Soccer analytics is attracting increasing interest in academia and industry, thanks to the availability of sensing technologies that provide high-fidelity data streams for every match. Unfortunately, these detailed data are owned by specialized companies and hence are rarely publicly available for scientific research. To fill this gap, this paper describes the largest open collection of soccer-logs ever released, containing all the spatio-temporal events (passes, shots, fouls, etc.) that occured during each match for an entire season of seven prominent soccer competitions. Each match event contains information about its position, time, outcome, player and characteristics. The nature of team sports like soccer, halfway between the abstraction of a game and the reality of complex social systems, combined with the unique size and composition of this dataset, provide an ideal ground for tackling a wide range of data science problems, including the measurement and evaluation of performance, both at individual and at collective level, and the determinants of success and failure.
|Technology Type(s)||visual observation method|
|Sample Characteristic - Location||Germany • Kingdom of Spain • French Republic • Italy • England|
Machine-accessible metadata file describing the reported data: https://doi.org/10.6084/m9.figshare.9711164
Background & Summary
Soccer analytics has attracted interest for a long time1,2. In the early 1950s Charles Reep collected statistics by hand to suggest that “the key to scoring goals is to transfer the ball as quickly as possible from back to front”3, thereby indirectly starting the long-ball movement in English football4.
Apart from a few sporadic attempts, it is only in recent years that soccer statistics have developed, thanks to sensing technologies that provide high-fidelity data streams extracted from every match. There are three main data sources available5: (i) soccer-logs describe the events that occur during a match and are collected through proprietary tagging software6,7,8,9; (ii) video-tracking data describe the trajectories of players during a match and are collected through video recordings10,11; (iii) GPS data describe the trajectories of players during training sessions and are collected through GPS devices worn by the players12. Despite this wealth of data, we cannot avoid noticing that soccer datasets are rarely available for scientific research. This limits the development of scientific methods for soccer analytics.
In this paper, we describe an open collection of soccer-logs that cover seven prominent male soccer competitions. The collection has been used recently during the Soccer Data Challenge initiative (https://sobigdata-soccerchallenge.it/) and, to the best of our knowledge, it is the largest collection of soccer-logs ever released to the public. Soccer-logs describe match events, each containing information about its type (pass, shot, foul, tackle, etc.), a time-stamp, the player(s), the position on the field and additional information (e.g., pass accuracy). We believe that these data are greatly beneficial to the scientific community because they can contribute to research in several directions, such as the ones we outline below.
Soccer-logs can be used to design algorithms for relevant problems such as the evaluation of performance and the discovery of tactics1,5. The problem of performance evaluation9,13,14 is crucial for many actors in the sports industry: from broadcasters who want to solicit critical analysis among the fans, to managers who want to monitor the quality of their players and scouts who aim to improve the retrieval of talents. The automatic discovery of tactics6,15 is also becoming a crucial task: while most tactical analyses are currently performed by reviewing video and matches in person, soccer-logs can be used to perform automatic discovery of tactics, simplifying the complex process of match analysis. While different approaches have been proposed in the literature using different datasets to attack these problems, our dataset is much larger and can serve as a common ground to compare and validate different solutions.
Complex systems analysis
Two soccer teams in a match represent a complex system whose global behavior depends in subtle ways on the dynamics of the interactions among the players. Soccer-logs enable the representation of a team as a network, in which nodes represent players and the edges interactions between nodes, usually passes7,14. While the structure of passing networks is proven to be linked to a team’s strength7,14, the potential of a multiplex and dynamic representation of networks in soccer has not been much investigated16. Soccer-logs allow the definition of different types of interactions between both teammates and opponents by relying on the several event types they encode. Such a richness of information, combined with the dichotomous nature of soccer matches (where collaboration and competition coexist), provides an unprecedented opportunity to investigate novel aspects about the dynamics of complex networks.
Science of success
The availability of a large dataset of sports performance also creates the opportunity to explore the relationship between performance and success, where a team’s success can be intended as its outcome in a competition and the player’s as their popularity or market value. While this relationship has been investigated for individual sports17,18, apart from a few attempts19,20 there is not much work for soccer, partly due to the absence of publicly available datasets of performance. Our dataset gives the unprecedented opportunity to answer fascinating questions like: ‘What are the tactical patterns of successful teams?’, ‘What are the factors influencing a player’s popularity and market value?’ and ‘To what extent is success predictable from the observable performance?’
