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Available online at www.sciencedirect.com ScienceDirect Procedia Engineering 72 ( 2014 ) 150 155 The 2014 conference of the International Sports Engineering Association Impact of electrical assistance on physiological parameters during cycling Daniel Meyer a, Moritz Steffan b, Veit Senner a a Division of Sports Equipment and Materials, Technical University Munich, Boltzmannstr. 15, 85748 Garching, Germany b Institute of Automotive Technology, Technical University Munich, Boltzmannstr. 15, 85748 Garching, Germany Abstract We have analysed the impact of electrical pedalling assistance on the physical strain of bicycle riders by monitoring different physiological parameters during test rides with electric bicycles. Within the frame of our study, we carried out two outdoor experiments. In the first experiment, we compared real and subjectively perceived physical strain during two test rides in mountainous terrain with and without electrical support. The actual physical strain is deduced from the heart rate and lactate, whereas subjectively perceived exertion is estimated using the Borg Scale. In the second experiment we measured the muscle activity of the thighs over crank cycles during rides with different electric bicycles (rear-wheel drive and mid-mounted motor). This resulted in three hypotheses: with higher load the influence of the electrical assistance increases; the positioning of the electrical assistance does not affect the points in time of muscle activity; the positioning of the electrical assistance affects the amount of the muscle activity. Our goal is to get a better understanding of the behaviour of the physical strain during bicycle rides and the influence of electrical assistance on the riders physiology. In addition, we aim to use this knowledge to improve the prediction of the required power support and to enhance the existing support strategies for the assistance. 2014 Published by Elsevier Ltd. Open access under CC BY-NC-ND license. 2014 The Authors. Published by Elsevier Ltd. Selection and peer-review under responsibility of the Centre for Sports Engineering Research, Sheffield Hallam University Selection and peer-review under responsibility of the Centre for Sports Engineering Research, Sheffield Hallam University. Keywords: electric power assisted bicycle; electromyography; physical strain * Corresponding author. Tel.: +49 89 289 10351 E-mail address: meyer@lfe.mw.tum.de 1877-7058 2014 Published by Elsevier Ltd. Open access under CC BY-NC-ND license. Selection and peer-review under responsibility of the Centre for Sports Engineering Research, Sheffield Hallam University doi: 10.1016/j.proeng.2014.06.026

Daniel Meyer et al. / Procedia Engineering 72 ( 2014 ) 150 155 151 1. Introduction Bicycles represent a reasonable and healthy alternative for independent and environmentally friendly travel. However, long distances or hilly terrain require a good physical constitution, which means cycling is only suitable for a few people and applications. Integrating an assisting electrical motor as in electric bicycles (E-bikes) opens up the possibility of healthy and independent mobility for all age groups. Over the past few years the number of E-bikes sold in Europe has risen quickly, exceeding 700000 in 2012 (Oortwijn, 2013). This means that E-bikes are attracting more attention as an alternative to private means of transportation. For example, in mega cities like Shanghai people commonly use bicycles and E-bikes to travel to their workplace (Cherry and Cervero, 2007). In rural tourist regions, high traffic volume accompanied by high pollutant and noise emissions and traffic jams contradicts the tourists wish for tranquillity and relaxation. However, the limited range of electric vehicles represents a challenge (Rose, 2012). The typical range of an E- bike varies between 16 and 80 kilometres (Mütze and Tan, 2007) depending on the driving resistances and the chosen level of assistance. The occurring resistances as well as the riders physical constitution have to be known, to exactly predict the residual range of an electric bicycle. Our work addresses the influence of electrical assistance on the riders physiology in order to better understand and thereby improve the range prediction as well as the assistance strategy of electric bicycles. 