IR2520D应用方案设计

安徽省电力公司集中招标采购临泉供电公司佳能iR 2525i 数码复印机佳能2525I A3 打印复印扫描一体机技术规范书设计单位：临泉供电公司2011年3月单位：批准：审核：编制：2011年3月1日分标编号：货物需求一览表（买方填写）供货范围（卖方填写）1 总则产品总体要求：1、上述组件均为必配部件，供应商不得变更、调整、减少，应保证设备正常运行所应配置的相关辅件、组件。

2、必需符合中国CCC认证、能源之星认证、环保（绿色）认证要求，必需提供相关证明文件。

3、为保证供货渠道的合法性，需出具原厂商针对该项目的供货证明函原件和原厂针对本项目的专项授权函。

4、产品推荐：2、打印机需求基本参数复印/打印方式激光静电转印方式感光材料 OPC显影系统干式单组分显影定影系统按需定影内存标配 256MB(iR 2525)or512MB(iR 2520i/2525i/2530i/2535i/2545i)最大 512MB(iR 2525)预热时间主机电源打开时 30秒或更短睡眠模式恢复时 1秒最大原稿尺寸 A3首页输出时间 iR 2520i 6.4秒iR 2525i/2525/2530i 5.4秒iR 2535i/2545i 3.9秒灰度等级 256级分辨率扫描 600dpi×600dpi复印 1200dpi(等效)×600dpi打印真正1200dpi×1200dpi复印倍率固定倍率 25%，50%，61%，70%，81%，86%，115%，122%，141%，200%，400% 手动缩放 25%-400%(以1%为单位)连续输出速度 iR 2520i 20页/分钟(A4)iR 2525i/2525 25页/分钟(A4)iR 2530i 30页/分钟(A4)iR 2535i 35页/分钟(A4)iR 2545i 45页/分钟(A4)连续复印张数 999 张供纸量 iR 2520i/2525i/2525/2530i 标准 250张+550张(前置式纸盒)＋100张(手送纸盘) 最大 250张+550张×3(前置式纸盒)＋100张(手送纸盘)iR 2535i/2545i 标准 550张×2(前置式纸盒)＋100张(手送纸盘)最大 550张×4(前置式纸盒)＋100张(手送纸盘)纸张尺寸纸盒 A3-A5R、8K、16K和16KR手送纸盘 A3-A5R、8K、16K、16KR、非标准尺寸和信封纸张厚度纸盒 64-90g/m2手送纸盘 64-128g/m2出纸托盘容量 250张(A4)电源 iR 2520i/2525i/2525/2530i 220V AC_50Hz_3.3AiR 2535i/2545i 220V AC_50Hz_4.2A最大功耗 iR 2520i/2525i/2525/2530i 1.5kwiR 2535i/2545i 1.8kw主机尺寸 (宽×深×高) iR 2520i/2525i/2530i 565mm×693mm×896mm(安装有双面自动输稿器)iR 2525 565mm×680mm×806mm(安装有稿台盖板)iR 2535i/2545i 565mm×693mm×907mm(安装有双面自动输稿器)主机安装空间(宽×深) 1079mm×1441mm(不安装可选设备时)1367mm×1441mm(安装了可选的内置式装订器-B1时)重量 iR 2520i/2525i/2530i 约76.1kgiR 2525 约70.6kgiR 2535i/2545i 约78.4kg打印规格(标配)UFR II LT网络打印(标配)打印分辨率真正1200dpi×1200dpi打印语言 UFR II LT接口 100BASE-TX/10BASE-T、USB2.0高速网络协议 TCP/IP系统环境 Microsoft Windows?2000/XP/Vista/7,Server 2003/2008,Macintosh OS?(10.4或以上)PCL打印组件-AF1(选配)打印分辨率 1200dpi(等效)×600dpi打印语言 PCL5e, PCL6接口 100BASE-TX/10BASE-T、USB2.0高速网络协议 TCP/IP系统环境 Microsoft Windows?2000/XP/Vista/7,Server 2003/2008PS打印组件-AF1(选配)打印分辨率 1200dpi(等效)×600dpi打印语言 PS3仿真接口 100BASE-TX/10BASE-T、USB2.0高速网络协议 TCP/IP系统环境 Microsoft Windows?2000/XP/Vista/7,Server 2003/2008双面自动输稿器(仅限iR 2520i/2525i/2530i/2535i/2545i,iR 2525需选配)输稿速度 iR 2520i/2525i/2525/2530i 复印25页/分钟(A4，80g/m2)扫描25页/分钟(A4，80g/m2，黑白/彩色)iR 2535i/2545i 复印45页/分钟(A4，80g/m2)扫描30页/分钟(A4，80g/m2，黑白/彩色)原稿尺寸 A3-A5、8K、16K原稿厚度 iR 2520i/2525i/2525/2530i 50-105g/m2iR 2535i/2545i 52-128g/m2原稿托盘容量 iR 2520i/2525i/2525/2530i 50张(A4、80g/m2)iR 2535i/2545i 100张(A4、80g/m2)扫描规格扫描方式拉式标配推式 iR 2525选配色彩方式彩色/黑白扫描分辨率最大600dpi×600dpi(推式，黑白)生成格式 JPEG/TIFF/PDF/高压缩PDF(标配)/OCR PDF(需选配)传真规格(选配)Super G3传真卡-AG1适用线路公用电话线路1条线路调制解调速度 Super G3(最大33.6kbps)数据压缩方式 MH,MR,MMR,JBIG传输速度大约3秒/页 (33.6kbps)其它主要选购件内置式装订器-B1托盘数量 2个(主体本身标配一个，另外的附加内置装订托盘-B1需选配) 托盘容量标准托盘不分套、分套或分组模式 1000张或125mm(A4)装订模式 30套或125mm(A4)安装了附加托盘-B1 不分套、分套或分组模式 100张或12.5mm(A4)装订模式 15套或8.1mm(A4)最大装订张数 50张(A4,64-80g/m2)装订位置角落、两点内置式双路托盘-G1托盘数量 2个(包括一个主机托盘)托盘容量 100张(A4,80g/m2)双纸盒组件-AE1纸张容量 550张×2(80g/m2)纸张尺寸 A3-A5R、8K、16K纸张厚度 64-90g/m2耗材墨粉 NPG-50墨粉(印量约19,400页,用于iR 2535i/2545i)NPG-51墨粉(印量约14,600页,用于iR 2520i/2525i/2525/2530i)感光鼓 NPG-50/51感光鼓(印量约140,000页,用于iR 2535i/2545i) NPG-50/51感光鼓(印量约132,000页,用于iR 2520i/2525i/2525/2530i) 装订针-J1 角落装订、两点装订用针,5000支×3,用于内置式装订器-B1 佳能复印纸 A4 70g复印纸A3 70g复印纸A4 80g复印纸A3 80g复印纸2 测试和验收2.1 概述a 验收包括工厂验收和现场验收；b 投标方提供给招标方的所有设备必须在交货前通过工厂验收，并得到招标方的确认，若招标方未签署工厂验收报告，任何设备不能从投标方工厂发运；c 投标方应提供工厂验收和现场验收的测试程序的详细说明，测试项目和性能都应在详细说明中指出；d 招标方要求的一些特殊试验，只要合理都应进行；e 即使招标方在试验报告上签字，投标方仍应对设备固有缺陷和合同中的项目承担责任；f 测试和验收计划：投标方应提交有关工厂验收和现场验收的详细计划，包括系统性能和功能等的测试方法等，招标方有权修改测试和验收计划，在计划被招标方确认前，计划不应生效；g 测试设备：在工厂验收和现场验收中，投标方应提供验收过程中必需的设备，如检验设备、测量设备、记录设备等。

