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Article

Statistical Modeling of Football Players’ Transfer Fees Worldwide

Centre International d’Étude du Sport, University of Neuchatel, 2000 Neuchatel, Switzerland
*
Author to whom correspondence should be addressed.
Int. J. Financial Stud. 2024, 12(3), 93; https://doi.org/10.3390/ijfs12030093
Submission received: 6 August 2024 / Revised: 12 September 2024 / Accepted: 17 September 2024 / Published: 19 September 2024
(This article belongs to the Special Issue Sports Finance (2nd Edition))

Abstract

:
Professional football clubs invest vast amounts of money in the recruitment of players. This article presents the latest advances in statistical modeling of the factors that market actors take into consideration to determine the transfer prices of professional football players. It extends to a global scale the econometric approach previously developed by the authors to evaluate the transfer prices of players under contract with clubs from the five major European leagues. The statistical technique used to build the model is multiple linear regression (MLR), with fees paid by clubs as an independent variable. The sample comprises over 8000 transactions of players transferred for money from clubs worldwide during the period stretching from July 2014 to March 2024. This paper shows that a statistical model can explain up to 85% of the differences in the transfer fees paid for players. Despite the specific cases and other possible distortions mentioned in the discussion, the use of a statistical model to determine player transfer prices is thus highly relevant on a global scale.

1. Introduction

This article presents the latest advances in statistical modeling of the factors that market actors take into consideration to determine the transfer prices of professional football players. It extends to a global scale the econometric approach previously developed by the authors to evaluate the transfer prices of players under contract with clubs from the five major European leagues (Poli et al. 2022).
The new linear regression model implemented to account for the transfer values of professional football players is now based on 8389 transactions compared with 2045 in the aforementioned article. The modification of certain variables and the inclusion of additional ones enabled us to maintain an explanatory power equivalent to that previously achieved for far fewer observations, with a coefficient of determination of almost 85%.
This result confirms that price formation on the transfer market is more rational and statistically modellable than it is often thought by public opinion. Beyond the rumors spread by the media (Fürész and Rappai 2020; Herrero-Gutiérrez and Urchaga-Litago 2021; Runsewe et al. 2024) and players’ agents (Kelly and Chatziefstathiou 2017), our analysis confirms that it is possible to objectively identify the main factors involved in the transfer fee determination process.
While the weight of the various price determinants may vary from transaction to transaction, and non-modellable or quantifiable criteria may also play a role (Poli et al. 2022), as will be further developed in the discussion, the rationales followed by transfer market actors are largely translatable into a statistical approach.
The pioneering publications on football players’ transfer values date back to the 1990s (Carmichael and Thomas 1993; Carmichael et al. 1999; Dobson and Gerrard 1999; Dobson et al. 2000). Many authors have since consolidated the existing literature, both before (notably Coates and Parshakov 2021; Garcia del Barrio and Pujol 2021; Majewski 2016; Müller et al. 2017; Ruijg and van Ophem 2015; Serna Rodríguez et al. 2018) and after (notably Campa 2022; McHale and Holmes 2022; Franceschi et al. 2023a; Franceschi et al. 2023b) our own previous publication (Poli et al. 2022).
In their remarkable synthesis of 29 peer-reviewed articles presenting empirical models to determine soccer players’ transfer values, Franceschi et al. (2023a) distinguish between six categories of variables, the first five of which are also included in our approach:
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Clubs’ characteristics (both releasing and engaging);
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Time (season or year of the transfer, etc.);
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Labor (contract length, previous fees, etc.);
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Performance (goals, minutes, etc.);
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Player’s characteristics (age, position, etc.);
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Popularity (press, social media, etc.).
While the variables used in our approach are not fundamentally different from those found elsewhere, our empirical model stands out in at least four respects: the historical depth of the observations (ten years), their geographical breadth (64 releasing or engaging countries), the number of observations (>8000 transfers) and, last but not least, the unrivaled explanatory power resulting both from the care with which the data were collected (Poli et al. 2022) and the optimized design and association of the variables selected.
From a theoretical point of view, our article is part of the broad theme of the economic valuation of intangible assets (Cohen 2005; Pastor et al. 2017). As stated by Franceschi et al., “football players and their employment contracts constitute the main assets of professional clubs” (Franceschi et al. 2023a, p. 2). Their transfer cost, even if payments are generally spread over time, can be immediately and entirely registered by clubs on the balance sheet as an asset, with amortization over the duration of the initially signed contract (Wilson and Plumley 2018).
However, in many cases, the residual book value of a player, recorded on the balance sheet as an intangible asset, differs greatly from the amount that clubs can realistically expect to receive from his transfer. This underscores the importance of using a robust approach, such as the one proposed in our article, to monitor the real value of players based on the prices paid in the past for footballers with similar characteristics.
Academic interest in the statistical analysis of the determinants of professional football players’ transfer prices has grown in parallel with the increase in the sums involved. According to the official data published by FIFA TMS (2024) and those collected by the CIES Football Observatory research group, of which the authors are the founders, using the methodology presented in the aforementioned article (Poli et al. 2022), a new spending record was set in 2023 (Figure 1).

