dataCMACAST1.9产品目录结构说明文档

资料内容仅供您学习参考，如有不当或者侵权，请联系改正或者删除。

北京市工业产品标准登记申请登记表企业名称( 盖章) : 企业法人代表: 企业地址: 北京市海淀区知春路邮编: 100086 组织代码:资料内容仅供您学习参考，如有不当或者侵权，请联系改正或者删除。

填表日期: 06月13日填表人: 负责人: 联系电话: 82665082资料内容仅供您学习参考，如有不当或者侵权，请联系改正或者删除。

L64Q/HD北京XXX科技有限公司企业标准Q/HDZTYO001-数据采集卡( 器)-06-05发布 -06-20实施北京XXX科技有限公司发布Q/HDZTYO001-前言本标准的编写符合GB/T1.1- 《标准化工作导则第1部分标准的结构和编写规则》编写。

本标准根据国家标准GB/T9813- 《微型计算机通用规范》拟制。

本标准由北京XXX科技有限公司提出.本标准起草单位: 北京XXX科技有限公司。

本标准主要起草人: 章磊。

本标准 06月首次发布。

资料内容仅供您学习参考，如有不当或者侵权，请联系改正或者删除。

资料内容仅供您学习参考，如有不当或者侵权，请联系改正或者删除。

Q/HDZTYO001-数据采集卡( 器)1 范围本标准规定了数据采集卡( 器) 的要求、试验方法、检验规则及标志、包装、运输、贮存。

本标准适用于XXX数据采集产品( 以下称: 本产品) 。

2 规范性引用文件下列文件中的条款经过本标准的引用而成为本标准的条款。

凡是注日期的引用文件, 其随后所有修改单( 不包括勘误的内容) 或修订均不适用于本标准, 然而, 鼓励根据本标准达成协议的各方研究是否可使用这些文件的最新版本。

凡是不注日期的引用文件, 其最新版本适用于本标准。

GB 191- 包装储运图示标志( eqvISO/IEC646-1991)GB/T2421-1999 电工电子产品环境试验规程第1部分: 总则( eqvIEC68-1: 1988) GB/T2422-1995 电工电子产品环境试验规程术语( eqvIEC68-5-2: 1990)GB/T2423.1-1989 电工电子产品环境试验规程试验A: 低温试验方法( eqvIEC68-2-1: 1974)GB/T2423.2-1989 电工电子产品基本环境试验规程试验B: 高温试验方法( eqvIEC68-2-2: 1974)GB/T2423.3-1993 电工电子产品基本环境试验规程试验Ca: 恒定湿热试验( eqvIEC68-2-3: 1984)GB/T2423.5-1995 电工电子产品环境试验第二部分: 试验方法试验Ea和导则: 冲击( eqvIEC68-2-27: 1987)GB/T2423.6-1995 电工电子产品环境试验第二部分: 试验方法试验Eb和导则: 碰撞( eqvIEC68-2-29: 1987)资料内容仅供您学习参考，如有不当或者侵权，请联系改正或者删除。

你CMACAST数据处理服务器配置使用说明一数据环境配置首先应该确认处理程序获取原始数据的方式，处理程序获取原始数据的方式有FTP和虚盘方式两种：FTP方式：从卫星接收的数据存储在处理程序可以访问的FTP服务器上。

虚盘方式：从卫星接收的数据存储在处理程序可以访问的虚拟硬盘或者本地硬盘上。

注意：FTP访问方式一定要确保有访问和读取权限。

二处理程序安装下载压缩包到本地进行解压。

将解压所得处理程序文件夹放在任意硬盘根目录下待用。

注意：1、处理程序文件夹是指包含：bin 、datatran、ini、localxml、log等子文件夹的文件夹。

2、务必将此文件夹直接放在硬盘根目录下使用。

存储路径太深容易导致处理程序无法正常运行。

三系统配置在确认第一步和第二步完成后，下面开始处理程序的配置工作。

3.1启动初始化配置1 打开bin文件夹，如下图所示：2 找到MicapsDataServerConfig.exe程序，启动该程序打开如下图所示窗口3 点击顶部菜单项打开如下图所示界面3.2 FTP方式获取数据如果“一、数据环境配置”中选择的数据访问方式为FTP方式，访问方式中选择FTP , 输入FTP服务器的IP地址、FTP端口、FTP用户名、FTP密码。

如下图所示：注意：1 确保所输入的内容可以正确登录FTP服务器并且可以读取数据。

最好通过dos方式进行验证，确认FTP服务器可用后再进行配置。

2 通过DOS登录FTP服务器查看登录后的目录是否为下发数据根目录,如果不是需在根目录中输入对应的目录。

确保登录FTP后可以正确访问数据。

例如：登录FTP服务器后，显示有cmacast文件夹，该文件夹下才为数据路径。

就需要在根目录中输入cmacast目录（如上图图所示）。

对每类数据和每类数据包含的数据源项进行逐一设置。

设置完成后一定要点击保存按钮，否则进行的设置无法保存。

3 如果登录的FTP服务器为linux服务器，所设置的根目录开头不要使用斜杠（/）,否则无法正确进入要访问的目录。

中国气象局卫星广播系统( CMACast)设计王春芳;李湘;陈永涛;蒋克俭【期刊名称】《应用气象学报》【年(卷),期】2012(023)001【摘要】Due to broad coverage, low-cost user equipment and easy installation, data broadcast system based on commercial communication satellite has been considered to be the most effective way for data dissemination worldwide. CMA has implemented three satellite broadcast systems, PCVSAT, DVB-S and FENGYUN-Cast since 1998. PCVSAT and DVB-S, which are Ku band systems covering China and surrounding area, are primarily used to distribute land and air based observation data and products. FENGYUNCast, which is a C-band system covering Asia and part of the south-western Pacific area, is primarily used to distribute space-based observation data and derived products from Fengyun series satellites of China. FENGYUNCast becomes part of GEONETCast Centre of GENONETCast Network in Asia-Pacific region in 2008. Currently PCVSAT, DVB-S and FENGYUNCast have 2400, 700 and 200 users respectively.The coexistence of three broadcast system causes inefficiency and inconvenience to both CMA and users. In 2008, CMA started to build a new system, CMACast, to consolidate the services and users of the three systems together. CMACast is a multimedia dissemination system based on the second-generation Digital Video Broadcast (DVB-S2) technologywith both file and multimedia transmission capability, employing a whole 36 MHz C-band transponder of AsiaSat-4 and the transmission capacity can reach up to 70 Mb-ps. Besides high data rate, CMACast is expected to enhance user management and data exchange cooperation with other regional GEONETCast Network Centres (GNC), including EUMETCast and GEONETCast Americas.CMACast is not only the main component of CMA national and international communication system, but also the main component of WMO IGDDS and GEONETCast. The infrastructural, main function and key technology of CMACast and its comparison between PCVSAT, DVB-S, FENGYUNCast, EUMETCast and GEONETCast A-mericas are introduced. Infrastructural introduction includes system architecture, coverage and capacity. Main function includes file broadcast, multimedia broadcast, data exchange, user management and data reception. Key technology includes DVB-S2 standard, bandwidth sharing mechanism and dynamic data encryption mechanism. The comparison result indicates that CMACast is a leading satellite data broadcast system in the world with broad coverage, advanced technology and multiple functions.CMACast is on trail operation in the middle of 2011 and will operate simultaneously together with PCVSAT,FENGYUNCast and DVB-S from June to October in 2011, when all the users of the current three systems will transit to CMACast. After that, the current three systems will be closed and CMACast will be the only operating data broadcast system of CMA.%CMACast是中国气象局基于DVB-S2标准的新一代卫星数据广播系统,使用亚洲卫星4号星一个完整的C波段转发器对中国及亚太地区进行气象资料、卫星遥感资料及流媒体视频的广播.该文详细介绍了CMACast的系统结构、主要功能和关键技术,并与中国气象局现有的3个广播系统PCVSAT,DVB-S和FENGYUNCast以及EUMETCast,GEONETCast Americas进行了比较.比较结果表明:CMACast覆盖面广,技术领先,功能强大,是目前世界领先的卫星数字广播系统.预计2012年初CMACast全面建成并投入使用,CMACast系统建成后,将全面整合PCVSAT,DVB-S和FENGYUNCast 3个系统的业务和用户,成为中国气象局唯一的广播系统,并作为GEONETCast的亚洲区域中心,向亚太地区进行GEOSS数据的广播.【总页数】8页(P113-120)【作者】王春芳;李湘;陈永涛;蒋克俭【作者单位】国家气象信息中心,北京100081;国家气象信息中心,北京100081;国家气象信息中心,北京100081;国家气象信息中心,北京100081【正文语种】中文【相关文献】1.中国气象局卫星广播系统(CMACast)主站播发平台的设计 [J], 刘然;蒋克俭;胡英楣2.浅谈中国气象局卫星广播系统（CMACast）的设计 [J], 刘然;李春来;蒋克俭;陈永涛3.卫星广播系统CMACast省级接收站缺收数据补调服务的设计与实现 [J], 韩书丽;谭小华;李湘;王鹏4.中国气象局卫星数据广播系统CMACast简介 [J], 吴玲;侯俊5.中国气象局卫星数据广播系统CMACast简介 [J], 吴玲;侯俊因版权原因，仅展示原文概要，查看原文内容请购买。

