Innovative Use of Wrist-Worn Wearable Devices in the Sports Domain: A Systematic Review
Abstract
:1. Introduction
What proposals for innovative use of wrist-worn wearable devices currently exist addressing the sports field?
2. Materials and Methods
2.1. Search Strategy
2.2. Eligibility Criteria
- Were not explicitly focused on sports issues.
- Used devices that cannot be considered wearable devices.
- Did not use a wrist wearable in a way that was instrumental to complete the research discussed.
- Were only aimed at verifying the reliability or accuracy of a sensor under certain conditions, even if these conditions were related to the sports realm.
- Were focused on proposing some algorithm to improve the accuracy or reliability of the data obtained using some sensor in certain conditions, even in a sports environment.
2.3. Selection Process
3. Results
4. Discussion
4.1. Innovative Uses of Wrist-Worn Wearables
4.2. Sports Introducing Wrist Wearables
- Baseball (four papers, 15.4% of the works reviewed [40,42,52,53]). By using sensors placed on the upper limbs, these works focus on trying to estimate the type of movements that players perform and, from these movements, predict (and consequently try to avoid) injuries due to the explosive nature of the arm movements characteristic of this sport.
- Handcycling (two papers, 7.7% of the works reviewed [36,51]). The practice of handcycling generates different parameters and signals from those collected during walking or running without a wheelchair. These peculiarities are used in the surveyed papers to implement recommendations on how to optimize wheelchair handling during a race, or to facilitate automatic monitoring of daily physical activity and training of wheelchair athletes.
- Australian football (one paper, 3.8% of the works reviewed [59]). The sensor measurements are used to obtain estimates of players’ energy expenses, both during matches and training.
- Weight lifting (one paper, 3.8% of the works reviewed [38]). Wrist sensors facilitates the computation of repetition rates of lift-weighting exercises with different loads, and thus estimate the maximum load borne by an athlete.
- Golf (one paper, 3.8% of the works reviewed [57]). Through the data collected by sensors on the wrists of golfers, players can be advised about their playing characteristics.
4.3. Wrist-Wearable Devices Used
4.4. Data Collection and Processing
4.5. Validation of the Proposals
5. Conclusions
Author Contributions
Funding
Conflicts of Interest
Abbreviations
ANN | Artificial Neural Network |
ANT+ | Adaptive Network Topology |
CCR | Correct classification rate |
GNSS | Global Navigation Satellite System |
GSR | Galvanic Skin Response |
HR | Heart Rate |
HIT | High Intensity Training |
IMU | Inertial measurement unit |
k-NN | k-Nearest Neighbor |
MABR | Motional Analysis Ball Release |
MCU | Micro Controller Unit |
MIMU | Magneto inertial measurement unit |
ML | Machine Learning |
MSA | Monitoring of Sports Activities |
NEAT | Non-Exercise Activity Thermogenesis |
NFC | Near Field Communication |
PCA | Principle Component Analysis |
PRISMA | Preferred Reporting Items for Systematic Reviews and Meta-Analysis |
POA | Peak Outward Acceleration |
RF | Random Forest |
ROC | Receiver Operating Characteristic |
SVM | Support Vector Machine |
VO2 max | Maximal Oxygen Consumption |
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Reference | Innovative Use | Device | Sport | Analysis Techniques | Validation |
---|---|---|---|---|---|
Maijers et al. [36] (2018) | The feasibility of using a commercial wrist wearable was studied to monitor daily physical activity and automatically track training sessions of wheelchair athletes using data not intended for this type of users (e.g., step count). | Fitbit Charge 2, and more specifically, information obtained from the pedometer and the heart rate sensor. | Handcycling | Ad-hoc data processing is not performed. The dashboard graphics provided by Fitbit are directly used. | Tested with 6 participants in the HandbikeBattle race, an annual trial for handcyclists, for periods between 2 weeks and 9 months. The validation of the proposal is informal and descriptive. |
