Development of retirement age prediction model for athletes
Article information
Abstract
The purpose of this study is to present retirement age predictive functions of athletes that can be utilized as data to reduce psychological shock of athletes from retirement and prepare for the future. To accomplish such purpose, athletes who retired as an undergraduate, unemployed or professional registered on the athlete registration system of the Korean Sport & Olympic Committee for three years were selected as the population. Stratified sampling was used for convenience sampling. Content validity of a retirement factor questionnaire was examined by consulting with experts. Opinions of 72 retirees were collected through an open questionnaire, and samples of 260 persons were used in the first and second parts after consulting with experts based on first sample data. The stepwise regression analysis method was applied to develop reliable and valid retirement predictive regression function. The degree of relevance was shown by multiple correlation coefficient between predicted age calculated by the predictive function and actual retirement age. Significance level was .05 for all tests. The 8 predictive function are presented according to the procedure above.
Introduction
According to an American medical news website called Medical News Today, a French institute for research in biomedicine and sports cognition named ‘IRMES’ conducted research on ‘physical prime age’ of athletes, which showed that male athletes enjoy their physical prime age in mid-20s.This study was carried out to find out physical prime age by comparing physical ability of 2,000 male athletes. Mean age at which athletes reach the peak of physical prowess was 26.1 years, and swimming athletes were found to experience prime age relatively early at an age of 21 years. Such changes in performance of athletes also agreed with the cycle of bodily changes including pulmonary functions(Dong-A Daily, 2015). In addition, athletes of the Korean national tea mare reported to retire at very young ages between 20s and 30s(Yong-Sik Lee, 2008). As such, athletes retire much earlier than other jobs. Most of athletes consider retiring after the age of 30 years. They would continue their athletic career if they are famous or acknowledged by team members (Kerr, Dacyshyn, 2000). However, since not all athletes are recognized and famous, they usually think about retirement after the age of 30 years (Sang-Deok Han, 1999). The biggest enemy of athletes is injury. An injured athlete cannot play sports during the recovery period, which leads to poor sensation. For this reason, athletes are most careful about injuries. A former member of the Korean national football team retired at a young age of 30 years because of an injury (Seok-Bae Lee, Mi-Hye Cho, 2012). Eitzen & Sage(1997) explained that mean duration of professional athletes is about 3-4 years, no matter how good their athletic performance may be.They mentioned that professional athletes start considering retirement in early or late 30s and when they are injured or become a substitute. Ok-Cheon Kim and Su-Won Lim(1999) reported that the biggest cause of retirement of professional athletes among voluntary and non-voluntary retirement problems is non-voluntary, one-sided removal by the team. Psychological conditions at the time of retirement include skepticism about sports, sense of betrayal about the team, perplexity, resentment, despondency and anxiety about future job(Coakley, 1983; Lerch, 1984; McKenna, Thomas, 2007; Ji-Hye Jeong, 2010; Yeon-Hee Seo, 2012; Du-Jae Park, Yeong-Jin Won, 2014). It would be desirable to recognize such problems of anxiety about retirement and suggest appropriate retirement age so that athletes can be helped mentally when they are about to give up on sports.
In relation to sports, studies were consistently conducted on predictive models for outcome prediction, ranking prediction, audience prediction and adolescent physique prediction(Cha-Yong Kim, 2001; Hyeong-Jun Choi, Ju-Hak Kim, 2006; Ju-hak Kim, Gab-Taek Noh, Jong-Seong Park, Won-Hee Lee, 2007; Jin-Seok Chae, Eun-Hyeong Cho, Han-Ju Eom, 2010; Jin-Seok Chae, 2012; Jin-Seok Chae, Jong-Guk Song, 2014, 2016; Bong-Ju Seong, Byeong-Gu Koh, 2017;Jin-Seok Chae, Jin Park, Wi-Yeong So, 2018). These studies are intended to predict future values based on actual measurement data, instead of using a survey tool to acquire data from human memory as done in this study.
