INCA软件最新版操作手册

INAC基本操作方法-INCA硬件连接图ES690功能：数据连接LA3显示器：侧量发动机空然比1新项目建立1.1建立项目文件夹1.2建立项目ECU使用数据A2L、HEX(HEX是ECU内运行的数据，A2L是将hex数据在INCA中显示的转换文件。

1.3建立项目模版页1.4建立项目工作平台1.5建立工作平台选项1.5.1选择项目模版1.5.2选择项目使用数据A2L、HEX1.5.3选择项目使用硬件连接方式及名称1.5.4选择使用辅助仪器的硬件连接方式及名称1.5.5点击查找1.5.6程序自动查找到的硬件，点击ok进行连接1.5.7连接出错或找不到硬件可进行选择知否继续连接1.5.8检查IP地址是否正确。

1.5.9选择网络设置1.5.10输入IP地址1.5.11选择数据刷入ECU的选项，按Do it刷数据。

2．工作页的建立2.1测量参数的选择2.1.1选择所需的测量参数2.1.2选择所需的测量参数显示窗口类型2.1.3选择所需的map名2.1.4选择所需的map显示窗口类型2.1.5选择所需的变量参数2.1.6选择所需的变量参数显示窗口类型2.1.7工作页的测量与修改窗口2.1.9选择需要保存的工作页2.1.11点击Change改变工作页保存路径2.1.12导入以保存工作页2.1.13选择以保存的工作页3测量参数与台架的通讯3.1打开通讯界面3.2选择通讯波特率和通讯串口3.3选择通讯协议选项3.4通讯协议与台架有关4．Hex数据4.1.1保存当前工作页的hex数据4.1.2写入所需保存hex的文件名4.1.3新保存hex文件4.2.1冻结当前工作页的数据4.2.2写入冻结数据保存文件名4.2.3新冻结数据保存区域4.3.1改变当前工作页数据4.3.2选择所需改变数据名4.3.3工作页中新改变的数据4.4.1创建hex到硬盘中4.4.2选择新创建hex文件的名称与路径4.5.1从硬盘中导入hex文件4.5.2选择导入文件的路径与文件名4.6.1从csv文件中导入数据4.6.2选择需要导入csv数据的路径与文件名4.6.3选择所需导入cvs中的label名5．实验数据的测量与读取5.1.1测量数据记录5.1.2注意：记录的数据名必须在工作页内5.1.3停止测量5.1.4保存测量文件，可以输入必要信息以便以后查询。

INCA基础教程本人使用的INCA版本是V7.2.17，以软件自带的Demo为例记录INCA学习过程，主要包括测量与标定。

说明：INCA自带的Demo不需要连接任何真实的硬件，需要提前在路径中（D:\ETASData\INCA7.2\Data\Demo）确认是否存在“0400.hex”和“0400.a2l”文件。

目录一、基于Demo的测量与标定学习1.1 任务目标二、创建数据库（Database）2.1 创建新的数据库2.2 在数据库中创建顶层文件夹三、添加工作区（Workspace）3.1 创建一个工作区3.2 创建和分配一个项目（Project）3.3 配置硬件信息3.3.1 配置项目硬件：3.3.2 添加额为的VADI硬件组件：3.3.3 显示硬件状态并初始化设备：四、建立一个实验（Experiment）4.1 创建并分配一个实验4.2 运行实验4.3 选择实验中使用的变量4.4 配置实验的显示4.4.1 通过显示配置设置实验：4.4.2 改变变量的显示类型：4.4.3 更改YT示波器中的变量横坐标范围、颜色：4.4.4 更改YT示波器中的坐标轴分配：五、测量并记录（Measuring and Record）5.1 加载Lambda标定实验并进行测量5.2 利用示波器分析测量结果5.2.1 在示波器中停止显示5.2.2 移动时间轴5.2.3 增加显示器大小5.2.4 添加光标5.2.5 添加边界线5.3 手动创建记录器5.3.1 创建记录管理器5.3.2 向记录器中添加变量5.3.3 指定存储记录的文件一、基于Demo的测量与标定学习1.1 任务目标目标：通过标定λ值优化燃料在发动机中燃烧的方式，以减少整体燃料的消耗和排放。

λ值的含义是指在气缸内燃烧的空气与燃料的比值（空燃比），理论情况下1kg的燃料需要14.7kg的空气。

二、创建数据库（Database）2.1 创建新的数据库（1）选择界面左上角的数据库→新建；（2）在新建数据库对话框中输入数据库的名字“Tutorial”，然后点击OK。

INCA V6.2操作指南1、打开INCA V6.2 在INCA中新建folder文件2、为folder文件添加环境（experiment)、workspace、720.a21及720.hex 文件。

