An offset-tolerant current-sampling-based sense amplifier for Sub-100nA-cell-current nonvolatile memory

Chang, Meng-Fan; Shen, Shin-Jang; Liu, Chia‐Chi; Wu, Che-Wei; Lin, Yung Ming; Wu, Shang-Chi; Huang, Chia-En; Lai, Hang–Chin; King, Ya‐Chin; Lin, Chorng-Jung; Liao, Haijun; Chih, Yu-Der; Yamauchi, Hiroyuki

doi:10.1109/isscc.2011.5746284

Cited by 21 publications

(4 citation statements)

References 8 publications

(8 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Figure 14 shows that when the device mismatch reaches 225 mV, the sensing margin is still enough, and the sense amplifier is valid. The performance in offset-tolerance of the TSOCC-SA is better than that of the CSB-SA in [ 85 ].…”

Section: Sensing Circuit Design Techniques For Rrammentioning

confidence: 99%

Sensing Circuit Design Techniques for RRAM in Advanced CMOS Technology Nodes

et al. 2021

View full text Add to dashboard Cite

Resistive random access memory (RRAM) is one of the most promising new nonvolatile memories because of its excellent properties. Moreover, due to fast read speed and low work voltage, it is suitable for seldom-write frequent-read applications. However, as technology nodes shrink, RRAM faces many issues, which can significantly degrade RRAM performance. Therefore, it is necessary to optimize the sensing schemes to improve the application range of RRAM. In this paper, the issues faced by RRAM in advanced technology nodes are summarized. Then, the advantages and weaknesses in the novel design and optimization methodologies of sensing schemes are introduced in detail from three aspects, the reference schemes, sensing amplifier schemes, and bit line (BL)-enhancing schemes, according to the development of technology in especially recent years, which can be the reference for designing the sensing schemes. Moreover, the waveforms and results of each method are illustrated to make the design easy to understand. With the development of technology, the sensing schemes of RRAM become higher speed and resolution, low power consumption, and are applied at advanced technology nodes and low working voltage. Now, the most advanced nodes the RRAM applied is 14 nm node, the lowest working voltage can reach 0.32 V, and the shortest access time can be only a few nanoseconds.

show abstract

Section: Sensing Circuit Design Techniques For Rrammentioning

confidence: 99%

Sensing Circuit Design Techniques for RRAM in Advanced CMOS Technology Nodes

et al. 2021

View full text Add to dashboard Cite

show abstract

“…The current sensing margin ( ) cannot be increased with a relaxed sensing time ( ), necessitating the use of small current-offset ( ) CSAs for NVMs or ReRAMs. Previous current-sampling based CSAs [25], [26] achieved a small but were not operable at a low because of the large voltage headroom requirement. A body-drain driven (BDD) CSA [16] was proposed to achieve near-0.5 V operations; however, a high yield from the small R-ratio could not be achieved at a low , preventing the use of CSAs for low-applications.…”

Section: B Challenges Of Low-voltage Sensing For Resistive Rammentioning

confidence: 99%

Low <formula formulatype="inline"><tex Notation="TeX">${\rm VDDmin}$</tex></formula> Swing-Sample-and-Couple Sense Amplifier and Energy-Efficient Self-Boost-Write-Termination Scheme for Embedded ReRAM Macros Against Resistance and Switch-Time Variations

Chang

Chien

et al. 2015

IEEE J. Solid-State Circuits

Self Cite

View full text Add to dashboard Cite

The designs of resistive RAM (ReRAM) macros are limited by 1) a small sensing margin, limited read-, and slow read access time ( ) caused by a high cell-resistance and small cell-resistance-ratio (R-ratio) and 2) poor power integrity and increased energy waste attributable to a large SET dc-current ( ) resulting from the wide distribution of write (SET)-times ( ). This study proposes a swing-sample-and-couple (SSC) voltage-mode sense amplifier (VSA) to enable an approximately greater sensing margin for lower and a faster read speed across a wide range, compared with conventional VSAs. A 4T self-boost-write-termination (SBWT) scheme is proposed tocut off the of devices with a rapid . The SBWT scheme reduces 99 of the with an area penalty below 0.5%. A fabricated 512 row 28 nm 1 Mb ReRAM macro achieved 404 ns when 0.27 V and confirmed the cutoff by the SBWT.Index Terms-ReRAM, RRAM, sense amplifier, voltage-mode sense amplifier, write driver. 0018-9200

show abstract

“…To improve the speed and yield in read operations, previous researches developed small-offset SAs, focusing on alleviating SA -mismatch at the expense of complex multistep -nulling processes, which require numerous capacitors and switching devices. Capacitor-based small-offset CSAs [17], [19], [20] employ run-time offset-compensation (RTOC) operations to reduce the offset of CSAs. Moreover, small-offset sense amplifiers based on threshod-votlage-nulling do not provide compensation for offset caused by fluctuations in -, BL parasitic capacitance , or .…”

Section: Introductionmentioning

confidence: 99%

An Asymmetric-Voltage-Biased Current-Mode Sensing Scheme for Fast-Read Embedded Flash Macros

Chang

Lin

Liu

et al. 2015

IEEE J. Solid-State Circuits

Self Cite

View full text Add to dashboard Cite

Current-mode sense amplifiers (CSA) are commonly used in eNVM, because of their fast read speed at large bitline (BL) loads and small cell read currents. However, conventional CSAs are unable to achieve fast random read access time , due to significant summed input offsets at read-path. This work proposes a calibration-based asymmetric-voltage-biased CSA (AVB-CSA) to suppress and enable high-speed sensing without the need for run-time offset-cancellation operations. This work then fabricated two 90 nm AVB-CSA 1 Mb Flash testchips (with and without BL-length test-modes). The AVB-CSA eFlash macros with 512 rows achieved of 3.9 ns at nominal VDD (1.2 V). The BL-length test-mode experiments confirmed a improvement in using AVB-CSA with a BL-length of 2048-rows operating at V. Index Terms-Current-mode sense amplifier (CSA), Flash.

show abstract

An offset-tolerant current-sampling-based sense amplifier for Sub-100nA-cell-current nonvolatile memory

Cited by 21 publications

References 8 publications

Sensing Circuit Design Techniques for RRAM in Advanced CMOS Technology Nodes

Sensing Circuit Design Techniques for RRAM in Advanced CMOS Technology Nodes

Low <formula formulatype="inline"><tex Notation="TeX">${\rm VDDmin}$</tex></formula> Swing-Sample-and-Couple Sense Amplifier and Energy-Efficient Self-Boost-Write-Termination Scheme for Embedded ReRAM Macros Against Resistance and Switch-Time Variations

An Asymmetric-Voltage-Biased Current-Mode Sensing Scheme for Fast-Read Embedded Flash Macros

Contact Info

Product

Resources

About