专家信息:
徐立军, 男,1968年7月出生。博士,教授,博士生导师。 现任北京航空航天大学仪器科学与光电工程学院教授、院长,“测试计量技术及仪器”学科和“热能工程”学科博导,国家杰出青年科学基金获得者、教育部“长江学者”特聘教授、国家“万人计划”领军人才、科技部“中青年科技创新领军人才”,2016年第七届全国优秀科技工作者。
分别于1990、1993和1996年在天津大学获得学士、硕士与博士学位,1997年晋升为副教授,于1998-1999年在德国卡尔斯鲁厄大学做博士后研究,2002.1-2006.4分别在英国格林尼治大学、肯特大学和伦敦大学癌症研究所做Research Fellow和Higher Scientific Officer.长期从事过程监测与成像等方面的研究工作,在过程层析成像、激光测试与诊断、激光雷达等研究中与英国、美国、德国、意大利等多个国家的多所大学和研究机构保持紧密的联系与合作,取得了多项重要创新成果,得到业界的高度评价,在国际本学科领域具有较大影响力。主持包括国家杰出青年科学基金、国家自然科学基金仪器研制专款项目、国际交流合作项目、面上项目、973计划课题、863计划子课题、国家重大专项子课题等省部级以上项目20余项。至今已发表论文250篇,其中SCI检索78篇,EI 检索133篇,SCI 引用550余次,SCI他引400余次;其中25篇发表在IEEE 会刊,其他发表在Optics Express、Applied Optics、App. Phy. B、Energy、Energy & Fuel、Comb. Sci. Techn.、Meas. Sci. Techn., Rev. Sci. Instrum. 等刊物上,申请国家发明专利76 项,已授权49 项,获省部级奖励4项。现任国际期刊《Measurement Science and Technology》编委、《北京航空航天大学学报》副主编、IEEE高级会员、中国计量测试学会理事、中国仪器仪表学会理事、中国计量测试学会多相流测试专委会副主任。作为组委会主席、大会主席主办IEEE系列国际会议3次,在国内外本领域具有较大的影响力。
 教育经历:
1993.03-1996.03 天津大学精密仪器与光电子工程学院,获工学博士学位。
1990.09-1993.03 天津大学电力及自动化工程系,获工学硕士学位。
1986.09-1990.07 天津大学电力及自动化工程系,获工学学士学位。
工作经历:
2006.05至今 北京航空航天大学仪器光电学院测控系,教授。
2004.12-2006.04 英国伦敦大学癌症研究所物理系, Higher Scientific Officer。
2002.01-2004.12 英国肯特大学电子系仪表与嵌入式系统研究组, Research Fellow。
1998.05-1999.11 德国卡尔斯鲁厄大学化工过程工程与应用机械研究所博士后研究。
1997.11-2001.12 天津大学电气工程与自动化学院自动化系任副教授,硕士指导教师。系支部书记、系副主任。
1996.10-1997.01 德国卡尔斯鲁厄大学测量与控制研究所学习访问。
1995.07-1997.11 天津大学电力及自动化工程系工业自动化仪表教研室任讲师。
1993.07-1995.07 天津大学电力及自动化工程系工业自动化仪表教研室任助教。
学术兼职:
(1) 学术机构与团体
2004-IEEE高级会员
2001- 中国化工装备协会石化工业仪表委员会委员
2000- 中国计量协会能源计控技术工作委员会委员
1998- 中国计量测试学会多相流测试专业委员会委员
(2) 下述学术刊物审稿人
IEEE Transactions on Signal Processing
IEEE Transactions on Instrumentation and Measurement
IEEE Sensors Journal
Measurement Science and Technology
Flow Measurement and Instrumentation
 教学和人才培养:
主讲课程:
1、计算机测控系统(自动测试技术)(本科生必修)
2、信号分析与处理(本科生必修)
3、计算机控制系统与技术(研究生必修)
教学成果:
获批国家精品课程一门(排名第二)。培养的硕士和博士研究生中2人次获IEEE系列国际会议最佳论文奖,多人次分别获国家奖学金、中国仪器仪表学会奖学金等。
培养研究生情况:
已培养博士后3人,博士9人,硕士20人。
 科学研究:
研究方向:
1、过程层析成象与多相流测量
2、激光吸收光谱诊断技术与燃烧过程监测
3、激光雷达技术及应用
承担科研项目情况:
1、3D elastography for cancer diagnosis using radiation force,英国NEAT Programme
2、An integrated sensor system for combustion plant optimisation,英国贸工部项目
3、On-line fuel tracking by advanced flame monitoring,英国贸工部项目
4、Mass flow metering using electrostatic sensors,英国Natural Resources Centre
5、非对称管流多参数电磁检测技术研究,国家自然科学基金
6、流体粘度的非浸入式在线测量研究,天津自然科学基金
7、智能型高效混输泵技术探索,国家863计划
8、基于电磁感应的流体流变参数的在线测量,教育部骨干教师资助计划
9、气液两相流体的电阻抗层析成象测试技术的研究,国家自然科学基金
10、基于感应原理的电磁层析成象技术及系统研究,国家科学自然基金
11、电阻抗层析成象技术的研究,天津市自然科学基金
12、煤浆质量流量计,机械部"八五"攻关项目
13、超声流动成像技术及系统的研究,国家自然科学基金
14、活动式井口计量装置研制,大庆石油有限责任公司
15、大厦实时电耗分布式监测系统,香港城市大学委托项目
16、微机仿真磁带及热敏打印机仿真胶片绘图仪的研究,中科院沈阳计算所
17、电导含水率--相关流量计的信号采集系统,大庆石油管理局
科研成果:
1 燃煤锅炉制粉、送粉及燃烧过程在线监测 徐立军;李小路;曹章;李晓敏;成艳亭;许晨峰 北京航空航天大学
2 燃煤锅炉安全高效运行关键参数检测技术及系统 徐立军;李小路;曹章;李晓敏;成艳亭;许晨峰 北京航空航天大学 2012
3 非对称管流多参数电磁检测技术研究 徐立军;王亚;董峰;徐苓安 天津大学 2009
4 一种单极性输入双极性输出压控恒流源 王亚;李鹏;徐立军 天津大学 2009
5 两相流过程截面检测信息提取研究 董峰;徐立军;许燕斌;谭超;邓湘 天津大学 2008
发明专利:
发明公开:
[1]徐立军, 张晓倩, 曹章, 温晋婷, 王钇丁. 一种结合波长调制大吸收修正的温度浓度离散成像方法[P]. 北京市: CN119125074A, 2024-12-13.
[2]徐立军, 王钇丁, 曹章, 温晋婷, 张晓倩, 赵锴. 一种适于少角度投影的二值分布断层图像重建方法[P]. 北京市: CN118918210A, 2024-11-08.
[3]李小路, 付文明, 苏丽轩, 徐立军. 一种基于次邻帧约束位姿图优化的点云三维重建方法[P]. 北京市: CN118887345A, 2024-11-01.
[4]曹章, 周文彬, 徐立军, 张晓倩, 侯广羽. 一种基于激光吸收光谱的发动机燃烧室推力非接触式测量方法[P]. 北京市: CN118857541A, 2024-10-29.
[5]郭晶晶, 脱佳霖, 徐立军. 一种柔性可拉伸的多模态光纤传感器及其制备方法[P]. 北京市: CN118500454A, 2024-08-16.
[6]李端, 徐立军, 吕林杰, 蒋燕宏, 江丽沙, 王昕宇. 一种高精度单光子探测激光雷达深度及强度反演方法[P]. 北京市: CN118311595A, 2024-07-09.
[7]李端, 蒋燕宏, 徐立军, 吕林杰. 一种基于模式时间拉伸的目标距离-反射光谱一体化主动探测系统及方法[P]. 北京市: CN118244289A, 2024-06-25.
[8]曹章, 李微卿, 徐立军, 张晓倩, 罗家豪. 一种基于数字频率锁定双光梳系统的气体温度测量方法[P]. 北京市: CN118168682A, 2024-06-11.
[9]钟景, 孙世杰, 徐立军, 张锐, 孙少奇. 一种基于频域-空间域信息融合的磁粒子成像方法及装置[P]. 北京市: CN118121180A, 2024-06-04.
[10]徐立军, 侯广羽, 曹章, 王钇丁. 一种基于干涉波形同步可调谐吸收光谱的气体流速测量方法[P]. 北京市: CN118068040A, 2024-05-24.
[11]徐立军, 张晓倩, 曹章, 温晋婷, 赵锴, 王钇丁. 一种基函数参数自适应选取的二维温度场和浓度场成像方法[P]. 北京市: CN117934645A, 2024-04-26.
[12]孙世杰, 钟景, 徐立军, 蔡荣, 赵明阳. 一种基于数据快速生成的磁粒子成像图像重建方法[P]. 北京市: CN117934655A, 2024-04-26.
[13]谢跃东, 刘福禄, 杜可钰, 徐立军. 一种气液两相流气泡分布及相含率的测量方法及装置[P]. 北京市: CN117825492A, 2024-04-05.
[14]曹章, 周文彬, 徐立军, 侯广羽, 王钇丁. 一种高温高速气流总温、静温、动温、流速同步测量系统[P]. 北京市: CN117825630A, 2024-04-05.
[15]孙江涛, 白旭, 徐立军, 索鹏, 高歌, 李效霖, 刘康祺. 一种基于接触阻抗噪声分布的肺部先验EIT成像方法[P]. 北京市: CN117808910A, 2024-04-02.
[16]孙江涛, 廉依倪, 李效霖, 白旭, 索鹏, 徐立军. 一种用于微尺度电特性分布检测的电学层析成像传感器[P]. 北京市: CN117723603A, 2024-03-19.
[17]孙江涛, 刘康祺, 索鹏, 白旭, 徐立军. 一种融合位置形状约束的膀胱EIT三维成像方法[P]. 北京市: CN117204841A, 2023-12-12.
[18]徐立军, 吴易恭, 曹章, 陆方皞, 李泓瑶, 赵锴. 一种基于单步经验模态分解的波长调制光谱谐波提取方法[P]. 北京市: CN117214134A, 2023-12-12.
[19]马建国, 徐立军, 张腾. 一种消除球差的菲涅尔声透镜及其设计方法[P]. 北京市: CN117180648A, 2023-12-08.
[20]曹章, 曹李培, 徐立军, 汤晓阳. 基于三波长剪切干涉图的瞬态燃烧温度场测量方法与系统[P]. 北京市: CN117168642A, 2023-12-05.
[21]曹章, 李心语, 徐立军, 周文彬, 李雪娇. 一种基于开放光路可调衰荡腔的气体温度及浓度测量方法[P]. 北京市: CN117030638A, 2023-11-10.
[22]付博, 徐立军, 王刚, 张淙彧, 孙婧轩, 张程宏. 一种激光脉冲类型的实时切换方法[P]. 北京市: CN117039589A, 2023-11-10.
[23]李端, 徐立军, 江丽沙, 肖奕莹, 吕林杰. 一种基于激光雷达的低慢小目标探测系统及方法[P]. 北京市: CN116990782A, 2023-11-03.
[24]曹章, 温晋婷, 徐立军, 赵锴. 一种融合优化高斯滤波的激光吸收光谱层析图像重建方法[P]. 北京市: CN116957994A, 2023-10-27.
[25]李端, 肖奕莹, 徐立军, 江丽沙, 吕林杰. 一种用于主动三维成像的APD焦平面器件计时精度测试系统[P]. 北京市: CN116859372A, 2023-10-10.
[26]徐立军, 谭雨田, 曹章, 周文彬, 李泓瑶. 一种基于激光吸收光谱低速采样参数辨识的温度测量方法[P]. 北京市: CN116558665A, 2023-08-08.
[27]孙世杰, 王颖, 徐立军, 孙江涛. 一种基于动态图像融合的三维电学成像方法[P]. 北京市: CN116509367A, 2023-08-01.
[28]李小路, 余瑞钦, 毕腾飞, 徐立军. 一种基于激光雷达强度校正与点云上采样的交通标志牌分类方法[P]. 北京市: CN116468933A, 2023-07-21.
[29]曹章, 邱爽, 徐立军, 张晓倩, 温晋婷. 一种基于归一化二次谐波线性模型的温度和浓度重建方法[P]. 北京市: CN116337155A, 2023-06-27.
[30]孙江涛, 索鹏, 徐立军, 白旭, 李效霖, 孙世杰. 一种基于区块自适应稀疏表达的电学成像方法[P]. 北京市: CN116342730A, 2023-06-27.
[31]徐立军, 庞应飞, 曹章, 张晓倩, 张宏宇. 一种基于单腔双光梳的温度测量方法与装置[P]. 北京市: CN116295907A, 2023-06-23.
[32]徐立军, 郭尚, 曹章, 田雨. 一种适于硬件实现的稀疏阻抗频谱快速测量方法与系统[P]. 北京市: CN116298528A, 2023-06-23.
[33]孙江涛, 白旭, 徐立军, 索鹏, 刘康祺, 高歌. 一种基于结构先验的肺部电阻抗层析成像方法[P]. 北京市: CN116309481A, 2023-06-23.
[34]孙江涛, 申梦娴, 白旭, 索鹏, 徐立军. 适用于电极阵列外部区域的气液两相电阻抗分布成像方法[P]. 北京市: CN116203080A, 2023-06-02.
[35]马建国, 徐立军, 蔡奕奇, 刘铁铭. 一种具备功率输出和成像能力的低损耗超声换能器[P]. 北京市: CN116173432A, 2023-05-30.
[36]李小路, 毕腾飞, 陈文彬, 徐立军. 一种基于波形补偿的激光雷达饱和信号在线测距方法[P]. 北京市: CN116125429A, 2023-05-16.
[37]马建国, 徐立军, 韩佳琪, 孙其振, 谢准, 樊梦之, 孙鹏飞. 一种基于定量超声的乳腺肿瘤快速筛查方法[P]. 北京市: CN116077094A, 2023-05-09.
[38]孙江涛, 李效霖, 张潇恺, 白旭, 孙世杰, 徐立军. 基于相关系数约束互相关的高动态气液两相流量测量方法[P]. 北京市: CN116086559A, 2023-05-09.
[39]曹章, 高欣, 徐立军, 温晋婷, 李泓瑶. 一种基于混合径向基迭代求解的二维温度浓度重建方法[P]. 北京市: CN116067912A, 2023-05-05.
[40]饶静, 谢跃东, 马建国, 徐立军. 基于声波无线传感技术的新型水下温度监测系统及方法[P]. 北京市: CN116026488A, 2023-04-28.
[41]郭晶晶, 郭校言, 徐立军, 脱佳霖, 尚策. 一种能感知接触压力的光纤消融探针[P]. 北京市: CN115919456A, 2023-04-07.
[42]孙世杰, 陈瑶瑶, 钟景, 徐立军. 一种基于稀疏表征的磁纳米粒子成像图像重建方法[P]. 北京市: CN115844362A, 2023-03-28.
[43]谢跃东, 刘福禄, 黄晓菲, 饶静, 徐立军. 管道缺陷与管内流体流量同步测量装置及方法[P]. 北京市: CN115824330A, 2023-03-21.
[44]谢跃东, 黄晓菲, 刘福禄, 饶静, 徐立军. 一种基于电磁超声导波的储箱液面高度检测装置及方法[P]. 北京市: CN115790781A, 2023-03-14.
[45]谢跃东, 刘福禄, 黄晓菲, 饶静, 徐立军. 基于管道周向环形加载的电磁超声多相流测量装置及方法[P]. 北京市: CN115791960A, 2023-03-14.
[46]谢跃东, 黄晓菲, 刘福禄, 饶静, 徐立军. 一种基于多频电磁超声导波的管内流速测量装置及方法[P]. 北京市: CN115774120A, 2023-03-10.
[47]郭晶晶, 尚策, 徐立军, 脱佳霖, 郭校言, 付博. 一种温度压力双参量柔性光纤触觉传感器、制备方法及测量系统[P]. 北京市: CN115727882A, 2023-03-03.
[48]马建国, 徐立军, 章曦. 一种可配置的双频超声阵列发射接收系统及其信号收发方法[P]. 北京市: CN115644923A, 2023-01-31.
[49]钟景, 徐立军, 孙少奇, 孙世杰, 田捷. 一种多频磁场激励下磁纳米粒子磁化响应及频谱测量装置与方法[P]. 北京市: CN115656898A, 2023-01-31.
[50]徐立军, 陆方皞, 曹章, 李泓瑶, 吴易恭, 张晓倩. 一种抑制乘性噪声的激光吸收光谱提取方法与系统[P]. 北京市: CN115639171A, 2023-01-24.
[51]徐立军, 陆方皞, 曹章, 张晓倩, 吴易恭, 李泓瑶. 一种基于波分复用的抗光学偏折吸收谱提取方法与系统[P]. 北京市: CN115639170A, 2023-01-24.
[52]徐立军, 张锐, 钟景, 孙世杰, 孙少奇. 一种基于尼尔弛豫的磁纳米粒子检测与成像方法[P]. 北京市: CN115568841A, 2023-01-06.
[53]曹章, 徐立军, 朱晓琳, 李泓瑶, 樊泽腾. 一种高动态冲击信号的频率解算方法与系统[P]. 北京市: CN115510786A, 2022-12-23.
[54]徐立军, 陆方皞, 曹章, 吴易恭. 一种基于激光气体吸收光谱的温度超帧率测量系统与方法[P]. 北京市: CN115468932A, 2022-12-13.
[55]曹章, 周文彬, 徐立军, 段小艳, 李心语. 一种开放路径上痕量气体浓度的实时测量方法与装置[P]. 北京市: CN115343233A, 2022-11-15.
[56]孙江涛, 白旭, 索鹏, 刘康祺, 魏晋钊, 徐立军. 一种基于参数水平集三维EIT图像重建的膀胱体积测量方法[P]. 北京市: CN115311227A, 2022-11-08.
[57]曹章, 曹李培, 徐立军, 汤晓阳. 基于三波长剪切干涉图的燃烧场瞬态温度测量系统与方法[P]. 北京市: CN115290210A, 2022-11-04.
[58]马建国, 徐立军, 孙其振, 谢准, 孙鹏飞. 一种基于宽带超声回波特征的乳腺肿瘤筛查方法和装置[P]. 北京市: CN115227293A, 2022-10-25.
[59]徐立军, 张宏宇, 曹章, 庞应飞, 李微卿. 一种基于无锁相双光梳吸收光谱的气体参数测量方法[P]. 北京市: CN115165781A, 2022-10-11.
[60]孙江涛, 徐立军, 白旭, 梁特, 孙世杰. 一种基于锁相放大的阻抗测量系统及方法[P]. 北京市: CN114983383A, 2022-09-02.
[61]曹章, 李春怡, 徐立军, 侯广羽. 一种免标定抗振动的吸收光谱测量方法与系统[P]. 北京市: CN114993941A, 2022-09-02.
[62]徐立军, 侯广羽, 曹章, 周文彬. 基于吸收光谱幅值调制的温度及气体浓度测量方法与系统[P]. 北京市: CN114993987A, 2022-09-02.
[63]曹章, 徐立军, 田雨, 陆方皞, 李泓瑶. 一种用于电学层析成像的先验滤波迭代解调方法与系统[P]. 北京市: CN114966208A, 2022-08-30.
[64]徐立军, 郭宇东, 曹章, 李泓瑶. 一种适用于双线激光吸收谱测温的谱线优化选取方法[P]. 北京市: CN114936340A, 2022-08-23.
[65]曹章, 温晋婷, 徐立军, 李泓瑶. 一种基于点扩散函数渐近序列的层析成像系统评价方法[P]. 北京市: CN114913139A, 2022-08-16.
[66]付博, 徐立军, 孙婧轩, 朝家乐, 金红, 赵小丽. 基于多模光纤的全光纤可调谐时空锁模激光器及系统[P]. 北京市: CN114825008A, 2022-07-29.
[67]曹章, 徐立军, 李微卿, 张宏宇, 张万鹏. 一种基于关联成像的物体表面温度分布测量方法与系统[P]. 北京市: CN114777931A, 2022-07-22.
[68]曹章, 徐立军, 高欣, 温晋婷, 李泓瑶, 陆方皞. 一种基于Zernike多项式拟合的二维温度场和浓度场成像方法[P]. 北京市: CN114782583A, 2022-07-22.
[69]孙世杰, 卢旭鹏, 王颖, 孙江涛, 徐立军. 一种耐高压耐低温的三维电容阵列传感器[P]. 北京市: CN114705735A, 2022-07-05.
[70]徐立军, 陆方皞, 曹章, 李泓瑶. 一种用于波长调制光谱信号在线递推解调的方法与系统[P]. 北京市: CN114544547A, 2022-05-27.
