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Abstract

The main aim of this study was to evaluate the validity and the reliability of a swimming sensor to assess swimming performance and spatial-temporal variables. Six international male open-water swimmers completed a protocol which consisted of two training sets: a 6×100m individual medley and a continuous 800 m set in freestyle. Swimmers were equipped with a wearable sensor, the TritonWear to collect automatically spatial-temporal variables: speed, lap time, stroke count (SC), stroke length (SL), stroke rate (SR), and stroke index (SI). Video recordings were added as a “gold-standard” and used to assess the validity and the reliability of the TritonWear sensor. The results show that the sensor provides accurate results in comparison with video recording measurements. A very high accuracy was observed for lap time with a mean absolute percentage error (MAPE) under 5% for each stroke (2.2, 3.2, 3.4, 4.1% for butterfly, backstroke, breaststroke and freestyle respectively) but high error ranges indicate a dependence on swimming technique. Stroke count accuracy was higher for symmetric strokes than for alternate strokes (MAPE: 0, 2.4, 7.1 & 4.9% for butterfly, breaststroke, backstroke & freestyle respectively). The other variables (SL, SR & SI) derived from the SC and the lap time also show good accuracy in all strokes. The wearable sensor provides an accurate real time feedback of spatial-temporal variables in six international open-water swimmers during classical training sets (at low to moderate intensities), which could be a useful tool for coaches, allowing them to monitor training load with no effort.

Keywords

Innovation load monitoring swimming performance

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References

Craig

Skehan

Pawelczyk

, et al. Velocity, stroke rate and distance per stroke during elite swimming competition. Med Sci Sports Exerc 1985; 17: 625– 634.

Huot-Marchand

Nesi

Sidney

, et al. Variations of stroking parameters associated with 200 m competitive performance improvement in top-standard front crawl swimmers. Sports Biomech 2005; 4: 89–99.

Ichikawa

Ohgi

Miyaji

, et al. Estimation of arm motion in front crawl swimming using accelerometer. Biomechanics and Medicine in Swimming IX 2002; ▪: 133–138.

Dadashi

Crettenand

Millet

, et al. Front-crawl instantaneous velocity estimation using a wearable inertial measurement unit. Sensors (Basel) 2012; 12: 12927–12939.

Chengalur

Brown

PL.

An analysis of male and female Olympic swimmers in the 200-meter events. Can J Appl Physiol 1992; 17: 104– 109.

Seifert

Boulesteix

Carter

, et al. The spatial – temporal and coordinative structures in elite male 100-m front crawl swimmers. Int J Sports Med 2005; 26: 286– 293.

Wakayoshi

D'Acquisto

Cappaert

, et al. Relationship between oxygen uptake, stroke rate and swimming velocity in competitive swimming. Int J Sports Med 1995; 16: 19– 23.

Wakayoshi

Yoshida

Ikuta

, et al. Adaptations to six months of aerobic swim training: changes in velocity, stroke rate, stroke length and blood lactate. Int J Sports Med 1993; 14: 368– 372.

Veiga

Roig

Underwater and surface strategies of 200 m world level swimmers. J Sports Sci 2016; 34: 766–771.

10.

Simbaña-Escobar D, Hellard P, Seifert L. Modelling stroking parameters in competitive sprint swimming: Understanding inter- and intra-lap variability to assess pacing management. Hum Mov Sci 2018; 61: 219–230.

11.

Zamparo

Cortesi

Gatta

The energy cost of swimming and its determinants. Eur J Appl Physiol 2020; 120: 41–66.

12.

Costill

Kovaleski

Porter

, et al. Energy expenditure during front crawl swimming: predicting success in Middle-distance events. Int J Sports Med 1985; 6: 266–270.

13.

Craig

Pendergast

DR.

Relationships of stroke rate, distance per stroke and velocity in competitive swimming. Med Sci Sports Exerc 1979; 11: 278– 283.

14.

Düking

Fuss

Holmberg

, et al. Recommendations for assessment of the reliability, sensitivity, and validity of data provided by wearable sensors designed for monitoring physical activity. JMIR Mhealth Uhealth 2018b; 6: e102. 30

15.

Seifert

Komar

Lepretre

, et al. Swim specialty affects energy cost and motor organization. Int J Sports Med 2010; 31: 624–630.

16.

Düking

Hotho

Holmberg

, et al. Comparison of non-invasive individual monitoring of the training and health of athletes with commercially available wearable technologies. Front Physiol 2016; 9: 71.

17.

Le Sage

Bindel

Conway

, et al. Embedded programming and real-time signal processing of swimming strokes. Sports Eng 2011; 14: 1–14.

18.

Siirtola

Laurinen

Roning

, et al. Efficient accelerometer-based swimming exercise tracking. In: Proceedings of the IEEE symposium on computational intelligence and data mining, (CIDM), 2011.

19.