The data described in this paper have been collected and provided by Wyscout, a leading company in the soccer industry which connects soccer professionals worldwide, supports more than 50 soccer associations and more than 1,000 professional clubs around the world. The procedure of data collection is performed by expert video analysts (the operators), who are trained and focused on data collection for soccer, through a proprietary software (the tagger). The tagger has been developed and improved over several years and it is constantly updated to always guarantee better and better performance at the highest standards. Based on the tagger and the videos of soccer games, to guarantee the accuracy of data collection, the tagging of events in a match is performed by three operators, one operator per team and one operator acting as responsible supervisor of the output of the whole match. Optionally for near-live data delivery a team of four operators is used, one of them acting to speed up the collection of complex events which need additional and specific attributes or a quick review.
The tagging of a match consists of three main steps.
Step 1: setting formations
At the beginning of the match, an operator sets the teams’ starting formations, the positions of the players on the pitch and their jersey number. The formation of a team consists of the list of players in the starting lineup and the list of players on the bench.
Step 2: event tagging
For each ball touch in the match, the operator selects one player and creates a new event on the timeline. The operator then adds the type (e.g., pass, duel, shot, etc.) and subtype (e.g., a duel can be aerial or ground) of the event by using a special custom keyboard which gives operators the possibility to insert events and data in a streamlined way (Fig. 1a). The operator finally adds the coordinates on the pitch and all the additional attributes for the event. These can be different depending on the event type: such as pass high/low, foot, dribbling side and so forth (Fig. 1b). When a player shoots on goal, like in the example of Fig. 1b for player n.6 (Koke), the system asks the operator to fill a shot specific module that collects where the shot ends (on goal, out of goal, on post and exact position).
Step 3: quality control
After the tagging, a procedure of quality control for each match is performed, mainly consisting of two different steps. The first step is automatic: an algorithm is used to avoid the majority of the errors made by operators, considerably reducing the margin of error. For example the algorithm matches the events tagged by both operators to crosscheck if they both collected events involving both teams, like duels, with the same positioning and interpretation. Similarly, the algorithm suggests events missed by the operators or searches for impossible combinations of event sequences. The second step of quality control is manual and supervised by quality controllers. It mainly consists of an in-depth check that is carried out once the match is completed. Going through each event of some sample matches, the controller can see and eventually correct any entered parameter. Sample matches for quality control are chosen by another algorithm in order to guarantee a well distributed and statistically meaningful coverage with respect to the kind and amount of analyzed matches.
The data sets are released under the CC BY 4.0 License and are publicly available on figshare21.
The competitions data set describes the seven competitions. Each competition is a document consisting of the following fields21 (see Wyscout documentation for further details at https://apidocs.wyscout.com/):
area: denotes the geographic area associated with the league as a sub-document, using the ISO 3166-1 specification;
format: the format of the competition. All competitions for clubs (Spanish first division, Italian first division, English first division, German first division, French first division) have value “Domestic league”. The competitions for national teams (World cup 2018, European cup 2016) have value “International cup”;
name: the official name of the competition (e.g., Spanish first division, Italian first division, World cup 2018, etc.);
type: the typology of the competition. It is “club” for the competitions for clubs (Spanish first division, Italian first division, English first division, German first division, French first division) and “international” for the competitions for national teams (World cup 2018, European cup 2016);
wyId: the unique identifier of the competition, assigned by Wyscout.
Box 1 shows a document in the competitions data set referring to the Italian first division (“name”: “Italian first division”), a competition for clubs (“type”: “club” and “format”: “Domestic League”) held in Italy (see field “area”).
