LT760高速差分比较器

IO-Link手册第三版请访问：/CN目录引言第4页第1部分：IO-Link简介第5页◆老派传感器第5页◆微型开关量传感器驱动第5页◆I O-Link：开放式低成本传感器接口第5页◆I O-Link节点第5页◆I O-Link系统第6页◆I O-Link接口在IEC 61131-9中被标准化为SDCI第6页◆物理层IO-Link标准化接口第6页◆物理层电气规范第7页◆自动化体系中的IO-Link第7页◆I O-Link：实现智能传感器第7页◆工业传感器生态系统第8页第6部分：提高系统性能第24页◆散热第24页◆测试A第24页◆测试B第24页◆测试C第24页◆热性能第24页◆分立解决方案第25页◆集成解决方案第25页◆选择TVS二极管第25页◆I O-Link保护电路第25页◆65 V（绝对最大值）如何帮助提供保护（对比40 V）第25页◆65 V绝对最大值的保护优势第25页◆小结第26页◆I O-Link信号摆率如何影响IO-Link电缆辐射？第26页引言当今的无风扇可编程逻辑控制器(PLC)和IO-Link®网关系统须消耗大量功率，具体取决于I/O配置（IO-Link、数字输入/输出、模拟输入/输出）。

随着这些PLC演变成新的工业4.0智能工厂，我们必须深谋远虑，实现更智能、更快速、更低功耗的解决方案。

这场革命的核心是一项名为“IO-Link”的新技术，能帮助实现灵活制造，从而改善工厂吞吐量，提高运营效率。

这项激动人心的新技术正使传统传感器转变为智能传感器。

ADI公司提供一系列先进的工厂自动化解决方案，并通过我们的IO-Link技术产品系列进一步改进性能，为实现工业4.0铺路架桥。

MAX22513是该产品系列的最新成员，这是一款微型双通道IO-Link收发器，集成了浪涌保护和DC-DC转换器，可减少热耗散并提高工厂车间传感器的稳定性。

为了帮助我们的客户缩短上市时间，我们与来自IO-Link联盟的软件协议栈供应商合作开发了一系列经过全面验证和测试的参考设计，本手册对此进行了详细说明。

特点⏹ 推荐工作电压：4.5V~50V ⏹ 输出ADJ 、5.0V 、12V 电压版本 ⏹ 输出电压范围：1.23V~45V ⏹ 最大占空比90%⏹ 反馈基准电压精度±1.5% ⏹ 恒定52KHz 开关频率 ⏹ 最大3A 开关电流 ⏹ 内置高压功率晶体管 ⏹ 效率高达90%以上⏹ 出色的线性调整率与负载调整率 ⏹ EN 引脚TTL 关机功能 ⏹ 内置限流保护功能⏹ 温度等级1级：-40℃至125℃的环境工作温度范围⏹ 器件HBM ESD 分类等级Class3B ⏹ TO220-5L 封装描述XL2576HVT 是一款高电压，高效率的降压型DC-DC 开关转换器，恒定52KHz 开关频率，输出电流能力高达3A ，XL2576HVT 支持4.5V~50V 的宽输入操作电压范围，同时支持最大占空比90%输出，芯片内置环路补偿模块有效减少系统元器件数量，降低整个电源系统的成本并减小印制电路板的空间。

XL2576HVT 提供ADJ 可调输出电压版本，5.0V 、12V 固定输出电压版本。

芯片内置输出限流保护功能等。

应用⏹ 汽车电子 ⏹ 工业控制 ⏹ 通讯设备 ⏹ 物联网典型应用示意图E f f i c i e n c y (%)Output current(A)图1.XL2576HVT-5.0典型应用示意图和转换效率曲线引脚配置GND SW VINFB 12345TO263-5LMetal Tab GNDEN GND SW VINFB TO220-5LMetal Tab GND图2. XL2576HVT 引脚配置表1.引脚说明订购信息方框图图3. XL2576HVT方框图绝对最大额定值（注1）作，在绝对最大额定值条件下长时间工作可能会影响芯片的寿命。

