max680esa芯片参数资料(免费)

General DescriptionThe MAX6800/MAX6801/MAX6802 microprocessor (µP)supervisory circuits monitor the power supplies in 2.85V to 5.0V 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 preset timeout period after V CC has risen above the reset threshold. The only difference among the three devices is their output. The MAX6801 (push/pull) and MAX6802(open-drain) have an active-low RESET output, while the MAX6800 (push/pull) has an active-high RESET output.The MAX6800/MAX6801 are guaranteed to be in the cor-rect state for V CC down to 0.7V. The MAX6802 is guaran-teed 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 2.63V and 4.80V, in approximately 100mV increments. These devices are available with a 1ms (min), 20ms (min), or 100ms (min) reset pulse width. Ideal for space-critical applications, the MAX6800/MAX6801/MAX6802 come packaged in a 3-pin SOT23. For a lower threshold voltage version, see the MAX6332/MAX6333/MAX6334.ApplicationsComputers ControllersIntelligent InstrumentsCritical µP/µC Power Monitoring Portable/Battery-Powered Equipment AutomotiveFeatureso Ultra-Low 0.7V Operating Supply Voltageo Low 4.0µA Supply Currento Precision Monitoring of 2.85V to 5.0V Power-Supply Voltages o Reset Thresholds Available from 2.63V to 4.80V,in Approximately 100mV Increments o Fully Specified over Temperatureo Three Power-On Reset Timeout Periods Available (1ms min, 20ms min, 100ms min)o Low Costo Three Available Output Structures: Push/Pull RESET, Push/Pull RESET , Open-Drain RESET o Guaranteed RESET/RESET Valid to V CC = 0.7V (MAX6800/MAX6801)o Power-Supply Transient Immunity o No External Components Required o 3-Pin SOT23 Packageo Pin Compatible with MAX809/MAX810, MAX6326/MAX6327/MAX6328, and MAX6346/MAX6347/MAX6348MAX6800/MAX6801/MAX68023-Pin, Low-Power µP Reset Circuits________________________________________________________________Maxim Integrated Products 1Ordering Information*These devices are available in factory-set V CC reset thresh-olds from 2.63V to 4.80V, 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.S ample 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.Typical Operating Circuit and Pin Configuration appear at end of data sheet.Selector Guide appears at end of data sheet.19-1933 Rev 1; 2/01For pricing, delivery, and ordering information,please contact Maxim/Dallas Direct!at 1-888-629-4642, or visit Maxim’s website at .M A X 6800/M A X 6801/M A X 68023-Pin, 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 V CC = +5.0V and T A = +25°C, reset notStresses 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)3-Pin SOT23 (derate 4mW/°C above +70°C)..............320mW Operating Temperature Range .........................-40°C to +125°C Junction Temperature......................................................+150°C Storage Temperature Range.............................-65°C to +150°C Lead Temperature (soldering, 10s).................................+300°CNote 2:I SOURCE for the MAX6800 is I00nA. I SINK for the MAX6801 is 100nA. I SINK for the MAX6802 is 50µA.3-Pin, Low-Power µP Reset Circuits_______________________________________________________________________________________33.04.03.55.04.56.05.56.5-5025-255075100125SUPPLY CURRENT vs. TEMPERATURETEMPERATURE (°C)I C C (µA )0.9500.9800.9700.9601.0000.9901.0401.0301.0201.0101.050-50-25255075100125NORMALIZED RESET TIMEOUT PERIODvs. TEMPERATUREM A X 6800/01/02 t o c 02TEMPERATURE (°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 D 0302010504090807060100-50-25255075100125V CC FALLING 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 )10075502501.02.01.52.53.0RESET (V OH )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 )806040201.01.52.0 2.53.0RESET (V OL )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.)MAX6800/MAX6801/MAX6802Pin DescriptionM A X 6800/M A X 6801/M A X 68023-Pin, Low-Power µP Reset Circuits 4_______________________________________________________________________________________Applications InformationInterfacing to µPs with BidirectionalReset PinsSince the RESET output on the MAX6802 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 pullup 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 CCtransients (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.Figure 1. Interfacing to µPs with Bidirectional Reset PinsFigure 2. Ensuring Reset Valid Down to V CC = 0Typical Operating Circuit3-Pin, Low-Power µP Reset Circuits_______________________________________________________________________________________5Table 1. Factory-Trimmed Reset ThresholdsEnsuring 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 when V CC drops below 1V. For the MAX6801 application, where RESET must be valid down to 0, adding a pulldown resistor between RESET and GND removes stray leakage cur-rents, holding RESET low (Figure 2a). The pulldown resistor value is not critical; 100k Ωis large enough notto load RESET and small enough to pull it low. For the MAX6800 application, where RESET must be valid to V CC = 0, a 100k Ωpullup resistor between RESET and V CC will hold RESET high when V CC falls below 0.7V (Figure 2b).Since the MAX6802 has an open-drain, active-low out-put, it typically uses a pullup resistor. With this device,RESET will most likely not maintain an active condition,but will drift to a non-active level due to the pullup 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.TRANSISTOR COUNT:505PROCESS: BiCMOSChip InformationM A X 6800/M A X 6801/M A X 68023-Pin, Low-Power µP Reset Circuits 6_______________________________________________________________________________________Selector Guide (Standard Versions *)MAX6800/MAX6801/MAX6802Maxim 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.7_____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600©2001 Maxim Integrated ProductsPrinted USAis a registered trademark of Maxim Integrated Products.Package Information3-Pin, Low-Power µP Reset Circuits。