[71]徐立军, 陆方皞, 曹章, 张晓倩. 一种波长调制激光气体吸收光谱的参数提取方法与系统[P]. 北京市: CN114548172A, 2022-05-27.
[72]马建国, 徐立军, 谢准, 孙其振. 基于超声回波时频谱特征的生物组织辨识方法和装置[P]. 北京市: CN114548179A, 2022-05-27.
[73]徐立军, 王仁德, 曹章, 李泓瑶. 一种基于激光色散光谱的温度和振幅遥测系统与方法[P]. 北京市: CN114518180A, 2022-05-20.
[74]徐立军, 汤晓阳, 曹章, 曹李培. 一种基于波长调制剪切干涉的火焰温度分布测量系统与方法[P]. 北京市: CN114518181A, 2022-05-20.
[75]曹章, 周文彬, 徐立军, 侯广羽. 一种痕量气体浓度和路径长度实时检测系统与方法[P]. 北京市: CN114384045A, 2022-04-22.
[76]孙江涛, 徐立军, 李效霖, 白旭, 刘康祺. 一种适用于微通道异质物检测的电阻抗层析成像传感器[P]. 北京市: CN114295688A, 2022-04-08.
[77]孙江涛, 申梦娴, 白旭, 徐立军. 一种适用于开域流场的气液两相流测量装置及方法[P]. 北京市: CN114216933A, 2022-03-22.
[78]马建国, 徐立军, 刘铁铭, 蔡奕奇. 一种双频超声换能器阵列及其工作方法[P]. 北京市: CN114190976A, 2022-03-18.
[79]徐立军, 王仁德, 曹章, 陆方皞, 黄昂. 一种高精度温度遥测系统与方法[P]. 北京市: CN113959581A, 2022-01-21.
[80]孙江涛, 李效霖, 田文斌, 白旭, 徐立军. 一种应用少电极ECT的气液两相含率检测方法[P]. 北京市: CN113777139A, 2021-12-10.
[81]徐立军, 曹章, 李卓川, 刘怡, 王仁德, 解恒. 一种基于低速采样的衰荡腔高速衰荡信号系数提取方法[P]. 北京市: CN113702294A, 2021-11-26.
[82]徐立军, 曹章, 王晨冉, 黄昂, 陆方皞. 一种波长调制激光吸收光谱线型参数在线提取方法与系统[P]. 北京市: CN113702330A, 2021-11-26.
[83]徐立军, 孙江涛, 索鹏, 孙世杰, 谢跃东, 白旭. 一种基于三维聚焦磁场的地下空间探测装置[P]. 北京市: CN113504570A, 2021-10-15.
[84]孙江涛, 张潇恺, 徐立军, 谢跃东, 孙世杰, 索鹏. 一种基于聚焦磁场的井周电阻率测量装置[P]. 北京市: CN113504573A, 2021-10-15.
[85]孙江涛, 白雪, 白旭, 徐立军. 一种用于小尺度管道内异质物识别的电特性检测方法[P]. 北京市: CN113466295A, 2021-10-01.
[86]曹章, 徐立军, 黄昂, 王仁德, 温晋婷. 一种基于激光吸收阻抗谱的气体温度与浓度参数测量方法[P]. 北京市: CN113447458A, 2021-09-28.
[87]付博, 徐立军, 张程宏, 郭晶晶, 程湲, 孙婧轩. 一种腔衰荡双光梳光谱检测标志性呼吸气体浓度的方法[P]. 北京市: CN113376111A, 2021-09-10.
[88]徐立军, 索鹏, 孙江涛, 孙世杰, 谢跃东. 一种基于聚焦磁场的井周电阻率测量方法[P]. 北京市: CN113359199A, 2021-09-07.
[89]徐立军, 曹章, 侯广羽, 邱爽, 黄昂, 张宏宇. 一种基于幅度调制的激光吸收光谱温度测量方法[P]. 北京市: CN113252204A, 2021-08-13.
[90]徐立军, 胡蝶, 曹章, 田雨. 一种用于环形燃烧场温度分布的可视化测量方法[P]. 北京市: CN113237569A, 2021-08-10.
[91]徐立军, 孙江涛, 索鹏, 孙世杰, 谢跃东. 一种地下目标高精度成像探测方法[P]. 北京市: CN113240791A, 2021-08-10.
[92]付博, 郭晶晶, 徐立军, 尚策. 一种基于金纳米复合材料光纤的反射式葡萄糖传感器及测量系统[P]. 北京市: CN113203712A, 2021-08-03.
[93]郭晶晶, 徐立军, 尚策, 付博. 一种可植入式水凝胶光纤光栅葡萄糖传感器、制备方法及测量系统[P]. 北京市: CN113171091A, 2021-07-27.
[94]付博, 吉训明, 李静, 徐立军, 尚策, 王子皓, 张奡杰. 一种血管内光学相干断层成像激光消融导管[P]. 北京市: CN112842522A, 2021-05-28.
[95]付博, 吉训明, 李静, 徐立军, 程湲, 张奡杰, 王子皓. 一种偏心性内窥镜激光导管[P]. 北京市: CN112842523A, 2021-05-28.
[96]吉训明, 付博, 李静, 尚策, 徐立军, 吕文浩, 欧阳昊. 一种血管内光声成像激光消融导管[P]. 北京市: CN112842524A, 2021-05-28.
[97]吉训明, 付博, 尚策, 徐立军, 李静, 欧阳昊, 吕文浩. 一种血管内窥镜激光消融导管[P]. 北京市: CN112842525A, 2021-05-28.
[98]谢跃东, 黄璞, 浦航, 徐立军, 孙江涛. 涡流检测装置和系统[P]. 北京市: CN112858470A, 2021-05-28.
[99]孙世杰, 王景浩, 王颖, 卢旭鹏, 张锐, 徐立军. 一种基于深度学习的三维电阻抗成像系统[P]. 北京市: CN112754456A, 2021-05-07.
[100]徐立军, 曹章, 谭雨田, 解恒, 杨亚如. 一种基于低带宽光电探测器的激光吸收光谱温度测量系统与方法[P]. 北京市: CN112729591A, 2021-04-30.
[101]刘顿, 索鹏, 孙江涛, 徐立军, 谢跃东. 一种用于离散相非导电颗粒的非接触电磁检测方法[P]. 北京市: CN112683754A, 2021-04-20.
[102]谢跃东, 浦航, 黄璞, 李继尧, 徐立军. 脱粘缺陷检测方法、装置、电子设备及存储介质[P]. 北京市: CN112540125A, 2021-03-23.
[103]曹章, 刘怡, 徐立军, 宋振源, 解恒, 马瑞. 一种基于衰荡腔的振动及气体温度浓度测量方法与系统[P]. 北京市: CN112525841A, 2021-03-19.
[104]马建国, 徐立军, 蔡奕奇. 一种堆叠式超声换能器[P]. 北京市: CN112403873A, 2021-02-26.
[105]谢跃东, 黄璞, 李继尧, 孙江涛, 徐立军. 一种用于无损检测的传感系统[P]. 北京市: CN112378993A, 2021-02-19.
[106]曹章, 王秦璀, 徐立军, 高欣, 田雨. 一种基于模糊PID控制的X射线层析成像图像重建方法[P]. 北京市: CN112381902A, 2021-02-19.
[107]孙江涛, 朱海, 白旭, 徐立军, 田文斌. 基于混合精度训练的深度ECT图像增强方法[P]. 北京市: CN112330761A, 2021-02-05.
[108]谢跃东, 杨晴曌, 孙江涛, 徐立军. 一种人机交互系统[P]. 北京市: CN112269469A, 2021-01-26.
[109]孙世杰, 王景浩, 王颖, 卢旭鹏, 徐立军. 一种三维双模态电阻抗成像传感器及制造方法[P]. 北京市: CN112179950A, 2021-01-05.
[110]曹章, 田雨, 徐立军, 胡蝶, 高欣. 一种用于二值化电容层析成像的闭环图像重建方法[P]. 北京市: CN112147189A, 2020-12-29.
[111]曹章, 郑昊轩, 徐立军, 杨心月, 陆方皞. 一种吸收光谱数据的自适应实时压缩方法与系统[P]. 北京市: CN112134567A, 2020-12-25.
[112]马建国, 徐立军, 马向东, 付博. 一种基于光致超声和激光干涉的全光学超声探测装置[P]. 北京市: CN111912908A, 2020-11-10.
[113]曹章, 黄昂, 徐立军, 赵文帅, 张宏宇. 一种基于频分复用和主峰扫描的激光吸收光谱层析成像方法[P]. 北京市: CN111579532A, 2020-08-25.
[114]孙江涛, 白旭, 田文斌, 谢跃东, 徐立军. 一种动态细胞阻抗成像装置[P]. 北京市: CN111543993A, 2020-08-18.
[115]单光存, 周文霞, 韩露, 王红宇, 徐立军, 高圣乔. 根据细胞影像进行药物疗效分类的方法与电子设备[P]. 北京市: CN111476267A, 2020-07-31.
[116]曹章, 田雨, 徐立军, 胡蝶, 高欣. 一种基于闭环控制原理的离散电容层析成像图像重建方法[P]. 北京市: CN111407272A, 2020-07-14.
[117]曹章, 徐立军, 杨亚如, 高欣, 陈麒屾. 一种基于单一组分吸收光谱的多组分浓度分布的估计方法[P]. 北京市: CN111272680A, 2020-06-12.
[118]高硕, 孙世杰, 吕瑞函, 黄安彪, 徐立军. 基于触摸屏应用Calderon算法重建图像的方法[P]. 北京市: CN111192338A, 2020-05-22.
[119]高硕, 孙世杰, 吕瑞函, 黄安彪, 徐立军. 一种电容式传感器及通过电容成像确定触摸屏定位的方法[P]. 北京市: CN111176496A, 2020-05-19.
[120]徐立军, 胡蝶, 曹章, 田雨. 一种用于单连通燃烧场温度分布的可视化测量方法[P]. 北京市: CN111157139A, 2020-05-15.
[121]高硕, 石佳卉, 陈君亮, 代晏宁, 徐立军. 提高压电触摸屏在阶梯力下测力准确度的装置及方法[P]. 北京市: CN111158528A, 2020-05-15.
[122]高硕, 黄安彪, 代晏宁, 徐立军. 终端控制方法、装置、终端及可读存储介质[P]. 北京市: CN111159669A, 2020-05-15.
[123]曹章, 邱爽, 徐立军, 黄昂, 杨亚如. 一种基于激光吸收光谱的温度快速提取方法[P]. 北京市: CN111089661A, 2020-05-01.
[124]徐立军, 曹章, 杨亚如, 黄昂, 陆方皞. 一种基于单一组分吸收光谱的多组分浓度的估计方法[P]. 北京市: CN111089850A, 2020-05-01.
[125]高硕, 黄安彪, 郭嵘, 邵明启, 徐立军. 一种基于电容检测和机器学习的触摸角度估计方法[P]. 北京市: CN111078064A, 2020-04-28.
[126]曹章, 蔡兆雨, 徐立军, 张宏宇, 黄昂. 一种基于双光梳光谱技术的温度和浓度测量系统和方法[P]. 北京市: CN111077109A, 2020-04-28.
[127]徐立军, 张宏宇, 曹章, 蔡兆雨, 陆方皞. 一种基于双光梳光谱的温度场和浓度场测量系统和方法[P]. 北京市: CN111077110A, 2020-04-28.
[128]高硕, 孙世杰, 吕瑞函, 黄安彪, 徐立军. 一种电容传感器及对其电容信号进行处理的成像定位方法[P]. 北京市: CN111077193A, 2020-04-28.
[129]高硕, 陈君亮, 林凯泽, 徐立军. 利用多传感系统检测针灸技法的装置及相应的方法[P]. 北京市: CN111076776A, 2020-04-28.
[130]高硕, 刘勇, 黄安彪, 徐立军. 触摸力度识别方法及其模型的训练方法、装置和电子系统[P]. 北京市: CN111061394A, 2020-04-24.
[131]高硕, 孙世杰, 吕瑞函, 黄安彪, 徐立军. 基于迭代算法处理电容信号并应用于触摸屏定位的方法[P]. 北京市: CN111061399A, 2020-04-24.
[132]高硕, 孙世杰, 吕瑞函, 黄安彪, 徐立军. 基于Calderon算法对触摸屏图像重建的方法[P]. 北京市: CN111061400A, 2020-04-24.
[133]高硕, 孙世杰, 吕瑞函, 黄安彪, 徐立军. 基于触摸屏应用迭代算法成像重建的定位方法[P]. 北京市: CN111063002A, 2020-04-24.
[134]高硕, 方潮铭, 王轶轩, 徐立军. 基于表面肌电信号与足底力的地形分类装置及方法[P]. 北京市: CN111053555A, 2020-04-24.
[135]高硕, 陈君亮, 石佳卉, 代晏宁, 徐立军. 检测用户手指施加静态力与手指抖动大小的装置及方法[P]. 北京市: CN111060235A, 2020-04-24.
[136]高硕, 陈君亮, 代晏宁, 石佳卉, 刘勇, 徐立军. 矫正动态力下压电系数的装置及相应的方法[P]. 北京市: CN111060250A, 2020-04-24.
[137]徐立军, 张宏宇, 曹章, 蔡兆雨, 黄昂. 一种可变帧率的激光吸收光谱层析成像系统[P]. 北京市: CN111024615A, 2020-04-17.
[138]孙江涛, 梁小凤, 徐立军, 谢跃东, 田文斌. 一种对尿液电导率不敏感的动态膀胱体积测量方法[P]. 北京市: CN110859636A, 2020-03-06.
[139]孙江涛, 梁小凤, 徐立军, 田文斌, 谢跃东. 一种基于边缘场检测的二维EIT电极阵列结构优化方法[P]. 北京市: CN110840457A, 2020-02-28.
[140]徐立军, 曹章, 张宏宇, 高欣, 解恒, 郭宇东. 一种瞬态燃烧场定量测量方法及装置[P]. 北京市: CN110823849A, 2020-02-21.
[141]付博, 徐立军, 尚策, 曹章, 张程宏, 张宏宇. 一种基于双光梳全光纤系统监测航空发动机燃烧场的方法[P]. 北京市: CN110736623A, 2020-01-31.
[142]谢跃东, 田文斌, 孙江涛, 徐立军. 电磁超声换能器[P]. 北京市: CN110702789A, 2020-01-17.
[143]徐立军, 曹章, 宋振源, 张宏宇, 刘怡, 解恒. 一种随机振动驱动衰荡腔免标定气体浓度测量系统与方法[P]. 北京市: CN110672554A, 2020-01-10.
[144]付博, 徐立军, 张程宏, 王刚, 黄浩璟, 孙世杰. 一种空间接入型双光梳系统监测航空发动机燃烧场的方法[P]. 北京市: CN110657992A, 2020-01-07.
[145]付博, 徐立军, 李静, 张程宏, 马宇轩, 李端. 一种基于全光纤光频梳系统监测航空发动机燃烧场的方法[P]. 北京市: CN110657993A, 2020-01-07.
[146]付博, 徐立军, 张程宏, 李静, 陆哲睿, 尚策. 一种空间接入型光频梳系统监测航空发动机燃烧场的方法[P]. 北京市: CN110657994A, 2020-01-07.
[147]付博, 徐立军, 孙婧轩, 尚策, 王帅鑫, 马建国. 高功率波长可调全光纤纳秒脉冲激光器及系统[P]. 北京市: CN110649452A, 2020-01-03.
[148]马建国, 徐立军, 马向东, 付博. 一种基于激光干涉的光纤阵列式声波信号采集装置[P]. 北京市: CN110553715A, 2019-12-10.
[149]付博, 何伯衢, 徐立军, 尚策, 孙江涛. 一种用于太赫兹辐射产生的光纤接入型液体池[P]. 北京市: CN110556689A, 2019-12-10.
[150]曹章, 邱爽, 徐立军, 侯广羽. 一种基于直方图信息的二维温度和浓度重建系统与方法[P]. 北京市: CN110514622A, 2019-11-29.
[151]曹章, 徐立军, 高欣, 田雨, 解恒. 一种基于电力线分布的Radon逆变换电容层析成像方法[P]. 北京市: CN110501587A, 2019-11-26.
[152]付博, 何伯衢, 徐立军, 尚策, 孙江涛. 一种用于太赫兹辐射产生的空间接入型液体池[P]. 北京市: CN110492338A, 2019-11-22.
[153]高硕, 黄安彪, 徐立军. 一种压力信号的校正方法及装置[P]. 北京市: CN110427126A, 2019-11-08.
[154]徐立军, 徐腾, 李小路, 刘畅. 一种地基激光雷达强度数据的自校正方法[P]. 北京市: CN110275155A, 2019-09-24.
[155]徐立军, 李小路, 徐腾, 刘畅. 一种基于激光雷达扫描的隧道表面渗水区域提取方法[P]. 北京市: CN110221277A, 2019-09-10.
[156]孙江涛, 徐立军, 陆方皞, 田文斌, 索鹏. 一种基于电阻抗层析成像的触觉压力传感器与信号采集方法[P]. 北京市: CN110207862A, 2019-09-06.
[157]付博, 吉训明, 徐立军, 尚策, 荣瑶. 一种基于内窥镜引导下的血管中激光溶栓的方法[P]. 北京市: CN110123446A, 2019-08-16.
[158]田文斌, 孙江涛, 徐立军. 一种多模态传感器[P]. 北京市: CN110068583A, 2019-07-30.
[159]吉训明, 付博, 徐立军, 尚策, 马建国. 一种在光学相干断层成像引导下实现在血管中激光溶栓的方法[P]. 北京市: CN110051432A, 2019-07-26.
[160]马建国, 徐立军, 马向东, 付博. 一种基于F-P干涉的低谐振偏心光纤声敏传感装置[P]. 北京市: CN110057439A, 2019-07-26.
[161]付博, 徐立军, 尚策, 马建国. 一种实现高重频波长可调全光纤超快脉冲激光器及系统的方法[P]. 北京市: CN110021871A, 2019-07-16.
[162]徐立军, 常刘勇, 曹章, 郭宇东. 一种监测钝体预混火焰贫燃熄火的方法[P]. 北京市: CN109990278A, 2019-07-09.
[163]徐立军, 常刘勇, 曹章, 郭宇东. 一种基于声学激励的脉动式钝体绕流燃烧装置[P]. 北京市: CN109990279A, 2019-07-09.
[164]孙世杰, 胡蝶, 徐立军, 曹章. 一种便携式电容层析成像测量装置[P]. 北京市: CN109900751A, 2019-06-18.
[165]曹章, 胡蝶, 徐立军, 孙世杰. 一种耐高温高压的电容阵列传感器[P]. 北京市: CN109900752A, 2019-06-18.
[166]孙江涛, 胡蝶, 徐立军, 孙世杰. 一种基于等离子体表面加工工艺的耐高温电容阵列传感器[P]. 北京市: CN109900753A, 2019-06-18.
[167]孙江涛, 徐立军, 陆方皞, 田文斌, 高硕, 梁小凤. 一种适用于运动状态下的电阻抗成像电极与系统[P]. 北京市: CN109745046A, 2019-05-14.
[168]孙江涛, 徐立军, 陆方皞, 高硕, 田文斌, 梁小凤. 一种基于压阻式电极的电阻抗成像系统[P]. 北京市: CN109745047A, 2019-05-14.
[169]付博, 徐立军, 张永彪. 多波长可调谐全光纤脉冲激光器及系统[P]. 北京市: CN109638625A, 2019-04-16.
[170]徐立军, 曹章, 郭宇东, 邱爽. 一种基于神经网络和激光吸收光谱的路径温度直方图测量系统与方法[P]. 北京市: CN109556731A, 2019-04-02.
[171]孙江涛, 徐立军, 梁小凤, 田文斌. 基于单层EIT电极边缘效应的膀胱体积测量方法[P]. 北京市: CN109498013A, 2019-03-22.
[172]付博, 徐立军, 刘会生. 宽带波长可调色散管理型全光纤超快脉冲激光器及系统[P]. 北京市: CN109378694A, 2019-02-22.
[173]曹章, 徐立军, 解恒, 汤晓阳. 一种用于轴对称燃烧场监测的激光吸收光谱层析成像系统[P]. 北京市: CN109324019A, 2019-02-12.
[174]徐立军, 曲前伟, 曹章. 一种用于激光吸收光谱层析成像的谱线选取方法[P]. 北京市: CN109211806A, 2019-01-15.
[175]徐立军, 曹章, 陈亚婧, 邱爽, 郭宇东. 基于单光路多光谱的气体温度概率密度分布拟合重建方法[P]. 北京市: CN109100044A, 2018-12-28.