2. Methodology

2.1. Sample

The sample from which the statistical model presented in this paper was built consists of 8389 transfers having taken place between July 2014 and March 2024, involving 6347 players. The number of transfers is greater than that of the footballers concerned, as in 1626 cases, the latter experienced several fee-paying transfers included in the model, up to a maximum of seven for the Franco-Algerian striker Andy Delort.
The model’s dependent variable is the indemnity (fee) negotiated by the clubs at the time of the transfer, whether fixed or conditional (add-ons). Only transfers involving at least three-quarters of the players’ economic rights were included, projected at 100% of the value. If the transfers concerned less than three-quarters of the economic rights, we considered that the price agreed was not necessarily thought of by market actors as a value proportional to the total value of the player at the time of the transfer, which justifies their exclusion from the sample.
Only permanent transfers were taken into consideration. Transfers concluded after a loan period to the club with which the player was on loan were systematically excluded, insofar as the amount of compensation is in this case usually negotiated in advance by means of a clause. Similarly, paid transfers without a prior loan period concluded thanks to the retrieval of a buy-out clause in the player’s contract were not included in the sample.
By year, the number of transfers in the sample ranges from 539 in 2014/15 to 1124 in 2023/24 (Table 1). The increase observed over the years, with the exception of the two seasons affected by the global health crisis (Poli et al. 2020), reflects both an increase in paying transactions, as illustrated in Figure 1, and an improvement in our own ability to collect the data needed to include transfers in the sample.
In terms of the number of transfers per association to which the releasing clubs belong, the countries with the richest leagues in the world (Frick et al. 2023) are in first place, namely England, France, Italy, Germany and Spain (Table 2). These associations account for 43% of the number of paid transactions in the sample, reflecting their central role in the global football market. However, the sample includes transfers from no fewer than 54 national associations.
From the perspective of recruitment associations, the same countries mentioned above stand out (Table 3). In this case, the over-representation of England is even more marked (16.7% of total incoming transfers compared to 10.7% of outcoming ones), reflecting the hold of English clubs over the global football players’ transfer market (FIFA TMS 2024). However, here too, the sample is fairly diversified, as it includes transactions to 61 different national associations.
Almost half of the players whose transfers are included in the sample from which the multiple linear regression was developed are center forwards (22.5%) or defensive/central midfielders (20.5%), as illustrated in Table 4. In contrast, the proportion of goalkeepers is only 4.2%, reflecting the smaller number of players in this position in club squads. However, there are still enough goalkeepers (350) for the statistical model to take them into account.
While the average age of players in the squads of professional football clubs worldwide is around 26.4 years (Poli et al. 2023b), the average for the footballers in the sample is 25.1 years. This discrepancy reflects the fact that younger players are more sought-after on the transfer market, and even more so when the transactions involve a financial compensation. Around 42% of the players in the sample were aged between 22 and 25 at the time of the transfer (Figure 2).
The vast majority of transfers from which the statistical model was built were concluded for a price of less than EUR 20 million (Figure 3). Just over a quarter were negotiated for fees between EUR 1 and EUR 2.5 million (25.4%). Transactions for more than EUR 20 million, on the other hand, were relatively infrequent, with a total of 626 observations, including only 178 for transfers in excess of EUR 40 million. The asymmetry in the distribution of transfer indemnities implies their normalization by a logarithmic transformation, so as to explain them using a multiple linear regression.