Package‘DSOpal’October12,2022Type PackageTitle'DataSHIELD'Implementation for'Opal'Version1.4.0Depends R(>=3.5),opalr(>=3.0),DSI(>=1.5),methodsDescription'DataSHIELD'is an infrastructure and series of R packages thatenables the remote and'non-disclosive'analysis of sensitive research data.This package is the'DataSHIELD'interface implementation for'Opal',which isthe data integration application for biobanks by'OBiBa'.Participant data,oncecollected from any data source,must be integrated and stored in a centraldata repository under a uniform model.'Opal'is such a central repository.It can import,process,validate,query,analyze,report,and export data.'Opal'is the reference implementation of the'DataSHIELD'infrastructure.License LGPL(>=2.1)URL https:///datashield/DSOpal/,https://datashield.github.io/DSOpal/,https://,https:///pages/products/opal/,https://,https:///ije/article/43/6/1929/707730,https:///ploscompbiol/article?id=10.1371/journal.pcbi.1008880 BugReports https:///datashield/DSOpal/issues/RoxygenNote7.2.1Encoding UTF-8Collate'DSOpal-package.R''OpalDriver.R''OpalConnection.R''OpalResult.R''datashield.aggregate.r''datashield.assign.r''mand.r''datashield.method.r''datashield.symbol.r''datashield.workspace.r''logindata.R''utils.R'NeedsCompilation no12dsAggregate,OpalConnection-method Author Yannick Marcon[aut,cre](<https:///0000-0003-0138-2023>), Becca Wilson[ctb](<https:///0000-0003-2294-593X>),OBiBa group[cph]Maintainer Yannick Marcon<************************>Repository CRANDate/Publication2022-10-0609:30:02UTCR topics documented:dsAggregate,OpalConnection-method (2)dsAssignExpr,OpalConnection-method (3)dsAssignResource,OpalConnection-method (4)dsAssignTable,OpalConnection-method (5)dsConnect,OpalDriver-method (6)dsDisconnect,OpalConnection-method (7)dsFetch,OpalResult-method (8)dsGetInfo,OpalResult-method (9)dsHasResource,OpalConnection-method (9)dsHasTable,OpalConnection-method (10)dsIsAsync,OpalConnection-method (11)dsIsCompleted,OpalResult-method (12)dsKeepAlive,OpalConnection-method (12)dsListMethods,OpalConnection-method (13)dsListPackages,OpalConnection-method (14)dsListProfiles,OpalConnection-method (14)dsListResources,OpalConnection-method (15)dsListSymbols,OpalConnection-method (16)dsListTables,OpalConnection-method (16)dsListWorkspaces,OpalConnection-method (17)dsRestoreWorkspace,OpalConnection-method (18)dsRmSymbol,OpalConnection-method (18)dsRmWorkspace,OpalConnection-method (19)dsSaveWorkspace,OpalConnection-method (20)logindata.opal.demo (20)Opal (21)Index22 dsAggregate,OpalConnection-methodAggregate dataDescriptionAggregate some data from the DataSHIELD R session using a valid R expression.The aggregation expression must satisfy the data repository’s DataSHIELD configuration.Usage##S4method for signature OpalConnectiondsAggregate(conn,expr,async=TRUE)Argumentsconn OpalConnection-class object.expr Expression to evaluate.async Whether the result of the call should be retrieved asynchronously.When TRUE (default)the calls are parallelized over the connections,when the connectionsupports that feature,with an extra overhead of requests.Examples##Not run:con<-dbConnect(DSOpal::Opal(),"username","password","https://") dsAssignTable(con,"D","SIM")dsAggregate(con,as.symbol("meanDS(D$WEIGHT)"))dsDisconnect(con)##End(Not run)dsAssignExpr,OpalConnection-methodAssign the result of an expressionDescriptionAssign a result of the execution of an expression in the DataSHIELD R session.Usage##S4method for signature OpalConnectiondsAssignExpr(conn,symbol,expr,async=TRUE)Argumentsconn OpalConnection-class object.symbol Name of the R symbol.expr A R expression with allowed assign functions calls.async Whether the result of the call should be retrieved asynchronously.When TRUE (default)the calls are parallelized over the connections,when the connectionsupports that feature,with an extra overhead of requests.ValueA OpalResult-class object.Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://")dsAssignExpr(con,"C",as.symbol("c(1,2,3)"))dsDisconnect(con)##End(Not run)dsAssignResource,OpalConnection-methodAssign a resourceDescriptionAssign a Opal resource in the DataSHIELD R session.Usage##S4method for signature OpalConnectiondsAssignResource(conn,symbol,resource,async=TRUE)Argumentsconn OpalConnection-class object.symbol Name of the R symbol.resource Fully qualified name of a resource in Opal.async Whether the result of the call should be retrieved asynchronously.When TRUE (default)the calls are parallelized over the connections,when the connectionsupports that feature,with an extra overhead of requests.ValueA OpalResult-class object.Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://")dsAssignResource(con,"D","SIM")dsDisconnect(con)##End(Not run)dsAssignTable,OpalConnection-methodAssign a tableDescriptionAssign a Opal table in the DataSHIELD R session.Usage##S4method for signature OpalConnectiondsAssignTable(conn,symbol,table,variables=NULL,missings=FALSE,identifiers=NULL,=NULL,async=TRUE)Argumentsconn OpalConnection-class object.symbol Name of the R symbol.table Fully qualified name of a table in Opal.variables List of variable names or Javascript expression that selects the variables of a table(ignored if value does not refere to a table).See javascript documentation:https:///en/latest/magma-user-guide/methods.html missings If TRUE,missing values will be pushed from Opal to R,default is FALSE.Ignored if value is an R expression.identifiers Name of the identifiers mapping to use when assigning entities to R(from Opal2.0).6dsConnect,OpalDriver-method Name of the column that will contain the entity identifiers.If not specified,the identifiers will be the data frame row names.When specified this column can beused to perform joins between data frames.async Whether the result of the call should be retrieved asynchronously.When TRUE (default)the calls are parallelized over the connections,when the connectionsupports that feature,with an extra overhead of requests.ValueA OpalResult-class object.Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://")dsAssignTable(con,"D","SIM")dsDisconnect(con)##End(Not run)dsConnect,OpalDriver-methodConnect to a Opal serverDescriptionConnect to a Opal server,with provided credentials.Does not create a DataSHIELD R session,only retrieves user profile.Usage##S4method for signature OpalDriverdsConnect(drv,name,restore=NULL,username=NULL,password=NULL,token=NULL,url=NULL,opts=list(),profile=NULL,...)dsDisconnect,OpalConnection-method7Argumentsdrv OpalDriver-class class object.name Name of the connection,which must be unique among all the DataSHIELDconnections.restore Workspace name to be restored in the newly created DataSHIELD R session.username User name in opal(s).password User password in opal(s).token Personal access token(since opal2.15,ignored if username is specified).url Opal url or list of opal urls.Can be provided by"opal.url"option.opts Curl options as described by httr(call httr::httr_options()for details).Can beprovided by"opal.opts"option.profile The DataSHIELD R server profile(affects the R packages available and theapplied configuration).If not provided or not supported,default profile will beapplied....Unused,needed for compatibility with generic.ValueA OpalConnection-class object.Examples##Not run:con<-dsConnect(DSOpal::Opal(),"server1","username","password","https://") condsDisconnect(con)##End(Not run)dsDisconnect,OpalConnection-methodDisconnect from a Opal serverDescriptionDisconnect from a Opal server and release all R resources.If a workspace ID is provided,the DataSHIELD R session will be saved before being destroyed.Usage##S4method for signature OpalConnectiondsDisconnect(conn,save=NULL)Argumentsconn OpalConnection-class class objectsave Save the DataSHIELD R session with provided ID(must be a character string).Examples##Not run:con<-dsConnect(DSOpal::Opal(),"server1","username","password","https://") condsDisconnect(con)##End(Not run)dsFetch,OpalResult-methodFetch the resultDescriptionFetch the DataSHIELD operation result.Usage##S4method for signature OpalResultdsFetch(res)Argumentsres OpalResult-class object.ValueTRUE if table exists.Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://")dsAssignExpr(con,"C",as.symbol("c(1,2,3)"))res<-dsAggregate(con,as.symbol("length(C)"))length<-dsFetch(res)dsDisconnect(con)##End(Not run)dsGetInfo,OpalResult-methodGet result infoDescriptionGet the information about a command(if still available).Usage##S4method for signature OpalResultdsGetInfo(dsObj,...)ArgumentsdsObj OpalResult-class class object...Unused,needed for compatibility with generic.ValueThe result information,including its status.Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://")dsAssignExpr(con,"C",as.symbol("c(1,2,3)"))res<-dsAggregate(con,as.symbol("length(C)"))dsGetInfo(res)dsDisconnect(con)##End(Not run)dsHasResource,OpalConnection-methodVerify Opal resourceDescriptionVerify Opal resource exist and can be accessible for performing DataSHIELD operations. Usage##S4method for signature OpalConnectiondsHasResource(conn,resource)10dsHasTable,OpalConnection-method Argumentsconn OpalConnection-class class object.resource The fully qualified name of the resource.ValueTRUE if the resource exists.Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://")dsHasResource(con,"SIM")dsDisconnect(con)##End(Not run)dsHasTable,OpalConnection-methodVerify Opal tableDescriptionVerify Opal table exist and can be accessible for performing DataSHIELD operations.Usage##S4method for signature OpalConnectiondsHasTable(conn,table)Argumentsconn OpalConnection-class class object.table The fully qualified name of the table.ValueTRUE if table exists.dsIsAsync,OpalConnection-method11 Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://")dsHasTable(con,"SIM")dsDisconnect(con)##End(Not run)dsIsAsync,OpalConnection-methodOpal asynchronous supportDescriptionList that Opal supports asynchronicity on all DataSHIELD operations.Usage##S4method for signature OpalConnectiondsIsAsync(conn)Argumentsconn OpalConnection-class class objectValueThe named list of logicals detailing the asynchronicity support.Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://")dsIsAsync(con)dsDisconnect(con)##End(Not run)12dsKeepAlive,OpalConnection-method dsIsCompleted,OpalResult-methodGet whether the operation is completedDescriptionGet the information about a command(if still available)and return TRUE if the command was completed successfully or not.Always TRUE for synchronous operations.Usage##S4method for signature OpalResultdsIsCompleted(res)Argumentsres OpalResult-class object.ValueA logical indicating the command completion.Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://")dsAssignExpr(con,"C",as.symbol("c(1,2,3)"))res<-dsAggregate(con,as.symbol("length(C)"))dsIsCompleted(res)dsDisconnect(con)##End(Not run)dsKeepAlive,OpalConnection-methodKeep connection with a Opal server aliveDescriptionMakes a dummy web service request.Usage##S4method for signature OpalConnectiondsKeepAlive(conn)Argumentsconn OpalConnection-class class objectExamples##Not run:con<-dsConnect(DSOpal::Opal(),"server1","username","password","https://") dsKeepAlive(con)dsDisconnect(con)##End(Not run)dsListMethods,OpalConnection-methodList methodsDescriptionList methods defined in the DataSHIELD configuration.Usage##S4method for signature OpalConnectiondsListMethods(conn,type="aggregate")Argumentsconn OpalConnection-class class objecttype Type of the method:"aggregate"(default)or"assign".ValueA data frame with columns:name,type(’aggregate’or’assign’),class(’function’or’script’),value,package,version.Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://")dsListMethods(con)dsDisconnect(con)##End(Not run)dsListPackages,OpalConnection-methodList packagesDescriptionList packages defined in the DataSHIELD configuration.Usage##S4method for signature OpalConnectiondsListPackages(conn)Argumentsconn OpalConnection-class class object ValueA data frame with columns:name,version.Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://") dsListPackages(con)dsDisconnect(con)##End(Not run)dsListProfiles,OpalConnection-methodList profilesDescriptionList profiles defined in the DataSHIELD configuration. Usage##S4method for signature OpalConnectiondsListProfiles(conn)Argumentsconn OpalConnection-class class objectValueA list containing the"available"character vector of profile names and the"current"profile(in casea default one was assigned).Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://")dsListProfiles(con)dsDisconnect(con)##End(Not run)dsListResources,OpalConnection-methodList Opal resourcesDescriptionList Opal resources that may be accessible for performing DataSHIELD operations.Usage##S4method for signature OpalConnectiondsListResources(conn)Argumentsconn OpalConnection-class class objectValueThe fully qualified names of the resources.Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://")dsListResources(con)dsDisconnect(con)##End(Not run)dsListSymbols,OpalConnection-methodList R symbolsDescriptionList symbols living in the DataSHIELD R session.Usage##S4method for signature OpalConnectiondsListSymbols(conn)Argumentsconn OpalConnection-class class objectValueA character vector.Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://")dsAssignTable(con,"D","SIM")dsListSymbols(con)dsDisconnect(con)##End(Not run)dsListTables,OpalConnection-methodList Opal tablesDescriptionList Opal tables that may be accessible for performing DataSHIELD operations. Usage##S4method for signature OpalConnectiondsListTables(conn)Argumentsconn OpalConnection-class class object ValueThe fully qualified names of the tables.Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://") dsListTables(con)dsDisconnect(con)##End(Not run)dsListWorkspaces,OpalConnection-methodList workspacesDescriptionList workspaces saved in the data repository.Usage##S4method for signature OpalConnectiondsListWorkspaces(conn)Argumentsconn OpalConnection-class class object ValueA data frame with columns:name,lastAccessDate,size. Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://") dsListWorkspaces(con)dsDisconnect(con)##End(Not run)18dsRmSymbol,OpalConnection-method dsRestoreWorkspace,OpalConnection-methodRestore workspaceDescriptionRestore workspace from the data repository.Usage##S4method for signature OpalConnectiondsRestoreWorkspace(conn,name)Argumentsconn OpalConnection-class class objectname Name of the workspace.Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://")dsListWorkspaces(con)dsRestoreWorkspace(con,"foo")dsDisconnect(con)##End(Not run)dsRmSymbol,OpalConnection-methodRemove a R symbolDescriptionRemoe a symbol living in the DataSHIELD R session.Usage##S4method for signature OpalConnectiondsRmSymbol(conn,symbol)Argumentsconn OpalConnection-class class objectsymbol Name of the R symbol.dsRmWorkspace,OpalConnection-method19 Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://")dsAssignTable(con,"D","SIM")dsRmSymbol(con,"D")dsDisconnect(con)##End(Not run)dsRmWorkspace,OpalConnection-methodRemove a workspaceDescriptionRemove a workspace on the data repository.Usage##S4method for signature OpalConnectiondsRmWorkspace(conn,name)Argumentsconn OpalConnection-class class objectname Name of the workspace.Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://")dsSaveWorkspace(con,"foo")dsListWorkspaces(con)dsRmWorkspace(con,"foo")dsListWorkspaces(con)dsDisconnect(con)##End(Not run)20logindata.opal.demo dsSaveWorkspace,OpalConnection-methodSave workspaceDescriptionSave workspace on the data repository.Usage##S4method for signature OpalConnectiondsSaveWorkspace(conn,name)Argumentsconn OpalConnection-class class objectname Name of the workspace.Examples##Not run:con<-dbConnect(DSOpal::Opal(),"server1","username","password","https://")dsSaveWorkspace(con,"foo")dsListWorkspaces(con)dsDisconnect(con)##End(Not run)logindata.opal.demo DataSHIELD login datafileDescriptionDataSHIELD login datafile based on Opal demo server,with CNSIM simulated data.The CNSIM datasets contain synthetic data based on a model derived from the participants of the1958Birth Cohort,as part of the obesity methodological development project.These datasets do contain some NA values.Note that the Opal demo server is rebuilt every day and is possibly not accessible.Opal21 DetailsField Description Type Noteserver Server/study name charurl Server/study URL char Opal demo URLuser User name charpassword User password chartable Table unique name char CNSIM tablesdriver Connection driver char OpalDriverReferenceshttps://Opal Create a Opal driverDescriptionConvenient function for creating a OpalDriver object.UsageOpal()Index∗datalogindata.opal.demo,20 dsAggregate,OpalConnection-method,2 dsAssignExpr,OpalConnection-method,3 dsAssignResource,OpalConnection-method,4dsAssignTable,OpalConnection-method,5 dsConnect,OpalDriver-method,6 dsDisconnect,OpalConnection-method,7 dsFetch,OpalResult-method,8dsGetInfo,OpalResult-method,9 dsHasResource,OpalConnection-method,9 dsHasTable,OpalConnection-method,10 dsIsAsync,OpalConnection-method,11 dsIsCompleted,OpalResult-method,12 dsKeepAlive,OpalConnection-method,12 dsListMethods,OpalConnection-method,13dsListPackages,OpalConnection-method,14dsListProfiles,OpalConnection-method,14dsListResources,OpalConnection-method,15dsListSymbols,OpalConnection-method,16dsListTables,OpalConnection-method,16 dsListWorkspaces,OpalConnection-method,17dsRestoreWorkspace,OpalConnection-method, 18dsRmSymbol,OpalConnection-method,18 dsRmWorkspace,OpalConnection-method,19dsSaveWorkspace,OpalConnection-method,20logindata.opal.demo,20Opal,2122。

