| Review article - (2026)25, 586 - 605 DOI: https://doi.org/10.52082/jssm.2026.586 |
| Beyond Traditional Metrics: A Systematic Review of Spatial and Spatiotemporal Indicators in 5-on-5 Basketball |
Yana Liu, Wenlong Zhang, Mingquan Zhang, Qi Su, Xiao Xu |
| Key words: Basketball, positional data, spatial indicators, spatiotemporal indicators, tactical performance |
| Key Points |
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| Search strategy |
This systematic review was conducted in accordance with the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) 2020 guidelines (Page et al., A comprehensive search was conducted across PubMed/MEDLINE, Scopus, and Web of Science, with Google Scholar used as a supplementary source. The search covered studies published through September 15, 2025. The search strategy was structured around two core concept blocks: basketball and spatial/spatiotemporal data. Search strings were adapted to the indexing structure of each database, with field tags and controlled vocabulary used where appropriate. Full database-specific search strategies are provided in Supplementary |
| Eligibility criteria |
Eligibility criteria were developed using the PICOS framework and refined to identify studies that used court-referenced player and/or ball location data to derive indicators relevant to tactical analysis in standard regulation 5-on-5 basketball. Studies were included only when such location data formed an essential part of the analysis, rather than being reported only descriptively or incidentally (Methley et al., The screening process was conducted independently by two trained reviewers, with EndNote used for reference management. Before formal screening, both reviewers completed a calibration exercise using a random sample of 62 records, corresponding to approximately 10% of the 621 records retained after deduplication. The calibration sample was selected using a computer-generated random sequence. These records were used to harmonize reviewers’ interpretation of the eligibility criteria and were not included in the κ estimate for formal title/abstract screening. During title/abstract screening and full-text assessment, the reviewers made decisions independently and were masked to each other’s decisions until the consensus stage. Inter-rater agreement was high for the calibration exercise, title/abstract screening, and full-text assessment (Cohen’s κ = 0.88, 0.86, and 0.90, respectively). Disagreements were resolved through consensus, with a third reviewer consulted when necessary. The study selection process is presented in the PRISMA flow diagram. |
| Assessment of reporting completeness |
The included studies were appraised for reporting completeness and transparency, rather than methodological quality or risk of bias, because the aim of this review was to examine how spatial and spatiotemporal indicators were defined, operationalized, and interpreted, rather than to synthesize intervention effects or estimate pooled outcomes. Empirical/observational studies were appraised using a STROBE-based framework (Rösch et al., For empirical/observational studies, the STROBE-based appraisal focused on the clarity and completeness of reporting in relation to study setting and competitive context, participant description, definition and measurement of positional variables and spatial or spatiotemporal indicators, outcome specification, and analytical/statistical procedures. For modeling/analytics studies, the adapted checklist focused on reporting clarity in relation to data source and sample definition, specification of spatial or spatiotemporal inputs, model structure and assumptions, definition of model-derived outputs, validation or performance checks, and discussion of practical interpretation and limitations. For each applicable item, studies were classified as adequately reported, partially reported, or not reported according to predefined decision rules. An item was rated as adequately reported when the information was sufficiently clear for readers to understand how the relevant data were obtained and how the indicator, model output, or interpretation was generated. An item was rated as partially reported when some relevant information was provided but one or more key details were missing. An item was rated as not reported when the information was absent or too unclear to support judgment. For example, data source was rated as adequately reported when the dataset, competition level, and sample source were all stated; as partially reported when only some of these elements were provided; and as not reported when the source could not be identified. Similar rating anchors were applied to indicator definition, validation or performance checks, and study limitations. Items considered not applicable to a given study design were coded as non-applicable and excluded from percentage calculations. The reporting appraisals were conducted independently by the same two reviewers who completed the study screening. Disagreements were resolved through discussion, with a third reviewer consulted when necessary. Inter-rater agreement for the appraisal process was high (Cohen’s κ = 0.89). Item-level results were summarized descriptively as counts and percentages, and per-study totals were used only as descriptive summaries of reporting completeness. The appraisal results were used to inform evidence interpretation and contextualize reporting transparency; they were not used to exclude studies, rank study quality, or weight findings quantitatively. |
| Data extraction and study classification |
