S9300测试报告

Data SheetCisco Nexus 9300 ACI Fixed Spine SwitchesProduct OverviewIndustry shifts are redefining IT at all levels. On-premise IT consumption models are shifting to cloud-based services. IT as a Service (IaaS) is supplanted by applications as a service. Separate development and operations are moving toward integrated Development and Operations (DevOps). Device-centric management models are migrating to application-centric management.Business agility requires application agility, so IT teams need to provision applications in hours instead of months. Resources need to scale up (or down) in minutes, not hours. Traditional approaches take a siloed operational view, with no common operational model for the application, network, security, and cloud teams. A common operational model delivers application agility, simplified operations, assured performance, and scale.The Solution: An Application-Centric Approach to Managing Your InfrastructureCisco® Application Centric Infrastructure (ACI) is a holistic architecture with centralized automation and policy-based application profiles. The Cisco ACI fabric is designed from the foundation to support emerging industry demands while maintaining a migration path for architecture already in place. The fabric is designed to support the industry move to management automation, programmatic policy, and dynamic “workload-anywhere” models. The Cisco ACI fabric accomplishes this with a combination of hardware, policy-based control systems, and software closely coupled to provide advantages not possible in other models.The fabric consists of three major components: the Cisco Application Policy Infrastructure Controller (APIC), spine switches, and leaf switches. These three components handle both the application of network policy and the delivery of packets. Organizations can use the ACI-ready Cisco Nexus® 9000 Series Switches as spine or leaf switches to take full advantage of an automated, policy-based, systems management approach. The Cisco Nexus 9300 Series Switches include both spine and leaf switches. For detailed information, please refer here.Switch ModelsThe Cisco Nexus 9336PQ ACI Spine Switch is a 2-Rack-Unit (2RU) spine switch for Cisco ACI that supports2.88 Tbps of bandwidth and 2.3 billion packets per second (bpps) across 36 fixed 40 QSFP+ ports (Figure 1). Cisco Nexus 9300 platform leaf switches are Layer 2 and 3 nonblocking 10 and 40 Gigabit Ethernet switches with up to 2.56 Terabits per second (Tbps) of internal bandwidth.Figure 1.Cisco Nexus 9336PQ SwitchThe Cisco Nexus 9364C ACI Spine Switch is a 2-Rack-Unit (2RU) spine switch for Cisco ACI that supports 12.84 Tbps of bandwidth and 4.3 bpps across 64 fixed 40/100G QSFP28 ports and 2 fixed 1/10G SFP+ ports(Figure 2). Breakout is not supported on ports 1 to 64. The last 16 ports marked in green support wire-rate MACsec encryption 1.Figure 2.Cisco Nexus 9364C SwitchThe Cisco Nexus 9332C is the smallest form-factor 1-Rack-Unit (1RU) spine switch for Cisco ACI that supports 6.4 Tbps of bandwidth and 2.3 bpps across 32 fixed 40/100G QSFP28 ports and 2 fixed 1/10G SFP+ ports(Figure 3). Breakout is not supported on ports 1 to 32. The last 8 ports marked in green support wire-rate MACsec encryption 2.Figure 3.Cisco Nexus 9332C SwitchSpecificationsTable 1 lists the specifications for the Cisco Nexus 9336PQ switch. (Please check Cisco ACI software release notes for feature support information.)Table 1.Cisco Nexus 9300 ACI Spine Switch Specifications1Software is expected in a future release. Please check the latest software update here . 2Software is expected in a future release. Please check the latest software update .●USB: 2 ports●RS-232 serial console ports: 1●Management ports: 1 x10/100/1000BASE-TPower and Cooling ●Power: 1200W AC, 930W DCor 1200W HVAC/HVDC●Input voltage: 100 to 240V*AC or -40V to -72V DC(min-max), -48V to -60V DC(nominal)*Supports input voltage of100-120V for a max output of800W; 200-240V for a maxoutput of 1200W●Frequency: 50 to 60 Hz (AC)●Efficiency: 90% or greater(20 to 100% load)●RoHS compliance: Yes●Hot swappable: Yes●Port-side intake or port-sideexhale options●Typical power: 400W (AC)●Maximum power: 660W (AC)●Power: 1200W AC, 930W DC3 or 1200WHVAC/HVDC●Input voltage: 100 to 240V* AC or -40V to-72V DC (min-max), -48V to -60V DC(nominal)*Supports input voltage of 100-120V for amax output of 800W; 200-240V for a maxoutput of 1200W; PSU redundancy is notsupported when used in 100-120V●Frequency: 50 to 60 Hz (AC)●Efficiency: 90% or greater (20 to 100%load)●RoHS compliance: Yes●Hot swappable: Yes●Port-side intake or port-side exhaleoptions●Typical power: 429W (AC)●Maximum power: 1245W (AC)●Power: 1100W AC, 1100 DC or 1100WHVAC/HVDC●Input voltage: 100 to 240V* AC or -40V to -72V DC (min-max), -48V to -60V DC(nominal)*Supports input voltage of 100-120V for amax output of 800W; 200-240V for a maxoutput of 1200W●Frequency: 50 to 60 Hz (AC)●Efficiency: 90% or greater(20 to 100% load)●RoHS compliance: Yes●Hot swappable: Yes●Port-side intake or port-side exhale options●Typical power: 296W (AC)●Maximum power: 700W (AC)Environme ntal ●Physical (H x W x D): 3.5 x17.5 x 22.5 in. (8.9 x 44.5 x57.1 cm)●Weight: 34.4 lb●Operating temperature: 32 to104°F (0 to 40°C)●Nonoperating (storage)temperature: -40 to 158°F (-40to 70°C)●Humidity: 5 to 95%(noncondensing)●Altitude: 0 to 13,123 ft (0 to4000m)●Physical (H x W x D): 3.38 x 17.37 x22.27 in. (8.59 x 44.13 x 56.58 cm)●Weight: 36.9lb (16.74kg) with powersupplies and fans, 27.4 lb (12.43kg)without power supplies and fans●Operating temperature: 32 to 104°F (0 to40°C)●Nonoperating (storage) temperature: -40to 158°F(-40 to 70°C)●Humidity: 5 to 85% (noncondensing)●Altitude: 0 to 13,123 ft (0 to 4000m)●Physical (H x W x D): 1.7 x 17.3 x 22.9 in.(4.4 x 43.9 x 58.1 cm)●Weight: 25.1lb (11.4kg) with powersupplies and fans, 19 lb (8.6kg) withoutpower supplies and fans●Operating temperature: 32 to 104°F (0 to40°C)●Nonoperating (storage) temperature: -40 to158°F (-40 to 70°C)●Humidity: 5 to 85% (noncondensing)●Altitude: 0 to 13,123 ft (0 to 4000m)Acoustics ●Fan speed at 40%: 64.4 dBA●Fan speed at 70%: 79.6 dBA●Fan speed at 100%: 89.8 dBA ●Fan speed at 40%: 76.7 dBA●Fan speed at 70%: 88.7 dBA●Fan speed at 100%: 97.4 dBA●Fan speed at 50%: 76.4 dBA●Fan speed at 70%: 83.3 dBA●Fan speed at 100%: 92.1 dBAMTBF ●242,000 hours ●257,860 hours ●363,500 hours3 930W-DC PSU is supported in redundancy mode if 3.5W QSFP+ modules or Passive QSFP cables are used & the system is used in 40C ambient temp or less; for other optics or higher ambient temps, 930W-DC is suppor ted with 2 PSU’s innon-redundancy mode only.Cisco Nexus 9300 ACI Spine Switch Deployment ScenariosThe Nexus 9300 ACI spine switch along with Nexus 9300 leaf nodes enable an automated and policy driven ACI architecture. The Cisco Nexus 9300 ACI spine switch offers advanced scalability in the smallest spine switch form factor, and enables connectivity to up-to 64 Cisco Nexus 9300 leaf switches with its high port density of 64 40/100 GbE ports and 12.84 Tbps throughput. The degree of redundancy in leaf-and-spine architectures delivers increased availability with a high level of flexibility in workload placement (Figure 3).Figure 4. Cisco Nexus 9300 Platform in a Leaf-and-Spine ArchitectureSoftware RequirementsFor the latest software release information and recommendations, please refer to the product bulletin athttps:///go/aci and Cisco Feature Navigator.Regulatory Standards ComplianceTable 2 summarizes regulatory standards compliance for the Cisco Nexus 9300 Spine switch.Table 2. Regulatory Standards Compliance: Safety and EMCSupported Optics PluggableFor details on the optical modules available and the minimum software release required for each supported optical module, visithttps:///en/US/products/hw/modules/ps5455/products_device_support_tables_list.html. Ordering InformationTable 3 presents ordering information for the Cisco Nexus 9300 ACI Spine Switch.Table 3. Ordering InformationWarrantyThe Cisco Nexus 9300 switch has a 1-year limited hardware warranty. The warranty includes hardware replacement with a 10-day turnaround from receipt of a Return Materials Authorization (RMA).Service and SupportCisco offers a wide range of services to help accelerate your success in deploying and optimizing the Cisco Nexus 9300 switch in your data center. The innovative Cisco Services offerings are delivered through a unique combination of people, processes, tools, and partners and are focused on helping you increase operation efficiency and improve your data center network. Cisco Advanced Services uses an architecture-led approach to help you align your data center infrastructure with your business goals and achieve long-term value. Cisco SMARTnet®Service helps you resolve mission-critical problems with direct access at any time to Cisco network experts and award-winning resources.Cisco CapitalFlexible payment solutions to help you achieve your objectives.Cisco Capital makes it easier to get the right technology to achieve your objectives, enable business transformation and help you stay competitive. We can help you reduce the total cost of ownership, conserve capital, and accelerate growth. In more than 100 countries, our flexible payment solutions can help you acquire hardware, software, services and complementary third-party equipment in easy, predictable payments. Learn more.For More InformationFor more information on the Cisco Nexus 9000 Series and for latest software release information and recommendations, please visit https:///go/nexus9000.。

