DC-DC应用指南V1.0

DC-DC芯片手册1. 引言DC-DC芯片作为电源管理系统中的核心组件之一，扮演着将直流电压转换为其他直流电压的重要角色。

本文将深入探讨DC-DC芯片的技术特点、应用场景以及手册的编写与使用。

1.1 DC-DC芯片的基本概念介绍DC-DC芯片的基本概念，阐述其在电源管理中的作用，以及在不同电子设备中的广泛应用。

1.2 DC-DC芯片手册的重要性强调DC-DC芯片手册在设计、调试和维护电源系统中的重要性，以及为用户提供准确信息的必要性。

2. 技术特点与规格详细介绍DC-DC芯片的技术特点和规格，使读者对该芯片有一个全面的了解。

2.1 输入与输出电压范围阐述DC-DC芯片所支持的输入和输出电压范围，以及在不同工作条件下的稳定性和性能。

2.2 效率与功率密度探讨DC-DC芯片的能效表现，包括效率的计算方法和功率密度的重要性。

2.3 转换拓扑与控制方式介绍不同DC-DC芯片的转换拓扑结构和控制方式，以及它们在实际应用中的优劣和适用场景。

3. 电路连接与布局建议提供DC-DC芯片在电路中的连接方式和布局建议，以确保最佳性能和稳定性。

3.1 输入输出电容的选择详细讨论在设计中如何选择适当的输入和输出电容，以保障电源系统的稳定性。

3.2 输入输出滤波电感的应用阐述滤波电感在DC-DC芯片电路中的作用，以及如何选择和应用合适的滤波电感。

3.3 PCB布局与散热设计探讨PCB布局对DC-DC芯片性能的影响，以及良好的散热设计对延长芯片寿命的重要性。

4. 保护特性与故障诊断详细介绍DC-DC芯片的保护特性，以及在故障发生时的诊断方法。

4.1 过流与过压保护讨论DC-DC芯片在过流和过压情况下的保护机制，确保电源系统的安全稳定运行。

4.2 温度保护与限流功能阐述芯片的温度保护机制和限流功能，以应对在高温或过载情况下可能出现的问题。

5. DC-DC芯片手册的编写与更新探讨编写DC-DC芯片手册的步骤和要点，以及在新版本发布时如何进行更新。

AN22 - 1High Frequency DC-DC Conversion using High Current Bipolar TransistorsNeil Chadderton Dino RosaldiIntroductionDC-DC conversion is o ne o f the fundamental circuit functions within the electronics industry and addresses a wi de f iel d of market secto rs,applications and supply requirements. A general trend, (to pursue cost, size and reliability advantages) has been to reduce the size of the DC-DC converter systems, and as the inductive elements of such a system are quite often the bulkiest components, increases in switching frequency provide one met ho d to al lo w this. Switch ing frequencies therefore have increased from tens of kHz to hundreds of kHz,which has forced a revision of the enabling switching devices.It is an often assumed maxim that bipolar transistors are useful for DC-DC conversion functions up to perhaps 50kHz, and for service beyond this frequency, that MOSFETs provide the only solution. The purpose of this application note is to demonstrate that bipolar transistors possessing superior geometrys - thereby providing a higher current capability per die area, can and are o p era te d to re aso n ab ly h igh switching frequencies with minimal loss. This often allows a more compactdesign (due to the higher silicon efficiency of bipolar technology) and lower cost.BackgroundTo obtain the most efficient performance fro m b ipo la r trans is to rs at h igh switching frequencies, an appreciation of the basic switching mechanisms and base charge analysis is useful. Appendix A provides an introduction to bipolar transistor switching behaviour, and appendix B provides references for mathematical treatments.Th ere are various methods for increasing the maximum switching speed of bipolar transistors. Some of these rely on preventing saturation of the device, thus vastly reducing the stored charge, while other methods remove the charge at turn-off. Figures 1,2 and 5 show a number of common speed-up networks. Figures 1a through 1d show various options for preventing saturation, and effectively reduce/limit base drive when the collector terminal has fallen to a specific level. (Figure 1a is often termed a Schottky transistor, and is often used for IC transistors, and400kHz Operation with Optimised Geometry DevicesFigures 1c and 1d are variants of the so called Baker clamp circuit).These methods (the Baker clamp being preferred for high power applications) of course do not allow the transistor’s collector-emitter voltage to saturate to a very low level, and so the resultant on-state loss may be high and therefore prohibit the use of smaller packaged, though adequately current capable devices. Figures 2 and 5 show two methods that allow true saturation by permitting sufficient forward base drive, while removing charge quickly at turn-off. Design of such networks is non-critical, and by suitable choice of components allow high levels of base overdrive with no penalty to turn-off time duration.Figure 2 shows a method of speeding up PNP devices to enable replacement of large P-Channel MOSFETs - this particular circuit being designed for fast charging of battery packs by Benchmarq Microelectronics. Figures 3 and 4 show the relevant waveforms, for a standard passive turn-off method (base-emitter pull-up resistor) and the speed-up circuit of Figure 2 - the combined storage and fall times being reduced from 1.2µs to 80ns. Importantly, the major switching loss contributor - the fall time, has been significantly reduced to 40ns, which is comparable to, or better than P-Channel MOSFET performance. This allows cost effective replacement of large packaged devices.To Oscilloscope+5V0VInput+5V0VFigure 5.Capacitive Speed-up method/Circuit to Determine Minimum Value of Turn-Off Chargeof a Bipolar Transistor.Figure 6.Turn-Off Waveforms, and Effect ofVarying Parallel (“Speed-Up”)Capacitance.Upper trace - Input waveform;lower traces - (a) C=0, (b) C=100pF,(c) C=120pF, (d) C=130pF (stored chargejust removed).Horizontal scale=200ns/div, Verticalscale=2V/div. ZTX300, I B=1mA, I C=10mA.Figure 7.Turn-Off Waveforms, and Effect ofVarying Parallel (“Speed-Up”)Capacitance.Trace (a) - Input waveform;turn-off traces - (b) C=0, (c) C=470pF, (d)C=820pF, (e) C=1.5nF (stored chargeremoved).Horizontal scale=500ns/div, Verticalscales: Input=2V/div; collector=5V/div.ZTX1048A, I B=10mA, I C=500mA.Figure 5 shows the standard speed-up capac itance method , altho ugh in practice a finished design would use a fixed value capacitor. A similar circuit can also be used to determine the capacitance required for a particular bias condition. In practise the variable cap ac itance (or value o f parallel capacitance) is adjusted such that the sum of stored charge and junction capacitance charge is just removed -all ow in g fo r device variation,temperature and bias tolerance.The oscillographs in Figures 6 and 7show the effect of increasing the capacitor value from zero (Eg. open circuit) to a value adequate to neutralise the stored charge. Figure 6 is for a small signal device, while Figure 7 is for the ZTX1048A - a transistor utilising the Zetex Matrix geometry, and a Super-βemitter process to produce a 4A DC rated part in the TO92 style E-Line package.Figure 8 summarises a set of suchmeasurements for the ZTX1048A - for example, at a collector current of 1A and a forced gain of 200, a turn-off charge of 900pC is required to neutralise stored charge and eliminate storage time effects.