MAX1034
美信芯片中文数据资料
iButton 1024位EEPROM
DS1982
iButton 1K位只添加
DS1990A
iButton序列号
DS1990R, DS1990R-F3, DS1990R-F5
序列号iButton
DS1991
iButton多密钥
DS2129
LVD SCSI 27线调节器
DS2401
硅序列号
具有以太网和CAN接口的网络微控制器
DS8102
双通道Σ-Δ调制器与编码器
DS8113
智能卡接口
DS8113-KIT
DS8113 EMV评估板
DS8313, DS8314
智能卡接口
DS89C430, DS89C440, DS89C450
超高速闪存微控制器
DS89C450-KIT
DS89C450评估套件
12位、多通道ADC/DAC,带有FIFO、温度传感器和GPIO端口
MAX1224, MAX1225
1.5Msps、单电源、低功耗、真差分、12位ADC
MAX1258EVC16, MAX1258EVKIT
MAX1057、MAX1058、MAX1257和MAX1258评估板/评估系统
MAX1274, MAX1275
MAX1034, MAX1035
8/4通道、±VREF多量程输入、串行14位ADC
MAX1072, MAX1075
1.8Msps、单电源、低功耗、真差分、10位ADC
MAX1076, MAX1078
1.8Msps、单电源、低功耗、真差分、10位ADC,内置电压基准
MAX11014, MAX11015
DS9490B, DS9490R
TC-MAX智能电动车使用说明书
电动两轮摩托车使用说明书下载APPTC-MAX 智能电动车具有无线通讯,GPS 定位等功能,可与您的智能手机连接。
通过速珂电动车APP ,您可以使用手机对车辆进行管理,查询等操作。
目前提供 iOS 与 Android 系统两个版本,安装前请先确认智能手机操作系统规格。
iOS 系统:App 支持Apple iOS 9.0及以上版本。
Android 系统:App 支持Android 4.4及以上版本。
绑定车辆及下载APP请识别封底二维码速珂电动车SOCO APP046参数须知 PARAMETER TABLE主要技术参数及性能指标 TC MAX 整车主要技术参数 (参数表仅供参考)主要技术参数电动机主要技术参数蓄电池主要技术参数电气系统主要技术参数长x宽x高(mm)轴距(mm)承载人数(含驾驶员)(人)额定载质量(Kg)前伸角(°)轮胎规格最高设计车速(km/h)爬坡角度(°)离地间隙(mm)前轮轴的轴荷(kg)后轮轴的轴荷(kg)过流保护值(A)欠压保护值(A)总重型号前轮后轮1963x735x1034134421502685≥10°1855252655810486168254整车整备质量型号电动机型式额定连续输出功率(W)额定转速(r/min)额定输出扭矩(N.m)总电压(V)总容量(Ah)前照灯规格前位灯仪表灯规格转向信号灯规格类型规格制动灯/后位灯规格16ZW-J7226413NA永磁35002600137245LEDLEDLEDLED锂电72V45AhLED厂定最大重质量ZWK072065A120/70-17主要质量参数控制器主要技术参数90/80-17充电器主要技术参数电压电流型号72V10A72V10A7零部件说明操作指南骑行指南电池使用说明APP使用说明保养维护常见问题售后服务09 14 19 22 25 26 27 32目录CONTENTS8零部件说明DESCRIPTION OF COMPONENTS AND PARTS网轮版铝轮版9132按住喇叭发出鸣响,放开则停止。
Motorola 3.5 kHz 产品说明书
RVN4126 3.59100-386-9100-386/T DEVICERVN41772-CD2-3.5MCS/MTSRVN41821-CD2-3.5XTS3000/SABER PORTABLE YES RKN4046KHVN9085 3.51-20 R NO HLN9359 PROG. STAND RVN4057 3.532 X 8 CODEPLUG NO3080385B23 & 5880385B30 MDVN4965 3.59100-WS/T CONFIG KITRVN4053 3.5ASTRO DIGITAL INTERFACE NO3080385B23RVN41842-CD RKN4046A (Portable) 2-3.5ASTRO PORTABLE /MOBILE YES3080369B73 or0180300B10 (Mobile) RVN41831-CD3080369B732-3.5ASTRO SPECTRA MOBILE YES(Low / Mid Power)0180300B10 (High Power) RVN4185CD ASTRO SPECTRA PLUS MOBILE NO MANY OPTIONS; SEESERVICE BRIEF#SB-MO-0101RVN4186CD ASTRO SPECTRA PLUS MANY OPTIONS;MOBILE/PORTABLE COMB SEE SERVICE BRIEF#SB-MO-0101RVN4154 3.5ASTROTAC 3000 COMPAR.3080385B23RVN5003 3.5ASTROTAC COMPARATORS NO3080399E31 Adpt.5880385B34RVN4083 3.5BSC II NO FKN5836ARVN4171 3.5C200RVN4029 3.5CENTRACOM SERIES II NO VARIOUS-SEE MANUAL6881121E49RVN4112 3.5COMMAND PLUS NORVN4149 3.5COMTEGRA YES3082056X02HVN6053CD CT250, 450, 450LS YES AAPMKN4004RVN4079 3.5DESKTRAC CONVENTIONAL YES3080070N01RVN4093 3.5DESKTRAC TRUNKED YES3080070N01RVN4091 3.5DGT 9000 DESKSET YES0180358A22RVN4114 3.5GLOBAL POSITIONING SYS.NO RKN4021AHVN8177 3.5GM/GR300/GR500/GR400M10/M120/130YES3080070N01RVN4159 3.5GP60 SERIES YES PMLN4074AHVN9128 3.5GP300 & GP350RVN4152 3.5GP350 AVSRVN4150 3.5GTX YES HKN9857 (Portable)3080070N01(Mobile) HVN9025CD HT CDM/MTX/EX SERIES YES AARKN4083/AARKN4081RiblessAARKN4075RIBLESS NON-USA RKN4074RVN4098H 3.5HT1000/JT1000-VISAR YES3080371E46(VISAR CONV)RVN4151 3.5HT1000 AVSRVN4098 3.5HT1000/ VISAR CONV’L.YES RKN4035B (HT1000) HVN9084 3.5i750YES HLN-9102ARVN4156 3.5LCS/LTS 2000YES HKN9857(Portable)3080070N01(Mobile) RVN4087 3.5LORAN C LOC. RECV’R.NO RKN4021ARVN4135 3.5M100/M200,M110,M400,R100 includesHVN9173,9177,9646,9774YES3080070N01RVN4023 3.5MARATRAC YES3080070N01RVN4019 3.5MAXTRAC CONVENTIONAL YES3080070N01RVN4139 3.5MAXTRAC LS YES3080070N01RVN4043 3.5MAXTRAC TRK DUPLEX YES3080070N01RVN4178CD MC SERIES, MC2000/2500DDN6124AW/DB25 CONNECTORDDN6367AW/DB9 CONNECTOR RVN41751-CD Rib to MIC connector 1-3.5MCS2000 RKN4062BRVN41131-3.5MCS2000RVN4011 3.5MCX1000YES3000056M01RVN4063 3.5MCX1000 MARINE YES3000056M01RVN4117 3.5MDC/RDLAP DEVICESRVN4105 3.5MOBILE PROG. TOOLRVN4119 3.5MOBITEX DEVICESRVN4128 3.5MPT1327-1200 SERIES YES SEE MANUALRVN4025 3.5MSF5000/PURC/ANALOG YES0180355A30RVN4077 3.5MSF5000/10000FLD YES0180355A30RVN4017K 3.5MT 1000YES RTK4205CRVN4148 3.5MTR 2000YES3082056X02RVN4140 3.5MTRI 2000NORVN41761-CD MTS2000, MT2000*, MTX8000, MTX90001-3.5*programmed by DOS which is included in the RVN4176RVN4131 3.5MTVA CODE PLUG FIXRVN4142 3.5MTVA DOCTOR YES3080070N01RVN4131 3.5MTVA3.EXERVN4013 3.5MTX800 & MTX800S YES RTK4205CRVN4097 1-CD MTX8000/MTX9000,MTS2000,MT2000*,* programmed by DOS which is included in the RVN4176HVN9067CD MTX850/MTX8250MTX950,MTX925RVN4138 3.5MTX-LS YES RKN4035DRVN4035 3.5MX 1000YES RTK4203CRVN4073 3.5MX 800YES RKN4006BHVN9395 P100, P200 LB, P50+, P210, P500, PR3000RVN4134 3.5P100 (HVN9175)P200 LB (HVN9794)P50+ (HVN9395)P210 (HVN9763)P500 (HVN9941)PR3000 (HVN9586)YES RTK4205HVN9852 3.5P110YES HKN9755A/REX1143 HVN9262 3.5P200 UHF/VHF YES RTK4205RVN4129 3.5PDT220YVN4051 3.5PORTABLE REPEATER Portable rptr.P1820/P1821AXRVN4061C 3.5PP 1000/500NO3080385B23 & 5880385B30 RVN5002 3.5QUANTAR/QUANTRO NO3O80369E31RVN4135 3.5R100 (HVN9177)M100/M200/M110/M400YES0180358A52RVN4146 3.5RPM500/660RVN4002 3.5SABER YES RTK4203CRVN4131 3.5SETTLET.EXEHVN9007 3.5SM50 & SM120YESRVN4039 3.5SMART STATUS YES FKN5825AHVN9054 3.5SOFTWARE R03.2 P1225YES3080070N01HVN9001 3.5SOFTWARE R05.00.00 1225LS YES HLN9359AHVN9012 3.5SP50RVN4001N 3.5SPECTRA YES3080369B73 (STANDARD)0180300B10 (HIGH POWER) RVN4099 3.5SPECTRA RAILROAD YES3080369B73RVN4110 3.5STATION ACCESS MODULE NO3080369E31RVN4089A 3.5STX TRANSIT YES0180357A54RVN4051 3.5SYSTEMS SABER YES RTK4203BRVN4075 3.5T5600/T5620 SERIES NO3080385B23HVN9060CD TC3000, TS3000, TR3000RVN4123 3.5VISAR PRIVACY PLUS YES3080371E46FVN4333 3.5VRM 100 TOOLBOX FKN4486A CABLE &ADAPTORRVN4133 3.5VRM 500/600/650/850NORVN4181CD XTS 2500/5000 PORTABLES RKN4105A/RKN4106A RVN41002- 3.5XTS3000 ASTRO PORTABLE/MOBILERVN4170 3.5XTS3500YES RKN4035DRIB SET UPRLN4008E RADIO INTERFACE BOX (RIB)0180357A57RIB AC POWER PACK 120V0180358A56RIB AC POWER PACK 220V3080369B71IBM TO RIB CABLE (25 PIN) (USE WITH XT & PS2)3080369B72IBM TO RIB CABLE (9 PIN)RLN443825 PIN (F) TO 9 PIN (M) ADAPTOR (USE W/3080369B72 FOR AT APPLICATION) 5880385B308 PIN MODULAR TO 25 PIN ”D” ADAPTOR (FOR T5600 ONLY)0180359A29DUPLEX ADAPTOR (MOSTAR/TRAXAR TRNK’D ONLY)Item Disk Radio RIB Cable Number Size Product Required Number Item Disk Radio RIB Cable Number Size Product Required NumberUtilizing your personal computer, Radio Service Software (RSS)/Customer Programming Software (CPS)/CustomerConfiguration Software (CCS) enables you to add or reprogram features/parameters as your requirements change. RSS/CPS/CCS is compatible with IBM XT, AT, PS/2 models 30, 50, 60 and 80.Requires 640K RAM. DOS 3.1 or later. Consult the RSS users guide for the computer configuration and DOS requirements. (ForHT1000, MT/MTS2000, MTX838/8000/9000, Visar and some newer products —IBM model 386, 4 MEG RAM and DOS 5.0 or higher are recommended.) A Radio Interface Box (RIB) may be required as well as the appropriate cables. The RIB and cables must be ordered separately.Licensing:A license is required before a software (RVN) order is placed. The software license is site specific (customer number and ultimate destination tag). All sites/locations must purchase their own software.Be sure to place subsequent orders using the original customer number and ship-to-tag or other licensed sites; ordering software without a licensed customer number and ultimate tag may result in unnecessary delays. To obtain a no charge license agreement kit, order RPX4719. To place an order in the U.S. call 1-800-422-4210. Outside the U.S., FAX 847-576-3023.Subscription Program:The purchase of Radio ServiceSoftware/Customer Programming/Customer ConfigurationSoftware (RVN & HVN kits) entitles the buyer/subscriber to three years of free upgrades. At the end of these three years, the sub-scriber must purchase the same Radio Service Software kit to receive an additional three years of free upgrades. If the sub-scriber does not elect to purchase the same Radio Service Software kit, no upgrades will be sent. Annually a subscription status report is mailed to inform subscribers of the RSS/CPS/CCS items on our database and their expiration dates.Notes:1)A subscription service is offered on “RVN”-Radio Service Software/Customer Programming/Customer Configuration Software kits only.2)“RVN” software must only be procured through Radio Products and Services Division (RPSD). Software not procured through the RPSD will not be recorded on the subscription database; upgrades will not be mailed.3)Upgrades are mailed to the original buyer (customer number & ultimate tag).4)SP software is available through the radio product groups.The Motorola General Radio Service Software Agreement is now available on Motorola Online. If you need assistance please feel free to submit a “Contact Us” or call 800-422-4210.SMART RIB SET UPRLN1015D SMART RIB0180302E27 AC POWER PACK 120V 2580373E86 AC POWER PACK 220V3080390B49SMARTRIB CABLE (9 PIN (F) TO 9 PIN (M) (USE WITH AT)3080390B48SMARTRIB CABLE (25 PIN (F) TO 9 PIN (M) (USE WITH XT)RLN4488ASMART RIB BATTERY PACKWIRELESS DATA GROUP PRODUTS SOFTWARERVN4126 3.59100-386/9100T DEVICES MDVN4965 3.59100-WS/T CONFIG’TN RVN41173.5MDC/RDLAP DEVICESPAGING PRODUCTS MANUALS6881011B54 3.5ADVISOR6881029B90 3.5ADVISOR ELITE 6881023B20 3.5ADVISOR GOLD 6881020B35 3.5ADVISOR PRO FLX 6881032B30 3.5BR8506881032B30 3.5LS3506881032B30 3.5LS5506881032B30 3.5LS7506881033B10 3.5LS9506881035B20 3.5MINITOR III8262947A15 3.5PAGEWRITER 20008262947A15 3.5PAGEWRITER 2000X 6881028B10 3.5TALKABOUT T3406881029B35 3.5TIMEPORT P7308262947A15 3.5TIMEPORT P930NLN3548BUNIVERSAL INTERFACE KITItem Disk Radio NumberSize Product。
贴片F系列三极管参数
Base I I N C N N X K N N D N N N N N B N N N N N N N N X N N N N N N N N N N N B P X P ZB X ZB
Package SCD80 URD SOT323 SOT23 SC59 SC59 SOT23 SOT23 SOT23 SOT23 SOT23 SOT23 SOT23 SOT23 SOT23 SOT323 SC59 SC59 SOT23 SC59 SC59 SC59 SC59 SOT23 SC59 SC59 SOT23 SC59 SC59 SC59 SC59 SC59 SOT23 SOT89 SOT89 SOT23 SOT23
Leaded Equivalent/Data uhf varicap 2.5-22pf npn RF fT 8GHz 35V RF pin sw diode npn dtr R1 2k2 40V 100mA npn dtr R1 4k7 40V 100mA fT 12GHz npn RF 4V 12mA 35V RF pin sw diode BF495 RF npn fT 150MHz hfe30-60 dual series HP3820 pin sw diode BF184 BF494 BF184 BF494 BF184 BF494 RF npn fT150MHz hfe60-120 BF495 dual cc HP3820 pin sw diode BF184 BF494 pnp dtr 1k + 1k 50V 500mA pnp dtr 2k2 + 2k2 50V 500mA pnp dtr 4k7+ 4k7 50V 500mA pnp dtr 4k7+ 4k7 50V 500mA pnp dtr 10k + 10k 50V 500mA fT 12GHz npn 6V 20mA npn dtr 1k + 1k 50V 500mA npn dtr 2k2 + 2k2 50V 500mA npn dtr 4k7 + 4k7 50V 500mA npn dtr 4k7 + 4k7 50V 500mA npn dtr 10k + 10k 50V 500mA pnp dtr 2k2 + 10k 50V 100mA pnp dtr 2k2 + 10k 50V 100mA npn dtr 2k2 + 10k 50V 100mA pnp dtr R1 2k2 40V 100mA pnp dtr R1 4k7 40V 100mA pnp dtr R110k 40V 100mA 0.5-3GHz cc pin dual anode npn RF 1.5GHz 300mA BFQ69 npn RF Ft 5.5GHz 100mA microproc -ve reset gen 2.700V BFW92 microproc -ve reset gen 2.800V
保险丝基础知识
"保险丝"基础知识1定义当电路发生故障或异常时,伴随着电流不断升高,并且升高的电流有可能损坏电路中的某些重要器件或贵重器件,也有可能烧毁电路甚至造成火灾。
若电路中正确地安置了保险丝,那么玻璃保险丝管VICFUSE,保险丝就会在电流异常升高到一定的高度和热度的时候,自身熔断切断电流,从而起到保护电路安全运行的作用。
2介绍外形1、条丝状。
早期原始型态的保险丝,直接以锁定,用于各种尺寸的旧式开关、。
车用片状保险丝VICFUSE2、片状(裸片状)。
比旧式丝状方便使用。
3、玻璃管状。
有几种不同尺寸,常见于电子产品。
x 32 mm (直径 x 长度)5 x 20 mm4、陶瓷管状。
有几种不同形状及尺寸,可避免玻璃爆裂。
5、塑胶片状带金属片状接脚:汽车保险丝。
6、表面接着元件(SMD)型7、圆柱体状,插件式:直接焊接于电路板上,用于产品内部。
标志标志大多数保险丝的标记在身上或端盖与标记,指示其评级。
但是“芯片类型”保险丝功能很少或没有标记,使识别非常困难。
保险丝可能出现类似的显著不同的特性,确定了它们的标记。
保险丝标记通常会传达以下信息:安培的保险丝的额定电压等级的保险丝时间 - 电流特性,即速度保险丝批准由国家和机构制造商 / 产品编号 /系列中断能力作用一百多年前由爱迪生发明的用于保护当时昂贵的白炽灯,随着时代的发展,保险丝保护电子/电力设备不受过电流/过热的伤害,避免电子设备因内部故障所引起的严重伤害。
[1]工作原理当电流流过导体时,因导体存在一定的电阻,所以将会发热。
且发遵循着这个公式:Q=;其中Q是发热量,是一个常数,I是流过导体的电流,R是导体的电阻,T是电流流过导体的时间;依此公式我们不难看出保险丝的简单的工作原理了。
一种保险丝当制作保险丝的材料及其形状确定了,其R就相对确定了(若不考虑它的电阻系数)。
当电流流过它时,它就会发热,随着的增加其发热量也在增加。
电流与电阻的大小确定了产生热量的速度,保险丝的构造与其安装的状况确定了热量耗散的速度,若产生热量的速度小于耗散的速度时,保险丝是不会熔断的。
MAX17043G+T;MAX17044G+T;MAX17043G+U;中文规格书,Datasheet资料
VIL
(Note 1)
VOL VOL-ALRT
IPD CBUS tSLEEP tTRAN
IOL = 4mA (Note 1) IOL-ALRT = 2mA (Note 1) VDD = 4.5V, VPIN = 0.4V
(Note 3) (Note 4)
0.2 1.75
1
at 1-888-629-4642, or visit Maxim’s website at .
