CDBB1100中文资料

Silicon Schottky Diode ChipsFeaturesI For Detector and Mixer Applications I Low Capacitance for Usage Beyond 40 GHz I ZBD and Low Barrier Designs I P-Type and N-Type Junctions I Large Bond Pad Chip DesignDescriptionAlpha’s product line of silicon Schottky diode chips are intended for use as detector and mixer devices in hybrid integrated circuits at frequencies from below 100 MHz to higher than 40 GHz.Alpha’s “Universal Chip”design features a 4 mil diameter bond pad that is offset from the semiconductor junction preventing damage to the active junction as a result of wire bonding.As power-sensing detectors, these Schottky diode chips all have the same voltage sensitivity so long as the output video impedance is much higher than the video resistance of the diode.Figure 1 shows the expected detected voltage sensitivity as a function of RF source impedance in an untuned circuit.Note that sensitivity is substantially increased by transforming the source impedance from 50 Ωto higher values.Maximum sensitivity occurs when the source impedance equals thevideo resistance.Electrical Specifications at 25°CJunction C J 1R T 2V F @ 1 mA V B 3R V @ Zero BiasOutline Part Number Barrier Type(pF)(Ω)(mV)(V)(k Ω)Drawing Max.Max.Min.–Max.Min.Typ.CDC7630-000ZBD P 0.2530135–2401 5.5526-006CDC7631-000ZBD P 0.1580150–30027.2526-006CDB7619-000Low P 0.1040275–3752735526-006CDB7620-000Low P 0.1530250–3502537526-006CDF7621-000Low N 0.1020270–3502680526-011CDF7623-000LowN0.3010240–3002245526-0111.C J for low barrier diodes specified at 0 V .C J for ZBDs specified at 0.15 V reverse bias.2.R T is the slope resistance at 10 mA.R S Max.may be calculated from:R S = R T - 2.6 x N.3.V B for low barrier diodes is specified at 10 µA.V B for ZBDs is specified at 100 µA.In a detector circuit operating at zero bias, depending on the video load impedance, a ZBD device with R V less than 10 k Ωmay be more sensitive than a low barrier diode with R V greater than 100 k Ω.Applying forward bias reduces the diode video resistance as shown in Figure 2.Lower video resistance also increases the video bandwidth but does not increase voltage sensitivity, as shown in Figure 3.Biased Schottky diodes have better temperature stability and also may be used in temperature compensated detector circuits.P-type Schottky diodes generate lower 1/F noise and are preferred for Doppler mixers and biased detector applications.The bond pad for the P-type Schottky diode is the cathode.N-type Schottky diodes have lower parasitic resistance, R S , and will perform with lower conversion loss in mixer circuits.The bond pad for the N-type Schottky diode is the anode.SPICE Model ParametersParameterCDB7619CDB7620CDF7621CDF7623CDC7630CDC7631Units IS 3.70E-085.40E-08 4.0E-08 1.1E-07 5.0E-06 3.8E-06A R S 9141262051ΩN 1.05 1.12 1.05 1.04 1.05 1.05TT 1E-111E-111E-111E-111E-111E-11S C J00.080.150.100.220.140.08pF M 0.350.350.350.320.400.4E G 0.690.690.690.690.690.69eV XTI 2.0 2.0 2.0 2.0 2.0 2.0F C 0.50.50.50.50.50.5B V 2.0 4.0 3.0 2.0 2.0 2.0V I BV1.00E-05 1.00E-05 1.0E-05 1.0E-05 1.0E-04 1.0E-04A V J0.4950.4950.4950.4950.3400.340V 0.1110100100010000-40-30-20-10010Input Power (dBm)D e t e c t e d V o l t a g e(m V )Typical Performance Data100100010000100000110100Forward Bias (µA)V i d e o R e s i s ta n c e (Ω)RF SOURCE IMPEDANCEDETECTOR VOLTAGEVIDEO LOAD IMPEDANCEZero Biased DetectorRF SOURCE IMPEDANCEVOLTAGE IMPEDANCEBiased Detector0.0010.010.11101001000100000.0010.010.1110Forward Current (mA)D e t e c t e d V o l t a g e (m V )Figure 1.Detected Voltage vs.Input Power and RF Source ImpedanceFigure 3.Detected Voltage vs.Forward CurrentFigure 2.Video Resistance vs.Forward Bias CurrentCharacteristicValue Reverse Voltage (V R )Voltage RatingForward Current (I F )50 mA Power Dissipation (P D )75 mW Storage T emperature (T ST )-65°C to +150°C Operating Temperature (T OP)-65°C to +150°CAbsolute Maximum Ratings0.015 (0.38 mm)–0.0065 (0.165 mm)526-006 = Cathode bond pad.526-011 = Anode bond pad.Outline Drawing526-006, 526-011。

