船只尾波的鸟瞰图 从前方观测的船只尾波 尾波 (英語 :wake )是固体 在划过流体 (特别是液体 )表面时在尾部产生的V形传播的波 ,例如水鸟 或船舶 匀速游过水体 时在水面激起的后方波纹。因为由英国 的开尔文男爵 ——物理学家 威廉·汤姆森(William Thomson,1824~1907)最先对船波进行数学研究,因此也称为开尔文船波 (Kelvin wake或Kelvin ship wave )。
船形物体的尾波形状和福祿數 F r {\displaystyle Fr}
F r = V g l {\displaystyle Fr={\frac {V}{\sqrt {gl}}}}
其中g 为重力常数,V 是船速,l 是船的长度。
令船的长度 l = k ⋅ V 2 g {\displaystyle l=k\cdot {\frac {V^{2}}{g}}} F r = 1 k {\displaystyle Fr={\frac {1}{\sqrt {k}}}}
对于长度大而速度低的轮船,Fr数小,开尔文船波主要是长波,其波前与速度矢量的夹角比较小。
而小快艇,长度小,速度高,Fr 数大,开尔文船波则以短波长的水波为主,而波前则与速度矢量成较大的夹角。[ 1]
开尔文船波动研究,对于船舶的设计有重要意义,因为船舶的马力,有一部分消耗在激起船波。利用Fr数与速度成正比,与长度的平方根成反比的规律,可以利用小的模型,缩小船长 M 2 {\displaystyle M^{2}} [ 2]
Integrand of Kelvin Wake Integral Kelvin Ship Wake Integrand contour Maple plot 当船只以速度V驶过深水湖面,波形的幅度在相对于船只为静止的极坐标( ρ , ϕ {\displaystyle \rho ,\phi } ϕ = 0 {\displaystyle \phi =0} [ 3]
K ( ϕ , ρ ) = ∫ − π / 2 π / 2 cos ρ cos ( θ + ϕ ) cos 2 θ d θ {\displaystyle K(\phi ,\rho )=\int _{-\pi /2}^{\pi /2}\cos \rho {\frac {\cos(\theta +\phi )}{\cos ^{2}\theta }}d\theta }
其中 ρ = g r / V 2 {\displaystyle \rho =gr/V^{2}}
1 ρ = V 2 g r {\displaystyle {\frac {1}{\rho }}={\frac {V^{2}}{gr}}} 福祿數 的平方 F r 2 {\displaystyle Fr^{2}}
g {\displaystyle g} l {\displaystyle l}
上列K函数是下列多鞍点积分的正数部分:
K ( ϕ , ρ ) = ℜ ( ∫ − ∞ ∞ exp ( i ρ f ( θ , ρ ) d θ ) {\displaystyle K(\phi ,\rho )=\Re (\int _{-\infty }^{\infty }\exp(i\rho f(\theta ,\rho )d\theta )}
f ( θ , ϕ ) = − cos ( θ + ϕ ) cos 2 θ {\displaystyle f(\theta ,\phi )=-{\frac {\cos(\theta +\phi )}{\cos ^{2}\theta }}}
此核函数是一个多鞍点函数,振荡剧烈如图
求其极点,
d f ( θ , ϕ ) d θ = sin ( θ + ϕ ) cos ( θ ) 2 − 2 cos ( θ + ϕ ) sin ( θ ) cos ( θ ) 3 = 0 {\displaystyle {\frac {df(\theta ,\phi )}{d\theta }}={\frac {\sin(\theta +\phi )}{\cos(\theta )^{2}}}-{\frac {2\cos(\theta +\phi )\sin(\theta )}{\cos(\theta )^{3}}}=0}
解之,得
θ 1 = arctan ( ( 1 / 4 ) ( 1 + ( 1 − 8 tan ( ϕ ) 2 ) ) tan ( ϕ ) ) = − arctan ( ( 1 / 4 ) ( − 1 + ( 1 − 8 tan ( ϕ ) 2 ) ) tan ( ϕ ) ) {\displaystyle \theta _{1}=\arctan({\frac {(1/4)(1+{\sqrt {(1-8\tan(\phi )^{2}))}}}{\tan(\phi )}})=-\arctan({\frac {(1/4)(-1+{\sqrt {(}}1-8\tan(\phi )^{2}))}{\tan(\phi )}})}
由此
ϕ 1 = 19.47 {\displaystyle \phi _{1}=19.47}
ϕ 2 = − 19.47 {\displaystyle \phi _{2}=-19.47}
这就是凯尔文船波的V型波包线 的夹角,最早由凯尔文男爵发现,而且角度与船速无关.[ 4] [ 5]
θ = π − 19.47 = 35.3 {\displaystyle \theta =\pi -19.47=35.3} [ 1]
Kelvin Wake (Maple density plot) 开尔文船波波形 开尔文船波积分 K ( ϕ , ρ ) {\displaystyle K(\phi ,\rho )}
原理:当被积分函数剧烈震荡时,除了在极点外,震荡的被积分函数正负相抵消,因此可以将此被积分函数在极点的值作为整个积分的近似,驻相法乃是拉普拉斯方法 的推广。[ 6]
被积分函数 f ( θ , ϕ ) = − c o s ( θ + ϕ ) c o s 2 θ {\displaystyle f(\theta ,\phi )=-{\frac {cos(\theta +\phi )}{cos^{2}\theta }}}
