MAX6337US18D1-T中文资料

北京德威特电力系统自动化有限公司系统硬件系列DVP – 633微机35kV线路相间距离保护装置使用说明书北京德威特电力系统自动化有限公司北京中关村中国科学院电工研究所科技公寓2002.8目录1.本保护装置的适用范围 (3)2.装置的功能及特点 (3)2.1装置的主要特点 (3)2．2装置配备的保护及保护原理 (4)3.技术数据 (6)4.结构说明 (8)4.1装置组成 (8)4.2安装与开孔 (9)5.保护装置的原理图与装置端子接线说明 (9)5.1保护装置的原理图 (9)5.2装置端子图及接线说明 (10)6. 数码管的六种显示及按键的使用说明 (13)6.1数码管的六种显示 (13)6.2按键使用说明: (13)6.2.1输入密码的方法: (13)6.2.2输入修改保护定值的方法: (13)6.2.3打开与关闭保护软压板的方法: (14)6.2.4搜索的三种方法(适用于定点显示和进入定值区的显示): (14)6.3几种显示列表: (14)6.3.1正常循环显示（供运行人员使用） (14)6.3.2定点显示(供运行人员或调试人员用) (14)6.3.3定值显示修改 (16)6.3.4跳闸及报警信号指示 (17)7.调试大纲(适用于现场调试人员及检修维护人员) (17)7.1查看、输入或修改保护定值: (17)7.2开关量的检查 (17)7.3遥控分合闸继电器出口检查 (17)7.4保护继电器的出口检查 (18)7.5模拟量输入检查及精度检查 (18)7.6重合闸试验 (19)7.7距离保护试验 (19)7.8过流保护试验 (19)7.9PT回路断线报警 (20)7.10动作时间测试 (20)7.11CAN网的连接 (20)7.12．更换插件注意事项 (21)8.运行人员注意事项及要求 (21)9.检修及维护: (21)10怎样调节模拟量 (21)11．订货须知 (23)1.本保护装置的适用范围DVP－633用于35KV输电线路,完成三段式相间距离和重合闸保护功能，保护装置由监控和保护两套完全独立的系统共同构成35KV线路成套保护。

35 SERIES HN35 PROFULL Y-FEATURED NVRS• View 16/32/64 channels simultaneously with synchronized real-time playback on your monitor (depending on your model) .32/64CH support 16 channels simultaneously with synchronizedreal-time playback.• Up to 8 MP (4K) resolution live view and playback.• Supports H.265 HEVC, H.264, Smart Codec.• Notify on triggering built-in video analytic alarms from 35S cameras: Crowd, Multi Loitering, Intrusion, Tampering, Motion and SmartMotion Detection (SMD).• Two-way audio/push notification.• Supports up to 16 alarm input channels and 6 alarm relay output channels. (8 SATA).• Maximum incoming bandwidth is 400 Mbps,and Maximum outgoing bandwidth is 400 Mbps.*• Supports redundancy Failover N+1 (Maximum N =10).• Supports people counter feature to accurately automate the gathering of data relating to people entering and exiting a certainarea.DYNAMIC, ACCESSIBLE MONITORING• Global P2P/TUTK service with reliable connection and mobile apps for both Apple® and Android™ devices for anytime, anywhere access.• P2P integration to manage remote configuration and firmware updating.CONVENIENT, FLEXIBLE, REDUNDANT STORAGE OPTIONS• Internal storage supports 8 HDDs expandable up to 80 TB (8 bays) of internal storage.• Store video clips and snapshots to external storage, such as USB device on local side or PC client on web side.• Supports RAID** 1/5/6 storage options.EASY TO SETUP AND USE• Plug and play feature together with 35 Series cameras for rapid and simple setup.• Dual network ports, making it easy to connect local IPCs and remote control.• Intuitive NVR design, quick installation wizard and easy-to-understand installation guide for fast and easy setup.Introducing Honeywell’s 35 Series HN35 PRO NVRs, a robustly-featured, cost-effective, NDAA Section 889 compliant NVR solution delivering 4K HD (UHD) video resolution perfect for small/medium businesses and enterprises. Choose a 16 , 32 or 64 channelNVR with multiple hard drive options and up to 80 TB (8 bays) of internal storage with fail-over and RAID redundancy features fora flexible and reliable solution that grows with your business.• H.265/H.264• HDMI/VGAsimultaneous videooutput• USB ports support Keyboard andMouse• Supports recording avideo clip of events fordistribution• Supports uploadingstill images at the timeof the event throughemail• Supports visual orauditory notificationssuch as a flashinglight, bell, or siren• Support RAID ** 1/5/6 • Supports alarm inputand alarm output• Supports sendingevents through email,FTP, alarm out or pushnotification• Configurable toautomatically detectand respond tomotion in the scene,alarm inputs, andnetwork failure ortamperingFEATURES SECURE AND COMPLIANT SOLUTION• For use as part of video systems which comply with NDAA Section 889.• The TPM (Trusted Platform Module) provides end-to-end stream and command encryption through integrated cryptographic keys.• Together with 35 Series cameras, provides an end-to-end encrypted solution with video streaming and control encryptedbetween NVR and web client / viewer / mobile app.• PCI-DSS compliance.• Secure boot feature combined with Honeywell cybersecurity standards helps ensure data protection.•Support secure NTP.HN351604xxR/HN353204xxNR/HN356404xxNRHN356408xxDRHN353208xxNR/HN356408xxNR16 / 32 /64 Ch 4K Embedded NVR*400Mbps is achievable when video streams are not encrypted. It is needed to split the HDD array into at least two equal storage groups.* * For optimum performance, RAID functionality requires models with Enterprise Hard Disk Drives.35 SERIES HN35 PRO, 16 / 32 / 64 CH 4KHard Disk Drives.**400Mbps is achievable when video streams are not encrypted. It is needed to split the HDD array into at least two equal storage groups.SYSTEM DIAGRAMHN351604XXR1. PoE Ports2. Audio Out3. Audio In4. eSATA Port5. LAN Port6. WAN Port7. RS232 Port8. HDMI 2 Port9. HDMI 1 Port 10. VGA Port 11. USB Port 12. Alarm Input/Output 13. Power Input 14. Power SwitchHN353204xxNR1. Alarm Input/Output2. Audio Out3. Audio In4. LAN Port5. WAN Port6. HDMI 2 Port7.VGA Port8. HDMI 1 Port9. RS232 Port 10. USB Port 11. eSATA Port 12. Power Input 13. Power SwitchHN356404xxNR1. Audio Out2. Audio In3. LAN Port4. WAN Port5. HDMI 1 Port6. HDMI 2 Port7.VGA Port8. RS232 Port9. USB Port 10. eSATA Port 11. Alarm Input/Output 12. Power Input 13. Power SwitchHN353208xxNR/HN356408xxNRHN356408xxDR (Dual Power Supply)1. Audio Out2. Audio In3. LAN Port4. WAN Port5. HDMI 1 Port6. HDMI 2 Port7.VGA Port8. RS232 Port9. USB Port 10. eSATA Port 11. Alarm Input/Output 12. Power Input 13. Power Switch1. Audio Out2. Audio In3. LAN Port4. WAN Port5. HDMI 1 Port6. HDMI 2 Port7.VGA Port8. RS232 Port9. USB Port 10. eSATA Port 11. Alarm Input/Output 12. Power Switch 13. Power InputSYSTEM DIAGRAMHN351604xxR/HN353204xxNR/HN356404xxNR”))”)DIMENSIONSDIMENSIONS HN353208xxNR/HN356408xxNRFor More Information/uk /securityHoneywell Commercial Security Building 5 Carlton ParkKing Edward Avenue Narborough, LeicesterLE19 0ALTel: +44 (0)1163 500714 HBT-SEC-HN35ENVRPRO-01-UK(0923)DS-Y© 2023 Honeywell International Inc.ONVIF and the ONVIF logo are trademarks of ONVIF Inc.HEVC Advance logo is a trademark of HEVC AdvanceHoneywell reserves the right, without notification, tomake changes in product design or specifications.HN35 16 04 00 xR16 = 16 CHANNELS32 = 32 CHANNELS64=64 CHANNELS00 = 0 TB35 = 35 SERIES04 = 4 SATA08= 8 SATA x=N, N means non-PoEx=D, D means redundant power supply R Suffix = Fail-over and RAID software*PART NUMBER LOOKUP* For optimum performance, RAID functionality requires models with Enterprise Hard Disk Drives.。

MAX-1000 矩阵系统用户手册HONEYWELL Co,. Ltd.目录1．综述1.1 简介1.2 CCTV键盘1.3 模拟操作面板1.4 其它设备1.5 本手册所作的前提假定1.6 本手册所用的惯例击键数字范围注意要点监示器信息1.7 厂商联络方式1.8 商标注明2 启动2.1 输入你的选择号码,怎样和为什么?2.2 监示器选择2.3 摄像机选择2.4 PTZ摄像机控制2.5 VCR选择2.6 CCTV键盘控制VCR2.7 摄像机录像2.8 辅助装置和复用器3 扫描序列的使用3.1 什么是扫描序列?什么是扫描序列3.2 启动扫描序列3.3 中止扫描序列3.4 暂停扫描序列3.5 产生新的扫描序列3.6 扫描序列的编辑用新的摄像机选择进行替换删除该摄像机选择插入新的摄像机选择3.7 改变停顿周期3.8 为一个摄像机增加停顿4 宏语言的使用4.1 什么是宏程序?齐投摄像机选择摄像机漫游自动控制4.2 宏语言的执行4.3 产生一个新的宏程序4.4 宏程序的删除4.5 我能编辑一个宏程序吗?5 警报管理5.1 什么是警报?5.2 外部警报输入5.3 摄像机故障警报视频丢失低电平视频5.4 PTZ解码箱故障警报5.5 PTZ解码箱防拆警报5.6 VCR警报5.7 其它装置警报5.8 警报堆栈5.9 在警报堆栈上移位5.10 清除警报6 键盘的其它功能6.1 快速摄像机选择6.2 设置摄像机视场(PTZ预置位) 6.3 调用摄像机视场(PTZ预置位) 6.4 摄像机PTZ复位6.5 选择代用摄像机6.6 隐藏显示的字符6.7 显示SMARTEXTTM7 菜单系统7.1 什么是菜单系统?访问菜单系统退出菜单系统7.2 从菜单上选择移动菜单进入窗口7.3 键盘操作员登记7.4 键盘操作员注销7.5 激活／中止视频输入中止一个摄像机激活一个摄像机7.6 锁定／释放视频输入控制锁定一个PTZ摄像机释放一个PTZ摄像机锁定／释放一个PTZ摄像机7.7 锁定／释放视频输出选项锁定视频输出选项释放视频输出选项锁定／释放视频输出选项7.8 中止／激活警报输入中止警报输入激活警报输入9.3 字符显示定时9.4 监示器黑屏9.5 黑屏暂停9.6 监示器访问9.7 操作员对系统的访问9.8 操作员的级别划分9.9 CCTV键盘定时9.1 0 自动注销9.11 摄像机故障检测视频丢失低电平视频1 0 排除提示10.1 摄像机选择第一章概述1.1简介MAX一1000 CCTV管理系统是一个强功能的计算机控制视频切换矩阵。

USA/ CanadaNEMA 5-15P AC male plugIEC 60320 C13 AC female connector SJT 18AWG*3C, 2m/78.7in (L)EuropeCEE 7/7 AC male plugIEC 60320 C13 AC female connector H05VV-F 0.75*3C, 2m/78.7in (L)JapanJIS C 8303 AC male plugIEC 60320 C13 AC female connector VCTF 0.75*3C, 2m/78.7in (L)AustraliaSAA power cord, AS3112 AC male plug, 10A IEC 60320 C13 AC female connector2m/78.7in (L)UKNEMA 5-15P AC male plugIEC 60320 C13 AC female connector H05VV-F 0.75*3C, 2m/78.7in (L)HARDWARE CHECKLISTUnpack the contents of the box and check that the following was included:One (1) MC403 Power SystemOne (1) MC403 instruction manualOne (1) 19” rack front panelTwo (2) pedalboard mounting bracketsTwenty (20) cables:F o u r (4) 2.1 x 5.5m m b l a c k r i g h t a n g l e t o s t r a i g h t, 1’ l o n gEight (8) 2.1 x 5.5mm black right angle to straight, 2’ longFour (4) 2.1 x 5.5mm black right angle to straight 3’ longTwo (2) 2.5 x 5.5mm red right angle to straight 4’ longOne (1) 2.1 x 5.5mm to 3.5mm black straight 2’ longOne (1) 2.1 x 5.5mm to 3.5mm black straight 3’ longOne (1) AC cord with appropriate connector for region of operation:DIRECTIONS(1) Set the red AC 115/230 input selector to your local AC voltage.(2) Plug the included AC power cord into the AC IN jack.(3) Connect the AC cord into a wall outlet.(4) Flip the ON/OFF switch to the ON position. A red LED on the rear panel will lightup to indicate the unit is active.(5) Read the OUTPUT GUIDE on the following pages to make sure you are using thecorrect output jacks and cables.(6) Connect pedals to the MC403 using supplied cables. The red LED aboveeach output jack will light to indicate that power is being supplied to theconnected pedal.(7) An AC THRU jack is located next to the AC IN jack to provide auxiliary powerto another device. DO NOT EXCEED 200 WATTS on AC THRU device!OUTPUT GUIDEBefore plugging anything into the MC403 Power System, check that the powerrequirements of the device match the output capabilities of the MC403.Specifically, you should check:(1) The device’s voltage requirement to match the MC403 output voltage.(2) Whether the device uses AC or DC.(3) The current requirement to not exceed the MC403’s MAX CURRENT spec.(4) The polarity when using DC power.The cables provided with the MC403support the industry standard positive (+)barrel and negative (-) center polarity.If you are unsure about what power your device requires,DO NOT PLUG THE DEVICE INTO THE MC403! The following list provides usageexamples for each of the output types available on the MC403.ADJUSTABLE DC OUTPUTS – Use 2.1 x 5.5mm black cables.Push the red button IN for the high voltage (10.5-15V) setting.Push the red button OUT for the low voltage (6.5-10.5V) setting.Rotate the black adjustment knob to fine tune the value.To simulate a dying battery tone on a transistor based distortion/fuzz/overdrive,set the red button OUT and rotate the adj. knob until desired tone is achieved.Radial™ Tonebone™ pedals requiring 15VDC, 400mA can be used with the redbutton IN and the adjustment knob rotated fully clockwise.9VAC OUTPUTS– Use 2.5 x 5.5mm red cables.Line 6® Stomp Modeler and POD® units (excluding Pocket POD®)9VDC OUTPUTS – Use 2.1 x 5.5mm black cables.MXR®, Crybaby®, Way Huge® Electronics pedals requiring Dunlop ECB-003Dunlop® UV1SC Stereo Chorus, JD4S RotovibeBoss® pedals requiring PSA-series adaptersElectro-Harmonix® pedals requiring 9DC-100 adapterMaxon® pedals requiring AC210N adapterIbanez® pedals requiring AC109 adapterRadial™ pedals requiring 9VDC, 40mA negative center adaptersLine6® ToneCore® series pedalsDigiTech® pedals requiring PSR200R18VDC OUTPUTS – Use 2.1 x 5.5mm black cables.MXR®, Crybaby® pedals requiring Dunlop ECB-004Dunlop® UV1 UnivibeFRONT PANEL & PEDAL BOARD BRACKET ASSEMBLYRemove the four screws on front of unit as indicated in Figure A for rack mountingor as in Figure B for pedalboard mounting. Place the brackets on the unit, line upthe holes, and replace screws to secure brackets. Use M3.0x0.5, L=8mm (max)screws if factory screws are lost.Figure B – Pedalboard MountFigure A – Rack Mount92503008461R E V CWARNING: READ THIS FIRST BEFORE OPERATING!(1)(2)(3)(4)(5)(6)(7)(8) (9) (10) (11)(12)(13) (14)。

