基于VC++的高光谱遥感影像仔储格式转化实现研究

海洋航空遥感多光谱图像,有多种存储格式,图像存储格式与其显示效果有重要的关系.各系统根据赤潮、溢油、海冰等海洋现象的特点,采用不同的存储格式进行处理,因此在集成系统中,需要对图像进行格式转换;利用VC 动态连接数据库编程,实现了它们间的快速转换存储,系统运行效果良好.     

循环流化床燃煤脱硫剂技术研究现状及开发前景

本文论述了循环流化床在煤燃烧领域中的优势地位,并着重阐述了国内外循环流化床脱硫技术研究与脱硫剂开发利用状况,指出了在脱硫剂应用方面与国外的差距,提出了脱硫剂生产的产业化发展方向。     

基于GIS技术的三江平原热量资源评价

基于GIS技术,使用黑龙江省气象观测站和农垦、森工系统观测站的气温资料,以及数字高程模型(DEM)资料,运用趋势面分析法和线性内插法得到三江平原栅格化的热量资源数据。分析表明,三江平原纬度和高度因子对各项热量指标分布均有影响,经度因子主要影响年平均气温、4月平均气温、7月平均气温、≥0℃积温和≥10℃积温;佳木斯西部、双鸭山西部、鸡西大部热量资源较丰富,而青黑山、完达山、老爷岭和太平岭等地区热量资源相对较差。分析结果为合理开发利用三江平原热量资源提供了依据。     

基于地面三维脉冲激光扫描技术的变形监测若干问题研究

在传统大地测量中,变形监测为控制网中稀疏监测点观测所驱动.近年来,随着地面激光扫描(terrestrial laser scanning,TLS)技术的迅速发展,该技术显示出应用于变形监测的巨大潜力,尤其是在危险和人员难以到达的灾害监测领域.由于 TLS 扫描测点的不可重复性,传统基于离散点的监测模式不再适用.为此,亟...     

不同鲜重秋茄胚轴形态及其对幼苗生长的影响

为了探讨不同鲜重秋茄胚轴的表型性状和营养成分含量差异,及其对幼苗生长的影响,确定浙江省秋茄胚轴质量标准,提高造林质量,本研究采集4.0～5.0g、5.0～6.0g、6.0～7.0g、7.0～8.0g、8.0～9.0g、9.0～10.0g共6组不同鲜重的秋茄胚轴,测定其表型性状、营养成分含量和幼苗生长性状。结果表明,胚轴长度、横径、顶径随着胚轴鲜重的增加而显著增加。不同鲜重等级胚轴间的氮(N)、磷(P)、钾(K)和有机碳百分含量差异不显著,但随着秋茄胚轴鲜重增加,淀粉百分含量显著减小。单根胚轴的营养成分总含量随胚轴鲜重的增加而显著增加。胚轴的C:N、N:P和C:P值在鲜重7.0～8.0g等级时均显著高于其他鲜重等级。幼苗生长高、基径、叶片数及生物量随胚轴鲜重的增加而显著增加,但在5.0～6.0g、6.0～7.0g和7.0～8.0g等级间幼苗茎干重、叶干重、净生物量和总生物量差异不显著。胚轴表型性状与幼苗生长指标之间的相关性均呈显著水平(P<0.05),除胚轴P总含量与生长高之间的相关性不显著外, N、K、Na、有机碳、淀粉总含量与幼苗生长指标之间均呈显著正相关关系(P<0.0...     

深层搅拌桩强度影响因素探讨

为提高水泥土强度,通过对影响深层搅拌桩水泥土强度（水泥掺入比、水泥土养护龄期、水泥强度等级、土体自身物理力学性质,外掺剂以及施工工艺等）诸因素进行探讨,对各参数的取值进行优化。当水泥土的掺入比在7％～15％,养护龄期90d,加入外掺剂,且施工采用复搅法和喷搅法时,水泥土强度可以得到不同程度的提高。     

Mineralogy of morphogenetic types of ferromanganese deposits in the world ocean

The mineralogy and structural features of the main types of ferromanganese deposits—nodules, micronodules, Co-bearing crusts, crustlike nodules, and low-temperature hydrothermal manganese crusts and ferruginous ochers—are considered. The correlation between their mineral composition and structure is shown. The proposed classification of mineral types is based on characteristic assemblages of Fe and Mn minerals.     

New data on mineralogy and metallogeny of scarns in the Pitkyaranta ore region

A wide application of modern precision research techniques to the studies of Pitkyaranta ores allowed us to find increased contents of indium (to 0.33%), silver (447 g/t), gold (0.2–0.4 g/t), and palladium (0.2 g/t). A series of rare minerals previously not found here was also discovered. Among ore minerals, these are roquesite, zavartskite, electrum, stutzite, altaite, bismite, glaucodot, cervelleite, hedleyite, pavonite, cannonite, plantnerite, lindkvistite, ashoverite, etc. The discovery of roquesite and electrum is the most important in terms of metallogeny. Roquesite (indium sulfide) is found in Karelia for the first time. The highest indium contents in direct correlation to those of zinc are characteristic for polymetallic ores of the Pitkyaranta ore fields with sphalerite as the concentrating mineral (to 0.5% of In). The predicted zinc resources are evaluated to ∼2.5 million t for the Pitkyaranta group of ore deposits, and to 400 000 t for the Hopunvaara region. Respectively, the resources of indium amount to ∼2400 t (total) and 600 t for the Hopunvaara region.     

Geochemical types of Volkhovites and possible diamond resource potential of areas occupied by Holocene fluidisites

Volkhovites—tektite-like glasses—have been detected in the Holocene glacial drift along the right bank of the Volkhov River. A cryptomagmatic model of their formation and pre-Holocene age of volkhovite melts, cinder, and frothed glasses has been suggested (Skublov et al., 2007). Four geochemical types of volkhovites are distinguished: (1) manganous (Mn, Fe, Cr, V, Si, Nb, Pb, H), (2) magnesian (Mg, Al, Ti, F, B), (3) potassic (K, Rb, Cs), and (4) calcic (Ca, REEs, Ba, U, Th, Ta, Hf, Y, Sc, Cl). In light of the geochemical data, volkhovites are regarded as natural silicate glasses of kimberlite-carbonatite composition. Their types are called kimberlitic (Mn type), kimberlitic-carbonatitic (Mg type), lamproitic-carbonatitic (K type), and carbonatitic (Ca type). Volkhovites are suggested to be indicators of undiscovered diamond mineralization of kimberlite or carbonatite (Chagatai) types.