DZXL03_运放参数&波形new

LTC6363 系列精密、低功耗差分放大器/ADC 驱动器系列特点⏹提供用户设置增益或0.5V/V、1V/V、2V/V的固定增益⏹折合到输入端噪声：2.9nV/√Hz⏹电源电流：2mA（最大值）⏹增益误差：45ppm（最大值）⏹增益误差漂移：0.5ppm/°C（最大值）⏹CMRR：94dB（最小值）⏹失调电压：100µV（最大值）⏹输入失调电流：50nA（最大值）⏹快速建立时间：720ns 至18 位，8V P–P输出⏹电源电压范围：2.8V (±1.4V) 至11V (±5.5V) ⏹差分轨到轨输出⏹输入共模范围包含地⏹低失真：115dB SFDR，2kHz 时，18V P–P⏹增益带宽积：500MHz⏹–3dB 带宽：35MHz⏹低功耗关断：20µA (V S = 3V)⏹8 引脚MSOP 和2 mm × 3mm 8 引脚DFN 封装应用⏹20 位、18 位和16 位SAR ADC 驱动器⏹单端至差分转换⏹低功耗ADC 驱动器⏹电平转换器⏹差分线路驱动器⏹电池供电仪器仪表说明LTC®6363系列包括四款全差分、低功耗、低噪声放大器，提供轨到轨输出，针对SAR ADC 驱动进行了优化。

LTC6363 是一款独立的差分放大器，其增益通常利用四个外部电阻设置。

LTC6363–0.5、LTC6363–1 和LTC6363–2 均有内部匹配电阻，形成增益分别为0.5V/V、1V/V 和2V/V 的固定增益模块。

每个固定增益放大器都有激光调整的精密片内电阻，可实现精确、超稳定的增益和出色的CMRR。

系列选型表产品型号增益配置LTC6363 用户设置LTC6363–0.5 0.5V/VLTC6363–1 1V/VLTC6363–22V/V所有注册商标和商标均属各自所有人所有。

典型应用从以地为基准的单端输入到LTC2378–20 SAR ADC 的直流耦合接口LTC6363–1 驱动LTC2378–20f IN = 2kHz，–1dBFS，131k 点FFTLTC6363 系列 绝对最大额定值（注释 1）总电源电压 (V + – V –) ........................................... 12V 输入电压（+IN 、–IN ）（注释 2）LTC6363–0.5 ........ (V –) – 14.9V 至 (V +) + 14.9V LTC6363–1 ........... (V –) – 11.1V 至 (V +) + 11.1V LTC6363–2 ........... (V –) – 7.45V 至 (V +) + 7.45V 输入电流（+IN 、–IN ）LTC6363（注释 3）............................................................................. ±10mA 输入电流（V OCM 、SHDN ）（注释 3） .................................................. ±10mA 输出短路持续时间（注释 4） ......................................... 受散热限制 工作温度范围（注释 5）LTC6363I/LTC6363I–0.5/LTC6363I–1/ LTC6363I–2 ................................... –40°C 至 85°C LTC6363H/LTC6363H–0.5/LTC6363H–1/LTC6363H–2 ............................... –40°C 至 125°C 额定温度范围（注释 6）LTC6363I/LTC6363I–0.5/LTC6363I–1/LTC6363I–2 .................................. –40°C 至 85°C LTC6363H/LTC6363H–0.5/LTC6363H–1/LTC6363H–2............................... –40°C 至 125°C 最高结温 .............................................................. 150°C 存储温度范围 .................................. –65°C 至 150°C MSOP 引脚温度（焊接，10 秒） ................ 300°C引脚配置LTC6363LTC6363LTC6363–0.5/LTC6363–1/LTC6363–2订购信息 /product/LTC6363#orderinfo管装卷带和卷盘 器件标识* 封装说明温度范围 LTC6363IMS8#PBF LTC6363IMS8#TRPBF LTGSQ 8 引脚塑料 MSOP –40°C 至 85°C LTC6363HMS8#PBFLTC6363HMS8#TRPBFLTGSQ8 引脚塑料 MSOP –40°C 至 125°C LTC6363IMS8–0.5#PBF LTC6363IMS8–0.5#TRPBF LTGST 8 引脚塑料 MSOP –40°C 至 85°C LTC6363HMS8–0.5#PBF LTC6363HMS8–0.5#TRPBF LTGST 8 引脚塑料 MSOP –40°C 至 125°C LTC6363IMS8–1#PBF LTC6363IMS8–1#TRPBF LTGSR 8 引脚塑料 MSOP –40°C 至 85°C LTC6363HMS8–1#PBF LTC6363HMS8–1#TRPBF LTGSR 8 引脚塑料 MSOP –40°C 至 125°C LTC6363IMS8–2#PBF LTC6363IMS8–2#TRPBF LTGSS 8 引脚塑料 MSOP –40°C 至 85°C LTC6363HMS8–2#PBFLTC6363HMS8–2#TRPBFLTGSS8 引脚塑料 MSOP–40°C 至 125°CLTC6363 系列订购信息无铅表面处理卷带和卷盘（迷你型）卷带和卷盘器件标识*封装说明温度范围LTC6363IDCB#TRMPBF LTC6363IDCB#TRPBF LGVG 8 引脚(2mm × 3mm) 塑料DFN –40°C 至85°CLTC6363HDCB#TRMPBF LTC6363HDCB#TRPBF LGVG 8 引脚(2mm × 3mm) 塑料DFN –40°C 至125°CTRM = 500 片。

运放参数介绍1.1主要直流指标输入失调电压VIO：输入失调电压定义为集成运放输出端电压为零时，两个输入端之间所加的补偿电压。

输入失调电压实际上反映了运放内部的电路对称性，对称性越好，输入失调电压越小。

输入失调电压是运放的一个十分重要的指标，特别是精密运放或是用于直流放大时。

输入失调电压与制造工艺有一定关系，其中双极型工艺（即上述的标准硅工艺）的输入失调电压在±1~10mV之间；采用场效应管做输入级的，输入失调电压会更大一些。

对于精密运放，输入失调电压一般在1mV以下。

输入失调电压越小，直流放大时中间零点偏移越小，越容易处理。

所以对于精密运放是一个极为重要的指标。

输入失调电压的温度漂移（简称输入失调电压温漂）αVIO：输入失调电压的温度漂移定义为在给定的温度范围内，输入失调电压的变化与温度变化的比值。

这个参数实际是输入失调电压的补充，便于计算在给定的工作范围内，放大电路由于温度变化造成的漂移大小。

一般运放的输入失调电压温漂在±10~20μV/℃之间，精密运放的输入失调电压温漂小于±1μV输入偏置电流IIB：输入偏置电流定义为当运放的输出直流电压为零时，其两输入端的偏置电流平均值。

输入偏置电流对进行高阻信号放大、积分电路等对输入阻抗有要求的地方有较大的影响。

输入偏置电流与制造工艺有一定关系，其中双极型工艺（即上述的标准硅工艺）的输入偏置电流在±10nA~1μA之间；采用场效应管做输入级的，输入偏置电流一般低于1nA。

输入失调电流IIO：输入失调电流定义为当运放的输出直流电压为零时，其两输入端偏置电流的差值。

输入失调电流同样反映了运放内部的电路对称性，对称性越好，输入失调电流越小。

输入失调电流是运放的一个十分重要的指标，特别是精密运放或是用于直流放大时。

输入失调电流大约是输入偏置电流的百分之一到十分之一。

输入失调电流对于小信号精密放大或是直流放大有重要影响，特别是运放外部采用较大的电阻（例如10k欧姆或更大时），输入失调电流对精度的影响可能超过输入失调电压对精度的影响。

