安捷伦89600矢量信号分析软件功能概述及测量指南

安捷伦8960实用简易操作说明安捷仑8960综合测试仪是GSM和CDMA手机测试常见的测试仪器，现把在生产过程常用的设置和调试在此说明，以便大家需要时参考1.如何将自动测试转换到手动测试？答：按面板右上方LOCAL键，进入本地设置状态即可（注：自动测试是指当仪器连接了电脑所有测试过程由电脑软件控制；手动测试即人工手动直接对仪器进行选择设置和测试。

）2.如何查看8960仪器的当前GPIB地址？答：1.按SYSTEM CONFIG键，进入系统设置界面，即可看到GPIB 地址，如：GPIB Address:20 3. 如何知道8960仪器当前的测试类型CDMA还是GSM？如何转换？答：1.按SYSTEM CONFIG键，进入系统设置界面，即可看到，如：Application：GSM/GPRS Mobile Test目前产线常用的有两种，（1）G网手机，采用GSM/GPRS Mobile Test（2）C网手机，采用CDMA2000 Mobile TestGSM手机校准时需把C网换成G网，否则不能校准，转换方法如下：先按按面板右上方LOCAL键，再Application Selection进入子画面，按Application Switch ，进入测试类型选项，通过旋钮选择GSM/GPRS Mobile Test或CDMA2000 Mobile Test，按下旋钮键确定，再选择YES 按下旋钮键确定，仪器将执行自动重启进入选定测试类项。

4.如何修改8960仪器的线损值？答：按SYSTEM CONFIG键，进入系统设置界面，按RF IN/OUT Amptd offset进入子画面，按IN/OUT Amptd offset setup，旋钮选择对应频段，按下旋钮键，进入线损值修改，如－10 dB。

（线损值理论上应该通过测试来定，但实际应用中直接输入经验值有8，10，12dB，使OK手机测试功率在33±3dB之内即可.5.如何用8960测试手机发射功率？答：在待机界面，按Mesutement Selection 进入弹出窗口，用旋钮选择功率***POWER 项，注意：GSM900M频段测试功率等级有5——15级， GSM1800M频段测试功率等级有0—15级，GSM900测试信道：1—124（中间信道62）;GSM1800测试信道: 512—885（中间信道698），通话测试时：900M功率等级选最大5，信道选62,功率标准为33±3dB；1800M功率等级选最大0，信道选698,功率标准为33±3dB6.GSM手机接收灵敏度测试用手机建立一个呼叫连接，按下Measurement selection键(测试项目选择)，选择测量项GSM Bit Error(误码)，按下F7(BCH)，再按F7调节Cell Power(信元功率)，当Bit Error(误码)不超过2.4%时，Cell Power的值即为所测手机的接收灵敏度，国标为-102 dBm。

一，选择GSM或CDMA开机后进入主界面，选择“SYSTEM CONFIG”按钮，选择F3（Application Selection）后，选择F1（Application Switch），调节仪器上的旋转按钮，光标停留在需设置的项目上，按下旋转按钮，即选中项目，例如选择GSM。

图1. 选择“SYSTEM CONFIG”按钮图2.选择F3图3.选择F2 图4.选择CDMA或GSM一，GSM测试设置线路损耗补偿打开综测仪开关，进入到主界面，选择“SYSTEM CONFIG”按钮，选择“F5（RF IN/out Amptd offset）”，选择“F2（RF IN/OUT Amptd Offset）”，调节仪器上的旋转按钮，光标停留在需设置的项目上，按下旋转按钮，即选中项目，用仪器上的数字键设置数值，设置完成后，再次按下旋转按钮即完成设置。

例如：设置900MHz，1800MHz，1900MHz三个频点的传输损耗分别为-25dBm、-30 dBm、 -20 dBm图5.主界面图6. 选择“SYSTEM CONFIG”按钮图7. 选择F5按钮图8.选择F2按钮图9.旋转按钮图10.设置损耗值图11设置损耗值图12.按旋转按钮二，GSM连接设置按下仪器上“CALL SETUP”按键，然后按下按键“F 7(BCH)”，Cell power设为-60dBm,cell bard为EGSM(测试EGSM和DCS都可选择EGSM,测试PCS要选择PCS),按F12返回。

按下按键“F8(TCH)”，Traffic Band设为测试频带（EGSM，DCS，PCS），选择Traffic channel为所测试相关信道信号（EGSM为62，DCS为699，PCS为660）设置Ms Tx level(EGSM设为5，DCS,PCS 设为0)按F12返回图13.按“CALL SETUP”按键图14.连接设置三，GSM连接综测仪操作把终端放置到综测仪指定位置，打开终端TF测试卡内phone(GSM)软件，按下仪器上“CALL SETUP”按键,按左侧按键“F3 （Originate Call）”,综测仪向机器发出呼叫，仪器出现“Alerting”时，点击终端软件上“接听”选项，终端显示“已接听”，此时综测仪显示“Connected”，证明终端已经连接上综测仪。

安捷伦8960测量原理及操作说明一、测量原理1.信号调制解调：测量设备与被测设备之间建立无线连接后，通过信号调制解调模块将测试信号转换成与被测设备相适应的信号，然后将被测设备发送的信号经过解调转换成数字信号。

