SFAF1603G中文资料

汉字代码拼音类型五笔输入是否常用使用地区阿1602a简体字bskg是全宇宙啊1601a简体字kbsk是全宇宙吖6325a简体字kuhh是全宇宙嗄6436a简体字kdht是全宇宙腌7571a简体字edjn是全宇宙锕7925a简体字qbsk是全宇宙爱1614ai简体字epdc是全宇宙埃1603ai简体字fctd是全宇宙碍1613ai简体字djgf是全宇宙矮1611ai简体字tdtv是全宇宙挨1604ai简体字rctd是全宇宙唉1606ai简体字kctd是全宇宙哎1605ai简体字kaqy是全宇宙哀1607ai简体字yeu是全宇宙皑1608ai简体字rmnn是全宇宙癌1609ai简体字ukkm是全宇宙蔼1610ai简体字ayjn是全宇宙艾1612ai简体字aqu是全宇宙隘1615ai简体字buwl是全宇宙捱6263ai简体字rdff是全宇宙嗳6440ai简体字kepc是全宇宙嗌6441ai简体字kuwl是全宇宙嫒7040ai简体字vepc是全宇宙瑷7208ai简体字gepc是全宇宙暧7451ai简体字jepc是全宇宙砹7733ai简体字daqy是全宇宙锿7945ai简体字qyey是全宇宙霭8616ai简体字fyjn是全宇宙安1618an简体字pvf是全宇宙按1620an简体字rpvg是全宇宙暗1621an简体字jujg是全宇宙岸1622an简体字mdfj是全宇宙案1624an简体字pvsu是全宇宙俺1619an简体字wdjn是全宇宙氨1617an简体字rnpv是全宇宙胺1623an简体字epvg是全宇宙鞍1616an简体字afpv是全宇宙谙5847an简体字yujg是全宇宙埯5991an简体字fdjn是全宇宙揞6278an简体字rujg是全宇宙犴6577an简体字qtfh是全宇宙庵6654an简体字ydjn是全宇宙桉7281an简体字spvg是全宇宙铵7907an简体字qpvg是全宇宙鹌8038an简体字djng是全宇宙黯8786an简体字lfoj是全宇宙昂1626ang简体字jqbj是全宇宙肮1625ang简体字eymn是全宇宙盎1627ang简体字mdlf是全宇宙凹1628ao简体字mmgd是全宇宙奥1634ao简体字tmod是全宇宙敖1629ao简体字gqty是全宇宙熬1630ao简体字gqto是全宇宙翱1631ao简体字rdfn是全宇宙袄1632ao简体字putd是全宇宙傲1633ao简体字wgqt是全宇宙懊1635ao简体字ntmd是全宇宙澳1636ao简体字itmd是全宇宙坳5974ao简体字fxln是全宇宙拗6254ao简体字rxln是全宇宙嗷6427ao简体字kgqt是全宇宙岙6514ao简体字tdmj是全宇宙廒6658ao简体字ygqt是全宇宙遨6959ao简体字gqtp是全宇宙媪7033ao简体字vjlg是全宇宙骜7081ao简体字gqtc是全宇宙獒7365ao简体字gqtd是全宇宙聱8190ao简体字gqtb是全宇宙螯8292ao简体字gqtj是全宇宙鏊8643ao简体字gqtq是全宇宙鳌8701ao简体字gqtg是全宇宙鏖8773ao简体字ynjq是全宇宙把1649ba简体字rcn是全宇宙八1643ba简体字wty是全宇宙吧1641ba简体字kcn是全宇宙巴1645ba简体字cnhn是全宇宙拔1646ba简体字rdcy是全宇宙霸1652ba简体字fafe是全宇宙罢1653ba简体字lfcu是全宇宙爸1654ba简体字wqcb是全宇宙坝1651ba简体字fmy是全宇宙芭1637ba简体字acb是全宇宙捌1638ba简体字rklj是全宇宙扒1639ba简体字rwy是全宇宙叭1640ba简体字kwy是全宇宙笆1642ba简体字tcb是全宇宙疤1644ba简体字ucv是全宇宙跋1647ba简体字khdc是全宇宙靶1648ba简体字afcn是全宇宙耙1650ba简体字dicn是全宇宙茇6056ba简体字adcu是全宇宙菝6135ba简体字ardc是全宇宙岜6517ba简体字mcb是全宇宙灞6917ba简体字ifae是全宇宙钯7857ba简体字qcn是全宇宙粑8446ba简体字ocn是全宇宙鲅8649ba简体字qgdc是全宇宙魃8741ba简体字rqcc是全宇宙百1657bai简体字djf是全宇宙白1655bai简体字rrrr是全宇宙败1660bai简体字mty是全宇宙摆1658bai简体字rlfc是全宇宙柏1656bai简体字srg是全宇宙佰1659bai简体字wdjg是全宇宙拜1661bai简体字rdfh是全宇宙稗1662bai简体字trtf是全宇宙捭6267bai简体字rrtf是全宇宙掰7494bai简体字rwvr是全宇宙办1676ban简体字lwi是全宇宙半1675ban简体字ufk是全宇宙板1669ban简体字srcy是全宇宙班1664ban简体字gytg是全宇宙般1667ban简体字temc是全宇宙版1670ban简体字thgc是全宇宙拌1672ban简体字rufh是全宇宙搬1665ban简体字rtec是全宇宙斑1663ban简体字gygg是全宇宙扳1666ban简体字rrcy是全宇宙伴1673ban简体字wufh是全宇宙颁1668ban简体字wvdm是全宇宙扮1671ban简体字rwvn是全宇宙瓣1674ban简体字urcu是全宇宙绊1677ban简体字xufh是全宇宙阪5870ban简体字brcy是全宇宙坂5964ban简体字frcy是全宇宙钣7851ban简体字qrcy是全宇宙瘢8103ban简体字utec是全宇宙癍8113ban简体字ugyg是全宇宙舨8418ban简体字terc是全宇宙帮1679bang简体字dtbh是全宇宙棒1684bang简体字sdwh是全宇宙邦1678bang简体字dtbh是全宇宙榜1681bang简体字supy是全宇宙梆1680bang简体字sdtb是全宇宙膀1682bang简体字eupy是全宇宙绑1683bang简体字xdtb是全宇宙磅1685bang简体字dupy是全宇宙蚌1686bang简体字jdhh是全宇宙镑1687bang简体字qupy是全宇宙傍1688bang简体字wupy是全宇宙谤1689bang简体字yupy是全宇宙蒡6182bang简体字aupy是全宇宙浜6826bang简体字irgw是全宇宙报1708bao简体字rbcy是全宇宙保1703bao简体字wksy是全宇宙包1692bao简体字qnv是全宇宙剥1694bao简体字vijh是全宇宙薄1701bao简体字aigf是全宇宙胞1691bao简体字eqnn是全宇宙暴1709bao简体字jawi是全宇宙宝1706bao简体字pgyu是全宇宙饱1705bao简体字qnqn是全宇宙抱1707bao简体字rqnn是全宇宙爆1712bao简体字ojai是全宇宙堡1704bao简体字wksf是全宇宙苞1690bao简体字aqnb是全宇宙褒1693bao简体字ywke是全宇宙雹1702bao简体字fqnb是全宇宙豹1710bao简体字eeqy是全宇宙鲍1711bao简体字qgqn是全宇宙葆6165bao简体字awks是全宇宙孢7063bao简体字bqnn是全宇宙煲7650bao简体字wkso是全宇宙鸨8017bao简体字xfqg是全宇宙褓8157bao简体字puws是全宇宙趵8532bao简体字khqy是全宇宙龅8621bao简体字hwbn是全宇宙北1717bei简体字uxn是全宇宙被1727bei简体字puhc是全宇宙倍1722bei简体字wukg是全宇宙备1724bei简体字tlf是全宇宙背1719bei简体字uxef是全宇宙辈1718bei简体字djdl是全宇宙贝1720bei简体字mhny是全宇宙杯1713bei简体字sgiy是全宇宙卑1716bei简体字rtfj是全宇宙悲1715bei简体字djdn是全宇宙碑1714bei简体字drtf是全宇宙钡1721bei简体字qmy是全宇宙狈1723bei简体字qtmy是全宇宙惫1725bei简体字tlnu是全宇宙焙1726bei简体字oukg是全宇宙孛5635bei简体字fpbf是全宇宙陂5873bei简体字bhcy是全宇宙邶5893bei简体字uxbh是全宇宙埤5993bei简体字frtf是全宇宙萆6141bei简体字artf是全宇宙蓓6177bei简体字awuk是全宇宙呗6334bei简体字kmy是全宇宙悖6703bei简体字nfpb是全宇宙碚7753bei简体字dukg是全宇宙鹎8039bei简体字rtfg是全宇宙褙8156bei简体字puue是全宇宙鐾8645bei简体字nkuq是全宇宙鞴8725bei简体字afae是全宇宙本1730ben简体字sgd是全宇宙奔1728ben简体字dfaj是全宇宙苯1729ben简体字asgf是全宇宙笨1731ben简体字tsgf是全宇宙畚5946ben简体字cdlf是全宇宙坌5948ben简体字wvff是全宇宙贲7458ben简体字famu是全宇宙锛7928ben简体字qdfa是全宇宙泵1735beng简体字diu是全宇宙崩1732beng简体字meef是全宇宙绷1733beng简体字xeeg是全宇宙甭1734beng简体字giej是全宇宙蹦1736beng简体字khme是全宇宙迸1737beng简体字uapk是全宇宙嘣6452beng简体字kmee是全宇宙甏7420beng简体字fkun是全宇宙比1740bi简体字xxn是全宇宙必1756bi简体字nte是全宇宙避1760bi简体字nkup是全宇宙闭1753bi简体字ufte是全宇宙辟1757bi简体字nkuh是全宇宙笔1742bi简体字ttfn是全宇宙壁1758bi简体字nkuf是全宇宙臂1759bi简体字nkue是全宇宙毕1747bi简体字xxfj是全宇宙彼1743bi简体字thcy是全宇宙逼1738bi简体字gklp是全宇宙币1750bi简体字tmhk是全宇宙鼻1739bi简体字thlj是全宇宙蔽1746bi简体字aumt是全宇宙鄙1741bi简体字kflb是全宇宙碧1744bi简体字grdf是全宇宙蓖1745bi简体字atlx是全宇宙毙1748bi简体字xxgx是全宇宙毖1749bi简体字xxnt是全宇宙庇1751bi简体字yxxv是全宇宙痹1752bi简体字ulgj是全宇宙敝1754bi简体字umit是全宇宙弊1755bi简体字umia是全宇宙陛1761bi简体字bxxf是全宇宙匕5616bi简体字xtn是全宇宙俾5734bi简体字wrtf是全宇宙荜6074bi简体字axxf是全宇宙荸6109bi简体字afpb是全宇宙薜6221bi简体字anku是全宇宙吡6333bi简体字kxxn是全宇宙哔6357bi简体字kxxf是全宇宙狴6589bi简体字qtxf是全宇宙庳6656bi简体字yrtf是全宇宙愎6725bi简体字ntjt是全宇宙滗6868bi简体字ittn是全宇宙濞6908bi简体字ithj是全宇宙弼6986bi简体字xdjx是全宇宙妣6994bi简体字vxxn是全宇宙婢7030bi简体字vrtf是全宇宙嬖7052bi简体字nkuv是全宇宙璧7221bi简体字nkuy是全宇宙畀7815bi简体字lgjj是全宇宙铋7873bi简体字qntt是全宇宙秕7985bi简体字txxn是全宇宙裨8152bi简体字purf是全宇宙筚8357bi简体字txxf是全宇宙箅8375bi简体字tlgj是全宇宙篦8387bi简体字ttlx是全宇宙舭8416bi简体字texx是全宇宙襞8437bi简体字nkue是全宇宙跸8547bi简体字khxf是全宇宙髀8734bi简体字merf是全宇宙变1768bian简体字yocu是全宇宙边1763bian简体字lpv是全宇宙便1767bian简体字wgjq是全宇宙编1764bian简体字xyna是全宇宙遍1773bian简体字ynmp是全宇宙辩1771bian简体字uyuh是全宇宙扁1766bian简体字ynma是全宇宙辨1770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技术参数光学参数*?? 95%能量时，CF=近焦，SF=标准焦距??? 最小焦距时的最小光点尺寸*? 最小的光点尺寸直径=最小焦距/最小的D:S 一般参数电气参数仪器特点Marathon FA?红外测温仪技术参数：1、温度测量范围: 250℃到 3000℃(482°F to 5432°F)2、光学分辨率最高可达 100:13、特别适用于现场安装空间狭小的安装条件4、精度高，测量值的± 0.3%5、更快速响应时间 10 毫秒，可选到10秒6、提供模拟量和数字量输出技术参数Marathon FA 红外测温仪介绍雷泰马拉松 FA 系列红外测温仪使用光纤技术可克服测量过程中各种极端的环境条件。

FA 系列红外测温仪由电子盒和光纤探头、光缆组成，探测器和信号处理部分集成在一电子盒中，此电子盒可远距离放置，光纤探头和光缆可安装在强电磁场中的环境中，并且可耐的最高环温达200℃。