[176]曹章, 徐立军, 邱爽, 郭宇东, 陈亚婧. 基于单光路多光谱的气体温度概率密度分布重建方法[P]. 北京市: CN109100045A, 2018-12-28.
[177]曹章, 徐立军, 任宇罡, 汤晓阳, 解恒. 一种基于横向剪切干涉的玻璃板厚度分布测量方法及系统[P]. 北京市: CN109059787A, 2018-12-21.
[178]徐立军, 曲前伟, 曹章, 常刘勇. 一种基于激光吸收光谱层析成像技术的气流二维速度分布测量方法[P]. 北京市: CN109061220A, 2018-12-21.
[179]徐立军, 曲前伟, 曹章, 常刘勇. 一种基于激光吸收光谱层析成像技术的气流三维速度分布测量方法[P]. 北京市: CN109061221A, 2018-12-21.
[180]徐立军, 曹章, 李远青, 邱爽. 一种基于干涉调制原理的激光吸收光谱测温方法和系统[P]. 北京市: CN108981953A, 2018-12-11.
[181]徐立军, 曹章, 冉辰浩, 李芳燕. 一种采用多角度直方图信息进行非均匀温度分布重建的方法[P]. 北京市: CN108955936A, 2018-12-07.
[182]李小路, 徐立军, 罗沛, 谢鑫浩. 一种激光雷达信号时刻鉴别系统[P]. 北京市: CN108919282A, 2018-11-30.
[183]徐立军, 曹章, 郭宇东, 张宏宇. 一种基于交叠吸收谱的路径温度直方图测量系统与方法[P]. 北京: CN108801496A, 2018-11-13.
[184]徐立军, 曹章, 郭宇东, 张宏宇. 一种基于波形分解的路径平均温度测量系统与方法[P]. 北京: CN108760681A, 2018-11-06.
[185]李小路, 徐立军, 谢鑫浩, 杨炳伟. 一种激光雷达波形时刻鉴别方法与在线测距系统[P]. 北京: CN108732553A, 2018-11-02.
[186]曹章, 徐立军, 吉俐, 胡蝶, 高欣. 一种基于闭环控制原理的电容层析成像图像重建方法[P]. 北京: CN108711178A, 2018-10-26.
[187]徐立军, 曹章, 冉辰浩, 张宏宇, 邱爽. 一种基于四角度激光吸收光谱的二维温度分布重建方法[P]. 北京: CN108627272A, 2018-10-09.
[188]徐立军, 李端, 李小路, 刘畅, 谢鑫浩. 一种基于光强分光的高光谱激光雷达系统[P]. 北京: CN108415030A, 2018-08-17.
[189]李端, 徐立军, 李小路, 刘畅, 谢鑫浩. 一种基于光谱分光的高光谱全波形激光雷达系统[P]. 北京: CN108415031A, 2018-08-17.
[190]孙世杰, 徐立军, 曹章, 何玉珠. 一种高压电容阵列传感器[P]. 北京: CN108398465A, 2018-08-14.
[191]李端, 李小路, 徐立军, 刘畅, 谢鑫浩. 一种基于接收端光纤色散的高光谱激光雷达系统[P]. 北京: CN108398695A, 2018-08-14.
[192]曹章, 徐立军, 吉俐, 胡蝶, 何玉珠. 一种用于电学成像的多导体体系导纳矩阵快速计算方法[P]. 北京: CN108376124A, 2018-08-07.
[193]孙世杰, 徐立军, 曹章, 黄昂, 何玉珠. 一种分程式并行结构电容阵列测量电路[P]. 北京: CN108333434A, 2018-07-27.
[194]李小路, 徐立军, 冯静, 刘畅. 一种结合激光雷达三维点云数据的相机自标定方法[P]. 北京: CN107977997A, 2018-05-01.
[195]徐立军, 曹章, 汤晓阳, 高欣, 解恒. 一种基于扫描振镜的光学层析成像系统[P]. 北京: CN107796333A, 2018-03-13.
[196]李小路, 徐立军, 李昀晔, 谢鑫浩. 一种基于自制地基激光雷达对准误差的点云误差校正方法[P]. 北京: CN107703499A, 2018-02-16.
[197]曹章, 徐立军, 常刘勇. 一种基于二向色分光的激光光线偏折校正装置及方法[P]. 北京: CN107560738A, 2018-01-09.
[198]徐立军, 曹章, 李芳燕. 一种基于调制锯齿波信号的激光光线偏折校正装置及方法[P]. 北京: CN107560754A, 2018-01-09.
[199]曹章, 徐立军, 谢艺歆, 孙世杰, 蝴蝶, 黄昂. 一种基于压缩感知理论的宽频谱阻抗测量装置及方法[P]. 北京: CN107561367A, 2018-01-09.
[200]曹章, 徐立军, 解恒. 一种基于光开关切换的激光光线偏折效应校正装置及方法[P]. 北京: CN107543620A, 2018-01-05.
[201]徐立军, 曹章, 李芳燕. 一种基于高频正弦校准光的激光光线偏折校正装置及方法[P]. 北京: CN107505063A, 2017-12-22.
[202]徐立军, 曹章, 陆方皞, 孙世杰, 黄昂. 一种用于解调含有高斯有色噪声信号的递推解调器[P]. 北京: CN107505507A, 2017-12-22.
[203]曹章, 徐立军, 牛贺, 解恒. 一种基于闭环控制原理的粒径分布测量装置及方法[P]. 北京: CN107490531A, 2017-12-19.
[204]徐立军, 徐腾, 李小路, 谢鑫浩, 杨炳伟. 一种基于GPS定位和航摄图像匹配的航空遥感平台姿态角高精度测量方法[P]. 北京: CN107462244A, 2017-12-12.
[205]李小路, 徐立军, 李昀晔, 谢鑫浩. 一种基于自制地基激光雷达垂直度误差的点云误差校正方法[P]. 北京: CN107290734A, 2017-10-24.
[206]李小路, 徐立军, 李昀晔, 谢鑫浩. 一种基于自制地基激光雷达铅垂度误差的点云误差校正方法[P]. 北京: CN107290735A, 2017-10-24.
[207]徐立军, 李端, 李小路, 谢鑫浩, 杨炳伟. 一种三维扫描全波形激光雷达系统[P]. 北京: CN107272018A, 2017-10-20.
[208]徐立军, 解恒, 曹章. 一种基于单光电探测器的颗粒粒度测量仪[P]. 北京: CN107255608A, 2017-10-17.
[209]曹章, 徐立军, 叶桢, 解恒. 一种基于相位式激光测距的三维关联成像方法[P]. 北京: CN107121682A, 2017-09-01.
[210]曹章, 徐立军, 吉俐, 孙世杰, 黄昂. 一种由电流#电压映射构造电压#电流映射的方法[P]. 北京: CN107091858A, 2017-08-25.
[211]徐立军, 李端, 李小路, 谢鑫浩, 杨炳伟. 一种基于FPGA的高重复频率三维扫描激光雷达扫描角测量电路[P]. 北京: CN107015215A, 2017-08-04.
[212]曹章, 徐立军, 陈坚亮, 曲前伟. 一种基于多视角多光谱层析成像的图像重建方法[P]. 北京: CN106815878A, 2017-06-09.
[213]徐立军, 曹章, 张文, 赵嘉宇. 一种基于最小均方根误差的水平井持水率测量方法[P]. 北京: CN105971594A, 2016-09-28.
[214]徐立军, 曹章, 杨阳, 刘畅, 曲前伟. 一种基于递推最小二乘法的激光吸收光谱谐波信号峰值点提取方法[P]. 北京: CN105866068A, 2016-08-17.
[215]徐立军, 曹章, 张文, 赵嘉宇, 张文强. 一种基于双环电导探针阵列的水平井持水率测量方法[P]. 北京: CN105574272A, 2016-05-11.
[216]徐立军, 孙世杰, 曹章, 刘翔宇. 一种多频信息滤波递推解调方法[P]. 北京: CN105548711A, 2016-05-04.
[217]徐立军, 张文, 曹章, 陈健军, 尹汭, 赵嘉宇. 一种融合总流量与电导探针阵列信号的水平井持水率测量方法[P]. 北京: CN105404747A, 2016-03-16.
[218]曹章, 徐立军, 孙世杰. 一种用于多源X射线成像的PID控制图像重建方法[P]. 北京: CN105319228A, 2016-02-10.
[219]曹章, 任迎, 徐立军, 孙世杰. 一种基于随机解调器的阻抗测量装置及方法[P]. 北京: CN105319445A, 2016-02-10.
[220]徐立军, 陈健军, 曹章, 赵嘉宇, 王友岭. 一种基于电导探针阵列投票表决的垂直井流型识别方法[P]. 北京: CN105114054A, 2015-12-02.
[221]曹章, 陈健军, 徐立军, 张文, 赵嘉宇. 一种基于电导探针阵列信息融合的垂直井含水率测量方法[P]. 北京: CN105064993A, 2015-11-18.
[222]曹章, 陈健军, 许国伟, 王友岭, 徐立军. 一种基于总流量与电导探针阵列信号的水平井流型识别方法[P]. 北京: CN105003249A, 2015-10-28.
[223]徐立军, 陈健军, 曹章, 王友岭, 张文. 一种基于总流量与电导探针阵列信号的垂直井含水率测量方法[P]. 北京: CN104989377A, 2015-10-21.
[224]徐立军, 曹章, 曲前伟, 刘畅. 一种用于圆对称参数分布的双倍分辨率图像重建方法[P]. 北京: CN104881887A, 2015-09-02.
[225]徐立军, 陈健军, 曹章, 徐文峰, 王友岭. 一种用于多频信号遥测的LC并联谐振接收电路设计方法[P]. 北京: CN104063557A, 2014-09-24.
[226]徐立军, 徐文峰, 曹章, 陈健军, 王友岭. 一种基于电导探针阵列和信息融合技术的水平井参数检测方法[P]. 北京: CN103967477A, 2014-08-06.
[227]徐立军, 徐文峰, 曹章, 陈健军, 王友岭. 一种基于电导探针的垂直井流型辨识方法[P]. 北京: CN103967478A, 2014-08-06.
[228]曹章, 徐立军, 魏天啸, 周家怡, 辛蕾. 一种基于质心法的光斑图像中心的快速定位方法[P]. 北京: CN103955687A, 2014-07-30.
[229]徐立军, 曹章, 魏天啸, 周家怡, 辛蕾. 一种基于导数法的光斑图像中心的快速定位方法[P]. 北京: CN103927536A, 2014-07-16.
[230]徐立军, 曹章, 魏天啸, 周家怡, 辛蕾. 一种基于几何法的光斑图像中心的快速定位方法[P]. 北京: CN103927766A, 2014-07-16.
[231]徐立军, 李端, 李小路, 孔德明, 马莲. 一种全光纤光路全波形激光雷达系统[P]. 北京: CN103901435A, 2014-07-02.
[232]曹章, 徐立军, 周家怡, 魏天啸. 一种基于液晶屏光调制的图像采样方法[P]. 北京: CN103871387A, 2014-06-18.
[233]曹章, 徐立军, 黄驰, 孙世杰. 一种由电压-电流映射构造电流-电压映射的方法[P]. 北京: CN103776873A, 2014-05-07.
[234]李小路, 徐立军, 李端, 孔德明, 马莲. 一种基于同轴双通道数据采集的全波形激光雷达系统[P]. 北京: CN103576134A, 2014-02-12.
[235]徐立军, 曹章, 魏天啸, 蔡小舒. 一种用于前向衍射光光强分布测量的对中装置及方法[P]. 北京: CN103411859A, 2013-11-27.
[236]徐立军, 曹章, 刘畅, 蔡小舒. 一种采用双路可调谐激光吸收光谱技术的归一化降噪方法[P]. 北京: CN103411923A, 2013-11-27.
[237]曹章, 徐立军, 孙世杰, 王海刚. 一种用于电学层析成像系统的信息滤波解调方法[P]. 北京: CN103412189A, 2013-11-27.
[238]曹章, 宋伟, 徐立军. 一种高精度正弦/余弦函数的计算方法[P]. 北京: CN103365827A, 2013-10-23.
[239]徐立军, 徐文峰. 一种基于电导探针阵列传感器的水平井多参数估计方法[P]. 北京: CN103277084A, 2013-09-04.
[240]李小路, 徐立军, 陈路路, 成艳亭. 一种基于图像拼接的空冷凝汽器散热面温度场测量方法[P]. 北京: CN103217221A, 2013-07-24.
[241]李小路, 徐立军, 马莲. 一种基于遗传算法的全波形激光雷达回波数据的高斯分解法[P]. 北京: CN103217679A, 2013-07-24.
[242]徐立军, 李小路, 成艳亭, 陈路路. 一种通过图像分割修正表面发射率的红外热成像测温方法[P]. 北京: CN103196564A, 2013-07-10.
[243]李小路, 徐立军, 马莲. 一种全波形激光雷达系统[P]. 北京: CN103197321A, 2013-07-10.
[244]徐立军, 孙世杰, 曹章. 一种基于相邻激励测量模式的电流-电压映射构造方法[P]. 北京: CN103163404A, 2013-06-19.
[245]曹章, 徐立军, 孙世杰, 黄驰. 一种基于二端子激励测量模式的电压-电流映射构造方法[P]. 北京: CN103149472A, 2013-06-12.
[246]曹章, 孙世杰, 徐立军, 黄驰. 一种基于相邻激励测量模式的电压-电流映射构造方法[P]. 北京: CN103116101A, 2013-05-22.
[247]曹章, 徐立军, 刘畅, 辛蕾. 一种采用单一光电探测器的激光光强分布精确测量系统[P]. 北京: CN103090966A, 2013-05-08.
[248]曹章, 徐立军, 辛蕾, 魏天啸. 一种光斑图像中心的快速定位方法[P]. 北京: CN103093223A, 2013-05-08.
[249]曹章, 徐立军, 彭智聪, 宋伟. 一种基于欧拉公式的高精度正弦/余弦函数计算方法[P]. 北京: CN103065039A, 2013-04-24.
[250]曹章, 刘畅, 徐立军, 孙世杰. 一种基于虚拟数据的轴对称参数分布图像重建方法[P]. 北京: CN103047946A, 2013-04-17.
[251]曹章, 徐立军, 彭智聪, 宋伟. 一种基于泰勒展开式的高精度正弦/余弦函数计算方法[P]. 北京: CN103049427A, 2013-04-17.
[252]曹章, 陈健军, 周海力, 徐立军, 蒋昌华. 一种基于二端子阻抗测量模式的四端子电阻抗层析成像方法[P]. 北京: CN103018284A, 2013-04-03.
[253]徐立军, 陈健军, 徐文峰, 曹章, 蒋昌华. 一种基于遗传算法的多环电极阵列传感器结构优化方法[P]. 北京: CN103015981A, 2013-04-03.
[254]徐立军, 孔德明, 李小路, 李端. 一种基于K-plane算法的建筑物顶面点云数据分割方法[P]. 北京: CN103020637A, 2013-04-03.
[255]徐立军, 曹章, 刘畅, 陈露露. 一种基于轴对称参数分布的图像重建方法[P]. 北京: CN103021005A, 2013-04-03.
[256]徐立军, 李小路, 孔德明, 李端. 一种激光雷达实时成像和建筑物特征提取的方法[P]. 北京: CN103018728A, 2013-04-03.
[257]徐立军, 陈健军, 曹章, 胡金海, 刘兴斌. 一种曼彻斯特码井下长距离传输装置及方法[P]. 北京: CN102843166A, 2012-12-26.
[258]徐立军, 曹章, 刘畅. 一种近红外激光对准方法[P]. 北京: CN102735616A, 2012-10-17.
[259]徐立军, 曹章, 刘雨佳, 张玉枚. 一种用于渡越时间测量的自适应相关算法[P]. 北京: CN102645552A, 2012-08-22.
[260]徐立军, 孔德明, 李小路. 一种对原始数据低失真的谐波噪声干扰和白噪声干扰的去除方法[P]. 北京: CN102624349A, 2012-08-01.
[261]徐立军, 周海力, 曹章, 曾轶. 一种用于电学层析成像系统的递推解调方法[P]. 北京: CN102565541A, 2012-07-11.
[262]曹章, 周海力, 徐立军, 曾轶. 一种用于电学层析成像系统的多频递推解调方法[P]. 北京: CN102570984A, 2012-07-11.
[263]徐立军, 田祥瑞, 李小路, 王建军, 张超曾. 一种机载激光雷达侧滚角偏差补偿方法[P]. 北京: CN102508221A, 2012-06-20.
[264]徐立军, 王建军, 李小路, 张超曾. 一种机载激光雷达激光发射指向扰动的补偿装置及方法[P]. 北京: CN102426355A, 2012-04-25.
[265]徐立军, 田祥瑞, 李小路, 王建军. 一种机载激光雷达航测参数的优化设计方法[P]. 北京: CN102176003A, 2011-09-07.
[266]徐立军, 曹章, 徐文峰, 陈健军, 刘兴斌, 马水龙, 胡金海. 一种环形持水率测井传感器阵列的结构优化方法[P]. 北京: CN102011575A, 2011-04-13.
[267]徐立军, 王建军, 李小路, 田祥瑞. 一种用于机载激光雷达滚动角偏差实时补偿的方法与装置[P]. 北京: CN101900806A, 2010-12-01.
[268]徐立军, 王建军, 李小路, 郜蕾. 一种用于机载激光雷达俯仰角偏差实时补偿的方法与装置[P]. 北京: CN101865996A, 2010-10-20.
[269]徐立军, 周婉露, 李小路, 田祥瑞. 一种提高机载平台定姿精度的在线快速方法[P]. 北京: CN101793517A, 2010-08-04.
[270]曹章, 徐立军, 丁洁. 一种粒径测量的有限分布积分反演算法[P]. 北京: CN101793665A, 2010-08-04.
[271]徐立军, 徐文峰, 曹章, 周海力, 刘兴斌, 胡金海. 一种多环电极阵列成像传感器[P]. 北京: CN101793852A, 2010-08-04.
[272]李小路, 徐立军. 一种实时在线的空间飞行器壳体受撞击度与撞击定位测量系统[P]. 北京: CN101776441A, 2010-07-14.
[273]徐立军, 曹章, 凌琪, 范士伟. 一种基于管内磁场仿真数值计算的电磁流量计干标定方法[P]. 北京: CN101750136A, 2010-06-23.
[274]徐立军, 李小路, 谭丞. 一种基于支持向量机的燃料种类在线识别方法[P]. 北京: CN101701951A, 2010-05-05.
[275]徐立军, 曹章, 范士伟, 凌琪. 一种可用于非满管流量测量的电容式电磁流量计[P]. 北京: CN101701836A, 2010-05-05.
[276]徐立军, 范士伟, 曹章. 一种可用于非满管流量测量的电磁流量计[P]. 北京: CN101699226A, 2010-04-28.
[277]徐立军, 曹章, 凌琪, 范士伟. 一种具有矩形截面结构的电容式电磁流量传感器[P]. 北京: CN101699227A, 2010-04-28.
[278]徐立军, 谭丞, 李小路. 一种基于多元火焰监测器的燃料种类在线判别方法[P]. 北京: CN101692270A, 2010-04-07.
[279]徐立军, 陈健军, 曹章. 一种基于阻抗测量的多通道植物缺水监测系统[P]. 北京: CN101666767, 2010-03-10.
[280]徐立军, 周海力, 曹章. 一种多通道电阻抗式植物含水率监测系统[P]. 北京: CN101666768, 2010-03-10.
[281]徐立军, 谭丞, 曹章. 一种新燃料在线识别方法[P]. 北京: CN101644699, 2010-02-10.
[282]徐立军, 李小路, 谭丞, 田祥瑞. 一种同时监测燃烧火焰温度场和中间产物浓度二维分布的方法[P]. 北京: CN101625269, 2010-01-13.
[283]李小路, 徐立军, 田祥瑞, 谭丞. 一种基于光学补偿设计的火焰温度场和燃烧中间产物浓度场监测系统[P]. 北京: CN101625270, 2010-01-13.
[284]徐立军, 李小路, 谭丞, 田祥瑞. 一种燃烧中间产物二维分布在线监测系统[P]. 北京: CN101609052, 2009-12-23.
[285]徐立军, 周婉露, 李小路, 王建军. 一种提高机载激光雷达定姿精度的方法[P]. 北京: CN101609149, 2009-12-23.
[286]曹章, 徐立军, 丁洁. 一种基于圆形传感器的电容层析成像的图像重建直接方法[P]. 北京: CN101520478, 2009-09-02.