3、添加目标数据，若是hex文件选择“Read Hex file……”，若是目标数据是exp文件则选择“Import dateset"，然后选择数据路径。

4、点击图示打开按钮，选择目标数据。

选择目标数据后，然后点击OK。

5、点击，进入环境。

6、在环境下点击调取需求变量，然后再在空格内输入变量，譬如“Epm_nEng”，选择相应的标量，选择后该变量呈橘色显示，然后点击OK。

7、导入DCM必须在WP状态下才可，导入DCM在环境下选择Dataset-Variables-Read all calibrations from file，弹出选择对话框根据选择路径后，点击相应的DCM，然后点击“打开”。

8、数据完成后导出数据，若导出Hex文件，就选择Create Hex file，若导出exp文件就用Export Dataset9、连接硬件:由于当前主机厂所用诊断接头不是统一的标准诊断接头，目前我们的连接方式只是简单从581引出2颗线，标准接头见下图，项目经理一定建议主机厂按下图做标准诊断接头。

将581 的两颗线从针脚引出的7和2分别为7接K75、2接K53。

10、选择查找硬件接着点击，查找硬件，有可能原先是585、590按下图所示选择Remove。

接着弹出下图对话框选择是。

11、接着出现下图对话框，选中USB1，点击OK。

12、接着弹出硬件选择对话框，选择CCP_1。

13、点击进行初始化连接。

14、点击双圆柱，出现下图对话框，选择Flash programming，将数据刷进ECU。

15、接着弹出下图对话框，选择是。

16、选择720配置文件，若没有720配置文件需要重新配置，否则刷写不成功。

17、选择刷写波特率Baudrate，选择CAN 1MBaud，就是选择CAN 总线刷写，刷写速率1M。

INCA使用方法及.bin文件的生成Inca v7.1.0 使用方法安装时记得选择中文，安装完成后需要配置如下使用方法1、在1数据库对象上右键-添加-添加顶层文件夹2、给上一步新建的文件夹命名后在该文件夹上右键-添加-ECU项目（A2l）；会自动弹出窗口添加文件（A2l文件）,添加完后，会自动弹出继续添加文件（s19文件）先添加a2l然后自动跳出选择s193、添加完文件后，在顶层文件夹上右键-添加-工作区4、在'4项目设备上’点击'+’，按照如下操作上一步OK操作完，弹出如下，点OK每次'4项目设备上’点击'+’就会生成一个新的文件（自动命名在原始文件上序号递增，建议更改为自己熟悉的名称，防止混乱）（重命名是在'3数据集’上面去更改）5、双击工作区-弹框后点继续（有时候没弹框，会直接跳到实验的页面）（双击工作区-跟点击3实验的图标应该是一样的功能）6、变量选择选择完后点确认，选择的变量会出现在上2图的界面中（不知道为什么有时候不出现，可以在变量选择时-右键-进行操作）改完变量值后直接关闭窗口就行了，弹框时选择'是’ 保存要修改的值（或者在窗口最左边的工具栏上选择保存）7、导出s19文件8、打开j-flash (V6.88a)打开原始bin（0000）文件，然后选择菜单栏中的Edit->Delete range>删除默认S19文件标定区域（F000-FFFF）9、合并文件，选择菜单栏中的File->Merge data file->选择步骤7 生成的s19文件10、最后选择菜单栏中的File->Save data file as->将合并后的S19文件另存为一个新文件bin,点击保存-> starta ddress (hex) =0xE000 End address (hex) =0xFFFFF ->点击OK 生成新的bin文件(注意：我们一般选择的是WBD 带boot loader的文件合并文件要从0000-FFFFF）。

