应用套件审核机制v0.9(1)

NT26E型Cat1模块硬件应用手册版本：V0.1日期：2022-03-27法律声明若接收浙江利尔达物联网技术有限公司（以下称为“利尔达”）的此份文档，即表示您已经同意以下条款。

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文件修订历史目录法律声明 (2)文件修订历史 (3)目录 (4)1引言 (7)1.1安全须知 (7)2模块综述 (8)2.1模块主要特性 (9)2.2功能框图 (10)2.3评估套件 (10)3应用接口 (11)3.1引脚描述 (12)3.2工作模式 (16)3.3电源设计 (16)3.3.1电源接口 (16)3.3.2其他电源接口 (17)3.4USB接口 (18)3.5UART接口 (18)3.5.1串口应用 (20)3.6USIM接口 (21)3.6.1USIM热插拔* (22)3.7I2S接口和IIC接口* (23)3.8ADC接口 (25)3.9GPIO接口* (26)3.10系统控制接口 (26)3.11状态指示 (27)3.11.1飞行模式* (27)3.11.2开机接口 (28)3.11.3复位接口 (29)3.11.4USB_BOOT接口 (30)3.12天线接口 (31)3.13NC接口 (32)3.14测试点设计 (32)4射频特性 (33)4.1工作频段 (33)4.2传导测试数据 (33)4.2.1测试环境 (33)4.2.2传导接收灵敏度 (33)4.2.3传导发射功率 (34)4.3射频LAYOUT设计指导 (34)4.3.1射频走线设计要求 (34)4.4天线设计要求 (36)4.4.1主天线指标 (36)5电气可靠性 (39)5.1工作和储存环境 (39)5.2电源特性 (39)5.2.1输入电压 (39)5.3功耗特性 (40)5.4EMC和ESD特性 (40)6生产及包装信息 (42)6.1过炉方式 (42)6.2回流焊作业指导 (42)6.3不良品维修 (43)6.4储存及包装方式 (44)6.4.1储存要求 (44)7相关文档及术语缩写 (45)7.1相关文档 (45)本文档定义了利尔达NT26E系列CAT1模块的应用规范,描述了其硬件接口、电气特性、应用方法及其机械规范等内容。

应用市场应用审核要求1.引言1.1 概述应用市场应用审核要求是指在应用上架之前，需要经过应用市场的审核才能上线。

随着移动互联网的快速发展，应用市场成为了用户获取应用的主要渠道之一。

为了保护用户的合法权益，提高用户体验，应用市场对上架的应用进行审核，以确保应用的质量和安全性。

应用市场应用审核要求主要包括以下几个方面。

首先，应用的功能必须符合应用市场的规定。

不同的应用市场可能对应用的功能有不同的要求，开发者需要了解并遵守这些规定，确保自己的应用符合要求。

例如，一些应用市场禁止发布含有色情、暴力等违法违规内容的应用。

其次，应用的用户体验要良好。

应用市场通常会要求应用的界面设计美观、操作流畅、功能完善。

用户体验是吸引用户的重要因素，只有用户体验好的应用才能获得更多的用户和好评。

再次，应用的安全性要保障。

应用市场会对应用的安全性进行评估，确保应用没有包含恶意代码、病毒、木马等危险元素。

开发者需要进行严格的代码审查和测试，确保自己的应用是安全可靠的。

此外，一些应用市场还会要求应用实施一些防护措施，如加密传输、隐私政策等，以保护用户的个人信息和隐私。

最后，应用市场还会对应用的版权进行审核。

开发者需要确保自己的应用不侵犯他人的知识产权，不盗用他人的品牌或logo等。

同时，开发者也需要保护自己的版权，避免他人盗用自己的应用。

总之，应用市场应用审核要求对于保护用户权益、提高用户体验、促进应用市场健康发展具有重要意义。

开发者需要了解并遵守这些审核要求，确保自己的应用能够通过审核并成功上架，从而获得更多的用户和商业机会。

1.2文章结构文章结构部分的内容可以按照以下方式进行撰写：第二部分正文本部分将详细介绍应用市场应用审核的要求。

在此部分，将提到审核的重要性以及审核的标准和流程。

同时，还将探讨一些常见的审核指南和建议，帮助开发者更好地通过应用审核。

2.1 第一个要点第一个要点将重点介绍应用审核的标准和指南。

在这一部分，将涵盖以下内容：- 应用内容的合规性要求：应用内涉及的内容必须符合法律法规和道德规范，包括不得传播暴力、色情、违法、侵权等信息。

UFIDA U9 OBA安装与使用技术指南注：UFIDA U9 OBA(Office Business Application)是指UFIDA U9与Microsoft Office集成的商业应用程序套件，包括取数函数、Lookup Data及表单三个具体应用产品。

一、必备软件环境1.支持的OS系统Windows XP Service Pack 2Windows 2003 ServerWindows Vista2.推荐的OS系统Windows XP Service Pack 2Windows Vista3.对目标机器系统盘的要求根据OS软件环境不同，要求安装目标机器系统盘上需要有20~320MB以上的可用空间，应用程序目标盘有25M以上的可用空间，详见下表：4.Microsoft Office环境要求本地机器已安装2007 Microsoft Office System以下至少一个组件，同时建议使用相应版本的最新补丁程序对本地Office进行更新。