Unwanted retirement due to unexpected removal from the team, injury, economic difficulty, physical limitation and accident would be shocking, not only for the athlete but also for family members. Athletes can gain mental stability and change job in a quick and effective way by preparing in advance. The purpose of this study is to present retirement age predictive functions for athletes to increase quality of life, reduce mental shock, and be used as data for future preparation.
Method
Research subjects
Since external validity that shows the degree of generalization of study results indicates how well samples represent the population, the population of this study was defined as retired athletes who were active for three years or longer as an undergraduate, unemployed or professional athlete and can be found on the athlete registration system of the Korean Sport & Olympic Committee. Among study variables, the dependent variable was retirement age, presented for each sex (male/female), sports event(combat/non-combat), organization of sports event(individual/group) and affiliated team(undergraduate/unemployed /professional). Predictor variables included accident or addiction, job plan, family economy, decline in popularity, group life, injury, interpersonal relationship, competitiveness, exercise attitude and contract cancellation.
Data collection
To develop a predictive function that can predict retirement age more accurately, stratified sampling which can apply convenience sampling was used by defining retired athletes around the nation in university and beyond as the population. Validity of the open questionnaire was examined by consulting with retired athlete experts, and samples were collected. The open questionnaire was made using literature related to retirement factors utilized in previous studies(Ji-Hye Jeong, 2010; Seung-Hu Hong, 2010). Opinions of 72 retirees were collected using the open questionnaire, and they were largely classified into three domains including demographic variables after discussing with 12 experts (one doctoral research and 11 professors specialized in measurement evaluation). The first domain was personal domain divided into popularity, competitiveness, physical limitation, exercise attitude, group life and job plan. The second domain was external environment domain divided into accident, addiction and injury. The third domain was other people’s domain divided into family, interpersonal relationship, economy and administration. (Jin-Seok Chae, Jin-I Shin, Deok-Hyeon Nam, 2018) As described above, the open questionnaire and main questionnaire (71 questions: 5-point scale comprised of strongly disagree, disagree, neither, agree and strongly agree) to predict retirement age were prepared through expert meetings to secure content validity. A total of 275 respondents participated in the questionnaire in the first and second parts combined. Among them, data with insincere responses or many missing values were excluded to use 260 responses for analysis. Characteristics of the subjects are presented in <Table 1>.
Data processing method
Predictor variables to be applied first to the predictive regression functions were comprised of questions (Table 3) obtained by performing exploratory factor analysis to secure validity of the questionnaire. For exploratory factor analysis, factors were extracted using the maximum likelihood method. Questions with eigen value of 1.0 or above and factor loading of .45 or above were included in the same factor(Tabachnick & Fidell, 1989). By performing exploratory factor analysis on the questionnaire, 13 retirement factors were reduced to 10 latent variables (accident and addiction, job plan, family economy, decline in popularity, group life, injury, interpersonal relationship, competitiveness, exercise attitude and contract cancellation)(Table 3). Based on normal distribution of data verified according to mean, standard deviation, skewness and kurtosis of measurement variables, the range of mean was 1.568~2.918 and the distribution of standard deviation was 0.817~1.315. The range of skewness was -0.080~1.687, whose absolute value is not greater than 3.0. The range of kurtosis was -1.145~2.588, whose absolute value is not greater than 10. Therefore, the distribution of data had normality (Kline 2005). The dependent variable of the predictive regression function was retirement age. The predictive regression function was divided into 8 predictive model functions based on stepwise regression analysis according to sex, combat/non-combat, individual/group and affiliation (undergraduate, unemployed, professional). For verification, the degree of relevance was shown by multiple correlation coefficient between predicted age calculated by the predictive function and actual retirement age(Table 13). Data collected during this study were entered into Excel 2007 and converted on the SPSS 22.0 program for analysis.
Statistics
The correlation analysis was used to examine the relevance among predictor variables or retirement factors. The predictive models presented as the study results used the stepwise regression analysis method, which is a general predictive statistical analysis method used when the dependent variable is a continuous variable. Predictor variables were extracted through exploratory factor analysis, and inter-item consistency of the measurement tool was verified using Cronbach's α. The verification method was the Pearson’s product-moment correlation coefficient between predicted retirement age and actual age. Significance level was .05 for all verifications.
