中国大学MOOC:以下程序的输出结果是____main(){intw=4,x=3,y=2,z=1;if(x>y&&!(z==w))printf(”%d\n”,(w<x?w:z<y?z:x));elseprintf(”%d\n”,(w>x?w:z>y?z:x));}
中国大学MOOC:以下程序的输出结果是____main(){intw=4,x=3,y=2,z=1;if(x>y&&!(z==w))printf(”%d\n”,(w<x?w:z<y?z:x));elseprintf(”%d\n”,(w>x?w:z>y?z:x));}
\( {1 \over {1 + x}} \)的麦克劳林公式为( )。 A: \( {1 \over {1 + x}} = 1 + x + { { {x^2}} \over 2} + \cdots + { { {x^n}} \over {n!}} + o\left( { { x^n}} \right) \) B: \( {1 \over {1 + x}} = 1 + x + {x^2} + \cdots + {x^n} + o\left( { { x^n}} \right) \) C: \( {1 \over {1 + x}} = 1 - x + {x^2} - \cdots + {( - 1)^n}{x^n} + o\left( { { x^n}} \right) \) D: \( {1 \over {1 + x}} = 1 - x - { { {x^2}} \over 2}- \cdots - { { {x^n}} \over {n!}} + o\left( { { x^n}} \right) \)
\( {1 \over {1 + x}} \)的麦克劳林公式为( )。 A: \( {1 \over {1 + x}} = 1 + x + { { {x^2}} \over 2} + \cdots + { { {x^n}} \over {n!}} + o\left( { { x^n}} \right) \) B: \( {1 \over {1 + x}} = 1 + x + {x^2} + \cdots + {x^n} + o\left( { { x^n}} \right) \) C: \( {1 \over {1 + x}} = 1 - x + {x^2} - \cdots + {( - 1)^n}{x^n} + o\left( { { x^n}} \right) \) D: \( {1 \over {1 + x}} = 1 - x - { { {x^2}} \over 2}- \cdots - { { {x^n}} \over {n!}} + o\left( { { x^n}} \right) \)
\( {1 \over {1 + x}} \)的麦克劳林公式为( ). A: \( {1 \over {1 + x}} = 1 + x + { { {x^2}} \over 2} + \cdots + { { {x^n}} \over {n!}} + o\left( { { x^n}} \right) \) B: \( {1 \over {1 + x}} = 1 + x + {x^2} + \cdots + {x^n} + o\left( { { x^n}} \right) \) C: \( {1 \over {1 + x}} = 1 - x + {x^2} - \cdots + {( - 1)^n}{x^n} + o\left( { { x^n}} \right) \)
\( {1 \over {1 + x}} \)的麦克劳林公式为( ). A: \( {1 \over {1 + x}} = 1 + x + { { {x^2}} \over 2} + \cdots + { { {x^n}} \over {n!}} + o\left( { { x^n}} \right) \) B: \( {1 \over {1 + x}} = 1 + x + {x^2} + \cdots + {x^n} + o\left( { { x^n}} \right) \) C: \( {1 \over {1 + x}} = 1 - x + {x^2} - \cdots + {( - 1)^n}{x^n} + o\left( { { x^n}} \right) \)
牛顿基本插值公式,填空使程序完整。 x=1:7; y=[5 3 2 1 2 4 7]; syms p; plot(x,y,'o','linewidth',3); n=length(x); for k=1:n for j=【1】 y(j) = (y(j)-y(j-1))/【2】; end end v=0; w=1; for k=1:n v=v+【3】; w=w*(p-x(k)); end s=subs(v,'p','x') s=collect(s) ezplot(s,1,7)
牛顿基本插值公式,填空使程序完整。 x=1:7; y=[5 3 2 1 2 4 7]; syms p; plot(x,y,'o','linewidth',3); n=length(x); for k=1:n for j=【1】 y(j) = (y(j)-y(j-1))/【2】; end end v=0; w=1; for k=1:n v=v+【3】; w=w*(p-x(k)); end s=subs(v,'p','x') s=collect(s) ezplot(s,1,7)
假设原始问题为: max z=2x 1 -x 2 +3x 3 -2x 4 s.t. x 1 +3x 2 - 2x 3 + x 4 ≤12 -2x 1 + x 2 -3x 4 ≥8 3x 1 - 4x 2 +5x 3 - x 4 = 15 x 1 ≥0, x 2 :Free, x 3 ≤0, x 4 ≥0 则对偶问题中约束条件及决策变量的符号依次为: min y=12w 1 +8w 2 +15w 3 s.t. w 1 - 2w 2 + 3w 3 ( ) 2 3w 1 + w 2 - 4w 3 ( ) -1 -2w 1 +5w 3 ≤3 w 1 - 3w 2 - w 3 ≥-2 w 1 () 0,w 2 () 0, w 3 :Free