雷泰马拉松 FA 系列光纤测温仪的测温范围为250℃到3000℃(482°F to 5432°F) ，FA 光纤探头由耐用光缆将光学探头连接到电路盒上，电路盒包括：探测器、电子线路、内置用户接口、LED 显示及连接电缆的接线端子。

FA1 和FA2 系列尤其适用于目标不能接近的、恶劣的工业环境，安装空间狭小的现场测温应用。

雷泰 FA 系列单色光纤式测温仪的固定焦距的光学探头包括一个小的不锈钢圆柱形外壳和透镜，其可承受的环境温度高达200℃，并且符合NEMA-4的标准。

雷泰 FA 系列的光纤探头可装一空气吹扫器以防止透镜被污染，光缆由金属套保护，并由VITON 保护套所密封，以防止水和油的流入，这种装配可使光缆以很小的半径弯曲以便其方便地穿过狭小的空间。

雷泰 FA 系列单色光纤式测温仪还提供可在PC 上使用的WINDOWS下的马拉松软件，以实现远程进行参数设置、数据读取、数据的图形显示及RS485的多点网络配置。

Welcome to the higher standard for steel adapters BrochureWelcome to the higher standard for steel adaptersHigher pressure.Higher performance.Beyond SAE certified.Danfoss expands your possibilities.With more than 3000 steel adapter part numbers globally, Danfoss has a wide variation of configurations with large portfolio of ORFS, JIC, BSPP , NPTF, and manyother terminal ends.Expand the equation.Same exceptional Danfoss adapters —now with outstanding corrosion resistance.Achieve operating pressures up to 125% more than SAE.Dura-Kote plating technology.Danfoss Competitor B Competitor Pan assembly that can perform up to 125% greater operating pressureCarbon steel corrosion protection This is a comparison of current carbon steel adaptersafter 650-hours of exposure to salt spray testing which far exceeds the SAE standard of 72-hours. Carbon steelfluid conveyance products protected with Danfoss’Dura-Kote plating technology resist rust longer than other carbon steel products available today.Discover the additional value of using a Danfoss system of products designed to work together to achieve even higher operating pressures. When Danfoss hoses are combined with Danfoss 1A or 4S/6S fittings and Danfoss adapters, assemblies can perform up to 125% higher pressures than the SAE rating.Danfoss adapters now come with Dura-Kote ® plating, which gives you up to 1,000 hours of corrosion resistance. Dura-Kote is an innovative plating technology for steel adapters, offering more corrosive protection for longer life, lower replacement costs, and improved appearance. This corrosion protection decreases the likelihood of leaking, meaning less equipment downtime and greater productivity. Plus, there are no compatibility issues with Dura-Kote plating. The Danfoss adapters you rely on today will look, feel, and perform exactly the same.Many companies offer extra plating services and special requests to enhance corrosion resistance. Requesting extra services can delay your order, complicate delivery, and add significantly to your costs. That is why Danfoss has responded to the needs of the market and simplified the entire process. With Dura-Kote plating now standard on Danfoss adapters, you’ll get products that look better, last longer, and cost less to maintain, which gives you and your customers one less thing to worry about. ++=Same form and functional capabilities Same torque values and pressure ratings Same silver appearance Same procedures for assemblyFor over 90 years, Danfoss has continued to manufacture and supply the highest performing quick disconnect couplings for customers globally. Danfoss’ quality and performance are never compromised when it comes to engineering and manufacturing its full line of quick disconnect couplings. From traditional industry standards to custom couplings for the next generation of emerging markets and new advanced technologies, Danfoss continues to provide quick disconnect coupling solutions to meet your demands. Quick Disconnect Coupling applications:• Hydraulic applications in construction, agriculture, etc. • Fluid transfer • Liquid cooling • Pneumatic • Chemical • Oil and Gas • Aerospace • Medical • Food and Beverage • Law enforcement/rescueCheck out our complete portfolio of Quick Disconnect Couplings found in our catalog at .Literature number: AF435258198969en-000101Patented STC Snap-To-Connect products are threadless connectors that keep equipment up and running longer with simple, leak-free connections.Danfoss has the broadest range of threadless connectors in the industry. Our patented STC technology excels in rigorous mobile application in agriculture, construction, forestry, transportation, utility, and lawn and turf. Because of their easy installation — even in confined spaces — and virtually zero-leak performance (per SAE J1176), more than 25 million STC connections are currently in use worldwide.STC benefits:• Fast reliable one-hand connections requiring no assembly tools • Eliminates cross-threading, over or undertorquing, and hose twisting • Virtually zero leak performance • Direct porting eliminates adapters to maximize cost savings • Resists external contamination • Allows easy disconnection with release toolA full list of available STC products can be found in our catalog at .Literature number: AF444058468933en-000101Making the right connections is easy with Danfoss’ Waltech metric tube fittings. A variety of available sizes and configurations make Danfoss’ metric tube fittings a simple, flexible and cost-effective solution for many applications. With three unique systems — including Walpro ®, WalringPlus ®, and Walform ® — each tube fitting is manufacturered to meet DIN 2353 and ISO 8434-1 standards and withstand pressure and corrosion with best-in-class performance. Metric tube fitting applications:• Harvester/balers • Machine tool • Hydraulic presses • Excavators • Loaders • Mining equipment • Mining equipment • Concrete pumpers • Off-shore equipmentLearn more about Danfoss’ entire line of metric tube fittings by reviewing our Waltech Metric Tube Fittings catalog at .Literature number: AF403661682130en-000201Regardless of the job, Danfoss has the right products to meet the challenge every time.Additional products available from Danfoss.Danfoss Quick Disconnect CouplingsWaltech Metric Tube FittingsDanfoss STC Snap-To-ConnectWalpro WalformWalringPlusAD440177948096en-000101© Danfoss | Power Solutions | April 2023Any information, including, but not limited to information on selection of product, its application or use, product design, weight, dimensions, capacity or any other technical data in product manuals, catalogues descriptions, advertisements, etc. and whether made available in writing, orally, electronically, online or via download, shall be considered informative, and is only binding if and to the extent, explicit reference is made in a quotation or order confirmation. Danfoss cannot accept any responsibility for possible errors in catalogues, brochures, videos and other material. Danfoss reserves the right to alter its products without notice. This also applies to products ordered but not delivered provided that such alterations can be made without changes to form, fit or function of the product. All trademarks in this material are property of Danfoss A/S or Danfoss group companies. Danfoss and the Danfoss logo are trademarks of Danfoss A/S. All rights reserved.Danfoss Power Solutions, Nordborgvej 81, 6430 Nordborg, Denmark, Tel. +45 74 88 22 22, Fax +45 74 65 25 80,E-mail:****************。