INCA6.2 使用说明天津同步动力有限公司尚震1.介绍本教程适用于使用INCA 的新手，INCA 主要特点：测量和标定。

使用此教程需要最基本的WINDOWS 操作能力。

1.1准备开始本教程必须保证系统装有INCA 软件。

本教程中的任务可以在演示模式下进行，这意味着你不需要任何实际硬件。

硬件模拟在ETK 测试设备和V A DI 测试设备。

该装置会随着INCA 软件安装。

确认0400.hex 和0400.a2l 这两个文件在<INCA base>\ETA SData\INCA6.2\Data\Demo 中。

最后请确认您使用本教程的计算机有一个互联网浏览器。

1.2建立一个DA TABA SE点击Database 选择new,然后输入工程的名字点击OK1.3 创建一个顶层文件夹点击Edi t->A dd->A dd to fol der输入文件夹名称并按回车键1.4 创建一个工作区单击Edi t->A dd->A dd fol der 并把文件夹命名为w orkspace选中w orkspac e 的文件夹，单击Edi t->A dd->Workspac e 并命名为OneETK1.5 添加一个工程先新建一Fol der 命名为004 并将其选中，单击Edi t->A dd->ECU proj ec t(A2L)然后添加\i nc a6.2\data\04001.6把工程添加到w orkspac e 中选中工作区OneETK,单击4 proj ec t/devi c e 下面打开按钮右边的选中 0400 单击OK单击 4 proj ec t/devi c e会出现许多设备，选中 ETKtestdevi c e 单击 OKINCA 界面会变成1.7添加V A DI 硬件组件下面的单击5 H ardw are选中ETK test devi c e 单击右键选中Insert选中V A DI test devi c e 单击OK然后会出现下面的界面关闭上面对话框返回硬件连接会显示然后 H ardw are->H ardware status会显示2.建立一个实验下面将学习如何将变量和窗口添加到实验中，并如何配置功能。

INCA Energy中文操作手冊本手冊適合 INCA V4.0以後版本Analyzer功能＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞PAGE 4 Point & ID ＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞ PAGE 12 Mapping ＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞ PAGE 14 Linescan ＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞ PAGE 16 儲存Project ＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞ PAGE 17 附註A: 能量校正＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞ PAGE 18 附註B: 執行Warm Up ＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞ PAGE 19 附註C: 執行Cooling Down ＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞ PAGE 20 附註D: 自我檢測＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞＞ PAGE 21捷東股份有限公司1. 樣品準備。

2. 放入SEM內觀察。

<JSM-5610圖例>a.設定高壓(Acc. Volt)後, HT ON, ,移動至欲分析位置。

b.設定工作距離(WD) =20mm(JSM5600/5610)=15mm(JSM6335/6340F)=10mm(JSM6500F)mm(JSM6700F)。

8=c.調整 Z 軸,使影像聚焦清晰並維持WD=20mm(JSM5600/5610)位置。

d.轉入EDS偵測器至設定位置。

3. 從Windows桌面按,開啟INCA軟體,或至START => PROGRAM => Oxford Instruments內執行。

導覽式視窗開啟。

4. INCA Energy有三大功能:5. Analyzer功能:a. 從Options內選 Microscope Control…,若有連線AutoColumn功能,則HV,WD及倍率資料會自動從SEM抓取,否則必須手動輸入,記得要按Enter。