矿产资源开发利用方案编写内容要求及审查大纲
矿产资源开发利用方案编写内容要求及《矿产资源开发利用方案》审查大纲一、概述
㈠矿区位置、隶属关系和企业性质。

如为改扩建矿山, 应说明矿山现状、
特点及存在的主要问题。

㈡编制依据
(1简述项目前期工作进展情况及与有关方面对项目的意向性协议情况。

(2 列出开发利用方案编制所依据的主要基础性资料的名称。

如经储量管理部门认定的矿区地质勘探报告、选矿试验报告、加工利用试验报告、工程地质初评资料、矿区水文资料和供水资料等。

对改、扩建矿山应有生产实际资料, 如矿山总平面现状图、矿床开拓系统图、采场现状图和主要采选设备清单等。

二、矿产品需求现状和预测
㈠该矿产在国内需求情况和市场供应情况
1、矿产品现状及加工利用趋向。

2、国内近、远期的需求量及主要销向预测。

㈡产品价格分析
1、国内矿产品价格现状。

2、矿产品价格稳定性及变化趋势。

三、矿产资源概况
㈠矿区总体概况
1、矿区总体规划情况。

2、矿区矿产资源概况。

3、该设计与矿区总体开发的关系。

㈡该设计项目的资源概况
1、矿床地质及构造特征。

2、矿床开采技术条件及水文地质条件。

© 2008–2011 Infinite Power Solutions, Inc. All rights reserved. Infinite Power Solutions®, THINERGY®, INFINERGY®, MEC®, and the Infinite Power Solutions, THINERGY , and INFINERGY logos are trademarks or registered trademarks of Infinite Power Solutions in various countries. All other names are the property of their respective owners. Information in this document supersedes and replaces all information previously supplied. All specifications are subject to change without notice.Features•Thin Form Factor – 170µm Thick •Capacity Options up to 1mAh •All Solid-State Construction •High Discharge Rate Capability •Ultra-Low Self-Discharge Rate •Industry-Leading Cycle Life •Fast Recharge •RoHS Compatible •Eco-Friendly/SafeApplications•Energy Harvesting Solutions/Self-Powered Systems •Remote/Autonomously Powered Wireless Sensors •Memory & Real Time Clock (RTC) Backup •Semi-Active RFID T ags•Smart Cards (Including Units with Displays/Biometrics)•Medical Devices•High Temperature Applications •Military/DoD & AerospaceBenefits•Lowest Cost of Ownership–No maintenance costs–Lasts the lifetime of the application–Can be recharged and reused over and over •Ideal energy storage solution for energy harvesting–Can be trickle-charged with no memory effect•Simple constant-voltage recharge with no current limiting required.Physical PropertiesGeneral DescriptionThe THINERGY ® MEC201 is a solid-state, flexible,rechargeable, thin-film Micro-Energy Cell (MEC ). This unique device substantially outperforms all other small form factor electrochemical energy storage technologies, includ-ing supercapacitors, printed batteries, and other thin-film batteries. The device is fabricated on a metal foil substrate to achieve its flexibility, thin profile, broad operating temper-ature range, and long life.The MEC is offered in a unique, patented package design that maximizes the active area of the cell and minimizes the device footprint to deliver the highest energy and power density of any energy storage element of its size. External terminals in the form of positive and negative nickel-plated tabs are located along the top edge of the cell for easy sol-dering to printed circuit boards (PCBs). The tabs are supported with a flex circuit for added strength and to keep them planar with the rigid or flex PCBs. Through-holeslocated in the terminal contacts allow the MECs to be aligned on solder posts for easy connection and cell stack-ing to create battery modules with higher capacity and current. These tabs also allow easy connection to both ter-minals from either side of the cell, which is important during automated assembly onto flex circuits and PCBs. The con-ductive metal tabs allow various connection methods including epoxies, anisotropic conductive film (ACF) materi-als, and solder. The cells can be oriented to stack in series (to multiply voltage) or in parallel (to multiply capacity and power).The active materials in the device include a Lithium Cobalt Oxide (LiCoO 2) cathode and a Li-metal anode. A solid-state electrolyte called LiPON (Lithium Phosphorus Oxynitride),with its high Li-ion conductivity, is used to provide superior power performance. The extremely low electron conductiv-ity within LiPON results in ultra-low self discharge, makingTHI NERGY ® MEC201Solid-State, Flexible, RechargeableThin-Film Micro-Energy Cell[a ct ua l s ize]Size:25.4mm x 25.4mm x 0.170mm [1.0in x 1.0in x 0.007 in]Mass:490mgthis technology ideal for applications where energy must be reliably stored for many years without the ability to recharge, or for low-power ambient energy harvesting charging solutions. In addition, this eco-friendly technology contains no toxic chemicals or heavy metals, providing industry-leading safety with absolutely no possibility for chemical leakage, thermal runaway or fire, as experienced with other Li-ion batteries using liquid or gel electrolytes. A proprietary flex-circuit encapsulation methodology is used to achieve the ultra-thin and flexible form factor and to ensure reliability and performance under harsh environ-mental conditions, far exceeding other micro-energy storage technologies.The thin form factor, rechargeability, and high discharge rate capability enable applications where conventional coin/button or primary thin batteries are not well suited. Due to its low internal cell resistance, the MEC offers superior charge acceptance, making it an ideal energy storage device for applications where extremely low current recharge sources are available, including various ambient energy harvesting methods. Pulsed or continuous currents as low as 1µA can be used to effectively recharge this device. The MEC recharges in seconds to minutes, depend-ing on its state of discharge and available charge current. MECs can be recharged using constant current, constant voltage, pulsed current, or pulsed voltage sources. Any charge voltage greater than cell voltage (not to exceed the maximum specified recharge voltage) will result in charging.A variety of charging methods can be used, such as direct connection to a power supply, wireless recharge via induc-tive coupling, or energy scavenging solutions that harvest kinetic, solar, RF, magnetic, or thermal energy.The low self-discharge rate results in decades of shelf life. With its recharge cycle stability, the device offers tens of thousands of recharge cycles for many years of use with no memory effects. The MEC201 provides an extremely safe, reliable, and low-cost energy storage solution that outper-forms any other micro-battery or capacitor solution. This component class device is intended to be designed in for the life of the product.SpecificationsParameterOptions (1)RatingConditionsMin Typ MaxCapacity (2)-70.7mAh C/2 Discharge Rate @ 25°C-10 1.0mAh Stored Energy (2)-710J -1014J Operating Temperature All –40°C +85°C (Note 3)Storage T emperature All–40°C+50°CCharge Time:to 80% State of ChargeS 15 Min 4.10V constant voltage recharge(min. peak