目 录CONTENT12 11注：只有符合RoHS的物料才符合CE认证。

14 13注：只有符合RoHS的物料才符合CE认证。

1615备注：1.仅CDBX 产品编码中极数编码5代表1P+N 产品；2.CDBXP 产品全部为1P+N 产品，产品编码中极数代码缺省；■ 产品说明短路保护、过载保护、隔离功能■主要功能额定工作电压（V ）1P ：230/400 、240/415AC 1P+N ：230/240 AC 2P,3P,3P+N,4P ：400/415 AC 额定电流（A ）1,2,3,4,5,6,8,10,13,16,20,25,32,40,50,63额定频率（Hz ）50/60极数1P,1P+N,2P,3P,3P+N,4P 分断能力（kA ）6、10脱扣曲线B 、C 、D 型■ 主要特性GB/T 10963.1 ■ 符合标准■ 符合认证注：该产品可拼装附件OF,SD,MSN,MV,MN,MVMN,FF,FS,MO(有源型),MOWY(无源型)■ 电气特性额定绝缘电压 Ui （V ）500额定工作电压Ue （V ） 1P （V ）230/400 AC 、240/415 AC 1P+N （V ）230/240 AC 2P ，3P ，4P ，3P+N （V ）400/415 AC 额定短路能力 Icn （IEC/EN 60898-1） （kA ）6、10额定冲击耐受电压 Uimp （1.2/50） （kV ）4 介电测试电压（kV ）2kV （50/60Hz,1分钟）隔离功能具备污染等级2脱扣形式热磁脱扣热磁脱扣特性B 型曲线（3ln~5ln ）■C 型曲线（5ln~10ln ）■D 型曲线（10ln~14ln ）■电气及机械附件■1817手柄红色，移印指示ON-OFF 位置机械寿命次20000电气寿命次12000防护等级安装于配电箱内:IP40直接安装:IP20抗机械冲击30g,3次冲击,持续时间11ms （无显著振动和冲击的地方）抗震动（IEC/EN 60068-2-6）无显著振动和冲击的地方抗湿热性（IEC 60068-2）湿热 ℃/RH 2类,28次循环,温度55℃时,相对湿度90%~96%温度25℃时,相对湿度95~100%基准环境温度 ℃30℃使用环境温度（日平均温度≤+35℃） ℃ -35℃~+70℃存储温度 ℃-40℃~+85℃■ 机械特性接线端子形式U 接线端子最大接线能力电流等级1-63A ：25mm 2最大极限扭矩电流等级1-63A ：2.5N.m 工具十字螺丝刀或者一字螺丝刀安装安装于标准DIN 导轨（35mm ）进线方式上下均可进线■ 安装特性■ 尺寸图■接线图1P3P4P2P1P+N3P+N 短路保护、过载保护、隔离功能■ 主要功能额定工作电压（V ）1P ：230/400 AC 1P+N ：230 AC 2P,3P,3P+N,4P ：400 AC 1P ：60V DC 2P ：125V DC 额定电流（A ）1-63额定频率（Hz ）50(仅限交流)极数1P,1P+N,2P,3P,3P+N,4P 分断能力（kA ）6■ 主要特性GB/T14048.2■ 符合标准■ 符合认证注：该产品可拼装附件OF,SD,MSN,MV,MN,MVMN,FF,FS,MO (有源型),MOWY(无源型)■ 电气特性额定绝缘电压 Ui （V ）500最大工作电压 Ubmax 1P ,1P+N （V ）230/400 AC 2P ，3P ，3P+N ，4P （V ）400 AC 1P （V ）60DC 2P （V ）125DC 额定短路能力 Icn （IEC/EN60898） （kA ）6额定冲击耐受电压 Uimp （1.2/50） （kV ）4 介电测试电压（kV ）2kV （50/60Hz,1分钟）使用类别A 隔离功能具备污染等级2脱扣形式热磁脱扣热磁脱扣特性Ii （B)型曲线4ln(AC)、5In(DC)■Ii （C)型曲线8ln(AC)、10In(DC)■Ii （D)型曲线12ln(AC)、15In(DC)■电气及机械附件■20191P 1P+N 3P 4P 2P3P+N1P 左视图1P 3P 1P+N ，2P 3P+N ，4P■ 尺寸图■ 接线图手柄红色，移印指示ON-OFF 位置机械寿命次20000电气寿命次10000防护等级安装于配电箱内:IP40直接安装:IP20抗机械冲击30g,3次冲击,持续时间11ms （无显著振动和冲击的地方）抗震动（IEC/EN 60068-2-6）无显著振动和冲击的地方抗湿热性（IEC 60068-2）湿热 ℃/RH 2类,28次循环,温度55℃时,相对湿度90%~96%温度25℃时,相对湿度95~100%基准环境温度 ℃30℃使用环境温度（日平均温度≤+35℃） ℃ -35℃~+70℃存储温度℃-40℃~+85℃■ 机械特性接线端子形式U 接线端子最大接线能力电流等级1-63：25mm 2最大极限扭矩电流等级1-63：2.5N.m 工具十字螺丝刀或者一字螺丝刀安装安装于标准DIN 导轨（35mm ）进线方式上下均可进线■ 安装特性短路保护、过载保护、漏电保护、隔离功能、过压保护（仅限于过压型号产品）■ 主要功能GB/T 16917.1 ■ 符合标准■符合认证额定工作电压（V ）1P+N,2P ：230 AC 3P,3P+N,4P ：400 AC 额定电流（A ）一般型：6~63S 型（延时型）：32~63额定频率（Hz ）50/60极数1P+N,2P,3P,3P+N,4P 分断能力（kA ）6、10脱扣曲线B 、C 、D 型额定剩余动作电流(mA)一般型：10(1P+N 、2P),30,50,75,100,300S 型（延时型）：50,75,100,300漏电脱扣时间一般型：t ≤0.1S S 型：0.13S ≤t ≤0.5S 漏电保护类型A 、AC 型过压保护功能(V)(280±14)VAC(仅适用于1P+N,2P)■ 主要特性 小体积，省空间：宽度整模数化，体积减小30%~50%，节约柜体空间及成本 大孔接线：25mm 2大孔接线，接线更便捷 规格齐全：增加A 型漏电保护、10kA 分断能力、漏电延时型及下进线规格，保护更全面，布线更灵活 快速闭合+放喷弧挡板设计：使用寿命更长久，分合闸操作更放心注：该产品可拼装附件：OF ，SD ，MSN ，MV ，MN ，MVMN ，FF ，FS ，MO （有源型），MOWY （无源型）22 21额定绝缘电压 Ui（V）500最大工作电压 Uemax （V）1P+N,2P：230 AC3P,3P+N,4P：400 AC额定短路能力 Icn（kA）6、10额定冲击耐受电压 Uimp（1.2/50）（kV） 4介电测试电压2kV（50/60HZ,1分钟)隔离功能具备(1P+N、3P+N不具备)漏电保护类型A、AC型污染等级2脱扣形式热磁脱扣热磁脱扣特性B型曲线(3ln~5ln)■C型曲线(5ln~10ln)■D型曲线(10ln~14ln)■电气及机械附件■■ 电气特性脱扣指示CDBXLES上有剩余电流动作脱扣指示，复位按钮弹起，为漏电脱扣手柄红色，机械寿命次20000电气寿命次10000防护等级安装于配电箱内IP40直接安装IP20抗机械冲击30g,3次冲击,持续时间11ms（无显著振动和冲击的地方）抗震动 (IEC/EN 60068-2-6)无显著振动和冲击的地方抗湿热性（IEC 60068-2）湿热℃/RH2类,28次循环,温度55℃时,相对湿度90%~96%温度25℃时,相对湿度95%~100%基准环境温度℃30℃使用环境温度（日平均温度≤+35℃） ℃-35℃~+70℃存储温度℃ -40℃~+85℃■ 机械特性接线端子形式U接线端子最大接线能力25mm2最大极限扭矩 2.5 N.m工具十字螺丝刀或者一字螺丝刀安装安装于标准DIN导轨（35mm）进线方式上进线（所有极数）；下进线（仅有1P+N/2P规格产品）■ 安装特性1P+N/2P■ 尺寸图1P+N3P+N4P2P3P■ 接线图■ 主要功能额定工作电压（V）230AC额定电流（A）6,10,16,20,25,32,40额定频率（Hz）50■ 主要特性GB/T 10963.1■ 符合标准■ 符合认证短路保护、过载保护、隔离功能极数1P+N分断能力（kA） 4.5、6注：该产品可拼装附件：OF，SD，MSN，MV，MN，MVMN，FF，FS，MO（有源型），MOWY（无源型）2423额定绝缘电压 Ui （V ）500额定电压Ue （V ）（V ）230额定短路能力 Icn （IEC/EN60898-1）（kA ） 4.5、6额定冲击耐受电压 Uimp （1.2/50）（kV ） 4介电测试电压2kV （50HZ,1分钟)隔离功能具备污染等级2脱扣形式热磁脱扣热磁脱扣特性C 型曲线(5ln~10ln)■D 型曲线(10ln~14ln)■电气及机械附件■■ 电气特性手柄红色，移印指示ON-OFF 位置机械寿命次20000电气寿命次10000防护等级安装于配电箱内:IP40直接安装:IP20抗机械冲击30g,3次冲击,持续时间11ms （无显著振动和冲击的地方）抗震动（IEC/EN 60068-2-6）无显著振动和冲击的地方抗湿热性（IEC 60068-2）湿热℃/RH2类,28次循环,温度55℃时,相对湿度90%~96%温度25℃时,相对湿度95~100%基准环境温度℃30℃使用环境温度（日平均温度≤+35℃） ℃ -35℃~+70℃存储温度℃-40℃~+85℃■ 机械特性接线端子形式U 接线端子最大接线能力电流等级6-40：10mm 2最大极限扭矩电流等级6-40：2 N.m工具十字螺丝刀或者一字螺丝刀安装安装于标准DIN 导轨（35mm ）进线方式上下均可进线■ 安装特性1P+N■ 接线图■ 主要功能额定工作电压（V ）1P ,1P+N ：230/240AC 、80DC2P,3P,3P+N,4P ：400/415 AC （2P ：125 DC ）额定电流（A ）63-125额定频率（Hz ）50/60极数1P ,1P+N,2P ,3P ,3P+N,4P 分断能力（kA ）10■ 主要特性GB/T 14048.2■ 符合标准短路保护、过载保护、隔离功能■符合认证注：该产品可拼装附件 OF ，SD ，MO ，MV ，MN ，MVMN2625额定绝缘电压 Ui（V ）500额定工作电压Ue（V ）1P ，1P+N ：230/240 AC 、80 DC2P ，3P ，3P+N ，4P ：400/415 AC （2P ：125 DC ）额定短路能力Icn （IEC/EN60898-1）（kA ）10额定冲击耐受电压 Uimp （1.2/50）（kV ）4 介电测试电压2kV（50HZ,1分钟)隔离功能具备污染等级2脱扣形式热磁脱扣热磁脱扣特性C 型曲线(5ln~10ln)■D 型曲线(10ln~14ln)■电气及机械附件■■ 电气特性接线端子形式U 接线端子最大接线能力电流等级63-125：50mm 2最大极限扭矩电流等级63-125：3.5N.m工具十字螺丝刀或者一字螺丝刀安装安装于标准DIN 导轨（35mm ）进线方式上下均可进线■ 安装特性■ 机械特性手柄红色触头指示通过红绿色指示产品的通断机械寿命次20000电气寿命次6000次（In ≤100A ）4000次（In>100A ）防护等级安装于配电箱内IP40直接安装IP20抗机械冲击30g,3次冲击,持续时间11ms （无显著振动和冲击的地方）抗震动 (IEC/EN 60068-2-6)无显著振动和冲击的地方抗湿热性（IEC 60068-2）湿热 ℃/RH2类,28次循环,温度55℃时,相对湿度90%~96%温度25℃时,相对湿度95%~100%基准环境温度℃30℃使用环境温度（日平均温度≤+35℃） ℃-35℃~+70℃存储温度℃ -40℃~+85℃■ 接线图1P3P4P2P1P+N3P+N2827■ 主要功能额定工作电压（V ）1P+N,2P ：230/240AC3P,3P+N,4P ：400/415AC额定电流（A ）63-125额定频率（Hz ）50/60极数1P+N,2P ,3P ,3P+N,4P■ 主要特性GB/T 14048.2■ 符合标准■ 符合认证短路保护、过载保护、漏电保护、隔离功能、过压保护分断能力（kA ）10额定剩余动作电流（mA ）30,50,75,100,300漏电动作时间t ≤0.1s过压保护功能（V ）（280±14）AC(仅适用于1P+N 、2P D 型产品，I △n=30mA)注： 该产品可拼装附件 OF ，SD额定绝缘电压 Ui（V ）500额定工作电压Ue（V ）1P+N,2P ：230/240 AC 3P ,3P+N,4P ：400/415 AC额定短路能力Icu （IEC/EN60898）（kA ）10额定冲击耐受电压 Uimp （1.2/50）（kV ）4 介电测试电压2kV （50HZ,1分钟)隔离功能具备漏电保护类型A 、AC 型污染等级2脱扣形式热磁脱扣热磁脱扣特性C 型曲线(5ln~10ln)■D 型曲线(10ln~14ln)■电气及机械附件■■ 电气特性接线端子形式U 接线端子最大接线能力电流等级63-125：50mm 2最大极限扭矩电流等级63-125：3.5N.m工具十字螺丝刀或者一字螺丝刀安装安装于标准DIN 导轨（35mm ）进线方式上进线■ 安装特性■ 机械特性脱扣指示CDBXLE-125上有剩余电流动作脱扣指示，复位按钮弹起，为漏电脱扣手动控制过电流故障给断路器手柄合闸漏电故障剩余电流动作装置先复位，断路器后复位手柄红色，移印指示ON-OFF 位置机械寿命次20000电气寿命次6000次（In ≤100A ）4000次（In>100A ）防护等级安装于配电箱内IP40直接安装IP20抗机械冲击30g,3次冲击,持续时间11ms （无显著振动和冲击的地方）抗震动 (IEC/EN 60068-2-6)无显著振动和冲击的地方抗湿热性（IEC 60068-2）湿热 ℃/RH2类,28次循环,温度55℃时,相对湿度90%~96%温度25℃时,相对湿度95%~100%基准环境温度℃30℃使用环境温度（日平均温度≤+35℃） ℃-35℃~+70℃存储温度℃ -40℃~+85℃1P+N 2P1P+N右视图30293P3PN■ 接线图4P3P+N1P+N3P2P■ 主要功能额定电压（V ）1P DC250V ；2P/3P DC500V额定电流（A ）1,2,3,4,5,6,8,10,13,16,20,25,32,40,50,63A （B 型无1-6A ）极数1P/2P/3P 分断能力（kA ）6■ 主要特性短路保护、过载保护、隔离、控制GB/T 14048.2■ 符合标准■ 符合认证注：该产品可拼装附件OF,SD,MSN,MV,MN,MVMN,FF,FS,MO (有源型),MOWY(无源型)■ 机械特性机械寿命次20000电气寿命次10000环境使用温度℃-35℃~70℃3231■33机械寿命次10000电气寿命次3000防护等级安装于配电箱内IP40直接安装IP20抗机械冲击30g,3次冲击,持续时间11ms （无显著振动和冲击的地方）抗震动 (IEC/EN 60068-2-6)无显著振动和冲击的地方抗湿热性（IEC 60068-2）湿热℃/RH2类,28次循环,温度55℃时,相对湿度90%~96%温度25℃时,相对湿度95%~100%基准环境温度℃30℃使用环境温度（日平均温度≤+35℃） ℃-35℃~+70℃存储温度℃ -40℃~+85℃■ 机械特性接线端子形式隧道式接线端子最大接线能力 3.5N.m 最大极限扭矩50mm 2工具十字螺丝刀或者一字螺丝刀安装安装于标准DIN 导轨（35mm ）进线方式上下进线均可■ 安装特性1P2P1P2P4P35■ 主要功能主要包含如 MO （分励脱扣）、OF （辅助触头）、SD （报警触头）、MSN（失压保护）等多类型附件GB/T 14048.1GB/T 14048.5■ 符合标准■ 符合认证品类齐全可靠稳定。