incampro使用手册欢迎使用Incampro视频编辑软件。

本手册将为您提供详细的使用指南，帮助您快速上手并充分发挥Incampro的功能。

请按照以下步骤操作，以获得最佳的使用体验。

第一步：安装和启动1. 下载Incampro软件并运行安装程序。

2. 完成安装后，双击桌面图标启动Incampro。

第二步：界面导览一旦启动Incampro，您将看到主界面。

下面是主界面的几个重要部分的介绍：1. 工具栏：位于主界面的上方，包含各种操作按钮和快捷键，用于编辑和处理视频。

2. 视频预览窗口：位于主界面中央的大窗口，可以预览正在编辑的视频。

3. 时间轴：位于主界面底部的水平条形图，用于管理视频的时间线和编辑轨道。

4. 资源库：位于主界面的右侧，用于管理您的媒体文件，例如视频剪辑、音频剪辑和图像。

第三步：导入媒体文件在使用Incampro编辑视频之前，您需要导入您的媒体文件。

按照以下步骤进行操作：1. 点击资源库中的“导入”按钮。

2. 选择您希望导入的媒体文件，并点击“确定”按钮。

3. 导入的媒体文件将显示在资源库中。

第四步：编辑视频在Incampro中，您可以进行各种视频编辑操作，包括剪辑、修剪、添加特效等。

以下是一些常见操作的简要说明：1. 剪辑视频：将视频从时间轴中剪切并排列，以创建所需的视频序列。

通过拖动视频剪辑到时间轴上，并调整其位置和长度来进行剪辑。

2. 添加特效：Incampro提供各种特效选项，如过渡效果、滤镜、文字和动画等。

通过选择特效并将其应用于视频剪辑，您可以改善视频的外观和感觉。

3. 调整音频：您可以使用Incampro来调整视频中的音频轨道。

通过选择音频轨道并调整音量、淡入淡出等设置，您可以获得所需的音频效果。

第五步：导出视频在完成视频编辑后，您可以将其导出为常见的视频格式，如MP4、AVI、MOV等。

按照以下步骤导出视频：1. 点击工具栏中的“导出”按钮。

2. 在打开的导出设置窗口中，选择输出格式和目标文件夹。

INCA软件的使用与安装1. 简介INCA是一种用于汽车发动机控制系统开发和测试的软件套件。

它提供了一个用户友好的界面，方便用户进行系统参数配置、数据采集和分析等操作。

本文将介绍INCA软件的基本安装步骤和使用方法。

2. 安装步骤以下是安装INCA软件的步骤：1.在官方网站上下载INCA软件安装包。

2.运行安装包，选择合适的安装路径并接受软件许可协议。

3.选择要安装的组件，根据需要进行选择。

4.点击“安装”按钮开始安装过程。

5.等待安装完成后，点击“完成”按钮退出安装程序。

3. 软件界面INCA软件的主界面如下所示：INCA软件界面INCA软件界面界面上有多个功能区，包括菜单栏、工具栏和数据显示区。

用户可以根据需要调整界面布局和显示选项。

4. 软件使用4.1 参数配置在使用INCA软件进行汽车发动机控制系统开发和测试之前，需要先进行参数配置。

可以通过以下步骤进行参数配置：1.点击菜单栏中的“参数配置”选项。

2.在参数配置窗口中，选择要配置的参数，如发动机转速、燃油喷射量等。

3.配置参数值和范围，可以手动输入或导入外部文件。

4.点击“应用”按钮保存配置。

4.2 数据采集INCA软件支持对汽车发动机控制系统进行数据采集。

可以按照以下步骤进行数据采集：1.点击菜单栏中的“数据采集”选项。

2.在数据采集窗口中，选择要采集的数据信号，如发动机转速、燃料压力等。

3.配置采样率和采样时间，并选择保存路径。

4.点击“开始采集”按钮开始数据采集。

4.3 数据分析INCA软件提供了强大的数据分析功能，可以对采集的数据进行处理和分析。

可以按照以下步骤进行数据分析：1.点击菜单栏中的“数据分析”选项。

2.在数据分析窗口中，选择要分析的数据文件。

3.选择分析方法，如曲线拟合、统计分析等。

4.根据需要进行参数设置。

5.点击“开始分析”按钮开始数据分析。

5. 总结本文介绍了INCA软件的基本安装步骤和使用方法，包括参数配置、数据采集和分析等功能。

INCA 5.4 使用手册解释1.1总览和目标1。

1。

1介绍本文档介绍主要围绕测量和标定两个主要任务介绍各个实用的步骤，不要求有INCA的任何知识,但需要有使用windows系统的能力1。

1.2 准备在介绍该指导书之前，你需要准备如下系统(1) 必须要安装INCA系统软件(2）有A2L，HEX文件（3）确保系统有网页浏览器，因为。

HTM的文档需要实用网页浏览器打开1.1.3 INCA连接步骤（1）建立数据库,包括workspace,project,hardware，experiment(最好提前建好)(2）初始化硬件,连接设备，注意链接前要进行网络设置（utilities—〉ETAS networking setting—〉选default IP）（3) download数据到控制器(4）测量与标定1.1。

4 重要概念●测量任务（measuring task）：发动机的状态是通过传感器得知的，传感器能够测量发动机参数，传递给控制器得到具体数值。

测量任务包括采集一定时间内所有的传感器数值。

●标定任务（calibration task）:标定是用于控制发动机按照预定目标运行的行为.控制器使用一个闭环控制行为去实现：它首先用传感器测量发动机状态，然后用执行器改变发动机状态使之达到目标状态。

新的状态不断地得到调整，直到达到平衡.标定就是这个调整过程，它调整其中的参数,使发动机运行在目标状态。

●INCA: INCA是一种测量和标定工具，它提供给标定工程师图像化的界面和连接控制器硬件的手段。

●存储器仿效（memory emulation):一般控制器包含只读存储器,标定数据放在只读存储器中不能被修改。

我们可以使用一定的硬件和INCA软件去嫁接只读存储器和随机存储器，标定数据同时下载到INCA的随机储存器，这样标定工程师就能在线修改标定数据，而不需要修改实际存储器中的标定数据。

●变量和匹配值（variable and calibration value）:变量表征发动机状态，不可修改；匹配值可以由匹配工程师进行修改。

INCA软件的使用目的：建立一个能实现有第一次预喷的试验首先建立一个试验环境（可以直接打开卢红兵给的新的试验环境，把卢红兵给的试验环境直接复制到D:\ETASData\INCA5.1\Database目录下。

）1.先建立一个新的试验，如图所示。

更名为test(随便，可以是任何名字)2.这时选择工作区（workspace）,在expreiment窗口更换试验到test试验。

然后双击workspace 进入试验test的工作区。

如下图切换试验到test切换试验到test双击workspace之后出现下面窗口,这就是test试验的工作界面。

3.一般在工作区域下要建立几个层，这样是为了使工作区有条理性，比如说建立一个监测层和一个用于预喷计算的计算层。

（这是针对本次试验而建的）出现下面的界面建立两个层，并重命名这样在图的下方出现了两个层4.现在一个典型的工作区已经建好了，那么下面的工作就是如何实现自己想要的试验。

