MAX4173F H T的区别

ams 4173标准摘要：1.AMS 4173 标准的概述2.AMS 4173 标准的主要内容3.AMS 4173 标准的应用领域4.AMS 4173 标准的重要性正文：AMS 4173 标准是由美国材料和试验协会（ASTM）制定的一种标准，全称为“Standard Specification for Tungsten and Tungsten Alloy Bars and Wires”，即“钨和钨合金棒和线材的标准规格”。

这个标准主要规定了钨和钨合金棒和线材的尺寸、形状、允许偏差、表面光洁度、机械性能、化学成分等技术要求。

AMS 4173 标准的主要内容包括：1.尺寸和形状：标准规定了钨和钨合金棒和线材的直径、长度、方形度、圆度等尺寸和形状要求。

2.允许偏差：标准规定了钨和钨合金棒和线材的壁厚、直径、长度等允许偏差。

3.表面光洁度：标准规定了钨和钨合金棒和线材的表面光洁度要求，包括表面粗糙度、光泽等。

4.机械性能：标准规定了钨和钨合金棒和线材的拉伸强度、屈服强度、硬度等机械性能要求。

5.化学成分：标准规定了钨和钨合金棒和线材的化学成分要求，包括钨、铜、银、镍等元素的含量。

AMS 4173 标准的应用领域非常广泛，主要应用于航空航天、军事、核能、电子、化工等高技术领域。

例如，钨合金棒和线材可以作为航空航天发动机的高温部件，也可以作为核能反应堆的控制棒，还可以作为电子器件的焊接材料等。

AMS 4173 标准的重要性不言而喻。

首先，这个标准为钨和钨合金棒和线材的生产和检验提供了一个统一的技术规范，保证了产品的质量和可靠性。

其次，这个标准有助于提高钨和钨合金棒和线材的生产效率和经济效益，降低了生产成本。

最后，这个标准有助于推动钨和钨合金棒和线材的技术进步和创新，促进了新材料、新工艺、新技术的发展。

基于LTC3780的超级电容恒功率充电分析作者：徐铭伟刘畅任建新来源：《中国科技博览》2019年第09期[摘要]分析了超级电容分别在CC、CV和恒功率模式下的充电速率。

介绍了Linear公司的四功率开关 Buck-Boost控制器LTC3780的工作原理及应用场合，并用其设计了一款针对超级电容的恒功率充电装置，然后对电路进行仿真，分析相关参数。

[关键词]LTC3780、恒功率、Buck-Boost、仿真中图分类号：TM910.6 文献标识码：A 文章编号：1009-914X（2019）09-0220-010 引言超级电容是一种新兴的具有特殊性能的电源，它在功率密度、能量转换效率、使用寿命、放电电流等指标上具有明显的优势。

鉴于此，超级电容在许多场合中使用广泛，其成本极低、容量大、功率密度极高的特点可以满足一定时间内，持续的电流输出，因此，在一些小功率、短时间的场合，可以作为备用电源使用。

其放电电流较大的特点可以对大功率设备的启动和负载突变的情况下提供瞬时高功率输出，以满足设备的正常运行。

是现代电力电子领域不可或缺的能量存储装置。

1 超级电容的等效电路模型超级电容的等效电路模型一般使用阻感容等基本的电路元器件来描述其电气特性，等效电路如图1.1所示。

如图，超级电容的等效模型由串联等效电阻（ESR）和等效电容构成。

在对超级电容充电或放电时测量两端电压，其端电压由充电或放电电流在串联等效电阻上产生的电压和电容自身的电压构成。

纯电容部分电压由下式所得：I=C·dv=串联等效电阻上的电压由下式所得：V=I·R因此，在超级电容充电或放电时，两端电压的变化量为： dv= +I·R2 超级电容在不同充电模式下的充电速率2.1 恒压和恒流模式下的充电速率比较恒压（CV）充电是指在电容两端加以恒定的电压进行充电，直至两端电压达到目标电压。

