Learning curve of transumbilical suture-suspension single-incision laparoscopic cholecystectomy

AIM: To investigate the learning curve of transumbilical suture-suspension single-incision laparoscopic cholecystectomy (SILC). METHODS: The clinical data of 180 consecutive transumbilical suture-suspension SILCs performed by a team in our department during the period from August 2009 to March 2011 were retrospectively analyzed. Patients were divided into nine groups according to operation dates, and each group included 20 patients operated on consecutively in each time period. The surgical outcome was assessed by comparing operation time, blood loss during operation, and complications between groups in order to evaluate the improvement in technique.RESULTS: A total of 180 SILCs were successfully performed by five doctors. The average operation time was 53.58 ± 30.08 min (range: 20.00-160.00 min) and average blood loss was 12.70 ± 11.60 mL (range: 0.00-100.00 mL). None of the patients were converted to laparotomy or multi-port laparoscopic cholecystectomy. There were no major complications such as hemorrhage or biliary system injury during surgery. Eight postoperative complications occurred mainly in the first three groups (n = 6), and included ecchymosis around the umbilical incision (n = 7) which resolved without special treatment, and one case of delayed bile leakage in group 8, which was treated by ultrasound-guided puncture and drainage. There were no differences in intraoperative blood loss, postoperative complications and length of postoperative hospital stay among the groups. Bonferroni's test showed that the operation time in group 1 was significantly longer than that in the other groups (F = 7.257, P = 0.000). The majority of patients in each group were discharged within 2 d, with an average postoperative hospital stay of 1.9 ± 1.2 d. CONCLUSION: Following scientific principles and standard procedures, a team experienced in multi-port laparoscopic cholecystectomy can master the technique of SILC after 20 cases.

Deep learning-based fault diagnostic network of high-speed train secondary suspension systems for immunity to track irregularities and wheel wear

Fault detection and isolation of high-speed train suspension systems is of critical importance to guarantee train running safety. Firstly, the existing methods concerning fault detection or isolation of train suspension systems are briefly reviewed and divided into two categories, i.e., model-based and data-driven approaches. The advantages and disadvantages of these two categories of approaches are briefly summarized. Secondly, a 1D convolution network-based fault diagnostic method for highspeed train suspension systems is designed. To improve the robustness of the method, a Gaussian white noise strategy(GWN-strategy) for immunity to track irregularities and an edge sample training strategy(EST-strategy) for immunity to wheel wear are proposed. The whole network is called GWN-EST-1 DCNN method. Thirdly, to show the performance of this method, a multibody dynamics simulation model of a high-speed train is built to generate the lateral acceleration of a bogie frame corresponding to different track irregularities, wheel profiles, and secondary suspension faults. The simulated signals are then inputted into the diagnostic network, and the results show the correctness and superiority of the GWN-EST-1DCNN method. Finally,the 1DCNN method is further validated using tracking data of a CRH3 train running on a high-speed railway line.

Applying machine learning for cars’semi-active air suspension under soft and rigid roads

To improve the ride quality and enhance the control efficiency of cars’semi-active air suspensions(SASs)under various surfaces of soft and rigid roads,a machine learning(ML)method is proposed based on the optimized rules of the fuzzy control(FC)method and car dynamic model for application in SASs.The root-mean-square(RMS)acceleration of the driver’s seat and car’s pitch angle are chosen as the objective functions.The results indicate that a soft surface obviously influences a car’s ride quality,particularly when it is traveling at a high-velocity range of over 72 km/h.Using the ML method,the car’s ride quality is improved as compared to those of FC and without control under different simulation conditions.In particular,compared with those cars without control,the RMS acceleration of the driver’s seat and car’s pitch angle using the ML method are respectively reduced by 30.20% and 19.95% on the soft road and 34.36% and 21.66% on the rigid road.In addition,to optimize the ML efficiency,its learning data need to be updated under all various operating conditions of cars.

Decoding of Raman spectroscopy-encoded suspension arrays based on the detail constraint cycle domain adaptive model

Previous studies have already shown that Raman spectroscopy can be used in the encoding of suspension array technology.However,almost all existing convolutional neural network-based decoding approaches rely on supervision with ground truth,and may not be well generalized to unseen datasets,which were collected under different experimental conditions,applying with the same coded material.In this study,we propose an improved model based on CyCADA,named as Detail constraint Cycle Domain Adaptive Model(DCDA).DCDA implements the clasification of unseen datasets through domain adaptation,adapts representations at the encode level with decoder-share,and enforces coding features while leveraging a feat loss.To improve detailed structural constraints,DCDA takes downsample connection and skips connection.Our model improves the poor generalization of existing models and saves the cost of the labeling process for unseen target datasets.Compared with other models,extensive experiments and ablation studies show the superiority of DCDA in terms of classification stability and generalization.The model proposed by the research achieves a classification with an accuracy of 100%when applied in datasets,in which the spectrum in the source domain is far less than the target domain.

