例句與造句

1. an explicit precise integration algorithm for nonlinear dynamics problems
   非線(xiàn)性動(dòng)力學(xué)問(wèn)題的一個(gè)顯式精細(xì)積分算法
2. precise time integration algorithm of stiff equation in nonlinear dynamic system
   非線(xiàn)性動(dòng)力系統(tǒng)剛性方程精細(xì)時(shí)程積分法
3. theory of getting inertial angular position from linear accelerometer measurements with double integration algorithm is analyzed
   分析了使用線(xiàn)加速度計(jì)測(cè)量慣性角加速度,通過(guò)二次積分算法得到慣性姿態(tài)角的原理。
4. 5 ) presentation and implementation of a constraints-subjoining integration algorithm ( csi ) . the results of transformation are integrated by separating constraints and containing constraints defined by csi algorithm
   5)提出了附加約束集成算法通過(guò)定義分離約束和包容約束，實(shí)現(xiàn)對(duì)異構(gòu)數(shù)據(jù)源的xmlschema轉(zhuǎn)化結(jié)果的進(jìn)一步集成，初步建立異構(gòu)數(shù)據(jù)源數(shù)據(jù)之間的關(guān)系。
5. the newmark-p step-by-step numerical integration algorithm is used to calculate the response behavior of system when feed cabin locates at a certain position ( typical location ) and when feed cabin moves along a certain trace ( time-dependent structure )
   。arkd數(shù)值積分方法，在時(shí)域上分析了饋源艙停留在空間某一位置（典型點(diǎn)）和沿空間某一軌跡運(yùn)行（變結(jié)構(gòu)）時(shí)，系統(tǒng)的順風(fēng)向風(fēng)致響應(yīng)。
6. It's difficult to find integration algorithm in a sentence. 用integration algorithm造句挺難的
7. borrowing the traditional two-speed approach originally developed in conventional attitude integration, we design one new numerical integration algorithm to solve the three kinematic equations . the new navigation algorithm based on dual quaternion is thus constituted
   借鑒成熟的姿態(tài)四元數(shù)積分的雙速算法結(jié)構(gòu),設(shè)計(jì)了一個(gè)數(shù)值積分算法求解以上三個(gè)運(yùn)動(dòng)學(xué)方程,構(gòu)建了基于對(duì)偶四元數(shù)的捷聯(lián)慣性導(dǎo)航算法。
8. based on the continuity of target ’ s trajectory, a detection algorithm formed by modified dpa and track association algorithm is presented . the modified dpa energy integration algorithm with a confined search field is developed to solve the target energy pervasion problem
   針對(duì)直接dpa能量累加算法存在能量擴(kuò)散的缺點(diǎn),采用限定搜索窗的dpa能量累加算法,在減小目標(biāo)能量擴(kuò)散程度的同時(shí),提高了累加圖像后的目標(biāo)信噪比。
9. 3 . scheme of varying integrating steps and integration algorithm are given after analysizing the difficulties of solving the capture phase dynamics equations, and the flow chart of the whole docking process simulation is given; the need and design principles of the docking dynamics simulation system is analyzed, basic structure and modules of the system are detailed, and the software is demonstrated
   3.對(duì)捕獲段對(duì)接動(dòng)力學(xué)方程組的求解難點(diǎn)進(jìn)行分析,給出了變步長(zhǎng)策略以及求解算法,并給出了整個(gè)對(duì)接過(guò)程的求解流程圖;分析了對(duì)接動(dòng)力學(xué)仿真系統(tǒng)的需求和設(shè)計(jì)原則,描述了系統(tǒng)的基本結(jié)構(gòu)和模塊劃分,并對(duì)軟件功能進(jìn)行了介紹。
10. the sculling error in the velocity calculation is described and the sculling optimal compensation algorithms are derived in the sculling base motion environment . for testing the sculling correction algorithms " performance, several simulations are practiced and the simulation results show that the sculling compensation term in the velocity integration algorithms can not be neglected for the high accuracy sins in highly dynamic environments . 3
    分析了速度更新計(jì)算中劃船誤差的產(chǎn)生機(jī)理，詳細(xì)推導(dǎo)了劃船補(bǔ)償算法并在劃船運(yùn)動(dòng)條件下推導(dǎo)了劃船補(bǔ)償優(yōu)化算法，最后對(duì)各階算法進(jìn)行了仿真分析，仿真結(jié)果表明：對(duì)處在高動(dòng)態(tài)環(huán)境下的高精度導(dǎo)航系統(tǒng)，劃船補(bǔ)償不可忽略；3
11. in frequency domain, we research dct based information hiding techniques, and then give an adaptive technique, and a parity based approach in the dct domain, and an approach based on improved integration algorithm . we also propose an approach based on difference matrix in dct domain, and show all the approaches to embed / detect the secret messages, and their robust analysises
    在頻率域內(nèi)，研究了基于dct變換的信息隱藏技術(shù)，提出了改進(jìn)的dct自適應(yīng)隱藏算法、dct域奇偶性嵌入方法和改進(jìn)的融合算法，同時(shí)提出了差值矩陣的dct域的隱藏算法，給出了這些算法的信息嵌入與恢復(fù)過(guò)程，并對(duì)頻率域內(nèi)的這些隱藏算法的魯棒性進(jìn)行了分析。
12. by means of an integral expression of non-linear dynamics equation an explicit precise integration algorithm with four order accuracy and self-correct and self-starting to solve this equation is given . this method is adapted to solve the non-conservative system with multi-dof and strong nonlinear . the non-linear dynamic equations are divided into some blocks or groups
    給出了求解非線(xiàn)性動(dòng)力學(xué)方程的精細(xì)積分表達(dá)式，利用插值近似該方程的非線(xiàn)性項(xiàng)，得到一個(gè)具有四階精度并且是單步顯式、自起步、預(yù)測(cè)-校正的lagrange(或hermite)插值精細(xì)積分算法，適于強(qiáng)非線(xiàn)性、非保守系統(tǒng)。
13. a new step-by-step integral procedure of dynamics equations is presented . the general expression of the solution of dynamics equations is obtained on the basis of the homogenous analytical solutions of dynamics equations and duhamel integration . the explicit analytical integration algorithm, which is characterized by fourth-order accuracy, self-starting and self-correcting, is employed to discretize the equivalent load terms
    另外提出了求解動(dòng)力學(xué)方程的一個(gè)新型的逐步積分法，基于線(xiàn)性動(dòng)力學(xué)方程的解析齊次解及duhamel積分，構(gòu)造出適用于非線(xiàn)性動(dòng)力學(xué)方程解的一般積分表達(dá)式，對(duì)包含非線(xiàn)性項(xiàng)的非齊次項(xiàng)采用插值近似的方法，得到一個(gè)單步顯式、自起步、預(yù)測(cè)校正具有四階精度的解析逐步積分算法。