Description The LM2901/2903 series comparators consist of four and two independent precision voltage comparators with very low input offset voltage specification. They are designed to operate from a single power supply over a wide range of voltages; however operation from split power supplies is also possible. They offer low power supply current independent of the magnitude of the power supply voltage.The LM2901/2903 series comparators are designed to directly interface with TTL and CMOS. When operating from both plus and minus power supplies, the LM2901/2903 series comparators will directly interface with MOS logic where their low power drain is a distinct advantage over standard comparators.The dual devices are available in SO-8, TSSOP-8, and MSOP-8, and the quad devices available in SO-14 and TSSOP-14 with industry standard pinouts. Both use green mold compound as standard.Features•Wide Power Supply Range: ▪ Single Supply: 2V to 36V ▪ Dual Supplies: ±1.0V to ±18V•Very Low Supply Current Drain—Independent of Supply Voltage ▪ LM2903: 0.6mA ▪ LM2901: 0.9mA• Low Input Bias Current: 25nA • Low Input Offset Current: ±5nA •Typical Offset Voltage: ▪ Non-A Device: 2mV ▪ A Device: 1mV• Common-Mode Input Voltage Range Includes Ground• Differential Input Voltage Range Equal to the Power Supply Voltage•Low Output Saturation Voltage: ▪ LM2903: 200mV at 4mA ▪ LM2901: 100mV at 4mA• Output Voltage Compatible with TTL, MOS and CMOS• Totally Lead-Free & Fully RoHS Compliant (Notes 1 & 2) •Halogen and Antimony Free. “Green” Device (Note 3)Pin Assignments(Top View)SO-8/TSSOP-8/MSOP-81OUT V CC2IN-2IN+1IN-1IN+GND2OUTLM2903/ LM2903A(Top View)SO-14/TSSOP-141OUT 3OUT GND4IN+3IN-3IN+4IN-2OUTV CC2IN-2IN+1IN-1IN+4OUTLM2901/ LM2901ANotes: 1. No purposely added lead. Fully EU Directive 2002/95/EC (RoHS), 2011/65/EU (RoHS 2) & 2015/863/EU (RoHS 3) compliant.2. See https:///quality/lead-free/ for more information about Diodes Incorporated’s definitions of Halogen- and Antimony-free, "Green" and Lead-free.3. Halogen- and Antimony-free "Green” products are defined as those which contain <900ppm bromine, <900ppm chlorine (<1500ppm total Br + Cl) and <1000ppm antimony compounds.Schematic DiagramOUTPUT-INPUTFunctional Block Diagram of LM2901/2901A/2903/2903A(Each Comparator)Pin DescriptionsLM2901, LM2901APin Name Pin # Function1OUT 1 Channel 1 Output2OUT 2 Channel 2 OutputV CC 3 Chip Supply Voltage2IN- 4 Channel 2 Inverting Input2IN+ 5 Channel 2 Non-Inverting Input1IN- 6 Channel 1 Inverting Input1IN+ 7 Channel 1 Non-Inverting Input3IN- 8 Channel 3 Inverting Input3IN+ 9 Channel 3 Non-Inverting Input4IN- 10 Channel 4 Inverting Input4IN+ 11 Channel 4 Non-Inverting InputGND 12 Ground4OUT 13 Channel 4 Output3OUT 14 Channel 3 OutputLM2903, LM2903A1OUT 1 Channel 1 Output1IN- 2 Channel 1 Inverting Input1IN+ 3 Channel 1 Non-Inverting InputGND 4 Ground2IN+ 5 Channel 2 Non-Inverting Input2IN- 6 Channel 2 Inverting Input2OUT 7 Channel 2 OutputV CC8 Chip Supply VoltageNotes: 4. Stresses beyond those listed under Absolute Maximum Ratings can cause permanent damage to the device. These are stress ratings only; functional operation of the device at these or any other conditions beyond those indicated under recommended operating conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods can affect device reliability.5. Short circuits from outputs to V CC can cause excessive heating and eventual destruction.6. Maximum power dissipation is a function of T J(MAX), θJA, and T A. The maximum allowable power dissipation at any allowable ambient temperature isP D = (T J(MAX)− T A)/θJA. Operating at the absolute maximum T J of 150°C can affect reliability.7. Human body model, 1.5kΩ in series with 100pF.Notes:8. Typical values represent the most likely parametric norm as determined at the time of characterization. Actual typical values may vary over time and will also depend on the application and configuration. The typical values are not tested and are not guaranteed on shipped production material.9. All limits are guaranteed by testing or statistical analysis. Limits over the full temperature are guaranteed by design, but not tested in production.10.V O ≅1.4V, R S= 0Ω with V CC from 5V to 30V;11.The direction of the input current is out of the IC due to the PNP input stage. This current is essentially constant, independent of the state of the output sono loading change exists on the input lines.12.The input common-mode voltage of either input signal voltage should not be allowed to go negative by more than 0.3V (@ +25°C). The upper end of thecommon-mode voltage range is V CC -1.5V (@ +25°C), but either or both inputs can go to +36V without damage, independent of the magnitude of V CC.13. The response time specified is for a 100mV step input with 5mV overdrive. For larger overdrive signals 300ns can be obtained, see typical performancecharacteristics.14. Positive excursions of input voltage may exceed the power supply level. As long as other voltages remain within the common mode range, thecomparator will provide a proper output stage. The low voltage state must not be less than -0.3V (or 0.3V below the magnitude of the negative powersupply, if used).Notes:8. Typical values represent the most likely parametric norm as determined at the time of characterization. Actual typical values may vary over time and will also depend on the application and configuration. The typical values are not tested and are not guaranteed on shipped production material.9. All limits are guaranteed by testing or statistical analysis. Limits over the full temperature are guaranteed by design, but not tested in production.10.V O ≅1.4V, R S= 0Ω with V CC from 5V to 30V;11.The direction of the input current is out of the IC due to the PNP input stage. This current is essentially constant, independent of the state of the output sono loading change exists on the input lines.12.The input common-mode voltage of either input signal voltage should not be allowed to go negative by more than 0.3V (@ +25°C). The upper end of thecommon-mode voltage range is V CC -1.5V (@ +25°C), but either or both inputs can go to +36V without damage, independent of the magnitude of V CC.13. The response time specified is for a 100mV step input with 5mV overdrive. For larger overdrive signals 300ns can be obtained, see typical performancecharacteristics.14. Positive excursions of input voltage may exceed the power supply level. As long as other voltages remain within the common mode range, thecomparator will provide a proper output stage. The low voltage state must not be less than -0.3V (or 0.3V below the magnitude of the negative powersupply, if used).Performance CharacteristicsSupply Current vs. Supply Voltage Supply Current vs. Supply VoltageSupply Current vs. Temperature Supply Current vs. TemperatureOutput Saturation Voltage vs. Sink Current Output Saturation Voltage vs. Sink CurrentPerformance Characteristics (continued)Response Time for Various Input Overdrive Response Time for Various Input OverdriveInput Current vs. Supply Voltage Input Current vs. TemperatureApplication InformationGeneral InformationThe LM2901/2903 series comparators are high-gain, wide bandwidth devices. Like most comparators, the series can easily oscillate if the output lead is inadvertently allowed to capacitive couple to the inputs via stray capacitance. This shows up only during the output voltage transition intervals as the comparators change states. Standard PC board layout is helpful as it reduces stray input-output coupling. Reducing the input resistors to <10kΩreduces the feedback signal levels. Finally, adding even a small amount (1.0mV to 10mV) of positive feedback (hysteresis) causes such a rapid transition that oscillations, due to stray feedback, are not possible. Simply socketing the IC and attaching resistors to the pins will cause input-output oscillations during the small transition intervals unless hysteresis is used. If the input signal is a pulse waveform, with relatively fast rise and fall times, hysteresis is not required. All input pins of any unused comparators should be tied to the negative supply.The bias network of the LM2901/2903 series comparators establishes a quiescent current independent of the magnitude of the power supply voltage over the range of from 2.0V DC to 30V DC.The differential input voltage may be larger than V CC without damaging the device. Protection should be provided to prevent the input voltages from going negative more than -0.3V DC (@ +25°C). An input clamp diode can be used as shown in the applications section.The output of the LM2901/2903 series comparators is the uncommitted collector of a grounded-emitter NPN output transistor. Many collectors can be tied together to provide an output ORing function. An output pull-up resistor can be connected to any available power supply voltage within the permitted supply voltage range and there is no restriction on this voltage due to the magnitude of the voltage applied to the V CC terminal of LM2901/2903 series comparator package. The output can also be used as a simple SPST switch to ground (when a pull-up resistor is not used).The amount of current the output device can sink is limited by the drive available (which is independent of V CC) and the β of this device. When the maximum current limit is reached (approximately 16mA), the output transistor will come out of saturation and the output voltage will rise very rapidly. The output saturation voltage is limited by the approximately 60ΩR SAT of the output transistor. The low offset voltage of the output transistor (1.0mV) allows the output to clamp essentially to ground level for small load currents.Typical Application Circuit (V CC = 5.0V DC )Typical Application Circuit(V CC = 5.0V DC) (continued)Typical Application Circuit (V CC = 5.0V DC ) (continued)Ordering Information (Note 15)LM290X X XXX - 13ChannelGrade3 : Dual PackingPackageS : SO-813 : Tape & Reel1 : Quad A : Low V IOBlank : Normal S14 : SO-14T14 : TSSOP-14M8: MSOP-8TH: TSSOP-8Part Number Package CodePackaging 13” Tape and ReelQuantity Part Number SuffixLM2901T14-13 T14 TSSOP-14 2500/Tape & Reel -13 LM2901AT14-13 T14 TSSOP-14 2500/Tape & Reel -13 LM2901S14-13 S14 SO-14 2500/Tape & Reel -13 LM2901AS14-13 S14 SO-14 2500/Tape & Reel -13 LM2903S-13 S SO-8 2500/Tape & Reel -13 LM2903AS-13 S SO-8 2500/Tape & Reel -13 LM2903AM8-13 M8 MSOP-8 2500/Tape & Reel -13 LM2903M8-13 M8 MSOP-8 2500/Tape & Reel -13 LM2903ATH-13 TH TSSOP-8 2500/Tape & Reel -13 LM2903TH-13THTSSOP-82500/Tape & Reel-13Note: 15. For packaging details, go to our website at /products/packages.html.Marking Information (1) TSSOP-14 and SO-14(2) SO-8(3) MSOP-8 & TSSOP-8Package Outline DimensionsPlease see /package-outlines.html for the latest version.SO-8SO-8Dim Min Max A − 1.75 A1 0.10 0.20 A2 1.30 1.50 A3 0.15 0.25 b 0.3 0.5 D 4.85 4.95 E 5.90 6.10 E1 3.85 3.95 e 1.27 Typ h − 0.35 L 0.62 0.82θ0° 8° All Dimensions in mmTSSOP-8MSOP-8MSOP-8Dim Min Max Typ A − 1.10 − A1 0.05 0.15 0.10 A2 0.75 0.95 0.86 A3 0.29 0.49 0.39 b 0.22 0.38 0.30 c 0.08 0.23 0.15 D 2.90 3.10 3.00 E 4.70 5.10 4.90 E1 2.90 3.10 3.00 E3 2.85 3.05 2.95 e − −0.65 L 0.400.80 0.60 a 0° 8° 4° x − − 0.750 y − − 0.750 All Dimensions in mmGauge Plane Seating PlaneDetail ‘A’Detail CSee Detail CDetail CPackage Outline Dimensions (continued)Please see /package-outlines.html for the latest version.SO-14SO-14Dim Min Max A 1.47 1.73 A1 0.10 0.25 A2 1.45 Typ B 0.33 0.51 D 8.53 8.74 E 3.80 3.99 e 1.27 Typ H 5.80 6.20 L 0.38 1.27θ0° 8° All Dimensions in mmTSSOP-14TSSOP-14 Dim Min Max a1 7° (4X) a2 0° 8° A 4.9 5.10 B 4.30 4.50 C − 1.2 D 0.8 1.05 F 1.00 Typ F1 0.45 0.75 G 0.65 Typ K 0.19 0.30 L 6.40 Typ All Dimensions in mmDetail “A”Pin# 1 Detail ‘A’Gauge Plane Seating PlaneSuggested Pad LayoutPlease see /package-outlines.html for the latest version.SO-8TSSOP-8MSOP-8XC2YSuggested Pad Layout (continued)Please see /package-outlines.html for the latest version.SO-14TSSOP-14XC1XC1。