电子镇流器控制器／半桥驱动器ＩＲ2520ＤIR2520D是美国国际整流器(IR)公司最近研制的荧光灯电子镇流器控制器和半桥驱动器单片IC。

该新型器件的主要特点是含有自适应零电压开关(ZVS)和波峰因数(即峰值电流与平均电流之比值)过电流保护。

IR2520D的核心是一个0～5V的压控振荡器(VCO)，其最低频率(即灯正常燃点时的输出频率)可由外部电阻来编程。

IR2520D的半桥驱动器输出专门用作驱动MOSFET或IGBT。

IR2520D 仅需要用很少量的元件，即可组成高性能和高可靠的荧光灯电子镇流器。

1.内部结构与引脚功能IR2520D采用8引脚PDIP和SOIC封装，在芯片上集成了电压控制振荡器、600V半桥驱动器、外部低端MOSFET电流感测(即VS感测)电路、自适应ZVS 逻辑和故障逻辑电路及自举二极管等，其内部结构及引脚排列如图1所示。

引脚功能如表1所示。

2.主要特点及工作条件IR2520D的主要特点如下：(1)将自适应镇流器控制器和600V半桥驱动器集成在同一芯片上，自适应ZVS使功率开关MOSFET有最低的功率损耗；(2)在Vcc脚内置15.6V的齐纳二极管，将IC电源电压箝位在15.6V的电平上；(3)VCO的最低频率(即荧光灯正常点燃时的工作频率)可通过FMIN脚外部电阻编程设定；(4)内置电流感测和波峰因数过电流保护及自举二极管，从而使外部元件减少到最小化；(5)微功率启动(启动电流仅约150μA)。

IR2520D的推荐工作条件如表2所列。

3.应用电路IR2520D的典型应用电路如图2所示。

图中，D1~D4为桥式整流器，C1和L1为LC滤波电路，IR2520D及功率MOSFET(Q1、Q2)等组成半桥式变换器，L2和C6组成LC串联谐振网络(在灯启动之后，L2起限流作用)。