Results
This study first presented the correlation coefficient among retirement factors (Table 4). The first predictive functions are retirement age predictive models according to sex. The second predictive functions are retirement age predictive models according to characteristics of sports. The third predictive functions are retirement age predictive models according to number of athletes in a team. The fourth predictive functions are retirement age predictive models according to affiliation.
Retirement age predictive models according to sex
The retirement age predictive function of female athlete was presented using stepwise regression analysis(Table 5). There are two significant predictor variables including physical limitation 11 and job plan 29.Explanation power of predictor variables in explaining fluctuation of the dependent variable is 19.0%, but modified explanation power is 16.0%. In addition, the fitness of this regression model is satisfactory (F=7.820 , p<.05). The retirement age predictive function of female athlete is Y(retirement age)=24.097+1.778*(physical limitation 11)-1.142* (job plan 29).
There are 8 significant predictor variables for male athletes including popularity 2, exercise attitude20, popularity 1, competitiveness 7, job plan 29, economy 18, administration 23 and interpersonal relationship 13. Explanation power of the regression model is 31.0%, and modified explanation power is 27.6%. The fitness of this regression model is satisfactory (F=9.101, p<.05). The retirement age predictive function of male athlete isY(retirement age)= 23.498+1.334*(popularity 2) -1.126*(exercise attitude 20)+1.021*(competitiveness 7)-1.020*(job plan 29)+0.871*(economy 18) -1.905* (administration 22)-1.024*(administration 23) +.778* (interpersonal relationship 13)(Table 6).
Retirement age predictive models according to characteristics of sports
The predictive function of combat sports was derived by stepwise regression analysis with six predictor variables(job plan 29, physical limitation 15, popularity 1, exercise attitude 16, job plan 30 and injury 46). The explanation power of the regression model is 23.9%. The fitness of the regression model is satisfactory (F=8.311**, p<.05). Job plan 29(β =-.516) was found to be the variable that has the greatest impact on retirement age among retirement factors. The retirement age predictive function of combat sports is Y(retirement age)=23.158+.688*(physical limitation 11)-1.790*(job plan 29)+0.960*(popularity 1)-0.656*(exercise attitude 16)+0.747*(job plan 33)+0.643*(economy 18)-0.461 *(administration 23)+.606*(injury 46)(Table 7).
There are 7 predictor variables for the predictive function of non-combat sports including popularity 2,exercise attitude20, competitiveness 7, family 5, administration 21, administration 25 and interpersonal relationship 8. The modified explanation power is 43.1%. In addition, the fitness of the regression model is satisfactory( F=13.016**, p<.05). Among retirement factors, administration 21(β =.-457) had the biggest effect on retirement age. The retirement age predictive function of non-combat sports is Y(retirement age)= 20.741+1.637*(popularity 2)-1.270*(exercise attitude 20)+0.942*(competitiveness 7)+2.061*(family 5)-3.291 *(administration 21)+1.082*(administration 25)+1.192 (interpersonal relationship 8)(Table 8).
Retirement age predictive models according to number of members in a team
There are four predictor variables for the predictive function of individual sports including job plan29, physical limitation15, popularity 1 and exercise attitude16. The modified explanation power of the regression model is 19.6%. In addition, the fitness of the regression model is satisfactory(F=10.346, p<.05). Among retirement factors, physical limitation 15(β =.359) was found to be the variable that has the biggest effect on retirement age. The retirement age predictive function of individual sports is Y(retirement age)= 27.414-1.295*(job plan 29)+1.463*(physical limitation 15)+0.972*(popularity 1)-0.639*(exercise attitude 16)(Table 9).