G网络架构下移动通信系统性能测试实验报告一、引言随着移动通信技术的不断发展，G 网络架构逐渐成为了通信领域的重要组成部分。

为了深入了解G 网络架构下移动通信系统的性能表现，我们进行了一系列的测试实验。

本报告将详细介绍实验的目的、方法、过程、结果以及分析。

二、实验目的本次实验的主要目的是评估 G 网络架构下移动通信系统在不同场景下的性能，包括数据传输速率、信号覆盖范围、网络延迟、通话质量等方面。

通过对这些性能指标的测试和分析，为移动通信系统的优化和改进提供参考依据。

三、实验设备与环境（一）实验设备1、支持 G 网络的移动终端设备若干，包括手机、平板电脑等。

2、网络测试仪器，如信号强度测试仪、数据传输速率测试仪等。

3、服务器，用于模拟网络中的数据中心和业务平台。

（二）实验环境1、选择了多个具有代表性的实验地点，包括城市中心、郊区、室内、室外等不同场景。

2、考虑了不同的时间段，包括高峰期和非高峰期，以评估网络在不同负载情况下的性能。

四、实验方法（一）数据传输速率测试1、在不同的实验地点和时间段，使用移动终端设备下载和上传大文件，记录下载和上传的速度。

2、重复多次测试，取平均值作为最终的数据传输速率。

（二）信号覆盖范围测试1、在不同的实验地点，使用信号强度测试仪测量 G 网络的信号强度，并绘制信号覆盖图。

2、记录信号强度低于一定阈值的区域，评估网络的覆盖范围和盲区。

（三）网络延迟测试1、在移动终端设备上运行网络延迟测试工具，向服务器发送请求并记录响应时间。

2、重复多次测试，取平均值作为网络延迟。

（四）通话质量测试1、在不同的实验地点进行通话，使用语音评估工具对通话质量进行打分。

2、记录通话过程中的杂音、卡顿、掉线等情况，评估通话的稳定性和清晰度。

五、实验过程（一）数据传输速率测试过程1、在城市中心的商业区，选择了一个人员密集的广场作为测试点。

在上午 10 点至 11 点的非高峰期，使用一部支持 G 网络的手机下载一个 1GB 的文件，同时使用另一部手机上传一个 500MB 的文件。

SOM-SM9300 核心板用户手册版本1.0–2016年10月版权声明：●SOM-SM9300核心板及其相关知识产权由深圳市英蓓特科技有限公司所有。

●本文档由深圳市英蓓特科技有限公司版权所有，并保留一切权利。

在未经英蓓特公司书面许可的情况下，不得以任何方式或形式来修改、分发或复制本文档的任何部分。

免责声明：●产品附带光盘所提供的程序源代码、软件、资料文档等，深圳市英蓓特有限公司不提供任何类型的担保；不论是明确的，还是隐含的，包括但不限于合适特定用途的保证，全部的风险，由使用者来承担。

版本更新记录：版本更新日期描述1.0 2016-10-18 初始版本目录第1章产品概述 (1)1.1产品简介 (1)1.1.1包装内容 (2)1.1.2产品特性 (2)1.2接口和按钮 ...................................................................... 错误！未定义书签。

1.3系统框图 (4)1.4产品尺寸(mm) (5)第2章硬件系统简介 (6)2.1SOM-SM9300简介 (6)2.2外围芯片介绍 (6)2.2.1MT41K128M16JT-125:K (6)2.2.2EMMC04G-S100 (6)2.2.3MMPF0100NPAEPR2 (7)2.2.4AR8035 (7)2.3接口详述 (7)2.3.1SAMRC接口 (7)技术支持和保修服务 (22)第1章产品概述1.1 产品简介SMARC标准是SGeT组织定义的一个面向低功耗、低成本、高性能的多用途小型计算机模块，设计符合SMARC标准的计算机模块的典型运用方案是ARM SOC或者是与之类似的架构方案如智能电话等。

SMARC标准的计算机模块典型设计功耗在6W以下，不过在一些极端的设计中，SMARC模块可以支持到最高15W的功率设计。

SOM-SM9300是英蓓特推出的基于NXP iMX6系列CPU的SMARC标准模块。

NPS9310系列电动机保护控制装置一、产品用途及特点NPS9310系列智能电动机保护控制装置主要用于690V以下低压电动机控制系统，对电动机的过负荷、短路、超长时间启动、堵转、不平衡、接地、欠压、过压、工艺联锁、绝缘保护等故障引起的危害予以保护，并集合全面的三相电量测量/显示、数字输入/输出与网络通讯于一身。

每个装置具有多种综合电力参数测量功能，既可单独作为电测仪表使用，亦可作为电力综合自动化监控系统之前端，可实现测量、监视、保护、控制等综合功能，该系列测控装置采用了先进的嵌入式控制器，以及全隔离的，高速安全的现场总线技术和大屏幕液显汉字显示，可直接安装在低压开关柜上，通过其标准的RS-485通讯接口及双绞线网络，或通过CAN接口和NPS9930管理机装置通信，轻松实现数据的远方管理及“四遥”功能。

其性能和技术指标处于国内先进水平。

1.1完备的保护功能z电流速断保护z负序过流一段保护z负序过流二段保护z接地保护z过热保护z过热禁止再启动保护z堵转保护z长启动保护z正序过流保护z过负荷保护z欠压保护z PT断线告警z可编程非电量保护1.2装置具有如下功能z8路的开入采集、装置遥信变位、事故遥信z遥控跳、合z交流量采集：三相电压、三相电流、零序电流、有功功率、无功功率、功率因数等z装置自诊断报警z2路脉冲量输入实现外部电度表自动抄表（选配）z1路GPS 硬对时（选配）z电度积分功能，完成电能计量z1路4～20mA直流模拟量输出，替代变送器作为DCS测量接口（选配）z交、直流操作回路（选配）1.3通讯功能z多种通讯接口：RS485、CAN（选配）z多种通讯协议，默认采用标准RS-485总线/MODBUS-RTU协议通信1.4本装置具有如下特点z采用先进的32位工业级摩托罗拉处理器z192*64 大屏幕汉字液晶显示、操作简便直观z采用14位的A/D转换器，各项测量指标轻松达到z配置以大容量的RAM和Flash Memory，可记录8至50个录波报告，记录的事件数不少于1000条z可独立整定32套保护定值，定值切换安全方便z软、硬件冗余设计，抗干扰性能强z完善的软、硬件自检，二级看门狗z全密封嵌入式机箱设计，体积小，重量轻，可直接安装在开关柜上z安全可靠的高速现场总线技术，多种通信接口，多种通信协议z全面、准确、可靠的测控功能z DCS测量接口（4～20mA模拟量输出）（选配）z高精度的时钟芯片，并可选配置GPS硬件对时电路，便于全系统时钟同步装置z电度积分功能，完成电能计量z现场免维护概念¾尽心的电气设计，整机无可调节器件¾高等级、品质保证的元器件选用¾优异的抗干扰性能，组屏或安装于开关柜时不需其它抗干扰模件¾防水、防尘、抗振动的机箱设计¾完善的自诊断功能二、主要技术数据2.1 额定数据直流电源： 220V±20% 或 110V±20%交流电源： 220V±20% 或 110V±20%交流电压： 380/3V，380V，100/3V，100V交流电流：5A或1A频率：50Hz2.2 功率消耗直流回路：≤5W交流电压回路：＜0.5V A/相（额定220V时）交流电流回路：＜0.5V A/相（额定5A时）＜0.1V A/相（额定1A时）2.3 工作环境环境温度：-10℃～+55℃保证正常工作相对湿度：5～95%大气压力：86～106KPa2.4 热稳定性2倍额定电流可连续运行10倍额定电流可连续运行10秒40倍额定电流可连续运行1秒2.5 DCS测量接口输出 （选配）输出范围：4～20mA输出精度：0.5级2.6 接点容量跳、合闸出口（常开接点）： 5A，DC 220V（吸合）信号出口（常开接点）：5A，DC 220V（吸合）开关量输入：空接点输入，导通电流＜10mA2.7 测量精度电压、电流: 1级频率: 0.02HzP、Q、COSΦ: 2级遥信分辨率：＜1ms电度积分精度：2级GPS对时精度：＜1ms2.8 通讯标准的RS-485通讯接口，MODBUS 通讯协议。