2.信号发射与接收：通过射频信号处理系统，将数字信号转换成高频射频信号，通过无线天线发送到被测设备，同时接收被测设备发送的信号。

3.信号分析：通过信号处理单元，对接收信号进行频谱分析、波形分析、调制解调分析等，获取信号的各项参数。

二、操作说明1.连接设备：将测试设备与被测设备通过数据线或者无线连接，在软件界面上选择正确的接口和通信制式。

2.设置测试参数：根据测试需求，设置相应的测试参数。

包括频率范围、带宽、功率级别、调制方式等。

3.启动测试：点击开始测试按钮，仪器将自动产生测试信号并发送到被测设备。

同时，仪器将接收被测设备发送的信号并进行分析。

4.监测信号性能：根据测试需求，在界面上选择需要监测的信号性能参数，如信号强度、误码率、速率等。

仪器将实时显示和记录这些参数。

5.结果分析：测试完成后，可以通过仪器提供的分析工具对测试结果进行进一步分析，如绘制波形图、功率谱图、调制解调图等。

6. 测试报告生成：系统可生成详细的测试报告，包括测试参数、测试结果、分析图表等。

可以导出为Excel、PDF等格式。

三、使用注意事项1.使用正确的天线和连接器，确保信号传输的质量和稳定性。

2.在设备连接之间进行频谱清洁，避免干扰信号的出现。

3.在设置测试参数时，根据被测设备的要求进行合理选择。

4.在测试过程中要注意设备的工作温度和通风情况，确保设备的正常运行。

5.对于不同通信制式的测试，要熟悉相关的技术标准和测试规范，确保测试结果的准确性。

通过以上的操作说明，您可以正确使用安捷伦8960进行无线信号测试和性能检测。

根据测试需求，合理设置测试参数并分析测试结果，可以帮助您更好地了解被测设备的性能和信号质量。

安捷伦8960常用使用方法一、启动和连接1.将8960与电源适配器连接并接通电源。

2.使用USB线将8960与电脑连接。

3. 打开PC Application Manager（PCAM）。

在PCAM主界面，选择仪器配置，然后选择安捷伦通信仪器配置向导（Agilent Connection Expert）。

4.在配置向导中，点击“”按钮，选择8960无线通信测试仪。

5.配置仪器地址，点击“确定”完成配置。

二、创建和配置测试项目1.在PCAM中，选择“测试”选项卡，然后点击“创建测试项目”按钮。

2.在创建测试项目向导中，选择您要测试的技术类型（如LTE、WCDMA等）和版本。

点击“下一步”。

3.在配置测试项目向导中，根据测试需求选择适当的配置选项，如信道模型、功率控制设置等。

点击“下一步”。

4.配置测试项参数，如频率、功率、带宽等。

点击“下一步”。

5.配置高级设置，如硬件连接和接收测试。

点击“下一步”。

6.配置测试报告设置，选择报告生成方式和路径。

点击“下一步”。

7.点击“完成”按钮完成测试项目的创建和配置。

三、进行测试1.在PCAM中，选择“测试”选项卡，然后选择您创建的测试项目。

2.点击“开始测试”按钮开始测试过程。

3.在测试过程中，仪器将自动进行测试并记录测试结果。

4.在测试完成后，可以在PCAM中查看测试结果，包括各种指标和性能参数。

四、分析和优化1.在PCAM中，选择“分析”选项卡，然后选择您感兴趣的测试项目。

2.可以查看各种指标和性能参数的分析结果，如信号质量、功率控制、误码率等。

3.根据分析结果，可以进行优化和改进，如调整测试参数、改变信道模型等。

五、生成测试报告1.在PCAM中，选择“报告”选项卡，然后选择您感兴趣的测试项目。

2.点击“生成报告”按钮生成测试报告。

3.可以选择生成报告的格式和布局。

4.点击“生成”按钮生成测试报告。

六、其他功能和操作1.通过PCAM界面可以对仪器进行各种操作，如远程控制、固件升级等。

安捷伦89600矢量信号分析软件功能概述及测量指南2009年4月© Copyright 2009Agilent Technologies, Inc.通告本文档所含内容如有修改，恕不另行通知。

安捷伦对本资料不作任何形式的保证，包括但不限于为特定目的的适销性和适用性所作的暗示保证。

对其中包含的错误或由供给、使用本资料或由本资料的实用性而引起的偶然或继发的损失，安捷伦不承担任何责任。

© Agilent Technologies, Inc. 2009在安捷伦没有预先同意之前。

不得以任何形式复制本手册中的任何部分（包括电子存储和检索或翻译为其它语言）。

简介本手册介绍了安捷伦89600矢量信号分析软件的基本功能并重点说明了其数字解调分析功能及操作流程。

同时给出89600 矢量信号分析软件的多种数字解调分析工具和故障诊断方法。

通过对QPSK和W-CDMA信号的测量举例，详细描述了使用89600 矢量信号分析软件进行解调分析的测量过程和操作步骤。

其它信息欲获得更多信息，包括最新的产品信息、软件升级和应用信息，请访问下列网址：/find/89600目录Agilent 89600 VSA软件描述 (5)配置 (5)包含两个应用模式 (5)可接收多个测量前端的数据 (5)设计流程中应用Agilent 89600 VSA软件 (6)软件编程 (6)Agilent 89600 VSA软件功能举例 (7)宽频带测量 (7)窄扫宽超高分辨率测量 (7)捕获完整信号 (7)使用Bandpower Markers简化信道功率测量 (8)录制信号以延展分析能力 (9)使用模拟解调分析信号的建立过程 (9)使用模拟解调定位残余调制 (9)使用数字解调隔离符号时钟错误 (10)使用数字解调更容易地发现滤波问题 (10)使用窗口灵活配置用户化工具栏和显示 (11)结合Agilent ADS的分析 (12)数字解调分析 (13)数字解调器工作原理 (13)数字解调器设置十步骤 (13)QPSK解调分析步骤 (13)分析工具 (16)矢量图 (17)星座图 (17)眼图 (18)I/Q vs时间 (18)解调频谱 (19)误差矢量幅度 (19)幅度和相位误差 (20)误差矢量频谱 (21)符号表/错误摘要 (21)自适应均衡结果：脉冲响应和信道响应 (22)故障诊断 (22)诊断测试流程 (22)诊断：I/Q增益不平衡 (23)诊断：正交误差 (23)诊断：I/Q偏移 (24)诊断：符号速率错误 (25)诊断：滤波错误 (25)诊断：杂散和干扰信号 (30)诊断：压缩 (32)无线测量举例 – W-CDMA(3GPP)/HSPA (34)W-CDMA (3GPP)/HSPA 概览 (34)进行W-CDMA测量 (34)解调下行信号 (35)解调上行信号 (37)分析W-CDMA信号 (40)选择所分析的时隙 (43)测量诊断 (45)Agilent 89600 VSA软件描述Agilent 89600 VSA(Vector Signal Analysis）矢量信号分析软件提供基于Windows用户界面的矢量信号分析。