2.2. Variables

With regard to the dependent variable, transfer fees, the values were relativized by a factor reflecting the level of inflation on the transfer market. This factor was calculated on the basis of the average fee between the 10th and 100th most expensive transfers of the last two transfer windows. It has risen from an index of 100 in July 2010 to an index of 395 in January 2023, indicating a four-fold increase in prices over this period. In addition, as noted above, the asymmetric distribution of values requires a logarithmic normalization, as suggested by the near-zero lambda value of a Box–Cox transform test (−0.02 for the 8389 observations).
All the independent variables included in the model have a probability of error inferior to 5%. Numerous other variables were tested and ultimately not retained because they were either not significant (e.g., numerous technical gestures, such as saves for goalkeepers, tackles, assists, etc.) or had too high a degree of collinearity with other variables.
Below, we introduce all the variables included in the multiple linear regression, explaining how they were calculated and the various issues that governed the choices made. Their relative weight in the formation of players’ prices is detailed in the following chapter.
  • Contract
    Residual contract duration at the time of transfer, in days, maximum 1825 days (i.e., 5 years). The value is transformed into a logarithm, which means that its impact on the transfer value increases as the end of the contract approaches (variable indicated by [contract] in the presentation of the statistical model in Table 5 of Section 3).
  • Age
    Age of the player at the time of transfer, without transformation, which implies its impact on the transfer value is linear ([age] in Table 5). As Franceschi et al. (2023a) point out, some authors have highlighted the non-linear effect of age and added the age-squared to their independent variables. In our case, the other variables in the model already correct this effect. Indeed, adding an age-squared variable is not significant (p = 0.173), with no added value in terms of explanatory power.
  • Sporting level
    Average sporting level of matches played by the footballer over the 365 days preceding the transfer ([level_s12] in Table 5) or between the 365th and 730th days preceding the transfer ([level_s34]). In order to calculate the sporting level of a match, for all players fielded, we compute all the minutes played in domestic leagues over the previous 365 days. Each minute played during this period is weighted by the sporting level of the corresponding league. The sporting level of a league is calculated on the basis of the sporting level of the corresponding national association, with a weighting according to the level of competition at domestic level (100% for the top division, 50% for the second, 25% for the third, etc.). Within a confederation, the sporting level of an association is calculated according to the results obtained by its representatives in international club competitions (Champions League, Copa Libertadores, etc.) over the last five years. In order to establish a single ranking worldwide, the highest-ranked association in each confederation is assigned the average sporting level of the best fifty UEFA clubs to which players from the corresponding confederation were transferred in the last five years. The remaining associations are ranked according to the intra-confederation hierarchy.
  • Domestic minutes
    Number of minutes played by the footballer in official national competition games (championships and cups) during the 365 days preceding the transfer ([mdom_s12] in Table 5) or between the 365th and 730th days preceding the transfer ([mdom_s34]).
  • International minutes
    Number of minutes played by the footballer in official international competition games (clubs and A- or U21 national teams) in the 365 days preceding the transfer ([mint_s12] in Table 5) or between the 365th and 730th days preceding the transfer ([mint_s34]).
  • Goals
    Number of goals scored by the footballer per 90 min played in club or national A- or U21 teams in the 365 days preceding the transfer ([goal_s12] in Table 5) or between the 365th and 730th days preceding the transfer ([goal_s34]).
  • Results
    Average number of points obtained by the player’s teams (two points for a win, one for a draw and zero for a loss) in all official matches played by the footballer during the 365 days preceding the transfer ([ppm_s12] in Table 5) or between the 365th and 730th days preceding the transfer ([ppm_s34]). The tests carried out show that the scale used (two-point win) is a better indicator of performance in this model than the one introduced in the 1990s giving an additional point for a win to foster offensive play.
  • Starting 11
    Percentage of minutes played by the footballer as a starter in official club or national team matches (A- or U21) in the 365 days preceding the transfer ([start_s12] in Table 5).
  • Position
    Position most occupied by the player in the six months preceding the transfer; binary variables (goalkeeper, center back, full or wing back, central or defensive midfielder, attacking midfielder and winger), with center forward as the reference value ([pos_gk], [pos_cb], [pos_fb], [pos_dm], [pos_am] and [pos_wi] in Table 5).
  • International status
    Footballer who has played at least one match in his career for a national A-team at the time of transfer ([inter] in Table 5).
  • Releasing club selling potential
    Maximum income earned by the selling club over the last ten transfer periods adjusted to a reference value to capture the level of inflation at the time of the record income. The reference value is calculated on the basis of the average fee between the 10th and 100th most expensive transfers over the four years prior to the transfer window of the record income ([sel_club] in Table 5).
  • Releasing league selling potential
    Average of the maximum income earned by each of the clubs from the selling league over the last ten transfer periods, adjusted to the reference value as above ([sel_leag] in Table 5).
  • Destination club buying potential
    Maximum expenditure of the buyer club over the last ten transfer periods, adjusted to the reference value as above ([buy_club] in Table 5).
  • Destination league buying potential
    Average of the maximum expenditure of each of the clubs in the buying league over the last ten transfer periods, adjusted to the reference value as above ([buy_leag] in Table 5).
Compared to the previously published article (Poli et al. 2022), the same categories of variables are used. However, the approach is slightly different. In the previous paper, we notably favored synthetic variables with regard to players’ experience, which combined playing time (last and previous year), results and the sporting or economic levels of employing teams. Now, we consider these dimensions separately. This choice allows us to have a better control of their respective effects.