2. Methods 2.1. First experiment: Measurement of physiological parameters during long-term rides 2.1.1. Subjects and test arrangement Three male test subjects (Table 1) rode electric bicycles on an outdoor track twice, without and with electrical assistance, respectively; with one day of rest for physical regeneration. All subjects rode without cleats and toeclips and with their preferred seat height. During each ride the heart rate, the subjectively perceived strain and the lactate concentration in the blood were measured. Table 1. Data of the three test subjects of the first experiment Subject Sex Age Weight [kg] Height [cm] Experience 1 m 25 74 181 Recreational rider 2 m 25 71 176 Recreational rider 3 m 27 79 183 Recreational rider Two similar types of mountain bikes were used for the study. Both were equipped with the same mid-mounted motor (Bosch, Germany) (Table 2). One of the bicycles was equipped with 29 inch wheels; the others with 26 inch wheels. The tyre pressure was set to three bar for both runs. The assistance mode was set to sport while the assistance level was set to 3 for the ride with assistance. With these settings 200% of the rider s torque is added to the rider s torque for additional propulsion. The 27km long test track was divided into five zones with different characteristics (Fig 1), after which lactate concentration and subjectively perceived strain were measured during a 15 to 20 minutes break. Table 2. Characteristics of the different motors used in the experiments of this study Motor Max. Power Max. Torque Modes Assistance Levels Max. Velocity with support Mid-mounted 250 W 50 Nm 4 3 25 km/h Rear-wheel 250 W 35 Nm - 3 25 km/h

152 Daniel Meyer et al. / Procedia Engineering 72 ( 2014 ) 150 155 Fig 1. Altitude profile of the test track with zones marked by dashed lines: First zone: short warm-up ride on asphalt; second zone: asphalt track with small ascents; third zone: long ascent on gravel; fourth zone: short ascent on gravel; fifth zone: downhill part on gravel 2.1.2. Data acquisition and analysis For the lactate measurements we took capillary blood from the ear of the subjects. Each subject filled out a questionnaire after each zone to indicate their subjectively perceived exertion on the basis of the Borg Scale (Borg, G. A. V., 1982). Heart rate was measured continuously with a Forerunner 910XT clock and chest belt (both Garmin, USA). For each zone, the mean heart rate of every subject was calculated. 2.2. Second experiment: Measurement of muscle activity 2.2.1. Subjects and test arrangement Three test subjects (Table 3) rode two electric bicycles with two different motor systems (Table 2) to examine the influence of the position of the assistance on the riders muscle activity. We used electromyography (EMG) to measure the muscle activity of four muscles of the thighs: vastus medialis (VM), rectus femoris (RF), gluteus maximus (GM), biceps femoris (BF). In addition, cadence was measured. Table 3. Data of the three test subjects of the second experiment Subject Sex Age Weight [kg] Height [cm] Experience 1 w 19 55 174 Recreational rider 2 m 26 78 190 Recreational rider 3 m 27 80 183 Recreational rider We used a mountain bike with mid-mounted motor (Bosch, Germany) and a trekking bike with rear-wheel motor (TranzX, Taiwan). For the mid-mounted motor, assistance mode was set to Tour and the assistance level to 3. For the rear wheel-motor no modes were available and the assistance level was set to 3. This means that for the mid-mounted motor 140% and for the rear-wheel motor 120% of the rider s torque respectively is added to the rider s torque by the motor. Subjects rode without cleats and toeclips and with preferred seat height. We examined the three following test situations: riding in the plane at a constant speed of 10km/h as well as 20 km/h and riding uphill at a constant speed of 10km/h. The cadence was kept constant at around 70rpm during the measurements. A path 20m long marked by traffic cones indicated the test track in which we carried out the measurements. Subjects started with enough run-up to reach the given velocity and cadence before they reached the measuring zone. They used a switch mounted on the bicycle to indicate the beginning and end of a measurement once they entered or left the measuring zone, so we could calculate the muscle activity for individual crank cycles afterwards.