Agilent 8960操作指导书Agilent 8960 （E5515C）是Agilent公司推出的移动台综测仪，可以测试IS-2000，IS-95和AMPS三种系统的移动台，测试项目基本含盖EIA/TIA—98D协议中的所有测试项，仪器本身已经按照协议要求设置了各项指标的协议要求值，可以直接显示所测项是否满足协议要求。

此外Agilent 8960还可以通过以太网接口与计算机进行通信，将仪器所测试的结果，波形上传到计算机，供测试人员分析使用。

主要包括各种制式的呼叫处理测试，移动台发射机性能和接收机性能测试。

该测试仪使用方便，界面友好，是进行终端射频研发测试的重要测试仪器，也是我们在WCDMA，GSM和CDMA2000终端射频指标测试常用的测试仪器。

第一章8960基本操作一、8960前面板介绍1:方向与确认钮 11：自动设置键 21：电源开关2:方向键 12：删除键 22：选择下页键3:系统设置键 13：取消键 23：设置项选择键4:呼叫设置键 14：RF IN 24：状态栏5:测试启动键 15：网络接口 25：手机状态显示6:功能键 16：RF OUT7:增量设置 17：注册键8:数字与符号键 18：功能选择键9:回车键 19：测试项选择键10:手动选择键 20：复位键二、移动台测试仪Agilent8960测试连接组网三、移动台测试仪Agilent8960基本操作步骤1、给仪器接上电源，让仪器预热约30分钟；开机后界面：2、将移动台和该测试仪连接起来。

可以用直连电缆，也可以利用屏蔽盒（后者效果更好）将移动台和测试仪连接起来；3、模式设置:(包括IS-2000，IS-95，AMPS三种模式,本文以IS－2000模式为例)先按下CALL SETUP键，进入设置界面后，按下F1键选择Active cell操作模式,按下F2键选择IS-2000系统模式；4、测量参数设置:(主要设置的参数包括：Cell Power,Cell Band,Channel,Protocol Rev, Radio Config 及FCH Service Option Setup)按下F7键输入Cell Power的值，一般默认值为－55dbm/1.23MHZ；按下F8键选择Cell Band，800MHZ手机选择US-Cellular,450MHZ选择NMT-450；按下F9键选择Channel，输入手机要注册的频点，一般选择手机所在频点；按下F10键选择Protocol Rev，这里大部分手机选择6(IS-2000-0)；按下F11键选择Radio Config的类型，按下F12键选择Service Option的类型；按下More键，可以对其他的参数进行设置，如SID，NID，闭环功率控制模式，业务/基本信道的数据速率，接收功率控制等，这里不作介绍。

安捷伦8960测量原理及操作说明
安捷伦8960测量原理及操作说明
一、引言
本文档旨在详细介绍安捷伦8960测量仪器的原理及操作步骤，以帮助用户更好地理解和使用该设备。

二、设备概述
1、设备外观及主要组成部分
2、设备技术参数
3、设备功能及应用领域
三、测量原理
1、信号发生及调制原理
2、信号接收及解调原理
3、信号分析原理
四、设备使用前准备
1、设备安装及连接要求
2、设备电源接入
3、设备连接计算机或其他设备
五、设备操作步骤
1、设备开机及初始化
2、测试配置设置
3、测试场景选择
4、测试参数设置
5、数据记录与分析
6、测试报告
六、常见故障解决方法
1、设备无法开机
2、设备显示异常
3、测量结果不准确
七、常见操作技巧和注意事项
1、测试项选择建议
2、测试环境要求
3、定期维护保养
附件：
本文档附带以下附件供参考使用：
1、安捷伦8960设备说明书
2、测试案例示例文件
3、相关技术资料
法律名词及注释：
1、测试配置设置 - 指设备进行测试前的参数设置，以满足特
定测试需求。

2、测试场景选择 - 指根据不同测试目的选择合适的测试环境，如网络场景、信号强度等。

3、测试参数设置 - 指设备进行测试时需要用户设置的相关参数，如频率、功率等。

4、数据记录与分析 - 指设备自动记录测试数据并提供分析功能，以评估测试结果的准确性。

5、测试报告 - 指设备自动根据测试数据相应的报告，以便用
户查看和保存。

安捷伦8960测量原理及操作说明安捷伦8960测量原理及操作说明1.简介本文档旨在提供关于安捷伦8960测试仪的测量原理及操作说明。

安捷伦8960是一款常用于移动通信设备测试的测试仪器，具有多种功能和测量选项。

2.原理介绍2.1 通信原理在移动通信领域，安捷伦8960基于数字信号处理技术和射频技术，能够模拟基站信号，与待测设备进行通信。

通过不同的信号，可以对各种移动通信标准进行测试。

2.2 功能原理安捷伦8960测试仪内置了多种测试功能，如功率测量、频谱测量、调制解调、通信性能测试等。

这些功能的实现是通过仪器内部的算法和信号处理模块来完成的。

3.操作说明3.1 连接设备首先，确保将安捷伦8960正确连接到待测设备。

根据设备的接口类型和连接要求，选择适当的连接方式，并进行相应的物理连接。

3.2 仪器配置在开始测试之前，需要对安捷伦8960进行相应的配置。

首先，设置待测设备的通信标准和参数，以便能够正确地模拟通信环境。

然后，选择相应的测试功能和测量选项，根据需要进行配置。

3.3 开始测试配置完成后，开始按钮，安捷伦8960将开始向待测设备发送信号，并对其进行相应的测量和分析。

根据不同的测试目的，可以选择适当的测试模式和参数。

3.4 结果分析测试完成后，安捷伦8960会测试报告，并显示各项测试指标的结果。

根据需要，可以对测试结果进行进一步的分析和处理。

4.附件本文档附带以下附件：附件1：安捷伦8960使用手册附件2：安捷伦8960技术规格5.法律名词及注释为避免发生法律纠纷，本文档中涉及的法律名词及注释如下：1) 移动通信设备：指用于移动通信的各类终端设备，如方式、平板电脑等。