Microsoft Office Word 2007Microsoft Office Excel 2007Microsoft Office Outlook 2007注：●UFIDA U9 OBA不支持并行安装了Microsoft Office产品的两个不同版本的配置●安装本软件的WINDOWS用户具备安装软件的权限●本软件仅安装在当前登陆WINDOWS的用户软件环境下，不同WINDOWS用户需要分别安装●若安装了先前版本的本应用程序，应在安装本版程序前卸载相关文件5.各应用产品的Microsoft Office组件支持取数函数：Microsoft Office Excel 2007Lookup Data: Microsoft Office Excel/Outlook/Word 2007表单：Microsoft Office Excel/Word 2007二、安装向导从本软件提供者处获取相应安装文件双击setup.exe启动UFIDA U9 OBA的安装向导按向导提示逐步完成必备软件及本软件的安装过程注：高级用户也可根据本地系统软件环境选择手动按安装顺序选择安装所缺少的必备软件后，（Microsoft .Net Framework Version 2.0 ：安装盘路径dotnetfx文件夹下dotnetfx.exe；Microsoft Visual Studio 2005 Tools for Office Second Edition Runtime：安装盘路径VSTOSERuntime文件夹下VSTOR.exe；Office Primary Interop Assemblies (PIA) ：安装盘路径Office2007PIA文件夹下o2007pia.msi），再双击UFIDA_U9_OBA_CN1.5.msi 完成安装过程三、使用前提用户具有访问U9 Web服务器的相关权限用户已知U9 Web服务器的URL 地址四、常见安装与使用问题1.安装过程出错检查当前WINDOWS用户是否具备管理员或安装应用程序的权限或目标安装路径的写权限 请系统管理员或相关人员检查安装日志以协助解决2.U9服务器连接失败或无法登陆检查本机网络连接是否正常检查访问的目标服务器地址的正确性检查访问的目标服务器是否运行正常检查本机登陆系统的用户名及密码是否正确3.UFIDA U9 OBA 在Office工具栏上不可见运用UFIDA U9 OBA 提供的诊断工具（安装后会出现在WINDOWS程序菜单对应项目中）进行自动修复。

