Cryptotanshinone_35825-57-1_DataSheet_MedChemExpress

第一部分化学品及企业标识化学品中文名：2-乙酰基-5-氰基噻吩化学品英文名：5-Acetylthiophene-2-carbonitrileCAS No.：88653-55-8分子式：C7H5NOS产品推荐及限制用途：工业及科研用途。

第二部分危险性概述紧急情况概述吞咽会中毒。

GHS危险性类别无危害分类标签要素：象形图：警示词：危险危险性说明：H301 吞咽会中毒●预防措施：—— P264 作业后彻底清洗。

—— P270 使用本产品时不要进食、饮水或吸烟。

—— P280 戴防护手套/穿防护服/戴防护眼罩/戴防护面具。

—— P261 避免吸入粉尘/烟/气体/烟雾/蒸气/喷雾。

—— P271 只能在室外或通风良好处使用。

●事故响应：—— P301+P310 如误吞咽：立即呼叫解毒中心/医生—— P330 漱口。

—— P302+P352 如皮肤沾染：用水充分清洗。

—— P332+P313 如发生皮肤刺激：求医/就诊。

—— P362+P364 脱掉沾染的衣服，清洗后方可重新使用—— P305+P351+P338 如进入眼睛：用水小心冲洗几分钟。

如戴隐形眼镜并可方便地取出，取出隐形眼镜。

继续冲洗。

—— P337+P313 如仍觉眼刺激：求医/就诊。

—— P304+P340 如误吸入：将人转移到空气新鲜处，保持呼吸舒适体位。

—— P312 如感觉不适，呼叫解毒中心/医生●安全储存：—— P403+P235 存放在通风良好的地方。

保持低温。

—— P405 存放处须加锁。

●废弃处置：—— P501 按当地法规处置内装物/容器。

物理和化学危险：无资料。

健康危害：吞咽会中毒。

环境危害：无资料。

第三部分成分/组成信息√物质混合物第四部分急救措施急救：吸入：如果吸入，请将患者移到新鲜空气处。

皮肤接触：脱去污染的衣着，用肥皂水和清水彻底冲洗皮肤。

如有4不适感，就医。

眼晴接触：分开眼睑，用流动清水或生理盐水冲洗。

如有不适感，就医。

型号资料名称备注4N35/4N36/4N37 光电耦合器AD7520/AD7521/AD7530/AD7521 D/A转换器10-Bit,12-Bit,Multiplying AD7541 12位D/A转换器12-Bit,Multiplying D/A Con ADC0802/ADC0803/ADC0804 8位A/D转换器8-Bit,Microprocessor-patib ADC0808/ADC0809 8位A/D转换器8-Bit μP patibie A/D Conv ADC0831/ADC0832/ADC0834/ADC0838 8位A/D转换器8-Bit Serial I/O A/D Conve CA3080/CA3080A OTA跨导运算放大器CA3140/CA3140A BiMOS运算放大器DAC0830/DAC0832 8位D/A转换器8-Bit μP patibie,Double-BICL7106,ICL7107 3位半A/D转换器ICL7106,ICL7107,ICL7106S,I 1/2 Digit,LCD/LED Display,ICL7116,ICL7117 3位半A/D转换器ICL7116,ICL7117 3位半LCD/L Converter with Display HolICL7650 载波稳零运算放大器ICL7660/MAX1044 CMOS电源电压变换器ICL8038 单片函数发生器ICM7216 10MHz通用计数器ICM7216A/ICM7216B/ICM7216D 须少量的外围元件就能构成10ICM7226 带BCD输出10MHz通用计数器ICM7226A/ICM7226B 带BCD输只须少量的外围元件就能构成ICM7555/7555 CMOS单/双通用定时器ICM7555/ICM7555 CMOS Gener ISO2-CMOS MT8880C DTMF收发器ISO2-CMOS MT8880C Integrat LF351 JFET输入运算放大器LF353 JFET输入宽带高速双运算放大器LM117/LM317A/LM317 三端可调电源LM124/LM124/LM324 低功耗四运算放大器LM124/LM124/LM324/LM2902 低LM137/LM337 三端可调负电压调整器LM139/LM239/LM339 低功耗四电压比较器LM139/LM239/LM339/LM2901/L LM158/LM258/LM358 低功耗双运算放大器LM158/LM258/LM358/LM2904 低LM193/LM293/LM393 低功耗双电压比较器LM193/LM293/LM393/LM2903 低LM201/LM301 通用运算放大器LM231/LM331 精密电压—频率转换器LM231A/LM231/LM331A/LM331 LM285/LM385 微功耗基准电压二极管LM308A 精密运算放大器LM386 低压音频小功率放大器LM399 带温度稳定器精密电压基准电路LM199/LM299/LM399/LM3999 带LM431 可调电压基准电路LM567/LM567C 锁相环音频译码器LM741 运算放大器LM741A/LM741E/LM741/LM741C LM831 双低噪声音频功率放大器LM833 双低噪声音频放大器LM8365 双定时LED电子钟电路LM8365 双定时LED电子钟电路MAX038 0.1Hz-20MHz单片函数发生器MAX232 5V电源多通道RS232驱动器/接收器+5V-Powered,Multichannel RMC1403 2.5V精密电压基准电路MC1404 5.0v/6.25v/10v基准电压MC1413/MC1416 七路达林顿驱动器MC145026/MC145027/MC145028 编码器/译码器Encoder and Decoder Pairs MC145403-5/8 RS232驱动器/接收器MC145403/MC145404/MC145405 MC145406 RS232驱动器/接收器EIA-232/V.28 CMOS Driver/R MC145407 RS232驱动器/接收器EIA-232/V.28 CMOS Driver/R MC145583 RS232驱动器/接收器 3.3V - 5.0V EIA-232/V.28 CMC145740 DTMF接收器The MC145740 is a silicon g (DTMF) munications, and conMC1488 二输入与非四线路驱动器MC1488/SN55188/SN75188 Qua 符合EIA标准No.EIA- 232D规MC1489 四施密特可控线路驱动器MC1489/MC1489A/SN55189/SN5 MC2833 低功率调频发射系统Low Power FM Tranmistter S MC3362 低功率调频窄频带接收器Low Power Dual Conversion MC4558 双运算放大器MC7800系列 1.0A三端正电压稳压器MC7805（5.0V）、LM340-5（5 LM340-12（12V）、 MC7815（MC78L00系列0.1A三端正电压稳压器MC78L05（5.0V）、MC78L08（8 MC78L24（24V）MC78M00系列0.5A三端正电压稳压器MC78M05（5.0V）、MC78M06（6 MC78M18（18V）、 MC78M20（MC78T00系列 3.0A正电压稳压器MC78T05（5.0V）、MC78T08（MC7900系列 1.0A三端负电压稳压器MC7905（5.0V）、MC7905.2（MC7918（18V）、 MC7924（24MC79L00系列0.1A三端负电压稳压器MC79L05（5.0V）、MC79L12（MC79M00系列0.5A三端负电压稳压器MC79M05（5.0V）、MC79M08（Microchip PIC系列单片机RS232通讯应用Microchip PIC系列单片机与数机与RS232通讯方面的应用参MM5369 3.579545MHz-60Hz 17级分频振荡器常用于LM8361、LM8362、LM83MOC3009/MOC3012 双向可控硅输出光电耦合器250V OPTOCOUPLERS/OPTOISOL MOC3020/MOC3023 双向可控硅输出光电耦合器400V OPTOCOUPLERS/OPTOISOLMOC3081/MOC3082/MOC3083 过零双向可控硅输出光电耦合器800V 6-Pin DIP Zero-CrossMOC8050 无基极达林顿晶体管输出光电耦合器PHOTODARLINGTON OPTOCOUPLEMOC8111 无基极晶体管输出光电耦合器PHOTODARLINGTON OPTOCOUPLEMT8870 DTMF双音频接收器MT8870C/MT8870C-1 IntegratMT8888C DTMF 收发器Integrated DTMF Transceive NE5532/NE5532A 双低噪声运算放大器NE5534/SE5534 低噪声运算放大器NE5534/NE5534A/SE5534/SE55 NE555/SA555 单时基电路NE555/NE555Y/SA555/SE555 单NE556/SA556/SE556 双时基电路NE570/NE571/SA571 音频压缩扩展器NE570/NE571/SA571 音频压缩OP07 低电压飘移运算放大器OP27 低噪音精密运算放大器OP37 低噪音高速精密运算放大器OP77 低电压飘移运算放大器OP90 精密低电压微功耗运算放大器PC817/PC827/PC847 高效光电耦合器PC817/PC827/PC837/PC847 高PT2262 无线遥控发射编码器芯片Remote Control Encoder PT2 PT2272 无线遥控接收解码器芯片Remote Control Decoder PT2 SG2524/SG3524 脉宽调制PWMST7537 电力线调制解调器电路ST7537 电力线调制解调器电路TDA1521 2×12W Hi-Fi 音频功率放大器TDA1521/TDA1521Q 2×12W HiTDA2030 14W Hi-Fi 音频功率放大器 14W Hi-Fi AUDIO AMPLIFIERTDA2616 2×12W Hi-Fi 音频功率放大器TDA2616/TDA2616Q 2×12W HiTDA7000T FM 单片调频接收电路TDA7010T FM 单片调频接收电路TDA7021T FM MTS单片调频接收电路TDA7040T 低电压锁相环立体声解码器TDA7050 低电压单/双声道功率放大器TL062/TL064 低功耗JFET输入运算放大器TL071/TL072/TL074 低噪声JFET输入运算放大器TL082/TL084 JFET 宽带高速运算放大器TL081/TL082/TL084 JFET输入宽带高速TL494 脉宽调制PWMTL594 精密开关模式脉宽调制控制TLP521/1-4 光电耦合器TLP521-1/TLP521-2/TLP521-4 光电耦合TOP100-4 TOPSwitch 三端PWM开关电源电路TOP100/TOP101/TOP102/TOP103/TOP104TOP200-4 TOPSwitch 三端PWM开关电源电路TOP200/TOP201/TOP202/TOP203/TOP204TOP209/TOP210 TOPSwitch 三端PWM开关电源电路TOP209/TOP210 TOPSwitch Family ThrTOP221-7 TOPSwitch-Ⅱ 三端PWM开关电源电路TOP221/TOP222/TOP223/TOP224/TOP225TOP232-4 TOPSwitch-FX 五端柔韧设计开关电源电路TOP232/TOP233/TOP234 TOPSwitch-FXTOP412/TOP414 TOPSwitch 三端PWMDC-DC 开关电源TOP412/TOP414 TOPSwitch Family ThrULN2068 1.5A/50V 4路达林顿驱动电路ULN2068 1.5A/50V 4路达林顿驱动电路ULN2803 500mA/50V 8路达林顿驱动电路ULN2803 500mA/50V 8路达林顿驱动电路ULN2803/ULN2804 线性八外围驱动器阵列八路NPN达林顿连接晶体管阵系列特别计算机，工业用和消费类产品中的灯、继的设计与标准TTL系列兼容，而ULN280VFC32 电压—频率/频率—电压转换器LM211 高灵活性电压比较器LM239 四单抑制器比较器LM2901 低功耗低失调四电压比较器LM2903 NSC [DATA] 低功耗低失调双电压比较器LM211 高灵活性电压比较器LM239 四单抑制器比较器LM2901 低功耗低失调四电压比较器LM2903 NSC [DATA] 低功耗低失调双电压比较器LM293 NSC [DATA] 低偏置电压双比较器LM311 单电压比较器 LM311(TI) LM339 NSC [DATA] 四电压比较器HA17339/LM339(TI)LM393 NSC [DATA] 低功耗低失调双电压比较器 HA17393LM711 单电压比较器MC3302 四单电源比较器MC3405 双运算放大器和双比较器CD4574 四可编程电压比较器CD4575 双可编程运放/比较器产品名称型号规格性能说明LMLM24J 四运放(军用级)LM148J 通用四运放LM1875T 无线电控制/接收器LM224J 四运放(工业级)LM258N 分离式双电源双运放LM2901N 四电压比较器LM2904N 四运放LM301AN 通用运算放大器LM308N 单比较器LM311P 单比较器LM317L 可调三端稳压器/100mA LM317T 可调三端稳压器/1.5ALM317K 可调三端稳压器/3ALM318 高速宽带运放LM324K 通用四运放LM331N V-F/F-V转换器LM336-2.5V 基准电压电路LM336 5V 基准电压电路LM337T 基准电压电路1ALM338K 可调三端稳压器5ALM339N 四比较器LM348N 四741运放LM358N 低功耗双运放LM361N 高速差动比较器LM386N 声频功率放大器LM3914N 十段点线显示驱动LM393N 低功耗低失调双比较器LM399H 精密基准源(6.9)LM723 可调正式负稳压器LM733 视频放大器LM741J 单运放LM741 双运放NENE521 高速双差分比较器NE5532 双运放NE5534 双运放NE555N 单运放NE555J 时基电路军品极NE556 双级型双时基电路NE564 锁相环NE565 锁相环NE567 音调译码器NE592 视频放大器OPOP07 低噪声运放OP27 超低噪声精密运放OP37 超低噪声精密运放光电耦合4N25 晶体管输出4N25MC 晶体管输出4N26 晶体管输出4N27 晶体管输出4N28 晶体管输出4N29 达林顿输出4N30 达林顿输出4N31 达林顿输出4N32 达林顿输出4N33 达林顿输出4N33MC 达林顿输出4N35 达林顿输出4N36 晶体管输出4N37 晶体管输出4N38 晶体管输出4N39 可控硅输出6N135 高速光耦晶体管输出6N136 高速光耦晶体管输出6N137 高速光耦晶体管输出6N138 达林顿输出6N139 达林顿输出MOC3020 可控硅驱动输出MOC3021 可控硅驱动输出MOC3023 可控硅驱动输出MOC3030 可控硅驱动输出MOC3040 过零触发可控硅输出MOC3041 过零触发可控硅输出MOC3061 过零触发可控硅输出MOC3081 过零触发可控硅输出TLP521-1 单光耦TLP521-2 双光耦TLP521-4 四光耦TLP621 四光耦TIL113 达林顿输出TIL117 TLL逻辑输出PC814 单光耦PC817 单光耦H11A2 晶体管输出H11D1 高压晶体管输出H11G2 电阻达林顿输出LFLF347N 宽带JFET输入四运放LF351N 宽带JFET输入运放LF353N JFET输入宽带运放LF355N JFET输入运放LF357N JFET宽带非全裣运放LF398N 采样/保持电路LF412N 低偏差飘移输入运放MCMC1377 彩色电视编码器MC1403 精密电压基准源(2.5)MC1413 周边七段驱动阵列MC1416 周边七段驱动陈列MC14409 二进制脉冲拨号器MC14433 3位半A/D转换器MC14489 多字符LED显示驱动器MC145026 编码器VD5026 编码器MC145027 译码器VD5027 译码器MC145028 译码器MC145030 编码译码器MC145106 频率合成器MC145146 4位数据总线TLTL062 低功耗JEFT输入双运放TL072 低噪声JEFTTL082TL084TL431TL494ULNULN20XX 周边七段驱动陈列ULN20XX 周边七段驱动陈列ULN2803 周边八段驱动陈列ULN2804 周边八段驱动陈列ICLICL7106 3位ADC/驱动LCDICL7107 3位半ADC/驱动LEDICL7109 4位半ADC/驱动LEDICL7129 4位半ADC/LCD驱动ICL7135 ADC/LCD驱动BCD输出ICL7136 3位半CMOSADC/LCD驱动ICL7218 CMOS低功耗运算放大器ICL7650 整零运放斩波ICL7652 整零运放斩波ICL7660 CMOS直流-直流转换器ICL8038 函数信号发生器ICL8049 反对数放大器CACA3140 单BIMOS运行CA3240 单BIMOS运行UCUC3842 WM电流型控制器UC3845 PWM电流型控制器DSDS12887 非易失实时时钟芯片L3845 中继接口电路SGSG3524 PWM解调调制器SG3525 PWM解调调制器20XX6 前置放大器MTMT8814 8x12模拟交换矩阵MT8816 8x模拟交换矩阵MT8870 综合DTMF接收器MT8870 综合DTMF接收器MT8880 综合DTMF发生接收器MIC24LC01 128x8串行EEPROM24LC02 256x8串行EEPROM24LC04 512x8串行EEPROM24LC16 2Kx8串行EEPROM93LC46 64x16串行EEPROM93LC56 256x16串行EEPROM93LC66 512x8 256x16 EEPROMPIC16C52 384x12 单片机PIC16C54 512x12 单片机PCI16C56 512x12 单片机PIC16C57 2048x12 单片机ATAT24C01 128x8串行EEPROMAT24C02 256x8串行EEPROMAT24C04 512x8串行EEPROMAT24C16 2Kx8串行EEPROMAT93C46 64x16串行EEPROMAT93C56 256x16串行EEPROMATF16V8 FLASH200门ATF20V8 FLASH300门高速ATF22V10 FLASH500门高速低电流AT28C16 2Kx8CMOS并行EEPROMAT28C17 2Kx8CMOS并行EEPROMAT28C64 8Kx8并行EEPROMAT28C256 32Kx8并行EEPROMAT28F010 128Kx8并行EEPROMA29C040 512Kx8 FLASH EEPROMHM6116 2Kx8 CMOS 静态PAMHY6264 8Kx8 CMOS 静态RAMHM6264 8Kx8 CMOS 静态RAMIS62C64 8Kx8 高速CMOS 静态RAM HY62256 32Kx8 CMOS 静态RAMHM62256 32Kx8 CMOS 静态RAMHM628128 128Kx8 CMOS 静态RAMHM628256 256Kx8 CMOS 静态RAMHM628512 512Kx8 CMOS 静态RAM HM628512 512Kx8 CMOS 静态RAM TCMTCM5087 双音调发生器MM5832 实时钟电路TCTC14433 3位半A/D转换器TC232 并行/串行接口电路TC7106 3位半ADC/LCD驱动TC7107 3位半ADC/LED驱动TC7116 3位半ADC/LCD驱动带保TC7129 4位半ADC/LCDTC7135 4位半ADC/LCD，BCD输出TC7650 整零运放斩波7575107 四差分线驱动器75174 四差分线驱动器75175 三态四差分接收器75176 差分总线接收器75188 四线驱动器75189 四线驱动器75451 双外围驱动器75452 双外围驱动器门阵PAL16L8 FLASH200门PALCE16V8-25 FLASH200门PALCE16V8-25JC FLASH200门(贴片)ATF16V8-25PC FLASH200门GAL16V8-25LP FLASH200门GAL16V8-25LPI 工业级FLASH200门GALV8-20LD 军品级FLASH200门GAL16V8-15LP 军品级FLASH200门GAL16V8-15LPI 工业级FLASH200门PALCF20V8-25PC FLASH300门ATF20V8-25PC FLASH300门GAL20V8-25LP FLASH300门GAL20V8-25LPI 工业级FLASH门GAL20V8-20LD 军品级门GAL20V8-15LP 军品级门GAL20V8-15LPI 工业级FLASH门ATF22C10-25PC FLASH500门高速低电流ATF22C10-25PC FLASH500门高速低电流GAI22V10-25LP FLASH500门高速低电流PALCE22V10-15JC FLASH500门高速低电流8000Z80 CP CTC PIO S10LD8031AH 8位微处理器工业级8031 8位微处理器80C31 8位CMOST微处理器80C31NT 8位CMOST微处理器N80C31BH 8位CMOST微处理器贴片LD80C31BH 8位CMOST微处理器MD80C31BH 8位CMOST微处理器8032 8位微处理器LD8032AH 8位CMOST微处理器80C32 8位CMOS微控制器8039 8位微控制器80C39 8位微控制器8051 8位微控制器80C51 8位CMOS微控制器80C552 8位微控制器80C552新8位微控制器8080 8位微处理器8085 8位NMOS微处理器80C85 8位NMOS微处理器8086 16位NMOS微处理器80C86 CMOS 16位微处理器8087 数值协处理器8088 8位HMOS微处理器80C88 CMOS 8位HMOS微处理器8097 16位单片机8098 准16位微控制器8155 通用接口电路81C55 CMOS通用接口电路8212 时钟发生器和驱动器8228 系统控制和总线驱动器8237 DMA控制器82C37 CMOS DMA 控制器8243 扩展器82C43 CMOS I/O扩展器8250 异步通信接口电路82C50 CMOS 异步通信接口电路8251 串行通信接口电路MD8251A 异步通信接口电路82C51 CMOS 异步通信接口电路8253 可编程区间计数器82C53 CMOS 可编程区间计数器8254 可编程间隔定时器83C54 CMOS 可编程间隔定时器LP82C54 CMOS 可编程间隔定时器8255 可编程外围并行接口电路MD8255A 可编程外围并行接口电路82C55 CMOS 可编程外围并行接口8257 可编程DMA控制器8259 可编程中段控制器82C59 CMOS 可编程中段控制器8279 可编程键盘显示器接口电路82C79 CMOS 82798282 8位锁存器8283 8位锁存器8284 时钟发生器和驱动器8286 8位总线收发器8287 8位总线收发器8288 总线控制器82C88 CMOS 总线控制器87C196KB87C196KD8748 8位微控制器8749 8位微控制器8751 8位微控制器87C51 CMOS 8位控制器87C51FA CMOS 8位微控制器87C52 87C51加强型87C552 8位微控制器89C1051PC 1K8位FLASH单片机89C2051PC 2K8位FLASH单片机89C2051PI 2K8位FLASH单片机89C51PC 4K8位FLASH单片机89C51PI 4K8位FLASH单片机89C52PC 2K8位FLASH单片机89C52PI 2K8位FLASH单片机89C52JC 2K8位FLASH单片机89C55PC 20Kx8位存储器2716 8Kx8 NMOS EPROM27C16 2Kx8 NMOS EPROM2732 4Kx8 NMOS EPROM27C32 4Kx8 NMOS EPROM2764F 8Kx8 NMOS EPROM27C64F 8Kx8 NMOS EPROM2764ST 8Kx8 NMOS EPROM27C64ST 8Kx8 NMOS EPROM27C64NS 8Kx8 NMOS EPROM27128 16Kx8 NMOS EPROM27C128 16Kx8 NMOS EPROM27256 32Kx8 NMOS EPROM27C256 32Kx8 NMOS EPROMMD27C256 16Kx8 CMOS EPROM27HC256-45 16Kx8 高速CMOS EPROM 27512 64Kx8 NMOS EPROM27C512 64Kx8 NMOS EPROMMD27C512 64Kx8 NMOS EPROM27HC512-45 64Kx 高速CMOS EPROM 27C010 128Kx8 CMOS EPROM27HC010-30 128Kx8 CMOS EPROM27C020 256Kx8 CMOS EPROM27C040 512Kx8 CMOS EPROM27HC040-30 512Kx8 CMOS EPROM27C080 1024Kx8 CMOS EPROM2816 2Kx8 并行EEPROM28C16 2Kx8 CMOS 并行EEPROM 2817 2Kx8 并行EEPROM28C17 2Kx8 CMOS 并行EEPROM 2864 8Kx8 并行EEPROM28C64 8Kx8 CMOS 并行EEPROM28C64B15JC 8Kx8 CMOS 并行EEPROM 28C256 32Kx8 CMOS 并行EEPROM贴片28F004BCT28F010 128Kx 高速并行EEPROM贴片2810 128Kx 高速并行EEPROM贴片20F01628F020 256Kx 高速并行EEPROM贴片28F020-150 256Kx 高速并行EEPROM 贴片28F01AVP-1028F256 32Kx 高速并行EEPROM贴片28F256 32Kx 高速并行EEPROM贴片28F51-15029C010 128Kx8 FLASH EEPROM29EE01028LV010A-20JC贴片29F010-45JC29C040 512Kx8 FLASH EEPROM贴片29F040-90 512Kx8 FLASH EEPROM贴29C512-12JCAD AD1674KN 12位2KHZ带采保ADCAD202JY 小型2KHZ隔离放大器AD232JN 线路驱动接收器AD521JD 电阻设置精密仪放器AD574AJD 12位数模转换器AD590JH 宽温度范围传感器AD624AD 精密仪表放大器AD650JN 低线性误差压频转换器ADC0804 8位A/D转换器ADC0808 8位A/D转换器ADC0809 8位A/D转换器ADC0820 8位A/D转换器DAC0808 8位A/D转换器DAC0832 8位A/D转换器DAC1210 12位A/D转换器MAXMAX1487CPA ESD保护RS-485MAX1202CPE RS-232接口电路MAX232CPA RS-232接口电路MAX485CPA RS-485接口电路MAX488CPA RS-485接口电路MAX706CPA UP监控电路MAX7219A 8位显示驱动器MAX756CPA UP监控电路MAX483 UP监控电路MAX813TDATDA1521 低电平检测宽带放大器TDA20XXA 单功率放大器5-10WTDA2030A 单功率放大器>10WTDA2822 桑苗双功率放大器逻辑器件资料型号规格性能说明CD4000 3输入双或非门1反相器CD4001 四2输入或非门CD4002 双4输入或非门CD4006 18级静态移位寄存器CD4007 双互补对加反相器CD4008 4位二进制并行进位全加器CD4009 六缓冲器/转换器（反相）CD4010 六缓冲器/转换器（同相）CD40100 32位双向静态移位寄存器CD40101 9位奇偶发生器/校验器CD40102 8位BCD可预置同步减法计数器CD40103 8位二进制可预置同步减法计数器CD40104 4位三态输出双向通用移位寄存器CD40105 先进先出寄存器CD40106 六施密特触发器CD40107 2输入双与非缓冲/驱动器CD40108 4×4多端寄存CD40109 四三态输出低到高电平移位器CD4011 四2输入与非门CD40110 十进制加减计数/译码/锁存/驱动CD40117 10线—4线BCD优先编码器CD4012 双4输入与非门CD4013 带置位/复位的双D触发器CD4014 8级同步并入串入/串出移位寄存器CD40147 10线—4线BCD优先编码器CD4015 双4位串入/并出移位寄存器CD4016 四双向开关CD40160 非同步复位可预置BCD计数器CD40161 非同步复位可预置二进制计数器CD40162 同步复位可预置BCD计数器CD40163 同步复位可预置二进制计数器CD4017 十进制计数器/分频器CD40174 六D触发器CD40175 四D触发器CD4018 可预置1/N计数器CD40181 4位算术逻辑单元CD40182 超前进位发生器CD4019 四与或选译门CD40192 可预制四位BCD计数器CD40193 可预制四位二进制计数器CD40194 4位双向并行存取通用移位寄存器CD4020 14级二进制串行计数/分频器CD40208 4×4多端寄存器CD4021 异步8位并入同步串入/串出寄存器CD4022 八进制计数器/分频器CD4023 三3输入与非门CD4024 7级二进制计数器CD4025 三3输入或非门CD40257 四2线-1线数据选择器/多路传输CD4026 7段显示十进制计数/分频器CD4027 带置位复位双J-K主从触发器CD4028 BCD-十进制译码器CD4029 可预制加/减（十/二进制）计数器CD4030 四异或门CD4031 64级静态移位寄存器CD4032 3位正逻辑串行加法器CD4033 十进制计数器/消隐7段显示CD4034 8位双向并、串入/并出寄存器CD4035 4位并入/并出移位寄存器CD4038 3位串行负逻辑加法器CD40CD40 12级二进制计数/分频器CD4041 四原码/补码缓冲器CD4042 四时钟控制D锁存器CD4043 四三态或非R/S锁存器CD4044 四三态与非R/S锁存器CD4045 21位计数器CD4046 PLL锁相环电路CD4047 单稳态、无稳态多谐振荡器CD4048 8输入端多功能可扩展三态门CD4049 六反相缓冲器/转换器CD4050 六同相缓冲器/转换器CD4051 8选1双向模拟开关CD4052 双4选1双向模拟开关CD4053 三2选1双向模拟开关CD4054 四位液晶显示驱动器CD4055 BCD—7段译码/液晶显示驱动器CD4056 BCD—7段译码/驱动器CD4059 可编程1/N计数器CD4060 14级二进制计数/分频/振荡器CD4063 四位数字比较器CD4066 四双向模拟开关CD4067 单16通道模拟开关CD4068 8输入端与非门CD4069 六反相器CD4070 四异或门CD4071 四2输入端或门CD4072 4输入端双或门CD4073 3输入端三与门CD4075 3输入端三或门CD4076 4位三态输出D寄存器CD4077 四异或非门CD4078 8输入端或非门CD4081 四2输入端与门CD4082 4输入端双与门CD4085 双2×2与或非门CD4086 2输入端可扩展四与或非门CD4089 二进制系数乘法器CD4093 四2输入端施密特触发器CD4094 8级移位存储总线寄存器CD4095 选通J-K同相输入主从触发器CD4096 选通J-K反相输入主从触发器CD4097 双8通道模拟开关CD4098 双单稳态多谐振荡器CD4099 八位可寻址锁存器恒流二极管型号恒定电流(ma)起始电压Us(V)动态电阻(MΩ)耐压分档(UHV)2DH00 ≤0.05<0.5 ≥8A:≥20 2DH01 0.1±0.05<0.8 ≥82DH02 0.2±0.05<1.5 ≥52DH03 0.3±0.05<1.5 ≥5B:≥30 2DH04 0.4±0.05<2 ≥2.52DH05 0.5±0.05<2 ≥2.52DH06 0.6±0.05<2 ≥2.5 C:≥40 2DH07 0.7±0.05<2 ≥1.52DH08 0.8±0.05<3 ≥1.52DH09 0.9±0.05<3 ≥1D:≥50 2DH1 1±0.05<3 ≥12DH2 2±0.05<3 ≥0.52DH3 3±0.05<3.5 ≥0.42DH4 4±0.05<3.5 ≥0.32DH5 5±0.05<4.5 ≥0.25 2DH6 6±0.05<4.5 ≥0.15 2DH7 7±0.05<5 ≥0.15快恢复二极管国外型号Vr(V) If(A) Ifsm(A) VF(V)Trr(us)Ir(ua)适用机型ES1A 400 0.75 30 2.5 1.5 10 日立三洋EU1 400 0.35 15 2.5 0.4 10 东芝三洋EU01A 600 0.35 15 2.5 0.4 10 三洋EU2 400 1 15 1.4 0.3 10 三洋EU2Z 200 1 15 1.4 0.3 10 三洋EU3A 600 1.5 20 1.5 0.4 10 三洋RC2 600120 1.5 0.4 10 松下RU3 800 1.5 20 1.5 0.4 10 三菱S5295G 400 0.5 30 2 0.4 10 东芝S5295J 600 0.5 30 1.5 0.4 10 东芝RGP10 600 1301.3 0.4 10 胜利夏普RU2 600 1 20 1.5 0.4 10松下胜利NECSM1-02FRA 200 0.8 35 1 0.4 10 东芝TVR06 400 0.6 25 1.4 0.3 10 NECV09 400 0.8 35 1.6 0.4 10 日立胜利V09C 200 0.8 35 1.6 0.4 10 日立V11 日立IS2471 60 0.15 1 0.8 0.03 10 三菱IS1553 70 0.1 1 1.4 ---- 0.5 东芝IS1555 35 0.1 1 1.4 ---- 0.5 东芝3JH61 600 3 60 1.5 0.2 10 东芝变容二极管参数。