2) 测试仪器：用于对移动通信设备进行测试和测量的仪器设备。

3) 通信标准：移动通信设备遵循的技术规范和通信协议。

4) 功率测量：对设备输出的射频功率进行测量的过程。

5) 频谱测量：对设备输出的信号频谱进行测量和分析的过程。

6) 调制解调：对设备信号进行调制和解调的过程。

A g i l e n t8960操作指导书(总5页)-CAL-FENGHAI.-(YICAI)-Company One1-CAL-本页仅作为文档封面，使用请直接删除Agilent8960操作指导书1.目的规范测试员能熟练掌握仪器的使用操作步骤。

2.适用范围适用于公司各类产品的射频传导和天线耦合测试工作。

3.相关文件无4.所需设备、工具、材料Agilent-设备型号：8960-E5515C。

5.过程5.1.准备工作：1.检查电源是否正常通电。

2.是否能正常开机。

3.每天试验前根据《实验室仪器点检表》进行操作点检确认。

5.2.操作步骤：一、对于GSM/GPRS制式的手机，常需要测量的参数有：✓发射功率✓功率时间模板✓相位误差&频率误差✓开关谱&调制谱✓参考灵敏度电平1.打开电源开关，仪器面板如下图所示（见图一)；2.线损设置：按SYSTEM CONFIG，弹出如下界面。

按RF IN/OUT Amptd Offset 。

按F5, RF IN/OUT Amptd Offset Setup。

输入要设置的频率及对应的线损，对于与处于Off状态的项目，我们按On键即可开启。

（详细步骤见8960原理及使用方法介绍）。

3.建立连接：按SYSTEM CONFIG，打开如下界面。

按 Format Switch,选择要切换的制式，在这里我们选择GSM/GPRS。

在Operating Mode里选择 Active Cell (GSM),按 Original Call，当屏幕下方显示Connected的时候，表示连接已成功。