基于深度迁移学习的车辆悬架高频异常振动故障诊断

在车辆悬架故障诊断过程中,深度学习故障诊断模型在面对少量样本数据时模型训练效果不佳,导致诊断模型的接收者操作特性曲线(receiver operating characteristic,ROC)的曲线下面积(area under curve,AUC)较小的问题,利用经验模态分解(empirical mode decomposition,EMD)方法,对采集的车辆悬架高频振动信号进行分解处理,根据每个经验模态分量(intrinsic mode functions,IMF)的能量,提取高频异常振动故障特征,构建了基于深度迁移学习的诊断模型;以深度卷积神经网络算法为基础,对小样本特征矢量信息进行故障知识迁移处理,通过参数微调更新权值,优化故障诊断模型。实验结果表明:优化后模型的AUC值为0.89,模型故障诊断结果具有较高准确性。

关于职业教育药学专业教学资源库建设应用成效的分析

职业教育药学专业教学资源库由重庆医药高等专科学校和江苏医药职业学院主持建设完成。笔者从课程数量、素材资源、用户数量、覆盖率、活跃度、满意度、教学比赛、配套教材、社会服务及“停课不停学”等方面,对资源库的建设和应用成效进行了全面分析,以了解国内职业院校对资源库应用的总体情况、发现资源库建设过程中的问题、探索持续维护和更新资源库素材的经验,为教学资源库的建设提供一定参考。

矿用宽体车互联式油气悬架系统平顺性分析

采用钢板弹簧悬架的矿用宽体车难以获得良好的行驶平顺性,为此,提出了一种刚度阻尼可调的互联式油气悬架系统。首先,阐述了互联式油气悬架系统的工作原理,建立了油气悬架系统的数学模型;其次,运用AMESim软件搭建了互联式油气悬架系统和钢板弹簧悬架的仿真模型,确定了仿真模型中的主要参数;最后,在D级随机路面激励下进行了匀速和加速-制动运行工况的车辆行驶平顺性仿真研究,并对仿真结果进行了分析。研究结果表明:与钢板弹簧悬架相比,匀速和加速-制动的空载工况下,互联式油气悬架系统的车身加速度均方根值分别下降了38.7%和38.8%,车轮动载荷均方根值分别增加了3.1%和0.5%,不影响车轮的接地性,悬架动挠度均方根值分别增加了41.6%和39.7%,悬架撞击限位块的概率小于0.1%,满足设计要求;匀速和加速-制动的满载工况下,互联式油气悬架系统的车身加速度、车轮动载荷、悬架动挠度三项平顺性评价指标均得到改善。该结果证明互联式油气悬架系统可提升车辆的行驶平顺性,为矿用宽体车油气悬架系统设计提供参考。

基于机器视觉与YOLOv5的吊弦高清图像采集方法

研究目的:针对高铁接触网整体吊弦高清图像采集检测低效、准确率不高、投入成本高等问题,研究提出一种基于前端图像识别触发与深度学习算法融合定位的整体吊弦高清采集方法。研究结论:(1)采用嵌入式FPGA+ARM双处理平台,将基于YOLOv5的吊弦定位算法嵌入硬件结构中,通过FPGA实现图像运算硬件加速及识别过滤,通过ARM实现图像数据的高精度识别,整体吊弦图像检出率为99%,检时为4 ms/张,满足实时性检测要求;(2)通过FPGA与ARM的结合,内置专用图像处理算法芯片,滤除大量无用图像,获得清晰的整体吊弦图像,在数据集上训练和测试的准确率和召回率为100%,实际线路大于99%;(3)通过嵌入式FPGA+ARM硬件系统与YOLOv5的吊弦定位算法融合设计,减少了系统检测成本、扩大了技术应用范围,对推动接触网高质量智能建造与智能化运维具有借鉴作用。

城轨交通接触网悬挂状态智能检测算法及应用

通过高清成像对接触网悬挂状态进行检测,及时发现零部件松脱卡磨断等缺陷问题并维修,是保障城轨交通接触网系统安全运行的重要手段。采用YOLOV4的最小版本YOLOV4-tiny作为检测算法的基础模型,将原有Dropout层去掉,将上层特征直接经过卷积层后输入到下层卷积层,并加入Mosaic数据增强方式提高算法的泛化性,同时将原有Leaky-Relu函数替换为更加平滑的Mish函数。接触网缺陷定位的流程为:根据改进后的YOLOv4-tiny算法训练得到零部件区域定位模型,用于定位零部件的位置;再根据改进后的YOLOv4-tiny算法训练得到缺陷识别模型,用于判断该零部件是否有缺陷,并给出缺陷的具体位置和缺陷类别。实际应用表明:该算法能准确、快速定位零部件缺陷位置,并给出缺陷类型,总精度达90%以上,大大地降低了检测耗时与成本,并保障了作业人员安全。

