科研成果

2023
陈美华,张明亮,王延飞. 面向国家安全体系和能力现代化建设的应急情报工作研究. 情报科学. 2023;41(7):2-7+13.Abstract
【目的/意义】结合二十大报告精神,探索新时代新征程上如何以面向国家安全体系和能力现代化建设为重心,定位好、规划好并发展好我国应急情报工作建设。【方法/过程】文章对国家安全体系和能力发展中应急管理体系发展的阶段进行了简要概述,厘清了应急情报工作赋能应急管理的重要性,同时概括分析了我国应急情报工作的研究现状;结合二十大报告内容,讨论了中国式现代化道路上应急情报工作所面临的机遇和现实挑战,最后提出应急情报工作体系和能力现代化的建议。【结果/结论】未来应立足总体国家安全观,以“形势推动,理念拉动、任务驱动”为构思,强化中国特色应急情报工作体系的顶层设计;聚焦大应急框架,围绕情报业务环节,形成技术与人文融合的大应急情报工作模式;着眼本土化视角从自主知识体系建设、人才培养、能力评估机制方面提升应急情报工作能力建设。【创新/局限】从国家战略层面探讨了应急情报工作体系和能力现代化建设的机遇、挑战和建议,但研究有待于从实践层面提炼出具体化问题进行深入探讨。
马雨萌,王延飞. 面向战略性新兴产业政策制定的情报感知研究. 情报学报. 2023;42(08):883-892.Abstract
以“情报感知”理念指导战略性新兴产业情报工作,能够帮助决策者应对复杂决策环境和科学把握产业政策窗口。本文在战略性新兴产业政策制定关切下,分析了情报用户需求、情报对象内容、情报任务组织三类情报感知要素,以情报感知线索发现、情报感知技术应用、情报感知结果刻画作为实施要件,针对战略性新兴产业决策中的信息不完备问题,提出了基于情报感知的解决方案,为开展基于情报感知理念的科技情报工作提供了参考示范。
康雁飞, 李丰. 预测:方法与实践. 在线出版; 2023. 访问链接
胡龙海, 黄炜, 任昶宇, 周羿. 风险感知、网络搜索与消费扭曲. 经济学 [Internet]. 2023;23(2):425-446. 访问链接Abstract
基于我国城镇住户月度面板数据和百度指数数据库,本文以地震为例,首次考察了风险感知如何影响家户消费行为和相关机制。结果表明,地震搜索指数每上升一个标准差,当地当月人均消费支出下降25元,且信息传播是导致搜索上升和消费下降的主要原因。灾难性事件通过改变居民主观风险造成消费扭曲,且影响甚至可能超过了直接经济损失。本文定量估算了对灾难性事件的风险感知造成的经济损失,能为政策制定者提供决策参考。
刘宇初. 高校图书馆创新能力提升策略研究——以北京大学图书馆创新实践为例. 大学图书馆学报. 2023;41(01):87-93.
2022
XIAO K, CUI X, WANG X'an, Wang Y. A 128Kb DAC-less 6T SRAM Computing-in-Memory Macro with Prioritized Subranging ADC for AI Edge Applications. Microelectronics Journal [Internet]. 2022;126:105506. 访问链接
Jia T, Mantovani P, dos Santos MC, Giri D, Zuckerman J, Loscalzo EJ, Cochet M, Swaminathan K, Tombesi G, Zhang JJ, et al. A 12nm agile-designed SoC for swarm-based perception with heterogeneous IP blocks, a reconfigurable memory hierarchy, and an 800MHz multi-plane NoC, in European Solid-State Circuits Conference (ESSCIRC).; 2022.
张子睿 胡敏. 2013~2020年北京大气PM_(2.5)和O_3污染演变态势与典型过程特征. 科学通报 [Internet]. 2022;67(18):1995-2007. 访问链接
Xie Y, Meng L, Zhou T, Xu L, Bao H, Chu R. The 2021 Mw 7.3 East Cape Earthquake: Triggered Rupture in Complex Faulting Revealed by Multi-Array Back-Projections. Geophysical Research Letters. 2022;49:e2022GL099643.
HU Y, ZHANG Y, WANG R, ZHANG Z, SONG J, TANG X, QIAN W, WANG Y, Wang Y, HUANG R. A 28nm 198.9 TOPS/W Fault-Tolerant Stochastic Computing Neural Network Processor. IEEE Solid-State Circuits Letters: [Internet]. 2022;5:198-201. 访问链接
PAN N, CUI X, QIAO X, XIAO K, GUO Q, Wang Y. A 28nm 64Kb SRAM based Inference-Training Tri-Mode Computing-in-Memory Macro, in 2022 IEEE International Symposium on Circuits and Systems (ISCAS). Austin TX, USA: IEEE Press; 2022:2561-2565. 访问链接
Xu X, Ye S, Gao J, Zhang Y, Shen L, Ye L. A 32-ppm/°C 0.9-nW/kHz Relaxation Oscillator with Event-Driven Architecture and Charge Reuse Technique, in 2022 IEEE International Symposium on Circuits and Systems (ISCAS).; 2022:1973-1977.