MAX6387XS18D7中⽂资料General Description The MAX6381–MAX6390 microprocessor (µP) supervisory circuits monitor power-supply voltages from +1.8V to +5.0V while consuming only 3µA of supply current at +1.8V. Whenever V CC falls below the factory-set reset thresholds, the reset output asserts and remains assert-ed for a minimum reset timeout period after V CC rises above the reset threshold. Reset thresholds are available from +1.58V to +4.63V, in approximately 100mV incre-ments. Seven minimum reset timeout delays ranging from 1ms to 1200ms are available.The MAX6381/MAX6384/MAX6387 have a push-pull active-low reset output. The MAX6382/MAX6385/ MAX6388 have a push-pull active-high reset output, and the MAX6383/MAX6386/MAX6389/MAX6390 have an open-drain active-low reset output. The MAX6384/MAX6385/MAX6386 also feature a debounced manual reset input (with internal pullup resistor). The MAX6387/MAX6388/MAX6389 have an auxiliary input for monitoring a second voltage. The MAX6390 offers a manual reset input with a longer V CC reset timeout period (1120ms or 1200ms) and a shorter manual reset timeout (140ms or 150ms). The MAX6381/MAX6382/MAX6383 are available in 3-pin SC70 and6-pinµDFN packages and the MAX6384–MAX6390 are available in 4-pin SC70 andFeaturesFactory-Set Reset Threshold Voltages Rangingfrom +1.58V to +4.63V in Approximately 100mVIncrements±2.5% Reset Threshold Accuracy OverTemperature (-40°C to +125°C)Seven Reset Timeout Periods Available: 1ms,20ms, 140ms, 280ms, 560ms, 1120ms,1200ms (min)3 Reset Output OptionsActive-Low Push-PullActive-High Push-PullActive-Low Open-DrainReset Output State Guaranteed ValidDown to V CC= 1VManual Reset Input (MAX6384/MAX6385/MAX6386)Auxiliary RESET IN(MAX6387/MAX6388/MAX6389)V CC Reset Timeout (1120ms or 1200ms)/ManualReset Timeout (140ms or 150ms) (MAX6390)Negative-Going V CC Transient ImmunityLow Power Consumption of 6µA at +3.6Vand 3µA at +1.8VPin Compatible withMAX809/MAX810/MAX803/MAX6326/MAX6327/MAX6328/MAX6346/MAX6347/MAX6348,and MAX6711/MAX6712/MAX6713Tiny 3-Pin/4-Pin SC70 and 6-Pin µDFN PackagesMAX6381–MAX6390 SC70/µDFN, Single/Dual Low-Voltage,Low-Power µP Reset Circuits ________________________________________________________________Maxim Integrated Products1Pin Configurations19-1839; Rev 4; 4/07Ordering InformationOrdering Information continued at end of data sheet.Typi cal Operati ng Ci rcui t appears at end of data sheet.Selector Guide appears at end of data sheet.after "XR", "XS", or "LT." Insert reset timeout delay (see ResetTimeout Delay table) after "D" to complete the part number.Sample stock is generally held on standard versions only (seeStandard Versions table). Standard versions have an orderincrement requirement of 2500 pieces. Nonstandard versionshave an order increment requirement of 10,000 pieces.Contact factory for availability of nonstandard versions.+Denotes a lead-free package.For pricing, delivery, and ordering information,please contact Maxim Direct at 1-888-629-4642,or visit Maxim’s website at /doc/5700977901f69e3143329415.html .ComputersControllersIntelligent InstrumentsCritical µP and µCPower MonitoringPortable/Battery-Powered EquipmentDual Voltage SystemsM A X 6381–M A X 6390SC70/µDFN, Single/Dual Low-Voltage, Low-Power µP Reset CircuitsABSOLUTE MAXIMUM RATINGSELECTRICAL CHARACTERISTICS(V CC = full range, T A = -40°C to +125°C, unless otherwise specified. Typical values are at T A = +25°C.) (Note 1)Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.V CC to GND..........................................................-0.3V to +6.0V RESET Open-Drain Output....................................-0.3V to +6.0V RESET , RESET (push-pull output)..............-0.3V to (V CC + 0.3V)MR , RESET IN.............................................-0.3V to (V CC + 0.3V)Input Current (V CC ).............................................................20mA Output Current (all pins).....................................................20mAContinuous Power Dissipation (T A = +70°C)3-Pin SC70 (derate 2.9mW/°C above +70°C)..............235mW 4-Pin SC70 (derate 3.1mW/°C above +70°C)..............245mW 6-Pin µDFN (derate 2.1mW/°C above +70°C)..........167.7mW Operating Temperature Range .........................-40°C to+125°C Storage Temperature Range.............................-65°C to +150°C Lead Temperature (soldering,10s).................................+300°CMAX6381–MAX6390SC70/µDFN, Single/Dual Low-Voltage,Low-Power µP Reset Circuits_______________________________________________________________________________________3M A X 6381–M A X 6390SC70/µDFN, Single/Dual Low-Voltage, Low-Power µP Reset Circuits4______________________________________________________________________________________Typical Operating Characteristics(T A = +25°C, unless otherwise noted.)215436789-40-105-25203550658095110125SUPPLY CURRENT vs. TEMPERATURE(NO LOAD)TEMPERATURE (°C)S U P P L Y C U R R E N T (µA )25292735333137394143-40-105-25203550658095110125POWER-DOWN RESET DELAYvs. TEMPERATURETEMPERATURE (°C)P O W E R -D O W N R E S E T D E L A Y (µs )0.940.980.961.021.001.061.041.08-40-10520-253550658095110125 NORMALIZED POWER-UP RESET TIMEOUTvs. TEMPERATUREM A X 6381/90 t o c 03TEMPERATURE (°C)N O R M A L I Z E D R E S E T T I M E O U T P E R I O D0.9900.9851.0150.9950.9901.0001.0051.0101.020-40-10520-253550958011065125 M A X 6381/90 t o c 04TEMPERATURE (°C)N O R M A L I Z E D R E S E T TH R E S H O L D NORMALIZED RESET THRESHOLDvs. TEMPERATURE00.40.20.80.61.01.2063912OUTPUT-VOLTAGE LOW vs. SINK CURRENTI SINK (mA)V O L (V )01.00.52.01.52.53.00500750250100012501500OUTPUT-VOLTAGE HIGH vs. SOURCE CURRENTI SOURCE (µA)V O H (V )45001100010010MAXIMUM TRANSIENT DURATION vs. RESET COMPARATOR OVERDRIVE15050350250500200100400300RESET COMPARATOR OVERDRIVE, V TH - V CC (mV)M A X I M U M T R A N S I E N T D U R A T I O N (µs )3.53.93.74.54.34.14.74.95.35.15.5-40-105-25203550658095110125RESET IN TO RESET DELAYvs. TEMPERATUREM A X 6381/90 t o c 08TEMPERATURE (°C)R E S E T I N D E L A Y (µs )MAX6381–MAX6390SC70/µDFN, Single/Dual Low-Voltage,Low-Power µP Reset CircuitsPin DescriptionM A X 6381–M A X 6390SC70/µDFN, Single/Dual Low-Voltage, Low-Power µP Reset Circuits6_______________________________________________________________________________________ Detailed DescriptionRESET OutputA µP reset input starts the µP in a known state. These µP supervisory circuits assert reset to prevent code execution errors during power-up, power-down, or brownout conditions.Reset asserts when V CC is below the reset threshold;once V CC exceeds the reset threshold, an internal timer keeps the reset output asserted for the reset timeout period. After this interval, reset output deasserts. Reset output is guaranteed to bein the correct logic state for V CC ≥1V.Manual Reset Input (MAX6384/MAX6385/MAX6386/MAX6390)Many µP-based products require manual reset capabil-ity, allowing the operator, a test technician, or external logic circuitry to initiate a reset. A logic low on MR asserts reset. Reset remains asserted while MR is low,and for the reset active timeout period (t RP ) after MR returns high. This input has an internal 63k ?pullup resistor (1.56k ?for MAX6390), so it can be left uncon-nected if it is not used. MR can be driven with TTL or CMOS logic levels, or with open-drain/collector outputs.Connect a normally open momentary switch from MR to G ND to create a manual-reset function; external debounce circuitry is not required. If MR is driven from long cables or if the device is used in a noisy environ-ment, connecting a 0.1µF capacitor from MR to G ND provides additional noise immunity.RESET IN Comparator(MAX6387/MAX6388/MAX6389)RESET IN is compared to an internal +1.27V reference.If the voltage at RESET IN is less than 1.27V, reset asserts. Use the RESET IN comparator as a user-adjustable reset detector or as a secondary power-sup-ply monitor by implementing a resistor-divider at RESET IN (shown in Figure 1). Reset asserts when either V CC or RESET IN falls below its respective threshold volt-age. Use the following equation to set the threshold:V INTH = V THRST (R1/R2 + 1)where V THRST = +1.27V. To simplify the resistor selec-tion, choose a value of R2 and calculate R1:R1 = R2 [(V INTH /V THRST ) - 1]Since the input current at RESET IN is 50nA (max),large values can be used for R2 with no significant loss in accuracy.___________Applications InformationNegative-Going V CC TransientsIn addition to issuing a reset to the µP during power-up,power-down, and brownout conditions, the MAX6381–MAX6390 are relatively immune to short dura-tion negative-going V CC transients (glitches).The Typical Operating Characteristics section shows the Maximum Transient Durations vs. Reset Comparator Overdrive, for which the MAX6381–MAX6390 do not generate a reset pulse. This graph was generated usinga negative-going pulse applied to V CC , starting above the actual reset threshold and ending below it by the magnitude indicated (reset comparator overdrive). The graph indicates the typical maximum pulse width a neg-ative-going V CC transient may have without causing a reset pulse to be issued. As the magnitude of the tran-sient increases (goes farther below the reset threshold),the maximum allowable pulse width decreases. A 0.1µF capacitor mounted as close as possible to V CC provides additional transient immunity.Ensuring a Valid RESET Output Down to V CC = 0VThe MAX6381–MAX6390 are guaranteed to operate properly down to V CC = 1V. In applications that require valid reset levels down to V CC = 0V, a pulldown resistor to active-low outputs (push/pull only, Figure 2) and a pullup resistor to active-high outputs (push/pull only)will ensure that the reset line is valid while the reset out-put can no longer sink or source current. This schemedoes not work with the open-drain outputs of the MAX6383/MAX6386/MAX6389/MAX6390. The resistor value used is not critical, but it must be small enough not to load the reset output when V CC is above the reset threshold. For most applications, 100k ?is ade-quate.MAX6381–MAX6390SC70/µDFN, Single/Dual Low-Voltage,Low-Power µP Reset Circuits_______________________________________________________________________________________7M A X 6381–M A X 6390SC70/µDFN, Single/Dual Low-Voltage, Low-Power µP Reset Circuits 8_______________________________________________________________________________________ Selector GuideOrdering Information (continued)Note:Insert reset threshold suffix (see Reset Threshold table)after "XR", "XS", or "LT." Insert reset timeout delay (see Reset Timeout Delay table) after "D" to complete the part number.Sample stock is generally held on standard versions only (see Standard Versions table). Standard versions have an order increment requirement of 2500 pieces. Nonstandard versions have an order increment requirement of 10,000 pieces.Contact factory for availability of nonstandard versions.*MAX6390 is available with D4 or D7 timing only.+Denotes a lead-free package.MAX6381–MAX6390SC70/µDFN, Single/Dual Low-Voltage,Low-Power µP Reset Circuits_______________________________________________________________________________________9Chip InformationTRANSISTOR COUNT: 647PROCESS: BiCMOSPin Configurations (continued)M A X 6381–M A X 6390SC70/µDFN, Single/Dual Low-Voltage, Low-Power µP Reset Circuits10______________________________________________________________________________________ Package Information(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,go to /doc/5700977901f69e3143329415.html /packages .)MAX6381–MAX6390SC70/µDFN, Single/Dual Low-Voltage,Low-Power µP Reset Circuits______________________________________________________________________________________11Package Information (continued)(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,go to /doc/5700977901f69e3143329415.html /packages .)M A X 6381–M A X 6390SC70/µDFN, Single/Dual Low-Voltage, Low-Power µP Reset Circuits12______________________________________________________________________________________ Package Information (continued)(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,go to /doc/5700977901f69e3143329415.html /packages .)SC70/µDFN, Single/Dual Low-Voltage,Low-Power µP Reset CircuitsMaxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600____________________13?2007 Maxim Integrated Productsis a registered trademark of Maxim Integrated Products, Inc.MAX6381–MAX6390Package Information (continued)(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,go to /doc/5700977901f69e3143329415.html /packages .)Revision HistoryPages changed at Rev 4: Title on all pages, 1, 2, 5,7–13。