在屏幕右侧Traffic Band中选择需要的频段，在Traffic Channel中选择需要的信道。

在手机与8960已连接的情况下，按Measurement selection,选择 Transmit Power,进入测试界面。

按确定可以看到测试结果（详细过程见8960原理及使用方法介绍）。

Agilent 89601A Vector Signal Analysis Software Technical Overview• Reach deeper into signals • Gather more data on signal problems • Gain greater insightTable of ContentsOverview (3)Basic Vector Signal Analysis, Option 200 (5)Flexible Modulation Analysis, Option AYA (20)W-CDMA/HSPA (Enhanced HSPA) Modulation Analysis, Option B7U (21)cdma2000/1xEV-DV, Option B7T (22)TD-SCDMA Modulation Analysis, Option B7X (23)1xEV-DO Modulation Analysis, Option B7W (24)3G-Modulation Analysis Bundle, Option B7N (24)LTE FDD Modulation Analysis, Option BHD (25)LTE TDD Modulation Analysis, Option BHE (25)WLAN (IEEE 802.11a/b/g/) Analysis, Option B7R (27)WLAN-HT (IEEE 802.11n) Analysis, Option B7Z (30)Fixed WiMAX (IEEE-802.16-2004 OFDM) Modulation Analysis, Option B7S (33)Mobile WiMAX (IEEE-802.16 OFDMA) Modulation Analysis, Option B7Y (36)TETRA Enhanced Data Service (TEDS) Modulation and Test, Option BHA (39)MB-OFDM Ultra-Wideband Modulation Analysis, Option BHB (40)RFID Modulation Analysis, Option BHC (41)Hardware Connectivity, Option 300 (43)Dynamic Link to EEsof ADS/SystemVue, Option 105 (47)Dynamic Link to The MathWorks Simulink, Option 106 (49)Flexible Licensing (50)Ordering Information (53)User-Supplied PC Requirements (57)Related Literature and Web Resources (58)23More than spectrum analysisThe 89600 VSA software provides traditional spectrum displays andmeasurements, but today, spectrum analysis isn’t enough. New digital formatsrequire new measurements.Familiar tools such as spectrum analyzers with demodulation may indicate that aproblem exists, but they can’t help you understand the cause of the problem. Forinstance, incorrect filtering, spurious interference, incorrect interpolation, DACoverflow, symbol mis-timing and other errors may all increase adjacent channelpower and distort the constellation. So how do you determine what the realproblem is?The 89600 VSA software provides you the tools to identify the root cause of theproblem and to analyze continually changing phase, magnitude, and frequency.Some tools, like the constellation and vector diagrams, are familiar to radiodesigners. Others, like the spectrogram display are tools for qualitatively under-standing system behavior. And still others, like error vector time and spectrum, areentirely new measurements bringing new capabilities and requiring new displays.PC-based for ease-of-useThe 89600 software relies on a PC for its processing. Improvements in PC capabilitiesautomatically improve the VSA software’s performance. New capabilities forintegrating test instrumentation and design automation software are also madepossible because the VSA software can accept measurement data from a widerange of supported hardware platforms, or time series data from computationaltools—and all with a familiar, easy-to-use Windows® GUI.4Figure 2. This FM demodulation of a transmitter at turn-on shows the frequency settling characteristics. Use AM or PM demodulation to show amplitude and phase settling performance as well.Characterize amplitude-modulated, frequency-modulated, and phase-modulated signals in both the frequency and time domains with the built-in analog demodulation capabilities of the 89600 VSA software.6Figure 4. Both CCDF and CDF functions are available. The CCDF marker readout at the bottom of the display indicates that the signal exceeds 9.56 dB above the average signal level only .003% of the time, useful information when calculating design headroom.Display format and scalingFigure 5. Example trace formats available.Scale your display the way you want it, with the units you need using the flexible display formatting and scaling tools provided standard in the 89600 VSA software. Select from a complete list of formats including log and linear displays of the signal magnitude, displays of only the real (I) or imaginary (Q) part of the signal, vector and constellation displays, eye displays, trellis displays and group delay. Scaling is automatic with manual override provided for all parameters, including reference level and units per division for both the X and Y-axes.Figure 6. Display one, two, three, four, or six displays, simultaneously. You can choose to have themappear stacked, or in a symmetrical grid. You also control the information displayed for each display,which varies depending on the analysis option invoked.Spectrogram display format8Figure 8. The signal recording user interface is familiar and simple to use.The 89600 VSA software lets you capture your digitized signal in your measure-ment hardware and transfer it directly to your PC’s disk drive. You can play the signal back at a later time, import it into other applications, and create and play your own recording through an Agilent signal generator.Why record signals?•No gaps – offers continuous time record at full bandwidth of your hardware.•Provides powerful post processing with more control over the analysis.•Allows slow playbacks with overlap processing. Overlap processing allows you to vary the amount of new information included in each display update. The end result is to provide a “slow motion” view of your signal—extremely useful in understanding transients and transitions.•Offers porting of simulations back to design software.•Allows you to archive – saving signal records for future analysis.You have full control of the playback including:•Start and pause•Drag the bar to any position in the record to begin playback•Back up and rewind1011Figure 11. ACPR measurement with summary table enables you to specify up to five adjacent channels.The OBW marker allows you to easily perform occupied bandwidth measurements.The OBW measurement determines the band of frequencies that contain a specifiedpercentage of the total power within the measurement span.Figure 12. The OBW measurement with summary table can determine the centroid frequency, or you canmanually set the centroid frequency to the center frequency.12Figure 13. Set the pass and fail color indication for either the limit, or the margin, or both. You define your own limits using the built-in limit line editor.These more sophisticated marker measurements allow more sophisticated setup. For example, you define a table of values, as for ACPR or simple limit tests. For more complex limit tests, you can either define a set of limit points segment by segment, or import a measurement and add a margin limit around it. For all of these and other markers, the results are displayed at the bottom of the display.14Figure 14. Everything, from reference information, to tutorials using recorded signals, to programming examples, is included in the incredibly comprehensive help text.Over 5000 equivalent paper pages of help text, application information and tutorials are provided with the 89600 software. A complete set of search tools and hot links provide ready access to all of this information.16Table 1. Choose from the many available modulation analysis options to meet your measurement needs. The modulation formats supported by each option are listed below.Supported modulation formatsAvailable with Option AYAAPCO 25, Phase 2 HCPM, DECT DVB64 HIPERLAN/1 (HBR) PHP (PHS)Phase 2-HDQPSKBluetooth™ DTV8 DVB128 HIPERLAN/1 (LBR) TETRACDMA base DTV16 DVB256 MIL-STD 188-181C CPM (Opt 21) VDL mode 3CDMA mobile DVB16 EDGE, EDGE NADC WLAN (802.11b)Evolution (EDGE2)CDPD DVB32 GSM PDC ZigBee (IEEE 802.15.4-2003) General modulation formats, available with Option AYA(With variable center frequency, symbol rate, filtering type and alpha/BT)BPSK, 8PSK VSB 8-, 16- Offset QPSKQPSK FSK 2-, 4-, 8-, 16-level EDGEPi/4 DQPSK DQPSK DVBQAM 16, 32, 64, 128, 256MSK type 1, type 2; CPM (FM) D8PSK APSK 16/32 (12/4QAM)QAM 16-, 32-, 64-, 128-, 256-, 512-, 1024-; Star-16, 32 π/8 D8PSK3G Wireless communications formats3GPP LTE FDD Option BHD3GPP LTE TDD Option BHEThe following formats are included in Option B7N:cdma2000®/1xEV-DV Opt B7TW-CDMA/HSPA Opt B7U1xEV-DO Opt B7WTD-SCDMA Opt B7XBroadband wireless access formatsIEEE 802.16-2004 OFDM Opt B7SIEEE 802.16 OFDMA Opt B7YWireless networking formatsWLAN (IEEE 802.11a,b,g,p,j); WLAN (HiperLAN/2) Opt B7RIEEE 802.11n MIMO (WLAN-HT) Opt B7ZPublic safety radio formatsTETRA Enhanced data service Opt BHAUltra-wideband formatsMB-OFDM Opt BHBRFID formats Option BHCEPCGlobal Class-1 Generation-2 UHF (ISO 18000-6 Type-C)ISO 18000-4 Mode-11ISO 18000-6 Type A1ISO 18000-6 Type B1ISO 18092ISO 14443 Type AISO 14443 Type BISO 15693General RFID modulation formats and coding with Option BHCForward: DSB-ASK, SSB-ASK, PR-ASK, FSK-2, OOK; None (NRZ); Manchester, FM0, PIE (ISO 18000-6 Type-A), PIE (EPC C1Gen2), Modified Miller; ISO 15693 1 out of 4, ISO 15693 1 out of 256Return: DSB-ASK, FSK-2, OOK; None (NRZ); Manchester, FM0, Miller, Miller-2, Miller-4, Miller-8, Modified Miller, SubcarrierFigure 15. The “v” shape in the EVM versus time display indicates a symbol clock timing error.Trace math can help determine the approximate clock rate.Figure 16. This signal shows higher EVM in between the