available current of 10mA)P 10 Min to 90% State of ChargeS 20 Min P 15 MinMax. Continuous Discharge Current (Standard vs. Performance Grade)S 30mA ≥25°CP 40mA Internal ResistanceS 50Ω60Ω25°CP35Ω45ΩCycle Life-7100,00010% depth of discharge with typical application load (4)10,000100% depth of discharge with typical application load (4)-10100,00010% depth of discharge with typical application load (4)5,000100% depth of discharge with typical application load (4)Nominal Output Voltage 3.9V C/2 rateRecharge 4.10V 4.15VConstant voltage Shelf Life15 years25°CDischarge Cutoff Voltage (5)2.1VFor currents of 1mA up to maximum discharge rate 3.0VFor currents < 1mAAnnual Non-reversible Capacity Loss (6)1%, 3%, 6%25°C, 45°C, and 65°C respectively Annual Self-Discharge Rate (Charge Loss)(6)1%, 3%, 6%25°C, 45°C, and 65°C respectivelyNotes:1.See Ordering Information .2.MECs may be shipped in a partially-charged state. Full charging prior to use is recommended.3.Standard electrochemical degradation is proportional to temperature increase. Contact IPS for performance information regarding higher temperature applications up to 150°C.4.80% of rated capacity remaining @ 25°C.5.Discharging the cell below the specified discharge cutoff voltage will cause permanent battery damage.6.After first year.7.MECs cannot be used in reflow or infrared soldering processes. Hand or robotic soldering is required.Typical CharacteristicsFigure 1:Typical Discharge Curves @25°C (0.7mAh Standard Grade Cell)Figure 2:Typical Discharge Curves @25°C (0.7mAh Performance Grade Cell)Figure 3:Typical Discharge Curves @25°C (1.0mAh Standard Grade Cell)Figure 4:Typical Discharge Curves @25°C (1.0mAh Performance Grade Cell)Figure 5:Typical Maximum Current vs. Temperature — All Capacity OptionsFigure 6:Typical Charge Curve @ 25°C — All Capacity OptionsShelf Life and Self-Discharge CharacteristicsTypical energy storage devices such as batteries and super capacitors exhibit self discharge behavior that pre-vents them from being used in many applications where the stored energy must be retained for periods in excess of ten years or more. Temperature changes that occur in typ-ical applications also have a strong effect on the self-discharge rates of these devices, normally resulting in much higher self-discharge rates as temperature increases. Traditional energy storage devices that have acceptable self-discharge rates at room temperature can easily become unsuitable at elevated temperatures due to elevated self-discharge rates. In contrast, IPS MEC tech-nology consistently demonstrates world leading self-discharge behavior, allowing MECs to be used in place of traditional energy storage devices in applications where decades of use without maintenance are required.MECs have a distinct advantage over traditional energy storage devices in that they possess a solid state electro-lyte. This solid state electrochemical system prevents the high self-discharge rates and premature device failures found in other electrochemical systems using liquid electrolytes.Shelf life will be determined by the condition of the energy storage device as the open circuit voltage (OCV) decreases over time in the application environment. Device or application failure occurs when the cell voltage drops below the useable cutoff voltage of the application, or when the residual capacity at a given voltage level is no longer sufficient to perform a task demanded by the appli-cation without recharge being supplied.Figure7 shows the typical MEC state of charge as a func-tion of the open circuit voltage. Note that a great deal of MEC capacity is reserved between 3.9 and 4.0V.Figure 7:OCV as a Function of State of Charge at 25°CSelf-Discharge PerformanceIn applications where no external load is applied to the MEC, it will experience self-discharge exhibited by an observable decrease in the OCV that is measured on the cell. Figure8 shows a typical self-discharge curve gener-ated from MEC test data over one year of self-discharge at25°C. The self-discharge rate increases with tempera-ture, but remains lower than any other energy storage device.Figure 8:Typical Voltage Decay over One Year at 25°CFigure 9 shows an extrapolated ten year self-discharge curve. Extrapolation is used since no known failure mech-anism has been identified in MECs that would cause the discharge curve to deviate from observed normal dis-charge behavior. As noted previously, the MEC capacity islargely reserved in the voltage region between 3.9 and 4.0V. This demonstrates that the MEC capacity has been reduced by only a fraction, even after ten years of storage at room temperature. Figure 10 shows the extrapolated remaining MEC capacity after 10 years of storage time.Figure 9:Ten-Year Extrapolated Voltage Decay at 25°CFigure 10:Extrapolated Ten-Year Remaining Capacity at 25°CPackage DimensionsFigure 11:Front and Side ViewsPCB Land Pattern DimensionsFigure 12:PCB Land PatternOrdering InformationThe complete IPS part number is as follows:MEC 201 - 10 PRelated DocumentsRelated ProductsAvailable Development ToolsFor more information on this and other IPS battery products, visit the IPS web site, or contact us at 303-749-4800 or **********************.Infinite Power Solutions, Inc.11149 Bradford RoadLittleton, Colorado 80127 USA303-749-4800Document DescriptionAN1014A Guide to Handling, Connecting, and Charging THINERGY ® MEC200-Series Micro Energy Cells .P/N DescriptionCapacity Current Voltage MEC202Micro-Energy Cell (25.4mm x 50.8mm) 1.7–2.5mAh 75–100mA 4V MEC220Micro-Energy Cell (25.4mm x 12.7mm)300–400µAh 10–15mA 4V MEC225Micro-Energy Cell (12.7mm x 12.7mm)130µAh5–7mA4VP/N DescriptionADPApplication Development Platform(includes three PCB-mounted MEC devices. Additional PCB-mounted MEC devices can be ordered.)IPS-EVAL-EH-01Universal Energy Harvesting Evaluation KitIdeal for developing and evaluating various energy harvesting solutions for self-powered applications. Contains THINERGY MEC, Maxim MAX17710 power management IC, and solar cell. Supports any externally connected AC or DC energy harvester.THI NERGY ®Micro-Energy CellFamilyModel:201=25.4 mm x 25.4 mm*[1.0 in x 1.0 in]*Min. Capacity:10= 1.0mAh 7=0.7mAhMax. Discharge Current:*P =Performance Grade S =Standard Grade*See Specifications section for ratings.Grade:[blank ]=Production ES =EngineeringSample *Does not include connection tabs. T otal dimensions of supported tab area is 11.2mm x 2.5mm along one edge of device.。