General DescriptionThe MAX6332/MAX6333/MAX6334 microprocessor (µP)supervisory circuits monitor the power supplies in 1.8V to 3.3V µP and digital systems. They increase circuit reliability and reduce cost by eliminating external com-ponents and adjustments.These devices perform a single function: they assert a reset signal whenever the V CC supply voltage declines below a preset threshold, keeping it asserted for a pre-set timeout period after V CC has risen above the reset threshold. The only difference among the three devices is their output. The MAX6333 (push/pull) and MAX6334(open-drain) have an active-low RESET output, while the MAX6332 (push/pull) has an active-high RESET out-put. The MAX6332/MAX6333 are guaranteed to be in the correct state for V CC down to 0.7V. The MAX6334 is guaranteed to be in the correct state for V CC down to 1.0V.The reset comparator in these ICs is designed to ignore fast transients on V CC . Reset thresholds are factory-trimmable between 1.6V and 2.5V, in approximately 100mV increments. There are 15 standard versions available (2,500 piece minimum-order quantity); con-tact the factory for availability of nonstandard versions (10,000 piece minimum-order quantity). For space-criti-cal applications, the MAX6332/MAX6333/MAX6334come packaged in a 3-pin SOT23.ApplicationsPentium II™ Computers Computers ControllersIntelligent InstrumentsCritical µP/µC Power Monitoring Portable/Battery-Powered Equipment AutomotiveFeatures♦Ultra-Low 0.7V Operating Supply Voltage♦Low 3.3µA Supply Current♦Precision Monitoring of 1.8V and 2.5V Power-Supply Voltages ♦Reset Thresholds Available from 1.6V to 2.5V,in Approximately 100mV Increments ♦Fully Specified over Temperature♦Three Power-On Reset Pulse Widths Available (1ms min, 20ms min, 100ms min)♦Low Cost♦Three Available Output Structures: Push/Pull RESET , Push/Pull RESET, Open-Drain RESET ♦Guaranteed RESET/RESET Valid to V CC = 0.7V (MAX6332/MAX6333)♦Power-Supply Transient Immunity ♦No External Components ♦3-Pin SOT23 Package♦Pin Compatible with MAX809/MAX810 and MAX6326/MAX6327/MAX6328MAX6332/MAX6333/MAX63343-Pin, Ultra-Low-Voltage, Low-PowerµP Reset Circuits________________________________________________________________Maxim Integrated Products119-1411; Rev 2; 12/05Ordering Information* These devices are available in factory-set V CC reset thresh-olds from 1.6V to 2.5V, in approximately 0.1V increments.Choose the desired reset threshold suffix from Table 1 and insert it in the blanks following “UR” in the part number.Factory-programmed reset timeout periods are also available.Insert the number corresponding to the desired nominal reset timeout period (1 = 1ms min, 2 = 20ms min, 3 = 100ms min) in the blank following “D” in the part number. There are 15 stan-dard versions with a required order increment of 2500 pieces.Sample stock is generally held on the standard versions only (see Selector Guide). Contact the factory for availability of non-standard versions (required order increment is 10,000 pieces).All devices available in tape-and-reel only.Devices are available in both leaded and lead-free packaging.Specify lead-free by replacing “-T” with “+T” when ordering.Typical Operating Circuit and Pin Configuration appear at end of data sheet.Selector Guide appears at end of data sheet.Pentium II is a trademark of Intel Corp.For pricing, delivery, and ordering information,please contact Maxim/Dallas Direct!at 1-888-629-4642, or visit Maxim’s website at .M A X 6332/M A X 6333/M A X 63343-Pin, Ultra-Low-Voltage, Low-Power µP Reset Circuits 2_______________________________________________________________________________________ABSOLUTE MAXIMUM RATINGSELECTRICAL CHARACTERISTICS(V CC = full range, T A = -40°C to +125°C, unless otherwise noted. Typical values are at T A = +25°C and V CC = 3V, reset not assert-Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.Terminal Voltage (with respect to GND)V CC ......................................................................-0.3V to +6V Push/Pull RESET, RESET .......................-0.3V to (V CC + 0.3V)Open-Drain RESET ..............................................-0.3V to +6V Input Current (V CC ).............................................................20mA Output Current (RESET, RESET ).........................................20mAContinuous Power Dissipation (T A = +70°C)SOT23-3 (derate 4mW/°C above +70°C)....................320mW Operating Temperature Range .........................-40°C to +125°C Storage Temperature Range.............................-65°C to +160°C Lead Temperature (soldering, 10s).................................+300°C3-Pin, Ultra-Low-Voltage, Low-PowerµP Reset Circuits_______________________________________________________________________________________32.02.62.23.03.63.83.43.24.0-602.4-40-202.820406080100SUPPLY CURRENT vs. TEMPERATURETEMPERATURE (°C)I C C (µA )0.9500.9900.9701.0001.0301.0401.0201.0101.050-60-400.980-2000.96020406080100NORMALIZED RESET TIMEOUT PERIODvs. TEMPERATURETEMPERATURE (°C)N O R M A L I Z E D R E S E T T I M E O U T P E R I O D1020-20403070605080-600-4020406080100V CCFALLING PROPAGATION DELAYvs. TEMPERATURETEMPERATURE (°C)P R O P A G A T I O N D E L A Y (µs )10010001002004003005006000.1110MAXIMUM TRANSIENT DURATION vs. RESET COMPARATOR OVERDRIVERESET COMPARATOR OVERDRIVE (mV)M A X I M U M T R A N S I E N T D U R A T I O N (µs )402080601001201401600.5 1.0 1.250.75 1.5 1.75 2.0 2.25 2.5OUTPUT VOLTAGE HIGH vs. SUPPLY VOLTAGEV CC (V)O U T P U T V O L T A G E H I G H (V C C - V O H ) (m V )20103060705040800.5 1.00 1.50 2.00 2.50 3.00OUTPUT VOLTAGE LOW vs. SUPPLY VOLTAGEV CC (V)O U T P U T V O L T A G E L O W (m V )Typical Operating Characteristics(Reset not asserted, T A = +25°C, unless otherwise noted.)MAX6332/MAX6333/MAX6334Pin DescriptionM A X 6332/M A X 6333/M A X 63343-Pin, Ultra-Low-Voltage, Low-Power µP Reset Circuits 4_____________________________________________________________________________________________________Applications InformationInterfacing to µPs with BidirectionalReset PinsSince the RESET output on the MAX6334 is open-drain,this device interfaces easily with µPs that have bidirec-tional reset pins, such as the Motorola 68HC11.Connecting the µP supervisor’s RESET output directly to the microcontroller’s (µC’s) RESET pin with a single pull-up resistor allows either device to assert reset (Figure 1).Negative-Going V CC TransientsIn addition to issuing a reset to the µP during power-up,power-down, and brownout conditions, these devices are relatively immune to short-duration, negative-going V CC transients (glitches). The Typical Operating Characteristics show the Maximum Transient Duration vs. Reset Comparator Overdrive graph. The graph shows the maxi-mum pulse width that a negative-going V CC transient may typically have without issuing a reset signal. As the ampli-tude of the transient increases, the maximum allowable pulse width decreases.Ensuring a Valid Reset OutputDown to V CC = 0When V CC falls below 1V and approaches the minimum operating voltage of 0.7V, push/pull-structured reset sinking (or sourcing) capabilities decrease drastically.High-impedance CMOS-logic inputs connected to the RESET pin can drift to indeterminate voltages. This does not present a problem in most cases, since most µPs and circuitry do not operate at V CC below 1V. For the MAX6333, where RESET must be valid down to 0,adding a pull-down resistor between RESET and GND removes stray leakage currents, holding RESET low (Figure 2a). The pull-down resistor value is not critical;100k Ωis large enough not to load RESET and small enough to pull it low. For the MAX6332, where RESET must be valid to V CC = 0, a 100k Ωpull-up resistor between RESET and V CC will hold RESET high when V CC falls below 0.7V (Figure 2b).Since the MAX6334 has an open-drain, active-low out-put, it typically uses a pull-up resistor. With this device,RESET will most likely not maintain an active condition,but will drift to a non-active level due to the pull-up resistor and the reduced sinking capability of the open-drain device. Therefore, this device is not recommend-ed for applications where the RESET pin is required to be valid down to V CC = 0.* Factory-trimmed reset thresholds are available in approximately 100mV increments, with a ±1.8% room-temperature variance.Table 1. Factory-Trimmed Reset Thresholds*Figure 1. Interfacing to µPs with Bidirectional Reset PinsFigure 2. Ensuring Reset Valid Down to V CC = 03-Pin, Ultra-Low-Voltage, Low-PowerµP Reset Circuits_______________________________________________________________________________________5MAX6332/MAX6333/MAX6334Pin ConfigurationSelector Guide (Standard Versions *)Typical Operating Circuit* Sample stock is generally held on all standard versions.M A X 6332/M A X 6333/M A X 63343-Pin, Ultra-Low-Voltage, Low-Power µP Reset Circuits Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.6_____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600©2005 Maxim Integrated ProductsPrinted USAis a registered trademark of Maxim Integrated Products, Inc.TRANSISTOR COUNT:505Chip InformationPackage Information(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,go to /packages .)。

Eaton MMX32AA017F0-0Eaton M-Max Series Adjustable Frequency Drive Full version AA software design series FS4 frame 200–240V 3–phase in 230V three–phase out IP20 enclosure rating 5 hp 17A Output current 17A Nomincal AC currentGeneral specificationsEaton M-Max Series sensorless vector adjustable frequency driveMMX32AA017F0-06.5 in14.57 in 6.61 in 12.5 lbEaton Selling Policy 25-000 generally applies with some exceptions. Drive products come with a standard 24 months from date of shipment and 36 months with Eaton certified start up all inclusive coverage parts labor and travel.EMC Category C2, C3, and C4 (Level H): With an internal RFI filter option CE Marked RoHS Compliant C-Tick CompliantEN 60204-1 UL Listed EN 61800-3 EN 61800-5-1 cUL Listed IEC RatedPlease consult factory for extended warranty options.Product NameCatalog Number Product Length/Depth Product Height Product Width Product Weight WarrantyCompliancesCertifications Catalog NotesEaton Corporation plc Eaton House30 Pembroke Road Dublin 4, Ireland © 2023 Eaton. All rights reserved. Eaton is a registered trademark.All other trademarks areproperty of their respective owners./socialmedia4EMC Category C2 C3 and C4 (Level H) with an internal RFI filter option Full version Three-phase 5 hp17 A AA IP2017 A 200-240 V, 230 VVariable frequency drive - Product overview M-Max Series adjustable frequency drives Eaton's Volume 6—Solid-State Motor Control MMX_(FR4) 2D PDFMMX_(FR4) 2D Drawing Xchange MMX_(FR4) 3D Model Xchange MMX_(FR4) 3D InventorMMX_(FR4) AutoCAD 2D Footprint MMX_(FR4) AutoCAD 2D Footprint (mm)User Manual, M-Max Series Adjustable Frequency Drive Eaton Specification Sheet - MMX32AA017F0-0Frame size Protection filteringOptions Phase Horsepower Nominal AC current Software Enclosure Output current - max Voltage rating BrochuresCataloguesDrawingsInstallation instructionsSpecifications and datasheets。