/
MAX17043/MAX17044
Compact, Low-Cost 1S/2S Fuel Gauges with Low-Battery Alert
Storage Temperature Range (TA = 0°C to +70°C (Note 10))........................-55°C to +125°C
Lead Temperature (TDFN soldering only, 10s) ...............+300°C Soldering Temperature (reflow) .......................................+260°C
VIH
(Note 1)
MIN
-1 -2 -3 -12.5 -30 -30 -60 15 1.4
TYP 50 0.5 1
Input Logic-Low: SCL, SDA, QSTRT
Output Logic-Low: SDA Output Logic-Low: ALRT Pulldown Current: SCL, SDA Input Capacitance: SCL, SDA Bus Low Timeout Mode Transition
TI常用运放芯片型号
CA3130?高输入阻抗运算放大器?Intersil[DA TA]CA3140?高输入阻抗运算放大器CD4573?四可编程运算放大器?MC14573ICL7650?斩波稳零放大器LF347(NS[DA TA])?带宽四运算放大器?KA347LF351?BI-FET单运算放大器?NS[DA TA]LF353?BI-FET双运算放大器?NS[DA TA]LF356?BI-FET单运算放大器?NS[DA TA]LF357?BI-FET单运算放大器?NS[DA TA]LF398?采样保持放大器?NS[DA TA]LF411?BI-FET单运算放大器?NS[DA TA]LF412?BI-FET双运放大器?NS[DATA]LM124?低功耗四运算放大器(军用档)?NS[DA TA]/TI[DATA] LM1458?双运算放大器?NS[DA TA]LM148?四运算放大器?NS[DA TA]LM224J?低功耗四运算放大器(工业档)?NS[DA TA]/TI[DATA] LM2902?四运算放大器?NS[DA TA]/TI[DA TA]LM2904?双运放大器?NS[DA TA]/TI[DA TA]LM301?运算放大器?NS[DA TA]LM308?运算放大器?NS[DA TA]LM308H?运算放大器(金属封装)?NS[DA TA]LM318?高速运算放大器?NS[DATA]LM324(NS[DA TA])?四运算放大器?HA17324,/LM324N(TI)LM348?四运算放大器?NS[DA TA]LM358?NS[DA TA]?通用型双运算放大器?HA17358/LM358P(TI) LM380?音频功率放大器?NS[DATA]LM386-1?NS[DA TA]?音频放大器?NJM386D,UTC386LM386-3?音频放大器?NS[DA TA]LM386-4?音频放大器?NS[DA TA]LM3886?音频大功率放大器?NS[DA TA]LM3900?四运算放大器LM725?高精度运算放大器?NS[DATA]LM733?带宽运算放大器LM741?NS[DA TA]?通用型运算放大器?HA17741MC34119?小功率音频放大器NE5532?高速低噪声双运算放大器?TI[DATA]NE5534?高速低噪声单运算放大器?TI[DATA]NE592?视频放大器OP07-CP?精密运算放大器?TI[DATA]OP07-DP?精密运算放大器?TI[DATA]TBA820M?小功率音频放大器?ST[DA TA]TL061?BI-FET单运算放大器?TI[DA TA]TL062?BI-FET双运算放大器?TI[DA TA]TL064?BI-FET四运算放大器?TI[DA TA]TL072?BI-FET双运算放大器?TI[DA TA]TL074?BI-FET四运算放大器?TI[DA TA]TL081?BI-FET单运算放大器?TI[DA TA]TL082?BI-FET双运算放大器?TI[DA TA]TL084?BI-FET四运算放大器?TI[DA TA]AD824?JFET输入,单电源,低电压,低功耗,精密四运算放大器?MC33171?单电源,低电压,低功耗运算放大器AD826?低功耗,宽带,高速双运算放大器?MC33172?单电源,低电压,低功耗双运算放大器AD827?低功耗,高速双运算放大器?MC33174?单电源,低电压,低功耗四运算放大器AD828?低功耗,宽带,高速双运算放大器?MC33178?大电流,低功耗,低噪音双运算放大器AD844?电流反馈型,宽带,高速运算放大器?MC33179?大电流,低功耗,低噪音四运算放大器AD846?电流反馈型,高速,精密运算放大器?MC33181?JFET输入,低功耗运算放大器AD847?低功耗,高速运算放大器?MC33182?JFET输入,低功耗双运算放大器AD8531?COMS单电源,低功耗,高速运算放大器?MC33184?JFET输入,低功耗四运算放大器AD8532?COMS单电源,低功耗,高速双运算放大器?MC33201?单电源,大电流,低电压运算放大器AD8534?COMS单电源,低功耗,高速四运算放大器?MC33202?单电源,大电流,低电压双运算放大器AD9617?低失真,电流反馈型,宽带,高速,精密运算放大器?MC33204?单电源,大电流,低电压四运算放大器AD9631?低失真,宽带,高速运算放大器?MC33272?单电源,低电压,高速双运算放大器AD9632?低失真,宽带,高速运算放大器?MC33274?单电源,低电压,高速四运算放大器AN6550?低电压双运算放大器?MC33282?JFET输入,宽带,高速双运算放大器AN6567?大电流,单电源双运算放大器?MC33284?JFET输入,宽带,高速四运算放大器AN6568?大电流,单电源双运算放大器?MC33502?BIMOS,单电源,大电流,低电压,双运算放大器BA718?单电源,低功耗双运算放大器?MC34071A?单电源,高速运算放大器BA728?单电源,低功耗双运算放大器?MC34072A?单电源,高速双运算放大器CA5160?BIMOS,单电源,低功耗运算放大器?MC34074A?单电源,高速四运算放大器CA5260?BIMOS,单电源双运算放大器?MC34081?JFET输入,宽带,高速运算放大器CA5420?BIMOS,单电源,低电压,低功耗运算放大器?MC34082?JFET输入,宽带,高速双运算放大器CA5470?BIMOS单电源四运算放大器?MC34084?JFET输入,宽带,高速四运算放大器CLC400?电流反馈型,宽带,高速运算放大器?MC34181?JFET输入,低功耗运算放大器CLC406?电流反馈型,低功耗,宽带,高速运算放大器?MC34182?JFET输入,低功耗双运算放大器CLC410?电流反馈型,高速运算放大器?MC34184?JFET输入,低功耗四运算放大器CLC415?电流反馈型,宽带,高速四运算放大器?MC35071A?单电源,高速运算放大器CLC449?电流反馈型,宽带,高速运算放大器?MC35072A?单电源,高速双运算放大器CLC450?电流反馈型,单电源,低功耗,宽带,高速运算放大器?MC35074A?单电源,高速四运算放大器CLC452?单电源,电流反馈型,大电流,低功耗,宽带,高速运算放大器?MC35081?JFET输入,宽带,高速运算放大器CLC505?电流反馈型,高速运算放大器?MC35082?JFET输入,宽带,高速双运算放大器EL2030?电流反馈型,宽带,高速运算放大器?MC35084?JFET输入,宽带,高速四运算放大器EL2030C?电流反馈型,宽带,高速运算放大器?MC35171?单电源,低电压,低功耗运算放大器EL2044C?单电源,低功耗,高速运算放大器?MC35172?单电源,低电压,低功耗双运算放大器EL2070?电流反馈型,宽带,高速运算放大器?MC35174?单电源,低电压,低功耗四运算放大器EL2070C?电流反馈型,宽带,高速运算放大器?MC35181?JFET输入,低功耗运算放大器EL2071C?电流反馈型,宽带,高速运算放大器?MC35182?JFET输入,低功耗双运算放大器EL2073?宽带,高速运算放大器?MC35184?JFET输入,低功耗四运算放大器EL2073C?宽带,高速运算放大器?MM6558?低电压,低失调电压,精密双运算放大器EL2130C?电流反馈型,宽带,高速运算放大器?MM6559?低电压,低失调电压,精密双运算放大器EL2150C?单电源,宽带,高速运算放大器?MM6560?低电压,低失调电压,精密双运算放大器EL2160C?电流反馈型,宽带,高速运算放大器?MM6561?低功耗,低电压,低失调电压,精密双运算放大器EL2165C?电流反馈型,宽带,高速,精密运算放大器?MM6564?单电源,低电压,低功耗,低失调电压,精密双运算放大器EL2170C?单电源,电流反馈型,低功耗,宽带,高速运算放大器?MM6572?低噪音,低电压,低失调电压,精密双运算放大器EL2175C?电流反馈型,宽带,高速,精密运算放大器?NE5230?单电源,低电压运算放大器EL2180C?单电源,电流反馈型,低功耗,宽带,高速运算放大器?NE5512?通用双运算放大器EL2224?宽带,高速双运算放大器?NE5514?通用四运算放大器EL2224C?宽带,高速双运算放大器?NE5532?低噪音,高速双运算放大器EL2232?电流反馈型,宽带,高速双运算放大器?NE5534?低噪音,高速运算放大器EL2232C?电流反馈型,宽带,高速双运算放大器?NJM2059?通用四运算放大器EL2250C?单电源,宽带,高速双运算放大器?NJM2082?JFET输入,高速双运算放大器EL2260C?电流反馈型,宽带,高速双运算放大器?NJM2107?低电压,通用运算放大器EL2270C?单电源,电流反馈型,低功耗,宽带,高速双运算放大器?NJM2112?低电压,通用四运算放大器EL2280C?单电源,电流反馈型,低功耗,宽带,高速双运算放大器?NJM2114?低噪音双运算放大器EL2424?宽带,高速四运算放大器?NJM2115?低电压,通用双运算放大器EL2424C?宽带,高速四运算放大器?NJM2119?单电源,精密双运算放大器EL2444C?单电源,低功耗,高速四运算放大器?NJM2122?低电压,低噪音双运算放大器EL2450C?单电源,宽带,高速四运算放大器?NJM2130F?低功耗运算放大器EL2460C?电流反馈型,宽带,高速四运算放大器?NJM2132?单电源,低电压,低功耗双运算放大器EL2470C?单电源,电流反馈型,低功耗,宽带,高速四运算放大器?NJM2136?低电压,低功耗,宽带,高速运算放大器EL2480C?单电源,电流反馈型,低功耗,宽带,高速四运算放大器?NJM2137?低电压,低功耗,宽带,高速双运算放大器HA-2640?高耐压运算放大器?NJM2138?低电压,低功耗,宽带,高速四运算放大器HA-2645?高耐压运算放大器?NJM2140?低电压双运算放大器HA-2839?宽带,高速运算放大器?NJM2141?大电流,低电压双运算放大器HA-2840?宽带,高速运算放大器?NJM2147?高耐压,低功耗双运算放大器HA-2841?宽带,高速运算放大器?NJM2162?JFET输入,低功耗,高速双运算放大器HA-2842?宽带,高速运算放大器?NJM2164?JFET输入,低功耗,高速四运算放大器HA-4741?通用四运算放大器?NJM3404A?单电源,通用双运算放大器HA-5020?电流反馈型,宽带,高速运算放大器?NJM3414?单电源,大电流双运算放大器HA-5127?低噪音,低失调电压,精密运算放大器?NJM3415?单电源,大电流双运算放大器HA-5134?低失调电压,精密四运算放大器?NJM3416?单电源,大电流双运算放大器HA-5137?低噪音,低失调电压,高速,精密运算放大器?NJM4556A?大电流双运算放大器HA-5142?单电源,低功耗双运算放大器?NJM4580?低噪音双运算放大器HA-5144?单电源,低功耗四运算放大器?NJU7051?CMOS单电源,低功耗,低电压,低失调电压运算放大器HA-5177?低失调电压,精密运算放大器?NJU7052?CMOS单电源,低功耗,低电压,低失调电压双运算放大器HA-5221?低噪音,精密运算放大器?NJU7054?CMOS单电源,低功耗,低电压,低失调电压四运算放大器HA-5222?低噪音,精密双运算放大器?NJU7061?CMOS单电源,低功耗,低电压,低失调电压运算放大器HA-7712?BIMOS,单电源,低功耗,精密运算放大器?NJU7062?CMOS单电源,低功耗,低电压,低失调电压双运算放大器HA-7713?BIMOS,单电源,低功耗,精密运算放大器?NJU7064?CMOS单电源,低功耗,低电压,低失调电压四运算放大器HA16118?CMOS单电源,低电压,低功耗双运算放大器?NJU7071?CMOS单电源,低功耗,低电压,低失调电压运算放大器AD704?低偏置电流,低功耗,低失调电压,精密四运算放大器?MAX430?CMOS单电源运算放大器AD705?低偏置电流,低功耗,低失调电压,精密运算放大器?MAX432?CMOS单电源运算放大器AD706?低偏置电流,低功耗,低失调电压,精密双运算放大器?MAX4330?单电源,低电压,低功耗运算放大器AD707?低失调电压,精密运算放大器?MAX4332?单电源,低电压,低功耗双运算放大器AD708?低失调电压,精密双运算放大器?MAX4334?单电源,低电压,低功耗四运算放大器AD711?JFET输入,高速,精密运算放大器?MAX473?单电源,低电压,宽带,高速运算放大器AD712?JFET输入,高速,精密双运算放大器?MAX474?单电源,低电压,宽带,高速双运算放大器AD713?JFET输入,高速,精密四运算放大器?MAX475?单电源,低电压,宽带,高速四运算放大器AD744?JFET输入,高速,精密运算放大器?MAX477?宽带,高速运算放大器AD745?JFET输入,低噪音,高速运算放大器?MAX478?单电源,低功耗,精密双运算放大器AD746?JFET输入,高速,精密双运算放大器?MAX478A?单电源,低功耗,精密双运算放大器AD795?JFET输入,低噪音,低功耗,精密运算放大器?MAX479?单电源,低功耗,精密四运算放大器AD797?低噪音运算放大器?MAX479A?单电源,低功耗,精密四运算放大器AD8002?电流反馈型,低功耗,宽带,高速双运算放大器?MAX480?单电源,低功耗,低电压,低失调电压,精密运算放大器AD8005?电流反馈型,低功耗,宽带,高速双运算放大器?MAX492C?单电源,低功耗,低电压,精密双运算放大器AD8011?电流反馈型,低功耗,宽带,高速运算放大器?MAX492E?单电源,低功耗,低电压,精密双运算放大器AD8031?单电源,低功耗,高速运算放大器?MAX492M?单电源,低功耗,低电压,精密双运算放大器AD8032?单电源,低功耗,高速双运算放大器?MAX494C?单电源,低功耗,低电压,精密四运算放大器AD8041?单电源,宽带,高速运算放大器?MAX494E?单电源,低功耗,低电压,精密四运算放大器AD8042?单电源,宽带,高速双运算放大器?MAX494M?单电源,低功耗,低电压,精密四运算放大器AD8044?单电源,宽带,高速四运算放大器?MAX495C?单电源,低功耗,低电压,精密运算放大器AD8047?宽带,高速运算放大器?MAX495E?单电源,低功耗,低电压,精密运算放大器AD8055?低功耗,宽带,高速运算放大器?MAX495M?单电源,低功耗,低电压,精密运算放大器AD8056?低功耗,宽带,高速双运算放大器?MC1458?通用双运算放大器AD8072?电流反馈型,宽带,高速双运算放大器?MC1458C?通用双运算放大器AD812?电流反馈型,低电压,低功耗,高速双运算放大器?MC33071A?单电源,高速运算放大器AD817?低功耗,宽带,高速运算放大器?MC33072A?单电源,高速双运算放大器AD818?低功耗,宽带,高速运算放大器?MC33074A?单电源,高速四运算放大器AD820?JFET输入,单电源,低电压,低功耗,精密运算放大器?MC33078?低噪音双运算放大器AD822?JFET输入,单电源,低电压,低功耗,精密双运算放大器?MC33079?低噪音四运算放大器AD823?JFET输入,单电源,低电压,低功耗,精密,高速双运算放大器?MC33102?低功耗双运算放大器HA16119?CMOS单电源,低电压,低功耗双运算放大器?NJU7072?CMOS单电源,低功耗,低电压,低失调电压双运算放大器HFA1100?电流反馈型,宽带,高速运算放大器?NJU7074?CMOS单电源,低功耗,低电压,低失调电压四运算放大器HFA1120?电流反馈型,宽带,高速运算放大器?OP-07?低漂移,精密运算放大器HFA1205?电流反馈型,低功耗,宽带,高速双运算放大器?OP-113?BICMOS单电源,低噪音,低失调电压,精密运算放大器HFA1245?电流反馈型,低功耗,宽带,高速双运算放大器?OP-150?COMS,单电源,低电压,低功耗ICL7611?CMOS低电压,低功耗运算放大器?OP-160?电流反馈型,高速运算放大器ICL7612?CMOS低电压,低功耗运算放大器?OP-162?单电源,低电压,低功耗,高速,精密运算放大器ICL7621?CMOS低电压,低功耗双运算放大器?OP-177?低失调电压,精密运算放大器ICL7641?CMOS低电压四运算放大器?OP-183?单电源,宽带运算放大器ICL7642?CMOS低电压,低功耗四运算放大器?OP-184?单电源,低电压,高速,精密运算放大器ICL7650S?稳压器?OP-191?单电源,低电压,低功耗运算放大器LA6500?单电源,功率OP放大器?OP-193?单电源,低电压,低功耗,精密运算放大器LA6501?单电源,功率OP放大器?OP-196?单电源,低电压,低功耗运算放大器LA6510?2回路单电源功率OP放大器?OP-200?低功耗,低失调电压,精密双运算放大器"LA6512?高压,功率OP放大器双运算放大器?OP-213?BICMOS单电源,低噪音,低失调电压,精密双运算放大器LA6513?高压,功率OP放大器双运算放大器?OP-250?COMS,单电源,低电压,低功耗双运算放大器LA6520?单电源,功率OP放大器三运算放大器?OP-260?电流反馈型,高速双运算放大器LF356?JFET输入,高速运算放大器?OP-262?单电源,低电压,低功耗,高速,精密双运算放大器LF356A?JFET输入,高速运算放大器?OP-27?低噪音,低失调电压,精密运算放大器LF411?JFET输入,高速运算放大器?OP-270?低噪声,低失调电压,精密双运算放大器LF411A?JFET输入,高速运算放大器?OP-271?精密双运算放大器LF412?JFET输入,高速双运算放大器?OP-275?高速双运算放大器LF412A?JFET输入,高速双运算放大器?OP-279?单电源,大电流双运算放大器LF441?低功耗,JFET输入运算放大器?OP-282?JFET输入,低功耗双运算放大器LF441A?低功耗,JFET输入运算放大器?OP-283?单电源,宽带双运算放大器LF442?低功耗,JFET输入双运算放大器?OP-284?单电源,低电压,高速,精密双运算放大器LF442A?低功耗,JFET输入双运算放大器?OP-290?单电源,低功耗,精密双运算放大器LF444?低功耗,JFET输入四运算放大器?OP-291?单电源,低电压,低功耗双运算放大器LF444A?低功耗,JFET输入四运算放大器?OP-292?BICMOS单电源,通用双运算放大器LM2902?单电源四运算放大器?OP-293?单电源,低电压,低功耗,精密双运算放大器LM2904?单电源双运算放大器?OP-295?BICMOS低功耗,精密双运算放大器LM324?单电源四运算放大器?OP-296?单电源,低电压,低功耗双运算放大器LM358?单电源双运算放大器?OP-297?低电压,低功耗,低漂移,精密双运算放大器LM4250?单程控、低功耗运算放大器?OP-37?低噪音,低失调电压,高速,精密运算放大器LM607?低失调电压,精密运算放大器?OP-400?低功耗,低失调电压,精密四运算放大器LM6118?宽带,高速双运算放大器?OP-413?BICMOS单电源,低噪音,低失调电压,精密四运算放大器。
MAX3490及MAX3491
VIH DE, DI, RE
2.0
VIL DE, DI, RE
IIN1 DE, DI, RE
IIN2
DE = 0V, VCC = 0V or 3.6V
VIN = 12V VIN = -7V
IO
DE = 0V, RE = 0V,
VOUT = 12V
VCC = 0V or 3.6V, MAX3491 VOUT = -7V
Change in Magnitude of Driver Differential Output Voltage for Complementary Output States (Note 1)
SYMBOL
CONDITIONS
RL = 100Ω (RS-422), Figure 4
VOD RL = 54Ω (RS-485), Figure 4 RL = 60Ω (RS-485), VCC = 3.3V, Figure 5
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.
MAX系列芯片速查