sgs测试报告
SGS测试报告。

一、测试目的。

本次测试旨在对产品进行全面的SGS测试，以验证其符合相关标准和规定，确保产品质量和安全性。

二、测试内容。

1. 化学成分测试，对产品的化学成分进行分析，确保不含有有害物质。

2. 物理性能测试，测试产品的强度、耐磨性、耐温性等物理性能指标。

3. 环境适应性测试，测试产品在不同环境条件下的适应性和稳定性。

4. 安全性能测试，测试产品在正常使用情况下的安全性能，包括电气安全、防火性能等。

三、测试结果。

1. 化学成分测试结果显示，产品化学成分符合相关标准，不含有有害物质，符合安全使用要求。

2. 物理性能测试结果显示，产品具有较高的强度和耐磨性，能够满足正常使用需求。

3. 环境适应性测试结果显示，产品在不同环境条件下表现稳定，适应性良好。

4. 安全性能测试结果显示，产品在电气安全和防火性能方面均符合相关标准，使用安全可靠。

四、结论。

根据SGS测试结果，产品在化学成分、物理性能、环境适应性和安全性能方面均符合相关标准和规定，能够满足用户的使用需求，具有较高的质量和安全性。

五、建议。

1. 针对测试中发现的小问题，建议及时进行改进和优化，以进一步提升产品质量和性能。

2. 建议定期进行类似的SGS测试，以确保产品始终符合相关标准和规定，保障用户权益和产品质量。

六、附录。

1. SGS测试报告原件。

2. 测试样品照片。

以上为本次SGS测试报告内容，如有任何疑问或需要进一步了解，请随时与我们联系。

交换机测试报告引言：网络交换机作为网络通信设备中的重要组成部分，扮演着连接和分发网络数据的角色。

它的可靠性和性能对整个网络的工作效果有着直接的影响。

因此，对交换机进行定期的测试和评估是保证网络运行稳定的重要一环。

本报告将对某型号交换机进行测试，并分析测试结果。

一、测试环境概述：测试采用了实际生产环境，在大型企业网络中运行了某型号交换机。

网络中包含了多个部门和终端设备，各类数据流量相对复杂。

二、测试目标：1. 网络稳定性：测试交换机在高负载情况下的稳定性，包括流量控制、数据转发速度等。

2. 存储容量：测试交换机对MAC地址表和路由表等存储容量的支持和扩展性。

3. 交换机性能：测试交换机的吞吐量、传输延迟和数据包丢失率等性能指标，以确保其能够胜任现实网络环境中的各项任务。

4. 安全性：测试交换机的安全功能，包括访问控制、身份验证等。

三、测试步骤和结果：1. 稳定性测试：a. 测试交换机在高负载情况下的流量控制能力，结果显示交换机能够合理地分配和控制流量，避免出现堵塞和丢包现象。

b. 测试交换机在多个部门间的数据转发速度，结果显示交换机在毫秒级别的转发速度下，能够满足网络流量的需求。

c. 测试交换机故障恢复速度，结果显示交换机在故障恢复方面表现出色，迅速恢复到正常运行状态。

2. 存储容量测试：a. 测试交换机对MAC地址表的存储容量，结果显示交换机能够支持大规模MAC地址的动态学习和存储。

b. 测试交换机对路由表的存储容量，结果显示交换机能够灵活扩展路由表的容量，满足复杂网络环境的需要。

3. 交换机性能测试：a. 测试交换机的吞吐量，结果显示交换机能够达到理论最大值，并且不会因流量增加导致性能下降。

b. 测试交换机的传输延迟，结果显示交换机的延迟在可接受范围内，不会对网络应用产生明显的影响。

c. 测试交换机的数据包丢失率，结果显示交换机基本没有数据包丢失，保证了网络数据的完整性。

4. 安全性测试：a. 测试交换机的访问控制能力，结果显示交换机能够严格限制对网络资源的访问。

机械设备测试报告模板篇一：设备验证报告模板设备验证文件（DQ/IQ/OQ/PQ总结报告）设备名称：XXXXXXXX 设备型号：XXXXXXXXXXXXXXXXXXXX公司XXX年验证报告审批XXX型XXXX设备验证报告1概述：年月日至年月日，验证领导小组根据批准的XXXXXX验证方案（文件编号：），对XXXX进行验证，达到了预期效果，现将验证过程进行总结。