CD4000 双3输入端或非门单非门CD4001 四2输入端或非门CD4002 双4输入端或非门CD4006 18位串入/串出移位存放器CD4007 双互补对加反相器CD4008 4位超前进位全加器CD4009 六反相缓冲/变换器CD4010 六同相缓冲/变换器CD4011 四2输入端与非门CD4012 双4输入端与非门CD4013 双主-从D型触发器CD4014 8位串入/并入-串出移位存放器CD4015 双4位串入/并出移位存放器CD4016 四传输门CD4017 十进制计数/分配器CD4018 可预制1/N计数器CD4019 四与或选择器CD4020 14级串行二进制计数/分频器CD4021 08位串入/并入-串出移位存放器CD4022 八进制计数/分配器CD4023 三3输入端与非门CD4024 7级二进制串行计数/分频器CD4025 三3输入端或非门CD4026 十进制计数/7段译码器CD4027 双J-K触发器CD4028 BCD码十进制译码器CD4029 可预置可逆计数器CD4030 四异或门CD4031 64位串入/串出移位存储器CD4032 三串行加法器CD4033 十进制计数/7段译码器CD4034 8位通用总线存放器CD4035 4位并入/串入-并出/串出移位存放CD4038 三串行加法器CD4040 12级二进制串行计数/分频器CD4041 四同相/反相缓冲器CD4042 四锁存D型触发器CD4043 三态R-S锁存触发器("1"触发) CD4044 四三态R-S锁存触发器("0"触发) CD4046 锁相环CD4047 无稳态/单稳态多谐振荡器CD4048 四输入端可扩展多功能门CD4049 六反相缓冲/变换器CD4050 六同相缓冲/变换器CD4051 八选一模拟开关CD4052 双4选1模拟开关CD4053 三组二路模拟开关CD4054 液晶显示驱动器CD4055 BCD-7段译码/液晶驱动器CD4056 液晶显示驱动器CD4059 “N〞分频计数器 NSC/TICD4060 14级二进制串行计数/分频器CD4063 四位数字比拟器CD4066 四传输门CD4067 16选1模拟开关CD4068 八输入端与非门/与门CD4069 六反相器CD4070 四异或门CD4071 四2输入端或门CD4072 双4输入端或门CD4073 三3输入端与门CD4075 三3输入端或门CD4076 四D存放器CD4077 四2输入端异或非门CD4078 8输入端或非门/或门CD4081 四2输入端与门CD4082 双4输入端与门CD4085 双2路2输入端与或非门CD4086 四2输入端可扩展与或非门CD4089 二进制比例乘法器CD4093 四2输入端施密特触发器CD4095 三输入端J-K触发器CD4096 三输入端J-K触发器CD4097 双路八选一模拟开关CD4098 双单稳态触发器CD4099 8位可寻址锁存器CD40100 32位左/右移位存放器CD40101 9位奇偶较验器CD40102 8位可预置同步BCD减法计数器CD40103 8位可预置同步二进制减法计数器CD40104 4位双向移位存放器CD40105 先入先出FI-FD存放器CD40106 六施密特触发器CD40107 双2输入端与非缓冲/驱动器CD40108 4字×4位多通道存放器CD40109 四低-高电平位移器CD40110 十进制加/减,计数,锁存,译码驱动CD40147 10-4线编码器CD40160 可预置BCD加计数器CD40161 可预置4位二进制加计数器CD40162 BCD加法计数器CD40163 4位二进制同步计数器CD40174 六锁存D型触发器CD40175 四D型触发器CD40181 4位算术逻辑单元/函数发生器CD40182 超前位发生器CD40192 可预置BCD加/减计数器(双时钟) CD40193 可预置4位二进制加/减计数器CD40194 4位并入/串入-并出/串出移位存放CD40195 4位并入/串入-并出/串出移位存放CD40208 4×4多端口存放器CD4501 4输入端双与门与2输入端或非门CD4502 可选通三态输出六反相/缓冲器CD4503 六同相三态缓冲器CD4504 六电压转换器CD4506 双二组2输入可扩展或非门CD4508 双4位锁存D型触发器CD4510 可预置BCD码加/减计数器CD4511 BCD锁存,7段译码,驱动器CD4512 八路数据选择器CD4513 BCD锁存,7段译码,驱动器(消隐) CD4514 4位锁存,4线-16线译码器CD4515 4位锁存,4线-16线译码器CD4516 可预置4位二进制加/减计数器CD4517 双64位静态移位存放器CD4518 双BCD同步加计数器CD4519 四位与或选择器CD4520 双4位二进制同步加计数器CD4521 24级分频器CD4522 可预置BCD同步1/N计数器CD4526 可预置4位二进制同步1/N计数器CD4527 BCD比例乘法器CD4528 双单稳态触发器CD4529 双四路/单八路模拟开关CD4530 双5输入端优势逻辑门CD4531 12位奇偶校验器CD4532 8位优先编码器CD4536 可编程定时器CD4538 精细双单稳CD4539 双四路数据选择器CD4541 可编程序振荡/计时器CD4543 BCD七段锁存译码,驱动器CD4544 BCD七段锁存译码,驱动器CD4547 BCD七段译码/大电流驱动器CD4549 函数近似存放器CD4551 四2通道模拟开关CD4553 三位BCD计数器CD4555 双二进制四选一译码器/别离器CD4556 双二进制四选一译码器/别离器CD4558 BCD八段译码器CD4560 "N"BCD加法器CD4561 "9"求补器CD4573 四可编程运算放大器CD4574 四可编程电压比拟器CD4575 双可编程运放/比拟器CD4583 双施密特触发器CD4584 六施密特触发器CD4585 4位数值比拟器CD4599 8位可寻址锁存器CD22100 4×4×1交叉点开关0206A 天线开关集成电路03VFG9 发射压控振荡集成电路1021AC 发射压控振荡集成电路1097C 升压集成电路140N 电源取样比拟放大集成电路14DN363 伺服控制集成电路15105 充电控制集成电路15551 管理卡升压集成电路1710 视频信号处理集成电路1N706 混响延时集成电路20810－F6096 存储集成电路2252B 微处理集成电路2274 延迟集成电路24C01ACEA 存储集成电路24C026 存储集成电路24C04 存储集成电路24C64 码片集成电路24LC16B 存储集成电路24LC65 电可改写编程只读存储集成电路27C1000PC－12 存储集成电路27C2000QC－90 存储集成电路27C20T 存储集成电路27C512 电可改写编程只读存储集成电路2800 红外遥控信号接收集成电路28BV64 码片集成电路28F004 版本集成电路31085 射频电源集成电路32D54 电源、音频信号处理集成电路1732D75 电源、音频信号处理集成电路32D92 电源中频放大集成电路4066B 电子开关切换集成电路4094 移位存放串入、并出集成电路424260SDJ 存储集成电路4260 动态随机存储集成电路4270351/91B9905 中频放大集成电路4370341/90M9919 中频处理集成电路4464 存储集成电路4558 双运算放大集成电路4580D 双运算放大集成电路47C1638AN－U337 微处理集成电路47C1638AU－353 微处理集成电路47C432GP 微处理集成电路47C433AN－3888 微处理集成电路49/4CR1A 中频放大集成电路5101 天线开关集成电路5G052 发光二极管四位显示驱动集成电路5G24 运算放大集成电路5W01 双运算放大集成电路649/CRIA70612 中频放大集成电路673/3CR2A 多模转换集成电路74122 可重触发单稳态集成电路74HC04 逻辑与非门集成电路74HC04D 六反相集成电路74HC123 单稳态集成电路74HC125 端口功能扩展集成电路74HC14N 六反相集成电路74HC157A 多路转换集成电路74HC165 移相存放集成电路1874HC245 总线收发集成电路74HC32 或门四2输入集成电路74HC374八D 触发集成电路74HC573D 存储集成电路74HCT157 多路转换双输入集成电路74HCT4046A 压控振荡集成电路74HCT4538D 单稳态集成电路74HCT4538N 触发脉冲集成电路74HCT86D 异或门四2输入集成电路74HCU04 与非门集成电路74LS125 端口功能扩展集成电路74LS373 锁存集成电路74LS393 计数双四位二进制集成电路74LS74双D 触发集成电路78014DFP 系统控制处理集成电路811N 伴音阻容偏置集成电路83D33 压控振荡集成电路85712 场扫描信号校正处理集成电路85713 行扫描信号校正集成电路87C52 微处理集成电路87CK38N－3584 微处理集成电路87CK38N－3627 微处理集成电路89C52 系统控制处理集成电路89C55 系统控制处理集成电路93C66 电可改写编程只读存储集成电路93LC56 电可改写编程存储集成电路9821K03 系统控制集成电路A1642P 背景歌声消除集成电路A701 红外遥控信号接收集成电路A7950 场频识别集成电路19A8772AN 色差信号延迟处理集成电路A9109 功率放大集成电路AAB 电源集成电路ACA650 色度信号解调集成电路ACFP2 色度、亮度信号别离集成电路ACP2371 多伴音、多语言改善集成电路ACVP2205 色度、亮度信号别离集成电路AD1853 立体声数/模转换集成电路AD1858 音频解调集成电路AD722 视频编码集成电路ADC2300E 音频数/模转换集成电路ADC2300J 音频数/模转换集成电路ADC2310E 音频数/模转换集成电路ADV7172 视频编码集成电路ADV7175A 视频编码集成电路AE31201 频率显示集成电路AJ7080 射频调制集成电路AK4321－VF－E1 音频数/模转换集成电路AN1319 双高速电压比拟集成电路AN1358S 双运算放大集成电路AN1393 双运算放大集成电路AN1431T 稳压电源集成电路AN1452 音频前置放大集成电路AN1458S 双运算放大集成电路AN206 伴音中频与前置放大集成电路AN222 自动频率控制集成电路AN236 副载波信号处理集成电路AN239Q 图像、伴音中频放大集成电路AN247P 图像中频放大、AGC控制集成电路AN253P 调频/调幅中频放大集成电路20AN262 音频前置放大集成电路AN2661NK 视频信号处理集成电路AN2663K 视频信号处理集成电路AN272 音频功率放大集成电路AN2751FAP 视频信号处理集成电路AN281 色度解码集成电路AN2870FC 多功能控制集成电路AN295 行、场扫描信号处理集成电路AN301 伺服控制集成电路AN305 视频自动增益控制集成电路AN306 色度自动相位控制集成电路AN318 直流伺服控制集成电路AN320 频率控制、调谐显示驱动集成电路AN3215K 视频信号处理集成电路AN3215S 视频信号处理集成电路AN3224K 磁头信号记录放大集成电路AN3248NK 亮度信号记录、重放处理集成电路AN331 视频信号处理集成电路AN3311K 磁头信号放大集成电路AN3313 磁头信号放大集成电路AN3321S 录像重放信号处理集成电路AN3331K 磁头信号处理集成电路AN3337NSB 磁头信号放大集成电路AN3380K 磁头信号处理集成电路AN3386NK 磁头信号处理集成电路AN3495K 色度、亮度信号降噪集成电路AN355 伴音中频放大、检波集成电路AN3581S 视频驱动集成电路AN366 调频/调幅中频放大集成电路AN3791 移位控制集成电路21AN3792 磁鼓伺服控制接口集成电路AN3795 主轴伺服控制接口集成电路AN3814K 电机驱动集成电路AN4265 音频功率放大集成电路AN4558 运算放大集成电路AN5010 电子选台集成电路AN5011 电子选台集成电路AN5015K 电子选台集成电路AN5020 红外遥控信号接收集成电路AN5025S 红外遥控信号接收集成电路AN5026K 红外遥控信号接收集成电路AN5031 电调谐控制集成电路AN5034 调谐控制集成电路AN5036 调谐控制集成电路AN5043 调谐控制集成电路AN5071 频段转换集成电路AN5095K 电视信号处理集成电路AN5110 图像中频放大集成电路AN5130 图像中频、视频检波放大集成电路AN5138NK 图像、伴音中频放大集成电路AN5156K 电视信号处理集成电路AN5177NK 图像、伴音中频放大集成电路AN5179K 图像、伴音中频放大集成电路AN5183K 中频信号处理集成电路AN5195K 中频、色度、扫描信号处理集成电路AN5215 伴音信号处理集成电路AN5520 伴音中频放大与鉴频集成电路AN5222 伴音中频放大集成电路AN5250 伴音中频放大、鉴频与功率放大集成电路AN5262 音频前置放大集成电路22AN5265 音频功率放大集成电路AN5270 音频功率放大集成电路AN5273 双声道音频功率放大集成电路AN5274 双声道音频功率放大集成电路AN5275 中置、3D放大集成电路AN5285K 双声道前置放大集成电路AN5295NK 音频信号切换集成电路AN5312 视频、色度信号处理集成电路AN5313NK 视频、色度信号处理集成电路AN5342 图像水平轮廓校正集成电路AN5342FB 水平清晰度控制集成电路AN5344FBP 色度信号处理集成电路AN5348K 人工智能信号处理集成电路AN5385K 色差信号放大集成电路AN5410 行、场扫描信号处理集成电路AN5421 同步检测集成电路AN5422 行、场扫描信号处理集成电路AN5512 场扫描输出集成电路AN5515 场扫描输出集成电路AN5521 场扫描输出集成电路AN5532 场扫描输出集成电路AN5534 场扫描输出集成电路AN5551 枕形校正集成电路AN5560 场频识别集成电路AN5600K 中频、亮度、色度与扫描信号处理集成电路AN5601K 视频、色度、同步信号处理集成电路AN5607K 视频、色度、行场扫描信号处理集成电路AN5615 视频信号处理集成电路AN5620X 色度信号处理集成电路AN5621 场扫描输出集成电路23AN5625 色度信号处理集成电路AN5633K 色度信号处理集成电路AN5635 色度解码集成电路AN5635NS 色度解码集成电路AN5637 色度解码、亮度延迟集成电路AN5650 同步信号别离集成电路AN5682K 基色电子开关切换集成电路AN5693K 视频、色度、行场扫描信号处理集成电路AN5712 图像中频放大、AGC控制集成电路AN5722 图像中频放大、检波集成电路AN5732 伴音中频放大、鉴频集成电路AN5743 音频功率放大集成电路AN5750 行自动频率控制与振荡集成电路AN5757S 行扫描电源电压控制集成电路AN5762 场扫描振荡、输出集成电路AN5764 光栅水平位置控制集成电路AN5765 电源稳压控制集成电路AN5767 同步信号处理集成电路AN5768 光栅倾斜校正控制集成电路AN5769 行、场会聚控制集成电路AN5790N 行扫描信号处理集成电路AN5791 同步脉冲相位与脉宽调整集成电路AN5803 双声道立体声解调集成电路AN5836 双声道前置放大集成电路AN5858K 视频信号控制集成电路AN5862 视频信号控制集成电路AN5862S－E1 视频信号开关控制集成电路AN5870K 模拟信号切换集成电路AN5891K 音频信号处理集成电路AN614 行枕形校正集成电路24AN6210 双声道前置放大集成电路AN6306S 亮度信号处理集成电路AN6308 模拟电子开关集成电路AN6327 视频重放信号处理集成电路AN6341N 伺服控制集成电路AN6342N 基准分频集成电路AN6344 伺服控制集成电路AN6345 分频集成电路AN6346N 磁鼓伺服控制集成电路AN6350 磁鼓伺服控制集成电路AN6357N 主轴接口集成电路AN6361N 色度信号处理集成电路AN6367NK 色度信号处理集成电路AN6371S 自动相位控制集成电路AN6387 电机伺服控制集成电路AN6550 