由于超级电容在充电的过程中，电压不断上升，使其与电源输出端电压的压差Ua-b减小，从而使充电电流逐渐减小。

四相五线步进电机有哪些型号
步进电机是一种电动机，它通过每步旋转一个固定的角度来执行离散的运动，通常被广泛应用于各种自动化设备中。

四相五线步进电机是一种常见的步进电机类型，其结构和特性在不同型号之间略有差异，下面将介绍几种常见的四相五线步进电机型号。

1.NEMA 17： NEMA 17是一种标准规格的四相五线步进电机，其外形尺寸为42mm
x 42mm。

通常用于3D打印机、数控机床等设备中，具有较好的精度和扭矩表现。

2.42BYG： 42BYG步进电机是一类直径为42mm的四相五线步进电机，在机械精度
和工作效率方面表现优异，常见于自动化设备和医疗器械中的应用。

3.NEMA 14： NEMA 14是一种较小尺寸的四相五线步进电机，外形尺寸为35.5mm
x 35.5mm。

尽管体积较小，但其高扭矩和低噪音的特点使其适用于一些空间受限
的场合。

4.17HS： 17HS型号是一种直径为42mm的四相五线步进电机，具有较稳定的性能
和较高的可靠性，常见于自动门控制系统、机器人等领域。

5.NEMA 23： NEMA 23是一种大尺寸的四相五线步进电机，外形尺寸为57mm x
57mm。

适用于需要承受较大负载和高精度要求的工业设备，如自动化生产线、激光切割机等。

通过以上介绍，可以看出四相五线步进电机在不同型号中都拥有各自的特点和适用领域。

选择适合的型号取决于具体的应用需求，包括所需扭矩、精度要求、空间限制等因素。

在实际应用中，应根据具体情况选择最合适的步进电机型号，以确保设备的稳定性和性能表现。

1。

不锈钢174ph密度-回复不锈钢174PH密度不锈钢174PH是一种特殊的不锈钢合金，其密度是多少呢？在这篇文章中，我们将一步一步回答这个问题，并深入探讨不锈钢174PH的性质和应用。

首先，我们来了解一下不锈钢的定义。

不锈钢是一种具有高抗腐蚀性能的合金材料，主要由铁、铬、镍和其他合金元素组成。

它在不同的环境中都能保持其表面光滑和耐用性能。

不锈钢174PH是在普通不锈钢的基础上，通过合金化处理得到的一种高强度、高硬度的不锈钢合金。

它通常含有17的铬和4的镍，以及少量的碳、铜和钼等元素。

不锈钢174PH由于其出色的机械性能和耐蚀性能，在航空航天、石油化工、医疗器械等领域得到广泛应用。

接下来，我们来回答问题，不锈钢174PH的密度是多少？不锈钢174PH 的密度为7.75克/立方厘米。

这个数值表明了单位体积内不锈钢174PH 的质量，它同时也是衡量不锈钢材料重量的重要指标之一。

那么，为什么不锈钢174PH的密度较高呢？这是由于其成分和结构决定的。

第一，高含量的铬元素提供了不锈钢174PH优异的抗腐蚀性能，但也增加了其密度。

第二，不锈钢174PH中的钼元素提高了其硬度和强度，但同样也增加了其密度。

除了密度，不锈钢174PH还有许多其他的性质值得我们关注。

首先是其优异的耐腐蚀性能。

不锈钢174PH可以在高温、酸碱等恶劣环境中保持良好的耐蚀性，这使得它成为一种理想的材料选择。

其次是其高强度和高硬度。

不锈钢174PH通过热处理可以达到非常高的尺寸稳定性和机械性能，使其在高压和高温环境下能够承受较大的力。

此外，不锈钢174PH 还具有良好的韧性和抗冲击性。

最后，让我们来看看不锈钢174PH的应用领域。

由于其独特的物理和化学性质，不锈钢174PH在航空航天、石油化工、海洋工程、医疗器械等领域都有广泛的应用。

例如，它常用于制造航空航天设备中的零部件，如引擎零件、涡轮叶片等。

在石油化工领域，不锈钢174PH可以用于生产化学反应器、储罐和管道等设备，以防止腐蚀和泄漏。

创维东芝超级单片机使用的微处理器的代用关系创维东芝超级单片机心有：3T30、4T30、5T30、3T36、4T36、5T36等机心，是创维公司与日本东芝公司联合开发的新一代超级单片集成电路彩电机心。

该机心采用了东芝公司最新推出的超大规模集成心片，有：TMPA8803CSN、TMPA8823CSN、TMPA8808CSN、TMPA8809CSN、TMPA8829CSN等。