Margarito et al. [37] (2015) | In this study, a user-independent algorithm is proposed to identify sport activities from the accelerometer data extracted from a wrist wearable. The sports considered are: cycling, cross training, rowing, running, squatting, stepping, walking and weight lifting. | Philips DirectLife activity tracker. Data generated by a triaxial accelerometer (±2 g, 20 Hz) is used. | Generic | Template acceleration signals are generated for each supported sport (template generation) and the similarity of the current signal is calculated with the template signals (template matching) to perform classification. | Tests performed with 29 subjects with normal weight and 19 with overweight. A true negative rate (TNR) greater than 90% and added sensitivity (considering all sports) of 74.7% for normal weight and 78.7% for overweight subjects were obtained. |
Balsalobre et al. [38] (2017) | The feasibility and reliability of using a commercial-off-the-shelf wearable to measure the speed of the barbell in several resistance training exercises was researched, namely full-squat, bench-press and hip-thrust. | Beast Sensor, a commercial wearable specific for weight training with accelerometer, gyroscope and compass. | Powerlifting (full-squat, bench-press, hip-thrust) | The Beast Sensor data collection app provided speed, so ad hoc processing is not performed to obtain this variable. | 10 powerlifters performed 6 sets of incremental exercises. Barbell velocity was simultaneously measured using a linear transducer (gold standard), two Beast Sensors (on the subjects’ wrist and on the barbell) and the iOS PowerLift app. High reliability is obtained, although with some bias in the average. |
Spratford et al. [39] (2015) | An ac-hoc wearable placed on the wrist was used to measure the peak outward acceleration (POA) of a ball at the end point of a bowling action in cricket. This variable is a key element when assessing the illegality of bowling. | Ad-hoc wearable with 2 accelerometers and a gyroscope. Only one ADXL190 accelerometer (±100 g, 200 Hz) was used. | Cricket | Data collected to compute POA are compared with those collected using a validated motional analysis ball release (MABR) protocol (based on high-speed video capture). The correlation between both data is analyzed. | 148 deliveries were monitored from 21 professional bowlers. A high correlation between the computed POA from the wearable data is verified with the measurement obtained by MABR, regardless of the delivery type and elbow anthropometry. |
Camp et al. [40] (2017) | Data from a wearable was used to support the modelling of the relationship between elbow varus torque and arm slot and arm rotation in baseball pitchers. The goal is to identify modifiable factors that may potentially reduce the stress experienced by the elbow. | motusBASEBALL, commercial compression sleeve equipped with an IMU. | Baseball | Linear mixed-effects models and likelihood ratio tests were used to estimate the within-subject relationship between elbow varus torque and arm slot, arm speed and arm rotation. | 81 professional pitchers performed 82,000 throws while wearing a motusBASEBALL. |
Stiles V.H. [41] (2018) | Study aimed at demonstrating the validity of several open-source metrics obtained from the analysis of data from wrist-worn accelerometers in runners, with the objective of discriminating between running/nonrunning training days and quantify training load on training days. | GENEActiv accelerometer, a commercial research-oriented smartband (±8 g, 100 Hz). | Running | Receiver operating characteristic (ROC) analysis was applied to accelerometer metrics to discriminate between running and nonrunning days. Variance explained in training log criterion metrics was examined using linear regression with leave-one-out cross-validation. | Accelerometer data obtained from 35 experienced runners over 9 to 18 weeks were date-matched with self-reported training log data. A total of 1494 accelerometer days with at least 10 hours of wear per day were analyzed. |
