Apparent wind

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V = boat speed, H = head wind, W = true wind, A = apparent wind, α = pointing angle, β = angle of apparent wind

Apparent wind is the wind experienced by a moving object.

Definition of apparent wind

The Apparent wind is the wind experienced by an observer in motion and is the relative velocity of the wind in relation to the observer.

Apparent wind velocity is the vector sum of the true wind and the headwind an object would experience in still air. The headwind velocity in still air is inverse of the object's velocity, therefore the apparent wind can also be defined as a vector subtraction: the Velocity of the wind minus the Velocity of the object.

A simple example

Suppose you are riding a bicycle on a day when there is no wind. Although the wind speed is zero (people sitting still feel no breeze), you will feel a breeze on the bicycle due to the fact that you are moving through the air. This is the apparent wind. On the windless day, the apparent wind will always be directly in front and equal in speed to the speed of the bicycle.

Now suppose there is a 5 mph wind coming directly from the north. If you pedal at 10 mph due north, you will feel an apparent wind of 15 mph from the north. But if you pedal 10 mph due south, you will feel an apparent wind of 5 mph from the south. The apparent wind is not only different in speed than the true wind (except when you are standing still), but may also be different in direction.

In these simple examples, the motion is parallel to the true wind which makes it easy to calculate the speed and direction of the apparent wind in relation to true wind speed (relative to the earth). When the motion is not parallel to the wind, one must use trigonometry to calculate the apparent wind. Vector mathematics might also be useful in some cases.

Apparent wind in sailing

In sailing, the apparent wind is the actual flow of air acting upon a sail. It is the wind as it appears to the sailor on a moving vessel. It differs in speed and direction from the true wind that is experienced by a stationary observer. In nautical terminology, these properties of the apparent wind are normally expressed in knots and degrees. On boats, apparent wind is measured (see "Instruments" below) or "felt on face / skin" if on a dinghy or looking at any telltales or wind indicators on board. True wind needs to be calculated or stop the boat.

Note that a number of additional factors come into play when converting the measurements from the masthead anemometer into the true wind if a high degree of accuracy is required, including the following:^[1]^[2]^[3]

Leeway (or drift on power vessels) - it is very seldom that a boat is pointing in the direction it is going, and on a sailboat the angle of leeway is the difference between the heading of the boat and its actual track through the water. This must be corrected for when converting apparent wind angle to true wind direction. The same effect is found when the boat is altering course.
Mast twist - the rigging loads often put a significant amount of torsion on the mast, especially if the rig has runners, so it is twisted along its length
Mast rotation - many racing multihulls have a mast that can be rotated, so the anemometer reading needs to be corrected by the angle of rotation of the mast
Heel angle - this is a simple trigonometric correction
Upwash from the sails - the airflow around the top of the mast is distorted by the presence of the sails. This effect varies with the sails set at the time, the wind speed and the point of sail, but is noticed by the true wind angle changing from port to starboard tack, and the true wind speed changing from when beating to running
Boat motions - as the masthead is so distant from the centre of motion of the boat, inertial effect on both the wind vane and the anemometer cups can be significant when the boat is moving, especially when pitching and rolling
Wind shear - there can be a significant change in both wind speed and direction between the water's surface and the top of the mast, especially in conditions of unstable, light airs. The wind instruments are just measuring conditions at the masthead, and these are not necessarily the same at all heights

Whilst in non-tidal waters it is valid to define the true wind as the wind when the vessel is stationary, but where there is a water flow (whether from tides or sailing on a river) this also has an effect on the wind experienced, and this is independent of the motion of the boat through the water. This is commonly factored out by defining the true wind as the wind experienced when the boat is drifting with the water (but moving with respect to the sea bed), and then defining the wind when the boat is stationary with respect to the sea bed as the ground or geographical wind.

Instruments

The apparent wind on board (a boat) is often quoted as a speed measured by a masthead transducer containing an anemometer and wind vane that measures wind speed in knots and wind direction in degrees relative to the heading of the boat. Modern instrumentation can calculate the true wind velocity when the apparent wind and boat velocity and direction are input.