(1)运行模式IR2520D及其应用电路的工作原理可通过运行模式来说明。

欠压锁定(UVLO)模式在电子镇流器接通AC线路之后，通过IC脚Vcc 上电阻R1的电流对电容C2充电。

IR场效应管MOS管广泛应用如下:1、HID,氙气灯,安定器等汽车照明用MOSFET,IC:IRFZ44N,IR,49A,55V,MOSFETIRF3205,IR,110A,55V,MOSFETIRF540N,IR,33A,100V,MOSFETIRF840,IR,8A,500V,MOSFETIRF740,IR,10A,400V,MOSFETHFA08TB60,IR,8A,600V,快恢复管MUR860,ON,8A,600V,快恢复管8ETH06,IR,8A,600V,快恢复管IR2103,IR,驱动IC2、UPS用IC,MOSFET:IRFP264,IR,38A,250V,MOSFETIRF3710,IR,57A,100V,MOSFETIRG4PH40UD,IR,21A,1200V,IGBTIRG4PC40W,IR,20A,600V,IGBTIRFZ44N,IR,49A,55V,MOSFETIRF3205,IR,110A,55V,MOSFETIRG4PF50WD,28A,900V,IGBTIRF1010E,IR,84A,60V,MOSFETUC3845N,ON,PWM控制器UC3854N,TI,PFC控制器UC3843AN,ON,PWM控制器RHRP860,仙童,8A,600V,FRED RHRP15120,仙童,15A,1200V,FRED RHRP30120,仙童,30A,1200V,FRED RHRG30120,仙童,30A,1200V,FRED 3、电动车控制器用MOSFET:STP75NF75,ST,80A,75V,MOSFETIRF1010E,IR,84A,60V,MOSFETIRF2807,IR,82A,75V,MOSFETIRFZ44N,IR,49A,55V,MOSFETIRF2907,IR,75A,75V,MOSFETFSM75N75,Foslink,75A,75V,MOSFET4、电动工具控制器用MOSFET:STP60NF06,ST,60A,60V,MOSFETSTP75NF75,ST,80A,75V,MOSFETIRFZ44N,IR,49A,55V,MOSFET5、电子镇流器,节能灯等产品用调光,控制,驱动IC,MOSFET: IRF830,IR,4.5A,500V,MOSFETIRF840,IR,8A,500V,MOSFETIRF740,IR,10A,400V,MOSFETIRF1010E,IR,81A,60V,MOSFETIRFP450,IR,14A,500V,MOSFETIRFP460,IR,20A,500V,MOSFETIRFP22N50A,IR,22A,500V,MOSFETIRFPS37N50A,IR,37A,500V,MOSFETIR2156,IR,镇流器控制ICIR2520D,IR,镇流器控制ICIR2166,IR,镇流器控制ICIR2153,IR,镇流器控制ICIR21592,IR,可调光镇流器控制IC 6、开关电源用MOSFET,IC:IRF840,IR,8A,500V,MOSFETIRF740,IR,10A,400V,MOSFET IRFP450,IR,14A,500V,MOSFET IRFP460,IR,20A,500V,MOSFET IRFP22N50A,IR,22A,500V,MOSFET IRFPS37N50A,IR,36A,500V,MOSFET IRF830,IR,4.5A,500V,MOSFET MBR20100CT,ON,20A,100V肖特基30CPQ100,IR,30A,100V,肖特基40CPQ100,IR,40A,100V,肖特基UC3825AN,TI,PWM控制器UC3875N,TI,PWM控制器7、逆变器用MOSFET:IRFZ44N,IR,49A,55V,MOSFETIRF3205,IR,110A,55V,MOSFETIRF2807,IR,82A,75V,MOSFETIRF1404,IR,162A,40V,MOSFETIRFP450,IR,14A,500V,MOSFETIRFP460,IR,20A,500V,MOSFET8、音响,汽车功放,舞台设备用MOSFET: IRFZ44N,IR,49A,55V,MOSFETIRF3205,IR,110A,55V,MOSFETIR2011,IR,1A驱动器FQP50N06,仙童,50A,60V,MOSFETIRF640N,IR,18A,200V,MOSFETIRF9640,IR,-11A,-200VIRF530,IR,14A,100V,MOSFETIRF1010E,IR,84A,60V,MOSFETIRFP250N,IR,30A,200V,MOSFETIRF9530N,IR,-14A,-100V,MOSFET IRLML6302,IR,-0.62A,-20V,MOSFET9、太阳能控制器用MOSFET:STP75NF75,ST,80A,75V,MOSFETSTP60NF06,ST,60A,60V,MOSFETIRFZ44N,IR,49A,55V,MOSFETIRF1010E,IR,84A,60V,MOSFET10、电焊机用MOSFET:IRFP460,IR,20A,500V,MOSFETIRFP260N,IR,49A,200V,MOSFETIRF9Z34N,IR,-17A,-55V,MOSFETIRFZ34N,IR,26A,55V,MOSFET11、超声波清洗机用MOSFETIRFP460LC,IR,20A,500V,MOSFETIRFP460,IR,20A,500V,MOSFETIRFP450,IR,14A,500V,MOSFET12、其它应用领域:家用电器、电脑、仪器仪表、通信网络设备、航空、卫星等各行各业。

远程打印机互联教程一、打印设置1.查看自己电脑操作系统。

打开“我的电脑”，进入后点击右键“属性”，系统类型中查看自己的系统是32位的还是64位的。

2.打印机驱动软件下载。

打开360云盘——常用软件——佳能打印机驱动，根据自己电脑系统选择下载32位或者64位打印机驱动软件。

3.打印机查找与安装。

将电脑无线网络设置到guangda3，打开下载后的软件包，点击setup.exe，完成打印机驱动安装。

4.打印机默认设置开始——控制面板——设备与打印机，右键已安装的打印机进行默认打印机设置。

二、扫描自动发送设置1.电脑设置打开“我的电脑”，进入后点击右键“属性”，点击下方的“更改设置”，进入后点击弹出框下方的“更改”，进行电脑的计算机名和工作组设置，确保计算机名为英文，工作组为WORKGROUP。

2.电脑用户名设置电脑要有登陆名和密码，且全部为英文。

3. 控制面板-管理工具-本地安全策略-本地策略-安全选项-网络访问：本地账户的共享和安全模式-经典本地用户以自己的身份验证（有些电脑有本地安全策略，有的话必须进行设置，没有的话此项可忽略）。

4.扫描文件夹设置（以“测试”文件夹演示）在电脑中新建一个文件夹“测试”，右键选择“属性”——共享，网络路径下选择“共享”待网络路径下出现“\\计算机名\\测试”即可实现网络共享。

此时点击“高级共享”——权限，并将框内的所有权限全部选上即可。

5.打印机扫描设置发送-地址薄-注册-注册新地址-注册新地址-文件-把FTP改WINDOWS(SMB)-浏览-选择工作组-向下-选择计算机名-向下-输入登入计算机的用户名例如：Administrator-确定-选择共享的文件夹-确定-下一步-设置显示的名称-确定-完成三、打印及扫描发送1.发送——地址簿（选择自己的计算机名字并确认）——TIFF（将保存文件类型改为彩色PDF然后确认），最后点击启动按钮，即可自动扫描发送。