MAXIM/DALLAS 中文数据资料DS12CR887, DS12R885, DS12R887 RTC,带有恒压涓流充电器DS1870 LDMOS RF功放偏置控制器DS1921L-F5X Thermochron iButtonDS1923 温度/湿度记录仪iButton,具有8kB数据记录存储器DS1982, DS1982-F3, DS1982-F5 1k位只添加iButton?DS1990A 序列号iButtonDS1990R, DS1990R-F3, DS1990R-F5 序列号iButtonDS1991 多密钥iButtonDS2129 LVD SCSI 27线调节器DS2401 硅序列号DS2406 双通道、可编址开关与1k位存储器DS2408 1-Wire、8通道、可编址开关DS2411 硅序列号,带有VCC输入DS2413 1-Wire双通道、可编址开关DS2430A 256位1-Wire EEPROMDS2431 1024位、1-Wire EEPROMDS2480B 串行、1-Wire线驱动器,带有负荷检测DS2482-100 单通道1-Wire主控制器DS2482-100 勘误表PDF: 2482-100A2DS2482-800, DS2482S-800 八通道1-Wire主控制器DS2482-800 勘误表PDF: 2482-800A2DS2502 1k位只添加存储器DS2505 16k位只添加存储器DS28E04-100 4096位、可寻址、1-Wire EEPROM,带有PIO DS3170DK DS3/E3单芯片收发器开发板DS3231, DS3231S 高精度、I2C集成RTC/TCXO/晶振DS33Z44 四路以太网映射器DS3902 双路、非易失、可变电阻器,带有用户EEPROMDS3906 三路、非易失、小步长调节可变电阻与存储器DS3984 4路冷阴极荧光灯控制器DS4302 2线、5位DAC,提供三路数字输出DS80C400-KIT DS80C400评估套件DS80C410, DS80C411 具有以太网和CAN接口的网络微控制器DS80C410 勘误表PDF: 80C410A1DS89C430, DS89C440, DS89C450 超高速闪存微控制器DS89C430 勘误表PDF: 89C430A2DS89C440 勘误表PDF: 89C440A2DS89C450 勘误表PDF: 89C450A2DS89C430 勘误表PDF: 89C430A3DS89C440 勘误表PDF: 89C440A3DS89C450 勘误表PDF: 89C450A3DS89C430 勘误表PDF: 89C430A5DS89C440 勘误表PDF: 89C440A5DS89C450 勘误表PDF: 89C450A5DS9090K 1-Wire器件评估板, B版DS9097U-009, DS9097U-E25, DS9097U-S09 通用1-Wire COM端口适配器DS9490, DS9490B, DS9490R USB至1-Wire/iButton适配器MAX1034, MAX1035 8/4通道、±VREF多量程输入、串行14位ADCMAX1072, MAX1075 1.8Msps、单电源、低功耗、真差分、10位ADCMAX1076, MAX1078 1.8Msps、单电源供电、低功耗、真差分、10位ADC,内置电压基准MAX1146, MAX1147, MAX1148, MAX1149 多通道、真差分、串行、14位ADC MAX1149EVKIT MAX1149评估板/评估系统MAX1220, MAX1257, MAX1258 12位、多通道ADC/DAC,带有FIFO、温度传感器和GPIO端口MAX1224, MAX1225 1.5Msps、单电源、低功耗、真差分、12位ADCMAX1258EVKIT MAX1057, MAX1058, MAX1257, MAX1258评估板/评估系统MAX1274, MAX1275 1.8Msps、单电源、低功耗、真差分、12位ADCMAX13000E, MAX13001E, MAX13002E, MAX13003E, MAX13004E, MAX13005E 超低电压电平转换器MAX1302, MAX1303 8/4通道、±VREF多量程输入、串行16位ADCMAX1304, MAX1305, MAX1306, MAX1308, MAX1309, MAX1310, MAX1312, MAX1313, MAX1314 8/4/2通道、12位、同时采样ADC,提供±10V、±5V或0至+5V 模拟输入范围MAX13050, MAX13052, MAX13053, MAX13054 工业标准高速CAN收发器,具有±80V故障保护MAX13080E, MAX13081E, MAX13082E, MAX13083E, MAX13084E, MAX13085E, MAX13086E, MAX13087E, MAX13088E, MAX13089E +5.0V、±15kV ESD保护、失效保护、热插拔、RS-485/RS-422收发器MAX13101E, MAX13102E, MAX13103E, MAX13108E 16通道、带有缓冲的CMOS 逻辑电平转换器MAX1334, MAX1335 4.5Msps/4Msps、5V/3V、双通道、真差分10位ADCMAX1336, MAX1337 6.5Msps/5.5Msps、5V/3V、双通道、真差分8位ADCMAX13481E, MAX13482E, MAX13483E ±15kV ESD保护USB收发器, 外部/内部上拉电阻MAX1350, MAX1351, MAX1352, MAX1353, MAX1354, MAX1355, MAX1356, MAX1357 双路、高端、电流检测放大器和驱动放大器MAX1450 低成本、1%精确度信号调理器,用于压阻式传感器MAX1452 低成本、精密的传感器信号调理器MAX1487, MAX481, MAX483, MAX485, MAX487, MAX488, MAX489, MAX490, MAX491 低功耗、限摆率、RS-485/RS-422收发器MAX1492, MAX1494 3位半和4位半、单片ADC,带有LCD驱动器MAX1494EVKIT MAX1493, MAX1494, MAX1495评估板/评估系统MAX1497, MAX1499 3位半和4位半、单片ADC,带有LED驱动器和μC接口MAX1499EVKIT MAX1499评估板/评估系统MAX15000, MAX15001 电流模式PWM控制器, 可调节开关频率MAX1515 低电压、内置开关、降压/DDR调节器MAX1518B TFT-LCD DC-DC转换器, 带有运算放大器MAX1533, MAX1537 高效率、5路输出、主电源控制器,用于笔记本电脑MAX1533EVKIT MAX1533评估板MAX1540A, MAX1541 双路降压型控制器,带有电感饱和保护、动态输出和线性稳压器MAX1540EVKIT MAX1540评估板MAX1551, MAX1555 SOT23、双输入、USB/AC适配器、单节Li+电池充电器MAX1553, MAX1554 高效率、40V、升压变换器,用于2至10个白光LED驱动MAX1556, MAX1557 16μA IQ、1.2A PWM降压型DC-DC转换器MAX1556EVKIT MAX1556EVKIT评估板MAX1558, MAX1558H 双路、3mm x 3mm、1.2A/可编程电流USB开关,带有自动复位功能MAX1586A, MAX1586B, MAX1586C, MAX1587A, MAX1587C 高效率、低IQ、带有动态内核的PMIC,用于PDA和智能电话MAX16801A/B, MAX16802A/B 离线式、DC-DC PWM控制器, 用于高亮度LED驱动器MAX1858A, MAX1875A, MAX1876A 双路180°异相工作的降压控制器,具有排序/预偏置启动和PORMAX1870A 升/降压Li+电池充电器MAX1870AEVKIT MAX1870A评估板MAX1874 双路输入、USB/AC适配器、1节Li+充电器,带OVP与温度调节MAX1954A 低成本、电流模式PWM降压控制器,带有折返式限流MAX1954AEVKIT MAX1954A评估板MAX19700 7.5Msps、超低功耗模拟前端MAX19700EVKIT MAX19700评估板/评估系统MAX19705 10位、7.5Msps、超低功耗模拟前端MAX19706 10位、22Msps、超低功耗模拟前端MAX19707 10位、45Msps、超低功耗模拟前端MAX19708 10位、11Msps、超低功耗模拟前端MAX2041 高线性度、1700MHz至3000MHz上变频/下变频混频器,带有LO缓冲器/开关MAX2043 1700MHz至3000MHz高线性度、低LO泄漏、基站Rx/Tx混频器MAX220, MAX222, MAX223, MAX225, MAX230, MAX231, MAX232, MAX232A, MAX233, MAX233A, MAX234, MAX235, MAX236, MAX237, MAX238, MAX239, MAX240, MAX241, MAX242, MAX243, MAX244, MAX245, MAX246, MAX247, MAX248, MAX249 +5V供电、多通道RS-232驱动器/接收器MAX2335 450MHz CDMA/OFDM LNA/混频器MAX2370 完备的、450MHz正交发送器MAX2370EVKIT MAX2370评估板MAX2980 电力线通信模拟前端收发器MAX2986 集成电力线数字收发器MAX3013 +1.2V至+3.6V、0.1μA、100Mbps、8路电平转换器MAX3205E, MAX3207E, MAX3208E 双路、四路、六路高速差分ESD保护ICMAX3301E, MAX3302E USB On-the-Go收发器与电荷泵MAX3344E, MAX3345E ±15kV ESD保护、USB收发器,UCSP封装,带有USB检测MAX3394E, MAX3395E, MAX3396E ±15kV ESD保护、大电流驱动、双/四/八通道电平转换器, 带有加速电路MAX3535E, MXL1535E +3V至+5V、提供2500VRMS隔离的RS-485/RS-422收发器,带有±15kV ESD保护MAX3570, MAX3571, MAX3573 HI-IF单芯片宽带调谐器MAX3643EVKIT MAX3643评估板MAX3645 +2.97V至+5.5V、125Mbps至200Mbps限幅放大器,带有信号丢失检测器MAX3654 47MHz至870MHz模拟CATV互阻放大器MAX3654EVKIT MAX3654评估板MAX3657 155Mbps低噪声互阻放大器MAX3658 622Mbps、低噪声、高增益互阻前置放大器MAX3735, MAX3735A 2.7Gbps、低功耗、SFP激光驱动器MAX3737 多速率激光驱动器,带有消光比控制MAX3737EVKIT MAX3737评估板MAX3738 155Mbps至2.7Gbps SFF/SFP激光驱动器,带有消光比控制MAX3744, MAX3745 2.7Gbps SFP互阻放大器,带有RSSIMAX3744EVKIT, MAX3745EVKIT MAX3744, MAX3745评估板MAX3748, MAX3748A, MAX3748B 紧凑的、155Mbps至4.25Gbps限幅放大器MAX3785 6.25Gbps、1.8V PC板均衡器MAX3787EVKIT MAX3787评估板MAX3793 1Gbps至4.25Gbps多速率互阻放大器,具有光电流监视器MAX3793EVKIT MAX3793评估板MAX3805 10.7Gbps自适应接收均衡器MAX3805EVKIT MAX3805评估板MAX3840 +3.3V、2.7Gbps双路2 x 2交叉点开关MAX3841 12.5Gbps CML 2 x 2交叉点开关MAX3967 270Mbps SFP LED驱动器MAX3969 200Mbps SFP限幅放大器MAX3969EVKIT MAX3969评估板MAX3982 SFP铜缆预加重驱动器MAX3983 四路铜缆信号调理器MAX3983EVKIT MAX3983评估板MAX3983SMAEVKIT MAX3983 SMA连接器评估板MAX4079 完备的音频/视频后端方案MAX4210, MAX4211 高端功率、电流监视器MAX4210EEVKIT MAX4210E、MAX4210A/B/C/D/F评估板MAX4211EEVKIT MAX4211A/B/C/D/E/F评估板MAX4397 用于双SCART连接器的音频/视频开关MAX4397EVKIT MAX4397评估系统/评估板MAX4411EVKIT MAX4411评估板MAX4729, MAX4730 低电压、3.5、SPDT、CMOS模拟开关MAX4754, MAX4755, MAX4756 0.5、四路SPDT开关,UCSP/QFN封装MAX4758, MAX4759 四路DPDT音频/数据开关,UCSP/QFN封装MAX4760, MAX4761 宽带、四路DPDT开关MAX4766 0.075A至1.5A、可编程限流开关MAX4772, MAX4773 200mA/500mA可选的限流开关MAX4795, MAX4796, MAX4797, MAX4798 450mA/500mA限流开关MAX4826, MAX4827, MAX4828, MAX4829, MAX4830, MAX4831 50mA/100mA 限流开关, 带有空载标记, μDFN封装MAX4832, MAX4833 100mA LDO,带有限流开关MAX4834, MAX4835 250mA LDO,带有限流开关MAX4836, MAX4837 500mA LDO,带有限流开关MAX4838A, MAX4840A, MAX4842A 过压保护控制器,带有状态指示FLAGMAX4850, MAX4850H, MAX4852, MAX4852H 双路SPDT模拟开关,可处理超摆幅信号MAX4851, MAX4851H, MAX4853, MAX4853H 3.5/7四路SPST模拟开关,可处理超摆幅信号MAX4854 7四路SPST模拟开关,可处理超摆幅信号MAX4854H, MAX4854HL 四路SPST、宽带、信号线保护开关MAX4855 0.75、双路SPDT音频开关,具有集成比较器MAX4864L, MAX4865L, MAX4866L, MAX4867, MAX4865, MAX4866 过压保护控制器,具有反向保护功能MAX4880 过压保护控制器, 内置断路开关MAX4881, MAX4882, MAX4883, MAX4884 过压保护控制器, 内部限流, TDFN封装MAX4901, MAX4902, MAX4903, MAX4904, MAX4905 低RON、双路SPST/单路SPDT、无杂音切换开关, 可处理负电压MAX4906, MAX4906F, MAX4907, MAX4907F 高速/全速USB 2.0开关MAX5033 500mA、76V、高效率、MAXPower降压型DC-DC变换器MAX5042, MAX5043 双路开关电源IC,集成了功率MOSFET和热插拔控制器MAX5058, MAX5059 可并联的副边同步整流驱动器和反馈发生器控制ICMAX5058EVKIT MAX5051, MAX5058评估板MAX5062, MAX5062A, MAX5063, MAX5063A, MAX5064, MAX5064A, MAX5064B 125V/2A、高速、半桥MOSFET驱动器MAX5065, MAX5067 双相、+0.6V至+3.3V输出可并联、平均电流模式控制器MAX5070, MAX5071 高性能、单端、电流模式PWM控制器MAX5072 2.2MHz、双输出、降压或升压型转换器,带有POR和电源失效输出MAX5072EVKIT MAX5072评估板MAX5074 内置MOSFET的电源IC,用于隔离型IEEE 802.3af PD和电信电源MAX5078 4A、20ns、MOSFET驱动器MAX5084, MAX5085 65V、200mA、低静态电流线性稳压器, TDFN封装MAX5088, MAX5089 2.2MHz、2A降压型转换器, 内置高边开关MAX5094A, MAX5094B, MAX5094C, MAX5094D, MAX5095A, MAX5095B, MAX5095C 高性能、单端、电流模式PWM控制器MAX5128 128抽头、非易失、线性变化数字电位器, 采用2mm x 2mm μDFN封装MAX5417, MAX5417L, MAX5417M, MAX5417N, MAX5417P, MAX5418, MAX5419 256抽头、非易失、I2C接口、数字电位器MAX5417LEVKIT MAX5417_, MAX5418_, MAX5419_评估板/评估系统MAX5477, MAX5478, MAX5479 双路、256抽头、非易失、I2C接口、数字电位器MAX5478EVKIT MAX5477/MAX5478/MAX5479评估板/评估系统MAX5490 100k精密匹配的电阻分压器,SOT23封装MAX5527, MAX5528, MAX5529 64抽头、一次性编程、线性调节数字电位器MAX5820 双路、8位、低功耗、2线、串行电压输出DACMAX5865 超低功耗、高动态性能、40Msps模拟前端MAX5920 -48V热插拔控制器,外置RsenseMAX5921, MAX5939 -48V热插拔控制器,外置Rsense、提供较高的栅极下拉电流MAX5932 正电源、高压、热插拔控制器MAX5932EVKIT MAX5932评估板MAX5936, MAX5937 -48V热插拔控制器,可避免VIN阶跃故障,无需RSENSE MAX5940A, MAX5940B IEEE 802.3af PD接口控制器,用于以太网供电MAX5940BEVKIT MAX5940B, MAX5940D评估板MAX5941A, MAX5941B 符合IEEE 802.3af标准的以太网供电接口/PWM控制器,适用于用电设备MAX5945 四路网络电源控制器,用于网络供电MAX5945EVKIT, MAX5945EVSYS MAX5945评估板/评估系统MAX5953A, MAX5953B, MAX5953C, MAX5953D IEEE 802.3af PD接口和PWM控制器,集成功率MOSFETMAX6640 2通道温度监视器,提供双路、自动PWM风扇速度控制器MAX6640EVKIT MAX6640评估系统/评估板MAX6641 兼容于SMBus的温度监视器,带有自动PWM风扇速度控制器MAX6643, MAX6644, MAX6645 自动PWM风扇速度控制器,带有过温报警输出MAX6678 2通道温度监视器,提供双路、自动PWM风扇速度控制器和5个GPIOMAX6695, MAX6696 双路远端/本地温度传感器,带有SMBus串行接口MAX6877EVKIT MAX6877评估板MAX6950, MAX6951 串行接口、+2.7V至+5.5V、5位或8位LED显示驱动器MAX6966, MAX6967 10端口、恒流LED驱动器和输入/输出扩展器,带有PWM亮度控制MAX6968 8端口、5.5V恒流LED驱动器MAX6969 16端口、5.5V恒流LED驱动器MAX6970 8端口、36V恒流LED驱动器MAX6977 8端口、5.5V恒流LED驱动器,带有LED故障检测MAX6978 8端口、5.5V恒流LED驱动器,带有LED故障检测和看门狗MAX6980 8端口、36V恒流LED驱动器, 带有LED故障检测和看门狗MAX6981 8端口、36V恒流LED驱动器, 带有LED故障检测MAX7030 低成本、315MHz、345MHz和433.92MHz ASK收发器, 带有N分频PLL MAX7032 低成本、基于晶振的可编程ASK/FSK收发器, 带有N分频PLLMAX7317 10端口、SPI接口输入/输出扩展器,带有过压和热插入保护MAX7319 I2C端口扩展器,具有8路输入,可屏蔽瞬态检测MAX7320 I2C端口扩展器, 带有八个推挽式输出MAX7321 I2C端口扩展器,具有8个漏极开路I/O口MAX7328, MAX7329 I2C端口扩展器, 带有八个I/O口MAX7347, MAX7348, MAX7349 2线接口、低EMI键盘开关和发声控制器MAX7349EVKIT MAX7349评估板/仿真: MAX7347/MAX7348MAX7375 3引脚硅振荡器MAX7381 3引脚硅振荡器MAX7389, MAX7390 微控制器时钟发生器, 带有看门狗MAX7391 快速切换时钟发生器, 带有电源失效检测MAX7445 4通道视频重建滤波器MAX7450, MAX7451, MAX7452 视频信号调理器,带有AGC和后肩钳位MAX7452EVKIT MAX7452评估板MAX7462, MAX7463 单通道视频重建滤波器和缓冲器MAX8505 3A、1MHz、1%精确度、内置开关的降压型调节器,带有电源就绪指示MAX8524, MAX8525 2至8相VRM 10/9.1 PWM控制器,提供精密的电流分配和快速电压定位MAX8525EVKIT MAX8523, MAX8525评估板MAX8533 更小、更可靠的12V、Infiniband兼容热插拔控制器MAX8545, MAX8546, MAX8548 低成本、宽输入范围、降压控制器,带有折返式限流MAX8550, MAX8551 集成DDR电源方案,适用于台式机、笔记本电脑及图形卡MAX8550EVKIT MAX8550, MAX8550A, MAX8551评估板MAX8552 高速、宽输入范围、单相MOSFET驱动器MAX8553, MAX8554 4.5V至28V输入、同步PWM降压控制器,适合DDR端接和负载点应用MAX8563, MAX8564 ±1%、超低输出电压、双路或三路线性n-FET控制器MAX8564EVKIT MAX8563, MAX8564评估板MAX8566 高效、10A、PWM降压调节器, 内置开关MAX8570, MAX8571, MAX8572, MAX8573, MAX8574, MAX8575 高效LCD升压电路,可True ShutdownMAX8571EVKIT MAX8570, MAX8571, MAX8572, MAX8573, MAX8574, MAX8575评估板MAX8576, MAX8577, MAX8578, MAX8579 3V至28V输入、低成本、迟滞同步降压控制器MAX8594, MAX8594A 5路输出PMIC,提供DC-DC核电源,用于低成本PDAMAX8594EVKIT MAX8594评估板MAX8632 集成DDR电源方案,适用于台式机、笔记本电脑和图形卡MAX8632EVKIT MAX8632评估板MAX8702, MAX8703 双相MOSFET驱动器,带有温度传感器MAX8707 多相、固定频率控制器,用于AMD Hammer CPU核电源MAX8716, MAX8717, MAX8757 交叉工作、高效、双电源控制器,用于笔记本电脑MAX8716EVKIT MAX8716评估板MAX8717EVKIT MAX8717评估板MAX8718, MAX8719 高压、低功耗线性稳压器,用于笔记本电脑MAX8725EVKIT MAX8725评估板MAX8727 TFT-LCD升压型、DC-DC变换器MAX8729 固定频率、半桥CCFL逆变控制器MAX8729EVKIT MAX8729评估板MAX8732A, MAX8733A, MAX8734A 高效率、四路输出、主电源控制器,用于笔记本电脑MAX8737 双路、低电压线性稳压器, 外置MOSFETMAX8737EVKIT MAX8737评估板MAX8738 EEPROM可编程TFT VCOM校准器, 带有I2C接口MAX8740 TFT-LCD升压型、DC-DC变换器MAX8743 双路、高效率、降压型控制器,关断状态下提供高阻MAX8751 固定频率、全桥、CCFL逆变控制器MAX8751EVKIT MAX8751评估板MAX8752 TFT-LCD升压型、DC-DC变换器MAX8758 具有开关控制和运算放大器的升压调节器, 用于TFT LCDMAX8758EVKIT MAX8758评估板MAX8759 低成本SMBus CCFL背光控制器MAX8760 双相、Quick-PWM控制器,用于AMD Mobile Turion 64 CPU核电源MAX8764 高速、降压型控制器,带有精确的限流控制,用于笔记本电脑MAX9223, MAX9224 22位、低功耗、5MHz至10MHz串行器与解串器芯片组MAX9225, MAX9226 10位、低功耗、10MHz至20MHz串行器与解串器芯片组MAX9483, MAX9484 双输出、多模CD-RW/DVD激光二极管驱动器MAX9485 可编程音频时钟发生器MAX9485EVKIT MAX9485评估板MAX9486 8kHz参考时钟合成器,提供35.328MHz倍频输出MAX9486EVKIT MAX9486评估板MAX9489 多路输出网络时钟发生器MAX9500, MAX9501 三通道HDTV滤波器MAX9500EVKIT MAX9500评估板MAX9502 2.5V视频放大器, 带有重建滤波器MAX9504A, MAX9504B 3V/5V、6dB视频放大器, 可提供大电流输出MAX9701 1.3W、无需滤波、立体声D类音频功率放大器MAX9701EVKIT MAX9701评估板MAX9702 1.8W、无需滤波、立体声D类音频功率放大器和DirectDrive立体声耳机放大器MAX9702EVSYS/EVKIT MAX9702/MAX9702B评估系统/评估板MAX9703, MAX9704 10W立体声/15W单声道、无需滤波的扩展频谱D类放大器MAX9705 2.3W、超低EMI、无需滤波、D类音频放大器MAX9705BEVKIT MAX9705B评估板MAX9710EVKIT MAX9710评估板MAX9712 500mW、低EMI、无需滤波、D类音频放大器MAX9713, MAX9714 6W、无需滤波、扩频单声道/立体声D类放大器MAX9714EVKIT MAX9704, MAX9714评估板MAX9715 2.8W、低EMI、立体声、无需滤波、D类音频放大器MAX9715EVKIT MAX9715评估板MAX9716, MAX9717 低成本、单声道、1.4W BTL音频功率放大器MAX9716EVKIT MAX9716评估板MAX9718, MAX9719 低成本、单声道/立体声、1.4W差分音频功率放大器MAX9718AEVKIT MAX9718A评估板MAX9719AEVKIT MAX9719A/B/C/D评估板MAX9721 1V、固定增益、DirectDrive、立体声耳机放大器,带有关断MAX9721EVKIT MAX9721评估板MAX9722A, MAX9722B 5V、差分输入、DirectDrive、130mW立体声耳机放大器,带有关断MAX9722AEVKIT MAX9722A, MAX9722B评估板MAX9723 立体声DirectDrive耳机放大器, 具有BassMax、音量控制和I2C接口MAX9725 1V、低功率、DirectDrive、立体声耳机放大器,带有关断MAX9728AEVKIT MAX9728A/MAX9728B评估板MAX9750, MAX9751, MAX9755 2.6W立体声音频功放和DirectDrive耳机放大器MAX9759 3.2W、高效、低EMI、无需滤波、D类音频放大器MAX9759EVKIT MAX9759评估板MAX9770, MAX9772 1.2W、低EMI、无需虑波、单声道D类放大器,带有立体声DirectDrive耳机放大器MAX9787 2.2W立体声音频功率放大器, 提供模拟音量控制MAX9850 立体声音频DAC,带有DirectDrive耳机放大器MAX9890 音频咔嗒声-怦然声抑制器MAX9951, MAX9952 双路引脚参数测量单元MAX9960 双闪存引脚电子测量/高压开关矩阵MAX9961, MAX9962 双通道、低功耗、500Mbps ATE驱动器/比较器,带有2mA负载MAX9967 双通道、低功耗、500Mbps ATE驱动器/比较器,带有35mA负载MAX9986A SiGe高线性度、815MHz至1000MHz下变频混频器, 带有LO缓冲器/开关MAXQ2000 低功耗LCD微控制器MAXQ2000 勘误表PDF: MAXQ2000A2MAXQ2000-KIT MAXQ2000评估板MAXQ3120-KIT MAXQ3120评估板MXL1543B +5V、多协议、3Tx/3Rx、软件可选的时钟/数据收发器。