卡拉OK音频放大集成电路AN6554 四运算放大集成电路AN6561 双运算放大集成电路AN6562SG 双运算放大集成电路AN6609N 电机驱动集成电路AN6612 电机稳速控制集成电路AN6650 电机速度控制集成电路AN6651 电机速度控制集成电路AN6652 电机稳速控制集成电路AN6875 发光二极管五位显示驱动集成电路AN6877 发光二极管七位显示驱动集成电路AN6884 发光二极管五位显示驱动集成电路AN6886 发光二极管五位显示驱动集成电路AN6888 发光二极管显示驱动集成电路AN6914 双电压比拟集成电路25AN7085N5 单片录、放音集成电路AN7105 双声道音频功率放大集成电路AN7106K 双声道音频功率放大集成电路AN7108 单片立体声放音集成电路AN710S 单片放音集成电路AN7110E 音频功率放大集成电路AN7114 音频功率放大集成电路AN7116 音频功率放大集成电路AN7118 双声道音频功率放大集成电路AN7118S 双声道音频功率放大集成电路AN7120 音频功率放大集成电路AN7124 双声道音频功率放大集成电路AN7145 双声道音频功率放大集成电路AN7148 双声道音频功率放大集成电路AN7158N 音频功率放大7.5W×2集成电路AN7161N 音频功率放大集成电路AN7164 双声道音频功率放大集成电路AN7171NK 音频功率放大集成电路AN7205 调频/调谐与高频放大集成电路AN7220 调频/调幅中频放大集成电路AN7222 调频/调幅中频放大集成电路AN7223 调频/调幅中频放大集成电路AN7226 调频/调幅中频放大集成电路AN7256 调频/调谐与中频放大集成电路AN7311 双声道前置放大集成电路AN7312 双声道前置放大集成电路AN7315 双声道前置放大集成电路AN7315S 双声道前置放大集成电路AN7320 音频前置放大集成电路AN7396K 双声道前置放大集成电路26AN7397K 双声道前置放大集成电路AN7410 调频立体声多路解码集成电路AN7414 调频立体声解码集成电路AN7420N 调频立体声解码集成电路AN7470 调频立体声解码集成电路AN7805 三端电源稳压＋5V/1A集成电路AN7806 三端电源稳压＋6V/1A集成电路AN7807 三端电源稳压＋7V/1A集成电路AN7808 三端电源稳压＋8V/1A集成电路AN7809 电源稳压＋9V/1A集成电路AN7810 三端电源稳压＋10V/1A集成电路AN7812 三端电源稳压＋12V/1A集成电路AN7815 三端电源稳压＋15V/1A集成电路AN7818 三端电源稳压＋18V/1A集成电路AN7820 三端电源稳压＋20V/1A集成电路AN7824 三端电源稳压＋24V/1A集成电路AN78L05 三端电源稳压＋5V/0.1A集成电路AN78L06 三端电源稳压＋6V/0.1A集成电路AN78L08 三端电源稳压＋8V/0.1A集成电路AN78L09 三端电源稳压＋9V/0.1A集成电路AN78L10 三端电源稳压＋10V/0.1A集成电路AN78L12 三端电源稳压＋12V/0.1A集成电路AN78L15 三端电源稳压＋15V/0.1A集成电路AN78L18 三端电源稳压＋18V/0.1A集成电路AN78L20 三端电源稳压＋20V/0.1A集成电路AN78L24 三端电源稳压＋24V/0.1A集成电路AN78M05 三端电源稳压＋5V/0.5A集成电路AN78M06 三端电源稳压＋6V/0.5A集成电路AN78M08 三端电源稳压＋8V/0.5A集成电路AN78M09 三端电源稳压＋9V/0.5A集成电路27AN78M10 三端电源稳压＋10V/0.5A集成电路AN78M12 三端电源稳压＋12V/0.5A集成电路AN78M15 三端固定式稳压＋15V/0.5A集成电路AN78M18 三端电源稳压＋18V/0.5A集成电路AN78M20 三端电源稳压＋20V/0.5A集成电路AN78M24 三端电源稳压＋24V/0.5A集成电路AN7905 三端电源稳压－5V/1A集成电路AN7906 三端电源稳压－6V/1A集成电路AN7908T 三端电源稳压－8V/1A集成电路AN7909T 三端电源稳压－9V/1A集成电路AN7910T 三端电源稳压－10V/1A集成电路AN7912 三端电源稳压－12V/1A集成电路AN7915 三端电源稳压－15V/1A集成电路AN7918 三端电源稳压－18V/1A集成电路AN7920 三端电源稳压－20V/1A集成电路AN7924 三端电源稳压－24V/1A集成电路AN79L05 三端电源稳压－5V/0.1A集成电路AN79L06 三端电源稳压－6V/0.1A集成电路AN79L08 三端电源稳压－8V/0.1A集成电路AN79L09 三端电源稳压－9V/0.1A集成电路AN79L10 三端电源稳压－10V/0.1A集成电路AN79L12 三端电源稳压－12V/0.1A集成电路AN79L15 三端电源稳压－15V/0.1A集成电路AN79L18 三端电源稳压－18V/0.1A集成电路AN79L20 三端电源稳压－20V/0.1A集成电路AN79L24 三端电源稳压－24V/0.1A集成电路AN79M05 三端电源稳压－5V/0.5A集成电路AN79M06 三端电源稳压－6V/0.5A集成电路AN79M08 三端电源稳压－8V/0.5A集成电路AN79M09 三端电源稳压－9V/0.5A集成电路28AN79M10 三端电源稳压－10V/0.5A集成电路AN79M12 三端电源稳压－12V/0.5A集成电路AN79M15 三端电源稳压－15V/0.5A集成电路AN79M18 三端电源稳压－18V/0.5A集成电路AN79M20 三端电源稳压－20V/0.5A集成电路AN79M24 三端电源稳压－24V/0.5A集成电路AN8028 自激式开关电源控制集成电路AN8270K 主轴电机控制集成电路AN8280 电机驱动集成电路AN8281S 电机驱动集成电路AN8290S 主轴电机驱动集成电路AN8355S 条形码扫描接收集成电路AN8370S 光电伺服控制集成电路AN8373S 射频伺服处理集成电路AN8375S 伺服处理集成电路AN8389S－E1 电机驱动集成电路AN8480NSB 主轴电机驱动集成电路AN8481SB－E1 主轴电机驱动集成电路AN8482SB 主轴电机驱动集成电路AN8623FBQ 主轴伺服处理集成电路AN8788FB 电机驱动集成电路AN8802CE1V 伺服处理集成电路AN8813NSBS 主轴电机驱动集成电路AN8819NFB 伺服驱动、直流交换集成电路AN8824FBQ 前置放大集成电路AN8825NFHQ－V 聚焦、循迹误差处理集成电路AN8831SC 视频预视放集成电路AN8832SB－E1 射频放大、伺服处理集成电路AN8837SB－E1 伺服处理集成电路AN89C2051－24PC 微处理集成电路29APU2400U 音频信号处理集成电路APU2470 音频信号处理集成电路AS4C14405－60JC 动态随机存储1M×4集成电路AS4C256K16ED－60JC 存储集成电路ASD0204－015 图文控制集成电路ASD0204GF－022－3BA显示控制集成电路AT24C08 存储集成电路AT24C08A 存储集成电路AT24C256－10CI 码片集成电路AT27C010 电可改写编程只读存储集成电路AT27C020 存储集成电路ATMEL834 存储集成电路AVM－1 视频信号处理厚膜集成电路AVM－2 音频信号处理厚膜集成电路AVSIBCP08 倍压整流切换集成电路B0011A 存储集成电路B1218 电子快门控制集成电路BA033T 三端电源稳压＋3.3V集成电路BA10324 四运算放大集成电路BA10393N 双运算放大集成电路BA1102F 杜比降噪处理集成电路BA1106F 杜比降噪处理集成电路BA12ST 电源稳压集成电路BA1310 调频立体声解码集成电路BA1332L 调频立体声解码集成电路BA1350 调频立体声解码集成电路BA1351 调频立体声解码集成电路BA1356 调频立体声解码集成电路BA1360 调频立体声解码集成电路BA15218N 双运算放大集成电路30BA225 可触发双单稳态振荡集成电路BA302 音频前置放大集成电路BA311 音频前置放大集成电路BA313 音频前置放大集成电路BA3283 单片放音集成电路BA328F 双声道前置放大集成电路BA329 双声道前置放大集成电路BA3304F 录放音前置均衡放大集成电路BA3306 音频、前置放大集成电路BA3312N 话筒信号前置放大集成电路BA3313L 自动音量控制集成电路BA3314 话筒信号前置放大集成电路BA335 自动选曲集成电路BA336 自动选曲集成电路BA340 音频前置放大集成电路BA3402F 双声道前置放大集成电路BA3404F 自返转放音集成电路BA343 双声道前置放大集成电路BA3503F 双声道前置放大集成电路BA3506 单片放音集成电路BA3513FS 单片放音集成电路BA3516 单片放音集成电路BA3706 自动选曲集成电路BA3707 录音带曲间检测集成电路BA3812L 五频段音调补偿集成电路BA3818F 电压比拟运放集成电路BA3822LS 双声道五频段显示均衡集成电路BA3828 电子选台预置集成电路BA3880 音频处理集成电路31BA401 调频中频放大集成电路BA402 调频中频放大集成电路BA4110 调频中频放大集成电路BA4234L 调频中频放大集成电路BA4402 调频调谐收音集成电路BA4403 调频高频放大、混频、本振集成电路BA4560 双运算放大集成电路BA5096 数字混响集成电路BA5102A 音频功率放大集成电路BA514 音频功率放大集成电路BA516 音频功率放大集成电路BA5208AF 音频功率放大集成电路BA532 音频功率放大集成电路BA534 音频功率放大集成电路BA5406 双声道音频功率放大集成电路BA5412 音频功率放大集成电路BA547 音频功率放大1.5W集成电路BA5912AFP－YE2 电机驱动、倾斜、加载集成电路BA5981FP－E2 聚焦、循迹驱动集成电路BA5983FB 四通道伺服驱动集成电路BA5983FM－E2 电机驱动集成电路BA6104 发光二极管五位显示驱动集成电路BA6107A 电机伺服控制集成电路BA6109 加载电机驱动集成电路BA6125 发光二极管五位显示驱动集成电路BA6137 发光二极管五位显示驱动集成电路BA6191 音频控制集成电路BA6196FP 伺服驱动集成电路BA6208 电机驱动集成电路BA6208D 电机驱动集成电路32BA6209 电机驱动集成电路BA6209N 双向驱动电机集成电路BA6218 加载电机驱动集成电路BA6219 电机驱动集成电路BA6219B 电机驱动集成电路BA6227 电机稳速控制集成电路BA6238 电机驱动集成电路BA6239 电机双向驱动集成电路BA6239A 电机双向驱动集成电路BA6246M 加载、转盘电机驱动集成电路BA6248 电机驱动集成电路BA6286 电机驱动集成电路BA6287 电机驱动集成电路BA6290 电机驱动集成电路BA6295AFP－E2 加载、倾斜驱动集成电路BA6296FP 电机速度控制集成电路BA6297AFP 伺服驱动集成电路BA6302A 电机伺服控制集成电路BA6305 控制放大集成电路BA6305F 控制放大集成电路BA6308 电子开关切换集成电路BA6321 电机伺服控制集成电路BA6392 伺服驱动集成电路BA6395 主轴电机驱动集成电路BA6396FP 伺服驱动集成电路BA6411 电机驱动集成电路BA6435S 主轴电机驱动集成电路BA6459P1 电机驱动集成电路BA6570FP－E2 聚焦、循迹驱动集成电路33BA6664FM 三相主电机驱动集成电路BA6791FP 四通道伺服驱动集成电路BA6796FP 电机驱动集成电路BA6810S 音频显示驱动集成电路BA6844AFP－E2 三相主电机驱动集成电路BA6849FP 主轴电机驱动集成电路BA689 发光二极管十二位显示驱动集成电路BA6893KE2 直流变换驱动集成电路BA6956AN 加载电机驱动集成电路BA6993 双运算放大集成电路BA7001 音频切换集成电路BA7004 测试信号发生集成电路BA7005AL 射频调制集成电路BA7007 信号检测集成电路BA7021 视频信号选择集成电路BA7024 视频信号测试集成电路BA7025L 信号检测集成电路BA7042 振荡集成电路BA7047 调频检波集成电路BA7048N 包络信号检测集成电路BA7106LS 检测信号控制集成电路BA7180FS 磁头信号放大集成电路BA7212S 磁头信号放大集成电路BA7253S 磁头信号放大集成电路BA7254S 四磁头信号放大集成电路BA7258AS 亮度信号处理集成电路BA7264S 视频信号处理集成电路BA7274S 磁头信号放大集成电路BA7357S 中频放大集成电路BA7604N 电子开关切换集成电路34BA7606F 色差信号切换集成电路BA7655 色度信号处理集成电路BA7665FS－E2 视频输出放大集成电路BA7725FS 混响立体声放大集成电路BA7725S 信号压缩与扩展处理集成电路BA7743FS 磁头信号放大集成电路BA7751ALS 音频信号录放处理集成电路BA7752LS 音频信号处理集成电路BA7755 磁头开关集成电路BA7755AF－E2 磁头开关集成电路BA7765AS 音频信号处理集成电路BA7766SA 音频信号处理集成电路BA7767AS 音频信号处理集成电路BA7797F 音频信号处理集成电路BA8420 特技控制处理集成电路BAL6309 场同步信号发生集成电路BH3866AS 音频、色度信号前置放大集成电路BH4001 微处理集成电路BH7331P 音频功率放大集成电路BH7770KS 音频信号处理集成电路BL3207 亮度延时集成电路BL3208B 音频延迟混响集成电路BL5132 中频放大集成电路BL54573 电子调频波段转换集成电路BL5612 视频放大、色差矩阵集成电路BM5060 微处理集成电路BM5061 字符发生集成电路BM5069 微处理集成电路BN5115 图像中频放大集成电路BOC31F 单片微处理集成电路35BP5020 视频电源转换集成电路BT852 视频编码集成电路BT864 视频编码集成电路BT866PQFP 微处理集成电路BU12102 时序信号发生解码集成电路BU2092F 扩展集成电路BU2185F 同步信号处理集成电路BU2285FV 时钟信号发生集成电路BU2820 伺服控制集成电路BU2841FS 视频、蓝背景信号发生集成电路BU2872AK 操作系统控制、屏显驱动集成电路BU3762AF 红外遥控信号发射集成电路BU4053B 电子开关切换集成电路BU5814F 红外遥控信号发射集成电路BU5994F 红外遥控信号发射集成电路BU6198F 屏幕显示集成电路BU9252F 音频延时集成电路BU9252S 数/模转换集成电路BU9253FS 话筒音频混响集成电路BX1303 音频功率放大集成电路BX1409 红外遥控信号接收集成电路BX7506 主轴电机电源控制集成电路C1363CA 红外遥控电子选台集成电路C1490HA 红外遥控信号接收集成电路C187 分配、十进制计数集成电路C301 译码BCD－10段集成电路C68639Y 微处理集成电路C75P036 微处理集成电路CA0002 调幅模拟声解调集成电路CA2004 音频功率放大集成电路36CA2006 音频功率放大集成电路CA270AW 视频检波放大集成电路CA3075 调频中频放大集成电路CA3089 调频中频放大集成电路CA3120E 视频信号处理集成电路CA3140 运算放大集成电路CA810 音频功率放大集成电路CA920 行扫描信号处理集成电路CAS126 天线开关集成电路CAT24C16 电可改写编程只读存储集成电路CAT35C104HP 存储集成电路CC4000 或非门双3输入集成电路CC4008 计数4位二进制集成电路CC40107 与非双2输入缓冲、驱动集成电路CC40174 六D触发集成电路CC40194 移位存放集成电路CC4025 或非门3输入集成电路CC4026 译码、驱动、十进制计数集成电路CC4027 上升沿J－K触发集成电路。