测试套件管理制度一、制度目的为了规范测试工作，提高测试效率和质量，特制定本制度。

二、适用范围本制度适用于公司内所有测试人员，包括测试工程师、测试分析师等。

三、测试套件管理责任1. 测试主管负责测试套件管理工作，包括测试套件的规划、设计、维护和更新。

2. 每个测试人员都有责任按照规定的流程和要求使用测试套件，并对测试套件提出建议和改进意见。

四、测试套件规划1. 制定测试套件规划，根据项目需求和测试目标确定测试套件的范围和内容。

2. 确定测试套件的版本控制方案，保证测试套件的版本管理规范和可控。

五、测试套件设计1. 测试套件应包括测试用例、测试数据、测试环境等内容，确保覆盖项目需求的各个方面。

2. 测试套件应根据项目需求和测试目标进行设计，确保测试套件的有效性和全面性。

六、测试套件更新和维护1. 测试套件应根据项目进展和需求变化进行及时更新，保证测试套件与项目需求的一致性。

2. 确保测试套件的定期维护，及时处理测试套件中发现的问题和缺陷。

七、测试套件使用1. 测试人员应按照规定的流程和要求使用测试套件，确保测试工作的顺利进行。

2. 测试人员应遵守测试套件的使用规范，确保测试套件的完整性和准确性。

八、测试套件改进1. 测试人员应对测试套件提出建议和改进意见，以不断完善测试套件。

2. 测试主管负责对提出的建议和改进意见进行评估和整合，确保测试套件的持续改进。

九、测试套件管理审查1. 定期对测试套件管理制度进行审查和评估，确保测试套件管理工作的有效性和规范性。

2. 对测试套件的使用情况进行定期的审查和评估，及时发现和处理问题。

十、测试套件管理制度的宣传和培训1. 定期开展测试套件管理制度的宣传和培训工作，确保测试人员对测试套件管理制度的了解和遵守。

2. 确保测试人员能够熟练掌握测试套件管理工作的流程和要求。

十一、制度的执行和监督1. 测试主管负责监督测试套件管理制度的执行情况，并及时处理发现的问题和异常。

MS Office高级应用1. 介绍MS Office是一套非常强大的办公软件套件，由微软公司开发。

它包括了多种应用程序，例如Word、Excel、PowerPoint 等等。

这些应用程序在办公和商业环境中被广泛使用，提供了各种强大的功能，帮助用户提高工作效率。

本文将介绍一些MS Office的高级应用技巧，以提高您的工作效率和生产力。

2. Word高级应用2.1 使用样式在大多数情况下，我们写文档时需要一致的格式和样式。

使用样式可以帮助我们快速应用统一的格式和布局。

在Word 中，您可以使用内置的样式库，也可以自定义样式。

使用样式可以使文档更具可读性，同时也方便后续的修改和排版。

2.2 自动目录和索引对于较大型的文档，经常需要创建目录和索引。

Word提供了自动创建目录和索引的功能，您只需要在文档中标记章节标题和索引关键词，然后通过少量的设置即可自动生成目录和索引。

这极大地简化了制作和更新文档的过程。

2.3 文档合并有时候我们需要将多个文档合并成一个，可以通过Word的“合并文档”功能实现。

您可以选择需要合并的文档，并按照指定的顺序进行合并。

这在多个人员协作撰写文档的情况下非常有用，并且保持了文档结构的完整性。

3. Excel高级应用3.1 使用数据透视表数据透视表是Excel强大的分析工具之一。

它可以帮助您快速分析和汇总大量数据。

您可以通过简单的拖放操作创建透视表，并使用各种汇总函数和排序功能对数据进行统计和分析。

数据透视表使得复杂的数据分析变得简单和直观。

3.2 使用条件格式化条件格式化可以根据指定的条件对单元格进行自动格式化。

这使得数据可视化变得更加简单，提供了更好的数据分析和展示效果。

您可以根据数值、文本或日期等类型设置条件，并对符合条件的单元格进行格式化。

通过合理使用条件格式化，您可以更好地呈现数据和展示结果。

3.3 利用宏自动化任务Excel提供了宏的支持，您可以录制并运行宏来自动执行一系列的任务。

LAS Xfor Confocal Systems Release Notes LAS X 4.1.1Leica Microsystems CMS GmbHRelease documentation for LAS X 4.1.1This document describes the 4.1.1 release of the Leica Application Suite X imaging and analysis software for advanced live cell research. You should read this document before installing a copy of this software.All reasonable steps have been taken to ensure that this publication is correct and complete. Should any user be in doubt about any detail, clarification may be sought from Leica Microsystems CMS GmbH, or their accredited representatives. The information in this document is subject to change without notice and should not be construed, as a commitment by Leica Microsystems CMS GmbH. Leica Microsystems CMS GmbH accepts no responsibility for any errors that may appear in this document.Copyright © 2020 Leica Microsystems CMS GmbHAll rights reserved. The contents of this publication may not be reproduced in any form, or communicated to a third party without prior written permission of Leica Microsystems CMS GmbH. Due to a policy of continuous development; we reserve the right to change specifications without notice. Microsoft and MS-DOS are registered trademarks and Windows, the Windows logo, the Windows 2000 logo, the Windows XP logo, the Windows Vista logo, the Windows 7, and the Windows 10 logo are trademarks of Microsoft Corporation.Date: October 23rd, 2020 applying to build number 23273Contents1. Compatible Microscopes and Technical Requirements (4)1.1 Compatible Microscopes and Hardware Requirements (4)1.2 Operating System Requirements (4)2. Reason for this Release – LAS X 4.1.1 (4)3. New functionality and features (5)3.1 Support of the DLS modality (5)3.2 Support of the STED modality (7)3.3 Miscellaneous novel features (9)4. Recommendations (10)5. Open Issues / Restrictions (10)6. Solved Issues / Restrictions (14)7. Compatible 3rd party software (14)1. Compatible Microscopes and Technical Requirements1.1 Compatible Microscopes and Hardware RequirementsThe LAS X 4.1.1 control software is a release for the STELLARIS confocal platform. Accordingly, the LAS X 4.1.1 control software is not compatible with any other microscope platform from Leica, i.e., SP8 confocal systems also cannot be upgraded from LAS X 3.5.7 with this release. Note that LAS X 4.1.1 supports DLS, FALCON and STED, but not any other advanced imaging modality of the STELLARIS platform (CARS, DIVE, FCS). All Leica-supplied CUDA workstations for the STELLARIS confocal platform meet the minimum PC requirements of the LAS X 4.1.1 control software.1.2 Operating System RequirementsLAS X 4.1.1 is a genuine 64-bit program and runs on Windows 10 64bit. Since the end of the lifetime of Windows 7 in 2020, LAS X 4.1.1 does not support Windows 7 anymore.2. Reason for this Release – LAS X 4.1.1LAS X 4.1.1 is a release to address vulnerabilities in a 3rd party application (WIBU CodeMeter Runtime) shipped with LAS X for license management.3. New functionality and featuresIn this Release Notes (LAS X 4.1.1), the following section about New functionality and features is identical to that of the previous Release Notes (LAS X 4.1.0). It informs the user about the new functionality coming with LAS X 4.1.x.3.1 Support of the DLS modalityThe LAS X 4.1.1 control software supports the DLS (Digitial LightSheet) module to extend the STELLARIS platform with a gentle and fast lightsheet imaging modality. DLS can be operated via an intuitive wizard (see figure LightSheet wizard –LightSheet tab).LightSheet wizard – LightSheet tabTwo-color recording of a zebrafish embryo with DLS in the xymzt mode. The red box on the lower left indicates the Widefield button for switching quickly to the Widefield acquisition mode; the red box on the top indicates the Widefield tab.With STELLARIS, we introduce several novel functionalities for DLS:∙We added a new Widefield mode for quickly navigating through the specimen. The Widefield mode can be used within the LightSheet tabor in the designated Widefield tab of the LightSheet wizard.