基于强化学习的半主动悬架PID控制

文章针对强化学习算法在半主动悬架控制策略学习与控制中存在样本效率低、泛化性能差等问题,设计一种基于强化学习算法的半主动悬架PID控制。通过DDPG算法实现PID参数的自适应整定,以应对半主动悬架控制中的复杂非线性动态行为和多变路况问题。通过合理设计动作量与奖励函数,实现对不同驾驶条件的自适应性调节。仿真结果验证该方法的有效性,显著提高车辆乘坐舒适性,展示在复杂路况下广泛的应用前景。

AR/VR学习情境设计问题的研究

在AR/VR技术高速发展的今天,AR/VR支撑的学习情境让学习者不仅能够学习知识,还能体验知识。文章分析了AR/VR学习情境的特性,从用户、技术、资源及服务四个维度构建了AR/VR学习情境设计模型,分析了AR/VR学习情境中学习悬念和学习交互的设计方法,并在实践的基础上提出学习体验评价的实现方法。

改进教与学优化算法的LQR控制器优化设计

为了快速有效地确定线性二次最优控制(linear quadratic regulator,LQR)问题中的加权矩阵Q和R,针对主动悬架LQR控制器权系数设计问题,提出一种改进的教与学优化算法进行LQR优化设计。算法对基本教与学优化算法中的"教"与"学"阶段进行了进一步的改进,同时提出一种"自我学习"策略。通过仿真实验表明,和基本教与学算法、粒子群算法、遗传算法相比,本文算法在对主动悬架LQR控制器优化时,具有收敛速度快,求解精度高和稳定性强等优势。

三七叶总皂苷酶解产物抗抑郁活性的评价

本文研究了三七叶总皂苷酶解产物EP-3的抗抑郁药效。采用强迫游泳、悬尾、获得性无助、利血平拮抗等行为模型以及甩头实验、奔跑实验、打斗实验进行评价。强迫游泳实验，EP-3可以使强迫游泳小鼠的不动时间缩短43.39~52.00%，具有明显的抗抑郁活性。获得性无助实验，EP-3能显著减少获得性无助小鼠的逃避失败次数，测定的第2 d EP-3给药组逃避失败次数减少了16.56~29.96%，测定的第3 d减少了20.06~35.28%，第4 d为29.63~62.82%，呈现出随给药时间延长，作用增强的特点。EP-3可以明显逆转利血平诱导的小鼠肛温下降和拮抗小鼠眼睑下垂，一定程度上缓解小鼠运动不能症状。此外，EP-3显著增加5-HTP诱导的小鼠甩头次数，减少可乐定诱导的小鼠打斗行为，提高L-Dopa诱导的小鼠奔跑速度。但是EP-3对悬尾实验小鼠的不动时间没有影响（P〉0.05）。EP-3具有良好的抗抑郁作用，其作用机制可能与5-HT、NE和DA等单胺能神经递质或其受体有关。

高职院校大规模在线教学成效、问题及提升策略研究

高职院校史无前例地实践了整个学期的师生居家式大规模在线教学,不仅挑战了课堂教学实践能力的极限,也是对我国40年来高职教育信息化建设成效的最强考验。作为“疫情”特殊时期课堂教学的应急替代方案,高职院校大规模在线教学化解了时空分离状态下的教学供需矛盾,交出了有效度又有温度的可喜答卷,用实践证明了在线教学有能力完成课堂教学任务,保障了“停课不停教”政策底线,树立了在线教育发展史上的里程碑。社会多主体协同为高职院校开展在线教学提供了所需的海量网络学习资源、多样化学习工具、虚拟化教学环境,教师转变角色当网红,学生相聚线上渐入佳境,以灵活的自组织教学方式实现在线教学质量超预期。变革教育领域深层“教学惯性”和师生“默契”教学心理场域并非朝夕之功,当前要以“身份”合法化赋予高职院校在线教学的社会基础,协同共建适切的优质在线教学资源,赋予教师在线教学人机结合、虚实叠加的协同组织者角色,以教学活动为中介统合在线教与学,培养学生自主在线学习能力,以情感为纽带协同家校、师生共同体、社区维系在线教学,为高职院校全面返校复课后线上线下协同的“混合教学”做好充足准备。

