一个简单的LabVIEW 登录界面

图像复原 逆滤波复原法 维纳滤波复原法 去除由匀速运动引起的模糊

这个程序是我帮别人编的.用那有名的56个例子算过的.与世界最好解也就差那么一丁点儿

计算均方误差MSE信噪比SNR峰值信噪比PSNR绝对平均误差的matlab函数

该课题为基于MATLAB SVM方法的植物病害检测系统，带GUI界面，可以识别多种被虫害侵蚀的植物叶子，输出结果。带论文和详细注释。train 对黄瓜子文件夹所有图片提取 颜色矩特征和gabor纹理特征，然后svm训练test 对测试图像灰度化，滤波，提取 颜色矩特征和gabor纹理特征，然后svm模型测试，输出类别colorMom.m 颜色矩特征提取Gabor_palm.m gabor纹理特征提取

完整的编译原理语法分析器的全套，还有实验报告。。。

山东大学2017年模式识别的考试题，题目很简单，供复习参考

从事科研或者工程的人员在文档撰写过程中，常需要将文献中的曲线与自己的结果对比，为获取原始数据，一种常用的办法是手动描点，即将原始曲线放大然后打印出来，选取一定数量的点，读出其横纵坐标，然后重绘。对于较为平坦的曲线，这种方法当然可行，但当曲线数量增加，曲线变化复杂，这种方法工作量可想而知。前段时间由于原始数据丢失，仅剩几十幅图片，本人尝试过手动描点，经历几个小时奋战，实在无法继续，索性转向matlab，借助其强大的数据处理能力，编写了两个GUI的小软件image2data、data_poly提取数据，如今大功告成，遂于大家分享。坐标轴标定按下面板上的按钮进行图像放大,按钮恢复初始显示大小,钮采用鼠标拖动图像按钮退出放大或者拖动的鼠标操作模式,空格键表示取点操作,键表示删除上一次取点操作,状态栏的显示当前鼠标取点总数目(注意,初始点数为,然后存处个坐标轴标定坐标,剩余用来存储曲线坐标)。值得指山的是,每次放大或者拖动桨作完毕后,必须按下按钮,才能用空格键进行取点操作。匹回图00.400.351 MHz足0.300.2530 MHz0.20frequency>100 MHz型30681012141618REVERSE VOLTAGE (VFigure 1. RF Capacitance vs ReverseBias. HSMP-3810 Series图坐标轴定标曲线描点按照上述操作反复进行图像放大、拖动、取点,状态栏的和用于显示当前坐标(注紊,这个坐标图像坐标,轴方向向下,后面坐标变换需要考虑),下图给出了描点完毕后的曲线,可以看出取点基本代表了曲线的全部信息。0.45E0400351 MHz0.3002530 MHZ.frequency> 100 MHzpr/。no0.1568101214161820REVERSE VOLTAGE (V)Figure 1. RF Capacitance vs Reversem[1Bias. hsMP-3810 Series图曲线描点数据处理及存储。按下按钮,描点后的曲线会显示在图像当中,按下按钮,程序自动进行坐标转换,得到所有描点的真实坐标,按卜按钮,使会生成一个文木,数据记录其和按钮下都有文本输入框,本别代表输入文本和存储文本的名称,不带后缀)。045"z55sd0.351M3002530 MHafrequency>100 MHz0.1502468101214161820REVERSE VOLTAGE (VFigure l. RF Capacitance vs Reversese4Bias. HsMP-3810 Series图拟合曲线效果记事本巴回囟文件〕编辑巴)格式迫!查看y1帮助)6,6ag15-92h432562gP-6811.18153B60-91488g2c-8912.15288c-E914.81Q68c-691.93177一Bg1571882c-6E-8Ube-出14.168y!:e-Uk1面=363211g-9g1py9py6-6817.99日969e-B914。394g55e-919.6696599e-B913.941218e-0911.119913-Bg3.E786699g-6511.36361243.779192-6811,5邵3777e十3.71813e-6117699899e+053.6164171e-6911_97了5775巴十B035小B725-6612-3111uB!g318286-B12.了7阳7P??5"24"9236P-R13.12096E5e+gs2502的9e-6613.526859e-E日31756187e-651391427562B9.1158646e-6814_287193.806E87ge-651h。47785F7eB98,38E17e-61↓816F877e+2.9877229e-6615.342g3B6e-Eg2.92049e-6615,6428g1eB9g2.B86ge6168697eBgg28616e-816652032cE9g78786ggc-691图数据记录文本数据后处理由于以上数据是于动选取的,故分布不够均匀,下面我们通过数据拟合,然后重新采样得到等间距的数据(可能大家会问,为什么两个功能不做在起呢?数据拟合是个比较味烦的事情,本组曲线采用多项式拟合即可,可对于更多的曲线采用指数函数、正弦函数等才能得到比较好的结果中的工具箱就包含了很多的拟合函数,为避免重复工作,仅绵写了这个小软件用来数据拟合再采样,其他的拟合就靠了)。运行代表多项式拟合的阶数(一般就够用了),代表重新釆样的数据个数,其他几个就不用解释了,默认输入文本为输出文本为,数据拟合结果如下图所示Xmax 23 ymax045fing图数据拟合再采样结果至此,数据提取过程完毕,可能操作上有些不便(毕竞只是小T具而已),但比起于动描点的速度和精度,可谓小巫见大巫。软件编写要点这两个小软件从构思到完成大概用了两大,功能的完成绝大部分归功」丰富的函数库和方便的,其中用到的主要函数上要有列衣如下,更详的介绍请参阅文档。表主要函数列表除了上述函数的掌握之外,还需要对的数据结构和函数响应有一定的理解,在此就不多讲了(多看相关例程就明白了)。编写程序之前,首先心中要有一个框架,做些什么,怎么做,顺序如何等。本软件的结构如下图所示:导入图像创建数据结构坐枟轴定标曲线描点坐标变換数据后处彐:拟合、重新采样、存储图程序沇程示意导入图像程序段:创建数据结构程序段坐标轴定标及坐标变换:数据后处理代码段附录3.1描点数据列表数据拟合结果3.3、重新采样数据列表

