. A 256-word 64-bit TCAM based on the proposed cell is designed under a 90nm CMOS/MTJ process and is evaluated using HSPICE simulation. The simulation resultsshow that the proposed TCAM properly operates under a one-bit error per cell with comparable energy, area and a 14% delay overhead compared to the conventional TCAM. Compared to a CMOS-based TCAM with an error-correction code that masks a one-bit error per word, the proposed TCAM reduces the nubmer of transistors by 81% while masking a one-bit error per cell.

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Section: B Simulation Resultsmentioning

confidence: 99%

Section: B Simulation Resultsmentioning

confidence: 99%

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Design of a soft-error tolerant 9-transistor/6-magnetic-tunnel-junction hybrid cell based nonvolatile TCAM

Onizawa

Matsunaga

Hanyu

2014

2014 IEEE 12th International New Circuits and Systems Conference (NEWCAS)

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“…Various hybrid CMOS/MTJ circuits are realized using this approach, a few of them are NV-NAND/AND, NV-NOR/OR and NV-XNOR/XOR [241,305], magnetic flip-flops [306,307], magnetic look up table [92,308], magnetic full adder [31,290,303,[309][310][311][312], magnetic decoder [313], magnetic true random number generator [314][315][316], magnetic arithmetic logic unit (ALU) [317,318] and magnetic cryptographic circuits [319] etc.. Due to high magnetic sensitivity of MTJ, hybrid circuits are further used in developing the magnetic sensors [14,320,321], NV-FPGA circuit [92,[322][323][324][325][326][327][328][329][330][331], NVternary content addressable memory (TCAM) memory [332][333][334][335][336][337][338][339], NV random access logic LSI unit [38,340], ultra-lowpower VLSI design processor…”

Section: (Iii)mentioning

confidence: 99%

From MTJ Device to Hybrid CMOS/MTJ Circuits: A Review

et al. 2020

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Spintronics is one of the growing research areas which has the capability to overcome the issues of static power dissipation and volatility suffered by the complementary metal-oxide-semiconductor (CMOS) industry. Magnetic tunnel junction (MTJ), one of the prominent spintronic devices, is not only used to develop the fully non-volatile-logic (NV-L) but combines magnetism and electronics to develop next-generation NVmemory (NV-M) and hybrid CMOS/MTJ circuits. To be specific towards hybrid CMOS/MTJ circuits, the fabrication of first hybrid full-adder in 2009, fabrication of MTJ based 240-tile NV-field programmable gate array (NV-FPGA) chip in 2013, fabrication of a 3000-6-input-LUTs based NV-FPGA chip in 2015, fabrication of MTJ based NV-logic-in-memory-large scale integration (NV-LIM-LSI) in 2017 and recently the fabrication of a full hybrid magnetic/CMOS System on Chip (SoC) under EU GREAT Project in 2019 has strengthened the belief and motivated the researcher to be continued in this domain. This review article aims to provide the complete design flow of hybrid CMOS/MTJ circuits developed using one of the fab compatible MTJ spintronic devices and its integration with conventional CMOS logic. The broad coverage of the article is MTJ construction, its switching mechanisms, a brief history of various compact models, reliability issues, and the concept of logic-in-memory (LIM) architecture. Finally, the article concludes with the challenges and future prospects of hybrid CMOS/MTJ circuits, which will motivate people in academia to cultivate research in this domain and industry to realize the prototype for a wide range of potential applications.

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“…These NVM-based CAM designs can help reduce area and power consumption while enabling acceleration of various neural network architectures [2], [11]. MTJ based CAM designs, e.g., 9T-2MTJ CAM cell [12], mitigates the memory density bottleneck, but the small R ON /R OF F ratio and large write power of MTJs significantly degrades the CAM performance. The CAM designs based on resistive memory devices, including ReRAM [7] and phase change memory (PCM) [6], are advantageous in memory density, but have limited R ON /R OF F ratio and significant write power, which is challenging to overcome.…”

Section: Introductionmentioning

confidence: 99%

FeCAM: A Universal Compact Digital and Analog Content Addressable Memory Using Ferroelectric

Yin

Huang

et al. 2020

IEEE Trans. Electron Devices

100

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Ferroelectric field effect transistors (FeFETs) are being actively investigated with the potential for in-memory computing (IMC) over other non-volatile memories (NVMs). Content Addressable Memories (CAMs) are a form of IMC that performs parallel searches for matched entries over a memory array for a given input query. CAMs are widely used for data-centric applications that involve pattern matching and search functionality. To accommodate the ever expanding data, it is attractive to resort to analog CAM for memory density improvement. However, the digital CAM design nowadays based on standard CMOS or emerging nonvolatile memories (e.g., resistive storage devices) is already challenging due to area, power, and cost penalties. Thus, it can be extremely expensive to achieve analog CAM with those technologies due to added cell components. As such, we propose, for the first time, a universal compact FeFET based CAM design, FeCAM, with search and storage functionality enabled in digital and analog domain simultaneously. By exploiting the multi-level-cell (MLC) states of FeFET, FeCAM can store and search inputs in either digital or analog domain. We perform a device-circuit co-design of the proposed FeCAM and validate its functionality and performance using an experimentally calibrated FeFET model. Circuit level simulation results demonstrate that FeCAM can either store continuous matching ranges or encode 3-bit data in a single CAM cell. When compared with the existing digital CMOS based CAM approaches, FeCAM is found to improve both memory density by 22.4× and energy saving by 8.6/3.2× for analog/digital modes, respectively. In the CAM-related application, our evaluations show that FeCAM can achieve 60.5×/23.1× saving in area/search energy compared with conventional CMOS based CAMs.

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Design of a Nine-Transistor/Two-Magnetic-Tunnel-Junction-Cell-Based Low-Energy Nonvolatile Ternary Content-Addressable Memory

Cited by 18 publications

References 22 publications

Design of a soft-error tolerant 9-transistor/6-magnetic-tunnel-junction hybrid cell based nonvolatile TCAM

Design of a soft-error tolerant 9-transistor/6-magnetic-tunnel-junction hybrid cell based nonvolatile TCAM

From MTJ Device to Hybrid CMOS/MTJ Circuits: A Review

FeCAM: A Universal Compact Digital and Analog Content Addressable Memory Using Ferroelectric

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