采样保持器各IC型号序号IC型号描述1ad1154Low Cost, 16-Bit Accurate Sample-and-Hold Amplifier 2ad1154ad$StartFalse3ad1154aw Sample/Track-and-Hold Amplifier4ad1154bd$StartFalse5ad1154bw Sample/Track-and-Hold Amplifier6ad386bd$StartFalse7ad386td Sample/Track-and-Hold Amplifier8ad386td/883b$StartFalse9ad582kd Sample/Track-and-Hold Amplifier10ad582kh$StartFalse11ad582sd Sample/Track-and-Hold Amplifier12ad582sd/883b$StartFalse13ad582sh Sample/Track-and-Hold Amplifier14ad582sh/883b$StartFalse15ad583kd Sample/Track-and-Hold Amplifier16ad585achips$StartFalse17ad585aq/+Sample/Track-and-Hold Amplifier18ad585schips$StartFalse19ad585se/883b Sample/Track-and-Hold Amplifier20ad585sq/883b$StartFalse21ad681aq Sample/Track-and-Hold Amplifier22ad681sq$StartFalse23ad682an Sample/Track-and-Hold Amplifier24ad682jn$StartFalse25ad682sq Sample/Track-and-Hold Amplifier26ad683aq$StartFalse27ad683sq Sample/Track-and-Hold Amplifier28ad684sq/883b$StartFalse29ad783an Sample/Track-and-Hold Amplifier30ad783jn$StartFalse31ad783sq Sample/Track-and-Hold Amplifier32ad783sq/883b$StartFalse33ad9100Ultrahigh Speed Monolithic Track-and-Hold 34ad9100*$StartFalse35ad9100ad Ultrahigh Speed Monolithic Track-and-Hold 36ad9100jd$StartFalse37ad9100sd Ultrahigh Speed Monolithic Track-and-Hold 38ad9100se/883b$StartFalse39ad9101125 MSPS Monolithic Sampling Amplifier40ad9101ae$StartFalse41ad9101ar125 MSPS Monolithic Sampling Amplifier 42ad9101se$StartFalse43adh-050Sample/Track-and-Hold Amplifier44adh-050-883b$StartFalse45adh-051Sample/Track-and-Hold Amplifier46adh-051-883b$StartFalse47ah20016Sample/Track-and-Hold Amplifier48ah201-1$StartFalse49ah201-2Sample/Track-and-Hold Amplifier50al1210ar$StartFalse51al1210-die Sample/Track-and-Hold Amplifier52al1210es$StartFalse53al1210jr Sample/Track-and-Hold Amplifier54al1210se$StartFalse55al1210sj Sample/Track-and-Hold Amplifier56cds-1401mc$StartFalse57cds-1401mm Sample/Track-and-Hold Amplifier59cs3101-kd Sample/Track-and-Hold Amplifier60cs3101-td$StartFalse61cs3112-bd1Sample/Track-and-Hold Amplifier62cs3112-kd1$StartFalse63cs3112-kd2Sample/Track-and-Hold Amplifier64cs3112-td1$StartFalse65cs31412-bc1Sample/Track-and-Hold Amplifier66cs31412-bd$StartFalse67cs31412-kc1Sample/Track-and-Hold Amplifier68cs31412-kc2$StartFalse69cs31412-kd Sample/Track-and-Hold Amplifier70cs31412-tc1$StartFalse71cs31412-td Sample/Track-and-Hold Amplifier72dgl-13-1$StartFalse73dgl-13-1-883b Sample/Track-and-Hold Amplifier74dgl-13-3$StartFalse75dgl-13-3-883b Sample/Track-and-Hold Amplifier76ha1-2420-2$StartFalse77ha1-2425-5 3.2レs Sample and Hold Amplifiers78ha1-5320-2$StartFalse79ha1-5320-5 1 Microsecond Precision Sample and Hold Amplifier 80ha1-5330-2$StartFalse81ha1-5330-5650ns Precision Sample and Hold Amplifier82ha-2420$StartFalse83ha-2425 3.2レs Sample and Hold Amplifiers84ha3-2425-5$StartFalse85ha3-5320-5 1 Microsecond Precision Sample and Hold Amplifier 86ha3-5330-5$StartFalse87ha4p2425-5 3.2レs Sample and Hold Amplifiers89ha-5330650ns Precision Sample and Hold Amplifier90ha9p2425-5$StartFalse91ha9p5320-5 1 Microsecond Precision Sample and Hold Amplifier 92ha9p5320-9$StartFalse93hs346b Sample/Track-and-Hold Amplifier94hs346c$StartFalse95hs9704b Sample/Track-and-Hold Amplifier96hs9704c$StartFalse97hs9705b Sample/Track-and-Hold Amplifier98hs9705c$StartFalse99hs9714k Sample/Track-and-Hold Amplifier100hs9714tb$StartFalse101hs9716k Sample/Track-and-Hold Amplifier102hs9716tb$StartFalse103hs9720k Sample/Track-and-Hold Amplifier104hs9720tb$StartFalse105htc-0300a Ultrahigh-Speed Hybrid Track-and-Hold Amplifiers106htc-0300am$StartFalse107htc-0300am/883b Ultrahigh-Speed Hybrid Track-and-Hold Amplifiers108htc-0300atd/883b$StartFalse109htc-0500am Sample/Track-and-Hold Amplifier110htc-0500sm$StartFalse111hts-0010Ultra High Speed Hybird Track-and Hold Amplifiers112hts-0010kd$StartFalse113hts-0010sd Ultra High Speed Hybird Track-and Hold Amplifiers115hts-0025m Ultra High Speed Hybird Track-and Hold Amplifiers116hv257$StartFalse117hv257fg32 CHANNEL HIGH VOLTAGE SAMPLE AND HOLD AMPLIFIER ARRAY 118hv257x$StartFalse119lf198MONOLITHIC SAMPLE AND HOLD CIRCUITS120lf198/bgc$StartFalse121lf198a Precision Sample and Hold Amplifier122lf198ah Monolithic Sample-and-Hold Circuits123lf198al Sample/Track-and-Hold Amplifier124lf198fe$StartFalse125lf198h Monolithic Sample-and-Hold Circuits126lf198h/883Monolithic Sample-and-Hold Circuits127lf198l$StartFalse128lf298MONOLITHIC SAMPLE AND HOLD CIRCUITS129lf298fe Sample-and-hold amplifiers130lf298h$StartFalse131lf298hb Sample/Track-and-Hold Amplifier132lf298m$StartFalse133lf298n Sample-and-hold amplifiers134lf398$StartFalse135lf398a$StartFalse136lf398ah$StartFalse137lf398ah/a+$StartFalse138lf398al Sample/Track-and-Hold Amplifier139lf398an$StartFalse140lf398an/a+Sample/Track-and-Hold Amplifier141lf398an/b+$StartFalse142lf398an8Precision Sample and Hold Amplifier143lf398d$StartFalse144lf398d-t Sample/Track-and-Hold Amplifier145lf398fe$StartFalse146lf398h Monolithic Sample-and-Hold Circuits 147lf398h/a+Sample/Track-and-Hold Amplifier148lf398hb$StartFalse149lf398jg Sample/Track-and-Hold Amplifier150lf398l$StartFalse151lf398m Monolithic Sample-and-Hold Circuits 152lf398mx$StartFalse153lf398n MONOLITHIC SAMPLE AND HOLD CIRCUITS 154lf398n/a+Sample/Track-and-Hold Amplifier155lf398n/b+$StartFalse156lf398n8Precision Sample and Hold Amplifier 157lf398nb$StartFalse158lf398p Sample/Track-and-Hold Amplifier159lf398s8$StartFalse160lf39j8Precision Sample and Hold Amplifier 161lf6197$StartFalse162lf6197ccj$StartFalse163lf6197j$StartFalse164lh0053g-mil Sample/Track-and-Hold Amplifier165max5165$StartFalse166max5165lccm 32-Channel Sample/Hold Amplifier with a Single Multiplexed Input167max5165lecm$StartFalse168max5165mccm 32-Channel Sample/Hold Amplifier with a Single Multiplexed Input169max5165mecm$StartFalse170max5165nccm 32-Channel Sample/Hold Amplifier with aSingle Multiplexed Input171max5165necm$StartFalse172max516632-Channel Sample/Hold Amplifier with Four Multiplexed Inputs173max5166lccm$StartFalse174max5166lecm 32-Channel Sample/Hold Amplifier with Four Multiplexed Inputs175max5166mccm$StartFalse176max5166mecm 32-Channel Sample/Hold Amplifier with Four Multiplexed Inputs177max5166nccm$StartFalse178max5166necm 32-Channel Sample/Hold Amplifier with Four Multiplexed Inputs179max5167lccm$StartFalse180max5167lecm SAMPLE/TRACK-AND-HOLD AMPLIFIER|32-CHANNEL|BICMOS|QFP|48PIN|PLASTIC 181max5167mccm$StartFalse182max5167mecm SAMPLE/TRACK-AND-HOLD AMPLIFIER|32-CHANNEL|BICMOS|QFP|48PIN|PLASTIC 183max5167nccm$StartFalse184max5167necm SAMPLE/TRACK-AND-HOLD AMPLIFIER|32-CHANNEL|BICMOS|QFP|48PIN|PLASTIC 185max5168$StartFalse186max5168lccm SAMPLE/TRACK-AND-HOLD AMPLIFIER|32-CHANNEL|BICMOS|QFP|48PIN|PLASTIC 187max5168lecm$StartFalse188max5168mccm SAMPLE/TRACK-AND-HOLD AMPLIFIER|32-CHANNEL|BICMOS|QFP|48PIN|PLASTIC 189max5168mecm$StartFalse190max5168nccm SAMPLE/TRACK-AND-HOLDAMPLIFIER|32-CHANNEL|BICMOS|QFP|48PIN|PLASTIC 191max5168necm$StartFalse192ne5537Sample-and-hold amplifier193ne5537d$StartFalse194ne5537n Sample-and-hold amplifier195se5537$StartFalse196se5537fe Sample-and-hold amplifier197vn1025cc$StartFalse198vn1025ci Sample/Track-and-Hold Amplifier 199vn1025cm$StartFalse200vn1025dc Sample/Track-and-Hold Amplifier 201vn1025di$StartFalse202vn1025dm Sample/Track-and-Hold Amplifier 203vn1025mc$StartFalse204vn1025mi Sample/Track-and-Hold Amplifier 205vn1025mm$StartFalse206vn1025sc Sample/Track-and-Hold Amplifier 207vn1225cc$StartFalse208vn1225ci Sample/Track-and-Hold Amplifier 209vn1225cm$StartFalse210vn1225dc Sample/Track-and-Hold Amplifier 211vn1225di$StartFalse212vn1225dm Sample/Track-and-Hold Amplifier 213vn1225sc$StartFalse厂家Analog DevicesAnalog Devices Analog Devices Analog Devices Analog Devices Analog DevicesIntersil CorporationIntersil CorporationIntersil Corporation Intersil CorporationIntersil Corporation Intersil CorporationIntersil Corporation Intersil CorporationAnalog Devices Analog DevicesAnalog Devices Analog Devices Analog Devices Supertex, Inc ETCLinear Technology National Semiconductor National Semiconductor National SemiconductorETCPhilips Semiconductors Philips SemiconductorsLinear Technology National SemiconductorNational Semiconductor ETCLinear Technology Linear Technology Maxim IntegratedProductsMaxim Integrated ProductsMaxim Integrated ProductsMaxim Integrated ProductsMaxim Integrated ProductsMaxim Integrated ProductsMaxim Integrated ProductsMaxim Integrated ProductsMaxim Integrated ProductsMaxim Integrated ProductsMaxim Integrated ProductsMaxim Integrated ProductsMaxim Integrated ProductsPhilips SemiconductorsPhilips SemiconductorsPhilips Semiconductors。