NVIDIA® Mellanox® ConnectX®-6 Dx SmartNIC is the industry’s most secure and advanced cloud network interface card to accelerate mission-critical data-center applications, such as security, virtualization, SDN/NFV, big data, machine learning, and storage. The SmartNIC provides up to two ports of 100 Gb/s Ethernet connectivity and delivers the highest return on investment (ROI) of any smart network interface card.ConnectX-6 Dx is a member of NVIDIA Mellanox’s world-class, award-winning ConnectX series of network adapters powered by leading 50 Gb/s (PAM4) and 25/10 Gb/s (NRZ) SerDes technology and novel capabilities that accelerate cloud and data-center payloads. SECURITY FROM ZERO TRUST TO HERO TRUSTIn an era where privacy of information is key and zero trust is the rule, ConnectX-6 Dx adapters offer a range of advanced built-in capabilities that bring security down to the endpoints with unprecedented performance and scalability, including:>Probes & DoS Attack Protection – ConnectX-6 Dx enables a hardware-based L4 firewall by offloading stateful connection tracking through Mellanox ASAP2 - Accelerated Switch and Packet Processing®.>NIC Security – Hardware Root-of-Trust (RoT) Secure Boot and secure firmware update using RSA cryptography, and cloning-protection, via a device-unique secret key. ADVANCED VIRTUALIZATIONConnectX-6 Dx delivers another level of innovation to enable building highly efficient virtualized cloud data centers:>Virtualization – Mellanox ASAP2 technology for vSwitch/vRouter hardware offloaddelivers orders of magnitude higher performance vs. software-based solutions.ConnectX-6 Dx ASAP2 offers both SR-IOV and VirtIO in-hardware offload capabilities, and supports up to 8 million rules.>Advanced Quality of Service – Includes traffic shaping and classification-baseddata policing. SmartNIC Portfolio>1/10/25/40/50/100 Gb/s Ethernet,PAM4/NRZ>PCIe low-profile form factor>QSFP56 connectors>PCIe Gen 3.0/4.0 x16 host interface Key Features>Up to 100 Gb/s bandwidth>Message rate of up to 215 Mpps>Sub 0.8 usec latency>Flexible programmable pipeline for new network flows>ASAP2 - Accelerated Switching and Packet Processing for virtual switches/routers >Overlay tunneling technologies>Hardware Root-of-Trust and secure firmware update>Connection Tracking offload>Advanced RoCE capabilities>Best in class PTP for TSN applications>GPUDirect® for GPU-to-GPU communication>Host chaining technology for economical rack design>Platform agnostic: x86, Power, Arm>ODCC compatibleNVIDIA MELLANOX CONNECTX-6 DX DELL EMC ETHERNET SMARTNICINDUSTRY-LEADING ROCEFollowing the Mellanox ConnectX tradition of industry-leading RoCE capabilities, ConnectX-6 Dx adds another layer of innovation to enable more scalable, resilient and easy-to-deploy RoCE solutions.>Zero Touch RoCE – Simplifying RoCE deployments, ConnectX-6 Dx allows RoCEpayloads to run seamlessly on existing networks without requiring special configuration on the network (no PFC, no ECN). New features in ConnectX-6 Dx ensure resiliency and efficiency at scale of such deployments.>Configurable Congestion Control – API to build user-defined congestion controlalgorithms, best serving various environments and RoCE and TCP/IP traffic patterns. BEST IN CLASS PTP FOR TIME SENSITIVE APPLICATIONS Mellanox offers a full IEEE 1588v2 PTP software solution as well as time sensitive related features called 5T45G. Mellanox PTP and 5T45G software solutions are designed to meet the most demanding PTP profiles. ConnectX-6 Dx incorporates an integrated Hardware Clock (PHC) that allows the device to achieve sub-20 usec accuracy while offering various timing related functions, including time-triggered scheduling or time-based SND accelerations (time based ASAP²). Furthermore, 5T45G technology enables software applications to transmit front-haul (ORAN) compatible in high bandwidth. The PTP solution supports slave clock, master clock, and boundary clock.EFFICIENT STORAGE SOLUTIONSWith its NVMe-oF target and initiator offloads, ConnectX-6 Dx brings further optimization to NVMe-oF, enhancing CPU utilization and scalability. Additionally, ConnectX-6 Dx supports hardware offload for ingress/egress of T10-DIF/PI/CRC32/CRC64 signatures. Solutions>Cloud-native, Web 2.0, hyperscale >Enterprise data-centers>Cyber security>Big data analytics>Scale-out compute and storage infrastructure>Telco and Network Function Virtualization (NFV)>Cloud storage>Machine Learning (ML) and Artificial Intelligence (AI)>Media and EntertainmentORDERING INFORMATION1 50G can be supported as either 2x25G NRZ or 1x50G PAM4 when using QSFP56.2 100G can be supported as either 4x25G NRZ or 2x50G PAM4 when using QSFP56. By default, the above products are shipped with a tall bracket mounted;a short bracket is included as an accessory.Learn more at /products/ethernet/connectx-smartnic© 2020 Mellanox Technologies. All rights reserved. NVIDIA, the NVIDIA logo, Mellanox, ConnectX, GPUDirect, Mellanox PeerDirect, and ASAP 2 - Accelerated Switch and Packet Processing are trademarks and/or registered trademarks of Mellanox Technologies Ltd. FEATURES *>IEEE 802.3cd, 50, 100 and 200 Gigabit Ethernet>IEEE 802.3bj, 802.3bm 100 Gigabit Ethernet>IEEE 802.3by, 25, 50 Gigabit Ethernet supporting all FEC modes>IEEE 802.3ba 40 Gigabit Ethernet >IEEE 802.3ae 10 Gigabit Ethernet >IEEE 802.3az Energy Efficient Ethernet (supports only “Fast-Wake” mode)>IEEE 802.3ap based auto-negotiation and KR startup >IEEE 802.3ad, 802.1AX Link Aggregation>IEEE 802.1Q, 802.1P VLAN tags and priority>IEEE 802.1Qaz (ETS) >IEEE 802.1Qbb (PFC) >IEEE 802.1Qbg>25/50 Ethernet Consortium “Low Latency FEC” for50GE/100GE/200GE PAM4 links >PCI Express Gen 3.0 and 4.0STANDARDS *Network Interface>2 x 25/50/100 GbEHost Interface>PCIe Gen 4.0, 3.0, 2.0, 1.1>16.0, 8.0, 5.0, 2.5 GT/s link rate >16 lanes of PCIe> MSI/MSI-X mechanisms >Advanced PCIe capabilitiesVirtualization/Cloud Native>Single Root IOV (SR-IOV) and VirtIO acceleration>Up to 1 K VFs per port >8 PFs>Support for tunneling>Encap/decap of VXLAN, NVGRE, Geneve, and more>Stateless offloads for Overlay tunnelsMellanox ASAP 2> SDN acceleration for:>Bare metal >Virtualization >Containers>Full hardware offload for OVS data plane>Flow update through RTE_Flow or TC_Flower >OpenStack support >Kubernetes support>Rich classification engine (L2 to L4) >Flex-Parser: user defined classification >Hardware offload for:>Connection tracking (L4 firewall) >NAT>Header rewrite >Mirroring >Sampling >Flow aging >Hierarchial QoS>Flow-based statisticsPlatform Security>Hardware root-of-trust >Secure firmware updateStateless Offloads>TCP/UDP/IP stateless offload >LSO, LRO, checksum offload>Receive Side Scaling (RSS) also on encapsulated packet>Transmit Side Scaling (TSS)>VLAN and MPLS tag insertion/stripping >Receive flow steeringAdvanced Timing & Synchronization>Advanced PTP>IEEE 1588v2 (any profile)>PTP Hardware Clock (PHC) (UTC format) >16 nsec accuracy>Line rate hardware timestamp (UTC format) >Time triggered scheduling >PTP based packet pacing>Time based SDN acceleration (ASAP 2) >Time Sensitive Networking (TSN)Storage Accelerations>NVMe over Fabric offloads for target>Storage protocols: iSER, NFSoRDMA, SMB Direct, NVMe-oF, and more >T-10 Dif/Signature HandoverRDMA over Converged Ethernet (RoCE)>RoCE v1/v2>Zero Touch RoCE: no ECN, no PFC >RoCE over overlay networks >Selective repeat>Programmable congestion control interface >GPUDirect ®>Burst buffer offloadManagement and Control>PLDM for Monitor and Control DSP0248 >PLDM for Firmware Update DSP026 >I 2C interface for device control and configurationRemote Boot>Remote boot over Ethernet >Remote boot over iSCSI>UEFI support for x86 and Arm servers >PXE boot* This section describes hardware features and capabilities. Please refer to the driver and firmware release notes for feature availability.。

用于Peltier模块的集成温度控制器概论MAX1978 / MAX1979是用于Peltier热电冷却器（TEC）模块的最小, 最安全, 最精确完整的单芯片温度控制器。

片上功率FET和热控制环路电路可最大限度地减少外部元件, 同时保持高效率。

可选择的500kHz / 1MHz开关频率和独特的纹波消除方案可优化元件尺寸和效率, 同时降低噪声。

内部MOSFET的开关速度经过优化, 可降低噪声和EMI。

超低漂移斩波放大器可保持±0.001°C的温度稳定性。

直接控制输出电流而不是电压, 以消除电流浪涌。

独立的加热和冷却电流和电压限制提供最高水平的TEC保护。

MAX1978采用单电源供电, 通过在两个同步降压调节器的输出之间偏置TEC, 提供双极性±3A输出。

真正的双极性操作控制温度, 在低负载电流下没有“死区”或其他非线性。

当设定点非常接近自然操作点时, 控制系统不会捕获, 其中仅需要少量的加热或冷却。

模拟控制信号精确设置TEC 电流。

MAX1979提供高达6A的单极性输出。

提供斩波稳定的仪表放大器和高精度积分放大器, 以创建比例积分（PI）或比例积分微分（PID）控制器。

仪表放大器可以连接外部NTC或PTC热敏电阻, 热电偶或半导体温度传感器。

提供模拟输出以监控TEC温度和电流。

此外, 单独的过热和欠温输出表明当TEC温度超出范围时。

片上电压基准为热敏电阻桥提供偏置。

MAX1978 / MAX1979采用薄型48引脚薄型QFN-EP 封装, 工作在-40°C至+ 85°C温度范围。

采用外露金属焊盘的耐热增强型QFN-EP封装可最大限度地降低工作结温。

评估套件可用于加速设计。

应用光纤激光模块典型工作电路出现在数据手册的最后。

WDM, DWDM激光二极管温度控制光纤网络设备EDFA光放大器电信光纤接口ATE特征♦尺寸最小, 最安全, 最精确完整的单芯片控制器♦片上功率MOSFET-无外部FET♦电路占用面积<0.93in2♦回路高度<3mm♦温度稳定性为0.001°C♦集成精密积分器和斩波稳定运算放大器♦精确, 独立的加热和冷却电流限制♦通过直接控制TEC电流消除浪涌♦可调节差分TEC电压限制♦低纹波和低噪声设计♦TEC电流监视器♦温度监控器♦过温和欠温警报♦双极性±3A输出电流（MAX1978）♦单极性+ 6A输出电流（MAX1979）订购信息* EP =裸焊盘。

B G A w i t h O p e n J o i n t sXD7800NT Ruby XL X-ray Inspection SystemAdvantagesD AGE NT500 Maintenance-Free, Sealed-Transmissive X-ray Tube< 0.5 μm Feature Recognition160 kV Tube with Up to 10 W Target Power - Always Retains Sub-Micron AbilityD AGE 3 Mpixel @ 25fps Long Lifetime CMOS Flat Panel Detector with Real Time Image Enhancements G eometric Magnification 1,800 X, System 7,800 X for Total 23,400 X with Digital ZoomDAGE, the only x-ray company whose focus is on x-ray electronics inspection, offers the DAGE XD7800NT Ruby XL x-ray inspection system as the DAGE NT maintenance-free, sealed-transmissive x-ray tube, providing 0.5 μm feature The Solution for Large Board Applicationsall controlled through simple, joystick-free, ‘point and click’ operation, provides the safe, collision-free and high magnification inspection required for production applications. All these tasks can be simply 33” x 24.2” (840 x 615mm) Tray Size47” x 26.4” (1205 x 672 mm) Maximum Board Size with reduced Magnification70° Oblique Views without Loss of Magnification T wo 24” TFT LCD MonitorsAXiS - Active X-ray Image StabilizationNo Programming Skills Required for Automated Inspection TasksO ptions: X-Plane®; Joysticks For more information, speak with your Nordson representative or contact your Nordson regional officeAmericas+ 1 760 930 3307*********************Europe+44 1296 317800***************************China+86 512 6665 2008************************Germany+49 89 2000 338 270************************Japan+81 120 537 555************************Korea+82 31 462 9642***********************South East Asia+65 6552 7533************************Taiwan+886 2 2902 1860***************************United Kingdom+44 1296 317800***************************XD7800NT Ruby XL X-ray Inspection System Specifications• DAGE NT500 sealed-transmissive, filament-free x-ray tube:– < 0.5 μm feature recognition 30 - 160 kV for < 4 W target power– < 0.95 μm feature recognition when above 4 W target power– 10 W max. target power above 110 kV– automated tube stabilisation• 1,800 X geometric magnification (7,800 X system magnification)• 23,400 X total magnification including digital zoom• Easy, collision-free, high magnification inspection:– even at oblique angle views– joystick-free, ‘point and click’ operation• Tray size: 33” x 24.2” (840 x 615mm)• Maximum board size: 47” x 26.4” (1205 x 672 mm) with reduced magnification *Please refer to Dage for clarification for larger boards• Maximum inspection area: 33” x 24.2” (840 x 615mm)• 70° oblique angle views (over 30” x 24”, 762 x 610 mm):– for 360° around a point of interest– isocentric manipulator configuration keeps features in field of view • Long Lifetime CMOS digital detector with 1940 x 1530 pixels (3 Mpixels)– 25 fps full-frame ‘real time’ image acquisition– real time image enhancements• 16-bit digital image processing• AXiS - Active X-ray Image Stabilisation - anti-vibration control• Two off 24” TFT LCD operator display monitors• DAGE Image Wizard operating software including:– automated and manual component fault analysis including BGA & QFN– simple to create and use robust automated inspection routines– plated through hole (PTH) fill percentage calculation– accurate measurement functions– automated and manual die attach / area void calculation– patented1 X-ray navigation map for easy fault location– simple to use, no complicated joysticks required• Fully lead-shielded system safety cabinet– providing < 1 μSv/hr x-ray leakage– meets all international standards• 1 years system warrantyOptions• P atented X-Plane® 2• J oystick control (X,Y or X,Y & Z)• B arcode reader• 2nd Year warranty System• A pproximate Size: 94.5” x 98.5” x 81.5” (w x d x h)• A pproximate Size: 2400 x 2500 x 2070 mm (w x d x h)• A pproximate System Weight: 3000 kg (6600 lbs)• M aximum Sample Weight: 10 kg (22 lbs)• P ower: Single Phase 200 - 230Vac, 16A• M ax. P ower Consumption: 1000 W Max.• A ir: 4-6 bar of clean dry air for anti-vibration• O perating Temp. Range: 10 - 30ºC• H umidity: < 85% (non-condensing)1 EP 20632612 US 9129427 DS-RXL-110821。