艾默生ES变频器参数表变频器参数表在设定下面参数前先将变频器0.00参数设定为1253后按下确定键。

再将0.48参数设定为SERVO.按下确定键，然后再输下面各参数。

设18号参数时先将18.48设为ON 参数含义范围默认值设定值单位0.03加速度0.0-10.00.50.5M\S0.04减速度0.0-10.00.80.6M\S1.06最高速度值300096RPM3.05零速阀值51RPM3.08超速限值0183RPM3.25编码器相角0整定值3.34编码器线数409620483.35编码器单圈精度0133.36编码器电压5V5V3.38编码器类型Ab.Servo SC.ENDAT3.4编码器故障等级113.41编码器自适应OFF ON4.07双向电流限175200％4.12电流环滤波10.0-0.802MS4.13电流环比例增益150整定值4.14电流环积分增益2000整定值4.15电机热时间常数20894.23电流环虑波20.0-25.0010MS5.07马达额定电流0A5.08马达额定转速3000RPM5.09马达额定电压400380V5.11马达极数6Pope205.17马达额定电阻0整定值5.18载波频率3--16612KHZ5.24瞬抗0整定值7.1T5\6模拟量输入1目的参数 1.3607.14T7模拟量输入2目的参数 1.3708.21端子24的输出源地址18.3210.028.22端子25的输出源地址18.3118.388.23端子26的输出源地址18.3718.378.24端子27的输出源地址18.3819.448.25端子28的输出源地址18.4418.448.26端子29的输出源地址18.3618.368.31端子24的输出选择NO ON8.32端子24的输出选择NO OFF18.11多端速V1500MM\S18.12多端速V2（检修速度）10-1000400200MM\S 18.13多端速V3(中速)100-10000800900MM\S 18.14多端速V4100-100001000MM\S 18.15多端速V510000MM\S 18.16多端速V6(爬行速度)10050MM\S 18.17多端速V7（额定速度）1001000MM\S 18.18启动优化速度0－1001010MM\S 18.23电机磁场建立阀值200－990500500% 18.24制动器闭合延时200-1000010001000MS 18.25速度环运行比例增益100-32767100450018.26速度环运行积分增益100-32767100350018.27速度环启动比例增益200-327672001000018.28速度环启动积分增益200-32767200800018.29电梯曳引机额定转速100096RPM 18.3电梯额定梯速8001000MM\S18.48启动速度环增益切环使能OFF NO19.11启动速度环增益切环时间100-10000500500MS 19.12启动锁定微分增益0019.13停车减速度10-20001000600MM\SS 19.14启动加加速10-10000500300MM\SS 19.15运行加加速100-100001000500MM\SS 19.16停车加加速10-10000800650MM\SS 19.17启动优化加加速0-10102MM\S 19.18设定最大距离误差值2000MM 19.25速度曲线给定延时200-100001000300MS 19.26双运行方向信号选择0119.27减速比分母1119.28启动优化时间10-10000300300MS 19.29曳引轮直径480100MM19.3加速比分子31120.01软件版本 1.0720.02软件运行标志1061420.1钢丝绳绕绳比122=2:1 20.12爬行速度参数选择18.1616.17编码器故障检测等级1016.24编码器分频输出源0 3.2916.25编码器分频输出分子0.250.204816.26编码器分频输出分母1 1.638416.28编码器分频输出方式AB(0)AB.L(4)。