附件：中国气象局CMACast广播节目表（试行）中国气象局预报与网络司国家气象信息中心二○一一年十一月前言中国气象局卫星数据广播系统（CMACast）是中国气象局气象数据和产品分发的主渠道，是中国气象局气象信息传输业务的重要组成部分。

《中国气象局CMACast广播节目表》依据国内外各级气象业务需求及播发策略，编排了各类气象资料的播发计划。

该节目表主要包括广播通道划分和广播资料目录两部分内容。

其中，广播通道划分部分，主要划分了CMACast的广播通道和目录，并概括描述了各通道播发数据的类型；广播资料目录部分，主要描述了各通道的组成及目录结构，并详细介绍了各通道播发数据的内容。

《中国气象局CMACast广播节目表》是中国气象局卫星数据广播系统业务运行和管理的依据，也是全国各级气象台站、行业部门及国外所有CMACast接收站接收和应用气象数据的参考依据。

本节目表由中国气象局预报与网络司组织，国家气象信息中心牵头编写。

参加编写单位还有：国家气象中心、国家气候中心、国家卫星气象中心、气象探测中心等单位。

在此对各单位的参与及支持表示感谢！中国气象局预报与网络司二○一一年十一月目录前言 .................................................................................................. 错误！未定义书签。

目录 (3)第1章CMACast广播通道划分 (7)第2章CMACast广播资料目录 (13)1.应急通道组 (13)1.1.应急通道（EMERG_001） (16)2.警报和预警信息通道组 (17)2.1.警报通道（WARNING_001） (19)3.常规资料通道组 (20)3.1.常规资料通道（MSG_001） (21)4.国内自定义格式观测资料通道组 (23)4.1.自动站资料通道（OBS_DOM_AWS） (32)4.2.国内自定义格式资料公共通道（OBS_DOM_PUB） (35)5.数值预报产品通道组 (43)5.1.国家气象中心T213产品通道（NWP_NMC_T213） (47)5.2.国家气象中心T639高时效产品通道（NWP_NMC_T639G） (58)5.3.国家气象中心T639高分辨率产品通道（NWP_NMC_T639R） (61)5.4.国家气象中心GRAPES产品通道（NWP_NMC_GRAPES） (65)5.5.国家气象中心台风路径预报系统产品通道（NWP_NMC_TYPH） (69)5.6.国家气象中心GRAPES-RUC产品通道（NWP_NMC_GRAPES-RUC）705.7.国家气象中心全球集合预报产品通道（NWP_NMC_GEPS） (71)5.8.国家气象中心区域集合预报产品通道（NWP_NMC_REPS） (72)5.9.数值预报公共通道1（NWP_MCTR_001） (74)5.10.数值预报公共通道2（NWP_MCTR_002） (88)5.11.数值预报公共通道3（NWP_MCTR_003） (89)6.天气雷达资料通道组 (91)6.1.北京雷达资料通道（RADA_BEPK） (96)6.2.天津雷达资料通道（RADA_BETJ） (98)6.3.河北雷达资料通道（RADA_BESZ） (99)6.4.山西雷达资料通道（RADA_BETY） (103)6.5.内蒙雷达资料通道（RADA_BEHT） (107)6.6.辽宁雷达资料通道（RADA_BCSY） (112)6.7.吉林雷达资料通道（RADA_BECC） (116)6.8.黑龙江雷达资料通道（RADA_BEHB） (119)6.9.上海雷达资料通道（RADA_BCSH） (126)6.10.江苏雷达资料通道（RADA_BENJ） (128)6.11.浙江雷达资料通道（RADA_BEHZ） (133)6.12.安徽雷达资料通道（RADA_BEHF） (138)6.13.福建雷达资料通道（RADA_BEFZ） (144)6.14.江西雷达资料通道（RADA_BENC） (148)6.15.山东雷达资料通道（RADA_BEJN） (152)6.16.河南雷达资料通道（RADA_BEZZ） (157)6.17.湖北雷达资料通道（RADA_BCWH） (162)6.18.湖南雷达资料通道（RADA_BECS） (167)6.19.广东雷达资料通道（RADA_BCGZ） (172)6.20.广西雷达资料通道（RADA_BENN） (180)6.21.海南雷达资料通道（RADA_BEHK） (186)6.22.四川雷达资料通道（RADA_BCCD） (188)6.23.重庆雷达资料通道（RADA_BECQ） (194)6.24.贵州雷达资料通道（RADA_BEGY） (196)6.25.云南雷达资料通道（RADA_BEKM） (201)6.26.西藏雷达资料通道（RADA_BELS） (206)6.27.陕西雷达资料通道（RADA_BEXA） (210)6.28.甘肃雷达资料通道（RADA_BCLZ） (215)6.29.青海雷达资料通道（RADA_BEXN） (219)6.30.宁夏雷达资料通道（RADA_BEYC） (221)6.31.新疆雷达资料通道（RADA_BCUQ） (223)6.32.雷达资料公用通道（RADA_PUB） (231)7.卫星资料通道组 (252)7.1.FY2D 1级数据S-VISSR数据流通道（SATE_FY2D_SVS） (259)7.2.FY2E 1级数据S-VISSR数据流通道（SATE_FY2E_SVS） (259)7.3.FY2D 1级标称数据通道（SATE_FY2D_NOM） (260)7.4.FY2E 1级标称数据通道（SATE_FY2E_NOM） (260)7.5.FY3A中国及周边高时效1级数据通道（SATE_FY3A_L1） (260)7.6.FY3B中国及周边高时效1级数据通道（SATE_FY3B_L1） (262)7.7.FY2D 2、3级产品通道（SATE_FY2D_L2L3） (262)7.8.FY2E 2、3级产品通道（SATE_FY2E_L2L3） (270)7.9.FY3A中国及周边高时效2、3级产品通道（SATE_FY3A_L2L3） (279)7.10.FY3B中国及周边高时效2、3级数据通道（SATE_FY3B_L2L3） (285)7.11.卫星资料公共通道1（卫星中心接收）（SATE_MULTI_001） (285)7.12.卫星资料公共通道2（GTS接收）（SATE_MULTI_002） (289)7.13.卫星资料公共通道3（EUMETSAT接收）（SATE_MULTI_003） (290)7.14.FY3A VIRR 1级数据通道（SATE_FY3A_VIRR1） (297)7.15.极轨卫星数据通道（SATE_POES_001） (297)8.预报服务产品通道组 (301)8.1.天气预报服务产品通道（SEVP_WE_001） (303)8.2.海洋气象预报服务产品通道（SEVP_OC_001） (308)8.3.气候预报服务产品通道（SEVP_CL_001） (312)8.4.农业气象服务产品通道（SEVP_AG_001） (314)8.5.大气成分预报服务产品通道（SEVP_EN_001） (328)8.6.传真图通道（SEVP_FAX_001） (329)9.其它资料通道组 (334)9.1.其它资料通道（OTHE_001） (334)10.省通道组 (335)10.1.北京通道（PROV_BEPK） (339)10.2.天津通道（PROV_BETJ） (341)10.3.河北通道（PROV_BESZ） (342)10.4.山西通道（PROV_BETY） (344)10.5.内蒙通道（PROV_BEHT） (345)10.6.辽宁通道（PROV_BCSY） (346)10.7.吉林通道（PROV_BECC） (348)10.8.黑龙江通道（PROV_BEHB） (349)10.9.上海通道（PROV_BCSH） (351)10.10.江苏通道（PROV_BENJ） (352)10.11.浙江通道（PROV_BEHZ） (354)10.12.安徽通道（PROV_BEHF） (355)10.13.福建通道（PROV_BEFZ） (356)10.14.江西通道（PROV_BENC） (359)10.15.山东通道（PROV_BEJN） (360)10.16.河南通道（PROV_BEZZ） (362)10.17.湖北通道（PROV_BCWH） (364)10.18.湖南通道（PROV_BECS） (365)10.19.广东通道（PROV_BCGZ） (366)10.20.广西通道（PROV_BENN） (369)10.21.海南通道（PROV_BEHK） (371)10.22.四川通道（PROV_BCCD） (372)10.23.重庆通道（PROV_BECQ） (373)10.24.贵州通道（PROV_BEGY） (375)10.25.云南通道（PROV_BEKM） (376)10.26.西藏通道（PROV_BELS） (378)10.27.陕西通道（PROV_BEXA） (379)10.28.甘肃通道（PROV_BCLZ） (381)10.29.青海通道（PROV_BEXN） (382)10.30.宁夏通道（PROV_BEYC） (384)10.31.新疆通道（PROV_BCUQ） (385)11.部门外通道组 (388)11.1.飞控中心通道（SVC_FKZX） (388)12.国外通道组 (390)12.1.平壤通道（INT_DKPY） (390)12.2.越南通道（INT_VNNN） (391)12.3.蒙古通道（INT_MNUB） (392)13.业务通知通道组 (393)14.EUMETSAT通道组 (394)14.1.EUMETSAT通道1（EUM-1） (394)14.2.EUMETSAT通道2（EUM-2） (396)第1章CMACast广播通道划分CMACast广播通道划分为14个通道组，每个通道组包括1个或多个通道，具体通道划分见表1.1。