[Note 1: Appendix A also includes some ancillary material on the minimum amount of trigger charge necessary for pulse circuits].Power Conversion CircuitsTo demonstrate the performance advantages possible when the bipolar transistor’s turn-off charge is addressed,th is se ction co nsiders such modifications to a basic step-down DC-DC converter. The circuit shown in Figure 9 was used to provide a means of evaluation, and is of fairly standard implementation, apart from the choice of the FMMT718 SuperSOT SOT23 PNP transistor. This circuit, with minimal design optimisation, can produce the eff ici en cy a ga in s t load curren t characteristic shown in Figure 10. This c ha rt als o s ho w s h o w the bias conditions for the pass device can be mod if ied to increase the curren t capability of the circuit, albeit with some compromise to conversion efficiency at lower load currents. Curves 1, 2 and 3illustrate this effect for base currents of 9.4mA, 43mA and 170mA respectively.Figure 11 shows how the efficiency varies with input voltage for the I B =43mA option. Higher output current designs are possible with larger die transistors from the Zetex range, such as the ZTX788B, ZTX789A, ZTX790A, ZTX948and ZTX949. For a comprehensive listing please refer to Semiconductor DataBooks one and two.100n1n0.1I C - Collector Current (A)Stored Charge v I C110S t o r e d C h a r g e (C )ZTX1048AI /I =50I /I =100I /I =150I /I =20010nFigure 8.Turn-off Charge Required as a Function of Collector Current and Forced Gain, for the ZTX1048A Bipolar Transistor.FMMTFigure 9.Basic Step-Down DC-DC Converter using the LM3578 and the FMMT718.(With values shown, F op=50kHz, I B=43mA, peak efficiency=88%).Output Current (A)Efficiency v Output Current10100Efficiency(%)20406080515Efficiency(%)100Input Voltage (V)Efficiency v Input Voltage20406080791113Figure 10.Efficiency against Load Current for theConverter of Figure 9, with I B as aparameter.Curve 1 - I B=9.4mA; Curve 2 - I B=43mA;Curve 3 - I B=170mA. F op=50kHz; Vin=7V;V out=5V.Figure 11.Efficiency against Input Voltage for theConverter of Figure 9. (I B=43mA; I out=1A).AN22 - 6E f f i c i e n c y (%)1000Output Current (A)Efficiency v Output Current20406080Figure 14.Efficiency against Load Current for the Converters of Figure 13 and 16.PWM ICFigure 15.Bipolar Transistor Turn-off Circuit to allow Capacitive Turn-off Charge Neutralisation with PWM Controller IC.VinFigure 16.Basic Step-down DC-DC Converter using the TI5001/FMMT718 Combination with Capacitive Turn-off Circuit.AN22 - 8Figure 14, curve 2. This shows a peak efficiency of 92%. Figure 17 shows the switching waveforms, including the collector-to-0V waveform - note the rapid turn-off edge; this was measured to be 25ns. The efficiency at lower currents has of course reduced, due to the extra current taken by the turn-off circuit. This efficiency profile can be modified for specific applications by sacrificing high current efficiency in favour of low current performance or vice-versa.Further modifications were effected to assess performance at still higher switching frequencies. Figure 18 shows the efficiency/load current profiles for switching frequencies from 150kHz to 400kHz. Figure 19 shows the efficiency against input voltage for the 220kHz155E f f i c i e n c y (%)1000Input Voltage (V)Efficiency v Input Voltage20406080791113Figure 19.Efficiency against Input Voltage for the Converter of Figure 16.F op =220kHz; V out=5V; load current=1A.Figure 20.Switching Waveforms for the Converter of Figure 16 operating at 400kHz. Turn-on edges. Risetime= 20ns. Upper trace - Base-to-0V, 2V/div.Lower trace - Collector-to-0V, 2V/div.Timebase at 50ns/div.Figure 21.Switching Waveforms for the Converter of Figure 16 operating at 400kHz.Turn-off edges. Falltime=30ns. Upper trace - Base-to-0V, 2V/div.Lower trace - Collector-to-0V, 2V/div.Timebase at 50ns/div.AN22 - 10charge necessary for small signal types ZTX107, ZTX300 and ZTX500, and switching transistors ZTX310 and ZTX510.Figure 25.Trigger Waveforms and Effect of Varying Trigger Capacitance. Upper trace - Input waveform; lower traces - output at collector, (a) Variable capacitor “C1” below critical value, (b) “C1” at critical value with collector voltage rising to 90% of final value,(c) “C1” above critical value. Horizontal scale=200ns/div, Vertical scale=2V/div.ZTX300, I B =1mA, I C =10mA.+5VTo Oscilloscope0VFigure 24.Circuit to Determine Minimum Value of Trigger Charge for Bipolar Transistor.AN22 - 14I B - Base Current (A)Min. T rigger Charge v I B for Small Signaland Switching Transistors10p 10nM i n i m u m T r i g g e r C h a r g e (C )100p1nFigure 26.Minimum Trigger Charge for Small Signal and Switching Transistors. Forced Gains (I C /I B ) of : a)10; b)20; c)40.No significant difference observed for different forced gains on the ZTX310 series.AN22 - 16。