Daniel Meyer et al. / Procedia Engineering 72 ( 2014 ) 150 155 153 2.2.2. Data acquisition and analysis The skin of the thighs was shaved in the appropriate areas and prepared with an antiseptic spray. Electrodes (Ambu Blue Sensor P, Ambu A/S, Denmark) with an active surface diameter of 13 mm were applied with a distance of 35mm between their centres. The electrode wires were taped to the skin to prevent the electrodes coming loose. The collected data were processed with a Noraxon TeleMyo 2400T G2 system and the MyoResearch XP Master Edition software (Noraxon, USA). The measurements were recorded at 1500Hz. After applying the electrodes, we measured the maximal voluntary contraction (MVC): The subjects had to increase their muscle power to the maximum and hold it for three to five seconds. We carried out three measurements of each muscle and took the highest one as the MVC. The cadence was measured by a potentiometer mounted to the chain stays. The angle of the chain stays was measured by a digital goniometer, to determine the muscle activity at every crank angle. We sampled the EMG activity of two muscles at a time, front thighs and back thighs. After measuring the activity of one muscle pair, we attached the electrode wires to the other muscle pair and the experiments were carried out again. Then the subjects changed the bicycle. After the measurement, the data were full-wave rectified and smoothed (Root Mean Square at 200ms). Then the data were normalized to the MVC. EMG activity for individual crank cycles was identified by using the signal of the crank potentiometer. The individual EMG signals were normalized to a range of 0 to 360 and then the mean of all crank cycles (4 to 8) was calculated. After that the mean of the EMG activity for every muscle and every riding situation of all subjects was determined. 3. Results 3.1. Results of the physiological measurements during long-term rides Fig 2 shows that without electrical assistance the highest real and subjectively perceived strains occur during the uphill parts (zones 3 and 4). With electrical assistance there is no significant change in strain. The mean lactate value rose during the uphill rides, meaning that its production exceeded the steady state of production and decomposition and thus lactate was accumulated during zones 3 and 4. With assistance the mean lactate value remains in the range of the lactate concentration at rest. This indicates higher strain when riding without assistance at high resistance forces. The difference in mean heart rate is also highest in the uphill zones. In contrast to lactate and Borg values, the mean heart rate is highest in the fourth zone, because the third zone also contains parts with smaller gradient and therefore the mean value is smaller. However, the maximum value of the heart rate in zone 3 is similar to that in zone 4. The highest subjectively perceived strain is also reached in zone 3. Significant increments in the physical strain with assistance occur during the downhill part. Lactate, heart rate and subjective strain reach their maximum there. Fig 2. Mean values and standard deviations for real and subjectively perceived strain for every test zone with and without assistance

154 Daniel Meyer et al. / Procedia Engineering 72 ( 2014 ) 150 155 3.2. Results of the muscle activity measurements Fig 3 shows the mean muscle activity of the uphill ride for both bicycles with and without assistance. For brevity and clarity we only show data for the uphill ride, but the results were similar for the other test situations albeit with different maximum values. The top dead centre (TDC) and bottom dead centre (BDC) mark a vertical position of the crank with the pedal in top and bottom position respectively. Fig 3. Muscle activity of vastus medialis, rectus femoris, gluteus maximus and biceps femoris with assistance (dashed line) and without assistance (continuous line) for a bicycle with mid-mounted motor (top row) and a bicycle with rear-wheel motor (bottom row) when riding uphill The muscle activity pattern for both bicycles is similar for VM, RF and BF. However, for GM the activity shows differences for the uphill ride. In the region from the TDC to the BDC the activity for the bicycle with rearwheel motor is higher than for the bicycle with mid-mounted motor. Fig 4. Differences of total muscle activity for the different muscles, bicycles and test situations with standard deviation

