Do Surface Slope and Posture Influence Lower Extremity Joint Kinetics during Cycling?

Tang, Yunqi; Wang, Donghai; Wang, Yong; Yin, Keyi; Zhang, Cui; Zou, Limin; Liu, Yu

doi:10.3390/ijerph17082846

Cited by 5 publications

(6 citation statements)

References 47 publications

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“…When switching from seated to standing cycling, joint angles drastically change, inducing changes in lower limb joint moments and powers (Caldwell et al 1998 , 1999 ; Tang et al 2020 ; Wilkinson et al 2020 ) and a slower preferred cadence (Harnish et al 2007 ). During seated cycling, a part of the cyclist’s body weight is passively supported by the saddle, whereas during standing, the body weight has to be actively supported by muscles but can also provide positive power during downstroke (Stone and Hull 1995 ), resulting in higher maximal power outputs reached during standing compared to sitting (Millet et al 2002 ; Reiser et al 2002 ).…”

Section: Optimal Slopementioning

confidence: 99%

Everesting: cycling the elevation of the tallest mountain on Earth

2022

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Purpose With few cycling races on the calendar in 2020 due to COVID-19, Everesting became a popular challenge: you select one hill and cycle up and down it until you reach the accumulated elevation of Mt. Everest (8,848 m or 29,029ft). With an almost infinite number of different hills across the world, the question arises what the optimal hill for Everesting would be. Here, we address the biomechanics and energetics of up- and downhill cycling to determine the characteristics of this optimal hill. Methods During uphill cycling, the mechanical power output equals the power necessary to overcome air resistance, rolling resistance, and work against gravity, and for a fast Everesting time, one should maximize this latter term. To determine the optimal section length (i.e., number of repetitions), we applied the critical power concept and assumed that the U-turn associated with an additional repetition comes with a 6 s time penalty. Results To use most mechanical power to overcoming gravity, slopes of at least 12% are most suitable, especially since gross efficiency seems only minimally diminished on steeper slopes. Next, we found 24 repetitions to be optimal, yet this number slightly depends on the assumptions made. Finally, we discuss other factors (fueling, altitude, fatigue) not incorporated in the model but also affecting Everesting performances. Conclusion For a fast Everesting time, our model suggests to select a hill climb which preferably starts at (or close to) sea level, with a slope of 12–20% and length of 2–3 km.

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Section: Optimal Slopementioning

confidence: 99%

Everesting: cycling the elevation of the tallest mountain on Earth

2022

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“…Further, the 95 % LoA between flat and uphill cycling derived power output at CP of + 7.7 to −10.1 % ( + 26 to −32 W) may be too large to consider both conditions as equivalent. Road gradient partially affects biomechanical (e. g. joint moments) [15][16][17][18][19] and physiological (e. g. EMG activity) [15,[20][21][22][23] parameters during cycling exercise, indicating an effect of gradient on muscle recruitment patterns. Recent studies investigated the influence of changes in muscle activity, muscle contraction and/or muscle fibre type recruitment patterns on critical speed or CP estimates and their associated metabolic rate [24,25].…”

Section: Power-duration Relationshipmentioning

confidence: 99%

“…It has been shown that field derived CP estimates may be considered as valid and reliable compared with laboratory esti-mates, whereas the reliability (and hence validity) of field derived W´ estimates is still debated [13,14]. However, previous research has shown that road gradient may partially affect biomechanical and physiological parameters like crank kinetics (e. g. crank inertial load, crank torque profile) [15][16][17], lower limb joint kinetics (e. g. joint moments, joint mechanical work) [18,19], lower limb neuromuscular activation (e. g. intensity and timing of EMG activity) [20][21][22] and gross efficiency [15,23] during cycling in a seated position. Furthermore, it has been shown that a certain metabolic rate (e. g. V ̇O2 and/or blood[lactate] at critical speed or CP) may be achieved by different interplays of muscle activity, muscle contraction and/ or muscle fibre type recruitment patterns, and external workrates [24,25].…”

Section: Introductionmentioning

confidence: 99%

Effects of Flat and Uphill Cycling on the Power-duration Relationship

et al. 2022

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The purpose of this study was to investigate the effects of flat and uphill cycling on critical power and the work available above critical power. Thirteen well-trained endurance athletes performed three prediction trials of 10-, 4- and 1-min in both flat (0.6%) and uphill (9.8%) cycling conditions on two separate days. Critical power and the work available above critical power were estimated using various mathematical models. The best individual fit was used for further statistical analyses. Paired t-tests and Bland-Altman plots with 95% limits of agreement were applied to compare power output and parameter estimates between cycling conditions. Power output during the 10- and 4-min prediction trial and power output at critical power were not significantly affected by test conditions (all at p>0.05), but the limits of agreement between flat and uphill cycling power output and critical power estimates are too large to consider both conditions as equivalent. However, power output during the 1-min prediction trial and the work available above critical power were significantly higher during uphill compared to flat cycling (p<0.05). The results of this investigation indicate that gradient affects cycling time-trial performance, power output at critical power, and the amount of work available above critical power.

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“…The pedaling torque might not fully contribute to the E-bike's wheel torque. As reported in [8][9][10][11][12][13][14], an effective pedaling torque can be different depending on different crank positions.…”

Section: Introductionmentioning

confidence: 99%

“…The sources in [ 1 , 2 , 24 , 38 , 39 ] aim to design suitable torque controllers for assisted E-bikes; however, no further analysis of the influence of the cyclist’s pedaling torque was addressed. By contrast, [ 4 , 5 , 6 , 7 , 8 , 9 , 10 , 11 , 12 , 13 , 14 ] investigate the cyclist’s pedaling dynamic with no motor-assisted torque assumed. Moreover, [ 15 , 16 , 17 , 18 , 19 , 20 , 21 , 22 , 23 , 25 , 26 , 27 , 28 , 29 , 30 , 31 , 32 , 33 , 34 , 35 ] focus on E-bike cycling performance with respect to human behaviors, including heartbeat, gender, and weight.…”

Section: Introductionmentioning

confidence: 99%

Torque Measurement and Control for Electric-Assisted Bike Considering Different External Load Conditions

Lin

et al. 2023

Sensors

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This paper proposes a novel torque measurement and control technique for cycling-assisted electric bikes (E-bikes) considering various external load conditions. For assisted E-bikes, the electromagnetic torque from the permanent magnet (PM) motor can be controlled to reduce the pedaling torque generated by the human rider. However, the overall cycling torque is affected by external loads, including the cyclist’s weight, wind resistance, rolling resistance, and the road slope. With knowledge of these external loads, the motor torque can be adaptively controlled for these riding conditions. In this paper, key E-bike riding parameters are analyzed to find a suitable assisted motor torque. Four different motor torque control methods are proposed to improve the E-bike’s dynamic response with minimal variation in acceleration. It is concluded that the wheel acceleration is important to determine the E-bike’s synergetic torque performance. A comprehensive E-bike simulation environment is developed with MATLAB/Simulink to evaluate these adaptive torque control methods. In this paper, an integrated E-bike sensor hardware system is built to verify the proposed adaptive torque control.

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Do Surface Slope and Posture Influence Lower Extremity Joint Kinetics during Cycling?

Cited by 5 publications

References 47 publications

Everesting: cycling the elevation of the tallest mountain on Earth

Everesting: cycling the elevation of the tallest mountain on Earth

Effects of Flat and Uphill Cycling on the Power-duration Relationship

Torque Measurement and Control for Electric-Assisted Bike Considering Different External Load Conditions

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