Cycling power meter

A cycling power meter is a device on a bicycle that measures the power output of the rider. Most cycling power meters use strain gauges to measure torque applied, and when combined with angular velocity, calculate power. The technology was adapted to cycling in the late 1980s and was tested in professional bicycle racing i.e.: the prototype Power Pacer (Team Strawberry) and by Greg LeMond with the SRM device. This type of power meter has been commercially available since 1989. Power meters using strain gauges are mounted in the bottom bracket, rear freehub, or crankset. Certain newer devices do not use strain gauges and instead measure power through handlebar-mounted units that utilize the principles of Newton's Third Law by measuring a cyclist's opposing forces (gravity, wind resistance, inertia, rolling resistance) and combining these with velocity to determine the rider's power output.

Training using a power meter is increasingly popular. Power meters generally come with a handlebar mounted computer that displays information about the power output generated by the rider such as instantaneous, max, and average power. Most of these computers also serve as all-around cycling computers and can measure and display heart rate as well as riding speed, distance and time. Power meters provide an objective measurement of real output that allows training progress to be tracked very simply—something that is more difficult when using, for example, a heart rate monitor alone. Cyclists will often train at different intensities depending on the adaptations they are seeking. A common practice is to use different intensity zones. When training with power, these zones are usually calculated from the power output corresponding to the so-called lactate threshold or MAP (maximal aerobic power).

Power meters provide instant feedback to the rider about their performance and measure their actual output; heart rate monitors measure the physiological effect of effort and therefore ramp up more slowly. Thus, an athlete performing "interval" training while using a power meter can instantly see that they are producing 300 watts, for example, instead of waiting for their heart rate to climb to a certain point. In addition, power meters measure the force that moves the bike forward multiplied by the velocity, which is the desired goal. This has two significant advantages over heart rate monitors: 1) An athlete's heart rate may remain constant over the training period, yet their power output is declining, which they cannot detect with a heart rate monitor; 2) While an athlete who is not rested or not feeling entirely well may train at their normal heart rate, they are unlikely to be producing their normal power—a heart rate monitor will not reveal this, but a power meter will. Further, power meters enable riders to experiment with cadence and evaluate its effect relative to speed and heart rate.

Power meters further encourage cyclists to contemplate all aspects of the sport in terms of power because power output is an essential, quantitative link between physiological fitness and speed achievable under certain conditions. A cyclist's VO₂ max (a proxy for fitness) can be closely related to power output using principles of biochemistry, while power output can serve as a parameter to power-speed models founded in Newton's laws of motion, thus accurately estimating speed.^[1] The joint application of power meters and power models has led to increasingly more scientific analyses of riding environments and physical properties of the cyclist, in particular aerodynamic drag.

Interfaces

Older cycling power meters use a set of wires to transmit power information to a computer mounted on the bicycle; this system has a serious disadvantage of having fine electrical cables being run all over the bicycle, making it harder to clean as well as using a fair number of fasteners to hold them up. However, since 2009 there is a general trend to move towards wireless systems . The most popular wireless system is ANT+ by ANT. Currently, Garmin, Quarq, Power2max, SRM (Schoberer Rad Meßtechnik), PowerTap and Pioneer have deployed this interface for various purposes on the bicycle. Stages Power meter, PowerTap , and 4iiii Precision all support both ANT+ and Bluetooth Smart protocols. Verve Cycling’s InfoCrank cycling power meter supports ANT+.

Power meter types

Crank

Crank based power meters measure the torque applied through both pedals via strain gauge/s positioned within the crank or crank spider. A calculation of power is derived from the deflection of the strain gauge/s and pedaling cadence.

These units require specific cranks or cranksets, but can be relatively simple to interchange between bikes, depending on compatibility.

Bottom bracket

Bottom bracket power meters rely on the torsional deflection in the BB shaft. This is done by the shaft having a disc at each end with perforations. These perforations are detected using non-contact photo-electric sensors that detect when torque is applied to the left pedal and then doubled. Data is sent digitally to a handlebar mounted computer unit.

These units are difficult to interchange and require a different bottom bracket unit for each bike.

Bottom bracket with connection cables

Freehub

A freehub power meter uses the same strain gauges that are present in the crank power meters, but is located in the rear wheel hub and measures the power after the drive chain. Because of this, power should theoretically be measured less than the crank based power meters. Because these units are built into the rear wheel, it is simple to interchange between bikes as long as the wheels are compatible.

