Optimal resistance for maximal power during treadmill running*

Jaskólski, Artur; Veenstra, B.; Goossens, P.; Jaskólska, Anna; Skinner, James S.

doi:10.1080/15438629609512067

Cited by 19 publications

(28 citation statements)

References 18 publications

(17 reference statements)

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“…the motor torque necessary to overcome the friction on the belt due to subject's body weight. The default torque was measured by requiring the subject to stand still at the centre of the treadmill and by increasing the driving torque value until observing a movement of the belt greater than 2 cm over 5 s. This default torque setting as a function of belt friction is in line with previous motorized treadmill studies (Chelly and Denis 2001;Falk et al 1996;Jaskolski et al 1996;Jaskoska et al 1999) and with the detailed discussion by McKenna and Riches in their recent study comparing ''torque treadmill'' sprint to overground sprint (McKenna and Riches 2007). The motor torque of 160% of the default value was selected after several preliminary measurements (data not shown) comparing various torques, because (a) it allowed subjects to sprint in a comfortable manner and produce their maximal effort without risking loss of balance, and (b) higher torques (180 and 200%) caused loss of balance in some of the subjects.…”

Section: Treadmill Measurementsmentioning

confidence: 63%

Sprint running performance: comparison between treadmill and field conditions

Morin

Sève

2011

Eur J Appl Physiol

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We investigated the differences in performance between 100-m sprints performed on a sprint treadmill recently validated versus on a standard track. To date, studies comparing overground and treadmill running have mainly focused on constant and not maximal "free" running speed, and compared running kinetics and kinematics over a limited number of steps, but not overall sprint performance. Eleven male physical education students including two sprinters performed one 100-m on the treadmill and one on a standard athletics track in a randomized order, separated by 30 min. Performance data were derived in both cases from speed-time relationships measured with a radar and with the instrumented sprint treadmill, which allowed subjects to run and produce speed "freely", i.e. with no predetermined belt speed imposed. Field and treadmill typical speed-distance curves and data of maximal and mean speed, 100-m time and acceleration/deceleration time constants were compared using t tests and field-treadmill correlations were tested. All the performance parameters but time to reach top speed and deceleration time constant differed significantly, by about 20% on average, between field and treadmill (e.g. top speed of 8.84 ± 0.51 vs. 6.90 ± 0.39 m s(-1)). However, significant correlations were found (r > 0.63; P < 0.05) for all the performance parameters except time to reach top speed. Treadmill and field 100-m sprint performances are different, despite the fact that subjects could freely accelerate the belt. However, the significant correlations found make it possible to investigate and interpret inter-individual differences in field performance from treadmill measurements.

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Section: Treadmill Measurementsmentioning

confidence: 63%

Sprint running performance: comparison between treadmill and field conditions

Morin

Sève

2011

Eur J Appl Physiol

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“…This allowed us to set, for each subject, the default motor torque that was necessary to overcome the friction on the belt due to subject's body weight. This was done by requiring the subject to stand still and by increasing the driving torque value until observing a movement of the belt greater than 2 cm over 5 s. This default torque setting as a function of belt friction is in line with previous motorized-treadmill studies (Chelly and Denis, 2001;Falk et al, 1996;Jaskolska et al, 1999a,b;Jaskolski et al, 1996), and with the detailed discussion by McKenna and Riches in their recent study comparing ''torque treadmill'' sprint to overground sprint (McKenna and Riches, 2007). From this value of default load, we determined individual values of higher resistance (20% lower motor torque) and lower resistance (20% higher motor torque).…”

Section: Sprint Treadmill Dynamometer and Load Settingmentioning

confidence: 74%

“…Power output is then measured as the product of the treadmill belt velocity and the horizontal component of the force exerted on the tether, measured by force transducers and goniometers. These treadmills are either non-motorized (Belli and Lacour, 1989;Cheetham et al, 1985;Funato et al, 2001;Lakomy, 1987;Nevill et al, 1989) or motorized (Chelly and Denis, 2001;Falk et al, 1996;Jaskolska et al, 1999b;Jaskolski et al, 1996) and in this case, the default motor torque is set to compensate for the friction of the treadmill belt-bed due to subjects' body weight.…”

Section: Introductionmentioning

confidence: 99%

“…Propulsive power is thus the product of the horizontal component of force and velocity, though these two entities are not applied/measured at the same location (the end of the tether and the ground, respectively). Further, an additional torque is needed to compensate the friction due to subjects' weight on the belt and allow them to reach maximal running velocities close to free running ones (Chelly and Denis, 2001;Falk et al, 1996;Jaskolska et al, 1999b;Jaskolski et al, 1996;McKenna and Riches, 2007).…”

Section: Introductionmentioning

confidence: 99%

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Direct measurement of power during one single sprint on treadmill

Morin

Samozino

Bonnefoy

et al. 2010

Journal of Biomechanics

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“…Further, testing the maximal power output of lower limbs extensor muscles is a common practice in the assessment of human exercise performance. Maximal power output has been assessed from different leg movements, namely sprint running (Jaskolska et al, 1999;Jaskolski et al, 1996), sprint pedalling (Arsac et al, 1996;Seck et al, 1995;Vandewalle et al, 1987a) or vertical jumping (Davies and Young, 1984;Rahmani et al, 2000;Wilson et al, 1997). No matter what the type of leg movement analysed, power output may be computed as the product of force times velocity.…”

Section: Introductionmentioning

confidence: 99%