XL2576HVT -ADJ电气特性T A = 25o C；图4与图6系统参数测量电路，除非特别说明。

XL2576HVT -5.0电气特性T A = 25o C；图8系统参数测量电路，除非特别说明。

Keysight InfiniiVision DSOX1204A/G 示波器用户指南声明Keysight Technologies, Inc. 2005-2018根据美国和国际版权法，未经 Keysight Technologies, Inc. 事先同 意和书面允许，不得以任何形式或通过 任何方式（包括电子存储和检索或翻译 为其他国家或地区的语言）复制本手册 中的任何内容。

手册部件号N2137-97002版本第一版 版, 2018 年 9 月Malaysia 印刷发布者：Keysight Technologies, Inc.1900 Garden of the Gods Road Colorado Springs, CO 80907 USA修订历史N2137-97002, 2018 年 9 月担保本文档中包含的材料" 按现状"提供，在将来版本中如有更改，恕不另行通知。

此外，在适用法律允 许的最大范围内，Keysight 不对本手册及其包含的任何信息提供任何明示或暗示的保证，包括但不仅限于对适销性和用于特定用途时的适用性的暗示担保。

对于因提供、使用或运用本文档或其包含的任何信息所导致的错误或者意外或必然损害，Keysight 概不负责。

如果Keysight 和用户之间已达成的单独书面协议包含涉及本文档内容的担保条款，但担保条款与这些条款有冲突，则应以单独协议中的担保条款为准。

技术许可对于本文档中描述的硬件和／或软件，仅在得到许可的情况下才会提供，并且只能根据许可进行使用或复制。

美国政府的权利如美国联邦采购法规（以下称"FAR"）第 2.101 条所定义，本软件是"商业计算机软件"。

根据 FAR 第 12.212条和第 27.405-3 条以及美国国防部FAR 补充条例（以下称"DFARS"）第227.7202 条，美国政府采购商业计算机软件须与本软件按惯例向公众提供时一样适用相同的条款。

AUTO TIME109AUTOMOBILE DESIGN | 汽车设计时代汽车 一种共差模信号分离器设计何梦之上海机动车检测认证技术研究中心有限公司　上海市　201805摘 要： 本文设计了一款基于射频变压器的共差模信号分离器，针对射频变压器在高频区域隔离度不够的缺点，引入差模滤波电容以及共模扼流圈从而提高了在高频区域的性能。

首先通过电路仿真分析了该装置的可行性，之后组装装置进行了实物测试，证明了该分离器对共差模信号分离的有效性。

关键词：电磁兼容　共模信号　差模信号　信号分离器1　引言随着电子技术的发展，越来越多的设备向着智能化、电子化发展，因此电磁兼容已成为研究微电子设备安全稳定的重要课题。

传导电磁干扰噪声是电磁兼容测试中非常容易超出限值的项目，其整改难度较高，因此国内外众多学者致力于传导电磁干扰噪声的整改技术研究。

对于噪声分离器的研究主要可以分为使用硬件实现噪声分离和使用软件实现噪声分离两大类。

在硬件方面，美国的Paul [1]、新加坡的See [2]、法国的Mardiguian [3]都采用了变压器作为主要的分离器件，通过将人工电源网络的L 端输出与N 端输出进行加减：V CM =V L +V N /2、V DM =L+V N/2，从而实现对共模差模信号的分离；美国的Guo [4]提出了采用0°/180°功率合成器取代变压器实现噪声分离，分别用0°和180°的功率合成器实现共模和差模的模态分离；区昌健[5]提出了采用共模抑制电路与差模抑制电路，分别抑制差模或者共模信号来实现单独噪声暑输出；在软件方面，刘鹏[6]将加窗差值算法应用在离散时域数据点的离散傅里叶分析上，从而实现共模差模信号的分离；台湾的Lo [7]提出将通过单模态硬件分离网络输出的CM 或DM 信号再输入到计算机中，然后根据LISN 检测到的实际线上干扰信号和前置单模分离网络得到的单模态信号，通过组合计算最终得到另一个模态干扰信号。