Chain

At the heart of chain units is essentially a guitar pick-up that mounts to the cycle's chain stay. The pick-up detects chain vibration from which it calculates chain tension which, along with chain speed, gives power output. Finnish company Polar was the first to bring a chain-based power meter to market.

Opposing force

Opposing force power meters measure hill slope (gravity), bike acceleration (inertia) and, sometimes, wind speed. From this, power can be indirectly calculated.

Direct Applied force

This method monitors the forces applied to the pedal by the cyclist's foot. Sensors in the shoe or pedal measure the forces as the cranks rotate, and calculate the power based on the magnitude and direction of the applied force, and the angular velocity of the crank. Advantages of this technique include independent measurement of power for each leg, measurement of efficiency of pedaling style, and (depending on placement of sensors) avoiding the need to replace bike components.

Current Power Meters in the Market

Hub - Based Power Meter

PowerTap Hub

Pedals Based Power Meter

Garmin Vector
PowerTap Pedals
Favero Bepro
Polar/Look Power
Look

Crank Base Power Meter

SRM
PowerTap ChanRing
Power2Max
Quarq
Stages (Crank Arm)
4III Precision (Crank Arm)
Pioner Power
Verve infocrank
Rotor

Footpod Power Meter

RPM2

References

↑ Martin, James C.; Milliken, Douglas L.; Cobb, John E.; McFadden, Kevin L.; Coggan, Andrew R. (1998). "Validation of a Mathematical Model for Road Cycling Power". Journal of Applied Biomechanics. 14 (3): 276–91. doi:10.1123/jab.14.3.276.

External links

Book: Training and Racing with a Power Meter, 2nd Ed.
DC Rainmaker - The Power Meters Buyer’s Guide–2016 Edition
Anhalt, Tom (January 12, 2013). "What's up with those funky rings...?".
Sullivan, Mark (October 3, 2014). "Bicycle Crank Power Meters and Round and Non-Round Chainrings".
Abbiss, C.; Quod, M.; Levin, G.; Martin, D.; Laursen, P. (2009). "Accuracy of the Velotron Ergometer and SRM Power Meter". International Journal of Sports Medicine. 30 (2): 107–112. doi:10.1055/s-0028-1103285.
Cullen, L.; Andrew, K.; Lair, K.; Widger, M.; Timson, B. (2008). "Efficiency of Trained Cyclists Using Circular and Noncircular Chainrings". International Journal of Sports Medicine. 13 (3): 264–9. doi:10.1055/s-2007-1021264. PMID 1601563.
Hopker, J.; Myers, S.; Jobson, S. A.; Bruce, W.; Passfield, L. (2010). "Validity and Reliability of the Wattbike Cycle Ergometer". International Journal of Sports Medicine. 31 (10): 731–6. doi:10.1055/s-0030-1261968. PMID 20665423.
Driss, Tarak; Vandewalle, Henry (2013). "The Measurement of Maximal (Anaerobic) Power Output on a Cycle Ergometer: A Critical Review". BioMed Research International. 2013: 589361. doi:10.1155/2013/589361. PMC 3773392. PMID 24073413.
Bini, Rodrigo Rico; Dagnese, Frederico (2012). "Noncircular chainrings and pedal to crank interface in cycling: a literature review". Revista Brasileira de Cineantropometria e Desempenho Humano. 14 (4): 470–82. doi:10.5007/1980-0037.2012v14n4p470.
Strutzenberger, Gerda; Wunsch, Tobias; Kroell, Josef; Dastl, Jacqueline; Schwameder, Hermann (2014). "Effect of chainring ovality on joint power during cycling at different workloads and cadences". Sports Biomechanics. 13 (2): 97–108. doi:10.1080/14763141.2014.908946. PMID 25122995.

Bicycle parts

Frame	Handlebars Stem Head tube Headset Fork Seatpost Saddle Bottom bracket Fork end Suspension

Wheels	Tire Spoke Spoke nipple Valve stem Dustcap Quick release skewer

Drivetrain	Pedal Crankset Chain Cogset Derailleur gears/Hub gears Gear case Sprocket

Cabling	Shifter Bowden cable Cable guide Brake Ferrule

Peripherals	Basket Bell Bottle cage Fairing Cyclocomputer Kickstand Lighting Luggage carrier Mudguards Panniers Saddlebag Spoke card Reflectors Skirt guard Training wheels

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