3. Results

Regression Model

The regression model developed from the variables detailed above explains 84.8% of the differences in the fees paid for the 8389 transfers included in the sample (Figure 4). As indicated, all the variables selected reach a level of significance greater than 95%. The standardized beta and the t-value show the relative weight of each variable in the determination of players’ prices (Table 5).
Table 5. Multiple linear regression to explain transfer fees.
Table 5. Multiple linear regression to explain transfer fees.
Countryb-Coeff.Std BetatProbSign
[contrat]+0.485+0.211+45.580.000***
[age]−0.050−0.286−51.090.000***
[pos_gk]−0.015−0.005−0.760.445ns
[pos_cb]−0.029−0.018−2.280.023*
[pos_fb]−0.078−0.043−5.890.000***
[pos_dm]−0.022−0.015−1.990.046*
[pos_am]−0.013−0.005−1.080.281ns
[pos_wi]−0.021−0.013−2.310.021*
[level_s12]+1.511+0.302+33.530.000***
[level_s34]+0.409+0.099+12.440.000***
[mindom_s12]+0.009+0.137+22.930.000***
[mindom_s34]+0.001+0.026+5.180.000***
[minint_s12]+0.002+0.044+7.320.000***
[minint_s34]+0.002+0.031+5.270.000***
[goal_s12]+2.961+0.134+18.050.000***
[goal_s34]+0.823+0.038+5.370.000***
[ppm_s12]+0.211+0.043+8.900.000***
[ppm_s34]+0.054+0.012+2.550.011*
[start_s12]+0.443+0.074+12.290.000***
[inter]+0.072+0.060+12.320.000***
[selclub]+0.134+0.059+10.180.000***
[selleag]+0.265+0.112+16.890.000***
[buyclub]+0.513+0.224+37.340.000***
[buyleag]+0.344+0.172+29.330.000***
[cons]−3.657−68.070.000***
[***]: p < 0.001, [*]: p < 0.05, [ns]: not significant.
With a standardized beta of +0.211 and a t-value of +45.58, the remaining contract duration is an extremely important variable in the formation of players’ prices on the transfer market. It is transformed on a logarithmic scale, which implies that the shorter the remaining contract period, the greater its impact. As a matter of example, all other things being equal, when a player has four years remaining on his contract, one year less implies a 13% drop in his value, whereas the decrease is 29% if the footballer only has two years remaining on his contract.
The standardized beta shows that age is also a very important contributor to the transfer fee, in this case, with a negative sign (−0.286). Given their longer-term potential, younger players are comparatively better valued than older ones. The effect is linear, which means that a difference of five years will have the same impact (−44%) if we compare, for example, two players with identical profiles aged 18 and 23 years, or 28 and 33 years.
The categorical variables that compare the position of players in relation to center forwards all have negative coefficients, which indicates that center forwards, all other things being equal, are the most valued. The most negative coefficient compared to center forwards is recorded for full/wing backs, who have a value 16% lower than the reference category. On the other hand, the difference is very limited (not significant) for goalkeepers and attacking midfielders (on average, around −3%).
Regarding all the variables referring to players’ performance, the most important is the sporting level of matches played, followed by the number of minutes played in the league, the number of goals scored and the tendency to be included in the starting 11 line-ups. In comparison, the results of matches played or the fact of playing international games, both for club or national teams, while also highly significant, are less important.