32位微控制器KF32LS200数据手册芯片特征●CPU32位高性能KungFu32内核工作频率最高为48MHz，可软件调节；基于16位/32位混合指令的高效指令集；3级流水线；32×32单周期乘法，32÷32硬件除法；支持中断优先级处理，实现自动中断堆栈；13个32位通用寄存器R0~R12；链接寄存器（R13/LR）；堆栈指针寄存器（R14/MSP/PSP）；程序计数器（R15/PC）；24位系统节拍定时器；●存储器最高512KByte FLASH，带ECC校验；最高48KByteRAM，最多32KByte带ECC 校验；16KByte引导ROM；FLASH可经受100000次写操作；●特殊功能内嵌上电复位电路；低电压检测及低电压复位；可编程电压检测；硬件双看门狗；系统时钟6种时钟源可选；支持两线串行编程/在线调试；●I/O口配置LQFP-100封装有94个通用I/O；LQFP-64封装有60个通用I/O；LQFP-48封装有45个通用I/O；支持输入输出口设置；支持内置上拉/下拉功能；支持推挽输出和开漏输出模式；支持数字/模拟引脚设置；支持引脚功能重映射；施密特电平输入；●定时器/计数器定时器0：16位低功耗通用定时器，支持CCP0；定时器1/2/3/4为16位通用定时器，其中定时器1/2/3/4支持CCP1/2/3/4；定时器5/6为高级定时器，其中定时器5/6支持ECCP5；定时器14/15：基本定时器；定时器7支持QEI0；●其它外设2个7通道DMA；2个SPI总线模块（兼容I2S）；2个I2C总线模块（兼容SMBUS/PMBUS）；最多8个USART模块（兼容7816/LIN/IRDA 功能），其中1个为低功耗USART；1个CFGL可配置逻辑单元模块；1个独立的RTC（万年历）；1个LCD显示模块，可以驱动8x48/4x44模式；1个12位ADC模块，支持最多29个通道；1个温度传感器；●功耗管理7种功耗模式：正常运行模式、低功耗运行模式、普通休眠模式、低功耗休眠模式、停止模式，待机模式，关断模式；●工作条件工作电压： 1.71V～3.6V工作温度范围：A:-40～85℃KF32LS200数据手册V1.0目录芯片特征 (2)1芯片资源 (4)1.1产品订购信息 (4)1.2KF32LS200X QS（LQFP-48） (5)1.3KF32LS200X QT（LQFP-64） (6)1.4KF32LS200X QV（LQFP-100） (7)2系统概述 (8)2.1系统概述 (8)2.2指令集 (8)2.3系统框图 (9)2.4KF32LS100外设资源对照表 (10)2.5芯片引脚图 (11)3I/O端口介绍 (13)3.1概述 (13)3.2引脚功能说明 (14)3.3引脚重映射说明（数字功能） (17)3.4引脚重映射说明（ADC） (20)3.5引脚重映射说明（LCD） (21)4封装信息 (22)4.1LQFP48封装 (22)4.2LQFP64封装 (22)4.3LQFP100封装 (23)5ROHS认证 (24)6声明及销售网络 (25)1.2KF32LS200xQS（LQFP-48）型号KF32LS200订货号KF32LS200FQS KF32LS200GQS KF32LS200IQS 封装LQFP-48GPIO45FLASH 32Kbyte，带ECC校验64Kbyte，带ECC校验128Kbyte，带ECC校验RAM16Kbyte，带ECC校验32Kbyte，带ECC校验ROM16Kbyte16位Timer2个高级定时器（T5/T6），支持1个增强型ECCP54个通用定时器（T1/2/3/4），支持4个通用CCP（CCP1/2/3/4）2个基本定时器（T14/T15）1个低功耗通用定时器（T0）QEI112位ADC1*20USART2低功耗UART1 I2C2SPI2DMA2x7RTC YCFGL YLCD4x31温度传感器Y内部高频振荡器16MHz内部低频振荡器32KHz外部高频时钟4~32MHz外部低频时钟32.768KHz 内部参考 1.5/2/2.5/3V 器件ID号含出厂版本号等指令系统V0工作电压 1.71V～3.6V 工作温度-40～85℃1.3KF32LS200xQT（LQFP-64）型号KF32LS200订货号KF32LS200I QT KF32LS200K QT 封装LQFP-64GPIO60FLASH128Kbyte，256Kbyte，带ECC校验带ECC校验RAM32Kbyte，48Kbyte，带ECC校验带ECC校验ROM16Kbyte16位Timer2个高级定时器（T5/T6），支持1个增强型ECCP54个通用定时器（T1/2/3/4），支持4个通用CCP（CCP1/2/3/4）2个基本定时器（T14/T15）1个低功耗通用定时器（T0）QEI112位ADC1*28USART27低功耗UART1I2C2SPI2DMA2x7CFGL YRTC YLCD8x36温度传感器Y内部高频振荡器16M Hz内部低频振荡器32K Hz外部高频时钟4~32MHz外部低频时钟32.768KHz内部参考2V器件ID号含出厂版本号等指令系统V0工作电压 1.71V～3.6V工作温度-40～85℃1.4KF32LS200xQV（LQFP-100）型号KF32LS200订货号KF32LS200KQV KF32LS200MQV 封装LQFP-100GPIO94FLASH 256Kbyte，带ECC校验512Kbyte，带ECC校验RAM 48Kbyte，带ECC校验ROM16Kbyte16位Timer2个高级定时器（T5/T6），支持1个增强型ECCP54个通用定时器（T1/2/3/4），支持4个通用CCP（CCP1/2/3/4）2个基本定时器（T14/T15）1个低功耗通用定时器（T0），支持1个通用CCP0QEI112位ADC1*28USART7低功耗UART1 I2C2SPI2DMA2x7CFGL YRTC YLCD8X48温度传感器Y内部高频振荡器16MHz内部低频振荡器32KHz外部高频时钟4~32MHz外部低频时钟32.768KHz 内部参考2V器件ID号含出厂版本号等指令系统V0工作电压 1.71V～3.6V 工作温度-40～85℃2系统概述2.1系统概述KF32LS200系列单片机是基于KF32内核架构开发的单片机。