User Guide FFFA001410TABLE OF CONTENTSOVERVIEW . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3 Introduction (3)Features .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. ..3 Box .Contents (4)System .Requirements (4)Mac .OS (4)Windows (4)GETTING STARTED . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5 Software .Installation (5)Mac .OS .only (6)Windows .only (6)Powering .your .Scarlett .Solo (6)Connecting .your .Scarlett .Solo (7)Audio .Setup .in .your .DAW (7)Examples .of .use (9)Connecting .a .microphone/instrument (9)Using .Direct .Monitoring (10)Headphone .monitoring (10)Connecting .Scarlett .Solo .to .loudspeakers (11)HARDWARE FEATURES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .13 Front .Panel (13)Back .Panel (14)PERFORMANCE SPECIFICATIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .15 Physical .and .Electrical .Characteristics (16)TROUBLESHOOTING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .17 COPYRIGHT AND LEGAL NOTICES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .172OVERVIEWIntroductionThank .you .for .purchasing .this .Second .Generation .Scarlett .Solo, .one .of .the .family .of .Focusrite . professional .audio .interfaces .incorporating .high .quality .Focusrite .analogue .pre-amplifiers. .You .now . have .a .simple .and .compact .solution .for .routing .high .quality .audio .to .and .from .your .computer.In .developing .the .Second .Generation .series .of .Scarlett .interfaces, .we .have .enhanced .both .the . performance .a nd .f eature .s et .i ncluding .s upport .f or .s ample .r ates .u p .t o .192 .k Hz, .i mproved .m ic .p reamp . performance .with .low .noise .and .plenty .of .gain, .and .upgraded .instrument .inputs .with .additional . headroom .for .recording .the .loudest .guitar .parts .without .clipping. .They .are .class .compliant .on .Mac, . which .m eans .t hey .a re .p lug-and-play, .s o .n o .n eed .t o .i nstall .a .d river .i f .y ou .a re .a .M ac .u ser. .Y ou .w ill .a lso . be .able .to .download .some .exciting .new .software .plug-ins .once .you’ve .registered .the .product.This .User .Guide .provides .a .detailed .explanation .of .the .hardware .to .help .you .achieve .a .thorough . understanding .of .the .product’s .operational .features. .We .recommend .that .both .users .who .are .new . to .computer-based .recording, .as .well .as .more .experienced .users, .take .the .time .to .read .through .the . user .g uide .s o .t hat .y ou .a re .f ully .a ware .o f .a ll .t he .p ossibilities .t hat .t he .S carlett .S olo .a nd .a ccompanying . software .have .to .offer. .If .the .main .User .Guide .sections .do .not .provide .the .information .you .need, . be .sure .to .consult .https:///, .which .contains .a .comprehensive .collection .of . common .technical .support .queries.FeaturesThe .Scarlett .Solo .hardware .interface .provides .the .means .for .connecting .a .microphone .and .an . instrument .or .line .level .audio .signals .to .a .computer .running .Mac .OS .or .Windows. .The .signals .at .the . physical .inputs .can .be .routed .to .your .audio .recording .software ./ .digital .audio .workstation .(referred . to .throughout .this .user .guide .as .the .“DAW”) .at .up .to .24-bit, .192 .kHz .resolution; .similarly, .the .DAW’s . monitor .or .recorded .output .will .appear .at .the .unit’s .physical .outputs.This .lets .you .record .“real-world” .instruments .into .Ableton .Live .Lite, .GarageBand® .(or .whichever . other .D AW .y ou .m ay .u se) .a long .w ith .– .o r .i nstead .o f .– .a ny .“native” .s ounds .a lready .a vailable .w ithin .y our . computer. .The .physical .outputs .can .be .connected .to .an .amplifier .and .speakers, .powered .monitors, . headphones .or .any .other .audio .equipment .with .analogue .inputs .that .you .wish .to .use. .Although . all .inputs .and .outputs .on .the .Scarlett .Solo .are .routed .directly .to .and .from .your .DAW .for .recording . and .playback, .you .can .configure .the .routing .within .your .DAW .in .order .to .meet .your .needs. .A .Direct . Monitoring .feature .lets .you .hear .what .you .are .playing .without .the .effects .of .computer .latency.3Box ContentsAlong .with .your .Scarlett .Solo .you .should .have:• . .Bundle .code* .for .accessing .the .following .on-line .resources:- .Solo .USB .Drivers .for .Windows- .Focusrite .Red .2 .& .3 .Plug-in .Suite- .Softube .Time .and .Tone .bundle- .ProTools .| .First- .Ableton .Live .Lite- .LoopMasters .sample .library- .Novation .Bass .station- .Multi-language .User .Guides.• .USB .cable.• .Getting .Started .Guide .and .Important .Safety .Information** .information .printed .on .the .inside .of .the .gift .boxSystem RequirementsMac OSApple .Macintosh .with .a .USB .2.0 .or .3.0-compliant .USB .port .and .an .Internet .connection* OS: .Mac .OS .X .10.10 .(Yosemite) .or .OS .X .10.11 .(El .Capitan)WindowsWindows .c ompatible .c omputer .w ith .a .U SB .2.0 .o r .3.0-compliant .U SB .p ort .a nd .a n .I nternet .c onnection* OS: .Windows .7 .(32- .or .64-bit), .8.1 .and .10* .Internet .connection .required .for .downloading .on-line .resources.4GETTING STARTEDIMPORTANT: WINDOWS .USERS .- .PLEASE .ENSURE .THAT .YOU .RUN .THE .INSTALLER .BEFORE .CONNECTING .THE .SCARLETT .SOLO .TO .YOUR .COMPUTER.THE .SECOND .GENERATION .SCARLETT .SOLO .IS .CLASS .COMPLIANT .FOR .MACS, .THEREFORE .DRIVER .INSTALLATION .IS .NOT .NECESSARY.Software InstallationAll .software .required .by .the .Scarlett .Solo .- .and .several .powerful .and .useful .extras .- .is . available .for .download .from .the .Focusrite .website /register. .You .will .find .a . .“Bundle .Code” .printed .on .the .inside .of .the .gift .box .your .Scarlett .Solo .comes .in, .and .the .Serial . number .can .be .found .on .the .underside .of .the .unit. .You .will .need .to .enter .these .when .you .access . the .downloads .area .of .the .website; .this .procedure .ensures .that .you .will .have .the .most .up-to-date . software .versions.music software preferences) 4. You are now ready to use your Scarlett Solo Array To download the included software, you will need to register your Scarlett Solo at /registerYou will need the product serial number which can be found on the underside of the Solo hardware.Once you have entered the serial number, you will be asked to enter your BUNDLE CODE, found below:XXXXXX-XXXXXX-XXXXXXFocusrite is a trade mark of Focusrite Audio Engineering Limited registered in the UK and other countries.Scarlett Solo is a trade mark of Focusrite Audio Engineering Limited registered in the UK and other countries.2016 Focusrite Audio Engineering Limited. All rights reserved.1. .Using .your .usual .browser, .go .to /register/.2. .Follow .the .on-screen .instructions, .entering .the .Serial .number .and .then .the .Bundle .Code . . (XXXXXX-XXXXXX-XXXXXX) .into .the .form .where .prompted. .Your .Bundle .Code .is .printed .on .the .inside . of .the .gift .box.3. .Y ou .w ill .t hen .b e .a ble .t o .a ccess .t he .“My .P roducts” .p age, .w here .t he .s oftware .p roducts .t o .w hich .y our . registration .e ntitles .y ou .a re .a vailable .f or .d ownload, .c omplete .w ith .a ctivation .c odes .w here .a pplicable.4. .Download .and .install .the .Scarlett .Solo .drivers .(Windows .only). .Follow .all .on-screen .instructions.• .When .the .installation .is .complete, .restart .your .computer.• .After .restart, .connect .the .Scarlett .Solo .to .your .computer .with .the .USB .cable .supplied.This .information .is .accurate .as .of .May .2016, .however .we .are .constantly .striving .to .improve .the .customer .experience .and .as .a .result .this .process .is .subject .to .change. .If .anything .appears .to .have .changed .please .refer .to /get-started .for .the .latest .info.5Mac OS only:Your .OS .should .automatically .switch .the .computer’s .default .audio .inputs .& .outputs .to .the .Scarlett . Solo. .To .verify .this, .go .to .System Preferences > Sound, .and .ensure .that .the .input .and .output . are .set .to .Scarlett Solo. .For .more .detailed .setup .options .on .a .Mac, .open .Applications > Utilities > Audio MIDI Setup.Windows only:Your .OS .should .automatically .switch .the .computer’s .default .audio .inputs .& .outputs .to .the .Scarlett . Solo. .To .verify .this .go .to: .Start > Control Panel > Hardware and Sound > Sound > Manage Audio Devices .and .ensure .that .‘Default Playback’ .and .‘Recording’ .are .set .to .‘Scarlett Solo’Powering your Scarlett SoloThe .Scarlett .Solo .is .an .active .device, .and .needs .a .DC .power .source .to .operate. .This .will .be .supplied . by .t he .M ac .o r .P C .t o .w hich .i t .i s .c onnected, .v ia .t he .s ingle .U SB .c onnection. .N ote .t hat .a n .e xternal .p ower . supply .is .not .required.You .should .experience .no .problems .in .powering .the .Scarlett .Solo .from .the .USB .ports .on .any . compatible .Mac .or .PC. .However, .please .be .aware .that .USB .ports .on .some .laptops .may .not .be . able .to .deliver .the .same .current .to .externally-connected .devices .when .they .are .running .off .their . internal .batteries, .compared .to .their .current .capability .when .running .from .AC .mains. .We .therefore . recommend .strongly .that .if .you .are .using .Scarlett .Solo .with .a .laptop, .please .power .the .laptop .from . the .mains .with .its .supplied .AC .adaptor.67Connecting your Scarlett Solo IMPORTANT - WINDOWS USERS: .Before .you .connect .the .Scarlett .Solo .to .your .computer, .please .complete .the .software .installation .according .to .the .instructions .on .page .5. .This .will .ensure .that .the .hardware .uses .the .correct .drivers, .and .will .prevent .unexpected .behaviour .Your .Scarlett .Solo .has .a .single .USB .2.0 .port .(on .the .rear .panel). .Once .the .software .installation .(if .necessary) .i s .c omplete, .s imply .c onnect .S carlett .S olo .t o .y our .c omputer .u sing .t he .U SB .c able .p rovided. .Note .that .Scarlett .Solo .is .a .USB .2.0 .device, .and .thus .the .USB .connection .requires .a .USB .2.0+ .compliant .port .on .your .computer . .It .will .not .operate .correctly .with .USB .1.0/1.1 .ports.Audio Setup in your DAWThe .Scarlett .Solo .is .compatible .with .any .Windows-based .DAW .that .supports .ASIO .or .WDM .or .any .Mac-based .DAW .that .uses .Core .Audio. .After .installing .the .USB .drivers .(Windows .only) .and .connecting .the .hardware, .you .can .start .using .your .Scarlett .Solo .with .the .DAW .of .your .choice. .To .allow .y ou .t o .g et .s tarted .i f .y ou .d o .n ot .a lready .h ave .a .D AW .a pplication .i nstalled .o n .y our .c omputer, .b oth . .Pro .Tools .| .First .and .Ableton .Live .Lite .are .included .in .the .software .package .available .once .you’ve .registered .y our .S carlett .S olo .o nline. .T o .i nstall .e ither .D AW, .d ownload .a nd .s ave .t he .d esired .i nstaller .fi le .from .your .registered .Focusrite .“My .Products” .as .described .on .page .5, .and .then .run .it, .following .all .on-screen .instructions.Operating .instructions .for .Pro .Tools .| .First .and .Ableton .Live .Lite .are .beyond .the .scope .of .this . .User .Guide, .but .both .applications .include .a .full .set .of .Help .files. .Please .note .- .your .DAW .may .not .automatically .select .the .Scarlett .Solo .as .its .default .I/O .device. .In .this .case, .you .must .manually .select .‘Scarlett Solo ’ .as .the .driver .on .your .DAW’s .Audio Setup* .page. .Please .refer .to .your .DAW’s .documentation .(or .Help .files) .if .you .are .unsure .where .to .select .the .ASIO .or .Core .Audio .driver . .The .example .below .shows .the .correct .configuration .in .the .Ableton .Live .Lite .Preferences .panel .(Windows .version .shown).*Typical .name. .Terminology .may .differ .slightly .between .DAWs.Once .the .Scarlett .Solo .is .set .as .the .preferred .Audio .Device* .in .your .DAW, .its .inputs .and .outputs . will .appear .in .your .DAW’s .Audio .I/O .preferences. .Depending .on .your .DAW, .you .may .need .to .enable . certain .inputs .or .outputs .before .use. .The .two .examples .below .show .two .Inputs .and .two .outputs .enabled .in .the .Ableton .Lite .Audio .Preferences.8Examples of useThe .Scarlett .Solo .is .an .ideal .audio .interface .for .many .DAW .applications .running .on .a .laptop .or .other . computer, .PC .or .Mac.A .typical .set .of .connections .is .illustrated .below.Connecting a microphone/instrumentThis .setup .illustrates .a .typical .configuration .for .recording .using .DAW .software .on .your .Mac .or .PC. . In .this .case, .you .might .record .vocals .through .Input .1 .and .guitar .through .Input .2 .into .your .recording . application, .while .monitoring .the .playback .via .headphones.Scarlett .Solo’s .inputs .are .on .the .front .panel: .Input .1 .uses .a .standard .3-pin .XLR .socket, .and .is . configured .to .work .with .microphones .of .most .types; .you .will .probably .have .a .mating .XLR .male . connector .on .the .end .of .your .mic .cable. .Input .2 .uses .a .¼” .(6.35 .mm) .jack .socket .(2-pole .when .in . instrument .mode .and .3-pole .when .used .as .a .line .input), .and .is .intended .to .accept .signals .from .an . electric .or .electroacoustic .guitar .or .bass.9If .you .are .using .a .“studio” .condenser .(capacitor) .microphone .designed .on .operate .on .48 .V .phantom . power, .press .the .48V .button. .Other .types .of .microphone .(including .the .common .dynamic .type) .do . not .require .phantom .power, .and .may .suffer .damage .if .phantom .power .is .applied. .Some .lower .spec. . condenser .m icrophones .a re .a ble .t o .o perate .f rom .a .l ower .p hantom .p ower .v oltage .– .t ypically .15 .V. .Y ou . should .check .the .mic .spec .to .see .if .it .is .safe .to .operate .it .from .48 .V; .if .not, .obtain .a .suitable .external . phantom .power .supply.Using Direct MonitoringYou .w ill .f requently .h ear .t he .t erm .“latency” .u sed .i n .c onnection .w ith .d igital .a udio .s ystems. .I n .t he .c ase . of .the .simple .DAW .recording .application .described .above, .latency .will .be .the .time .it .takes .for .your . input .signals .to .pass .through .your .recording .device .(your .Mac .or .PC) .and .the .associated .software. . Latency .c an .b e .a .p roblem .f or .a .p erformer .w ho .w ishes .t o .r ecord .w hile .m onitoring .t heir .i nput .s ignals. .The .Scarlett .Solo .is .fitted .with .a .“Direct .Monitoring” .option, .which .overcomes .this .problem. .Setting . the .front .panel .DIRECT MONITOR .switch .to .ON .will .route .your .input .signals .directly .to .the .Scarlett . Solo’s .headphone .and .main .monitor .outputs. .This .enables .you .to .hear .yourself .with .zero .latency .– .i.e., .in .“real .time” .– .along .with .the .computer .playback. .The .input .signals .to .your .computer .are .not . affected .in .any .way .by .this .setting.When .Direct .Monitoring .is .set .to .ON, .ensure .that .your .recording .software .is .not .set .to .route .its .input . (what .you .are .currently .recording) .to .its .output. .If .it .is, .you .will .hear .yourself .“twice”, .with .one .signal . audibly .delayed .as .an .echo.Headphone monitoringConnect .a .pair .of .stereo .headphones .to .the .front .panel .headphone .socket .to .hear .both .what .you .are . recording .- .your .current .input .signal(s), .plus .any .tracks .you’ve .already .recorded .in .your .computer. . Note: .Set .the .front .panel .DIRECT MONITOR .switch .to .ON .when .recording. .The .pre-recorded .tracks . will .b e .h eard .i n .s tereo, .a nd .t he .c urrent .i nput .s ignals .i n .m ono .– .c entral .i n .t he .s tereo .i mage. .I f .y ou .a re . using .both .the .mic .and .instrument .inputs, .the .two .inputs .will .be .summed .in .mono.10Connecting Scarlett Solo to loudspeakersThe .phono .(RCA) .outputs .on .the .rear .panel .can .be .used .to .connect .monitoring .speakers. . . Self-powered .monitors .(i.e., .typical .computer .speakers) .incorporate .internal .amplifiers .with .a . volume .c ontrol, .a nd .m ay .b e .c onnected .d irectly. .L arger, .p assive .l oudspeakers .w ill .r equire .a .s eparate . stereo .amplifier; .in .this .case, .the .rear .panel .outputs .should .be .connected .to .the .amplifier’s .inputs.The .line .output .connectors .are .standard .phono .(RCA) .sockets. .Typical .consumer .(hi-fi) .amplifiers . and .small .powered .monitors .will .have .inputs .on .phono .(RCA) .sockets .or .a .single .3.5 .mm .3-pole .jack . plug .(intended .for .direct .connection .to .a .computer). .In .either .case, .use .a .suitable .connecting .cable . with .phono .plugs .(RCA .jacks) .at .one .end.NOTE: You .r un .t he .r isk .o f .c reating .a n .a udio .f eedback .l oop .i f .l oudspeakers .a re .a ctive .a t .t he .s ame .t ime . as .a .microphone! .We .recommend .that .you .always .turn .off .(or .turn .down) .monitoring .loudspeakers . while .recording, .and .use .headphones .when .overdubbing.HARDWARE FEATURESFront PanelThe .f ront .p anel .i ncludes .t he .i nput .c onnectors .f or .m ic .a nd .l ine/instrument .s ignals, .a nd .t he .i nput .g ain . and .monitoring .controls.1. .Input .1 .– .electronically .balanced .input .via .3-pin .XLR .socket .for .microphones.2. .GAIN 1 .– .a djust .t he .g ain .f or .t he .m icrophone .s ignal .a t .I nput .1. .T he .g ain .c ontrol .h as .a .c oncentric .bi-colour .L ED .‘ring’ .t o .c onfirm .s ignal .l evel: .g reen .i ndicates .a n .i nput .l evel .o f .a t .l east .-24 .d BFS .(i.e., .‘signal .present’), .the .ring .then .turns .red .when .signal .level .reaches .0 .dBFS, .indicating .digital .clipping.3. .48V .– .phantom .power .switch .for .mic .input .- .enables .48 .V .phantom .power .at .the .XLR .socket.4. .Input .2 .– .for .connecting .instruments .(unbalanced) .or .line .level .(balanced) .sources; .¼” .TRS .jack .socket.5. .GAIN 2 .– .adjusts .the .gain .for .the .line/instrument .signal .at .Input .2. .The .gain .control .has .a .bi-colour .LED .ring .as .[2].6. .INST/LINE .– .Instrument/Line .level .switch .for .Input .2 .– .switches .gain .to .suit .instrument .or .line .level .signals.7. .MONITOR .– .m ain .m onitor .o utput .l evel .c ontrol .- .s ets .t he .o utput .l evel .a t .t he .r ear .p anel .o utputs .and .the .front .panel .headphone .output.8. .USB .LED .– .illuminates .when .the .unit .receives .USB .bus .power .and .is .confirmed .by .the .computer .as .connected .and .operating .correctly.9. .DIRECT MONITOR .– .selects .monitoring .of .input .signals .(mixed .with .the .DAW .output) .to .be .directly .from .inputs .(ON) .or .via .the .DAW .(OFF).10. . .– .¼” .TRS .output .jack .- .connect .your .stereo .headphones .here.Back Panel11. .K (Kensington .security .lock) .– .secure .your .Scarlett .Solo .to .a .suitable .structure .if .desired. .Please .see /kensington/us/us/s/1704/kensington-security-slot.aspx .for .further .information .on .how .to .use .this .feature.12. . .U SB .2.0port .– .T ype .B .c onnector; .c onnect .t o .y our .l aptop .o r .c omputer .w ith .t he .U SB .c able .supplied.13. .LINE OUTPUTS: LEFT and .RIGHT .– .2 .x .phono .(RCA) .sockets; .+9 .dBu .max. .output .level.PERFORMANCE SPECIFICATIONSPhysical and Electrical CharacteristicsTROUBLESHOOTINGFor .all .troubleshooting .queries, .please .visit .the .Focusrite .Answerbase .athttps:/// .where .you .will .find .articles .covering .numerous .troubleshooting . examples.COPYRIGHT AND LEGAL NOTICESFocusrite .i s .a .r egistered .t rade .m ark .a nd .S carlett .S olo .i s .a .t rade .m ark .o f .F ocusrite .A udio .E ngineering . Limited.All .other .trade .marks .and .trade .names .are .the .property .of .their .respective .owners. .2016 .© .Focusrite .Audio .Engineering .Limited. .All .rights .reserved.。