Whatever the variable, that referring to the most recent period (last 365 days) has systematically the strongest t-value and standardized beta. This result indicates that the prices of players on the transfer market are formed essentially on the basis of their performances over the last year, with the previous year also playing a significant role, but to a much lesser extent. The tests carried out including previous years were all negative. International status, acquired once and for all, is another element that tends to increase the price paid for a footballer by around a third, all other things being equal.
Finally, characteristics relating to the economic potential of both releasing and recruiting clubs form the last key group of factors. In this case, variables referring to the destination club and league have a greater weight compared to those relating to the club of departure. This finding reflects the overriding importance of the recruiters’ buying power in determining prices during negotiations.
Compared with the results presented in the previous article focused on the European Big Five league transfers (Poli et al. 2022), the results are highly convergent. The closeness of the standardized beta for age (−0.286 compared with −0.306) and contract length (+0.211 compared with +0.214), two variables defined in the same way in both analyses, confirms that the transfer market operates according to similar logic on a global scale, which makes it possible to build a statistical model to explain fees worldwide.
The correlation levels are also very high when observations are segmented according to different criteria. By period (Table 6), the coefficients of determination increase over time, suggesting a rationalization of the market on the basis of the logic underlying the variables included in the statistical model. An improvement in the quality of the data gathered can also explain this development. The explanatory power of the model is relatively similar across all positions and age categories: between 83% and 87% (Table 7 and Table 8).
Cross-validation is another way of testing the quality and robustness of the model. To achieve this, the sample was randomly divided into five groups with the same number of individuals. Each time, a model was created with the transfers of four of these groups, and the parameters were applied to predict the values of the fifth. The results obtained in terms of coefficients of determination are very stable (between 83% and 85%), both in terms of modeling and application (Table 9).
On a global scale, the scatter plot linking the model’s estimates and the residuals does not show any particular shape, which rules out any flagrant problem of heteroscedasticity (Figure 5). The application of statistical tests, such as the White or Breusch–Pagan tests, does not validate the hypothesis of the homoscedasticity of the variance of the residuals. Indeed, the model tends to slightly underestimate the values in the most extreme spectra, while the values for certain intermediate segments are slightly overestimated (Figure 6).