元器件交易网ChipconSmartRF ® CC1100CC1100 Single Chip Low Cost Low Power RF-TransceiverApplications• Ultra low power UHF wireless transceivers • 315/433/868 and 915MHz ISM/SRD band systems • AMR – Automatic Meter Reading • Consumer Electronics • RKE – Two-way Remote Keyless Entry • • • • • Low power telemetry Home and building automation Wireless alarm and security systems Industrial monitoring and control Wireless sensor networksProduct DescriptionThe CC1100 is a low cost true single chip UHF transceiver designed for very low power wireless applications. The circuit is mainly intended for the ISM (Industrial, Scientific and Medical) and SRD (Short Range Device) frequency bands at 315, 433, 868 and 915MHz, but can easily be programmed for operation at other frequencies in the 300348MHz, 400-464MHz and 800-928MHz bands. The RF transceiver is integrated with a highly configurable baseband modem. The modem supports various modulation formats and has a configurable data rate up to 500kbps. Performance can be increased by enabling a Forward Error Correction option, which is integrated in the modem. microcontroller and a few additional passive components.CC1100 is based on Chipcon’s SmartRF®04technology in 0.18µm CMOS.CC1100 provides extensive hardware support for packet handling, data buffering, burst transmissions, clear channel assessment, link quality indication and wake on radio.The main operating parameters and the 64byte transmit/receive FIFOs of CC1100 can be controlled via an SPI interface. In a typical system, the CC1100 will be used together with aKey Features• • • • • • • • Small size (QLP 4x4mm package, 20 pins) True single chip UHF RF transceiver Frequency bands: 300-348MHz, 400464MHz and 800-928MHz High sensitivity (–110dBm at 1.2kbps, 1% packet error rate) Programmable data rate up to 500kbps Low current consumption (15.6mA in RX, 2.4kbps, 433MHz) Programmable output power up to +10dBm for all supported frequencies Excellent receiver selectivity and blocking performance • • • • • • • • Very few external components: Totally onchip frequency synthesizer, no external filters or RF switch needed Programmable baseband modem Ideal for multi-channel operation Configurable packet handling hardware Suitable for frequency hopping systems due to a fast settling frequency synthesizer Optional Forward Error Correction with interleaving Separate 64-byte RX and TX data FIFOs Efficient SPI interface: All registers can be programmed with one “burst” transferChipcon ASSmartRF® CC1100 Preliminary Data Sheet (rev. 1.0) 2005-04-25Page 1 of 68元器件交易网ChipconFeatures (continued from front page)• • • • • • • Digital RSSI output Suited for systems compliant with EN 300 220 (Europe) and FCC CFR Part 15 (US) Wake-on-radio functionality for automatic low-power RX polling Many powerful digital features allow a high-performance RF system to be made using an inexpensive microcontroller Integrated analog temperature sensor Lead-free “green“ package Flexible support for packet oriented systems: On chip support for sync word detection, address check, flexible packet length and automatic CRC handling. Programmable channel filter bandwidth OOK and flexible ASK shaping supported 2-FSK, GFSK and MSK supported. Automatic Frequency Compensation can be used to align the frequency synthesizer to the received centre frequencySmartRF ® CC1100• • Optional automatic whitening and dewhitening of data Support for asynchronous transparent receive/transmit mode for backwards compatibility with existing radio communication protocols Programmable Carrier Sense indicator Programmable Preamble Quality Indicator for detecting preambles and improved protection against sync word detection in random noise Support for automatic Clear Channel Assessment (CCA) before transmitting (for listen-before-talk systems) Support for per-package Link Quality Indication• •• •• • • •AbbreviationsAbbreviations used in this data sheet are described below.2-FSK ADC AFC AGC AMR ASK BER CCA CRC CS DC EIRP ESR FEC FIFO FSK GFSK IF LBT LNA LO LQI MCU Binary Frequency Shift Keying Analog to Digital Converter Automatic Frequency Offset Compensation Automatic Gain Control Automatic Meter Reading Amplitude Shift Keying Bit Error Rate Clear Channel Assessment Cyclic Redundancy Check Carrier Sense Direct Current Equivalent Isotropic Radiated Power Equivalent Series Resistance Forward Error Correction First-In-First-Out Frequency Shift Keying Gaussian shaped Frequency Shift Keying Intermediate Frequency Listen Before Transmit Low Noise Amplifier Local Oscillator Link Quality Indicator Microcontroller Unit MSK PA PCB PD PER PLL PQI PQT RCOSC RF RSSI RX SAW SNR SPI TBD TX VCO WOR XOSC XTAL Minimum Shift Keying Power Amplifier Printed Circuit Board Power Down Packet Error Rate Phase Locked Loop Preamble Quality Indicator Preamble Quality Threshold RC Oscillator Radio Frequency Received Signal Strength Indicator Receive, Receive Mode Surface Aqustic Wave Signal to Noise Ratio Serial Peripheral Interface To Be Defined Transmit, Transmit Mode Voltage Controlled Oscillator Wake on Radio, Low power polling Crystal Oscillator CrystalChipcon ASSmartRF® CC1100 Preliminary Data Sheet (rev. 1.0) 2005-04-25Page 2 of 68元器件交易网ChipconTable Of Contents1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 18.1 18.2 18.3 18.4 18.5 19 19.1 19.2 19.3 20 21 22 22.1 22.2 22.3 23 23.1 23.2 23.3 23.4 23.5 24 24.1 24.2 24.3 25 25.1 25.2 25.3 25.4 25.5 26 26.1 26.2 27 27.1SmartRF ® CC1100ABSOLUTE MAXIMUM RATINGS ...........................................................................................................5 OPERATING CONDITIONS ......................................................................................................................5 ELECTRICAL SPECIFICATIONS ...............................................................................................................6 GENERAL CHARACTERISTICS ...............................................................................................................7 RF RECEIVE SECTION...........................................................................................................................8 RF TRANSMIT SECTION ........................................................................................................................9 CRYSTAL OSCILLATOR .........................................................................................................................9 LOW POWER RC OSCILLATOR............................................................................................................10 FREQUENCY SYNTHESIZER CHARACTERISTICS ...................................................................................10 ANALOG TEMPERATURE SENSOR ........................................................................................................11 DC CHARACTERISTICS .......................................................................................................................11 POWER ON RESET...............................................................................................................................12 PIN CONFIGURATION ..........................................................................................................................12 CIRCUIT DESCRIPTION ........................................................................................................................14 APPLICATION CIRCUIT ........................................................................................................................14 CONFIGURATION OVERVIEW ..............................................................................................................16 CONFIGURATION SOFTWARE ..............................................................................................................17 4-WIRE SERIAL CONFIGURATION AND DATA INTERFACE ...................................................................18 CHIP STATUS BYTE ............................................................................................................................18 REGISTER ACCESS ..............................................................................................................................19 COMMAND STROBES ..........................................................................................................................19 FIFO ACCESS .....................................................................................................................................19 PATABLE ACCESS ............................................................................................................................19 MICROCONTROLLER INTERFACE AND PIN CONFIGURATION ...............................................................21 CONFIGURATION INTERFACE ..............................................................................................................21 GENERAL CONTROL AND STATUS PINS ..............................................................................................21 OPTIONAL RADIO CONTROL FEATURE .................................................................................................22 DATA RATE PROGRAMMING ...............................................................................................................22 RECEIVER CHANNEL FILTER BANDWIDTH..........................................................................................22 DEMODULATOR, SYMBOL SYNCHRONIZER AND DATA DECISION ......................................................23 FREQUENCY OFFSET COMPENSATION.................................................................................................23 BIT SYNCHRONIZATION ......................................................................................................................23 BYTE SYNCHRONIZATION ...................................................................................................................23 PACKET HANDLING HARDWARE SUPPORT .........................................................................................24 DATA WHITENING ...............................................................................................................................24 PACKET FORMAT ................................................................................................................................24 PACKET FILTERING IN RECEIVE MODE ...............................................................................................26 PACKET HANDLING IN TRANSMIT MODE ............................................................................................26 PACKET HANDLING IN RECEIVE MODE ..............................................................................................26 MODULATION FORMATS.....................................................................................................................27 FREQUENCY SHIFT KEYING ................................................................................................................27 MINIMUM SHIFT KEYING....................................................................................................................27 AMPLITUDE MODULATION .................................................................................................................27 RECEIVED SIGNAL QUALIFIERS AND LINK QUALITY INFORMATION ...................................................27 PREAMBLE QUALITY THRESHOLD (PQT) ...........................................................................................27 RSSI...................................................................................................................................................28 CARRIER SENSE (CS)..........................................................................................................................28 CLEAR CHANNEL ASSESSMENT (CCA) ..............................................................................................28 LINK QUALITY INDICATOR (LQI) .......................................................................................................28 FORWARD ERROR CORRECTION WITH INTERLEAVING ........................................................................29 FORWARD ERROR CORRECTION (FEC)...............................................................................................29 INTERLEAVING ...................................................................................................................................29 RADIO CONTROL ................................................................................................................................30 POWER ON START-UP SEQUENCE.........................................................................................................31Chipcon ASSmartRF® CC1100 Preliminary Data Sheet (rev. 1.0) 2005-04-25Page 3 of 68元器件交易网Chipcon27.2 27.3 27.4 27.5 27.6 27.7 28 29 30 30.1 31 32 33 34 35 36 36.1 36.2 37 37.1 37.2 37.3 38 38.1 38.2 38.3 38.4 38.5 39 40 40.1 40.2 40.3 40.4 40.5 41SmartRF ® CC1100CRYSTAL CONTROL ............................................................................................................................31 VOLTAGE REGULATOR CONTROL.......................................................................................................31 ACTIVE MODES ..................................................................................................................................31 WAKE ON RADIO (WOR) ...................................................................................................................32 TIMING ...............................................................................................................................................33 RX TERMINATION TIMER ...................................................................................................................33 DATA FIFO ........................................................................................................................................34 FREQUENCY PROGRAMMING ..............................................................................................................35 VCO...................................................................................................................................................35 VCO AND PLL SELF-CALIBRATION ...................................................................................................35 VOLTAGE REGULATORS .....................................................................................................................35 OUTPUT POWER PROGRAMMING ........................................................................................................36 CRYSTAL OSCILLATOR .......................................................................................................................37 ANTENNA INTERFACE.........................................................................................................................38 GENERAL PURPOSE / TEST OUTPUT CONTROL PINS ...........................................................................38 ASYNCHRONOUS AND SYNCHRONOUS SERIAL OPERATION ................................................................40 ASYNCHRONOUS OPERATION..............................................................................................................40 SYNCHRONOUS SERIAL OPERATION ....................................................................................................40 CONFIGURATION REGISTERS ..............................................................................................................40 CONFIGURATION REGISTER DETAILS – REGISTERS WITH PRESERVED VALUES IN SLEEP STATE ..........45 CONFIGURATION REGISTER DETAILS – REGISTERS THAT LOOSE PROGRAMMING IN SLEEP STATE ......59 STATUS REGISTER DETAILS .................................................................................................................60 PACKAGE DESCRIPTION (QLP 20)......................................................................................................63 RECOMMENDED PCB LAYOUT FOR PACKAGE (QLP 20).....................................................................64 PACKAGE THERMAL PROPERTIES ........................................................................................................64 SOLDERING INFORMATION..................................................................................................................64 TRAY SPECIFICATION ..........................................................................................................................65 CARRIER TAPE AND REEL SPECIFICATION ...........................................................................................65 ORDERING INFORMATION ...................................................................................................................65 GENERAL INFORMATION ....................................................................................................................66 DOCUMENT HISTORY .........................................................................................................................66 PRODUCT STATUS DEFINITIONS .........................................................................................................66 DISCLAIMER .......................................................................................................................................66 TRADEMARKS .....................................................................................................................................66 LIFE SUPPORT POLICY ........................................................................................................................66 ADDRESS INFORMATION .....................................................................................................................68Chipcon ASSmartRF® CC1100 Preliminary Data Sheet (rev. 1.0) 2005-04-25Page 4 of 68元器件交易网Chipcon1 Absolute Maximum RatingsSmartRF ® CC1100Under no circumstances must the absolute maximum ratings given in Table 1 be violated. Stress exceeding one or more of the limiting values may cause permanent damage to the device.Caution! ESD sensitive device. Precaution should be used when handling the device in order to prevent permanent damage. Parameter Supply voltage Voltage on any digital pin Voltage on the pins RF_P, RF_N and DCOUPL Input RF level Storage temperature range Solder reflow temperature –50 Min –0.3 –0.3 –0.3 Max 3.6 VDD+0.3, max 3.6 2.0 10 150 265 Units V V V dBm °C °C According to IPC/JEDEC J-STD-020C Condition All supply pins must have the same voltageTable 1: Absolute Maximum Ratings2Operating ConditionsMin -40 1.8 Max 85 3.6 Unit °C V All supply pins must have the same voltage ConditionThe operating conditions for CC1100 are listed Table 2 in below.Parameter Operating temperature Operating supply voltageTable 2: Operating ConditionsChipcon ASSmartRF® CC1100 Preliminary Data Sheet (rev. 1.0) 2005-04-25Page 5 of 68元器件交易网Chipcon3 Electrical SpecificationsMin Typ 900 400 90 160 Current consumption 15 MaxSmartRF ® CC1100Tc = 25°C, VDD = 3.0V if nothing else stated. Measured on Chipcon’s CC1100EM reference design. Parameter Current consumption in power down modes Unit Condition nA nA µA µA µA Voltage regulator to digital part off, register values retained, lowpower RC oscillator running (SLEEP state with WOR enabled) Voltage regulator to digital part off, register values retained (SLEEP state) Voltage regulator to digital part off, register values retained, XOSC running (SLEEP state with MCSM0.OSC_FORCE_ON set) Voltage regulator to digital part on, all other modules in power down (XOFF state) Automatic RX polling once each second, using low-power RC oscillator, with 460kHz filter bandwidth and 250kbps data rate, th PLL calibration every 4 wakeup. Average current with signal in channel below carrier sense level. Same as above, but with signal in channel above carrier sense level, 1.9ms RX timeout, and no preamble/sync word found. Automatic RX polling every 15 second, using low-power RC oscillator, with 460kHz filter bandwidth and 250kbps data rate, th PLL calibration every 4 wakeup. Average current with signal in channel below carrier sense level. Same as above, but with signal in channel above carrier sense level, 14ms RX timeout, and no preamble/sync word found. Only voltage regulator to digital part and crystal oscillator running (IDLE state) Only the frequency synthesizer running (after going from IDLE until reaching RX or TX states, and frequency calibration states) Transmit mode, +10dBm output power Transmit mode, 5dBm output power Transmit mode, 0dBm output power Transmit mode, –10dBm output power Receive mode, 2.4kbps, input at sensitivity limit Receive mode, 2.4kbps, input 30dB above sensitivity limit Receive mode, 250kbps, input at sensitivity limit Receive mode, 250kbps, input 30dB above sensitivity limit mA Transmit mode, +10dBm output power Transmit mode, 5dBm output power Transmit mode, 0dBm output power Transmit mode, –10dBm output power Receive mode, 2.4kbps, input at sensitivity limit Receive mode, 2.4kbps, input 30dB above sensitivity limit Receive mode, 250kbps, input at sensitivity limit Receive mode, 250kbps, input 30dB above sensitivity limitth34 1.8µA µA15 1.9 8.7 Current consumption, 315MHz 26.9 18.3 15.1 13.4 15.1 14.0 16.2 15.1 Current consumption, 433MHz 28.8 19.3 16.1 14.3 15.6 14.5 16.5 15.5µA mA mA mAChipcon ASSmartRF® CC1100 Preliminary Data Sheet (rev. 1.0) 2005-04-25Page 6 of 68元器件交易网ChipconParameter Current consumption, 868/915MHz Min Typ 30.3 19.7 16.6 14.0 15.4 14.2 16.2 15.2 Max mASmartRF ® CC1100Unit Condition Transmit mode, +10dBm output power Transmit mode, 5dBm output power Transmit mode, 0dBm output power Transmit mode, –10dBm output power Receive mode, 2.4kbps, input at sensitivity limit Receive mode, 2.4kbps, input 30dB above sensitivity limit Receive mode, 250kbps, input at sensitivity limit Receive mode, 250kbps, input 30dB above sensitivity limitTable 3: Electrical Specifications4General CharacteristicsMin 300 400 800 Typ Max 348 464 928 500 Unit MHz MHz MHz kbps Modulation formats supported: (Shaped) MSK (also known as differential offset QPSK) up to 500kbps 2-FSK up to 500kbps GFSK and OOK/ASK (up to 250kbps) Optional Manchester encoding (halves the data rate). Condition/NoteParameter Frequency rangeData rate1.2Table 4: General CharacteristicsChipcon ASSmartRF® CC1100 Preliminary Data Sheet (rev. 1.0) 2005-04-25Page 7 of 68元器件交易网Chipcon5 RF Receive SectionMin Typ TBD –110 –100 -88 Max Unit Ω dBm dBm dBmSmartRF ® CC1100Tc = 25°C, VDD = 3.0V if nothing else stated. Measured on Chipcon’s CC1100EM reference design. Parameter Differential input impedance Receiver sensitivity 315/433/868/915MHz Condition/Note Follow CC1100EM reference design 2-FSK, 1.2kbps, 5.2kHz deviation, 1% packet error rate, 62 bytes packet length, 58kHz digital channel filter bandwidth 2-FSK, 38.4kbps, 20kHz deviation, 1% packet error rate, 62 bytes packet length, 100kHz digital channel filter bandwidth 2-FSK, 250kbps, 127kHz deviation, 1% packet error rate, 62 bytes packet length, 540kHz digital channel filter bandwidth OOK, 250kbps OOK, 1% packet error rate, 62 bytes packet length, 540kHz digital channel filter bandwidth-88 Saturation Digital channel filter bandwidth Adjacent channel rejection, 868MHz 58 –15 650dBm dBm kHzUser programmable. The bandwidth limits are proportional to crystal frequency (given values assume a 26.0MHz crystal). 2-FSK, 38.4kbps, 20kHz deviation, 1% packet error rate, 62 bytes packet length, 100kHz digital channel filter, 150kHz channel spacing Desired channel 3dB above the sensitivity limit.23dBAlternate channel rejection, 868MHz33dB2-FSK, 38.4kbps, 20kHz deviation, 1% packet error rate, 62 bytes packet length, 100kHz digital channel filter, 150kHz channel spacing Desired channel 3dB above the sensitivity limit.Image channel rejection, 868MHz29dB2-FSK, 38.4kbps, 20kHz deviation, 1% packet error rate, 62 bytes packet length, 100kHz digital channel filter, 150kHz channel spacing, IF frequency 305kHz Desired channel 3dB above the sensitivity limit.Blocking at 1MHz offset, 868MHz Blocking at 2MHz offset, 868MHz Blocking at 5MHz offset, 868MHz Blocking at 10MHz offset, 868MHz Spurious emissions52 54 61 64 –57 –47dB dB dB dB dBm dBmDesired channel 3dB above the sensitivity limit. Compliant to ETSI EN 300 220 class 2 receiver requirement. Desired channel 3dB above the sensitivity limit. Compliant to ETSI EN 300 220 class 2 receiver requirement. Desired channel 3dB above the sensitivity limit. Compliant to ETSI EN 300 220 class 2 receiver requirement. Desired channel 3dB above the sensitivity limit. Compliant to ETSI EN 300 220 class 2 receiver requirement. 25MHz – 1GHz Above 1GHzTable 5: RF Receive SectionChipcon ASSmartRF® CC1100 Preliminary Data Sheet (rev. 1.0) 2005-04-25Page 8 of 68元器件交易网Chipcon6 RF Transmit SectionSmartRF ® CC1100Tc = 25°C, VDD = 3.0V, +10dBm if nothing else stated. Measured on Chipcon’s CC1100EM reference design. Parameter Differential load impedance Output power, highest setting Min Typ TBD 10 Max Unit Ω dBm Condition/Note Follow CC1100EM reference design Output power is programmable, and full range is available in all frequency bands. Delivered to a 50Ω single-ended load via Chipcon reference RF matching network. Output power, lowest setting –30 dBm Output power is programmable, and full range is available in all frequency bands. Delivered to a 50Ω single-ended load via Chipcon reference RF matching network. Spurious emissions and harmonics, 433/868MHz –36 –54 –47 dBm dBm dBm 25MHz – 1GHz 47-74, 87.5-118, 174-230, 470-862MHz 1800MHz-1900MHz (restricted band in Europe), when the nd operating frequency is below 900MHz (2 harmonic can not fall within this band when used in Europe) Otherwise above 1GHz <200µV/m at 3m below 960MHz. <500µV/m at 3m above 960MHz. 2 , 3 and 4 harmonic when the output power is maximum 6mV/m at 3m. (-19.6dBm EIRP) 5 harmonic 2 harmonic 3 , 4 and 5 harmonicrd th th nd th nd rd th–30 Spurious emissions, 315/915MHz -49.2 -41.2 Harmonics 315MHz -20dBm dBm EIRP dBm EIRP dBc-41.2 Harmonics 915MHz -20 -41.2dBm dBc dBmTable 6: RF Transmit Parameters7Crystal OscillatorTc = 25°C @ VDD = 3.0 V if nothing else is stated. Parameter Crystal frequency Tolerance Min 26 Typ 26 ±40 Max 27 Unit MHz ppm This is the total tolerance including a) initial tolerance, b) aging and c) temperature dependence. The acceptable crystal tolerance depends on RF frequency and channel spacing / bandwidth. ESR Start-up time 300 100 Ω µs Measured on Chipcon’s CC1100EM reference design. This parameter is to a large degree crystal dependent. Condition/NoteTable 7: Crystal Oscillator ParametersChipcon ASSmartRF® CC1100 Preliminary Data Sheet (rev. 1.0) 2005-04-25Page 9 of 68元器件交易网Chipcon8 Low Power RC OscillatorSmartRF ® CC1100Typical performance is for Tc = 25°C @ VDD = 3.0 V if nothing else is stated. The values in the table are simulated results and will be updated in later versions of the data sheet. Parameter Calibrated frequency Frequency accuracy after calibration Temperature coefficient Supply voltage coefficient Initial calibration time +0.4 +3 2 Min 34.6 Typ 34.7 Max 36 ±0.2 Unit kHz % % / °C %/V ms Frequency drift when temperature changes after calibration Frequency drift when supply voltage changes after calibration When the RC Oscillator is enabled, calibration is continuously done in the background as long as the crystal oscillator is running. Programmable, dependent on XTAL frequency Condition/Note Calibrated RC Oscillator frequency is XTAL frequency divided by 750Wake-up period58e-659650SecondsTable 8: RC Oscillator parameters9Frequency Synthesizer CharacteristicsTc = 25°C @ VDD = 3.0 V if nothing else is stated. Measured on Chipcon’s CC1100EM reference design. Parameter Programmed frequency resolution Synthesizer frequency tolerance PLL turn-on / hop time Min 397 Typ FXOSC/ 16 2 ±40 Max 412 Unit Hz Condition/Note 26MHz-27MHz crystal. The resolution (in Hz) is equal for all frequency bands. ppm Given by crystal used. Required accuracy (including temperature and aging) depends on frequency band and channel bandwidth / spacing. Time from leaving the IDLE state until arriving in the RX, FSTXON or TX state, when not performing calibration. Crystal oscillator running. Settling time for the 1xIF frequency step from RX to TX, and vice versa. Calibration can be initiated manually, or automatically before entering or after leaving RX/TX. Min/typ/max time is for 27/26/26MHz crystal frequency.80µsPLL RX/TX and TX/RX settling time PLL calibration time 0.69 18739 0.7210µs XOSC cycles0.72msTable 9: Frequency Synthesizer ParametersChipcon ASSmartRF® CC1100 Preliminary Data Sheet (rev. 1.0) 2005-04-25Page 10 of 68。