在创维东芝超级单片机心中，3T30、3T36、4T36是同一种机心，使用的软件基本相同，对应的超级单片型号是’rMPA8803CSN或者TMPA8823CSN。

TMPA8823CSN是TMPA8803CSN软件升级后的版本，但二者配套使用的存储器不同，不能互换使用。

4T30、5T36、5T30是同一种机心，使用的软件基本相同(电源电路不同)，对应的超级单片型号是TMPA8808CSN、TMPA8809CSN 或者TMPA8829CSN。

TPMA8829C8N是TMPA8809CSN软件升级后的版本，其存储器的代换原则配套使用的存储器不同，不能互换使用。

创维的83703可代8370183735可代83702和837325P30的83731没有可代换的。

83703还能带83702，但是会出现无声或者白屏把OP2调成28即可。

创维T系列机型CPU的代换目前T系列机芯共有5种CPU，其分别为：1、87CM38N-3856，在3T01、4T01机芯上使用，其可存储100个频道。

2、87CM38N-1N86，在21寸9000系列机芯上使用，可存储256个频道，并带有游戏功能。

3、87CM38N-1N10，在25寸5T10机芯上使用，可存储228个频道。

4、87CM38N-1R02，在29寸5T10、5T20机芯一使用，可存储256个频道，带有游戏功能。

5、87TPS38N，此种为OTP产品，为T系列最早使用的CPU，在25寸5T10机芯上使用，有两种，其分别为可存储228和256个频道。

17-4ph作为弹簧的标准17-4ph钢是一种不锈钢材料，具有优异的力学性能和耐腐蚀性。

它常被用作弹簧的材料，以提供高弹性和耐久性。

在本文中，我们将介绍17-4ph钢的特点以及它为什么适合作为弹簧的标准材料。

首先，我们来了解一下17-4ph钢的化学成分和物理性能。

它主要由铁、铬、镍、铜和钛组成，其中铁和铬是主要的成分，占比分别为50％和17％。

此外，镍和铜的含量分别为4％和3％。

钛的含量则低于1％。

这种化学成分使得17-4ph钢具有良好的耐腐蚀性和高强度。

它可以在高温和潮湿环境中长时间使用，并且不容易生锈或受到化学物质损害。

其次，17-4ph钢的物理性能也使其成为理想的弹簧材料。

它具有优异的弹性模量和抗拉强度。

弹性模量是弹性材料在受力时产生的变形程度与作用力之间的关系。

17-4ph钢的弹性模量高，使得它能够承受更大的变形，同时能够恢复到原始的形状和长度。

抗拉强度是材料在拉伸过程中抵抗外部力的能力。

17-4ph钢具有很高的抗拉强度，在受力时不易断裂或变形。

另外，17-4ph钢的硬度也是它适合作为弹簧材料的特点之一。

它可以通过热处理来改变硬度和强度，从而满足不同应用的需求。

常见的热处理方式包括固溶处理和时效处理。

固溶处理是将17-4ph钢加热到高温，然后迅速冷却，以使其变得更加硬度和强度。

时效处理是将固溶处理后的材料在中温下保持一定的时间，以使其维持所需的硬度和强度。

这种硬度使得17-4ph钢能够承受高压力和重复变形的要求，因此非常适合作为弹簧材料。

另一个值得注意的特点是17-4ph钢具有优异的耐磨性。

它的表面硬度高，不容易被划伤或磨损。

这使得17-4ph弹簧具有长寿命和稳定的性能，即使在频繁使用的条件下也能保持其原有的弹性和强度。

除了上述特点，17-4ph钢还具有良好的可焊性和加工性。

它可以通过常规的焊接和加工工艺进行加工，从而满足各种设计要求和应用需求。

这使得17-4ph钢能够在不同类型的弹簧中得到广泛应用，如工业设备、汽车、航空航天等领域。

General DescriptionThe MAX4372 low-cost, precision, high-side current-sense amplifier is available in a tiny, space-saving SOT23 5-pin package. Offered in three gain versions (T = 20V/V, F = 50V/V, and H = 100V/V), this device oper-ates from a single 2.7V to 28V supply and consumes only 30μA. It features a voltage output that eliminates the need for gain-setting resistors and is ideal for today’s notebook computers, cell phones, and other systems where battery/ DC current monitoring is critical.High-side current monitoring is especially useful in bat-tery-powered systems since it does not interfere with the ground path of the battery charger. The input common-mode range of 0 to 28V is independent of the supply volt-age and ensures that the current-sense feedback remains viable even when connected to a 2-cell battery pack in deep discharge.The user can set the full-scale current reading by choos-ing the device (T, F, or H) with the desired voltage gain and selecting the appropriate external sense resistor. This capability offers a high level of integration and flex-ibility, resulting in a simple and compact current-sense solution. For higher bandwidth applications, refer to the MAX4173T/F/H data sheet.Applications●Power-Management Systems●General-System/Board-Level Current Monitoring●Notebook Computers●Portable/Battery-Powered Systems●Smart-Battery Packs/Chargers●Cell Phones●Precision-Current Sources Features●Low-Cost, Compact Current-Sense Solution●30μA Supply Current● 2.7V to 28V Operating Supply●0.18% Full-Scale Accuracy●0.3mV Input Offset Voltage●Low 1.5Ω Output Impedance●Three Gain Versions Available• 20V/V (MAX4372T)• 50V/V (MAX4372F)• 100V/V (MAX4372H)●High Accuracy +2V to +28V Common-Mode Range,Functional Down to 0V, Independent of SupplyVoltage●Available in a Space-Saving 5-Pin SOT23 Packageand 3 x 2 UCSP™ (1mm x 1.5mm) Package Ordering Information appears at end of data sheet.UCSP is a trademark of Maxim Integrated Products, Inc.19-1548; Rev 5; 5/11+Denotes lead(Pb)-free/RoHS-compliant package.T = Tape and reel.