1603hfr-hs 规格书产品名称：1603hfr-hs 规格书一、产品概述：1603hfr-hs是一款高性能的电子产品，具有多种功能和特点。

本规格书旨在提供详细的产品信息，方便用户了解产品的基本参数和应用场景。

请仔细阅读以下内容，以便更好地使用和了解该产品。

二、产品特点：1. 高性能：1603hfr-hs采用先进的技术，具有出色的性能表现。

2. 多功能：该产品集成了多种功能，包括但不限于xxxxxx、yyyyyy 和zzzzzz。

3. 稳定性：该产品具有良好的稳定性，能够在各种环境条件下正常运行。

4. 节能环保：1603hfr-hs采用先进的节能技术，能够有效降低能耗，符合环境保护要求。

三、产品规格：1. 外观尺寸：xxxmm x xxxmm x xxxmm2. 重量：xxxkg3. 工作电压：xxxxV4. 工作温度：x℃-x℃5. 存储温度：x℃-x℃6. 通信接口：xxxxx7. 功率消耗：xxxW8. 其他规格：xxxxx四、应用场景：1603hfr-hs适用于xxxxx领域的应用，比如xxxxx、yyyyy和zzzzz。

该产品可以广泛应用于xxxxx行业，为用户提供高质量、可靠的解决方案。

五、注意事项：1. 在使用本产品前，请确保已仔细阅读并理解用户手册。

2. 请勿自行拆卸和修改本产品，否则可能会导致安全问题。

3. 如有任何问题或疑问，请及时联系我们的客户服务团队。

六、售后服务：我们将为您提供专业的售后服务，如遇产品质量问题，请及时与我们联系。

备注：本规格书仅供参考，请以最新的产品信息为准，如有变更恕不另行通知。

国内下一代防火墙第一品牌
深信服下一代防火墙（Next-Generation Application Firewall）NGAF是面向应用层设计，能够精确识别用户、应用和内容，具备完整安全防护能力，能够全面替代传统防火墙，并具有强劲应用层处理能力的全新网络安全设备。

NGAF 解决了传统安全设备在应用识别、访问控制、内容安全防护等方面的不足，同时开启所有功能后性能不会大幅下降。

区别于传统的网络层防火墙，NGAF具备L2-L7层的协议的理解能力。

不仅能够实现网络层访问控制的功能，且能够对应用进行识别、控制、防护，解决了传统防火墙应用层控制和防护能力不足的问题。

区别于传统DPI技术的入侵防御系统，深信服NGAF具备深入应用内容的威胁分析能力，具备双向的内容检测能力为用户提供完整的应用层安全防护功能。

同样都能防护web攻击，与web应用防火墙关注web应用程序安全的设计理念不同，深信服下一代防火墙NGAF 关注web系统在对外发布的过程中各个层面的安全问题，为对外发布系统打造坚实的防御体系。

铁塔电池温度探头型号规【原创版】目录1.铁塔电池温度探头的概述2.铁塔电池温度探头的型号规格3.铁塔电池温度探头的功能及应用4.铁塔电池温度探头的安装与维护5.铁塔电池温度探头的市场前景正文一、铁塔电池温度探头的概述铁塔电池温度探头是一种测量电池温度的设备，主要用于监测电池在充电和放电过程中的温度变化，确保电池安全运行。

铁塔电池温度探头具有测量精度高、响应速度快、安装简便等特点，广泛应用于各种电池设备中。

二、铁塔电池温度探头的型号规格铁塔电池温度探头有多种型号规格，常见的有以下几种：1.型号：CWFS-series特点：测试精度高，响应速度快，安装简便，适用于各种电池设备。

2.型号：NTC 热敏电阻器特点：测量范围广，抗干扰能力强，适用于高寒环境。

三、铁塔电池温度探头的功能及应用铁塔电池温度探头的主要功能是实时监测电池温度，通过将温度信号转换为电信号，传输给电池管理系统，实现对电池温度的实时监控。

一旦发现电池温度异常，电池管理系统可以及时采取措施，保证电池安全运行。

铁塔电池温度探头广泛应用于电动汽车、电力储能系统、太阳能发电系统等领域。

四、铁塔电池温度探头的安装与维护铁塔电池温度探头的安装非常简便，只需将其与电池连接，并通过线束将信号传输给电池管理系统即可。

在维护方面，需要定期检查温度探头的连接是否牢固，信号传输是否正常，以确保温度探头能够准确监测电池温度。

五、铁塔电池温度探头的市场前景随着电动汽车、电力储能系统、太阳能发电系统等领域的快速发展，对铁塔电池温度探头的需求越来越大。

此外，铁塔电池温度探头具有测量精度高、响应速度快、安装简便等优点，在未来的市场竞争中具有较大优势。

Technical DataFluke 1555 and 1550C Insulation Resistance TestersFluke insulation testers can now conduct the entire range of test voltages specified in IEEE 43-2000 with a best in class, 3 yearwarranty and CAT IV 600 V safety rating. With measurement storage and PC interface, the 1555 and 1550C are perfect tools for pre-ventative or predictive maintenance programs designed to identify potential equipment failures before they occur.Features include:• Test voltages to up 10 kV provides solutions for all applications • CAT III 1000 V, CAT IV 600 V safety rating• Warning function alerts the user that line voltage is present andgives the voltage reading up to 600 V ac or dc for increased user safety• Selectable test voltages in 50 V steps from 250 V to 1000 V, and 100 V steps above 1000 V• Measurements can be stored in up to 99 memory locations, with each location assigned a unique, user defined, label for easy recall• Long battery life gives the user over 750 tests between charges • Automatic calculation of Dielectric Absorption (DAR) and Polarization Index (PI) with no additional setup• Guard system eliminates the effect of surface leakage current on high-resistance measurements• Large digital/analog LCD for easy viewing• Capacitance and leakage current measurement • Ramp function for breakdown testing • Resistance measurements up to 2TΩ• Timer settings up to 99 minutes for timed tests • 3-year warrantyDigital insulation testing up to 10 kVThe new Fluke 1555 and redesigned Fluke1550C insulation resistance testers, offer digital insulation testing up to 10 kV, making them ideal for testing a wide range of high voltage equipment including switchgear, motors, generators and cables.19812 Fluke Corporation Fluke 1555 and 1550C Insulation Resistance TestersFluke CorporationPO Box 9090, Everett, WA USA 98206Fluke Europe B.V.PO Box 1186, 5602 BD Eindhoven, The NetherlandsFor more information call:In the U.S.A. (800) 443-5853 or Fax (425) 446-5116In Europe/M-East/Africa +31 (0) 40 2675 200 or Fax +31 (0) 40 2675 222In Canada (800)-36-FLUKE or Fax (905) 890-6866From other countries +1 (425) 446-5500 or Fax +1 (425) 446-5116Web access: ©2005-2010 Fluke Corporation.Specifications subject to change without notice. Printed in U.S.A. 10/2010 1629685G D-EN-N Modification of this document is not permitted without written permission from Fluke Corporation.Fluke. Keeping your world up and running.Ordering information1550C 5 kV Insulation Tester 1555 10 kV Insulation Tester 1550C/Kit 5 kV Insulation Tester Kit 1555/Kit 10 kV Insulation Tester KitOptional accessoriesTL1550EXT 25 foot extendedtest lead setIncluded accessoriesTest Cables with Alligator Clips (red, black, green)Infrared adapter with interface cable FlukeView Forms Basic CD-ROM AC Power CordSoft Carrying Case (base models only)English ManualUsers Manual on CD-ROM Quick Reference CardSoftware License Agreement Registration CardFlukeView Forms Installation Guide USB-IR Cable Installation Guide IP67 Hard Case (kit only)Certificate of Calibration (kit only)Ruggedized Alligator Clips (kit and 1555 only)Software specification sFluke ViewForms basic softwarerequires a PC running Windows 2000, Windows XP and Windows Vista.SpecificationsElectrical specificationsThe tester’s accuracy is specified for one year after calibration at operating temperatures of 0 °C to 35 °C. For operating temperatures outside the range (-20 °C to 0 °C and 35 °C to 50 °C), add ± .25 % per °C, except on the 20 % bands add ± 1 % per °C.Insulation resistance measurementTest voltage (dc)RangeAccuracy (± reading)250 V< 200 kΩ200 kΩ to 5 GΩ5 GΩ to 50 GΩ> 50 GΩunspecified 5 %20 %unspecified 500 V< 200 kΩ200 kΩ to 10 GΩ10 GΩ to 100 GΩ> 100 GΩunspecified 5 %20 %unspecified 1000 V< 200 kΩ200 kΩ to 20 GΩ20 GΩ to 200 GΩ> 200 GΩunspecified 5 %20 %unspecified 2500 V< 200 kΩ200 kΩ to 50 GΩ50 GΩ to 500 GΩ> 500 GΩunspecified 5 %20 %unspecified 5000 V< 200 kΩ200 kΩ to 100 GΩ100 GΩ to 1 TΩ> 1 TΩunspecified 5 %20 %unspecified 10000 V (1555 Only)< 200 kΩ200 kΩ to 200 GΩ200 GΩ to 2 TΩ> 2 TΩunspecified 5 %20 %unspecifiedBar graph range0 to 1 TΩInsulation test voltage accuracy -0 %, +10 % at 1 mA load current Induced ac mains current rejection 2 mA maximum Charging rate for capacitive load5 seconds per μF Discharge rate for capacitive load 1.5 s/μFRangeAccuracyLeakage current measurement1 nA to2 mA ± (5 % + 2 nA)Capacitance measurement 0.01 uF to 15.00 μF ± (15 % rdg + 0.03 μF)TimerRangeResolution0 to 99 minutesSetting: 1 minute Indication: 1 second Live circuit warningWarning rangeVoltage accuracy 30 V to 660 V ac/dc, 50/60 Hz± (15 % + 2 V)General specifications。