Low Noise Fixed Frequency Band - Pass FiltersDescription:The D100B Series are low noise and distortion 2-pole-pair, fixed center frequency (f o) band-pass filters. These filters feature near theoretical low noise and distortion performance, by providing up to -120 dB noise floors (20-Bit). D100B’s take advantage of FDI’s design expertise utilizing high performance amplifiers and surface-mount technology to provide design engineers with precision signal conditioning solutions in a compact package. These fully self-contained units require no external components or adjustments. Each D100B comes factory tuned to a user specified corner frequency between 100 Hz to 100 kHz. Available Q’s for D100B models are 1, 2 or 5 and operate with low harmonic distortion over an input voltage range to ±10 V. Features/Benefits:• Small 32-pin DIP (1.8"L x 0.8"W) footprint minimizes board space requirements.• Plug-in ready-to-use,reducing engineering design and manufacturing cycle time.• Factory tuned, no external clocks or adjustments needed.• Broad range of center frequencies to meet a wide range of applications.Applications• Transducer output filtering.• Production test instrumentation• Medical electronics equipment and research • Noise and harmonic analysis• Frequency spectrum analysisAvailable Band-Pass Models: Page D100BP2 2-PolePair2General SpecificationsPin-out/package data & order information 3Low Noise Fixed Frequency Band - Pass Filters1. Q – Quality Factor for band-pass and band-reject filters. Q = f O/(f H-f L), f o = L H f f2. Use I/O jumpers to bypass input and output buffers, for low noise operation. With FMA, D100B distortion specs at50k to 100kHz may degrade slightly.D100B SeriesSpecifications (25ºC and Vs ± 15 Vdc) Pin-Out and Package Data Ordering Information2. Output is short circuit protected to common. DO NOT CONNECT TO ±Vs.3. Adjustable to zero.4. Units operate with or without offset pin connected.5. How to specify Center Frequency F0. Center frequency is specified by attaching a three-digit frequency designator to the basic model number. Center frequencies can range from 100 Hz to 100 kHz.2.50 kHz 33.3 kHzWe hope the information given here will be helpful. The information is based on data and our best knowledge, and we consider the information to be true and accurate. Please read all statements, recommendations or suggestions herein in conjunction with our conditions of sale, which apply, to all goods supplied by us. We assume no responsibility for the use of these statements, recommendations or suggestions, nor do we intend them as a recommendation for any use, which would infringe any patent or copyright. PR-D100BP2 元器件交易网Q = 1Q = 2Q = 5Q = 10f L < f O < f Hf L < f O < f Hf L < f O < f Hf L < f O < f HAmp(dB) f / f O f / f O f / f O f / f O f / f O f / f O f / f O f / f O -0.100.824 1.2140.907 1.1020.962 1.0400.981 1.020-0.250.783 1.2770.884 1.1310.952 1.0510.976 1.025-0.500.747 1.3380.863 1.1590.943 1.0610.971 1.030-1.000.705 1.4180.837 1.1940.931 1.0740.9651.036-1.500.677 1.4780.820 1.2200.923 1.0830.961 1.041-2.000.654 1.5290.805 1.2420.916 1.0910.957 1.045-2.500.635 1.5740.792 1.2620.910 1.0980.954 1.048-3.000.618 1.6170.781 1.2800.905 1.1050.951 1.051-5.000.563 1.7760.742 1.3480.886 1.1290.941 1.062-10.000.457 2.1890.657 1.5230.842 1.1880.917 1.090-15.000.368 2.7200.572 1.7480.792 1.2630.889 1.125-20.000.290 3.4450.485 2.0620.733 1.3640.855 1.170-25.000.2254.4390.399 2.5060.664 1.5070.811 1.233-30.000.1735.7950.319 3.1300.585 1.7090.758 1.320-35.000.1317.6300.250 3.9990.500 2.0000.693 1.443-40.000.09910.090.193 5.1920.414 2.4140.618 1.618-45.000.07513.410.1476.8140.333 3.0010.535 1.869-50.000.05617.830.1119.0020.262 3.8190.449 2.228-55.000.04223.750.08411.940.202 4.9450.365 2.737-60.000.03231.650.06315.870.154 6.4790.290 3.453-65.000.02442.190.04721.130.1178.5520.225 4.443-70.000.01856.250.03628.150.08811.330.172 5.798-75.000.01375.000.02737.520.06615.060.1317.632-80.000.010100.00.02050.010.05020.050.09910.10Band-Pass 2-Pole PairAppendix AAmplitude Response Curves0.11.010.0Normalized Frequency (f/fo)-80-70-60-50-40-30-20-100A m p (d B )Normalized Frequency (f/fo)1.00A m p (d B )Q1Q2Q5Q10Band-Pass2-Pole PairAppendix AQ = 1Q = 2Q = 5Q = 10(+)(-)(+)(-)(+)(-)(+)(-)Phase Mag ( deg) f / f O f /f O f / f O f / f O f / f O f / f O f / f O f / f O 1.00.994 1.0060.997 1.0030.999 1.0010.9991.0012.50.985 1.0160.992 1.0080.997 1.0030.998 1.0025.00.970 1.0310.985 1.0160.994 1.0060.9971.00310.00.940 1.0630.970 1.0310.988 1.0120.994 1.00615.00.913 1.0960.955 1.0470.982 1.0180.991 1.00920.00.886 1.1280.941 1.0620.976 1.0250.988 1.01225.00.861 1.1610.928 1.0780.970 1.0300.985 1.01530.00.838 1.1940.915 1.0930.965 1.0360.982 1.01835.00.815 1.2270.902 1.1080.960 1.0420.980 1.02140.00.794 1.2590.891 1.1230.955 1.0480.977 1.02445.00.774 1.2920.879 1.1380.950 1.0530.974 1.02650.00.755 1.3240.868 1.1520.945 1.0590.972 1.02960.00.719 1.3910.846 1.1820.935 1.0690.967 1.03470.00.685 1.4600.825 1.2120.925 1.0810.962 1.04080.00.652 1.5350.803 1.2450.916 1.0920.957 1.04590.00.618 1.6180.781 1.2810.905 1.1050.951 1.051105.00.564 1.7720.743 1.3460.887 1.1280.941 1.062120.00.502 1.9910.695 1.4390.862 1.1600.928 1.077135.00.4242.3560.628 1.5940.825 1.2120.908 1.101150.00.3203.1260.520 1.9230.758 1.3190.869 1.150165.00.177 5.6390.327 3.0580.593 1.6860.764 1.310180.00inf0inf0inf0infPhase Response CurvesNormalized Frequency (f/fo)1.00.90.80.70.6P h a s e (d e g )1.1 1.2 1.41.3 1.51.6Normalized Frequency (f/fo)0P h a s e (d e g )Q1Q2Q5Q10Normalized Theoretical Phase Data-180-90090180。