2.如果需要双面扫描。

Application Note AN-1062IRPLMB1E - 25W 230VAC Small Size BallastUsing IR2520DBy Cecilia ContentiTable of ContentsPage Overview (1)Features (2)Electrical Characteristics (2)IR2520D Ballast Control IC (2)Circuit Description (3)Miniballast 1 Bill of Materials (4)Functional Description (5)Fault Conditions (6)Open Filaments Protection (7)Low AC Line Protection (8)Miniballast Layout (9)Design Tip: Auto Restart Option (11)Different Procedure to Adapt the Design (12)Small sizes ballasts (often called Matchbox ballasts) are becoming very common in Europe to drive a wide range of lamps with power between 18W and 26W like PLC 18W, PLT 18W, TC-L 18W, TC-L 24W, TC-F18W, TC-F 24W, TC-DEL/TEL 26W, T5 24W, T8 18W, T5C 22W and TR 22W. Limiting the maximum power to 25W the design does not need to conform to THD and PF requirements and this allows saving the PFC stage reducing the components count and maintaining a very small size.Topics CoveredOverview FeaturesElectrical Characteristics IR2520D Ballast Control IC Circuit DescriptionMiniballast Circuit Diagram Functional Description Fault Conditions Miniballast LayoutDesign Tip: AUto-restart Option Design Procedure to adapt the design to different lamp types1. OverviewSmall sizes ballasts (often called Matchbox ballasts) are becoming very common in Europe to drive a wide range of lamps with power between 18W and 26W like PLC 18W, PLT 18W, TC-L 18W, TC-L 24W, TC-F 18W,TC-F 24W, TC-DEL/TEL 26W, T5 24W, T8 18W, T5C 22W and TR 22W. Limiting the maximum power to 25W the design does not need to conform to THD and PF requirements and this allows saving the PFC stage reducing the components count and maintaining a very small size.The MINIBALLAST1 is an electronic ballast for driving 26W compact fluorescent lamps from 220VAC. The circuit provides all of the necessary functions for preheat, ignition and on-state operation of the lamp and also includes the EMI filter and the rectification stage. The ballast size is 36mmx55mm.The circuit is built around the IR2520D Ballast Control IC. The IR2520D provides adjustable preheat time,adjustable run frequency to set the lamp power, high starting frequency for soft start and to avoid lamp flash,fault protection for open filament condition and failure to strike, low AC line protection and auto-restart after line brownout conditions. The IR2520D is a low-cost solution with only 8 pins and allows the componentcount for the complete solution to be reduced down to 19 components.- 25W 230VAC small size ballast using IR2520DByCecilia Contenti 12AN10622. FeaturesProgrammable run frequency Programmable preheat timeOpen filaments and no-lamp protectionFailure to Strike and deactivated-lamp protection Low AC line protection3. Electrical CharacteristicsInput Power: 24W @ 220VACInput Current: 168mArms @ 220VAC Starting Frequency: 100KHz Average Run Frequency: 40KHz Ballast turn-on voltage: 120VAC Ballast turn-off voltage: 70VAC4. IR2520D Ballast Control ICThe IR2520D is intended for driving CFL and TL lamps in CFL or matchbox (small size ballasts)applications. The IR2520D integrates all of the necessary functions for preheat, ignition and on-state operation of the lamp, plus, lamp fault protection and low AC-line protection, together with a complete high and low-side 600V half-bridge driver. The IR2520D has only 8 pins and fits into a standard SOIC8 or DIP8 package. The IR2520D has been designed to overcome the disadvantage of discrete self-oscillating solutions while maintaining low cost.In the CFL market, the self-oscillating bipolar transistor solution is still more popular than a ballast control IC plus FETs solution due to lower cost. This approach is very simple in nature but has disadvantages including:DIAC or additional circuit required for starting,additional free-wheeling diodes required operating frequencies determined by bi-polar tran-sistor storage time and toroid saturation (not easy todesign, very dependent on tolerances in production and difficult to set the frequencies precisely),unreliable “always hot” PTC thermistor used for preheat that often fails in the field,no protection against lamp non-strike or open filaments conditions,no smooth frequency ramping during ignition, capacitive mode operations,high crest factor in the lamp current.These can result in high susceptibility to components and load tolerances and/or catastrophic failure of ballast output stage components and a short lamp life. The IR2520D includes adaptive zero-voltage switching (ZV, adaptive run frequency for zero-volt-age switching), internal crest factor and non-zero voltage switching (ZVS) protection, as well as an in-tegrated bootstrap diode. The heart of this IC is a voltage controlled oscillator (VCO) with externally programmable minimum frequency and a 0-5VDC analog voltage input. One of the biggest advantages of the IR2520 is that it uses the VS pin and the RDSon of the low-side half-bridge MOSFET for over-current protection and to detect non-ZVS conditions. An internal 600V FET connects the VS pin to the VS sens-ing circuitry and allows for the VS pin to be accu-rately measured during the time when pin LO is high, while withstanding the high DC bus voltage during the other portion of the switching cycle when the high-side FET is turned on and VS is at the DC bus potential. This eliminates the need for a high-precision current sensing resistor that is typically used to detect over current. Please refer to the IR2520D datasheet for further information on the IR2520D including electrical parameters, state diagram and complete functional description.As a result of the IR2520 features, the MINIBALLAST1circuit using the IR2520D is a complete matchbox solution that offers better reliability and longer lamp life than self oscillating solutions while reducing component count and ballast size.AN10625. Circuit DescriptionThe schematic for MINIBALLAST1 is shown in figure 5.1. The BOM with the components values is shown in table 5.2.The ballast incorporates a fuse, EMI filter, input recti-fier, bus capacitor, half-bridge, control and output stage. The output stage is the classical resonant circuit consisting of an inductor, LRES, and a capaci-tor, CRES. The circuit is built around the IR2520D Ballast Control IC. The IR2520 provides adjustable preheat time, adjustable run frequency to set the lamp power, high starting frequency (about 2.5 times fmin) to avoid lamp flash, capacitive mode protection for open filament condition and current crest factor protection for failure to strike or no lamp conditions.The AC line input voltage is rectified to provide a bus voltage of approximately 300 volts. The start up resistor, Rsupply (in the reference design we have 2 resistors, Rsupply and Rsupply 