123428fV IN , V OUT , SWA, SWB Voltage.......................–0.3 to 6V SWA, SWB Voltage, Pulsed, <100ns .........................7V SHDN, VC Voltage .........................................–0.3 to 6V FB Voltage ...................................–0.3 to (V OUT + 0.3V)Operating Temperature Range (Note 2)..–40°C to 85°C Storage Temperature Range..................–65°C to 125°CORDER PART NUMBER DD PART MARKING T JMAX = 125°C, θJA = 45°C/W,θJC = 3°C/WConsult LTC Marketing for parts specified with wider operating temperature ranges.LBBGABSOLUTE AXI U RATI GSW W WU PACKAGE/ORDER I FOR ATIOUUW (Note 1)ELECTRICAL CHARACTERISTICSNote 1: Absolute Maximum Ratings are those values beyond which the life of a device may be impaired.Note 2: The LTC3428E is guaranteed to meet performance specifications from 0°C to 70°C. Specifications over the –40°C to 85°C operatingtemperature range are assured by design, characterization and correlation with statistical process controls.The ● denotes the specifications which apply over the full operatingtemperature range, otherwise specifications are at T A = 25°C. V IN = 3.3V, V OUT = 5V unless otherwise noted.PARAMETERCONDITIONS MIN TYP MAX UNITSMinimum Startup Voltage 1.5 1.6V Quiescent Current, V OUT SHDN = V IN 100200µA Quiescent Current, V IN SHDN = V IN 1.32.0mA Shutdown Current SHDN = 0V 1µA Switching Frequency Per Phase ●0.8 1.0 1.2MHz FB Regulated Voltage ●1.2191.243 1.268V FB Input CurrentV FB = 1.24V150nA Error Amp Transconductance 170µS Output Adjust Voltage 1.65.25V NMOS Switch Leakage V SWA , V SWB = 5.5V, Per Phase 0.1 2.5µA NMOS Switch On Resistance V OUT = 5V, Per Phase 0.093ΩNMOS Current Limit Per Phase●2 2.5ASHDN Input Threshold ●0.40.8 1.5V SHDN Input Current 0.011µA Maximum Duty Cycle ●8087%Minimum Duty Cycle ●%Current Limit Delay to Output(Note 3)40nsNote 3: Specification is guaranteed by design and not 100% tested in production.Note 4: This IC includes overtemperature protection that is intended to protect the device during momentary overload conditions. Junctiontemperature will exceed 125°C when overtemperature protection is active.Continuous operation above the specified maximum operating junction temperature may impair device reliability.TOP VIEWDD PACKAGE10-LEAD (3mm × 3mm) PLASTIC DFN EXPOSED PAD MUST BE SOLDEREDTO GROUND PLANE ON PCB 10967845321PGNDB SWB V IN AGND FBPGNDA SWA V OUT SHDN V C11LTC3428EDD33428 G043428 G023428 G013428 G033428 G0710ns/DIV500ns/DIV500ns/DIV500ns/DIV100µs/DIVOutput Voltage Ripple with 22µF43428fPI FU CTIO SU U UPGNDA, PGNDB (Pins 1, 10, 11 (Exposed Pad)): Power Ground for the IC. Tie directly to local ground plane.SWB (Pin 2), SWA (Pin 9): Phase B and Phase A Switch Pins. The inductor and Schottky diodes for each phase are connected to these pins. Minimize trace length to reduce EMI.V OUT (Pin 3): Power Supply Output and Bootstrapped Power Source for the IC. Connect low ESR output filter capacitors from this pin to the ground plane.SHDN (Pin 4): Shutdown Pin. Grounding this pin shuts down the IC. Connect to a voltage greater than 1.5V to enable.TYPICAL PERFOR A CE CHARACTERISTICSU WP E A K C U R R E N T L I M I T (A )3.43.23.02.82.62.42.22.03428 G10TEMPERATURE (°C)–451555–25–5357595Peak Current Limit vs TemperatureV C (Pin 5): Error Amp Output. A frequency compensation network is connected to this pin to compensate the boost converter loop.FB (Pin 6): Feedback Pin. A resistor divider from V OUT is connected here to set the output voltage according to V OUT = 1.243 • (1 + R1 / R2)AGND (Pin 7): Signal Ground for the IC. Connect to ground plane near feedback resistor divider.V IN (Pin 8): Input Supply Pin. Bypass V IN with a low ESR ceramic capacitor of at least 4.7µF. X5R and X7R dielec-trics are preferred for their superior voltage and tempera-ture characteristics.56783428fTable 2. Capacitor Vendor InformationSupplier PhoneFaxWebsiteAVX (803) 448-9411(803) Sanyo (619) 661-9322(619) TDK (847) 803-6100(847) Murata(814) 237-1431(814) Taiyo Yuden (408) 573-4150(408) Output Diode SelectionFor high efficiency, a fast switching diode with low reverse leakage and a low forward drop is required. Schottky diodes are recommended for their low forward drop and fast switching times. When selecting a diode, it is important to remember that the average diode current in a boost converter is equal to the average load current: I D = I LOAD When selecting a diode, make sure that the peak forward current and average power dissipation ratings meet the application requirements. See Table 3 for a list of Schottky diode manufacturers. Example diodes are Philips PMEG1020, PMEG2010, On-Semi