esam芯片
芯片是一种电子元件，是电子设备的核心部件之一。

它是由不同材料制成，通过相互连接和控制传递电信号，实现对电流、电压和功率的控制和处理。

芯片的尺寸通常很小，但功能强大，可以实现复杂的计算和数据处理功能。

ESAM芯片是一种特殊类型的芯片，它是一款嵌入式安全模块芯片。

ESAM芯片通常内置了硬件加密和安全算法，能够提供安全的身份验证、加密和解密功能。

它还可以存储数字证书和密钥，并提供对这些机密信息的保护。

ESAM芯片的应用领域非常广泛。

它可以用于智能卡、智能电表、智能锁、智能家居安全系统等各种物联网设备中。

通过使用ESAM芯片，这些设备可以实现数据的加密传输和安全验证，保护用户的隐私和信息安全。

ESAM芯片还可以用于金融领域，提供安全的支付解决方案。

例如，在银行卡中嵌入ESAM芯片，可以实现用户身份验证
和交易数据的加密传输，有效防止金融欺诈行为的发生。

此外，ESAM芯片还可以用于电力系统的安全保护。

通过在电力设备中嵌入ESAM芯片，可以实现对设备的远程监控和控制，提高电力系统的安全性和可靠性。

ESAM芯片还能够实现电力设备的安全隔离，防止电力设备被非法篡改或恶意攻击。

总之，ESAM芯片是一款功能强大且应用广泛的芯片。

它能够提供安全的身份验证、加密和解密功能，保护用户的隐私和信
息安全。

它在物联网、金融和电力等领域有着广泛的应用前景。

随着科技的不断进步，ESAM芯片的功能和性能也将不断提升，为各个行业带来更多的便利和安全保障。

市电ＬＥＤ驱动ＩＣＭＡＸｌ６８０１工作原理及其应用作者：李继方武莹王孝军来源：《现代电子技术》2008年第04期摘要：LED作为一种新型的光源，他所使用的材料不含重金属，与其他光源相比发光效率可以提高20％以上，节能效果非常名显。

针对LED光源MAXIM推出高效率LED驱动控制器MAXl6801，MAXl6801是高亮度(HB)LED驱动器控制IC，内部包含设计一个宽输入范围LED驱动器所需的全部电路，适合通用照明和显示应用。

主要介绍他的内部组成、各管脚功能定义、工作原理，并给出典型应用电路。

关键词：MAXl6801lLED驱动；新型光源；典型应用电路中图分类号：TN710文献标识码：B文章编号：1004—373X(2008)04—172—021 引言目前，节能环保的绿色产品已经成为各个行业的主流方向，光源也不例外。

LED作为一种新型的光源，他所使用的材料不含重金属，与其他光源相比发光效率可以提高20％以上，节能效果非常明显。

LED的寿命也很长，平均无故障工作时间为10万小时，大大超过白炽灯寿命3 000小时的规定。

LED属于实心封装的固体光源，其抗振动性也是其他光源无法比拟的。

因此LED光源具很广泛的应用前景和实用价值，市电高亮LED驱动器的设计对LED光源大范围应用与推广必将产生重要意义。

针对LED光源MAXIM推出了高效率LED驱动控制器MAXl6801，该驱动器具有262 kHz固定开关频率，采用电流模式控制方案。

配合使用外部MOSFET，可提供大功率输出(超过50 w)，并实现了较高的效率(超过85％)。

可驱动几路串联的HB LED，通过PWM或线性亮度调节可实现宽调节范围(0～100％)。

该IC具有45μA启动电流，允许使用大阻值启动电阻和小容量启动电容，启动迅速、功耗降低。

允许通过外部电阻分压器设置输入启动电压，实现输入电压欠压锁定(UVLO)功能；拉低UVLO引脚将关断器件；并且具有数字软启动，可在启动过程中较好地控制输出电流的上升。