全新RTCM3.3协议完整版RTCM STANDARD 10403.3DIFFERENTIAL GNSS(GLOBAL NAVIGATION SATELLITE SYSTEMS)SERVICES – VERSION 3DEVELOPED BYRTCM SPECIAL COMMITTEE NO. 104OCTOBER 7, 2016COPYRIGHT©2016 RTCMRadio Technical Commission for Maritime Services1611 N. Kent St., Suite 605Arlington, Virginia 22209-214RTCM Paper 141-2016-SC104-STD000ocRTCMco00c30RTCM 10403. 3, Differential GNSS Global Navigation Satellite Systems)Services- Version 3, October 7, 2016This standard (referred to as version 3 has been developed by rtCm special Committee 104 as a moreefficient alternative to the standards entitled rtcm recommended standards for diffe rentialRecommended Standards for Differential gNss Global Navigation Satellite Systems Service, Version 2.x(Current version is 2. 3, now designated as RTCM 10402. 3. Service providers and vendors represented onthe SC104 Committee wanted a new standard that would be more efficient, easy to use, and more easilyadaptable to new situations. The main complaint was that the version 2. x parity scheme, which useswords with 24 bits of data followed by 6 bits of parity, was wasteful of bandwidth. Another complaint wasthat the parity was not independent from word to word. Still another was that even with so many bitsdevoted to parity the actual integrity of the message was not as high as it should be. Plus, 30-bit wordsare awkward to handle. the new standard version 3 is intended to correct these weaknessesUnlike Version 2. x, this standard does not include tentative messages The messages in Version 3 haveundergone testing for validity and interoperability and are considered to be permanent. amendments tothe standard may change the meaning of reserved bits or provide additional clarifying text, but no changeswill be made in the data fields. Changes will require new messages to be developed. In addition to themessages described in the current standard the committee continues to develop new messages whichare described in separately published amendments and periodically gathered into a new edition of thestandard. RTCM 10403x for dgNSS services is proving useful in supporting highly accurate differentialand kinematic positioning as well as a wide range of navigation applications worldwideNote that Version 3 messages are not compatible with Version 2. x. Since many receivers have beendesigned and programmed for use with Version 2. x messages, rtCm is maintaining both standards0402 3 and 10403, 3 as" standardsVersion 3.0The initial edition consisted primarily of messages designed to support real-time kinematic (RTK)operations. The reason for this emphasis is that rtk operation involves broadcasting a lot of informationand thus benefits the most from an efficient data format. Version 3.0 provided messages that supportGPS and gloNaSs rTK operations including code and carrier phase observables antenna parametersand ancillary system parametersVersion 3. 1(RTCM Standard 10403.1:The next edition, Version 3. 1 (RTCM Standard 10403. 1), incorporated GPS Network Corrections, whichenable a mobile receiver to obtain accurate rtk information valid over a large area. In addition, new GPSand GLoNaSS messages provide orbital parameters to assist in rapid acquisition a Unicode text messageis also provided for the transmission of textual data. Finally a set of messages are reserved for vendorswho want to encapsulate proprietary data in their broadcasts the gps Network Corrections enable amobile receiver to obtain accurate rtk information valid over a large area. the network rtk correctioninformation provided to a rover can be considered as interpolated corrections between the referencestations in the rtk network this interpolation is not perfect and varies with the actual conditions of theatmosphere. A residual interpolation error has to be expected. With sufficient redundancy in the RtKnetwork, the network server process can provide an estimate for residual interpolation errors. Suchquality estimates may be used by the rover to optimize the performance of rtk solutions The values maybe considered by the rover as a priori estimates only with sufficient tracking data available the rovermight be able to judge residual geometric and ionospheric errors itselfVersion 3. 