MBRA210, IR 10BQ015, Microsemi UPS120E, UPS315.Table 3. Diode Vendor InformationSupplier PhoneFaxWebsite Philips +31 40 27 Microsemi (949) 221-7100(949) On-Semi(602) 244-6600 International (310) 469-2161(310) RectifierThermal ConsiderationsTo deliver maximum power, it is necessary to provide a good thermal path to dissipate the heat generated within the LTC3428’s package. The large thermal pad on the IC underside can accomplish this requirement. Use multiple PC board vias to conduct heat from the IC and to a copper plane that has as much area as possible.APPLICATIO S I FOR ATIOW UUU If the junction temperature gets too high, the LTC3428 will stop all switching until the junction temperature drops to safe levels. The typical over temperature threshold is 150°C.Closing the Feedback LoopThe LTC3428 uses current mode control with internal,adaptive slope compensation. Current mode control elimi-nates the 2nd order pole in the loop response of voltage mode converters due to the inductor and output capacitor,simplifying it to a single pole response. The product of the modulator control to output DC gain and the error amp open-loop gain equals the DC gain of the system.G G G V V G V I G DC CONTROL EA REF OUTCONTROL IN OUTEA ==≈•••2100The output filter pole is given by:f I V C HzPOLE OUTOUT OUT=π••where C OUT is the output filter capacitor value. The output filter zero is given by:f R C HzZERO ESR OUT=12•••πwhere R ESR is the output capacitor equivalent series resistance.A complication of the boost converter topology is the right half plane (RHP) zero and is given by:f V R L V HzRHP IN O O=222••••π91011Information furnished by Linear Technology Corporation is believed to be accurate and reliable.However, no responsibility is assumed for its use. Linear Technology Corporation makes no represen-tation that the interconnection of its circuits as described herein will not infringe on existing patent rights.LTC3428123428fLinear Technology Corporation1630 McCarthy Blvd., Milpitas, CA 95035-7417(408) 432-1900 ● FAX: (408) 434-0507 ● © LINEAR TECHNOLOGY CORPORA TION 2004LT/TP 0804 1K • PRINTED IN USARELATED PARTSPART NUMBER DESCRIPTIONCOMMENTSLT1613550mA (I SW ), 1.4MHz, High Efficiency Step-Up 90% Efficiency, V IN : 0.9V to 10V, V OUT(MAX) = 34V, I Q = 3mA,DC/DC ConverterI SD <1µA, ThinSOT PackageLT1615/LT1615-1300mA/80mA (I SW ), High Efficiency Step-Up V IN : 1V to 15V, V OUT(MAX) = 34V, I Q = 20µA,DC/DC ConvertersI SD <1µA, ThinSOT PackageLT1618 1.5A (I SW ), 1.25MHz, High Efficiency Step-Up 90% Efficiency, V IN : 1.6V to 18V, V OUT(MAX) = 35V, I Q = 1.8mA,DC/DC ConverterI SD <1µA, MS PackageLT1930/LT1930A 1A (I SW ), 1.2MHz/2.2MHz, High Efficiency Step-Up High Efficiency, V IN : 2.6V to 16V, V OUT(MAX) = 34V,DC/DC ConvertersI Q = 4.2mA/5.5mA, I SD <1µA, ThinSOT PackageLT1946/LT1946A 1.5A (I SW ), 1.2MHz/2.7MHz, High Efficiency Step-Up High Efficiency, V IN : 2.45V to 16V, V OUT(MAX) = 34V, I Q = 3.2mA,DC/DC ConvertersI SD <1µA, MS8 PackageLT19611.5A (I SW ), 1.25MHz, High Efficiency Step-Up 90% Efficiency, V IN : 3V to 25V, V OUT(MAX) = 35V, I Q = 0.9mA,DC/DC ConverterI SD 6µA, MS8E PackageLTC3400/LTC3400B 600mA (I SW ), 1.2MHz, Synchronous Step-Up 92% Efficiency, V IN : 0.85V to 5V, V OUT(MAX) = 5V, I Q = 19µA/300µA,DC/DC ConverterI SD <1µA, ThinSOT PackageLTC34011A (I SW ), 3MHz, Synchronous Step-Up DC/DC Converter 97% Efficiency, V IN : 0.5V to 5V, V OUT(MAX) = 5.5V, I Q = 38µA,I SD <1µA, MS PackageLTC34022A (I SW ), 3MHz, Synchronous Step-Up DC/DC Converter 97% Efficiency, V IN : 0.5V to 5V, V OUT(MAX) = 5.5V, I Q = 38µA,I SD <1µA, MS PackageLTC34213A, 3MHz Synchronous Boost Converter 96% Efficiency, V IN : 0.5V to 4.5V, V OUT(MAX) = 5.5V, I Q = 12µA,with Output DisconnectI SD <1µA, QFN-24 PackageLTC34255A (I SW ), 8MHz, 4-Phase Synchronous Step-Up 95% Efficiency, V IN : 0.5V to 4.5V, V OUT(MAX) = 5.25V, I Q = 12µA,DC/DC ConverterI SD <1µA,QFN-32 PackageLTC3429600mA, 500kHz Synchronous Boost Converter 96% Efficiency, V IN : 0.5V to 4.4V, V OUT(MAX) = 5.5V, I Q = 20µA,with Output DisconnectI SD <1µA,ThinSOT PackageLTC34363A (I SW ), 1MHz, 34V Step-Up DC/DC Converter V IN : 3V to 25V, V OUT(MAX) = 34V, I Q = 0.9mA,I SD <6µA, TSSOP-16E PackageLTC345910V Micropower Synchronous Boost Converter 85% Efficiency, V IN : 1.5V to 5.5V, V OUT(MAX) = 10V, I Q = 10µA,I SD <1µA,ThinSOT PackageLT346485mA (I SW ), High Efficiency Step-Up DC/DC Converter V IN : 2.3V to 10V, V OUT(MAX) = 34V, I Q = 25µA,with Integrated Schottky and PNP DisconnectI SD <1µA,ThinSOT PackageNo R SENSE is a registered trademark of Linear Technology Corporation.。