General DescriptionThe MAX6369–MAX6374 are pin-selectable watchdog timers that supervise microprocessor (µP) activity and signal when a system is operating improperly. During normal operation, the microprocessor should repeated-ly toggle the watchdog input (WDI) before the selected watchdog timeout period elapses to demonstrate that the system is processing code properly. If the µP does not provide a valid watchdog input transition before the timeout period expires, the supervisor asserts a watch-dog (WDO ) output to signal that the system is not exe-cuting the desired instructions within the expected time frame. The watchdog output pulse can be used to reset the µP or interrupt the system to warn of processing errors.The MAX6369–MAX6374 are flexible watchdog timer supervisors that can increase system reliability through notification of code execution errors. The family offers several pin-selectable watchdog timing options to match a wide range of system timing applications:•Watchdog startup delay: provides an initial delay before the watchdog timer is started.•Watchdog timeout period: normal operating watch-dog timeout period after the initial startup delay.•Watchdog output/timing options: open drain (100ms)or push-pull (1ms).The MAX6369–MAX6374 operate over a +2.5V to +5.5V supply range and are available in miniature 8-pin SOT23 packages.________________________ApplicationsEmbedded Control Systems Industrial ControllersCritical µP and Microcontroller (µC) Monitoring AutomotiveTelecommunications NetworkingFeatures♦Precision Watchdog Timer for Critical µP Applications ♦Pin-Selectable Watchdog Timeout Periods ♦Pin-Selectable Watchdog Startup Delay Periods ♦Ability to Change Watchdog Timing Characteristics Without Power Cycling ♦Open-Drain or Push-Pull Pulsed Active-Low Watchdog Output ♦Watchdog Timer Disable Feature ♦+2.5V to +5.5V Operating Voltage ♦8µA Low Supply Current♦No External Components Required ♦Miniature 8-Pin SOT23 PackageMAX6369–MAX6374Pin-Selectable Watchdog Timers19-1676; Rev 3; 11/05Ordering InformationPin Configuration appears at end of data sheet.Note:All devices are available in tape-and-reel only. Required order increment is 2,500 pieces.Devices are available in both leaded and lead-free packaging.Specify lead-free by replacing “-T” with “+T” when ordering.Selector GuideFor pricing, delivery, and ordering information,please contact Maxim/Dallas Direct!at1-888-629-4642, or visit Maxim’s website at .M A X 6369–M A X 6374Pin-Selectable Watchdog Timers 2_______________________________________________________________________________________ABSOLUTE MAXIMUM RATINGSELECTRICAL CHARACTERISTICS(V CC = +2.5V to +5.5V, SET_ = V CC or GND, T A = -40°C to +85°C, unless otherwise noted. Typical values are at T A = +25°C andStresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.Terminal Voltage (with respect to GND)V CC .....................................................................-0.3V to +6V WDI.....................................................................-0.3V to +6V WDO (Open Drain: MAX6369/71/73).................-0.3V to +6V WDO (Push-Pull: MAX6370/72/74 .......-0.3V to (V CC + 0.3V)SET0, SET1, SET2................................-0.3V to (V CC + 0.3V)Maximum Current, Any Pin (input/output)...........................20mAContinuous Power Dissipation (T A = +70°C)SOT23-8 (derate 8.75mW/°C above +70°C)...............700mW Operating Temperature Range ...........................-40°C to +85°C Storage Temperature Range.............................-65°C to +150°C Junction Temperature......................................................+150°C Lead Temperature (soldering, 10s).................................+300°C V CC Rise or Fall Rate......................................................0.05V/µsMAX6369–MAX6374Pin-Selectable Watchdog Timers_______________________________________________________________________________________3ELECTRICAL CHARACTERISTICS (continued)M A X 6369–M A X 6374Pin-Selectable Watchdog Timers 4_______________________________________________________________________________________461081214-4010-15356085SUPPLY CURRENT vs. TEMPERATURETEMPERATURE (°C)S U P P L Y C U R R E N T (µA )Typical Operating Characteristics(Circuit of Figure 1, T A = +25°C, unless otherwise noted .)0.9970.9990.9981.0011.0001.0021.003-4010-15356085WATCHDOG TIMEOUT PERIODvs. TEMPERATUREM A X 6369/74-02TEMPERATURE (°C)N O R M A L I Z E D W A T C H D O G T I M E O U T P E R I O DELECTRICAL CHARACTERISTICS (continued)Note 2:Guaranteed by design.Note 3:In this setting the watchdog timer is inactive and startup delay ends when WDI sees its first level transition. See SelectingDevice Timing for more information.Note 4:After power-up, or a setting change, there is an internal setup time during which WDI is ignored.MAX6369–MAX6374Pin-Selectable Watchdog Timers_______________________________________________________________________________________5Pin DescriptionDetailed DescriptionThe MAX6369–MAX6374 are flexible watchdog circuits for monitoring µP activity. During normal operation, the internal timer is cleared each time the µP toggles the WDI with a valid logic transition (low to high or high to low) within the selected timeout period (t WD ). The WDO remains high as long as the input is strobed within the selected timeout period. If the input is not strobed before the timeout period expires, the watchdog output is asserted low for the watchdog output pulse width (t WDO ). The device type and the state of the three logic control pins (SET0, SET1, and SET2) determine watch-dog timing characteristics. The three basic timing varia-tions for the watchdog startup delay and the normalTable 1 for the timeout characteristics for all devices in the family):•Watchdog Startup Delay:Provides an initial delay before the watchdog timer is started.Allows time for the µP system to power up and initial-ize before assuming responsibility for normal watch-dog timer updates.Includes several fixed or pin-selectable startup delay options from 200µs to 60s, and an option to wait for the first watchdog input transition before starting the watchdog timer.M A X 6369–M A X 6374Pin-Selectable Watchdog Timers 6_______________________________________________________________________________________•Watchdog Timeout Period:Normal operating watchdog timeout period after the initial startup delay.A watchdog output pulse is asserted if a valid watch-dog input transition is not received before the timeout period elapses.Eight pin-selectable timeout period options for each device, from 30µs to 60s.Pin-selectable watchdog timer disable feature.•Watchdog Output/Timing Options:Open drain, active low with 100ms minimum watch-dog output pulse (MAX6369/MAX6371/MAX6373).Push-pull, active low with 1ms minimum watchdog output pulse (MAX6370/MAX6372/MAX6374).Each device has a watchdog startup delay that is initi-ated when the supervisor is first powered or after the user modifies any of the logic control set inputs. The watchdog timer does not begin to count down until theFigure 1. Functional Diagramcompletion of the startup delay period, and no watch-dog output pulses are asserted during the startup delay. When the startup delay expires, the watchdog begins counting its normal watchdog timeout period and waiting for WDI transitions. The startup delay allows time for the µP system to power up and fully ini-tialize before assuming responsibility for the normal watchdog timer updates. Startup delay periods vary between the different devices and may be altered by the logic control set pins. To ensure that the system generates no undesired watchdog outputs, the routine watchdog input transitions should begin before the selected minimum startup delay period has expired. The normal watchdog timeout period countdown is initi-ated when the startup delay is complete. If a valid logic transition is not recognized at WDI before the watchdog timeout period has expired, the supervisor asserts a watchdog output. Watchdog timeout periods vary between the different devices and may be altered by the logic control set pins. To ensure that the system generates no undesired watchdog outputs, the watch-dog input transitions should occur before the selected minimum watchdog timeout period has expired.The startup delay and the watchdog timeout period are determined by the states of the SET0, SET1, and SET2 pins, and by the particular device within the family. For the MAX6369 and MAX6370, the startup delay is equal to the watchdog timeout period. The startup and watchdog timeout periods are pin selectable from 1ms to 60s (minimum).For the MAX6371 and MAX6372, the startup delay is fixed at 60s and the watchdog timeout period is pin selectable from 1ms to 60s (minimum).The MAX6373/MAX6374 provide two timing variations for the startup delay and normal watchdog timeout. Five of the pin-selectable modes provide startup delays from 200µs to 60s minimum, and watchdog timeout delays from 3ms to 10s minimum. Two of the selectable modes do not initiate the watchdog timer until the device receives its first valid watchdog input transition (there is no fixed period by which the first input must be received). These two extended startup delay modesare useful for applications requiring more than 60s for system initialization.All the MAX6369–MAX6374 devices may be disabledwith the proper logic control pin setting (Table 1).Applications InformationInput Signal Considerations Watchdog timing is measured from the last WDI risingor falling edge associated with a pulse of at least 100nsin width. WDI transitions are ignored when WDO is asserted, and during the startup delay period (Figure2). Watchdog input transitions are also ignored for asetup period, t SETUP, of up to 300µs after power-up ora setting change (Figure 3).Selecting Device TimingSET2, SET1, and SET0 program the startup delay and watchdog timeout periods (Table 1). Timeout settingscan be hard wired, or they can be controlled with logicgates and modified during operation. To ensure smooth transitions, the system should strobe WDI immediately before the timing settings are changed. This minimizesthe risk of initializing a setting change too late in thetimer countdown period and generating undesired watchdog outputs. After changing the timing settings,two outcomes are possible based on WDO. If the change is made while WDO is asserted, the previous setting is allowed to finish, the characteristics of thenew setting are assumed, and the new startup phase is entered after a 300µs setup time (t SETUP) elapses. Ifthe change is made while WDO is not asserted, thenew setting is initiated immediately, and the new start-up phase is entered after the 300µs setup time elapses.MAX6369–MAX6374Pin-Selectable Watchdog Timers_______________________________________________________________________________________7 Figure 3. Setting Change TimingM A X 6369–M A X 6374Pin-Selectable Watchdog TimersSelecting 011 (SET2 = 0, SET1 = 1, SET0 = 1) disables the watchdog timer function on all devices in the family.Operation can be reenabled without powering down by changing the set inputs to the new desired setting. The device assumes the new selected timing characteris-tics and enter the startup phase after the 300µs setup time elapses (Figure 3).The MAX6373/MAX6374 offer a first-edge feature. In first-edge mode (settings 101 or 110, Table 1), the internal timer does not control the startup delay period.Instead, startup terminates when WDI sees a transition.If changing to first-edge mode while the device is oper-ating, disable mode must be entered first. It is then safe to select first-edge mode. Entering disable mode first ensures the output is unasserted when selecting first-edge mode and removes the danger of WDI being masked out.OutputThe MAX6369/MAX6371/MAX6373 have an active-low,open-drain output that provides a watchdog output pulse of 100ms. This output structure sinks current when WDO is asserted. Connect a pullup resistor from WDO to any supply voltage up to +5.5V.Select a resistor value large enough to register a logic low (see Ele ctrical Characte ristics ), and small enoughto register a logic high while supplying all input current and leakage paths connected to the WDO line. A 10k Ωpullup is sufficient in most applications. The MAX6370/MAX6372/MAX6374 have push-pull outputs that pro-vide an active-low watchdog output pulse of 1ms.When WDO deasserts, timing begins again at the beginning of the watchdog timeout period (Figure 2).Usage in Noisy EnvironmentsIf using the watchdog timer in an electrically noisy envi-ronment, a bypass capacitor of 0.1µF should be con-nected between V CC and GND as close to the device as possible, and no further away than 0.2 inches.________________Watchdog SoftwareConsiderationsTo help the watchdog timer monitor software execution more closely, set and reset the watchdog input at differ-ent points in the program, rather than pulsing the watch-dog input high-low-high or low-high-low. This technique avoids a stuck loop, in which the watchdog timer would continue to be reset inside the loop, keeping the watch-dog from timing out. Figure 4 shows an example of a flow diagram where the I/O driving the watchdog input is set high at the beginning of the program, set low at the end of every subroutine or loop, then set high again when the program returns to the beginning. If the pro-gram should hang in any subroutine, the problem would be quickly corrected, since the I/O is continually set low and the watchdog timer is allowed to time out, causing WDO to pulse.Figure 4. Watchdog Flow DiagramChip InformationTRANSISTOR COUNT: 1500PROCESS: BiCMOSPin ConfigurationMaxim cannot assume re sponsibility for use of any circuitry othe r than circuitry e ntire ly e mbodie d in a Maxim product. No circuit pate nt lice nse s are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.8_____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600©2005 Maxim Integrated ProductsPrinted USAis a registered trademark of Maxim Integrated Products, Inc.。