∙There is now the possibility to generate the DLS lightsheet with the resonant scanner. Due to shorter pixel dwell times, using the resonantscanner will result in even more gentle imaging paradigms. Users canoperate the galvo/resonant scanner switch in Calibration>Optimization> Acquisition. It is possible to change the scan modewithin the current LAS X session.∙We added an illumination wavelength-specific calibration for the lightsheet to correct for chromatic aberrations. Users can do the basecalibration in the Calibration tab and the channel-specific calibrationin the LightSheet tab.∙Since data volumes can quickly grow large in DLS experiments, we would like to point out the novel Compatibility mode for largeexperiments for recordings of large data sets. This data mode allowsfor saving experiments larger than the caching folder (DataContainer).∙We fully integrated the ImageCompass into the Confocal tab of the LightSheet wizard, i.e., users can set up (high-res) confocal scans justlike in the main STELLARIS interface.A comprehensive description of how to operate the DLS wizard (including the above-mentioned features) can be found in the Online-Help.3.2 Support of the STED modalityThe LAS X 4.1.1 control software enables STED nanoscopy on STELLARIS STED and STELLARIS 8 STED. The STED modality is seamlessly integrated into the ImageCompass user interface: Users can intuitively define even complex imaging paradigms via Drag&Drop(see figure ImageCompass STED –confocal/STED comparison and ImageCompass STED– Drag&Drop).ImageCompass STED – confocal/STEDThe STED modality is seamlessly integrated into the ImageCompass: The unified interface allows for setting up confocal/STED comparisons (upper and lower setting) as well as multi-color STED experiments (not shown) with ease.ImageCompass STED – Drag&DropWhen choosing a STED-able dye, users can choose between the confocal (C) and STED (S) modality by clicking on the respective small flag (a), and subsequently Drag&Drop the dye (b) into a setting. The ImageCompass will configure the hardware automatically for STED dyes (i.e., excitation wavelength from the white light laser (c), STED laser line (d), and emission range of the detector), so that the user only needs to fine-tune some Beam Path settings (such as the laser power of the white light laser and STED laser, or the STED 3D parameter (e)). STED is compatible with all members from the Power HyD family(here, a HyD S detector is used).STED supports our novel TauSense technology: Simply choose a mode from the TauModes drop-down menu (see also figure ImageCompass STED –confocal/STED for the TauModes menu in the upper setting). The various TauSense modes allow for powerful, digital gating to increase STED performance (GateScan, TauGating) and exploit life-time based information(TauContrast, TauScan, TauSeparation).Furthermore, on STELLARIS 8 STED FALCON, τ-STED is available. τ-STED uses lifetime information in combination with phasor analysis to increase the resolution and eliminate uncorrelated background in an automatic manner. Since much less excitation and STED laser power are necessary, τ-STED can even enable gentle live-cell imaging with cutting-edge resolution and high image quality.A comprehensive description of how to operate the STED modality (including Auto and Expert Beam Alignment, TauSense and τ-STED) can be found in the Online-Help.3.3 Miscellaneous novel featuresFRET wizardsThe FRET AB (A cceptor B leaching) and the FRET SE (S ensitized E mission) wizards are now available with the MicroLab license. The first step of both wizards (Overview) provides a guideline on how to perform the respective FRET workflow: From Setup (using the ImageCompass) to Evaluation(generating insights about the FRET efficiency).FLIM zipFor STELLARIS 8 FALCON, a new FLIM data format is now available: FLIM zip. FLIM zip works both online and offline. It optimizes the file size for faster analysis performance and improved data storage (up to 8 times smaller file size). FLIM zip can be activated with a right-click on an acquired image(once activated all the images will be acquired as FLIM zip) or in the Tool menu. With the latter option, it is possible to optimize already acquired FALCON data with FLIM zip (i.e., data acquired on LAS X 4.0.2 or lower), however, FLIM zipped data can only be handled with LAS X 4.1.0 or higher.TauSense improvementsTauSense describes several acquisition tools which use pulsed laser excitation and photon counting detectors to obtain fluorescence lifetime-based information for image formation. With LAS X 4.1.1, TauSense modes are further integrated into LAS X. Now, stage applications (such as the Navigator) can use TauScan and TauSeparation. Furthermore, we have refined the metadata handling of the TauSense technology (improved channel labeling and image properties).4. RecommendationsFor an optimal performance and the safety of the product, we strongly recommend the installation of/upgrade to LAS X 4.1.1 for systems of the STELLARIS confocal platform!5. Open Issues / RestrictionsThe following list enumerates the known, unresolved anomalies of LAS X 4.1.1:∙Bleach point not available in the core softwareWorkaround: The bleach point functionality allows for applying a high laser intensity to small defined regions within the specimen so that FRAP or photo-conversion experiments can be performed. Since the bleach point functionality in the core software will only be implemented in an upcoming LAS X release, for the time being, there are two mitigation strategies:o If the temporal domain is not critical (e.g., photo-conversion of fluorescent proteins for long-term cell tracking), a simple solution is using small ROIsto manually zoom-in and apply high laser intensity.o The FRAP wizard contains the bleach point functionality. For more complex experimental conditions in which the temporal domain matters,get in touch with us so that we can assist you with a license for MicroLab.