e 3B170/B - B1100/B1.0A HIGH VOLTAGE SCHOTTKY BARRIER RECTIFIERFeaturesMaximum Ratings and Electrical Characteristics@ T A = 25°C unless otherwise specified·Guard Ring Die Construction for Transient Protection ·Ideally Suited for Automatic Assembly ·Low Power Loss, High Efficiency ·Surge Overload Rating to 30A Peak·For Use in Low Voltage, High Frequency Inverters, Free Wheeling, and Polarity Protection Application·High Temperature Soldering: 260°C/10 Second at Terminal ·Lead Free Finish/RoHS Compliant (Note 3)Mechanical Data·Case: SMA / SMB·Case Material: Molded Plastic . UL Flammability Classification Rating 94V-0·Moisture Sensitivity: Level 1 per J-STD-020C ·Terminals: Lead Free Plating (Matte Tin Finish).Solderable per MIL-STD-202, Method 208·Polarity: Cathode Band or Cathode Notch ·Marking: Type Number·SMA Weight: 0.064 grams (approximate)·SMB Weight: 0.093 grams (approximate)Single phase, half wave, 60Hz, resistive or inductive load.For capacitive load, derate current by 20%.Notes: 1. Valid provided that terminals are kept at ambient temperature. 2. Measured at 1.0MHz and applied reverse voltage of 4.0V DC.3. RoHS revision 13.2.2003. High Temperature Solder Exemption Applied, see EU Directive Annex Note 7.No Suffix Designates SMA Package “B” Suffix Designates SMB Package0.010.11.0100.20.40.60.81.0I , I N S T A N T A N E O U S F O R W A R D C U R R E N T (A )F V , INSTANTANEOUS FORWARD VOLTAGE (V)F Fig. 2 Typical Forward Characteristics102030400110100I , P E A K F O R W A R D S U R G E C U R R E N T (A )F S M NUMBER OF CYCLES AT 60 HzFig. 3 Max Non-Repetitive Peak Forward Surge Current1010010000.1110100C , T O T A L C A P A C I T A N C E (p F )TV , REVERSE VOLTAGE (V)R Fig. 4 Typical T otal Capacitance0.51.0255075100125150I A V E R A G E F O R W A R D C U R R E N T (A )(A V ),T , TERMINAL TEMPERATURE (°C)T Fig. 1 Forward Current Derating CurveXXX = Product type marking code, ex: B170 (SMA package)XXXX = Product type marking code, ex: B190B (SMB package) = Manufacturers’ code marking YWW = Date code markingY = Last digit of year ex: 2 for 2002 WW = Week code 01 to 52YWW Marking InformationNotes: 4. For Packaging Details, go to our website at /datasheets/ap02007.pdf.* x = Device type, e.g. B180-13-F (SMA package); B1100B-13-F (SMB package).Ordering Information(Note 4)IMPORTANT NOTICEDiodes Incorporated and its subsidiaries reserve the right to make modifications, enhancements, improvements, corrections or other changes without further notice to any product herein. Diodes Incorporated does not assume any liability arising out of the application or use of any product described herein; neither does it convey any license under its patent rights, nor the rights of others. The user of products in such applications shall assume all risks of such use and will agree to hold Diodes Incorporated and all the companies whose products are represented on our website, harmless against all damages.LIFE SUPPORTDiodes Incorporated products are not authorized for use as critical components in life support devices or systems without the expressed written approval of the President of Diodes Incorporated.。

