共查询到19条相似文献,搜索用时 120 毫秒
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本文提出了一个参数化的多次散射激光雷达方程,该方程基于本文引出的四个因子,即几何消光因子、消光分布因子、前向散射因子和后向散射因子.前两个因子表征多次散射成分对大气消光系数分布、激光的发散角和接收视场角以及接收孔径的依赖关系,后两个因子表征多次散射成分对散射相函数的依赖关系.这个参数化多次散射雷达方程在241个数值试验中得以检验,这些试验包含很宽的大气条件和雷达几何参数,包括14个大气散射相函数,均匀和不均匀的大气消光系数分布,0.5至1之间变化的一次散射反照率,地基和空间站激光雷达两种情形.数值试验表明 相似文献
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本文根据参数化的多次散射雷达方程,分析了激光多次散射对激光回波信号和一次散射雷达方程反演结果的效应,提出了迭代前向积分法和迭代后向积分法以求解参数化的多次散射雷达方程,并根据多次散射信号对云和气溶胶的前向散射相函数的高度敏感性提出了一个从双接收视场的多次散射激光回波信号,同时确定云和气溶胶消光系数分布和前向散射相函数的方法.此外,本文还根据数值试验分析了这些反演方法在地基激光雷达和空间站激光雷达两种情形下的适用性. 相似文献
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本文根据参数化的多次散射雷达方程,分析了激光多次散射对激光回波信号和一次散射雷达方程反演结果的效应,提出了迭代前向积分法和迭代后向积分法以求解参数化的多次散射雷达方程,并根据多次散射信号对云和气溶胶的前向散射相函数的高度敏感性提出了一个从双接收视场的多次散射激光回波信号,同时确定云和气溶胶消光系数分布和前向散射相函数的方法.此外,本文还根据数值试验分析了这些反演方法在地基激光雷达和空间站激光雷达两种情形下的适用性. 相似文献
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本文论述了一个数值求解齐次的第一类Fredholm积分方程的方法,并以消光系数和体积散射系数综合反演气溶胶谱分布为例,说明采用比值通道以反演气溶胶谱分布有利于消除多次散射等系统误差.本文还证明了在Junge谱分布下,不同波长的体积消光系数、散射相函数等Mie散射光学参数之比与折射率无关的特性,指出了采用比值通道能够有效地消除折射率的不确定性对于消光——小角散射法反演气溶胶谱分布的影响. 相似文献
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激光遥测大气消光系数的误差分析 总被引:2,自引:1,他引:2
激光遥测大气消光系数分布的主要方法,是假设大气消光系数与大气体后向散射微分截面之比值k为常数,并取激光实测的地面值,然后由解光雷达方程求得。本文将讨论由于大气气溶胶物理属性随高度变化以及大气分子散射的作用,使比值k产生相应变化,并分析由此引起大气消光系数的探测误差。 相似文献
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介绍了激光雷达在气象上的作用,并在使用光子计数法的基础上利用激光雷达方程计算出了在不同高度处大气的后向散射光子.为进行激光大气探测奠定理论基础. 相似文献
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第六届国际激光雷达会议于1974年9月8日至6日在日本仙台举行。会议涉及的问题有能见度和云底高度的测量;激光雷达光谱学应用拉曼旋转后向散射谱测量气温;用激光观测大气消光作用;气溶胶对光的散射的物理特征;从云、霾反射回来的激光的退极性观测;行星边界层和大气污染问题,用激光雷达监测大气污染,研究大气污染的扩散,监测环境污染;平流层气溶胶的测量;多次散射问题。 相似文献
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本文利用成都2017年6~8月的米散射微脉冲激光雷达观测数据,对成都夏季气溶胶消光系数、边界层高度以及气溶胶光学厚度进行了反演,并结合太阳光度计观测资料、地面颗粒物浓度以及大气能见度数据研究了气溶胶消光系数日变化与月变化规律,气溶胶消光系数的垂直分布特征及影响因素。结果表明:气溶胶消光系数的日变化受人类活动以及边界层日变化影响显著,表现出凌晨与傍晚最大,早晨次之,午后最小的特征。消光高值出现在200m以下和300~700m的高度区间,夜间观察到的消光高值可能与颗粒物在夜间近地面浓度较高以及本地夜间降水频发有关。激光雷达反演的消光系数与光度计反演的气溶胶光学厚度在夏季各月的表现一致,夏季各月消光极值均出现在100~150m的近地面层。近地面消光系数与地面颗粒物浓度之间具有较好的正相关,并且粒子粒径更小时相关性更好。气溶胶光学厚度主要来自低层大气的贡献,0.1~0.2μm的细粒子气溶胶占比对于大气消光有主要影响,但气溶胶对大气的消光影响除了与粒子浓度有关,还与粒子的理化性质有关。 相似文献
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用于空间对地遥感的一个参数化辐射传输计算模式 总被引:4,自引:1,他引:3
一个足够精度的参数化向上亮度模式对空间对地遥感的大气订正应用是很有意义的。依据向上天空亮度对大气散射相函数、光学厚度、太阳天顶角、空间方位和天顶角等有关参数的依赖特性,基于大量的天空亮度数值模拟计算资料,本文发展了一个关于向上天空亮度的参数化模式。39440组的数值模拟对比资料表明,在气溶胶光学厚度#Aτt≤1,太阳天顶角小于72°,μ≤0.432 (天顶角小于65°)以及无云的条件下,由现在的参数化的模式所计算的向上亮度的误差一般小于6%。地表反射率越大,参数化模式的精度越高。参数化模式的精度一般随着光学厚度和太阳天顶角的增大而变差。 相似文献
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The aerosol optical depth of the atmospheric boundary layer was determined both from direct solar irradiance measurements and from vertical extrapolation of ground-based nephelometry, during a period with cloudless skies and high aerosol mass loadings in the Netherlands. The vertical profile of the aerosol was obtained from lidar measurements. From humidity controlled nephelometry at the ground and humidity profiles from soundings, the scattering aerosol extinction as a function of height was assessed. Integration of the extinction over the aerosol layer