2总结设计确认：按照设计确认方案，对URS的符合性、GMP提供的资料进行了预确认。

经确认，其设计符合《药品生产质量管理规范（XX符合我公司的《XXX设备用户需求》（文件编号：XXXXXXX）文件安装确认：划、建造材料、公司配套文件进行了确认。

账，已起草了XXXXX操作SOP 运行确认：/报警装置/联锁装置、断电后重启、PLC 符合性、空转操作确认试验。

XXX~XXX转速运转正常，XXXXXSOP（草案）符合操作，文件内容未做修改。

XXXX工艺规程，采用XX产品，进行三批（批号：）试生产按同步验证的方法进行验证。

每批经过XX小时生产，每30分钟检测一次重量差异、崩解时限、硬度项目。

经确认：重量差异趋势分析：崩解时限趋势分析：硬度趋势分析：以上数据经统计分析，重量差异、崩解时限、硬度指标数据在受控范围内，性能检查合格。

3 未完成的工作4 偏差和变更情况5 再验证建议关键部件大修和更换部件进行“安装确认”。

趋势分析中发现有系统性偏差定期验证设备每运行XX年进行一次确认”项进行。

6 结论：分钟监测一次平均片重；QAXXXX小时监测一次崩解时限，XX小时监测一次硬度。

GMP要求规定，可以交付生产使用。

篇二：测试报告模板XXX产品测试报告版本号：更新记录目录1引言 ................................................ ................................................... . (3)2编写目的 ................................................ ................................................... ............................. 3 项目背景 ................................................ ................................................... ............................. 3 参考资料 ................................................ ................................................... ............................. 3 名词解释 ................................................ ................................................... .. (3)测试概要 ................................................ ................................................... .. (3)测试准备 ................................................ ................................................................................ 3 测试环境及工具 ................................................ ................................................... ................. 3 测试资源 ................................................ ................................................... .. (4)3 测试结果及缺陷分析 ................................................ ................................................... (4)测试执行情况与记录 ................................................ ................................................... ......... 4 缺陷统计与分析 ................................................ ................................................... ................. 5 兼容性分析 ................................................ ................................................... ......................... 6 性能分析（可选） .............................................. ................................................... ............... 7 测试通过准则 ................................................ ................................................... ..................... 7 未解决问题清单 ................................................ ................................................... .. (7)4 测试结论与建议 ................................................ ................................................... .. (7)测试结论 ................................................ ................................................... ............................. 8 建议 ................................................ ................................................... . (8)5 6其他 ................................................ ................................................... . (8)修订说明 ................................................ ................................................... .. (8)1 引言编写目的描述编写本文档的目的。