•Capability of Single-wire Operation•Hardware Fault Recognition•Inputs with High Common-mode and Differential-mode Interference Rejection Above 100 V PP due to External Filters at the Receiver Input•Immunity Against Electromagnetic Interference Array•Immunity Against Ground-voltage Offsets < 6V•Ruggedized Against ESD by MIL-STD-883C, Method 3015BenefitsSystems which employ this device have the following benefits compared to solutions using discrete components:•High ReliabilityApplications•Especially Suited for Truck and Van Applications•Interface Between Truck and Trailer•Interface Between Dashboard and Engine1.DescriptionThe CAN driver IC B10011S is a low-speed, high-level interface for 24V (27V) opera-tion with transmission levels according to ISO WD 11992-1 (point-to-point interface between trucks and trailers). It is developed for signal levels of 8V/16V and a speed of up to 250 kbits/s.This device allows transmission, that is insensitive to electromagnetic interference. Such interferences may especially occur in truck applications where (due to the length of the wires) high common-mode voltages (e.g., 50) can be coupled into the lines. This device contains a fault recognition circuit that detects faults on one of the twowires, which are normally used for transmission. If a fault occurs the operation can beswitched from double-wire to single-wire mode thus, allowing proper operation even ifone wire is broken, has a short-cut or a high series resistance.24749C–AUTO–09/05B10011SFigure 1-1.Block Diagram34749C–AUTO–09/05B10011S2.Pin ConfigurationFigure 2-1.Pinning SO16Table 2-1.Pin Description16-lead SOIC (SO16), Small Outline Gull - WingPin Symbol Function1ASEL Select control input 2BSEL Select control input 3ER Error signal output 4RX1Reference voltage 2.5V 5RX0Receiver output 6TX0T ransmitter input7VDD Controller supply voltage 5V 8VSS Controller supply voltage 0V 9S-Collector of internal NPN switch 10GND Vehicle ground 0V 11L ’Data out driver 12H’Data out driver13VCC Vehicle power supply 24V 14S+Control output for external PNP 15F0Receiver input 16F1Receiver input44749C–AUTO–09/05B10011SER (error signal) is low when normal operation is disturbed by line faults (interruption, short to ground or to V CC , H to L short disturbance by high voltage transients). After a waiting period due to transient delays, the controller is asked to test if single-wire operation is possible by changing the A sel and B sel state.A sel andB sel have an internal pull-up resistor. Therefore, the no-connect state is 1, but connec-tion to V DD is recommended when not in use.3.Absolute Maximum RatingsStresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.Parameters Symbol Value Unit Supply voltageV CC –0.5 to +36V Controller supply voltage V DD –0.5 to +5.5V Input voltage at any input V in –0.5 to V DDV Junction temperature T j 150°C Storage temperature rangeT stg –55 to +150°C Soldering temperature (for 10s maximum)T sld260°COperating Conditions ParametersSymbol Value Unit Supply voltage car battery V CC 7 to 32V Controller supply voltage V DD 4.75 to 5.25V Control input voltage A sel , B sel0 to V DD V Input voltageT x00 to V DD V Operating temperatureT amb–40 to +105°C4.Operating Modes0 = 0V , 1 = 5VA selB sel R x0Mode00 3.8V H, L drivers disabled, L load disabled, S-, S+ disabled station not in operation, but consuming current10From H Single-wire H, L driver, L load, S-, S+ disabled 01From L Single-wire L, H driver disabled 11From L-HT wo-wire operation, normal mode54749C–AUTO–09/05B10011S5.Pulse DiagramThe pulse diagram for two connected, identical stations is shown below. The resistor levels have to be kept constant when additional stations are connected.Figure 5-1.Pulse Diagram64749C–AUTO–09/05B10011S6.Electrical CharacteristicsT est condition: T est circuit (see Figure 6-1 on page 7), 0 = 0V , 1 = 5VV CC = 27V , V DD = 5V , V SS = 0V , T amb = –40°C to +105°C, unless otherwise specified. ParametersTest Conditions Symbol Min.Typ.Max.Unit Supply currentT x0 = 0, A sel = 1, B sel = 1I CC 15mA T x0 = 0, A sel = 0, B sel = 0I DD 22mA T x0 = 1, A sel = 1, B sel = 1I CC 26mA T x0 = 1, A sel = 1, B sel = 1I DD 16mA Input currentT x0 = 1, A sel = 1, B sel = 1I(T x0)650µA T x0 = 1, A sel = 1, B sel = 1I(A sel , B sel )150µA Output voltageT x0 = 0, A sel = 1, B sel = 0V IL (F 0) = 1.9V , V IH (F 1) = 2.7V R x0 1.0V T x0 = 1, A sel = 1, B sel = 1V IL (F 1) = 1.9 V , V IH (F 0) = 2.7 V R x0 3.8V T x0 = 0, A sel = 1, B sel = 1U(H’)24.5V T x0 = 1, A sel = 1, B sel = 1U(H’) 1.0V T x0 = 1, A sel = 1, B sel = 1U(L ’)26V T x0 = 0, A sel = 1, B sel = 1U(L ’) 1.0V No fault ER 4.7V Fault on lineER100mVV CC = 7V , V DD = 4.75V , V SS = 0V , T amb = 25°C, unless otherwise specified. ParametersTest Conditions Symbol Min.Typ.Max.Unit Output voltageT x0 = 0, A sel = 1, B sel = 1U(H’) 4.5V T x0 = 1, A sel = 1, B sel = 1U(H’)100mV T x0 = 1, A sel = 1, B sel = 0U(L ’) 6.5V T x0 = 0, A sel = 1, B sel = 1U(L ’) 1.0V T x0 = 1, A sel = 1, B sel = 0V IL (F 1) = 1.0V , V IH (F 0) = 1.15V R x0 3.3V T x0 = 0, A sel = 1, B sel = 0V IL (F 0) = 1.0V , V IH (F 1) = 1.15VR x01.0VV CC = 32V , V DD = 5.25V , V SS = 0V , T amb = 25°C, unless otherwise specified. ParametersTest Conditions Symbol Min.Typ.Max.Unit Output voltageT x0 = 0, A sel = 1, B sel = 1U(H’)29V T x0 = 1, A sel = 1, B sel = 1U(H’)500mV T x0 = 1, A sel = 1, B sel = 0U(L ’)31.5V T x0 = 0, A sel = 1, B sel = 1U(L ’) 1.0V T x0 = 1, A sel = 1, B sel = 0V IL (F 1) = 1.6V , V IH (F 0) = 2.7V R x0 4.0V T x0 = 0, A sel = 1, B sel = 0 V IL (F 0) = 1.6V , V IH (F 1) = 2.7VR x01.0V74749C–AUTO–09/05B10011SFigure 6-1.Test CircuitFigure 6-2.Application CircuitThe implementation of a power filter and overvoltage clamp as follows is highly recommended:84749C–AUTO–09/05B10011SFigure 6-3.Implementation of a Power Filter and Over Clamps7.Application HintsAs an interface between CAN controllers and a two-wire data bus system for serial data inter-change, this device is adapted to a special high-level, low-speed transmission system, which is useful in harsh environments. High immunity against ground offset and interference voltages on the bus have been the design goals for this device, rather than low power consumption or a min-imum of external components. An error detection scheme is implemented in the receiver part to give quick information to the controller in case of faults occurring on the bus. Thus, the controller is able to start a search cycle in order to look for the possibility of single-wire operation or to dis-able the station from the bus.An automatic error-signal end is not feasible because parts of the system are disabled during single-wire operation. Therefore, the controller has to carry out short tests by switching to the two-wire state and checking, whether the error signal is still present or not. Errors due to dirty contacts, shorts between high and low line, or interruptions may not be recognized at all, because this device does not contain a complete fault computer.Two control inputs A sel and B sel enable four operation modes (see Table “Operating Modes” on page 4’). Depending on the nature of the error, the error signal ER is internally generated partly in the recessive or partly in the dominant transmission state. In order to avoid watching the error bits bitwise, an open-collector output driver (with a 1-k Ω series resistor) discharges a storage capacitor, which is charged by a time constant, long enough to hold the 0 state for, e.g., 200 µs, thus, giving the controller enough time to recognize this status during idle times. Only the charg-ing resistor may be changed and not the 2.2-nF capacitor. In order to perform a faster error-end test, the charging resistor may be shorted by an NPN emitter follower or by a tristate output high for approximately 1 to 2 µs.The pinout of the device shows a controller side (pins 1 to 8) and a bus side (pins 9 to 16). The application circuit utilizes an input filter section which is necessary for every station and a bias section which is needed in two master stations only. Additional slave stations only contain the driving resistors at pins 11 and 12 (270Ω and 220Ω), the choke coil, and capacitor between pins 13 and 10.A power filter and overvoltage clamp is highly recommended in order to avoid transmission errors due to spikes on the 24-V battery voltage.The input filter is designed as an 2-RC filter for 125 kbit/s and may be changed to 250 kbit/s. Its good pulse response and good suppression of high frequencies should not be weakened by omitting one of the capacitors.94749C–AUTO–09/05B10011SAll the logical and sensing functions in the device are powered by V DD = 5V. Therefore, the filter section also acts as a level shifter to the input comparator range (approximately 1 to 3.3V). The diagram (see Figure 7-1) shows how the battery voltage, V CC , influences the comparator input voltages, F 0 and F 1, in relation to the internal reference voltage, V ref , in the recessive state.The lower V CC , the lower the bus level. Taking this into account the comparator input levels are F 1 – V ref for single-wire H respectively F 1 – F 0 for two-wire operation. The comparator’s offsetvoltage is ≤10 mV. Matching the filter biasing to the internal reference is essentially for safe operation even at low battery voltages during motor start.The level investigations and tests described in the following description have been carried out within the temperature range of –40°C to +105°C with two B10011S on a bus line, one of them always in the recessive state (see Figure 7-2 on page 10).In case of line shorts to V CC or to ground or in case of H to L shorts, all participants on the bus are intended to switch to single-wire operation and to disable their drivers not in use.The dynamic behavior of the circuit depends on the line capacitances to ground. Approximately 200 pF/m and a maximum of 6 nF have to be taken into account. The transition from the domi-nant to the recessive state enables the bias network to recharge the line through a driving resistor of approximately 300Ω. The transition from the recessive to the dominant state is approximately twice as fast. This is probably the source of emitted radiation having no capaci-tance on the line. The choke coil enables the suppression of this radiation in the frequency range above 5 MHz to 7 MHz. Care should be taken not to feed noise from V DD or V CC to the line. Therefore, they should be properly blocked by low-inductance capacitors.Data loss by externally induced interference is avoided by careful PCB layout and EMC design for this circuit as well as by providing appropriate overvoltage protection. It is very essential to separate battery ground and filter ground as indicated in the application circuit (see Figure 6-2 on page 7). Especially important is that the filter ground must be connected to pin 8 by a short connection not subject to disturbing currents from external sources. The ground wire of the “star-quad” cable may introduce such currents and should be connected to battery ground via a 0.1-µF capacitor in a way as short as possible, perhaps to the metal housing.In order to avoid thermal problems, the voltage divider and driving resistors should be kept away from the IC. Otherwise they would heat up the environment of the small IC and might reduce its life expectancy.Figure 7-1.Comparator Thresholds104749C–AUTO–09/05B10011SFigure 7-2.Test Circuit Equivalents114749C–AUTO–09/05B10011S9.Package Information10.Revision History8.Ordering InformationPart Number Package RemarksB10011S-MFPG1Y SO16Taped and reeled, Pb-free B10011S-MFPG3YSO16Taped and reeled, Pb-freePlease note that the following page numbers referred to in this section refer to the specific revisionmentioned, not to this document.Revision No.History4749C-AUTO-09/05• Put datasheet in a new template • Pb-free logo on page 1 added• T able “Ordering Information” on page 11 changed 4749B-AUTO-09/04• Figure 2 “Pinning SO16” on page 2 changed4749C–AUTO–09/05© Atmel Corporation 2005. All rights reserved. Atmel ®, logo and combinations thereof, Everywhere You Are ® and others, are registered trade-marks or trademarks of Atmel Corporation or its subsidiaries. Other terms and product names may be trademarks of others.Disclaimer: The information in this document is provided in connection with Atmel products. No license, express or implied, by estoppel or otherwise, to any intellectual property right is granted by this document or in connection with the sale of Atmel products. EXCEPT AS SET FORTH IN ATMEL ’S TERMS AND CONDI-TIONS OF SALE LOCATED ON ATMEL ’S WEB SITE, ATMEL ASSUMES NO LIABILITY WHATSOEVER AND DISCLAIMS ANY EXPRESS, IMPLIED OR STATUTORY WARRANTY RELATING TO ITS PRODUCTS INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTY OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, OR NON-INFRINGEMENT. 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LDD1100 投入式数字液位计　LDD1100投入式数字液位计是LDD1000投入式精密数字液位计的简化版本。

通讯协议与LDD 系列智能数字压力变送器兼容。

水位输出精度为： 0.1%FSO （10~20℃时）， 0.3%FSO （0~30℃时） 数字输出，直接读取液位值，读数分辨率1cm温度数字输出，精度为±2℃，读数分辨率1℃（可选功能）支持RS485双绞线网络，可带载32个LDD 系列变送器。

多于32个时，需加RS485中继器 低功耗 静态电流8mA ，宽直流电压供电范围：11V~24V 。

适合蓄电池或太阳能供电内嵌MCU ，对LDD 进行数字调理，包括全温度范围的压力非线性补偿、零位和灵敏度的补偿等。

RS485半双工串行异步数字通讯接口，有2种通讯速率可供选择，分别是（BPS ）：1200，9600。

数字通讯接口的工作协议为：1位开始位，8位数据位，1位停止位。

传输距离1200米。

命令返回延迟时间约10ms 。

水位读数刷新周期100毫秒(采样频率10次/秒)。

初始上电稳定周期2秒。

典型特点量程范围（水位变幅）：0~1000cmH 2O m 到0~6000cmH 2O ， 探头外壳：1Cr18Ni9Ti 不锈钢 专用4芯防水屏蔽电缆 绝压防护等级IP68产品描述 产品特点江门市利德信息技术有限公司　广东省江门市五邑碧桂园翠山聆水二街６８号 邮编：（ｚｉｐ）５２９０００　电话：＋　８６　７５０　３２８９６８０ ３２８９６９０ 传真：＋　８６　７５０　３２８９６９９精度等级2级备注压力输出允许误差≤10M量程±1cm室温>10M量程≤全量程的0.1%在10~20℃下的总误差≤10M量程±3cm全温区>10M量程≤全量程的0.3% 在整个补偿温度(0~30℃)范围内的总误差数字输出信号分辨率 1cm输出更新周期 100ms温度输出误差（最大值）±2℃供电电压11 ~ 24VDC静态耗电电流（典型值） 8mA最大压力过载能力 1.5倍满量程补偿温度0℃~30℃工作环境温度 -10℃~50℃（水不结冰）长期稳定性（典型值） 0.2%FS/年压力介质与不锈钢兼容的液体和气体采用4芯防水屏蔽专用电缆连接LDD1100探头。