∙No f rame accumulation with TauContrast imagingWorkaround:Enabling frame accumulation results in images with an improved signal-to-noise ratio (SNR). Since frame accumulation will only become available for TauContrast imaging with an upcoming LAS X release, an immediate mitigation strategy is the use of line accumulation in TauContrast imaging.Indeed, line accumulation even has the advantage of being better suited for fast imaging since it minimizes the interval between the iterative recording of the same pixel. However, consider that line accumulation will allow for less relaxation of fluorescent dyes/proteins between repetitive excitation cycles, and thus. a more cautious approach regarding the photon budget should be considered.∙No Dynamic Signal Enhancement with TauSeparationWorkaround: Dynamic Signal Enhancement(DSE) is an image filter for noise reduction in time series experiments. It is particularly useful for fast life-cell imaging with the resonant scanner, as it reduces noise without sacrificing much of the temporal resolution. Since DSE will only become available for TauSeparation imaging with an upcoming LAS X release, line accumulation can be used for noise reduction as a temporary mitigation strategy. Since line accumulation does decrease the temporal resolution (proportional to the number of times a line is accumulated), several measures and/or a combination thereof should be considered for minimizing the acquisition time of individual image frames. These measures include: Minimize line accumulation by “hardware means”(high-NA objective, appropriate detector, higher excitation power), minimize line accumulation by “lower resolution” (larger pinhole, smaller image format), use of the resonant scanner (shorter pixel dwell times), and a smaller field of view (crop along y- and/or x-axis).∙Unused disk memory blocks new experimentWorkaround: If unused disk space is not freed after an experiment is executed, the user should close and reopen the project.∙LAS X freezes/unresponsiveWorkaround: If software performance slows down or even freezes due to high and prolonged workload, the user should restart the LAS X (software) and scanner (hardware). Closing of the LAS X session may require using the Windows Task Manager.∙Frequency of the White Light Laser (WLL) wrongly displayedWorkaround: The WLL frequency in the GUI is not synchronized correctly with the hardware control on LAS X start. Therefore, the user must once change the frequency of the WLL to correctly sync the GUI and the hardware control. This will solve the issue for the remaining LAS X session.∙Optimize format not working correctly for STEDWorkaround: The format optimization does not work correctly for STED and thus the user should set the format (pixel size) manually.∙Selection of different detector modes in STELLARIS 8 FALCON for HyD S possibleWhen FLIM is started, the appropriate detector mode(‘counting’) is automatically activated on HyD S. Nevertheless, users are not prevented from actively choosing an inappropriate detector mode (‘analog’ or ‘reflection’) on HyD S while FLIM is on.∙Average Arrival Time (AAT) changed when LIGHTNING applied to an image with TauSenseWorkaround: Since AAT data is changed in LIGHTNING, the user must use the raw data (i.e., not deconvolved) for analysis of the AAT channel.∙Saving with .xlef/.lof in FALCONWorkaround: Due to the newly introduced FLIM zip, FALCON data can currently only be saved reliably as LIF file. LIF is now the default format for saving in LAS X.∙FRET efficiency image does not match the statisticCalculation of the FRET efficiency statistics works correctly while the FRET efficiency image may not be displayed correctly and thus should not be used.∙Only single histogram is generated when using TauSeparation in combination with multiple settings and line sequentialWorkaround: When using TauSeparation with multiple settings and line sequential, only a single(identical) histogram is generated for all settings. Nevertheless, the generated image data is correct and can be used for further analysis. If the histogram data is important, the user must choose frame sequential mode for TauSeparation with multiple settings.∙Galvo switch (from resonant to FOV scanner) should not be used in the LIGHTNING wizardWorkaround: When using the Galvo switch (from resonant to FOV scanner) in the LIGHTNING wizard, the software creates an error. Accordingly, the user must not operate the Galvo switch inside the LIGHTNING wizard. If the user accidently operated the Galvo switch, the user must close the LIGHTNING wizard and set up reasonable scan parameters (Speed) for the FOV scanner in the main STELLARIS interface before returning to the LIGTNING wizard.∙FRAP wizard: “Overview” tab button malfunctionWorkaround: “Overview”tab in FRAP wizard must not be clicked since it causes a scan loop. The information from the “Overview” tab can be found in the Online-Help. If the “Overview” tab is accidently clicked, the user can terminate the initiated scan by clicking on the ”Close X” at the top right of the LAS X and then returning to the Setup tab.6. Solved Issues / RestrictionsAmongst other bugfixes, we have resolved the following issues/restrictions from the LAS X 4.0.2 release:∙FRET wizards not available∙TauSeparation/TauScan not compatible with Navigator and TileScan∙TauScan values not fully visible in image properties∙GUI elements not consistently explained via Mouse over∙LDM lacks Trigger functionality∙Save progress bar does not disappear∙Data Export of TauContrast images does not work (e.g. as .tiff)∙STELLARIS systems without Tandem Scanner have Galvo switch icon in GUI7. Compatible 3rd party softwareLAS X 4.1.1 does not support the integration of any 3rd party software packages, i.e., neither SVI’s Huygens Suite nor PicoQuant’s SymPhoTime. The f unctionality of these packages is covered by the LAS X LIGHTNING and LAS X FLIM packages.。