Application Note Single-Wire and I2C Interfaces Seamless DebuggingUsing Saleae Logic AnalyzerATSHA204A, ATECC108A, and ATECC508A Prerequisites●Hardware PrerequisitesAtmel® AT88CK490 or AT88CK590 Demo-Evaluation Board orAtmel AT88CK101-() KitSaleae Logic Analyzer●Software PrerequisitesAtmel Crypto Evaluation Studio (ACES)IntroductionThe purpose of this document is to help the user gain a better understanding of how to use the Atmel CryptoAuthentication™ ATSHA204A, ATECC108A, and ATECC508A devices (crypto device) with the Saleae Logic Analyzer. The Saleae Logic Analyzer is a powerful tool to debug and evaluate the commands coming to and from these devices. The tool supports both the standard I2C and the Atmel Single-Wire Interface (SWI) protocols.The goal of this application note is to:●Understand the bus interfaces of the crypto device using the Saleae LogicAnalyzer.●Develop and debug with the crypto device using the Saleae Logic Analyzer. SummaryThe Saleae Logic Analyzer provides an in depth tool to quickly develop and debug integration of the crypto device into a customer’s system. The bus decoding allows for easy understanding of all bus traffic to the crypto device. By reducing the development time, the Saleae Logic Analyzer greatly reduces the cost of adding the crypto device.CryptoAuthentication for Single-Wire and I 2C Interfaces Seamless Debugging Using SaleaeLogic Analyzer [APPLICATION NOTE]Atmel-8847B-CryptoAuth-SWI-I2C-Seamless-Debugging-Saleae-Logic-Analyzer-ApplicationNote_08201521.Saleae Logic AnalyzerOn load of the analyzer, either 8 or 16 channels will display depending on the analyzer used. Protocol specific settings are located on the far right under the heading, Analyzers .Figure 1-1.Channels and Protocol SettingsThe crypto device supports either a Single-Wire Interface (SWI) or I 2C Interface depending on the P/N. ●SWI — Supported through the use of a DLL library. Use version 1.1.16 or greater. This version comes with support on Win, LNX, and IOS.●I 2C — Supported by the use of the built-in I 2C interface that is included in the Saleae download.3CryptoAuthentication for Single-Wire and I 2C Interfaces Seamless Debugging Using SaleaeLogic Analyzer [APPLICATION NOTE]Atmel-8847B-CryptoAuth-SWI-I2C-Seamless-Debugging-Saleae-Logic-Analyzer-ApplicationNote_0820152.Single-Wire Interface (SWI)Use the SWI DLL library version 1.1.16 or greater.1.Copy the DLL into the Saleae LLC\Analyzers directory on the user’s PC. Once the driver has been copied to the correct folder, the Atmel SWI option will appear and be listed in the Analyzer drop-down options. The SWI Analyzer has three display modes:Token Byte Packet (as described in the datasheet)Figure 2-1.Atmel SWI Option2.Select the Atmel SWI Analyzer from the list. 3.After selecting Atmel SWI Analyzer , rename the channel when prompted, 4.Select the Falling Edge Trigger option and start sampling. Using ACES, select a command and send it to the device. For an overview of the ACES tool, please see “Using ACES Application Note”. This will cause the bus to become active and the Analyzer will trigger on the first falling edge and data line.In the screen shot below, the Wake command has been captured followed by Wake Status Read. The Wake command is a special token designed to wake the device and reset the watchdog timer.Figure 2-2.Wake Command Followed by Wake Status ReadEnlargement ofthe Analyzerpull-down options.CryptoAuthentication for Single-Wire and I 2C Interfaces Seamless Debugging Using SaleaeLogic Analyzer [APPLICATION NOTE]Atmel-8847B-CryptoAuth-SWI-I2C-Seamless-Debugging-Saleae-Logic-Analyzer-ApplicationNote_0820154The token view displays each logic bit which is made up of seven bits on the wire. Each group of seven bits is encoded either as a Logic 1 or Logic 0 as follows:●A Logic 1 is one low bit followed by six high bits. ● A Logic 0 is one low bit followed by one high bit, then by one low bit, and then by four high bits.Figure 2-3.Token View Figure 2-4.Logic BitsThe byte view builds on the token view by combining eight tokens into a single byte. This view allows for easy matching of information on the data bus to the command set defined in the datasheet. The byte view istransmitted with the less significant bit first.Figure 2-5.BytesThe packet view further builds on the byte view by ordering the data into logic packets based on the datasheet definition. This allow for quick and easy review of the commands without the need to reference the datasheet.Figure 2-6.Packets0x880x045CryptoAuthentication for Single-Wire and I 2C Interfaces Seamless Debugging Using SaleaeLogic Analyzer [APPLICATION NOTE]Atmel-8847B-CryptoAuth-SWI-I2C-Seamless-Debugging-Saleae-Logic-Analyzer-ApplicationNote_0820153.I 2C InterfaceThe crypto device supports an I 2C interface that is directly supported by the Saleae tool.1.To configure the Analyzer for I 2C , select the I2C option from the Analyzer drop-down list and follow the configuration guide.Figure 3-1.I2C Analyzer Option 2.Select the clock and data channels that will be used for the I2C bus. Different encoding options can also be selected. The crypto device uses the default 8-bit encoding.Figure 3-2.Clock and Data Channels Enlargement ofthe Analyzerpull-down options.CryptoAuthentication for Single-Wire and I 2C Interfaces Seamless Debugging Using SaleaeLogic Analyzer [APPLICATION NOTE]Atmel-8847B-CryptoAuth-SWI-I2C-Seamless-Debugging-Saleae-Logic-Analyzer-ApplicationNote_0820156 3.Next, the Update Channel Names dialog box will be prompted to rename the channels to reflect SCL andSDA. This is an optional step, but helps when analyzing more then one bus at a time.Figure 3-3.Update Channel Names 4.Now that the analyzer is configured, set-up the trigger settings. The Saleae has a One Shot trigger thatcan be triggered on either the falling or rising edge of the SCL channel. The bus is normally held high;therefore, setting a falling edge trigger is recommended.Figure 3-4.Trigger Settings7CryptoAuthentication for Single-Wire and I 2C Interfaces Seamless Debugging Using SaleaeLogic Analyzer [APPLICATION NOTE]Atmel-8847B-CryptoAuth-SWI-I2C-Seamless-Debugging-Saleae-Logic-Analyzer-ApplicationNote_0820155.Once the analyzer has been started, execute a command in order to generate data on the bus.Figure 3-5.Execute a Command After the Analyzer has been triggered, it will collect the waveform information and display it in the viewer. The first token shown is the ATSHA204 Wake.Figure 3-6.First Token — ATSHA204 WakeThe Wake command is a special command that is required to wake-up the device. The command consists of a I 2C Start event followed by a long period of Logic 0 on the SDA line, then followed a Stop event.Figure 3-7.Wake CommandCryptoAuthentication for Single-Wire and I 2C Interfaces Seamless Debugging Using SaleaeLogic Analyzer [APPLICATION NOTE]Atmel-8847B-CryptoAuth-SWI-I2C-Seamless-Debugging-Saleae-Logic-Analyzer-ApplicationNote_0820158After a Wake command, an optional Read can be performed to read the status of the crypto device as shown in the waveform below. After the Read command is issued, the device will send four bytes of data (1-count, 1-data, and 2-CRC).Figure 3-8.Read WaveformThe Saleae tool supports a variety of display options for the I 2C interface including Binary, Hex, and ASCII to help quickly and easily evaluate the data. It can be selected by clicking the Configuration button next to the analyzer of interest on the right.Figure 3-9.Display Options4.Revision HistoryX X X X X XAtmel Corporation 1600 Technology Drive, San Jose, CA 95110 USA T: (+1)(408) 441.0311F: (+1)(408) 436.4200| © 2015 Atmel Corporation. / Rev.: Atmel-8847B-CryptoAuth-SWI-I2C-Seamless-Debugging-Saleae-Logic-Analyzer-ApplicationNote_082015.Atmel ®, Atmel logo and combinations thereof, Enabling Unlimited Possibilities ®, CryptoAuthentication ™, and others are registered trademarks or trademarks of Atmel Corporation in U.S. and other countries. Other terms and product names may be trademarks of others.DISCLAIMER: The information in this document is provided in connection with Atmel products. No license, express or implied, by estoppel or otherwise, to any intellectual property right is granted by this document or in connection with the sale of Atmel products. EXCEPT AS SET FORTH IN THE ATMEL TERMS AND CONDITIONS OF SALES LOCATED ON THE ATMEL WEBSITE, ATMEL ASSUMES NO LIABILITY WHATSOEVER AND DISCLAIMS ANY EXPRESS, IMPLIED OR STATUTORY WARRANTY RELATING TO ITS PRODUCTS INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTY OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, OR NON-INFRINGEMENT. IN NO EVENT SHALL ATMEL BE LIABLE FOR ANY DIRECT, INDIRECT, CONSEQUENTIAL, PUNITIVE, SPECIAL OR INCIDENTAL DAMAGES (INCLUDING, WITHOUT LIMITATION, DAMAGES FOR LOSS AND PROFITS, BUSINESS INTERRUPTION, OR LOSS OF INFORMATION) ARISING OUT OF THE USE OR INABILITY TO USE THIS DOCUMENT, EVEN IF ATMEL HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES. Atmel makes no representations or warranties with respect to the accuracy or completeness of the contents of this document and reserves the right to make changes to specifications and products descriptions at any time without notice. Atmel does not make any commitment to update the information contained herein. Unless specifically provided otherwise, Atmel products are not suitable for, and shall not be used in, automotive applications. Atmel products are not intended,authorized, or warranted for use as components in applications intended to support or sustain life.SAFETY-CRITICAL, MILITARY, AND AUTOMOTIVE APPLICATIONS DISCLAIMER: Atmel products are not designed for and will not be used in connection with any applications where the failure of such products would reasonably be expected to result in significant personal injury or death (“Safety-Critical Applications”) without an Atmel officer's specific written consent. Safety-Critical Applications include, without limitation, life support devices and systems, equipment or systems for the operation of nuclear facilities and weapons systems.Atmel products are not designed nor intended for use in military or aerospace applications or environments unless specifically designated by Atmel as military-grade. Atmel products are not designed nor intended for use in automotive applications unless specifically designated by Atmel as automotive-grade.。