Huawei S9300 SwitchProduct BrochuresRealize Your Potential01 Huawei S9300 Switch ProductHuawei S9300 series (S9300 for short) terabit routing switches are next-generation high-end smart switches tailored for multiservice networks. The S9300 uses Huawei's intelligent multilayer switching concept to provideAn S9300 running a system software version of V2R5C00 or later can be upgraded to an agile switch by using S9303 S9306S9312 Product OverviewProduct FeaturesAgile Switch, Enabling Networks to Be More Agile for Services• The high-speed ENP is tailored for Ethernet networks. The ENP's flexible packet processing and traffic control capabilities can meet current and future service requirements and help build a highly scalable network. The ENP has a fully programmable architecture, in which customers can define their own forwarding models, forwarding behaviors, and lookup algorithms. Microcode programmability enables new services to be provisioned within six months, without the need of replacing the hardware. In contrast, with traditional ASIC chips, new services cannot be provisioned until new hardware is developed to support the services, which may take 1 to 3 years, because ASIC chips use a fixed forwarding architecture and follow a fixed forwarding process.• By using an X1E board, the S9300 supports the unified user management function to authenticate both wired and wireless users, ensuring a consistent user experience regardless of whether they use wired or wireless access devices to connect to the network. The unified user management function supports various authentication methods, including 802.1x, MA C, and Portal authentications, and is capable of managing users based on user groups, domains, and time ranges. This function visualizes user and service management and enables the transformation from device-centric management to user-centric management.• The X1E board supports the Packet Conservation Algorithm for Internet (iPCA) function, which changes the traditional method of using simulated traffic for fault location. iPCA technology can monitor network quality for any service flow at any network node, at any time, and without extra costs. It can detect temporary service interruptions in a very short time and precisely identify faulty ports. This cutting-edge fault detection technology turns "extensive management" to "fine granular management."Innovative CSS Technology• S9300 switches can set up a clustering switch system (CSS) through cluster cards or service ports. The CSS provides industry-leading 320 Gbps inter-chassis bandwidth due to Huawei's novel approach of using the switching fabric clustering technology in CSS. Member switches can be connected through the service ports on LPUs. These service ports can be configured as stack member ports and added to a logical stack port to enable connectionthrough SFP+ optical modules and fibers, or direct connection through SFP+ stack cables. Virtualization technology improves link use efficiency and preventssingle-point failures through inter-chassis link aggregation.• The S9300 uses route hot backup technology to backup and uninterruptedly forward all data of the controland data planes at Layer 3. This technology significantly improves reliability and performance of the S9300. Theinter-chassis links in a CSS can be bundled to improve linkuse efficiency and eliminate single-point failures.• The S9300 can use common service ports as cluster ports,and member switches can be connected through opticalfibers. This increases the permitted distance between switches in the CSS.• All member switches in a CSS are managed through asingle IP address, which simplifies network device and topology management, improves network operationefficiency, and reduces maintenance costs.Carrier-Class Reliability• The S9300's key components, such as MPUs, power supplies, and fans trays, use a redundant design, and all modules are hot swappable to ensure stable network running.• The S9300 supports 3.3 ms hardware-based BFD for staticroutes and routing protocols such as RIP, OSPF, BGP, IS-IS, VRRP, PIM, and MPLS. Hardware-based BFD significantly improves network reliability.• The S9300 supports High-speed Self Recovery (HSR) technology. Using Huawei's ENP cards, the S9300 is the industry's only switch that implements end-to-end IPMPLS bearer network protection switchover within 50 ms, improving network reliability.• The S9300 supports hardware-based Ethernet OA Min compliance with IEEE 802.3ah, 802.1ag, and ITU-Y.1731. Hardware-based Ethernet OAM can collect precise network parameters, such as transmission latency andjitter, to help customers monitor network operating statusin real time and to realize fast fault detection, location,and failover.• The S9300 supports Graceful Restart (GR) technology to implement nonstop forwarding (NSF) and ensure reliableand high-speed operation of the entire network.Powerful Service Processing Capabilities• The S9300 provides high-density 10GE ports and provide 2 x100GE line card, Each S9312 chassis can provide a maximumof 480 x 10GE ports and 24 x 100GE ports, meeting the requirements of bandwidth-consuming applications, such as multimedia conferencing and data access.02• Based on a multi-service routing and switching platform, the S9300 provides wireless access, voice, video, and data services for network access, aggregation, and core layers, helping customers build a highly reliable, low-latency, and multi-service network.• The S9300 supports distributed MPLS L2/L3VPN functions including MPLS, virtual private LA N service (VPLS), hierarchical VPLS (HVPLS), and virtual leased line (VLL), to provide secure access for VPN users.• The S9300 supports comprehensive Layer 2 and Layer 3 multicast protocols, including Protocol Independent Multicast Sparse Mode (PIM SM), PIM Dense Mode (DM), PIM Source-Specific Multicast (SSM), Multicast Listener Discovery (MLD), and Internet Group Management Protocol (IGMP) snooping, to ensure high-quality HD video surveillance and video conferencing services.