2 in series), is sized such that they can supply the micro-power current during under-voltage lockout (UVLO). When VCC exceeds the UVLO+ threshold, the IR2520 begins to oscillate and the charge pump circuit (CSNUB, DCP1 and DCP2) supplies the current to VCC that causes the internal 15.6V zener clamp to regulate.The IR2520 Ballast Control IC controls the frequency of the half-bridge programming the right parameters on the lamp to provide lamp preheat, lamp ignition, running mode, low AC line protection and lamp/ ballast fault protection.Fig. 5.1) MINIBALLAST1 Circuit Diagram34AN1062TABLE 5.2) MINIBALLAST1 Bill Of Materials.Lamp type: Spiral CFL 26W, Line Input Voltage: 190-240 VAC. Note: Different lamp types may require BOM changes.AN10626. Functional DescriptionFigure 6.1 shows the voltage across the lamp and the current in the resonant inductor LRES during Startup, Preheat, Ignition and Run Mode.Fig. 6.1:Voltage across the lamp(yellow waveform) and current in the resonant inductor (green waveform) during Startup, Preheat, Ignition and Run ModeWhen power is turned on, the IR2520D goes into Under Voltage Lockout (UVLO) mode.The UVLO mode is designed to maintain a very low (<200uA) supply current and to guarantee that the IC is fully functional before the high- and low-side out-put drivers are activated. During UVLO, the high- and low-side driver outputs (LO and HO) are both low and pin VCO is pulled down to COM for resetting the starting frequency to the maximum.Once VCC reaches the startup threshold (UVLO+), the IR2520D turns on and the half-bridge FETs startto oscillate. The IC goes into Frequency Sweep Mode.At startup, VCO is 0V and the frequency is very high (about 2.5 times fmin). This minimizes voltage spikes and lamp flash at startup. The frequency ramps down towards the resonant frequency of the high-Q ballast output stage, causing the lamp voltage and lamp current to increase. During this time, the filaments of the lamp are pre-heated to the emission tempera-ture to guarantee a long lamp life. The frequency keeps decreasing until the lamp ignites. If the lamp ignites successfully, the IR2520D enters RUN Mode. If the minimum frequency has been chosen below or very close to the resonant frequency, the IC will work near resonance and will adjust the frequency continuously to maintain ZVS at the half-bridge and to minimize the losses in the FETs. If the minimum frequency has been chosen higher than the reso-nant frequency the IR2520D will work at the mini-mum frequency.Figure 6.2 shows the current across the resonant inductor and the voltage across the lamp filamentsat the startup.Figure 6.2:Voltage across the lamp filaments (yellow) and current in the resonant inductor (green) at the startup.56AN1062Figure 6.3 shows the VS (HB) Voltage, the lamp voltage and the lamp current during Run Mode.Figure 6.3:VS (HB) Voltage (blue), Lamp Voltage (yellow) and the Lamp Current (green) during Run Mode.7. Fault ConditionsIn case of fault conditions such as open filaments,failure to strike, deactivated lamp or no lamp, the IR2520D will go into Fault Mode. In this mode the oscillator is latched off. To reset the IC back to pre-heat mode, VCC must be recycled below and above the UVLO thresholds. Resetting the mains does this.In case of low AC line, the IR2520D will automati-cally increase the frequency to maintain ZVS. In this way, the ballast will work at a lower power during a low AC line condition and will operate at the proper power again when the line increases again.7.1. Failure To Strike/ Deactivated Lamp Protection This protection relies on the crest factor protection together with the non-ZVS circuit of the IR2520D, bothenabled when the voltage in pin VCO reaches 4.6V.In order to detect failure to strike conditions, the IR2520D performs an internal crest factor measure-ment for detecting excessive dangerous currents or inductor saturation that can occur during a lamp non-strike fault condition or deactivated lamp condition.The IR2520D measures the VS pin during the entire on-time of the low-side MOSFET. Should the peak current exceed the average current by a factor of 4during the on-time of LO, the IC will enter Fault Mode and both gate driver outputs will be latched ‘low’.Performing the crest factor measurement provides a relative current measurement that cancels tem-perature and/or tolerance variations of the RDSon of the low-side half-bridge MOSFET and does not need to be programmed differently for different lamp types. During normal operation, the current will increase until the lamp ignites. After lamp ig-nition the current will decrease down to the nomi-nal current. Should a lamp non-strike condition occur where the filaments are intact but the lamp does not ignite, the lamp voltage and output stage current will increase during the ignition ramp until excessive currents occur or the resonant induc-tor saturates. The non-ZVS circuit or the crest factor circuit will detect this condition and the IC willenter Fault Mode and both gate driver outputs will be latched ‘low’. This will prevent damaging of the half-bridge MOSFET s.Fig. 7.1 shows the inductor current and the lamp voltage in case of failure to strike condition together with the VCO pin voltage. At initial turn-on of the bal-last, the frequency will ramp down from fmax, through resonance, to fmin. If the lamp does not ignite, the inductor current will saturate and high-voltages will occur across the lamp as the frequency sweeps through resonance. The voltages and currents in the output stage will decrease as the frequency contin-ues to decrease to the capacitive side of resonance.The voltages and currents will be low but hard-switch-ing will occur (non-ZVS). When the frequency reachesAN1062fmin (VCO > 4.6V), the non-ZVS and crest-factor pro-tection will be activated and the frequency will in-crease again to try and maintain ZVS. The frequency will sweep back through resonance (from the ca-pacitive side) and the crest-factor protection will shut-down the IC on the first event when the inductor satu-rates to a level where the crest factor exceeds 3 (see Fig. 7.1).Fig. 7.2 shows pin LO, pin VS and the current in the resonant inductor during shutdown, with a shorter time scale. The final shortened pulse of LO just be-fore shutdown (Fig. 7.2) occurs due to the internal 1us blank time of the crest-factor detection during each turn-on rising edge of LO (to provide immunityto noise and transients).Fig. 7.1:4 is the current in the resonant inductor, 2 is the lampvoltage, 3 is the voltage in pin VCOFig. 