Rawashdeh et al. [42] (2016) | This work describes a proposal to detect movements and activities that are likely to cause shoulder injuries. It focuses on the types of specific movements that, during sport practice, make intensive use of the shoulder. | Ad-hoc wearable with a 3-axis accelerometer (ADXL345), 3-axis gyroscope (ITG-3200 MEMS) and 3-axis magnetometer (HMC5883L) | Baseball/ volleybal | Preprocessing based on the AHRS algorithm is applied. Descriptive statistics are used on the captured data, signal processing (FFT) to detect that the upper limb was elevated, and a Decision Tree Classifier to measure the overuse of the arm. | Tests carried out with 11 subjects who performed 7 shoulder movement exercises and 2 sports activities: baseball throw (99 valid repetitions) and volleyball serve (103 valid repetitions). |
Wang et al. [43] (2018) | The innovative use of this research is to detect the level of a volleyball player. 3 levels of play are considered, namely amateur, sub-elite and elite. Detection is done using players’ spikes. | Ad-hoc wearable using an MPU9250 unit. 3-axis acelerometer (±16 g) and 3-axis gyroscope. | Volleyball | SVM, SVM + PCA, k-NN and Naive Bayes machine learning (ML) techniques are used to develop the classifier. Supervised training is performed using images taken with a high speed camera. Manual processing of these images. | The tests carried out with 10 right-handed men (3 amateurs, 3 sub-elite and 4 elite). 120 spiking trials were performed. Average accuracy of 94%. |
Margarito et al. [37] (2015) | This research develops a system to monitor lactic acid secretion on the surface of the skin. The innovation is to make a sensor that can monitor lactic acid secretions while exercising. | Ad-hoc sensor. The system combines a biosensor using LOD and osmium wired HRP (Os-HRP) reaction system with a microflow-cell. | Generic | The measurement of the changes in the sensor is performed with an ammeter. During exercise, heart rate is also monitored (9722B-FS from Adidas). The relationship between intensity, segregated lactic acid, potential applied to the sensor, exercise intensity and heart rate is represented by graphs. | Tested with 1 user who was subjected to exercise of variable intensity using an exercise bike. A correlation between the sensor measurements and the intensity of the exercise was confirmed. |
Kölling et al. [44] (2016) | This study carries out an innovative analysis of the effect that high-intensity training (HIT) sports practice has on sleep parameters. Sleep quality is measured objectively using a wearable, and subjectively by means of standardized questionnaires. | Commercial SenseWear ArmbandTM wearable. This device has a 2-axis acelerometer, skin temperature sensor, galvanic skin response sensor, and heat flux sensor. | Generic (HIT training) | Statistical analysis is carried out using descriptive statistics and ANOVA on quality-of-sleep data provided by the wearable. "Subjective sleep rating" and "Recovery-Stress Questionnaire for Athletes" questionnaires are used for subjective assessment. | The sleep of 42 athletes was monitored. These were classified into 2 groups of 21 subjects. One of the groups performed high-intensity training for 14 days and the other served as a control group. |
Burns et al. [45] (2019) | This work uses wrist-worn wearables to monitor step frecuency (SF) and SF variability of participants in the 2016 100-km World Championship. SF variations are studied with respect to speed, distance run, height, age, weight or previous experience. | Commercial wearables suitable for running practice (Garmin, Suunto and Polar). Accelerometer data is used to detect steps. | Running | A descriptive statistics analysis is performed to compare different parameters with SF data. Comparative graphs are provided and linear regression tests are computed in some cases. | The data captured by the 20 best participants who monitored themselves using their own wrist bands were used. |
Salman et al. [46] (2017) | The innovative application discussed in this work consists of to detect when a bowling action in cricket is legal or not by using data from inertial sensors in a wrist-worn wearable. | Ad-hoc wearable with a 3-axis accelerometer and a 3-axis gyroscope. | Cricket | The classifier is developed using different ML techniques: SVM, k-NN, Naïve Bayes, RF and ANN. Supervised training is performed using the opinion of cricket experts as a reference. | Tested with 14 male players between 15 and 30 years old. Series of legal and illegal bowls were made. |