Data extraction was performed using a standardized extraction template by one reviewer and independently verified by a second reviewer. Disagreements were resolved through discussion, with a third reviewer consulted when necessary. Extracted data included study characteristics, sample information, study design, analytical methods, spatial and spatiotemporal indicators, main findings, and reported limitations. Missing information was recorded as “not reported.” Indicators were extracted with a focus on how court-referenced positional information was translated into representations of tactical performance. This coding framework captured the tactical context of each study, the tactical unit addressed, the use of model-based analytical procedures were used, and the measurement approach adopted. Studies were first classified according to tactical context as offensive or defensive. Studies with an offensive component were then further classified by tactical unit as individual, interactional, or collective. Studies using model-based analytical procedures to derive indicators or represent game dynamics were identified separately. A complementary coding framework was also applied to characterize how indicators were constructed and interpreted. This framework included analytical scale, modeling approach, and measurement approach. Measurement approach was classified as state-based when indicators were derived from discrete events or single time points, sequence-based when they were derived from trajectories or time windows, and mixed when both approaches were used (Gudmundsson and Horton, Inter-rater reliability for coded data-extraction and classification items was assessed using Cohen’s κ (κ = 0.87), indicating strong agreement. Final classifications were determined by consensus after all discrepancies had been resolved. |
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| Search results |
A total of 759 records were identified through database and supplementary searches, including 342 from PubMed, 141 from Scopus, 206 from Web of Science, and 70 supplementary records from Google Scholar, with all searches conducted through September 15, 2025. After 138 duplicates were removed, 621 records remained for title/abstract screening. Of these, 579 were excluded on the basis of the predefined eligibility criteria, mainly because they were not directly relevant to standard regulation 5-on-5 basketball (n = 193), did not include valid court-referenced player and/or ball location data from which game-based spatial or spatiotemporal indicators could be derived (n = 216), or did not meet the inclusion criteria for original empirical research (n = 170). As a result, 42 reports were sought for retrieval. Three reports could not be retrieved and were therefore not assessed for eligibility. The availability and publication status of these reports were checked through database records and publisher or journal websites, and they were recorded as reports not retrieved in the PRISMA flow diagram. Because these reports were not available as retrievable full-text records, they were not included in the eligibility assessment or listed among the full-text exclusion reasons. The remaining 39 reports were assessed for eligibility. Following full-text review, 23 reports were excluded for the following reasons: absence of valid court-referenced player and/or ball location data (n = 6), non-standard 5-on-5 basketball context (n = 3), absence of derived spatial or spatiotemporal indicators (n = 5), lack of relevance to basketball tactical performance analysis (n = 4), non-original or non-peer-reviewed publication type (n = 3), and insufficient methodological detail in the available report (n = 2). Ultimately, 16 studies met the inclusion criteria and were included in the qualitative synthesis and reporting-methodology analysis. The study selection process is presented in |
| Assessment of reporting completeness |
Reporting completeness and transparency were appraised separately for empirical/observational studies and modeling/analytics studies, reflecting the different methodological characteristics of the included research. Item-level results for the STROBE-based appraisal are presented in Among the empirical/observational studies, reporting was generally more complete for basic descriptive study elements. Items related to the title and abstract, background and objectives, definition of key variables, data sources, outcome reporting, and presentation of the main results were most often classified as adequately reported. By contrast, items relating to study design, setting, participant description, and statistical methods were more often classified as partially reported. The least consistently reported items concerned potential sources of bias, study size, limitations, generalizability, and funding. Among the modeling/analytics studies, core elements of the analytical workflow were generally reported more clearly than validation procedures and practical interpretation. Data source and sample description, specification of model inputs, and definition of model-derived outputs were usually classified as adequately reported. In contrast, reporting was less consistent for model assumptions, validation or performance checks, and discussion of practical interpretation and limitations. Overall, the included studies generally reported their core data, indicators, and main findings clearly, but reporting was less consistent for elements related to bias, study size, validation, limitations, and generalizability. The reporting appraisals were used to inform evidence interpretation and contextualize reporting transparency across the included studies; they were not used to exclude studies, rank study quality, or weight findings quantitatively. |
| Classification of included studies |
A total of 16 studies met the inclusion criteria and were retained for synthesis. All included studies examined performance in standard regulation 5-on-5 basketball and used court-referenced player and/or ball location data to derive indicators relevant to tactical performance. The included studies covered four competition levels, as summarized in Studies were first grouped according to tactical context as offensive, defensive, or combined offensive-defensive. Nine studies focused on offensive contexts, two focused on defensive contexts, and five addressed both offensive and defensive contexts, including studies of team interaction. Studies were then classified by tactical unit as individual, interactional, collective, or defensive-only. Three studies focused on individual-level spatial conditions, such as positioning, defender proximity, and shot-related spatial constraints. Four studies examined interactional relations between players, including attacker-defender configurations and coordination within small groups. Seven studies described collective spatial organization, including measures of dispersion, centroid movement, and overall spacing structure. The two defensive-only studies were retained as a separate category and were not further subdivided by offensive tactical unit. Nine studies also used modeling approaches to derive indicators or represent game dynamics. These studies were identified