3DS MAX标准文本导出格式ASE的文件结构
3DS MAX标准文本导出格式ASE的文件结构如果你正在寻找它的几何体存放在哪的话,事实上,这不是描述具体信息层级关系的图示,而是类似XML的一种存储规范,它具有独立标签和嵌套标签,独立标签有名称和值表,而嵌套标签不仅可以嵌套子标签,还可以嵌套“子嵌套标签”,如此递归下去。
这种格式固然带来很大的灵活性,但是非常浪费时间。
需要对它们全部解套然后利用一致的算法,提供一个匹配标签名进行标签取出和迭代。
*3DSMAX_ASCIIEXPORT 200*COMMENT "AsciiExport 版本 2.00 - Wed Sep 19 22:16:39 2007"*SCENE {*SCENE_FILENAME "box.max"*SCENE_FIRSTFRAME 0*SCENE_LASTFRAME 100*SCENE_FRAMESPEED 30*SCENE_TICKSPERFRAME 160*SCENE_BACKGROUND_STA TIC 0.00000000 0.00000000 0.00000000*SCENE_AMBIENT_STA TIC 0.00000000 0.00000000 0.00000000}第二行使用了双引号对值进行了限定,避免被分割成子单元。
我们可以假设*SCENE块还可以内嵌子块,假如存在,便可将此子块作为独立单元进行递归分解。
直到所有嵌套子块全部被遍历。
* QUICK NOTES *This tutorial shows how to load a .Ase file. An ASE file is a 3D Studio Max ASCII file that saves all the information in a text file instead of in binary.The good thing about this is that it's easy to read in, as well as easy to change without having the software. The bad thing is that it's a HUGE file size, it takes a lot longer to read in, no other programs support it and it can't even be imported back into 3D Studio Max. I would recommend looking at this tutorial before you look at the 3DS tutorial though. That way you can see what is actually being read in.Let me mention that the math functions above are not so important and don't need to be in this file. I wanted to show how to calculate vertex normals so your models would have some excellent lighting. You most likely have functions alre ady that dothe basics so I encourage you to just use those. This will cut down the code significantly.* What's An STL (Standard Template Library) Vector? *Let me quickly explain the STL vector for those of you who are not familiar with them.To use a vector you must include <vector> and use the std namespace: using namespace std;A vector is an array based link list. It allows you to dynamically add and remove nodes.This is a template class so it can be a list of ANY type. To create a vector of type"int" you would say: vector<int> myIntList;Now you can add a integer to the dynamic array by saying: myIntList.push_back(10);or you can say: myIntList.push_back(num);. The more you push back, the largeryour array gets. You can index the vector like an array. myIntList[0] = 0;To get rid of a node you use the pop_back() function. To clear the vector use clear().It frees itself so you don't need to worry about it, except if you have datastructures that need information freed from inside them, like our objects.Let's go over some of the format of the .Ase file. I will only address the information that we really care about for object loading. The rest is Scene stuff. I created a single box around the origin that had a texture map over it to showthe simplest and smallest amount of data.This next block is the material block. This holds all the info on the materials.*MATERIAL_LIST { // This is the tag for the start of the material info*MATERIAL_COUNT 1 // This tells us how many materials there are*MATERIAL 0 { // This is the material ID that the next data is refering too.*MATERIAL_NAME "Material #1" // The material name*MATERIAL_CLASS "Standard"*MATERIAL_AMBIENT 0.1791 0.0654 0.0654*MATERIAL_DIFFUSE 0.5373 0.1961 0.1961 // The color of the object*MATERIAL_SPECULAR 0.9000 0.9000 0.9000*MATERIAL_SHINE 0.2500*MATERIAL_SHINESTRENGTH 0.0500*MATERIAL_TRANSPARENCY 0.0000*MATERIAL_WIRESIZE 1.0000*MATERIAL_SHADING Blinn*MATERIAL_XP_FALLOFF 0.0000*MATERIAL_SELFILLUM 0.0000*MATERIAL_FALLOFF In*MATERIAL_XP_TYPE Filter*MAP_DIFFUSE {*MAP_NAME "Map #1"*MAP_CLASS "Bitmap"*MAP_SUBNO 1*MAP_AMOUNT 1.0000*BITMAP "texture.bmp" // This is the file name for the texture*MAP_TYPE Screen*UVW_U_OFFSET 0.0000 // This is the U offset for the tile*UVW_V_OFFSET 0.0000 // This is the V offset for the tile*UVW_U_TILING 1.0000 // This is the U tiling ratio (1 is standard)*UVW_V_TILING 1.0000 // This is the V tiling ratio (1 is standard)*UVW_ANGLE 0.0000*UVW_BLUR 1.0000*UVW_BLUR_OFFSET 0.0000*UVW_NOUSE_AMT 1.0000*UVW_NOISE_SIZE 1.0000*UVW_NOISE_LEVEL 1*UVW_NOISE_PHASE 0.0000*BITMAP_FILTER Pyramidal}}}*GEOMOBJECT { // This tag let's us know that objects are next *NODE_NAME "Box01" // This is the object name*NODE_TM {*NODE_NAME "Box01" // Once again, this is the objects name*INHERIT_POS 0 0 0*INHERIT_ROT 0 0 0*INHERIT_SCL 0 0 0*TM_ROW0 1.0000 0.0000 0.0000*TM_ROW1 0.0000 1.0000 0.0000*TM_ROW2 0.0000 0.0000 1.0000*TM_ROW3 0.0000 0.0000 0.0000*TM_POS 0.0000 0.0000 0.0000*TM_ROTAXIS 0.0000 0.0000 0.0000*TM_ROTANGLE 0.0000*TM_SCALE 1.0000 1.0000 1.0000*TM_SCALEAXIS 0.0000 0.0000 0.0000*TM_SCALEAXISANG 0.0000}*MESH { // This tells us an objects data is next*TIMEVALUE 0*MESH_NUMVERTEX 8 // This holds the number of vertices for this object *MESH_NUMFACES 12 // This is the number of faces in this object*MESH_VERTEX_LIST { // The tag for the start of the vertex list*MESH_VERTEX 0 -1.5000 -1.5000 0.0000 // These next 8 are the vertices.*MESH_VERTEX 1 1.5000 -1.5000 0.0000 // The first number is the index*MESH_VERTEX 2 -1.5000 1.5000 0.0000 // and the next 3 are the (X, Y, Z)*MESH_VERTEX 3 1.5000 1.5000 0.0000 // ...*MESH_VERTEX 4 -1.5000 -1.5000 3.0000*MESH_VERTEX 5 1.5000 -1.5000 3.0000*MESH_VERTEX 6 -1.5000 1.5000 3.0000*MESH_VERTEX 7 1.5000 1.5000 3.0000}Below is the tag for the face list. We have a list of vertices and texture coordinates.Each of these vertices and coordinates are unique. This cuts down memory.We then have a structure that holds index's into the vertex and UV array.After *MESH_FACE it has the index, then the A B and C values. These valuesare for point1 point2 and point3 indices into the vertex array. The rest canbe ignored. They have to do with visibility issues.*MESH_FACE_LIST {*MESH_FACE 0: A: 0 B: 2 C: 3 AB: 1 BC: 1 CA: 0*MESH_SMOOTHING 2 *MESH_MTLID 1*MESH_FACE 1: A: 3 B: 1 C: 0 AB: 1 BC: 1 CA: 0*MESH_SMOOTHING 2 *MESH_MTLID 1*MESH_FACE 2: A: 4 B: 5 C: 7 AB: 1 BC: 1 CA: 0*MESH_SMOOTHING 3 *MESH_MTLID 0*MESH_FACE 3: A: 7 B: 6 C: 4 AB: 1 BC: 1 CA: 0 *MESH_SMOOTHING 3 *MESH_MTLID 0*MESH_FACE 4: A: 0 B: 1 C: 5 AB: 1 BC: 1 CA: 0*MESH_SMOOTHING 4 *MESH_MTLID 4*MESH_FACE 5: A: 5 B: 4 C: 0 AB: 1 BC: 1 CA: 0*MESH_SMOOTHING 4 *MESH_MTLID 4*MESH_FACE 6: A: 1 B: 3 C: 7 AB: 1 BC: 1 CA: 0*MESH_SMOOTHING 5 *MESH_MTLID 3*MESH_FACE 7: A: 7 B: 5 C: 1 AB: 1 BC: 1 CA: 0*MESH_SMOOTHING 5 *MESH_MTLID 3*MESH_FACE 8: A: 3 B: 2 C: 6 AB: 1 BC: 1 CA: 0*MESH_SMOOTHING 6 *MESH_MTLID 5*MESH_FACE 9: A: 6 B: 7 C: 3 AB: 1 BC: 1 CA: 0*MESH_SMOOTHING 6 *MESH_MTLID 5*MESH_FACE 10: A: 2 B: 0 C: 4 AB: 1 BC: 1 CA: 0*MESH_SMOOTHING 7 *MESH_MTLID 2*MESH_FACE 11: A: 4 B: 6 C: 2 AB: 1 BC: 1 CA: 0*MESH_SMOOTHING 7 *MESH_MTLID 2}*MESH_NUMTVERTEX 36 // This is the number of texture coordinates for this objectThe next block is the texture coordinates. The first value after *MESH_TVERTis the index and the next 2 values are the ones we care about. The third is ignored.The 2 we care about are the U and V values for the vertices.*MESH_TVERTLIST { // The tag to let us know there are UV coordiantes *MESH_TVERT 0 0.9995 0.0005 0.0005 // Format: Index U V Ignore*MESH_TVERT 1 0.0005 0.0005 0.9995*MESH_TVERT 2 0.0005 0.0005 0.0005*MESH_TVERT 3 0.0005 0.0005 0.9995*MESH_TVERT 4 0.9995 0.9995 0.0005*MESH_TVERT 5 0.0005 0.9995 0.9995*MESH_TVERT 6 0.0005 0.9995 0.0005*MESH_TVERT 7 0.0005 0.9995 0.9995*MESH_TVERT 9 0.9995 0.9995 0.0005*MESH_TVERT 10 0.0005 0.9995 0.0005*MESH_TVERT 11 0.0005 0.9995 0.0005*MESH_TVERT 12 0.0005 0.0005 0.0005*MESH_TVERT 13 0.9995 0.0005 0.0005*MESH_TVERT 14 0.0005 0.0005 0.9995*MESH_TVERT 15 0.9995 0.0005 0.9995*MESH_TVERT 16 0.9995 0.9995 0.9995*MESH_TVERT 17 0.9995 0.9995 0.9995*MESH_TVERT 18 0.0005 0.9995 0.9995*MESH_TVERT 19 0.0005 0.0005 0.9995*MESH_TVERT 20 0.0005 0.0005 0.0005*MESH_TVERT 21 0.9995 0.0005 0.0005*MESH_TVERT 22 0.9995 0.9995 0.0005*MESH_TVERT 23 0.9995 0.9995 0.0005*MESH_TVERT 24 0.0005 0.9995 0.0005*MESH_TVERT 25 0.0005 0.0005 0.0005*MESH_TVERT 26 0.0005 0.0005 0.9995*MESH_TVERT 27 0.9995 0.0005 0.9995*MESH_TVERT 28 0.9995 0.9995 0.9995*MESH_TVERT 29 0.9995 0.9995 0.9995*MESH_TVERT 30 0.0005 0.0005 0.9995*MESH_TVERT 31 0.9995 0.0005 0.9995*MESH_TVERT 32 0.9995 0.9995 0.9995*MESH_TVERT 33 0.9995 0.9995 0.9995*MESH_TVERT 34 0.0005 0.0005 0.0005*MESH_TVERT 35 0.9995 0.9995 0.0005}This next block is the indices for the faces into the texture coordinate array.Just like the vertex indices with the A B and C values, these do work the same.We use the 3 values to index the UV coordinates in the texture coordinate array.The format after the *MESH_TFACE is: The face index, then the 3 indices into the array.For example, the top line below has a 0 for the index (not read in)the next is an 8, which will be used to index the 8th texture coordinate in thearray. Like so: int coordIndex = pObject->pFaces[j].coordIndex[whichVertex];If j was zero and whichVertex was zero, coordIndex would be 8. Get it?*MESH_NUMTVFACES 12 // This is the number of textured faces*MESH_TFACELIST { // This tag tells us the UV indices are next*MESH_TFACE 0 89 10 // Format: faceIndex UVIndex1 UVIndex2 UVIndex3*MESH_TFACE 1 11 12 13 // ...*MESH_TFACE 2 14 15 16*MESH_TFACE 3 17 18 19*MESH_TFACE 4 20 21 22*MESH_TFACE 5 23 24 25*MESH_TFACE 6 26 27 28*MESH_TFACE 7 29 5 1*MESH_TFACE 8 30 31 32*MESH_TFACE 9 33 7 3*MESH_TFACE 10 34 0 35*MESH_TFACE 11 4 6 2}}So that's the main stuff. There is more things like animation and normals butI prefer to calculate my own normals, because not all formats have vertex normalsand animation is a huge topic not to be discussed in a file format tutorial :)For those of you who don't know what vertex normals are, it means you have a normalfor not just every polygon, but for every vertex. That makes lighting more real looking.Also it makes the models look more smooth.*Note* - Remember after saving your .Ase file, to delete the path in frontof the texture name. You want: "texture.bmp" verses "C:\MyStuff\Pictures\texture.bmp"That way you can just stick the bitmap in the same folder as the program and not bedependant on paths.I hope this helped someone out. Let us know at what you do withthis. We are always interested. Eventually there will probably be an animationtutorial for this format so stay in touch.Ben Humphrey (DigiBen)Game ProgrammerDigiBen@Co-Web Host of 。