首先要考虑一般试验要监测的基本参数，比如说发动机的转速（eng_nAvrg）、油门踏板比率和安全检查（AccPed_rChkdVal,其实主要是用来看踩油门踏板的百分比，可在说明文件的80找到）、共轨的压力（Railcd_pPeak,最后10秒轨压的最大值，说明文件的428页）、当前的喷油量（Injctl_qsetUnBal,当前的喷射量，可在说明文件的416页找到）、发动机机械状况（EngM_stSync,可在说明文件650页找到）选择变量点击后出现下面窗口选择变量（可以在变量区直接输入变量的名称进行查找），点击一下即可选择。

选择好后的情况下面对所选的变量进行定义出现下面界面定义参数的类型，以及显示类型为了便于观测，定义为示波器形式。

确定后出现下面的窗口。

另外还有一部分变量是应该监测的。

对于本次试验还要监测InjCrv_stInjCharDes_mp(用户想得到的喷射特性，具体请看说明文件的691页)、InjCrv_stInjCharsetVal（喷射特性设定值，具体请看说明文件的708页）、InjCrv_stInjCharActVal（喷射特性的现行值，具体看说明文件的469页）、InjCrv_stPiIRlsStruct_mp（预喷放行的结构，具体看说明文件的690页），因为喷射特性的实际值和用户想得到的喷射特性不一定一样，这样就出现了问题，这与上面的InjCrv_stPiIRlsStruct_mp有关。