P/N: 1802051010013*1802051010013*MGate 5101-PBM-MN Quick Installation GuideVersion 3.1, November 2019Technical Support Contact Information /support Moxa Americas:Toll-free: 1-888-669-2872Tel: 1-714-528-6777Fax: 1-714-528-6778 Moxa China (Shanghai office): Toll-free: 800-820-5036 Tel: +86-21-5258-9955 Fax: +86-21-5258-5505 Moxa Europe:Tel: +49-89-3 70 03 99-0Fax: +49-89-3 70 03 99-99 Moxa Asia-Pacific: Tel: +886-2-8919-1230 Fax: +886-2-8919-1231 Moxa India:Tel: +91-80-4172-9088Fax: +91-80-4132-10452019 Moxa Inc. All rights reserved.OverviewThe MGate 5101-PBM-MN is an industrial Ethernet gateway for PROFIBUS-to-Modbus-TCP network communication.Package ChecklistBefore installing the MGate 5101-PBM-MN, verify that the package contains the following items:• 1 MGate 5101-PBM-MN gateway•Quick installation guide (printed)•Warranty CardPlease notify your sales representative if any of the above items are missing or damaged.Optional Accessories (can be purchased separately): •CBL-F9M9-150: DB9-female-to-DB9-male serial cable, 150 cm •CBL-F9M9-20: DB9-female-to-DB9-male serial cable, 20 cm •Mini DB9F-to-TB: DB9-female-to-terminal-block connector •WK-36-01: Wall-mounting kitHardware IntroductionLED IndicatorsLED Color FunctionPWR1 Green Power is on Off Power is offPWR2 Green Power is on Off Power is offReady GreenSteady on: Power is on and the MGate isfunctioning normallyBlinking: The MGate has been located by theMGate Manager’s Location functionRedSteady on: Power is on and the MGate is bootingupBlinking: Indicates an IP conflict, or the DHCP orBOOTP server is not responding properlyOff Power is off or fault condition existsCOMMOff No data exchangeGreen Data exchange with all slavesGreen,flashingData exchange with at least one slave (not allconfigured slaves can communicate with gateway) Red Bus control errorCFGOff No PROFIBUS configuration Green PROFIBUS configuration OKPBMOff PROFIBUS master is offlineRed PROFIBUS master is in STOP mode Green,flashingPROFIBUS master is in CLEAR mode Green PROFIBUS master is in OPERATE modeTOK Green Gateway holds the PROFIBUS tokenOff Gateway is waiting for the PROFIBUS tokenLED Color FunctionEthernet AmberSteady: 10Mbps, no data is transmittingBlinking: 10Mbps, data is transmitting GreenSteady: 100Mbps, no data is transmittingBlinking: 100Mbps, data is transmitting Off Ethernet cable is disconnectedReset ButtonThe reset button is used to load factory defaults. Use a pointed object such as a straightened paper clip to hold the reset button down for five seconds. Release the reset button when the Ready LED stops blinking. Hardware Installation ProcedureSTEP 1:Connect the power adapter. Connect the 12-48 VDC power line or DIN-rail power supply with the MGate 5101-PBM-MNdevice’s terminal block. Make sure the adapter is connected toan earthed socket.STEP 2:Use a PROFIBUS cable to connect the unit to a PROFIBUS slave device.STEP 3:Connect the unit to the Modbus TCP device.STEP 4:The MGate 5101-PBM-MN series is designed to be attached toa DIN rail or mounted on a wall. For DIN-rail mounting, pushdown the spring and properly attach it to the DIN-rail until it“snaps” into place. For wall mounting, install the wall-mountkit (optional) first and then screw the device onto the wall.Wall or Cabinet MountingTwo metal plates are provided for mounting theunit on a wall or inside a cabinet. Attach the platesto the unit’s rear panel with screws. With the platesattached, use screws to mount the unit on a wall.The heads of the screws should be 5 to 7 mm indiameter, the shafts should be 3 to 4 mm indiameter, and the length of the screws should bemore than 10.5 mm.For each screw, the head should be 6 mm or less in diameter, and the shaft should be 3.5 mm or less in diameter.The following figure illustrates the two mounting options:Software Installation InformationTo install MGate Manager, please download it from Moxa’s website at . For more detailed information about MGateManager, click the Documents button and select the MGate 5101-PBM-MN User’s Manual.The MGate 5101 also supports login via a web browser.Default IP address: 192.168.127.254Default account: adminDefault password: moxaPin Assignments PROFIBUS Serial Port (Female DB9)PINSignal Name 1– 2– 3PROFIBUS D+ 4RTS 5Signal common 65V 7– 8PROFIBUS D- 9 –Power Input and Relay Output PinoutsV2+ V2-V1+ V1- Shielded Ground DC Power Input 2 DC Power Input 2 N.O. Common N.C. DC Power Input 1 DC Power Input 1SpecificationsPower Input12 to 48 VDC Power Consumption(Input Rating)12 to 48 VDC, 360 mA (max.) Operating Temperature Standard Models: 0 to 60°C (32 to 140°F) Wide Temp. Models: -40 to 75°C (-40 to 167°F)Storage Temperature-40 to 85°C (-40 to 185°F) ATEX and IECEx Information1. ATE X Certificate number: DEMKO 14 ATEX 12882. IECEx number: IECEx UL 14.0023X3. Certificate string: Ex nA IIC T4 GcAmbient range: 0°C ≤ Tamb ≤ 60°C (for suffix without –T)Ambient range: -40°C ≤ Tamb ≤ 75°C (for suffix without –T)4. Standards covered:EN 60079-0: 2012+A11:2013/IEC 60079-0: Ed 6.0EN 60079-15:2010/IEC 60079-15: Ed 4.05. Field-wiring connection:The device uses a terminal block, solder on the power distribution board, suitable for 12-24 AWG wire size, torque value 4.5 lb-in (0.51 N-m).6. Battery information: Battery is not user replaceable.7. Installation instructions:• A 4 mm 2 conductor must be used when the connection to theexternal grounding screw is utilized.• Conductors suitable for use at an ambient temperature of 84°Cmust be used for the power supply terminal.8. Special conditions for safe use:• The device is to be installed in an IECEx/ATEX Certified IP54enclosure and accessible only through the use of a tool.• The device is for use in an area of not more than pollution degree2 in accordance with IEC 60664-1.NOTE The equipment must be suitable for use in Class 1, Division 2, Groups A, B, C, D, or nonhazardous locations only.Moxa Inc.Fl. 4, No. 135, Lane 235, Baoqiao Rd.Xindian Dist., New Taipei City, 23145, Taiwan, R.O.C.。

NSC 633U数字式厂用变压器保护装置技术说明书V2.00南京南自四创电气有限公司2012年06月* 本公司保留对此说明书修改的权利，请注意最新版本资料目录1 装置简介 (1)2 技术参数 (2)2.1额定参数 (2)2.2主要技术性能 (2)2.3绝缘性能 (2)2.4抗电磁干扰性能 (3)2.5机械性能 (3)2.6环境条件 (3)3 装置硬件 (4)3.1机箱结构 (4)3.2交流插件 (4)3.3CPU插件 (4)3.4电源插件 (5)3.5人机对话（MMI）插件 (5)4 保护原理 (7)4.1过电流元件 (7)4.2过负荷元件 (7)4.3电流加速元件 (7)4.4零序过电流元件 (7)4.5低压元件 (7)4.6开关位置不对应启动 (7)4.7非电量保护 (8)4.8TV断线检测 (8)4.9数据记录 (8)5 定值及整定说明 (9)5.1NSC633U数字式厂用变保护装置定值清单及说明 (9)5.2NSC633U数字式厂用变保护装置软压板清单及说明 (9)6 附图...................................................................错误！未定义书签。

1 装置简介NSC 633U数字式厂用变压器保护装置是以电流电压及非电量保护为基本配置的成套所用变压器保护装置，适用于66kV及以下电压等级的变电站或发电厂用变压器。

本保护装置每个电气保护单元的基本配置为两个CPU插件，其一为由32位微处理器构成的保护功能单元，该单元配置了大容量的RAM和Flash Memory，具有极强的数据处理、逻辑运算和信息存储能力；另一CPU由总线不出芯片的单片机构成通用的人机接口单元。

两个CPU插件之间相互独立，无依存关系。

各种保护功能及自动化功能均由软件实现。

1）装置特点●全中文汉化液晶显示，人机界面友善，操作方面。

●专用测量模块，包括电度计量在内的各种测量及计量精度可达0.5级●提供累计脉冲电度的接入端●配置了充足的开关量输入端，方便外部遥信量的接入●设置了高精度的时钟芯片，并配置有GPS硬件对时回路，便于全系统时钟同步●配备高速以太网络通信接口，并集成了IEC 60870-5-103标准通信规约●完善的故障录波功能2）完备的保护功能配置表1 NSC 633U 型装置功能配置表3)监控功能●遥测：Ia，Ib，Ic，Ua，Ub，Uc，P，Q 等模拟量的遥测●遥控：正常断路器的遥控分合●遥信：11路遥信开入量的采集、装置遥信变位、事件遥信等●遥脉：2路电度脉冲输入●开出：装置具有8路开出，其中5路由于驱动出口跳闸继电器，3路用于预告警信号驱动。