Shi W, Liu J, Mukherjee A, Yang X, TANG X, Shen L, Zhao W, Sun N. A 3.7mW 12.5MHz 81dB-SNDR 4th-Order Continuous-time DSM with Single-OTA and 2nd-Order Noise-shaping SAR. IEEE Open Journal of the Solid-State Circuits Society. 2022:1-1.Abstract
This paper presents a hybrid 4th-order delta-sigma modulator (DSM). It combines a continuous-time (CT) loop filter and a discrete-time (DT) passive 2nd-order noise-shaping SAR (NSSAR). Since the 2nd-order NS-SAR is robust against PVT variation, the stability of this 4th-order DSM is similar to that of a 2nd-order CT-DSM. The CT loop filter is based on single-amplifier bi-quad (SAB) structure. As a result, only one OTA is used to achieve 4th-order noise shaping, leading to a high power efficiency. Moreover, this work implements both excess loop delay (ELD) compensation and an input feedforward path inside the NS-SAR in the charge domain, further reducing the circuit complexity and the OTA power. Overall, this work achieves 81 dB SNDR over 12.5 MHz with 3.7 mW power, leading to a Schreier FoM of 176 dB.
SONG J, LUO H, TANG X, XU K, JI Z, Wang Y, WANG R, HUANG R. A 3T eDRAM In-Memory Physically Unclonable Function with Spatial Majority Voting Stabilization. IEEE Solid-State Circuits Letters [Internet]. 2022;5:58-61. 访问链接Abstract
This letter presents a 3T eDRAM in-memory physically unclonable function (PUF) for low-cost Internet of Things (IoT) applications. The proposed design integrates PUF to eDRAM with a small peripheral overhead. With the subthreshold leakage of the bit-cell read path exploited as the entropy source, two adjacent 3T eDRAMs (with 2 × 197 F2 = 394 F2 area) race to generate the key bit. To overcome voltage and temperature variations, the spatial majority voting (SMV) is adopted. Implemented in 65-nm CMOS, the proposed eDRAM PUF achieves <0.35% bit error rate (BER) across a voltage range of 1.0–1.2 V and temperature range of 0 ◦C–60 ◦C, presenting a low-cost and robust solution for IoT security.
GUO Q, CUI X, Zhang J, ZHANG A, GUO X, Wang Y. A 4-bit Integer-Only Neural Network Quantization Method Based on Shift Batch Normalization, in 2022 IEEE International Symposium on Circuits and Systems (ISCAS). Austin TX, USA: IEEE Press; 2022:707-711. 访问链接
QIAO X, SONG J, TANG X, LUO H, PAN N, CUI X, WANG R, Wang Y. A 65nm 73Kb SRAM-Based Computing-In-Memory Macro with Dynamic-Sparsity Controlling. IEEE Transactions on Circuits and Systems II: Brief Paper [Internet]. 2022;69(6):2977-2981. 访问链接Abstract
For neural network (NN) applications at the edge ofAI, computing-in-memory (CIM) demonstrates promising energyefficiency. However, when the network size grows while fulfillingthe accuracy requirements of increasingly complicated applicationscenarios, significant memory consumption becomes an issue.Model pruning is a typical compression approach for solvingthis problem, but it does not fully exploit the energy efficiencyadvantage of conventional CIMs, because of the dynamic distributionof sparse weights and the increased data movement energyconsumption of reading sparsity indexes from outside the chip.Therefore, we propose a vector-wise dynamic-sparsity controllingand computing in-memory structure (DS-CIM) that accomplishesboth sparsity control and computation of weights in SRAM, toimprove the energy efficiency of the vector-wise sparse pruningmodel. Implemented in a 65 nm CMOS process, the measurementresults show that the proposed DS-CIM macro can save upto 50.4% of computational energy consumption, while ensuringthe accuracy of vector-wise pruning models. The test chip canalso achieve 87.88% accuracy on the CIFAR-10 dataset at 4-bitprecision in inputs and weights, and it achieves 530.2TOPS/W(normalized to 1 bit) energy efficiency.