Implications on sailing speeds

In sailboat racing, and especially in speed sailing, apparent wind is a vital factor, when determining the points of sail a sailboat can effectively travel in. A vessel traveling at increasing speed relative to the prevailing wind will encounter the wind driving the sail at a decreasing angle and increasing velocity. Eventually, the increased drag and diminished degree of efficiency of a sail at extremely low angles will cause a loss of accelerating force. This constitutes the main limitation to the speed of wind-driven vessels and vehicles.

Windsurfers and certain types of boats are able to sail faster than the true wind. These include fast multihulls and some planing monohulls. Ice-sailors and land-sailors also usually fall into this category, because of their relatively low amount of drag or friction.

In the foiling AC72 America's cup catamarans, the boats sail through the water at up to double the environmental wind strength. The effect of this is to radically change the apparent wind direction when sailing "downwind". In these boats the forward speed is so great that the apparent wind is always forward—at an angle that varies between 2 and 4 degrees to the wing sail. This means that AC72's are effectively tacking downwind, although at a greater angle than the normal 45-degree upwind angle, usually between 50 and 70 degrees.^[4]

Other areas of relevance

In fixed-wing aircraft, apparent wind is what is experienced on board, and it determines the necessary speeds for take-off and landing. Aircraft carriers generally steam directly upwind at maximum speed, in order to increase apparent wind and reduce the necessary take-off velocity. Land-based airport traffic, as well as most mid-sized and large birds generally take off and land facing upwind for the same reason.

Calculating apparent velocity and angle

$A = \sqrt{W^2 + V^2 +2WV\cos{\alpha}}$

Where:

$V$ = velocity (boat speed over ground, always > 0)
$W$ = true wind velocity (always > 0)
$\alpha$ = true pointing angle in degrees (0 = upwind, 180 = downwind)
$A$ = apparent wind velocity (always > 0)

The above formula is derived from the Law of cosines and using $\cos(\alpha') = \cos(180^\circ-\alpha) = -\cos(\alpha)$ .

The angle of apparent wind ( $\beta$ ) can be calculated from the measured velocity of the boat and wind using the inverse cosine in degrees ( $\arccos$ )

$\beta = \arccos \left( \frac{W\cos \alpha+V}{A} \right) = \arccos \left( \frac{W\cos \alpha+V}{\sqrt{W^2 + V^2 +2WV\cos{\alpha}}} \right)$

If the velocity of the boat and the velocity and the angle of the apparent wind are known, for instance from a measurement, the true wind velocity and direction can be calculated with:

$W = \sqrt{A^2 + V^2 - 2AV\cos{\beta}}$

and

$\alpha = \arccos \left( \frac{A\cos \beta-V}{W} \right) = \arccos \left( \frac{A\cos \beta-V}{\sqrt{A^2 + V^2 -2AV\cos{\beta}}} \right)$

Note: Due to quadrant ambiguity, this equation for $\alpha$ is only valid when the apparent winds are coming from the starboard direction (0° < β < 180°). For port apparent winds (180° < β < 360° or 0° > β > -180°), the true pointing angle (α) has the opposite sign:

$\alpha = -\arccos \left( \frac{A\cos \beta-V}{W} \right) = -\arccos \left( \frac{A\cos \beta-V}{\sqrt{A^2 + V^2 -2AV\cos{\beta}}} \right)$

Online calculation and graphical impact presentation

Short introduction related to Kitebuggy, Kite-MTB, Kitesurf
Input Wind speed & Course in degrees and Course speed, as an input to calculate apparent wind speed and apparent wind angle

References

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↑ TVNZ Live America's cup Broadcast. Interview with Tom Schnackenburg. 22/9/2013

External links

Navigational Algorithms Apparent wind soft, math: vector solution, and examples.
Apparent Wind Simulator from Hyde Sails, useful for Sailors

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[4] TVNZ Live America's cup Broadcast. Interview with Tom Schnackenburg. 22/9/2013

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Apparent wind

Contents

Definition of apparent wind

A simple example

Apparent wind in sailing

Instruments

Implications on sailing speeds

Other areas of relevance

Calculating apparent velocity and angle

Online calculation and graphical impact presentation

References

External links

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