MAX660 CMOS Monolithic Voltage ConverterM A X 660CMOS Monolithic Voltage Converter ______________Detailed DescriptionThe MAX660 capacitive charge-pump circuit eitherinverts or doubles the input voltage (see TypicalOperating Circuits ). For highest performance, loweffective series resistance (ESR) capacitors should beused. See Capacitor Selection section for more details.When using the inverting mode with a supply voltageless than 3V, LV must be connected to G ND. Thisbypasses the internal regulator circuitry and providesbest performance in low-voltage applications. Whenusing the inverter mode with a supply voltage above3V, LV may be connected to GND or left open. The partis typically operated with LV grounded, but since LVmay be left open, the substitution of the MAX660 for theICL7660 is simplified. LV must be grounded when over-driving OSC (see Changing Oscillator Frequency sec-tion). Connect LV to OUT (for any supply voltage) whenusing the doubling mode.__________Applications InformationNegative Voltage ConverterThe most common application of the MAX660 is as acharge-pump voltage inverter. The operating circuituses only two external capacitors, C1 and C2 (seeTypical Operating Circuits ).Even though its output is not actively regulated, theMAX660 is very insensitive to load current changes. Atypical output source resistance of 6.5Ωmeans thatwith an input of +5V the output voltage is -5V underlight load, and decreases only to -4.35V with a load of100mA. Output source resistance vs. temperature andsupply voltage are shown in the T ypical OperatingCharacteristics graphs.Output ripple voltage is calculated by noting the outputcurrent supplied is solely from capacitor C2 during one-half of the charge-pump cycle. This introduces a peak-to-peak ripple of:V RIPPLE = I OUT +I OUT (ESR C2)2(f PUMP ) (C2)For a nominal f PUMP of 5kHz (one-half the nominal 10kHz oscillator frequency) and C2 = 150µF with an ESR of 0.2Ω, ripple is approximately 90mV with a 100mA load current. If C2 is raised to 390µF, the ripple drops to 45mV.Positive Voltage Doubler The MAX660 operates in the voltage-doubling mode as shown in the T ypical Operating Circuit.The no-load output is 2 x V IN .Other Switched-Capacitor Converters Please refer to Table 1, which shows Maxim’s charge-pump offerings.Changing Oscillator Frequency Four modes control the MAX660’s clock frequency, as listed below:FC OSC Oscillator Frequency Open Open 10kHz FC = V+Open 80kHz Open or External See Typical Operating FC = V+Capacitor Characteristics Open External External Clock Frequency Clock When FC and OSC are unconnected (open), the oscil-lator runs at 10kHz typically. When FC is connected to V+, the charge and discharge current at OSC changes from 1.0µA to 8.0µA, thus increasing the oscillatorTable 1. Single-Output Charge Pumps。

喷码机操作及维修手册目录⏹技术参数 (5)✧电气规格 (5)✧重量 (5)✧尺寸 (5)✧环境规格 (6)✧墨水的用量 (6)✧喷码机耗材容量 (6)⏹喷码原理 (7)✧喷码机的应用特点 (7)✧喷印字符的形成 (7)✧工作原理简述 (8)喷墨打印原理 (8)墨路工作原理 (10)✧影响喷印质量及稳定性的因素 (11)✧主要组成部件及功能 (11)⏹喷码机描述 (12)✧外观及主要部件 (12)✧墨路系统组件 (13)✧喷头 (13)✧外部连接 (14)✧操作面板描述 (15)✧液晶屏 (16)⏹喷码机操作 (17)✧操作界面架构图 (18)✧新机器开机流程 (19)✧正常开机 (22)✧正常关机 (22)✧停机流程表 (23)✧快速关机 (25)✧整机清洗流程 (25)✧查看喷码机状态参数 (26)✧编辑信息 (27)清除屏幕 (27)选择字体 (27)字符间距 (28)字符方向 (28)字符加粗 (28)插入项目 (28)●插入时钟 (29)●插入序列号 (30)●插入班次： (31)●插入信息： (32)●插入二维码： (33)●插入条形码： (35)●插入串口随机号 (36)●插入磁盘字符串 (38)打印信息 (40)保存信息 (40)另存信息 (40)显示模式 (40)✧选择信息 (41)✧喷印设置 (42)喷印延时 (42)喷印速度 (42)喷印高度 (43)信息方向 (43)粗体喷印 (45)电眼控制 (45)●有效状态 (45)●滤波间隔 (45)●响应方式 (46)速度模式 (46)●内同步 (46)●外同步 (47)重复喷印 (48)充电算法 (49)计米喷印 (49)✧序列号 (50)✧功能限制 (51)✧系统设置 (52)时钟设置 (53)密码设置 (54)计数器 (55)外部接口 (56)事件记录 (56)系统恢复 (56)软件升级 (56)配置信息 (57)通讯设置 (57)特殊设置 (58)✧墨路维护 (59)喷头维护 (59)喷头结构图 (60)黏度标定 (61)手动控制 (61)墨路系统原理图 (63)墨路引灌 (64)墨路排空 (64)飞行时间校准 (64)自动清洗 (64)帮助 (64)✧系统维护 (65)墨线开关 (65)高压开关 (65)喷印测试 (66)喷嘴调制 (67)相位测试 (67)高压监测 (68)黏度监测 (68)压力设置 (68)转速设置 (68)运行时间 (68)✧更多功能 (69)⏹技术参数✧电气规格✧重量喷码机净重量为30Kg。

