GraphSTGAN:Situation understanding network of slow-fast high maneuvering targets for maritime monitor services of IoT data

With the rapid growth of the maritime Internet of Things(IoT)devices for Maritime Monitor Services(MMS),maritime traffic controllers could not handle a massive amount of data in time.For unmanned MMS,one of the key technologies is situation understanding.However,the presence of slow-fast high maneuvering targets and track breakages due to radar blind zones make modeling the dynamics of marine multi-agents difficult,and pose significant challenges to maritime situation understanding.In order to comprehend the situation accurately and thus offer unmanned MMS,it is crucial to model the complex dynamics of multi-agents using IoT big data.Nevertheless,previous methods typically rely on complex assumptions,are plagued by unstructured data,and disregard the interactions between multiple agents and the spatial-temporal correlations.A deep learning model,Graph Spatial-Temporal Generative Adversarial Network(GraphSTGAN),is proposed in this paper,which uses graph neural network to model unstructured data and uses STGAN to learn the spatial-temporal dependencies and interactions.Extensive experiments show the effectiveness and robustness of the proposed method.

Coal/Gangue Volume Estimation with Convolutional Neural Network and Separation Based on Predicted Volume and Weight

In the coal mining industry,the gangue separation phase imposes a key challenge due to the high visual similaritybetween coal and gangue.Recently,separation methods have become more intelligent and efficient,using newtechnologies and applying different features for recognition.One such method exploits the difference in substancedensity,leading to excellent coal/gangue recognition.Therefore,this study uses density differences to distinguishcoal from gangue by performing volume prediction on the samples.Our training samples maintain a record of3-side images as input,volume,and weight as the ground truth for the classification.The prediction process relieson a Convolutional neural network(CGVP-CNN)model that receives an input of a 3-side image and then extractsthe needed features to estimate an approximation for the volume.The classification was comparatively performedvia ten different classifiers,namely,K-Nearest Neighbors(KNN),Linear Support Vector Machines(Linear SVM),Radial Basis Function(RBF)SVM,Gaussian Process,Decision Tree,Random Forest,Multi-Layer Perceptron(MLP),Adaptive Boosting(AdaBosst),Naive Bayes,and Quadratic Discriminant Analysis(QDA).After severalexperiments on testing and training data,results yield a classification accuracy of 100%,92%,95%,96%,100%,100%,100%,96%,81%,and 92%,respectively.The test reveals the best timing with KNN,which maintained anaccuracy level of 100%.Assessing themodel generalization capability to newdata is essential to ensure the efficiencyof the model,so by applying a cross-validation experiment,the model generalization was measured.The useddataset was isolated based on the volume values to ensure the model generalization not only on new images of thesame volume but with a volume outside the trained range.Then,the predicted volume values were passed to theclassifiers group,where classification reported accuracy was found to be(100%,100%,100%,98%,88%,87%,100%,87%,97%,100%),respectively.Although obtaining a classification with high accuracy is the main motive,this workhas a remarkable reduction in the data preprocessing time compared to related works.The CGVP-CNN modelmanaged to reduce the data preprocessing time of previous works to 0.017 s while maintaining high classificationaccuracy using the estimated volume value.

Sugarcane/soybean intercropping with reduced nitrogen addition enhances residue-derived labile soil organic carbon and microbial network complexity in the soil during straw decomposition

Sugarcane/soybean intercropping with reduced nitrogen addition is an important sustainable agricultural pattern that can alter soil ecological functions,thereby affecting straw decomposition in the soil.However,the mechanisms underlying changes in soil organic carbon(SOC)composition and microbial communities during straw decomposition under long-term intercropping with reduced nitrogen addition remain unclear.In this study,we conducted an in-situ microplot incubation experiment with^(13)C-labeled soybean straw residue addition in a two-factor(cropping pattern:sugarcane monoculture(MS)and sugarcane/soybean intercropping(SB);nitrogen addition levels:reduced nitrogen addition(N1)and conventional nitrogen addition(N2))long-term experimental field plot.The results showed that the SBN1 treatment significantly increased the residual particulate organic carbon(POC)and residual microbial biomass carbon(MBC)contents during straw decomposition,and the straw carbon in soil was mainly conserved as POC.Straw addition changed the structure and reduced the diversity of the soil microbial community,but microbial diversity gradually recovered with decomposition time.During straw decomposition,the intercropping pattern significantly increased the relative abundances of Firmicutes and Ascomycota.In addition,straw addition reduced microbial network complexity in the sugarcane/soybean intercropping pattern but increased it in the sugarcane monoculture pattern.Nevertheless,microbial network complexity remained higher in the SBN1 treatment than in the MSN1 treatment.In general,the SBN1 treatment significantly increased the diversity of microbial communities and the relative abundance of microorganisms associated with organic matter decomposition,and the changes in microbial communities were mainly driven by the residual labile SOC fractions.These findings suggest that more straw carbon can be sequestered in the soil under sugarcane/soybean intercropping with reduced nitrogen addition to maintain microbial diversity and contribute to the development of sustainable agriculture.