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目录1 登录 ................................................................................................................................................1-1 1.1 登录Web管理界面 ......................................................................................................................1-11.1.1 需求介绍 ...........................................................................................................................1-11.1.2 设置方法 ...........................................................................................................................1-1 1.2 FAT模式下连云设置方法 .............................................................................................................1-41.2.1 商云APP扫码添加设备上云 ............................................................................................1-51.2.2 商云APP通过设备的ID/MAC添加设备上云 ..................................................................1-71.2.3 商云APP无线添加设备上云 ..........................................................................................1-101.2.4 商用网络云平台通过设备的ID添加设备上云 ...............................................................1-12 1.3 基础连网设置 .............................................................................................................................1-141.3.1 DHCP动态获取IP上网 .................................................................................................1-141.3.2 配置静态IP上网 ............................................................................................................1-162 工作模式 .........................................................................................................................................2-1 2.1 FAT AP模式 .................................................................................................................................2-12.1.1 设备信息 ...........................................................................................................................2-22.1.2 无线参数 ...........................................................................................................................2-22.1.3 扫码上云 ...........................................................................................................................2-32.1.4 易展设备列表 ...................................................................................................................2-42.1.5 无线服务 ...........................................................................................................................2-42.1.6 无线客户端 .......................................................................................................................2-5 2.2 FIT AP模式 ...................................................................................................................................2-5 2.3 易展组网 .......................................................................................................................................2-52.3.1 易展AP .............................................................................................................................2-52.3.2 AP模式 .............................................................................................................................2-62.3.3 Router模式 ......................................................................................................................2-83 无线 ................................................................................................................................................3-13.2.1 扫描选择 ...........................................................................................................................3-63.2.2 手动设置 ...........................................................................................................................3-7 3.3 高级设置 .......................................................................................................................................3-8 3.4 FAT模式下弱信号限制和弱信号剔除配置指南 ...........................................................................3-93.4.1 应用介绍 ...........................................................................................................................3-93.4.2 需求介绍 ...........................................................................................................................3-93.4.3 设置方法 .........................................................................................................................3-10 3.5 FAT模式下多个SSID配置指南 .................................................................................................3-103.5.1 应用介绍 .........................................................................................................................3-103.5.2 需求介绍 .........................................................................................................................3-103.5.3 设置方法 .........................................................................................................................3-114 安全 ................................................................................................................................................4-1 4.1 无线MAC地址过滤 ......................................................................................................................4-1 4.2 VLAN设置 ....................................................................................................................................4-2 4.3 FAT模式下MAC地址过滤配置指南 ............................................................................................4-34.3.1 应用介绍 ...........................................................................................................................4-34.3.2 需求介绍 ...........................................................................................................................4-34.3.3 设置方法 ...........................................................................................................................4-35 系统 ................................................................................................................................................5-1 5.1 工作模式 .......................................................................................................................................5-2 5.2 云管理 ..........................................................................................................................................5-25.2.1 TP-LINK本地NMS管理平台 ...........................................................................................5-25.2.2 TP-LINK商用网络云平台 .................................................................................................5-3 5.3 设备管理 .......................................................................................................................................5-45.3.1 IPv4 ..................................................................................................................................5-45.3.2 IPv6 ..................................................................................................................................5-5 5.4 管理账号 .......................................................................................................................................5-65.7 配置管理 .......................................................................................................................................5-8 5.8 在线软件升级 ...............................................................................................................................5-8 5.9 软件升级 .......................................................................................................................................5-9 5.10 Ping看门狗 ..................................................................................................................................5-9 5.11 FAT模式下Ping看门狗配置指南 ..............................................................................................5-10 5.11.1 应用介绍 .........................................................................................................................5-10 5.11.2 需求介绍 .........................................................................................................................5-10 5.11.3 设置方法 .........................................................................................................................5-10 5.11.4 配置注意事项 .................................................................................................................5-121 登录双频WiFi 6无线易展AP用户手册双频WiFi 6无线易展AP支持两种工作模式：FAT AP模式和FIT AP模式。

文章标题：深入理解DC-DC变换电路原理及应用入门DC-DC变换电路是一种将直流电源转换为不同电压或电流输出的电子电路。

它在现代电子设备中应用广泛，包括手机、笔记本电脑、电动车和太阳能系统等。

本文将全面探讨DC-DC变换电路的原理及应用入门，以便读者更深入地理解和掌握这一重要的电子技术。

1. 什么是DC-DC变换电路？DC-DC变换电路是一种能够将直流电源转换为不同电压或电流输出的电路。

它可以实现直流电源的升压、降压、反向输出以及变换电流等功能。

在电子设备中，由于不同的电路和元件需要不同的工作电压和电流，DC-DC变换电路成为了必不可少的部分。

2. DC-DC变换电路的原理及工作方式DC-DC变换电路的原理基于电感和电容的储能特性，通过控制开关管的导通和截止，将输入电源以脉冲的形式加到电感上，再通过电容滤波获得稳定的输出电压。

根据不同的控制方式和拓扑结构，DC-DC变换电路可以分为多种类型，包括Buck、Boost、Buck-Boost、Cuk等。

每种类型都有其特定的工作方式和应用场景。

3. DC-DC变换电路的应用DC-DC变换电路在电子设备中有着丰富的应用场景，比如手机充电器中常用的Boost变换器、笔记本电脑电池管理系统中的Buck变换器、以及电动车和太阳能系统中的Buck-Boost变换器等。

通过合理选择和设计DC-DC变换电路，可以实现高效能的功率转换和电源管理。

4. 个人观点及总结通过本文的讲解，相信读者已经对DC-DC变换电路的原理及应用有了一定的了解。

在今后的学习和工作中，对于电子技术方面的研究和应用，深入掌握DC-DC变换电路的知识将会大有裨益。

希望读者能在实践中不断积累经验，尝试设计和应用更加复杂和高效的DC-DC变换电路，为电子技术的发展和应用做出更大的贡献。

总结来看，文章详细解释了DC-DC变换电路的原理及应用入门，帮助读者从零开始全面理解这一重要的电子技术。

对于想要深入研究和应用DC-DC变换电路的人来说，这篇文章将是一份有价值的指南和参考。

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如何使用本手册本手册共分成六章的内容向管理员详细介绍了该产品的使用方法，各章节的内容是按照操作员的操作步骤从简单操作到复杂操作的顺序执行的，操作人员在使用本产品时必须遵守这些具体的操作步骤正确使用。

第一章是流量整形网关的概述，用户在使用该设备时需要首先阅读本章的内容。

这一章是该设备的简要介绍，包括产品的功能、特点、结构、安装环境和缺省参数的使用说明。

第二章是系统管理，包括设备的电源管理、设置系统时间、管理员设置、修改密码、日志查询、软件许可等可管理的内容，目的是确保产品的正确使用。

第三章是网络管理，这一章是该产品网络控制功能的主要内容，管理员必须仔细阅读这些功能的说明和操作步骤。

网络设置不正确，就会造成系统不能正常运行或起不到应有的作用。

该章的内容有网络接口设置、路由设置等。

第四章是对象管理，这一章是该产品设置规则所需要的对象设置。

包括应用对象管理、时间对象管理、地址对象管理等。

第五章是规则管理，规则管理是网络用户接入控制的关键技术，规则使用的正确与否，决定了系统是否能按照用户要求正常运行，所以管理员在操作使用前一定要详细阅读这章的内容。