LT1990IS8#TRPBF LT1990IS8#PBF LT1990ACS8#PBF LT1990CS8#PBF LT1990AIS8#PBF LT1990AIS8#PBF.134LT199051990fbLT1990H SYMBOL PARAMETER CONDITIONSMINTYP MAXUNITS∆GGain ErrorV OUT = 0.5V to (+V S ) – 0.75V LT1990, G = 1●0.69%LT1990A, G = 1●0.37%G = 10●0.97%G/T Gain vs Temperature G = 1 (Note 10)●210ppm/°C G = 10 (Note 10)●720ppm/°CV CMInput Voltage RangeGuaranteed by CMRR V S = 3V, 0V, V REF = 1.25V ●–525V V S = 5V, 0V, V REF = 1.25V ●–580V V S = 5V, 0V, V REF = 2.5V ●–3748VCMRR Common Mode Rejection Ratio, RTIV S = 3V, 0V (Note 7)V CM = –5V to 25V, V REF = 1.25V LT1990●56dB LT1990A●66dBV S = 5V, 0VV CM = –5V to 80V, V REF = 1.25V LT1990●56dB LT1990A●66dBV S = 5V, 0V (Note 7)V CM = –38V to 47V, V REF = 2.5V LT1990●56dB LT1990A●66dB3V/5V ELECTRICAL CHARACTERISTICSThe ● denotes the specifications which apply over the temperature range of –40°C ≤ T A ≤ 85°C. V S = 3V, 0V; V S = 5V, 0V;R L = 10k, V CM = V REF = half supply, G = 1, 10, unless otherwise noted. (Notes 4, 6)LT1990C/LT1990I SYMBOL PARAMETERCONDITIONS MIN TYP MAXUNITS V OSInput Offset Voltage, RTIV S = 3V, 0V G = 1, 10● 4.5mV V S = 5V, 0V G = 1, 10● 4.5mV V OS /T Input Offset Voltage Drift, RTI (Note 10)●522µV/°C V OSH Input Offset Voltage Hysteresis, RTI (Note 11)●230µV PSRRPower Supply Rejection Ratio, RTI V S = 2.7V to 12.7V V CM = V REF = 1.25V ●76dB Minimum Supply VoltageGuaranteed by PSRR ● 2.7V I S Supply Current(Note 8)●170µA V OL Output Voltage Swing LOW –IN = V +, +IN = Half Supply (Note 8)●70mV V OHOutput Voltage Swing HIGH–IN = 0V, +IN = Half Supply V S = 3V, 0V, Below V +●200mV V S = 5V, 0V, Below V +●275mV I SCOutput Short-Circuit CurrentShort to GND (Note 9)●2mA Short to V + (Note 9)●8mAThe ● denotes the specifications which apply over the temperature range of –40°C ≤ T A ≤ 125°C. V S = 3V, 0V; V S = 5V, 0V; R L = 10k,V CM = V REF = half supply, G = 1, 10, unless otherwise noted. (Notes 4, 6)3V/5V ELECTRICAL CHARACTERISTICSLT199061990fb±15V ELECTRICAL CHARACTERISTICSV S = ±15V, R L = 10k, V CM = V REF = 0V, G = 1, 10, T A = 25°C, unless otherwise noted. (Note 6)SYMBOL PARAMETER CONDITIONSMINTYP MAX UNITSG Gain Pins 5 and 8 = Open 1Pins 5 and 8 = V REF 10∆GGain ErrorV OUT = ±10V LT1990, G = 10.40.6%LT1990A, G = 10.070.28%G = 100.20.8%GNL Gain NonlinearityV OUT = ±10V G = 10.00080.002%G = 100.0050.02%V CM Input Voltage RangeGuaranteed by CMRR –250250V CMRRCommon Mode Rejection Ratio, RTIV CM = –250V to 250V LT19906068dB LT1990A 7075dBV OS Offset Voltage, RTI G = 1, 100.9 5.2mV e n Input Noise Voltage, RTI f O = 0.1Hz to 10Hz 22µV P-P Noise Voltage Density, RTI f O = 1kHz 1µV/√Hz R IN Input ResistanceDifferential 2M ΩCommon Mode 0.5M ΩPSRR Power Supply Rejection Ratio, RTI V S = ±1.35V to ±18V 82100dBMinimum Supply Voltage Guaranteed by PSRR±1.2±1.35V I S Supply Current 140180µA V OUTOutput Voltage Swing±14.5±14.79VLT1990H SYMBOL PARAMETERCONDITIONS MINTYP MAXUNITS V OSInput Offset Voltage, RTIV S = 3V, 0V G = 1, 10● 5.2mV V S = 5V, 0V G = 1, 10● 5.2mV V OS /T Input Offset Voltage Drift, RTI (Note 10)●522µV/°C V OSH Input Offset Voltage Hysteresis, RTI (Note 11)●250µV PSRRPower Supply Rejection Ratio, RTI V S = 2.7V to 12.7V V CM = V REF = 1.25V ●75dBMinimum Supply VoltageGuaranteed by PSRR ● 2.7V I S Supply Current(Note 8)●200µA V OL Output Voltage Swing LOW –IN = V +, +IN = Half Supply (Note 8)●80mV V OHOutput Voltage Swing HIGH–IN = 0V, +IN = Half Supply V S = 3V, 0V, Below V +●230mV V S = 5V, 0V, Below V +●275mV I SCOutput Short-Circuit CurrentShort to GND (Note 9)●1mA Short to V + (Note 9)●5mAThe ● denotes the specifications which apply over the temperature range of –40°C ≤ T A ≤ 125°C. V S = 3V, 0V; V S = 5V, 0V; R L = 10k,V CM = V REF = half supply, G = 1, 10, unless otherwise noted. (Notes 4, 6)3V/5V ELECTRICAL CHARACTERISTICSLT199071990fbLT1990C/LT1990I SYMBOL PARAMETER CONDITIONS MIN TYP MAXUNITS∆GGain ErrorV OUT = ±10V LT1990, G = 1●0.65%LT1990A, G = 1●0.33%G = 10●0.9%GNL Gain NonlinearityV OUT = ±10V G = 1●0.0025%G = 10●0.025%G/T Gain vs Temperature G = 1 (Note 10)●210ppm/°C G = 10 (Note 10)●720ppm/°CV CM Input Voltage RangeGuaranteed by CMRR ●–250250V CMRRCommon Mode Rejection Ratio, RTIV CM = –250V to 250V LT1990●59dB LT1990A ●68dB V OS Input Offset Voltage, RTI G = 1, 10● 6.2mV V OS /T Input Offset Voltage Drift, RTI (Note 10)●522µV/°C V OSH Input Offset Voltage Hysteresis, RTI (Note 11)●250µV PSRR Power Supply Rejection Ratio, RTI V S = ±1.35V to ±18V ●80dB Minimum Supply Voltage Guaranteed by PSRR●±1.35V I S Supply Current ●230µA V OUT Output Voltage Swing ●±14.4V I SC Output Short-Circuit Current Short to V –●5mA Short to V +●13mA SRSlew RateG = 1, V OUT = ±10V●0.25V/µs±15V ELECTRICAL CHARACTERISTICSThe ● denotes the specifications which apply over the temperature range of 0°C ≤ T A ≤ 70°C. V S = ±15V, R L = 10k, V CM = V REF = 0V,G = 1, 10, unless otherwise noted. (Notes 4, 6)SYMBOL PARAMETERCONDITIONS MIN TYP MAXUNITS I SC Output Short-Circuit Current Short to V –69mA Short to V +1522mA BW Bandwidth G = 1105kHz G = 107kHz SR Slew RateG = 1, V OUT = ±10V 0.30.55V/µs Settling Time to 0.01%10V Step, G = 160µsAV REFReference Gain to OutputG = 1 1 ± 0.0007G = 101 ± 0.007V S = ±15V, R L = 10k, V CM = V REF = 0V, G = 1, 10, T A = 25°C, unless otherwise noted. (Note 6)LT199081990fbLT1990C/LT1990I SYMBOL PARAMETER CONDITIONS MIN TYP MAXUNITS∆GGain ErrorV OUT = ±10V LT1990, G = 1●0.67%LT1990A, G = 1●0.35%G = 10●0.95%GNL Gain NonlinearityV OUT = ±10V G = 1●0.003%G = 10●0.03%G/T Gain vs Temperature G = 1 (Note 10)●210ppm/°C G = 10 (Note 10)●720ppm/°CV CM Input Voltage RangeGuaranteed by CMRR ●–250250V CMRRCommon Mode Rejection Ratio, RTIV CM = –250V to 250V LT1990●58dB LT1990A ●67dB V OS Input Offset Voltage, RTI G = 1, 10● 6.7mV V OS /T Input Offset Voltage Drift, RTI (Note 10)●522µV/°C V OSH Input Offset Voltage Hysteresis, RTI (Note 11)●250µV PSRR Power Supply Rejection Ratio, RTI V S = ±1.35V to ±18V ●78dB Minimum Supply Voltage Guaranteed by PSRR●±1.35V I S Supply Current ●280µA V OUT Output Voltage Swing ●±14.3V I SC Output Short-Circuit Current Short to V –●3mA Short to V +●10mA SRSlew RateG = 1, V OUT = ±10V●0.2V/µs±15V ELECTRICAL CHARACTERISTICSThe ● denotes the specifications which apply over the temperature range of –40°C ≤ T A ≤ 85°C. V S = ±15V, R L = 10k, V CM = V REF = 0V,G = 1, 10, unless otherwise noted. (Notes 4, 6)LT1990H SYMBOL PARAMETER CONDITIONS MINTYP MAXUNITS∆GGain ErrorV OUT = ±10V LT1990, G = 1●0.69%LT1990A, G = 1●0.37%G = 10●0.97%GNL Gain NonlinearityV OUT = ±10V G = 1●0.0035%G = 10●0.035%G/T Gain vs Temperature G = 1 (Note 10)●210ppm/°C G = 10 (Note 10)●720ppm/°CV CM Input Voltage RangeGuaranteed by CMRR ●–250250V CMRRCommon Mode Rejection Ratio, RTIV CM = –250V to 250V LT1990●57dB LT1990A ●66dBV OS Input Offset Voltage, RTI G = 1, 10●7.4mV V OS /TInput Offset Voltage Drift, RTI(Note 10)●522µV/°C±15V ELECTRICAL CHARACTERISTICSThe ● denotes the specifications which apply over the temperature range of –40°C ≤ T A ≤ 125°C. V S = ±15V, R L = 10k, V CM = V REF = 0V,G = 1, 10, unless otherwise noted. (Notes 4, 6)LT199091990fbLT1990H SYMBOL PARAMETERCONDITIONS MIN TYP MAX UNITS V OSH Input Offset Voltage Hysteresis, RTI (Note 11)●250µV PSRR Power Supply Rejection Ratio, RTI V S = ±1.35V to ±18V ●77dB Minimum Supply Voltage Guaranteed by PSRR●±1.35V I S Supply Current ●330µA V OUT Output Voltage Swing ●±14.2V I SC Output Short-Circuit Current Short to V –● 1.5mAShort to V +●7mA SRSlew RateG = 1, V OUT = ±10V ●0.1V/µs±15V ELECTRICAL CHARACTERISTICSThe ● denotes the specifications which apply over the temperature range of –40°C ≤ T A ≤ 125°C. V S = ±15V, R L = 10k, V CM = V REF = 0V,G = 1, 10, unless otherwise noted. (Notes 4, 6)Note 1: Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. Exposure to any Absolute Maximum Rating condition for extended periods may affect device reliability and lifetime.Note 2: ESD (Electrostatic Discharge) sensitive device. Extensive use of ESD protection devices are used internal to the LT1990, however, high electrostatic discharge can damage or degrade the device. Use proper ESD handling precautions.Note 3: A heat sink may be required to keep the junction temperature below absolute maximum.Note 4: The LT1990C/LT1990I are guaranteed functional over the operating temperature range of –40°C to 85°C. The LT1990H isguaranteed functional over the operating temperature range of –40°C to 125°C.Note 5: The LT1990C is guaranteed to meet the specified performance from 0°C to70°C and is designed, characterized and expected to meet specified performance from –40°C to 85°C but is not tested or QAsampled at these temperatures. The LT1990I is guaranteed to meetspecified performance from –40°C to 85°C. The LT1990H is guaranteed to meet specified performance from –40°C to 125°C.Note 6: G = 10 limits are guaranteed by correlation to G = 1 tests and gain error tests at G = 10.Note 7: Limits are guaranteed by correlation to –5V to 80V CMRR tests.Note 8: V S = 3V limits are guaranteed by correlation to V S = 5V and V S = ±15V tests.Note 9: V S = 5V limits are guaranteed by correlation to V S = 3V and V S = ±15V tests.Note 10: This parameter is not 100% tested.Note 11: Hysteresis in offset voltage is created by package stress that differs depending on whether the IC was previously at a higher or lower temperature. Offset voltage hysteresis is always measured at 25°C, but the IC is cycled to 85°C I-grade (70°C C-grade or 125°C H-grade) or –40°C I/H-grade (0°C C-grade) before successive measurement.101112TIME (S)801990 G262010305070904060100TIME (S)081990 G252135794610V S = ±1.5V TO ±15V T A = 25°C G = 1V S = ±1.5V TO ±15V T A = 25°C G = 113V S = ±15V G = 1, –1R L = 10k V REF = GND50µs/DIV1990 G30V S = ±15V G = 1, –1R L = 10k V REF = GNDV S = 3V, 0V G = 1, –1R L = 10k V REF = 1.5V50µs/DIV50µs/DIV1990 G281990 G29LT1990141990fbV CM+ ≤ 27 • V + – 26 • V REF – 23 – V GAIN V CM– ≥ 27 • V – – 26 • V REF + 27 – V GAINFor split supplies over about ±11V, the full ±250V common mode range is normally available (with V REF a small fraction of the supply). With lower supply voltages, an appropriate selection of V REF can tailor the input common mode range to a specific requirement. As an example, the following low supply voltage scenarios are readily imple-mented with the LT1990:Supply V REF V CM Range+3V 1.25V –5V to 25V (e.g. 12V automotive environment)+5V 1.25V –5V to 80V (e.g. 42V automotive environment)+5V4.00V–77V to 8V (e.g. telecom environment;use downward signaling)Configuring Other GainsAn intermediate gain G ranging between 1 and 10 may be produced by placing an adjustable resistance between the GAIN1 and GAIN2 pins according to the following nominal relationship:R GAIN ≈ (180k/(G – 1)) – 20kWhile the expression is exact, the value is approximate because the absolute resistance of the internal network could vary on a unit-to-unit basis by as much as ±30%from the nominal figures and the external gain resistance is required to accommodate that deviation. Once ad-justed, however, the gain stability is excellent by virtue of the –30ppm/°C typical temperature coefficient offered by the on-chip thin-film resistor process.Preserving and Enhancing Common Mode Rejection The basic difference amplifier topology of the LT1990requires that source impedances seen by the input pins +IN and –IN, should be matched to within a few tens of ohms to avoid increasing common mode induced errors beyond the basic production limits of the part. Known source imbalances beyond that level should be compen-sated for by the addition of series resistance to the lower-impedance source. Also the source impedance of a signal connected to the REF pin must be on the order of a few ohms or less to preserve the high accuracy of the LT1990.APPLICATIO S I FOR ATIOW UUU Primary FeaturesThe LT1990 is a complete gain-block solution for high input common mode voltage applications, incorporating a low power precision operational amplifier providing rail-to-rail output swing along with on-chip precision thin-film resistors for high accuracy. The Block Diagram shows the internal architecture of the part. The on-chip resistors form a modified difference amplifier including a reference port for introducing offset or other additive waveforms.With pin-strapping alone either unity gain or gain of 10 is produced with high precision. The resistor network is designed to produce internal common-mode voltage divi-sion of 27 so that a very large input range is available compared to the power supply voltage(s) used by the LT1990 itself. The LT1990 is ideally suited to situations where relatively small signals need to be extracted from high voltage circuits, as is the case in many current monitoring instrumentation applications for example. With the ability to accept a range of input voltages well outside the limits of the local power rails and its greater than 1M Ωinput impedances, development of precision low power over-the-top and under-the-bottom instrumentation de-signs is greatly simplified with the LT1990 single chip solution over conventional discrete implementations.Classic Difference AmplifierUsed in the basic difference amplifier topology where the gain G is pin-strap configurable to be unity or ten, the following relationship is realized:V O = G • (V +IN – V –IN ) + V REFTo operate in unity gain, the GAIN1 and GAIN2 pins are left disconnected. For G = 10 operation, the GAIN1 and GAIN2pins are simply connected to the REF pin.The input common mode range capability is up to ±250V,governed by the following relationships:For G = 1 and G = 10 where GAIN1 and GAIN2 are only tied together (not grounded,etc):V CM+ ≤ 27 • V + – 26 • V REF – 23V CM– ≥ 27 • V – – 26 • V REF + 27For G = 10 where GAIN1 and GAIN2 are tied to a common potential V GAIN :15Information furnished by Linear Technology Corporation is believed to be accurate and reliable.However, no responsibility is assumed for its use. Linear Technology Corporation makes no represen-tation that the interconnection of its circuits as described herein will not infringe on existing patent rights.16© LINEAR TECHNOLOGY CORPORA TION 2004LT 0406 REV B • PRINTED IN USALT1990IS8#TRPBF LT1990IS8#PBF LT1990ACS8#PBF LT1990CS8#PBF LT1990AIS8#PBF LT1990AIS8#PBF.。