1. Amendment 1:Amendments 1 was an extensive addition that adds rtcm messages containing transformation data andinformation about Coordinate reference Systems. For rtCm data supporting a rtk service, coordinatesare measured within the itrf or a regional realization surve yors and other users of rtk services mustnormally present their results in the coordinates of local datums. Therefore, coordinate transformationsare necessary. by having RTCM messages that contain transformation data and information about theCoordinate reference systems the users of the rtk service can obtain their results in the desired datumwithout any manual operations. the rtk service providers can then ensure that current information forthe computation of the transformations is always used. the convenience of this method will promote theacceptance of rtK servicesVersion 3. 1. amendment 2:Amendment 2 added residual error messages to support the use of Non-Physical or Computed referenceStations in a network rtk environmentVersion 3. 1. amendment 3:Amendment 3 addressed differences in the way gnss receiver manufacturers have implemented carrierphase encoding of some Version 3 messages so that carrier phase observations are in phase for all carrierphases of a specific frequency i e. they correct for quarter cycle phase shifts. others retain the quartercycle offset between the carrier phase observations in the data. this amendment documents the waydifferent manufacturers have handled the phase shift issue and prescribes a uniform approach for futureproducts.∨ersiⅰon3.1, Amendment4:Amendment 4 added sections 3.5.13 on glONASS Network rtK Correction Messages and 3.5. 14 on FKPNetwork Rtk Correction Messages Related revisions were also made elsewhere in the document.Version 3. 1. amendment 5Amendment 5 added section 3. 5. 12 on State Space Representation related revisions are also madeelsewhere in the document, along with some editorial correctionsVersion 3. 2(RTCM Standard 10403.2)Version 3.2 consolidates Version 3. 1 and all five amendments into a new edition, and it adds MultipleSignal Messages (MSM)as well. the Multiple Signal Message (MSm)format generates receiverobservables in the same way for all included satellite systems. the messages include compact and fullmessages for Pseudorange, PhaseRange, Carrier to Noise Ratio (standard and high resolution), andPhaseRangeratea table near the beginning of the standard lists which messages were included in each separate editionand amendment, so it should not be necessary for users to refer to older versions. Multiple signalMessages are a generic format that will be followed for all GNSs systems. version 3 originally consisted ofmessages for GPS and GLONASS, each in their own format Now with the imminent addition of signals forBeiDou, Galileo, and QZSS, as well as new signals provided by modernized GPS and GloNASS satellitesthe need for a consistent generic format became evident. service providers and users are urged to migrateto the MsM messages to make it easier to accommodate new gNss services(See The RTCM Multiple Signal Messages: A New Step in GNSS Data Standardization")Another newmessage is the gloNaSS Bias Information message. This message provides information which is intendedto compensate for the first-order inter-frequency phase range biases introduced by the reference receivercode- phase biasVersion 3.2, Amendment 1:Added Galileo F/NAv Satellite Ephemeris Data(msg. 1045 )and Bds MSM(msgs. 1121-1127)Version 3.2 amendment 2Added qzss ephemeris(msg. 1044 )and QZss MSm (msgs. 1111-1117Version 3. 3(RTCM Standard 10403.3)This new edition adds Satellite-Based Augmentation System Multiple Signal Messages to previouslydopted messages for GPS, GLONASS, Galileo, and QzssA new ephemeris message has been added for BeiDou(BDS)and a new I/NAV ephemeris message hasbeen added for Galileo. The new edition also reserves 100 messages be used exclusively by sc104 fornew message developmentFinally, the new edition makes consolidates previous amendments and makes numerous editorialImprovementsNavstar GPS Service, Version 2. x. Service providers and vendors represented on the scco000c30z1O2co00c30Contentsco00c30

这是修改了bug的版本，目前已经在stm32f407zgt6上、msp430F5529上仿真过。

一种用于卡尔曼Kalman滤波的捷联惯性导航解算，输出位置、姿态、速度等误差曲线。