Kos and Kramberger [47] (2017) | This work successfully explores the possibility of using ad hoc wearables to detect the impact of the racket against the ball and estimate the type of shot made. This information is the result of processing raw data from the sensors. | Ad-hoc weareable device including a 3D gyro, 3D accelerometer (±16 g), a heart rate sensor, and temperature sensor. | Tennis | The shot is identified by means of a two-point derivative of the acceleration curves. The identification of the type of stroke is based on the rotation accelerations in a temporal window around the hit moment. | 446 strokes from 7 different tennis players. |
Mangiarotti et al. [48] (2019) | Using custom made devices, authors attempt to get a real-time system to identify game actions in basketball (pass, shot and dribbling) by analysing data related to accelerations. | Ad-hoc wearable device with a MIMU sensor and a Bluetooth module. | Basketball | Implementation of k-NN and SVM in MATLAB for the detection of target game actions. | Not specified. |
Wells et al. [49] (2019) | MIMU sensors are applied to cricket actions in an attempt to measure and monitor these actions without the support of motion capture systems. | Commercial wearable Xsens MTv Awinda MIMU sensors. | Cricket | Measurements from the proposed model are just compared with the gold standard. | Nine injury-free participants attending a single test session each. |
Whiteside et al. [50] (2017) | The authors explore how data obtained with wrist-wearable sensors can be used to automatically classify shot types in tennis by means of different ML algorithms. | Commercial wearable from IMeasureU involving a 500 Hz 9-axis IMU. | Tennis | A custom MATLAB script was developed to process accelerometer and gyroscope data. Information obtained and annotated was used to train and test 6 types of learning classifiers (support vector machine (SVM), discriminant analysis, random forest (RF), k-nearest neighbor (k-NN), classification tree, and artificial neural networks (ANN)). | 66 training sessions involving 19 athletes. |
Bergamini et al. [51] (2015) | Information obtained from regular wrist-wearable devices on handcycling athletes is used to evaluate the effectiveness of specific training routines in wheelchair with bio-mechanical propulsion. The devices involved are intended to be used for walking or running. | Commercial wearable from Opal (APDM Inc.) involving IMUs. | Handcycling | Descriptive statistical analysis using SPSS. | Twelve junior wheelchair basketball players distributed into 2 groups (control and experimentation) carried out three experimental sessions where measurements were completed. |
Makhni et al. [52] ([2018) | Information from sensing devices (accelerations and changes in orientation) worn by baseball pitchers is used to try to identify the type of launch made. | Commercial device including a gyroscopic sensor with an accelerometer from Motus Global. | Baseball | Classification system based on general linear models implemented using R. | 37 players took part in the experiment, completing 24 pitches each. |
Okoroha et al. [53] (2018) | Off-the-shelf devices are used to assess valid predictors of torque across the medial elbow for baseball pithcers’ injuries. | Commercial device including a gyroscopic sensor with an accelerometer from Motus Global. | Baseball | Basic descriptive statistics. Tukey-Kramer fit and Mixed Models—Repeated Measures were applied. | 20 young baseball pitchers were instructed to throw 8 fastballs, 8 curveballs, and 8 changeups in a standardized but randomized sequence over a 25-min period. |
Ma et al. [54] (2018) | A full custom wearable is applied to implement a system capable of identifying 9 characteristic basketball movements using just acceleration and rotational speed without the support of further sensing devices. | Ad-hoc device with a MIMU sensor. | Basketball | ANN implemented in MATLAB. | Not specified. |
Bai et al. [55] (2016) | Commercial smartbands are used to deploy a system for the automatic identification of shooting actions from basketball players. This feature requires an advanced data processing and goes beyond the capabilities provided by the manufacturer of the bands used. | Microsoft Band. | Basketball | Basic statistical values are generated from the downloaded data, followed by a two-stage processing: first, a RF is applied and then a collaborative classifier. | 2 one-to-one basketball games (20 min of playing time in total). |
