调整点的调整

Optimal screw path length: The distance from the optimal entrancepoint to the optimal vent point Screw tail distance: The distance between left and right optimalentrance point Transverse section angle: Half of the included angle between left andright optimal screw Sagital section angle: The average of angle between both side optimalscrew with the upper terminal plate 1.2.2 Modify the threshold of CT value to distinguish the rear partof the lumbar, Observate the the optimal entrance point and the adjustable range.

1.2.2三维重建观察螺钉最佳进钉点的位置和各方向螺钉进钉点关系，调整CT值下限阈值使椎弓后部结构尽量显示清晰，以利观察。 1.3统计方法本实验采用SPSS13.0统计软件。对同一椎体左右两侧椎弓根螺钉相对数据行计量资料配对样本t检验，对男女组间相关数据行计量资料独立样本t检验，对男女组内不同腰椎节段间相关数据行单向方差分析及不同腰椎节段间LSD法多重比较。

A convenient procedure for drawing Bezier curves, after the selected point will be able to draw the corresponding Bessel function, while the location of the point can be adjusted to adjust the curve.

详细说明：一个方便绘出贝塞尔曲线的程序，选好点之后就能画出相应的贝塞尔函数，同时可以调整点的位置来调整曲线。

Forearm flexor origin from the medial epicondyle was exposed to allow tunneling of the long head tendon underneath the flexor origin.

方法切断胸大肌在肱骨的止点，在肱骨结节间沟顶端切断肱二头肌长头腱，然后向远端分离，显露至长头腱桡骨结节止点处，将前臂屈肌起点从肱骨内髁下方分离；将肱二头肌长头腱从前臂屈肌下方深面穿过，反折后穿过胸大肌止点，调整好张力再返回远端编结缝合。

The existing points and lines would form a closed geometric shape. If we put the new point Z outside the closed geometric shape at first and later then found that the point Z has neighboring relationship with the existing point A which is inside the closed geometric shape, we could not link point Z and A directly because that would bring line crossing. If we rearrange the point Z into the closed geometric shape, that also would cause a lot of work to do. With the help of Exclave, all problems could be solved easily. We use point X outside the closed geometric shape as the Exclave of the point A. Then the line between point Z and X could demonstrate the neighboring relationship of the point Z and A.

原有的各点和相邻线段往往会形成一个封闭的几何图形，如果我们把新增点 Z 设在原有的封闭几何图形外部，后来又发现该点 Z 和位于封闭几何图形内部的点 A 存在相邻关系，这时不能直接将两点连接因为那将产生交叉，而如果将点 Z 重新设在封闭图形内部也将导致大量的调整工作；此时借助外飞地的概念，可以轻松地解决上述问题，即在封闭几何图形外部设置点 X 作为点 A 的外飞地，两点使用同样的颜色，用点 Z 和点 X 的相邻线段表示点 Z 和点 A 之间的相邻关系。

We presents an accurate F method based on corresponding point adjustment.The method adjusts coresponding points according to the fixedness of projective transformed cross ratio,then calculates F matrix accurately through linear and non-linear methods. When computing intrinsic parameter,A matrix,we simplify the step,and stress on the two important parameters of A.The result will be getten through solving Kruppa equation based on SVD decomposition.In order to compute extrinsic parameters,we use linear method to get initial R and t,then apply non-linear method to accurate them.

提出了基于匹配点调整的F求精方法，先根据摄影交比不见性对手工选择的匹配点进行调整，再用线性、非线性结合的方法求精F矩阵；在计算内部参数A中，进行了一定的简化，把重心放在A中重要的两个参数上，用SVD分解法计算Kruppa方程；在计算外部参数时，首先用线性法求解R、t，然后再用非线性法迭代求精。

In the self - calibration scheme , the thesis emphasizes the accuracy of camera intrinsic and extrinsic parameters . we presents an accurate f method based on corresponding point adjustment . the method adjusts coresponding points according to the fixedness of projective transformed cross ratio , then calculates f matrix accurately through linear and non - linear methods . when computing intrinsic parameter , a matrix , we simplify the step , and stress on the two important parameters of a . the result will be getten through solving kruppa equation based on svd decomposition . in order to compute extrinsic parameters , we use linear method to get initial r and t , then apply non - linear method to accurate them

提出了基于匹配点调整的f求精方法，先根据摄影交比不见性对手工选择的匹配点进行调整，再用线性、非线性结合的方法求精f矩阵；在计算内部参数a中，进行了一定的简化，把重心放在a中重要的两个参数上，用svd分解法计算kruppa方程；在计算外部参数时，首先用线性法求解r、 t ，然后再用非线性法迭代求精。

Present a new LVQ wavelet image coding algorithm in which entropy coding and enumeration codes of different length are utilized. For wavelet image coding, there is a problem of mismatch between lattice distribution and the input vector probability density function in traditional LVQ algorithms (such as product-code pyramid VQ and piecewise uniform LVQ).

提出一种使用熵编码和非等长枚举码的格点矢量量化算法用于小波图象的编码，该算法以格点标记码码长的变化来适应输入矢量的非均匀分布，解决了传统的乘积码塔形矢量量化和分块均匀格点矢量量化算法中格点的调整难以与输入矢量概率分布实现良好匹配的问题。

This approach uses the geometric features and radiation features of the road, according to the small amount seed points given by the user, each point in the road centerline can be gotten. Then an adaptive gray template is used to adjust each point in the road centerline. Finally, least square method and Newton iteration method are adapted to each point in the road centerline to fit a polygonal line.