The matches data set describes all the matches we make available. Each match is a document consisting of the following fields21 (see Wyscout documentation for further details at https://apidocs.wyscout.com/):
competitionId: the identifier of the competition to which the match belongs to. It is a integer and refers to the field “wyId” of the competition document;
date and dateutc: the former specifies date and time when the match starts in explicit format (e.g., May 20, 2018 at 8:45:00 PM GMT + 2), the latter contains the same information but in the compact format YYYY-MM-DD hh:mm:ss;
duration: the duration of the match. It can be “Regular” (matches of regular duration of 90 minutes + stoppage time), “ExtraTime” (matches with supplementary times, as it may happen for matches in continental or international competitions), or “Penalities” (matches which end at penalty kicks, as it may happen for continental or international competitions);
gameweek: the week of the league, starting from the beginning of the league;
label: contains the name of the two clubs and the result of the match (e.g., “Lazio - Internazionale, 2–3”);
roundID: indicates the match-day of the competition to which the match belongs to. During a competition for soccer clubs, each of the participating clubs plays against each of the other clubs twice, once at home and once away. The matches are organized in match-days: all the matches in match-day i are played before the matches in match-day i + 1, even tough some matches may be postponed to facilitate players and clubs participating in Continental or Intercontinental competitions. During a competition for national teams, the “roundID” indicates the stage of the competition (eliminatory round, round of 16, quarter finals, semifinals, final);
seasonId: indicates the season of the match;
status: it can be “Played” (the match has officially started and finished), “Cancelled” (the match has been canceled before it started), “Postponed” (the match has been postponed and no new date and time is available yet) or “Suspended” (the match has been suspended by the referee because of conditions which make it impossible to continue play, such as inclement weather or power failure, and no new date and time is available yet);
venue: the stadium where the match was held (e.g., “Stadio Olimpico”);
winner: the identifier of the team that won the game, or 0 if the match ended with a draw;
wyId: the identifier of the match, assigned by Wyscout;
teamsData: it contains several subfields describing information about each team that is playing that match, such as lineup, bench composition, list of substitutions, coach and scores:
hasFormation: it has value 0 if no formation (lineups and benches) is present, and 1 otherwise;
score: the number of goals scored by the team during the match (not counting penalties);
scoreET: the number of goals scored by the team during the match, including the extra time (not counting penalties);
scoreHT: the number of goals scored by the team during the first half of the match;
scoreP: the total number of goals scored by the team after the penalties;
side: the team side in the match (it can be “home” or “away”);
teamId: the identifier of the team;
coachId: the identifier of the team’s coach;
bench: the list of the team’s players that started the match on the bench and some basic statistics about their performance during the match (goals, own goals, cards);
lineup: the list of the team’s players in the starting lineup and some basic statistics about their performance during the match (goals, own goals, cards);
substitutions: the list of team’s substitutions during the match, describing the players involved and the minute of the substitution.
Box 2 shows a document describing a match between Lazio and Internazionale (“label”: “Lazio - Internazionale, 2–3”) of the Italian first division (“competitionId”: 524), held on May 20th 2018 (see fields “date” and “dateutc”). Box 3 shows the structure of the formation subdocument for one of the teams, which includes the list of players on the bench, the list of players in the starting lineup and the list of substitutions made by the team.
The teams data set describes the clubs or national teams playing in the seven competitions. Each document in this data set consists of the following fields21 (see Wyscout documentation for further details at https://apidocs.wyscout.com/):
city: the city where the team is located. For national teams it is the capital of the country;
name: the common name of the team;
area: information about the geographic area associated with the team;
wyId: the identifier of the team, assigned by Wyscout;
officialName: the official name of the team (e.g., Juventus FC);
type: the type of the team. It is “club” for teams in the competitions for clubs (Spanish first division, Italian first division, English first division, German first division, French first division.) and “national” for the teams in international competitions (World cup 2018, European cup 2016);
Box 4 shows a document describing team Juventus (“name”: “Juventus”) which is located in Turin (“city”: “Torino”) in Italy (see field “area”).
The players data set describes all players in the seven competitions21 (see Wyscout documentation for further details at https://apidocs.wyscout.com/). Each document in this data set consists of the following fields:
birthArea: geographic information about the player’s birth area;
birthDate: the birth date of the player, in the format “YYYY-MM-DD”;
currentNationalTeamId: the identifier of the national team where the players currently plays;
currentTeamId: the identifier of the team the player plays for. The identifier refers to the field “wyId” in a team document;
firstName: the first name of the player;
lastName: the last name of the player;
foot: the preferred foot of the player;
height: the height of the player (in centimeters);
middleName: the middle name (if any) of the player;
passportArea: the geographic area associated with the player’s current passport;
role: the main role of the player. It is a subdocument containing the role’s name and two abbreviations of it;
shortName2: the short name of the player;
weight: the weight of the player (in kilograms);
wyId: the identifier of the player, assigned by Wyscout.