DescriptionEdwards Catalog Series 332EX, 333EX, 340EX and 435EX Adaptabel Bells are heavy duty, UL listed audible signal-ing appliances intended for use in hazardous locations.The 332EX and 333EX series are single stroke bells suit-able for use in coded signaling applications such as tim-ing, scheduling, paging, or alarm. The 340EX and 435EX series are vibrating bells suitable for use in general sig-naling and alarm applications. The 332EX and 340EX se-ries are ac-powered and the 333EX and 435EX series are dc-powered. The bells are electromechanical devices and utilize solid state components. They are Outdoor Type 4listed. All series of the bells are listed for installation in the following hazardous locations:Installation Instructions for Catalog Series 332EX, 333EX, 340EX and 435EX Adaptabel Bells for Use in Hazardous LocationsMechanical SpecificationsDimensionsWith 6" gong ......7" (178 mm) H x 5" (127 mm) D With 8" gong 9" (229 mm) H x 5 1/8" (130 mm) D With 10" gong11" (279 mm) H x 5 1/4" (133 mm) D WeightWith 6" gong .......................5 1/4 pounds (2.4 kg)With 8" gong .............................7 pounds (3.2 kg)With 10" gong .....................8 1/4 pounds (3.8 kg)InstallationThe following items (not supplied) are required for instal-lation of the bell:•3/4" conduit to contain power supply and ground wires •One 3/4" NPT nipple•One conduit outlet box suitable for use in the hazardous location•Two fasteners up to 3/8" diameter and washers suitable for securing bell to mounting surface.•Two wire nuts.The bell can be mounted to any solid surface. Install bell as follows:1.See Figure 1. Remove cover from conduit outlet box.Feed the two wires from the applicable power sourceElectrical SpecificationsP-047550-0585 ISSUE 6 © 2005CHESHIRE, CT 203-699-3300 CUST. SERV. FAX 203-699-3365 TECH SERV. FAX 203-699-3078through conduit and into outlet box. Also, feed the bell's two wire leads through nipple and into box.Secure bell, nipple, and conduit to box.2.Remove gong from bell. Place bell against mountingsurface and mark mounting hole positions for fasteners per dimensions in Figure 2. Install fasteners with washers through mounting brackets and secure bell to surface. Replace gong in original orientation.is positive (+), black wire is negative (-). Replace cover on outlet box.4.Apply power to the bell and verify that it sounds.Maintenance and Maintenance and TT est Examine the bell annually for accumulation of dirt and clean when necessary.Test the bell annually or at the intervals required by ap-plicable regulations and codes.P-047550-0585 ISSUE 6PAGE 23.Connect power supply wires to bell wires using wirenuts. For a dc-powered bell, observe polarity--red wire。