MAX481_MAX483_MAX485_MAX487_MAX1487_MAX490_MAX491_中文资料
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_____________________________ _概述MAX481、MAX483、MAX485、MAX487-MAX491以及MAX1487是用于RS-485与RS-422通信的低功耗收发器,每个器件中都具有一个驱动器和一个接收器。
MAX483、MAX487、MAX488以及MAX489具有限摆率驱动器,可以减小EMI ,并降低由不恰当的终端匹配电缆引起的反射,实现最高250k b p s 的无差错数据传输。
M A X 481、MAX485、MAX490、MAX491、MAX1487的驱动器摆率不受限制,可以实现最高2.5Mbps 的传输速率。
这些收发器在驱动器禁用的空载或满载状态下,吸取的电源电流在120(A 至500(A 之间。
另外,MAX481、MAX483与MAX487具有低电流关断模式,仅消耗0.1µA 。
所有器件都工作在5V 单电源下。
驱动器具有短路电流限制,并可以通过热关断电路将驱动器输出置为高阻状态,防止过度的功率损耗。
接收器输入具有失效保护特性,当输入开路时,可以确保逻辑高电平输出。
MAX487与MAX1487具有四分之一单位负载的接收器输入阻抗,使得总线上最多可以有128个M A X 487/MAX1487收发器。
使用MAX488-MAX491可以实现全双工通信,而MAX481、MAX483、MAX485、MAX487与MAX1487则为半双工应用设计。
_______________________________应用低功耗RS-485收发器低功耗RS-422收发器电平转换器用于EMI 敏感应用的收发器工业控制局域网____________________下一代器件的特性♦容错应用MAX3430: ±80V 故障保护、失效保护、1/4单位负载、+3.3V 、RS-485收发器MAX3440E-MAX3444E: ±15kV ESD 保护、±60V 故障保护、10Mbps 、失效保护、RS-485/J1708收发器♦对于空间受限应用MAX3460-MAX3464: +5V 、失效保护、20Mbps 、Profibus RS-485/RS-422收发器MAX3362: +3.3V 、高速、RS-485/RS-422收发器,采用SOT23封装MAX3280E-MAX3284E: ±15kV ESD 保护、52Mbps 、+3V 至+5.5V 、SOT23、RS-485/RS-422、真失效保护接收器MAX3293/MAX3294/MAX3295: 20Mbps 、+3.3V 、SOT23、RS-485/RS-422发送器♦对于多通道收发器应用MAX3030E-MAX3033E: ±15kV ESD 保护、+3.3V 、四路RS-422发送器♦对于失效保护应用MAX3080-MAX3089: 失效保护、高速(10Mbps)、限摆率RS-485/RS-422收发器♦对于低电压应用MAX3483E/MAX3485E/MAX3486E/MAX3488E/MAX3490E/MAX3491E: +3.3V 供电、±15kV ESD 保护、12Mbps 、限摆率、真正的RS-485/RS-422收发器MAX481/MAX483/MAX485/MAX487–MAX491/MAX1487低功耗、限摆率、RS-485/RS-422收发器_____________________________________________________________________选择表19-0122; Rev 8; 10/03定购信息在本资料的最后给出。
MAXIM MAX3314 说明书
General DescriptionThe MAX3314 is a ±5V powered EIA/TIA-232-compati-ble interface. It has one transmitter and one receiver in a flow-through architecture. The transmitter has a low-dropout output stage providing minimum RS-232-com-patible ±3.7V output levels while driving 3k Ωand 1000pf at 460kbps. Both +5V and -5V are supplied externally.The MAX3314 has a SHDN function that reduces sup-ply current to 1µA. The transmitter is disabled and put into 3-state mode while the receiver remains active.The MAX3314 is available in 8-pin SOT23, µMAX and SO packages.________________________ApplicationsDigital Cameras PDA GPS POSTelecommunications Handy Terminals Set-Top BoxesFeatureso 1µA Low-Power Shutdown with Receiver Activeo 30µA Operating Supply Current o 460kbps (min) Data Rate o 8-Pin SOT23 Package o RS-232-Compatible LevelsMAX3314460kbps, 1µA, RS-232-Compatible Transceiver________________________________________________________________Maxim Integrated Products 1Pin ConfigurationTypical Operating Circuit19-1725; Rev 1a; 3/01Ordering InformationFor pricing, delivery, and ordering information,please contact Maxim/Dallas Direct!at 1-888-629-4642, or visit Maxim’s website at .M A X 3314460kbps, 1µA, RS-232-Compatible TransceiverABSOLUTE MAXIMUM RATINGSELECTRICAL CHARACTERISTICSStresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.V CC to GND..............................................................-0.3V to +6V V- to GND.................................................................+0.3V to -6V Input VoltagesTIN, SHDN to GND..............................................-0.3V to +6V RIN to GND.....................................................................±25V Output VoltagesTOUT to GND...............................................................±13.2V ROUT.................................................…-0.3V to (V CC + 0.3V)Short-Circuit DurationTOUT to GND........................................................ContinuousContinuous Power Dissipation8-Pin SOT23 (derate 9.7mW/°C above +70°C)...........777mW 8-Pin µMAX (derate 4.1mW/°C above +70°C)............300mW 8-Pin SO (derate 5.88mW/°C above +70°C)...............471mW Operating Temperature RangesMAX3314C_A.....................................................0°C to +70°C MAX3314E_A..................................................-40°C to +85°C Junction Temperature.....................................................+150°C Storage Temperature Range............................-65°C to +150°C Lead Temperature (soldering, 10s)................................+300°CMAX3314460kbps, 1µA, RS-232-Compatible TransceiverTIMING CHARACTERISTICSTypical Operating Characteristics(V CC = +5V, V- = -5V, 250kbps data rate, transmitter loaded with 3k Ωand C L , T A = +25°C, unless otherwise noted.)021********10005001500200025003000SLEW RATE vs. LOAD CAPACITANCELOAD CAPACITANCE (pF)S L E W R A T E (V /u s )-6-3-4-51-10-253426010005001500200025003000TRANSMITTER OUTPUT VOLTAGEvs. LOAD CAPACITANCELOAD CAPACITANCE (pF)T R A N S M I T T E R O U T P U T V O L T A G E (V )01.51.00.53.02.52.05.04.04.53.55.510005001500200025003000SUPPLY CURRENT vs. LOAD CAPACITANCELOAD CAPACITANCE (pF)S U P P L Y C U R R E N T (m A )Detailed DescriptionRS-232-Compatible DriversThe transmitter is an inverting level translator that con-verts CMOS-logic levels to EIA/TIA-232-compatible lev-els. I t guarantees data rates up to 460kbps with worst-case loads of 3k Ωin parallel with 1000pF. When SHDN is driven low, the transmitter is disabled and put into 3-state mode. The transmitter input does not have a pull-up resistor. Connect to ground if unused.RS-232-Compatible ReceiversThe MAX3314’s receiver converts RS-232 signals to CMOS-logic output levels. The receiver is rated to sig-nals up to ±25V. The MAX3314’s receiver will remain active during shutdown mode.MAX3314 Shutdown ModeI n shutdown mode, the transmitter output is put into high impedance. This reduces the supply current to 1µA. The time required to exit shutdown is less than 2.5µs. Table 1 is the shutdown logic truth table.Applications InformationCapacitor SelectionThe capacitor type used is not critical for proper opera-tion; either polarized or nonpolarized capacitors are acceptable. I f polarized capacitors are used, connect polarity as shown in the Typical Operating Circuit.Bypass V CC and V- to ground with at least 0.1µF.Transmitter Output WhenExiting ShutdownFigure 1 shows the transmitter output when exiting shut-down mode. The transmitter is loaded with 3k Ωin par-allel with 1000pF. The transmitter output displays no ringing or undesirable transients as the MAX3314comes out of shutdown. Note that the transmitter is enabled only when the magnitude of V- exceeds approximately -3V.High Data RatesThe MAX3314 maintains minimum RS-232-compatible ±3.7V transmitter output voltage even at high data rates.Figure 2 shows a transmitter loopback test circuit.Figure 3 shows the loopback test result at 120kbps, and Figure 4 shows the same test at 250kbps.Chip InformationTRANSISTOR COUNT: 128M A X 3314460kbps, 1µA, RS-232-Compatible Transceiver 4_______________________________________________________________________________________Figure 1. Transmitter Output When Exiting Shutdown or Powering Up1µs/divTIN = GNDTIN = V CCFigure 2. Loopback Test CircuitSHDN TOUTTINV CCMAX3314V-MAX3314460kbps, 1µA, RS-232-Compatible TransceiverFigure 4. Loopback Test Results at 250kbps2µs/divFigure 3. Loopback Test Results at 120kbps 5µs/div Package InformationM A X 3314460kbps, 1µA, RS-232-Compatible Transceiverimplied. Maxim reserves the right to change the circuitry and specifications without notice at any time.6_____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600©2001 Maxim Integrated ProductsPrinted USAis a registered trademark of Maxim Integrated Products.Package Information (continued)。
三洋103450P技术规格书带保险