该章的内容包括参数设置、应用访问控制和带宽策略分配等。

第六章是在线监控，包括带宽流量监控、网络运行状态监控、磁盘空间监控、在线管理员监控等系统的管理工具，目的是让管理员能实时掌握系统的运行状态，对系统的管理提供方便、快速的监控功能。

目录内容简介 (1)关于本手册 (1)如何使用本手册 (1)第一章系统概述 (5)1.1产品功能介绍 (5)1.1.1应用识别功能 (5)1.1.2灵活的带宽通道管理 (5)1.1.3动态的带宽分配技术 (5)1.1.4 TCP速率控制技术 (5)1.1.5系统监控功能 (5)1.1.5友好的系统管理界面 (5)1.1.6安全的管理方式 (6)1.2产品特点 (6)1.3产品结构 (6)1.4手册结构 (6)1.5读者对象 (7)1.6安装环境 (7)1.7系统的缺省设置 (7)第二章系统管理 (9)2.1概述 (9)2.2添加/修改管理员 (9)2.2.1管理员列表 (9)2.2.2添加/修改管理员 (10)2.3 设置系统时间 (11)2.4保存全部设置 (11)2.5查询操作日志 (12)2.6配置文件管理 (12)2.6.1配置文件下载 (12)2.6.2配置文件上传 (13)2.7重启/关闭系统 (13)2.8恢复出厂设置 (13)2.9软件许可 (14)2.10注销 (14)第三章网络管理 (15)3.1概述 (15)3.2网络接口设置 (15)3.3路由设置 (16)3.4 VLAN设置 (17)3.5 编辑接口名称 (17)3.6 网络区域设置 (18)第四章对象管理 (19)4.1概述 (19)4.2应用对象管理 (19)4.3 HTTP对象管理 (20)4.3.1增加HTTP对象元素 (20)4.3.2 使用HTTP对象 (24)4.4地址对象管理 (24)4.5服务对象管理 (25)4.6时间对象管理 (26)4.7地址组对象管理 (28)4.7.1新增地址组 (29)4.7.2显示/修改地址组 (30)4.7.3删除地址组 (31)4.7.4保存地址组 (31)4.8用户映射管理 (31)4.9黑名单管理 (33)第五章控制策略 (34)5.1概述 (34)5.2参数设置 (34)5.3预置安全规则 (38)5.4应用访问规则 (40)5.5带宽通道管理 (41)5.6带宽分配策略 (45)5.7二级带宽策略 (47)5.8分区统计策略 (49)第六章系统监控 (51)6.1概述 (51)6.2流量分析图 (51)6.3流量自动分类 (52)6.4系统状态监控 (52)6.4.1 CPU状态 (53)6.4.2内存状态 (53)6.5监控管理员 (54)6.6会话和主机监控 (54)6.6.1 会话统计 (54)6.6.2 主机状态 (55)6.6.3 会话搜索 (57)6.7网络工具 (57)6.7.1 PING (57)6.7.2 TRACEROUTE (58)6.7.3 连接检测工具 (59)6.8监控设置 (59)6.8.1 流量分析设置 (59)6.8.2 系统状态监控设置 (60)6.8.3 日志服务器设置 (60)6.8.4 清空应用流量数据 (61)6.8.5 清空系统状态数据 (61)附录一：终端方式下的系统设置 (61)附录二：配置示例 (63)示例一：快速拦截P2P应用 (63)示例二：限制P2P应用的流量 (64)示例三：限制IP地址段中每个IP的带宽 (67)第一章系统概述1.1产品功能介绍1.1.1应用识别功能系统可以分析和识别多种网络应用，高效智能的应用分析引擎是高性能应用系统的基本保障，可升级的应用分析数据库可以保证系统的可扩展性，为运营商解决后顾之忧。

11. 电池充电器（BatMod）设计指南和应用手册针对VI-200和VI-J00系列DC-DC转换器和可配置电源2.5 VdcVdcVdc=1.25 Vdc50% of V outV out5 Vdc100%额定值100%额定值最大=1 Vdc0 A5 =1 0ADC BatModGATE IN GATE OUT +OUT –OUT+IN –IN+–TRIM V TRIM I MON I DC InputBatModGATE IN GATE OUT +OUT –OUTV I MON +IN–INExternal Control FunctionsGATE IN GATE OUT +OUT–OUT+IN –INBatMod BoosterGATE IN GATE OUT +OUT–OUT+IN –INEnable/Disable+–Load TRIM TRIM I BatMod Booster图11-1 — DC输入单模块图11-2 — DC输入大功率阵列概述BatMod模块是用于电池充电或类似电流源应用的可编程电流源模块。

它可以从外部进行控制，以满足范围广泛的充电参数：电压、电流、充电速率和充电时间。

传导性噪声是在源极电压和电源之间流动的AC电流。

它包括共模噪声和差模噪声。

Vicor零电流开关转换器的传导性噪声比传统电路板上安装的PWM转换器低20 - 40 dB；但是，如果必须满足特定EMC规范，如FCC或VDE，则可能需要额外的滤波。

虽然BatMod主要用于电池充电应用，它也可以作为一个可编程电流源，用于电阻性负载或CW激光二极管。

在同时为零输出电压和电流的条件下，BatMod将无法正常运行。

由此可见，不能用电阻性负载将电流调整到零。

请在 参阅BatMod数据表的安全工作区曲线。

引脚说明输入可从1 – 5 V接收一个模拟控制电压，调整从零到BatMod的最大额定值的源电流。

重要的是要注意每个未经微调BatMod类型的标称输出电压。

DC使用说明文件说明：在进行下面的演示时需要用到两个文件，一个是example1.v，它是描述一个电路的verilog代码，我们的目标就是用DC综合这个代码得到满足约束条件的电路网表；另一个是dc.scr，它是综合example1.v的脚本文件。