Hybrid Gaussian Network Intrusion Detection Method Based on CGAN and E-GraphSAGE

The rapid development of the Internet of Things(IoT)and modern information technology has led to the emergence of new types of cyber-attacks.It poses a great potential danger to network security.Consequently,protecting against network attacks has become a pressing issue that requires urgent attention.It is crucial to find practical solutions to combat such malicious behavior.A network intrusion detection(NID)method,known as GMCE-GraphSAGE,was proposed to meet the detection demands of the current intricate network environment.Traffic data is mapped into gaussian distribution,which helps to ensure that subsequent models can effectively learn the features of traffic samples.The conditional generative adversarial network(CGAN)can generate attack samples based on specified labels to create balanced traffic datasets.In addition,we constructed a communication interaction graph based on the connection patterns of traffic nodes.The E-GraphSAGE is designed to capture both the topology and edge features of the traffic graph.From it,global behavioral information is combined with traffic features,providing a solid foundation for classifying and detecting.Experiments on the UNSW-NB15 dataset demonstrate the great detection advantage of the proposed method.Its binary and multi-classification F1-score can achieve 99.36%and 89.29%,respectively.The GMCE-GraphSAGE effectively improves the detection rate of minority class samples in the NID task.

0.2~2.0GHz100W超宽带GaN功率放大器

设计并实现了一款基于0.25μm GaN高电子迁移率晶体管(HEMT)工艺的100 W超宽带功率放大器。基于SiC无源工艺设计了集成无源器件(IPD)输入预匹配电路芯片;设计了基于陶瓷基片的T型集成输出预匹配电路;基于建立的传输线变压器(TLT)的精确模型,设计了宽带阻抗变换器,在超宽频带内将50Ω的端口阻抗变换至约12.5Ω,再通过多节微带电路与预匹配后的GaN HEMT芯片实现阻抗匹配。最终,以较小的电路尺寸实现了功率放大器的超宽带性能指标。测试结果表明,功率放大器在0.2~2.0 GHz频带内,在漏极电压36 V、输入功率9 W、连续波的工作条件下,输出功率大于103 W,漏极效率大于50%,输入电压驻波比(VSWR)≤2.5。

MACDCGAN的发电机轴承故障诊断方法

在实际工况中,发电机中传感器采集到的故障样本数据有限,使用基于深度学习的方法进行故障诊断存在过拟合问题导致模型泛化能力较差以及诊断精度不高。为了解决这个问题,采用样本扩充的思路,提出了一种改进的辅助分类器条件深度卷积生成对抗网络(MACDCGAN)的故障诊断方法。通过对采集的一维时序信号进行小波变换增强特征,构建简化结构参数的条件深度卷积生成对抗网络模型生成样本,并在模型中采用Wasserstein距离优化损失函数解决训练过程中存在模式崩塌和梯度消失的缺点;通过添加一个独立的分类器来改进分类模型的兼容性,并在分类器中引入学习率衰减算法增加模型稳定性。试验结果表明,该方法可以有效地提高故障诊断的精度,并且验证了所提模型具有良好的泛化性能。

VHF频段小型化千瓦级GaN功率放大器

为了满足VHF频段对高功率放大器小型化的需求,设计并制备了一款基于05μm GaN高电子迁移率晶体管(HEMT)工艺的VHF频段小型化千瓦级功率放大器。通过采用多节微带电容网络和高介电常数的印制电路板(PCB)实现了末级功率放大器匹配电路的小型化;以高通滤波器作为级间匹配电路,在减小电路尺寸的同时,提高了链路增益;采用混合集成工艺,实现了电源调制器、前级驱动功率放大器和末级功率放大器等各单元的小型化高密度集成。测试结果表明,在024~030 GHz频带内,该功率放大器的工作电压为50 V,工作脉宽为100μs,在占空比10%、输入功率10 dBm的工作条件下,带内输出功率大于1000 W,功率附加效率约为60%~69%,功率增益大于50 dB,功放体积为46 mm×30 mm×6 mm。

