目的：透過比較有無電力輔助騎乘情境下，了解電動輔助自行車對運動效果之影響，並比較在上坡與平地，有無電力輔助騎乘情境下對運動效果之影響。方法：本研究招募10名健康受試者參與，以隨機的方式進行有助力、無助力與平地、上坡的騎乘，觀察有無助力受試者的騎乘表現、生理反應有無不同，以成對樣本t檢定比較有、無助力之間是否有差，以二因子變異數分析比較不同時間點、有無助力的騎乘模式之間攝氧量是否有差，並以Bonferroni進行事後比較，顯著水準皆訂為α = .05。結果：平路時，平均速度與平均踏頻有、無助力之間並無達顯著差異，平均踩踏功率、平均心率與平均攝氧量無助力皆顯著高於有助力；上坡時，平均速度與平均踏頻有助力皆顯著高於無助力，平均踩踏功率、平均心率與平均攝氧量無助力皆顯著高於有助力。結論：電輔車在開啟動力輔助時能有效提升騎乘效率且降低生理負荷，在不同地形中，皆能達到運動效果，此結果可用於推廣電輔車作為有效的運動和通勤工具，並為設計更符合用戶需求的電輔車提供科學依據。

Objective: To understand the impact of electric bicycles on exercise effectiveness, and to compare the exercise effects on uphill and flat terrain under these conditions. Methods: This study recruited 10 healthy participants to randomly ride in assisted and unassisted modes on flat and uphill terrain. Participants' riding performance and physiological responses were observed under both conditions. Paired samples t-tests were used to compare the differences between assisted and unassisted riding. A two-way repeated ANOVA was conducted to compare the oxygen consumption across different time points and assistance modes. Post hoc comparisons were performed using the Bonferroni method. The significance level was set at α = .05. Results: On flat terrain, there were no significant differences in average speed and average cadence between assisted and unassisted riding. However, average power output, average heart rate, and average oxygen consumption were significantly higher in the unassisted mode compared to the assisted mode. On uphill terrain, average speed and average cadence were significantly higher in the assisted mode compared to the unassisted mode, whereas average power output, average heart rate, and average oxygen consumption were significantly higher in the unassisted mode. Conclusion: Electric bicycles effectively improve riding efficiency and reduce physiological load when power assistance is activated. They can achieve exercise effects on various terrains. These findings support the promotion of electric bicycles as effective exercise and commuting tools and provide scientific evidence for designing electric bicycles that better meet user needs.

國民健康署，(2015)。104 年健康促進統計年報。台北市：衛生福利部。
教育部體育署，(2017)。106 年運動現況調查報告。台北市：教育部。
Alessio, H. M., Reiman, T., Kemper, B., von Carlowitz, W., Bailer, A. J., & Timmerman, K. L. (2021). Metabolic and cardiovascular responses to a simulated commute on an E-bike. Translational Journal of the American College of Sports Medicine, 6(2), e000155.
Avina-Bravo, E. G., Sodre Ferreira de Sousa, F. A., Escriba, C., Acco, P., Giraud, F., Fourniols, J. Y., & Soto-Romero, G. (2023). Design and validity of a smart healthcare and control system for electric bikes. Sensors, 23(8), 4079.
Behrendt, F., Cairns, S., Raffo, D., & Philips, I. (2021). Impact of E-bikes on cycling in hilly areas: Participants’ experience of electrically-assisted cycling in a UK study. Sustainability, 13(16), 8946.
Berntsen, S., Malnes, L., Langåker, A., & Bere, E. (2017). Physical activity when riding an electric assisted bicycle. International Journal of Behavioral Nutrition and Physical Activity, 14, 1-7.
Białkowski, A., Soszyński, P., Stencel, D., & Religioni, U. (2024). Consequences of insufficient physical activity: A comparative analysis of Poland and Europe. Medical Science Monitor: International Medical Journal of Experimental and Clinical Research, 30, e942552-1.
Blondel, B., Mispelon, C., & Ferguson, J. (2011). cycle more often 2 cool down the planet: quantifying co2 savings of cycling. European\Cyclists Federation.
Booth, F. W., Roberts, C. K., & Laye, M. J. (2012). Lack of exercise is a major cause of chronic diseases. Comprehensive Physiology, 2(2), 1143.
Bouillod, A., Pinot, J., Valade, A., Cassirame, J., Soto-Romero, G., & Grappe, F. (2018). Influence of standing position on mechanical and energy costs in uphill cycling. Journal of Biomechanics, 72, 99-105.
Bull, F. C., Al-Ansari, S. S., Biddle, S., Borodulin, K., Buman, M. P., Cardon, G., et al. (2020). World Health Organization 2020 guidelines on physical activity and sedentary behaviour. International Journal of Behavioral Nutrition and Physical Activity, 17(1), 1-12.
Celis-Morales, C. A., Lyall, D. M., Welsh, P., Anderson, J., Steell, L., Guo, Y., Maldonado, R., Mackay, D. F., Pell, J. P., Sattar, N., & Gill, J. M. (2017). Association between active commuting and incident cardiovascular disease, cancer, and mortality: Prospective cohort study. BMJ, 357, j1456.
Cheng, Y. H., Chang, Y. H., & Lu, I. J. (2015). Urban transportation energy and carbon dioxide emission reduction strategies. Applied Energy, 157, 953-973.
Chondrogianni, D., Stephanedes, Y. J., & Fatourou, P. (2023). Assessing cycling accessibility in urban areas through the implementation of a new cycling scheme. Sustainability, 15(19), 14472.