INCA软件最新版操作⼿册INCA EnergyOperator Manualf??ìé=OKN=g~?ì~êó=OMMSOxford Instruments AnalyticalHalifax RoadHigh Wycombe HP12 3SE, UKSection 1 - INCA Energy System Overview1Section 2 - Introduction to INCA Energy Software2 Navigators23 DataManagementHelp 10 Energy Options12Section 3 – Description of Main Steps131.Optimum Microscope Conditions Setup for X-ray Microanalysis142.Quant optimization - Why do we need to do it?173.Selecting Optimum Acquisition Conditions for X-ray Acquisition194.Start/Stop/Resume Spectrum Acquisition215.Automatic Peak Identification (AutoID)216.Manually Identifying Peaks237.Spectrum Display and Manipulation258.Spectrum Export259.Four Modes of Spectra Acquisition2510.Acquiring Spectra from Lines and Grids of Beam Points27 /doc/9e651c43eff9aef8941e069d.html pare2912.Quantitative Analysis3113.SmartMap4514.Element Maps4815.LineScan5016.Cameo+5217.PhaseMap53QuantMap5718.19.AutoMate59Montage 6520.21.Feature6884Report22.Section 1 - INCA Energy System OverviewThe main components that make up an INCA Energy system are:PCx-stream module to control X-ray acquisition and/ or mics module to control imaging EDS detector to detect X-raysThe PC is loaded with the INCA Energy software and an IEEE 1394 card.System Block DiagramFigure 1: INCA Energy SystemPage 1Page 2Section 2 - Introduction to INCA Energy SoftwareThe INCA software platform has four main components:Navigators ?Data Management ?Help ?Energy OptionsNavigatorsThe INCA software platform has unique navigators for guiding the user through the stages of the microanalysis process from starting a new project to producing a hardcopy report.You can easily switch between a Navigator, which directs the work flow, and the data tree which keeps avisual record of work progress.Point & ID Navigator Data treeData ManagementData within INCA Energy and Energy TEM is archived in a logical and easily accessible manner and can be directly viewed in the Data tree. To access the Data tree, press the Data tab to the right of the Navigator tab.ProjectsWithin INCA Energy, data is managed within Projects as illustrated by the Data tree shown above. As you acquire data, you will see your data build up in the Data tree. The entries in theData tree can be renamed within the Data tree view.Within a Project you may examine more than one Sample, and on each Sample, more than one Site of Interest. Data acquired from an individual Site of Interest is stored together for example electron or Cameo+ image, spectra and maps as easily recognizable icons as displayed below:Page 3Page 4SpectrumProjectSmartMapSampleSite of InterestReconstructed spectrumSynthesized spectrumPhaseMapCameo+imageElement MapISIS Imported spectrumElectron imageOther images (e.g. ISIS Importedimage)Combined ED/WD spectrumNote that more than one Project can be viewed at any one time in the Data tree. ?A Project is a single file with the extension .ipj which can be saved in any directory on any drive in the conventional Windows? way. Note that the name of the current Project is displayed as partof the Menu Title.At any time you can save your Project by going to the main menu, under File and selecting 'Save Project as' or using Ctrl and S on the keyboard. Autosaving your ProjectYou can set the Autosave function to save your current Project at regular intervals. This can be set by going to the main menu, under Options, and checking the box in Preferences under'Saving'.If you open a Project and you have the Autosave function on, Autosave will save the Project ontop of the original.If you create a Project and save it and you have the Autosave function on, further autosaves will save the Project to the original saved location.If you create a new Project and you have the Autosave function on, Autosave will save the Project to a recovery file.The recovery file is located under Program files\INCA\Data. If you wish to open this file, make a copy of this file with a different name in a different directory.Note that Autosave does not take effect during data acquisition.Autosave does not function on read-only Projects.If you have multiple Projects open, ensure that you save your Projects.Samples and Site of InterestWithin a Project you may analyze more than one Sample, and on each Sample, more than one Site of Interest.Data acquired from an individual Site of Interest is stored together for example electron or Cameo+ image, spectra and maps as easily recognizable icons. The current analytical conditions such as kV, Mag and Quant optimization data are also stored with the data.Thumbnail images of the individual images and spectra can be easily viewed by hovering over the data labels with the mouse.Page 5Exporting spectra, images, maps, linescans and Cameo+ dataElectron images, maps, linescans, Cameo+ images and spectra can be exported from INCA in a variety of formats thus allowing them to be read by appropriate software packages. You can export either from the data tree or from theimage/spectrum viewer:Data treeTo export from the Data tree click with the right hand mouse button on the data label and select Export. This enables the user to convert and export the data in file formats such as JPG and TIF:Image ViewerWhen you click with the right hand mouse button on an image or map you have two options for exporting:?ExportThis allows the data to be converted as a bitmap (BMP), TIFF (TIF), or JPEG(JPG, with optional high compression) file. You can select the image size fromthe drop-down list. The default size is set to the size of the original image. Enterthe file name and select a folder in which you wish to save the image:Page 6Page 7Export Data OnlyThis allows the raw data to be exported in suitable formats for further processinge.g., 8-bit or 16-bit TIF and TSV (Tab Separated Variable). Only raw data isexported without contrast enhancement or annotation. However, the TIFF Coloroption will save a color image with contrast enhancement. The scalinginformation is also included in the exported data.If you have analySIS ?software (Soft Imaging Systems) installed on your computer you can export the data to the analySIS ?database. There are two options for exporting data to the analySIS ?database:analySIS ?database: Use this option if you wish to export the raw data. analySIS ?database (color): Use this option if you wish to export eithera Cameo+ image or a contrast enhanced image. Spectrum ViewerWhen you click with the right hand mouse button on the spectrum you are allowed to convert and export the spectrum as BMP, TIF, JPG or WMF(Metafile). You can also export the spectrum inEMSA or ISIS format. If you have analySIS software installed on your computer you can exportthe data to the analySIS database.Linescan ViewerYou can export a linescan in a variety of formats. When you click with the right hand mousebutton on the linescan you are allowed to convert and export the linescan as BMP, JPG or TSVetc.Note that it is the data as currently displayed which is exported. Therefore, if the current image has been zoomed, the contrast or brightness, the color or the spectrum scaling has beenchanged, this will be included in the conversion.Note also that images exported to files include the scalemarker.Exporting SmartMap dataYou can export the current SmartMap data by selecting 'Export SmartMap' under File from the main menu.Exporting data in an INCA formatElectron images, maps, Cameo+ images and energy dispersive (ED) spectra can be exported from INCA in an INCA format. These can be displayed within INCA Viewer.Click with the right hand mouse button on the data label, select Export and then, INCA Export Format. This allows the data to be converted and exported in file formats: .iex for spectra and .mcv for images. INCA ViewerINCA Viewer is installed with INCA although INCA Viewer can be installed separately if desiredTo start INCA Viewer either:Double click on the exported file from Windows ExplorerSelect INCA Viewer from Start/Programs/Oxford Instruments menuCopying spectra, images, maps, linescans and Cameo+ dataSpectra, electron images, maps, linescans, Cameo+ images and spectra can be copied to the clipboard from INCA Energy in two ways:1.By clicking with the right hand mouse button on the data label and selecting Copy.2.By clicking with the right hand mouse button on the image, linescan etc and selecting Copy. Hereyou are allowed to choose the size of the image before you copy it to the clipboard:The data will be copied to the Clipboard. You can then use your desired application into which you wish to transfer the image etc from the Clipboard.Note that it is the data as currently displayed which is copied. Therefore, if the current image has been zoomed, the contrast or brightness, the color, or the spectrum scaling has been changed;this will be included in the copying.Note also that images copied to the clipboard include the scalemarker.Page 8Deleting images, spectra, samples and Sites of InterestSpectra, electron images, maps, linescans, Cameo+ images and spectra can be deleted from INCA Energy by clicking with the right hand mouse button on the data label and selecting delete.Projects, Sites of Interest and Samples can also be deleted directly from the Data tree by clicking with the right hand mouse button on the appropriate icon.Note: You can not delete the last Site of Interest in a Sample and last Sample in a Project. Page 9Page 10HelpThere is an expert multimedia user Help system, which is fully integrated with the applications software. The Help has the following features:On-line Bubble help and tool tips for expert advice and guidance through each stage of the microanalysis process.A fully integrated and indexed microanalysis encyclopaedia that provides comprehensive description of key microanalysis terms, background, and theory.Multimedia training and background tutorials with movie based modules.