这两个文件都在/home/student1000目录下，大家把它们拷贝到自己的目录下，以备使用。

DC既可使用图形界面，也可不使用图形界面而直接运行脚本来综合电路。

一、DC图形界面的使用。

1.DC图形界面的启动1.1 打开一个终端窗口，写入命令dv –db_mode，敲入回车。

则DC图形界面启动，如下图所示红框处是DC的命令输入框，以下在图形界面上的操作都可以在命令输入框中输入相应的命令来完成。

选择Help----- Man Pages可以查看DC的联机帮助。

相应指令：man。

例：man man表示查看man命令的帮助。

man create_clock表示查看creat_clock命令的帮助。

2.设置库文件选择File---- Setup需要设置以下库文件，如下图。

相应指令：set search_path [list /tools/lib/smic25/feview_s/version1/STD/Synopsys \/tools/lib/smic25/feview_s/version1/STD/Symbol/synopsys] set target_library { smic25_ff.db }set link_library { smic25_ff.db smic25_ss.db }set symbol_library { smic25.sdb }点OK，设置完成。

3.读入verilog文件选择File--- Read在打开文件对话框中选中要打开的文件，在这里我们选中example1.v文件。

在Log框中出现successfully字样表明读入文件成功。

DC/DC基本知识DC/DC是开关电源芯片。

开关电源，指利用电容、电感的储能的特性，通过可控开关（MOSFET等）进行高频开关的动作，将输入的电能储存在电容（感）里，当开关断开时，电能再释放给负载，提供能量。

其输出的功率或电压的能力与占空比（由开关导通时间与整个开关的周期的比值）有关。

开关电源可以用于升压和降压。

我们常用的DC-DC产品有两种。

一种为电荷泵（Charge Pump），一种为电感储能DC-DC转换器。

本文详细讲解了这两种DC/DC产品的相关知识。

目录一.1. 工作原理2. 倍压模式如何产生3. 电荷泵的效率4. 电荷泵的应用5. 电荷泵选用要点二.电感式DC/DC1. 工作原理（BUCK）2. 整流二极管的选择3. 同步整流技术4. 电感器的选择5. 输入电容的选择6. 输出电容的选择7. BOOST 与 BUCK的拓扑结构一. 电荷泵电荷泵为容性储能DC-DC产品，可以进行升压，也可以作为降压使用，还可以进行反压输出。

电荷泵消除了电感器和变压器所带有的磁场和电磁干扰。

1. 工作原理电荷泵是通过外部一个快速充电电容（Flying Capacitor），内部以一定的频率进行开关，对电容进行充电，并且和输入电压一起，进行升压（或者降压）转换。

最后以恒压输出。

在芯片内部有负反馈电路，以保证输出电压的稳定，如上图V out ，经R1,R2分压得到电压V2，与基准电压V REF做比较，经过误差放大器A，来控制充电电容的充电时间和充电电压，从而达到稳定值。

电荷泵可以依据电池电压输入不断改变其输出电压。

例如，它在1.5X或1X的模式下都可以运行。

当电池的输入电压较低时，电荷泵可以产生一个相当于输入电压的1.5倍的输出电压。

而当电池的电压较高时，电荷泵则在1X模式下运行，此时负载电荷泵仅仅是将输入电压传输到负载中。

这样就在输入电压较高的时候降低了输入电流和功率损耗。

2. 倍压模式如何产生以1.5x mode为例讲解：电压转换分两个阶段完成。

典型应用电路图概述 OC5800 是一款支持宽电压输入的开关降压型DC-DC ，芯片内置100V/2A 功率MOS 。

OC5800具有高效率、低纹波、优异的母线电压调整率和负载调整率。

支持大电流输出，在输入80V 时可支持输出电流5V/1.5A ，12V/1.1A 。

OC5800同时支持输出恒压和输出恒流功能。

通过设置CS 电阻可设置输出恒流值。

通过设置FB1的分压电阻可设置输出恒压值，输出电压范围从5V 到30V 。

OC5800采用固定频率的PWM 控制方式，典型开关频率为160KHz 。

轻载时会自动降低开关频率以获得高的转换效率。

OC5800内部集成软启动以及过温保护电路，输出短路保护，限流保护等功能，提高系统可靠性。

OC5800采用ESOP8封装。

散热片内置接VIN 引脚。

特点 宽输入电压范围：8V~100V 内置100V/2A 功率MOS 输出电压从5V 到30V 可调 支持输出恒流 高效率：可高达93%工作频率：160KHz 内置过温保护 内置软启动 内置输出短路保护 应用 车充、电池充电 恒压源电动汽车、电动自行车、电瓶车 扭扭车、卡车封装及管脚分配管脚定义管脚号管脚名描述1 VIN 接输入电源，内置MOS漏极2 VDD 芯片电源3 FB1 输出反馈电压采样4 FB2 负载调整率与线损补偿脚5 CC 频率补偿脚，接电容。

6 VSS 芯片地7 VSEN 功率管电流检测脚8 VSEND 内置MOS源极内部电路方框图极限参数（注1）符 号描述参数范围 单位V IN VIN 脚电压 100 V VDD VDD 端最大电压 33 V VmaxFB1,FB2,CC,VSEN,VSEND 脚电压-0.3~6 VP ESOP8 ESOP8封装最大功耗0.8 WT A 工作温度范围 -20~85 oC T STG 存储温度范围-40~120 oC T SD 焊接温度范围（时间小于30秒）240o CV ESD静电耐压值（人体模型）2000 V注1：极限参数是指超过上表中规定的工作范围可能会导致器件损坏。