假设原始问题为: max z=2x 1 -x 2 +3x 3 -2x 4 s.t. x 1 +3x 2 - 2x 3 + x 4 ≤12 -2x 1 + x 2 -3x 4 ≥8 3x 1 - 4x 2 +5x 3 - x 4 = 15 x 1 ≥0, x 2 :Free, x 3 ≤0, x 4 ≥0 则对偶问题中约束条件及决策变量的符号依次为: min y=12w 1 +8w 2 +15w 3 s.t. w 1 - 2w 2 + 3w 3 ( ) 2 3w 1 + w 2 - 4w 3 ( ) -1 -2w 1 +5w 3 ≤3 w 1 - 3w 2 - w 3 ≥-2 w 1 () 0,w 2 () 0, w 3 :Free
δ(n)的z变换是( )? δ(w)|2π|2πδ(w)|;1
δ(n)的z变换是( )? δ(w)|2π|2πδ(w)|;1
将\(f(x) = {1 \over {2 - x}}\)展开成\(x \)的幂级数为( )。 A: \({1 \over {2 - x}} = \sum\limits_{n = 0}^\infty { { { { x^n}} \over { { 2^{n }}}}} \),\(( - 2,2)\) B: \({1 \over {2 - x}} = \sum\limits_{n = 0}^\infty { { { { x^n}} \over { { 2^{n }}}}} \),\(\left( { - 2,2} \right]\) C: \({1 \over {2 - x}} = \sum\limits_{n = 0}^\infty { { { { x^n}} \over { { 2^{n + 1}}}}} \),\(( - 2,2)\) D: \({1 \over {2 - x}} = \sum\limits_{n = 0}^\infty { { { { x^n}} \over { { 2^{n + 1}}}}} \),\(\left( { - 2,2} \right]\)
将\(f(x) = {1 \over {2 - x}}\)展开成\(x \)的幂级数为( )。 A: \({1 \over {2 - x}} = \sum\limits_{n = 0}^\infty { { { { x^n}} \over { { 2^{n }}}}} \),\(( - 2,2)\) B: \({1 \over {2 - x}} = \sum\limits_{n = 0}^\infty { { { { x^n}} \over { { 2^{n }}}}} \),\(\left( { - 2,2} \right]\) C: \({1 \over {2 - x}} = \sum\limits_{n = 0}^\infty { { { { x^n}} \over { { 2^{n + 1}}}}} \),\(( - 2,2)\) D: \({1 \over {2 - x}} = \sum\limits_{n = 0}^\infty { { { { x^n}} \over { { 2^{n + 1}}}}} \),\(\left( { - 2,2} \right]\)
已知()y()=()ln()x(),则()y()(()n())()=()。A.()(()−()1())()n()n()!()x()−()n()"()role="presentation">()(()−()1())()n()n()!()x()−()n();()B.()(()−()1())()n()(()n()−()1())()!()x()−()2()n()"()role="presentation">()(()−()1())()n()(()n()−()1())()!()x()−()2()n();()C.()(()−()1())()n()−()1()(()n()−()1())()!()x()n()"()role="presentation">()(()−()1())()n()−()1()(()n()−()1())()!()x()-n();()D.()(()−()1())()n()−()1()n()!()x()−()n()+()1()"()role="presentation">()(()−()1())()n()−()1()n()!()x()−()n()+()1().
已知()y()=()ln()x(),则()y()(()n())()=()。A.()(()−()1())()n()n()!()x()−()n()"()role="presentation">()(()−()1())()n()n()!()x()−()n();()B.()(()−()1())()n()(()n()−()1())()!()x()−()2()n()"()role="presentation">()(()−()1())()n()(()n()−()1())()!()x()−()2()n();()C.()(()−()1())()n()−()1()(()n()−()1())()!()x()n()"()role="presentation">()(()−()1())()n()−()1()(()n()−()1())()!()x()-n();()D.()(()−()1())()n()−()1()n()!()x()−()n()+()1()"()role="presentation">()(()−()1())()n()−()1()n()!()x()−()n()+()1().
已知N点有限长序列x(n)=δ((n+m))NRN(n),则N点DFT[x(n)]=()。 A: N B: 1 C: W D: W
已知N点有限长序列x(n)=δ((n+m))NRN(n),则N点DFT[x(n)]=()。 A: N B: 1 C: W D: W
已知N点有限长序列x(n)=δ((n+m)) A: ['N B: 1 C: W D: W
已知N点有限长序列x(n)=δ((n+m)) A: ['N B: 1 C: W D: W