【应用上架】超详细开发者账号申请应用上架审核经验整理一、甲方与乙方的关系甲方为应用开发者，乙方为应用上架平台。

双方经协商一致，签订本合同，并遵循以下条款进行合作。

二、合作内容1.甲方负责开发和完善应用，并按照乙方的要求提交应用上架申请材料。

2.乙方负责审核甲方提交的应用上架申请材料，并根据审核结果决定是否将应用上架至乙方平台。

3.甲方在应用上架审核过程中，须积极配合乙方的要求，提供所需的补充资料和修改应用的支持。

三、甲方义务1.甲方保证所开发的应用无侵犯他人合法权益的内容，不得违反法律法规和乙方相关规定。

2.甲方保证所提交的申请材料真实、准确、完整。

3.甲方保证应用开发过程中的源代码、算法等技术信息的保密。

4.甲方应按照乙方要求对应用进行必要的修改和优化，以满足上架审核的标准和要求。

四、乙方义务1.乙方承诺对甲方提交的应用上架申请材料进行认真、客观、公正的审核。

2.乙方保证在合理时间范围内完成对甲方应用上架申请的审核，并及时向甲方反馈审核结果。

3.若审核未通过，乙方应向甲方提供详细的审核意见，并指导甲方进行修改和优化。

4.若审核通过，乙方应将甲方的应用上架至乙方平台，并按照双方约定进行分成结算等后续事宜。

五、保密条款双方在本合作过程中可能接触到对方的商业秘密和技术信息。

双方承诺对所接触的保密信息予以严格保密，不得泄露或向第三方披露，除非获得对方明确的书面许可。

六、违约责任1.若甲方违反本合同约定，造成乙方损失的，甲方承担相应的赔偿责任。

2.若乙方违反本合同约定，造成甲方损失的，乙方承担相应的赔偿责任。

3.若一方违约致使对方无法继续履行本合同的，违约方应承担违约责任。

七、有效期与解除1.本合同自双方签署之日起生效，有效期为一年。

2.若一方违反合同约定且经对方书面通知后仍未改正的，对方有权解除本合同。

八、其他事项1.本合同如需修改或补充事项，须经双方协商一致，并以书面形式进行确认。

2.本合同一式两份，甲方和乙方各持一份，具有同等法律效力。

ESP32-S2ESP-IDF编程指南Release v4.3.3乐鑫信息科技2022年06月02日Table of contentsTable of contents i 1快速入门31.1概述 (3)1.2准备工作 (3)1.3开发板简介 (4)1.3.1ESP32-S2-Saola-1 (4)1.3.2ESP32-S2-DevKitM-1(U) (9)1.3.3ESP32-S2-DevKitC-1 (15)1.3.4ESP32-S2-Kaluga-1套件v1.3 (19)1.4详细安装步骤 (54)1.4.1设置开发环境 (54)1.4.2创建您的第一个工程 (54)1.5第一步：安装准备 (54)1.5.1Windows平台工具链的标准设置 (54)1.5.2Linux平台工具链的标准设置 (59)1.5.3macOS平台工具链的标准设置 (60)1.6第二步：获取ESP-IDF (61)1.6.1Linux和macOS操作系统 (61)1.6.2Windows操作系统 (61)1.7第三步：设置工具 (61)1.7.1Windows操作系统 (62)1.7.2Linux和macOS操作系统 (62)1.7.3下载工具备选方案 (62)1.7.4自定义工具安装路径 (63)1.8第四步：设置环境变量 (63)1.8.1Windows操作系统 (63)1.8.2Linux和macOS操作系统 (63)1.9第五步：开始创建工程 (64)1.9.1Linux和macOS操作系统 (64)1.9.2Windows操作系统 (64)1.10第六步：连接设备 (64)1.11第七步：配置 (64)1.11.1Linux和macOS操作系统 (64)1.11.2Windows操作系统 (65)1.12第八步：编译工程 (65)1.13第九步：烧录到设备 (66)1.13.1烧录过程中可能遇到的问题 (66)1.13.2常规操作 (67)1.14第十步：监视器 (67)1.15更新ESP-IDF (68)1.16相关文档 (68)1.16.1与ESP32-S2创建串口连接 (69)1.16.2Eclipse IDE创建和烧录指南 (74)1.16.3VS Code IDE快速入门 (75)1.16.4IDF监视器 (75)i1.16.5工具链的自定义设置 (79)2API参考852.1连网API (85)2.1.1Wi-Fi (85)2.1.2以太网 (166)2.1.3IP网络层协议 (181)2.1.4应用层协议 (197)2.2外设API (197)2.2.1Analog to Digital Converter (197)2.2.2Digital To Analog Converter (221)2.2.3通用定时器 (225)2.2.4GPIO&RTC GPIO (234)2.2.5Dedicated GPIO (252)2.2.6HMAC (257)2.2.7Digital Signature (260)2.2.8I2C驱动程序 (265)2.2.9I2S (277)2.2.10LED PWM控制器 (287)2.2.11Pulse Counter (300)2.2.12RMT (308)2.2.13SD SPI Host Driver (326)2.2.14Sigma-delta Modulation (330)2.2.15SPI Master Driver (333)2.2.16SPI Slave Driver (349)2.2.17SPI Slave Half Duplex (355)2.2.18ESP32-S2Temperature Sensor (361)2.2.19触摸传感器 (363)2.2.20Touch Element (385)2.2.21TWAI (409)2.2.22UART (425)2.2.23USB Driver (447)2.3应用层协议 (454)2.3.1mDNS服务 (454)2.3.2ESP-TLS (462)2.3.3ESP HTTP Client (474)2.3.4ESP WebSocket Client (488)2.3.5HTTP服务器 (495)2.3.6HTTPS server (516)2.3.7ICMP Echo (518)2.3.8ASIO port (523)2.3.9ESP-MQTT (523)2.3.10ESP-Modbus (534)2.3.11ESP Local Control (539)2.3.12ESP Serial Slave Link (548)2.3.13ESP x509Certificate Bundle (560)2.3.14IP网络层协议 (562)2.4配网API (563)2.4.1Unified Provisioning (563)2.4.2Protocol Communication (566)2.4.3Wi-Fi Provisioning (577)2.5存储API (593)2.5.1SPI Flash API (593)2.5.2SD/SDIO/MMC驱动程序 (615)2.5.3非易失性存储库 (623)2.5.4NVS分区生成程序 (642)2.5.5虚拟文件系统组件 (646)2.5.6FAT文件系统 (657)ii2.5.7磨损均衡API (661)2.5.8SPIFFS文件系统 (665)2.5.9量产程序 (668)2.6System API (672)2.6.1App Image Format (672)2.6.2Application Level Tracing (677)2.6.3The Async memcpy API (682)2.6.4控制台终端 (685)2.6.5eFuse Manager (692)2.6.6Error Codes and Helper Functions (711)2.6.7ESP HTTPS OTA (713)2.6.8ESP-pthread (716)2.6.9Event Loop Library (719)2.6.10FreeRTOS (735)2.6.11FreeRTOS Additions (828)2.6.12Heap Memory Allocation (844)2.6.13Heap Memory Debugging (855)2.6.14High Resolution Timer (866)2.6.15Call function with external stack (870)2.6.16Interrupt allocation (872)2.6.17Logging library (877)2.6.18Miscellaneous System APIs (882)2.6.19空中升级(OTA) (890)2.6.20Performance Monitor (900)2.6.21电源管理 (902)2.6.22Sleep Modes (907)2.6.23Watchdogs (916)2.6.24System Time (920)2.6.25Internal and Unstable APIs (924)2.7Project Configuration (924)2.7.1Introduction (924)2.7.2Project Configuration Menu (924)2.7.3Using sdkconfig.defaults (925)2.7.4Kconfig Formatting Rules (925)2.7.5Backward Compatibility of Kconfig Options (925)2.7.6Configuration Options