• The S9300 supports multi-service virtualization technology to provide value-added service (VAS) solutions for campus networks. This technology virtualizes the VAS capabilities, such as firewall (FW), antivirus engine (AVE), and application security gateway (ASG), so that the network entities, such as switches, routers, ACs, APs, and terminals, can use these virtualized capabilities without the restriction of physical locations.• The software platform where the S9300 runs supports various routing protocols (including IPv6) to meet carriers' network requirements and allows carriers to smoothly upgrade their networks to IPv6.Various Network Traffic Analysis Functions• The S9300 supports NetStream, including V5/V8/V9 versions. The NetStream features involve aggregation traffic template, real-time traffic sampling, dynamic report generation, traffic attribute analysis, and traffic exception alarms. The S9300 sends traffic statistics logs to master and backup servers simultaneously to avoid data loss. NetStream helps monitor the operating status and traffic model on the entire network. It also provides fault pre-detection, effective fault rectification, fast problem handling, and security monitoring capabilities to help customers optimize network structure and adjust service deployment.Comprehensive Security Measures• The S9300 supports MAC security (MACSec) that enables hop-by-hop secure data transmission. The S9300 can be applied to scenarios that pose high requirements on data confidentiality, such as government and finance sectors.• NGFW is a next-generation firewall card installed on an S9300. In addition to the traditional defense functions, such as identity authentication and Anti-DDoS, the NGFWsupports IPS, anti-spam, web security, and application control functions.• The S9300 provides comprehensive network admission control (NAC) solutions, involving MAC, 802.1x, and Portal authentications as well as authentication triggered by DHCP snooping. These authentication methods ensure the security of various access users, such as dumb terminals, mobile users, and users allocated dynamic IP addresses. • The S9300 supports a two-level CPU protection mechanism, which supports 1K CPU hardware queues and separates the data plane from the control plane, to help minimize threats of DoS attacks, unauthorized access, and control plane overloading. With this mechanism, the S9300 offers an industry-leading integrated security solution.Comprehensive IPv6 Solution• The S9300 software and hardware platforms support IPv6. The Ministry of Industry and Information Technology (MIIT) has certified the S9300 as IPv6 network-access compliant and has awarded IPv6 Ready Logo Phase 2 certification.• The S9300 supports IPv6 routing protocols such as RIPng, OSPFv3, IS-ISv6, as well as IPv6 static routes, and supports BGP4+, MLD v1/v2, MLD snooping, PIM-SM/DMv6, and PIM-SSMv6.• The S9300 supports various IPv4-to-IPv6 technologies to ensure seamless network migration. The technologies include IPv6 manual tunnel, 6to4 tunnel, Intra-site Automatic Tunnel Addressing Protocol (ISATAP) tunnel, Generic Routing Encapsulation (GRE) tunnel, and IPv4-compatible automatic tunnel.Innovative Energy Saving Design• The S9300 uses a rotating ventilation channel to improve heat dissipation efficiency and a variable-current chip to dynamically adjust power according to traffic volume. These technologies reduce power consumption of the entire chassis by 11%. The S9300 supports port sleeping. Idle ports enter the sleeping state to reduce power consumption.• The S9300 supports intelligent fan-speed adjustment, in which fans are grouped into multiple zones and fan speed in each zone is adjusted individually based on service loads. This technology lowers power consumption, reduces noise, and extends the service life of fans.• The S9300 supports Energy Efficient Ethernet (EEE) in compliance with IEEE 802.3az. Transceivers on line cards can quickly transition to the lower power idle state to reduce power consumption when no traffic is being transmitted.03Product Specifications040506ApplicationsApplications in Carriers' MANsApplications in Large-Scale Data CentersThe S9300 provides carrier-class reliability, security, and manageability. By converging DSLAM, LAN, and enterprise access services, the S9300 provides large-capacity switching and high-density 10G interfaces. At the convergence layer, the interface rate can be smoothly upgraded from 10GE to 40GE/100GE, meeting the increasing bandwidth requirements of ISP networks. The S9300 supports features such as RRPP , Ethernet OAM, VRRP , and MPLS L2/L3VPN, and satisfies the requirements for IPTV, high speed Internet (HSI), and enterprise leased lines.The S9300 switches function as high-density 10G core and aggregation nodes in large-scale data centers, helping enterprises build highly reliable, non-blocking, and virtualized data center networks. The S9300 switches use various technologies, including IP FRR, hardware-level BFD, NSF, VRRP , and E-Trunk, to ensure uninterrupted services. In addition, the S9300 switches support the CSS function to improve network IT efficiency and reduce network maintenance costs.For more information, visit / or contact your local Huawei sales office.Web & Email Application Application DatabaseS2300Copyright © Huawei Technologies Co., Ltd. 2016. All rights reserved.No part of this document may be reproduced or transmitted in any form or by any means without prior written consent of Huawei Technologies Co., Ltd.Trademark Notice, HUAWEI, and are trademarks or registered trademarks of Huawei Technologies Co., Ltd.Other trademarks, product, service and company names mentioned are the property of their respective owners.General DisclaimerThe information in this document may contain predictive statements including,without limitation, statements regarding the future financial and operating results,future product portfolio, new technology, etc. There are a number of factors thatcould cause actual results and developments to differ materially from thoseexpressed or implied in the predictive statements. Therefore, such information isprovided for reference purpose only and constitutes neither an offer nor anacceptance. Huawei may change the information at any time without notice.。