30High CapacityThe fast Epson Stylus Office B1100 allows your business to think big and print big. Producing high-quality results up to A3+, it brings new freedom to your office printing.With this A3+ printer your office has the flexibility to print large, vibrant graphics and documents at fast speeds of up to 30 ppm in black and 17 ppm in colour*1.The Epson Micro Piezo™ printhead and DURABrite Ultra Inks produce bright graphics, detailed photos and laser-like prints that are water, smudge and even highlighter resistant. Featuring the International Colour Consortium profile (ICC), you get exact colour reproduction for all your materials.The high capacity individual ink cartridges let you print more pages and deliver a cost per page that’s comparable to a laser printer*3. This means less frequent cartridge changes and more cost-effective business prints.EPSON STYLUS OFFICE B1100• F ast A3+ business printer • P rint everything from laser-like text to full colour business presentations • H igh speeds of up to 30 ppm in black and 17 ppm in colour*1• L aser-like print speeds at up to 13 ppm in black and 5.3 ppm in colour (ISO/IEC 24734)*2• P rints dry instantly and resist water, smudging and even highlighter pens • P rint more with high capacity individual inks • L ow cost per page comparable to a laser*3EPSON STYLUS OFFICEB1100INK CARTRIDGESEPSON DURABRITE ULTRA INKSave money. With Epson DURABrite Ultra individual ink cartridges you only replace the colour used.••T0711H •T1003•T1002•T1004•••T1006PRODUCT SPECIFICATIONS B 1100 – 1E N _I N T – 07/09WHAT’S IN THE BOX• E pson Stylus Office B1100 printer • 5 individual ink cartridges • P ower cable • ‘Start here’ guide • S oftware CD Rom • W arranty documentPAPEREpson’s Micro Piezo™ inkjet technology gives great results on a wide range of paper types, giving you the flexibility to printwhatever you want. And Epson produces a range of paper to help you do this, from A4 inkjet paper through to glossy photo paper in a variety of sizes.FOR THE BEST RESULTS ALWAYS USEGENUINE EPSON INK AND PAPER.* For more information, please visit * D etermined in accordance with ISO/IEC 24734 showing the average of ESAT from the Office Category Test for default simplex. For full report see * C ompared with laser printers below €199 (inc. tax) in Western Europe. Cost Per Page calculated from published manufacturers’ list prices and official specifications as of February 2009. Epson cost per page based on recommended ink cartridges.* O therwise 3 mm top, left, right, bottomEPSON STYLUS OFFICEB1100T rademarks and registered trademarks are the property of Seiko Epson Corporation or their respective owners. Product information is subject to change without prior notice.For further information please contact your local Epson office or visit Austria 0810/20 01 13 (0,07 E /Min.) Belgium 070/350120 (0.1735 E /min.) Czech 800/142 052 Denmark 44 50 85 85 Finland 0201 552 091 France 09 74 75 04 04 (0,12E /min) Germany 01805/23 41 10 (0,14 E /Min.) Greece 210-8099499 Hungary 06800 147 83 Ireland 01 436 7742 Italy 02-660321 10 (0,12 E /min.) Luxembourg 900/43010 (0,24 E /min.) Middle East +9714 8818934 Netherlands ************(0.05E /oproep+ 0.15 E /min.) Norway +47 67 11 37 00 Poland 0-0-800 4911299 (0,16 zł/min.) Portugal 707 222 111 Russia (095) 777-03-55 Slovakia 0850 111 429 South Africa (+2711) 465-9621 Spain 93 582 15 00 Sweden 0771-400135 (Mobilsamtal – 0,99 kr/min, Lokala samtal – 0,30 kr/min, Utlandssamtal – 0,89 kr/min) Switzerland 0848 448820 (4-8 cent./min.) Turkey (0212) 3360303 United Kingdom ************ Warranty offers are not available for all countries. Please contact your local Epson representative.。

CDB-1 断路器保护装置及CYB-1短引线保护装置运行规程目次前言 (Ⅱ)1范围……………………………………………………………………………………… (1)2保护装置主要功能构成 (1)3保护装置主要技术、定值参数 (1)4保护装置运行规定 (2)5保护装置运行监视及检查 (2)6保护装置保护动作处理 (3)7断路器保护柜保护压板配置和有关说明 (3)前言为了贯彻“安全第一，预防为主”的方针，切实执行“两票三制”制度，防止误操作和其他不安全情况发生，确保xx水力发电厂（以下简称岩滩电厂）设备以及电网系统安全可靠供电，根据有中国南方电网电力调度通信有关规定以及《中国大唐集团公司企业标准编制规则》（试行）和厂颁《企业标准编制规则》中的有关规定，参考CDB-1、2、3型断路器保护装置技术说明书、CYB-1型短引线保护装置技术说明书、FCX-500型操作继电器箱技术说明书、南方电力调度通信中心继电保护定值单，特制定本规程。

本规程是对Q/YTD—1040006—2000《继电保护自动装置运行规程》有关内容的修订。

本规程1992年首次发布，本次为第三次修订。

本规程自发布之日起实施，自实施之日起原规程相关规定同时作废。

本规程对原规程作了如下主要内容的修改：（1）增加了目次和前言。

（2）增加了保护装置主要技术、定值参数。

（3）增加了保护装置运行规定。

（4）增加了保护装置运行监视及检查。

（5）增加了保护装置保护动作处理。

（6）增加了记录。

本规程主要起草人：本规程主要审核人：本规程主要审定人：本规程批准人：CDB-1 断路器保护装置及CYB-1短引线保护装置运行规程1 范围本规程规定了CDB-1断路器保护装置、CYB-1短引线保护装置主要技术定值参数、运行规定、运行监视及检查、保护动作处理等内容。

本规程适用于岩滩电厂。

2 保护装置主要功能构成2.1 CDB-1断路器保护装置是适用于3/2接线的断路器保护，我厂500kV一号主变5011开关、500kV第一串联络5012开关、500kV二号主变5021开关、500kV 第二串联络5022开关、500kV备用线5023开关各配置一套，主要功能包括断路器失灵保护、断路器三相不一致保护、两相故障跳三相回路、重合闸沟通三相跳闸回路等。