symbols (shown in green) than atthe symbol clock times (shown in red), a clear indication of filtering errors. You can try anddetermine the correction needed by using the adaptive equalization filter.Agilent 89600 VSAs offer sophisticated error analysis that lets you see both RFand DSP problems. The key is the EVM measurement. The error vector time plotsan error signal versus time diagram. With it, you can identify problems such asclock timing errors, DAC overflow, compensation errors and more —all with onescreen. Other tools include error vector spectrum and adaptive equalization.18Figure 17. This signal’s spectrum, constellation, and EVM error look reasonable. But the error vector spectrum display (top right) clearly shows the presence of an interferer. Further investigation shows that this frequency is related to a subsystem in another part of the DUT. It is obviously leaking through to the point where this measurement was made.EVM is a powerful analysis tool that helps you pinpoint marginal conditions before they become system performance problems. EVM compares the phase and magnitude of the input signal with an ideal reference signal stream. The average error over time is displayed as a single percent, or the error can be viewed on a symbol-by-symbol basis.Use the FFT of the error vector time signal to identify systematic impairments you couldn’t otherwise see. Identify spurs coupling from other parts of the system by looking at the error vector spectrum for peaks.Adaptive equalizationAdaptive equalization identifies and removes linear errors from I-Q modulated signals by dynamically creating and applying a compensating filter. These errors include group delay distortion, frequency response errors, and reflections or multi-path distortion. You can also uncover DSP errors such as miscoded bits, or incorrect filter coefficients.Equalization is a tool designers can use to identify and correct linear errors.Pre-distorting a signal to correct for linear errors can be simpler, faster, and cheaper than modifying hardware to make the corrections. Further, some wide-band signals are almost impossible to measure without adaptive equalization.19Figure 18: The VSA software auto-detects many important EDGE Evolution signal parameters, and reportsthe results in a summary table. You can choose to see the de-rotated IQ constellation.Figure 19. 16QAM signal with spectrum and error vector magnitude versus time display.20Figure 20. Option B7U provides enhanced HSPA uplink, downlink, and MIMO analysis. View data at the single channel, composite channel, code domain, and MIMO antenna 1 or antenna 2 for detailed troubleshooting.Measure, evaluate and troubleshoot your W-CDMA and Enhanced HSPA (HSPA+) signals with the tools in Option B7U. Use these tools to descramble, despread, and demodulate W-CDMA uplink and downlink signals. The analyzer automatically identifies all active channels regardless of the symbol rate or spread code-length. Measure 2x2 DL MIMO for HS-PDSCH with supported 2-channel hardware. Take advantage of new MIMO measurement traces to get an overall view of the signal quality, or to dive down into the individual antenna CDE or CDP performance. Speed measurement set-up with standard pre-sets for uplink (mobile station or user equipment) and downlink (base station). Use the single layer and composite code-domain power and code-domain error displays (the composite display shows all codeFigure 21. Use the extensive 89600 Option B7T toolset to evaluate the performance of your cdma2000/ 1xEV-DV signals. Notice the code domain power and error displays, vector constellation display and error summary table. These traces are for the composite (entire) signal. Similar tools are available for layer and channel analysis.The robust and flexible features provided in Option B7T give you the tools you need to test your cdma2000/1xEV-DV signals to their standards and identify the cause if the signal fails to meet its standard. Descramble, despread, and demodulate both the forward and reverse link signals. The software automatically identifies all active channels regardless of symbol rate or Walsh code.Signal analysis capabilities are identical to the advanced tools provided for W-Figure 22. Composite TD-SCDMA modulation analysis.Troubleshoot and analyze your time division synchronous code domain multiple access (TD-SCDMA) modulation and RF performance with Option B7X for Agilent’s 89600 VSA software.This analysis package handles the 3GPP N-TDD 1.28 Mcps version of TD-SCDMA, including HSDPA (16QAM, 64QAM, and 8PSK). Demodulate HSDPA 16QAM and 8PSK modulated code channels, with automatic detection of code channel modu-lation type with manual override and automatic detection of multiple midamble shifts. Single code domain layer or composite power and code domain displays are provided. Normalize code-domain power to display code domain power relative toFigure 23. Multiple views of a composite 1xEV-DO signal.Measure and analyze 1xEV-DO modulated signals with the capabilities offered as part of Option B7W. Descramble, despread, and demodulate 1xEV-DO modulated signals. You can also analyze the reverse link (mobile station or access terminal) and forward link (base station or access network) channels. The analyzer auto-matically identifies all active channels regardless of the symbol rate or Walsh code length.The advanced technology demodulator used in this option does not require coherent carrier signals, or symbol-clock timing signals, and comes with an internal IS-2000 filter. All you have to do is enter carrier frequency, chip rate, reverse/forward link direction, and set the long code mask. The analyzer will do the rest.LTE FDD Modulation Analysis (Option BHD)LTE TDD Modulation Analysis (Option BHE)Agilent LTE modulation analysis options enable comprehensive 3GPP LTE trouble-shooting. Option BHD provides LTE FDD modulation analysis, while Option BHE provides LTE TDD modulation analysis.Both options provide:• Analysis of UL and DL signals, supporting up to 50 users x 250 allocations • Analysis of all LTE bandwidths • Up to 4x4 DL MIMO analysis, including multi-layer results analysis and display • DL and UL auto-detection • Simultaneous analysis of multiple UL channels • DL test models for verification per the E-UTRA standard • Up to 6 simultaneous displays, color-coded by channel/signal type • Channel-selective measurements to troubleshoot by resource block, sub-carrier, slot, or symbolPowerful Visualization ToolsFigure 24. The 89600 VSA LTE analysis options provide graphical tools to help you quickly visualize your signal and begin to identify and examine errors.LTE analysis is a complicated task. The 89600 VSA software helps make it easier by providing up to six simultaneous, user-selectable displays. Color-coding by user channels and signals lets you quickly see if errors are due to any specific channel or signal. You can select which channels and signals you want to include in mea-surements, for easier display of potential problems.Complete Measurement Setup ControlSignal measurements use auto-detection of both UL and DL channels, as well as auto-detection of CP length, Cell ID, and RS-PRS. But you can adjust many shared channel and control channel/signal parameters.Consistent color-coding by channel type throughout data and error displays Detected allocations provide high level view of signal for overall structure verificationColor-coded error traces with average line help to visually indicate potential error sourcesFigure 25. Use Preset to Standard and UL/DL Auto Detection for fast LTE measurement setup. Manual control of a wide range of parameters allows for measurement adjustment during early design stages. You can adjust the measurement offset and interval to gate the measurement and select only specific intervals for analysis. Or you can choose to display only certain channels/signals. This flexibility lets you focus the analysis on potential errors and adjust your setup to measure even early LTE designs which might not yet be fully realized or compliant. 