Zhang H, Shen L, Zhang S, Li H, Zhang Y, Tan Z, HUANG R, Ye L. A 77μW 115dB-Dynamic-Range 586fA-Sensitivity Current-Domain Continuous-Time Zoom ADC with Pulse-Width-Modulated Resistor DAC and Background Offset Compensation Scheme, in 2022 IEEE Custom Integrated Circuits Conference (CICC).; 2022:1-2. 访问链接Abstract
High-precision large dynamic-range (DR) current-sensing front-ends are widely used in biomedical applications, such as patch-clamp, molecular concentration detection, and gene sequencing. The new gene sequencers require low-noise analog front-ends capable of sensing large DR current (>100 dB) down to sub-pA-level. At this level of precision, oversampled data converters are usually used. However, given the limited oversampling ratio in high throughput applications, it is very challenging to achieve a sub-pA-level sensitivity and >100dB DR within the limited area and energy budgets [1]. In [2], a 140dB DR is achieved using a multi-bit delta-sigma modulator (DSM), but the power consumption is over 1mW and the current sensitivity is limited to 6.3pA. An hourglass ADC achieving a 100fA sensitivity and 140dB DR is presented in [3], but is limited by conversion rate and relatively high power consumption (295μW). For a 100Hz bandwidth, its noise floor increases to 18pA.
Liu Y, Wang Z, He W, Shen L, Zhang Y, Chen P, Wu M, Zhang H, Zhou P, Liu J, et al. An 82nW 0.53pJ/SOP Clock-Free Spiking Neural Network with 40µs Latency for AloT Wake-Up Functions Using Ultimate-Event-Driven Bionic Architecture and Computing-in-Memory Technique, in 2022 IEEE International Solid- State Circuits Conference (ISSCC).Vol 65.; 2022:372-374.
Du P, Liu W, Rao Z, Wang J. Accelerated Oxidation of Organic Micropollutants during Peracetic Acid Treatment in the Presence of Bromide Ions. ACS ES&T Water [Internet]. 2022;2:320-328. 访问链接Abstract
Peracetic acid (PAA), an alternative disinfectant of chlorine, has drawn increasing attention in the application of wastewater treatment. However, little is known about the influence of water matrices on PAA-induced organic micropollutant (OMP) degradation. Here, we found that the coexisting bromide ions (Br–) in water can trigger the oxidation of OMP during PAA treatment but probably result in higher ecotoxicity. Br– can efficiently decompose PAA with a species-specific rate constant (kPAAH/Br–) of 0.198 ± 0.003 M–1·s–1. The thus generated HOBr led to a significant abatement (31.8–81.3%) of OMPs (17α-ethinylestradiol, sulfamethoxazole, naproxen, and phenol) after a 1 h reaction at pH 7.1. The coexisting H2O2 component in the PAA solution can competitively consume HOBr and inhibit OMP transformation. The OMP degradation in the PAA/Br– process was highly pH-dependent and preferred acidic conditions. Furthermore, a comprehensive model was established to simulate the reaction kinetics of the OMP degradation by the PAA/Br– process with good accuracy. High-performance/electrospray ionization-triple quadrupole mass spectrometry results indicated the generation of various brominated products, with higher model-predicted toxicity than their parent compounds. This work significantly advances the understanding of the role of Br– in OMP oxidation by PAA and alerts the possible environmental health risks.
Chen L, Duan J, Du P, Sun W, Lai B, Liu W. Accurate identification of radicals by in-situ electron paramagnetic resonance in ultraviolet-based homogenous advanced oxidation processes. Water Research [Internet]. 2022;221:118747. 访问链接Abstract
Accurate identification of radicals in advanced oxidation processes (AOPs) is important to study the mechanisms on radical production and subsequent oxidation-reduction reaction. The commonly applied radical quenching experiments cannot provide direct evidences on generation and evolution of radicals in AOPs, while electron paramagnetic resonance (EPR) is a cutting-edge technology to identify radicals based on spectral characteristics. However, the complexity of EPR spectrum brings uncertainty and inconsistency to radical identification and mechanism clarification. This work presented a comprehensive study on identification of radicals by in-situ EPR analysis in four typical UV-based homogenous AOPs, including UV/H2O2, UV/peroxodisulfate (and peroxymonosulfate), UV/peracetic acid and UV/IO4− systems. Radical formation mechanism was also clarified based on EPR results. A reliable EPR method using organic solvents was proposed to identify alkoxy and alkyl radicals (CH3C(=O)OO·, CH3C(=O)O· and ·CH3) in UV/PAA system. Two activation pathways for radical production were proposed in UV/IO4− system, in which the produced IO3·, IO4·, ·OH and hydrated electron were precisely detected. It is interesting that addition of specific organic solvents can effectively identify oxygen-center and carbon-center radicals. A key parameter in EPR spectrum for 5,5-dimethyl-1-pyrroline N-oxide (DMPO) spin adduct, AH, is ranked as: ·CH3 (23 G) >·OH (15 G) >IO3· (12.9 G) >O2·− (11 G) ≥·OOH (9–11 G) ≥IO4· (9–10 G) ≥SO4·− (9–10 G) >CH3C(=O)OO· (8.5 G) > CH3C(=O)O· (7.5 G). This study will give a systematic method on identification of radicals in AOPs, and shed light on the insightful understanding of radical production mechanism.

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