InGaN/GaN量子阱悬空微盘发光二极管

设计并制备了三种不同结构的电泵浦InGaN/GaN量子阱微盘发光器件,对其光增益和光损耗进行了分析和优化。以p型层的结构为分类标准,器件Ⅰ为圆柱形;器件Ⅱ为器件Ⅰ的悬空结构;器件Ⅲ是悬空的圆环形结构。实验和仿真结果表明,三种器件结构中,器件Ⅱ的结果最好。电极布局为内p外n型的圆柱形器件表面电流分布能够保证发光区和微腔高增益区重合,悬空结构能够降低微盘在垂直方向上的光损耗,有利于更好的光学增益。考虑到共振模式,器件Ⅱ在注入电流大于0.7 mA时,器件Ⅱ实现了峰值波长为408.2 nm、半峰宽为2.62 nm的振荡模式输出。这种电泵浦InGaN/GaN量子阱悬浮微盘二极管器件的设计思路对电泵浦微盘或微环激光器的研制具有重要参考意义。

石墨烯插入层对蓝宝石上GaN材料的应力调制

较大的晶格失配和热失配使得异质外延生长的GaN材料具有很高的残余应力,对材料和器件的性能产生重要影响。在蓝宝石衬底和GaN外延层之间插入一层石墨烯,通过Raman光谱和弯曲度测试分析了石墨烯插入层对GaN材料应力的影响。Raman测试结果表明,蓝宝石衬底上GaN材料压应力为0.56 GPa,引入石墨烯插入层后GaN材料压应力为0.08 GPa。弯曲度测试结果表明无石墨烯插入层的蓝宝石上GaN材料弯曲度约为21.74μm,引入石墨烯插入层后弯曲度约为1.39μm,引入石墨烯插入层的GaN材料弯曲度显著降低。讨论了石墨烯插入层对蓝宝石上GaN材料的应力调制机制,验证了石墨烯插入层技术对于异质衬底上获得完全弛豫GaN外延层的可行性。

大尺寸GaN微波材料范德瓦耳斯外延机理及应力调控研究

本文基于金属有机化学气相沉积(MOCVD)技术,以少层氮化硼(BN)作为插入层在4英寸蓝宝石衬底上开展范德瓦耳斯异质外延GaN微波材料的生长机理及应力调控方面的研究,探讨了AlN成核工艺对GaN缓冲层生长机制的影响,以及与材料晶体质量、应力及电学性能等之间的关联。提出了一种基于AlN/AlGaN复合成核技术的应力调控方案,首次实现了大尺寸范德瓦耳斯(vdW)异质外延材料应力的有效管控,研制的GaN微波材料的弯曲度(Bow)为+20.4μm,(002)/(102)面半峰全宽为471.6/933.5 arcsec,表面均方根粗糙度为0.52 nm,电子迁移率达到2000 cm^(2)/(V·s)。最后,基于机械剥离实现了大尺寸晶圆级GaN微波材料与蓝宝石衬底的分离,为高导热衬底转移提供便利,为大功率射频器件的制作创造条件。

GAN与Diffusion在传统纹样设计中的实验研究

传统纹样是中国优秀传统文化的重要组成部分,传统人工设计已经无法满足纹样的现代设计需求,生成式AI为传统纹样设计提供了新的设计路径和方法。文章将生成式AI应用于传统纹样设计中,通过适配实验优选基于GAN的Style GAN和基于Diffusion的Stable Diffusion两种主流图像生成模型进行实验,采用技术分析与艺术分析相结合,对实验结果进行多角度、多维度对比分析,为设计师选择生成设计方法提供参照。实验结果表明,两个模型均能满足基本的艺术设计需求。Style GAN模型生成的纹样图像更接近真实图像的分布,具有更高的图像质量和多样性;Stable Diffusion模型能较好地传承传统纹样的基因,艺术性与创造性兼具,更加符合传统纹样的艺术设计需求。