Note: Some revisions of this device may incorporate deviations from published specifications known as errata. Multiple revisions of any device may be simultaneously available through various sales channels. For information about device errata, click here: /errata .FEATURES§ Two 32-bit counters keep track of real -time and elapsed time§ Counters keep track of seconds for over 125 years§ Battery powered counter counts seconds from the time battery is attached until V BAT is less than 2.5V§ V CC powered counter counts seconds while V CC is above V TP and retains the count in the absence of V CC under battery backup power § Clear function resets selected counter to 0 § Read/write serial port affords low pin count § Powered internally by a lithium energy cell that provides over 10 years of operation§ One-byte protocol defines read/write, counter address and software clear function§ Self-contained crystal provides an accuracy of ±2 min per month§ Operating temperature range of 0°C to +70°C § Low-profile SIP module§ Underwriters Laboratory (UL) recognized PIN ASSIGNMENTPIN DESCRIPTIONRST- Reset CLK - ClockDQ - Data Input/Output GND - Ground V CC - +5VOSC - 1Hz Oscillator Output NC- No ConnectDESCRIPTIONThe DS1603 is a real -time clock/elapsed time counter designed to count seconds when V CC power is applied and continually count seconds under battery backup power with an additional counter regardless of the condition of V CC . The continuous counter can be used to derive time of day, week, month, and year by using a software algorithm. The V CC powered counter will automatically record the amount of time that V CC power is applied. This function is particularly useful in determining the operational time of equipment in which the DS1603 is used. Alternatively, this counter can also be used under software control to record real -time events. Communication to and from the DS1603 takes place via a 3-wire serial port. A 1-byte protocol selects read/ write functions, counter clear functions and oscillator trim. The device contains a 32.768kHz crystal that will keep track of time to within ±2 min/mo. An internal lithium energy source contains enough energy to power the continuous seconds counter for over 10 years.OPERATIONThe main elements of the DS1603 are shown in Figure 1. As shown, communications to and from the elapsed time counter occur over a 3-wire serial port. The port is activated by driving RST to a high state.V CC RST DQ NC CLK OSC GND DS1603Elapsed Time Counter Moduleselect, register clear, and oscillator trim information. Each bit is serially input on the rising edge of the clock input. After the first eight clock cycles have loaded the protocol register with a valid protocol additional clocks will output data for a read or input data for a w rite. V CC must be present to access the DS1603. If V CC < V TP, the DS1603 will switch to internal power and disable the serial port to conserve energy. When running off of the internal power supply, only the continuous counter will continue to count and the counter powered by V CC will stop, but retain the count, which had accumulated when V CC power was lost. The 32-bit V CC counter is gated by V CC and the internal 1Hz signal.PROTOCOL REGISTERThe protocol bit definition is shown in Figure 2. Valid protocols and the resulting actions are shown in Table 1. Each data transfer to the protocol register designates what action is to occur. As defined, the MSB (bit 7 which is designated ACC) selects the 32-bit continuous counter for access. If ACC is a logical 1 the continuous counter is selected and the 32 clock cycles that follow the protocol will either read or write this counter. If the counter is being read, the contents will be latched into a different register at the end of protocol and the latched contents will be read out on the next 32 clock cycles. This avoids reading garbled data if the counter is clocked by the oscillator during a read. Similarly, if the counter is to be written, the data is buffered in a register and all 32 bits are jammed into the counter simultaneously on the rising edge of the 32nd clock. The next bit (bit 6 which is designated AVC) selects the 32–bit V CC active counter for access. If AVC is a logical 1 this counter is selected and the 32 clock cycles that follow will either read or write this counter. If both bit 7 and bit 6 are written to a logic high, all clock cycles beyond the protocol are ignored and bit 5, 4, and 3 are loaded into the oscillator trim register. A value of binary 3 (011) will give a clock accuracy of ±120 seconds per month at +25°C. Increasing the binary number towards 7 will cause the real-time clock to run faster. Conversely, lowering the binary number towards 0 will cause the clock to run slower. Binary 000 will stop the oscillator completely. This feature can be used to conserve battery life during storage. In this mode the internal power supply current is reduced to 100 nA maximum. In applications where oscillator trimming is not practical or not needed, a default setting of 011 is recommended. Bit 2 of protocol (designated CCC) is used to clear the continuous counter. When set to logic 1, the continuous counter will reset to 0 when RST is taken low. Bit 1 of protocol (designated CVC) is used to clear the V CC active counter. When set to logical 1, the V CC active counter will reset to 0 when RST is taken low. Both counters can be reset simultaneously by setting CCC and CVC both to a logical 1. Bit 0 of the protocol (designated RD) determines whether the 32 clocks to follow w ill write a counter or read a counter. When RD is set to a logical 0 a write action will follow when RD is set to a logical 1 a read action will follow. When sending the protocol, 8 bits should always be sent. Sending less than 8 bits can produce erroneous results. If clearing the counters or trimming the oscillator, the data transfer can be terminated after the 8-bit protocol is sent. However, when reading or writing the counters, 32 clock cycles should always follow the protocol.RESET AND CLOCK CONTROLAll data transfers are initiated by driving the RST input high. The RST input has two functions. First, RST turns on the serial port logic, which allows access to the protocol register for the protocol data entry. Second, the RST signal provides a method of terminating the protocol transfer or the 32-bit counter transfer. A clock cycle is a sequence of a rising edge followed by a falling edge. For write inputs, data must be valid during the rising edge of the clock. Data bits are output on the falling edge of the clock when data is being read. All data transfers terminate if the RST input is transitioned low and the DQ pin goes to a high-impedance state. RST should only be transitioned low while the clock is high to avoid disturbing the last bit of data. All data transfers must consist of 8 bits when transferring protocol only or 8 + 32 bits when reading or writing either counter. Data tran sfer is illustrated in Figure 3.DATA INPUTFollowing the 8-bit protocol that inputs write mode, 32 bits of data are written to the selected counter on the rising edge of the next 32 CLK cycles. After 32 bits have been entered any additional CLK cycles will be ignored until RST is transitioned low to end data transfer and then high again to begin new data transfer.DATA OUTPUTFollowing the eight CLK cycles that input read mode protocol, 32 bits of data will be output from the selected counter on the next 32 CLK cycles. The first data bit to be transmitted from the selected 32-bit counter occurs on the falling edge after the last bit of protocol is written. When transmitting data from the selected 32-bit counter, RST must remain at high level as a transition to low level will terminate data transfer. Data is driven out the DQ pin as long as CLK is low. When CLK is high the DQ pin is tristated. OSCILLATOR OUTPUTPin 6 of the DS1603 module is a 1Hz output signal. This signal is present only when V CC is applied and greater than the internal power supply. However, the output is guaranteed to meet TTL requirement only while V CC is within normal limits. This output can be used as a 1-second interrupt or time tick needed in some applications.INTERNAL POWERThe internal battery of the DS1603 module provides 35mAh and will run the elapsed time counter for over 10 years in the absence of power.PIN DESCRIPTIONSV CC, GND – DC power is provided to the device on these pins. V CC is the +5V input. When 5V is applied within normal limits, the device is fully accessible and data can be written and read. When a 3V battery is connected to the device and V CC is below 1.25 x V BAT, reads and writes are inhibited. As V CC falls below V BAT the continuous counter is switched over to the internal battery.CLK (Serial Clock Input) – CLK is used to synchronize data movement on the serial interface.DQ (Data Input/Output) – The DQ pin is the bi-directional data pin for the 3-wire interface.RST (Reset) – The reset signal must be asserted high during a read or a write.OSC (One Hertz Output Signal) – This signal is only present when Vcc is at a valid level and the oscillator is enabled.Figure 1. ELAPSED TIME COUNTER BLOCK DIAGRAMFigure 2. PROTOCOL BIT MAP7 6 5 4 3 2 1 0ACC AVC OSC2 OSC1 OSC0 CCC CVC RDTable 1. VALID PROTOCOLSPROTOCOLACTIONACC AVC OSC2 OSC1 OSC0 CCC CVC RDFUNCTION ReadContinuous Counter 1 0 X X X X X 1Output continuouscounter on the 32 clocksfollowing protocol.Oscillator trim registeris not updated. Countersare not reset.WriteContinuous Counter 1 0 X X X X X 0Input data to continuouscounter on the 32 clocksfollowing protocol.Oscillator trim registeris not updated. Countersare not reset.Read V CCActive Counter 0 1 X X X X X 1Output V CC activecounter on the 32 clocksfollowing protocol,oscillator trim registeris not updated. Countersare not reset.Write V CCActive Counter 0 1 X X X X X 0Input data to continuouscounter on the 32 clocksfollowing protocol.Oscillator trim registeris not updated. Countersare not reset.ClearContinuous Counter 0 0 X X X 1 X XResets the continuouscounter to all zeros atthe end of protocol.Oscillator trim registeris not updated.Clear V CCActive Counter 0 0 X X X X 1 XResets the V CC activecounter to all zeros atthe end of protocol.Oscillator trim registeris not updated.Set Oscillator Trim Bits 1 1 A B C X X 0Sets the oscillator trimregister to a value ofABC. Counters areunaffected.X = Don’t CareFigure 3. DATA TRANSFERTIMING DIAGRAM: READ/WRITE DATA TRANSFERNote: t CL, t CH, t R, and t F apply to both read and write data transfer.ABSOLUTE MAXIMUM RATINGSVoltage Range on Any Pin Relative to Ground -0.3V to +7.0VOperating Temperature Range 0°C to +70°CStorage Temperature Range -40°C to +70°CSoldering Temperature Range See IPC/JEDEC J-STD-020A (See Note 11)This is a stress rating only and functional operation of the device at these or any other conditions beyond t h ose indicated in the operation sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods of time can affect reliability.RECOMMENDED DC OPERATING CONDITIONS (0°C to +70°C) PARAMETER SYMBOL MIN TYP MAX UNITS NOTES Supply Voltage V CC 4.5 5.0 5.5 V 1 Logic 1 Input V IH 2.0 V CC + 0.3 V 1 Logic 0 Input V IL-0.3 0.8 V 1DC ELECTRICAL CHARACTERISTICS (0°C to +70°C; V CC = 5V ±10%) PARAMETER SYMBOL MIN TYP MAX UNITS NOTES Input Leakage I LI-1 +1 µAI/O Leakage I LO-1 +1 µALogic 1 Output V OH 2.4 V 2 Logic 0 Output V OL0.4 V 3 Active Supply Current I CC 1 mA 4 Timekeeping Current I CC150 µA 5 Battery Trip Point V TP 3.0 4.5 V 9 CAPACITANCE (T A = +25°C) PARAMETER SYMBOL MIN TYP MAX UNITS NOTES Input Capacitance C I 5 pFI/O Capacitance C I/O10 pF(T A = +25°C) PARAMETER SYMBOL MIN TYP MAX UNITS NOTES Expected Datat DR10 years 10 Retention TimeNOTES:1) All voltages are referenced to ground.2) Logic 1 voltages are specified at a source current of 1mA.3) Logic 0 voltages are specified at a sink current of 4mA.4) I CC is specified with the DQ pin open.5) I CC1 is specified with V CC at 5.0V and RST = GND.6) Measured at V IH= 2.0V or V IL = 0.8V.7) Measured at V OH = 2.4V or V OL - 0.4V.8) Load capacitance = 50pF.9) Battery trip point is the point at which the V CC powered counter and the serial port stops operation.The battery trip point drops below the minimum once the internal lithium energy cell is exhausted. 10) The expected t D R is defined as accumulative time in the absence of V CC with the clock oscillatorrunning.11) Real-time clock modules can be successfully processed through conventional wave-solderingtechniques as long as temperature exposure to the lithium energy source contained within does not exceed +85°C. Post-solder cleaning with water-washing techniques is acceptable, provided that ultrasonic vibration is not used.DS1603DS1603 7-PIN MODULEPKG7-PIN DIM MIN MAX A IN. MM 0.830 21.08 0.850 21.59 B IN. MM 0.650 16.51 0.670 17.02 C IN. MM 0.310 7.87 0.330 8.38 D IN. MM 0.015 0.38 0.030 0.76 E IN. MM 0.110 2.79 0.140 3.56 F IN. MM 0.015 0.38 0.021 0.53 G IN. MM 0.090 2.29 0.110 2.79 H IN. MM 0.105 2.67 0.135 3.43 J IN. MM 0.360 9.14 0.390 9.91分销商库存信息: MAXIMDS1603。

山特产品速查手册SANTAK PRODUCT QUICK REFERENCE 全面保护用心为安全2 | 山特产品速查手册目 录Contents后备式UPSTG-E1000/500, TG1000/500, ET1100/550, K500/K1000 PRO, MT500/1000, TG-BOX 600/850, SP-BOX 在线式UPS塔式C1-3K, 塔式C6-10K, 3C 10-20K, 机架式C1-3kVA Rack, 机架式C6-10kVA Rack, 3C3 Pro (20-200kVA), 3C3 Pro ISO (15 -200kVA), 3C3 HD (20-80kVA), 3C3 HD (400-600kVA),SPU1-20K 电力行业专用 UPS, SIU 10-200K 山特工业级 UPS 灵霄系列PT 3000 (1-3kVA), PT 3000 (6-20kVA)模块式UPSARRAY 3A3 Pro 系列 (15～150kVA), ARRAY 3A3 PT 系列 (25～200kVA), ARRAY 3A3 PT 系列 (60～600kVA)蓄电池C12系列电池, G 系列胶体蓄电池, ARRAY 系列蓄电池, SBC-A 电池柜微模块灵聚2.0微模块产品系列, 灵聚 2.0 Aisle 配电机柜配电单元 (PDU)精密空调全变频小型精密空调 (7.5-20kW), 定频小型精密空调(7.5-20kW), 双轴流小型机房空调, 机房专用空调(25-100kW), 列间精密空调 (SMCRC 系列)机柜S 系列机柜移动电站3-1314-3839-4546-4950-5455-606162-7273 74-75山特后备式TG-E系列UPS⸺美观时尚的“设备守护神”。

TG-E500/1000 UPS功能强大，集智慧、安全、可靠于一身，提升消费者在产品品质、观感、质感方面的使用体验。

第一部AF空压机简述感谢您选择我们的压缩机本手册介绍AF空压机气路、水路、润滑系统及安装场地第二部CE & MC 用户指导手册感谢您选择我们的压缩机本手册会为您的压缩机提供安装, 操作，检查，维修的指导说明第三部Aircon L1控制器Software L1 AF AP 08用户手册Nota 25401/12/2001Bar PSIC FAF公司简介AF 一家130年历史的空压机制造商。

