(1)求极限
\[ \lim_{x\rightarrow \infty} (3^x+9^x)^{1/x},
\lim_{x\rightarrow\infty}\frac{(x+2)^{x+2}(x+3)^{x+3}}{(x+5)^{2x+5}},
\lim_{x \rightarrow a}{\left(\frac{\tan x}{\tan a}\right)^{\cot(x-a)}},\\lim_{x\rightarrow 0}\left[\frac{1}{\ln(x+\sqrt{1+x^2})}-\frac{1}{\ln(1+x)}\right],\\lim_{x\rightarrow \infty}\left[\sqrt[3]{x^3+x^2+x+1}-\sqrt{x^2+x+1}\frac{\ln(e^x+x}{x}\right]\]>> syms x,a;
>> f1=(3^x+9^x)^(1/x);
>> f2=(x+2)^(x+2)*(x+3)^(x+3)/(x+5)^(2*x+5);
>> f3=(tan(x)/tan(a))^cot(x-a);
>> f4=1/log(x+sqrt(1+x^2))-1/log(1+x);
>> f5=(x^3+x^2+x+1)^(1/3)-sqrt(x^2+x+1)*log(exp(x)+x)/x;
>> limit(f1,x,inf)
>> limit(f2,x,inf)
>> limit(f3,x,a)
>> limit(f4,x,0)
>> limit(f5,x,inf)
(2)
(5)\(y(t)=\sqrt{\frac{(x-1)(x-2)}{(x-3)(x-4)}}\)的4阶导数
>> syms x;y=sqrt((x-1)*(x-2)/((x-3)*(x-4)));
>> tic,diff(y,x,4),toc
(6)
(8)直接求极限与洛必达对比:
\[\lim_{x\rightarrow 0}\frac{\ln(1+x)\ln(1-x)-\ln(1-x^2)}{x^4}
\]>> syms x;f=(log(1+x)*log(1-x)-log(1-x^2))/x^4;
>> f1=log(1+x)*log(1-x)-log(1-x^2);f2=x^4;
>> y1=limit(f,x,0)
>> y2=diff(f1,x,4)/diff(f2,x,4);subs(y2,x,0)
(9)参数方程\(\begin{cases}x=\ln(\cos t)\\y=\cos t-t\sin t\end{cases}\),计算\(\frac{\text{d}y}{\text{d}x},\frac{\text{d}^2y}{\text{d}x^2}\)(例题的paradiff)
>> syms t;x=log(cos(t));y=cos(t)-t*sin(t);
>> paradiff(y,x,t,1)
>> paradiff(y,x,t,2)
(11)\(u=\arccos\sqrt{\frac{x}{y}}\)验证\(\frac{\partial^2u}{\partial x\partial y}=\frac{\partial^2u}{\partial y\partial x}\)
>> syms x y;
>> u=acos(sqrt(x/y));
>> diff(diff(u,y,1),x,1)-diff(diff(u,x,1),y,1)
(14)计算\(\frac{x}{y}\frac{\partial^2 f}{\partial x^2}-2\frac{\partial^2 f}{\partial x\partial y}+\frac{\partial^2 f}{\partial^2 y}\) 其中$$f(x,y)=\int_0^{xy} e^{-t^2}\text{d}t$$
>> syms x y t;
>> f(x,y)=int(exp(-t^2),0,x*y);
>> %f(x,y)=int(exp(-t^2),t,0,x*y);
>> g=diff(f,x,2)*x/y-2*diff(diff(f,x,1),y,1)+diff(f,y,2)
(15)计算\(\frac{\text{d}y}{\text{d}x},\frac{\text{d}^2y}{\text{d}x^2},\frac{\text{d}^3y}{\text{d}x^3}\)
\[\begin{cases}x=e^{2t}\cos^2t\\y=e^{2t}\sin^2t\end{cases};\begin{cases}x=\frac{\arcsin t}{\sqrt{1+t^2}}\\ y=\frac{\arccos t}{\sqrt{1+t^2}}\end{cases}
\]>> syms t x1 y1 x2 y2;
>> x1=exp(2*t)*cos(t)^2;
>> y1=exp(2*t)*sin(t)^2;
>> x2=asin(t)/sqrt(1+t^2);
>> y2=acos(t)/sqrt(1+t^2);
>> paradiff(y1,x1,t,1)
>> paradiff(y1,x1,t,2)
>> paradiff(y1,x1,t,3)
>> paradiff(y2,x2,t,1)
>> paradiff(y2,x2,t,2)
>> paradiff(y2,x2,t,3)
(16)写题目浪费时间,专心代码
>> syms x y;f=x^2-x*y+2*y^2+x-y-1;
>> subs(impldiff(f,x,y,1),{x,y},{0,1})
>> subs(impldiff(f,x,y,2),{x,y},{0,1})
>> subs(impldiff(f,x,y,3),{x,y},{0,1})
(17)
>> syms x y z;
>> f=[3*x+exp(y)*z, x^3+y^2*sin(z)];
>> jacobian(f,[x y z])
(18)
>> syms x y;
>> u=x-y+x^2+2*x*y+y^2+x^3-3*x^2*y-y^3+x^4-4*x^2*y^2+y^4;
>> ux4=diff(u,x,4); ux3y1=diff(diff(u,x,3),y,1); ux2y2=diff(diff(u,x,2),y,2);
(19)
>> syms x y;
>> u=x-y+x^2+2*x*y+y^2+x^3-3*x^2*y-y^3+x^4-4*x^2*y^2+y^4;
>> laplacian(u,[x,y])
(20)
(21)
>> syms x y z t psi(z);
>> z=x^2+y^2;t=psi(z);
>> y*diff(t,x)-x*diff(t,y)
(22)
>> syms x y z u psi(z) phi(z);
>> z=x+y;u=x*phi(z)+y*psi(z);
>> diff(u,x,2)-2*diff(diff(u,x),y)+diff(u,y,2)
(23)
%1
>> syms x y v(x,y);
>> v(x,y)=[5*x^2*y 3*x^2-2*y];
>> divergence(v(x,y),[x,y]),curl(v(x,y),[x,y])
%2
>> syms x y z v;
>> v=[x^2*y^2 1 z];
>> divergence(v,[x,y,z]),curl(v,[x,y,z])
%3
>> syms x y z v;
>> v=[2*x*y*z^2 x^2*z^2+z*cos(y*z) 2*x^2*y*z+y*cos(y*z)]
>> divergence(v,[x,y,z]),curl(v,[x,y,z])
(25)
>> syms a b c x t;
>> I1=-(3*x^2+a)/(x^2*(x^2+a)^2);
>> I2=sqrt(x*(x+1))/(sqrt(x)+sqrt(1+x));
>> I3=x*exp(a*x)*cos(b*x);
>> I4=exp(a*x)*sin(b*x)*sin(c*x);
>> I5=(7*t^2-2)*3^(5*t+1);
>> int(I1,x),int(I2,x),int(I3,x),int(I4,x),int(I5,t)
>> %I2积不出
(26)
>> syms x, n;
>> f1=cos(x)/sqrt(x);
>> f2=(1+x^2)/(1+x^4);
>> f3=abs(cos(log(1/x)));
>> int(f1,x,0,inf),int(f2,x,0,1),int(f3,x,exp(-2*pi*n),1)
>> subs(int(3,x),x,1)-subs(int(3,x),x,exp(-2*pi*n))
>> %f3定积分积不出,先不定积分处理再利用牛顿莱布尼茨公式
>> %这里使用的是解析函数,使用subs赋值,如果直接函数格式,代入即可
(27)
原文:/Math-Nav/p/13367308.html