上海贝特产品性能指标说明一、分支分配器指标一分支器 (BTT1XXE)二分支器 (BTT2XXE)三分支器 (BTT3XXE)四分支器 (BTT 4XXE)五分支器 (BTT5XXE)六分支器 (BTT6XXE)八分支器 (BTT8XXE)二分配器 (BTS204E)三分配器 (BTS306E)四分配器 (BTS408E)四分配器 (BTS408EA)四分配器 (BTS408EB)五分配器 (BTS509E)六分配器 (BTS610E)频率范围（ MHz ）分配损耗（ dB ）隔离（ dB ）反射损耗（ dB ）5-10 ≤ 8.9≥ 27≥ 1610-50 ≤ 8.8 ≥ 28≥ 1850-750 ≤ 9.9≥ 28≥ 18750-1000 ≤ 10.5≥ 28≥ 18八分配器 (BTS812E)频率范围（ MHz ）分配损耗（ dB ）隔离（ dB ）反射损耗（ dB ）5-10 ≤ 10.8≥ 27≥ 1610-50 ≤ 10.8≥ 28≥ 1850-750 ≤ 11.5≥ 28≥ 18750-1000 ≤ 12.5≥ 28≥ 18二、射频传输放大设备BTIA4000系列放大器技术指标特点：1,BTIA4000系列放大器是吸收了国外最新同类产品的长处，为有线电视系统研制的放大设备。

2，采用进口BGY系列推挽集成电路模块作放大电路，输出电平高。

3，采用铝合金压铸全密封防水型外壳，屏蔽性能佳，防水性能好，能适用于野外各种环境。

4，性能可靠，安装方便。

参数单位指标型号4021D 4026D 4033D 4021G 4026G 4032G 4021H 4026H 4032H 带宽MHz 47-550 47-750 47-862注 : ① 59 个频道安排在 550MHz 以下，在系统最高频道处测得。

② 59 个频道，采用同步视频方波调制，在系统低端测得。

SGF4100系列自动增益控制及斜率补偿放大器特点：1功率倍增输出有利于系统的扩展和延伸。