4. Discussion

Although our regression model for assessing the transfer price of professional football players is particularly robust and effective, some of the prices paid by clubs differ significantly from the estimated values. Below, we present some of the main discrepancies observed, which allows us to account for certain specific or statistically non-modellable criteria that may nevertheless have an impact on the price determination process.
The transfer of the Brazilian striker Hulk Givanildo from Zenit St. Petersburg to Shanghai Port in 2016 was negotiated at a price almost four times higher than that estimated by our statistical model. Part of the discrepancy can be explained by the fact that Chinese clubs had previously not been very active on the transfer market. Consequently, their economic potential as integrated into the model, calculated on the basis of past transactions, lagged behind.
In addition, as in the case of other countries or clubs stepping up their recruitment to acquire a more central role in the football economy, overpaying players and their former clubs is often an essential condition for transfers to go through. Finally, it cannot be ruled out that the very fact of paying large sums is valued by the emerging recruiting countries or clubs as a signal of their new status and ambition, which does not encourage them to negotiate prices downwards.
The transfer of Willem Geubbels from Olympique Lyonnais to Monaco in 2018 was also negotiated at a much higher price than estimated. Geubbels was a very young player, who had already shone at youth level, so much so that he was considered to have similar potential to Kylian Mbappé, who is two and a half years older and was transferred by Monaco to PSG in the same transfer window for EUR 180 million, including add-ons. However, Geubbels had played very little at professional level up to that point, which makes our model less suitable for evaluating him, insofar as the vast majority of the transactions on which the model was built involved players with at least one-year experience at adult level.
An opposite case, where the value was overestimated, is that of the transfer of striker Mario Balotelli from Milan to Liverpool in 2014, negotiated at half the estimated value. The Italian’s disciplinary problems may explain this discrepancy, as they do for other players, whose behavior does not offer the best guarantees to the recruiting clubs. This has a negative and non-modellable impact on the fees that clubs are willing to invest to sign them.
Other cases also involve aspects that are difficult to model. The financial difficulties of the clubs to which players belong can have a negative impact on transfer prices, as was notably the case in the summer of 2024 for Girondins de Bordeaux, a French club that finally went into administration. In such cases, deals can be heavily cut to generate money in the short term.
Financial accounting needs may also explain some of the discrepancies observed in certain transactions, in particular those carried out in a hurry before the annual accounts are closed. This can result either in transfers on the cheap (for example, Mohammed Salah’s transfer from Rome to Liverpool in June 2017) or, on the contrary, overpaid transfers and swap deals raising suspicions of accounting manipulation and collusion between clubs (in summer 2024, among other cases, Nottingham Forest and Olympique Lyonnais, Everton and Newcastle United, Aston Villa and Chelsea, etc.).
Other cases involve teams that have been relegated or have speculated on promotion but have failed to achieve it and are therefore forced to drastically reduce their wage bill, sometimes at the cost of having to sell off players in order to balance their books and avoid spiraling into debt. From this point of view, if it were available on a large scale, the variable of the player’s salary would certainly provide an addition to the statistical model developed.
Despite these specific cases and other possible distortions, our approach shows that it is possible to use a statistical model to account for the way in which market actors determine player transfer prices. The various tests carried out by segmenting the sample by period show that these criteria are relatively stable over time, albeit with some changes.
Since the health crisis, for example, the age factor has become even more discretizing, with an increasing number of clubs targeting their recruitment toward young talent in order to make capital gains through their subsequent transfer, which has led to higher inflation for players under 23 than for older footballers (Poli et al. 2023a).
The approach presented is particularly effective in assessing the fair price of players after their transfer. However, from a predictive perspective, when the acquiring club is not known, in order to determine an expected amount, it is necessary to develop another statistical model with the financial strength of the likely acquirer as the dependent variable. Various tests were also carried out for this purpose, which enabled us to achieve a coefficient of determination of around 65%, certainly with still room for improvement.

Author Contributions

Conceptualization, R.P.; Data curation, R.B. and L.R.; Formal analysis, R.B.; Investigation, R.P. and R.B.; Methodology, R.B.; Project administration, R.P.; Resources, L.R.; Supervision, L.R.; Validation, L.R.; Writing—Original draft, R.P.; Writing—Review and editing, R.P. and R.B. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Informed Consent Statement

Not applicable.

Data Availability Statement

Embargo on data due to commercial restrictions.

Acknowledgments

The authors warmly thank the CIES direction and colleagues for their continuous support over the years.

Conflicts of Interest

The authors declare no conflicts of interest.