Series 09VR9mm Panel Potentiometer▪ Miniature 9 mm package size ▪ Rotational life (5,000 cycles)▪ Wide temperature range (-10°C to +70°C) ▪ Mechanical travel options (280° and 300°) ▪ Variety of standard resistances and tapersApplications▪ Consumer portable electronics ▪ Commercial appliances▪ Instrument amplifiers and guitar effects ▪ Keyboards and synthesizers ▪ Communications equipmentOrdering Information Ordering InformationCode Spec.1280° 2300°Code Spec.**A2 10% Log A3 15% Log B1 linearC315% AntilogCodeSpec.MHorizontal/Side Mount Bushingless, PC Pins, 6.5mm HeightBHorizontal/Side Mount Sleeve Bushing, PC Pins, 6.5mm HeightS Horizontal/Side Mount Thread Bushing, PC Pins, 6.5mm HeightH Vertical/Rear Mount Thread Bushing, PC Pins K Vertical/Rear Mount Sleeve Bushing, PC Pins UVertical/Rear Mount Bushingless, PC PinsCode Spec.*15 15 mm 20 20 mm 25 25 mm 3030 mmCodeSpec.502 5kΩ 103 10kΩ 203 20kΩ 503 50kΩ 104 100kΩ 254 250kΩ 504 500kΩ 1051MΩ* See shaft trim options for available lengths on next page. ** Other JIS tapers are available. See charts.Code Spec.1SingleCodeSpec.N No Detent CCenter DetentCodeSpec.B Knurled (18 teeth) F Flatted LKnurled (40 teeth)SeriesElementTerminalConfigurationShaftLength Shaft Trim Mechanical TravelDetent Option Resistance CodeResistance Taper09VR 1 M 20F2N103B1Available Shaft Trim Combinations by Terminal Configuration And Shaft LengthShaft Trim Options Shaft 15mmlengthShaft 20mm length Shaft 25mmlengthShaft 30mmlength09VR1M Knurled (18 teeth) ••Flatted ••••Knurled (40 teeth) ••••09VR1B Knurled (18 teeth) ••Flatted •••Knurled (40 teeth) •••09VR1S Knurled (18 teeth) •Flatted ••Knurled (40 teeth) ••09VR1H Knurled (18 teeth) •Flatted ••Knurled (40 teeth) ••09VR1K Knurled (18 teeth) ••Flatted •••Knurled (40 teeth) •••09VR1U Knurled (18 teeth) ••Flatted ••••Knurled (40 teeth) ••••Electrical SpecificationsMin Typical Max Unit Total Resistance Tolerance-20 –+20 % Power Rating –+0.05 –watt Operating Voltage ––+20 VDC Residual Resistance –+300 –ΩSlider Noise ––+100 mV Insulation Resistance 250 VDC for 1 min. +100 MΩDielectric Strength 250 VAC for 1 min. no arcingTaper Linear and audio options (see charts)MechanicalTotal Mechanical Travel 280° ± 5°300° ± 5°Operating Torque 10 to 80 gf-cmStarting Torque 100 gf-cm max.Shaft WobbleBushingless With Bushing 0.8 x L/20mm p-p max.; L = Shaft Length 0.5 x L/20mm p-p max.; L = Shaft LengthShaft Push-Pull Strength 5 kgf for 3 sec. Stop Strength 3 kgf-cm min.Detent Position 280° travel 300° travel 140° ± 5° 150° ± 5°Detent Torque 30 to 300 gf-cm Rotational Life 5,000 cycles Panel Nut Tightening Torque 6 kgf-cmIP Rating 40Mounting Hardware One flat washer and one mounting hex nut supplied with bushing option Packaging Bulk. For Thread Bushing terminal (09VR1S, 09VR1H) furnish with washer and nut inseparate package.Weight 2 gramsEnvironmentalMin Typical Max Unit Operating Temperature-10 –+70 °C Storage Temperature -30 –+70 °CSoldering Conditions Wave SolderManual Solder Wash Preheat: 100°C max for 2 min max; Solder temperature: 260°C ± 5°C for 5 sec max.; No clean foam flux recommended350°C ± 5°C for 3 sec max.; Sn95Ag5 no clean solderNot recommendedMoisture Sensitivity Level 1ESD Classification (HBM) Not applicableAll testing is performed at room ambient conditions except as noted. Users should verify device actual performance in their specific applications .This product is compliant to RoHS3 Directive 2015/863 Amendments of Annex II on 31 March 2015, and REACH SVHC Directive EC 1907/2006 Amendments of Annex XIV & Annex XVII on 10 June 2022.Custom and value-added options available on request. Please contact your sales representative for additional information.Mechanical SpecificationsSeries 09VR1M Horizontal/Side Mount BushinglessSeries 09VR1U Vertical/Rear Mount Bushingless280° ROTATION 300° ROTATIONUnit: mmMechanical SpecificationsSeries 09VR1B Horizontal/Side Mount Sleeve BushingSeries 09VR1K Vertical/Rear Mount Sleeve Bushing280° ROTATION 300° ROTATIONUnit: mmMechanical SpecificationsSeries 09VR1S Horizontal/Side Mount with Threaded BushingSeries 09VR1H Vertical/Rear Mount with Threaded Bushing280° ROTATION 300° ROTATIONUnit: mmMechanical Specifications40 Tooth Knurl Shaft Trim Optiona18 Tooth Knurl Shaft Trim Option280° ROTATION300° ROTATION280° ROTATION300° ROTATIONUnit: mmElectrical Specification Series 09VR Taper Graphs。