across both offensive and defensive contexts and across different tactical units. Studies were further classified according to measurement approach. Of the 16 included studies, five used a state-based approach, eight used a sequence-based approach, and three used a combined state- and sequence-based approach. State-based approaches were more commonly used in studies focused on discrete events, such as shot attempts or possession outcomes, whereas sequence-based approaches were more often used in studies examining continuous spatial dynamics and coordination over time. Beyond sample source and tactical focus, the included studies also differed in the analytical level at which spatial or spatiotemporal information was operationalized. Some studies used local shot-space indicators, such as shot location, distance to the basket, defender distance, shot angle, and shot-trajectory factors. Other studies focused on interactional or collective indicators, including dyadic coordination, attacker-defender distance, passer-receiver relations, team spatial center, stretch index, court-area occupation, and spatial phase structure. Several studies further used model-derived indicators, such as expected possession value, offensive network parameters, player-density estimates, player gravity, and intrinsic dimension. To integrate the study-level findings, the extracted indicators were organized according to their primary interpretive role. As shown in The classification of each included study according to competition level, tactical context, tactical unit, modeling approach, and measurement approach is presented in |
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Across the included studies, spatial and spatiotemporal indicators were used to extend basketball performance analysis beyond outcome description toward the analysis of game behavior as it unfolds in space and time. Their value lies in revealing the local conditions of actions, the relations between players, and the broader organization of teams during possessions. At the same time, their meaning depends on the analytical level at which they are constructed and the possession context in which they are observed. The following sections discuss how these indicators support interpretation at the individual, interactional, collective, defensive, and model-derived levels, with attention to the conditions under which spatial evidence can be linked to tactical-performance claims. |
| Local indicators and immediate action conditions |
Individual spatial indicators are commonly used to describe the immediate spatial conditions surrounding a player at the moment of action, including nearest-defender distance, location relative to the basket, and available space at the time of a shot or pass (Franks et al., However, this interpretive clarity should not be overstated. Individual spatial indicators describe the spatial state in which an action occurs, but they do not explain how that state was created. A shot taken with substantial space may reflect effective offensive creation through off-ball movement, screening, or ball circulation, but it may also arise from a late defensive rotation or a missed assignment (Sampaio et al., Individual/local indicators remain analytically useful because they stay close to the visible game situation. They can describe where an action occurred, how much local space was available, and how closely it was contested, but they cannot by themselves explain how that situation developed. This limitation becomes clearer when individual spatial indicators are considered alongside traditional outcome-based metrics. Measures such as field-goal percentage or opponent field-goal percentage provide limited information about how an action developed, but their meaning is relatively stable because they summarize the outcome itself (Kubatko et al., When interpreted in isolation, individual spatial indicators can be overinterpreted. Their strength lies in showing the local conditions in which an action occurred rather than explaining the full tactical process that produced them. For applied analysis, this means that an apparently favorable spatial condition should be interpreted alongside the possession sequence, defensive response, and eventual outcome, rather than being taken as sufficient evidence of offensive quality. Individual indicators are most useful for clarifying the immediate spatial problem facing the player at the moment of action. They are less able to explain how that spatial problem developed. Broader interpretation therefore depends on the surrounding sequence and on how the possession unfolded. |
| Interactional indicators in offensive play |
Offensive play rarely emerges from isolated player actions alone. Many tactical advantages in basketball begin to develop through local relations between players, such as those between a passer and receiver, a screener and ball-handler, or an attacker and a nearby defender (Bourbousson et al., However, this closer connection to the offensive process does not, by itself, resolve the problem of interpretation. Local coordination does not carry a fixed tactical meaning, because similar interaction patterns may arise under different offensive conditions. A short passer-receiver distance, for example, may reflect a deliberate compact action designed to create an immediate connection, but it may also occur when offensive options have narrowed and the possession has become spatially compressed under defensive pressure. In both cases, the indicator captures the local relation, but not the reason that relation assumed its observed form (Gudmundsson and Horton, This also helps explain their relationship with traditional outcome-based metrics. Interaction indicators can reveal how an advantage begins to emerge before the final result is recorded, making them more informative about the offensive process than conventional measures such as assist rate or turnover count (Fewell et al., For applied work, interaction indicators are most useful when the analytical question concerns how a local advantage begins to form before the possession outcome is decided. They are particularly helpful for examining how passing options, screening relations, and temporary spatial advantages develop within the flow of play. In this respect, they provide information that conventional outcome measures cannot capture directly. Even so, they do not carry a self-contained tactical meaning. The same local relation may reflect different offensive situations depending on timing, defensive reaction, and the wider sequence in which it occurs. Interaction-level indicators are therefore most informative when treated as relational evidence within a possession rather than as standalone markers of offensive quality. |