Box 5 shows a document describing player Lionel Andres Messi Cuccittini (“shortName2”: “L. Messi”), who was born in Argentina (see field “birthArea”) and has the Spanish passport (see “passportArea”). From the document we observe that Messi’s preferred foot is the left foot (“foot”: “left”), his height and weight are 170 centimeters (“height”: 170) and 72 kilograms (“weight”: 72) respectively, he preferably plays as a forward (see field “role”) and he was born in 1987 (“birthDate”: “1987-06-24”).
The events data set describes all the events that occur during each match21 (see Wyscout documentation for further details at https://apidocs.wyscout.com/). Each event document contains the following information:
eventId: the identifier of the event’s type. Each eventId is associated with an event name (see next point);
eventName: the name of the event’s type. There are seven types of events (see Table 2): pass, foul, shot, duel, free kick, offside and touch;
subEventId: the identifier of the subevent’s type. Each subEventId is associated with a subevent name (see next point);
subEventName: the name of the subevent’s type. Each event type is associated with a different set of subevent types (see Table 2);
tags: a list of event tags, each describing additional information about the event (e.g., accurate). Each event type is associated with a different set of tags (see Table 2). The Wyscout documentation provides a mapping of the tag identifiers to the corresponding names and descriptions (https://apidocs.wyscout.com/);
eventSec: the time when the event occurs (in seconds since the beginning of the current half of the match);
id: a unique identifier of the event;
matchId: the identifier of the match the event refers to. The identifier refers to the field “wyId” in a match document;
matchPeriod: the period of the match. It can be “1H” (first half of the match), “2H” (second half of the match), “E1” (first extra time), “E2” (second extra time) or “P” (penalties time);
playerId: the identifier of the player who generated the event. The identifier refers to the field “wyId” in a player document;
positions: the origin and destination positions associated with the event. Each position is a pair of coordinates (x, y). The x and y coordinates are always in the range [0, 100] and indicate the percentage of the field from the perspective of the attacking team. In particular, the value of the x coordinate indicates the event’s nearness (in percentage) to the opponent’s goal, while the value of the y coordinates indicates the event’s nearness (in percentage) to the right side of the field;
teamId: the identifier of the player’s team. The identifier refers to the field “wyId” in a team document.
Box 6 shows an example of pass event (“eventId”: 8, “eventName”: “Pass”) generated by player 3344 (“playerId”: 3344) of team 3161 (“teamId”: 3161) in match 2576335 (“matchId”: 2576335) at second 2.41 of the first half of the match (“eventSec”: 2.4175, “matchPeriod”: “1H”). The pass started at position (49, 50) of the field and ended at position (38, 58) of the field (see field “positions”). Moreover, the pass was accurate as indicated by the presence of tag 1801 (field “tags”).
The coaches data set describes all coaches of the clubs and the national teams of the seven competitions we make available21 (see Wyscout documentation for further details at https://apidocs.wyscout.com/). It consists of the following fields:
wyId: the identifier of the coach, assigned by Wyscout.
shortName: the short name of the coach;
firstName: the first name of the coach;
middleName: the middle name (if any) of the coach;
lastName: the last name of the coach;
birthDate: the birth date of the coach, in the format “YYYY-MM-DD”;
birthArea: geographic information about the coach’s birth area;
passportArea: the geographic area associated with the coach’s current passport;
currentTeamId: the identifier of the coach’s team. The identifier refers to the field “wyId” in a team document.
Box 7 shows a document describing coach Maurizio Sarri (“shortName”: “M. Sarri”), who was born in Italy (see field “birthArea”), has the Italian passport (see “passportArea”) and he was born in 1959 (“birthDate”: “1959-01-10”).
The referees data set describes all referees in the national and international competitions we make available21 (see Wyscout documentation for further details at https://apidocs.wyscout.com/). It consists of the following fields:
wyId: the identifier of the referee, assigned by Wyscout.
shortName: the short name of the referee;
firstName: the first name of the referee;
middleName: the middle name (if any) of the referee;
lastName: the last name of the referee;
birthDate: the birth date of the referee, in the format “YYYY-MM-DD”;
birthArea: geographic information about the referee’s birth area;
passportArea: the geographic area associated with the referee’s current passport;
Box 8 shows a document describing referee William Collum (“shortName”: “W. Collum”), who was born in Scotland (see field “birthArea”), has a Scottish passport (see “passportArea”) and was born in 1979 (“birthDate”: “1979-01-18”).