Contò, C., & Bianchi, N. (2022). E-bike motor drive: A review of configurations and capabilities. Energies, 16(1), 160.
Dash, A., & Sheshadri, V. (2023, December). E-Bike controller: modelling and simulation of hysteresis current control based BLDC drive. 2023 International Conference on Next Generation Electronics (NEleX) (pp. 1-6).
de Sa Rosa, T., & Kim, J. Y. (2021). Power assistance algorithm of an E-Trike for older adults based on inverse dynamics. Intelligent Service Robotics, 14(4), 519-534.
Elagizi, A., Kachur, S., Carbone, S., Lavie, C. J., & Blair, S. N. (2020). A review of obesity, physical activity, and cardiovascular disease. Current Obesity Reports, 9, 571-581.
Falconer, C. L., Cooper, A. R., & Flint, E. (2017). Patterns and correlates of active commuting in adults with type 2 diabetes: cross-sectional evidence from UK Biobank. BMJ Open, 7(10), e017132.
Fishman, E., & Cherry, C. (2016). Electrically assisted bicycles in the mainstream: Reviewing a decade of research. Transport Reviews, 36(1), 72-91.
Guthold, R., Stevens, G. A., Riley, L. M., & Bull, F. C. (2018). Worldwide trends in insufficient physical activity from 2001 to 2016: A pooled analysis of 358 population-based surveys with 1.9 million participants. The Lancet Global Health, 6(10), e1077-e1086.
Hoj, T. H., Bramwell, J. J., Lister, C., Grant, E., Crookston, B. T., Hall, C., & West, J. H. (2018). Increasing active transportation through e-bike use: Pilot study comparing the health benefits, attitudes, and beliefs surrounding e-bikes and conventional bikes. JMIR Public Health and Surveillance, 4(4), e10461.
Huang, J., Song, Z., Xie, L., Lin, Z., & Li, L. (2023). Analysis of risky riding behavior characteristics of the related road traffic injuries of electric bicycle riders. International Journal of Environmental Research and Public Health, 20(7), 5352.
Jobson, S. A., Woodside, J., Passfield, L., & Nevill, A. M. (2008). Allometric scaling of uphill cycling performance. International Journal of Sports Medicine, 29(9), 753-757.
Kim, D., Seo, J., Ha, K. H., & Kim, D. J. (2022). Maintaining physical activity is associated with reduced major adverse cardiovascular events in people newly diagnosed with diabetes. Journal of Obesity & Metabolic Syndrome, 31(2), 187.
La Salle, D. T., Shute, R., Heesch, M., & Slivka, D. (2017). Demands of simulated commuting using an electrically assisted bicycle. International Journal of Exercise Science, 10(3), 454.
Laverty, A. A., Mindell, J. S., Webb, E. A., & Millett, C. (2013). Active travel to work and cardiovascular risk factors in the United Kingdom. American Journal of Preventive Medicine, 45(3), 282-288.
Logan, G., Somers, C., Baker, G., Connell, H., Gray, S., Kelly, P., McIntosh, E., Welsh, P., Gray, C. M., & Gill, J. M. R. (2023). Benefits, risks, barriers, and facilitators to cycling: a narrative review. Frontiers in Sports and Active Living, 5, 1168357.
Mahindru, A., Patil, P., & Agrawal, V. (2023). Role of physical activity on mental health and well-being: A review. Cureus, 15(1).
Nystoriak, M. A., & Bhatnagar, A. (2018). Cardiovascular effects and benefits of exercise. Frontiers in Cardiovascular Medicine, 5, 408204.
Rérat, P. (2021). The rise of the e-bike: Towards an extension of the practice of cycling?. Mobilities, 16(3), 423-439.
Sagaama, I., Kchiche, A., Trojet, W., & Kamoun, F. (2020, March). Impact of road gradient on electric vehicle energy consumption in real-world driving. In International Conference on Advanced Information Networking and Applications (pp. 393-404).
Sergeeva, V. A., Lipatova, T. E., Chamkina, K. S., & Khodyushova, A. V. (2022). Assessment of diet, bad habits and psychological status in men and women of the 21st century. Qualitative Clinical Practice, (2), 28-36.
Sundfør, H. B., & Fyhri, A. (2017). A push for public health: The effect of electrically assisted bicycles on physical activity levels. BMC Public Health, 17(1), 1-12.
Tang, Y., Wang, D., Wang, Y., Yin, K., Zhang, C., Zou, L., & Liu, Y. (2020). Do surface slope and posture influence lower extremity joint kinetics during cycling? International Journal of Environmental Research and Public Health, 17(8), 2846.
Wanich, T., Hodgins, J. L., Duchman, K. R., Riley, P. M., & Parsons, B. O. (2007). Biomechanical analysis of knee angles and ground reaction forces during a cycling sprint. The American Journal of Sports Medicine, 35(1), 51-56.
Wanich, T., Hodgkins, C., Columbier, J. A., Muraski, E., & Kennedy, J. G. (2007). Cycling injuries of the lower extremity. Journal of the American Academy of Orthopaedic Surgeons, 15(12), 748-756.
Wild, K., & Woodward, A. (2019). Why are cyclists the happiest commuters? Health, pleasure and the e-bike. Journal of Transport & Health, 14, 100569.
Wolniak, R. (2023). European Union smart mobility–aspects connected with bike road system’s extension and dissemination. Smart Cities, 6(2), 1009-1042.