下列不等式正确的是( ) A: \( { { {e^x} + {e^y}} \over 2} < {e^ { { {x + y} \over 2}}}\quad (x \ne y)\) B: \((x + y){e^{x + y}} < x{e^{2x}} + y{e^{2y}}\quad (x > 0,y > 0,x \ne y)\) C: \( { { {x^n} + {y^n}} \over 2} < {( { { x + y} \over 2})^n}\quad (x > 0,y > 0,x \ne y,n > 1)\) D: \(x\ln x + y\ln y < (x + y)ln { { x + y} \over 2}\quad (x > 0,y > 0,x \ne y)\)
下列不等式正确的是( ) A: \( { { {e^x} + {e^y}} \over 2} < {e^ { { {x + y} \over 2}}}\quad (x \ne y)\) B: \((x + y){e^{x + y}} < x{e^{2x}} + y{e^{2y}}\quad (x > 0,y > 0,x \ne y)\) C: \( { { {x^n} + {y^n}} \over 2} < {( { { x + y} \over 2})^n}\quad (x > 0,y > 0,x \ne y,n > 1)\) D: \(x\ln x + y\ln y < (x + y)ln { { x + y} \over 2}\quad (x > 0,y > 0,x \ne y)\)
设X1,X2,,,Xn是总体X的样本,则有()? A: X拔=E(X) B: X拔≈E(X) C: X拔=1/nE(X) D: 以上三种都不对
设X1,X2,,,Xn是总体X的样本,则有()? A: X拔=E(X) B: X拔≈E(X) C: X拔=1/nE(X) D: 以上三种都不对
以4,9,1为为插值节点,求\(\sqrt x \)的lagrange的插值多项式 A: \( {2 \over {15}}(x - 9)(x - 1) + {3 \over {40}}(x - 4)(x - 1) + {1 \over {24}}(x - 4)(x - 9)\) B: \( - {2 \over {15}}(x - 9)(x - 1) + {3 \over {40}}(x - 4)(x - 1) + {1 \over {24}}(x - 4)(x - 9)\) C: \( - {2 \over {15}}(x - 9)(x - 1) + {3 \over {40}}(x - 4)(x +1) + {1 \over {24}}(x - 4)(x - 9)\) D: \( - {2 \over {15}}(x - 9)(x - 1) + {3 \over {40}}(x - 4)(x - 1) - {1 \over {24}}(x - 4)(x - 9)\)
以4,9,1为为插值节点,求\(\sqrt x \)的lagrange的插值多项式 A: \( {2 \over {15}}(x - 9)(x - 1) + {3 \over {40}}(x - 4)(x - 1) + {1 \over {24}}(x - 4)(x - 9)\) B: \( - {2 \over {15}}(x - 9)(x - 1) + {3 \over {40}}(x - 4)(x - 1) + {1 \over {24}}(x - 4)(x - 9)\) C: \( - {2 \over {15}}(x - 9)(x - 1) + {3 \over {40}}(x - 4)(x +1) + {1 \over {24}}(x - 4)(x - 9)\) D: \( - {2 \over {15}}(x - 9)(x - 1) + {3 \over {40}}(x - 4)(x - 1) - {1 \over {24}}(x - 4)(x - 9)\)
能正确表示“当x的取值在[-58,-40]和[40,58]范围内为真,否则为假”的表达式是: (x>= -58) && (x<= -40) && (x>=40) && (x<=58)|(x>= -58) && (x<= -40) || (x>=40) && (x<=58)|(x>= -58) | |(x<= -40) && (x>=40) || (x<=58)|(x>= -58) || (x<= -40) || (x>=40) || (x<=58)
