Tucker VA
Department of Zoology, Duke University, Durham, NC 27708, USA.
J Exp Biol. 1998 Jan 14;201(Pt 3):403-14. doi: 10.1242/jeb.201.3.403.
Some falcons, such as peregrines (Falco peregrinus), attack their prey in the air at the end of high-speed dives and are thought to be the fastest of animals. Estimates of their top speed in a dive range up to 157 m s-1, although speeds this high have never been accurately measured. This study investigates the aerodynamic and gravitational forces on 'ideal falcons' and uses a mathematical model to calculate speed and acceleration during diving. Ideal falcons have body masses of 0.5-2.0 kg and morphological and aerodynamic properties based on those measured for real falcons. The top speeds reached during a dive depend on the mass of the bird and the angle and duration of the dive. Given enough time, ideal falcons can reach top speeds of 89-112 m s-1 in a vertical dive, the higher speed for the heaviest bird, when the parasite drag coefficient has a value of 0.18. This value was measured for low-speed flight, and it could plausibly decline to 0.07 at high speeds. Top speeds then would be 138-174 m s-1. An ideal falcon diving at angles between 15 and 90 degrees with a mass of 1 kg reaches 95 % of top speed after travelling approximately 1200 m. The time and altitude loss to reach 95 % of top speed range from 38 s and 322 m at 15 degrees to 16 s and 1140 m at 90 degrees, respectively. During pull out at top speed from a vertical dive, the 1 kg ideal falcon can generate a lift force 18 times its own weight by reducing its wing span, compared with a lift force of 1.7 times its weight at full wing span. The falcon loses 60 m of altitude while pulling out of the dive, and lift and loss of altitude both decrease as the angle of the dive decreases. The 1 kg falcon can slow down in a dive by increasing its parasite drag and the angle of attack of its wings. Both lift and drag increase with angle of attack, but the falcon can cancel the increased lift by holding its wings in a cupped position so that part of the lift is directed laterally. The increased drag of wings producing maximum lift is great enough to decelerate the falcon at -1.5 times the acceleration of gravity at a dive angle of 45 degrees and a speed of 41 m s-1 (0.5 times top speed). Real falcons can control their speeds in a dive by changing their drag and by choosing the length of the dive. They would encounter both advantages and disadvantages by diving at the top speeds of ideal falcons, and whether they achieve those speeds remains to be investigated.
一些猎鹰,如矛隼(矛隼属矛隼),会在高速俯冲结束时在空中攻击猎物,被认为是速度最快的动物。据估计,它们俯冲时的最高速度可达157米/秒,不过如此高的速度从未被精确测量过。本研究调查了“理想猎鹰”所受的空气动力和重力,并使用数学模型来计算俯冲过程中的速度和加速度。理想猎鹰的体重为0.5至2.0千克,其形态和空气动力学特性基于对真实猎鹰的测量。俯冲过程中达到的最高速度取决于鸟的体重、俯冲角度和持续时间。如果有足够的时间,理想猎鹰在垂直俯冲中可以达到89至112米/秒的最高速度,对于最重的鸟来说速度更高,此时寄生阻力系数的值为0.18。该值是在低速飞行时测量的,在高速时可能合理地降至0.07。那么最高速度将为138至174米/秒。一只体重1千克的理想猎鹰以15至90度的角度俯冲时,在飞行约1200米后达到最高速度的95%。达到最高速度的95%所需的时间和高度损失分别为:15度时为38秒和322米,90度时为16秒和1140米。在从垂直俯冲中以最高速度拉起时,体重1千克的理想猎鹰通过减小翼展可产生自身重量18倍的升力,而在翼展完全展开时升力为自身重量1.7倍。猎鹰在拉起俯冲时会损失60米的高度,并且随着俯冲角度减小,升力和高度损失都会降低。体重1千克的猎鹰可以通过增加寄生阻力和翅膀的攻角来在俯冲中减速。升力和阻力都随攻角增加,但猎鹰可以通过将翅膀保持成杯状位置来抵消增加的升力,使部分升力侧向作用。在45度俯冲角和41米/秒(最高速度的0.5倍)的速度下,产生最大升力的翅膀增加的阻力足以使猎鹰以重力加速度的1.5倍减速。真实的猎鹰可以通过改变阻力和选择俯冲长度来控制俯冲速度。它们以理想猎鹰的最高速度俯冲会有优势也有劣势,它们是否能达到这些速度仍有待研究。