‘Getting Started’ multimedia tutorial for immediate training of new user.Also, advice on using the application to achieve good results.INCA Bubble HelpINCA TutorialsPage 11Energy OptionsThe basic packaged system has two navigators:AnalyzerMappingThe advanced packaged system has three navigators:AnalyzerPoint & IDMappingThere are additional software options such as Cameo+, Spectrum Synthesis, PhaseMap, Matching, AutoMate, GSR, QuantMap and Feature. The basic system can be upgraded in steps by adding new software options easily.Application KeysEach software application is supplied as a key-enabled locked module. You need to have an appropriate key for unlocking each application.Page 12Section 3 – Description of Main StepsThis manual describes the main steps to enable the users to carry out analysis using the INCA Energy system. Comprehensive INCA Energy Help is available within the software that users can easily access for further information. List of topics described in the manual are:1. Optimum Microscope Conditions Setup for X-ray Microanalysis2. Quant Optimization3. Selecting Optimum Conditions for X-ray Acquisition4. Start/Stop/Resume Spectrum Acquisition5. AutoMatic Peak Identification (AutoID)6. Manually Identifying Peaks7. Spectrum Display and Manipulation8. Spectrum Export9. Four Modes of Spectrum Acquisition10. Acquiring Spectra from Lines & Grids of Beam Points11. Compare12. QuantitativeAnalysis13. SmartMapMaps14. Elementscans15. Line16. Cameo+17. PhaseMap18. QuantMap19. AutoMate20. Montage21. Feature22. ReportPage 131. Optimum Microscope Conditions Setup for X-ray MicroanalysisThe main purpose of this step is to enable you to set up an appropriate X-ray count rate from your sample to use for your analysis before you start collecting data into your Project.If you are starting a new session with INCA Energy, there are a few things we recommend you optimize on your microscope, which will ensure that you get the best results for your analysis.The main points to consider are listed below.1.1 Are you working with tilted samples?If you are working with tilted samples and you are going to use the spectrum for quantitative analysis, it is important to enter the correct value of the sample tiltIf you have purchased Microscope Control (the application for controlling and reading the electron beam and column parameters ) and you have a motorized tilt stage, the current tilt angle will be automatically read by the software.More commonly, the stage tilt will not be motorized; in which case you will need to enter the value into Microscope Control.1.2 What value of accelerating voltage should I use?Initially you need to choose a kV to get an image of your sample and then you can adjust the beam current such that you get sufficient X-rays in your spectrum. You may want to refine the kV once you have performed a more detailed analysis on your sample.20kV is a good starting point, particularly if the sample is unknown. This kV will excite most X-ray lines from most elements and these will be automatically identified in the spectrum.Choose a lower kV if you are concerned about:1. Accuracy of quantification of light elements since the lower penetration into the samplewill reduce the absorption correction.2. Analysis of a small particle, inclusion or a film less than 10mm in depth since a smallerexcitation volume will enhance the contribution from these features.If you have purchased Microscope (column) control INCA Energy will automatically read the current microscope accelerating voltage.If you have not purchased Microscope (column) control and you are working in Point & ID, you will need to go to the ‘Site of Interest step’ in the Navigator and manually enter the currentkV on your microscope into the space provided. Alternatively, select Microscope (column)control under Options from the main menu and enter the kV in the space provided.1.3 Setting up the beam currentIt is generally easiest to setup the microscope if you operate in secondary electron imaging mode.The next stage is to produce a stable beam of electrons for X-ray microanalysis. You may have a tungsten,LaB6 emitter or a field emission gun each requiring its own type of setup procedure.The degree of electron emission can be monitored in more than one way, depending on your microscope. If you have a tungsten or LaB6gun, it is good practice to increase the filament current slowly as this will preserve the lifetime of the filament. Initially, as you increase the filament or heating current, the beamPage 14current increases to an initial maximum, before dropping and then rising again to a point above which the beam current no longer increases. This is known as the saturation point, and any further increase in heating current just reduces the lifetime of the filament.With the filament operating at the saturation point, emission is stabilized and this is where you should operate if you wish the beam to be stable.You can observe the saturation point for a filament by viewing the trace variation on the CRT, or waveform monitor, which represents the signal from the sample. Increase the filament current such that you no longer produce an increase in the height of the waveform above the baseline. At this point, you have reached filament saturation.Another common way of monitoring the emission from a gun is by observing the so called ‘emission image’.1.4 Working distanceThe working distance is defined as the distance between the lower pole piece of the objective lens and the plane at which electrons are focused.1.4.1 Which value of working distance should I use for X-ray microanalysis?Ensure that the working distance, as displayed in millimeters on your microscope monitor, is the desired value for performing X-ray microanalysis. This is specific to the geometry of the detector mount on the SEM chamber.The recommended value for your instrument can be viewed by going to Microscope Control from the Options menu on the INCA menu bar.If you have purchased Microscope (column) Control, the value of the working distance displayed on your microscope monitor will be automatically read by INCA Energy. If you do not have Microscope (column) control installed, you should manually enter the working distance by selecting Microscope (column) control under Options from the main menu.1.4.2 How do I adjust the working distance?Adjust the strength of the objective lens by adjusting the ‘focus’ on your microscope until your microscope monitor displays the recommended working distance. Note that your image may now appear out of focus.Carefully adjust the sample height using the Z drive of your stage so that the image comes into focus. Check for excessive lens hysterisis.If you move to another area of the sample or move to another sample completely, don’t adjust the focus, but adjust the Z drive of the stage to bring the image into focus. This means that X-rays are always generated at the same position within the microscope, which gives the correct geometry for the detector. Take care that if you have a large sample, or have many samples of different heights mounted on the stage, that any sample does not collide with any detector mounted directly below the pole piece of the objective lens (e.g. backscattered electron detector).1.4.3 How to improve image qualityBy now you should see a focused image on your microscope monitor.The quality of your image will very much depend on how well your column has been aligned. Your image quality will be optimized if your filament has been exactly centered in the gun area, and the electron beam travels exactly down the optic axis of the column before it strikes the sample. There are a variety of methods provided on microscopes to achieve these optimum conditions.Page 15Some microscopes have a ‘Wobbler’ button to check the alignment of the objective aperture which when activated fluctuates the objective lens current about a fixed value. Alternatively you can manually increase and decrease the focus about a fixed point.If you do this, look at your secondary electron image, it will appear to go through focus but will distort if the objective aperture is not centered. When correctly centered, the image will appear to go in and out of focus, without moving or distorting.You may further improve the quality of the image by adjusting the stigmators on your microscope. Astigmatism manifests itself in images by causing streaking of features as you change the focus about a fixed point. You can reduce any astigmatism by adjusting the stigmators in conjunction with the focus.If you are going to perform any X-ray analysis, make sure that you re-adjust the focus to ensure that you are operating at your recommended working distance and bring your image into focus using the Z drive of the stage.Page 16。