General DescriptionThe MAX6369–MAX6374 are pin-selectable watchdog timers that supervise microprocessor (µP) activity and signal when a system is operating improperly. During normal operation, the microprocessor should repeated-ly toggle the watchdog input (WDI) before the selected watchdog timeout period elapses to demonstrate that the system is processing code properly. If the µP does not provide a valid watchdog input transition before the timeout period expires, the supervisor asserts a watch-dog (WDO ) output to signal that the system is not exe-cuting the desired instructions within the expected time frame. The watchdog output pulse can be used to reset the µP or interrupt the system to warn of processing errors.The MAX6369–MAX6374 are flexible watchdog timer supervisors that can increase system reliability through notification of code execution errors. The family offers several pin-selectable watchdog timing options to match a wide range of system timing applications:•Watchdog startup delay: provides an initial delay before the watchdog timer is started.•Watchdog timeout period: normal operating watch-dog timeout period after the initial startup delay.•Watchdog output/timing options: open drain (100ms)or push-pull (1ms).The MAX6369–MAX6374 operate over a +2.5V to +5.5V supply range and are available in miniature 8-pin SOT23 packages.________________________ApplicationsEmbedded Control Systems Industrial ControllersCritical µP and Microcontroller (µC) Monitoring AutomotiveTelecommunications NetworkingFeatureso Precision Watchdog Timer for Critical µP Applications o Pin-Selectable Watchdog Timeout Periods o Pin-Selectable Watchdog Startup Delay Periods o Ability to Change Watchdog Timing Characteristics Without Power Cycling o Open-Drain or Push-Pull Pulsed Active-Low Watchdog Output o Watchdog Timer Disable Feature o +2.5V to +5.5V Operating Voltage o 8µA Low Supply Currento No External Components Required o Miniature 8-Pin SOT23 PackageMAX6369–MAX6374Pin-Selectable Watchdog Timers19-1676; Rev 2; 2/03Ordering InformationPin Configuration appears at end of data sheet.Note:All devices are available in tape-and-reel only. Required order increment is 2,500 pieces.Selector GuideFor pricing, delivery, and ordering information,please contact Maxim/Dallas Direct!at1-888-629-4642, or visit Maxim’s website at .M A X 6369–M A X 6374Pin-Selectable Watchdog Timers 2_______________________________________________________________________________________ABSOLUTE MAXIMUM RATINGSELECTRICAL CHARACTERISTICS(V= +2.5V to +5.5V, SET_ = V or GND, T = -40°C to +85°C, unless otherwise noted. Typical values are at T = +25°C and Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.Terminal Voltage (with respect to GND)V CC .....................................................................-0.3V to +6V WDI.....................................................................-0.3V to +6V WDO (Open Drain: MAX6369/71/73).................-0.3V to +6V WDO (Push-Pull: MAX6370/72/74 .......-0.3V to (V CC + 0.3V)SET0, SET1, SET2................................-0.3V to (V CC + 0.3V)Maximum Current, Any Pin (input/output)...........................20mAContinuous Power Dissipation (T A = +70°C)SOT23-8 (derate 8.75mW/°C above +70°C)...............700mW Operating Temperature Range ...........................-40°C to +85°C Storage Temperature Range.............................-65°C to +150°C Junction Temperature......................................................+150°C Lead Temperature (soldering, 10s).................................+300°C V CC Rise or Fall Rate......................................................0.05V/µsMAX6369–MAX6374Pin-Selectable Watchdog Timers_______________________________________________________________________________________3ELECTRICAL CHARACTERISTICS (continued)M A X 6369–M A X 6374Pin-Selectable Watchdog Timers 4_______________________________________________________________________________________461081214-4010-15356085SUPPLY CURRENT vs. TEMPERATURETEMPERATURE (°C)S U P P L Y C U R R E N T (µA )Typical Operating Characteristics(Circuit of Figure 1, T A = +25°C, unless otherwise noted .)0.9970.9990.9981.0011.0001.0021.003-4010-15356085WATCHDOG TIMEOUT PERIODvs. TEMPERATUREM A X 6369/74-02TEMPERATURE (°C)N O R M A L I Z E D W A T C H D O G T I M E O U T P E R I O DELECTRICAL CHARACTERISTICS (continued)Note 2:Guaranteed by design.Note 3:In this setting the watchdog timer is inactive and startup delay ends when WDI sees its first level transition. See SelectingDevice Timing for more information.Note 4:After power-up, or a setting change, there is an internal setup time during which WDI is ignored.MAX6369–MAX6374Pin-Selectable Watchdog Timers_______________________________________________________________________________________5Pin DescriptionDetailed DescriptionThe MAX6369–MAX6374 are flexible watchdog circuits for monitoring µP activity. During normal operation, the internal timer is cleared each time the µP toggles the WDI with a valid logic transition (low to high or high to low) within the selected timeout period (t WD ). The WDO remains high as long as the input is strobed within the selected timeout period. If the input is not strobed before the timeout period expires, the watchdog output is asserted low for the watchdog output pulse width (t WDO ). The device type and the state of the three logic control pins (SET0, SET1, and SET2) determine watch-dog timing characteristics. The three basic timing varia-tions for the watchdog startup delay and the normalTable 1 for the timeout characteristics for all devices in the family):•Watchdog Startup Delay:Provides an initial delay before the watchdog timer is started.Allows time for the µP system to power up and initial-ize before assuming responsibility for normal watch-dog timer updates.Includes several fixed or pin-selectable startup delay options from 200µs to 60s, and an option to wait for the first watchdog input transition before starting the watchdog timer.M A X 6369–M A X 6374Pin-Selectable Watchdog Timers 6_______________________________________________________________________________________•Watchdog Timeout Period:Normal operating watchdog timeout period after the initial startup delay.A watchdog output pulse is asserted if a valid watch-dog input transition is not received before the timeout period elapses.Eight pin-selectable timeout period options for each device, from 30µs to 60s.Pin-selectable watchdog timer disable feature.•Watchdog Output/Timing Options:Open drain, active low with 100ms minimum watch-dog output pulse (MAX6369/MAX6371/MAX6373).Push-pull, active low with 1ms minimum watchdog output pulse (MAX6370/MAX6372/MAX6374).Each device has a watchdog startup delay that is initi-ated when the supervisor is first powered or after the user modifies any of the logic control set inputs. The watchdog timer does not begin to count down until theFigure 1. Functional Diagramcompletion of the startup delay period, and no watch-dog output pulses are asserted during the startup delay. When the startup delay expires, the watchdog begins counting its normal watchdog timeout period and waiting for WDI transitions. The startup delay allows time for the µP system to power up and fully ini-tialize before assuming responsibility for the normal watchdog timer updates. Startup delay periods vary between the different devices and may be altered by the logic control set pins. To ensure that the system generates no undesired watchdog outputs, the routine watchdog input transitions should begin before the selected minimum startup delay period has expired. The normal watchdog timeout period countdown is initi-ated when the startup delay is complete. If a valid logic transition is not recognized at WDI before the watchdog timeout period has expired, the supervisor asserts a watchdog output. Watchdog timeout periods vary between the different devices and may be altered by the logic control set pins. To ensure that the system generates no undesired watchdog outputs, the watch-dog input transitions should occur before the selected minimum watchdog timeout period has expired.The startup delay and the watchdog timeout period are determined by the states of the SET0, SET1, and SET2 pins, and by the particular device within the family. For the MAX6369 and MAX6370, the startup delay is equal to the watchdog timeout period. The startup and watchdog timeout periods are pin selectable from 1ms to 60s (minimum).For the MAX6371 and MAX6372, the startup delay is fixed at 60s and the watchdog timeout period is pin selectable from 1ms to 60s (minimum).The MAX6373/MAX6374 provide two timing variations for the startup delay and normal watchdog timeout. Five of the pin-selectable modes provide startup delays from 200µs to 60s minimum, and watchdog timeout delays from 3ms to 10s minimum. Two of the selectable modes do not initiate the watchdog timer until the device receives its first valid watchdog input transition (there is no fixed period by which the first input must be received). These two extended startup delay modesare useful for applications requiring more than 60s for system initialization.All the MAX6369–MAX6374 devices may be disabledwith the proper logic control pin setting (Table 1).Applications InformationInput Signal Considerations Watchdog timing is measured from the last WDI risingor falling edge associated with a pulse of at least 100nsin width. WDI transitions are ignored when WDO is asserted, and during the startup delay period (Figure2). Watchdog input transitions are also ignored for asetup period, t SETUP, of up to 300µs after power-up ora setting change (Figure 3).Selecting Device TimingSET2, SET1, and SET0 program the startup delay and watchdog timeout periods (Table 1). Timeout settingscan be hard wired, or they can be controlled with logicgates and modified during operation. To ensure smooth transitions, the system should strobe WDI immediately before the timing settings are changed. This minimizesthe risk of initializing a setting change too late in thetimer countdown period and generating undesired watchdog outputs. After changing the timing settings,two outcomes are possible based on WDO. If the change is made while WDO is asserted, the previous setting is allowed to finish, the characteristics of thenew setting are assumed, and the new startup phase is entered after a 300µs setup time (t SETUP) elapses. Ifthe change is made while WDO is not asserted, thenew setting is initiated immediately, and the new start-up phase is entered after the 300µs setup time elapses.MAX6369–MAX6374Pin-Selectable Watchdog Timers_______________________________________________________________________________________7 Figure 3. Setting Change TimingM A X 6369–M A X 6374Pin-Selectable Watchdog TimersSelecting 011 (SET2 = 0, SET1 = 1, SET0 = 1) disables the watchdog timer function on all devices in the family.Operation can be reenabled without powering down by changing the set inputs to the new desired setting. The device assumes the new selected timing characteris-tics and enter the startup phase after the 300µs setup time elapses (Figure 3).The MAX6373/MAX6374 offer a first-edge feature. In first-edge mode (settings 101 or 110, Table 1), the internal timer does not control the startup delay period.Instead, startup terminates when WDI sees a transition.If changing to first-edge mode while the device is oper-ating, disable mode must be entered first. It is then safe to select first-edge mode. Entering disable mode first ensures the output is unasserted when selecting first-edge mode and removes the danger of WDI being masked out.OutputThe MAX6369/MAX6371/MAX6373 have an active-low,open-drain output that provides a watchdog output pulse of 100ms. This output structure sinks current when WDO is asserted. Connect a pullup resistor from WDO to any supply voltage up to +5.5V.Select a resistor value large enough to register a logic low (see Electrical Characteristics ), and small enoughto register a logic high while supplying all input current and leakage paths connected to the WDO line. A 10k Ωpullup is sufficient in most applications. The MAX6370/MAX6372/MAX6374 have push-pull outputs that pro-vide an active-low watchdog output pulse of 1ms.When WDO deasserts, timing begins again at the beginning of the watchdog timeout period (Figure 2).Usage in Noisy EnvironmentsIf using the watchdog timer in an electrically noisy envi-ronment, a bypass capacitor of 0.1µF should be con-nected between V CC and GND as close to the device as possible, and no further away than 0.2 inches.________________Watchdog SoftwareConsiderationsTo help the watchdog timer monitor software execution more closely, set and reset the watchdog input at differ-ent points in the program, rather than pulsing the watch-dog input high-low-high or low-high-low. This technique avoids a stuck loop, in which the watchdog timer would continue to be reset inside the loop, keeping the watch-dog from timing out. Figure 4 shows an example of a flow diagram where the I/O driving the watchdog input is set high at the beginning of the program, set low at the end of every subroutine or loop, then set high again when the program returns to the beginning. If the pro-gram should hang in any subroutine, the problem would be quickly corrected, since the I/O is continually set low and the watchdog timer is allowed to time out, causing WDO to pulse.Figure 4. Watchdog Flow DiagramChip InformationTRANSISTOR COUNT: 1500PROCESS: BiCMOSPin ConfigurationMaxim cannot assume responsibility f or use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.8_____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600©2003 Maxim Integrated ProductsPrinted USAis a registered trademark of Maxim Integrated Products.。