Reference (926)2.7.7Customisations (1094)2.8Error Codes Reference (1094)3ESP32-S2H/W硬件参考11013.1ESP32-S2系列模组和开发板 (1101)3.1.1模组 (1101)3.1.2相关文档 (1101)3.2ESP32-S2模组与开发板（历史版本） (1101)3.2.1模组 (1101)3.2.2开发板 (1102)3.2.3相关文档 (1102)3.3Chip Series Comparison (1102)3.3.1Related Documents (1104)4API指南11054.1应用层跟踪库 (1105)4.1.1概述 (1105)4.1.2运行模式 (1105)4.1.3配置选项与依赖项 (1105)4.1.4如何使用这个库 (1106)4.2应用程序的启动流程 (1112)4.2.1一级引导程序 (1113)iii4.2.2二级引导程序 (1113)4.2.3应用程序启动阶段 (1113)4.3引导加载程序（Bootloader） (1114)4.3.1引导加载程序兼容性 (1114)4.3.2恢复出厂设置 (1114)4.3.3从测试应用程序分区启动 (1115)4.3.4从深度睡眠中快速启动 (1115)4.3.5自定义引导程序 (1115)4.4构建系统（CMake版） (1115)4.4.1概述 (1116)4.4.2使用构建系统 (1116)4.4.3示例项目 (1119)4.4.4项目CMakeLists文件 (1120)4.4.5组件CMakeLists文件 (1121)4.4.6组件配置 (1123)4.4.7预处理器定义 (1123)4.4.8组件依赖 (1124)4.4.9组件CMakeLists示例 (1128)4.4.10自定义sdkconfig的默认值 (1131)4.4.11Flash参数 (1132)4.4.12构建Bootloader (1132)4.4.13选择目标芯片 (1132)4.4.14编写纯CMake组件 (1133)4.4.15组件中使用第三方CMake项目 (1133)4.4.16组件中使用预建库 (1134)4.4.17在自定义CMake项目中使用ESP-IDF (1134)4.4.18ESP-IDF CMake构建系统API (1135)4.4.19文件通配&增量构建 (1138)4.4.20构建系统的元数据 (1139)4.4.21构建系统内部 (1139)4.4.22从ESP-IDF GNU Make构建系统迁移到CMake构建系统 (1141)4.5Deep Sleep Wake Stubs (1142)4.5.1Rules for Wake Stubs (1143)4.5.2Implementing A Stub (1143)4.5.3Loading Code Into RTC Memory (1143)4.5.4Loading Data Into RTC Memory (1143)4.6Device Firmware Upgrade through USB (1144)4.6.1Building the DFU Image (1145)4.6.2Flashing the Chip with the DFU Image (1145)4.7错误处理 (1146)4.7.1概述 (1146)4.7.2错误码 (1147)4.7.3错误码到错误消息 (1147)4.7.4ESP_ERROR_CHECK宏 (1147)4.7.5错误处理模式 (1148)4.7.6C++异常 (1148)4.8ESP-MESH (1148)4.8.1概述 (1149)4.8.2简介 (1149)4.8.3ESP-MESH概念 (1149)4.8.4建立网络 (1155)4.8.5管理网络 (1159)4.8.6数据传输 (1161)4.8.7信道切换 (1163)4.8.8性能 (1166)4.8.9更多注意事项 (1167)4.9Core Dump (1167)4.9.1Overview (1167)iv4.9.2Configurations (1167)4.9.3Save core dump toflash (1168)4.9.4Print core dump to UART (1168)4.9.5ROM Functions in Backtraces (1168)4.9.6Dumping variables on demand (1169)4.9.7Running espcoredump.py (1169)4.10Event Handling (1170)4.10.1Wi-Fi,Ethernet,and IP Events (1170)4.10.2Mesh Events (1171)4.10.3Bluetooth Events (1171)4.11片外RAM (1172)4.11.1简介 (1172)4.11.2硬件 (1172)4.11.3配置片外RAM (1172)4.11.4片外RAM使用限制 (1173)4.12严重错误 (1174)4.12.1概述 (1174)4.12.2紧急处理程序 (1174)4.12.3寄存器转储与回溯 (1175)4.12.4GDB Stub (1176)4.12.5Guru Meditation错误 (1177)4.12.6其它严重错误 (1178)4.13Flash加密 (1179)4.13.1概述 (1179)4.13.2Flash加密过程中使用的eFuse (1180)4.13.3Flash的加密过程 (1180)4.13.4设置Flash加密的步骤 (1181)4.13.5Flash加密的要点 (1187)4.13.6使用加密的Flash (1187)4.13.7更新加密的Flash (1188)4.13.8关闭Flash加密 (1188)4.13.9Flash加密的局限性 (1189)4.13.10Flash加密与安全启动 (1189)4.13.11使用无安全启动的Flash加密 (1189)4.13.12Flash加密的高级功能 (1189)4.13.13技术细节 (1190)4.14ESP-IDF FreeRTOS SMP Changes (1191)4.14.1Overview (1191)4.14.2Tasks and Task Creation (1191)4.14.3Scheduling (1192)4.14.4Critical Sections&Disabling Interrupts (1194)4.14.5Task Deletion (1195)4.14.6Thread Local Storage Pointers&Deletion Callbacks (1195)4.14.7Configuring ESP-IDF FreeRTOS (1195)4.15Hardware Abstraction (1195)4.15.1Architecture (1196)4.15.2LL(Low Level)Layer (1197)4.15.3HAL(Hardware Abstraction Layer) (1198)4.16High-Level Interrupts (1199)4.16.1Interrupt Levels (1199)4.16.2Notes (1199)4.17JTAG调试 (1200)4.17.1引言 (1200)4.17.2工作原理 (1201)4.17.3选择JTAG适配器 (1201)4.17.4安装OpenOCD (1202)4.17.5配置ESP32-S2目标板 (1202)4.17.6启动调试器 (1207)v4.17.7调试范例 (1207)4.17.8从源码构建OpenOCD (1207)4.17.9注意事项和补充内容 (1211)4.17.10相关文档 (1215)4.18链接脚本生成机制 (1240)4.18.1概述 (1240)4.18.2快速上手 (1240)4.18.3链接脚本生成机制内核 (1243)4.19lwIP (1247)4.19.1Supported APIs (1247)4.19.2BSD Sockets API (1248)4.19.3Netconn API (1252)4.19.4lwIP FreeRTOS Task (1252)4.19.5esp-lwip custom modifications (1252)4.19.6Performance Optimization (1253)4.20应用程序的内存布局 (1254)4.20.1IRAM（指令RAM） (1254)4.20.2IROM（代码从Flash中运行） (1255)4.20.3RTC快速内存 (1255)4.20.4DRAM（数据RAM） (1255)4.20.5DROM（数据存储在Flash中） (1255)4.20.6RTC慢速内存 (1256)4.21DMA能力要求 (1256)4.22分区表 (1257)4.22.1概述 (1257)4.22.2内置分区表 (1257)4.22.3创建自定义分区表 (1258)4.22.4生成二进制分区表 (1260)4.22.5烧写分区表 (1260)4.22.6分区工具(parttool.py) (1260)4.23RF calibration (1262)4.23.1Partial calibration (1262)4.23.2Full calibration (1262)4.23.3No calibration (1262)4.23.4PHY initialization data (1263)4.24Secure Boot V2 (1263)4.24.1Background (1263)4.24.2Advantages (1263)4.24.3Secure Boot V2Process (1263)4.24.4Signature Block Format (1264)4.24.5Verifying the signature Block (1264)4.24.6Bootloader Size (1265)4.24.7eFuse usage (1265)4.24.8How To Enable Secure Boot V2 (1265)4.24.9Restrictions after Secure Boot is enabled (1266)4.24.10Generating Secure Boot Signing Key (1266)4.24.11Remote Signing of Images (1266)4.24.12Secure Boot Best Practices (1267)4.24.13Key Management (1267)4.24.14Multiple Keys (1267)4.24.15Key Revocation (1267)4.24.16Technical Details (1268)4.24.17Secure Boot&Flash Encryption (1268)4.24.18Signed App Verification Without Hardware Secure Boot (1269)4.24.19Advanced Features (1269)4.25Thread Local Storage (1269)4.25.1Overview (1270)4.25.2FreeRTOS Native API (1270)vi4.25.3Pthread API (1270)4.25.4C11Standard (1270)4.26工具 (1270)4.26.1Downloadable Tools (1270)4.26.2IDF Docker Image (1279)4.26.3IDF Windows Installer (1281)4.26.4IDF Component Manager (1282)4.27ULP协处理器编程 (1283)4.27.1ESP32-S2ULP coprocessor instruction set (1283)4.27.2Programming ULP coprocessor using C macros(legacy) (1299)4.27.3安装工具链 (1303)4.27.4编译ULP代码 (1303)4.27.5访问ULP程序变量 (1304)4.27.6启动ULP程序 (1305)4.27.7ESP32-S2ULP程序流 (1306)4.28ULP-RISC-V协处理器编程 (1307)4.28.1安装ULP-RISC-V工具链 (1307)4.28.2编译ULP-RISC-V代码 (1307)4.28.3访问ULP-RISC-V程序变量 (1308)4.28.4启动ULP-RISC-V程序 (1308)4.28.5ULP-RISC-V程序流 (1309)4.29ESP32-S2中的单元测试 (1309)4.29.1添加常规测试用例 (1310)4.29.2添加多设备测试用例 (1310)4.29.3添加多阶段测试用例 (1311)4.29.4应用于不同芯片的单元测试 (1312)4.29.5编译单元测试程序 (1312)4.29.6运行单元测试 (1313)4.30USB OTG Console (1314)4.30.1Hardware Requirements (1314)4.30.2Software Configuration (1314)4.30.3Uploading the Application (1314)4.30.4Limitations (1315)4.31Wi-Fi驱动程序 (1316)4.31.1ESP32-S2Wi-Fi功能列表 (1316)4.31.2如何编写Wi-Fi应用程序 (1316)4.31.3ESP32-S2Wi-Fi API错误代码 (1317)4.31.4初始化ESP32-S2Wi-Fi API参数 (1317)4.31.5ESP32-S2Wi-Fi编程模型 (1317)4.31.6ESP32-S2Wi-Fi事件描述 (1318)4.31.7ESP32-S2Wi-Fi station一般情况 (1321)4.31.8ESP32-S2Wi-Fi AP一般情况 (1323)4.31.9ESP32-S2Wi-Fi扫描 (1323)4.31.10ESP32-S2Wi-Fi station连接场景 (1330)4.31.11找到多个AP时的ESP32-S2Wi-Fi station连接 (1334)4.31.12Wi-Fi重新连接 (1334)4.31.13Wi-Fi beacon超时 (1334)4.31.14ESP32-S2Wi-Fi配置 (1334)4.31.15Wi-Fi Easy Connect™(DPP) (1338)4.31.16无线网络管理 (1339)4.31.17无线资源管理 (1339)4.31.18Wi-Fi Location (1339)4.31.19ESP32-S2Wi-Fi节能模式 (1340)4.31.20ESP32-S2Wi-Fi吞吐量 (1340)4.31.21Wi-Fi80211数据包发送 (1341)4.31.22Wi-Fi Sniffer模式 (1342)4.31.23Wi-Fi多根天线 (1343)4.31.24Wi-Fi信道状态信息 (1344)vii4.31.25Wi-Fi信道状态信息配置 (1345)4.31.26Wi-Fi HT20/40 (1345)4.31.27Wi-Fi QoS (1345)4.31.28Wi-Fi AMSDU (1346)4.31.29Wi-Fi分片 (1346)4.31.30WPS注册 (1346)4.31.31Wi-Fi缓冲区使用情况 (1346)4.31.32如何提高Wi-Fi性能 (1347)4.31.33Wi-Fi Menuconfig (1350)4.31.34故障排除 (1353)4.32Wi-Fi Security (1358)4.32.1ESP32-S2Wi-Fi Security Features (1358)4.32.2Protected Management Frames(PMF) (1358)4.32.3WPA3-Personal (1359)5Libraries and Frameworks13615.1Cloud Frameworks (1361)5.1.1AWS IoT (1361)5.1.2Azure IoT (1361)5.1.3Google IoT Core (1361)5.1.4Aliyun IoT (1361)5.1.5Joylink IoT (1361)5.1.6Tencent IoT (1361)5.1.7Tencentyun IoT (1362)5.1.8Baidu IoT (1362)6Contributions Guide13636.1How to Contribute (1363)6.2Before Contributing (1363)6.3Pull Request Process (1363)6.4Legal Part (1364)6.5Related Documents (1364)6.5.1Espressif IoT Development Framework Style Guide (1364)6.5.2Install pre-commit Hook for ESP-IDF Project (1370)6.5.3编写代码文档 (1371)6.5.4文档的附加工具和扩展功能指南 (1380)6.5.5创建示例项目 (1383)6.5.6API Documentation Template (1384)6.5.7Contributor Agreement (1386)7ESP-IDF版本简介13897.1发布版本 (1389)7.2我该选择哪个版本？ (1389)7.3版本管理 (1389)7.4支持期限 (1390)7.5查看当前版本 (1391)7.6Git工作流 (1392)7.7更新ESP-IDF (1392)7.7.1更新至一个稳定发布版本 (1393)7.7.2更新至一个预发布版本 (1393)7.7.3更新至master分支 (1393)7.7.4更新至一个发布分支 (1393)8资源13958.1PlatformIO (1395)8.1.1What is PlatformIO? (1395)8.1.2Installation (1395)8.1.3Configuration (1396)8.1.4Tutorials (1396)viii8.1.5Project Examples (1396)8.1.6Next Steps (1396)8.2有用的链接 (1396)9Copyrights and Licenses13979.1Software Copyrights (1397)9.1.1Firmware Components (1397)9.1.2Build Tools (1398)9.1.3Documentation (1398)9.2ROM Source Code Copyrights (1398)9.3Xtensa libhal MIT License (1399)9.4TinyBasic Plus MIT License (1399)9.5TJpgDec License (1399)10关于本指南1401 11切换语言1403索引1405索引1405ix这里是乐鑫IoT开发框架(esp-idf)的文档中心。