In general, based on the events data set, a soccer match consists of an average of 1,682 ± 101 events (Fig. 2b), with an inter-time between two consecutive events of 3.59 ± 7.42 seconds. There are on average 59 ± 29 events observed for a player in a match, one every 78.78 ± 105.64 seconds, confirming that soccer players are typically in ball possession for less than two minutes22. Passes are the most frequent events, accounting for around 50% of the total events (Fig. 2a). Duels (e.g., tackles and dribbles) are the second most frequent events (≈28%), while shots account for about 1.5% of the total events. The goals scored, the most important events in soccer since they determine a match outcome, are the rarest ones accounting for less than 1% of the total number of events. We provide an example of all the events (1,620) observed for the match “Lazio - Internazionale” of the Italian first division (May 20, 2018), plotted on the position of the field where they have occurred (Fig. 2c).
By looking at the position of the field where the events occur, we can investigate interesting aspects of a soccer match, such as the spatial distribution of players and events. For example the kernel density plot in Fig. 3a shows that passes are distributed mostly in the center of the field, where actually most of the match takes place. As one could expect, we observe differences in the spatial distribution of events when we select the players by their role: while the events of forwards are observed mainly in the opponent’s half of the field (Fig. 3h), the events of defenders are observed mostly in the own half and on the sides of the field (Fig. 3g). Similarly, as expected the spatial distribution of events change with their type: attacking events (e.g., shots) are mostly observed close to the opponent’s goal (Fig. 3b), while defensive events (e.g., clearances) are mostly observed close to the team’s own goal (Fig. 3f). The spatial dimension of match events can provide us with information about a player’s behavior during a match, giving for example the possibility to determine a player’s profile from his average position during a match13.
By looking at when the events occur during a game, we can investigate interesting dynamics of teams and players. For example, Fig. 4 shows that goals are scored more frequently in the second half of the match23,24, mirroring several of the possible factors that could affect scoring, such as a decrease of attention by the defenders towards the end of the match due to a loss of stamina, or a more offensive attitude of the opponents who try to win or equalize the match. Similarly, we observe that the frequency of other rare events like yellow and red cards is the highest in the recovery time. This aspect could highlight the presence of a bias by the referees who are less prone to award a card in the beginning of a match (as suggested in25), a reduction of stamina or an increment of aggression of players at the end of the match.
Another aspect that can be investigated by combining the spatial and the temporal dimensions of soccer-logs are the so-called invasion index, a measure of how close to the opponent’s goal a team plays during a match (i.e., its dangerousness), and acceleration index, a measure of how fast a team reaches the closest position to the opponent’s goal26. By exploiting the spatial and temporal dimension of soccer-logs, the invasion index can be computed on each possession phase, which is defined as a sequence of events on the ball made by a team before the opponents gain the possession. To compute the invasion index of a possession phase we compute: (i) for each event in the possession phase, the probability of scoring from the position where the event occurs (defined as the fraction of goals that have been scored from that position); (ii) we take the highest of these probabilities. A team’s overall invasion index during a match is simply the average invasion index across its possession phases. Figure 5 shows the invasion and acceleration index of the teams throughout the match Roma - Fiorentina (0–2), played on April 7, 2018. We observe that Fiorentina has on average a higher invasion index than Roma (0.27 ± 0.33 and 0.23 ± 0.31, respectively).
A team’s average acceleration index is another measure of its playing efficacy during a match. The acceleration index of a team’s possession phase is computed as the ratio between its invasion index and the square of the time between the first event and most dangerous event of the possession phase. A team’s average acceleration index during a match is the average acceleration index across its possession phases. Similarly to the invasion index, Fiorentina has a higher average acceleration than Roma (Roma: 0.06 ± 0.16, Fiorentina: 0.07 ± 0.15).
Both the invasion and the acceleration indices show that Fiorentina (the winner of the match) was more dangerous during the match, staying closer to the opponent’s goal and reaching dangerous zones faster than Roma.
Soccer-logs enable the analysis of the interactions between players through the reconstruction of a team’s passing network7,14, a representation of the movements of the ball between teammates during a match. A passing network allows identifying the key players in the team, i.e., the ones having more connections to the teammates or a high passing activity27,28. Figure 6 shows two examples of a team passing network for the match Napoli - Juventus (Italian first division). Although Napoli engaged in more passes than Juventus (666 vs. 332), the two passing networks show similar average weighted out-degrees (1.01 ± 0.93% and 1.10 ± 0.84%, respectively). However, Juventus’ playing style resulted in a higher connectivity29, defined as the network’s second smallest eigenvalue (i.e., a root of the characteristic equation of a matrix). This value indicates the robustness of a team, i.e., the strength of the links between its players. As a matter of fact, large values of connectivity between teammates are associated with a better overall team performance.
