经度

A map database of the key points of storage, to accede to the point of latitude and longitude.

在地图数据库中各关键点存储的时候，加入该点的经度和纬度。

The results show that the seasonal variations of the centers of both the SAH and the anticyclone are obvious and in consistence with each other.

结果表明，100hPa高压环流中心有明显的季节分布特征，其中心经度的主频区与100 hPa南亚高压中心经度的主频区位置较为一致。

In light of different sources of data, three groups of affecting factors, that is, 1 mean annual air temperature; 2 longitude, latitude and elevation; and 3 mean annual air temperature, longitude, latitude and elevation; were designed as auxiliary variable, and the regression kriging method was adopted to predict the spatial patterns of mean annual soil temperatures across the country.

本文用我国698个气象站点的年均土壤温度和年均气温数据以及数字高程模型数据，分析不同气象和地形因素对年均土壤温度的影响；根据全国各地可获取数据源的不同，分别用3组不同的影响因素为辅助变量：(1)年均气温；(2)经度、纬度和海拔；(3)年均气温、经度、纬度和海拔，采用回归克里格法预测我国年均土壤温度空间分布。

Considering some period of time geomagnetic data recorded at the Observatory Surlari (colatitude 45.3°, longitude 26.3°) and comparing them with data recorded at other observatories, such as Ottawa (colatitude 44.6°, longitude 284.5°), Canberra (colatitude 125.3°, longitude 149.3°), Kakioka (colatitude 53.8°, longitude 140.2°) and Vernadsky (colatitude 155.3°, longitude 295.7°), including comparison to the windowed Fourier transform, the choice of an appropriate wavelet basis function, edge effects due to finite-length time series, and the relationship between wavelet scale and Fourier frequency.

我们分析了Surlari观测台（余纬45.3°，经度26.3°）的地磁时间序列，并与Ottawa（余纬44.6°，〖JP2〗经度284.5°），Canberra（余纬125.3°，经度149.3°）， Kakioka（余纬53.8°，经度140.2°），Vernadsky〖JP〗（余纬155.3°，经度295.7°）等台站的结果进行了对比分析，讨论了Fourier变换时间窗和小波基函数选取的影响，有限长时间序列引起的边缘效应，以及小波尺度和Fourier频率的关系等问题。

The difference in longitude between two positions as a result of a movement to the west.

经度差因为向西的运动而产生的两个位置之间的经度上的差别

A unit of measure of longitude or right ascension, equal to 15= or !

经度15°：经度或赤经单位，相当于15°或圆周的二十四分之一

The distribution characteristics of permafrost in this area were described based on drilling investigation. With the increase of altitude, the seasonally frozen ground zone is subrogated by patchy permafrost zone and then by continuous permafrost zone.

多年冻土分布具有明显的高度地带性，随高度增加，冻土分布呈现出季节冻土－岛状冻土－连续冻土更替，同时，多年冻土下界高程与经度明显相关，自西向东表现出下降趋势，下降率约为每经度150m，这一变化与降水在东西方向的变化有关。

In chapter 3, the characteristics of relative motion of small satellite based on ground station are firstly analyzed, in which using spherical trigometry, the analytic formulas evaluating the longitude ranges of ascending node which can cover the target are deduced with J2 precession. With the solution, the longitude ranges of ascending node limited by the cross-time can be gained. Secondly, a serious of characteristics of small satellite to space station is studied.

在第3章，首先分析了卫星相对地基的运动特性，在地基的运动特性研究中，重点研究了以升交点地理经度来描述所有能覆盖到目标点的轨道，利用球面三角形方法推导了在考虑地球形状J2项摄动影响时，各种情况下能覆盖目标点的轨道升交点经度范围，得到了完整的解析表达式。

The following conclusions are drawn. 1 The orbit parameters that have relatively greater influence on the number and latitudinal distribution of annual occultation events are orbit inclination, orbit height, Right Ascension of Ascending Node and Argument of Perigee in turn. All four parameters have little impact on the longitudinal distribution of annual occultation events. 2 The orbit inclination of Transmitting Satellite and Receiving Satellite impacts both LEO－LEO occultation events number and their latitudinal distribution most. The number of occultation events reaches the maximum as the sum of the two inclination angles nears 180 degrees. The one that far away from 90 degrees of the two inclination angles determines the latitude range of the occultation events. 3 LEO－LEO occultation events number reaches a maximum when the heights of TS and RS are the same, and it reaches the maximum when the heights of TS and RS are 600 km . 4 The RAAN of TS and RS has a great influence on the LEO－LEO occultation number, but has little influence on occultation distribution.