*Note: Gain values are as follows: 20V/V for the T version,50V/V for the F version, and 100V/V for the H version. Current-Sense Amplifier with Voltage OutputPin ConfigurationsOrdering InformationPARTTEMPRANGEPIN-PACKAGETOPMARK MAX4372T EUK+T-40°C to +85°C 5 SOT23ADIU MAX4372TESA+-40°C to +85°C8 SO—MAX4372TEBT+T-40°C to +85°C 3 x 2 UCSP ACXV CC , RS+, RS- to GND .........................................-0.3V to +30V OUT to GND ..........................................................-0.3V to +15V Differential Input Voltage (V RS+ - V RS-) .............................±0.3V Current into Any Pin .........................................................±10mA Continuous Power Dissipation (T A = +70°C)5-Pin SOT23 (derate 3.9mW/°C above +70°C) .......312.6mW 8-Pin SO (derate 7.4mW/°C above +70°C) ..............588.2mW 3 x 2 UCSP (derate 3.4mW/°C above +70°C) .........273.2mWOperating Temperature Range ...........................-40°C to +85°C Storage Temperature Range ............................-65°C to +150°C Lead Temperature (soldering, 10s) .................................+300°C Soldering Temperature (reflow) .......................................+260°C(V RS+ = 0 to 28V, V CC = 2.7V to 28V, V SENSE = 0V, R LOAD = 1MΩ, T A = T MIN to T MAX , unless otherwise noted. Typical values are at T A = +25°C.) (Note 1)Current-Sense Amplifier with Voltage OutputAbsolute Maximum RatingsStresses 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.Electrical CharacteristicsPARAMETERSYMBOL CONDITIONSMIN TYPMAX UNITS Operating Voltage Range (Note 2)V CC 2.728V Common-Mode Input Range (Note 3)V CMR 028V Common-Mode Rejection CMR V RS+ > 2V85dB Supply Current I CC V RS+ > 2V, V SENSE = 5mV 3060μA Leakage CurrentI RS+, I RS-V CC = 0V, V RS+ = 28V 0.051.2μAInput Bias CurrentI RS+V RS+ > 2V 01μAV RS+ ≤ 2V -25+2I RS-V RS+ > 2V 02V RS+ ≤ 2V-50+2Full-Scale Sense Voltage (Note 4)V SENSEGain = 20V/V or 50V/V 150mV Gain = 100V/V 100Input Offset Voltage (Note 5)V OST A = +25°CV CC = V RS+ = 12V MAX4372_ESA 0.3±0.8mVMAX4372_EUK, _EBT 0.3±1.3T A = T MIN to T MAX V CC = V RS+ = 12VMAX4372_ESA ±1.1MAX4372_EUK, _EBT±1.9Full-Scale Accuracy (Note 5)V SENSE = 100mV, V CC = 12V,V RS+ = 12V, T A = +25°C (Note 7)±0.18±3%Total OUT Voltage Error (Note 6)V SENSE = 100mV, V CC = 12V,V RS+ = 12V (Note 7)±6V SENSE = 100mV, V CC = 28V,V RS+ = 28V (Note 7)±0.15±7V SENSE = 100mV, V CC = 12V,V RS+ = 0.1V (Note 7)±1±28V SENSE = 6.25mV, V CC = 12V,V RS+ = 12V (Note 8)±0.15(V RS+ = 0 to 28V, V CC = 2.7V to 28V, V SENSE = 0V, R LOAD = 1MΩ, T A = T MIN to T MAX , unless otherwise noted. Typical values are at T A = +25°C.) (Note 1)Note 1: All devices are 100% production tested at T A = +25°C. All temperature limits are guaranteed by design.Note 2: Guaranteed by PSR test.Note 3: Guaranteed by OUT voltage error test.Note 4: Output voltage is internally clamped not to exceed 12V.Note 5: V OS is extrapolated from the gain accuracy tests.Note 6: Total OUT voltage error is the sum of gain and offset voltage errors.Note 7: Measured at I OUT = -500μA (R LOAD = 4kΩ for gain = 20V/V, R