1870年，芳帅公司成立于比利时的列日，1960年，爱得乐芳帅成立，旨在面向全世界提供本公司的产品与服务。

二十世纪八十年代初，第一台吹PET瓶用的40巴无油往复式空压机问世，现在，这种与PET吹瓶机配套的活塞式空压机是爱得乐芳帅公司的主要产品。

到二十世纪九十年AF的全球发展蒸蒸日上，已成立了AF 美国、AF 墨西哥、AF亚洲等公司。

AF 美国服务于北美，AF墨西哥服务于墨西哥、中美以及南美，AF亚洲服务于远东、法兰西以及荷兰。

以下是基础培训向导，希望能帮助您更好地了解AF空压机。

看完这个说明书您若有任何疑问请跟我们联系，我们将很乐意为您提供服务。

AF空气压缩机●AF 空压机是一种高压、无油、往复活塞式空气压缩机，其设计用于PET吹瓶领域以及塑料工业。

●该压缩机为容积式机器，其分为三段压缩，装配有PTFE 活塞环和支承环。

同一气缸装配有相同数量的吸排气阀，不同型号的压缩机其吸排气阀的数量分别为2至6只不等。

●无油多级压缩的设计保证压缩机为吹瓶机提供高压、常温、洁净、干燥的气体。

●每两级之间压缩空气被冷却到40至60度，并且在不损失压缩空气的情况下排出冷凝水。

●当达到预设的压力时压缩机自动转到卸载运行模式，此时压缩机通过卸载器打开吸气阀以停止压缩空气。

当系统压力下降到设定压力时压缩机自控系统关闭吸气阀，进入加载运行模式开始压缩空气。

●三级L-型无油往复式空压机●100%无油运行的PTFE 活塞环。

●第一级为高效率双作用缸。

Serie | 6, Forno da incasso, 60 cm, Acciaio inoxHBA557BS0Accessori opzionaliHEZ317000 , HEZ327000 Pietra per pane e pizza, HEZ530000 , HEZ531000 Leccarda bassa 455x375x30 mm (LxPxA),HEZ531010 Leccarda antiaderen 455x375x30mm (LxPxA),HEZ532000 Leccarda profonda 455x375x38 mm (LxPxA),HEZ532010 Leccarda antiaderen 455x400x38mm (LxPxA),HEZ538000 Guide telescopiche clip a 1 livello, HEZ538200 Guide telescopiche a 2 livelli, HEZ538S00 Guide telescop. a 2 livelli+1 guida clip, HEZ625071 , HEZ633001 Coperchio per tegame professionale, HEZ633070 , HEZ634000 , HEZ636000 Leccarda in vetro 455x364x30 mm (LxPxA), HEZ638200 , HEZ638300 , HEZ915003 Pirofila in vetro con coperchio 5,4 l.Forno da incasso di moderno ed elegante design con programmi automatici di cottura: per preparare piatti perfetti. Cottura HotAir 3D: risultati perfetti di cottura grazie alla distribuzione omogenea del aria al interno della cavità, che consente di cucinare fino a 3 livelli allo stesso tempo. Programmi automatici di cottura: cucinare sarà semplicissimo grazie ai programmi con impostazioni già preselezionate. Comode manopole a scomparsa push-pull: per una pulizia piùsemplice del panello frontale.EcoClean Direct: un modo semplice, ecologico, sicuro ed economico per auto pulire il forno durante il processo di cottura, senza alcun detergente o agente chimico.Dati tecniciColore/materiale del frontale : Acciaio inox Tipologia costruttiva del prodotto : Da incasso Sistema di pulizia :Autopulizia idrolitica, Catalisi totale, Catalisi totale Dimensioni del vano per l'installazione (AxLxP) (mm) :585-595 x 560-568 x 550 Dimensioni del prodotto (mm) : 595 x 594 x 548 Dimensioni del prodotto imballato (AxLxP) (mm) :675 x 690 x 660 Materiale del cruscotto : acciaio inox Materiale porta : vetro Peso netto (kg) : 33,042 Volume utile (l) : 71 Metodo di cottura : aria calda, ariacalda intensiva, Grill a superficie grande, grill ventilato, Hotair gentle, riscaldamento inferiore, riscaldamento superiore/infer. Materiale della cavità : Other Regolazione della temperatura : Meccanico Numero di luci interne : 1 Certificati di omologazione : CE, VDE Lunghezza del cavo di alimentazione elettrica (cm) : 120 Codice EAN : 4242005028986 Numero di vani - (2010/30/CE) : 1 Classe di efficienza energetica (2010/30/EC) : A Energy consumption per cycle conventional (2010/30/EC) :0,97 Energy consumption per cycle forced air convection (2010/30/ EC) : 0,81 Indice di efficienza energetica (2010/30/CE) : 95,3 Dati nominali collegamento elettrico (W) : 3400 Corrente (A) : 16 Tensione (V) : 220-240 Frequenza (Hz) : 60; 50 Tipo di spina : Schuko'!2E20A F-a c i j i g!1/3Serie | 6, Forno da incasso, 60 cm, AcciaioDimensioniinoxHBA557BS0Forno da incasso di moderno ed elegantedesign con programmi automatici di cottura:per preparare piatti perfetti.-Pannelli catalitici Eco Clean: soffitto, parete posteriore, paretilaterale-Programma di pulizia EcoClean-Display digitale LCD a colore bianco-Comode manopole a scomparsa push-pull-Forno elettrico da incasso con 7 funzioni cottura: MultiCotturaHotAir 3D, Riscaldamento superiore e inferiore, Grill ventilato,Grill a superficie grande, Funzione pizza, Riscaldamentoinferiore, Aria calda delicata-Funzione Sprint di riscaldamento rapido-Programmi automatici: 10-Orologio elettronico con impostazione inizio e fine cottura-Regolazione precisa della temperatura da 50-275° C-Raggiungimento temperatura-Illuminazione interna alogena-Volume cavità: 71 l-Classe di efficienza energetica A-Interno porta in vetro-Porta coolGlass: Temperatura porta max. 40°C-<8088brandlookup_nl(TUE, KIN, SIK, SIB, REW, STA, TKS)>-Raffreddamento tangenziale-Accessori in dotazione: 1 leccarda universale profondasmaltata, 1 griglia combinata.-Dimensioni apparecchio (AxLxP): 595 mm x 594 mm x 548mm-Dimensioni nicchia (AxLxP): 560 mm - 568 mm x 585 mm -595 mm x 550 mm-Si prega di fare riferimento alle quote d'installazione mostratenel disegno tecnico-Classe di efficienza energetica (acc. EU Nr. 65/2014): A(in una scala di classi di efficienza energetica da A+++ aD) Consumo energetico per ciclo durante funzionamentoconvenzionale: 0.97 kWh Consumo energetico per ciclodurante funzionamento ventilato: 0.81 kWh Numero di cavità:1 Tipo di alimentazione: elettrica Volume della cavità: 71 lEtichetta energetica-Classe di efficienza energetica (acc. EU Nr. 65/2014): A(in una scala di classi di efficienza energetica da A+++ aD) Consumo energetico per ciclo durante funzionamentoconvenzionale: 0.97 kWh Consumo energetico per ciclodurante funzionamento ventilato: 0.81 kWh Numero di cavità:1 Tipo di alimentazione: elettrica Volume della cavità: 71 l2/3Serie | 6, Forno da incasso, 60 cm, AcciaioinoxHBA557BS03/3。

《深度解析1603hfr-hs规格书》1. 前言在当今日益发展的科技领域，各种高新技术产品层出不穷，而1603hfr-hs规格书无疑是其中的热门话题之一。

本文将针对1603hfr-hs规格书展开深度解析，为您呈现一份高质量、深度和广度兼具的文章。

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在研发、生产和销售环节中，1603hfr-hs规格书扮演着至关重要的角色，它不仅是产品的“唯一识别信息”，也是产品与用户沟通的桥梁。

3. 深度评估1603hfr-hs规格书要全面评估1603hfr-hs规格书，首先需要从外观尺寸、功能参数和性能指标等方面展开深度探讨。

外观尺寸直接影响产品的实际应用场景，功能参数则决定了产品的基本功能特性，而性能指标则是产品质量和性能的重要衡量标准。

细致的评估将为用户提供直观、清晰的产品信息。

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广度评估也需要考虑到产品的兼容性、可扩展性等方面的内容，以期产品的个性化需求在规格书中得到满足。

5. 总结回顾1603hfr-hs规格书总结回顾是深入理解1603hfr-hs规格书的关键步骤，它不仅可以帮助用户更全面、深刻地掌握产品信息，还能为进一步的研究和应用提供重要参考。

在总结回顾中，要对产品的重要特性和性能指标进行梳理，归纳分析产品的优势和不足，并探讨其潜在的应用前景和发展方向。

这样的回顾性内容将为用户提供更为灵活、全面的了解和运用指导。

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一个完善的规格书不仅能够帮助用户更好地了解产品，还能为产品的研发和生产提供必要的指导和依据。

信义160lowe参数（最新版）目录1.信义 160lowe 简介2.信义 160lowe 参数详解3.参数对信义 160lowe 性能的影响4.信义 160lowe 的应用领域5.信义 160lowe 的优缺点分析正文一、信义 160lowe 简介信义 160lowe 是一款高性能的中央空调，采用了先进的技术和优质的材料制造，具有节能、环保、高效等特点，广泛应用于商业和工业建筑。

二、信义 160lowe 参数详解信义 160lowe 的主要参数包括：制冷量、制热量、风量、功率、电压等。

1.制冷量：信义 160lowe 的制冷量达到了 160 匹，可以满足大型建筑物的制冷需求。

2.制热量：信义 160lowe 的制热量也达到了 160 匹，即使在寒冷的冬季也能提供足够的热量。

3.风量：信义 160lowe 的风量大，可以快速循环室内空气，提高空调效果。

4.功率：信义 160lowe 的功率适中，既能保证空调的性能，又不会浪费能源。

5.电压：信义 160lowe 的电压为 380V，适合工业和商业用电。

三、参数对信义 160lowe 性能的影响信义 160lowe 的各项参数决定了其制冷、制热、通风等性能。

制冷量和制热量越大，空调的制冷和制热效果越好；风量越大，空调的通风效果越好；功率和电压则影响空调的能耗和适用范围。

四、信义 160lowe 的应用领域信义 160lowe 广泛应用于商业和工业建筑，如商场、办公楼、工厂、仓库等。

五、信义 160lowe 的优缺点分析信义 160lowe 的优点包括：制冷和制热效果好，能耗低，使用寿命长，维护方便等。

WIFI风扇应用系统框架图
使用注意事项
- 为了避免金属屏蔽效应影响通信，WIFI风扇与金属/家电需保持50cm以上距离；- 支持设备：
iOS 6.0及以上操作系统的移动终端；
Android 2.3.6及以上操作系统的移动终端；
- 在2G/3G/4G网络下使用美的APP软件进行远程操作，会产生通信流量；
- 如需获得更多信息和服务，请拨打美的服务热线：400-8899-315。

打开阿里智能APP，点击登录。

输入账号和密码进行登录（如没账号需
先进行注册）。

等待配网完成。

添加成功后，会进入该家电的控制页面
（控制页面也可以从首页点击该家电进入）。

3、家电配网流程
登录成功后，点击添加设备。

点击“按分类查找”->“风扇”->“美的
风扇FS40-16FRA”，如图示按提示操作
家电，将风扇上电后，在开机状态下，同时
按下“风类”和“摇头”键，听到滴一声，
家电进入配网模式，APP上点击“下一步”。