附录A：智能卡及ESAM安全模块基础知识北京握奇智能科技有限公司2003年5月欢迎惠顾及垂询：北京握奇智能科技有限公司北京市（100013）朝阳区东土城路8号林达大厦A座9层Tel**************************Fax*************http:// Email:************************************附录A：智能卡及ESAM安全模块基础知识A.1 智能卡和ESAM安全模块介绍A.1.1 智能卡简介智能卡一般特指具有微处理器（CPU）和操作系统（COS）的IC卡，也称CPU卡。

所谓IC卡又称集成电路卡（Integrated Circuit Card），从信号传输接口方式来分，有接触式IC卡、非接触式IC卡、两种接口方式合一的双界面IC卡。

接触式IC卡主要遵循的国际标准为ISO7816系列，非接触卡主要遵循的国际标准为ISO14443系列。

智能卡因为具有智能分析、计算、判断和学习等功能所以才称之为智能卡。

握奇公司智能卡的文件管理、安全属性、读写操作、密钥管理是通过卡内芯片操作系统COS（Chip Operating System）监控、管理和执行，并受到发卡方对卡片个人化时在卡内预先设定的密钥系统及安全认证机制的控制。

握奇公司TimeCOS智能卡和通用智能卡的操作系统TimeCOS可应用在金融、安全控制、税务等多个领域，具有用户空间大，读写速度快，有良好防火墙保护功能支持的一卡多用的特点。

支持标准的DES算法或Triple-DES算法，符合中国人民银行金融卡应用规范（PBOC规范），并且也完全符合ISO7816国际标准。

根据应用领域的不同要求，握奇公司TimeCOS智能卡有TimeCOS/PBOC（接触式符合银行卡规范）、TimeCOS/PK（接触式支持PKI公钥算法）和TimeCOS/DI（接触/非接触式双界面卡）等多种系列。

A.1.2 ESAM安全模块简介ESAM（Embedded Secure Access Module）嵌入式安全控制模块系列产品，是北京握奇智能科技有限公司研制出的具有普遍应用价值的嵌入式数据安全产品。

DCRS-6800E系列多业务万兆路由交换机DCRS-6808E DCRS-6804EDCRS-6800E系列是神州数码网络以业务智能化为核心理念的多业务万兆路由交换机。

该产品具备成熟的IPv6特性、线速MPLS L2/L3 VPN功能、多平面分离的高可靠性设计、高性能的L2/L3交换、丰富精细的QoS策略、强大的融合业务支持、整合安全特性。

它能够帮助用户切实提升商务效率和业务竞争力。

DCRS-6800E系列可作为园区网、城域网的关键设备之一，它不仅能够降低用户构建下一代网络的复杂性，而且提供了很好的投资保护。

DCRS-6800E系列路由交换机提供4槽和10槽两款产品，提供多业务增强处理模块，DCRS-6800E 系列所有产品的业务模块均可以通用，有效保护了客户投资。

所有模块均采用同样版本的系统软件，平台统一，升级方便，大大降低客户的总体成本。

DCRS-6800E系列交换机的管理模块、电源模块支持热插拔、冗余备份和负载均衡，板卡、电源、风扇均支持热插拔，为DCRS-6800E系列提供了电信运营商级的可靠性。

产品特色丰富的产品功能特性●强大的IPv6商用实现DCRS-6800E系列路由交换机在IPv6方面处于领先地位，在IPv6的先进性、稳定性、兼容性、丰富性方面，令您无后顾之忧。

DCRS-6800E系列完全基于ASIC的分布式全线速硬件方式进行IPv6转发，能够满足高性能的IPv6应用。

分布式硬件IPv6转发方式，可以在本地实现IPv6报文的处理，并可在接口模块内部及模块与背板间实现IPv6报文的线速转发，避免了集中式转发、NP转发等模式存在的瓶颈和时延问题，同时新增加了更安全的邻居发现（ND）信息、认证封装安全负载、避免了受到路由头RH0攻击的影响、避免了使用IPv6任播地址的限制、完善了无状态地址分配的协议交互过程，为IPv6能真正在大规模商用环境中应用提供了安全方面的保障。

●运营商级以太网ReadyDCRS-6800E系列在运营商级以太网方面具备出色的性能，MRPP多层环网保护技术实现了环网条件下的毫秒级链路故障恢复，收敛时间可以达到50ms以内；作为MRPP的有效补充，EMVTE技术提供了非环网条件下的毫秒级链路故障恢复能力，实现运营商级可靠性。