| Collective organization indicators in offensive play |
At the collective level, collective organization indicators are used to describe how offensive organization emerges at the team level, rather than through isolated actions or short-range player relations. Measures such as team spread, stretch index, and centroid displacement are useful because they show how a team expands, contracts, and reorganizes over the course of a possession (Bourbousson et al., The main limitation is that, once offensive behavior is summarized at the collective level, the local decisions that generated that structure become less visible. A wide offensive shape, for example, may reflect deliberate spacing and coordinated ball movement, but it may also emerge from defensive disorganization or temporary dispersal late in the possession. What the indicator captures is the resulting spatial arrangement, not the full tactical process through which that arrangement was created (Rein and Memmert, This limitation also explains why collective indicators require careful interpretation when they are used to make claims about tactical performance. Similar collective patterns may serve different offensive purposes under different game conditions. The same team spread, for instance, may be associated with effective half-court spacing in one possession and with disorganized or passive dispersion in another. Similarly, a larger stretch index may reflect purposeful floor spacing, but it may also indicate that players are disconnected from the ball or from the next action. For the same reason, their relationship with traditional outcome-based metrics is more indirect than that observed for individual or interactional indicators. A measure such as points per possession provides a stable summary of the outcome, whereas collective spatial indicators provide richer information about offensive structure but depend more heavily on how the possession phase is defined and which part of the sequence is analyzed (Manisera et al., For applied analysis, collective indicators are most useful when treated as descriptors of team structure rather than as direct evidence of tactical quality. They are most informative when interpreted alongside lower-level indicators and possession outcomes, so that team shape, local interactions, and action results can be interpreted as parts of the same sequence rather than as separate pieces of evidence. Used in this way, collective indicators help place offensive actions within the wider spatial structure of the possession and show how local behavior is embedded in broader team organization. |
| Defensive-impact indicators |
From a spatial perspective, defensive tactics in basketball concern how space is controlled, denied, and redistributed in response to offensive actions. Positional-data studies therefore tend to represent defense not as a sequence of isolated reactions, but as a continuous process of spatial adjustment relative to the ball, offensive players, and key court areas (Bourbousson et al., Defensive analysis becomes more tactically informative when attention shifts from isolated defender-attacker relations to coordination among defenders. Indicators based on inter-defender distance, relative phase, or synchronization provide insight into how defensive units move together, recover, and share responsibilities under offensive pressure (Bourbousson et al., A further level of abstraction appears in collective and model-based approaches. Collective indicators such as defensive centroid displacement, stretch index, and compactness describe how defensive shape expands, contracts, and reorganizes across possessions (Bourbousson et al., Defensive indicators do not all address the same analytical question. Proximity-based measures are most helpful when the analytical focus is immediate contest pressure, coordination metrics are better suited to examining how defenders move together, and collective or model-derived indicators provide information about the broader distribution of defensive control. Treating these measures as interchangeable can obscure the tactical question being asked. In practical analysis, defensive interpretation is usually strongest when these levels are considered together. Local indicators show where pressure was applied, interactional measures show how defenders adjusted collectively, and broader indicators place those actions within the overall defensive structure of the possession. Taken alone, each level provides only partial evidence. |
| Model complexity and interpretive clarity |
As positional datasets have become richer, the models used to analyze them have also become more complex. Recent studies have moved beyond simple spatial descriptors and increasingly use models designed to capture possession dynamics, defensive influence, movement complexity, and temporal changes in offensive value (Barron et al., A related issue concerns analytical scale. Highly detailed models may operate at a level of resolution that exceeds the level at which tactical behavior is typically interpreted or communicated in applied settings (Jiao et al., This point should not be read as an argument for using simpler models by default. Analytical sophistication is often necessary to capture the complexity of competitive team behavior, particularly when the aim is to represent evolving interactions rather than isolated events (Barron et al., The main issue for future work is therefore not whether models should become more complex, but whether that complexity helps answer a recognizable tactical question. Model structure, inputs, temporal scale, and outputs should be chosen with the intended interpretation in mind. This requires researchers to report not only model performance but also the spatial inputs, state definitions, temporal windows, and validation checks that connect model outputs to basketball-specific interpretatio. A model is most useful when it clarifies the game process it is intended to represent rather than simply producing a more sophisticated summary. |