[287]曹章, 徐立军, 丁洁. 一种粒径测量的积分反演算方法[P]. 北京: CN101430268, 2009-05-13.
[288]徐立军, 谭丞. 双元火焰监测器[P]. 北京: CN101408313, 2009-04-15.
发明授权:
[1]曹章, 王秦璀, 徐立军, 高欣, 田雨. 一种基于模糊PID控制的X射线层析成像图像重建方法[P]. 北京市: CN112381902B, 2024-12-17.
[2]徐立军, 陆方皞, 曹章, 李泓瑶. 一种用于波长调制光谱信号在线递推解调的方法与系统[P]. 北京市: CN114544547B, 2024-11-26.
[3]徐立军, 陆方皞, 曹章, 吴易恭. 一种基于激光气体吸收光谱的温度超帧率测量系统与方法[P]. 北京市: CN115468932B, 2024-11-26.
[4]孙江涛, 徐立军, 白旭, 梁特, 孙世杰. 一种基于锁相放大的阻抗测量系统及方法[P]. 北京市: CN114983383B, 2024-09-10.
[5]曹章, 温晋婷, 徐立军, 李泓瑶. 一种基于点扩散函数渐近序列的层析成像系统评价方法[P]. 北京市: CN114913139B, 2024-06-18.
[6]曹章, 曹李培, 徐立军, 汤晓阳. 基于三波长剪切干涉图的燃烧场瞬态温度测量系统与方法[P]. 北京市: CN115290210B, 2024-06-18.
[7]徐立军, 侯广羽, 曹章, 周文彬. 基于吸收光谱幅值调制的温度及气体浓度测量方法与系统[P]. 北京市: CN114993987B, 2024-04-30.
[8]曹章, 周文彬, 徐立军, 段小艳, 李心语. 一种开放路径上痕量气体浓度的实时测量方法与装置[P]. 北京市: CN115343233B, 2024-04-30.
[9]曹章, 李春怡, 徐立军, 侯广羽. 一种免标定抗振动的吸收光谱测量方法与系统[P]. 北京市: CN114993941B, 2024-04-12.
[10]徐立军, 陆方皞, 曹章, 张晓倩, 吴易恭, 李泓瑶. 一种基于波分复用的抗光学偏折吸收谱提取方法与系统[P]. 北京市: CN115639170B, 2024-04-12.
[11]曹章, 周文彬, 徐立军, 侯广羽. 一种痕量气体浓度和路径长度实时检测系统与方法[P]. 北京市: CN114384045B, 2024-01-12.
[12]谢跃东, 黄璞, 李继尧, 孙江涛, 徐立军. 一种用于无损检测的传感系统[P]. 北京市: CN112378993B, 2023-12-12.
[13]孙江涛, 申梦娴, 白旭, 徐立军. 一种适用于开域流场的气液两相流测量装置及方法[P]. 北京市: CN114216933B, 2023-11-24.
[14]谢跃东, 黄璞, 浦航, 徐立军, 孙江涛. 涡流检测装置和系统[P]. 北京市: CN112858470B, 2023-07-28.
[15]马建国, 徐立军, 刘铁铭, 蔡奕奇. 一种双频超声换能器阵列及其工作方法[P]. 北京市: CN114190976B, 2023-07-21.
[16]孙江涛, 徐立军, 李效霖, 白旭, 刘康祺. 一种适用于微通道异质物检测的电阻抗层析成像传感器[P]. 北京市: CN114295688B, 2023-05-23.
[17]付博, 徐立军, 张程宏, 郭晶晶, 程湲, 孙婧轩. 一种腔衰荡双光梳光谱检测标志性呼吸气体浓度的方法[P]. 北京市: CN113376111B, 2023-04-18.
[18]徐立军, 张锐, 钟景, 孙世杰, 孙少奇. 一种基于尼尔弛豫的磁纳米粒子检测与成像方法[P]. 北京市: CN115568841B, 2023-04-14.
[19]高硕, 孙世杰, 吕瑞函, 黄安彪, 徐立军. 基于触摸屏应用Calderon算法重建图像的方法[P]. 北京市: CN111192338B, 2023-03-24.
[20]郭晶晶, 徐立军, 尚策, 付博. 一种可植入式水凝胶光纤光栅葡萄糖传感器、制备方法及测量系统[P]. 北京市: CN113171091B, 2023-03-21.
[21]徐立军, 王仁德, 曹章, 李泓瑶. 一种基于激光色散光谱的温度和振幅遥测系统与方法[P]. 北京市: CN114518180B, 2022-12-09.
[22]孙世杰, 王景浩, 王颖, 卢旭鹏, 张锐, 徐立军. 一种基于深度学习的三维电阻抗成像系统[P]. 北京市: CN112754456B, 2022-10-28.
[23]孙江涛, 白旭, 朱海, 徐立军, 田文斌, 谢跃东. 一种基于FFT和CORDIC算法的高速高精度阻抗数据采集系统[P]. 北京市: CN113098512B, 2022-10-28.
[24]曹章, 郑昊轩, 徐立军, 杨心月, 陆方皞. 一种吸收光谱数据的自适应实时压缩方法与系统[P]. 北京市: CN112134567B, 2022-10-25.
[25]孙江涛, 白雪, 白旭, 徐立军. 一种用于小尺度管道内异质物识别的电特性检测方法[P]. 北京市: CN113466295B, 2022-10-18.
[26]付博, 郭晶晶, 徐立军, 尚策. 一种基于金纳米复合材料光纤的反射式葡萄糖传感器及测量系统[P]. 北京市: CN113203712B, 2022-10-11.
[27]徐立军, 孙江涛, 索鹏, 孙世杰, 谢跃东. 一种地下目标高精度成像探测方法[P]. 北京市: CN113240791B, 2022-09-20.
[28]曹章, 徐立军, 黄昂, 王仁德, 温晋婷. 一种基于激光吸收阻抗谱的气体温度与浓度参数测量方法[P]. 北京市: CN113447458B, 2022-08-19.
[29]徐立军, 曹章, 王晨冉, 黄昂, 陆方皞. 一种波长调制激光吸收光谱线型参数在线提取方法与系统[P]. 北京市: CN113702330B, 2022-08-19.
[30]孙江涛, 李效霖, 田文斌, 白旭, 徐立军. 一种应用少电极ECT的气液两相含率检测方法[P]. 北京市: CN113777139B, 2022-08-16.
[31]徐立军, 索鹏, 孙江涛, 孙世杰, 谢跃东. 一种基于聚焦磁场的井周电阻率测量方法[P]. 北京市: CN113359199B, 2022-07-08.
[32]吉训明, 付博, 尚策, 徐立军, 李静, 欧阳昊, 吕文浩. 一种血管内窥镜激光消融导管[P]. 北京市: CN112842525B, 2022-06-10.
[33]付博, 吉训明, 李静, 徐立军, 程湲, 张奡杰, 王子皓. 一种偏心性内窥镜激光导管[P]. 北京市: CN112842523B, 2022-05-17.
[34]孙江涛, 朱海, 白旭, 徐立军, 田文斌. 基于混合精度训练的深度ECT图像增强方法[P]. 北京市: CN112330761B, 2022-04-29.
[35]曹章, 徐立军, 解恒, 汤晓阳. 一种用于轴对称燃烧场监测的激光吸收光谱层析成像系统[P]. 北京市: CN109324019B, 2022-04-12.
[36]徐立军, 胡蝶, 曹章, 田雨. 一种用于环形燃烧场温度分布的可视化测量方法[P]. 北京市: CN113237569B, 2022-04-01.
[37]徐立军, 曹章, 侯广羽, 邱爽, 黄昂, 张宏宇. 一种基于幅度调制的激光吸收光谱温度测量方法[P]. 北京市: CN113252204B, 2022-04-01.
[38]高硕, 孙世杰, 吕瑞函, 黄安彪, 徐立军. 基于触摸屏应用迭代算法成像重建的定位方法[P]. 北京市: CN111063002B, 2022-03-25.
[39]谢跃东, 浦航, 黄璞, 李继尧, 徐立军. 脱粘缺陷检测方法、装置、电子设备及存储介质[P]. 北京市: CN112540125B, 2022-03-25.
[40]高硕, 黄安彪, 代晏宁, 徐立军. 终端控制方法、装置、终端及可读存储介质[P]. 北京市: CN111159669B, 2022-03-18.
[41]谢跃东, 杨晴曌, 孙江涛, 徐立军. 一种人机交互系统[P]. 北京市: CN112269469B, 2022-03-08.
[42]孙世杰, 高硕, 吕瑞函, 黄安彪, 徐立军. 基于Calderon算法对触摸屏图像重建的方法[P]. 北京市: CN111061400B, 2022-02-25.
[43]李小路, 徐立军, 谢鑫浩, 杨炳伟. 一种激光雷达波形时刻鉴别方法与在线测距系统[P]. 北京市: CN108732553B, 2022-02-01.
[44]孙江涛, 白旭, 田文斌, 谢跃东, 徐立军. 一种动态细胞阻抗成像装置[P]. 北京市: CN111543993B, 2022-01-28.
[45]高硕, 陈君亮, 林凯泽, 徐立军. 利用多传感系统检测针灸技法的装置及相应的方法[P]. 北京市: CN111076776B, 2021-12-07.
[46]徐立军, 曹章, 谭雨田, 解恒, 杨亚如. 一种基于低带宽光电探测器的激光吸收光谱温度测量方法[P]. 北京市: CN112729591B, 2021-11-23.
[47]曹章, 刘怡, 徐立军, 宋振源, 解恒, 马瑞. 一种基于衰荡腔的振动及气体温度浓度测量方法[P]. 北京市: CN112525841B, 2021-11-19.
[48]孙世杰, 王景浩, 王颖, 卢旭鹏, 徐立军. 一种三维双模态电阻抗成像传感器及制造方法[P]. 北京市: CN112179950B, 2021-11-16.
[49]高硕, 陈君亮, 石佳卉, 代晏宁, 徐立军. 检测用户手指施加静态力与手指抖动大小的装置及方法[P]. 北京市: CN111060235B, 2021-11-05.
[50]孙世杰, 高硕, 吕瑞函, 黄安彪, 徐立军. 基于迭代算法处理电容信号并应用于触摸屏定位的方法[P]. 北京市: CN111061399B, 2021-10-26.
[51]孙世杰, 高硕, 吕瑞函, 黄安彪, 徐立军. 一种电容传感器及对其电容信号进行处理的成像定位方法[P]. 北京市: CN111077193B, 2021-10-22.
[52]高硕, 孙世杰, 吕瑞函, 黄安彪, 徐立军. 一种电容式传感器及通过电容成像确定触摸屏定位的方法[P]. 北京市: CN111176496B, 2021-10-08.
[53]曹章, 徐立军, 吉俐, 胡蝶, 高欣. 一种基于闭环控制原理的电容层析成像图像重建方法[P]. 北京市: CN108711178B, 2021-09-28.
[54]徐立军, 曹章, 杨亚如, 黄昂, 陆方皞. 一种基于单一组分吸收光谱的多组分浓度的估计方法[P]. 北京市: CN111089850B, 2021-09-28.
[55]徐立军, 胡蝶, 曹章, 田雨. 一种用于单连通燃烧场温度分布的可视化测量方法[P]. 北京市: CN111157139B, 2021-09-28.
[56]曹章, 徐立军, 杨亚如, 高欣, 陈麒屾. 一种基于单一组分吸收光谱的多组分浓度分布的估计方法[P]. 北京市: CN111272680B, 2021-09-28.
[57]马建国, 徐立军, 蔡奕奇. 一种堆叠式超声换能器[P]. 北京市: CN112403873B, 2021-09-28.
[58]刘顿, 索鹏, 孙江涛, 徐立军, 谢跃东. 一种用于离散相非导电颗粒的非接触电磁检测方法[P]. 北京市: CN112683754B, 2021-08-24.
[59]马建国, 徐立军, 马向东, 付博. 一种基于光致超声和激光干涉的全光学超声探测装置[P]. 北京市: CN111912908B, 2021-08-17.
[60]高硕, 方潮铭, 王轶轩, 徐立军. 基于表面肌电信号与足底力的地形分类装置及方法[P]. 北京市: CN111053555B, 2021-08-13.
[61]高硕, 刘勇, 黄安彪, 徐立军. 触摸力度识别方法及其模型的训练方法、装置和电子系统[P]. 北京市: CN111061394B, 2021-08-13.
[62]孙江涛, 徐立军, 陆方皞, 田文斌, 高硕, 梁小凤. 一种适用于运动状态下的电阻抗成像电极与系统[P]. 北京市: CN109745046B, 2021-07-02.
[63]孙江涛, 徐立军, 陆方皞, 高硕, 田文斌, 梁小凤. 一种基于压阻式电极的电阻抗成像系统[P]. 北京市: CN109745047B, 2021-07-02.
[64]高硕, 石佳卉, 陈君亮, 代晏宁, 徐立军. 提高压电触摸屏在阶梯力下测力准确度的装置及方法[P]. 北京市: CN111158528B, 2021-06-29.
[65]曹章, 徐立军, 高欣, 田雨, 解恒. 一种基于电力线分布的Radon逆变换电容层析成像方法[P]. 北京市: CN110501587B, 2021-06-11.
[66]曹章, 蔡兆雨, 徐立军, 张宏宇, 黄昂. 一种基于双光梳光谱技术的温度和浓度测量系统和方法[P]. 北京市: CN111077109B, 2021-06-11.
[67]徐立军, 张宏宇, 曹章, 蔡兆雨, 陆方皞. 一种基于双光梳光谱的温度场和浓度场测量系统和方法[P]. 北京市: CN111077110B, 2021-06-11.
[68]徐立军, 曹章, 张宏宇, 高欣, 解恒, 郭宇东. 一种瞬态燃烧场定量测量方法及装置[P]. 北京市: CN110823849B, 2021-04-27.
[69]马建国, 徐立军, 马向东, 付博. 一种基于激光干涉的光纤阵列式声波信号采集装置[P]. 北京市: CN110553715B, 2021-03-30.
[70]付博, 徐立军, 尚策, 曹章, 张程宏, 张宏宇. 一种基于双光梳全光纤系统监测航空发动机燃烧场的方法[P]. 北京市: CN110736623B, 2021-03-12.
[71]高硕, 陈君亮, 代晏宁, 石佳卉, 刘勇, 徐立军. 矫正动态力下压电系数的装置及相应的方法[P]. 北京市: CN111060250B, 2021-03-02.
[72]曹章, 徐立军, 陈坚亮, 曲前伟. 一种基于多视角多光谱层析成像的图像重建方法[P]. 北京市: CN106815878B, 2021-02-05.
[73]孙江涛, 胡蝶, 徐立军, 孙世杰. 一种基于等离子体表面加工工艺的耐高温电容阵列传感器[P]. 北京市: CN109900753B, 2021-02-05.
[74]付博, 徐立军, 李静, 张程宏, 马宇轩, 李端. 一种基于全光纤光频梳系统监测航空发动机燃烧场的方法[P]. 北京市: CN110657993B, 2021-02-02.
[75]徐立军, 张宏宇, 曹章, 蔡兆雨, 黄昂. 一种可变帧率的激光吸收光谱层析成像系统[P]. 北京市: CN111024615B, 2021-01-19.
[76]付博, 何伯衢, 徐立军, 尚策, 孙江涛. 一种用于太赫兹辐射产生的空间接入型液体池[P]. 北京市: CN110492338B, 2021-01-15.
[77]付博, 何伯衢, 徐立军, 尚策, 孙江涛. 一种用于太赫兹辐射产生的光纤接入型液体池[P]. 北京市: CN110556689B, 2021-01-15.
[78]付博, 徐立军, 张程宏, 王刚, 黄浩璟, 孙世杰. 一种空间接入型双光梳系统监测航空发动机燃烧场的方法[P]. 北京市: CN110657992B, 2021-01-15.
[79]付博, 徐立军, 张程宏, 李静, 陆哲睿, 尚策. 一种空间接入型光频梳系统监测航空发动机燃烧场的方法[P]. 北京市: CN110657994B, 2021-01-15.
[80]高硕, 黄安彪, 郭嵘, 邵明启, 徐立军. 一种基于电容检测和机器学习的触摸角度估计方法[P]. 北京市: CN111078064B, 2021-01-01.
[81]孙江涛, 梁小凤, 徐立军, 谢跃东, 田文斌. 一种对尿液电导率不敏感的动态膀胱体积测量方法[P]. 北京市: CN110859636B, 2020-12-25.
[82]孙世杰, 胡蝶, 徐立军, 曹章. 一种便携式电容层析成像测量装置[P]. 北京市: CN109900751B, 2020-12-04.
[83]徐立军, 李端, 李小路, 谢鑫浩, 杨炳伟. 一种基于FPGA的高重复频率三维扫描激光雷达扫描角测量电路[P]. 北京市: CN107015215B, 2020-11-24.
[84]李小路, 徐立军, 李昀晔, 谢鑫浩. 一种基于自制地基激光雷达对准误差的点云误差校正方法[P]. 北京市: CN107703499B, 2020-11-24.
[85]孙江涛, 梁小凤, 徐立军, 田文斌, 谢跃东. 一种基于边缘场检测的二维EIT电极阵列结构优化方法[P]. 北京市: CN110840457B, 2020-11-13.
[86]徐立军, 常刘勇, 曹章, 郭宇东. 一种克服将钝体火焰脱火判定为稳态的贫燃熄火监测方法[P]. 北京市: CN109990278B, 2020-11-03.
[87]高硕, 黄安彪, 徐立军. 一种压力信号的校正方法及装置[P]. 北京市: CN110427126B, 2020-11-03.
[88]曹章, 邱爽, 徐立军, 黄昂, 杨亚如. 一种基于激光吸收光谱的温度快速提取方法[P]. 北京市: CN111089661B, 2020-11-03.
[89]曹章, 徐立军, 谢艺歆, 孙世杰, 蝴蝶, 黄昂. 一种基于压缩感知理论的宽频谱阻抗测量方法[P]. 北京市: CN107561367B, 2020-10-16.
[90]孙江涛, 徐立军, 梁小凤, 田文斌. 基于单层EIT电极边缘效应的膀胱体积测量方法[P]. 北京市: CN109498013B, 2020-10-09.
[91]李端, 李小路, 徐立军, 刘畅, 谢鑫浩. 一种基于接收端光纤色散的高光谱激光雷达系统[P]. 北京市: CN108398695B, 2020-10-02.
[92]曹章, 徐立军, 吉俐, 胡蝶, 何玉珠. 一种用于电学成像的多导体体系导纳矩阵快速计算方法[P]. 北京市: CN108376124B, 2020-09-29.
[93]徐立军, 陈健军, 曹章, 王友岭, 张文. 一种基于总流量与电导探针阵列信号的垂直井含水率测量方法[P]. 北京市: CN104989377B, 2020-09-25.
[94]徐立军, 曹章, 宋振源, 张宏宇, 刘怡, 解恒. 一种随机振动驱动衰荡腔免标定气体浓度测量系统[P]. 北京市: CN110672554B, 2020-09-25.
[95]曹章, 陈健军, 许国伟, 王友岭, 徐立军. 一种基于总流量与电导探针阵列信号的水平井流型识别方法[P]. 北京市: CN105003249B, 2020-09-25.
[96]徐立军, 李端, 李小路, 刘畅, 谢鑫浩. 一种基于光强分光的高光谱激光雷达系统[P]. 北京市: CN108415030B, 2020-08-28.
[97]李端, 徐立军, 李小路, 刘畅, 谢鑫浩. 一种基于光谱分光的高光谱全波形激光雷达系统[P]. 北京市: CN108415031B, 2020-08-28.
[98]孙世杰, 徐立军, 曹章, 黄昂, 何玉珠. 一种分程式并行结构电容阵列测量电路[P]. 北京市: CN108333434B, 2020-08-18.
[99]徐立军, 曲前伟, 曹章, 常刘勇. 一种基于激光吸收光谱层析成像技术的气流二维速度分布测量方法[P]. 北京市: CN109061220B, 2020-07-31.
[100]曹章, 邱爽, 徐立军, 侯广羽. 一种基于直方图信息的二维温度和浓度重建系统与方法[P]. 北京市: CN110514622B, 2020-07-31.
[101]徐立军, 曹章, 李远青, 邱爽. 一种基于干涉调制原理的激光吸收光谱测温方法和系统[P]. 北京市: CN108981953B, 2020-07-31.
[102]徐立军, 曲前伟, 曹章, 常刘勇. 一种基于激光吸收光谱层析成像技术的气流三维速度分布测量方法[P]. 北京市: CN109061221B, 2020-07-31.