7.2:4 is the current in the resonant inductor, 2 is pin VS (HB Voltage), 3 is pin LO7.2. Open Filaments ProtectionThe open filament protection relies on the non-ZVS circuit of the IR2520D, enabled when pin VCO reaches 4.6V. Should an open filament lamp fault occur, hard-switching will occur at the half-bridge and the non-ZVS circuit inside the IR2520 will detect this condition, increase the frequency each cycle and shut down when VCO decreases below 1V; both gate driver outputs will be latched ‘low’. This will prevent hard-switching and damaging of the half-bridge MOSFET s.Fig. 7.3 shows the pin VCO and pin VS at the shut-down with open filament. As you can see, at startup pin VCO charges from 0V up to 4.6V, at 4.6V the non-ZVS circuit is enabled, CVCO discharges and the frequency increases. When the voltage on pin VCO decreases below 1V we have latched shutdown.78AN1062Fig. 7.4 shows pin VCO and pin VS (HB Voltage) at the shutdown with a shorter time scale. The FMIN pin can be used as trigger as this pin transitions from 5V to COM when the IC enters fault mode orUVLO-.Fig. 7.3:3 is the voltage in pin VCO and 2 is pin VSFig. 7.4:1 is the voltage in pin FMIN, 3 is the voltage in pin VCO,2 is pin VS7.3. Low AC line ProtectionAs you can see from figure 7.5, varying the AC line from 220V to 130VAC the ZVMCS circuit of the IR2520increases automatically the frequency to maintain ZVS.When the mains voltage decreases, the resonant frequency increases, becoming close to the run frequency. This will cause non-ZVS. The IR2520will detect non-ZVS and increase the frequency continuously as long as non-ZVS is detected. This will protect the half-bridge MOSFETs against hard-switching. 9AN1062Figure 7.5:VS PIN for AC line 220V (on the top) and AC line 130V (on the bottom)8. MINIBALLAST LayoutThe Layout of the Reference Kit MINIBALLAST1 is shown in Fig. 8.1.The critical components are CVCC, CVCO, RFMIN and CBOOT. They must be placed as close as possible to the pins of the IR2520D. The ground of CCVO, RFMIN and CVCC need to be connected to pin COM of the IR2520D and this ground pathmust be connected to the power ground at a single point10AN1062Figure 8.1: MINIBALLAST1 Layout 11AN10629. Design Tip: Auto-restart OptionThe design can be modified to include re-lamp/auto-restart option as shown in Fig. 9.1.The resistors Rsupply must be moved across the upper lamp filament and the lamp connected to the bus voltage, instead than to ground. When the lampFig. 9.1: Circuit Modification to include auto-restart optionis replaced, Rsupply together with the upper filament of the lamp provide a path from the DC bus to supply the micro-power current to the IR2520 and to restart the IR2520 as soon as VCC exceeds the UVLO+threshold. Rsupply need to be able to handle high voltage. If using SMD components, 2 resistors are needed.12AN106210. Design Procedure to adapt the design to different lamps typesThe design with the IR2520D is very simple because it only has 2 control pins: VCO (0-5VDC oscillator voltage input) and FMIN (minimum frequency set-ting). To modify the design for a higher lamp power,you will need to modify RFMIN, CVCO, LRES and CRES. Make sure that FET s and inductors are rated to the current you need with the new lamp and that VCC is stable. To modify the design to a lower lamp power, you will need to decrease RFMIN and only in some case to modify also CVCO, LRES and CRES.In most cases you can use FET s and inductors with lower current ratings.Pin FMIN is connected to ground through a resistor (RFMIN). The value of this resistor programs the mini-mum frequency (fmin) of the IC and the starting fre-quency of the IC (2.5xfmin). The IR2520 will work in run mode at the minimum frequency unless non-ZVS is detected. Generally, to work with constant fre-quency, the minimum frequency needs to be chosen above the resonant frequency of the low-Q R-C-L circuit. In this case, one can increase the value of RFMIN to decrease the frequency and increase the lamp power, or, decrease the value of RFMIN to in-crease the run frequency and decrease the lamp power.Pin VCO is connected to ground through a capacitor (CVCO). The value of this capacitor programs the time the frequency needs to ramp down from 2.5times fmin (fmax) to fmin.One can increase the capacitor value to increase the preheat time, or, decrease the capacitor value to de-crease the preheat time.The suggested design procedure is as follows:1)Use the BDA software to calculate LRESand CRES.Select the input configuration without PFC,select the IR2156 IC and select single lamp current mode configuration. Select the new lamp in the database or add the lamp pa rameters by hand selecting the “Advanced”option.Calculate the operating point and chose the right values of L and C that satisfy:1.1)Run frequency (best working range) 40-50KHz 1.2) C as small as possible to minimizelosses (suggested value 4.7nF)1.3)L values you have available2)While measuring LO, apply 15V from pinVCC to pin COM and adjust the value of RFMIN to obtain the right minimum fre-quency (it is suggested set fmin = run fre-quency obtained with the BDA software).Increase RFMIN to decrease the minimum frequency or decrease RFMIN to increase the minimum frequency.3)Apply the AC input and check preheat, igni-tion and run states of the lamp.3.1) If the lamp ignites during preheat, the preheat current is too small or the starting volt age across the lamp is too big, increase the value of CRES to decrease the voltage across the lamp during preheat and startup while increasing the preheat current. LRES may need to be decreased to maintain the same power and the same frequency.3.2) If the IC works at a frequency > fmin, increase CRES or LRES to decrease the reso nant frequency avoiding hard-switching, or,decrease the value of the snubber capaci tor CSNUBBER (a CSNUBBER minimum value of 680pF is suggested to make sure VCC stays above the UVLO-).AN1062 3.3) If VCC drops, increase the value ofCSNUBBER or CVCC4)Adjust the value of RFMIN to have the rightpower on the lamp (increase RFMIN to in-crease power or decrease RFMIN to de-crease power) and the value of CVCO to setthe correct preheat time (increase CVCO toincrease the preheat time and decreaseCVCO to decrease the preheat time).5)Test the ballast over the entire input rangeand make sure that the frequency does notchange dramatically in your working range.Select the value of RSUPPLY to have startupat the correct AC line voltage. Increase thevalue of RSUPPLY to start the IC at higherAC voltages and decrease the value ofRSUPPLY to start the IC at lower AC volt-ages.6)Test your lamp life (number of starts). A gooddesign should guarantee at least 5,000starts. To increase the number of starts, in-crease CRES or the preheat time (CVCO)WORLD HEADQUARTERS:233 Kansas St., El Segundo, California 90245 Tel: (310) 252-7105/ Data and specifications subject to change without notice. 3/2/200413。

