Editing Lift-to-drag ratio (section)

==Glide ratio==
{{see also|Gliding flight#Glide ratio}}

As the aircraft [[fuselage]] and control surfaces will also add drag and possibly some lift, it is fair to consider the L/D of the aircraft as a whole. The [[Gliding (flight)#Glide ratio|glide ratio]], which is the ratio of an (unpowered) aircraft's forward motion to its descent, is (when flown at constant speed) numerically equal to the aircraft's L/D. This is especially of interest in the design and operation of high performance [[sailplane]]s, which can have glide ratios almost 60 to 1 (60 units of distance forward for each unit of descent) in the best cases, but with 30:1 being considered good performance for general recreational use. Achieving a glider's best L/D in practice requires precise control of airspeed and smooth and restrained operation of the controls to reduce drag from deflected control surfaces. In zero wind conditions, L/D will equal distance traveled divided by altitude lost. Achieving the maximum distance for altitude lost in wind conditions requires further modification of the best airspeed, as does alternating cruising and thermaling.  To achieve high speed across country, glider pilots anticipating strong thermals often load their gliders (sailplanes) with [[Gliding competitions#Water ballast|water ballast]]: the increased [[wing loading]] means optimum glide ratio at greater airspeed, but at the cost of climbing more slowly in thermals.  As noted below, the maximum L/D is not dependent on weight or wing loading, but with greater wing loading the maximum L/D occurs at a faster airspeed.  Also, the faster airspeed means the aircraft will fly at greater [[Reynolds number]] and this will usually bring about a lower [[zero-lift drag coefficient]].