[103]付博, 徐立军, 刘会生. 宽带波长可调色散管理型全光纤超快脉冲激光器及系统[P]. 北京市: CN109378694B, 2020-07-24.
[104]孙江涛, 徐立军, 陆方皞, 田文斌, 索鹏. 基于电阻抗层析成像的触觉压力传感器与信号采集方法[P]. 北京市: CN110207862B, 2020-07-03.
[105]田文斌, 孙江涛, 徐立军. 一种多模态传感器[P]. 北京市: CN110068583B, 2020-06-05.
[106]徐立军, 曹章, 汤晓阳, 高欣, 解恒. 一种基于扫描振镜的光学层析成像系统[P]. 北京市: CN107796333B, 2020-04-24.
[107]徐立军, 曹章, 冉辰浩, 张宏宇, 邱爽. 一种基于四角度激光吸收光谱的二维温度分布重建方法[P]. 北京市: CN108627272B, 2020-04-24.
[108]曹章, 徐立军, 叶桢, 解恒. 一种基于相位式激光测距的三维关联成像方法[P]. 北京市: CN107121682B, 2020-04-24.
[109]徐立军, 解恒, 曹章. 一种基于单光电探测器的颗粒粒度测量仪[P]. 北京市: CN107255608B, 2020-04-24.
[110]徐立军, 常刘勇, 曹章, 郭宇东. 一种基于声学激励的脉动式钝体绕流燃烧装置[P]. 北京市: CN109990279B, 2020-04-24.
[111]徐立军, 曹章, 杨阳, 刘畅, 曲前伟. 一种基于递推最小二乘法的激光吸收光谱谐波信号峰值点提取方法[P]. 北京市: CN105866068B, 2020-04-24.
[112]徐立军, 曹章, 郭宇东, 张宏宇. 一种基于交叠吸收谱的路径温度直方图测量系统与方法[P]. 北京市: CN108801496B, 2020-04-24.
[113]徐立军, 曹章, 陈亚婧, 邱爽, 郭宇东. 基于单光路多光谱的气体温度概率密度分布拟合重建方法[P]. 北京市: CN109100044B, 2020-04-24.
[114]曹章, 徐立军, 邱爽, 郭宇东, 陈亚婧. 基于单光路多光谱的气体温度概率密度分布重建方法[P]. 北京市: CN109100045B, 2020-04-24.
[115]李小路, 徐立军, 李昀晔, 谢鑫浩. 一种基于自制地基激光雷达垂直度误差的点云误差校正方法[P]. 北京市: CN107290734B, 2020-03-24.
[116]李小路, 徐立军, 李昀晔, 谢鑫浩. 一种基于自制地基激光雷达铅垂度误差的点云误差校正方法[P]. 北京市: CN107290735B, 2020-03-24.
[117]徐立军, 李端, 李小路, 谢鑫浩, 杨炳伟. 一种三维扫描全波形激光雷达系统[P]. 北京市: CN107272018B, 2020-02-14.
[118]曹章, 徐立军, 吉俐, 孙世杰, 黄昂. 一种由电流-电压映射构造电压-电流映射的方法[P]. 北京市: CN107091858B, 2020-02-14.
[119]李小路, 徐立军, 冯静, 刘畅. 一种结合激光雷达三维点云数据的相机自标定方法[P]. 北京市: CN107977997B, 2020-01-17.
[120]徐立军, 曹章, 冉辰浩, 李芳燕. 一种采用多角度直方图信息进行非均匀温度分布重建的方法[P]. 北京市: CN108955936B, 2019-12-24.
[121]曹章, 徐立军, 任宇罡, 汤晓阳, 解恒. 一种基于横向剪切干涉的玻璃板厚度分布测量方法及系统[P]. 北京市: CN109059787B, 2019-12-24.
[122]徐立军, 曹章, 陆方皞, 孙世杰, 黄昂. 一种用于解调含有高斯有色噪声信号的递推解调器[P]. 北京市: CN107505507B, 2019-10-01.
[123]曹章, 徐立军, 解恒. 一种基于光开关切换的激光光线偏折效应校正装置[P]. 北京市: CN107543620B, 2019-10-01.
[124]曹章, 徐立军, 常刘勇. 一种基于二向色分光的激光光线偏折校正装置[P]. 北京市: CN107560738B, 2019-10-01.
[125]曹章, 徐立军, 牛贺, 解恒. 一种基于闭环控制原理的粒径分布测量方法[P]. 北京市: CN107490531B, 2019-07-16.
[126]徐立军, 曹章, 李芳燕. 一种基于高频正弦校准光的激光光线偏折校正装置及方法[P]. 北京市: CN107505063B, 2019-07-12.
[127]徐立军, 曹章, 李芳燕. 一种基于调制锯齿波信号的激光光线偏折校正装置及方法[P]. 北京市: CN107560754B, 2019-07-12.
[128]徐立军, 曹章, 张文, 赵嘉宇. 一种基于最小均方根误差的水平井持水率测量方法[P]. 北京市: CN105971594B, 2019-02-01.
[129]曹章, 任迎, 徐立军, 孙世杰. 一种基于随机解调器的阻抗测量方法[P]. 北京市: CN105319445B, 2018-11-09.
[130]徐立军, 曹章, 张文, 赵嘉宇, 张文强. 一种基于双环电导探针阵列的水平井持水率测量方法[P]. 北京市: CN105574272B, 2018-11-06.
[131]徐立军, 孙世杰, 曹章, 刘翔宇. 一种多频信息滤波递推解调方法[P]. 北京市: CN105548711B, 2018-06-12.
[132]曹章, 徐立军, 孙世杰. 一种用于多源X射线成像的PID控制图像重建方法[P]. 北京市: CN105319228B, 2018-01-12.
[133]曹章, 陈健军, 徐立军, 张文, 赵嘉宇. 一种基于电导探针阵列信息融合的垂直井含水率测量方法[P]. 北京市: CN105064993B, 2018-01-09.
[134]徐立军, 陈健军, 曹章, 赵嘉宇, 王友岭. 一种基于电导探针阵列投票表决的垂直井流型识别方法[P]. 北京市: CN105114054B, 2018-01-09.
[135]徐立军, 徐文峰, 曹章, 陈健军, 王友岭. 一种基于电导探针的垂直井流型辨识方法[P]. 北京市: CN103967478B, 2017-10-27.
[136]曹章, 徐立军, 魏天啸, 周家怡, 辛蕾. 一种基于质心法的光斑图像中心的快速定位方法[P]. 北京市: CN103955687B, 2017-10-10.
[137]徐立军, 曹章, 曲前伟, 刘畅. 一种用于圆对称参数分布的双倍分辨率图像重建方法[P]. 北京市: CN104881887B, 2017-10-10.
[138]徐立军, 曹章, 魏天啸, 周家怡, 辛蕾. 一种基于导数法的光斑图像中心的快速定位方法[P]. 北京市: CN103927536B, 2017-07-18.
[139]徐立军, 陈健军, 曹章, 徐文峰, 王友岭. 一种用于多频信号遥测的LC并联谐振接收电路设计方法[P]. 北京市: CN104063557B, 2017-07-18.
[140]徐立军, 徐文峰, 曹章, 陈健军, 王友岭. 一种基于电导探针阵列和信息融合技术的水平井参数检测方法[P]. 北京市: CN103967477B, 2016-05-25.
[141]徐立军, 李端, 李小路, 孔德明, 马莲. 一种全光纤光路全波形激光雷达系统[P]. 北京市: CN103901435B, 2016-05-18.
[142]徐立军, 曹章, 魏天啸, 蔡小舒. 一种用于前向衍射光光强分布测量的对中装置及方法[P]. 北京市: CN103411859B, 2016-05-11.
[143]曹章, 徐立军, 黄驰, 孙世杰. 一种由电压-电流映射构造电流-电压映射的方法[P]. 北京市: CN103776873B, 2016-04-06.
[144]曹章, 徐立军, 辛蕾, 魏天啸. 一种光斑图像中心的快速定位方法[P]. 北京市: CN103093223B, 2016-03-02.
[145]曹章, 徐立军, 彭智聪, 宋伟. 一种基于欧拉公式的高精度正弦/余弦函数计算方法[P]. 北京市: CN103065039B, 2016-02-24.
[146]徐立军, 孔德明, 李小路, 李端. 一种基于K-plane算法的建筑物顶面点云数据分割方法[P]. 北京市: CN103020637B, 2016-01-27.
[147]曹章, 徐立军, 周家怡, 魏天啸. 一种基于液晶屏光调制的图像采样方法[P]. 北京市: CN103871387B, 2016-01-06.
[148]徐立军, 曹章, 刘畅, 蔡小舒. 一种采用双路可调谐激光吸收光谱技术的归一化降噪方法[P]. 北京市: CN103411923B, 2015-11-18.
[149]曹章, 刘畅, 徐立军, 孙世杰. 一种基于虚拟数据的轴对称参数分布图像重建方法[P]. 北京市: CN103047946B, 2015-11-04.
[150]李小路, 徐立军, 李端, 孔德明, 马莲. 一种基于同轴双通道数据采集的全波形激光雷达系统[P]. 北京市: CN103576134B, 2015-10-07.
[151]曹章, 徐立军, 孙世杰, 黄驰. 一种基于二端子激励测量模式的电压-电流映射构造方法[P]. 北京市: CN103149472B, 2015-07-22.
[152]徐立军, 孙世杰, 曹章. 一种基于相邻激励测量模式的电流-电压映射构造方法[P]. 北京市: CN103163404B, 2015-07-15.
[153]李小路, 徐立军, 马莲. 一种全波形激光雷达系统[P]. 北京市: CN103197321B, 2015-07-15.
[154]徐立军, 徐文峰. 一种基于电导探针阵列传感器的水平井多参数估计方法[P]. 北京市: CN103277084B, 2015-07-15.
[155]曹章, 孙世杰, 徐立军, 黄驰. 一种基于相邻激励测量模式的电压-电流映射构造方法[P]. 北京市: CN103116101B, 2015-07-01.
[156]曹章, 徐立军, 孙世杰, 王海刚. 一种用于电学层析成像系统的信息滤波解调方法[P]. 北京市: CN103412189B, 2015-07-01.
[157]曹章, 陈健军, 周海力, 徐立军, 蒋昌华. 一种基于二端子阻抗测量模式的四端子电阻抗层析成像方法[P]. 北京市: CN103018284B, 2015-05-13.
[158]徐立军, 李小路, 成艳亭, 陈路路. 一种通过图像分割修正表面发射率的红外热成像测温方法[P]. 北京市: CN103196564B, 2015-04-29.
[159]徐立军, 陈健军, 徐文峰, 曹章, 蒋昌华. 一种基于遗传算法的多环电极阵列传感器结构优化方法[P]. 北京市: CN103015981B, 2015-03-25.
[160]李小路, 徐立军, 陈路路, 成艳亭. 一种基于图像拼接的空冷凝汽器散热面温度场测量方法[P]. 北京市: CN103217221B, 2015-03-11.
[161]徐立军, 曹章, 刘畅, 陈露露. 一种基于轴对称参数分布的图像重建方法[P]. 北京市: CN103021005B, 2015-01-21.
[162]曹章, 徐立军, 刘畅, 辛蕾. 一种采用单一光电探测器的激光光强分布精确测量系统[P]. 北京市: CN103090966B, 2015-01-21.
[163]李小路, 徐立军, 马莲. 一种基于遗传算法的全波形激光雷达回波数据的高斯分解法[P]. 北京市: CN103217679B, 2014-10-08.
[164]徐立军, 孔德明, 李小路. 一种对原始数据低失真的谐波噪声干扰和白噪声干扰的去除方法[P]. 北京市: CN102624349B, 2014-09-17.
[165]曹章, 周海力, 徐立军, 曾轶. 一种用于电学层析成像系统的多频递推解调方法[P]. 北京市: CN102570984B, 2014-08-06.
[166]徐立军, 曹章, 刘雨佳, 张玉枚. 一种用于渡越时间测量的自适应相关算法[P]. 北京市: CN102645552B, 2014-06-25.
[167]徐立军, 李小路, 孔德明, 李端. 一种激光雷达实时成像和建筑物特征提取的方法[P]. 北京市: CN103018728B, 2014-06-18.
[168]徐立军, 陈健军, 曹章, 胡金海, 刘兴斌. 一种曼彻斯特码井下长距离传输装置及方法[P]. 北京市: CN102843166B, 2014-05-28.
[169]徐立军, 周海力, 曹章, 曾轶. 一种用于电学层析成像系统的递推解调方法[P]. 北京市: CN102565541B, 2014-01-15.
[170]徐立军, 田祥瑞, 李小路, 王建军, 张超曾. 一种机载激光雷达侧滚角偏差补偿方法[P]. 北京市: CN102508221B, 2013-09-04.
[171]徐立军, 曹章, 徐文峰, 陈健军, 刘兴斌, 马水龙, 胡金海. 一种环形持水率测井传感器阵列的结构优化方法[P]. 北京市: CN102011575B, 2013-05-08.
[172]徐立军, 王建军, 李小路, 郜蕾. 一种用于机载激光雷达俯仰角偏差实时补偿的方法与装置[P]. 北京市: CN101865996B, 2013-03-27.
[173]徐立军, 王建军, 李小路, 田祥瑞. 一种用于机载激光雷达滚动角偏差实时补偿的方法与装置[P]. 北京市: CN101900806B, 2013-03-27.
[174]徐立军, 王建军, 李小路, 张超曾. 一种机载激光雷达激光发射指向扰动的补偿装置及方法[P]. 北京市: CN102426355B, 2013-02-13.
[175]徐立军, 田祥瑞, 李小路, 王建军. 一种机载激光雷达航测参数的优化设计方法[P]. 北京市: CN102176003B, 2012-11-21.
[176]徐立军, 陈健军, 曹章. 一种基于阻抗测量的多通道植物缺水监测系统[P]. 北京市: CN101666767B, 2012-11-21.
[177]徐立军, 曹章, 凌琪, 范士伟. 一种基于管内磁场仿真数值计算的电磁流量计干标定方法[P]. 北京市: CN101750136B, 2012-07-25.
[178]徐立军, 徐文峰, 曹章, 周海力, 刘兴斌, 胡金海. 一种多环电极阵列成像传感器[P]. 北京市: CN101793852B, 2012-07-25.
[179]徐立军, 曹章, 范士伟, 凌琪. 一种可用于非满管流量测量的电容式电磁流量计[P]. 北京市: CN101701836B, 2012-07-04.
[180]徐立军, 周婉露, 李小路, 田祥瑞. 一种提高机载平台定姿精度的在线快速方法[P]. 北京市: CN101793517B, 2012-05-23.
[181]徐立军, 范士伟, 曹章. 一种可用于非满管流量测量的电磁流量计[P]. 北京市: CN101699226B, 2012-03-21.
[182]徐立军, 谭丞, 李小路. 一种基于多元火焰监测器的燃料种类在线判别方法[P]. 北京市: CN101692270B, 2011-12-07.
[183]曹章, 徐立军, 丁洁. 一种基于圆形传感器的电容层析成像的图像重建直接方法[P]. 北京市: CN101520478B, 2011-08-17.
[184]李小路, 徐立军, 田祥瑞, 谭丞. 一种基于光学补偿设计的火焰温度场和燃烧中间产物浓度场监测系统[P]. 北京市: CN101625270B, 2011-08-17.
[185]曹章, 徐立军, 丁洁. 一种粒径测量的有限分布积分反演算法[P]. 北京市: CN101793665B, 2011-07-27.
[186]徐立军, 李小路, 谭丞. 一种基于支持向量机的燃料种类在线识别方法[P]. 北京市: CN101701951B, 2011-07-27.
[187]徐立军, 谭丞, 曹章. 一种新燃料在线识别方法[P]. 北京市: CN101644699B, 2011-06-01.
[188]徐立军, 谭丞. 双元火焰监测器[P]. 北京市: CN101408313B, 2011-05-04.
[189]曹章, 徐立军, 丁洁. 一种粒径测量的积分反演算方法[P]. 北京市: CN101430268B, 2011-04-13.
[190]徐立军, 李小路, 谭丞, 田祥瑞. 一种同时监测燃烧火焰温度场和中间产物浓度二维分布的方法[P]. 北京市: CN101625269B, 2010-12-01.
 论文专著:
发表英文部分论文:
[1]Xie, Xinhao; Xu, Lijun; Li, Xiaolu*; Li, Duan.Time-Division-Multiplexed Online Gauss-Newton-Based Multi-Echo Decomposition Method for Real-Time In-Situ Laser Ranging.IEEE Sensors Journal, 2022, 22(5): 4152-4163.
[2]Bai, Xu; Sun, Jiangtao*; Bai, Xue; Sun, Shijie; Xu, Lijun.A Modified Noise Model of Electrical Impedance Tomography System by Considering Colored Noises.IEEE Transactions on Instrumentation and Measurement, 2022, 71: 1001910.
[3]Gao, Xin; Cao, Zhang*; Li, Hongyao; Lu, Fanghao; Huang, Ang; Xu, Lijun.Sparse Zernike Fitting for Dynamic LAS Tomographic Images of Temperature and Water Vapor Concentration.IEEE Transactions on Instrumentation and Measurement, 2022, 71: 5009314.
[4]Ma, Xiangdong; Fan, Mengzhi; Cai, Yiqi; Xu, Lijun; Ma, Jianguo*.A FabryPerot Fiber-Optic Array for Photoacoustic Imaging.IEEE Transactions on Instrumentation and Measurement, 2022, 71: 4501508.
[5]Zhang, Xiaokai; Sun, Jiangtao*; Hu, Jinhai; Liu, Xiaolei; Liu, Xingbin; Xie, Ronghua; Cai, Bing; Sun, Liang; Xu, Lijun*.A Modified Adaptive Cross Correlation Method for Flow Rate Measurement of High-Water-Cut Oil-Water Flow Using Planar Flowmeter.IEEE Transactions on Instrumentation and Measurement, 2022, 71: 9500210.
[6]Liu, Chang; Li, Xiaolu*; Huang, Jianbin; Xu, Lijun.B-Spline Based Progressive Decomposition of LiDAR Waveform With Low SNR.IEEE Transactions on Instrumentation and Measurement, 2022, 71: 8501812.
[7]Xie, Yuedong; Li, Jiyao; Huang, Pu; Zhang, Le; Tian, Wenbin*; Lu, Mingyang*; Zhao, Xin; Huo, Zhilin; Liu, Zenghua; Wang, Shupei; Huang, Ruochen; Yin, Wuliang; Peyton, Anthony; Xu, Lijun.A novel design of window function modulated meander-line-coils EMATs for unidirectional Rayleigh waves generation and sidelobes suppression.NDT & E International, 2021, 123: 102501.
[8]Guo, Jingjing*; Zhou, Bingqian; Du, Zhou; Yang, Changxi; Kong, Lingjie*; Xu, Lijun.Soft and plasmonic hydrogel optical probe for glucose monitoring.Nanophotonics, 2021, 10(13): 3549-3558.
[9]Li, Xiaolu; Zhang, Zhixin; Xie, Xinhao; Xu, Lijun; Li, Duan*.A multi-target on-line ranging method based on matrix sparsification and a division-free Gauss-Jordan solver.Measurement Science and Technology, 2021, 32(9): 095207.
[10]Xie, Heng; Xu, Lijun*; Tan, Yutian; Hou, Guangyu; Cao, Zhang*.Ultra-Low Sampled and High Precision TDLAS Thermometry Via Artificial Neural Network.IEEE Photonics Journal, 2021, 13(3): 1-9.
[11]Wang, Zining; Xu, Lijun; Li, Duan*; Zhang, Zhixin; Li, Xiaolu.Online Multi-Target Laser Ranging Using Waveform Decomposition on FPGA.IEEE Sensors Journal, 2021, 21(9): 10879-10889.
[12]Wang, Xiao-Hong; Bi, Zheng; Dong, Xiang; Hu, Sen-Yuan; Xu, Li-jun; Cheng, Cheng-Kung*.Increasing the height of the anterior lip on a tibial insert in a posterior stabilized knee prosthesis has little effect on the wear rate.Medical Engineering & Physics, 2021, 91: 48-53.
[13]Lu, Fanghao; Cao, Zhang*; Xie, Yixin; Xu, Lijun.Precise wide-band electrical impedance spectroscopy measurement via an ADC operated below the Nyquist sampling rate.Measurement, 2021, 174: 108995.
[14]Zhu, Hai; Sun, Jiangtao; Long, Jun; Tian, Wenbin*; Sun, Shijie; Xu, Lijun.Deep Image Refinement Method by Hybrid Training With Images of Varied Quality in Electrical Capacitance Tomography.IEEE Sensors Journal, 2021, 21(5): 6342-6355.