Dell UltraSharp 25 USB-C 显示器 - U2520D/U2520DR用户指南管制型号：U2520D/U2520DR注： “注”表示可以帮助您更好使用计算机的重要信息。

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2020 - 01Rev. A00目录关于本显示器. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6包装物品 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6产品特性 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8识别零部件及控制装置. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9正视图 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9后视图 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10侧视图 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11底视图 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .12显示器规格 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14分辨率规格 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15支持的视频模式 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .16预设显示模式. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .16多串流传输 (MST) 模式 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .17电气规格 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .17实际特性 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .17环境特性 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .19电源管理模式. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20针脚分配 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .21 HDMI 连接器 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23即插即用功能. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24通用串行总线 (USB) 接口 . . . . . . . . . . . . . . . . . . . . . . . . . 24 USB 3.0 下游连接器. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 USB Type-C连接器. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 USB 端口. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26液晶显示器质量和像素规定 . . . . . . . . . . . . . . . . . . . . . . . . 26维护指导 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26清洁显示器. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26│3设置显示器 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .27连接支架 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27连接显示器 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30连接 DisplayPort（DisplayPort 转 DisplayPort）电缆（适用于U2520D） . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30连接 HDMI 电缆（适用于 U2520DR）. . . . . . . . . . . . . . . . . . . . . . . 31连接 USB Type-C电缆 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32连接显示器应用 DP 多串流传输 (MST) 功能 . . . . . . . . . . . . . . . . . . 32连接显示器应用 USB-C 多串流传输 (MST) 功能 . . . . . . . . . . . . . . . 33整理电缆 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33卸下显示器支架. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 VESA 壁挂安装（选配） . . . . . . . . . . . . . . . . . . . . . . . . . . 34操作显示器 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36打开显示器电源. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36使用前面板控制部件 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36前面板按钮 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37使用屏幕显示 (OSD) 菜单 . . . . . . . . . . . . . . . . . . . . . . . . . 38访问菜单系统 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38 OSD 警告信息. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .50设置最大分辨率. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53查看或播放 HDR 内容的要求 . . . . . . . . . . . . . . . . . . . . . . . 54使用倾斜、旋转和垂直展开功能. . . . . . . . . . . . . . . . . . . . . 55倾斜、旋转 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .55垂直展开. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .55旋转显示器 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56顺时针旋转 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .56逆时针旋转 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57调节系统的旋转显示设置 . . . . . . . . . . . . . . . . . . . . . . . . . . 57故障排除 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 58自检. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 584 │内置诊断功能. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59始终开启 USB Type-C 充电 . . . . . . . . . . . . . . . . . . . . . . . . 60常见问题 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 60产品特定问题. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62通用串行总线 (USB)特定问题. . . . . . . . . . . . . . . . . . . . . . 63附录. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65 FCC 声明（仅针对美国）和其它管制信息 . . . . . . . . . . . . . 65中国能源效率标识 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65电器电子产品有害物质限制使用要求 . . . . . . . . . . . . . . . . . 65联系 Dell . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 66│5关于本显示器包装物品您的显示器配有下表中的部件。

International Rectifier Xi’an Application Center94 Zhuque St. Xi’an 710061, Tel: 29-85215553 Fax:29-85389151采用IR2520D控制集成电路，具有功率因数校正的55W紧凑型节能灯镇流器IR2520D For 55W CFL Ballast With Passive PFCHanjie Yin 一、概述(Abstract)该演示板针对的是220V交流输入的55W紧凑型荧光灯（CFL）。

该电路具有灯的所有必须功能，如预热、触发、运行和保护功能，电路以IR公司CFL镇流器控制集成电路IR2520D为基础，并结合无源功率因数校正技术，改善镇流器输入功率因数，降低其电流谐波含量。

功能如下：预热时间可调，可调运行频率以设置灯功率，可以避免灯闪烁的高启始频率的软启动，灯丝开路和触发失败时故障保护，低线电压输入保护及电压升高后自动重启动。

IR2520D 是一个低成本方案，特别适合于CFL应用。

IR2520D 仅有8个管脚。

二、特点(Features)• 运行频率可调• 预热时间可调• 灯丝开路和无灯保护• 触发失败和无效灯保护• 输入交流线电压过低保护三、技术参数(Specification)• 输入功率：55W （220V交流输入）• 输入电流：255mA（220V交流输入）• 起始频率：112KHz• 运行频率：44.6KHz• 启动电压：170VAC• 关断电压：110VAC• 灯的类型：4U（55W）四、电路功能描述(Description of circuit functions)镇流器的组成分为四个部分：输入EMI滤波器、整流器、无源PFC校正电路和镇流器控制电路。

C1、L1、L2和C3组成的滤波器是必须的且要满足对EMI的需求。

D1、D2、D3、C5、C7和R2组成无源功率因数校正电路可以使输入功率因数提升到0.93以上。

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自适应电子镇流器控制器IR2520类别：传感与控制阅读：988IR2520是国际整流器公司生产的自适应CFL(小型荧光灯）照明镇流器控制芯片，可使镇流器的组件数量减少20%，与传统的电子镇流器设计相比，可提高镇流器的可靠性，并可补偿由于温度和老化而引起的电灯特性变化。

（1）特性IR2520依靠经过整流的线路电压来工作，并为600 V半桥提供栅极驱动。

600 V半桥通过一个简单的谐振LC网络为灯管供电。

IR2520能自我启动，并能防范灯丝烧断和灯管放电故障。

IR2520的主要特点如下：集成有600 V的半桥驱动器、高压自举二极管及15.6 V的齐纳钳位二极管；内置0-5 V直流电压控制振荡器；具有波峰因数检测过电流保护功能，可省去外部电流感测电阻；最小频率及正常工作时的工作频率均可编程；启动电流很小（只有150μA）。