基于智能体理论的空气悬架车身高度智能控制系统研究

为了进一步发挥空气悬架车身高度调节系统的性能,在Belief-Desire-Intention(BDI)框架下构建了目标车身高度控制智能体,并采用汤普森抽样算法构建智能体学习行为。结合车身高度调节系统模型,建立空气悬架车身高度智能控制系统。单一工况下的仿真结果验证了智能体学习行为的可行性以及学习结果的适用性;混合工况下的仿真结果验证了空气悬架车身高度智能控制系统的可行性和有效性。结果表明:在车身高度智能控制系统的控制下,簧上质量质心位置处的加权加速度均方根值上升了0. 45%,侧倾因子降低了22. 82%,在不恶化行驶平顺性的同时,提高了操纵稳定性。

悬尾应激对小鼠空间记忆及其反转学习的损伤效应

该文探讨了连续数天短时悬尾应激对小鼠十字迷宫空间记忆及其反转学习的作用。81只成年雄性昆明小鼠被分为4大组:绝对空间记忆获得组及巩固组;相对空间记忆获得组及巩固组。每大组又分为悬尾组(每天训练前或训练后立即接受悬尾处理20min)和对照组。结果表明,在空间记忆训练初期,各对照组和悬尾组动物正确反应率无明显差异,均在机遇水平;随着训练天数的增加,对照组成绩显著提高,当其正确反应率达到80%时,悬尾组正确反应率仍处于或略高于机遇水平,两组间差异显著(P<0.01);在反转学习中,悬尾组正确反应率也显著低于对照组(P<0.01)。这些表明,悬尾应激可显著损伤小鼠的空间记忆及其反转学习的获得和巩固,其中相对空间记忆及其反转学习的巩固受损尤为严重。

长期高脂饮食对小鼠认知功能及情绪的影响

目的 :观察长期高脂饮食对小鼠学习记忆功能及情绪的影响。方法:将14只C57BL/6J成年小鼠随机分为2组:正常对照组(NC组)和长期高脂饮食组(HF组)。NC组无任何处理,HF组以40%高脂饲料饲养8周,之后行Morris水迷宫、八臂放射迷宫检测高脂饮食对小鼠学习记忆功能的影响,行开场实验、高架十字迷宫、强迫游泳和悬尾实验观察小鼠情绪及活动性的变化,同时,在造模期间观察体质量、空腹血糖、平均饮水量和饮食量等指标。结果:与NC组相比,HF组平均饮水量和饮食量增加,体质量明显增加;空腹血糖增高;Morris水迷宫提示HF组空间记忆受损,工作记忆未受损;八臂迷宫提示HF组参考记忆错误和工作记忆错误增多。开场实验提示HF组小鼠探索行为活跃,有焦虑行为;强迫游泳实验提示HF组有抑郁情绪和绝望行为。结论:长期高脂饮食可引起小鼠体质量和空腹血糖增高,可损伤小鼠的工作记忆和空间记忆,并引起小鼠活动性增加和焦虑抑郁行为。

基于疫情背景下的《药物分析》在线教学探索

新冠病毒疫情背景下的"停课不停学"对在线教学提出了迫切的需要,在线教学在迎来机遇的同时,也面临诸多挑战。按照教育部的要求,各个高校积极制定在线教学指导方案,授课教师们也各显神通的开展在线教学活动。在此过程中能明显感受到互联网对教学带来的巨大帮助,同时也发现了其中的一些问题。以疫情期间《药物分析》课程的在线教学为例,通过在线教学设计、在线教学过程实施、问题思考等方面对在线教学进行探索性研究。

网络教育学生流失情况的分析与对策

在我国,远程教育普遍存在着学生流失率高的现象,这不仅影响办学单位的经济效益,更影响远程教育机构的社会信任度,在一定程度上阻碍了远程教育的长远发展。为了找出学生辍学的个中原因,以北京邮电大学网络教育学院2004—2006年秋季入学的远程教育学生为研究对象,通过采用查阅学生档案、分析数据等方法,研究学生流失的规律和特点,从而提出一些有针对性的解决措施,对远程教育机构学生工作的开展有一定的借鉴意义。

护理专业“生物化学”课程网络教学模式探索

为了共同应对新型冠状病毒肺炎的疫情,探索积极有效的线上教学方式,做到“停课不停学”,文章针对现阶段网络教学中存在的问题,提出了提高护理专业生物化学课程网络教学效果的方法,包括细致进行前期备课、互动讨论式直播授课、增强学习社群感等,多措并举提升网络授课的教学效果,保障教学质量。