θ p = a r c t a n ( ( 1 / 4 ) ∗ ( 1 + ( 1 − 8 ∗ t a n ( ϕ ) 2 ) ) t a n ( ϕ ) ) {\displaystyle \theta _{p}=arctan({\frac {(1/4)*(1+{\sqrt {(1-8*tan(\phi )^{2}))}}}{tan(\phi )}})}
θ m = − a r c t a n ( ( 1 / 4 ) ∗ ( − 1 + ( 1 − 8 ∗ t a n ( ϕ ) 2 ) ) t a n ( ϕ ) ) {\displaystyle \theta _{m}=-arctan({\frac {(1/4)*(-1+{\sqrt {(}}1-8*tan(\phi )^{2}))}{tan(\phi )}})}
令
f m = f ( θ m , ϕ ) = s i n ( ( 1 / 2 ) ∗ ϕ − ( 1 / 2 ) ∗ a r c s i n ( 3 ∗ s i n ( ϕ ) ) ) s i n ( ( 1 / 2 ) ∗ ϕ + ( 1 / 2 ) ∗ a r c s i n ( 3 ∗ s i n ( ϕ ) ) ) {\displaystyle f_{m}=f(\theta _{m},\phi )={\frac {sin((1/2)*\phi -(1/2)*arcsin(3*sin(\phi )))}{sin((1/2)*\phi +(1/2)*arcsin(3*sin(\phi )))}}}
f p = f ( θ p , ϕ ) = c o s ( ( 1 / 2 ) ∗ ϕ + ( 1 / 2 ) ∗ a r c s i n ( 3 ∗ s i n ( ϕ ) ) ) c o s ( − ( 1 / 2 ) ∗ ϕ + ( 1 / 2 ) ∗ a r c s i n ( 3 ∗ s i n ( ϕ ) ) ) {\displaystyle f_{p}=f(\theta _{p},\phi )={\frac {cos((1/2)*\phi +(1/2)*arcsin(3*sin(\phi )))}{cos(-(1/2)*\phi +(1/2)*arcsin(3*sin(\phi )))}}}
f b a r := 1 / 2 ∗ ( f p + f m ) {\displaystyle fbar:=1/2*(f_{p}+f_{m})}
D 2 F = d 2 F ( θ , ϕ ) d θ 2 {\displaystyle D2F={\frac {d^{2}F(\theta ,\phi )}{d\theta ^{2}}}}
D 2 F p = D 2 F ( θ p , ϕ ) {\displaystyle D2F_{p}=D2F(\theta _{p},\phi )}
D 2 F m = D 2 F ( θ m , ϕ ) {\displaystyle D2F_{m}=D2F(\theta _{m},\phi )}
Δ := ( 3 / 4 ∗ ( f m − f p ) ) ( 2 / 3 ) {\displaystyle \Delta :=(3/4*(f_{m}-f_{p}))^{(}2/3)}
u = Δ 1 / 2 2 ∗ ( 1 D 2 F p + 1 − D 2 F m ) {\displaystyle u={\sqrt {\frac {\Delta ^{1/2}}{2}}}*({\frac {1}{\sqrt {D2F_{p}}}}+{\frac {1}{\sqrt {-D2F_{m}}}})}
v = 2 Δ 1 / 2 ∗ ( 1 D 2 F p − 1 − D 2 F m ) {\displaystyle v={\sqrt {\frac {2}{\Delta ^{1/2}}}}*({\frac {1}{\sqrt {D2F_{p}}}}-{\frac {1}{\sqrt {-D2F_{m}}}})}
K ( ϕ , ρ ) ≈ 2 ∗ π ∗ ( u ∗ c o s ( ρ ∗ f b a r ) ∗ A i r y A i ( − ρ ( 2 / 3 ) ∗ Δ ) / ρ ( 1 / 3 ) + v ∗ s i n ( ρ ∗ f b a r ) ∗ A i r y A i ( 1 , − ρ ( 2 / 3 ) ∗ Δ ) / ρ ( 2 / 3 ) ) {\displaystyle K(\phi ,\rho )\approx 2*\pi *(u*cos(\rho *fbar)*AiryAi(-\rho ^{(}2/3)*\Delta )/\rho ^{(}1/3)+v*sin(\rho *fbar)*AiryAi(1,-\rho ^{(}2/3)*\Delta )/\rho ^{(}2/3))}
[ 7]
x := X ∗ s i n ( β ) ∗ ( 1 − ( 1 / 2 ) ∗ s i n ( β ) 2 ) {\displaystyle x:=X*sin(\beta )*(1-(1/2)*sin(\beta )^{2})}
y := X ∗ s i n ( β ) 2 ∗ c o s ( β ) / ( 2 ∗ M ) {\displaystyle y:=X*sin(\beta )^{2}*cos(\beta )/(2*M)}
Frank J. Oliver, NIST Handbook of Mathematical Functions, 2010, Cambridge University Press Jame Lighthill Waves in Fluids, Cambridge University Press 1979 
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Deutsch
. doi:10.1023/B:INAM.0000041400.70961.1b. 