The reconstruction of passing networks from soccer-logs enables several performance analyses7. For example, by using the passing network and the players’ position during a pass it is possible to identify the most efficient tactical patterns across teams30,31.
Soccer-logs can be used to compare the performance of players and track their evolution in time. As an example, we compare three forwards with different characteristics – L. Messi (FC Barcelona), C. Ronaldo (Juventus FC) and M. Salah (Liverpool). We observe that L. Messi has the highest passing activity: while he produces 49 ± 19 passes per match on average, C. Ronaldo and M. Salah produce 26 ± 6 and 25 ± 9 passes per matches, respectively. Additionally, we observe that L. Messi engages in more duels per match (25 ± 8) than C. Ronaldo and M. Salah (15 ± 5 and 21 ± 7 duels per match). The data we release to the public also enable the computation of several performance metrics, such as Flow Centrality14 and PlayeRank13. A player’s flow centrality in a match is defined as his betweenness centrality in the passing network14. Figure 7a shows the distribution of flow centrality of L. Messi, C. Ronaldo and M. Salah for the matches in season 2017/2018. L. Messi results in a higher flow centrality (0.10 ± 0.01) than C. Ronaldo and M. Salah (0.09 ± 0.01 and 0.09 ± 0.01, respectively).
The performance quality of the players during the season can be assessed using PlayeRank, a data-driven framework that offers a principled multi-dimensional and role-aware evaluation of the soccer players’ performance quality in a match or in a series of matches13. Figure 7b shows that the three aforementioned players have different performance trends during the season. M. Salah obtained his best performance in the first part of the season, then decreasing during the course of the season. In contrast, L. Messi significantly increases his performance quality throughout the season while C. Ronaldo, who was not playing the first part of the season due to an injury, has on average a performance quality slightly higher than Salah but lower than Messi. We can conclude that, according to two measures computed on soccer-logs, Messi performs the best both in terms of passing centrality and performance quality.
The code to reproduce the plots in the paper is available upon request by writing at firstname.lastname@example.org or email@example.com.
Bornn, L., Cervone, L. D. & Fernández, J. Soccer analytics: Unravelling the complexity of “the beautiful game”. Significance 15, 26–29 (2018).
Anderson, C. & Sally, D. The Numbers Game: Why Everything You Know About Football is Wrong. Penguin Books (2013)
Reep, C. & Benjamin, B. Skill and Chance in Association Football. Journal of the Royal Statistical Society 131, 581–585 (1968).
Sykes J. & Paine N. How One Man’s Bad Math Helped Ruin Decades Of English Soccer. Five Thirty Eight (2016)
Gudmundsson, J., Butte, A. J. & Horton, M. Spatio-Temporal Analysis of Team Sports. ACM Computing Surveys 50(2), 22:1-22:34 (2017).
Decroos, T., Van Haaren, J. & Davis, J. Automatic Discovery of Tactics in Spatio-Temporal Soccer Match Data. Proceedings of the 24th ACM SIGKDD International Conference on Knowledge Discovery & Data Mining (KDD ’18), 223–232 (2018).
Cintia, P., Pappalardo, L., Pedreschi, D., Giannotti, F. & Malvaldi, M., The harsh rule of the goals: Data-driven performance indicators for football teams. Proceedings of the 2015 IEEE International Conference on Data Science and Advanced Analytics (DSAA), 1–10 (2015).
Cintia, P., Rinzivillo, S. & Pappalardo, L. Network-based Measures for Predicting the Outcomes of Football Games. Proceedings of the 2nd Workshop on Machine Learning and Data Mining for Sports Analytics (MLSA), 46–54 (2015).
Brooks, J., Kerr, M. & Guttag, J. Developing a Data-Driven Player Ranking in Soccer Using Predictive Model Weights. Proceedings of the 22nd ACM SIGKDD International Conference on Knowledge Discovery and Data Mining (KDD ’16), 49–55 (2016).
Bornn, L. & Fernendez, J. Wide Open Spaces: A statistical technique for measuring space creation in professional soccer. MIT Sloan Sports Analytics Conference 2018 (2018).