[15]Xie, Xinhao; Li, Xiaolu; Li, Duan*; Xu, Lijun.Real-Time In-Situ Laser Ranging via Back Propagation Neural Network on FPGA.IEEE Sensors Journal, 2021, 21(4): 4664-4673.
[16]Gao, Shuo*; Chen, Jun-Liang; Dai, Yan-Ning; Wang, Rui; Kang, Shuai-Bo; Xu, Li-Jun.Piezoelectric-Based Insole Force Sensing for Gait Analysis in the Internet of Health Things.IEEE Consumer Electronics Magazine, 2021, 10(1): 39-44.
[17]Liao, Shaolin*; Ou, Lu; Xu, Lijun.Super-Resolution Ultrasound Lamb Wave NDE Imaging of Anisotropic Airplane Laminates via Deconvolutional Neural Network.IEEE Transactions on Instrumentation and Measurement, 2021, 70: 4500508.
[18]Tian, Yu; Cao, Zhang*; Hu, Die; Gao, Xin; Xu, Lijun; Yang, Wuqiang.A Fuzzy PID-Controlled Iterative Calderon's Method for Binary Distribution in Electrical Capacitance Tomography.IEEE Transactions on Instrumentation and Measurement, 2021, 70: 4502911.
[19]Sun, Shijie; Lu, Xupeng; Xu, Lijun*; Cao, Zhang; Sun, Jiangtao; Yang, Wuqiang.Real-Time 3-D Imaging and Velocity Measurement of Two-Phase Flow Using a Twin-Plane ECT Sensor.IEEE Transactions on Instrumentation and Measurement, 2021, 70.
[20]Huang, Ang; Cao, Zhang*; Wang, Chenran; Wen, Jinting; Lu, Fanghao; Xu, Lijun.An FPGA-Based On-Chip Neural Network for TDLAS Tomography in Dynamic Flames.IEEE Transactions on Instrumentation and Measurement, 2021, 70: 4506911.
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[22]Tang, Xiaoyang; Cao, Zhang*; Wang, Zhonghong; Xie, Heng; Xu, Lijun*.Retrieval of Phase and Temperature Distributions in Axisymmetric Flames From Phase-Modulated Large Lateral Shearing Interferogram.IEEE Transactions on Instrumentation and Measurement, 2021, 70.
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[138]Zhang Cao*; Lijun Xu.Direct recovery of the electrical admittivities in 2D electrical tomography by using Calderon's method and two-terminal/electrode excitation strategies.Measurement Science and Technology, 2013, 24(7): 74007.
[139]Zhongbao Wei; Xiaolu Li; Lijun Xu*; Yanting Cheng.Comparative study of computational intelligence approaches for NOx reduction of coal-fired boiler.Energy, 2013, 55: 683-692.
[140]Cao, Z; LI JUN XU*.2Dimage reconstruction of a human chest by using Calderon’s method and theadjacent current pattern.Journal of Instrumentation, 2013, 8.
[141]Zhang Cao*; Lijun Xu.Direct image reconstruction for 3-D electrical resistance tomography by using the factorization method and electrodes on a single plane.IEEE Transactions on Instrumentation and Measurement, 2013, 62(5): 999-1007.
[142]Lijun Xu*; Haili Zhou; Zhang Cao; Wuqiang Yang.A Digital Switching Demodulator for Electrical Capacitance Tomography.IEEE Transactions on Instrumentation and Measurement, 2013, 62(5): 1025-1033.
[143]Lijun Xu*; Chang Liu; Zhang Cao; Xiaomin Li.Particle size influence on effective permittivity of particle-gas mixture with particle clusters.Particuology, 2013, 11(2): 216-224.
[144]Lijun Xu*; Haili Zhou; Zhang Cao.A recursive least squares-based demodulator for electrical tomography.Review of Scientific Instruments, 2013, 84(4): 44704.
[145]Cao, Z.*; Xu, L.2D image reconstruction of a human chest by using Calderon's method and the adjacent current pattern.Journal of Instrumentation, 2013, 8: P03004.
[146]Xu, Wenfeng; Xu, Lijun*; Cao, Zhang; Chen, Jianjun; Liu, Xingbin; Hu, Jinhai.Normalized least-square method for water hold-up measurement in stratified oil-water flow.Flow Measurement and Instrumentation, 2012, 27: 71-80.
[147]Wang, Jianjun; Xu, Lijun*; Li, Xiaolu; Quan, Zhongyi.Quantitative Evaluation of Impacts of Random Errors on ALS Accuracy Using Multiple Linear Regression Method.IEEE Transactions on Instrumentation and Measurement, 2012, 61(8): 2242-2252.
[148]Lijun Xu*; Xiaolu Li; Xiangrui Tian; Deming Kong.Terrain slope estimation within footprint from ICESat/GLAS waveform: model and method.Journal of Applied Remote Sensing, 2012, 6: 1-10.
[149]Wei, Zhongbao; Li, Xiaolu; Xu, Lijun*; Tan, Cheng.Optimization of Operating Parameters for Low NOx Emission in High-Temperature Air Combustion.Energy & Fuels, 2012, 26(5): 2821-2829.
[150]Lijun Xu*; Lei Xin; Zhang Cao.l(1)-norm-based reconstruction algorithm for particle sizing.IEEE Transactions on Instrumentation and Measurement, 2012, 61(5): 1395-1404.
[151]Xu, Lijun*; Zhou, Wanlu; Li, Xiaomin.Wet gas flow modeling for a vertically mounted Venturi meter.Measurement Science and Technology, 2012, 23(4): 045301.
[152]Haili Zhou; Lijun Xu*; Zhang Cao; Jinhai Hu; Xingbin Liu.Image reconstruction for invasive ERT in vertical oil well logging.Chinese Journal of Chemical Engineering, 2012, 20(2): 319-328.
[153]Xu, Lijun; Tan, Cheng; Li, Xiaomin*; Cheng, Yanting; Li, Xiaolu.Fuel-Type Identification Using Joint Probability Density Arbiter and Soft-Computing Techniques.IEEE Transactions on Instrumentation and Measurement, 2012, 61(2): 286-296.
[154]Xu, L.*; Wang, Q.; Li, W.; Hou, Y. Stability analysis and stabilisation of full-envelope networked flight control systems: switched system approach.IET Control Theory and Applications, 2012, 6(2): 286-296.
[155]Tan, Cheng; Xu, Lijun; Li, Xiaomin*; Yan, Yong.Independent component analysis-based fuel type identification for coal-fired power plants.Combustion Science and Technology, 2012, 184(3): 277-292.
[156]Lijun Xu; Lei Xin; Zhang Cao.ℓ1-norm based reconstruction algorithm for particle sizing.IEEE Transactions on Instrumentation and Measurement, 2012, 61.
[157]Xu, Lijun*; Tian, Xiangrui; Li, Xiaolu; Shang, Guangyi; Yao, Junen.Geometric distortion correction for sinusoidally scanned images.Measurement Science and Technology, 2011, 22(11): 114023.
[158]Cao, Zhang; Xu, Lijun*; Fang, Wenru; Wang, Huaxiang.2D electrical capacitance tomography with sensors of non-circular cross sections using the factorization method.Measurement Science and Technology, 2011, 22(11): 114003.
[159]Takei, Masahiro*; Xu, Lijun.Sixth World Congress on Industrial Process Tomography (WCIPT6).Measurement Science and Technology, 2011, 22(10): 100101.
[160]Cao, Zhang; Xu, Lijun*.Direct image reconstruction for electrical capacitance tomography by using the enclosure method.Measurement Science and Technology, 2011, 22(10): 104001.
[161]Xu, Lijun; Zhou, Wanlu; Li, Xiaomin*; Wang, Minghao.Wet-Gas Flow Modeling for the Straight Section of Throat-Extended Venturi Meter.IEEE Transactions on Instrumentation and Measurement, 2011, 60(6): 2080-2087.
[162]Xu, Lijun*; Zhou, Wanlu; Li, Xiaomin; Tang, Shaliang.Wet Gas Metering Using a Revised Venturi Meter and Soft-Computing Approximation Techniques.IEEE Transactions on Instrumentation and Measurement, 2011, 60(3): 947-956.
[163]Cao, Zhang*; Xu, Lijun; Fan, Wenru; Wang, Huaxiang.Electrical Capacitance Tomography for Sensors of Square Cross Sections Using Calderon's Method.IEEE Transactions on Instrumentation and Measurement, 2011, 60(3): 900-907.
[164]Wang Jianjun; Xu Lijun; Li Xiaolu; Tian Xiangrui.Impact of attitude deviations on laser point cloud of airborne LiDAR.仪器仪表学报, 2011, 32(8).
[165]Zhang Z; Ruan NJ; Zhou F; Zhijun Liu; Lijun Xu.High power continuous wave Tm:YAP laser dual-end-pumped by laser diode at 795 nm.Laser Physics, 2011, 21(6): 1078-1080.
[166]Cao, Zhang*; Xu, Lijun; Fan, Wenru; Wang, Huaxiang.Electrical capacitance tomography with a non-circular sensor using the dbar method.Measurement Science and Technology, 2010, 21(1): 015502.
[167]Tan Cheng; Li Xiaomin; Xu Lijun; Zhang Qi.On-line identification of new fuel type using joint probability density arbiter.仪器仪表学报, 2010, 31(6).
[168]Zhou Wanlu; Xu Lijun.Modeling of wet gas flow in Vertically mounted Venturi meter.仪器仪表学报, 2010, 31(5).
[169]Xu, Lijun; Tan, Cheng; Li, Xiaomin; Li, Xiaolu.On-line Identification of Fuel Type Using Joint Probability Density Arbiter and Support Vector Machine Techniques
[170]Zhou, Wanlu; Xu, Lijun; Li, Xiaomin.Wet gas flow modeling for the straight section of throat-extended Venturi meter
[171]Zhang Cao; Lijun Xu; Huaxiang Wang.Electrical capacitance tomography with a non-circular sensor using the dbar method.Measurement Science and Technology, 2009, 21(1): 15502-15502.
[172]Cao, Zhang; Xu, Lijun; Wang, Huaxiang.Image reconstruction technique of electrical capacitance tomography for low-contrast dielectrics using Calderon's method.Measurement Science and Technology, 2009, 20(10): 104027.
[173]Zhang Cao; Lijun Xu; Jie Ding.Integral inversion to Fraunhofer diffraction for particle sizing.Applied Optics, 2009, 48(25): 4842-4850.
[174]Lijun Xu*; Xiaomin Li.Dual-channel pseudorandom sequence generator with precise time delay between its two channels.IEEE Transactions on Instrumentation and Measurement, 2008, 57(12): 2880-2884.
[175]Cao, Zhang; Wang, Huaxiang; Xu, Lijun*.Electrical impedance tomography with an optimized calculable square sensor.Review of Scientific Instruments, 2008, 79(10): 103710.
[176]Xiaomin Li; Lijun Xu; Songyun Li.Experimental Study on Size-Dependency of Effective Permittivity of Particle-Gas Mixture with Agglomeration.Chinese Journal of Scientific Instrument, 2007, 28(11): 1932-1936.
[177]Lijun Xu*; Yong Yan.An improved algorithm, for the measurement of flame oscillation frequency.IEEE Transactions on Instrumentation and Measurement, 2007, 56(5): 2087-2093.
[178]Yan, Yong*; Xu, Lijun; Lee, Peter.Mass flow measurement of fine particles in a pneumatic suspension using electrostatic sensing and neural network techniques.IEEE Transactions on Instrumentation and Measurement, 2006, 55(6): 2330-2334.
[179]Xu, Lijun*; Yan, Yong.A new flame monitor with triple photovoltaic cells.IEEE Transactions on Instrumentation and Measurement, 2006, 55(4): 1416-1421.
[180]David Melodelima, Jeffrey C. Bamber, Francis A. Duck, Jacqueline A. Shipley, Lijun Xu, Elastography for breast cancer diagnosis using radiation force: System development and performance evaluation, Ultrasound in Medicine and Biology, vol. 32, no. 3, pp. 387-396, March 2006.
[181]Feng Dong; Yanbin Xu; Lijun Xu; Lei Hua; Xutong Qiao.Application of dual-plane ERT system and cross-correlation technique to measure gas-liquid flows in vertical upward pipe.Flow Measurement and Instrumentation, 2005, 16(2-3): 191-197.
[182]Lijun Xu.Cancellation of harmonic interference by baseline shifting of wavelet packet decomposition coefficients.IEEE Trans. Signal Processing, 2005, 53(1): 222-230.
[183Feng Dong; Yanbin Xu; Xutong Qiao; Lijun Xu; Ling-an Xu.Void fraction measurement for two-phase flow using electrical resistance tomography.Canadian Journal of Chemical Engineering, 2005, 83(1): 19-23.
[184]Lijun Xu; Yong Yan; Steve Cornwell; Gerry Riley.On-line fuel tracking by combining principal component analysis and neural network techniques.IEEE Transactions on Instrumentation and Measurement, 2005, 54(4): 1640-1645.
[185]Lijun Xu; Jun Han; Ya Wang.Design of electrode array of inductance flowmeter.IEEE Sensors Journal, 2005, 5(5): 929-933.
[186]Lijun Xu; Jian Qiu Zhang; Yong Yan.A wavelet-based multi-sensor data fusion algorithm.IEEE Transactions on Instrumentation and Measurement, 2004, 53(6): 1539-1545.
[187]Lijun Xu; Yong Yan.Wavelet-based Removal of Sinusoidal Interference from a Signal.Measurement Science and Technology, 2004, 15(9): 1779-1786.
[188]Lijun Xu; Ya Wang; Feng Dong.On-line monitoring of nonaxisymmetric flow profile with a multielectrode inductance flowmeter.IEEE Transactions on Instrumentation and Measurement, 2004, 53(4): 1321-1326.
[189]Lijun Xu; Yong Yan; Steve Cornwell; Gerry Riley.On-Line Fuel Identification Using Digital Signal Processing and Fuzzy Inference Techniques.IEEE Transactions on Instrumentation and Measurement, 2004, 53(4): 1316-1320.
[190]Lijun Xu; Jian Xu; Feng Dong; Tao Zhang.On fluctuation of the dynamic differential pressure signal of Venturi meter for wet gas metering.Flow Measurement and Instrumentation, 2003, 14(4-5): 211-217.
[191]Lijun Xu; Xiaomin Li; Feng Dong; Y. Wang; L. A. Xu.Optimum estimation of the mean flow velocity for the multi-electrode inductance flowmeter.Measurement Science and Technology, 2001, 12(8): 1139-1146.
[192]Feng Dong; Xiaoping Liu; Xiang Deng; Lijun Xu; Ling-an Xu.Identification of two-phase flow regimes in horizontal, inclined and vertical pipes.Measurement Science and Technology, 2001, 12(8): 1069-1075.
[193]X. Deng; Feng Dong; Lijun Xu; X. P. Liu; L. A. Xu.The design of a dual-plane ERT system for cross correlation measurement of bubbly gas/liquid pipe flow.Measurement Science and Technology, 2001, 12(8): 1024-1031.
[194]A. Weber; Lijun Xu; G. Kasper.Simultaneous in situ measurement of size, charge and velocity of single aerosol particles.Journal of Aerosol Science, 2000, 31: 1015-1016.
[195]Lijun Xu; A. Weber; G. Kasper.Capacitance-based concentration measurement for gas-particle system with low particles loading.Flow Measurement and Instrumentation, 2000, 11(3): 185-194.
[196]Lijun Xu; YT Han; YS Yang; LA Xu.Application of ultrasonic tomography to monitoring gas/liquid flow.Chemical Engineering Science, 1997, 52(13): 2171-2183.
[197]Lijun Xu; L. A. Xu.Ultrasound tomography system used for monitoring bubbly gas/liquid two-phase flow.IEEE Trans. on Ultrasonics, Ferroelectrics, and Frequency Control, 1997, 44(1): 67-76.
[198]J. S. Yang; Lijun Xu; C. Y. Xing; G. Yang.Finite element-artificial transmitting boundary method for wave scattering from irregular cylinder.Trans. of Tianjin University, 1997, 3(2): 128-131.
[199]Lijun Xu; L. A. Xu.Gas/liquid two-phase flow regime identification by ultrasonic tomography.Flow Measurement and Instrumentation, 1997, 8(3-4): 145-155.
[200]Fu, Bo; Zhang, Chenghong; Lyu, Wenhao; Sun, Jingxuan; Shang, Ce; Cheng, Yuan; Xu, Lijun*.Recent progress on laser absorption spectroscopy for determination of gaseous chemical species.Applied Spectroscopy Reviews.
发表中文期刊论文:
[1]郭晶晶, 郭校言, 脱佳霖, 李卓洲, 徐立军. 柔性有机聚合物光子器件及其生物医学应用[J]. 激光与光电子学进展, 2023, 60 (13): 33-51.
[2]马向东, 徐立军, 马建国. 用于超声成像的阵列式光纤传感系统研究[J]. 国外电子测量技术, 2023, 42 (04): 74-79.
[3]曹章, 高欣, 陆方皞, 徐立军. 激光吸收光谱层析成像及复杂燃烧场动态监测[J]. 中国激光, 2022, 49 (19): 117-138.
[4]付博, 赵小丽, 张晗, 徐立军. 激光技术在血栓消融中的应用与进展[J]. 中国激光, 2022, 49 (19): 207-218.
[5]李小路, 周依尔, 毕腾飞, 余瑞钦, 王子宁, 黄建斌, 徐立军. 轻量型感知激光雷达关键技术发展综述[J]. 中国激光, 2022, 49 (19): 263-277.
[6]徐立军, 刘福禄, 丁一清, 李正勇, 谢跃东. 基于电磁超声横波的管道剩余厚度检测[J]. 北京航空航天大学学报, 2022, 48 (09): 1767-1773.
[7]李小路, 张艺龄, 徐立军. 研究生国际化培养实施情况调研分析[J]. 教育教学论坛, 2022, (11): 1-4.
[8]车汉桥, 王海刚, 徐立军. 制药流化床湿式制粒过程CFD-DEM建模:方法及挑战[J]. 工程热物理学报, 2021, 42 (11): 2885-2892.
[9]李效霖, 孙江涛*, 田文斌, 龙军, 刘旭辉, 徐立军. 微小卫星液化推进剂气化过程可视化检测方法[J]. 空间控制技术与应用, 2021, 47 (04): 93-102.
[10]李小路, 徐立军, 李端, 张艺龄. 大学课程中的学术规范化教育与新思路——以本科核心通识课为例[J]. 教育教学论坛, 2021, (24): 17-20.
[11]周相坡, 周依尔, 徐立军, 李小路. 一种基于概率路线图的月球巡航车路径规划算法[J]. 空间控制技术与应用, 2020, 46 (06): 43-49+78.
[12]呼延嘉玥,徐立军,李小路.自研激光雷达三维点云配准技术[J].北京航空航天大学学报,2019,45(10):2099-2107.
[13]李小路,曾晶晶,王皓,徐立军.三维扫描激光雷达系统设计及实时成像技术[J].红外与激光工程,2019,48(05):35-42.
[14]谢艺歆,曹章,孙世杰,徐立军.基于压缩感知的扫频阻抗测量方法及硬件实现[J].电子测量技术,2018,41(16):108-112.
[15]陈亚婧,邱爽,徐立军.多谱线TDLAS测温中谱线选择的实验研究[J].电子测量与仪器学报,2017,31(12):1948-1952.
[16]李小路,李昀晔,谢鑫浩,徐立军.基于叶片含水量的激光偏振成像模型研究[J].红外与激光工程,2017,46(11):121-126.
[17]杨阳,刘畅,徐立军.基于波长调制谐波信号主峰拟合的气体浓度测量方法[J].北京航空航天大学学报,2017,43(11):2187-2192.
[18]王雪松,戴琼海,焦李成,洪文,徐立军,邢孟道,冯德军,陈思伟,代大海.高性能探测成像与识别的研究进展及展望[J].中国科学:信息科学,2016,46(09):1211-1235.
[19]田祥瑞,徐立军,徐腾,李小路,张勤拓.车载LiDAR扫描系统安置误差角检校[J].红外与激光工程,2014,43(10):3292-3297.
[20]马莲,李小路,徐腾,徐立军,冯显宗.一种基于重复轨道高程数据的坡度估计算法[J].武汉大学学报(信息科学版),2014,39(09):1121-1127.
[21]陈路路,李小路,贺涛,徐立军.基于图像拼接的空冷凝汽器散热面温度场测量[J].光学学报,2013,33(11):98-103.