电气安全标准测试多功能分析仪科电工程之TOS9300系列是可对电子设备／电子元件进行多种安全测试的电气安全标准测试多功能分析仪。

安全测试种类包括耐电压试验，绝缘电阻测试，接地导通测试，泄漏电流测试（接触电流测试，保护导体电流测试，患者泄漏电流测试），局部放电测试。

由于机型结构以必要的测试组合为准，因此１台可充分应对各类安全测试。

最适合用于研究开发设备，质量保证测试及标准认证机构的测试设备，生产线的设备。

科电工程电气安全标准测试多功能分析仪特点1.采用了彩色液晶显示器，产品风格焕然一新！通过用7寸显示器显示各种测试设定值以及概要，图纸，实现了高清晰度，还实现了简单易懂的操作性。

2.以较稳定的输出完成AC耐电压测试！［输入电压变动率±0.3％］一般的耐电压测试仪是针对AC线路的输入电压使用转换变压器升压后进行输出。

采用这种转换变压器方式时，输入电压的变动会影响到输出，有时可能无法正确完成测试。

甚至当变形的电压施加到被测试装置后，也可能会形成新产品不良的原因（加速部件的劣化）。

TOS9300系列产品内置有高效率PWM放大器，不会受到AC线路变动的影响，能够输出稳定的高电压，即使在电压变动大的地区，也可以“放心”，“稳定”地实现可靠性高的“安全”的测试。

3.可以执行自动测试可以组合并连续执行预先设定的测试。

自动测试由程序和步骤构成。

程序是步骤的集合体。

每一个步骤设定为一个测试，并从步骤1开始以升序逐个执行。

最后的步骤结束，即程序结束。

4.支持接触/保护导体/患者泄漏电流测试(TOS9303LC)除了常规电气设备仪器外，也支持医疗设备仪器的各种泄漏电流测试（Patient Current）。

另外，也可以简单地设定网络（测试所使用的测量电路网）。

5.可用1台完成电气安全标准测试(TOS9303LC)配备了AC/DC耐电压测试，绝缘电阻测试，AC/DC接地导通测试，泄漏电流测试的所有功能的TOS9303LC机型，可用1台即可完成电气安全标准的符合性测试。

NVIDIA选择Agilent93000进行SOC测试--通过这一投资，NVIDIA 可以满足不断增长的图形处理器单元和PC 平台芯片组需求-- 安捷伦科技公司日前宣布，全球著名的图片处理器技术领导者—NVIDIA 公司(NASDAQ:NVDA)已经购买多部Agilent93000PinScale 系统，对图形处理器单元(GPUs)及介质和通信处理器进行生产测试。

新购买的PinScale 系统扩大了NVIDIA 的生产测试能力，此外，这些系统能够与NVIDIA 已安装的93000 相互兼容，为测试资源提供了最大的灵活性。

“我们之所以选择安捷伦PinScale 系统，因为它们可以扩充，非常灵活，能够满足当前和未来的测试要求。

”NVIDIA公司高级业务总监BobJafari 说，“通过提高并行测试效率，它降低了我们的测试成本。

”“消费电子供应商面临的产品开发周期压力日益加大，使得设备容量成为关键问题。

”安捷伦半导体测试解决方案副总裁PascalRonde 说，“在需要改变生产测试容量时，Agilent93000 测试系统将为NVIDIA 提供最大的灵活性。

NVIDIA 能够选择我们作为首选的SOC 测试系统，我们深感荣幸。

”关于Agilent93000 Agilent93000SOC 系列是业内在SOCs(system-on-chips)和SIPs（system-in-packages）测试方面增长速度最快的可扩充平台结构。

全球超过1,000 套的装机量，使Agilent93000SOC 系列成为分包制造商、整合设备制造商和设计公司的首选。

不论在实速器件特性分析还是大批量制造，Agilent93000 都能满足业界在性能和成本方面的需求和挑战。

这个测试系统提供了大规模的多点测试能力，使数据传输速率高达10Gb/s,并且支持最广泛的数字、混合信号和RF 射频应用。

Agilent93000 的灵活性和高性能提供了更快的产品上市周期，更好的良率和更低的总体测试成本。

Verigy 93000 SOC测试系统随着半导体设计技术的进步，越来越多的功能模块被设计在同一块芯片中，也就是我们经常提到的SOC(system on a chip，系统芯片)技术。

高速(high speed)，模拟(analog)， 嵌入式内存(embedded memory)和射频(RF)等不同功能模块的集成使SOC 芯片的功能越来越强大，同时也对测试设备的能力及可扩展能力提出了更高的要求。