When selecting AC and DC switchgear for grid-tied inverters, system designers have a variety of options. There are key design considerations to avoid downtime and reduce overall project costs.OverviewIn many design decisions, there is a “good,”“better,” and “best” scenario that is directly proportional to cost. As inverter-pricing pressures escalate, many vendors are faced with decisions that involve quality and cost tradeoffs. Because many inverter customers are not experts in AC or DC switchgear, it can be tempting to select less than optimal equipment that has a lower upfront cost, but may not be well suited for the application long-term.Eaton is a long-time industry leader in both AC and DC switchgear and continues to invest in research and development to continue to deliver solutions that support new levels of safety, reliability, and efficiency for global applications. This paper aims to assist customers in making good long-term decisions about low voltageAC and DC switchgear selections and design philosophy for grid-tied inverters.DC-side design choicesMost inverters have some type of disconnecton the DC side to isolate the inverter from theDC source.Figure 1. DisconnectThe DC disconnect has multiple purposes that include providing:1. A way to isolate and disconnect theinverter for service2. Means to isolate the DC source so workcan be performed3. Isolation of the power module in theinverter if the power module failsIn cases where there are multiple power modules in the inverter, the DC disconnect becomes even more important. Multiple power modules mean multiple potential points of failure. With proper isolation capabilities on both the AC and DC side, such inverters can become fault tolerant. This is most commonly achieved by isolating a failed module while allowing the other modulesto continue operating. This is a critical function particularly when two or more power modules are in the inverter. Without this feature, modular inverters can become substantially less reliable. In Figure 2, the inverter diagram shows a modular inverter with double-pole DC disconnects on each power module. In this scenario, each power module has complete DC isolation because both the positive and negative lines are isolated.Low voltage switchgear selection in grid-tied invertersChris ThompsonEaton2White Paper WP083019ENEffective April 2016Low voltage switchgear selection in grid-tied invertersEATON By having a double-pole disconnect on each module, both isolation and fault tolerance are achieved. This is the design approach taken on most Eaton grid-tied inverters. See Figure 2.Figure 2. Double-pole DC disconnects on each power module An alternate approach could be to integrate a DC disconnect oneach power module but only in the + line. While this can stop power flow to the inverter for maintenance purposes, it does not isolate the DC bus if a power module were to fail. This approach may be cheaper and easier, but it compromises fault tolerance of the inverter. See Figure 3.Figure 3. Single-pole DC disconnects on each power module The final and least preferable option is putting one large DCdisconnect on the + line. This approach provides for no containment of a failed power module and no fault tolerance. However, this method can seem attractive when there is so much focus oninitial equipment costs; the long-term operating cost impact of this approach is greater. See Figure 4.Figure 4. Single DC disconnectAC-side design choicesOn the AC side of the inverter, there are a wide variety of design choices. Given the higher frequency and usage stress of ACswitching, the selection of proper equipment is even more important than on the DC side. Extensive research on installed bases of inverters has demonstrated that AC contactors are the highest failure rate component in the power path of the inverter 1. In fact, AC contactors have demonstrated failure rates that are twice as high as the next component—IGBTs. Given the usage stress and documented field failure rates of AC contactors, the proper selection of AC switchgear on the inverter is exceptionally important in impacting overall inverter reliability.Similar to the DC side of the inverter, there are a few design choices that include AC isolation of individual power modules or isolation of the inverter for an entire unit.Figure 5 shows a preferred implementation that includes AC contactor isolation on each power module. Notice there is stillalso a main breaker for inverter isolation and lock-out/tag-out.Figure 5. AC contactor on each power moduleThe combination of AC contactor with a main breaker is effective in terms of both reliability and system protection. Contactors are specifically designed for a high duty cycle and are well suited for regular and heavy daily usage. Circuit breakers on the other hand are optimized around fault clearing. In Figure 6, this design difference can be clearly seen in each components cycle rating.Figure 6. Component cycle ratings3White Paper WP083019ENEffective April 2016Low voltage switchgearselection in grid-tied inverters EATON However, a contactor is not designed for fault protection, log-out/tag-out, or manual isolation. Thus the combination of the twoprovides for all the needs of an inverter in a safe and reliable fashion. This is the design approach for Eaton grid-tied inverters.A less expensive alternative would be to use one main AC contactor. Once again, this approach is much less expensive, but does not provide fault isolation if a power stack fails. See Figure 7.Figure 7. Main AC contactorA second factor to consider in either of these configurations isthe selection of contactor technology. A conventional mechanical contactor will physically move a metal arm from an open toclosed position. As the arm approaches the closed position, there is arcing that occurs on the surface of the contacts due to thevoltage across those contacts. As this arcing happens, the metallic surfaces soften, melt, and deform slightly. Though individually these events are relatively minor, over time this surface pitting reduces the contactor’s ability to open and close freely and provides a low resistance current path. Vacuum technology, however, virtually eliminates this phenomenon. With a vacuum type contactor, the contacts actually open and close in a vacuum. This minimizes arcing and greatly enhances contactor life. In the chart above, one can see that vacuum contactors have a cycle life 10X that of conventional mechanical contactors.Similarly, for inverter fault protection and isolation, there are various alternatives as well. The highest feature approach is anANSI air power breaker. These typically have the highest interrupting fault current ratings and can clear such faults repetitively. Molded-case circuit breakers are another alternative, but typically do not have the same interrupting current ratings. Air power breakers also have the best capability to interface with utility protective relays. Finally a fused mechanical switch is an option. The fuses provide for good fault interrupting current handling but “blow” under such conditions and require component replacement to bring the device back into service.An extremely low cost solution could be to remove the contactors entirely and then use the AC breaker for daily isolation. Because breakers are not meant to be operated as contactors andhave limited duty cycle in this application, this approach is not recommended for long-term reliability. In particular, because this component has substantial operating stress and is a leading cause of field failures, it would be recommended to look for other cost-cutting opportunities. See Figure 8.Figure 8. AC protection without contactors and without stack isolationT able 1 aggregates the various AC and DC design choices— as “good,” “better,” and “best”.With these design choices, a matrix can also be established based on system functionality.T able 2.System functionalityFaultConclusionsThere are a variety of protection and control options on both the AC and DC side of the inverter and in summarizing the options, it is clear that there is a classical cost/benefit trade-off. Switchgear options that provide for maximum reliability and fault tolerance are substantially more costly while less reliable ones are inexpensive. In this analysis, the most reliable approach uses AC vacuum contactors on each stack and a main AC air power breaker.Eaton1000 Eaton Boulevard Cleveland, OH 44122 United States © 2016 EatonAll Rights ReservedPrinted in USAPublication No. WP083019EN / Z18002 April 2016Eaton is a registered trademark.All other trademarks are propertyof their respective owners.Low voltage switchgear selection in grid-tied invertersWhite Paper WP083019ENEffective April 2016About EatonEaton’s electrical business is a global leader with expertise in power distribution and circuit protection; backup power protection; control and automation; lighting and security; structural solutions and wiring devices; solutions for harsh and hazardous environments; and engineering services. Eaton is positioned through its global solutions to answer today’s most critical electrical power management challenges.Eaton is a power management company with 2015 sales of$20.9 billion. Eaton provides energy-efficient solutions thathelp our customers effectively manage electrical, hydraulic and mechanical power more efficiently, safely and sustainably. Eaton has approximately 97,000 employees and sells products to customers in more than 175 countries. For more information,visit .Source1 Golans, A., “PV System Reliability: An Operator’s Perspective,”Photovoltaics, IEEE Journal of, vol.3, no.1, pp. 416, 421, Jan 2013.。