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Figure 1. Global transfer fee spending, EUR billion (2014–2023).
Figure 1. Global transfer fee spending, EUR billion (2014–2023).
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Figure 2. Sample per age.
Figure 2. Sample per age.
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Figure 3. Sample per transfer fee category.
Figure 3. Sample per transfer fee category.
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Figure 4. Fitted and actual transfer fees.
Figure 4. Fitted and actual transfer fees.
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Figure 5. Scatter plot of the estimates and residuals.
Figure 5. Scatter plot of the estimates and residuals.
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Figure 6. Average residuals, as per estimate in percentile.
Figure 6. Average residuals, as per estimate in percentile.
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Table 1. Sample per season of transfer.
Table 1. Sample per season of transfer.
SeasonNumber
2014/15539
2015/16725
2016/17852
2017/18889
2018/19875
2019/20896
2020/21639
2021/22779
2022/231071
2023/241124
Table 2. Sample per releasing association.
Table 2. Sample per releasing association.
CountryNumberPercentage
England89510.7%
France7508.9%
Italy7328.7%
Germany7188.6%
Spain5096.1%
The Netherlands4134.9%
Belgium3574.3%
Argentina2793.3%
Brazil2783.3%
Portugal2783.3%
44 others318037.9%
Total8389100.0%
Table 3. Sample per recruiting association.
Table 3. Sample per recruiting association.
CountryNumberPercentage
England139816.7%
Italy93211.1%
Germany8219.8%
France6818.1%
Spain5126.1%
Turkey3624.3%
Belgium3464.1%
The Netherlands2422.9%
Russia2412.9%
USA2322.8%
51 others262231.3%
Total8389100.0%
Table 4. Sample per player position.
Table 4. Sample per player position.
CountryNumberPercentage
Goalkeepers3504.2%
Center backs144917.3%
Full backs101412.1%
Defensive midfielders171920.5%
Attacking midfielders5897.0%
Wingers137716.4%
Center forwards189122.5%
Total8389100.0%
Table 6. Coefficient of determination per period.
Table 6. Coefficient of determination per period.
SeasonNR2
2014/15–2015/16126480.0%
2016/17–2017/18174183.7%
2018/19–2019/20177184.8%
2020/21–2021/22141884.5%
2022/23–2023/24219587.6%
Table 7. Coefficient of determination per player position.
Table 7. Coefficient of determination per player position.
CountryNR2
Goalkeepers35087.1%
Center backs144984.0%
Full backs101485.2%
Defensive midfielders171985.2%
Attacking midfielders58987.6%
Wingers137785.2%
Center forwards189183.1%
Table 8. Coefficient of determination per age category.
Table 8. Coefficient of determination per age category.
CountryNumberPercentage
21 years or less159983.4%
22–25 years358785.6%
26–29 years241984.2%
30 years or more78483.2%
Table 9. Five-fold cross-validation analysis of the model to assess transfer fees.
Table 9. Five-fold cross-validation analysis of the model to assess transfer fees.
Training SampleTest Sample
NR2 adjNR2 adj
Cross-validation 1671284.70%167785.00%
Cross-validation 2671184.81%167884.57%
Cross-validation 3671184.71%167884.97%
Cross-validation 4671185.05%167883.54%
Cross-validation 5671184.59%167885.46%
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Poli, R.; Besson, R.; Ravenel, L. Statistical Modeling of Football Players’ Transfer Fees Worldwide. Int. J. Financial Stud. 2024, 12, 93. https://doi.org/10.3390/ijfs12030093

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Poli R, Besson R, Ravenel L. Statistical Modeling of Football Players’ Transfer Fees Worldwide. International Journal of Financial Studies. 2024; 12(3):93. https://doi.org/10.3390/ijfs12030093

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Poli, Raffaele, Roger Besson, and Loïc Ravenel. 2024. "Statistical Modeling of Football Players’ Transfer Fees Worldwide" International Journal of Financial Studies 12, no. 3: 93. https://doi.org/10.3390/ijfs12030093

APA Style

Poli, R., Besson, R., & Ravenel, L. (2024). Statistical Modeling of Football Players’ Transfer Fees Worldwide. International Journal of Financial Studies, 12(3), 93. https://doi.org/10.3390/ijfs12030093

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