Parak et al. [56] (2017) | This research proposes an innovative approach to estimate heart rate, energy expenditure and maximal oxygen outtake (VO2 max) while running using an optical heart rate sensor from a basic commercial wearable. | Commercial wearables suitable for running practice. PulseOn to measure heart rate, and a Samsung Galaxy S3 smartphone for geolocation. | Running | An analysis with descriptive statistics is performed, and basic parameters are computed (e.g., mean and standard deviation), as well as some comparative analysis tests (e.g., Wilcoxon test, paired t-test, etc.). A chest band and respiratory analysis used as gold standard. | Tested with a sample of 24 healthy adults running outdoors and on a treadmill. |
Kim et al. [57] (2017) | An ad hoc developed wearable is used to analyze the golf swing, performed with both hands, right and left. Its objective is to improve golfing technique and serve as a training tool for golfers. | Ad-hoc designed wearable, consisting of a silicone wristband, battery and MCU speed sensor. It is used a tri-axial accelerometer sensor (250 Hz). | Golf | Performs a mathematical analysis consisting of transforming the data collected from the sensor into quaternions, and modeling the swing movement through position, direction and speed of these quaternions. | A 3D model of the movement performed is generated to be compared with an average swing. Initial study. No data provided from a validation pilot. |
Hsu et al. [58] (2018) | Study focused on the recognition of sports and daily life activities. A wearable based on an inertial sensor network, and a recognition algorithm are used. | Ad-hoc wearable based on an inertial sensor network, composed by a microcontroller (Arduino Pro Mini, 16MHz) and a six-axis inertial sensor (MPU-6050, 100 Hz). | Generic | First, it captures and processes the microcontroller data for calibration, signal filtering and normalization. Then, it uses a ML algorithm based on SVM to classify the activities monitored with the sensor. | Validated with a sample of 13 people. Data about the correct classification rate (CCR) of activity classification is provided. |
Walker et al. [59] (2016) | A system is designed to estimate energy expenditure (EE) of professional Australian football players during training and competition. It aims to improve the physical performance of players. | Commercial wearables are used: SenseWear Armband (Model MF-SW) to estimate energy expenditure; and MiniMax4.0 (Scoresby Australia), to monitor oxygen consumption. | Australian football | A descriptive statistical analysis is performed to compute basic parameters (e.g., mean and standard deviation), as well as Pearson’s correlation analysis and error estimation. | Tested with a total of 18 professional Australian football players, during training, competition, and non-exercise activity thermogenesis (NEAT) sessions. |
Soltani et al. [60] (2019) | Study aimed at accurately estimate gait speed during outdoor exercise (walking and running) using a low-consumption wrist wearable device. | Commercial wearables suited for running practice: wirst-worn inertial sensors (Physilog® IV, GaitUp, CH), and a head-worn Global Navigation Satellite System (GNSS) device as a location reference. | Running | A descriptive statistical analysis is performed to compute basic parameters (e.g., mean and standard deviation), as well as a Kruskal–Wallis test and a Spearman correlation for comparative analysis. ML algorithms are also applied to predict wrist movement-related parameters (e.g., energy, periodicity, posture, etc.). | Tested with a total of 30 volunteers who run and walked during 90 min outdoors. |
Aim | # Studies | References | |
---|---|---|---|
Monitoring of sports activities | Sportsperson’s physiological or biological variables | 5 | [47,56,59,60,61] |
Sportsperson’s behaviour | 2 | [41,45] | |
Other elements beyond sportsperson | 2 | [38,39] | |
Training tracking | 1 | [36] | |
Identification and classification of sports activities | Several sports | 3 | [37,52,58] |
Single sport | 8 | [41,46,47,48,49,50,54,55] | |
Performance improvement | Impact evaluation of training for the sportsperson | 2 | [44,51] |
Identification of technical improvement | 3 | [43,57,59] | |