测试设备必须具有SOC 的整体测试能力，这成为业界对SOC 测试机台品质考量的共识。

Verigy 93000 SOC 测试系统，正是考虑到当前及未来SOC 技术全面集成的需要所提供的芯片测试的系统解决方案。

Verigy 93000 SOC 系统的功能模块93000 SOC 测试系统是由Verigy 在业界享有盛誉的三大系列测试机台整合改进而成。

它们是在数字功能和模拟功能分别具有领先地位的83000和94000测试机台， 以及在射频(RF)和微波方面领导业界标准的84000测试机台。

93000 SOC 将数字，模拟和射频三种测试功能和谐的整合在同一个测试机台中， 并且延续了Verigy 一贯的自由灵活化升级配置，即保留大部分硬件配置，仅通过部分数字测试通道板(channel board)，模拟模块(analog module)，射频模块(RF module)等的增加或改变，实现向更高性能的升级。

93000 SOC 在整合三种测试机台的基础上，还对高速，模拟，嵌入式内存，扫描测试(Scan)以及射频等多种测试功能分别进行了扩展和改进。

目前，93000 提供PS800 和PS400两种系列的数字通道板，速率从PS400 的100Mb/s 到PS800 的800Mb/s。

用户可根据芯片的实际需要选择不同速率的数字通道板，并可实现不同系列的混合配置。

每片数字通道板包含32 或64个数字I/O 通道，每个数字通道具有各自的测试向量内存，其测试向量深度最高达56M。

Quidway@S9300系列T比特核心路由交换机概述Quidway® S9300系列是华为公司面向以业务为核心的网络架构而推出的新一代高端智能T比特核心路由交换机。

该产品基于华为公司智能多层交换的技术理念，在提供稳定、可靠、安全的高性能L2/L3层交换服务基础上，进一步提供业务流分析、完善的QOS策略、可控组播、一体化安全等智能业务优化手段，同时具备超强扩展性和可靠性。

Quidway® S9300系列广泛适用于广域网、城域网，园区网络和数据中心核心、汇聚节点，帮助企业构建面向应用的网络平台，提供交换路由一体化的端到端融合网络。

Quidway® S9300系列提供S9303、S9306、S9312三种产品形态，支持不断扩展的交换能力和端口密度。

整个系列秉承模块通用化、部件归一化的设计理念，最小化备件成本，在保证设备扩展性的同时最大限度地保护用户投资。

此外，S9300作为新一代智能交换机采用了多种绿色节能创新技术，在不断提升性能及稳定性的同时，大幅降低设备能源消耗，减小噪声污染，为网络绿色可持续发展提供领先的解决方案。

产品特点先进交换架构提升网络扩展性S9300采用先进的分布式交换技术，提供业界最大整机交换容量和槽位带宽。

创新的交换速率自适应技术，支持单端口速率40G、100G平滑升级，同时完美兼容现网板卡，保护初始投资。

背板通流能力充分考虑未来带宽升级对整机电源功率和散热需求，数据总线预留升级高速交换网能力。

超高万兆端口密度，单台设备支持576个万兆端口，助力企业园区和数据中心迎来全万兆核心时代。

创新的三平面架构设计S9300在传统交换机数据转发、管理控制双平面基础上创新地增加了独立的环境监控平面，实现对单板、风扇和电源配电模块的监控、管理和维护。

业界首创的环境监控板，采用华为自主知识产权的高集成度中控芯片，实现硬件级的按流量动态调整功率、风扇分区控制、风扇智能调速、端口休眠技术等多项节能技术，在提升系统性能的同时大大降低整机功耗。

华为S9300核心交换机链路聚合配置实例配置静态LACP模式链路聚合示例组网需求如图1所示，在两台S9300设备上配置静态LACP模式链路聚合组，提高两设备之间的带宽与可靠性，具体要求如下：•2条活动链路具有负载分担的能力。

•两设备间的链路具有1条冗余备份链路，当活动链路出现故障链路时，备份链路替代故障链路，保持数据传输的可靠性。

图1 配置静态LACP模式链路聚合组网图配置思路采用如下的思路配置静态LACP模式链路聚合：1.在S9300设备上创建Eth-Trunk，配置Eth-Trunk为静态LACP模式。

2.将成员接口加入Eth-Trunk。

3.配置系统优先级确定主动端。

4.配置活动接口上限阈值。

5.配置接口优先级确定活动链路。

数据准备为完成此配置例，需准备如下的数据：•两端S9300设备链路聚合组编号。

•S9300-A系统优先级。

•活动接口上限阈值。

•活动接口LACP优先级。

操作步骤1.创建编号为1的Eth-Trunk，配置它的工作模式为静态LACP模式# 配置S9300-A。

<Quidway> system-view[Quidway] sysname S9300-A[S9300-A] interface eth-trunk 1[S9300-A-Eth-Trunk1] mode lacp-static[S9300-A-Eth-Trunk1] quit# 配置S9300-B。

<Quidway> system-view[Quidway] sysname S9300-B[S9300-B] interface eth-trunk 1[S9300-B-Eth-Trunk1] mode lacp-static[S9300-B-Eth-Trunk1] quit2.将成员接口加入Eth-Trunk# 配置S9300-A。

[S9300-A] interface gigabitethernet 1/0/1[S9300-A-Gigabitethernet1/0/1] eth-trunk 1[S9300-A-Gigabitethernet1/0/1] quit[S9300-A] interface gigabitethernet 1/0/2[S9300-A-Gigabitethernet1/0/2] eth-trunk 1[S9300-A-Gigabitethernet1/0/2] quit[S9300-A] interface gigabitethernet 1/0/3[S9300-A-Gigabitethernet1/0/3] eth-trunk 1[S9300-A-Gigabitethernet1/0/3] quit# 配置S9300-B。