能正确表示“当x的取值在[-58,-40]和[40,58]范围内为真,否则为假”的表达式是: (x>= -58) && (x<= -40) && (x>=40) && (x<=58)|(x>= -58) && (x<= -40) || (x>=40) && (x<=58)|(x>= -58) | |(x<= -40) && (x>=40) || (x<=58)|(x>= -58) || (x<= -40) || (x>=40) || (x<=58)
能正确表示“当x的取值在[-58,-40]和[40,58]范围内为真,否则为假”的表达式是()。 A: (x>=-58)&&(x<=-40)&&(x>=40)&&(x<=58) B: (x>=-58)∥(x<=-40)∥(x>=40)∥(x<=58) C: (x>=-58)&&(x<=-40)∥(x>=40)&&(x<=58)
能正确表示“当x的取值在[-58,-40]和[40,58]范围内为真,否则为假”的表达式是()。 A: (x>=-58)&&(x<=-40)&&(x>=40)&&(x<=58) B: (x>=-58)∥(x<=-40)∥(x>=40)∥(x<=58) C: (x>=-58)&&(x<=-40)∥(x>=40)&&(x<=58)
(多选)以下平面弹性体的位移或形变状态不可能存在的是 A: 位移分量$u = {k_1}\left( {{x^2} + {y^2}} \right),v = {k_2}xy$(${k_1},{k_2}$为常数) B: ${\varepsilon _x} = k\left( {{x^2} + {y^2}} \right),{\varepsilon _y} = k{y^2},{\gamma _{xy}} = 2kxy$(${k \ne 0}$) C: ${\varepsilon _x} = 0,{\varepsilon _y} = 0,{\gamma _{xy}} = kxy$(${k \ne 0}$) D: ${\varepsilon _x} = ax{y^2},{\varepsilon _y} = b{x^2}y,{\gamma _{xy}} = cxy$($a \ne 0,b \ne 0,c \ne 0$)
(多选)以下平面弹性体的位移或形变状态不可能存在的是 A: 位移分量$u = {k_1}\left( {{x^2} + {y^2}} \right),v = {k_2}xy$(${k_1},{k_2}$为常数) B: ${\varepsilon _x} = k\left( {{x^2} + {y^2}} \right),{\varepsilon _y} = k{y^2},{\gamma _{xy}} = 2kxy$(${k \ne 0}$) C: ${\varepsilon _x} = 0,{\varepsilon _y} = 0,{\gamma _{xy}} = kxy$(${k \ne 0}$) D: ${\varepsilon _x} = ax{y^2},{\varepsilon _y} = b{x^2}y,{\gamma _{xy}} = cxy$($a \ne 0,b \ne 0,c \ne 0$)
若|x-3|=3-x,则x的取值范围是______ A: x>0 B: x=3 C: x<3 D: x≤3 E: x≥3
若|x-3|=3-x,则x的取值范围是______ A: x>0 B: x=3 C: x<3 D: x≤3 E: x≥3
假定16<X≤40,那么用边界值分析法,X在测试中应该取的边界值是: A: X=16,X=17,X=40,X=41 B: X=15,X=16,X=40,X=41 C: X=16,X=17,X=39,X=40 D: X=15,X=16,X=39,X=40
假定16<X≤40,那么用边界值分析法,X在测试中应该取的边界值是: A: X=16,X=17,X=40,X=41 B: X=15,X=16,X=40,X=41 C: X=16,X=17,X=39,X=40 D: X=15,X=16,X=39,X=40
M1型白血病骨髓中原始细胞应() A: ≥30%(NE B: C: ≥50%(NE D: E: ≥60%(NE F: G: ≥80%(NE H: I: ≥90%(NE J:
M1型白血病骨髓中原始细胞应() A: ≥30%(NE B: C: ≥50%(NE D: E: ≥60%(NE F: G: ≥80%(NE H: I: ≥90%(NE J:
直接积分法1.∫(3^x)(e^x)dx2.∫e^(3+t)/2dx3.∫[3^x-e^(-x)]e^xdx
直接积分法1.∫(3^x)(e^x)dx2.∫e^(3+t)/2dx3.∫[3^x-e^(-x)]e^xdx