gave the aerosol optical depth of the atmospheric boundary layer. This optical depth at the narrow band of the nephelometer was translated to a spectrally integrated value, assuming an Angstrom wavelength exponent of 1.5, a typical value for The Netherlands.It was found that scattering by the boundary layer aerosol contributed on average 80% to the total atmospheric aerosol optical depth. The uncertainty in this value is estimated to be of the order of 13%. Ammonium nitrate dominated the light scattering. This is an anthropogenic aerosol component.The radiative forcing caused by the light scattering of the anthropogenic aerosol was calculated assuming an upward scattered fraction of 0.3. An average value of − 12 W m −2 was found (with an estimated uncertainty of 20%). This corresponds to an absolute increase in the planetary albedo of 0.03, which is equivalent to a 15% increase in the local planetary albedo of 0.2. 相似文献
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本文针对传统的体散射模型并未考虑大气不均匀性对信号传输的影响等问题,通过引入垂直非均匀的大气参数改进了模型,并利用其建立了体目标的双基地激光测风雷达方程,仿真了侧向散射回波信号,并与单基地雷达进行了对比分析。研究表明:水平方向上,双基地激光测风雷达的回波信号分布特征与单基地雷达差异较大,其回波信号等值线在近地面为卵形线,随着探测高度的增加,回波信号等值线逐渐变为以主、被动雷达为焦点的椭圆形,并最终趋近于圆形;垂直方向上,双基地激光测风雷达的回波信号随高度衰减剧烈,近地面的回波能量约为10-10 J,4 km高度的回波能量约为10-15J,在中低层大气(0~10 km),回波信号中气溶胶散射占比大,在高层大气(10 km以上),分子散射占比大。 相似文献
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Qiu Jinhuan 《大气科学进展》1995,12(2):177-186
Two-wavelengthLidarMeasurementofCloud-aerosolOpticalPropertiesQiuJinhuan(邱金桓)(InshtuteofAtmosphericPhysics,ChineseAcademyofSc... 相似文献
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The longwave upward radiation was calculated for an urban canopy by using a Monte Carlo model. The effects of the urban geometry were examined in terms of the fractional roof area, the height of the buildings and the emissivity. The urban canopy consists of identically sized buildings and the ground surfaces. The model allows for the temperature differences between the buildings and the ground surface and for multiple reflections in the canyon.The Monte Carlo results show that neglect of the geometric effects causes significant errors in calculated upward radiation: calculations with area-weighting of the radiation emitted from flat homogeneous surfaces are not appropriate. The upward flux is a nonlinear function of the fractional roof area, which may be approximated by a function of the square or cube of the fractional roof area. Neglect of the reflections by non-black surfaces (emissivity<1) underestimates the upward flux by a few percent for a canopy of emissivity=0.9. Radiation effects due to multiple reflections in the canyon are parameterized by use of the view factor and the fractional roof area. The parameterization scheme yields accurate results. 相似文献