1. Extent of the applicationThis specification is applied to the SANYO Lithium Ion Battery of the abovementioned type for a Scanner of D ongguan JN Electronics Co., Ltd..2. Battery Classification and Type2.1 Battery Classification SANYO Lithium Ion Battery2.2 Battery Type UF103450P (with Fuse)3. Nominal SpecificationsItem Specification Remark3.1 Nominal Capacity 1880mAh 0.376A discharge3.2 Nominal Voltage 3.7V 0.376A discharge3.3 End Voltage 3.0V3.4 Charging Current (Std.) 1.88A 0 ~ +40℃3.5 Charging Voltage4.20V Tolerance is ±0.03V3.6 Charging Time (Std.) 3hours3.7 Discharging Current (Std.) 0.94A -20 ~ +60℃3.8 Discharging Current (Max.)※1 2.00A 0 ~ +40℃3.9 Internal Resistance less than 100mΩAC Impedance 1kHz3.10 Weight less than 40g3.11 Surroundings less than 1month -20 ~ +50℃Temperature range less than 3months-20 ~ +40℃for shipped battery less than 1year -20 ~ +20℃Percentage of recoverable capacity80%※2※1 Maximum discharge current as a single cell state is as above stated. However after assembling to the battery pack, there is the limitation of maxi mum discharge current because of protection circuit and protection device.※2 Percentage of recoverable capacity= (discharging time after storage / Initial discharging time)×100Discharging time is measured by the disc harge at 0.376A to 3.0V end voltage after fully charged according to specification at approximately 25℃.No. Date Remark No.Date Remark(0) 20/May/’10 Issue(Tentative) (b)(a) (c)Mobile Energy Company4. Electrical CharacteristicsItem Test Method Criterion4.1 ChargeFull ChargeThe charger supply 1.88A constant current untilbattery voltage reaches 4.20V, then be changed atconstant voltage of 4.20V while tapering the chargecurrent. Charging time is 3.0 hours in all.①Within 1hour after fully charged, discharge at0.376A continuously down to 3.0V end voltage.300min. or more4.2 Capacity②Within 1hour after fully charged, discharge at0.94A continuously down to 3.0V end voltage.108min. or more4.3 Cycle Life A battery unit shall be repeated 500charge/discharge cycles, charged at CC-CV(1.88A-4.20V) for 3.0hours, discharged at 0.94A to3.0V end voltage. After 500cycles, dischargingtime is measured as s pecified in paragraph 4.2②.64min. or more①Within 1hour after fully charged at 20℃, a battery unit is stored at 0℃. Discharge time is measured by discharging at 0.94A continuously down to 3.0V end voltage. 70min. or more4.4 Temperature②Within 1hour after fully charged at 20℃,a batteryunit is stored at 60℃. Discharge time ismeasured by discharging at 0.94A continuouslydown to 3.0V end voltage.100min. or more①After fully charged, stored for 10days at 60℃and rested at room te mperature for 1hour. Discharge time is meas ured by discharging at 0.94A continuously down to 3.0V end voltage. 70min. or more4.5 Full ChargedState StorageThen next discharge time is measured asspecified in paragraph 4.2 ②.90min. or more②After fully charged, stored for 20days at 60℃and rested at room temperature for 1hour.Discharge time is meas ured by discharging at0.94A continuously down to 3.0V end voltage.60min. or moreThen next discharge time is measured asspecified in paragraph 4.2 ②.80min. or more4.6 Full DishargedState Storage After fully charged and discharged as specified inparagraph 4.2 ②, then store for 20days at 60℃and rest at room temperature for 1hour.Discharging time is measured as specified inparagraph 4.2 ②.100min. or more4.7 Drop The cell is freely dropped 6 times from a height of1m onto a flat surface of hard wood.No electrical changeSTANDARD TEST CONDITIONS:The battery used for the test mentioned above should be new one delivered a week before at most. The test s hall be performed at 25±2℃, 65±5%. It is allowed however to test at 45~85%humidity, as long as there is no big differ ence in test results. The battery used for the test without residual capacity indicator. T he grade of voltmeter and ammeter used in the test shall be higher than class 0.5 adopted in JIS C 1102(Electric Indicator).5. Design, ConstructionA battery unit shall be of the design, constr uction and physical dimensions shown in theattached drawing. (Drawing No. NUF103450P-45601)6. AppearanceThere shall be no practical damage such as cons picuous liquid electrolyte leakage, flaw electrolyte leakage, flaw, rust, dirt, and deformation. The battery must have marketability.7. ShipmentThe battery shall be shipped in about 30% charged state.It is not specified more t han 30% capacity remain at D ongguan JN Electronics Co., Ltd., because of self discharge.8. Precautions on Design of Scanner, Charger and Battery Pack8-1. Precautions on Design of Scanner and charger.①Charge・A battery must be charged with constant current-constant voltage.・In case of UF103450P, charge current must be below 2.0A/cell.・Charging voltage must be set 4.20V/cell.Concerning charge voltage tole rance of charger, charging voltage must be set below4.23V/cell. Even if the charge could be out of order, charge voltage of charger should notbe above 4.30V/cell.・Have pre-charge system in charger.In case of a battery voltage is below 3.0V, a battery should be c harged with pre-charge that current is below 0.188A. Then a battery voltage reach over 3.0V, standard charge starts. And if a battery voltage never reach to 3.0V in spec ified period (timer), charger stop charging.・Have full charge detection in charger.By timer, current detection and open circuit voltage detection, charger detects fullcharge. When charger detect full charge, charger stop charging.・ Do not use the continuous char ging (trickle charging) method.・Charger should start charging at temperature range 0~40℃②Discharge・Max discharge current is 2.0A/cell at 0~40℃.③ Over-discharge・Do not over-discharge a battery below 2.0V/cell.④Battery position in Scanner and charger.・To avoid degradation of battery performance by heat, a battery should set the place apart from heat generating electronic parts inside Scanner and charger.8-2. Precautions on Battery Pack Design.①Battery pack Shape, Mechanism and Material・Do not make the shape which easy connect to other chargers exclusive of charger.・Do not make the shape and mechanism whic h easy use another equipment exclusive of Scanner and charger.・Do not make the terminal shape which easy caus e short circuit by metal object such as necklaces, hairpins, etc. And further, have ov er current protection function to prevent outer short circuit.・Do not make the terminal shape and mechanism which connect reverse to equipment.・ Do not make the shape and mechanism whic h static electricity and water easy go through the battery pack inside.・Make the shape and mechanism which can ins pect protection circuit function (specified paragraph 8-2②) before the battery pack makes completely.・Fix cells with mold case by rib, tape, gl ue etc., but do not make damage cells (especially sealing part) by rib or sharp part of mold case.In case of the battery pack is struck by har d shock or vibration, the battery pack has possibility to cause leakage, smoke, explosion.・SANYO requests to use the gl ue for the welding of cases. If the ultra sonic is used for welding of cases, SANYO will not accept any responsibility for any defects. (In case of ultra sonic welding, SANYO recommends to c heck the functional quality after using the process of ultra sonic welding to insure the performance and reliability.)② Protection CircuitHave protection circuit function which is de scribed below inside battery pack, to insure safety of battery in case of misuse.・Overcharge ProtectionAt the voltage range 4.24~4.30V/cell by charge, overcharge protection should work. Then charge current shall be shut down.・Over discharge ProtectionAt the voltage range 2.20~2.40V/cell, over discharge protection should work.Then discharge current shall be shut down and consumption current is below 1μA.・Over discharge Current ProtectionWhen discharge current exceed about 2.0A, ov er discharge current protection should work. Then over discharge current shall be shut down.③Electric circuit・ To avoid to discharge duri ng storage, design the low cons umption current electronic circuit(e.g. Protection circuit, fuel gauge, etc) inside battery pack.④Battery connection・Do not solder onto a battery in order to avoid a damage on the battery.Weld spot welding lead plate onto battery, and solder lead wire or lead plate.⑤Precautions on label・ Write maker’s name, trade mark, maker’s nation, model number and precautions on label.Precautions are based on chapter 14.Write the precaution manual based on chapter 14.9. Storage Condition9-1 Storage Temperature and Humidity・Store the battery at temperature range -20~+40℃, low humidity and no corrosive gas atmosphere.・No condensation on the battery.Mobile Energy Company9-2 Long Period Storage・In case of long period storage (more than 3 m onths), store the battery at temperaturerange -20~+20℃, low humidity, no corrosive gas atmosphere.And in this case, charge condition of the bat t ery is Sanyo shipment charge state ordischarge state.・No condensation on the battery.10. Precautions on Handling Lithium Ion CellsIn term of shipping and assembling the battery pack, this chapter describes precautions on handling Sanyo lithium ion cells, which are assembled for Scanner’s battery packs by Dongguan JN Electronics Co., Ltd. This battery pack consists of UF103450P.10-1 Precautions on series connection of cell・When the cells are connected in series, use same lot number, same shipping charge date and same capacity rank cells, and use within 20mV voltage difference.*Lot number, shipping charge date and capacit y rank are on carton label when SANYO shipping for series.10-2 Precautions on terminals of cell・Do not over-stress or rotate at positive terminal plate and negative cap.By over-stress, it has possibility to remove the welding point and cause leakage.10-3 Inspection Before Shipment of The Battery pack・ About all battery pack, inspect voltage, internal impedance and function of protection circuit before shipment.10-4 Packing and shipping cells・When cells are re-shipped to assembling fact ory, make enough attention the packing to avoid stress by shipping.Sanyo recommends the same package shipped from Sanyo when re-shipping.Even if after open package, when re-shipping, use the same parts and materials from Sanyo for re-packing.10-5 Abnormal cell・Do not use abnormal cell which has damages by shipping stress, drop, short or something else, and which gives off electrolyte odor.11. Exemption from Warrantee・Sanyo will not be responsible for trouble occu rred by handling outside of the precautions in this specification.・Sanyo will not be responsible for trouble occu rred by matching electric circuit, battery pack, Scanner and charger.・Sanyo will be exempt from warrantee any defect cells during assembling afteracceptance.12. Other Remarks・If there are problems in this specification, Sanyo can consider to change specification after discussion.・About the things not covered by this specification, Sanyo will have discussion.・ Do not use this cell for other models or equipment.13. Standard Charging Method(1) The battery voltage fall to about 0V by stor age. If the battery is rapidly charged at thisstate, FET of a protection circuit ma y generate heat. The charger must have thepre-charge system.