LOAD = 10kΩ for gain = 50V/V, R LOAD = 20kΩ for gain = 100V/V).Note 8: 6.25mV = 1/16 of 100mV full-scale voltage (C/16).Note 9: The device does not reverse phase when overdriven.Current-Sense Amplifier with Voltage OutputElectrical Characteristics (continued)PARAMETERSYMBOL CONDITIONSMINTYP MAXUNITSOUT Low Voltage(MAX4372T, MAX4372F)V OLV CC = 2.7V,V SENSE = -10mV, V RS+ = 28V I OUT = 10μA 2.6mVI OUT = 100μA 965OUT Low Voltage (MAX4372H)V OLV CC = 2.7V,V SENSE = -10mV, V RS+ = 12VI OUT = 10μA 2.6mVI OUT = 100μA965OUT High VoltageV CC - V OHV CC = 2.7V, I OUT = -500μA, V SENSE = 250mV, V RS+ = 28V0.10.25V-3dB Bandwidth BWV RS+ = 12V,V CC = 12V,C LOAD = 10pFV SENSE = 20mV,gain = 20V/V275kHzV SENSE = 20mV,gain = 50V/V 200V SENSE = 20mV,gain = 100V/V 110V SENSE = 6.25mV50GainMAX4372T20V/VMAX4372F 50MAX4372H100Gain AccuracyV SENSE = 20mV to 100mV, V R S + = 12V T A = +25°C ±0.25±2.5%T A = -40°C to +85°C ±5.5OUT Settling Time to 1% of Final ValueGain = 20V/V, V CC = 12V, V RS+ = 12V, C LOAD = 10pFV SENSE = 6.25mV to 100mV20µsV SENSE = 100mV to 6.25mV20Capacitive-Load Stability No sustained oscillations1000pF OUT Output Resistance R OUT V SENSE = 100mV 1.5ΩPower-Supply Rejection PSRV OUT = 2V, V RS+ > 2V7585dB Power-Up Time to 1% of Final ValueV CC = 12V, V RS+ = 12V,V SENSE = 100mV, C LOAD = 10pF 0.5ms Saturation Recovery Time (Note 9)V CC = 12V, V RS+ = 12V, C LOAD = 10pF0.1ms(V CC = 12V, V RS+ = 12V, V SENSE = 100mV, T A = +25°C, unless otherwise noted.)Current-Sense Amplifier with Voltage OutputTypical Operating Characteristics25.027.530.032.535.0SUPPLY CURRENT vs. SUPPLY VOLTAGESUPPLY VOLTAGE (V)S U P P L Y C U R R E N T (µA )121648202428-1.2-0.8-1.0-0.2-0.4-0.60.40.200.6010515202530TOTAL OUTPUT ERROR vs. SUPPLY VOLTAGESUPPLY VOLTAGE (V)O U T P U T E R R O R (%)00.20.40.60.81.01.21.41.610515202530TOTAL OUTPUT ERROR vs. COMMON-MODE VOLTAGECOMMON-MODE VOLTAGE (V)O U T P U T E R R O R (%)510152025303540-401060-153585SUPPLY CURRENT vs. TEMPERATURETEMPERATURE (°C)S U P P L Y C U R R E N T (µA )-1.0-0.50.501.01.5010050150200250300TOTAL OUTPUT ERROR vs. V SENSEV SENSE (mV)O U T P U T E R R O R (%)-1.0-0.9-0.8-0.7-0.6-0.5-0.4-0.3-0.2-0.10GAIN ACCURACY vs. TEMPERATURETEMPERATURE (°C)G A I N A C C U R A C Y (%)-401060-15358528.029.028.530.029.531.531.030.532.0SUPPLY CURRENTvs. COMMON-MODE VOLTAGECOMMON-MODE VOLTAGE (V)S U P P L Y C U R R E N T (µA )-45-90100100k10k 1k POWER-SUPPLY REJECTIONvs. FREQUENCY-75-85-55-65-40-70-80-50-60M A X 4372T t o c 06FREQUENCY (Hz)P S R (d B )-1.0-0.8-0.6-0.4-0.200.20.40.60.81.0-401060-153585TOTAL OUTPUT ERROR vs. TEMPERATURETEMPERATURE (°C)T O T A L O U T P U T E R R O R (%)(V CC = 12V, V RS+ = 12V, V SENSE = 100mV, T A = +25°C, unless otherwise noted.)Current-Sense Amplifier with Voltage OutputTypical Operating Characteristics (continued)V OUTV SENSE600mV200mV30mV10mV MAX4372TSMALL-SIGNAL TRANSIENT RESPONSEMAX4372T toc1020µs/div V OUTV SENSE1V3V50mV 150mV MAX4372TLARGE-SIGNAL TRANSIENT RESPONSEMAX4372T toc1320µs/divV OUTV SENSE 010V0100mV MAX4372HLARGE-SIGNAL TRANSIENT RESPONSE20µs/divMAX4372T toc15V OUTV SENSE2.5V7.5V50mV 150mVMAX4372FLARGE-SIGNAL TRANSIENT RESPONSE20µs/divMAX4372T toc143-81k100k10k1MSMALL-SIGNAL GAIN vs. FREQUENCY-7FREQUENCY (Hz)G A I N (d B)-6-5-4-3-2-1012V OUTV SENSE 1.5V0.5V30mV 10mVMAX4372FSMALL-SIGNAL TRANSIENT RESPONSEMAX4372T