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随着国家电网公司分布式数据中心建设数量的不断增加,受困于分布式机房的规模、距离等客观因素,运维人员疲于奔波应付巡检和故障检修,导致分布式数据机房运维效率低下,运维人员工作量日益加大.为了提升分布式数据中心监控管理和故障处置能力,该文将研究一套分布式数据中心统一运营支撑平台,通过对数据中心机房设施进行统一管理,对故障告警... 相似文献
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基于小波变换的图像融合方法 总被引:14,自引:0,他引:14
数据融合是80年代初形成与发展起来的一种信息综合处理技术。图像融合是数据融合在数字图像处理方面的一个应用。本文着重讨论了基于小波变换的两种融合方法:基于像素的融合方法与基于区域的融合方法,及它们各自的实现方式。 相似文献
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An Al0.13GalnP sub-cell used as the top cell in the next generation of high efficiency multi-junction solar cells is fabricated. An efficiency of 10.04% with 1457.3 mV in Voc and 11.9 mA/cm2 in Isc was obtained. QE comparison was carried out to verify the influence of an O-related defect introduced by the high Al-content materials on the cell performance during MOCVD growth. Hetero-structures are employed to confirm the origin of the decreasing short circuit current density compared to a GalnP single junction solar cell. An effective method to improve the performance of broadband solar cells by increasing Isc with a cost of Voc was proposed. 相似文献
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GaInP and AlGaInP solar cells were grown by metal organic chemical vapor deposition (MOCVD), and theoretical analysis demonstrated that hetero-interface recombination velocity plays an important role in the optimizing of cell performance, especially the interface between base layer and back surface field (BSF). Measurements including lattice-matched growth and pseudo-BSF were taken to optimize BSF design. Significant improvement of Voc in GaInP and AlGaInP solar cells imply that the measures we took are effective and promising for performance improvement in the next generation high efficiency solar cells. 相似文献
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研制了应用于下一代高效多结太阳电池中的定电池的 Al0.13GaInP子电池,其实验室效率为10.04%,开路电压为1457.3mV,短路电流为11.9mA。使用量子效率来验证MOVPE生长过程中涉及高Al组分引起的O缺陷对电池性能的影响。相比GaInP单结电池,Al0.13GaInP电池的短路电流下降地较为厉害,实验中生长了GaInP/Al0.13GaInP异质结电池来分析其原因,因此也提出了以牺牲部分开路电压来提升短路电流的一种有效提升电池性能的方法。 相似文献
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现有1.0eV/0.75 eV InGaAsP/InGaAs双结太阳电池的开路电压小于各子电池的开路电压之和,鲜有研究探索开路电压损耗的来源以及如何抑制。通过研究发现,InGaAs底电池背场/基区界面处的少数载流子输运的主要机制是热离子发射,而不是缺陷诱导复合。SIMS测试表明,采用InP或InAlAs背场均不能有效抑制Zn掺杂剂的扩散。此外,由于生长过程中持续的高温热处理.,III-V族主元素在界面处发生了热扩散。为了抑制上述现象,提出了一种新型InP/InAlAs超晶格背场,并应用到InGaAs底电池中。制备得到的双结太阳电池在维持短路电流密度不变的情况下,开路电压提升到997.5 mV,与传统采用InP背场的双结太阳电池相比,开路电压损耗降低了30 mV。该研究成果对提升四结太阳电池的整体开路电压有重要意义。 相似文献
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