{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"为了改善彩色液晶显示器件的色差,提升画面品质,针对(128,192,192)灰阶图形下色差的问题,对色差产生的机理进行了分析.模拟了 RGB 三色像素透过率对该图形下色差的影响.通过分别调整 RGB 彩膜膜,不仅相对调整了三色像素下的液晶盒,而且还调整了三色像素的透过率,改善了 RGB 的 Gamma 曲线,对色差进行了补偿优化.实验结果表明,增加 G 像素和减小 B 像素的液晶盒,对色差有明显补偿改善效果;同时,当 RGB 膜保持不变时,色差与液晶呈正比关系,液晶每减小1%时,色差约降低0.2.当 RGB 三色液晶盒从(3.47,3.38,3.4)μm 分别调整到(3.5,3.45,3.36)μm 和(3.5,3.44,3.28)μm 时,(128,192,192)灰阶图形下样品色差平均值从13.8分别降低到12.8和12.通过分别调整 RGB 彩膜膜,相对调整了三色像素下的液晶和液晶量调节,可以一定程度优化补偿色差.","authors":[{"authorName":"占红明","id":"cf4d794c-966d-45fc-8948-43f8df8c3579","originalAuthorName":"占红明"},{"authorName":"徐征","id":"868b76e7-4a05-45f2-8a0e-4d4672e4372f","originalAuthorName":"徐征"},{"authorName":"董学","id":"7bb141ac-8c10-44d2-b907-cdd4ba862e7e","originalAuthorName":"董学"},{"authorName":"陈明","id":"f44823f0-f7b1-4fa1-b7db-00efd0531501","originalAuthorName":"陈明"},{"authorName":"金雄","id":"e899951f-c808-4f45-a915-316049e45627","originalAuthorName":"金雄"},{"authorName":"布占场","id":"f348e3c5-3b68-4343-a971-9c99e5f46c21","originalAuthorName":"布占场"},{"authorName":"邵喜斌","id":"c5fd20af-a124-4c6f-a458-7ec2cd4b190c","originalAuthorName":"邵喜斌"},{"authorName":"李成圭","id":"90a74fd2-1bc8-4bbe-b09e-b0d007875681","originalAuthorName":"李成圭"}],"doi":"10.3788/YJYXS20142906.0916","fpage":"916","id":"86a228a8-1f75-4df5-b314-672047ec1fbd","issue":"6","journal":{"abbrevTitle":"YJYXS","coverImgSrc":"journal/img/cover/YJYXS.jpg","id":"72","issnPpub":"1007-2780","publisherId":"YJYXS","title":"液晶与显示 "},"keywords":[{"id":"03febb36-3397-4b7f-9275-d83942c26cfb","keyword":"色差","originalKeyword":"色差"},{"id":"4da80b49-d14a-45a3-96d5-8e28b9098905","keyword":"液晶显示","originalKeyword":"液晶显示"},{"id":"9d9da8fa-c55d-4f15-9601-15fae6856eff","keyword":"","originalKeyword":"层厚"},{"id":"820b51ba-16d1-42a9-8db7-56e6ee0debc7","keyword":"灰阶","originalKeyword":"灰阶"}],"language":"zh","publisherId":"yjyxs201406009","title":"彩色液晶显示器件色差补偿优化","volume":"","year":"2014"},{"abstractinfo":"基于超声浸水透射技术,分别沿着二维正方晶格钢/水声子晶体第一布里渊Γ-X和Γ-M方向测试声带隙,详细分析了声子晶体Γ-X和Γ-M方向和第一方向带隙稳定性的关系,进而为设计有限尺寸声带隙材料或声波器件提供重要参考依据.同时,对比了实验测得透射谱频率重合范围与平面波展开法计算完全带隙很好的吻合.","authors":[{"authorName":"何存富","id":"9d5c36a5-21ff-4b0c-8d41-e29e5d449866","originalAuthorName":"何存富"},{"authorName":"赵寰宇","id":"6d325f18-7966-423e-bfe5-2c84ae07b1b0","originalAuthorName":"赵寰宇"},{"authorName":"魏瑞菊","id":"3f2f138f-28d9-4205-a1a2-15cbe48e593e","originalAuthorName":"魏瑞菊"},{"authorName":"吴斌","id":"93c5b460-0f64-44e8-a29c-727367dad619","originalAuthorName":"吴斌"},{"authorName":"宋国荣","id":"76845664-88c7-482d-80a6-7d4461509ef2","originalAuthorName":"宋国荣"}],"doi":"","fpage":"214","id":"6d5870c7-9cce-423e-9df0-4542cc14ab58","issue":"2","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"97fcf0eb-d3c2-44be-8bd8-c2ea4ffb2848","keyword":"方向带隙","originalKeyword":"方向带隙"},{"id":"b1023368-3cc7-4cbf-9836-c171d317dcb3","keyword":"实验研究","originalKeyword":"实验研究"},{"id":"4d958adc-3b30-4ae4-a33e-4e6e8a3d01cb","keyword":"","originalKeyword":"层厚"},{"id":"93b19aca-3d24-431c-8b2d-54b061711801","keyword":"声子晶体","originalKeyword":"声子晶体"}],"language":"zh","publisherId":"gncl201102006","title":"二维正方晶格钢/水声子晶体方向带隙实验研究","volume":"42","year":"2011"},{"abstractinfo":"高速电镀是将钢质圆筒在较短的时间内镀取较厚的铜.按设计要求在上用照相制版工艺制得理想的图案,镀铬后供印染厂使用.用毕的圆筒经化学退镀又可重新使用.该工艺可取代铜制圆筒,从而节省大量铜材,降低成本.","authors":[{"authorName":"程沪生","id":"cc100b4c-38b0-4f47-9f31-a404b816396e","originalAuthorName":"程沪生"}],"doi":"10.3969/j.issn.1001-3849.2005.01.009","fpage":"27","id":"cb80823b-3149-416b-ae43-65bca8b864c4","issue":"1","journal":{"abbrevTitle":"DDYJS","coverImgSrc":"journal/img/cover/DDYJS.jpg","id":"20","issnPpub":"1001-3849","publisherId":"DDYJS","title":"电镀与精饰 "},"keywords":[{"id":"48f3ae04-6252-461c-851c-8f6627039386","keyword":"镀铜","originalKeyword":"镀厚铜"},{"id":"f97ba30e-7d58-422d-9d2f-e8e24d5e9e4f","keyword":"高速电镀","originalKeyword":"高速电镀"},{"id":"781e22ed-9dec-46f2-88e5-ced288d5711e","keyword":"钢质圆筒","originalKeyword":"钢质圆筒"}],"language":"zh","publisherId":"ddjs200501009","title":"圆筒高速电镀","volume":"27","year":"2005"},{"abstractinfo":"通过对电弧离子镀金膜工艺过渡的深入研究,得出了采用离子轰击清洗、Ni-Cu过渡和镀膜室内热处理是离子镀金膜的工艺路线,通过一次装炉实现了制备Ni-Cu过渡、沉积金膜、热处理和金膜增等工序一次完成.经过现场实验,摩擦副的往复运动次数在运动速度2.5 m/s时超过120次,完全满足要求.","authors":[{"authorName":"李争显","id":"33b276e9-ebdd-475e-a718-9f3b7a021249","originalAuthorName":"李争显"},{"authorName":"骆瑞雪","id":"e8d9296f-e5e7-4587-8f61-75c005a2ae37","originalAuthorName":"骆瑞雪"},{"authorName":"周慧","id":"faa8ee82-bb4e-4e53-b587-fa3d1c944e25","originalAuthorName":"周慧"}],"doi":"","fpage":"460","id":"5443818f-dffb-4325-b1f0-9ec4660d9618","issue":"6","journal":{"abbrevTitle":"XYJSCLYGC","coverImgSrc":"journal/img/cover/XYJSCLYGC.jpg","id":"69","issnPpub":"1002-185X","publisherId":"XYJSCLYGC","title":"稀有金属材料与工程"},"keywords":[{"id":"3e1f9521-5a1f-4adc-83b6-94ff229f67d4","keyword":"离子镀","originalKeyword":"离子镀"},{"id":"c2e6a633-ca47-45ed-8d10-fa2dad9599a2","keyword":"金膜","originalKeyword":"厚金膜"},{"id":"8767f03a-3b51-4e3a-927a-36d76b5ada56","keyword":"过渡","originalKeyword":"过渡层"}],"language":"zh","publisherId":"xyjsclygc200106014","title":"离子镀金膜过渡的研究","volume":"30","year":"2001"},{"abstractinfo":"为提高电镀的存储性能,采用优化镀层预处理工艺方法,利用换向脉冲电镀技术在铍青铜试件上制备镀,并研究不同预处理工艺对长时间存储条件下镀层结合力的影响规律;利用X-射线能谱仪研究了优化预处理工艺对存储1~5年后镀的成分变化规律的影响;利用扫描电子显微镜与能谱仪研究了存储1~5年后镀层与铜基体之间的扩散行为.