概述DW03是一款高精度的单节可充电锂电池保护芯片，芯片内部集成了功率管以及高精度的过电压充电、过电压放电、过电流充电和过电流放电等保护电路。

同时，DW03具有短路保护、过温保护、充电器检测和0V电池充电允许等功能。

正常工作状态下，DW03的VDD 脚电压保持在过电压充电保护阈值和过电压放电保护阈值之间，同时DW03的充/放电流在过电流充电保护阈值和过电流放电保护阈值之间，此时DW03内置的功率管导通，既可以使用充电器对电池充电，也可以通过负载对电池放电。

当充/放电保护条件发生时，并持续相应的延时后，DW03内置的功率管开始关闭，此时充/放电过程停止。

DW03对每种保护状态都有相应的恢复条件，当恢复条件满足，并持续相应的延时后，DW03内置的功率管再次导通，芯片重新进入正常工作状态。

DW03采用体积超小的SOT23-3L封装，外围应用电路精简，只需要一个电容和一个电阻。

这非常适合对空间限制要求非常严格的可充电锂电池组的应用。

特点∙集成功率管：R ON=55mΩ∙过电压充电/放电保护∙过电流放电保护∙异常充电/过电流充电保护∙0V电池充电允许∙充电器检测功能∙延时时间内部设定∙负载短路保护∙充电器反接保护∙过温保护∙超低静态电流：工作状态：典型值2.5uA低功耗状态：典型值1.5uA ∙极少的外围元器件∙采用SOT23-3L封装应用∙单节锂离子电池组∙单节锂聚合物电池组典型应用电路管脚SOT23-3L管脚描述极限参数（注1）注1: 最大极限值是指超出该工作范围芯片可能会损坏。

推荐工作范围是指在该范围内芯片工作正常，但不完全保证满足个别性能指标。

电气参数定义了器件在工作范围内并且在保证特定性能指标的测试条件下的直流和交流电气参数规范。

对于未给定的上下限参数，该规范不予保证其精度，但其典型值合理反映了器件性能。

注2：环境温度升高最大功耗会减小，这是由T JMAX，ѲJA和环境温度T A所决定的。

最大允许功耗为P DMAX=(T JMAX-T A)/ ѲJA或是极限参数范围给出的数值中比较低的那个值。

V OUTREFR GProduct FolderSample &BuyTechnical Documents Tools &SoftwareSupport &CommunityINA333ZHCSAK0C –JULY 2008–REVISED DECEMBER 2015INA333微功耗(50μA)、零漂移、轨到轨输出仪表放大器1特性•低偏移电压：25µV （最大值），G ≥100•低漂移：0.1μV/°C ，G ≥100•低噪声：50nV/√Hz ，G ≥100•高共模抑制比(CMRR)：100dB （最小值），G ≥10•低输入偏置电流：200pA （最大值）•电源范围：1.8V 至5.5V•输入电压：(V–)+0.1V 至(V+)–0.1V •输出电压：(V–)+0.05V 至(V+)–0.05V •低静态电流：50μA•工作温度范围：-40°C 至+125°C •已过滤射频干扰(RFI)的输入•8引脚VSSOP 和8引脚WSON 封装2应用范围•桥式放大器•心电图(ECG)放大器•压力传感器•医疗仪表•便携式仪表•衡器•热电偶放大器•电阻式温度检测器(RTD)传感器放大器•数据采集3说明INA333器件是一款低功耗的精密仪表放大器，具有出色的精度。

该器件采用通用的三运算放大器设计，并且拥有小巧尺寸和低功耗特性，非常适合各类便携式应用。

可通过单个外部电阻在1到1000范围内设置增益。

INA333设计为采用符合行业标准的增益公式：G =1+(100k Ω/R G )。

INA333器件拥有超低的偏移电压（25μV ，G ≥100），出色的偏移电压漂移（0.1μV/°C ，G ≥100），以及较高的共模抑制比（100dB ，G ≥10）。

该器件可由低至1.8V (±0.9V)的电源供电运行，静态电流仅为50μA ，因此非常适合电池供电类系统。

通用雙元熱釋電紅外線感測器熱釋電紅外線感測器是利用溫度變化的特徵來探測紅外線的輻射，採用雙靈敏元互補的方法抑制溫度變化産生的干擾，提高了感測器的工作穩定性。

産品應用廣泛，例如，保險裝 置，防盜報警器，感應門，自動燈具，智慧玩具等。

標準規格和尺寸型號D203S `TO-5紅外接收電極 2×1mm, 2 個靈敏元 窗口尺寸 4×3mm 接收波長 5-14µm 透過率≥75% 輸出信號峰值[Vp-p] ≥3500mV 靈敏度≥3300V/W探測率 (D*) ≥1.4 ×108 cmHz 1/2/W 雜訊峰值[Vp-p] <70mV 輸出平衡度 <10% 源極電壓 0.3-1.5V 電源電壓 3-15V 工作溫度範圍 -30-70ºC 保存溫度範圍 -40-80ºC入射視角圖等效電路圖1.Drain2.Source3.Ground測試方法測量條件♦ 環境溫度 25ºC♦ 黑體溫度 420K( 147˚C )♦ 調製頻率1赫茲, 0.3-3.5赫茲△f,♦ 放大倍數 72.5 dB雙元感測器的靈敏平衡度是通過測量每個單元的靈敏度（即單個輸出峰值電壓），並採用下列公式計算得出。

平衡度 =|V A-V B|/(V A+V B) ×100%V A = A面的靈敏度( mVp-p )V B = B面的靈敏度( mVp-p )典型應用電路注意:U1A-D: LM324電源:12VDCRs=47KΩ，作爲參考電壓設置電阻窗口材料的可接收通過波長注意:圖表所示爲典型的5.5µm紅外濾光片參考圖，曲線是紅外線通過率的平均值。

該窗口材料是經過特殊真空鍍膜處理過的半導體矽片。

菲涅耳透鏡用於感測器的探測方位注意感測器敏感元的放置方向和器件平面圖的尺寸，結合菲涅爾透鏡的焦點可以獲得一種最佳的光學設計。

感測器出廠參數測試是在標準黑體和相關電路條件下經過一分鐘的穩定時間後取得的。

运放分类及选型对于较大音频、视频等交流信号，选SR （转换速率）大的运放比较合适.对于处理微弱的直流信号的电路，选用精度比较高的运放比较合适（即失调电流，失调电压及温漂均比较小）运算放大器大体上可以分为如下几类：1、 通用型运放2、 高阻型运放3、 低温漂型运放4、 高速型运放5、 低功耗型运放6、 高压大功率型运放1、 通用型运放其性能指标能适合于一般性（低频以及信号变化缓慢）使用，例如741A μ，LM358（双运放）,LM324及场效应管为输入级的LF356。

2、 高阻型运放这类运放的特点是差模输入阻抗非常高，输入偏置电流非常小。

实现这些指标的主要措施是利用场效应管的高输入阻抗的特点，但这类运放的输入失调电压较大.这类运放有LF356、LF355、LF347、CA3130、CA3140等3、 低温漂型运放在精密仪器、弱信号检测等自动控制仪表中，希望运放的失调电压要小，且不随温度的变化而变化。

底温漂型运放就是为此设计的。

目前常用的低温漂型运放有OP07、OP27、OP37、AD508及MOSFET 组成的斩波稳零型低温漂移器件ICL7650等.4、 高速型运放在快速A/D 及D/A 以及在视频放大器中，要求运放的转换速率SR 一定要高，单位增益带宽BWG 一定要足够大。

高速型运放的主要特点是具有高的转换速率和宽的频率响应。

常见的运放有LM318、175A μ等.其SR=50～70V/ms5、 低功耗型运放由于便携式仪器应用范围的扩大，必须使用低电源电压供电、低功耗的运放。

常用的低功耗运放有TL-022C ，TL-160C 等。

6、 高压大功率型运放运放的输出电压主要受供电电源的限制.在普通运放中，输出的电压最大值一般仅有几十伏，输出电流仅几十毫安，若要提高多输出电压或输出电流，运放外部必须要加辅助电路。

高压大功率运放外部不需要附加任何电路，即可输出高电压和大电流。

D41运放的电源电压可达V 150±，791A μ运放的输出电流可达1A 。