Zamparo

Bonifazi

Faina

, et al. Energy cost of swimming of elite long-distance swimmers. Eur J Appl Physiol 2005; 94: 697–704.

20.

Ohgi

Ichikawa

Homma

, et al. Stroke phase discrimination in breaststroke swimming using a tri-axial acceleration sensor device. Sports Eng 2003; 6: 113–123.

21.

Mooney

Corley

Godfrey

, et al. Inertial sensor technology for elite swimming performance analysis: a systematic review. Sensors 2016; 16: 1–55.

22.

Ceseracciu

Sawacha

Fantozzi

, et al. Markerless analysis of front crawl swimming. J Biomech 2011; 44: 2236–2242. 11

23.

Benarab

Napoléon

Alfalou

, et al. Optimized swimmer tracking system by a dynamic fusion of correlation and color histogram techniques. Optics Commun 2015; 356: 256–268.

24.

Davey

Anderson

James

DA.

Validation trial of an accelerometer-based sensor platform for swimming. Sports Technol 2008; 1: 202–207.

25.

Dekerle

Nesi

Lefevre

, et al. Stroking parameters in front crawl swimming and maximal lactate steady state speed. Int J Sports Med 2005; 26: 53–58.

26.

Hellard

Dekerle

Avalos

, et al. Kinematic measures and stroke rate variability in elite female 200-m swimmers in the four swimming techniques: Athens 2004 Olympic semi-finalists and French National 2004 Championship semi-finalists. J Sports Sci 2008; 26: 35–46. 1

27.

Mooney

Quinlan

Corley

, et al. Evaluation of the finis Swimsense® and the Garmin swim™ activity monitors for swimming performance and stroke kinematics analysis. PloS One 2017; 12: e0170902.

28.

Seifert

Chollet

Bardy

BG.

Effect of swimming velocity on arm coordination in the front crawl: a dynamic analysis. J Sports Sci 2004; 22: 651–660.

29.

Thomas

Sunehag

Dror

, et al. Wearable sensor activity analysis using semi-Markov models with a grammar. J Pervas Mob Comp 2010; 6: 342–350.

30.

Stamm

James

Thiel

DV.

Velocity profiling using inertial sensors for freestyle swimming. Sports Eng 2013; 16: 1–11.

31.

Fernandes

Vilas-Boas

JP.

Time to exhaustion at the VO2max velocity in swimming: a review. J Hum Kinet 2012; 32: 121–134.

32.

Callaway

Cobb

Jones

A comparison of video and accelerometer based approaches applied to performance monitoring in swimming. Int J Sports Sci Coach 2009; 4: 139–153.

33.

Beanland

Main

Aisbett

, et al. Validation of GPS and accelerometer technology in swimming. J Sci Med Sport 2014; 17: 234–238.

34.

Butterfield

Tallent

Patterson

, et al. The validity of a head-worn inertial sensor for measurements of swimming performance. Movement Sport Sci 2019; in press.

35.

Keskinen

Komi

PV.

Stroking characteristics of front crawl swimming during exercice. J Appl Biomech 1993; 9: 219–226.

36.

Longo

Scurati

Michielon

, et al. Correlation between two propulsion efficiency indices in front crawl swimming. Sport Sci Health 2008; 4: 65–67.

37.

Sperlich

Holmberg

HC.

Wearable, yes, but able…?: it is time for evidence-based marketing claims!.

Br J Sports Med 2017; 51: 1240–1240.

38.

Toussaint

Carol

Kranenborg

, et al. Effect of fatigue on stroking characteristics in an arms-only 100-m front-crawl race. Med Sci Sports Exerc 2006; 38: 1635–1642.

39.

Alberty

Sidney

Pelayo

, et al. Stroking characteristics during time to exhaustion tests. Med Sci Sports Exerc 2009; 41: 637–644.

40.

Düking

Achtzehn

Holmberg

, et al. Integrated framework of load monitoring by a combination of smartphone applications, wearables and point-of-care testing provides feedback that allows individual responsive adjustments to activities of daily living. Sensors (Basel) 2018; 18: 1632.

41.

Mooney

Corley

Godfrey

, et al. Analysis of swimming performance: perceptions and practices of US-based swimming coaches. J Sports Sci 2015; 34(11): 997–1005.

42.

Seifert

Toussaint

Alberty

, et al. Arm coordination, power, and swim efficiency in national and regional front crawl swimmers. Hum Mov Sci 2010; 29: 426–439.

43.

Guignard

Rouard

Chollet

, et al. Behavioral dynamics in swimming: the appropriate use of inertial measurement units. Front Psychol 2017; 8: 1092–1017.

44.

Alberty

Potdevin

Dekerle

, et al. Changes in swimming technique during time to exhaustion at freely chosen and controlled stroke rates. J Sport Sci 2008; 26: 1191–1200.

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Spatial-temporal variables for swimming coaches: A comparison study between video and TritonWear sensor

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