There are four predictor variables for the predictive function of group sports including popularity 2, exercise attitude 20, interpersonal relationship 6 and addiction 41. The modified explanation power of the regression model is 43.6%. In addition, the fitness of the regression model is satisfactory (F=15.287, p<.05). Among retirement factors, interpersonal relationship 6(β =.648) is the variable that has the biggest effect on retirement age. The retirement age predictive function of group sports is Y(retirement age)= 21.950+1.950*(popularity 2)-1.318*(exercise attitude 20)+4.635*(interpersonal relationship 6)-3.337*(addiction 41)(Table 10).
Retirement age predictive model according to affiliation
Multiple regression analysis was used to present the retirement age predictive function of undergraduate athlete. Predictor variables include economy 18, economy 16, administration 21 and competitiveness 4. The modified explanatory power of the regression model is 26.0%. In addition, the fitness of the regression model is satisfactory (F=10.754**, p<.05). Among retirement factors, economy 16(β =-.732) is the variable that has the biggest effect on retirement age. The retirement age predictive function of undergraduate athlete is Y(retirement age)=22.186+1.559*(economy 18)-1.889*(economy 16)+1.298*(administration 21) -0.453*(competitiveness 4)(Table 11).
Multiple regression analysis was used to present the retirement age predictive function of unemployed and professional athlete. There are four predictor variables including exercise attitude 19, competitiveness 8, administration 21 and popularity 2. The modified explanation power of the regression model is 23.4%. In addition, the fitness of the regression model is satisfactory(F=9.880**, p<.05). Among retirement factors, competitiveness 8(β =.318) was found to be the variable that has the biggest effect on retirement age. The retirement age predictive function of unemployed and professional athlete is Y(retirement age)= 27.808 -0.874*(exercise attitude 19)+1.287* (competitiveness 8)-1.402*(administration 21)+0.757 *(popularity 2) (Table 12).
Verification of retirement age predictive functions
The degree of relevance was shown by the multiple correlation coefficient between predicted age calculated using the retirement age predictive functions presented in the study results and actual retirement age. As shown in <Table 13>, all 8 models showed significant (**p<.05) relevance between predicted value and actual value.
Discussion
Prediction is difficult, but it is also difficult to develop reliable and valid predictive functions. There is a greater difficulty in developing retirement age predictive functions for athletes because injury occurs unexpectedly in many cases. Nonetheless, 8 retirement age predictive functions for athletes were presented by increasing the number of samples in the retirement factor measurement tool developed by Jin-Seok Chae, Jin-Lee Shin and Deok-Hyeon Nam (2018) to reduce mental shock and prepare for the future of athletes. Discussions are as follows.
First, the 8 retirement age predictive models are created using stepwise regression analysis according to characteristics of athletes. As a result of applying 60 variables obtained by dimension reduction of data taken using the questionnaire of previous studies with increased number of samples through exploratory factor analysis, when classified according to sex, two significant predictor variables including physical limitation 11 and job plan 29 were obtained for the model of female athlete and 8 variables including popularity 2, exercise attitude 20, popularity 1, competitiveness 7, job plan 29, economy 18, administration 23 and interpersonal relationship 13 were obtained for the model of male athlete. In addition, for combat and non-combat sports classified based on face-to-face combat of athletes, six variables including job plan 29, physical limitation 15, popularity 1, exercise attitude 16, job plan 30 and injury 46 were obtained for combat sports and 7 variables including popularity 2, exercise attitude 20, competitiveness 7, family 5, administration 21, administration 25 and interpersonal relationship 8 were obtained for non-combat sports.
When classified into individual sports and group sports based on number of members in a team,four significant predictor variables (job plan 29, physical limitation 15, popularity 1 and exercise attitude) were obtained for individual sports and four variables including popularity 2, exercise attitude 20, interpersonal relationship 6 and addiction 41 were obtained for group sports. Lastly, team affiliation was divided into university, unemployed and professional. Four significant predictor variables (economy 18, economy 16, administration 21 and competitiveness 4) were selected for undergraduate athletes and four predictor variables (exercise attitude 19, competitiveness 8, administration 21 and popularity 2) were obtained for unemployed and professional athletes.