TR1100916.50MHz Hybrid TransceiverThe TR1100hybrid transceiver is ideal for short-range wireless data applications where robust operation,small size,low power consumption and low cost are required.The TR1100employs RFM’s amplifier-sequenced hybrid (ASH)architecture to achieve this unique blend of character-istics.All critical RF functions are contained in the hybrid,simplifying and speeding design-in.The receiver section of the TR1100is sensitive and stable.A wide dynamic range log detector,in combination with digital AGC and a compound data slicer,provide robust performance in the presence of on-channel interference or noise.Two stages of SAW filtering provide excellent re-ceiver out-of-band rejection.The TR1100is optimized for RF data rates from 256kbps to1Mbps using amplitude-shift keyed (ASK)modulation.The transmitter employs SAW filtering to suppress output harmonics,facilitating compliance with FCC 15.249and similar regulations.Absolute Maximum Ratings·Designed for Short-Range Wireless Data Communications ·Supports RF Data Rates Up to 1Mbps ·3V,Low Current Operation plus Sleep Mode ·Stable,Easy to Use,Low External Parts CountooNotes:1.Typical sensitivity data is based on a10-3bit error rate(BER),using DC-balanced data.There are two test methods commonly used to measure OOK/ASK receiver sensitivity,the“100%AM”test method and the“Pulse”test method.Sensitivity data is given for both test meth-ods.See Appendix3.8in the ASH Transceiver Designer’s Guide for the details of each test method.The application/test circuit and compo-nent values are shown on the next page.2.Data is given with the ASH radio matched to a50ohm load.Matching component values are given on the next page.3.See Table1on Page8for additional information on ASH radio eventtiming.MMTransceiver Set-Up,3.0Vdc,-40to +850CCAUTION:Electrostatic Sensitive Device.Observe precautions when handling.ASH Transceiver Theory of OperationIntroductionRFM’s amplifier-sequenced hybrid(ASH)transceiver is specifically designed for short-range wireless data communication applications. The transceiver provides robust operation,very small size,low power consumption and low implementation cost.All critical RF functions are contained in the hybrid,simplifying and speeding de-sign-in.The ASH transceiver can be readily configured to support a wide range of data rates and protocol requirements.The transceiver features excellent suppression of transmitter harmonics and virtually no RF emissions when receiving,making it easy to certify to short-range(unlicensed)radio regulations.Amplifier-Sequenced Receiver OperationThe ASH transceiver’s unique feature set is made possible by its system architecture.The heart of the transceiver is the amplifier-sequenced receiver section,which provides more than100dB of stable RF and detector gain without any special shielding or de-coupling provisions.Stability is achieved by distributing the total RF gain over time.This is in contrast to a superheterodyne receiver, which achieves stability by distributing total RF gain over multiple frequencies.Figure1shows the basic block diagram and timing cycle for an am-plifier-sequenced receiver.Note that the bias to RF amplifiers RFA1 and RFA2are independently controlled by a pulse generator,and that the two amplifiers are coupled by a surface acoustic wave (SAW)delay line,which has a typical delay of0.5µs.An incoming RF signal is first filtered by a narrow-band SAW filter, and is then applied to RFA1.The pulse generator turns RFA1ON for0.5µs.The amplified signal from RFA1emerges from the SAW delay line at the input to RFA2.RFA1is now switched OFF and RFA2is switched ON for0.55µs,amplifying the RF signal further. The ON time for RFA2is usually set at1.1times the ON time for RFA1,as the filtering effect of the SAW delay line stretches the sig-nal pulse from RFA1somewhat.As shown in the timing diagram, RFA1and RFA2are never on at the same time,assuring excellent receiver stability.Note that the narrow-band SAW filter eliminates sampling sideband responses outside of the receiver passband,and the SAW filter and delay line act together to provide very high re-ceiver ultimate rejection.Amplifier-sequenced receiver operation has several interesting char-acteristics that can be exploited in system design.The RF amplifiers in an amplifier-sequenced receiver can be turned on and off almost instantly,allowing for very quick power-down(sleep)and wake-up times.Also,both RF amplifiers can be off between ON sequences to trade-off receiver noise figure for lower average current consump-tion.The effect on noise figure can be modeled as if RFA1is on continuously,with an attenuator placed in front of it with a loss equivalent to10*log10(RFA1duty factor),where the duty factor is the average amount of time RFA1is ON(up to50%).Since an amplifier-sequenced receiver is inherently a sampling receiver,the overall cycle time between the start of one RFA1ON sequence andFigure1the start of the next RFA1ON sequence should be set to sample the narrowest RF data pulse at least10times.Otherwise,significant edge jitter will be added to the detected data pulse.ASH Transceiver Block DiagramFigure2is the general block diagram of the ASH transceiver. Please refer to Figure2for the following discussions.Antenna PortThe only external RF components needed for the transceiver are the antenna and its matching components.Antennas presenting an impedance in the range of35to72ohms resistive can be satisfacto-rily matched to the RFIO pin with a series matching coil and a shunt matching/ESD protection coil.Other antenna impedances can be matched using two or three components.For some impedances, two inductors and a capacitor will be required.A DC path from RFIO to ground is required for ESD protection.Receiver ChainThe output of the SAW filter drives amplifier RFA1.This amplifier in-cludes provisions for detecting the onset of saturation(AGC Set), and for switching between35dB of gain and5dB of gain(Gain Se-lect).AGC Set is an input to the AGC Control function,and Gain Se-lect is the AGC Control function output.ON/OFF control to RFA1 (and RFA2)is generated by the Pulse Generator&RF Amp Bias function.The output of RFA1drives the SAW delay line,which has a nominal delay of0.5µs.The second amplifier,RFA2,provides51dB of gain below satura-tion.The output of RFA2drives a full-wave detector with19dB of threshold gain.The onset of saturation in each section of RFA2is detected and summed to provide a logarithmic response.This is added to the output of the full-wave detector to produce an overall detector response that is square law for low signal levels,and tran-sitions into a log response for high signal levels.This combination provides excellent threshold sensitivity and more than70dB of detector dynamic range.In combination with the30dB of AGC range in RFA1,more than100dB of receiver dynamic range is achieved.The detector output drives a gyrator filter.The filter provides a three-pole,0.05degree equiripple low-pass response with excellent group delay flatness and minimal pulse ringing.The3dB bandwidth of the filter can be set from4.5kHz to1.8MHz with an external re-sistor.The filter is followed by a base-band amplifier which boosts the de-tected signal to the BBOUT pin.When the receiver RF amplifiers are operating at a50%-50%duty cycle,the BBOUT signal changes about10mV/dB,with a peak-to-peak signal level of up to685mV. For lower duty cycles,the mV/dB slope and peak-to-peak signal level are proportionately less.The detected signal is riding on a1.1Vdc level that varies somewhat with supply voltage,tempera-ture,etc.BBOUT is coupled to the CMPIN pin or to an external data recovery process(DSP,etc.)by a series capacitor.The correct value of the series capacitor depends on data rate,data run length, and other factors as discussed in the ASH Transceiver Designer’s Guide.When an external data recovery process is used with AGC,BBOUT must be coupled to the external data recovery process and CMPIN by separate series coupling capacitors.The AGC reset function is driven by the signal applied to CMPIN.When the transceiver is placed in power-down(sleep)or in a trans-mit mode,the output impedance of BBOUT becomes very high.This feature helps preserve the charge on the coupling capacitor to mini-mize data slicer stabilization time when the transceiver switches back to the receive mode.Data SlicersThe CMPIN pin drives two data slicers,which convert the analog signal from BBOUT back into a digital stream.The best data slicer choice depends on the system operating parameters.Data slicer DS1is a capacitively-coupled comparator with provisions for an ad-justable threshold.DS1provides the best performance at lowFigure2signal-to-noise conditions.The threshold,or squelch,offsets the comparator’s slicing level from0to90mV,and is set with a resistor between the RREF and THLD1pins.This threshold allows a trade-off between receiver sensitivity and output noise density in theno-signal condition.For best sensitivity,the threshold is set to0.In this case,noise is output continuously when no signal is present. This,in turn,requires the circuit being driven by the RXDATA pin to be able to process noise(and signals)continuously.This can be a problem if RXDATA is driving a circuit that must “sleep”when data is not present to conserve power,or when it its necessary to minimize false interrupts to a multitasking processor. In this case,noise can be greatly reduced by increasing the thresh-old level,but at the expense of sensitivity.The best3dB bandwidth for the low-pass filter is also affected by the threshold level setting of DS1.The bandwidth must be increased as the threshold is in-creased to minimize data pulse-width variations with signal ampli-tude.Data slicer DS2can overcome this compromise once the signal level is high enough to enable its operation.DS2is a“dB-below-peak”slicer.The peak detector charges rapidly to the peak value of each data pulse,and decays slowly in between data pulses(1:1000 ratio).The slicer trip point can be set from0to120mV below this peak value with a resistor between RREF and THLD2.A threshold of60mV is the most common setting,which equates to“6dB below peak”when RFA1and RFA2are running a50%-50%duty cycle. Slicing at the“6dB-below-peak”point reduces the signal amplitude to data pulse-width variation,allowing a lower3dB filter bandwidth to be used for improved sensitivity.DS2is best for ASK modulation where the transmitted waveform has been shaped to minimize signal bandwidth(TR1100).However, DS2is subject to being temporarily“blinded”by strong noise pulses, which can cause burst data errors.Note that DS1is active when DS2is used,as RXDATA is the logical AND of the DS1and DS2 outputs.DS2can be disabled by leaving THLD2disconnected.A non-zero DS1threshold is required for proper AGC operation. AGC ControlThe output of the Peak Detector also provides an AGC Reset signal to the AGC Control function through the AGC comparator.The pur-pose of the AGC function is to extend the dynamic range of the re-ceiver,so that two transceivers can operate close together when running ASK and/or high data rate modulation.The onset of satura-tion in the output stage of RFA1is detected and generates the AGC Set signal to the AGC Control function.The AGC Control function then selects the5dB gain mode for RFA1.The AGC Comparator will send a reset signal when the Peak Detector output(multiplied by0.8)falls below the threshold voltage for DS1.A capacitor at the AGCCAP pin avoids AGC“chattering”during the time it takes for the signal to propagate through the low-pass filter and charge the peak detector.The AGC capacitor also allows the hold-in time to be set longer than the peak detector decay time to avoid AGC chattering during runs of“0”bits in the received data stream.Note that AGC operation requires the peak detector to be functioning,even if DS2is not being used.AGC operation can be defeated by connecting the AGCCAP pin to Vcc.The AGC can be latched ON once engaged by connecting a150kilohm resistor be-tween the AGCCAP pin and ground in lieu of a capacitor. Receiver Pulse Generator and RF Amplifier BiasThe receiver amplifier-sequence operation is controlled by the Pulse Generator&RF Amplifier Bias module,which in turn is controlled by the PRATE and PWIDTH input pins,and the Power Down(sleep) Control Signal from the Modulation&Bias Control function.In the low data rate mode,the interval between the falling edge of one RFA1ON pulse to the rising edge of the next RFA1ON pulse t PRI is set by a resistor between the PRATE pin and ground.The in-terval can be adjusted between0.1and5µs.In the high data rate mode(selected at the PWIDTH pin)the receiver RF amplifiers oper-ate at a nominal50%-50%duty cycle.In this case,the start-to-start period t PRC for ON pulses to RFA1are controlled by the PRATE re-sistor over a range of0.1to1.1µs.In the low data rate mode,the PWIDTH pin sets the width of the ON pulse t PW1to RFA1with a resistor to ground(the ON pulse widtht PW2to RFA2is set at1.1times the pulse width to RFA1in the low data rate mode).The ON pulse width t PW1can be adjusted between 0.55and1µs.However,when the PWIDTH pin is connected to Vcc through a1M resistor,the RF amplifiers operate at a nominal50%-50%duty cycle,facilitating high data rate operation(TR1100). In this case,the RF amplifiers are controlled by the PRATE resistor as described above.Both receiver RF amplifiers are turned off by the Power Down Con-trol Signal,which is invoked in the sleep and transmit modes. Transmitter ChainThe transmitter chain consists of a SAW delay line oscillator fol-lowed by a modulated buffer amplifier.The SAW filter suppresses transmitter harmonics to the antenna.Note that the same SAW de-vices used in the amplifier-sequenced receiver are reused in the transmit modes.Transmitter operation supports two modulation formats,on-off keyed(OOK)modulation,and amplitude-shift keyed(ASK)modula-tion which is normally used by the TR1100.When OOK modulation is chosen,the transmitter output turns completely off between“1”data pulses.When ASK modulation is chosen,a“1”pulse is repre-sented by a higher transmitted power level,and a“0”is represented by a lower transmitted power level.OOK modulation provides com-patibility with first-generation ASH technology,and provides for power conservation.ASK modulation must be used for high data rates(data pulses less than30µs).ASK modulation also reduces the effects of some types of interference and allows the transmitted pulses to be shaped to control modulation bandwidth.The modulation format is chosen by the state of the CNTRL0and the CNTRL1mode control pins,as discussed below.When either modulation format is chosen,the receiver RF amplifiers are turned off.In the OOK mode,the delay line oscillator amplifier TXA1and buffer amplifier TXA2are turned off when the voltage to the TXMOD input falls below220mV.In the OOK mode,the data rate is limited by the turn-on and turn-off times of the delay line oscillator,which are12and6µs respectively.In the ASK mode TXA1is biased ON continuously,and the output of TXA2is modulated by the TXMOD input current.Minimum output power occurs in the ASK mode when the modulation driver sinks about10µA of current from the TXMOD pin.The transmitter RF output power is proportional to the input current to the TXMOD pin.A series resistor is used to adjust the peak trans-mitter output power.0dBm of output power requires about450µA of input current.Transceiver Mode ControlThe four transceiver operating modes–receive,transmit ASK, transmit OOK,and power-down(sleep),are controlled by the Modu-lation&Bias Control function,and are selected with the CNTRL1and CNTRL0control pins.Setting CNTRL1and CNTRL0both high place the unit in the receive mode.Setting CNTRL1high and CNTRL0low place the unit in the ASK transmit mode(TR1100). Setting CNTRL1low and CNTRL0high place the unit in the OOK transmit mode.Setting CNTRL1and CNTRL0both low place the unit in the power-down(sleep)mode.Note that the resistor driving TXMOD must be low in the receive and power-down modes.The PWIDTH resistor must also be low in the power down mode to mini-mize TRL1and CNTRL0are CMOS compatible inputs. These inputs must be held at a logic level;they cannot be left un-connected.Transceiver Event TimingTransceiver event timing is summarized in Table1.Please refer to this table for the following discussions.Turn-On TimingThe maximum time t PR required for the receive function to become operational at turn on is influenced by two factors.All receiver cir-cuitry will be operational5ms after the supply voltage reaches2.2Vdc.The BBOUT-CMPIN coupling-capacitor is then DC stabi-lized in3time constants(3*t BBC).The total turn-on time to stable re-ceiver operation for a10ms power supply rise time is:t PR=15ms+3*t BBCThe maximum time required for either the OOK or ASK transmitter mode to become operational is5ms after the supply voltage reaches2.2Vdc.Receive-to-Transmit TimingAfter turn on,the maximum time required to switch from receive to either transmit mode is12µs.Most of this time is due to the start-up of the transmitter oscillator.Transmit-to-Receive TimingThe maximum time required to switch from the OOK or ASK trans-mit mode to the receive mode is3*t BBC,where t BBC is the BBOUT-CMPIN coupling-capacitor time constant.When the operating tem-perature is limited to60o C,the time required to switch from transmit to receive is dramatically less for short transmissions,as less charge leaks away from the BBOUT-CMPIN coupling capacitor. Sleep and Wake-Up TimingThe maximum transition time from the receive mode to thepower-down(sleep)mode t RS is10µs after CNTRL1and CNTRL0 are both low(1µs fall time).The maximum transition time from either transmit mode to the sleep mode(t TOS and t TAS)is10µs after CNTRL1and CNTRL0are both low(1µs fall time).The maximum transition time t SR from the sleep mode to the receive mode is3*t BBC,where t BBC is the BBOUT-CMPIN coupling-capacitor time constant.When the operating temperature is limited to60o C, the time required to switch from sleep to receive is dramatically less for short sleep times,as less charge leaks away from the BBOUT-CMPIN coupling capacitor.The maximum time required to switch from the sleep mode to either transmit mode(t STO and t STA)is16µs.Most of this time is due to the start-up of the transmitter oscillator.AGC TimingThe maximum AGC engage time t AGC is5µs after the reception of a -30dBm RF signal with a1µs envelope rise time.The minimum AGC hold-in time is set by the value of the capacitor at the AGCCAP pin.The hold-in time t AGH=C AGC/19.1,where t AGH is inµs and C AGC is in pF.Peak Detector TimingThe Peak Detector attack time constant is set by the value of the ca-pacitor at the PKDET pin.The attack time t PKA=C PKD/4167,where t PKA is inµs and C PKD is in pF.The Peak Detector decay time con-stant t PKD=1000*t PKA.Pulse Generator TimingIn the low data rate mode,the interval t PRI between the falling edge of an ON pulse to the first RF amplifier and the rising edge of the next ON pulse to the first RF amplifier is set by a resistor R PR be-tween the PRATE pin and ground.The interval can be adjusted be-tween0.1and5µs with a resistor in the range of51K to2000K. The value of the R PR is given by:R PR=404*t PRI+10.5,where t PRI is inµs,and R PR is in kilohmsIn the high data rate mode normally use by the TR1100(selected at the PWIDTH pin),the receiver RF amplifiers operate at a nominal 50%-50%duty cycle.In this case,the period t PRC from the start of an ON pulse to the first RF amplifier to the start of the next ON pulse to the first RF amplifier is controlled by the PRATE resistor over a range of0.1to1.1µs using a resistor of11K to220K.In this case R PR is given by:R PR=198*t PRC-8.51,where t PRC is inµs and R PR is in kilohmsIn the low data rate mode,the PWIDTH pin sets the width of the ON pulse to the first RF amplifier t PW1with a resistor R PW to ground(the ON pulse width to the second RF amplifier t PW2is set at1.1times the pulse width to the first RF amplifier in the low data rate mode). The ON pulse width t PW1can be adjusted between0.55and1µs with a resistor value in the range of200K to390K.The value ofR PW is given by:R PW=404*t PW1-18.6,where t PW1is inµs and R PW is in kilohms However,when the PWIDTH pin is connected to Vcc through a1M resistor,the RF amplifiers operate at a nominal50%-50%duty cy-cle,facilitating high data rate operation.In this case,the RF amplifi-ers are controlled by the PRATE resistor as described above.LPF Group DelayThe low-pass filter group delay is a function of the filter3dB band-width,which is set by a resistor R LPF to ground at the LPFADJ pin. The minimum3dB bandwidth f LPF=1445/R LPF,where f LPF is in kHz, and R LPF is in kilohms.The maximum group delay t FGD=1750/f LPF=1.21*R LPF,where t FGD is inµs,f LPF in kHz,and R LPF in kilohms.a n s c e i v e r E v e n t T i m i n g ,3.0V d c ,-40t o +850CT a b l e 1file:tr1100za.vp,2003.08.19revNote:Specifications subject to change withoutnotice.W。