-10 位 ADC（仅 C8051F380/1/2/3/C）•高达 500ksps•内建模拟多路复用器，单端和差分模式•VREF 来自外部引脚、内部参考或 V DD•内建温度传感器•外部转换启动输入选项-两个比较器-内部参考电压（仅 C8051F380/1/2/3/C）-掉电检测器和上电复位电路USB 功能控制器-符合 USB 规格 2.0-全速 (12Mbps) 或低速 (1.5Mbps) 运行-集成时钟恢复；全速或低速无需外部晶体-支持八个灵活的终端-1kB USB 缓冲存储器-集成收发器；无需外部电阻片上调试-片上调试电路提供全速、非侵入式的系统内调试（无需仿真器）-提供断点、单步执行、检查/修改内存和寄存器-比使用 ICE 芯片、目标仿真头和仿真插座的仿真系统有更优越的性能电源电压输入： 2.7 至 5.25V-使用片内稳压器时，支持的电压范围为 2.7~5.25V -流水线指令体系结构；70% 指令的执行时间为 1 个或2个系统时钟-高达 48 MIPS 的操作-扩展的中断处理程序内存-4352 或 2304字节 RAM-64、32 或 16kB 闪存；可在系统内编程的 512 字节扇区数字外围设备-40/25 个端口 I/O；全部能承受 5V 高灌电流-硬件增强型SPI™、两个 I2C/SMBus™ 和两个增强型UART 串口-六个通用 16 位计数器/定时器-16 位可编程计数器阵列 (PCA)，有五个采集/比较模块-外部存储器接口 (EMIF)时钟源-内部振荡器：启用时钟恢复时精度为 ±0.25%。