Wei, X., Sha, L., Lucey, P., Morgan, S. & Sridharan, S. Large-Scale Analysis of Formations in Soccer. Proceedings of the 2013 International Conference on Digital Image Computing: Techniques and Applications (DICTA), 1–8 (2013).
Rossi, A. et al. Effective injury forecasting in soccer with GPS training data and machine learning. PloS One 13(7), 1–15 (2018).
Pappalardo, L. et al. PlayeRank: data-driven performance evaluation and player ranking in soccer via a machine learning approach. ACM Transactions on Intelligent Systems and Technology (TIST), 10(5), 59:1-59:27 (2018).
Duch, J., Waitzman, J. S. & Amaral, L. A. N. Quantifying the Performance of Individual Players in a Team Activity. PlosOne 5(6), 1–7 (2010)
Bialkowski, A. et al. Large-Scale Analysis of Soccer Matches Using Spatiotemporal Tracking Data. Proceedings of the 2014 IEEE International Conference on Data Mining (ICDM), 725–730 (2014).
Buldú, J. M. et al. Using Network Science to Analyse Football Passing Networks: Dynamics, Space, Time, and the Multilayer Nature of the Game. Frontiers in Psychology 9, 1664–1078 (2018).
Yucesoy, B. & Barabasi, A.-L. Untangling performance from success. EPJ Data Science 5(1), 1–17 (2016).
Cintia, P., Pappalardo, L. & Pedreschi, D. “Engine Matters”: A First Large Scale Data Driven Study on Cyclists’ Performance. Proceedings of the 13th IEEE International Conference on Data Mining Workshops, 147–153 (2013).
Pappalardo, L. & Cintia, P. Quantifying the relation between performance and success in soccer. Advances in Complex Systems 21(3) (2017).
Pappalardo, L., Cintia, P., Pedreschi, D., Giannotti, F. & Barabasi, A.-L. Human Perception of Performance. Preprint at, http://arxiv.org/abs/1712.02224 (2017).
Pappalardo, L. & Massucco, E. Soccer match event dataset. figshare, https://doi.org/10.6084/m9.figshare.c.4415000.v2 (2019).
Link, D. & Hoerning, M. Individual ball possession in soccer. PLoS One 12(7), 1–15 (2017).
Armatas, V., Yiannakos, A., Papadopoulou, S. & Skoufas, D. Evaluation of goals scored in top ranking soccer matches: Greek “Superleague” 2006-07. Serbian Journal of Sports Sciences 3(1), 39–43 (2009).
Alberti, G., Iaia, F. M., Arcelli, E., Cavaggioni, L. & Rampinini, E. Goal scoring patterns in major European soccer leagues. Sport Sciences for Health 9(3), 151–153 (2013).
Unkelbach, C. & Memmert, D. Game Management, Context Effects, and Calibration: The Case of Yellow Cards in Soccer Journal of Sport and Exercise Psychology 1, 95–109 (2008).
Link, D. & Weber, H. Using individual ball possession as a performance indicator in soccer. Workshop on Large-Scale Sports Analytics (2015)
Gama, J. et al. Network analysis and intra-team activity in attacking phases of professional football. International Journal of Performance Analysis in Sport 14(3), 692–708 (2014).
Passos, P. et al. Networks as a novel tool for studying team ball sports as complex social systems. Journal of Science and Medicine in Sport 14(2), 170–176 (2011).
Clemente, F. M., Martins, F. M. L., Kalamares, D., Wong, D. P. & Mendes, R. S. General network analysis of national soccer teams in FIFA World Cup 2014. International Journal of Performance Analysis in Sport 15, 80–96 (2015).
Wang, Q., Zhu, H., Hu, W., Shen, Z. & Yao, Y. Discerning tactical patterns for professional soccer teams: an enhanced topic model with applications. 21th ACM SIGKDD International Conference on Knowledge Discovery and Data Mining (2015).
Rein, R. & Memmert, D. Big data and tactical analysis in elite soccer: future challenges and opportunities for sports science. SpringerPlus 5(1) (2016).
This work has been partially funded by EU project SoBigData RI, grant #654024.
The authors declare no competing interests.
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Pappalardo, L., Cintia, P., Rossi, A. et al. A public data set of spatio-temporal match events in soccer competitions. Sci Data 6, 236 (2019). https://doi.org/10.1038/s41597-019-0247-7
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