[22]靖丽丽,徐立军,李小路,田祥瑞,潘亮.SURF算法在航摄图像导航中的应用[J].武汉大学学报(工学版),2013,46(05):621-625.
[23]孙绪彬,徐立军,王宏,董海荣.射流火焰温度场广义随机分布模型的迭代学习控制[J].北京理工大学学报,2013,33(05):523-528.
[24]周海力,徐立军,曹章,胡金海,刘兴斌.用于竖直油井测井的侵入式电阻层析成像图像重建(英文)[J].Chinese Journal of Chemical Engineering,2012,20(02):319-328.
[25]李小路,徐立军,田祥瑞,王建军.平台运动误差对机载LiDAR激光脚点分布的影响分析[J].武汉大学学报(信息科学版),2011,36(11):1270-1274+1279.
[26]王建军,徐立军,李小路,田祥瑞.姿态角扰动对机载激光雷达点云数据的影响[J].仪器仪表学报,2011,32(08):1810-1817.
[27]王建军,徐立军,李小路.姿态角随机测量误差对机载激光扫描成像的影响[J].中国激光,2011,38(03):225-233.
[28]谭丞,李晓敏,徐立军,吴煜婷.基于联合概率密度判别器和神经网络技术的煤种辨识方法[J].机械工程学报,2010,46(18):18-23.
[29]谭丞,李晓敏,徐立军,张琦.一种基于联合概率密度判别器的新煤种在线辨识方法[J].仪器仪表学报,2010,31(06):1229-1234.
[30]周婉露,徐立军.垂直安装文丘里管湿气测量模型研究[J].仪器仪表学报,2010,31(05):1120-1125.
[31]徐立军,李小路,曹章.《信号分析与处理》双语教学的探索[J].教育教学论坛,2010(06):20-22.
[32]谭丞,徐立军,曹章.煤燃烧过程监测与诊断技术的发展与应用[J].工程研究-跨科学视野中的工程,2009,1(02):111-118.
[33]徐立军,李松云,龚立艳,商广义,姚骏恩.原子力显微镜图像小波去噪方法的研究[J].电子显微学报,2009,28(02):135-140.
[34]龚立艳,徐立军,钱建强,姚骏恩.原子力显微镜图像降噪与平面校正的同步实现[J].高技术通讯,2008,18(07):725-731.
[35]张博,王陶,徐立军,闫勇.粉料气力输送状态在线监测装置研究[J].仪器仪表学报,2007(11):1999-2002.
[36]徐立军,王亚,姜印平,徐苓安.电磁流量计电场动态平衡过程分析[J].仪器仪表学报,2004(01):39-43.
[37]许燕斌,董峰,王文辉,徐立军.基于RS-485的多电极电磁流量计的远程监控[J].自动化仪表,2004(01):17-20.
[38]许燕斌,董峰,徐立军.ERT数据采集系统通讯模块的设计[J].仪器仪表学报,2003(S2):706-708.
[39]徐立军,王亚,乔旭彤,徐苓安.多对电极电磁流量计传感器电极阵列设计[J].仪器仪表学报,2003(04):335-339.
[40]李鹏,徐立军,董峰.非牛顿液体粘度的在线测量方法[J].天津大学学报,2003(02):169-173.
[41]许建,徐立军,董峰,张涛.气液两相流动态差压信号分析[J].仪器仪表学报,2002(S2):509-510.
[42]姜之旭,董峰,徐立军,徐苓安.基于神经网络的水平管中气/液两相流流型识别[J].仪器仪表学报,2002(S2):511-512.
[43]郑兆敏,姜常珍,孙永进,徐立军.电阻层析成像均匀场域的建立方法[J].仪器仪表学报,2002(S2):660-661.
[44]乔旭彤,徐立军,董峰.多电极电磁流量计励磁线圈的优化与设计[J].仪器仪表学报,2002(S2):867-869.
[45]李鹏,徐立军,姜印平.基于电磁感应的液体粘度在线测量方法研究[J].仪器仪表学报,2002(S2):870-872.
[46]张涛,李香平,徐立军.智能控制双通道伪随机信号发生器[J].仪器仪表学报,2002(04):382-385.
[47]姜常珍,孙永进,徐立军.电阻层析成像激励电极加权研究[J].天津大学学报,2002(03):348-353.
[48]徐立军,王亚,董峰,徐苓安.基于多电极电磁流量计的流速场重建[J].自然科学进展, 2002, 12(5): 524-528.
[49]王亚; 董峰; 徐立军.基于变频器技术的气/液两相流流型的控制.天津大学学报 增刊, 2002, 35: 41-44.
[50]孙永进,姜常珍,徐立军.电阻层析成像(ERT)两相流检测激励源对比分析[J].仪器仪表学报,2001(S1):1-2.
[51]邓湘,董峰,徐立军,刘小平,徐苓安.双敏感电极阵列的电阻层析成像系统的优化设计[J].仪器仪表学报,2001(S1):241-242.
[52]王亚,李鹏,徐立军.一种单极性输入双极性输出压控恒流源[J].仪器仪表学报,2001(S1):366-367+369.
[53]董峰,徐立军,刘小平,徐苓安.用电阻层析成像技术实现两相流流型识别[J].仪器仪表学报,2001(S1):416-417+431.
[54]刘泽,何敏,徐立军,徐苓安,熊汉亮.电磁层析成像系统信号检测与处理的优化设计[J].天津大学学报,2001(04):425-429.
[55]邓湘,董峰,徐立军,刘小平,徐苓安.提高电阻层析成像实时性能的研究[J].天津大学学报,2001(04):467-471.
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发表会议论文:
[1]Lu F.; Xu L.*; Zhang H.; Wang C.; Cao Z.A flexibly reconfigurable data acquisition system for tunable diode laser absorption spectroscopy.2020 IEEE International Instrumentation and Measurement Technology Conference, I2MTC 2020, 2020-05-25 To 2020-05-29.
[2]Xu L.*; Hou G.; Li Y.; Qiu S.; Song Z.; Cao Z.A compact noise-immune TDLAS temperature sensor using intensity modulation.2020 IEEE International Instrumentation and Measurement Technology Conference, I2MTC 2020, 2020-05-25 To 2020-05-29.
[3]Ran Chenhao; Xu Lijun; Chang Liuyong; Cao Zhang.Distribution retrieval of temperature from its histograms via the tunable diode laser absorption spectroscopy.IEEE International Instrumentation and Measurement Technology Conference (I2MTC), 2017-05-22 to 2017-05-27.
[4]Zhang Wenqiang; Xu Lijun; Qu Qianwei; Cao Zhang; Sun Jiangtao.Local Integrated Absorbance Tomography Based on Revised Iterative Reconstruction-Reprojection Algorithm.IEEE International Conference on Imaging Systems and Techniques (IST) / IEEE International School on Imaging, 2017-10-18 to 2017-10-20.
[5]Qu, Qianwei*; Xu, Lijun; Cao, Zhang; Liu, Chang.Effects of Views and Spectral Lines Numbers on Hyperspectral Temperature Distribution Tomography.2016-05-23 to 2016-05-26.
[6]Liu, Chang; Xu, Lijun*; Cao, Zhang; Li, Fangyan; Lin, Yuzhen.Reconstruction of Temperature Distribution for Swirling Flames Using One-dimensional TDLAS Tomography.2016-10-04 to 2016-10-06.
[7]Mahmoud, Alaaeldin*; Xu, Dong; Xu, Lijun.Optical design of common aperture and high resolution electrooptical/infrared system for aerial imaging applications.2016-04-04 to 2016-04-07.
[8]Mahmoud, Alaaeldin*; Xu, Dong; Xu, Lijun.Optical design of high resolution and shared aperture electrooptical/infrared sensor for uav remote sensing applications.2016-07-10 to 2016-07-15.
[9]Rui Yin; Lijun Xu; Xiaolu Li*.A simplified PIV-based method for flame velocity distribution measurement.2015 IEEE International Conference on Imaging Systems and Techniques (IST), Macau, 2015-09-16 to 2015-09-18.
[10]Fangyan Li; Lijun Xu*; Zhang Cao; Minglong Du.A chemi-ionization processing approach for characterizing flame flickering behavior.2015 IEEE International Instrumentation and Measurement Technology Conference (I2MTC), Italy, 2015-05-11 to 2015-05-14.
[11]Shijie Sun; Zhang Cao; Lijun Xu*.A noncontact conductivity detection method based on the principle of electromagnetic induction.2015 IEEE International Instrumentation and Measurement Technology Conference (I2MTC), Italy, 2015-05-11 to 2015-05-14.
[12]Jianjun Chen; Lijun Xu*; Zhang Cao; Xingbin Liu.Identification of oil-water flow patterns using conductance probe in vertical well.2015 IEEE InternationalInstrumentation and Measurement Technology Conference (I2MTC), Italy, 2015-05-11 to 2015-05-14.
[13]Xie, Heng; Cao, Zhang; Zhou, Jiayi; Xu, Lijun.Ghost Imaging of Binary-valued Objects by Using a CCD and an Equivalent Photodiode.2015-09-16 to 2015-09-18.
[14]Zhou, Z.*; Chen, T.; Xu, L.An Improved Dead Reckoning Algorithm for Indoor Positioning Based on Inertial Sensors.2015-07-26 to 2015-07-27.
[15]李小路; 吴迪; 徐立军.基于全波形激光雷达实验系统的波形特征及其目标反射率研究.中国仪器仪表学会第十六届青年学术会议, 中国,北京市.
[16]Liu, Chang*; Xu, Lijun; Cao, Zhang; Li, Fangyan.One-dimensional Tomography of Axisymmetric Temperature Distribution with Limited TDLAS Data by Using Three-point Abel Deconvolution.2014-10-14 to 2014-10-17.
[17]Cao, Zhang*; Huang, Chi; Xu, Lijun.Factorization method for electrical resistance tomography with partial boundary measurements.2014-10-14 to 2014-10-17.
[18]Li, Duan*; Xu, Lijun; Li, Xiaolu; Wu, Di.A novel full-waveform LiDAR echo decomposition method and simulation verification.2014-10-14 to 2014-10-17.
[19]Sun, Shijie; Xu, Lijun*; Cao, Zhang; Jing, Wenyang.A Digital Demodulator Based on the Recursive Gauss-Newton Method for Electrical Tomography.2014-10-14 to 2014-10-17.
[20]Zhang, Yumei*; Xu, Lijun; Cao, Zhang.Analysis of the Electromagnetic Wave Resistivity Tool in Deviated Well Drilling.8th International Symposium on Measurement Techniques for Multiphase Flows, 2013-12-13 to 2013-12-15.
[21]Zhang, Yumei; Xu, Lijun; Cao, Zhang; Xu, L*.Optimization of the Electromagnetic Wave Resistivity Tool in Logging While Drilling.2013-10-22 to 2013-10-23.
[22]Xu, Teng*; Xu, Lijun; Li, Xiaolu; Tian, Xiangrui.Impact of Attitude Measurement Errors on Laser Footprints Positioning Accuracy.2013-10-22 to 2013-10-23.
[23]Jing, Lili*; Xu, Lijun; Li, Xiaolu; Tian, Xiangrui.Determination of Platform Attitude Through SURF Based Aerial Image Matching.2013-10-22 to 2013-10-23.
[24]Nie, Jing*; Meng, XiaoFeng; Xu, LiJun; Zheng, Rui.Dew point measurement using a quartz crystal sensor.2013-05-06 to 2013-05-09.
[25]Zhang Cao*; Lijun Xu.Direct image reconstruction for ERT by using measurements on partial boundary.IEEE International Conference on Imaging Systems and Techniques (IST), China,Beijing, 2013-10-22 to 2013-10-23.
[26]Lili Jing*; Lijun Xu; Xiaolu Li; Xiangrui Tian.A federal UKF algorithm in INS/GPS/aerial image integrated attitude determination system.IEEE International Conference on Imaging Systems and Techniques (IST), China,Beijing, 2013-10-22 to 2013-10-23.
[27]Xiaolu Li*; Lian Ma; Lijun Xu.Land classification from LiDAR full-waveforms based on multi-class support vector machines.IEEE International Conference on Imaging Systems and Techniques (IST), China,Beijing, 2013-10-22 to 2013-10-23.
[28]Kong, Deming; Xu, Lijun*; Li, Xiaolu; Li, Shuyang.A Real-time Method for DSM Generation from Airborne LiDAR Data.IEEE International Instrumentation and Measurement Technology Conference (I2MTC), 2013-05-06 to 2013-05-09.
[29]Xin, Lei; Xu, Lijun; Cao, Zhang*.Laser spot center location by using the gradient-based and least square algorithms.IEEE International Instrumentation and Measurement Technology Conference (I2MTC), 2013-05-06 to 2013-05-09.
[30]Li, Duan; Xu, Lijun*; Li, Xiaolu; Ma, Lian.FULL-WAVEFORM LIDAR SIGNAL FILTERING BASED ON EMPIRICAL MODE DECOMPOSITION METHOD.IEEE International Geoscience and Remote Sensing Symposium (IGARSS), 2013-07-21 to 2013-07-26.
[31]Li, Xiaolu; Ma, Lian; Li, Duan; Xu, Lijun*.AN AUTOMATIC ALGORITHM FOR SLOPE ESTIMATION FROM REPEAT TRACKS OF ICESAT/GLAS.IEEE International Geoscience and Remote Sensing Symposium (IGARSS), 2013-07-21 to 2013-07-26.
[32]Liu Chang; Xu Lijun; Cao Zhang.Measurement of axisymmetric temperature distributions using single view fan-beam TDLAS tomography.2013 IEEE International Instrumentation and Measurement Technology Conference: Instrumentation and Measurement for Life, I2MTC 2013 , United States, 2013-05-06 to 2013-05-09.
[33]Haili Zhou; Lijun Xu*; Zhang Cao.A digital demodulation method for electrical tomography based on sine wave rectification.Proceedings of 2012 IEEE International Conference, United Kingdom, 2012-07-16 to 2012-07-17.
[34]Zhang Cao; Lijun Xu*.A direct reconstruction algorithm for recovering the admittivities in 2D electrical tomography.Proceedings of 2012 IEEE International Conference on Imaging Systems and Techniques (IST2012), United Kingdom, 2012-07-16 to 2012-07-17.
[35]Xiaolu Li; Zhongbao Wei; Lijun Xu*.Effect of inclined angle of fuel jet on NOx emission in high temperature air combustion.2012 IEEE International Conference on Imaging Systems and Techniques (IST), United Kingdom, 2012-07-16 to 2012-07-17.
[36]Yujia Liu; Yumei Zhang; Zhang Cao; Lijun Xu*.An adaptive algorithm for cross-correlation velocity measurement.Proceedings of the 8th IEEE International Symposium on Instrumentation and Control Technology, 2012-07-11 to 2012-07-13.
[37]Chang Liu; Lijun Xu*; Zhang Cao.Simulation on measuring of nonuniform temperature distribution based on line-of-sight TDLAS by using Tikhonov regularization method.Proceedings of the 8th IEEE International Symposium on Instrumentation and Control Technology ., 2012-07-11 to 2012-07-13.
[38]Lijun Xu*; Yanting Cheng; Xiaolu Li.Online coal calorific value prediction from mutiband coal/air combustion radiation characteristics.Proceedings of the 8th IEEE International Symposium on Instrumentation and Control Technology, United Kingdom, 2012-07-11 to 2012-07-13.
[39]Kong Deming; Xu Lijun*; Li Xiaolu; Tian Xiangrui.A new concept for the distributions of wavelet packet decomposition coefficients in detail subbands.8th IEEE International Symposium on Instrumentation and Control Technology, ISICT 2012, 2012-07-11 to 2012-07-13.
[40]Li, Xiaolu; Li, Duan; Xu, Lijun; Xu, L*.Slope estimations in forest area from waveform and dem.2012-07-22 to 2012-07-27.
[41]Cao, Zhang*; Xu, Lijun.Direct Image Reconstruction for 3D Electrical Resistance Tomography by Using the Factorization Method.IEEE International Instrumentation and Measurement Technology Conference (I2MTC), 2012-05-13 to 2012-05-16.
[42]Li, Xiaolu; Xu, Lijun*; Wang, Changwei.TERRAIN SLOPE CALCULATION FROM WAVEFORM OF AIRBORNE LIDAR.IEEE International Geoscience and Remote Sensing Symposium (IGARSS), 2012-07-22 to 2012-07-27.
[43]Zhou, Haili; Xu, Lijun*; Cao, Zhang; Xu, Chenfeng.An Alternative Digital Multiplication Demodulation Method for Electrical Capacitance Tomography.IEEE International Instrumentation and Measurement Technology Conference (I2MTC), 2012-05-13 to 2012-05-16.
[44]Yanting Cheng; Lijun Xu; Xiaolu Li; Tao He.Compensation of optical path difference for colorimetric temperature imaging.2011 IEEE International Conference on Imaging Systems and Techniques (IST2011), Malaysia, 2011-05-17 to 2011-05-18.
[45]Cheng Tan; Lijun Xu; Xiaolu Li; Zhongbao Wei.CFD Modelling of Velocity Distribution in Tangential Coal-fired Flame.2011 IEEE International Conference on Imaging Systems and Techniques (IST2011), Malaysia, 2011-05-17 to 2011-05-18.
[46]Haili Zhou; Lijun Xu; Zhang Cao; Jinhai Hu; Xingbin Liu.DC Bias Compensation in Digital AC-based Capacitance Measurement for ECT.2011 IEEE International Conference on Imaging Systems and Techniques (IST2011), Malaysia, 2011-05-17 to 2011-05-18.
[47]Jianjun Wang; Lijun Xu; Xiaolu Li; Xiangrui Tian.Simulation on Impact of Random Attitude Measurement Errors on Point Cloud and 3D Image of ALS.2011 IEEE International Conference on Imaging Systems and Techniques (IST2011), Malaysia, 2011-05-17 to 2011-05-18.
[48]Zhang Cao; Lijun Xu; Chenfeng Xu; Yanping Zhu.Direct image reconstruction for electromagnetic tomography by using the factorization method.2011 IEEE International Conference on Imaging Systems and Techniques (IST2011), Malaysia, 2011-05-17 to 2011-05-18.
[49]Lei Xin; Lijun Xu; Zhang Cao.ℓ1 norm based reconstruction algorithm for particle sizing.I2MTC2011-IEEE International Instrumentation and Measurement Technology Conference, China, 2011-05-10 to 2011-05-12.
[50]Xin Lei; Xu Lijun*; Cao Zhang.ℓ1 norm based reconstruction algorithm for particle sizing.2011 IEEE International Instrumentation and Measurement Technology Conference, I2MTC 2011, 2011-05-10 to 2011-05-12.
[51]Xu, Lijun; Peng, Zhicong; Cao, Zhang; Ling, Qi; Wang, Gang; Xu, L*.Weighting Function-Based Coil Size Optimization for Electromagnetic Flowmeter.2011-05-10 to 2011-05-12.
[52]Chen, Jianjun; Cao, Zhang; Xu, Lijun; Xu, L*.Four-terminal Scheme Used in a Two-terminal EIT System.2011-05-10 to 2011-05-12.
[53]Wang, Jianjun*; Xu, Lijun; Li, Xiaolu; Tian, Xiangrui.Impact Analysis of Random Measurement Errors on Airborne Laser Scanning Accuracy.2011-05-10 to 2011-05-12.
[54]Cao, Zhang*; Xu, Lijun; Liu, Xingbin.Direct Image Reconstruction For Electromagnetic Tomography(EMT) by Using the Dbar Method.2011-05-10 to 2011-05-12.
[55]Zeng, Yi; Xu, Lijun; Cao, Zhang; Ma, Shuilong; Xu, L*。FPGA-based implementation of Prony Demodulation in the Multi-frequency EIT System.2011-05-10 to 2011-05-12.
[56]Li, Xiaolu*; Xu, Lijun; Quan, Zhongyi; Zhang, Chaozeng.Model of Measuring Slop from Raw Data of Full-waveform Topographic lidar.2011-05-10 to 2011-05-12.
[57]Wu, Yuting; Cao, Zhang; Xu, Lijun; Xu, L*.A simplified model for non-destructive thickness measurement immune to the lift-off effect.2011-05-10 to 2011-05-12.
[58]Xin, Lei; Xu, Lijun*; Cao, Zhang.l(1) norm based reconstruction algorithm for particle sizing.IEEE International Instrumentation and Measurement Technology Conference (I2MTC), 2011-05-10 to 2011-05-12.
[59]Haili Zhou; Lijun Xu; Zhang Cao; Jinhai Hu.Simulation on invasive ERT for void fraction measurement in vertical production oil well.6th WCIPT- World Congress on Industrial Process Tomography, China, 2010-09-06 to 2010-09-09.