支持所有USB 和 UART 模式-外部振荡器：晶体、RC、C 或时钟（1 或 2 引脚模式）-低频 (80kHz) 内部振荡器-在运行中可切换时钟源封装-48 引脚 TQFP (C8051F380/2/4/6)-32 引脚 LQFP (C8051F381/3/5/7/C)-5x5mm 32 引脚 QFN (C8051F381/3/5/7/C)温度范围： –40 至 +85°CC8051F380/1/2/3/4/5/6/7/CC8051F380/1/2/3/4/5/6/7/CTable of Contents1. System Overview (16)2. C8051F34x Compatibility (20)2.1. Hardware Incompatibilities (21)3. Pinout and Package Definitions (22)4. Typical Connection Diagrams (34)4.1. Power (34)4.2. USB (36)4.3. Voltage Reference (VREF) (36)5. Electrical Characteristics (37)5.1. Absolute Maximum Specifications (37)5.2. Electrical Characteristics (38)6. 10-Bit ADC (ADC0, C8051F380/1/2/3/C only) (46)6.1. Output Code Formatting (47)6.3. Modes of Operation (50)6.3.1. Starting a Conversion (50)6.3.2. Tracking Modes (51)6.3.3. Settling Time Requirements (52)6.4. Programmable Window Detector (56)6.4.1. Window Detector Example (58)6.5. ADC0 Analog Multiplexer (C8051F380/1/2/3/C only) (59)7. Voltage Reference Options (62)8. Comparator0 and Comparator1 (64)8.1. Comparator Multiplexers (71)9. Voltage Regulators (REG0 and REG1) (74)9.1. Voltage Regulator (REG0) (74)9.1.1. Regulator Mode Selection (74)9.1.2. VBUS Detection (74)9.2. Voltage Regulator (REG1) (74)10. Power Management Modes (76)10.1. Idle Mode (76)10.2. Stop Mode (77)10.3. Suspend Mode (77)11. CIP-51 Microcontroller (79)11.1. Instruction Set (80)11.1.1. Instruction and CPU Timing (80)11.2. CIP-51 Register Descriptions (85)12. Prefetch Engine (88)13. Memory Organization (89)13.1. Program Memory (91)13.2. Data Memory (91)13.3. General Purpose Registers (92)13.4. Bit Addressable Locations (92)13.5. Stack (92)C8051F380/1/2/3/4/5/6/7/C14. External Data Memory Interface and On-Chip XRAM (93)14.1. Accessing XRAM (93)14.1.1. 16-Bit MOVX Example (93)14.1.2. 8-Bit MOVX Example (93)14.2. Accessing USB FIFO Space (94)14.3. Configuring the External Memory Interface (95)14.4. Port Configuration (95)14.5. Multiplexed and Non-multiplexed Selection (98)14.5.1. Multiplexed Configuration (98)14.5.2. Non-multiplexed Configuration (98)14.6. Memory Mode Selection (100)14.6.1. Internal XRAM Only (100)14.6.2. Split Mode without Bank Select (100)14.6.3. Split Mode with Bank Select (101)14.6.4. External Only (101)14.7. Timing (102)14.7.1. Non-multiplexed Mode (104)14.7.1.1. 16-bit MOVX: EMI0CF[4:2] = 101, 110, or 111 (104)14.7.1.2. 8-bit MOVX without Bank Select: EMI0CF[4:2] = 101 or 111 (105)14.7.1.3. 8-bit MOVX with Bank Select: EMI0CF[4:2] = 110 (106)14.7.2. Multiplexed Mode (107)14.7.2.1. 16-bit MOVX: EMI0CF[4:2] = 001, 010, or 011 (107)14.7.2.2. 8-bit MOVX without Bank Select: EMI0CF[4:2] = 001 or 011 (108)14.7.2.3. 8-bit MOVX with Bank Select: EMI0CF[4:2] = 010 (109)15. Special Function Registers (111)15.1. 13.1. SFR Paging (111)16. Interrupts (118)16.1. MCU Interrupt Sources and Vectors (119)16.1.1. Interrupt Priorities (119)16.1.2. Interrupt Latency (119)16.2. Interrupt Register Descriptions (119)16.3. INT0 and INT1 External Interrupt Sources (127)17. Reset Sources (129)17.1. Power-On Reset (130)17.2. Power-Fail Reset / VDD Monitor (131)17.3. External Reset (132)17.4. Missing Clock Detector Reset (132)17.5. Comparator0 Reset (132)17.6. PCA Watchdog Timer Reset (133)17.7. Flash Error Reset (133)17.8. Software Reset (133)17.9. USB Reset (133)18. Flash Memory (135)18.1. Programming The Flash Memory (135)18.1.1. Flash Lock and Key Functions (135)C8051F380/1/2/3/4/5/6/7/C18.1.2. Flash Erase Procedure (135)18.1.3. Flash Write Procedure (136)18.2. Non-Volatile Data Storage (137)18.3. Security Options (137)19. Oscillators and Clock Selection (142)19.1. System Clock Selection (143)19.2. USB Clock Selection (143)19.3. Programmable Internal High-Frequency (H-F) Oscillator (145)19.3.1. Internal Oscillator Suspend Mode (145)19.4. Clock Multiplier (147)19.5. Programmable Internal Low-Frequency (L-F) Oscillator (148)19.5.1. Calibrating the Internal L-F Oscillator (148)19.6. External Oscillator Drive Circuit (149)19.6.1. External Crystal Mode (149)19.6.2. External RC Example (151)19.6.3. External Capacitor Example (151)20. Port Input/Output (153)20.1. Priority Crossbar Decoder (154)20.2. Port I/O Initialization (158)20.3. General Purpose Port I/O (161)21. Universal Serial Bus Controller (USB0) (172)21.1. Endpoint Addressing (172)21.2. USB Transceiver (173)21.3. USB Register Access (175)21.4. USB Clock Configuration (179)21.5. FIFO Management (181)21.5.1. FIFO Split Mode (181)21.5.2. FIFO Double Buffering (182)21.5.1. FIFO Access (182)21.6. Function Addressing (183)21.7. Function Configuration and Control (183)21.8. Interrupts (186)21.9. The Serial Interface Engine (193)21.10. Endpoint0 (193)21.10.1. Endpoint0 SETUP Transactions (193)21.10.2. Endpoint0 IN Transactions (193)21.10.3. Endpoint0 OUT Transactions (194)21.11. Configuring Endpoints1-3 (196)21.12. Controlling Endpoints1-3 IN (197)21.12.1. Endpoints1-3 IN Interrupt or Bulk Mode (197)21.12.2. Endpoints1-3 IN Isochronous Mode (198)21.13. Controlling Endpoints1-3 OUT (201)21.13.1. Endpoints1-3 OUT Interrupt or Bulk Mode (201)21.13.2. Endpoints1-3 OUT Isochronous Mode (201)22. SMBus0 and SMBus1 (I2C Compatible) (205)C8051F380/1/2/3/4/5/6/7/C22.1. Supporting Documents (206)22.2. SMBus Configuration (206)22.3. SMBus Operation (206)22.3.1. Transmitter Vs. Receiver (207)22.3.2. Arbitration (207)22.3.3. Clock Low Extension (207)22.3.4. SCL Low Timeout (207)22.3.5. SCL High (SMBus Free) Timeout (208)22.4. Using the SMBus (208)22.4.1. SMBus Configuration Register (208)22.4.2. SMBus Timing Control Register (210)22.4.3. SMBnCN Control Register (214)22.4.3.1. Software ACK Generation (214)22.4.3.2. Hardware ACK Generation (214)22.4.4. Hardware Slave Address Recognition (217)22.4.5. Data Register (221)22.5. SMBus Transfer Modes (223)22.5.1. Write Sequence (Master) (223)22.5.2. Read Sequence (Master) (224)22.5.3. Write Sequence (Slave) (225)22.5.4. Read Sequence (Slave) (226)22.6. SMBus Status Decoding (226)23. UART0 (232)23.1. Enhanced Baud Rate Generation (233)23.2. Operational Modes (234)23.2.1. 8-Bit UART (234)23.2.2. 9-Bit UART (235)23.3. Multiprocessor Communications (236)24. UART1 (240)24.1. Baud Rate Generator (241)24.2. Data Format (242)24.3. Configuration and Operation (243)24.3.1. Data Transmission (243)24.3.2. Data Reception (243)24.3.3. Multiprocessor Communications (244)25. Enhanced Serial Peripheral Interface (SPI0) (250)25.1. Signal Descriptions (251)25.1.1. Master Out, Slave In (MOSI) (251)25.1.2. Master In, Slave Out (MISO) (251)25.1.3. Serial Clock (SCK) (251)25.1.4. Slave Select (NSS) (251)25.2. SPI0 Master Mode Operation (251)25.3. SPI0 Slave Mode Operation (253)25.4. SPI0 Interrupt Sources (254)25.5. Serial Clock Phase and Polarity (254)25.6. SPI Special Function Registers (256)26. Timers (263)26.1. Timer 0 and Timer 1 (266)26.1.1. Mode 0: 13-bit Counter/Timer (266)26.1.2. Mode 1: 16-bit Counter/Timer (267)26.1.3. Mode 2: 8-bit Counter/Timer with Auto-Reload (267)26.1.4. Mode 3: Two 8-bit Counter/Timers (Timer 0 Only) (268)26.2. Timer 2 (274)26.2.1. 16-bit Timer with Auto-Reload (274)26.2.2. 8-bit Timers with Auto-Reload (275)26.2.3. Timer 2 Capture Modes: USB Start-of-Frame or LFO Falling Edge (275)26.3. Timer 3 (281)26.3.1. 16-bit Timer with Auto-Reload (281)26.3.2. 8-bit Timers with Auto-Reload (282)26.3.3. Timer 3 Capture Modes: USB Start-of-Frame or LFO Falling Edge (282)26.4. Timer 4 (288)26.4.1. 16-bit Timer with Auto-Reload (288)26.4.2. 8-bit Timers with Auto-Reload (289)26.5. Timer 5 (293)26.5.1. 16-bit Timer with Auto-Reload (293)26.5.2. 8-bit Timers with Auto-Reload (294)27. Programmable Counter Array (298)27.1. PCA Counter/Timer (299)27.2. PCA0 Interrupt Sources (300)27.3. Capture/Compare Modules (301)27.3.1. Edge-triggered Capture Mode (302)27.3.2. Software Timer (Compare) Mode (303)27.3.3. High-Speed Output Mode (304)27.3.4. Frequency Output Mode (305)27.3.5. 8-bit Pulse Width Modulator Mode (306)27.3.6. 16-Bit Pulse Width Modulator Mode (307)27.4. Watchdog Timer Mode (308)27.4.1. Watchdog Timer Operation (308)27.4.2. Watchdog Timer Usage (309)27.5. Register Descriptions for PCA0 (311)28. C2 Interface (316)28.1. C2 Interface Registers (316)28.2. C2 Pin Sharing (319)Document Change List (320)Contact Information (321)List of FiguresFigure1.1. C8051F380/2/4/6 Block Diagram (18)Figure1.2. C8051F381/3/5/7/C Block Diagram (19)Figure3.1. TQFP-48 Pinout Diagram (Top View) (25)Figure3.2. TQFP-48 Package Diagram (26)Figure3.3. TQFP-48 Recommended PCB Land Pattern (27)Figure3.4. LQFP-32 Pinout Diagram (Top View) (28)Figure3.5. LQFP-32 Package Diagram (29)Figure3.6. LQFP-32 Recommended PCB Land Pattern (30)Figure3.7. QFN-32 Pinout Diagram (Top View) (31)Figure3.8. QFN-32 Package Drawing (32)Figure3.9. QFN-32 Recommended PCB Land Pattern (33)Figure4.1. Connection Diagram with Voltage Regulator Used and No USB (34)Figure4.2. Connection Diagram with Voltage Regulator Not Used and No USB (34)Figure4.3. Connection Diagram with Voltage Regulator Used and USB Connected (Bus-Powered) (35)Figure4.4. Connection Diagram with Voltage Regulator Used and USB Connected (Self-Powered) (35)Figure4.5. Connection Diagram for USB Pins (36)Figure4.6. Connection Diagram for Internal Voltage Reference (36)Figure6.1. ADC0 Functional Block Diagram (46)Figure6.2. Typical Temperature Sensor Transfer Function (48)Figure6.3. Temperature Sensor Error with 1-Point Calibration (49)Figure6.4. 10-Bit ADC Track and Conversion Example Timing (51)Figure6.5. ADC0 Equivalent Input Circuits (52)Figure6.6. ADC Window Compare Example: Right-Justified Data (58)Figure6.7. ADC Window Compare Example: Left-Justified Data (58)Figure7.1. Voltage Reference Functional Block Diagram (62)Figure8.1. Comparator0 Functional Block Diagram (64)Figure8.2. Comparator1 Functional Block Diagram (65)Figure8.3. Comparator Hysteresis Plot (66)Figure8.4. Comparator Input Multiplexer Block Diagram (71)Figure11.1. CIP-51 Block Diagram (79)Figure13.1. On-Chip Memory Map for 64kB Devices (C8051F380/1/4/5) (89)Figure13.2. On-Chip Memory Map for 32kB Devices (C8051F382/3/6/7) (90)Figure13.3. On-Chip Memory Map for 16kB Devices (C8051F38C) (91)Figure14.1. USB FIFO Space and XRAM Memory Map with USBFAE set to ‘1’ (94)Figure14.2. Multiplexed Configuration Example (98)Figure14.3. Non-multiplexed Configuration Example (99)Figure14.4. EMIF Operating Modes (100)Figure14.5. Non-Multiplexed 16-bit MOVX Timing (104)Figure14.6. Non-multiplexed 8-bit MOVX without Bank Select Timing (105)Figure14.7. Non-multiplexed 8-bit MOVX with Bank Select Timing (106)Figure14.8. Multiplexed 16-bit MOVX Timing (107)C8051F380/1/2/3/4/5/6/7/CFigure14.9. Multiplexed 8-bit MOVX without Bank Select Timing (108)Figure14.10. Multiplexed 8-bit MOVX with Bank Select Timing (109)Figure17.1. Reset Sources (129)Figure17.2. Power-On and VDD Monitor Reset Timing (130)Figure18.1. Flash Program Memory Map and Security Byte (137)Figure19.1. Oscillator Options (142)Figure19.2. External Crystal Example (150)Figure20.1. Port I/O Functional Block Diagram (Port 0 through Port 3) (153)Figure20.2. Port I/O Cell Block Diagram (154)Figure20.3. Peripheral Availability on Port I/O Pins (155)Figure20.4. Crossbar Priority Decoder in Example Configuration(No Pins Skipped) (156)Figure20.5. Crossbar Priority Decoder in Example Configuration (3 Pins Skipped) (157)Figure21.1. USB0 Block Diagram (172)Figure21.2. USB0 Register Access Scheme (175)Figure21.3. USB FIFO Allocation (181)Figure22.1. SMBus Block Diagram (205)Figure22.2. Typical SMBus Configuration (206)Figure22.3. SMBus Transaction (207)Figure22.4. Typical SMBus SCL Generation (209)Figure22.5. Typical Master Write Sequence (223)Figure22.6. Typical Master Read Sequence (224)Figure22.7. Typical Slave Write Sequence (225)Figure22.8. Typical Slave Read Sequence (226)Figure23.1. UART0 Block Diagram (232)Figure23.2. UART0 Baud Rate Logic (233)Figure23.3. UART Interconnect Diagram (234)Figure23.4. 8-Bit UART Timing Diagram (234)Figure23.5. 9-Bit UART Timing Diagram (235)Figure23.6. UART Multi-Processor Mode Interconnect Diagram (236)Figure24.1. UART1 Block Diagram (240)Figure24.2. UART1 Timing Without Parity or Extra Bit (242)Figure24.3. UART1 Timing With Parity (242)Figure24.4. UART1 Timing With Extra Bit (242)Figure24.5. Typical UART Interconnect Diagram (243)Figure24.6. UART Multi-Processor Mode Interconnect Diagram (244)Figure25.1. SPI Block Diagram (250)Figure25.2. Multiple-Master Mode Connection Diagram (252)Figure25.3. 3-Wire Single Master and 3-Wire Single Slave Mode Connection Diagram (252)Figure25.4. 4-Wire Single Master Mode and 4-Wire Slave Mode Connection Diagram (253)Figure25.5. Master Mode Data/Clock Timing (255)Figure25.6. Slave Mode Data/Clock Timing (CKPHA = 0) (255)C8051F380/1/2/3/4/5/6/7/C Figure25.7. Slave Mode Data/Clock Timing (CKPHA = 1) (256)Figure25.8. SPI Master Timing (CKPHA = 0) (260)Figure25.9. SPI Master Timing (CKPHA = 1) (260)Figure25.10. SPI Slave Timing (CKPHA = 0) (261)Figure25.11. SPI Slave Timing (CKPHA = 1) (261)Figure26.1. T0 Mode 0 Block Diagram (267)Figure26.2. T0 Mode 2 Block Diagram (268)Figure26.3. T0 Mode 3 Block Diagram (269)Figure26.4. Timer 2 16-Bit Mode Block Diagram (274)Figure26.5. Timer 2 8-Bit Mode Block Diagram (275)Figure26.6. Timer2 Capture Mode (T2SPLIT = 0) (276)Figure26.7. Timer2 Capture Mode (T2SPLIT = 0) (277)Figure26.8. Timer 3 16-Bit Mode Block Diagram (281)Figure26.9. Timer 3 8-Bit Mode Block Diagram (282)Figure26.10. Timer3 Capture Mode (T3SPLIT = 0) (283)Figure26.11. Timer3 Capture Mode (T3SPLIT = 0) (284)Figure26.12. Timer 4 16-Bit Mode Block Diagram (288)Figure26.13. Timer 4 8-Bit Mode Block Diagram (289)Figure26.14. Timer 5 16-Bit Mode Block Diagram (293)Figure26.15. Timer 5 8-Bit Mode Block Diagram (294)Figure27.1. PCA Block Diagram (298)Figure27.2. PCA Counter/Timer Block Diagram (299)Figure27.3. PCA Interrupt Block Diagram (300)Figure27.4. PCA Capture Mode Diagram (302)Figure27.5. PCA Software Timer Mode Diagram (303)Figure27.6. PCA High-Speed Output Mode Diagram (304)Figure27.7. PCA Frequency Output Mode (305)Figure27.8. PCA 8-Bit PWM Mode Diagram (306)Figure27.9. PCA 16-Bit PWM Mode (307)Figure27.10. PCA Module 4 with Watchdog Timer Enabled (308)Figure28.1. Typical C2 Pin Sharing (319)List of TablesTable1.1. Product Selection Guide (17)Table2.1. C8051F38x Replacement Part Numbers (20)Table3.1. Pin Definitions for the C8051F380/1/2/3/4/5/6/7/C (22)Table3.2. TQFP-48 Package Dimensions (26)Table3.3. TQFP-48 PCB Land Pattern Dimensions (27)Table3.4. LQFP-32 Package Dimensions (29)Table3.5. LQFP-32 PCB Land Pattern Dimensions (30)Table3.6. QFN-32 Package Dimensions (32)Table3.7. QFN-32 PCB Land Pattern Dimensions (33)Table5.1. Absolute Maximum Ratings (37)Table5.2. Global Electrical Characteristics (38)Table5.3. Port I/O DC Electrical Characteristics (39)Table5.4. Reset Electrical Characteristics (39)Table5.5. Internal Voltage Regulator Electrical Characteristics (40)Table5.6. Flash Electrical Characteristics (40)Table5.7. Internal High-Frequency Oscillator Electrical Characteristics (41)Table5.8. Internal Low-Frequency Oscillator Electrical Characteristics (41)Table5.9. External Oscillator Electrical Characteristics (41)Table5.10. ADC0 Electrical Characteristics (42)Table5.11. Temperature Sensor Electrical Characteristics (43)Table5.12. Voltage Reference Electrical Characteristics (43)Table5.13. Comparator Electrical Characteristics (44)Table5.14. USB Transceiver Electrical Characteristics (45)Table11.1. CIP-51 Instruction Set Summary (81)Table14.1. AC Parameters for External Memory Interface (110)Table15.1. Special Function Register (SFR) Memory Map (112)Table15.2. Special Function Registers (113)Table16.1. Interrupt Summary (120)Table21.1. Endpoint Addressing Scheme (173)Table21.2. USB0 Controller Registers (178)Table21.3. FIFO Configurations (182)Table22.1. SMBus Clock Source Selection (209)Table22.2. Minimum SDA Setup and Hold Times (210)Table22.3. Sources for Hardware Changes to SMBnCN (217)Table22.4. Hardware Address Recognition Examples (EHACK = 1) (218)Table22.5. SMBus Status Decoding: Hardware ACK Disabled (EHACK = 0) (227)Table22.6. SMBus Status Decoding: Hardware ACK Enabled (EHACK = 1) (229)Table23.1. Timer Settings for Standard Baud Rates Using Internal Oscillator (238)Table24.1. Baud Rate Generator Settings for Standard Baud Rates (241)Table25.1. SPI Slave Timing Parameters (262)Table27.1. PCA Timebase Input Options (299)Table27.2. PCA0CPM Bit Settings for PCA Capture/Compare Modules (301)Table27.3. Watchdog Timer Timeout Intervals1 (310)List of RegistersSFR Definition6.1. ADC0CF: ADC0 Configuration (53)SFR Definition6.2. ADC0H: ADC0 Data Word MSB (54)SFR Definition6.3. ADC0L: ADC0 Data Word LSB (54)SFR Definition6.4. ADC0CN: ADC0 Control (55)SFR Definition6.5. ADC0GTH: ADC0 Greater-Than Data High Byte (56)SFR Definition6.6. ADC0GTL: ADC0 Greater-Than Data Low Byte (56)SFR Definition6.7. ADC0LTH: ADC0 Less-Than Data High Byte (57)SFR Definition6.8. ADC0LTL: ADC0 Less-Than Data Low Byte (57)SFR Definition6.9. AMX0P: AMUX0 Positive Channel Select (60)SFR Definition6.10. AMX0N: AMUX0 Negative Channel Select (61)SFR Definition7.1. REF0CN: Reference Control (63)SFR Definition8.1. CPT0CN: Comparator0 Control (67)SFR Definition8.2. CPT0MD: Comparator0 Mode Selection (68)SFR Definition8.3. CPT1CN: Comparator1 Control (69)SFR Definition8.4. CPT1MD: Comparator1 Mode Selection (70)SFR Definition8.5. CPT0MX: Comparator0 MUX Selection (72)SFR Definition8.6. CPT1MX: Comparator1 MUX Selection (73)SFR Definition9.1. REG01CN: Voltage Regulator Control (75)SFR Definition10.1. PCON: Power Control (78)SFR Definition11.1. DPL: Data Pointer Low Byte (85)SFR Definition11.2. DPH: Data Pointer High Byte (85)SFR Definition11.3. SP: Stack Pointer (86)SFR Definition11.4. ACC: Accumulator (86)SFR Definition11.5. B: B Register (86)SFR Definition11.6. PSW: Program Status Word (87)SFR Definition12.1. PFE0CN: Prefetch Engine Control (88)SFR Definition14.1. EMI0CN: External Memory Interface Control (96)SFR Definition14.2. EMI0CF: External Memory Interface Configuration (97)SFR Definition14.3. EMI0TC: External Memory TIming Control (103)SFR Definition15.1. SFRPAGE: SFR Page (111)SFR Definition16.1. IE: Interrupt Enable (121)SFR Definition16.2. IP: Interrupt Priority (122)SFR Definition16.3. EIE1: Extended Interrupt Enable 1 (123)SFR Definition16.4. EIP1: Extended Interrupt Priority 1 (124)SFR Definition16.5. EIE2: Extended Interrupt Enable 2 (125)SFR Definition16.6. EIP2: Extended Interrupt Priority 2 (126)SFR Definition16.7. IT01CF: INT0/INT1 ConfigurationO (128)SFR Definition17.1. VDM0CN: VDD Monitor Control (132)SFR Definition17.2. RSTSRC: Reset Source (134)SFR Definition18.1. PSCTL: Program Store R/W Control (139)SFR Definition18.2. FLKEY: Flash Lock and Key (140)SFR Definition18.3. FLSCL: Flash Scale (141)SFR Definition19.1. CLKSEL: Clock Select (144)C8051F380/1/2/3/4/5/6/7/CSFR Definition19.2. OSCICL: Internal H-F Oscillator Calibration (145)SFR Definition19.3. OSCICN: Internal H-F Oscillator Control (146)SFR Definition19.4. CLKMUL: Clock Multiplier Control (147)SFR Definition19.5. OSCLCN: Internal L-F Oscillator Control (148)SFR Definition19.6. OSCXCN: External Oscillator Control (152)SFR Definition20.1. XBR0: Port I/O Crossbar Register 0 (159)SFR Definition20.2. XBR1: Port I/O Crossbar Register 1 (160)SFR Definition20.3. XBR2: Port I/O Crossbar Register 2 (161)SFR Definition20.4. P0: Port 0 (162)SFR Definition20.5. P0MDIN: Port 0 Input Mode (162)SFR Definition20.6. P0MDOUT: Port 0 Output Mode (163)SFR Definition20.7. P0SKIP: Port 0 Skip (163)SFR Definition20.8. P1: Port 1 (164)SFR Definition20.9. P1MDIN: Port 1 Input Mode (164)SFR Definition20.10. P1MDOUT: Port 1 Output Mode (165)SFR Definition20.11. P1SKIP: Port 1 Skip (165)SFR Definition20.12. P2: Port 2 (166)SFR Definition20.13. P2MDIN: Port 2 Input Mode (166)SFR Definition20.14. P2MDOUT: Port 2 Output Mode (167)SFR Definition20.15. P2SKIP: Port 2 Skip (167)SFR Definition20.16. P3: Port 3 (168)SFR Definition20.17. P3MDIN: Port 3 Input Mode (168)SFR Definition20.18. P3MDOUT: Port 3 Output Mode (169)SFR Definition20.19. P3SKIP: Port 3 Skip (169)SFR Definition20.20. P4: Port 4 (170)SFR Definition20.21. P4MDIN: Port 4 Input Mode (170)SFR Definition20.22. P4MDOUT: Port 4 Output Mode (171)SFR Definition21.1. USB0XCN: USB0 Transceiver Control (174)SFR Definition21.2. USB0ADR: USB0 Indirect Address (176)SFR Definition21.3. USB0DAT: USB0 Data (177)USB Register Definition21.4. INDEX: USB0 Endpoint Index (179)USB Register Definition21.5. CLKREC: Clock Recovery Control (180)USB Register Definition21.6. FIFOn: USB0 Endpoint FIFO Access (182)USB Register Definition21.7. FADDR: USB0 Function Address (183)USB Register Definition21.8. POWER: USB0 Power (185)USB Register Definition21.9. FRAMEL: USB0 Frame Number Low (186)USB Register Definition21.10. FRAMEH: USB0 Frame Number High (186)USB Register Definition21.11. IN1INT: USB0 IN Endpoint Interrupt (187)USB Register Definition21.12. OUT1INT: USB0 OUT Endpoint Interrupt (188)USB Register Definition21.13. CMINT: USB0 Common Interrupt (189)USB Register Definition21.14. IN1IE: USB0 IN Endpoint Interrupt Enable (190)USB Register Definition21.15. OUT1IE: USB0 OUT Endpoint Interrupt Enable (191)USB Register Definition21.16. CMIE: USB0 Common Interrupt Enable (192)USB Register Definition21.17. E0CSR: USB0 Endpoint0 Control (195)USB Register Definition21.18. E0CNT: USB0 Endpoint0 Data Count (196)C8051F380/1/2/3/4/5/6/7/C USB Register Definition21.19. EENABLE: USB0 Endpoint Enable (197)USB Register Definition21.20. EINCSRL: USB0 IN Endpoint Control Low (199)USB Register Definition21.21. EINCSRH: USB0 IN Endpoint Control High (200)USB Register Definition21.22. EOUTCSRL: USB0 OUT Endpoint Control Low Byte 202 USB Register Definition21.23. EOUTCSRH: USB0 OUT Endpoint Control High Byte (203)USB Register Definition21.24. EOUTCNTL: USB0 OUT Endpoint Count Low (203)USB Register Definition21.25. EOUTCNTH: USB0 OUT Endpoint Count High (204)SFR Definition22.1. SMB0CF: SMBus Clock/Configuration (211)SFR Definition22.2. SMB1CF: SMBus Clock/Configuration (212)SFR Definition22.3. SMBTC: SMBus Timing Control (213)SFR Definition22.4. SMB0CN: SMBus Control (215)SFR Definition22.5. SMB1CN: SMBus Control (216)SFR Definition22.6. SMB0ADR: SMBus0 Slave Address (218)SFR Definition22.7. SMB0ADM: SMBus0 Slave Address Mask (219)SFR Definition22.8. SMB1ADR: SMBus1 Slave Address (219)SFR Definition22.9. SMB1ADM: SMBus1 Slave Address Mask (220)SFR Definition22.10. SMB0DAT: SMBus Data (221)SFR Definition22.11. SMB1DAT: SMBus Data (222)SFR Definition23.1. SCON0: Serial Port 0 Control (237)SFR Definition23.2. SBUF0: Serial (UART0) Port Data Buffer (238)SFR Definition24.1. SCON1: UART1 Control (245)SFR Definition24.2. SMOD1: UART1 Mode (246)SFR Definition24.3. SBUF1: UART1 Data Buffer (247)SFR Definition24.4. SBCON1: UART1 Baud Rate Generator Control (248)SFR Definition24.5. SBRLH1: UART1 Baud Rate Generator High Byte (248)SFR Definition24.6. SBRLL1: UART1 Baud Rate Generator Low Byte (249)SFR Definition25.1. SPI0CFG: SPI0 Configuration (257)SFR Definition25.2. SPI0CN: SPI0 Control (258)SFR Definition25.3. SPI0CKR: SPI0 Clock Rate (259)SFR Definition25.4. SPI0DAT: SPI0 Data (259)SFR Definition26.1. CKCON: Clock Control (264)SFR Definition26.2. CKCON1: Clock Control 1 (265)SFR Definition26.3. TCON: Timer Control (270)SFR Definition26.4. TMOD: Timer Mode (271)SFR Definition26.5. TL0: Timer 0 Low Byte (272)SFR Definition26.6. TL1: Timer 1 Low Byte (272)SFR Definition26.7. TH0: Timer 0 High Byte (273)SFR Definition26.8. TH1: Timer 1 High Byte (273)SFR Definition26.9. TMR2CN: Timer 2 Control (278)SFR Definition26.10. TMR2RLL: Timer 2 Reload Register Low Byte (279)SFR Definition26.11. TMR2RLH: Timer 2 Reload Register High Byte (279)SFR Definition26.12. TMR2L: Timer 2 Low Byte (279)SFR Definition26.13. TMR2H Timer 2 High Byte (280)SFR Definition26.14. TMR3CN: Timer 3 Control (285)C8051F380/1/2/3/4/5/6/7/CSFR Definition26.15. TMR3RLL: Timer 3 Reload Register Low Byte (286)SFR Definition26.16. TMR3RLH: Timer 3 Reload Register High Byte (286)SFR Definition26.17. TMR3L: Timer 3 Low Byte (286)SFR Definition26.18. TMR3H Timer 3 High Byte (287)SFR Definition26.19. TMR4CN: Timer 4 Control (290)SFR Definition26.20. TMR4RLL: Timer 4 Reload Register Low Byte (291)SFR Definition26.21. TMR4RLH: Timer 4 Reload Register High Byte (291)SFR Definition26.22. TMR4L: Timer 4 Low Byte (291)SFR Definition26.23. TMR4H Timer 4 High Byte (292)SFR Definition26.24. TMR5CN: Timer 5 Control (295)SFR Definition26.25. TMR5RLL: Timer 5 Reload Register Low Byte (296)SFR Definition26.26. TMR5RLH: Timer 5 Reload Register High Byte (296)SFR Definition26.27. TMR5L: Timer 5 Low Byte (296)SFR Definition26.28. TMR5H Timer 5 High Byte (297)SFR Definition27.1. PCA0CN: PCA Control (311)SFR Definition27.2. PCA0MD: PCA Mode (312)SFR Definition27.3. PCA0CPMn: PCA Capture/Compare Mode (313)SFR Definition27.4. PCA0L: PCA Counter/Timer Low Byte (314)SFR Definition27.5. PCA0H: PCA Counter/Timer High Byte (314)SFR Definition27.6. PCA0CPLn: PCA Capture Module Low Byte (315)SFR Definition27.7. PCA0CPHn: PCA Capture Module High Byte (315)C2 Register Definition28.1. C2ADD: C2 Address (316)C2 Register Definition28.2. DEVICEID: C2 Device ID (317)C2 Register Definition28.3. REVID: C2 Revision ID (317)C2 Register Definition28.4. FPCTL: C2 Flash Programming Control (318)C2 Register Definition28.5. FPDAT: C2 Flash Programming Data (318)。