(2) Pre-charge current of charger should be approximatel y 0.188A. When the batteryvoltage becomes 3.0V, standard charge should be started. When the battery voltage is less than 3.0V even after the set period of timer, charging should be stopped.(3) Rapid charge is 1.88A-4.20V (Constant current-constant voltage).Charging should be suspended when the time, OCV or current is certain value.(4) The maximum current of the cell is 2.0A. Charging current of ch arger must not exceed2.0A/cell.(5) The battery could be swelled by cont inuous charging, especially under the hightemperature atmosphere.Therefore, do not use the continuous charging (trickle charging) method or the short term re-charging (supplementary charging) method.14. Safety InstructionProhibition Points on HandleThe battery pack includes the flammable objects such as the organic solvent. If the handling is missed there will be possibility that the battery rupture flames or ho t, or it will cause the deterioration or damage of battery. Please obser ve the following prohibitive matters. And also, add the protection device the equipment for fear that the trouble would affect the battery by the abnormality of equipment. In addition, ment ion the following matters as "Prohibition Points on Handle" in the instruction manual of the equipment.!Danger1. Disassemble and Reconstruction"Do not disassemble or reconstruct battery"The battery pack has safety function and protecti on circuit to avoid the danger. If they have serious damage, it will cause the generating heat, smoke, rupture or flame.2. Short-circuit"Do not short-circuit battery"Do not connect the + and - terminals with metals (such as wire). Do not carry or store the battery with metal objects (such as wire, necklace or hairpins). If the battery isshort-circuited, excessive large current will flow and then the generating heat, smoke, rupture or flame will occur. And also, it causes generating heat at metals.3. Incineration and Heating"Do not incinerate or heat the battery"These occur the melting of insulator, damage of gas release vent or safety function,or ignition on electrolyte. Above mentioned matters cause the generating heat, smoke, rupture or flame.4. Use nearby Heated Place"Do not use or leave battery nearby fire,stove or heated place(more than80℃)"In case that separator made of polymer is melted by high temperature, the internalshort-circuit occurs in individual cells and then it causes the generating heat, smoke, rupture or flame. In addition, do not use the battery under the heated place (more than 80℃) for same reason.5. Immersion"Do not immerse the battery in water or sea water,or get it wet"If the protection circuit included in the battery is broken, the battery will be charged at extreme current or vo ltage and the abnormal chemical reaction occurs in it. And then it causes the generating heat, smoke, rupture or flame.6. Charge nearby heated place"Do not charge battery nearby the fire or under the blazing sun"If the protection circuit to avoid the danger wor ks under high temperature or it is broken, the battery will be charged at abnormal current (or voltage) and abnormal chemical reaction will occur. It causes the generating heat, smoke, rupture or flame.7. Charger and Charge Condition"Do use the specified charger and observe charging requirement"If the battery is charged with unspecified c ondition (under high temperature over the regulated value, excessive high voltage or cu rrent over regulated va lue, or remodeled charger), there are cases t hat it will be overcharged or t he abnormal chemical reaction will occur in cells. It causes the generating heat, smoke, rupture or flame.8. Penetration"Do not drive a nail into the battery,strike it by hammer,or tread it"As the battery might be broken or deformed and t hen it will be short-circuited, it causes the generating heat, smoke, rupture or flame.9. Impact"Do not give battery impact or throw it"The impact might cause leakage, heat, smoke, rupt ure, and/or fire of cell in the battery. And also if the protection circuit in the battery is broken, the battery will be charged at abnormal voltage or current, and abnormal chemical reaction might occur. It might cause leakage, heat, smoke, rupture, and/or fire.10. Deformation"Do not use the battery with conspicuous damage or deformation"It causes the generating heat, smoke, rupture or flame.11. Soldering"Do not make the direct soldering on battery"As the insulator is melted by heat or the gas release vent (or safety function) is broken, it causes the generating heat, smoke, rupture or flame.12. Reverse Charge and Overdischarge"Do not reverse polarity(and terminals)"On charging, the battery is reverse-char ged and abnormal chemical reaction occurs. And also, there may be case that unexpected large current flows on discharging. These cause the generating heat, smoke, rupture or flame.13. Reversed Polarity Use"Do not reverse-charge or reverse-connect"The battery has polarity. In case the battery is not connected with charger or equipment smoothly, do not force them to connect and do check polarity of battery. If the battery is connected to opposite polarity with charger, it will be reverse-charged and abnormal chemical reaction will occur. It causes the generating heat, smoke, rupture or flame.14. Connect Battery To the Plug"Do not connect battery to the plug socket or car-cigarette-plug"Added high voltage to the battery, the excessive cu rrent will flow in it and then it will cause the generating heat, smoke, rupture or flame.15. Inappropriate Use For Other Equipment"Do not use battery for other equipment"If the battery is used for unspecified equipm ent, it will deteriorate its performance and cycle-life. At worst, abnormal curr ent will flow or battery may generate heat, smoke, rupture or flame.Mobile Energy Company16. Leakage"Do not touch a leaked battery directly"In case the leaked electrolyte gets into eyes, wash them with fresh water as soon as possible without rubbing eyes. And then, see a doctor immediately.If leave damaged eyes undone, it will cause eye-trouble.!Warning1. Mixed Use"Do not use Lithium ion battery in mixture"Do not use Lithium ion battery with the primary batteries or secondary batteries whose capacity or kinds or maker is different. If do that, the battery will be discharged or charged excessively in use. And it may cause the generating heat, smoke,rupture or flame because of the abnormal chemical reaction in cells.2. Ingestion"Keep the battery away from babies"Keep the little battery out of the reach of babies in order to avoid troubles by Swallowing. In case of swallowing the battery, see a doctor immediately.3. Charging Time"Do not continue to charge battery over specified time"If the battery is not finished charging over regulated time, le t it stop charging. There is possibility that the battery might generate heat, smoke, rupture or flame.4. Store"Do not get into a microwave or a high pressure container"It causes the generating heat, smoke, rapture or flame because of a sudden heat or damage of sealing condition of battery.5. Leakage"Do not use a leaked battery nearby fire"If the liquid leaks from the battery (or the batte ry gives out bad smell), let the battery leave from flammable objects immediately. Unless do that, the electrolyte leaked from battery will catch fire and it will cause the smoke, flame or rupture of it.6. Rust, Changing color and Deformation"Do not use an abnormal battery"In case the battery has bad smell or is generat ed its changing color or deformation or causes something wrong in using (includes charging and storage), let it take out from equipment or charger and do not use it. If an abnormal battery is used, it will generate heat, smoke, rupture or flame.File No UF103450-769Mobile Energy CompanyBattery System Development Management Department!Caution1. Use under strong sunshineDo not use or leave the battery under the blazing sun(or in heated car by sunshine).The battery may generate heat, smoke or flame. A nd also, it might cause the deterioration of battery's characteristics or cycle life.2. Static ElectricityThe battery pack has the protection circuit to avoid the danger. Do not use nearby the place where generates static electricity (more t han 100V) which gives damage to the protection circuit. If the protection circuit were broken, the battery would generat e smoke, rupture or flame.3. Charging Temperature RangeCharging temperature r ange is regulated between 0℃ and 40℃. Do not charge the battery out of recommended temperatur e range. Charging out of recommended range might cause the generating heat or serious dam age of battery. And also, it might cause the deterioration of battery's characteristics and cycle life.4. ManualPlease read the manual before using t he b attery and let it keep after reading.And also, please reread if neccesary.5. Charging MethodPlease read the manual of specified charger about charging method.6. First time useWhen the battery has rust, bad smell or someth ing abnormal at first-time-using, do not use the equipment and go to bring the battery to the shop which it was bought.7. Used by childrenIn case younger children use the battery, their parents teach how to use batteries according to the manual with care. And also, when children are using the batteries, pay attention to use it according to that or not.8. Keep Battery away from childrenKeep the battery out of the reach of younger c hildren. And also, using the battery, pay attention to be taken out it from the charger or equipment by little children.9. LeakageIf the skin or cloth is smeared with liquid from the battery, wash with fresh water.It may cause the skin inflammation.File No UF103450-769Mobile Energy CompanyBattery System Developm ent Management Department15. Warranty Period of BatteryThe warranty period of a battery is for one year after shipment. However, if a battery causes unusual operation within this period,SANYO will replace by a new battery for free as long as it is clear that the cause of the failure is in the battery manufacturing process and the battery has not been used in the abnormal condition.16. Requirement for Safety AssuranceFor the sake of safety assurance, please discuss the equipment d esign, its system and protection circuit of Lithium ion battery with SANYO in advance.And also, consult SANYO about the high rate current, rapid charge and special application such as extreme condition and / or environment.17.Effectiveness of This Specification①This specification has effectiveness for 6 months.②In case of Dongguan JN Electr onics Co., Ltd. receives permanent specification, pleaseabrogate or send back this specification to SANYO.③The standardized figure stated in this s pecification is tentative value.File No UF103450-769Mobile Energy CompanyBattery System Development Management Department。