Daniel Meyer et al. / Procedia Engineering 72 ( 2014 ) 150 155 155 For the uphill rides the muscle activity was always higher without assistance. For the rides in the plane sometimes the activity was higher with assistance, because the total muscle activity was low due to the low resistances. Figure 4 shows the differences in total muscle activity between test rides with and without assistance. 4. Discussion The aim of this study was to examine physiological parameters while riding electrical-assisted bicycles and to formulate hypotheses about the influence of the assistance on these parameters. The greatest differences in lactate production and heart rate are reached when riding uphill. The muscle activity showed the same characteristics as found in other studies (Ryan and Gregor, 1992; Jorge and Hull, 1986), although differences occurred in the maximal activation of gluteus maximus when riding the bike with rear-wheel motor. Keeping the test conditions equal for all test measurements was challenging, because the experiments were conducted outdoors. After each zone blood was taken from the subjects in random order. Hence the time between the end of a zone and the lactate measurement varied for every subject and zone, which affects the lactate value. Since no performance diagnostics were carried out, the results cannot be used to determine exact physical strain, but are suitable to show that with electrical assistance it is possible to keep the lactate production below the steady state of production and decomposition. Subjectively perceived strain showed great differences for the rides with electrical assistance. The reason for that might be muscle fatigue due to the exhausting trip without assistance. Other parameters also affect the muscle activity pattern (So et al, 2005; Duc et al, 2008), which make more standardized test arrangements necessary. MVC measurements were carried out without warm-up phase and might not be the maximum possible voluntary contraction. However, this should not affect the comparison of the muscle activity. 5. Conclusion As a result of the physiological measurements, we obtained three hypotheses: with higher loads the effect of the electrical assistance on the physical strain increases overproportionately; the positioning of the electrical assistance does not affect the points in time of muscle activity; the positioning of the electrical assistance affects the amount of EMG activity. Based on our findings, we think that the effect of electrical assistance is overproportionately higher for higher loads and that therefore, different assistance strategies for rides in the plane and uphill are required. We also believe that electrical assistance has no influence on the points in time of muscle activation and therefore on the EMG pattern. However, we believe that it affects the amplitude of the EMG activity for different muscles and thus different strategies are necessary to optimize the relationship between muscle activity and power output. In order to be able to identify the right causes for the changes in riders physiology and to statistically corroborate the hypotheses, it is necessary to further standardize the test arrangements. However, our findings give a first idea of the influence of electrical assistance on the riders physiology. References Borg, G. A. V., 1982. Psychophysical bases of perceived exertion. Medicine and Science in Sports and Exercise, Vol. 14, No. 5, 377-381 Cherry, C., Cervero, R., 2007. Use characteristics and mode choice behavior of electric bike users in China. Transport Policy 14, 247-257 Duc, S., Bertucci, W., Pernin, J.N., Grappe, F., 2008. Muscular activity during uphill cycling: Effect of slope, posture, hand grip position and constrained bicycle lateral sways. Journal of Electromyography and Kinesiology 18, 116-127 Jorge, M., Hull, M. L., 1986. Analysis of EMG Measurements During Bicycle Pedalling. Journal of Biomechanics Vol. 19, No. 9, 683-694 Mütze, A., Tan, Y. C., 2007. Electric Bicycles: A performance evaluation. IEEE Industry Applications Magazine Jul/Aug, 12-21 Oortwijn, J., 2013. Europe s E-bike imports indicate market size. http://www.bike-eu.com/sales-trends/market-report/2013/8/europes-e- Bike-Imports-Indicate-Market-Size-1326022W/. Accessed 29.10.2013 Rose, G., 2012. E-bikes and urban transportation: emerging issues and unresolved questions. Transportation 39, 81-96 Ryan, M. M., Gregor, R. J., 1992. EMG Profiles of Lower Extremity Muscles During Cycling at Constant Workload and Cadence. Journal of Electromyography and Kinesiology Vol. 2, No. 2, 69-80 So, R. C. H., Ng, J. K.-F., Ng, G. Y. F., 2005. Muscle recruitment pattern in cycling: a review. Physical Therapy in Sport 6, 89 96