Atmel 推出SHA-256 密码认证IC 系列保护数据安全爱特梅尔公司(Atmel®Corporation) 宣布推出AT88SA 系列最低成本、超低功耗的安全密码认证IC，该系列中的首款器件AT88SA102S 是通用CryptoAuthentication™IC，经专门设计，能够保护用户避免假冒电子产品和医疗耗材如电池、墨盒、测试条、血袋、呼吸管及其它。

这一系列器件能够用于保护网络传输安全如卫星无线广播或医疗记录，或者任何其它类型逻辑数据如固件或媒体。

基于MCU 的先进系统通常使用非易失性存储器以存储固件/软件，CryptoAuthentication 提供了一种低成本的方法，确保存储数据是可信的，并保护下载资料不受盗窃或修改。

对于使用AVR®和ARM®微控制器且包含AES 加密引擎的系统而言，CryptoAuthentication 提供了理想的安全关键性存储解决方案。

业界唯一具有SHA-256 的认证IC爱特梅尔的AT88SA 器件是业界最安全的认证IC，具有嵌入式SHA-256 引擎，其256 位密钥容量提供了更多的可能密钥，数量之多甚至超过太阳中的原子，几乎不可能使用任何暴力方法去击破，而最接近的同类认证IC 产品的密钥容量仅及其一半。

AT88SA102S 包括23 位一次性可编程(one-time- programmable, OTP) 熔丝，可用于个性化、状态或消耗记录，以及一个保证是独一无二的48 位串行数字。

这款器件具有一个与所有微控制器兼容的高速单线接口，使用硬件UART 或者单一GPIO 引脚上的位操作(bit manipulation) 固件。

认证－认证是基于微控制器主机和客户之间的“挑战/响应”协议，主机可。

GETTING STARTED GUIDEPXIe-578512-Bit, 6.4 GS/s, 2-Channel PXI FlexRIO IF TransceiverThis document explains how to install, configure, test, and use the PXIe-5785. You can program the PXIe-5785 with the following software options.•FlexRIO driver software•NI LabVIEW Instrument Design Libraries for FlexRIO (instrument design libraries) Note Before you begin, install and configure your chassis and controller.Note Adapter modules are not installable or interchangeable on PXIe-5785devices.ContentsFlexRIO Documentation and Resources (2)Verifying the System Requirements (2)Unpacking the Kit (3)PXIe-5785 Kit Contents (3)Preparing the Environment (4)Installing the Software and Driver (4)Installing the PXIe-5785 (5)PXIe-5785 Front Panel (6)Configuring the PXIe-5785 in MAX (8)FlexRIO Examples (9)Accessing FlexRIO Examples (9)Block Diagram (9)Component-Level Intellectual Property (CLIP) (11)Making a Measurement (12)Making a Measurement with LabVIEW (12)Troubleshooting (12)What Should I Do if the PXIe-5785 Doesn't Appear in MAX? (12)What Should I Do if the PXIe-5785 Fails the Self-Test? (12)Where to Go Next (13)Worldwide Support and Services (13)FlexRIO Documentation and ResourcesVerifying the System RequirementsTo use the PXIe-5785, your system must meet certain requirements. For more information about minimum system requirements, recommended system, and supported application development environments (ADEs), refer to the readme, which is available on the software media or online at /updates.2| | PXIe-5785 Getting Started GuideUnpacking the KitNotice To prevent electrostatic discharge (ESD) from damaging the device, groundyourself using a grounding strap or by holding a grounded object, such as yourcomputer chassis.1.Touch the antistatic package to a metal part of the computer chassis.2.Remove the device from the package and inspect the device for loose components or anyother sign of damage.Notice Never touch the exposed pins of connectors.Note Do not install a device if it appears damaged in any way.3.Unpack any other items and documentation from the kit.Store the device in the antistatic package when the device is not in use.PXIe-5785 Kit ContentsThe following items are included in the device kit:•PXIe-5785•FlexRIO driver software media•Documentation:–Maintain Forced-Air Cooling Note to Users–PXIe-5785 Getting Started Guide (this document)–PXIe-5785 Safety, Environmental, and Regulatory InformationPXIe-5785 Getting Started Guide| © National Instruments| 3Preparing the EnvironmentEnsure the environment in which you are using the PXIe-5785 meets the following specifications.Operating environmentAmbient temperature range0 °C to 55 °C1 (Tested in accordance withIEC-60068-2-1 and IEC-60068-2-2. MeetsMIL-PRF-28800F Class 3 low temperaturelimit and MIL-PRF-28800F Class 2 hightemperature limit.)Relative humidity range10% to 90%, noncondensing (Tested inaccordance with IEC 60068-2-56.) Maximum altitude2,000 m (800 mbar) (at 25 °C ambienttemperature)Pollution Degree2Indoor use only.Note For complete specifications, refer to the specifications document for yourdevice at /manuals.Installing the Software and DriverBefore installing your hardware, you must install the application software and instrument driver. Visit NI FlexRIO Driver Supported Versions for FlexRIO Adapters and Modules to determine which minimum software versions you need for your device. Install the software in the following order:1.Install LabVIEW.Refer to the LabVIEW Installation Guide for installation instructions for LabVIEW and system requirements for the LabVIEW software. Refer to the LabVIEW Upgrade Notes for additional information about upgrading to the most recent version of LabVIEW for Windows. Documentation for LabVIEW is available at /manuals.2.Install the LabVIEW FPGA Module.Refer to the LabVIEW FPGA Module Release and Upgrade Notes for installationinstructions and information about getting started with the LabVIEW FPGA Module.Documentation for the LabVIEW FPGA Module is available at /manuals.3.(Optional) Install the LabVIEW Real-Time Module.1The PXIe-5785 requires a chassis with slot cooling capacity ≥58 W. Not all chassis with slotcooling capacity ≥58 W can achieve this ambient temperature range. Refer to the PXI ChassisManual for specifications to determine the ambient temperature ranges your chassis can achieve. 4| | PXIe-5785 Getting Started GuideRefer to the LabVIEW Real-Time Module Release and Upgrade Notes for systemrequirements, installation instructions, and additional information about using theLabVIEW Real-Time Module.4.Install FlexRIO.Refer to the FlexRIO Readme for system requirements and installation instructions for FlexRIO. Documentation for FlexRIO is available at /manuals. Installing the PXIe-5785Notice To prevent damage to the PXIe-5785 caused by ESD or contamination,handle the module using the edges or the metal bracket.1.Ensure the AC power source is connected to the chassis before installing the module.The AC power cord grounds the chassis and protects it from electrical damage while you install the module.2.Power off the chassis.3.Inspect the slot pins on the chassis backplane for any bends or damage prior toinstallation. Do not install a module if the backplane is damaged.4.Remove the black plastic covers from all the captive screws on the module front panel.5.Identify a supported slot in the chassis. The following figure shows the symbols thatindicate the slot types.Figure 1. Chassis Compatibility Symbols1.PXI Express System Controller Slot2.PXI Peripheral Slot3.PXI Express Hybrid Peripheral Slot4.PXI Express System Timing Slot5.PXI Express Peripheral SlotPXIe-5785 modules can be placed in PXI Express peripheral slots, PXI Express hybrid peripheral slots, or PXI Express system timing slots.6.Touch any metal part of the chassis to discharge static electricity.7.Ensure that the ejector handle is in the downward (unlatched) position.8.Place the module edges into the module guides at the top and bottom of the chassis. Slidethe module into the slot until it is fully inserted.PXIe-5785 Getting Started Guide| © National Instruments| 5Figure 2. Module Installation1.Chassis2.Hardware Module3.Ejector Handle in Downward (Unlatched) Positiontch the module in place by pulling up on the ejector handle.10.Secure the module front panel to the chassis using the front-panel mounting screws.Note Tightening the top and bottom mounting screws increases mechanicalstability and also electrically connects the front panel to the chassis, which can improve the signal quality and electromagnetic performance.11.Cover all empty slots using EMC filler panels or fill using slot blockers to maximizecooling air flow, depending on your application.12.Power on the chassis.PXIe-5785 Front PanelThe following figure shows the PXIe-5785 front panel.6 | | PXIe-5785 Getting Started GuideFigure 3. PXIe-5785 Front PanelThe following table describes the signal connections for the PXIe-5785.PXIe-5785 Getting Started Guide| © National Instruments| 7The following table lists the available pins on the DIO connector.Notice The maximum input signal levels are valid only when the module ispowered on. To avoid permanent damage to the PXIe-5785, do not apply a signal tothe device when the module is powered down.Notice Connections that exceed any of the maximum ratings of any connector onthe PXIe-5785 can damage the device and the chassis. NI is not liable for anydamage resulting from such connections.Configuring the PXIe-5785 in MAXUse Measurement & Automation Explorer (MAX) to configure your NI hardware. MAX informs other programs about which NI hardware products are in the system and how they are configured. MAX is automatically installed with FlexRIO.unch MAX.2.In the configuration tree, expand Devices and Interfaces to see the list of installed NIhardware.Installed modules appear under the name of their associated chassis.3.Expand your Chassis tree item.2MGTs are available only on devices with KU040 and KU060 FPGAs.8| | PXIe-5785 Getting Started GuideMAX lists all modules installed in the chassis. Your default names may vary.Note If you do not see your module listed, press <F5> to refresh the list ofinstalled modules. If the module is still not listed, power off the system, ensurethe module is correctly installed, and restart.4.Record the identifier MAX assigns to the hardware. Use this identifier whenprogramming the PXIe-5785.5.Self-test the hardware by selecting the item in the configuration tree and clicking Self-Test in the MAX toolbar.The MAX self-test performs a basic verification of hardware resources.FlexRIO ExamplesFlexRIO includes several example applications for LabVIEW. These examples serve as interactive tools, programming models, and as building blocks in your own applications. Accessing FlexRIO ExamplesFlexRIO examples are available in LabVIEW's NI Example Finder. Complete the following steps to access the examples by task.1.In LabVIEW, click Help»Find Examples.2.In the NI Example Finder window that appears, click Hardware Input and Output»FlexRIO.The examples are sorted by task. Click on an example and refer to the Informationwindow for a description of the example. Refer the Requirements window for a list of hardware devices that can run the example.You can also click the Search tab to search all installed examples by keyword. Forexample, search for FlexRIO to locate all FlexRIO examples.Examples also are available online that demonstrate FlexRIO basics, such as using DRAM, acquiring data from adapter modules, and performing high throughput streaming. Refer to /examples for these examples and for more information.Block DiagramThe following figure shows a block diagram of the carrier portion of the PXIe-5785 (KU035 FPGA option).PXIe-5785 Getting Started Guide| © National Instruments| 9Figure 4. Carrier Block Diagram (KU035)The following figure shows a block diagram of the carrier portion of the PXIe-5785 (KU040 and KU060 FPGA options).Figure 5. Carrier Block Diagram (KU040 and KU060)The following figure shows a block diagram of the I/O portion of the PXIe-5785.10| | PXIe-5785 Getting Started GuideFigure 6. PXIe-5785 Block DiagramADC12DJ3200Dual 12-bit, 3.2 GS/sComponent-Level Intellectual Property (CLIP) The LabVIEW FPGA Module includes component-level intellectual property (CLIP) for HDL IP integration. FlexRIO devices support two types of CLIP: user-defined and socketed.•User-defined CLIP allows you to insert HDL IP into an FPGA target, enabling VHDL code to communicate directly with an FPGA VI.•Socketed CLIP provides the same IP integration of the user-defined CLIP, but it also allows the CLIP to communicate directly with circuitry external to the FPGA. Adapter module socketed CLIP allows your IP to communicate directly with both the FPGA VI and the external adapter module connector interface.The PXIe-5785 ships with socketed CLIP items that add module I/O to the LabVIEW project.PXIe-5785 Getting Started Guide| © National Instruments| 11Making a MeasurementMaking a Measurement with LabVIEWunch LabVIEW.2.Select Help»Find Example.3.Open the example VI that you want to use by selecting Hardware Input and Output»FlexRIO.4.Follow any setup, configuration, and execution instructions in the VI.TroubleshootingIf an issue persists after you complete a troubleshooting procedure, contact NI technical support or visit /support.What Should I Do if the PXIe-5785 Doesn't Appear in MAX?1.In the MAX configuration tree, expand Devices and Interfaces.2.Expand the Chassis tree to see the list of installed hardware, and press <F5> to refreshthe list.3.If the module is still not listed, power off the system, ensure that all hardware is correctlyinstalled, and restart the system.4.Navigate to the Device Manager.Operating System DescriptionWindows 7Select Start»Control Panel»Device Manager.5.Verify the PXIe-5785 appears in the Device Manager.a)Under an NI entry, confirm that a PXIe-5785 entry appears.Note If you are using a PC with a device for PXI remote control system,under System Devices, also confirm that no error conditions appear for thePCI-to-PCI Bridge.b)If error conditions appear, reinstall FlexRIO and the PXIe-5785.What Should I Do if the PXIe-5785 Fails the Self-T est?1.Restart the system.unch MAX, and perform the self-test again.3.Power off the chassis.4.Reinstall the failed module in a different slot.12| | PXIe-5785 Getting Started Guide5.Power on the chassis.6.Perform the self-test again.Where to Go NextRefer to the following figure for information about other product tasks and associated resources for those tasks.Worldwide Support and ServicesThe NI website is your complete resource for technical support. At /support, you have access to everything from troubleshooting and application development self-help resources to email and phone assistance from NI Application Engineers.Visit /services for information about the services NI offers.Visit /register to register your NI product. Product registration facilitates technical support and ensures that you receive important information updates from NI.NI corporate headquarters is located at 11500 North Mopac Expressway, Austin, Texas, 78759-3504. NI also has offices located around the world. For support in the United States, create your service request at /support or dial 1 866 ASK MYNI (275 6964). ForPXIe-5785 Getting Started Guide| © National Instruments| 13support outside the United States, visit the Worldwide Offices section of /niglobal to access the branch office websites, which provide up-to-date contact information.Information is subject to change without notice. Refer to the NI T rademarks and Logo Guidelines at /trademarks for information on NI trademarks. Other product and company names mentioned herein are trademarks or trade names of their respective companies. For patents covering NI products/technology, refer to the appropriate location: Help»Patents in your software, the patents.txt file on your media, or the National Instruments Patent Notice at /patents. Y ou can find information about end-user license agreements (EULAs) and third-party legal notices in the readme file for your NI product. Refer to the Export Compliance Information at /legal/export-compliance for the NI global trade compliance policy and how to obtain relevant HTS codes, ECCNs, and other import/export data. NI MAKES NO EXPRESS OR IMPLIED WARRANTIES AS TO THE ACCURACY OF THE INFORMA TION CONTAINED HEREIN AND SHALL NOT BE LIABLE FOR ANY ERRORS. U.S. Government Customers: The data contained in this manual was developed at private expense and is subject to the applicable limited rights and restricted data rights as set forth in FAR 52.227-14, DFAR 252.227-7014, and DFAR 252.227-7015.© 2018—2019 National Instruments. All rights reserved.376897B-01March 21, 2019。

Strumenti AnalogiciAnalog DevicesAppareils AnalogiquesAnaloge Geräteinstrumentos AnalógicosРуководство Пользователя模拟装备Manuale d’usoUser’s manualManuel de l’utilisateurBedienerhandbuchManual de usoАналоговые приборы用户手册made in ItalyITA: La dichiarazione di conformità UE del presente DPI è consultabile all’interno del sito EN: The EU declaration of conformity of this PPE is available on the websiteFRA: La déclaration UE de conformité de cet EPI est disponible sur le site internet ES: La declaración de conformidad de la UE de este PPE está disponible en el sitio web DE: Die EU-Konformitätserklärung dieser PSA ist auf der Website verfügbarRUS: Декларация ЕС о соответствии этого СИЗ доступна на веб-сайте CN: 欧盟的PPE符合性声明可在网站上获得43简介恭喜您！通过了解我们的技术中心进行的持续研究和发展以及Cressi-sub享有盛誉的可靠性品质，您购买了我们的产品，您可以长时间舒适、安全地进行潜水运动。