基于GaN器件与磁集成技术的车载充电机实验平台研究

随着新能源汽车的普及,对车载充电机的要求越来越高。为了有效提升整机效率和功率密度,将GaN器件与磁集成技术应用于车载充电机,进行了实验平台研究。基于GaN器件设计了两级式车载充电机拓扑结构与外围电路,通过制作磁集成平面变压器,优化了CLLC变换器,完成了整机控制程序设计及2kW车载充电机实验样机搭建,并对样机进行了实验测试与波形分析。实验结果表明,实验样机具有良好的稳态特性与动态特性,整机功率因数在0.98以上,满载峰值效率达到95.22%。该平台能够帮助学生加深对电力电子技术的认识,掌握新型电力电子器件的特性及应用,锻炼实践操作能力,提高相关课程的教学质量。

低成本高结晶GaN纳米线柔性薄膜制备及其场发射性能

旨在探究非贵金属Cu替代贵金属Au作为催化剂在柔性碳膜上制备高结晶的GaN纳米线的可行性,并研究其场发射特性及机理。采用非贵金属Cu替代贵金属Au作为催化剂,在柔性碳膜上制备了直径为20~100 nm、长度为3~15μm的高结晶的GaN纳米线,并通过工艺参数对其结构与尺寸进行调控,得到GaN纳米线薄膜的催化生长机制。通过对其场发射特性进行研究,发现其场发射性能与其纳米结构紧密相关,催化剂厚度以及薄膜弯曲状态可显著影响其场发射性能。结果表明,采用Cu作为催化剂所制备的GaN纳米线柔性薄膜的场发射电流具有较好的稳定性。该研究为GaN纳米线的低成本制备方法提供了可借鉴思路,同时也为场发射柔性器件的制作提供了可行的技术手段。

GaN HEMT源漏通道区电阻的自热和准饱和效应模型

GaN HEMT在栅极与源极和漏极之间存在一段通道区域,在等效电路模型中通常等效为一电阻,称为源漏通道区电阻R_(D,S)。准确构建GaN HEMT R_(D,S)模型,对于分析GaN HEMT直流和射频特性,构建GaN HEMT大信号模型具有十分重要的意义。本研究给出考虑自热和准饱和效应的R_(D,S)模型。首先由源漏通道区温度T_(CH)与耗散功率P_(diss)的关系,推导出非线性自热效应模型。进一步基于准饱和效应和Trofimenkoff模型,给出源漏通道区电子漂移速度与电场强度的关系表达式,构建非线性R_(D,S)模型。在环境温度Tamb=300~500 K时,源漏通道区二维电子气2DEG面密度n_(S,acc)(T_(CH))和迁移率μ_(acc)(T_(CH))随T_(CH)的升高而下降,这导致低偏置条件下的源漏通道区电阻R_(D0,S0)随T_(CH)呈非线性增长。将本研究和文献报道的R_(D,S)模型与TCAD(Technology Computer Aided Design)仿真数据进行对比,结果显示:本研究与文献报道的漏通道区电阻RD模型的平均相对误差分别为0.32%和1.78%,均方根误差(RMSE)分别为0.039和0.20Ω;RS模型的平均相对误差分别为0.76%和1.73%,RMSE分别为0.023和0.047Ω。与文献报道的实验数据进行对比,结果显示:本研究与文献RD模型的平均相对误差分别为0.91%和1.59%,RMSE分别为0.012和0.015Ω;RS平均相对误差分别为1.22%和2.77%,RMSE分别为0.0015和0.0034Ω。本研究提出的R_(D,S)模型具有更低的平均相对误差和均方根误差,能够更加准确地表征GaN HEMT线性工作区R_(D,S)随漏源电流I_(DS)的变化。可将本模型用于器件的设计优化,也可作为Spice模型用于电路仿真。

基于图像小波域自适应干扰的GAN生成人脸反取证

针对现有生成对抗网络(GAN)生成人脸反取证方法攻击迁移性不强的问题,提出了一个基于图像小波域自适应干扰的GAN生成人脸反取证方法以提升攻击迁移性.该方法通过对GAN生成人脸图像的小波域信息(即图像经过小波分解后的频率分量)施加扰动以实现其对取证模型的抵抗,并且分别在空域和频域上基于最小可觉察误差(JND)设计自适应扰动阈值,对图像不同像素点位置设置不同的扰动强度,从而增强扰动的人眼不可感知性.此外,还设计了一种数据增强方式对反取证人脸进行数据分布多样性扩充,以进一步提升攻击迁移性.实验结果表明,与6种基线方法相比,所提方法生成的反取证人脸在保证扰动对人眼不可感知前提下具有更强的攻击迁移性.