There was no previous study that presented predictive functions related to retirement age.The method of this study partially agreed with the method of Bong-Ju Seong and Byeong-Gu Koh(2017) who developed a physical age predictive function for adult men and women, but there were differences in verification methods. In addition, Laval lee, Grove and Gordon (1997) who studied causes of retirement of Australian elite athletes reported schooling, decline in performance, economic difficulty and loss of interest as causes of retirement. These causes partially agreed with the independent variables for the retirement age predictive functions of this study including economic difficulty, job plan and exercise attitude. In a study on active female basketball players of the national team, Ji-Hye Jeong(2010) reported admission to higher school, path of a leader, honorable retirement and family life as causes of retirement, which agree with job plan, honorable retirement and school admission of this study. Hee-Yun Choi and Yong-CheolJeong (2012). reported that the basic rights of female handball players are seriously violated and depicted routine violence of leaders and seniors and frequent injury as causes of retirement. These causes were associated with group life and injury of this study.
Mean retirement age of women was found to be 22 years in a previous study by Job Korea (2017), but it was 23.73 years in this study. In relation to retirement age, Yong-Sik Lee (2008) reported that athletes of the national team generally retire in their 20s and 30s, and Job Korea (2017)reported mean retirement age to be about 22 years for female athletes of Korea and about 28 years for male athletes. These results are similar to the result of this study, which showed mean retirement age of about 25.84 years for men and women combined.
Conclusion and Suggestion
First, the retirement age predictive function of female athlete is Y(retirement age)= 24.097+1.778*(physical limitation 11)-1.142*(job plan29). Second, the retirement age predictive function of male athlete is Y= 23.498+1.334*(popularity 2)-1.126*(exercise attitude 20)+1.021*(competitiveness 7)-1.020*(job plan 29) +0.871*(economy 18)-1.905*(administration 22) -1.024*(administration 23)+.778*(interpersonal relationship 13). Third is the retirement age predictive function of combat sports athlete. The predictive function is Y(retirement age)=23.158+.688*(physical limitation 11)-1.790*(job plan 29)+0.960*(popularity 1)-0.656* (exercise attitude 16)+0.747*(job plan 33)+0.643* (economy 18)-0.461*(administration 23)+ .606*(injury 46). Fourth is the retirement age predictive function of non-combat sports athlete. The predictive function is Y(retirement age)= 20.741 +1.637*(popularity 2) -1.270*(exercise attitude 20) +0.942*(competitiveness 7)+2.061*(family 5)-3.291* (administration 21)+1.082* (administration 25)+1.192 (interpersonal relationship 8). Fifth is the retirement age predictive function of individual sports athlete. The predictive function isY(retirement age)= 27.414-1.295* (job plan 29)+1.463* (physical limitation 15)+0.972* (popularity 1)-0.639* (exercise attitude 16). Sixth is the retirement age predictive function of group sports athlete. The predictive function isY(retirement age)= 21.950+1.950*(popularity 2)-1.318*(exercise attitude 20)+4.635*(interpersonal relationship 6)-3.337*(addiction 41).
Seventh is the retirement age predictive function of undergraduate athlete. The predictive function is Y(retirement age)= 22.186+1.559*(economy 18)-1.889* (economy 16)+1.298*(administration 21)-0.453*(competitiveness 4). Eighth is the retirement age predictive function of unemployed and professional athlete. The predictive function is Y(retirement age)= 27.808 -0.874*(exercise attitude 19)+1.287*(competitiveness 8)-1.402*(administration 21)+0.757*(popularity 2).
When an active athlete is concerned about the time of retirement, expected retirement age of the athlete can be suggested by applying predictor variables of the athlete based on the 5-point scale to the retirement age predictive function of this study. In conducting this study, there was a difficulty in finding retired athletes to collect samples. The regret for not increasing the number of samples further always exists, but this is more so with the questionnaire on retired athletes. The trouble of accurately training past memory would be inversely proportional to the error. Especially, a more reliable and valid retirement age predictive function that can be applied to all affiliations, sex and individual and group sports can be developed by increasing number of samples.
Acknowledgements
This paper was conducted with the support of the National Research Foundation of Korea (2014S1A5B5A02016834).
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