toc1120µs/div V OUTV SENSE 3V1V30mV10mV MAX4372HSMALL-SIGNAL TRANSIENT RESPONSEMAX4372T toc1220µs/divDetailed DescriptionThe MAX4372 high-side current-sense amplifier features a 0 to 28V input common-mode range that is indepen-dent of supply voltage. This feature allows the monitoring of current flow out of a battery in deep discharge, and also enables high-side current sensing at voltages far in excess of the supply voltage (V CC).Current flows through the sense resistor, generating a sense voltage (Figure 1. Functional Diagram). Since A1’s inverting input is high impedance, the voltage on the negative terminal equals V IN - V SENSE. A1 forces its positive terminal to match its negative terminal; therefore, the voltage across R G1 (V IN - V1-) equals V SENSE. This creates a current to flow through R G1 equal to V SENSE/ R G1. The transistor and current mirror amplify the current by a factor of β. This makes the current flowing out of the current mirror equal to:I M = β V SENSE/R G1A2’s positive terminal presents high impedance, so this current flows through R GD, with the following result:V2+ = R GD β x V SENSE/R G1R1 and R2 set the closed-loop gain for A2, which ampli-fies V2+, yielding:V OUT = R GD x β x V SENSE/R G1 (1 + R2/R1)The gain of the device equals:OUT SEN G1SE RGD x (1 + R2/R1)V V/Rβ=Applications Information Recommended Component ValuesThe MAX4372 operates over a wide variety of current ranges with different sense resistors. Table 1 lists com-mon resistor values for typical operation of the MAX4372.Choosing R SENSEGiven the gain and maximum load current, select R SENSE such that V OUT does not exceed V CC - 0.25V or 10V. To measure lower currents more accurately, use a high value for R SENSE. A higher value develops a higher sense volt-age, which overcomes offset voltage errors of the internal current amplifier.In applications monitoring very high current, ensure R SENSE is able to dissipate its own I2R losses. If the resistor’s rated power dissipation is exceeded, its value may drift or it may fail altogether, causing a differential voltage across the terminals in excess of the absolute maximum ratings.Figure 1. Functional DiagramCurrent-Sense Amplifier with Voltage OutputPin/Bump DescriptionPIN BUMPNAME FUNCTIONSOT23SO UCSP13A2GND Ground24A3OUT Output Voltage. V OUT is proportional to the magnitude of V SENSE (V RS+ - V RS-).31A1V CC Supply Voltage. Use at least a 0.1μF capacitor to decouple V CC from fast transients.48B1RS+Power Connection to the External Sense Resistor56B3RS-Load-Side Connection to the External Sense Resistor —2, 5, 7—N.C.No Connection. Not internally connected.Using a PC Board Trace as R SENSEIf the cost of R SENSE is an issue and accuracy is not criti-cal, use the alternative solution shown in Figure 2. This solution uses copper PC board traces to create a sense resistor. The resistivity of a 0.1in wide trace of 2oz copper is about 30mΩ/ft. The resistance temperature coefficient of copper is fairly high (approximately 0.4%/°C), so sys-tems that experience a wide temperature variance must compensate for this effect. In addition, self-heating intro-duces a nonlinearity error. Do not exceed the maximum power dissipation of the copper trace.For example, the MAX4372T (with a maximum load cur-rent of 10A and an R SENSE of 5mΩ) creates a full-scale V SENSE of 