Injury prevention | 3 | [40,42,53] |
# Studies | References | ||
---|---|---|---|
Data collection | Bluetooth | 14 | [38,40,46,48,49,50,51,52,53,54,55,57,58,59] |
USB | 2 | [47,61] | |
microSD | 3 | [39,42,43] | |
NA/Other | 7 | [36,37,41,44,45,56,60] |
# | References | |||
---|---|---|---|---|
Data analysis | Statistical/mathematical analysis | Basic statistics (e.g., mean, SD) | 13 | [38,39,40,41,42,44,45,51,53,55,56,59,60] |
Variance studies (e.g., ANOVA, ) | 4 | [39,44,51,60] | ||
Correlation studies (e.g., Pearson, Spearman, etc.) | 5 | [37,38,56,59,60] | ||
Other tests (e.g., t-Test, Tukey-Kramer, Wilcoxon test, Kruskal–Wallis test, etc.) | 4 | [38,53,56,60] | ||
Signal process (e.g., Fast Fourier Transform, Time Series Signals, “quaternions”, etc.) | 4 | [37,42,47,57] | ||
Other | 4 | [45,49,52,61] | ||
Machine learning analysis | Linear regression | 1 | [41] | |
SVM | 5 | [43,46,48,50,58] | ||
RF | 3 | [46,50,55] | ||
ANN | 3 | [46,50,54] | ||
k-NN | 4 | [43,46,48,50] | ||
Naive Bayes | 2 | [43,46] | ||
SW to perform analysis | MATLAB | 4 | [39,48,50,54] | |
R | 1 | [52] | ||
SPSS | 2 | [44,51] | ||
N/A | 17 | [37,38,40,41,42,43,45,46,47,49,53,56,57,58,59,60,61] | ||
NO data analysis (i.e., using data from sensor) | 1 | [36] |
Ref. | Pilot Study | Validation and Fiability 3 | ||
---|---|---|---|---|
Sample | Tasks | |||
baseball | [42] | N = 11 | Warm-up exercises; Baseball Throw; Volleyball Serve | - |
[40] | N = 81 (healthy pitchers) | Warm-up exercises; 10 fastballs | Yes | |
[52] | N = 37 | Fastballs | - | |
[53] | N = 20 (young pitchers) | Pitching Motion: Fastball, Curveball, and Change-up | - | |
running | [41] | N = 35 (experienced runners) | Running and “other training” (e.g., gym, swimming, cycling, circuits or yoga) | Yes |
[45] | N = 20 (Best runners) | run | - | |
[56] | N = 24 (health and adults) | Running treadmill and outdoor | - | |
[60] | N = 30 (volunteers) | Walking and running 90’ | - | |
generic | [61] | N = 1 | Static cycling | Yes |
[37] | N = 48 (29 normal weight; 19 overweight) | Cycling, cross training, rowing, running, squatting, stepping, walking, and weight lifting | Yes | |
[58] | N = 13 (healthy participants) | Human daily live’s and sports activities | Yes | |
[44] | N = 42 (athletes) | High intensity training (HIT) | Yes | |
basketball | [48] | N = 2 | - | - |
[54] | - | - | - | |
[55] | N = 2 | One-to-one basketball games | Yes | |
cricket | [49] | N = 9 | 5 measures/participant | - |
[39] | N = 21 (12 spin bowlers; 9 fast bowlers) | 148 deliveries | - | |
[46] | N = 14 | Legal and un-legal bowls | Yes | |
hc 1 | [51] | N = 12 | - | - |
[36] | N = 6 (spinal cord injury) | Handcycling | - | |
tenis | [47] | N = 7 | 400 racket blows | - |
[50] | N = 30 | - | - | |
volleyball | [43] | N = 10 (Right-handed) | 120 spiking trials | Yes |
Af 2 | [59] | N = 18 (professional players) | Training, competition, and non-exercise activity thermogenesis (NEAT) | Yes |
golf | [57] | Experimental | - | - |
powerlifting | [38] | N = 10 | Powerlifting (6 types) | Yes |
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Santos-Gago, J.M.; Ramos-Merino, M.; Vallarades-Rodriguez, S.; Álvarez-Sabucedo, L.M.; Fernández-Iglesias, M.J.; García-Soidán, J.L. Innovative Use of Wrist-Worn Wearable Devices in the Sports Domain: A Systematic Review. Electronics 2019, 8, 1257. https://doi.org/10.3390/electronics8111257
Santos-Gago JM, Ramos-Merino M, Vallarades-Rodriguez S, Álvarez-Sabucedo LM, Fernández-Iglesias MJ, García-Soidán JL. Innovative Use of Wrist-Worn Wearable Devices in the Sports Domain: A Systematic Review. Electronics. 2019; 8(11):1257. https://doi.org/10.3390/electronics8111257
Chicago/Turabian StyleSantos-Gago, Juan M., Mateo Ramos-Merino, Sonia Vallarades-Rodriguez, Luis M. Álvarez-Sabucedo, Manuel J. Fernández-Iglesias, and Jose L. García-Soidán. 2019. "Innovative Use of Wrist-Worn Wearable Devices in the Sports Domain: A Systematic Review" Electronics 8, no. 11: 1257. https://doi.org/10.3390/electronics8111257
APA StyleSantos-Gago, J. M., Ramos-Merino, M., Vallarades-Rodriguez, S., Álvarez-Sabucedo, L. M., Fernández-Iglesias, M. J., & García-Soidán, J. L. (2019). Innovative Use of Wrist-Worn Wearable Devices in the Sports Domain: A Systematic Review. Electronics, 8(11), 1257. https://doi.org/10.3390/electronics8111257