1．INCA基础在使用INCA软件建立试验环境时必须用到两个文件A2L、HEX·A2L描述文件（*.a2l）包含数据和控制单元程序的物理描述，它包括— 结构信息— 地址范围— 存储器大小— 每个参数和测量信号的地址范围— 每个参数和测量信号的名字·HEX文件（*.hex、*.s19）包含控制单元程序的代码和数据，这些内容能直接读取到控制单元并且被各自的处理器执行。

2．建立一个新的试验环境Inca软件界面打开之后下图：这时点开database菜单并指向new标签确定打开一个new database 对话框，在框内键入dcd（你想用的任何名字）确定后如下图：导入要用的A2L文件选择A2L文件选择HEX文件确定后会发现出现一个对话框，正在读取a2l文件和hex文件读取完成后界面如下：在界面右侧显示的就是刚才读取HEX文件，而左侧是A2L文件。

这时增加一个试验同样你也可以对试验进行命名，我们姑且把它命名为dcd增加一个工作区workspace我们也可以对工作区进行命名因为在一个根目录下你不能使用相同的名字，如果你把试验命名为dcd，同样也把工作区命名为dcd的话，它会默认生成dcd_1这样的名字，同时我们也可以对根目录更改名字。

点击工作区dcd_1，在整个窗口的右侧出现如下图的界面，点击改变试验（红线）这时会出现一个选择试验的对话框，将刚才我们建立的试验dcd导入导入硬件配置和数据，点击如下图的打开窗口，会出现在一个选择的对话框，然后选择硬件配置和数据，点OK确定。

完成后如下图：下面配置PC和ETAS690的通讯系统点击如下图菜单及选项会出现一个对话框，来进行网络配置我们可以点击缺省设置（如果PC机上的网络已经配置过，这时应注意没有禁用相应的网络）下面我们搜索一下可用的硬件连接，此时注意一下是否所有的硬件已经连接好，包括发动机线束和整车线束与ECU的连接、ETAS工具和ECU的连接以及各种供电设备。