If you need detailed product information, or help choosing the right product for your application, see our Interactive Catalog . Use the Interactive Catalog to access the most complete and up-to-date information available.The Interactive Catalog provides an extensive collection of product specifications, application data, and technical literature that can be searched based on criteria you select.This PDF catalog information was published in November 2000.Sensing and Control Honeywell Inc.11 West Spring Street Freeport, IL 61032/sensingSensing and ControlInteractive Catalog...Click this icon to try the Interactive Catalog.Interactive Catalog Supplements Catalog PDFsRocker Button SwitchesAbove panelFlushpanelUL/CSA Rating CodeElectrical RatingL19210amps-125,250,277VAC;1⁄4Hp-125VAC;1⁄2Hp-250,277VAC 3Amps-125VAC ‘‘L’’L19115amps-125,250,277VAC:1⁄2Hp-125VAC;1Hp-250,277VAC5amps-120VAC ‘‘L’’Application Note:Honeywell MICRO SWITCH does not recommend the use of silver cadmium oxide switch contacts in non-arcing loads.Non-arcing loads are generally loads less than 12volts and/or 0.5amp.TP switches use silver cadmium oxide contacts.For other options,contact the MICRO SWITCH Application Center at 1-800-537-6945.FEATURESɀ2and 3position pushbutton action ɀVarious button colors ɀ1,2,and 4pole circuitryɀFlush panel and above panel mountingɀTemperature range is from –65°F to +160°F (–54°C to +71°C)ɀUL recognized,CSA certified ɀCE approvedCONSTRUCTIONAbove panel mounting givesa distinctbutton appearance.Flush panel mount-ing presents a low button profile.TERMINAL CIRCUIT IDENTIFICATIONTerminal identifications are referred to in the order guides to indicate which circuits are made in each toggle position (i.e.,1-2indicates circuit closure through termi-nals 1and 2).One poleTwo poleFour poleToggle/RockersRocker Button SwitchesTypical two-pole flush panel translucent buttonswitchTypical one-pole above panel transparent button switch BUTTON OPTIONSButtons are removable and inter-changeable.They measure.87⍯⍥1.46⍯(22,1⍥37,1mm).Transparent(colorless plastic)buttonsaccept under-the-surface legend insertsfor station and function identification.Legend inserts are not furnished.Insertlegending can be done by your local sup-plier.Translucent(white plastic)buttons havea clear appearance.Colored(opaque plastic)buttons are ex-cellent for color coding switch functions.SWITCHES WITHOUT BUTTONSTo order switches without buttons,con-vert catalog listings shown in the orderguides.Substitute TP7for TP4and TP16above panel mounted switches;substi-tute TP8for TP201and TP12flush panelmounted switches.Order buttons sep-arately from the chart below.BUTTON ORDER GUIDEColor Catalog ListingTranslucent12PA6Transparent12PA4White*12PA5-WYellow*12PA5-YBlack*12PA5-BKGreen*12PA5-GRed*12PA5-RBlue*12PA5-BL*Opaque2-POSITION ORDER GUIDEFurnished with buttons.Catalog ListingsCircuits Made with Button at:Flush Panel Above PanelUL/CSA Elec.No.of Ident.Opposite Rating Rating Translucent Transparent Translucent Transparent Poles Lug Position Ident.Lug Code Code Button Button Button Button 1OFF2-3L19111TP201-21TP12-21TP216-21TP4-2 OFF*2-3L19221TP201-4———1-2*OFF L19221TP201-61TP12-6—1TP4-61-22-3L19111TP201-31TP12-31TP216-31TP4-31-2*2-3L19221TP201-81TP12-81TP216-8—2OFF2-3,5-6L19132TP201-22TP12-22TP216-22TP4-2 1-2,4-52-3,5-6L19132TP201-32TP12-32TP216-32TP4-31-2,4-5*2-3,5-6L19242TP201-82TP12-82TP216-82TP4-8 4OFF2-3,5-6,8-9,11-12L19154TP201-24TP12-2——OFF*2-3,5-6,8-9,11-12L1926——4TP216-4—1-2,4-5,7-8,10-112-3,5-6,8-9,11-12L19154TP201-34TP12-34TP216-34TP4-31-2,4-5,7-8,10-11*2-3,5-6,8-9,11-12L1926——4TP216-8—*These positions only are momentary.All others are maintained.Rocker Button Switches3-POSITION ORDER GUIDEFurnished with buttons.Circuits Made with Button at:UL/CSA Elec.No.of Ident.Lug Center Opposite Lug Rating RatingPoles Position Position Position Code Code1-2OFF2-3L19111TP201-11TP12-11TP216-11TP4-11-2*OFF2-3L19221TP201-51TP12-51TP216-51TP4-51-2*OFF2-3*L19221TP201-71TP12-71TP216-71TP4-7 1NONE**OFF2-3L19111TP201-211TP12-21—1TP4-21 NONE**1-22-3L19111TP201-311TP12-31—1TP4-31NONE**1-22-3*L19221TP201-511TP12-511TP216-511TP4-511-2*OFF NONE**L19221TP201-611TP12-611TP216-611TP4-611-2,4-5OFF2-3,5-6L19132TP201-12TP12-12TP216-12TP4-11-2,4-5*OFF2-3,5-6L19242TP201-52TP12-52TP216-52TP4-51-2,4-5*OFF2-3,5-6*L19242TP201-72TP12-72TP216-72TP4-7NONE**OFF2-3,5-6L19132TP201-212TP12-212TP216-212TP4-21 2NONE**1-2,4-52-3,5-6L19132TP201-312TP12-312TP216-312TP4-31 NONE**1-2,4-52-3,5-6*L19242TP201-5122TP12-5122TP216-5122TP4-5121-2,4-5*OFF NONE**L19242TP201-612TP12-612TP216-612TP4-611-2,4-51-2,5-62-3,5-6L19132TP201-10†2TP12-102TP216-102TP4-101-2,4-5*1-2,5-62-3,5-6L19242TP201-50†2TP12-502TP216-502TP4-501-2,4-5*1-2,5-62-3,5-6*L19242TP201-70†2TP12-702TP216-702TP4-701-2,4-5,OFF2-3,5-6L19154TP201-14TP12-14TP216-14TP4-17-8,10-118-9,11-121-2,4-5OFF2-3,5-6L19264TP201-54TP12-5—4TP4-57-8,10-11*8-9,11-121-2,4-5,OFF2-3,5-6L19264TP201-74TP12-74TP216-74TP4-77-8,10-11*8-9,11-12*NONE**OFF2-3,5-6,L19154TP201-214TP12-214TP216-214TP4-218-9,11-124NONE**1-2,4-52-3,5-6,L19154TP201-31—4TP216-314TP4-31 7-8,10-118-9,11-12NONE**1-2,4-52-3,5-6L19264TP201-51—4TP216-514TP4-51 7-8,10-118-9,11-12*1-2,4-5,OFF NONE**L19264TP201-614TP12-614TP216-614TP4-617-8,10-11*1-2,4-5,2-3,4-52-3,5-6,L19154TP201-10†4TP12-10—4TP4-107-8,10-118-9,11-121-2,4-5,2-3,4-52-3,5-6,L19264TP201-50†4TP12-504TP216-504TP4-507-8,10-11*7-8,11-128-9,11-121-2,4-5,2-3,4-52-3,5-6,L19264TP201-70†4TP12-704TP216-704TP4-707-8,10-11*8-9,11-12**These positions only are momentary.All others are maintained.**Operator is blocked from these positions.Switch becomes two position,with center being one extreme position.†Special on-on-on circuitry.See page123.Rocker Button SwitchesMOUNTING DIMENSIONS (For reference only)Panel cutoutOne poleTwo poleFour poleKey:0,0=mm0.00=inchesFlange mounting torque is 10–12in./lbs.Terminal screw mounting torque is 5in./lbs.max.。