4x4 MIMO Analysis The 89600 VSA software supports analysis of 2- or 4-antenna MIMO signals using a combination of Tx Diversity or Spatial Multiplexing pre-coding. Per-layer error analysis measurements including Error Vector Spectrum and Error Vector Time, plus decoded symbols, IQ constellation displays, and more are available. Powerful MIMO-specific measurement tools such as equalizer condition number and equalizer channel frequency response help quantify the quality of MIMO systems and identify problems by carrier or MIMO path.Figure 26. Trace D displays the equalizer frequency response for all detected ports of a 4x2 MIMO system. The marker readout indicates problems with the Tx0/Rx1 path. The MIMO info table shows that this path has highRS EVM. Note the matching color-coding between the two traces.Up to 2x2 MIMO analysis can be done using dual MXA/EXA signal analyzers, 2-channel 89600S VXI-based VSA analyzer, or 2-channel supported Agilent Infiniium and Infiniivision Series oscilloscopes. For 4x4 MIMO analysis, the 89600 VSA software supports the oscilloscopes.Use built-in preset to standard function, or manually adjust measurement parameters Graphical tool added to show MIMO signal path for easier results interpretation Use auto-detection, or manually create channel maps.Manually edit control parameters Select which signals to display in measurement tracesFigure 27. Demodulate the optional PBCC modes of IEEE 802.11g.Figure 28. Time gating is a powerful tool for selective analysis of time waveforms. The time gate (two vertical lines in the lower trace) allows FFT analysis on only the payload portion of the waveform.Agilent is an industry leader in base band, RF, and modulation quality measurements of WLAN signals. The 89600 VSA software WLAN analysis option offers:•IEEE 802.11a OFDM modulation analysis•IEEE 802.11b DSSS/CCK/PBCC modulation analysis•IEEE 802.11g modulation analysis•IEEE 802.11a/b/g standards-based testing•IEEE 802.11p DSRC modulation analysis•IEEE 802.11j 10 MHz modulation analysisTwo modes, DSSS/CCK/PBCC and OFDM, are offered with Option B7R. Use these modes together to analyze the IEEE 802.11g signals and use them separately to analyze IEEE 802.11b or IEEE 802.11a signals. For IEEE 802.n MIMO analysis, see Option B7Z.Figure 29. View the EVM spectrum or EVM time of an IEEE 802.11a OFDM burst. The EVM spectrum error shows a ‘V’-shaped pattern, indicating a timing error of some sort. The most likely causes are an I-Q time offset, or symbol clock error.Demodulate and analyze IEEE 802.11a, IEEE 802.11g, and HiperLAN2 compatible signals with the OFDM modulation analysis mode provided in Option B7R. This high performance capability supports demodulating OFDM bursts down to the bit level. Use the compound constellation display to automatically determine and dis-play all modulation formats (BPSK, QPSK, 16QAM, 64QAM) present in the burst.Figure 31. The 89600 software with Option B7Z provides 2x2, 3x3, or 4x4-MIMO analysis and allows you to see important parameters associated with each channel or data stream, individually or simultaneously.Figure 32. Use the wealth of information available for 4x4 MIMO analysis to improve your designs. Note the constellations with and without IQ compensation. The IQ mismatch removed is reported in the Error Summary table. Note the "IQ COMP" indicator in each trace where the IQ mismatch was compensated out.Figure 33. Up to 16 equalizer channel frequency response traces are available, one for each streampresent on each channel. Use the x-axis expand capability to see detailed behavior of all equalizerfrequency response data.32Figure 34. Familiar and new tools combine to provide invaluable troubleshooting information.Here the six displays simultaneously show (l to r) I-Q constellation, time, CCDF, spectrum, modulation error summary, and error vector vs. time.Agilent is the industry leader in base band, RF, and modulation quality measurements for IEEE 802.16-2004 OFDM signals. Whether your measurements are on base band, IF or RF signals, or even simulated signals from ADS design simulations, the 89600 VSA software with Option B7S has the tools you need to troubleshoot your designs today.Analyzing OFDM signals requires developers like you to think in the time and frequency domains simultaneously. You need OFDM-specific signal analysis tools to help you manipulate and break down the signal in order to effectively trouble-shoot the situation. The 89600 vector signal analysis software helps you do this quickly and efficiently.First, Option B7S provides comprehensive coverage of the IEEE 802.16-2004 standard:•All IEEE 802.16-2004 modulation formats, including BPSK, QPSK, 16QAM, and 64QAM•TDD, FDD, and H-FDD•Uplink and downlink34IEEE 802.16 OFDMA Modulation Analysis(Option B7Y)The IEEE 802.16 OFDMA PHY layer structure is the most complex structure for wire-less networking. Option B7Y provides an advanced and comprehensive tool set toevaluate and troubleshoot signaling format. These tools work together to simplifyanalysis complexity for even the challenging Mobile WiMAX™ Wave 2 features.Comprehensive tool kitOption B7Y provides analysis of:•PUSC, OPUSC, FUSC, OFUSC, AMC zones, including dedicated pilot option forPUSC and AMC beamforming•Uplink and downlink•All bandwidths from 1.25 MHz through 28 MHz•All FFT sizes from 128 to 2048•DL-PUSC signals using 2-antenna matrix A or B transmission schemes forSTC/MIMO•UL-PUSC signals containing data bursts with collaborative spatialmultiplexing (SM) enabled•CDMA ranging regions to aid with troubleshooting network entry•IQ impairment compensation allows RCE measurements to be made even inearly design phases or prior to calibration•Downlink signals employing Cyclic Delay Diversity (CDD)Figure 36. Detailed MIMO information is available for each T x/Rx path in both tabular and graphical formats. 36STC/MIMO measurementsAnalyze DL-PUSC single-channel matrix A and B antenna 1 signal format transmissions, or use 2-channel analysis hardware to analyze 2-antenna matrix A and 2-antenna matrix B signals providing WiMAX STC/MIMO features. See the channel frequency response, equalizer impulse response, and common pilot error for each antenna. Other per-antenna path metrics, like power and pilot RCE, are displayed on a separate MIMO Info summary trace. Option B7Y decodes the MIMO DL Enhanced IE so that the software can auto-configure the measurement setup.The software is designed to make WiMAX RCT testing easier. For instance, make DL-PUSC MIMO measurements even on single input channels where no preamble or non-MIMO zones exist. This can reduce the cost of making certain MIMO BTS transmission RCTs called out by the WiMAX forum. And the software's ability to make measurements even when slots are allocated but unused make it useful for analyzing and comparing signal profiles often used at WiMAX plugfests. Finally, the software can display the total power in a data burst as specified in several WiMAX RCTs.Option B7Y supports the sophisticated transmission modes for BTS transmitters. For instance, you can use the DL-PUSC dedicated pilots mode to make RCE mea-surements for beamforming BTS transmitters. And a new cyclic delay diversity metric is provided on the selected input channel for BTS transmissions using CDD.Advanced WiMAX features include collaborative spatial multiplexing (SM). Collaborative SM is a method where two independent mobile stations simultane-ously transmit on the same subchannels at the same time. The base station extracts the data from each mobile station using MIMO channel separation techniques. The 89600 VSA software can analyze UL-PUSC signals from a single transmitter containing data bursts with collaborative SM enabled. See information on the transmission mode detected such as power, RCE, and data RCE.37Complex signals, easy-to-use analysis tools with auto-configuration The 89600 VSA's OFDMA tools work together to simplify the complex analysis challenge presented by Mobile WiMAX.Option B7Y can automatically decode the DL-MAP to provide dynamic auto-con-figuration of complex downlink signals, including those using MIMO/STC support. Even uplink signals for most Mobile WiMAX default profiles can be decoded to provide auto-configuration. Configurations decoded from downlink signals can be copied to user MAP Files in order to more easily analyze the signal, or to share signal configuration information with colleagues. Measurement results are color coded by data burst, where appropriate. You can look at the compound constellation of a multi-burst data zone and tell at a glance if your data bursts are using the modulations you programmed. You are able to go to the error vector time display and easily determine which data burst an EVM spike belongs to.The same works with the error vector spectrum display. Other analyzers make you move back and forth between measurements looking at symbol times and logical sub-carrier numbers to get the information you need, while Agilent uses color to simplify and streamline your analysis task. You can also couple markers across multiple displays to ‘walk’ through your signal and simultaneously look at its behavior in the time, frequency, modulation, and error domains.Figure 37. Use auto-detection or manually adjust a wide range of set-up parameters for troubleshooting. Color-coding throughout eases data interpretation, and 6 simultaneous user-selected displays let you choose the information that is important to you.38Detailed error summary with bitsAuto-detection and configuration EVM per symbol or carrierDouble-click on a burst to show constellation and error traces for that burst onlyConsistent color coding by burst throughout all measurement tracesDetected allocations trace shows user occupation of subcarriers across all symbols for easy overviewFigure 38. Define your TEDS test parameters with an easy-to-use menu setup. A test properties menu lets you set test parameters, select the test, preset test definitions, and even modify the test definitions if desired. Step-by-step configuration procedures are provided for each of the five TEDS tests. In addition, the test presets are defined for each of these tests.39。