50mV that yields a maximum V OUT of 1V. R SENSE, in this case, requires about 2in of 0.1in wide copper trace.UCSP Applications InformationFor the latest application details on UCSP construction, dimensions, tape carrier information, printed circuit board techniques, bump-pad layout, and recommended reflow temperature profile, as well as the latest information on reliability testing results, go to the Maxim’s website at /ucsp to find the Application Note: UCSP—A Wafer-Level Chip-Scale Package.Figure 2. Connections Showing Use of PC BoardTable 1. Recommended Component ValuesCurrent-Sense Amplifier with Voltage OutputFULL-SCALE LOAD CURRENT,I LOAD (A)CURRENT-SENSERESISTOR,R SENSE (mΩ)GAIN(V/V)FULL-SCALE OUTPUTVOLTAGE (FULL-SCALEV SENSE = 100mV),V OUT (V)0.1100020 2.0 50 5.0 10010.0110020 2.0 50 5.0 10010.052020 2.0 50 5.0 10010.0101020 2.0 50 5.0 10010.0Current-Sense Amplifier with Voltage Output Ordering Information (continued)Pin Configurations (continued)PARTTEMPRANGEPIN-PACKAGETOPMARKMAX4372F EUK+T-40°C to +85°C 5 SOT23ADIV MAX4372FESA+-40°C to +85°C8 SO—MAX4372FEBT+T-40°C to +85°C 3 x 2 UCSP ACX MAX4372H EUK+T-40°C to +85°C 5 SOT23ADIW MAX4372HESA+-40°C to +85°C8 SO—MAX4372HEBT+T-40°C to +85°C 3 x 2 UCSP ACZChip InformationPROCESS: BiCMOS+Denotes lead(Pb)-free/RoHS-compliant package. T = Tape and reel.Current-Sense Amplifier with Voltage Output Package InformationFor the latest package outline information and land patterns (footprints), go to /packages. Note that a “+”, “#”, or “-” in the package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the package regardless of RoHS status.PACKAGE TYPE PACKAGE CODE OUTLINE ND PATTERN NO.5 SOT23U5+121-005790-01748 SO S8+221-004190-00965 UCSP B6+221-0097—Note: MAX4372_EBT uses package code B6-2.Current-Sense Amplifier with Voltage Output Package Information (continued)For the latest package outline information and land patterns (footprints), go to /packages. Note that a “+”, “#”, or “-” in the package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the package regardless of RoHS status.Current-Sense Amplifier with Voltage Output Package Information (continued)For the latest package outline information and land patterns (footprints), go to /packages. Note that a “+”, “#”, or “-” in the package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the package regardless of RoHS status. Maxim Integrated │11Maxim Integrated cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim Integrated product. No circuit patent licenses are implied. Maxim Integrated reserves the right to change the circuitry and specifications without notice at any time. The parametric values (min and max limits) shown in the Electrical Characteristics table are guaranteed. Other parametric values quoted in this data sheet are provided for guidance.Maxim Integrated and the Maxim Integrated logo are trademarks of Maxim Integrated Products, Inc.Current-Sense Amplifier with Voltage Output© 2011 Maxim Integrated Products, Inc. │ 12Revision HistoryREVISIONNUMBERREVISION DATE DESCRIPTION PAGES CHANGED 47/09Updated feature in accordance with actual performance of the product 155/11Updated V RST conditions to synchronize with tested material and addedlead-free designation 1–3, 8For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642, or visit Maxim Integrated’s website at .。