| Limitations and Future Directions |
Several limitations of this review should be acknowledged. The included studies differed in data sources, sampling rates, competition levels, and indicator definitions, which made direct comparisons difficult. Some studies used only shot-location or event-linked data, whereas others used full player-tracking data or model-based outputs. In addition, many studies reported what an indicator was associated with, such as shot outcome, spacing, or possession value, but provided less detail about the exact possession phase or action sequence in which the indicator was observed. Accordingly, the present review focused on how indicators were defined, operationalized, and interpreted rather than on ranking studies or quantitatively synthesizing their findings. Future studies should make the link between spatial indicators and basketball actions more explicit. One useful approach would be to analyze complete possessions rather than isolated moments. For each possession, researchers could first identify the phase of play, such as transition, early offense, half-court offense, or shot creation. The key action type could then be coded, such as a screen, cut, handoff, drive, pass, closeout, switch, or defensive rotation. Spatial indicators could be calculated within the corresponding temporal window, including shooter-defender distance, passer-receiver distance, team width, team center, defensive spacing, and expected possession value. This would show not only the indicator value itself but also the basketball action and possession context in which that value emerged. Future work should also compare these indicators against expert-coded tactical judgments and possession outcomes. For example, an open shot identified by defender distance could be compared with coaches’ judgments of whether the possession reflected successful spacing, a missed defensive rotation, or a late-clock forced shot. Similarly, a large team spread could be compared against expert judgments of whether it reflected effective floor spacing or disconnected offensive movement. These checks would help determine when a spatial indicator supports tactical interpretation and when it merely describes the visible arrangement of players. To support this approach, future studies should report several core methodological details more clearly: the tracking system and sampling rate, how possessions started and ended, how phases of play were defined, how possessions were started and ended, who coded the basketball actions, whether coding reliability was checked, and how model outputs were validated. Clearer reporting of these details would make spatial and spatiotemporal indicators more comparable across studies and more interpretable for coaches, analysts, and researchers. |
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This review examined how spatial and spatiotemporal indicators have been used to analyze tactical performance in standard regulation 5-on-5 basketball. Compared with event counts, shooting percentages, and possession-based outcomes, these indicators provide a more detailed description of where players were located, how they were positioned relative to one another, how teams occupied space, and how spatial conditions changed during possessions. The included studies show that different indicators support different levels of tactical interpretation. Local indicators, such as shot location, defender distance, and distance to the basket, describe the immediate conditions of an action. Interactional indicators capture relations among players, such as dyadic coordination, passer-receiver links, and linked offensive actions. Collective indicators characterize team spacing, court occupation, and changes in team shape. Defensive-impact indicators describe contest pressure, defensive positioning, and defender influence on shot selection or shot success. Model-derived and complexity indicators, such as expected possession value, player gravity, and intrinsic dimension, summarize possession value, player influence, and movement complexity under specific model assumptions. These distinctions are important because similar indicator values or spatial configurations may be produced by different basketball situations. An open shot may result from effective off-ball movement, a late defensive rotation, or a broken play. An expanded team shape may indicate effective spacing, but it may also reflect disconnected offensive movement. Accordingly, spatial and spatiotemporal indicators should not be treated as direct evidence of tactical effectiveness unless the possession phase, action sequence, defensive response, and, where relevant, model assumptions are clearly specified. Future studies should report the tracking data source and sampling rate, how possessions and phases of play were defined, how each indicator was calculated, which basketball actions were coded, how model outputs were validated, and what interpretive boundaries were placed on tactical claims. Clear reporting of these details would make spatial and spatiotemporal indicators more comparable across studies and more useful for linking positional data to basketball-specific performance interpretation. |
| ACKNOWLEDGEMENTS |
The authors would like to thank all researchers whose work was included in this systematic review. No external assistance was received for study design, data extraction, data analysis, or manuscript preparation. This study did not involve any experiments on human participants or animals. As a systematic review of previously published literature, the study was conducted in accordance with internationally accepted standards for research integrity, transparency, and reporting, and complied with all applicable institutional and national regulations. This work was supported by the Liaoning Provincial Doctoral Research Start-up Fund Project [grant number: 2026-BS-0852]. No new data were generated or analyzed in this study. All data supporting the findings of this review are derived from published articles that are publicly available and appropriately cited within the manuscript. The authors declare that they have no conflicts of interest. Artificial intelligence tools were used to assist with language editing and clarity improvement. The authors take full responsibility for the integrity and accuracy of the content. |
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