1) auxiliary differential equation
辅助微分方程
1.
By constructing auxiliary differential equations,we obtain exact solutions of the generalized Camassa-Holm Equations,which include periodic cusp waves expressed by elliptic functions.
运用构造辅助微分方程的方法,获得了广义Camassa-Holm方程的精确解,此解包含了由椭圆函数表达的周期尖波解,推广了相关文献的结果。
2.
By constructing auxiliary differential equations,we obtain cusp wave solutions of the generalized Camassa-Holm Equations,which include periodic cusp waves expressed by elliptic functions.
通过构造辅助微分方程,求得了广义Camassa-Holm方程的尖波解,此解包含了由椭圆函数表达的周期尖波解,推广了有关文献的结果。
2) additional ordinary differential equation
辅助常微分方程
1.
By introducing an additional ordinary differential equation and the method of variable separation, some explicit and exact solutions to double sine-Gordon equation were found in a concise way.
借助于一个可用分离变量法求解的辅助常微分方程,简洁地求得了双sine-Gordon方程的若干显式精确解。
3) Sub-ODE method
辅助微分方程方法
4) Auxiliary ODE method
辅助常微分方程法
5) auxiliary equation
辅助方程
1.
The auxiliary equation for constructing the exact solutions of the variable coefficient combined KdV equation with forcible term;
辅助方程构造带强迫项变系数组合KdV方程的精确解
2.
The auxiliary equation for constructing the exact solutions of coupled KdV equations
辅助方程构造耦合KdV方程组的精确解
3.
Global asymptotic stability of a class of nonlinear rational difference equations was studied by means of setting up an auxiliary equation,so that a sufficient condition was obtained.
运用建立辅助方程的方法研究一类非线性有理差分方程正平衡点的全局渐近稳定性,得到一个充分条件。
6) auxiliary equation method
辅助方程
1.
In this paper,we make use of extended mapping method and auxiliary equation method for finding new periodic wave solutions of nonlinear evolution equations in mathematical physics,we obtain some new periodic wave solutions for Klein-Gordon equation which can not be found by previous work.
运用映射法,结合辅助方程,利用计算机代数系统Mathematica求出了非线性Klein-Gordon方程的一系列新的精确周期解,补充了前面研究的结果。
2.
In this paper,we make use of extended mapping method and auxiliary equation method for finding new periodic wave solutions of nonlinear evolution equations in mathematical physics,we obtain some new periodic wave solutions for mKdV and Klein-Gordon equation which can not be found by previous work.
本文运用映射法,结合辅助方程,利用计算机代数系统Mathematica求出了典型的非线性mKdV方程和Klein-Gordon方程的一系列新的精确周期解。
3.
In this work,2D cubic-quintic Ginzburg-Landau equation with diffractive-diffusive terms and normal dispersion is considered,some new exact traveling wave solution are obtained successfully by using identical reforming of differential equation method combine with a new auxiliary equation method.
利用同解变型法并结合一个高阶辅助方程的解,成功地取得了该方程的一些新的精确行波解。
补充资料:微分方程的差分方程逼近
微分方程的差分方程逼近
approximation of a differential equation by difference equations
微分方程的差分方程通近【app拟。mati.ofa山价犯n-ti习闪姗柱.by山血魂.理equa西姗;即即肠。砚田朋.朋巾卜碑四.别吸.。印冲.旧e朋,pa3I.ecTll目M] 微分方程用关于未知函数在某种网格上的值的代数方程组的逼近,当网格的参数(网络、步长)趋于零时可使得逼近更加精确. 设L(Lu可)是某个微分算子,几(L声。=几,。。任叭,人“凡)是某个有限差分算子(见徽分算子的差分算子通近(aPProximation of a dilferential operator by dif-feren沈。perators”.如果算子L、关于解u逼近算子L,其阶为p,即如果 }}Lh[u]*I}汽=o(hp),那么有限差分式L声、二0(o任凡)称为关于解“对微分方程Lu=O的P阶逼近. 构造有限差分方程L声*=0关于解u逼近微分方程Lu=0的最简单例子是将Lu的表达式中每个导数用相应的有限差分来代替. 例如,方程 _子“.,、血._,_八_一n Lu三书舟+P(x)于+q(x)u=U ~“一dxZr‘~产dxl‘’可用有限差分方程 L‘“‘三生理二丛吐丛二+ h‘ U~丰I一U,_I_ +尸(x们厂竺二兹巴几十,(x功)u朋一o作二阶精度逼近,其中网格几。和几;由点x.“。h组成(m是一整数),“.是函数u*在点x.的值.又,方程 au aZu L“三共牛一斗冬二0, --一ar ax,可用关于光滑解的两种不同的差分近似来逼近: _.月+1_”月气.月上.” 一门、“nt4用“用十l‘“阴l“用一I八 于九‘(撇式格式(exPlie,}seheme))和! “几’l一嗽试,‘l}一翔二,曰衅,‘从 拭’价二一一-一—一了一--一一几,(隐式格式(一mf)liczt scheme)),其中网格D*。和D*:由点(x。,甲=(川入,似)组成,:二rhZ,r二常数,巾和n是整数,。二是函数翻、在网格点(x,,t。)的值.存在这样的有限差分算子L,它对微分算子L的逼近,仅关于方程L。一0的解。特别好,而关于其他函数则差一些.例如,算一子L*L*U。三兴,·卜·夸卫一尹{刁内队引〔其中汀二·。州一随甲‘气))关f任意的光滑函数。(*)是算 广L- d仪 L“一…一甲〔戈,“)Z(工) 办的一阶逼近(_关于八)、而关于方程大u=O的解却是二阶逼近(假定函数:,充分光滑)在利用有限差分方程与。。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条