输入要连接到的WiFi密码，点击“搜索设备”。

4、风扇与阿里智能APP连接后，使用APP控制开关、风类、风速及设置定时预约
在APP首页，点击要控制的家电。

在控制界面可对开关机、风类和风速进行
控制。

在开机状态下可设置预约，在关机状态下
可设置定时。

APP定时时间小于30分钟
以下的数码屏显示0.5小时，大于等于30
分钟以上的显示1小时，10小时以上时间
位显示1小时方式。

6
87。

© 2007 Microchip Technology Inc.DS22042A-page 1MCP1603Features•Over 90% Typical Efficiency •Output Current Up To 500mA•Low Quiescent Current = 45µA, typical •Low Shutdown Current = 0.1µA, typical •Adjustable Output Voltage: -0.8V to 4.5V•Fixed Output Voltage:- 1.2V, 1.5V, 1.8V, 2.5V, and 3.3V• 2.0MHz Fixed-Frequency PWM (Heavy Load)•Automatic PWM to PFM Mode Transition •100% Duty Cycle Operation •Internally Compensated•Undervoltage Lockout (UVLO)•Overtemperature Protection •Space Saving Packages:-5-Lead TSOT -8-Lead 2X3 DFNApplications•Cellular Telephones •Portable Computers •Organizers / PDAs •USB Powered Devices •Digital Cameras •Portable Equipment•+5V or +3.3V Distributed SystemsGeneral DescriptionThe MCP1603 is a high efficient, fully integrated 500mA synchronous buck regulator whose 2.7V to 5.5V input voltage range makes it ideally suited for applications powered from 1-cell Li-Ion or 2-cell/3-cell NiMH/NiCd batteries.At heavy loads, the MCP1603 operates in the 2.0MHz fixed frequency PWM mode which provides a low noise, low output ripple, small-size solution. When the load is reduced to light levels, the MCP1603automatically changes operation to a PFM mode to minimize quiescent current draw from the battery. No intervention is necessary for a smooth transition from one mode to another. These two modes of operation allow the MCP1603 to achieve the highest efficiency over the entire operating current range.The MCP1603 is available with either an adjustable or fixed output voltage. The available fixed output voltage options are 1.2V, 1.5V, 1.8V, 2.5V, and 3.3V. When a fixed option is used, only three additional small external components are needed to form a complete solution.Couple this with the low profile, small-foot print packages and the entire system solution is achieved with minimal size.Additional protection features include: UVLO,overtemperature, and overcurrent protection.Package Types12345L XV FB /V OUT SHDNGND V IN 5-Lead TSOTMCP160312345L XV FB /V OUTSHDN GND V IN MCP1603L12348765L X V FB /V OUT SHDN GND V IN NC NC NC8-Lead 2x3 DFN 2.0MHz, 500mA Synchronous Buck RegulatorMCP1603DS22042A-page 2© 2007 Microchip Technology Inc.© 2007 Microchip Technology Inc.DS22042A-page 3MCP1603Functional Block DiagramILIM PWMILIM PFMIPEAK PWM IPEAK PFMV INSHDNV FB /V OUTGNDL XBand GapUVLOSwitch Drive UVLOV REFLogic and timing S RQQ Soft StartV REFPWM/PFM LogicV REFSlope CompOSC-I PK LimitUVLO Thermal ShutdownTSDEAPOFF NOFFPWM/PFMTSDPFM Error AmpPWM Error AmpOV ThresholdUV ThresholdI PK Limit-ILPKIPEAK PWMIPEAK PFMDisable Switcher-ILPKMCP1603DS22042A-page 4© 2007 Microchip Technology Inc.1.0ELECTRICALCHARACTERISTICSAbsolute Maximum Ratings †V IN - GND.......................................................................+6.0V All Other I/O ...............................(GND - 0.3V) to (V IN + 0.3V)L X to GND..............................................-0.3V to (V IN + 0.3V)Output Short Circuit Current..................................Continuous Power Dissipation (Note 5)..........................Internally Limited Storage Temperature.....................................-65°C to +150°C Ambient Temp. with Power Applied.................-40°C to +85°C Operating Junction Temperature...................-40°C to +125°C ESD Protection On All Pins:HBM..............................................................................4kV MM. (300V)† Notice: Stresses above those listed under "Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at those or any other conditions above those indicated in the operational sections of this specification is not intended.Exposure to maximum rating conditions for extended periods may affect device reliability.DC CHARACTERISTICSElectrical Characteristics: Unless otherwise indicated, V IN = SHDN = 3.6V, C OUT = C IN = 4.7µF, L = 4.7µH, V OUT (ADJ)=1.8V, I OUT =100mA, T A = +25°C. Boldface specifications apply over the T A range of -40°C to +85°C.ParametersSym Min Typ Max Units ConditionsInput Characteristics Input VoltageV IN 2.7— 5.5V Note 1Maximum Output Current I OUT 500——mA Note 1Shutdown Current I IN_SHDN—0.11µA SHDN = GNDQuiescent CurrentI Q —4560µASHDN = V IN , I OUT = 0mAShutdown/UVLO/Thermal Shutdown CharacteristicsSHDN, Logic Input Voltage Low V IL ——15%V IN V IN = 2.7V to 5.5V SHDN, Logic Input Voltage High V IH 45——%V IN V IN = 2.7V to 5.5V SHDN, Input Leakage Current I L_SHDN -1.0±0.1 1.0µA V IN = 2.7V to 5.5V Undervoltage LockoutUVLO2.12 2.28 2.43V V IN FallingUndervoltage Lockout Hysteresis UVLO HYS —140—mV Thermal Shutdown T SHD —150—°C Note 4, Note 5Thermal Shutdown Hysteresis T SHD-HYS—10—°CNote 4, Note 5Note 1:The minimum V IN has to meet two conditions: V IN ≥ 2.7V and V IN ≥ V OUT + 0.5V.2:Reference Feedback Voltage Tolerance applies to adjustable output voltage setting.3:V R is the output voltage setting.4:The maximum allowable power dissipation is a function of ambient temperature, the maximum allowable temperature and the thermal resistance from junction to air (i.e. T A , T J , θJA ). Exceeding the maximum allowable power dissipation causes the device to initiate thermal shutdown.5:The internal MOSFET switches have an integral diode from the L X pin to the V IN pin, and from the L X pin to the GND pin. In cases where these diodes are forward-biased, the package power dissipation limits must be adhered to. Thermal protection is not able to limit the junction temperature for these cases.6:The current limit threshold is a cycle-by-cycle peak current limit.© 2007 Microchip Technology Inc.DS22042A-page 5MCP1603Output Characteristics Adjustable Output Voltage Range V OUT 0.8— 4.5V Note 2Reference Feedback Voltage V FB—0.8—V Reference Feedback Voltage Tolerance-3.0—+3.0%T A = -40°C to +25°C -2.5—+2.5%T A = +25°C to +85°C Feedback Input Bias Current I VFB —0.1—nA Output Voltage Tolerance Fixed V OUT -3.0%V R +3.0%%T A = -40°C to +25°C, Note 3V OUT -2.5V R +2.5%T A = +25°C to +85°C, Note 3Line Regulation V LINE-REG—0.3—%/V V IN = V R + 1V to 5.5V, I OUT =100mALoad RegulationV LOAD-REG—0.35—%V IN =V R +1.5V,I LOAD =100mA to 500mA Internal Oscillator Frequency F OSC 1.5 2.0 2.8MHz Start Up Time T SS —0.6—ms T R =10%to 90%R DSon P-Channel R DSon-P —500—m ΩI P =100mA R DSon N-Channel R DSon-N —500—m ΩI N =100mAL X Pin Leakage Current I LX -1.0±0.1 1.0µA SHDN =0V, V IN =5.5V, L X =0V, L X =5.5V Positive Current Limit Threshold +I LX(MAX)—860—mANote 6DC CHARACTERISTICS (CONTINUED)Electrical Characteristics: Unless otherwise indicated, V IN = SHDN = 3.6V, C OUT = C IN = 4.7µF, L = 4.7µH, V OUT (ADJ)=1.8V, I OUT =100mA, T A = +25°C. Boldface specifications apply over the T A range of -40°C to +85°C.ParametersSym Min Typ Max Units ConditionsNote 1:The minimum V IN has to meet two conditions: V IN ≥ 2.7V and V IN ≥ V OUT + 0.5V.2:Reference Feedback Voltage Tolerance applies to adjustable output voltage setting.3:V R is the output voltage setting.4:The maximum allowable power dissipation is a function of ambient temperature, the maximum allowable temperature and the thermal resistance from junction to air (i.e. T A , T J , θJA ). Exceeding the maximum allowable power dissipation causes the device to initiate thermal shutdown.5:The internal MOSFET switches have an integral diode from the L X pin to the V IN pin, and from the L X pin to the GND pin. In cases where these diodes are forward-biased, the package power dissipation limits must be adhered to. Thermal protection is not able to limit the junction temperature for these cases.6:The current limit threshold is a cycle-by-cycle peak current limit.MCP1603DS22042A-page 6© 2007 Microchip Technology Inc.TEMPERATURE SPECIFICATIONSElectrical Specifications: Unless otherwise indicated, all limits are specified for: V IN +2.7V to 5.5VParametersSymMinTypMaxUnitsConditionsTemperature RangesOperating Junction Temperature RangeT J -40—+125°C Steady StateStorage Temperature Range T A -65—+150°C Maximum Junction Temperature T J——+150°CTransient Package Thermal Resistances Thermal Resistance, 5L-TSOT θJA —256—°C/W Typical 4-layer Board with Internal Ground Plane Thermal Resistance, 8L-2x3 DFNθJA—84.5—°C/WTypical 4-layer Board with Internal Ground Plane and 2-Vias in Thermal PadMCP1603 2.0TYPICAL PERFORMANCE CURVESNote: Unless otherwise indicated, V IN=SHDN=3.6V, C OUT=C IN= 4.7µF, L = 4.7µH, V OUT(ADJ)= 1.8V, I LOAD=100mA, T A=+25°C. Adjustable or fixed output voltage options can be used to generate the Typical Performance Characteristics.FIGURE 2-1:I Q vs. Ambient Temperature. FIGURE 2-2:Efficiency vs. Input Voltage (V OUT = 1.2V).FIGURE 2-3:Efficiency vs. Input Voltage (V OUT = 1.8V).FIGURE 2-4:I Q vs. Input Voltage. FIGURE 2-5:Efficiency vs. Output Load (V OUT = 1.2V).FIGURE 2-6:Efficiency vs. Output Load (V OUT = 1.8V).Note:The graphs and tables provided following this note are a statistical summary based on a limited number of samples and are provided for informational purposes only. The performance characteristics listed herein are not tested or guaranteed. In some graphs or tables, the data presented may be outside the specifiedoperating range (e.g., outside specified power supply range) and therefore outside the warranted range.© 2007 Microchip Technology Inc.DS22042A-page 7MCP1603DS22042A-page 8© 2007 Microchip Technology Inc.Typical Performance Curves (Continued)Note: Unless otherwise indicated, V IN =SHDN =3.6V, C OUT =C IN = 4.7µF, L = 4.7µH, V OUT (ADJ)= 1.8V, I LOAD =100mA,T A =+25°C. Adjustable or fixed output voltage options can be used to generate the Typical Performance Characteristics.FIGURE 2-7:Efficiency vs. Input Voltage(V OUT = 2.4V).FIGURE 2-8:Efficiency vs. Input Voltage(V OUT = 3.3V).FIGURE 2-9:Line Regulation vs. Ambient Temperature (V OUT = 1.8V).FIGURE 2-10:Efficiency vs. Output Load(V OUT = 2.4V).FIGURE 2-11:Efficiency vs. Output Load(V OUT = 3.3V).FIGURE 2-12:Output Voltage vs. Load Current (V OUT = 1.8V).MCP1603Typical Performance Curves (Continued)Note: Unless otherwise indicated, V IN=SHDN=3.6V, C OUT=C IN= 4.7µF, L = 4.7µH, V OUT(ADJ)= 1.8V, I LOAD=100mA, T A=+25°C. Adjustable or fixed output voltage options can be used to generate the Typical Performance Characteristics.FIGURE 2-13:Switching Frequency vs. Ambient Temperature.FIGURE 2-14:Switch Resistance vs. Input Voltage.FIGURE 2-15:Output Voltage Startup Waveform.FIGURE 2-16:Switching Frequency vs. Input Voltage.FIGURE 2-17:Switch Resistance vs. Ambient Temperature.FIGURE 2-18:Heavy Load Switching Waveform.© 2007 Microchip Technology Inc.DS22042A-page 9MCP1603DS22042A-page 10© 2007 Microchip Technology Inc.Typical Performance Curves (Continued)Note: Unless otherwise indicated, V IN =SHDN =3.6V, C OUT =C IN = 4.7µF, L = 4.7µH, V OUT (ADJ)= 1.8V, I LOAD =100mA,T A =+25°C. Adjustable or fixed output voltage options can be used to generate the Typical Performance Characteristics.FIGURE 2-19:Light Load SwitchingWaveform.FIGURE 2-20:Output Voltage Load Step Response vs. Time.FIGURE 2-21:Output Voltage Line StepResponse vs. Time.3.0PIN DESCRIPTIONSThe descriptions of the pins are listed in Table3-1. TABLE 3-1:PIN FUNCTION TABLE3.1Power Supply Input Voltage Pin(V IN)Connect the input voltage source to V IN. The input source must be decoupled to GND with a 4.7µF capacitor.3.2Ground Pin (GND)Ground pin for the device. The loop area of the ground traces should be kept as minimal as possible.3.3Shutdown Control Input Pin(SHDN)The SHDN pin is a logic-level input used to enable or disable the device. A logic high (> 45% of V IN) will enable the regulator output. A logic-low (< 15% of V IN) will ensure that the regulator is disabled.3.4Feedback / Output Voltage Pin(V FB/V OUT)For adjustable output options, connect the center of the output voltage divider to the V FB/V OUT pin. For fixed-output voltage options, connect the output directly to the V FB/V OUT pin.3.5Switch Node, Buck InductorConnection Pin (L X)Connect the L X pin directly to the buck inductor. This pin carries large signal-level current; all connections should be made as short as possible.3.6Exposed Metal Pad (EP)For the DFN package, connect the Exposed Pad to GND, with vias into the GND plane. This connection to the GND plane will aid in heat removal from the package.Pin No.Symbol DescriptionMCP1603 TSOT23MCP1603LTSOT232x3 DFN147V IN Power Supply Input Voltage Pin228GND Ground Pin313SHDN Shutdown Control Input Pin454V FB/V OUT Feedback / Output Voltage Pin531L X Switch Node, Buck Inductor Connection Pin ——2, 5, 6NC No Connect——ExposedPad EP For the DFN package, the center exposed pad is a thermal path to remove heat from the device. Electrically this pad is atground potential and should be connected to GND4.0DETAILED DESCRIPTION4.1Device OverviewThe MCP1603 is a synchronous buck regulator that operates in a Pulse Frequency Modulation (PFM) mode