研究结果表明,换向脉冲电镀储存5年后,镀铜作为镀金的预镀层,镀层结合力最为优异;换向脉冲电镀的金原子数分数高于99.9%,镀具有优异的存储性能,但是镀界面处存在1.0~1.5 μm的相互扩散现象.","authors":[{"authorName":"唐作琴","id":"f8a4e3a4-3397-40bd-b20d-2d0c0b8e319e","originalAuthorName":"唐作琴"},{"authorName":"胡素荣","id":"82955bd8-92de-4e25-b637-5dc96bb73e02","originalAuthorName":"胡素荣"},{"authorName":"杜东兴","id":"65ad24b3-d698-4940-bd8c-f9c7e8bab049","originalAuthorName":"杜东兴"}],"doi":"10.3969/j.issn.1001-3849.2017.03.001","fpage":"1","id":"b4dd54b7-6f36-40bc-9e83-d90d27963530","issue":"3","journal":{"abbrevTitle":"DDYJS","coverImgSrc":"journal/img/cover/DDYJS.jpg","id":"20","issnPpub":"1001-3849","publisherId":"DDYJS","title":"电镀与精饰 "},"keywords":[{"id":"833baa01-3d63-4ad7-92ce-eeedbf869e1f","keyword":"预处理","originalKeyword":"预处理"},{"id":"3fff8827-5c3f-4ae9-87c8-fc3eebba8cc2","keyword":"换向脉冲","originalKeyword":"换向脉冲"},{"id":"12d46af2-70ee-4af1-8bc8-273ddf4d02bb","keyword":"铍青铜","originalKeyword":"铍青铜"},{"id":"f0a93eb2-f041-4f73-bc2f-aec378c1c666","keyword":"镀金","originalKeyword":"镀金"},{"id":"d6cdc49a-31c6-4d00-a681-48f0fc70e4bb","keyword":"结合力","originalKeyword":"结合力"},{"id":"bfb21b24-59c1-4255-96a7-11d1c669e204","keyword":"存储性","originalKeyword":"存储性"}],"language":"zh","publisherId":"ddjs201703001","title":"换向脉冲镀金对铍青铜镀产品存储能力的影响","volume":"39","year":"2017"},{"abstractinfo":"为了克服超声体积波测量方法只适用于测试厚度大于声波波长的弹性的缺点,提出了频域相对传递函数法测量超薄弹性的厚度的新方法.在推导超薄弹性相对反射传递函数的基础上,用相对反射传递函数幅度谱、相位谱和复谱定征超薄弹性的厚度,分析了影响估计准确性的各种因素,研究了相对反射传递函数对厚度的灵敏度函数在误差传递中的意义.实验结果表明:相对传递函数法能够测量厚度为波长百分之一的铝薄层的厚度,相对误差小于2.5%,其中用幅度谱定征得到的结果最准确.这表明相对传递函数法可以有效地测量超薄弹性的厚度,在实际应用中更加实用,其定征的准确性主要由相对传递函数对厚度灵敏度函数和测量误差共同决定.","authors":[{"authorName":"陈晓","id":"63b80bac-7b3c-4049-8222-52d108fb8e25","originalAuthorName":"陈晓"}],"doi":"","fpage":"817","id":"c1b375b3-a173-4226-9d4e-bf4398428660","issue":"6","journal":{"abbrevTitle":"CLKXYGY","coverImgSrc":"journal/img/cover/CLKXYGY.jpg","id":"14","issnPpub":"1005-0299","publisherId":"CLKXYGY","title":"材料科学与工艺"},"keywords":[{"id":"12720e4a-2cba-40c0-a316-b5e560693f0c","keyword":"超薄单层介质","originalKeyword":"超薄单层介质"},{"id":"4de09ae6-c7ff-4954-83cf-afb7e05e8fe5","keyword":"超声波","originalKeyword":"超声波"},{"id":"ffbf784d-58e3-4374-99e0-4eda80d6b83d","keyword":"相对传递函数","originalKeyword":"相对传递函数"},{"id":"db40c9ee-fe97-4934-92b3-de2208eb6972","keyword":"定量无损评价","originalKeyword":"定量无损评价"},{"id":"cde00cd3-ce94-4ff5-b0be-6417fa901e31","keyword":"定征","originalKeyword":"定征"}],"language":"zh","publisherId":"clkxygy200806020","title":"超薄弹性超声反射波频域测法","volume":"16","year":"2008"},{"abstractinfo":"通过石英杯中断试验检测超烧结过程中的水分变化情况,总结得出超烧结时的一些特点如下:同一料厚度下,随着烧结过程的进行,下部料的平均过湿度和最大过湿度均增加;随着料厚度增加,下部料的平均过湿度和最大过湿度均增加,烧结料越容易发生过湿,因此700~1 