Agilent8960关于3G使用说明Agilent8960关于3G使用说明Agilent8960关于3G使用说明日前，安捷伦科技公司(NYSE: A)宣布，针对Agilent W-CDMA/HSDPA和GSM/GPRS/EGPRS实验室应用推出多种先进的3G解决方案，并将通过Agilent 8960无线测试仪来提供。

这些解决方案可帮助研发工程师和集成工程师在保证原有设计性能水平的同时，尽快将产品推向市场。

目前，8960 W-CDMA/HSPDA实验室应用可以支持FRC通道，包括同时支持RB和FDD测试模式能力。

在本季度内，还将发布针对该产品的多项增强特性，其中包括：1} 端对端数据连接能力，它将使用户能够建立一条采用HSPDA的IP数据通道，在测试台上仿真最终用户的应用体验;2} HSDPA数据吞吐量监视器，使设计师可通过数据通道查看实时数据速率。

“无线协议分析软件（Wireless Protocol Advisor）还会增加对HSDPA的支持。

这款独特的实时分析工具可以快速确定和解决最难处理的协议问题。

安捷伦科技公司副总裁兼无线部总经理Earl Thompson先生说：“W-CDMA/HSDPA实验室应用以室内测试为基础，通过一体化的测试仪提供了当前速度最快的包数据通道。

这些先进特性表明，安捷伦正在积极致力于确保Agilent 8960继续成为当今研发工程师和集成工程师的最佳选择。

”Agilent 8960的HSDPA包数据通道，使开发商能够测试HSDPA应用的功能和HSDPA数据吞吐量。

其支持全球频带的特性，也使工程师能够针对所有地区的电话进行性能验证。

增强的HS-DPCCH工具可被用于分析和修复HSDPA功率放大器的故障。

安捷伦正在对Agilent 8960 W-CDMA/HSDPA实验室应用做出进一步改进。

其中包括：支持CA T 6（6类）端对端数据连接和HSDPA衰落、InterRA T 2-box数据和话音切换，以及空闲和数据重新选择能力。