DEVICE SPECIFICATIONSNI 6351X Series Data Acquisition: 1.25 MS/s, 16 AI, 24 DIO, 2 AOThe following specifications are typical at 25 °C, unless otherwise noted. For more information about the NI 6351, refer to the X Series User Manual available from / manuals.Analog InputNumber of channels8 differential or 16 single endedADC resolution16 bitsDNL No missing codes guaranteedINL Refer to the AI Absolute Accuracy section. Sample rateSingle channel maximum 1.25 MS/sMultichannel maximum (aggregate) 1.00 MS/sMinimum No minimumTiming resolution10 nsTiming accuracy50 ppm of sample rateInput coupling DCInput range±0.1 V, ±0.2 V, ±0.5 V, ±1 V, ±2 V, ±5 V,±10 V±11 V of AI GNDMaximum working voltage for analoginputs (signal + common mode)CMRR (DC to 60 Hz)100 dBInput impedanceDevice onAI+ to AI GND>10 GΩ in parallel with 100 pFAI- to AI GND>10 GΩ in parallel with 100 pFDevice offAI+ to AI GND820 ΩAI- to AI GND820 ΩInput bias current±100 pACrosstalk (at 100 kHz)Adjacent channels-75 dBNon-adjacent channels-95 dBSmall signal bandwidth (-3 dB) 1.7 MHzInput FIFO size2,047 samplesScan list memory4,095 entriesData transfersPCIe DMA (scatter-gather), programmed I/O USB USB Signal Stream, programmed I/O Overvoltage protection for all analog input and sense channelsDevice on±25 V for up to two AI pinsDevice off±15 V for up to two AI pinsInput current during overvoltage condition±20 mA max/AI pinSettling Time for Multichannel Measurements2| | NI 6351 SpecificationsTypical Performance GraphsFigure 1. Settling Error versus Time for Different Source Impedances10 KTime (µs)E r r o r (p p m o f S t e p S i z e )101001 KFigure 2. AI <0..15> Small Signal Bandwidth–8–7–6–5–4–3–2–1011 k10 k100 k 1000 k10000 kFrequency (Hz)N o r m a l i z e d S i g n a l A m p l i t u d e (d B )NI 6351 Specifications | © National Instruments | 3Figure 3. AI <0..15> CMRRFrequency (Hz)C M R R (d B )AI Absolute AccuracyTable 1. AI Absolute Accuracy4 | | NI 6351 SpecificationsFor more information about absolute accuracy at full scale, refer to the AI Absolute Accuracy Example section.Gain tempco13 ppm/°CReference tempco 1 ppm/°CINL error46 ppm of rangeNote Accuracies listed are valid for up to two years from the device externalcalibration.AI Absolute Accuracy EquationAbsoluteAccuracy = Reading · (GainError) + Range · (OffsetError) + NoiseUncertainity GainError = ResidualGainError + GainTempco · (TempChangeFromLastInternalCal) + ReferenceTempco · (TempChangeFromLastExternalCal)OffsetError = ResidualOffsetError + OffsetTempco · (TempChangeFromLastInternalCal) + INLErrorNoiseUncertainty10,000 points.AI Absolute Accuracy ExampleAbsolute accuracy at full scale on the analog input channels is determined using the following assumptions:•TempChangeFromLastExternalCal = 10 °C •TempChangeFromLastInternalCal = 1 °C•number_of_readings = 10,000•CoverageFactor = 3 σFor example, on the 10 V range, the absolute accuracy at full scale is as follows: GainError = 48 ppm + 13 ppm · 1 + 1 ppm · 10 = 71 ppmOffsetError = 13 ppm + 21 ppm · 1 + 46 ppm = 80 ppmAbsoluteAccuracy = 10 V · (GainError) + 10 V · (OffsetError) + NoiseUncertainty = 1,520 µVNI 6351 Specifications| © National Instruments| 5Analog T riggersNumber of triggers1Source AI <0..15>, APFI 0Functions Start Trigger, Reference Trigger, PauseTrigger, Sample Clock, Convert Clock, SampleClock TimebaseSource levelAI <0..15>±Full scaleAPFI 0±10 VResolution16 bitsModes Analog edge triggering, analog edge triggeringwith hysteresis, and analog window triggering Bandwidth (-3 db)AI <0..15> 3.4 MHzAPFI 0 3.9 MHzAccuracy±1% of rangeAPFI 0 characteristicsInput impedance10 kΩCoupling DCProtection, power on±30 VProtection, power off±15 VAnalog OutputNumber of channels2DAC resolution16 bitsDNL±1 LSBMonotonicity16 bit guaranteedAccuracy Refer to the AO Absolute Accuracy table. Maximum update rate1 channel 2.86 MS/s2 channels 2.00 MS/sTiming accuracy50 ppm of sample rateTiming resolution10 ns6| | NI 6351 SpecificationsOutput range±10 V, ±5 V, ±external reference on APFI 0 Output coupling DCOutput impedance0.2 ΩOutput current drive±5 mAOverdrive protection±25 VOverrdrive current26 mAPower-on state±5 mVPower on/off glitchPCIe 1.5 V peak for 200 msUSB 1.5 V for 1.2 s1Output FIFO size8,191 samples shared among channels used Data transfersPCIe DMA (scatter-gather), programmed I/OUSB USB Signal Stream, programmed I/OAO waveform modes Non-periodic waveform, periodic waveformregeneration mode from onboard FIFO,periodic waveform regeneration from hostbuffer including dynamic updateSettling time, full-scale step, 15 ppm2 μs(1 LSB)Slew rate20 V/μsGlitch energy at midscale transition,10 nV · s±10 V rangeExternal ReferenceAPFI 0 characteristicsInput impedance10 kΩCoupling DCProtection, device on±30 VProtection, device off±15 VRange±11 VSlew rate20 V/μs1Typical behavior. Time period may be longer due to host system USB performance. Time period will be longer during firmware updates.NI 6351 Specifications| © National Instruments| 7Figure 4. AO External Reference Bandwidth–90–80–70–60–50–40–30–20–10010Frequency (Hz)N o r m a l i z e d A O A m p l i t u d e A t t e n u a t i o n (d B )AO Absolute AccuracyAbsolute accuracy at full-scale numbers is valid immediately following self calibration and assumes the device is operating within 10 °C of the last external calibration.Note Accuracies listed are valid for up to two years from the device externalcalibration.AO Absolute Accuracy EquationAbsoluteAccuracy = OutputValue · (GainError) + Range · (OffsetError )GainError = ResidualGainError + GainTempco · (TempChangeFromLastInternalCal ) +ReferenceTempco · (TempChangeFromLastExternalCal )OffsetError = ResidualOffsetError + OffsetTempco · (TempChangeFromLastInternalCal)+ INLError8 | | NI 6351 SpecificationsDigital I/O/PFIStatic CharacteristicsNumber of channels24 total, 8 (P0.<0..7>),16 (PFI <0..7>/P1, PFI <8..15>/P2)Ground reference D GNDDirection control Each terminal individually programmable asinput or outputPull-down resistor50 kΩ typical, 20 kΩ minimumInput voltage protection±20 V on up to two pinsCaution Stresses beyond those listed under the Input voltage protectionspecification may cause permanent damage to the device.Waveform Characteristics (Port 0 Only)Terminals used Port 0 (P0.<0..7>)Port/sample size Up to 8 bitsWaveform generation (DO) FIFO2,047 samplesWaveform acquisition (DI) FIFO255 samplesDI Sample Clock frequencyPCIe0 to 10 MHz, system and bus activitydependentUSB0 to 1 MHz, system and bus activity dependent DO Sample Clock frequencyPCIeRegenerate from FIFO0 to 10 MHzStreaming from memory0 to 10 MHz, system and bus activitydependentUSBRegenerate from FIFO0 to 10 MHzStreaming from memory0 to 1 MHz, system and bus activity dependent Data transfersPCIe DMA (scatter-gather), programmed I/OUSB USB Signal Stream, programmed I/ODigital line filter settings160 ns, 10.24 μs, 5.12 ms, disableNI 6351 Specifications| © National Instruments| 9PFI/Port 1/Port 2 FunctionalityFunctionality Static digital input, static digital output, timinginput, timing outputTiming output sources Many AI, AO, counter, DI, DO timing signals Debounce filter settings90 ns, 5.12 μs, 2.56 ms, custom interval,disable; programmable high and lowtransitions; selectable per input Recommended Operating ConditionsInput high voltage (V IH)Minimum 2.2 VMaximum 5.25 VInput low voltage (V IL)Minimum0 VMaximum0.8 VOutput high current (I OH)P0.<0..7>-24 mA maximumPFI <0..15>/P1/P2-16 mA maximumOutput low current (I OL)P0.<0..7>24 mA maximumPFI <0..15>/P1/P216 mA maximumDigital I/O CharacteristicsPositive-going threshold (VT+) 2.2 V maximumNegative-going threshold (VT-)0.8 V minimumDelta VT hysteresis (VT+ - VT-)0.2 V minimumI IL input low current (V IN = 0 V)-10 μA maximumI IH input high current (V IN = 5 V)250 μA maximum10| | NI 6351 SpecificationsFigure 5. P0.<0..7>: I OH versus V OHI O H (m A )V OH (V)Figure 6. P0.<0..7>: I OL versus V OLI O L (m A )1535302520105V OL (V)400Figure 7. PFI <0..15>/P1/P2: I OH versus V OHI O H (m A )–30–5–10–15–20–25–35–40–45V OH (V)0–50Figure 8. PFI <0..15>/P1/P2: I OL versus V OLI O L (m A )5V OL (V)0General-Purpose CountersNumber of counter/timers 4Resolution32 bitsCounter measurements Edge counting, pulse, pulse width,semi-period, period, two-edge separation Position measurements X1, X2, X4 quadrature encoding withChannel Z reloading; two-pulse encoding Output applications Pulse, pulse train with dynamic updates,frequency division, equivalent time sampling Internal base clocks100 MHz, 20 MHz, 100 kHzExternal base clock frequency0 MHz to 25 MHzBase clock accuracy50 ppmInputs Gate, Source, HW_Arm, Aux, A, B, Z,Up_Down, Sample ClockRouting options for inputsPCIe Any PFI, RTSI, analog trigger, many internalsignalsUSB Any PFI, analog trigger, many internal signals FIFO127 samples per counterData transfersPCIe Dedicated scatter-gather DMA controller foreach counter/timer, programmed I/O USB USB Signal Stream, programmed I/OFrequency GeneratorNumber of channels1Base clocks20 MHz, 10 MHz, 100 kHzDivisors 1 to 16Base clock accuracy50 ppmOutput can be available on any PFI or RTSI terminal.Phase-Locked LoopNumber of PLLs1Table 3. Reference Clock Locking FrequenciesOutput of PLL100 MHz Timebase; other signals derived from100 MHz Timebase including 20 MHz and100 kHz TimebasesExternal Digital TriggersSourcePCIe Any PFI, RTSIUSB Any PFIPolarity Software-selectable for most signalsAnalog input function Start Trigger, Reference Trigger, PauseTrigger, Sample Clock, Convert Clock,Sample Clock TimebaseAnalog output function Start Trigger, Pause Trigger, Sample Clock,Sample Clock TimebaseCounter/timer functions Gate, Source, HW_Arm, Aux, A, B, Z,Up_Down, Sample ClockDigital waveform generation (DO) function Start Trigger, Pause Trigger, Sample Clock, Sample Clock TimebaseDigital waveform acquisition (DI) function Start Trigger, Reference Trigger, Pause Trigger, Sample Clock, Sample Clock TimebaseDevice-to-Device T rigger BusInput SourcePCIe RTSI <0..7>USB NoneOutput destinationPCIe RTSI <0..7>USB NoneOutput selections10 MHz Clock, frequency generator output,many internal signalsDebounce filter settings90 ns, 5.12 μs, 2.56 ms, custom interval,disable; programmable high and lowtransitions; selectable per inputBus InterfacePCIeForm factor x1 PCI Express, specification v1.1 compliant Slot compatibility x1, x4, x8, and x16 PCI Express slots 2DMA channels8, analog input, analog output, digital input,digital output, counter/timer 0, counter/timer 1,counter/timer 2, counter/timer 3USBUSB compatibility USB 2.0 Hi-Speed or full-speed3USB Signal Stream8, can be used for analog input, analog output,digital input, digital output, counter/timer 0,counter/timer 1, counter/timer 2,counter/timer 32Some motherboards reserve the x16 slot for graphics use. For PCI Express guidelines, refer to/pciexpress.3Operating on a full-speed bus results in lower performance, and you might not be able to achieve maximum sampling/update rates.Power RequirementsPCIeWithout disk drive power connector installed+3.3 V 4.6 W+12 V 5.4 WWith disk drive power connector installed+3.3 V 1.6 W+12 V 5.4 W+5.0 V15 WUSBPower supply requirements11 to 30 VDC, 30 W, 2 positions 3.5 mm pitchpluggable screw terminal with screw lockssimilar to Phoenix Contact MC 1,5/2-STF-3,5 BKPower input mating connector Phoenix Contact MC 1,5/2-GF-3,5 BK orequivalentCaution NI USB-6351 devices must be powered with an NI offered AC adapter ora National Electric Code (NEC) Class 2 DC source that meets the powerrequirements for the device and has appropriate safety certification marks forcountry of use.Current LimitsCaution Exceeding the current limits may cause unpredictable behavior by thedevice and/or PC.PCIeWithout disk drive power connector installedP0/PFI/P1/P2 and +5 V0.59 A maxterminals combinedWith disk drive power connector installed+5 V terminal (connector 0) 1 A max4+5 V terminal (connector 1) 1 A max4P0/PFI/P1/P2 combined 1 A max4Has a self-resetting fuse that opens when current exceeds this specification.USB+5 V terminal 1 A max42 A maxP0/PFI/P1/P2 and +5 V terminalscombinedPhysical CharacteristicsPrinted circuit board dimensionsPCIe9.9 × 16.8 cm (3.9 × 6.6 in.) (half-length) Enclosure dimensions (includes connectors)USB26.4 × 17.3 × 3.6 cm (10.4 × 6.8 × 1.4 in.) WeightPCIe161 g (5.6 oz)USB 1.42 kg (3 lb 2 oz)I/O connectorPCIe 1 68-pin VHDCIUSB64 screw terminalsPCIe disk drive power connector Standard ATX peripheral connector (not serialATA)USB screw terminal wiring16-24 AWGCalibrationRecommended warm-up time15 minutesCalibration interval 2 yearsMaximum Working VoltageMaximum working voltage refers to the signal voltage plus the common-mode voltage. Channel to earth11 V, Measurement Category ICaution Do not use for measurements within Categories II, III, or IV.EnvironmentalOperating temperaturePCIe0 to 50 °CUSB0 to 45 °CStorage temperature-40 to 70 ºCOperating humidity10 to 90% RH, noncondensingStorage humidity 5 to 95% RH, noncondensingPollution Degree2Maximum altitude2,000 mIndoor use only.SafetyThis product is designed to meet the requirements of the following electrical equipment safety standards for measurement, control, and laboratory use:•IEC 61010-1, EN 61010-1•UL 61010-1, CSA 61010-1Note For UL and other safety certifications, refer to the product label or the OnlineProduct Certification section.Electromagnetic CompatibilityThis product meets the requirements of the following EMC standards for electrical equipment for measurement, control, and laboratory use:•EN 61326-1 (IEC 61326-1): Class A emissions; Basic immunity•EN 55011 (CISPR 11): Group 1, Class A emissions•EN 55022 (CISPR 22): Class A emissions•EN 55024 (CISPR 24): Immunity•AS/NZS CISPR 11: Group 1, Class A emissions•AS/NZS CISPR 22: Class A emissions•FCC 47 CFR Part 15B: Class A emissions•ICES-001: Class A emissionsNote In the United States (per FCC 47 CFR), Class A equipment is intended foruse in commercial, light-industrial, and heavy-industrial locations. In Europe,Canada, Australia and New Zealand (per CISPR 11) Class A equipment is intendedfor use only in heavy-industrial locations.Note Group 1 equipment (per CISPR 11) is any industrial, scientific, or medicalequipment that does not intentionally generate radio frequency energy for thetreatment of material or inspection/analysis purposes.Note For EMC declarations and certifications, and additional information, refer tothe Online Product Certification section.CE ComplianceThis product meets the essential requirements of applicable European Directives, as follows:•2014/35/EU; Low-V oltage Directive (safety)•2014/30/EU; Electromagnetic Compatibility Directive (EMC)Online Product CertificationRefer to the product Declaration of Conformity (DoC) for additional regulatory compliance information. To obtain product certifications and the DoC for this product, visit / certification, search by model number or product line, and click the appropriate link in the Certification column.Environmental ManagementNI is committed to designing and manufacturing products in an environmentally responsible manner. NI recognizes that eliminating certain hazardous substances from our products is beneficial to the environment and to NI customers.For additional environmental information, refer to the Minimize Our Environmental Impact web page at /environment. This page contains the environmental regulations and directives with which NI complies, as well as other environmental information not included in this document.Waste Electrical and Electronic Equipment (WEEE) EU Customers At the end of the product life cycle, all NI products must bedisposed of according to local laws and regulations. For more information abouthow to recycle NI products in your region, visit /environment/weee.电子信息产品污染控制管理办法（中国RoHS）中国客户National Instruments符合中国电子信息产品中限制使用某些有害物质指令(RoHS)。

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本器具用于家用和类似用途,如：—— 商店、办公室或其他工作场合的厨房区域；—— 农场以及宾馆、 汽车旅店和居住型环境的顾客；—— 家庭旅馆型环境；—— 餐饮业和类似的非零售业应用；2安全注意事项 ....................................................................3安装步骤 ...........................................................................5首次使用步骤 ....................................................................7部件名称 ...........................................................................8BCD-633WDCSU1 / BCD-633WDCHU1/BCD-633WLCFDMFA5U1/BCD-633WLCFDMFVAU1功能介绍 ...........................................................................11可拆卸部件........................................................................19BCD-633WICTU1 / BCD-633WIGWU1功能介绍 ...........................................................................20可拆卸部件........................................................................35贮存建议 ...........................................................................36节能使用的注意事项 ...........................................................39冷藏室的使用 ....................................................................40冷冻室的使用 ....................................................................42制冰机的使用和清洁 .. (44)冰箱的清洁........................................................................49各部件的拆卸与清洁 ...........................................................50冰箱的搬运........................................................................53冰箱的停用........................................................................53疑问解答 ...........................................................................54保修说明 ...........................................................................57技术数据 ..........................................................................59装箱单 ..............................................................................61食品接触清单及环保清单 ....................................................62Wi-Fi 使用注意事项 . (63)安全警示使用说明保养维护服务指南3尊敬的卡萨帝用户：您好！感谢您使用卡萨帝产品，为了您能更好的阅读本说明书和使用本产品，防止人身伤害及物品损坏事故，请务必仔细阅读并遵守本说明书中有以下标志符号的内容。

功能监控器MAX705/706/813中文资料。

概述MAX705/706/813L是一组CMOS监控电路，能够监控电源电压、电池故障和微处理器(MPU或mP)或微控制器(MCU或mC)的工作状态。

将常用的多项功能集成到一片8脚封装的小芯片内，与采用分立元件或单一功能芯片组合的电路相比，大大减小了系统电路的复杂性和元器件的数量，显著提高了系统可靠性和精确度。

该系列产品采用3种不同的8脚封装形式：DIP、SO和mMAX。

主要应用于：微处理器和微控制器系统；嵌入式控制器系统；电池供电系统；智能仪器仪表；通信系统；寻呼机；蜂窝移动电话机；手持设备；个人数字助理(PDA)；电脑电话机和无绳电话机等等。

功能说明RESET/RESET操作复位信号用于启动或者重新启动MPU/MCU，令其进入或者返回到预知的循环程序并顺序执行。

一旦MPU/MCU处于未知状态，比如程序“跑飞”或进入死循环，就需要将系统复位。

对于MAX705和MAX706而言，在上电期间只要Vcc大于1.0V，就能保证输出电压不高于0.4V的低电平。

在Vcc上升期间RESET维持低电平直到电源电压升至复位门限(4.65V或4.40V)以上。

在超过此门限后，内部定时器大约再维持200ms后释放RESET，使其返回高电平。

无论何时只要电源电压降低到复位门限以下(即电源跌落)，RESET引脚就会变低。

如果在已经开始的复位脉冲期间出现电源跌落，复位脉冲至少再维持140ms。

在掉电期间，一旦电源电压Vcc降到复位门限以下，只要Vcc不比1.0V还低，就能使RESET维持电压不高于0.4V的低电平。

MAX705和MAX706提供的复位信号为低电平RESET，而MAX813L提供的复位信号为高电平RESET，三者其它功能完全相同。

有些单片机，如INTEL的80C51系列，需要高电平有效的复位信号。

看门狗定时器MAX705/706/813L片内看门狗定时器用于监控MPU/MCU的活动。