000 mm的烧结时,料厚度每提高100 mm,在保持烧结透气性的基础上,布到烧结机下部的烧结料水分可以适当降低0.24%~0.32%.","authors":[{"authorName":"陈东峰","id":"92192100-fda9-4786-b2ed-4ce08c883e36","originalAuthorName":"陈东峰"},{"authorName":"胡夏雨","id":"07d591df-47f3-49af-877a-8a47f7ff8433","originalAuthorName":"胡夏雨"},{"authorName":"黄发元","id":"a36e845a-a771-4acc-a2b2-b93e8e0bedd3","originalAuthorName":"黄发元"},{"authorName":"金俊","id":"52f25e55-afd1-4248-8859-776358f68683","originalAuthorName":"金俊"},{"authorName":"李小静","id":"9833fd72-ec71-48fd-9a27-0a1e2dbdc02b","originalAuthorName":"李小静"},{"authorName":"吴胜利","id":"f9c59c54-b8ed-4093-be32-ff66daa1225a","originalAuthorName":"吴胜利"}],"doi":"","fpage":"34","id":"01d3a046-eeb6-4941-a003-dd4e624ce2e5","issue":"9","journal":{"abbrevTitle":"ZGYJ","coverImgSrc":"journal/img/cover/ZGYJ.jpg","id":"87","issnPpub":"1006-9356","publisherId":"ZGYJ","title":"中国冶金"},"keywords":[{"id":"66c5945e-ac3d-402d-83bb-f409b9c9cc54","keyword":"超烧结","originalKeyword":"超厚料层烧结"},{"id":"7b16e74c-af6e-4874-bb4d-ef3f8adf609c","keyword":"过湿带","originalKeyword":"过湿带"},{"id":"1bcae4c2-09fb-44b6-8f9a-aa588656b9bb","keyword":"平均过湿度","originalKeyword":"平均过湿度"},{"id":"2e98236a-f055-4733-8e9e-ff1d60befe38","keyword":"最大过湿度","originalKeyword":"最大过湿度"}],"language":"zh","publisherId":"zgyj201209007","title":"超烧结过湿带水分变化的试验研究","volume":"22","year":"2012"},{"abstractinfo":"首次报道了采用高介电常数的陶瓷膜作绝缘、ZnS∶Er作发光的绿色薄膜电致发光器件(CTFEL).器件结构为陶瓷基片/内电极/陶瓷膜/发光(ZnS∶Er)/透明电极(ZnO∶Al).发光是用电子束蒸发制备的,透明电极是采用溅射法制备的.器件在市电频率驱动下发出明亮的绿光,研究了器件的亮度-电压和效率-电压等特性.","authors":[{"authorName":"唐春玖","id":"f4506c0e-5374-4f21-a24e-82d9a4882dce","originalAuthorName":"唐春玖"},{"authorName":"朱文清","id":"a5666355-f6d1-49f8-ac65-d5556f410392","originalAuthorName":"朱文清"},{"authorName":"赵伟明","id":"b430dc3c-3d8c-4a3a-a960-d68c35281380","originalAuthorName":"赵伟明"},{"authorName":"刘祖刚","id":"a400ddff-921a-428d-bd3b-67913ba567ef","originalAuthorName":"刘祖刚"},{"authorName":"蒋雪茵","id":"17b6dda3-7fcc-45b2-9e0d-f74abe303645","originalAuthorName":"蒋雪茵"},{"authorName":"张志林","id":"6bd0baa9-6782-45f5-96f8-2026a1ddf762","originalAuthorName":"张志林"},{"authorName":"许少鸿","id":"48cc4c62-2d8d-4075-8e08-64f4acc28d97","originalAuthorName":"许少鸿"}],"doi":"10.3969/j.issn.1007-2780.1999.01.008","fpage":"39","id":"541a0335-3ac8-4d4f-bbee-21cd830534f6","issue":"1","journal":{"abbrevTitle":"YJYXS","coverImgSrc":"journal/img/cover/YJYXS.jpg","id":"72","issnPpub":"1007-2780","publisherId":"YJYXS","title":"液晶与显示 "},"keywords":[{"id":"f69eff93-e86f-4c51-b98f-818592057e7f","keyword":"陶瓷膜","originalKeyword":"陶瓷厚膜"},{"id":"eeb3c973-c01f-49d1-bfca-7e5e103115ea","keyword":"绝缘","originalKeyword":"绝缘层"},{"id":"c7226b25-46fd-4056-9609-602f5a7a3de6","keyword":"薄膜电致发光器件","originalKeyword":"薄膜电致发光器件"}],"language":"zh","publisherId":"yjyxs199901008","title":"以陶瓷膜为绝缘的绿色薄膜电致发光器件","volume":"14","year":"1999"},{"abstractinfo":"烧结是烧结技术发展的重要方向。料引起一系列烧结行为的变化,如自动蓄热加强,导致料层高温区变厚,气体体积膨胀量增加,透气性恶化,氧气的质量含量降低,燃料燃烧速度减慢,高温区宽度进一步增加,同时,还使得残碳和无益燃烧增加,下部烧结矿过熔,影响烧结矿的产、质量,同时使降低燃耗的效果不明显。为了解决这些问题,本文采用粒度为1~3.15mm的高燃烧性燃料,选择燃料的配加方式为“燃料分加”或“燃料、熔剂共同分加”等方案提高烧结固体燃料的燃烧性,并对各试验方案下的透气性和烧结指标进行研究,结果表明上述三个措施均有利于烧结的实施。","authors":[{"authorName":"吴胜利\t陈东峰","id":"fec09307-1885-43fc-a6ca-e356bfb1c546","originalAuthorName":"吴胜利\t陈东峰"}],"categoryName":"|","doi":"","fpage":"16","id":"1c0946ec-73b2-43c3-b012-31144b29fb1b","issue":"11","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[],"language":"zh","publisherId":"0449-749X_2010_11_14","title":"提高烧结燃料燃烧性的试验研究","volume":"45","year":"2010"},{"abstractinfo":"烧结是烧结技术发展的重要方向,但料引起一系列烧结行为的变化,如自动蓄热加强,导致料层高温区变厚,气体体积膨胀量增加,透气性恶化,氧气的质量含量降低,燃料燃烧速度减慢,高温区宽度进一步增加,还使得残碳和无益燃烧增加,下部烧结矿过熔,影响烧结矿的产、质量,进而降低的节能效果.为了解决这些问题,采用粒度为1.00~3.15mm的高燃烧性燃料,选择燃料的配加方式为\"燃料分加\"或\"燃料、熔剂共同分加\"等方案提高烧结固体燃料的燃烧性,并对各试验方案下的透气性和烧结指标进行研究,结果表明上述3个措施均有利于烧结的实施.","authors":[{"authorName":"吴胜利","id":"d20025d8-462c-44ec-987f-c0a6284cb9f3","originalAuthorName":"吴胜利"},{"authorName":"陈东峰","id":"7227b938-b664-4d26-9d7a-4ba597f57579","originalAuthorName":"陈东峰"},{"authorName":"赵成显","id":"72439366-cef7-4d5e-bc72-b4567207eedb","originalAuthorName":"赵成显"},{"authorName":"韩宏亮","id":"7ca584f4-722e-484a-9cce-f3a2410e686b","originalAuthorName":"韩宏亮"},{"authorName":"薛方","id":"fe445d81-7d7a-40bc-a482-29acd67eb658","originalAuthorName":"薛方"},{"authorName":"张丽华","id":"467cad65-a536-43d8-b5c5-ba0baff50139","originalAuthorName":"张丽华"}],"doi":"","fpage":"16","id":"1c7af5ff-f662-4be1-9870-1c3cb8b44901","issue":"11","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"0b110a12-945a-4cbb-ba51-8d6d3bc6d3b8","keyword":"烧结","originalKeyword":"厚料层烧结"},{"id":"b9e396f7-abe3-415b-800e-298b8222dbf3","keyword":"燃料粒度","originalKeyword":"燃料粒度"},{"id":"3666da41-25b2-46fb-a6e0-d9979ada3529","keyword":"燃料分加方式","originalKeyword":"燃料分加方式"}],"language":"zh","publisherId":"gt201011003","title":"提高烧结燃料燃烧性的试验研究","volume":"45","year":"2010"}],"totalpage":2565,"totalrecord":25645}