一种L波段300W GaN脉冲功率模块

随着第三代半导体GaN器件技术的不断发展,GaN高电子迁移率晶体管(HEMT)在电子系统中逐步得到了广泛应用。研制了一款小型化L波段300 W GaN脉冲功率模块。研发了满足高压脉冲工作条件的GaN HEMT芯片,采用负载牵引技术进行了器件大信号阻抗参数提取,并以此为基础设计了小型化匹配网络进行阻抗变换。基于高压驱动芯片和开关器件芯片设计了小型化高压脉冲调制电路。测试结果表明,在工作频率990~1130 MHz、工作电压50 V、脉冲宽度100μs、占空比10%下,功率模块脉冲输出功率大于300 W,功率附加效率大于53%,功率增益大于38 dB。功率模块尺寸为30 mm×30 mm×8 mm。

一种抑制栅极正负向串扰的GaN HEMT无源驱动电路

GaN器件由于其更快的开关速度,比硅器件更容易发生严重的开关振荡,也更容易受到栅源电压振荡的影响。为了抑制GaN基半桥结构中的串扰,提出了一种抑制GaN高电子迁移率晶体管(HEMT)栅极正负向串扰的无源钳位驱动电路来抑制栅源电压振荡。采用基本无源元件建立自举驱动回路,并增加三极管以构成从驱动电路到GaN HEMT的低阻抗米勒电流路径,抑制正负向串扰。在LTspice软件下进行电路模拟仿真,并搭建实验平台进行实测验证,结果表明栅源电压的最大正向串扰可降至1.2 V,最大负向串扰可降至1.6 V,漏源电流的正向和负向串扰均降至2 A以下,证明该电路对栅源电压以及漏源电流的振荡均有良好的抑制效果。

具有自驱动有源缓冲器的GaN基高效准谐振反激式功率变换器

提出了一种具有自驱动有源缓冲器的GaN基高效准谐振(QR)反激式功率变换器,以解决准谐振反激式功率变换器中开关管关断时电压过高的问题。电路以GaN高电子迁移率晶体管(HEMT)器件为主开关管和同步整流器开关管,自驱动有源缓冲器由钳位电容和有源开关管组成。该变换器在主开关管关断期间将开关管的电压浪涌钳位为恒定电压,由于有源开关管驱动信号由变压器的次级侧电流控制,因此不需要单独的控制电路。为验证所提出的变换器和控制电路的有效性,搭建了一个60 W的AC-DC功率变换器,测试结果表明,主开关管的最大电压浪涌约为450 V,具有高达91.6%的能量转换效率。

双栅GaN HEMT生物传感器仿真研究

GaN HEMT因具有优异的高灵敏度、快速响应特性、电学特性和生物相容性,其在生物传感领域具有广泛的应用潜力。为提升GaN HEMT生物传感器直接检测生物分子的灵敏度,提出了一种双栅结构分析模型,并使用Silvaco TCAD工具研究了其电学特性。从漏极电流、阈值电压和电势方面分析了单栅和双栅器件的结构特性,比较了其灵敏度。研究表明,在特定生物分子(尿酸酶、链霉亲和素、蛋白质和胆固醇氧化酶)的检测中,双栅GaN HEMT生物传感器的灵敏度分别比单栅器件高1.55%,2.18%,1.07%和3.3%。其中,增加空腔长度可以为生物分子与生物功能化层(AlGaN)的相互作用提供更多的面积,从而使传感器的灵敏度增加。因此,双栅和较大空腔的GaN HEMT生物传感器器件更适用于高灵敏度的应用。

非分段GaN HEMT EF2类功率放大器理论研究

目前,增强型氮化镓高电子迁移率晶体管(GaN HEMT)的仿真模型存在仿真时间长、复杂度高且收敛性不好等问题。为了解决GaN HEMT器件在电力电子电路中仿真收敛性和准确性差的问题,提出一种非分段的GaN HEMT SPICE模型。使用非分段连续方程对GaN HEMT器件的静态和动态特性进行建模;再对GaN HEMT的输出特性进行仿真,并与Si MOSFET的仿真结果进行对比。仿真结果表明,所提模型的收敛性较好,收敛速度快,有较高的准确性。另外,将此模型应用于EF2类功率放大器中,研究该模型对传输效率的影响。仿真结果进一步表明:该模型具有良好的收敛性;且当开关频率为10~20 MHz,输入功率为75 W时,输出功率可达73 W,传输效率为95%,这也证明了GaN HEMT器件可以提高EF2类功率放大器的传输效率。