结果指出：1对一年掩星事件数量及其纬度分布影响大的轨道参数依次是轨道倾角、轨道高度、升交点赤经和近地点角距；而这些参数对一年掩星事件的经度分布影响都不大；2发射卫星和接收卫星倾角之间的相互关系对掩星事件数量和纬度分布影响最大，两卫星倾角接近互补时掩星事件最多，两颗LEO卫星中与90°相差较大的倾角决定了LEO－LEO掩星事件的纬度分布范围；3发射卫星和接收卫星处于同一轨道高度时，LEO－LEO掩星事件数取得极大值，发射卫星和接收卫星都采用600 km的轨道高度，一年LEO－LEO掩星事件数最多；4 发射卫星和接收卫星升交点赤经的相互关系对LEO－LEO掩星事件数量影响很大，发射卫星和接收卫星升交点赤经之差为120°或240°时掩星事件数量最多，RAAN对掩星事件纬度和经度分布影响不大；5近地点角距对掩星事件数量和分布影响都不大。

This is because you used the mean ecliptic longitude of the sun for midday of your chosen day and not the actual time of the event .

现在你可以看到你的时候差别很大，从时代的一个年历，这是因为你用的意思，黄道经度的阳光中午，你选择一天，而不是实际的时候，该事件如果你希望你的计算是完美，你将需要插平均黄道经度的太阳为实际的时候，这项活动。

right ascension：赤经度

"Ridley-Watkins-Hilsum mechnasim","芮瓦希机构" | "right ascension","赤经度" | "right ascension of ascending node","右上升交点"

astronomical azimuth：天文方位角;天文经度

太空航行学;星际航行学;宇宙航行学 astronautic | 天文方位角;天文经度 astronomical azimuth | 天文钟 astronomical clock

Longitude of Projection Center：投影中心经度

投影原点纬度 Latitude of Projection Origin | 投影中心经度 Longitude of Projection Center | 投影中心纬度 Latitude of Projection Center

chosen longitude：假设经度

chosen latitude 假设纬度 | chosen longitude 假设经度 | chosen position 假设船位

geodetic longitude：大地经度地理经度

geodetic longitude 大地经度 | geodetic longitude 大地经度地理经度 | geodetic meridian 大地子午线

geodetic longitude：大地经度 測地経度

■ geodetic latitude 大地经度 測地緯度 | ■ geodetic longitude 大地经度 測地経度 | ■ geodetic meridian 大地子午线 測地子午線

geographic longitude：地理经度

地面上某点的地理经度(Geographic longitude)是这样来确定的:以格林子午线为基准,用该子午线与某点子午线之间所截的赤道短弧,作为某点的地理经度(l). 地理经度的计算方法是:从格林子午线起算,沿赤道向东或向西,由0到180计量,计算至该点子午线,

Longitude：经度

我们不妨先探讨一下"经度"(longitude)的问题. 所谓经度,指的是本初子午线(primemeridian)以东或以西的距离度数. 目前国际公认的本初子午线,是一条虚构的曲线,从北极一直画到南极,穿过伦敦格林威治村的英国皇家天文台. 因此,

longitude of ascending node：升交点经度[天]

longitude; selenocentric 月心系经度[天] | longitude of ascending node 升交点经度[天] | longitudinal axis 纵轴

ascending node：升交点经度

Pericentric distance : 近日距 | Ascending node : 升交点经度 | Arg of pericentre : 近日点经度