1829型水 蒸汽冷热水值,含60%乙醛
Flow arrow shown onrear of valveApplicationThis valve is typically used in large air handling units on heating or cooling coils. This valve is suitable for use in a hydronic system with variable flow. Bronze or stainless steel trim valves can be used for steam applications, depending on actuator and close-off combination.PipingThe valves should be mounted in a weather-protected area in a location that is within the ambient limits of the actuator. Allow sufficient room for valve with actuator and for service. The preferred mounting position of the valve is with the valve stem vertical above the valve body, for maximum life. However, the assemblies can be mounted with valve stem vertical above the valve or up to 45 degrees in relation to the horizontal pipe. The actuators should never be mounted underneath the valve, as condensation can build up and result in a failure of the actuators. Do not reverse flow direction.G6125CS, 2-Way, Pressure Compensated Flanged Globe ValveD a t e c r e a t e d , 01/19/2017 - S u b j e c t t o c h a n g e . © B e l i m o A i r c o n t r o l s (U S A ), I n c .G6125CS, 2-Way, Pressure Compensated Flanged Globe ValveD a t e c r e a t e d , 01/19/2017 - S u b j e c t t o c h a n g e . © B e l i m o A i r c o n t r o l s (U S A ), I n c .† Use flexible metal conduit. Push the listed conduit fitting device over the actuator’s cable to butt against the enclosure. Screw in conduit connector. Jacket the actuators input wiring with listed flexible conduit. Properly terminate the conduit in a suitable junction box. Rated impulse Voltage 800V. Type of action 1. Control pollution degree 3.EVB24-3On/Off, Floating Point, Non-Spring Return, Linear, 24 VD a t e c r e a t e d , 11/03/2016 - S u b j e c t t o c h a n g e . © B e l i m o A i r c o n t r o l s (U S A ), I n c .Actuators may be connected in parallel. Power consumption and inputimpedance must be observed.Actuators may also be powered by 24 VDC.Actuators with plenum cable do not have numbers; use color codesinstead.Meets cULus requirements without the need of an electrical ground connection.!WARNING! LIVE ELECTRICAL COMPONENTS!During installation, testing, servicing and troubleshooting of this product, it may be necessary to work with live electrical components. Have a qualified licensed electrician or other individual who has been properly trained in handling live electrical components perform these tasks. Failure to follow all electrical safety precautions when exposed to live electrical components could result in death or serious injury.EVB24-3On/Off, Floating Point, Non-Spring Return, Linear, 24 VD a t e c r e a t e d , 11/03/2016 - S u b j e c t t o c h a n g e . © B e l i m o A i r c o n t r o l s (U S A ), I n c .。
基于多重特征提取的DNN窃电检测方法
基于多重特征提取的DNN窃电检测方法赵艳龙1 汪卓俊1 杨勇胜1 章建华1 蒋 钟2 刘一民1(1.国网浙江省电力有限公司安吉县供电公司 2.国网浙江省电力有限公司湖州供电公司)摘 要:用户窃电行为是导致非技术损失的主要原因之一,对电力公司的经济效益产生负面影响,并在严重情况下可能危及电网的稳定性。
然而,目前的研究中存在电网窃电行为特征提取方法解释性不佳的问题,导致这些方法难以在实际应用中推广。
为解决这个问题,本文提出了一种多重特征提取方法。
首先,使用主成分分析(PCA)对用电负荷曲线进行初步特征提取,然后通过分割用户曲线进一步提取特征值。
实验结果表明,相较于PCA、时频域和随机森林等方法,所提出的方法在性能上更为优越。
最后,采用深度神经网络(DNN)作为窃电检测器,获得了91.89%的检测精度。
关键词:窃电行为;大数据分析;特征提取;PCA;DNN0 引言电网的损失主要分为技术损失和非技术损失[1]。
电阻损耗、变压器损耗和老化损耗等是造成技术损失的原因,该损失难以解决[2];而窃电则是造成电网非技术损失的主要原因。
随着用户的窃电方式从早期修改电表结构、私自连接电线到篡改智能电表数据[3]。
窃电手段越来越智能化和多样化,检测窃电用户的难度也越来越大[4]。
2017年美国因为窃电造成的损失已达100亿美元[5]。
中国国家电网也在过去追回了近130亿元的窃电资金。
随着AMI的应用与普及,用电信息数据呈爆炸式增长[6]。
通过挖掘、分析和有效利用这些海量数据来检测窃电是当前研究的热点[7,8],同时对保证电网的供电质量和效率具有重要意义[9]。
阙华坤等人搭建了基于随机森林的窃电检测模型,并以南方电网数据作为输入,验证了模型的检测效果,但是没有用合理的指标加以说明模型的性能[10]。
黄刚等人提出了一种基于多层次非负稀疏编码的窃电检测方法,用爱尔兰数据集验证了其准确率[11]。
但该方法的窃电用户需要以月度单位的连续数据作为证据才能识别,当电表故障时存在用电量记录缺失,该情况会使得窃电检测效率降低。
gym103428部分题解
gym103428部分题解B考虑集合不好算,先算⼀个长为 k 的序列(可以重复)的⽅案数,然后容斥出集合的⽅案。
第⼀部分:计算序列个数。
称⼀个可重集为⼀个「块」当且仅当其所有元素在 [c ⋅2k ,c ⋅2k +1) 之间且所有元素的出现次数相同。
于是 [0,n ] 可以分解成 O(log n ) 个块。
容易发现如下两个性质:从⼀个块中选择若⼲个元素异或起来,得到的还是⼀个⼤⼩相同的块从两个块中选择各若⼲个(⾮空个)元素异或起来,得到的还是⼀个块,且⼤⼩等于较⼤的那个于是考虑枚举⼀个块 (c ,2t ),然后统计所有元素中最⼤的那个出现在这个块中的⽅案数。
注意到此时所有⼩于这个块的数全都是等价的,只需要统计其个数 sum ,然后容易写出如下的柿⼦:f k ←f k +∑x ≥1(tb −h x )2t k x 2tx sum k −x其意义即为从当前块中选取 x 个元素,然后从后⾯选取 k −x 个元素异或起来,其中恰好有 h x 个 1 的我们统计进答案,其中 h x 为⼀个只和 x 奇偶性有关的量,其表⽰了⼆进制⼤于 t 的那些位置的 1 的个数。
然后我们要对每个 k 计算这个柿⼦,暴⼒复杂度是 O(k 2log n ) 的,但是注意到这个柿⼦只和 x 奇偶性有关,于是考虑计算 (A +Bx )k mod (x 2−1) 的值,这可⽤长为 2 的 NTT 快速进⾏计算,于是复杂度优化成了 O(k log n )第⼆部分:容斥。
考虑记 g i 为 i 的答案,于是枚举⼀个 j <i ,然后计算去重后变成 j 的序列个数。
相当于 j 个元素要求出现奇数次,n −j +1 个元素要求出现偶数次,可以写出如下的两个多项式:sinh(x )=e x −e −x 2=∑i ≥0x 2i +1(2i +1)!cosh(x )=e x +e −x 2=∑i ≥0x 2i (2i )!于是要求的容斥系数就是 [x i ]sinh j (x )cosh n −j +1(x )。
伏魔记攻略——精选推荐
最初的一段时光是最难熬的了,刚开始没找师父前在百草地西北角有把绝世好剑--钨龙剑!在百草地你还能找到金蝥、珠仙草(增加人物属性最大值的药品发现后马上吃掉)。
来到百草地东面的三清宫内,进入无机阁中找到师父后在无机阁北面的墙上有勾魂散、七步蛇毒和六脏蚀毒粉。
出了无机阁在炼丹房内北面墙上的一排葫芦中可以找到两颗无忧仙丹,在两间普通弟子居中有天山盐、金蝥和一些钱币。
在厨房中有玉蓝草、茶叶蛋和天山盐,在师父居有降魔符、回神丹和定心符。
在大师兄居有些钱币和白衣,在清风居(你自己的房间)中有发带、草鞋和一些钱币,其中的一张床可以休息(补满生命)。
以上是三清宫中可以找到的所有物品了。
宫中有间药房,可以从柜台处买些青阴君带着。
伏魔洞在百草地的西面,途中有座三清坟场,别在那儿耽误时间,直接去伏魔洞。
要想拿到伏魔剑,先要打倒8个分布在8个灯洞中的护灯神兽,练成“降魔符法”后就能轻易地将其搞定。
暗器和药品等到打护剑兽时再用,不然提前用完后打护剑兽会很困难的。
要等到练成剑气术才能去搞护剑兽。
下山的途中经过摩天顶时不要忘了去西面的观星亭拿督化笛。
在经过一些错综复杂的歇息台子时可以到处找些物品。
清单如下:青铜铠、长剑、双手剑、步护腕、花布鞋、彩带、八仙石、飞蝗石、玉蓝草……在此就不一一列出了。
三清山入口出西面的草地上有玉蓝草和七杳草根。
来到忘忧村的途中有个向北的岔路口,一东一西的树上有青仙果和霸王花。
进了忘忧村后来到村子东北角的房内与主人打个招呼后在他屋内找到披风出来后去杂货店下面的房子中与主人说一下话后在屋内找到香袋去村子西北角蔡婆婆的房子中与蔡婆婆说话,她会让你救她女儿,一定要按照上述顺序才能进入蔡婆婆的房间,房间中还有一枚战狂石。
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MAX1034
20 REF 19 REFCAP 18 DVDD 17 DVDDO 16 DGND 15 DGNDO 14 DOUT 13 SCLK
SPI and QSPI are a trademarks of Motorola, Inc. MICROWIRE is a trademark of National Semiconductor Corp.
19-3574; Rev 0; 5/05
8-/4-Channel, ±VREF Multirange Inputs, Serial 14-Bit ADCs
General Description
The MAX1034/MAX1035 multirange, low-power, 14-bit, successive-approximation, analog-to-digital converters (ADCs) operate from a single +5V supply and achieve throughput rates up to 115ksps. A separate digital supply allows digital interfacing with 2.7V to 5.25V systems using the SPI™-/QSPI™-/MICROWIRE™-compatible serial interface. Partial power-down mode reduces the supply current to 1.3mA (typ). Full power-down mode reduces the power-supply current to 1µA (typ). The MAX1034 provides eight (single-ended) or four (true differential) analog input channels. The MAX1035 provides four (single-ended) or two (true differential) analog input channels. Each analog input channel is independently software programmable for seven single-ended input ranges (0 to +VREF/2, -VREF/2 to 0, 0 to +VREF, -VREF to 0, ±VREF/4, ±VREF/2, and ±VREF), and three differential input ranges (±VREF/2, ±VREF, ±2 x VREF). An on-chip +4.096V reference offers a small convenient ADC solution. The MAX1034/MAX1035 also accept an external reference voltage between 3.800V and 4.136V. The MAX1034 is available in a 24-pin TSSOP package and the MAX1035 is available in a 20-pin TSSOP package. Each device is specified for operation from -40°C to +85°C.
Industrial Control Systems Data-Acquisition Systems Avionics Robotics
*Future product—contact factory for availability.
Pin Configurations
TOP VIEW
AVDD1 1 CH0 2 CH1 3 CH2 4 CH3 5 CH4 6 CH5 7 CH6 8 CH7 9 CS 10 DIN 11 SSTRB 12 24 AGND1 23 AGND2 22 AVDD2 21 AGND3
TSSOP Pin Configurations continued at end of data sheet.
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Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.
8-/4-Channel, ±VREF Multirange Inputs, Serial 14-Bit ADCs MAX1034/MAX1035
ABSOLUTE MAXIMUM RATINGS
AVDD1 to AGND1 ....................................................-0.3V to +6V AVDD2 to AGND2 ....................................................-0.3V to +6V DVDD to DGND ........................................................-0.3V to +6V DVDDO to DGNDO ..................................................-0.3V to +6V DVDD to DVDDO ......................................................-0.3V to +6V DVDD, DVDDO to AVDD1 ........................................-0.3V to +6V AVDD1, DVDD, DVDDO to AVDD2 ..........................-0.3V to +6V DGND, DGNDO, AGND3, AGND2 to AGND1 ......-0.3V to +0.3V CS, SCLK, DIN, DOUT, SSTRB to DGNDO ............................................-0.3V to (DVDDO + 0.3V) CH0–CH7 to AGND1 ...................................................-6V to +6V REF, REFCAP to AGND1.......................-0.3V to (AVDD1 + 0.3V) Continuous Current (any pin) ...........................................±50mA Continuous Power Dissipation (TA = +70°C) 20-Pin TSSOP (derate 11mW/°C above +70°C) ..........879mW 24-Pin TSSOP (derate 12.2mW/°C above +70°C) .......976mW Operating Temperature Range ...........................-40°C to +85°C Junction Temperature .....................................................+150°C Storage Temperature Range .............................-65°C to +150°C Lead Temperature (soldering, 10s) .................................+300°C
MAX1034/MAX1035
Ordering Information
PART MAX1034EUG* MAX1035EUP TEMP RANGE -40°C to +85°C -40°C to +85°C PINCHANNELS PACKAGE 24 TSSOP 20 TSSOP 8 4
Applications
PARAMETER DC ACCURACY (Notes 1, 2) Resolution Integral Nonlinearity Differential Nonlinearity Transition Noise INL DNL No missing codes External or internal reference Single-ended inputs Offset Error Differential inputs (Note 3) Channel-to-Channel Gain Matching Channel-to-Channel Offset Error Matching Offset Temperature Coefficient Gain Error Gain Temperature Coefficient Unipolar Endpoint Overlap Unipolar or bipolar Unipolar or bipolar Unipolar Bipolar Unipolar Bipolar Unipolar Bipolar Negative unipolar full scale to positive unipolar zero-scale 0 1.5 1.0 5 Unipolar Bipolar Unipolar Bipolar 0.5 2 0 -1.0 0 -2 0.025 1.0 10 5 ±0.5 ±0.3 ±10 ±10 ±20 ±20 %FSR mV ppm/°C %FSR ppm/°C LSB mV 14 ±0.25 ±1 ±1 Bits LSB LSB LSBRMS SYMBOL CONDITIONS MIN TYP MAX UNITS