碧云天生物技术/Beyotime Biotechnology订货热线：400-168-3301或800-8283301订货e-mail：******************技术咨询：*****************碧云天网站微信公众号网址：3M NaAc, pH5.2 (Sterile, DNase free)产品编号产品名称包装ST351 3M NaAc, pH5.2 (Sterile, DNase free) 100ml产品简介：3M NaAc pH5.2 (Sterile, DNase free)，即无菌，无DNA酶污染的醋酸钠缓冲液，是一种常用的分子生物学试剂。

本产品无菌，无DNA酶污染，主要用于DNA的乙醇沉淀等。

NaAc即醋酸钠(Sodium Acetate)，也称乙酸钠，分子式为CH3COONa，分子量82.03，CAS号127-09-3。

DNA是一种多聚阴离子水溶性化合物，在DNA提取过程中，经常需要加入醋酸钠等适当的缓冲液并用乙醇等适当有机溶剂来沉淀DNA。

其原理是乙醇能夺取DNA周围的水分子，使DNA失水从而易于聚合；同时乙醇也能够消除DNA的水化层使带负电荷的磷酸基团暴露出来与醋酸钠缓冲液中的高浓度钠离子(Na+)结合，从而减少DNA分子之间的同性电荷排斥力而更易于聚合，最终形成DNA钠盐沉淀。

在低温环境下，这种促沉淀效应会被加强，因此对于低浓度DNA或者较难沉淀的小分子量DNA通常宜在-20ºC或-70ºC等低温条件下沉淀，以提高沉淀效率。

本产品常用于各种常见DNA样品的浓缩和纯化。

包装清单：产品编号产品名称包装ST351 3M NaAc, pH5.2 (Sterile, DNase free) 100ml—说明书1份保存条件：室温保存。

注意事项：本产品仅限于专业人员的科学研究用，不得用于临床诊断或治疗，不得用于食品或药品，不得存放于普通住宅内。

为了您的安全和健康，请穿实验服并戴一次性手套操作。

EVKT-MSM942038-24EVKT-MSM942038-24eMotion System TM Smart Motor ModuleEvaluation KitEvaluation Kit EVKT-MSM942038-24 ContentsPart Number EVKT-MSM942038-24Diameter (mm) 42 Power (W)38 Typical Voltage (V)24 InterfaceRS485# Part Number Item Quantity 1EVKT-MSM942038-24 BLDC motor withMMP742038-24 smart motor module installed 1 2eMotion System TMcommunication kitUSB communication interface with cable1FEATURESThe EVKT-MSM942038-24 evaluation kit is part of a family of fully integrated smart motor solutions for servo motor applications. This 42mm (NEMA 17), 38W motor integrates a brushless DC motor and a smart motor module. The user can program the system to operate in speed control mode, position control mode, or torque control mode. Two control interface options are available: an RS485 interface and a PULSE/DIR interface. Easy-to-use GUI software provides flexibility by allowing users to optimize the design online through the RS485 control interface. The parameters are saved in the motor module ’s non-volatile memory. A design guide for the GUI is available for download at .The smart motor modules can be ordered separately for customization into different motor types. The MMP742038-24 is the driver module part number used in the kit.The datasheet for the MMP742038-24 is available for download at .∙ 18V to 36V Input Voltage Range ∙ Max 38W Continuous Power Output ∙ 0.12N-m Rated Torque (0.36N-m Peak Torque)∙0.3° Position Resolution ∙ RS485 Interface and PULSE/DIR Interface ∙ Position, Speed, and Torque Control Modes ∙ Operating Temperature: 0°C to 70°C (Power Derated > 40°C) ∙ Storage Temperature: -40°C to +125°CORDERING INFORMATIONDESCRIPTIONEVKT-MSM942038-24 – eMOTION SYSTEM TM EVALUATION KITSmart Motor Module Evaluation KitParameter Condition Value UnitsInput voltage24 VOutput power0°C to40°C38 WPositionresolution0.3 °Nominal speed3000 rpmNominal torque0.12 N-mRotor inertia24 g-cm2Diameter42 mmShaft diameter 5 mmLength Body only 40 mmWeight300 gHARDWARE CONNECTIONSRECOMMENDED OPERATING CONDITIONSInput voltage ................................. 18V to 36VControl interface voltage ................ 0V to 5.5VMax pulse frequency .......................... 500kHzRS485 A/B voltage ........................ 0V to 5.5VRS485 common mode voltage ................±15VOperation temperature................. 0°C to 70°CStorage temperature ............. -40°C to +125°C EVALUATION KIT SPECIFICATIONSEVKT-MSM942038-24 – eMOTION SYSTEM TM EVALUATION KIT8 9 10 11 121 2 3 45 6 7Fault IndicationPower On IndicationT A = 25°C, V IN = 24V, unless otherwise noted.Pin NumberDesignation Pin Description RS485 Interface 1 EXT_5V5V input for firmware programming 2 B RS485 node B 3 AGND RS485 ground 4 A RS485 node A Power Interface5 GND Power ground6 R- Shunt resistor return node7 VIN Input power supply Control Interface8 COM- Common return 9 EN+ Enable input 10 PEND+ Position end output11 PUL+ Pulse input 12DIR+Direction inputPIN CONFIGURATIONTYPICAL PERFORMANCE CHARACTERISTICSEVKT-MSM942038-24 – eMOTION SYSTEM TM EVALUATION KITMECHANICAL DRAWINGEVKT-MSM942038-24。

ATECC508AAtmel CryptoAuthentication DeviceSUMMARY DATASHEETFeatures∙ Cryptographic Co-processor with Secure Hardware-based Key Storage ∙ Performs High-Speed Public Key (PKI) Algorithms– ECDSA: FIPS186-3 Elliptic Curve Digital Signature Algorithm – ECDH: FIPS SP800-56A Elliptic Curve Diffie-Hellman Algorithm ∙ NIST Standard P256 Elliptic Curve Support ∙ SHA-256 Hash Algorithm with HMAC Option ∙ Host and Client Operations ∙ 256-bit Key Length ∙ Storage for up to 16 Keys∙ Two high-endurance monotonic counters ∙ Guaranteed Unique 72-bit Serial Number∙ Internal High-quality FIPS Random Number Generator (RNG) ∙ 10Kb EEPROM Memory for Keys, Certificates, and Data ∙ Storage for up to 16 Keys∙ Multiple Options for Consumption Logging and One Time Write Information∙ Intrusion Latch for External Tamper Switch or Power-on Chip Enablement. Multiple I/O Options:– High-speed Single Pin Interface, with One GPIO Pin – 1MHz Standard I 2C Interface ∙ 2.0V to 5.5V Supply Voltage Range ∙ 1.8V to 5.5V IO levels ∙ <150nA Sleep Current∙ 8-pad UDFN, 8-lead SOIC, and 3-lead CONTACT PackagesApplications∙ IoT Node Security and ID ∙ S ecure Download and Boot ∙ E cosystem Control ∙ M essage Security ∙ A nti-CloningThis is a summary document. The complete document is available under NDA. For more information, please contact your local Atmel sales office.Secure Download and BootAuthentication and Protect Code In-transitEcosystem ControlEnsure Only OEM/Licensed Nodes and Accessories WorkAnti-cloningPrevent Building with Identical BOM or Stolen CodeMessage SecurityAuthentication, Message Integrity,and Confidentiality of Network Nodes (IoT)CryptoAuthenticationEnsures Things and Code are Real, Untampered, and ConfidentialPin Configuration and Pinouts Table 1. Pin ConfigurationFigure 1. PinoutsATECC508A [Summary Datasheet]Atmel-8923BS-CryptoAuth-ATECC508A-Datasheet-Summary_102015221 Introduction1.1 ApplicationsThe Atmel® ATECC508A is a member of the Atmel CryptoAuthentication™ family of crypto engine authentication devices with highly secure hardware-based key storage.The ATECC508A has a flexible command set that allows use in many applications, including the following,among many others:∙Network/IoT Node ProtectionAuthenticates node IDs, ensures the integrity of messages, and supports key agreement to create sessionkeys for message encryption.∙Anti-CounterfeitingValidates that a removable, replaceable, or consumable client is authentic. Examples of clients could besystem accessories, electronic daughter cards, or other spare parts. It can also be used to validate asoftware/firmware module or memory storage element.∙Protecting Firmware or MediaValidates code stored in flash memory at boot to prevent unauthorized modifications, encrypt downloadedprogram files as a common broadcast, or uniquely encrypt code images to be usable on a single systemonly.∙Storing Secure DataStore secret keys for use by crypto accelerators in standard microprocessors. Programmable protection isavailable using encrypted/authenticated reads and writes.∙Checking User PasswordValidates user-entered passwords without letting the expected value become known, maps memorablepasswords to a random number, and securely exchanges password values with remote systems.1.2 Device FeaturesThe ATECC508A includes an EEPROM array which can be used for storage of up to 16 keys, certificates,miscellaneous read/write, read-only or secret data, consumption logging, and security configurations. Access to the various sections of memory can be restricted in a variety of ways and then the configuration can be locked to prevent changes.The ATECC508A features a wide array of defense mechanisms specifically designed to prevent physical attacks on the device itself, or logical attacks on the data transmitted between the device and the system. Hardware restrictions on the ways in which keys are used or generated provide further defense against certain styles of attack.Access to the device is made through a standard I2C Interface at speeds of up to 1Mb/s. The interface iscompatible with standard Serial EEPROM I2C interface specifications. The device also supports a Single-Wire Interface (SWI), which can reduce the number of GPIOs required on the system processor, and/or reduce the number of pins on connectors. If the Single-Wire Interface is enabled, the remaining pin is available for use as a GPIO, an authenticated output or tamper input.Using either the I2C or Single-Wire Interface, multiple ATECC508A devices can share the same bus, which saves processor GPIO usage in systems with multiple clients such as different color ink tanks or multiple spare parts, for example.Each ATECC508A ships with a guaranteed unique 72-bit serial number. Using the cryptographic protocolssupported by the device, a host system or remote server can verify a signature of the serial number to prove that the serial number is authentic and not a copy. Serial numbers are often stored in a standard Serial EEPROM;however, these can be easily copied with no way for the host to know if the serial number is authentic or if it is a clone.ATECC508A [Summary Datasheet]Atmel-8923BS-CryptoAuth-ATECC508A-Datasheet-Summary_1020153 3ATECC508A [Summary Datasheet]Atmel-8923BS-CryptoAuth-ATECC508A-Datasheet-Summary_10201544The ATECC508A can generate high-quality FIPS random numbers and employ them for any purpose, including usage as part of the device’s crypto protocols. Because each random number is guaranteed to be essentially unique from all numbers ever generated on this or any other device, their inclusion in the protocol calculation ensures that replay attacks (i.e. re-transmitting a previously successful transaction) will always fail.System integration is easy due to a wide supply voltage range (of 2.0V to 5.5V) and an ultra-low sleep current (of <150nA). Multiple package options are available.See Section 3 for information regarding compatibility with the Atmel ATSHA204 and ATECC108.1.3 Cryptographic OperationThe ATECC508A implements a complete asymmetric (public/private) key cryptographic signature solution based upon Elliptic Curve Cryptography and the ECDSA signature protocol. The device features hardware acceleration for the NIST standard P256 prime curve and supports the complete key life cycle from high quality private key generation, to ECDSA signature generation, ECDH key agreement, and ECDSA public key signature verification.The hardware accelerator can implement such asymmetric cryptographic operations from ten to one-thousand times faster than software running on standard microprocessors, without the usual high risk of key exposure that is endemic to standard microprocessors.The device is designed to securely store multiple private keys along with their associated public keys andcertificates. The signature verification command can use any stored or an external ECC public key. Public keys stored within the device can be configured to require validation via a certificate chain to speed-up subsequent device authentications.Random private key generation is supported internally within the device to ensure that the private key can never be known outside of the device. The public key corresponding to a stored private key is always returned when the key is generated and it may optionally be computed at a later time.The ATECC508A also supports a standard hash-based challenge-response protocol in order to simplifyprogramming. In its most basic instantiation, the system sends a challenge to the device, which combines that challenge with a secret key and then sends the response back to the system. The device uses a SHA-256cryptographic hash algorithm to make that combination so that an observer on the bus cannot derive the value of the secret key, but preserving that ability of a recipient to verify that the response is correct by performing the same calculation with a stored copy of the secret on the recipient’s system.Due to the flexible command set of the ATECC508A, these basic operation sets (i.e. ECDSA signatures, ECDH key agreement and SHA-256 challenge-response) can be expanded in many ways.In a host-client configuration where the host (for instance a mobile phone) needs to verify a client (for instance an OEM battery), there is a need to store the secret in the host in order to validate the response from the client. The CheckMac command allows the device to securely store the secret in the host system and hides the correct response value from the pins, returning only a yes or no answer to the system.All hashing functions are implemented using the industry-standard SHA-256 secure hash algorithm, which is part of the latest set of high-security cryptographic algorithms recommended by various government agencies and cryptographic experts. The ATECC508A employs full-sized 256 bit secret keys to prevent any kind of exhaustive attack.2 Electrical Characteristics 2.1 Absolute Maximum Ratings*Operating Temperature .......................... -40°C to 85°C Storage Temperature ........................... -65°C to 150°C Maximum Operating Voltage................................. 6.0V DC Output Current ................................................ 5mA Voltage on any pin ...................... -0.5V to (V CC + 0.5V) *Notice: Stresses beyond those listed under “AbsoluteMaximum Ratings” may cause permanent damage tothe device. This is a stress rating only and functionaloperation of the device at these or any otherconditions beyond those indicated in the operationalsections of this specification are not implied.Exposure to absolute maximum rating conditions forextended periods may affect device reliability.2.2 ReliabilityThe ATECC508A is fabricated with the Atmel high reliability of the CMOS EEPROM manufacturing technology.Table 2-1. EEPROM Reliability2.3 AC Parameters: All I/O InterfacesFigure 2-1. AC Parameters: All I/O InterfacesNote: 1. These parameters are guaranteed through characterization, but not tested.ATECC508A [Summary Datasheet]Atmel-8923BS-CryptoAuth-ATECC508A-Datasheet-Summary_1020155 5ATECC508A [Summary Datasheet]Atmel-8923BS-CryptoAuth-ATECC508A-Datasheet-Summary_102015662.3.1AC Parameters: Single-Wire InterfaceTable 2-2.AC Parameters: Single-Wire InterfaceApplicable from T A = -40°C to +85°C, V CC = +2.0V to +5.5V, CL =100pF (unless otherwise noted).Note: 1.START, ZLO, ZHI, and BIT are designed to be compatible with a standard UART running at 230.4Kbaud for both transmit and receive. The UART should be set to seven data bits, no parity and one Stop bit.2.3.2 AC Parameters: I2C InterfaceTable 2-3. AC Characteristics of I2C InterfaceApplicable over recommended operating range from TA = -40°C to + 85°C, V CC = +2.0V to +5.5V, CL = 1 TTL Gate and 100pF (unless otherwise noted).Note: 1. Values are based on characterization and are not tested.AC measurement conditions:∙RL (connects between SDA and V CC): 1.2k (for V CC +2.0V to +5.0V)∙Input pulse voltages: 0.3V CC to 0.7V CC∙Input rise and fall times: ≤ 50ns∙Input and output timing reference voltage: 0.5V CCATECC508A [Summary Datasheet]Atmel-8923BS-CryptoAuth-ATECC508A-Datasheet-Summary_1020157 7ATECC508A [Summary Datasheet]Atmel-8923BS-CryptoAuth-ATECC508A-Datasheet-Summary_102015882.4DC Parameters: All I/O InterfacesTable 2-4. DC Parameters on All I/O Interfaces2.4.1V IH and V IL SpecificationsThe input voltage thresholds when in sleep or idle mode are dependent on the V CC level as shown in the graphbelow. When the device is active (i.e. not in sleep or idle mode), the input voltage thresholds are different depending upon the state of TTLenable (bit 1) within the ChipMode byte in the Configuration zone of theEEPROM. When a common voltage is used for the ATECC508A V CC pin and the input pull-up resistor, then this bit should be set to a one, which permits the input thresholds to track the supply.If the voltage supplied to the V CC pin of the ATECC508A is different than the system voltage to which the input pull-up resistor is connected, then the system designer may choose to set TTLenable to zero, which enables a fixed input threshold according to the following table. The following applies only when the device is active:Table 2-5. V IL , V IH on All I/O Interfaces3 Compatibility3.1 Atmel ATSHA204ATECC508A is fully compatible with the ATSHA204 and ATSHA204A devices. If properly configured, it can be used in all situations where the ATSHA204 or ATSHA204A is currently employed. Because the Configuration zone is larger, the personalization procedures for the device must be updated when personalizing theATSHA204 or ATSHA204A.3.2 Atmel ATECC108ATECC508A is designed to be fully compatible with the ATECC108 and ATECC108A devices. If properlyconfigured, can be used in all situations where ATECC108 is currently employed. In many situations, theATECC508A can also be used in an ATECC108 application without change. The new revisions providesignificant advantages as outlined below:New Features in ATECC108A vs. ATECC108∙Intrusion Detection Capability, Including Gating Key Use∙New SHA Command, Also Computes HMAC∙X.509 Certificate Verification Capability∙Programmable Watchdog Timer Length∙Programmable Power Reduction∙Shared Random Nonce and Key Configuration Validation (Gendig Command)∙Larger Slot 8 which is Extended to 416 bytes4 Ordering InformationNotes: 1. Please contact Atmel for availability.2. Please contact Atmel for thinner packages.ATECC508A [Summary Datasheet]Atmel-8923BS-CryptoAuth-ATECC508A-Datasheet-Summary_1020159 9ATECC508A [Summary Datasheet]Atmel-8923BS-CryptoAuth-ATECC508A-Datasheet-Summary_1020151105Package Drawings5.18-lead SOICATECC508A [Summary Datasheet]Atmel-8923BS-CryptoAuth-ATECC508A-Datasheet-Summary_10201511 115.2 8-pad UDFNATECC508A [Summary Datasheet]Atmel-8923BS-CryptoAuth-ATECC508A-Datasheet-Summary_1020151125.33-lead CONTACTATECC508A [Summary Datasheet]Atmel-8923BS-CryptoAuth-ATECC508A-Datasheet-Summary_10201513 136 Revision HistoryATECC508A [Summary Datasheet] Atmel-8923BS-CryptoAuth-ATECC508A-Datasheet-Summary_102015114Atmel Corporation 1600 Technology Drive, San Jose, CA 95110 USA T: (+1)(408) 441.0311 F: (+1)(408) 436.4200 │ © 2015 Atmel Corporation. / Rev.:Atmel-8923BS-CryptoAuth-ATECC508A-Datasheet-Summary_102015.Atmel ®, Atmel logo and combinations thereof, Enabling Unlimited Possibilities ®, CryptoAuthentication™, and others are registered trademarks or trademarks of Atmel Corporation in U.S. and other countries.DISCLAIMER: The information in this document is provided in connection with Atmel products. No license, express or implied, by estoppel or otherwise, to any intellectual property right is granted by this document or in connection with the sale of Atmel products. EXCEPT AS SET FORTH IN THE ATMEL TERMS AND COND ITIONS OF SALES LOCATED ON THE ATMEL WEBSITE, ATMEL ASSUMES NO LIABILITY WHATSOEVER AND DISCLAIMS ANY EXPRESS, IMPLIED OR STATUTORY WARRANTY RELATING TO ITS PRODUCTS INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTY OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, OR NON -INFRINGEMENT. IN NO EVENT SHALL ATMEL BE LIABLE FOR ANY DIRECT, INDIRECT, CONSEQUENTIAL, PUNITIVE, SPECIAL OR INCIDENTAL DAMAGES (INCLUDING, WITHOUT LIMITATION, DAMAG ES FOR LOSS AND PROFITS, BUSINESS INTERRUPTION, OR LOSS OF INFORMATION) ARISING OUT OF THE USE OR INABILITY TO USE THIS DOCUMENT , EVEN IF ATMEL HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES. Atmel makes no representations or warranties with respect to the accuracy or completeness of the contents of this document and reserves the right to make changes to specifications and products descriptions at any time without notice. Atmel does not make any commitment to update the information contained herein. Unless specifically provided otherwise, Atmel products are not suitable for, and shall not be used in, automotive applications. At mel products are not intended, authorized, or warranted for use as components in applications intended to support or sustain life.SAFETY-CRITICAL, MILITARY, AND AUTOMOTIVE APPLICATIONS DISCLAIMER: Atmel products are not designed for and will not be used in connection with any applications where the failure of such products would reasonably be expected to result in significant personal injury or death (“Safety -Critical Applications”) without an Atmel officer's specific written consent. Safety-Critical Applications include, without limitation, life support devices and systems, equipment or systems for the operation of nuclear fac ilities and weapons systems. Atmel products are not designed nor intended for use in military or aerospace applications or environments unless specifically designated by Atmel as military-grade. Atmel products are not designed nor intended for use in automotive applications unless specifically designated by Atmel as automotive -grade.。