(2)内部电路与引脚功能IR2520有8脚PDIP封装（IR2520D）和8脚SOIL封装（IR2520S）两种封装形式。

其内部电路框图如图所示，各引脚功能见下表.(3)应用电路IR2520已在芯片内集成了自适应镇流器控制器和600 V半桥驱动器，既不需要变压器，也不需要PTC热敏电阻，从而使采用它的镇流器具有体积小、发热量少的优点，因而可方便地驱动30 W以下的紧凑型荧光灯（俗称节能灯）。

由IR2520组成的紧凑型荧光灯电子镇流器电路框图如图所示。

该镇流器的输人电压范围为180--270 V，输出端可配接7-35 W的灯管。

当图中的启动电路工作时，流过启动电阻RSUPPLY的电流将对启动电容CVCC进行充电，并使CVCC上的电压逐渐升高。

在1脚电压达到启动门限电平13.2 V之前，3脚和4脚上的电压均为OV，半桥截止。

一旦1脚上的电压超过13 ．2V，IR2520将导通并开始振荡。

此时，IR2520内部的电流源将对4脚外部电容CVCO充电，从而使4脚上的电压从OV 线性增加，同时使内部压控振荡器的振荡频率从最大值开始线性降低。

第2章紧凑型荧光灯控制驱动ICP=C5×V DC2×f0/2(W) 假如C5=1nF、V DC=310V、f0=50kHz，可以算出P≈2.4W。

对于FAN7710来说，这样大的功耗，如果不采取预防措施，IC有可能损坏，而且在容性负载下的硬开关状态，还会引起较大的电磁干扰。

FAN7710遇到这种情况会减小C PH上的电压，以增加死区时间。

如果V CPH电压降到2.6V以下，仍达不到ZVS要求，FAN7710将自动关断，以免IC损坏。

要重新启动IC，必须将V DD电压降到关闭门限以下，使内部的锁存器复位，然后再提高V DD电压才行。

另外，FAN7710能检测IC的结温，如其温度超过160˚C，FAN7710内部的热关断线路会自动让IC停止工作。

通过上述分析可以看出，FAN7710比UBA2024的保护功能更多、更强，驱动能力更大，可以用来做20W以下的荧光灯，而无须外接半桥功率管。

如采用贴片元件，并用贴片机、回流焊等工艺，可以大大简化紧凑型荧光灯的装配工艺，并提高紧凑型荧光灯的质量水平。

在下一节将要介绍IR2520D，它的驱动功率较大，可以用在25～30W的节能灯或电子镇流器中，不过它需要外接半桥功率开关管，这是它不及FAN7710的地方。

2.4 自振荡镇流器控制器IR2520D美国国际整流器公司（IR公司）新近推出了一种适用于电子镇流器的控制器芯片IR2520D。

它可以装在紧凑型荧光灯中，也可以装在小型电子镇流器里，用来驱动管形荧光灯或紧凑型荧光灯。

它集中了预热、触发、驱动灯管，并使之正常工作所必需的一切功能。

另外，它还有异常状态保护功能，如灯管异常、灯管故障保护、电源电压低保护等。

其电路结构紧凑，所用外围元器件数目不多，IC仅有8脚，占面积小，有双列直插及表面贴装2种封装形式。

它比前面介绍的UBA2024、FAN7710的驱动能力和保护能力更强。

这种产品主要用来驱动18～30W的荧光灯管，管形可以是直管、环形、螺旋形或紧凑型。

Dell Vostro 2520 用户手册管制型号： P18F管制类型： P18F0032注、小心和警告备注: “注”表示可以帮助您更好地使用计算机的重要信息。

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第1章有关电子镇流器IC的基础知识470pF；如电源电压为AC 120V，C4的值可取为1nF。

C4的取值大小会影响它为V CC提供电流的大小，电容大，提供的电流也大，即I C4=C4×V DC×f0例如，V DC=300V，电路工作的开关频率f0=45kHz，C4=470pF，则I C4=470×10−12×300×45×103≈6.35(mA)当然，电容C4的值也不能取得太大，因为这会影响半桥电路开关管的转换速率和管子的零电压开关（ZVS）情况，如其值选得过大，会因非零电压开关而使管子过热或损坏。

IR2520D的高端驱动器的低压电源是这样得到的：在V CC（1脚）与V B（8脚）之间，在IC内部集成有FET管，称为自举FET（或称为充电泵FET），由IC内部逻辑控制，使它与半桥电路下管VT2同时导通；有的IC不用FET，而采用自举二极管；也有的IC内部根本没有集成自举二极管或FET，这时，就必须在IC的1、8脚之间外接一个快速的开关二极管。

当VT2导通而VT1截止时，V CC通过自举FET（或自举二极管，如后面图1-5中的VD1）及导通的VT2对电容C BS充电，如果忽略FET及VT2的微小导通压降，C BS上的充电电压基本上等于V CC。

当VT1导通而VT2截止时，自举FET也不导通。

如为自举二极管，则被反偏。

C BS上的电荷不会被泄放，保持稳定不变，这样C BS上的电压可以看成一个等于V CC的稳定电源，它浮置在VT1的源极、VT2的漏极之上，接在IC的6、8脚之间，作为IC内部高端驱动器的电源，由它输出驱动信号，驱动半桥逆变电路的上管VT1栅极。

大多数镇流器控制器IC普遍采用这种自举供电方式。

熟悉了它的工作之后，在后面所要介绍的镇流器芯片里提到供电方式时，将不再过多介绍。

上面的2种方法中，都是由高频能量提供V CC以电流，无须再由启动电阻R1向高压直流电源支取电流，R1可采用阻值较大而瓦数较小的电阻，从而可以减小其损耗及发热。