Design Compiler使用说明一．软件说明Design Compiler是synopsys的综合软件，它的功能是把RTL级的代码转化为门级网表。

综合包括转译（Translation），优化(Opitimization)，映射(Mapping)三个过程。

在转译的过程中，软件自动将源代码翻译成每条语句所对应的功能模块以及模块之间的拓扑结构，这一过程是在综合器内部生成电路的布尔函数的表达，不做任何的逻辑重组和优化。

优化：基于所施加的一定时序和面积的约束条件，综合器按照一定的算法对转译结果作逻辑优化和重组。

在映射过程中,根据所施加的一定的时序和面积的约束条件，综合器从目标工艺库中搜索符合条件的单元来构成实际电路。

DC有两种界面，图形界面通过敲入design vision&调用出来，另一种命令行界面通过dc_shell-t调用。

建议初学者使用图形界面，因为图形界面比较容易上手；业界的人士比较青睐命令行界面，因为其所耗的资源少，并且将所用的命令写成综合脚本的形式，便于查阅。

因为门级和代码级不同，代码级考虑的是理想情况，但是实际电路不是这样的，它有门级的延时，线的延时，信号的转换时间，甚至时钟信号到达各个触发器的时间不相等。

基于这些考虑，DC通过施加约束，模拟实际环境，根据实际情况得出门级网表。

因此如何适当的施加约束是DC的关键所在。

二．库的配置通过上述说明可知，DC需要通用库和工艺库的支持，DC用到的工艺库是.db或者是.lib格式的，其中.lib格式的文件是可读得，通过此文件可以了解库的详细信息，比如说工作电压，操作温度，工艺偏差等等。

.db格式的库是二进制的，不可读。

.db格式的库由.lib格式的库通过命令read_lib生成。

目标工艺库（Target_library）：是指将RTL级的HDL描述到门级时所需的标准单元综合库，它是由芯片制造商（Foundry）提供的，包含了物理信息的单元模型。

DC/DC 模块电源 应用手册广州德励电子科技有限公司二零零七年三月二十二日目 录一、基本术语解释 (1)输入电压范围（Input Voltage Range） (1)负载电压调整率（Load Voltage Regulation） (1)输入（线性）电压调整率（Line Voltage Regulation） (1)输出电压精度（Ouput Voltage Accuracy） (1)输入和输出波纹电压（Input and Output Ripple） (1)输入与输出隔离电压（Input to Output Isolation） (1)绝缘阻抗（Insulation Resistance） (1)全负载效率（Efficiency at Full Load） (1)温度漂移(Temperature Drift) (1)温升（Temperature above Ambient） (1)开关频率（Switching Frequency） (1)空载功耗（No Load Power consumption） (1)隔离电容（Isolation Capacitance） (1)平均无故障时间（Mean Time Between Failure）[MTBF] (1)躁声(Noise) (1)工作温度范围（Operating temperature range） (2)二、电源的设计及选用 (3)确定电源规格 (3)系统配电设计 (4)三、电源的测试 (7)开尔文四端测试法 (7)模块的性能 (7)四、电源的应用 (11)隔离（Isolation） (11)串联使用（Connecting DC/DC Converters in Series） (11)并联使用（Connecting DC/DC Converters in Parallel） (11)模块并联使用的推荐值 (12)滤波（Filtering） (12)输出滤波计算 (12)限制涌浪电流（Limiting Inrush Current） (13)容性负载 (13)隔离电容和漏电流 (13)过载保护 (14)输入欠压保护 (15)无负载过压上锁 (15)输入短路保护 (15)EIA-232接口 (16)隔离数据采集系统 (16)远距离传输 (16)减小噪声 (17)电磁兼容 (17)一、 基本术语解释输入电压范围（Input Voltage Range）指产品维持正常工作性能所能容忍的输入电压波动范围。

DC/DC电源简单介绍及实际遇到问题背景：因目前LCD上所用IC的供电电压越来越低，如3.3v，1.8V，1.5V，1.0V 等，而且电流越来越大，一般都要1~2A左右，电源模块提供的电压一般在18v，12v，5v，因此在负载供电同样的输出功率，如果单靠LDO来完成，一部分（40%以上）能量就会损失在LDO上，势必产生LDO的散热可靠性问题，而如果采用DC/DC控制元件，其效率通常在80%以上，使得能量有效传递，也改善了元件的温升问题。

2．相对LDO而言，DC/DC控制电路都带有过流/过压保护电路，对于电源的开短路实验来说不需要外加检测和保护电路。

*DC/DC电源有常用的有两种结构：升压式和降压式，但其核心元件是一样的：电感，开关MOS管，二极管，滤波电容1．升压式如下：其工作原理如下：在控制开关SW上输入PWM波形，当开关 SW导通时，构成回路，电感L中电流逐渐变大，同时将能量在电感中。

此时二极管的正极电压几乎为零，而其负极为电容的正极电压，所以二极管此时处于截至状态，此时的负载电流靠电容Cout 放电来维持。

当SW关断时，电感上产生较高感应电压，二极管导通，给电容Cout充电，并把储存在电感上的能量释放出来，当于一个另外的电源叠加在电容上，所以此时电容两端的电压得到提升。

此时的负载电流同样靠电容Cout 来维持。

升压电路曾经在B+的逆变电源上有用。

2．降压式如下：工作原理如下：容充电，同时能量存储在电感中。

输出端的负载的电流靠电容来维持。

当开关SW断开时，因为流过电感上的电流不能突变，所以通过电容，二极管回路继续续流，同时电容Cout来维持负载端的电流输出。

通过调整控制开关管上PWM脉冲宽度，就可以控制V out的大小而降压式的DC/DC在我们小信号部分的电源供电中经常用到。

一般除了核心元件（MOS管，续流二极管，滤波电感）外，实际应用中为了得到不同的输出电压和提高系统的稳定性，还需要有反馈和补偿等控制电路，如下图RX，RY为反馈取样电阻，将输出的电压取样后与IC内部的参考电压Vref 进行比较放大，输出一个放大后的误差电压，再通过比较器与锯齿波。