DEVICE SPECIFICATIONSPXI-2576 SpecificationsMulti-Bank MultiplexerThis document lists specifications for the PXI-2576 multiplexer module. All specifications are subject to change without notice. Visit /manuals for the most current specifications. ContentsPXI-2576 Specifications (1)Topology (2)Input Characteristics (2)Dynamic Characteristics (3)Trigger Characteristics (4)Physical Characteristics (4)Environment (5)Shock and Vibration (5)Compliance and Certifications (6)Diagrams (7)Accessories (10)PXI-2576 SpecificationsSpecifications characterize the warranted performance of the instrument under the stated operating conditions. Data in this document are Specifications unless otherwise noted.Typical Specifications are specifications met by the majority of the instrument under the stated operating conditions and are tested at 23 °C ambient temperature. Typical specifications are not warranted.All voltages are specified in DC, AC pk, or a combination unless otherwise specified.Caution The protection provided by the PXI-2576 can be impaired if it is used in amanner not described in this document.TopologyRefer to the NI Switches Help at /manuals for detailed topology information. Topologies Independent2-wire sixteen 4 × 1 multiplexer2-wire octal 8 × 1 multiplexer2-wire quad 16 × 1 multiplexer2-wire dual 32 × 1 multiplexer2-wire 64 × 1 multiplexerInput CharacteristicsCaution This module is rated for Measurement Category I and intended to carrysignal voltages no greater than 100 V. This module can withstand up to 500 Vimpulse voltage. Do not use this module for connection to signals or formeasurements within Categories II, III, or IV.Caution When hazardous voltages (>42.4 Vpk/60 V DC) are present on anychannel, safety low-voltage (≤42.4 Vpk/60 V DC) cannot be connected to any otherchannel.Maximum switching voltageChannel-to-channel100 VChannel-to-ground100 V, Measurement Category I1 AMaximum current (per channel orcommon, switching or carry)Caution The switching power is limited by the maximum switching current andthe maximum voltage.Maximum switching power (per channel)30 W, 37.5 V ANote Switching inductive loads (for example, motors and solenoids) can producehigh voltage transients in excess of the module’s rated voltage. Without additionalprotection, these transients can interfere with module operation and impact relay life.For more information about transient suppression, visit /info and enter theInfo Code relayflyback.Maximum DC path resistance (channel-to-common)Initial<1.1 Ω (0.5 Ω, typical)End-of-life≥2 Ω2| | PXI-2576 SpecificationsPath resistance is a combination of relay contact resistance and trace resistance. Contact resistance typically remains low for the life of a relay. At the end of relay life, the contact resistance may rise rapidly above 1 Ω.Thermal EMF<10 μV, typicalMinimum switch load20 mV/1 mABandwidth50 Ω system4 × 1, 8 × 1 configurations>30 MHz, typical16 × 1 configuration>20 MHz, typical32 × 1 configuration>15 MHz, typical64 × 1 configuration>10 MHz, typical100 Ω system4 × 1, 8 × 1 configurations>60 MHz, typical16 × 1 configuration>40 MHz, typical32 × 1 configuration>20 MHz, typical64 × 1 configuration>10 MHz, typicalBank-to-bank crosstalk (50 Ω or 100 Ω system, 4 × 1 configuration)100 kHz<-75 dB, typical1 MHz<-53 dB, typical10 MHz<-35 dB, typicalOpen-channel isolation (50 Ω or 100 Ω system, 4 × 1 or 8 × 1 configuration) 100 kHz>79 dB, typical1 MHz>52 dB, typical10 MHz>40 dB, typicalDynamic CharacteristicsRelay operate time 2 ms, typical3.4 ms, maximumNote Certain applications may require additional time for proper settling. Refer tothe NI Switches Help at /manuals for more information about includingadditional settling time.Expected relay lifeMechanical 5 × 107 cycles, typicalPXI-2576 Specifications| © National Instruments| 3Electrical (resistive)30 V, 200 mA 2 × 106 cycles, typical30 V, 400 mA 5 × 105 cycles, typical30 V, 1 A 1 × 105 cycles, typical100 V, 100 mA 2 × 106 cycles, typical100 V, 200 mA 2.5 × 105 cycles, typical100 V, 300 mA 1 × 105 cycles, typicalNote Relays are field replaceable. Refer to the NI Switches Help at /manualsfor more information about replacing a failed relay.T rigger CharacteristicsInput triggerSources PXI trigger lines <0...7>Minimum pulse width150 nsNote The PXI-2576 can recognize trigger pulse widths less than 150 ns if youdisable digital filtering. For information about disabling digital filtering, refer to theNI Switches Help at /manuals.Output triggerDestinations PXI trigger lines <0...7>Pulse width Software-selectable: 1 μs to 62 μs Physical CharacteristicsCaution Clean the hardware with a soft, nonmetallic brush. Make sure that thehardware is completely dry and free from contaminants before returning it toservice.Relay type Electromechanical, latchingRelay contact material Silver, gold coveredI/O connector LFH matrix 50, 160 positions, malePXI power requirement 2.5 W at 3.3 V10 W at 5 VDimensions (L × W × H)3U, one slot, PXI/cPCI module,21.6 cm × 2.0 cm × 13.0 cm(8.5 in. × 0.8 in. × 5.1 in.)Weight300 g (12 oz)4| | PXI-2576 SpecificationsEnvironmentMaximum altitude2,000 m (at 25 °C ambient temperature) Pollution Degree2Indoor use only.Operating EnvironmentAmbient temperature range0 °C to 55 °C (Tested in accordance withIEC 60068-2-1 and IEC 60068-2-2.) Relative humidity range10% to 90%, noncondensing (Tested inaccordance with IEC 60068-2-56.) Storage EnvironmentAmbient temperature range-20 °C to 70 °C (Tested in accordancewith IEC 60068-2-1 and IEC 60068-2-2.) Relative humidity range5% to 95%, noncondensing (Tested inaccordance with IEC 60068-2-56.) Shock and VibrationOperational shock30 g peak, half-sine, 11 ms pulse (Tested inaccordance with IEC 60068-2-27. Test profiledeveloped in accordance withMIL-PRF-28800F.)Random vibrationOperating 5 Hz to 500 Hz, 0.31 g rms (Tested inaccordance with IEC 60068-2-64.) Nonoperating 5 Hz to 500 Hz, 2.46 g rms (Tested inaccordance with IEC 60068-2-64. Test profileexceeds the requirements of MIL-PRF-28800F,Class 3.)PXI-2576 Specifications| © National Instruments| 5Compliance and CertificationsSafetyThis 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•AS/NZS CISPR 11: Group 1, 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, refer to the Online ProductCertification 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.6| | PXI-2576 SpecificationsEnvironmental 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)。

SILICONMICROSTRUCTURES I N C O R P O R A T E DSM5812/SM5852Amplified Pressure Sensor• N OW WITH ACCESS TO D IGITAL T EMPERATURE AND C ORRECTED D IGITAL P RESSURE • L OW -COST , FULLY AMPLIFIED , CALIBRATED , AND COMPENSATED IN A SINGLE PACKAGE• A VAILABLE FOR D IFFERENTIAL , S INGLE -ENDED DIFFERENTIAL , G AGE & A BSOLUTE APPLICATIONS •M ULTIPLE PRESSURE RANGES AVAILABLE TO MEASURE PRESSURE DOWN TO 0.15 PSI FULL -SCALEAND UP TO 100 PSI FULL -SCALEDESCRIPTIONThe Silicon Microstructures SM5812 and SM5852 series of OEM pressure sensors combines state-of-the-art pressure sensor technology with CMOS digital signal processing technology to produce an amplified, fully conditioned, multi-order pressure and temperature compensated sensor in a dual in-line package (DIP) configuration.Combining the pressure sensor with acustom signal conditioning ASIC in a single package simplifies the use of advanced silicon micromachined pressure sensors. Now, the pressure sensor can be mounted directly to a standard printed circuit board and an amplified, high level, calibrated pressure signal can be acquired from the digital interface or analog output. This eliminates the need of additional circuitry, such as a compensation network or micro-controller containing a custom correction algorithm.The SM5812/SM5852 Series pressure sensors are based on SMI's highly stable, piezoresistive pressure sensor chips mounted on a ceramic substrate. An electronically programmable ASIC iscontained in the same package to provide calibration and temperature compensation.The model SM5812 is designed foroperating pressure ranges from 0-5 PSI up to 0-100 PSI. The model SM5852 isdesigned for operating pressure ranges from 0-0.15 PSI up to 0-3 PSI. For both models, the sensor output is ratiometric with the supply voltage.FEATURES• Amplified, calibrated, fully signalconditioned output span of 4.0 VDC FS (0.5 to 4.5 V signal)• Digital temperature and calibratedpressure available through I 2C interface • Output ratiometric with supply voltage • Multi-order correction for pressure non-linearity (factory programmed)• Multi-order correction for temperature coefficient of span and offset (factory programmed)• Gage, differential, and absolute versions •SMI’s unique low-pressure die allows for a full-scale pressure range of 0-0.15 PSITYPICAL APPLICATIONS• Barometric measurement • Medical instrumentation • Pneumatic control • Gas flow• Respirators and ventilators•Heating, Ventilation and Air Conditioning (HVAC)查询SM5812-005-A-3-L供应商SM5812/SM5852THEORY OF OPERATIONThe operation of the signal processor is depicted in the block diagram below. The external pressure sensor is a piezoresistive bridge. This transduces the applied pressure into an electronic signal, which is then inputted into the integrating amplifier of the ASIC. During the amplification step an offset correction factor is added in order to allow maximum gain for a given pressure while minimizing the offset error.The signal is then passed to an 11-bit analog to digital converter (ADC). The ADC samples the signal multiple times and uses the sum of those samples as a 13-bit word.A digital signal processor (DSP) is then used to correct and calibrate the pressure signal. The DSP provides multi-order correction of both pressure and temperature non-linearity through the use of factory-programmed coefficients. A combined total of twenty coefficients are available for correcting pressure and temperature non-linearity. The unique coefficients are determined during a calibration process performed at the factory. Factory calibration is the last step performed which means the effect of the package on the pressure signal will also be taken into account. This provides a great advantage over conventional laser-trimming approaches.The DSP outputs a corrected digital word, which travels to a 12-bit digital to analog converter (DAC) to provide a calibrated analog output. In addition to the analog output, the corrected pressure signal is accessible through an I2C digital interface. See SMI application note AN05-001 for a detailed description of how to read out the digital corrected pressure signal using theI2C bus interface.Analog OutputSDA SCLSILICONMICROSTRUCTURES I N C O R P O R A T E DSM5812/SM5852CHARACTERISTICS FOR SM5812/SM5852 – SPECIFICATIONSAll parameters are measured at room temperature while applying 5.000V supply, unless otherwise specified.Absolute 1, Gage & Single 2DifferentialMIN TYP MAX MIN TYP MAX UNITS NOTES Zero output (absolute and gauge) 0.42 0.50 0.58 V 3 Zero output (differential)2.422.502.58V3Output Span3.924.00 4.08 1.96 2.00 2.04 V FS 3, 40.15 PSI 3.80 4.00 4.20 1.90 2.00 2.10 V FS 3, 4 Linearity -0.5 +0.5 -0.5 +0.5 %FS 5 0.15 PSI-2.5+2.5-2.5+2.5%FS5 Pressure hysteresis 5812 -0.1 +0.1 -0.1 +0.1 %FS5852 -0.3+0.3 -0.3 +0.3 %FS Temperature coefficient - Zero-1.0 +1.0 -1.0 +1.0 %FS 0.15 PSI-2.5 +2.5 -2.5 +2.5 %FS Temperature coefficient – Span-1.0 +1.0 -1.0 +1.0 %FS 0.15 PSI-2.0 +2.0 -2.0 +2.0 %FS Thermal hysteresis -0.1 +0.1 -0.1 +0.1 %FS Response Time 2 2 msec Supply voltage 4.75 5.00 5.25 4.75 5.00 5.25 V 3, 7Current consumption10 10 mAOverpressure 5812 3X 3X %FS 65852 15X15X %FS 6 Operating temperature range -40 25 +125 -40 25 +125 °C Compensated temperature range 0 25 +70 0 25 +70 °CStorage temperature range -5525+135-5525+135°CMedia compatibility 8Weight 3 3 gramNotes: 1. Absolute parts are only offered in the SM5812 Series.2. Single-ended parts (Pressure Type - S) have 2 ports and are for higher gain differential applications where the differential pressure is always positive.3. Sensor output is ratiometric to supply.4.Full-scale (FS) is defined as zero pressure to rated pressure; differential parts can be used ±FS. Absolute and Gauge zero output is 0.5 V typical and full-scale output is 4.5 V. Span is the difference between Full-scale output and zero output, (4 V). For Differential parts, the negative full-scale is typically at 0.5 V, zero is typically 2.5 V, and positive full-scale is 4.5 volts to give a span of ±2.0 V.5. Defined as best fit straight line for positive pressure applied to the part6. Or 225 PSI, whichever is less. Output amplifier will saturate at about 0.25 V for applied pressure below the rated Zero and at about 4.75 V for applied pressure above the rated Full-scale.7. A 100 nF filter capacitor must be placed between Vsupply and Ground.8.Clean, dry gas compatible with wetted materials. Wetted materials include Pyrex glass, silicon, alumina ceramic, epoxy, RTV, gold, aluminum, and nickel.SM5812/SM5852ADDITIONAL INFORMATIONFull-Scale Pressure RangesSM5812 PSI [kPa] SM5852 PSI [kPa]005 5 [34.5] 001 0.15 [1.0] 015 15 [103.4]003 0.30 [2.1] 030 30 [206.8]008 0.80 [5.5] 060 60 [413.7]015 1.50 [10.3] 100 100[689.5]030 3.00 [20.7]。