[60]Zhang Cao; Lijun Xu.Direct methods for image reconstruction in electrical capacitance tomography.6th WCIPT- World Congress on Industrial Process Tomography, China, 2010-09-06 to 2010-09-09.
[61]李小路; 徐立军; 王建军; 田祥瑞.平台运动误差对机载激光雷达点云分布影响的理论研究.中国,北京市.
[62]王建军; 徐立军; 李小路.姿态角随机测量误差对机载激光雷达点云定位精度和三维成像精度的影响.中国,北京市.
[63]Lijun Xu*; Cheng Tan; Xiaomin Li; Chenfeng Xu.On-line identification of new coal type using joint probability density arbiter.IEEE International Conference on Intelligent Systems, United Kingdom, 2010-07-07 to 2010-07-09.
[64]Xiangrui Tian; Lijun Xu; Xiaolu Li; Guangyi Shang; Junen Yao.Geometric distortion correction for sinusoidally scanned atomic force microscopic images.Proceedings of 2010 IEEE International Conference on Imaging Systems and Techniques, Greece, 2010-07-01 to 2010-07-02.
[65]Zhang Cao; Lijun Xu; Wenru Fan; Huaxiang Wang.2D ECT for sensors of non-circular cross sections using the factorization method.Proceedings of 2010 IEEE International Conference on Imaging Systems and Techniques, Greece, 2010-07-01 to 2010-07-02.
[66]Zhang Cao; Lijun Xu; Chengfeng Xu; Huaxiang Wang.Electrical resistance tomography(ERT) by using an ECT sensor.Proceedings of 2010 IEEE International Conference on Imaging Systems and Techniques, Greece, 2010-07-01 to 2010-07-02.
[67]Lijun Xu; Cheng Tan; Xiaomin Li; Xiaolu Li.On-line Identification of Fuel Type Using Joint Probability Density Arbiter and Support Vector Machine Techniques.Proceedings of 2010 IEEE International Instrumentation and Measurement Technology Conference, United States, 2010-05-03 to 2010-05-06.
[68]Wanlu Zhou; Lijun Xu; Xiaomin Li.Wet gas flow modeling for the straight section of throat-extended Venturi meter.Proceedings of 2010 IEEE International Instrumentation and Measurement Technology Conference, United States, 2010-05-03 to 2010-05-06.
[69]Li, Xiaolu*; Xu, Lijun; Tan, Cheng; Tian, Xiangrui.Real-Time Measurement of Aerodynamic Deformation of Wing by Laser Rangefinder.2010-05-03 to 2010-05-06.
[70]Cao, Zhang*; Xu, Lijun; Wang, Huaxiang.A Direct Reconstruction Method of Electromagnetic Tomography(EMT) for High Permeability and Low Conductivity Distributions.2010-05-03 to 2010-05-06.
[71]Cao, Zhang; Xu, Lijun; Ding, Jie.Integral inversion to Fraunhofer diffraction for particle sizing.
[72]Zhang Cao; Lijun Xu; Huaxiang Wang.2D ECT with square sensor using Calderon's method.2009 IEEE International Workshop on Imaging Systems and Techniques, China, 2009-05-11 to 2009-05-12.
[73]Lijun Xu; Shaliang Tang.Wet Gas Metering Using a Venturi-Meter and Support Vector Machines.I2MTC 2009 - IEEE International Instrumentation and Measurement Technology Conference Proceedings, Singapore, 2009-05-05 to 2009-05-07.
[74]Cheng Tan; Lijun Xu; Zhang Cao.On-Line Fuel Identification Using Optical Sensing and Support Vector Machines Technique.I2MTC 2009 - IEEE International Instrumentation and Measurement Technology Conference Proceedings, Singapore, 2009-05-05 to 2009-05-07.
[75]Zhang Cao; Lijun Xu; Jie Ding.A New Analytical Inversion to Fraunhofer Diffraction.I2MTC 2009 - IEEE International Instrumentation and Measurement Technology Conference Proceedings, Singapore, 2009-05-05 to 2009-05-07.
[77]Wenfeng Xu; Lijun Xu; Xingbin Liu; Jinhai Hu.Experimental Study On Cylindrical Capacitance Sensor.I2MTC 2009 - IEEE International Instrumentation and Measurement Technology Conference Proceedings, Singapore, 2009-05-05 to 2009-05-07.
[78]徐立军; 李松云; 龚立艳; 商广义; 姚骏恩.原子力显微镜图像小波去噪方法研究.中国,广东省,广州市.
[79]李松云; 徐立军; 商广义.高速原子力显微术最新进展.中国,广东省,广州市.
[80]Lijun Xu; H. Li; J. Xu.Wet gas metering by using a long-throat Venturi tube.Seventh International Symposium on Instrumentation and Control Technology: Sensors and Instruments, Computer Simulation and Artificial Intelligence, Proceedings of SPIE , China,Beijing, 2008-10-10 to 2008-10-13.
[81]Zhang Cao; Qinghao Meng; Huaxiang Wang; Lijun Xu.A new strategy for robot path planning based on the finite element method.Seventh International Symposium on Instrumentation and Control Technology: Sensors and Instruments, Computer Simulation and Artificial Intelligence, Proceedings of SPIE , China,Beijing, 2008-10-10 to 2008-10-13.
[82]Lijun Xu; Hui Li; Shaliang Tang; Cheng Tan; Bo Hu.Wet Gas Metering Using a Venturi-meter and Neural Networks.IEEE Instrumentation and Measurement Technology Conference, 2008 IEEE International Instrumentation and Measurement Technology Conference Proceedings, Canada, 2008-05-12 to 2008-05-15.
[83]Lijun Xu; Cheng Tan; Liyan Gong; Jian Qiu Zha.Two-in-One Implementation of Noise Reduction and Incline Emendation for Atomic Force Microscopic Images.IEEE Instrumentation and Measurement Technology Conference, 2008 IEEE International Instrumentation and Measurement Technology Conference Proceedings, Canada, 2008-05-12 to 2008-05-15.
[84]Xu, Lijun; Li, Hui; Xu, Jian.Wet gas metering by using a long-throat Venturi meter - art. no. 712719.7th International Symposium on Instrumentation and Control Technology, 2008-10-10 to 2008-10-13.
[85]Cao, Zhang; Meng, Qinghao; Wang, Huaxiang; Xu, Lijun.A new strategy for robot path planning based on the finite element method - art. no. 71272R.7th International Symposium on Instrumentation and Control Technology, 2008-10-10 to 2008-10-13.
[86]王陶; 张博; 徐立军; 闫勇.粉料气力输送状态在线监测装置研究.第一届气/固两相流检测控制全国研讨会, 中国,天津市, 2007-09-13至2007-09-14.
[87]李晓敏; 徐立军; 李松云.颗粒粒度对聚集态气固混合物有效介电常数影响的实验研究.第一届气/固两相流检测控制全国研讨会, 中国,天津市, 2007-09-13至2007-09-14.
[88]徐立军; 龚立艳; 钱建强; 陈强; 姚骏恩.深空探测原子力显微镜图像原位处理技术初探—图像增强与压缩.中国宇航学会深空探测技术专业委员会第四届学术年会, 中国,山西省,太原市, 2007-09-02至2007-09-04.
[89]Zhang Cao; Huaxiang Wang; Lijun Xu.Electrical impedance tomography with optimized square sensor.IMTC 2007 – IEEE Instrumentation and Measurement Technology Conference, Poland, 2007-05-01 to 2007-05-03.
[90]Bo Zhao; Huaxiang Wang; Li Hu; Lijun Xu; Yong Yan.An Adaptive Multigrid Method For EIT.IMTC 2007 – IEEE Instrumentation and Measurement Technology Conference, Poland, 2007-05-01 to 2007-05-03.
[91]Xiaomin Li; Lijun Xu.Particle Size Influence on Effective Permittivity of Particle-Gas Mixture with Particles Agglomeration: Experimental Study.IMTC 2007 – IEEE Instrumentation and Measurement Technology Conference, Conference Proceedings - Synergy of Science and Technology in Instrumentation and Measurement, Poland, 2007-05-01 to 2007-05-03.
[92]Jun Han; Ying Hao; Lijun Xu.Simultaneous Removal of Harmonic Interference and White Noise by Combining Multi-Rate Signal Processing and Wavelet Denoising Techniques.IMTC 2007 – IEEE Instrumentation and Measurement Technology Conference, Conference Proceedings - Synergy of Science and Technology in Instrumentation and Measurement, Poland, 2007-05-01 to 2007-05-03.
[93]Jun’en Yao; Lijun Xu.Autonomous atomic force microscope for on-site measurement in lunar exploration.The 3rd UK-China Workshop on Space Science & Technology, China,Shanghai, 2007-03-29 to 2007-04-01.
[94]Han, Jun; Hao, Ying; Xu, Lijun.Simultaneous removal of harmonic interference and white noise by combining mufti-irate signal processing and wavelet denoising techniques.24th IEEE Instrumentation and Measurement Technology Conference, 2007-05-01 to 2007-05-03.
[95]Jun Han; Lijun Xu.A New Method for Variance Estimation of White Noise Corrupting a Signal.IMTC 2006–IEEE Instrumentation and Measurement Technology Conference, Italy, 2006-04-24 to 2006-04-27.
[96]Lijun Xu; Jun Han.Cancellation of Harmonic Interference Using Multi-Rate Signal Processing Techniques.IMTC 2006 - IEEE Instrumentation and Measurement Technology Conference, Italy, 2006-04-24 to 2006-04-27.
[97]Lijun Xu; Jeffrey C. Bamber.Noise reduction in elastographic strain estimation from displacement.Fourth International Conference on the Ultrasonic Measurement and Imaging of Tissue Elasticity, United States, 2005-10-16 to 2005-10-19.
[98]Lijun Xu; Jeffrey C. Bamber.Wavelet transform-based strain estimation for elastography.2005 IEEE Ultrasonics Symposium, Netherlands, 2005-09-18 to 2005-09-21.
[99]Lijun Xu; Yong Yan.A New Flame Monitor with Triple Photovoltaic Cells.Proceedings of the 2005 IEEE Instrumentation and Measurement Technology Conference, Canada, 2005-05-17 to 2005-05-19.
[100]Lijun Xu; Jun Han; Tao Zhang.Dual-Channel Pseudo-Random Signal Generator with Precise Control of Time Delay between Channels.Proceedings of the 2005 IEEE Instrumentation and Measurement Technology Conference, Canada, 2005-05-17 to 2005-05-19.
[101]Lijun Xu; Robert M. Carter; Yong Yan.Mass flow measurement of fine particles in a pneumatic suspension using electrostatic sensing and neural network techniques.Proceedings of the 2005 IEEE Instrumentation and Measurement Technology Conference, Canada, 2005-05-16 to 2005-05-19.
[102]Lijun Xu; Robert M Carter; Yong Yan; Hongjian Zhang.Mass flow measurement of pneumatically conveyed solids using electrostatic sensing and neural network techniques.Proceedings of the 4th International Symposium on Measurement Techniques for Multiphase Flows, China, 2004-09-10 to 2004-09-12.
[103]Lijun Xu; Yong Yan; Steve Cornwell; Gerry S Riley.A cost-effective approach to on-line fuel tracking.5th European Conference on Coal Research and Its Applications, 2004-09-06 to 2004-09-08.
[104]Lijun Xu; Yong Yan; Steve Cornwell; Gerry Riley.On-line Fuel Tracking by Combining Principal Component Analysis and Neural Network Techniques.Proceedings of the 21th IEEE Instrumentation and Measurement Technology Conference, Italy, 2004-05-18 to 2004-05-20.
[105]Lijun Xu; Yong Yan.An Improved Algorithm for the Measurement of Flame Flicker Frequency.Proceedings of the 21th IEEE Instrumentation and Measurement Technology Conference, Italy, 2004-05-18 to 2004-05-20.
[106]Feng Dong; Yanbin Xu; Lijun Xu; Lei Hua; Xutong Qiao.Application of dual-plane ERT system and cross-correlation technique to measure gas-liquid flows in vertical upward pipe.4th International Symposium on Measurement Techniques for Multiphase Flows, China, 2003-09-10 to 2003-09-12.
[107]Kien Chua; Lijun Xu; Yong Yan.Emission Monitoring Using Optical and Acoustic Sensors Combined with Neural Networks.Sensors and their applications XII-Proceedings of the Twelfth Conference on Sensors and their Applications, Ireland, 2003-09-02 to 2003-09-04.
[108]Lijun Xu; Yong Yan.On-line fuel identification using optical sensors and neural network techniques.Sensors and their applications XII - Proceedings of the Twelfth Conference on Sensors and their Applications, Ireland, 2003-09-02 to 2003-09-04.
[109]Lijun Xu; Yong Yan.Recovery of a Signal From Contamination of Sinusoidal Interference.Sensors and their applications XII - Proceedings of the Twelfth Conference on Sensors and their Applications, Ireland, 2003-09-02 to 2003-09-04.
[110]Ning-de Jin; Jun Wang; Lijun Xu.Optimization of a conductance probe with vertical multi-electrode array for the measurement of oil-water two-phase flow.Proceedings of the Second International Conference on Machine Learning and Cybernetics, China, 2003-09-02 to 2003-09-05.
[111]Lijun Xu; Ya Wang; Feng Dong; Yong Yan.On-line monitoring of the non-axisymmetric flow profile with a multi-electrode inductance flowmeter.Proceedings of the 20th IEEE Instrumentation and Measurement Technology Conference, United States, 2003-05-20 to 2003-05-22.
[112]Lijun Xu; Jian Qiu Zhang; Yong Yan.A Wavelet-Based Multi-Sensor Data Fusion Algorithm.Proceedings of the 20th IEEE Instrumentation and Measurement Technology Conference, United States, 2003-05-20 to 2003-05-22.
[113]Lijun Xu; Yong Yan; Gerry Riley.n-Line Fuel Identification Using Digital Signal Processing and Soft-Computing Techniques.Proceedings of the 20th IEEE Instrumentation and Measurement Technology Conference, United States, 2003-05-20 to 2003-05-22.
[114]Feng Dong; Yanbin Xu; Xutong Qiao; Lijun Xu; Ling-an Xu.Void fraction measurement for two-phase flow using electrical resistance tomography.3rd World Congress in Process Tomography, Canada, 2003.
[115]张涛; 许建; 徐立军.气液两相流流经文丘里管的动态差压信号分析.工程热物理学会与多相流分会2002年学术年会, 中国, 2002-11-26至2002-11-28.
[116]徐立军; 李晓敏.燃煤锅炉煤粉输送状况监测.2001年天津青年科技论坛, 中国, 2001-10-15.
[117]F. Dong; X. P. Liu; X. Deng; Lijun Xu; L. A. Xu.Identification of two-phase flow regime using Electrical Resistance Tomography.Proc. of 2nd World Congress on Industrial Process Tomography, Germany, 2001-08-29 to 2001-08-31.
[118]X. Deng; F. Dong; Lijun Xu; L. A. Xu.Measurement of the gas phase velocity in gas/liquid flows using dual plane ERT sustem.Proc. of 2nd World Congress on Industrial Process Tomography, Germany, 2001-08-29 to 2001-08-31.
[119]M. He; Z. Liu; Lijun Xu; L. A. Xu.Multi-excitation-mode EMT system.Proc. of 2nd World Congress on Industrial Process Tomography, Germany, 2001-08-29 to 2001-08-31.
[120]X. Deng; F. Dong; Lijun Xu; L. A. Xu.Research of dual plane electrical resistance tomography cross-correlation for gas/liquid flow measurement.Proc. of the 3rd ISMTMF, Japan, 2001-08 to 2001-08.
[121]F. Dong; X. Deng; Lijun Xu; L. A. Xu.Measurment of two-phase flow using electrical resistance tomography.Proc. of the 3rd ISMTMF, Japan, 2001.
[122]徐苓安,徐立军. 过程层析成像技术的发展及应用现状[C]. 新世纪 新机遇 新挑战——知识创新和高新技术产业发展(下册). 2001:422.
[123]董峰,徐立军,刘小平,徐苓安. 用电阻层析成像技术实现两相流流型识别[C]. 中国仪器仪表学会测控技术在资源节约和环境保护中的应用学术会议论文集. 2001:18-19+33.
[124]许燕斌,董峰,徐立军. ERT数据采集系统通讯模块的设计[C]. 中国仪器仪表学会测控技术在资源节约和环境保护中的应用学术会议论文集. 2001:177-179.
[125]王亚,李鹏,徐立军. 一种单极性输入双极性输出压控恒流源[C]. 中国仪器仪表学会第三届青年学术会议论文集(上). 2001:374-375+377.
[126]孙永进,姜常珍,徐立军. 电阻层析成像(ERT)两相流检测激励源对比分析[C]. 中国仪器仪表学会第三届青年学术会议论文集(上). 2001:9-10.
[127]邓湘,董峰,徐立军,刘小平,徐苓安. 双敏感电极阵列的电阻层析成像系统的优化设计[C]. 中国仪器仪表学会第三届青年学术会议论文集(上). 2001:249-250.
[128]李香平; 徐立军; 张涛.智能型双通道伪随机信号发生器.21世纪信息技术、电子技术、仪器仪表技术,开拓、创新、上水平战略研讨会(暨)学术会议, 中国, 2000-09至2000-09.
[129]徐立军; 董峰; 徐苓安.气液两相流检测技术进展.21世纪信息技术、电子技术、仪器仪表技术,开拓、创新、上水平战略研讨会(暨)学术会议, 中国, 2000-09至2000-09.
[130]Lijun Xu; Alfred Weber; Gerhard Kasper.Simultaneous measurements of velocity, charge and size of individual aerosol particles.Proceedings of the fifth international conference on measurement and control of granular materials, China, 2000-08 to 2000-08.
[131]Lijun Xu; Alfred Weber; Gerhard Kasper.Particles packing influence on effective permittivity of particle-gas mixture.Proceedings of the fifth international conference on measurement and control of granular materials, China, 2000-08 to 2000-08.
[132]Lijun Xu; Alfred Weber; Gerhard Kasper.Simultane in-situ Messung von Geschwindigkeit.34th International Seminar for Research and Teaching in Chemical Engineering, Technical and Physical Chemistry, Germany, 1999-07-15.
[133]Lijun Xu; Ling-An Xu.Application of ultrasonic tomography to gas/liquid flow regime identification.Proceedings of the Conference on Frontiers in Industrial Process Tomography II, Netherlands, 1997-04-09 to 1997-04-12.
[134]Lijun Xu; Yongtao Han; Lingan Xu.An ultrasonic tomography system for monitoring gas/liquid two-phase flow.Proceedings of the 8th International Conference on Flow Measurement, China, 1996-10-20 to 1996-10-24.
[135]Lijun Xu; YT Han; LA Xu.Application of ultrasonic tomography to monitoring gas/liquid flow.Proceedings of the International Conference on Frontiers in Industrial Process Tomography, United States, 1995-10-29 to 1995-11-03.
[136]徐苓安; 徐立军.过程层析成象技术的研究现状与发展趋势.中国仪器仪表学会过程检测控制分会第三届年会, 中国, 1995-10至1995-10.
[137]L. A. Xu; Lijun Xu; Y. T. Dong; Y. T. Han.Process Tomography technique and its application to two-phase flow measurement.Proceedings of the 1995 International Symposium on Measuring Techniques for Multiphase Flows (Modern Measuring Techniques for Multiphase Flows), China, 1995-04-10 to 1995-04-13.
[138]杨吉生,徐立军,孙天宇,叶声华. 非常规形体散射近场的数值解法[C]. 1995年全国微波会议论文集(上册). 1995:634-637.
 荣誉奖励:
所获荣誉:
1、国家杰出青年科学基金获得者。
2、教育部“长江学者”特聘教授。
3、国家“万人计划”领军人才。
4、科技部“中青年科技创新领军人才”。
5、2016年第七届全国优秀科技工作者。
7、2001年第六届天津青年科技奖(个人奖)。
8、教育部高等学校骨干教师资助计划。
9、天津大学第七届十佳杰出青年。
10、天津大学-摩托罗拉奖教金。
所获奖励:
1、2014年度中国仪器仪表学会科学技术奖一等奖,项目名称:气固两相流动过程在线监测技术及应用,第一完成人。
2、2012年度高等学校科学研究优秀成果奖(技术发明一等奖),项目名称:燃煤锅炉安全高效运行关键参数检测技术及系统,第一完成人。
3、2001年度天津市自然科学奖二等奖,项目名称:基于电学敏感原理的过程层析成像技术研究,第二完成人。
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