• Wave resistance and friction drag charts
• Friction drag vs. speed
• Wave drag vs. speed
• Total drag vs. speed
• Coefficient of total drag vs. volumetric Froude number

As the hull plows through the water, a thin layer of water trapped in the 'roughness' of the surface is dragged along with the hull. Since the 'trapped' water molecules are in contact with many other molecules further from the hull, their kinetic energy is transferred progressively through 'layers' further from the kayak skin. This viscous interaction of water molecules is confined in a space called the boundary layer. The boundary layer is where water causes 99% of Frictional resistance.

When you think of kinetic energy transfer between water molecules, a game of billiard is a good analogy. A 'simple' chain reaction initiated by one ball hitting other balls that hit other balls.... This energy transfer essentially 'bleeds' the energy of the kayak into the turbulence of the surrounding water.
You may remember from school that kinetic energy is a function of mass and velocity such that:
E(kinetic)=0.5 x m x V^2
It is not surprising that theoretical frictional resistance also varies with the square of speed. In the real world it is a bit less since frictional resistance further subdivides into laminar flow resistance and fully turbulent flow resistance. Despite the difference, the formula below lumps them both together.

Viscous drag (Rf) depends on the following:

• wetted surface area - S (m^2)
• speed of the hull - V (m/s)
• viscosity (mu)
• kinematic viscosity (nu)
• density of water (rho)
• coefficient of friction- Cf (assumes smooth hull) no units
• length of waterline- L(m)

Unlike viscous drag, wave resistance is far more complicated to calculate for it takes into account many more hull parameters as well as other factors which are beyond the scope of this page (at this point).
Note from the graph that wave resistance doesn't really play much role in recreational paddling speeds under 4 knots but the difference between the hull forms becomes much more prominent at higher cruising speeds (4-5 knots).
As the longest hull in the group, the Double will predictably have the smallest wave resistance. The Expedition shows the lowest wave resistance at speeds of 3.5 - 5 knots which covers almost the entire envelope of 'normal' paddling. The Storm comes close second after the Expedition, but supersedes it at speeds over 5 knots.
Most recreational paddling speeds are about 2 - 3.5 knots. Energetic cruising speeds are largely in the 3.5 - 5.5 knots range. Speeds higher than 6 knots are in the realm of long distance racing and sprinting. Olympic sprint speeds average 9.98 knots (off the chart ).

Wave drag depends largely on the following:

• displacement
• speed of the hull
• BWL - waterline beam
• draft
• LWL - waterline length
• EWL - effective waterline length
• LCB - longitudinal center of buoyancy
• Cp - prismatic coeff.
• Cb - block coeff.
• Cm - midship coeff.
• angle of entry exit
• form factors (adjustment due to hard chines, appendages, stern and bow shape etc...)

Total resistance is the sum of frictional and wave resistance. (If you added the Frictional resistance graph to the residual drag graph you would get the chart on the left)

The blue line for the double shows the largest resistance but remember there are two people to share the load, so if you divided the total resistance, each paddler would need to exert less energy than in any of the single kayaks.
Take for example the total double resistance at 4 knots. It is 4.53lb and if you divide it in two, each paddler has to exert only 2.26lb. The Cape Ann Double will easily beat the pants off any single kayak even if one of the double's partners doesn't do their fair share of the work :)

The StormSLT has the lowest total resistance across the entire speed range making it the ideal cruising kayak for lighter paddlers with less physical strength.

This chart really shows the relative efficiency of the hulls adjusted for displacement (that is why the volumetric Froude number as the horizontal x-axis).
The interpretation is different (than with speed) and may be a little confusing because the volumetric Froude number takes into consideration BOTH speed AND volume at the same time.

Fn= V / (g^-1/2 x D^-1/6) (nondimensional)

V - speed (m/s)
g - gravitational acceleration (m/s^2)
D - displacement (m^3)
It may be mysterious that the equation is formulated as it is but if you substitute units in the Fn, everything will conveniently cancel out - that is why. You may have seen another Froude number which takes into account speed and waterline length as in:

Fn= V/(gL)^1/2

L - length of waterline (m)
If you substitute the units, everything will cancel out here as well. This Froude number is essentially the "speed / length" ratio so often talked about in relation to prismatic coefficient, 'hull speed' and wave resistance.

Finally, here is the definition of the Ct (coefficient of total resistance)

Ct = Rt/(1/2 x (rho) x V^2 x D^2/3)

Rt - are the values in chart #3
Again the divisor term units work out to become the units of force (kg x m/s^2) so that the entire coefficient becomes nondimensional.