该方法利用道路地物的几何特征和辐射特征，根据用户提供的少量道路种子点，利用自适应灰度模板对道路中心线上的每个点进行调整，最后采用最小二乘算法和牛顿迭代法对调整后的道路中心线上的每个点进行拟合，以此获得趋近于道路中心线的最佳折线。

But this wave of adjustments should not reach 2,400 points, 2,600 points in the above should be able to bottoming out.

但这一波的调整应该不会达到2400点，在2600点之上就应该可以见底。

New box design with durable 0.5 inch (13 mm) paving skin Vertically-adjusting mold mount for precise leveling of mold to machine Telescoping end sections with 12 inches (305 mm) of width variation on each side are available Standard paving depth is zero to 24 inches (610 mm)Edge slump adjustment Hydraulic Vertical Hinged Sideplates, self-contained inside the mold for track clearance Split, pressure-compensated sideplates Folding side plate wings for transporting without removing Pivoting mold mounting beam to eliminate stress points Self-supported TA is hydraulically driven with 3.5 inch (89 mm) ACME screws for up to a six inch (152 mm) crown Front and rear top T-bar on mold for attaching accessories and structural integrity Inserts are bolted together with front and rear alignment pins for easy mold assembly New vibrator mounting tube attaches to T-bar on mold – Vertical vibrator lift – Rear lubrication system with grease zerks accessible from the work bridge New strike-off – Mounted on paver frame T-rail, independent of the mold – New modular design with wedge lock system for ease in changing widths – 10 inches (254 mm) of hydraulic height adjustment – Hydraulic crown adjustment Spreader plow mounted to paver frame T-rail, optional auger available Tamper bar optional

与耐久性的新的箱子设计铺精密水准测量的0.5英寸(13 mm)皮肤垂直调整的模子登上模子用机器制造挤撞与12英寸(305 mm)的末端部分在每边的宽度变异是可利用的标准铺的深度是零对24英寸(610 mm)边缘暴跌调整水力垂直的取决于的Sideplates，独立性在轨道清除分裂的模子里面，折叠运输的pressure-compensated sideplates旁边板材翼没有去除在轴上旋转的模子架置射线消灭重音点Self-supported TA水力驾驶与3.5英寸(89 mm)由六英寸(152 mm)冠决定的尖端螺丝在前后冠上在模子的T酒吧附有的辅助部件并且结构正直插入物与容易的模子汇编新的振荡器架置管随员T酒吧的定位销一起在前后被闩上在模子–垂直的振荡器推力与油膏zerks的–后方润滑系统容易接近从新工作的桥梁触击–在摊铺机框架足迹，模子的独立登上了与楔子锁系统的–新的模块设计在改变的宽度的舒适的– 10英寸(254 mm)水力高低调整–水力冠调整分布器犁登上了对摊铺机框架足迹，任意任意木钻可利用的堵塞器的酒吧

adjustable：可调整的

汇率的界限已大大超过了金本位制度下黄金输送点,汇率只是相对固定. 况且当一国的国际收支出现根本性的不平衡使汇率变动成为必要时,则将允许汇率进行变动. 可见,布雷顿森林体系下的固定汇率制度实质上是"可调整的(Adjustable)盯住"汇率制度.

counterbalance：调整平衡

调整平衡 调整平衡(Counterbalance)又称平衡控制(Flagging),并非特定之攀岩技巧,而是一项攀岩原则--平均分配身体之重量以保持平衡. 调整平衡意即选择最能平衡身体的把手点或踏足点;也意指无把手点或踏足点时,将手或脚摆在特定位置,

GD;GDR;GDRV：绿激励;显像管亮平衡绿色调整

GB;GC;GCF;GCO;GCT;GCUT;GCUT OFF 绿色截止点;显像管暗平衡绿色调整 | GD;GDR;GDRV 绿激励;显像管亮平衡绿色调整 | GENERAL 一般性的(调整)

larger：較大

目前大部分的浏览器都可由使用者自行调整字体大小,如果您使用的是IE浏览器,请参考下面的调整方式: 在菜单中,点击查看(View)---文字大小(Fonts)--- 最大(Largest )、较大(Larger)、中(Medium)、较小(Smaller)、最小(Smallest)等五

modulated：已调整[制] 的, 被调的

cross lay (钢丝绳的)导向捻, 交叉捻 | modulated 已调整[制] 的, 被调的 | point representation 点线表示法

scattering：分布

在画笔面板中左侧选择散点分布(scattering)选项,产生水草效果. 调整scattering的数值,使画笔产生出离散点状效果. 然后,调整count选项控制的离散点产生数量. 利用intuos2的压感功能可以很随意的画出疏密不一的水草效果.

Ships：舰船

机动车辆(Vehicles)、舰船(Ships)的导航点(Waypoint)参数有以下两项: Time:此处的时间设置方法与飞机导航点一样. 唯一的区别在于.这几种物体的速度和到达该点的时间是不能调整的. 它们总是按照其最高速度运动的.所以到达该点的时间也是固定的.

SIVA Algorithm：场模拟计算中一种对变量进行逐点调整的迭代方法

situation unit leader 情况科科长<从属计划部 | SIVA Algorithm 场模拟计算中一种对变量进行逐点调整的迭代方法 | size of rope 绳的尺寸

Tangents：显示物体上每个点的切线

● Vertex Normals - 显示物体上点的法线 | ● Tangents - 显示物体上每个点的切线 | ● Normals Size - 调整法线显示的长短

connectionless：非连接导向

二.IP本身非连接导向(connectionless)的特性,提供网路扩张的弹性,及点对点的第三层服务. ABR提供详尽的资讯给相邻的交换器,所以使得ATM的核心网路可以随时调整传输速率以防止细胞的漏失. 如图六所示,伫列的深度主要是取决於最终边际路由器的出口介面,