DC/DC Conver ter Specifications (measured @ ta= 25°C, nominal input voltage, full load and after warm-up)E224736UL-60950-1 CertifiedEN-55022 Certified20 Watt 2:11.6“ x 1“Ribbed StyleSingle OutputSelection GuidePart Input Input Output Output Efficiency Max. CapacitiveNumber VoltageRange Current Voltage Current typ. Load[VDC] [mA] [VDC] [mA] [%] [µF]RPP20-2412S 18-36 940 12 1670 90 1000DescriptionThe RPP20 series 2:1 input range DC/DC converters are ideal for high end industrial applications and COTS Militaryapplications where a very wide operating temperature range of -45°C to +115°C is required. Although the case sizeis very compact, the converter contains a built-in EMC filter EN-55022 Class B without the need for any externalcomponents. The RPP20 is available in a ribbed case style for active cooling. They are UL-60950-1 certified.FeaturesICETechnology*• +115°C Maximum Case Temperature• -45°C Minimum Case Temperature• Built-in EMC Filter• Ribbed Case Style• 2250VDC Isolation• EN-55022 Class B RPP20-2412S* ICE TechnologyICE (Innovation in Converter Excellence)uses state-of-the-art techniques to minimiseinternal power dissipation and to increasethe internal temperature limits to extend theambient operating temperature range to themaximum.Notes:Note1: Typical values at nominal input voltage and full load.Only the single output converters have a trim function that allows users to adjust the output voltage from +10% to -10%, please refer to the trim table that follow for details. Adjustment to the output voltage can be used with a simple fixed resistor as shown in Figures 1 and 2. A single fixed resistor can increase or decrease the output voltage depending on its connection. Resistor should be located close to the converter. If the trim function is not used, leave the trim pin open.Trim adjustments higher than the specified range can have an adverse effect on the converter´s performance and are not recommended. E xcessive voltage differences between output voltage sense voltage, in conjunction with trim adjustment of the output voltage; can cause the OVP circuitry to activate. Thermal derating is based on maximum output current and voltage at the converter´s output pins. Use of the trim and sense function can cause output voltages to increase, thereby increasing output power beyond the converter´s specified rating. Therefore: (Vout at Pins) X (Iout) ≤ rated output power.PROTECTIONSParameterConditionValueOutput Power Protection (OPP)current limit 120% typ.Over Voltage Protection (OVP)10% load 120% typ.Over Temperature Protection (OTP)case temperature 120°C, auto-recovery Isolation Voltage I/P to O/P , at 70% RH I/P to Case, O/P to Case 2250VDC / 1 Minute 1500VDC / 1 MinuteIsolation Resistance I/P to O/P , at 70% RH100M W min.Isolation CapacitanceI/P to O/P1500pF typ.Specifications (measured @ ta= 25°C, nominal input voltage, full load and after warm-up)Notes:Note2:This Power Module is not internally fused. A input fuse must be always used. Recommended Fuse: T1.6AREGULATIONSParameterConditionValueOutput Voltage Accuracy 50% load ±1.5% max.Line Voltage Regulation low line to high line ±0.3% max.Load Voltage Regulation 10% to 100% load±0.5% max.Transient Response 25% load step change, ΔIo/Δt=2.5A/us 800µs typ.Transient Peak Deviation25% load step change, ΔIo/Δt=2.5A/us±2%Vout max.Trimming Output VoltageFigure 2. Trim connections to decrease output voltage using fixed resistorsFigure 1. Trim connections to increase output voltage using fixed resistors+V IN -V INCTRL +V OUT R TRIM UP-V OUTTRIMLOAD+V IN -V INCTRL +V OUT R TRIM DOWN-V OUTTRIMLOADTrim down resistor value (K W )Vout-1%-2%-3%-4%-5%-6%-7%-8%-9%-10%12VDC 322.2137.281.153.135.524.016.09.75.01.3Trim up resistor value (K W )Vout1%2%3%4%5%6%7%8%9%10%12VDC 238.7113.168.246.332.122.415.49.86.53.2ENVIRONMENTALParameterConditionValueRelative Humidity95%, non condensing Temperature Coefficient ±0.04% / °C max.Thermal Impedance natural convection, mounting at FR4(254x254mm) PCB vertical horizontal7.2°C/W 7.8°C/WOperating Temperature Range start up at -45°C-45°C to (see calculation)Maximum Case Temperature +115°CMTBFaccording to MIL-HDBK-217F (+50°C G.B.)according to BellCore-TR-332 (+50°C G.B.)768 x 103 hours 1572 x 103 hourscontinued on next pageDerating Graph(Ta= +25°C, natural convection, typ. Vin and vertical mounting)CalculationSpecifications (measured @ ta= 25°C, nominal input voltage, full load and after warm-up)302535404550102030405060708090100Load [%]C a s e T e m p e r a t u r e [°C ]105060708090100203040506070809010018Vin24Vin 36Vin Load [%]E f f i c i e n c y [%]R thcase-ambient = 7.2°C/W (vertical) T case = Case Temperature R thcase-ambient = 7.8°C/W (horizontal)T ambient= Environment TemperatureP dissipation = Internal lossesR thcase-ambient = T case - T ambientP IN = Input PowerP dissipationP OUT = Output Powerh = Efficiency under given Operating Conditions P dissipation = P IN - P OUT = P OUTapp- P OUTapp R thcase-ambient = Thermal ImpedancehPractical Example:Take the RPP20-2412S with 50% load. What is the maximum ambient operating temperature? Use converter vertical in application.Eff min = 89% @ V nom P OUT = 20WP OUTapp = 20 x 0.5 = 10W P dissipation = P OUTapp- P OUTapp R th = T casemax - T ambient --> 7.2°C/W = 115°C - T ambienthP dissipation1.24Wh = ~88% (from Eff vs Load Graph)T ambientmax = 106.1°CP dissipation = 10- 10 = 1.24W0.89Specifications (measured @ ta= 25°C, nominal input voltage, full load and after warm-up)DC/DC Conver terSpecifications (measured @ ta= 25°C, nominal input voltage, full load and after warm-up)RPP20-2412SSeriesPACKAGING INFORMATIONParameterTypeValuePackaging Dimension (LxWxH)Tube160.0 x 45.0 x 16.0mmPackaging Quantity 5pcsStorage Temperature Range-55°C to +125°CThe product information and specifications may be subject to changes even without prior written notice.The product has been designed for various applications; its suitability lies in the responsibility of each customer. The products are not authorized for use in safety-critical applications without RECOM’s explicit written consent. A safety-critical application is an application where a failure may reasonably be expected to endanger or cause loss of life, inflict bodily harm or damage property. The applicant shall indemnify and hold harmless RECOM, its affiliated companies and its representatives against any damage claims in connection with the unauthorizeduse of RECOM products in such safety-critical applications.。