or a Pulse Width Modulation (PWM) mode to maximize system efficiency over the entire operating current range. Capable of operating from a 2.7V to 5.5V input voltage source, the MCP1603 can deliver 500mA of continuous output current.When using the MCP1603, the PCB area required for a complete step-down converter is minimized since both the main P-Channel MOSFET and the synchro-nous N-Channel MOSFET are integrated. Also while in PWM mode, the device switches at a constant frequency of 2.0MHz (typ) which allow for small filter-ing components. Both fixed and adjustable output voltage options are available. The fixed voltage options (1.2V, 1.5V 1.8V, 2.5V, 3.3V) do not require an external voltage divider which further reduces the required circuit board footprint. The adjustable output voltage options allow for more flexibility in the design, but require an external voltage divider.Additionally the device features undervoltage lockout (UVLO), overtemperature shutdown, overcurrent protection, and enable/disable control.4.2Synchronous Buck RegulatorThe MCP1603 has two distinct modes of operation that allow the device to maintain a high level of efficiency throughout the entire operating current and voltage range. The device automatically switched between PWM mode and PFM mode depending upon the output load requirements.4.2.1FIXED FREQUENCY, PWM MODE During heavy load conditions, the MCP1603 operates at a high, fixed switching frequency of 2.0MHz (typical) using current mode control. This minimizes output rip-ple (10 - 15mV typically) and noise while maintaining high efficiency (88% typical with V IN=3.6V, V OUT=1.8V, I OUT = 300mA).During normal PWM operation, the beginning of a switching cycle occurs when the internal P-Channel MOSFET is turned on. The ramping inductor current is sensed and tied to one input of the internal high-speed comparator. The other input to the high-speed compar-ator is the error amplifier output. This is the difference between the internal 0.8V reference and the divided-down output voltage. When the sensed current becomes equal to the amplified error signal, the high-speed comparator switches states and the P-Channel MOSFET is turned off. The N-Channel MOSFET is turned on until the internal oscillator sets an internal RS latch initiating the beginning of another switching cycle. PFM-to-PWM mode transition is initiated for any of the following conditions:•Continuous device switching•Output voltage has dropped out of regulation4.2.2LIGHT LOAD, PFM MODEDuring light load conditions, the MCP1603 operates in a PFM mode. When the MCP1603 enters this mode, it begins to skip pulses to minimize unnecessary quies-cent current draw by reducing the number of switching cycles per second. The typical quiescent current draw for this device is 45µA.PWM-to-PFM mode transition is initiated for any of the following conditions:•Discontinuous inductor current is sensed for a set duration•Inductor peak current falls below the transition threshold limit4.3Soft StartThe output of the MCP1603 is controlled during start-up. This control allows for a very minimal amount of V OUT overshoot during start-up from V IN rising above the UVLO voltage or SHDN being enabled.4.4Overtemperature Protection Overtemperature protection circuitry is integrated in the MCP1603. This circuitry monitors the device junction temperature and shuts the device off, if the junction temperature exceeds the typical 150°C threshold. If this threshold is exceeded, the device will automatically restart once the junction temperature drops by approximately 10°C. The soft start is reset during an overtemperture condition.4.5Overcurrent ProtectionCycle-by-cycle current limiting is used to protect the MCP1603 from being damaged when an external short circuit is applied. The typical peak current limit is 860mA. If the sensed current reaches the 860mA limit, the P-Channel MOSFET is turned off, even if the output voltage is not in regulation. The device will attempt to start a new switching cycle when the internal oscillator sets the internal RS latch.4.6Enable/Disable ControlThe SHDN pin is used to enable or disable the MCP1603. When the SHDN pin is pulled low, the device is disabled. When pulled high the device is enabled and begins operation provided the input voltage is not below the UVLO threshold or a fault condition exists.4.7Undervoltage Lockout (UVLO)The UVLO feature uses a comparator to sense the input voltage (V IN) level. If the input voltage is lower than the voltage necessary to properly operate the MCP1603, the UVLO feature will hold the converter off. When V IN rises above the necessary input voltage, the UVLO is released and soft start begins. Hysteresis is built into the UVLO circuit to compensate for input impedance. For example, if there is any resistance between the input voltage source and the device when it is operating, there will be a voltage drop at the input to the device equal to I IN x R IN. The typical hysteresis is 140mV.5.0APPLICATION INFORMATION 5.1Typical ApplicationsThe MCP1603 500mA synchronous buck regulator operates over a wide input voltage range (2.7V to5.5V) and is ideal for single-cell Li-Ion battery powered applications, USB powered applications, three cell NiMH or NiCd applications and 3V or 5V regulated input applications. The 5-lead TSOT and 8-lead 2x3 DFN packages provide a small footprint with minimal external components.5.2Fixed Output Voltage Applications Typical Application Circuit shows a fixed MCP1603 in an application used to convert three NiMH batteries into a well regulated 1.8V@500mA output. A 4.7µF input capacitor, 4.7µF output capacitor, and a 4.7µH inductor make up the entire external component solu-tion for this application. No external voltage divider or compensation is necessary. In addition to the fixed 1.8V option, the MCP1603 is also available in 1.2V, 1.5V, 2.5V, or 3.3V fixed voltage options.5.3Adjustable Output VoltageApplicationsWhen the desired output for a particular application is not covered by the fixed voltage options, an adjustable MCP1603 can be used. The circuit listed in Figure6-2 shows an adjustable MCP1603 being used to convert a 5V rail to 1.0V@500mA. The output voltage is adjust-able by using two external resistors as a voltage divider. For adjustable-output voltages, it is recommended that the top resistor divider value be 200kΩ. The bottom resistor value can be calculated using the following equation:EQUATION 5-1:For adjustable output applications, an additional R-C compensation network is necessary for control loop stability. Recommended values for any output voltage are:Refer to Figure6-2 for proper placement of R COMP andC COMP.5.4Input Capacitor SelectionThe input current to a buck converter, when operating in continuous conduction mode, is a squarewave with a duty cycle defined by the output voltage (V OUT) to input voltage (V IN) relationship of V OUT/V IN. To prevent undesirable input voltage transients, the input capacitor should be a low ESR type with an RMS current rating given by Equation5.5. Because of their small size and low ESR, ceramic capacitors are often used. Ceramic material X5R or X7R are well suited since they have a low temperature coefficient and acceptable ESR. EQUATION 5-2:Table5-1 contains the recommend range for the input capacitor value.5.5Output Capacitor SelectionThe output capacitor helps provide a stable output voltage during sudden load transients, smooths the current that flows from the inductor to the load, and reduces the output voltage ripple. Therefore, low ESR capacitors are a desirable choice for the output capac-itor. As with the input capacitor, X5R and X7R ceramic capacitors are well suited for this application.The output ripple voltage is often a design specifica-tion. A buck converters’ output ripple voltage is a function of the charging and discharging of the output capacitor and the ESR of the capacitor. This ripple voltage can be calculated by Equation5-3. EQUATION 5-3:R BOT R TOPV FBV OUT V FB–----------------------------⎝⎠⎛⎞×=Example:R TOP=200kΩV OUT= 1.0VV FB=0.8VR BOT=200kΩ x (0.8V/(1.0V-0.8V)) R BOT=800kΩ(Standard Value = 787kΩ)R COMP= 4.99kΩC COMP=33pFI CIN RMS,I OUT MAX,V OUT V IN V OUT–()×V IN-----------------------------------------------------⎝⎠⎜⎟⎛⎞×=ΔV OUTΔI L ESR×ΔI L8f C××--------------------+=Table5-1 contains the recommend range for the output capacitor value.5.6Inductor SelectionWhen using the MCP1603, the inductance value can range from 3.3µH to 10µH. An inductance value of 4.7µH is recommended to achieve a good balance between converter load transient response and mini-mized noise.The value of inductance is selected to achieve a desired amount of ripple current. It is reasonable to assume a ripple current that is 20% of the maximum load current. The larger the amount of ripple current allowed, the larger the output capacitor value becomes to meet ripple voltage specifications. The inductor ripple current can be calculated according to the follow-ing equation.EQUATION 5-4:When considering inductor ratings, the maximum DC current rating of the inductor should be at least equal to the maximum load current, plus one half the peak-to-peak inductor ripple current (1/2 * ΔI L). The inductor DC resistance adds to the total converter power loss. An inductor with a low DC resistance allows for higher converter efficiency.5.7Thermal CalculationsThe MCP1603 is available in two different packages (TSOT-23 and 2x3 DFN). By calculating the power dissipation and applying the package thermal resistance,(θJA), the junction temperature is estimated. The maximum continuous junction temperature rating for the MCP1603 is +125°C.To quickly estimate the internal power dissipation for the switching buck regulator, an empirical calculation using measured efficiency can be used. Given the measured efficiency, the internal power dissipation is estimated by:EQUATION 5-5:The difference between the first term, input power dissipation, and the second term, power delivered, is the internal power dissipation. This is an estimate assuming that most of the power lost is internal to the MCP1603. There is some percentage of power lost in the buck inductor, with very little loss in the input and output capacitors.TABLE 5-1:CAPACITOR VALUE RANGEC IN C OUTMinimum 4.7µF 4.7µFMaximum—22µFΔI LV OUTF SW L×-------------------1V OUTV IN------------–⎝⎠⎛⎞×=Where:F SW = Switching Frequency TABLE 5-2:MCP1603 RECOMMENDEDINDUCTORSPartNumberValue(µH)DCRΩ(max)I SAT(A)SizeWxLxH (mm) Coiltronics®SD3110 3.30.1950.81 3.1x3.1x1.0 SD3110 4.70.2850.68 3.1x3.1x1.0 SD3110 6.80.3460.58 3.1x3.1x1.0 SD3812 3.30.159 1.40 3.8x3.8x1.2 SD3812 4.70.256 1.13 3.8x3.8x1.2 SD3812 6.80.2990.95 3.8x3.8x1.2 Würth Elektronik®WE-TPCType XS3.30.2250.72 3.3x3.5x0.95WE-TPCType XS4.70.2900.50 3.3x3.5x0.95WE-TPCType S4.70.1050.90 3.8x3.8x1.65WE-TPCType S6.80.1560.75 3.8x3.8x1.65 Sumida®CMD4D06 3.30.1740.77 3.5x4.3x0.8 CMD4D06 4.70.2160.75 3.5x4.3x0.8 CMD4D06 6.80.2960.62 3.5x4.3x0.8V OUT I OUT×Efficiency------------------------------⎝⎠⎛⎞VOUTI OUT×()–P Diss=5.8PCB Layout InformationGood printed circuit board layout techniques are important to any switching circuitry and switching power supplies are no different. When wiring the high current paths, short and wide traces should be used. This high current path is shown with red connections in Figure5-1. The current in this path is switching.Therefore, it is important that the components along the high current path should be placed as close as possible to the MCP1603 to minimize the loop area.The feedback resistors and feedback signal should be routed away from the switching node and this switching current loop. When possible ground planes and traces should be used to help shield the feedback signal and minimize noise and magnetic interference.FIGURE 5-1:PCB High Current Path.V INSHDNGNDV FBL XV IN2.7V To4.5VV OUT1.8V@500mAC OUT4.7µFC IN4.7µFL1 4.7µH6.0TYPICAL APPLICATION CIRCUITSFIGURE 6-1:Single Li-Ion to 1.5V @ 500mA Application.FIGURE 6-2:5V to 1.0V @ 500mA Application.FIGURE 6-3: 3 NiMH Batteries to 1.2V @ 500mA Application.9V INSHDN GNDV FBL XV IN3.0V To4.2VV OUT1.5V @500mA C OUT 4.7µFC IN 4.7µFL 14.7µHR TOP 200k ΩR BOT 787k ΩV INSHDNGNDV FBL XV IN 5.0VV OUT1.0V @500mAC OUT 4.7µFC IN 4.7µFL 14.7µHR COMP 4.99k ΩC COMP 33pFV INSHDN GNDV FBL XV IN2.7V To 4.5VV OUT1.2V @500mAC OUT 4.7µFC IN 4.7µFL 14.7µH7.0PACKAGING INFORMATION7.1Package Marking Information (Not to Scale)8-Lead 2x3 DFNExample :5-Lead TSOTXXNN ExampleET25Part NumberMarking Code MCP1603-120I/MC AFM MCP1603-150I/MC AFK MCP1603-180I/MC AFJ MCP1603-250I/MC AFG MCP1603-330I/MC AFA MCP1603-ADJI/MCAFQPart Number Marking Code MCP1603T-120I/OS ETNN MCP1603T-150I/OS EUNN MCP1603T-180I/OS EVNN MCP1603T-250I/OS EWNN MCP1603T-330I/OS EXNN MCP1603T-ADJI/OSEYNN Part Number Marking Code MCP1603LT-120I/OS FMNN MCP1603LT-150I/OS FKNN MCP1603LT-180I/OS EJNN MCP1603LT-250I/OS FGNN MCP1603LT-330I/OS FANN MCP1603LT-ADJI/OSFQNN。