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In this paper, characterization of cirrus clouds are made by using data from ground based polarization lidar and radiosonde measurements over Chung-Li (24.58°N, 121.10°E), Taiwan for a period of 1999–2006. During this period, the occurrence of cirrus clouds is about 37% of the total measurement nights over the lidar site. Analysis of the measurement gives the statistical characteristics about the macrophysical properties such as occurrence height, ambient temperature, and its geometrical thickness while the microphysical properties are interpreted in terms of extinction coefficient, optical depth, effective lidar ratio and depolarization ratio. The effective lidar ratio has been retrieved by using the simulation technique of backscattered lidar signals. The effect of multiple scattering has been taken into the account by a model calculation. Summer (Jun–Aug) shows the maximum appearances of cirrus due to its formation mechanism. It is shown that tropopause cirrus clouds may occur with a probability of about 24%. These clouds are usually optically thin and having laminar in structure with some cases resembling the characteristics similar to that of polar stratospheric clouds (PSCs). The radiative properties of the cirrus clouds are also discussed in detail by the empirical equations with results show a positive feedback on any climate change. 相似文献
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激光遥测大气气溶胶的尺度谱分布 总被引:3,自引:0,他引:3
在采用Deirmendjian气溶胶谱分布模式条件下,利用多波长激光雷达所探测的气溶胶消光系数,通过与Mie散射理论计算的气溶胶消光系数拟合的方法,可获得气溶胶的尺度谱分布。 相似文献
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Feasibility is investigated of multi-wavelength lidar exploration of size distribution patterns (SDP) and complex refractive indices (CRI) of aerosols in different layers of a stratified atmosphere, and an improved observational scheme is worked out for the optical parameters (extinction coefficients, angular scattering coef-ficients and their ratios) of the substance in layers homogeneous horizontally in optical depth obtained by a bi-static lidar system. Variations are examined of these parameters versus CRI (whose real part is 1.33- l.63 and imaginary 0.00-0.1) and working wavelengths (0.3472, 0.53, 0.6943 and 1.06 μm) in such SDP as Junge-3, 4 and 5. The Deirmendjian Haze M and L. A method is thereupon developed for retrieval of aerosols’ SDP and CRI from these parameters and tested by suitable numerical experiments. 相似文献
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New solution techniques to improve the accuracy of quantitatively determining the atmospheric extinction coefficient and the backscattering-to-extinction ratio from lidar signals are developed. The integration method is proposed to analytically retrieve the extinction coefficient at ground level, which has the advantage of eliminating the effect of backscattering fluctuations on the inversion results.The ratio method, on the other hand, deals with the inversion of the vertical distribution of the extinction coefficient. The main idea of this method is to begin with a calculation of the transmittance by eliminating the backscattering through ratioing lidar signals at two elevations, and subsequently derive the extinction coefficient from the transmittance, thus avert from ambiguous results caused by inappropriate assumptions on the backscattering-to-extinction ratio. Observational investigations have demonstrated that the integration method is superior to the slope method in terms of accuracy and stability, and the ratio method is reasonable and feasible as well. 相似文献