一种基于进化算法的概化理论最佳样本量估计新方法：兼与三种传统方法比较

doi:10.3724/SP.J.1041.2022.01262

摘要/Abstract

摘要：

概化理论在心理与教育测量领域应用较广。如何使测量程序在预算限制的情况下达到较优的可靠性是研究者需要考虑的重要问题, 这个问题可以转换为最佳样本量估计的问题。提出了一种基于进化算法的估计概化理论下最佳样本量的新方法——约束进化算法, 并采用模拟研究的方法比较了微分优化法、拉格朗日法、柯西不等式法等三种传统方法与约束进化算法的优劣。结果表明：在两侧面交叉设计、两侧面嵌套设计和三侧面交叉设计中都证明了约束进化算法更具优越性, 建议研究者在今后的研究中优先使用。

关键词: 概化理论, 预算限制, 最佳样本量估计, 约束进化算法

Abstract:

Generalizability Theory (GT) is widely applied in psychological measurement and evaluation. A larger generalizability coefficient often indicates a higher reliability the test may have. Generalizability coefficients can be improved by increasing sample sizes. However, the size of a sample would be subject to budget constraints. Therefore, it is important to examine how to effectively determine the size of a sample considering the budget constraints. The existing literature has been largely limited to traditional methods, such as the differential optimization method, the Lagrange method and the Cauchy Schwartz inequality method.

These traditional methods have limited scope of application and their typical conditions are hard to satisfy. In addition, there is no unified comparison available. Fortunately, with the increased use of high performance computing, the Constrained Optimization Evolutionary Algorithms (COEAs) becomes highly feasible.

This paper expands and compares the four methods—the differential optimization method, Lagrange method, Cauchy Schwartz inequality method, and COEAs—determine the best solution to the optimal sample size problem under the budget constraints in GT. Specifically, this paper compares the applicability of the four methods using three generalizability designs, including p × i × r, (r: p) × i and p × i × r × o designs. The results are presented as follows:

(1) In the optimization performance of two-facet generalizability design of p × i × r and (r: p) × i, the performance of COEAs is slightly better than that of the traditional methods, whereas the performance of three traditional methods is equivalent. Although COEAs and the traditional methods have showed similar accuracy, the former has better compliance concerning budget constraints.

(2) In the optimization performance of three-facet generalizability design of p × i × r × o, the performance of COEAs is obviously better than that of the traditional methods. The least ideal generalizability coefficient is obtained using the differential optimization method, whereas its budget compliance is the best; the generalizability coefficient obtained by Lagrange method is the best, but higher than the budget. The Cauchy inequality method obtains a better generalizability coefficient under special budget constraints. But, the performance of COEAs is slightly better than that of Cauchy Schwartz inequality method, especially closer to the budget constraints.

(3) In terms of the algorithm complexity, COEAs obtains an obviously smaller algorithm complexity than do the traditional methods. The complexity of the three traditional methods is relatively high. However, COEAs does not rely on the derivation of mathematical formulas, and the algorithm is relatively less complex.

(4) In terms of the algorithm applicability, COEAs is significantly better than the traditional methods. The applicability of the three traditional methods is relatively narrow. However, COEAs does not rely on a specific generalizability design or a budget expression, and, therefore, the applicability of COEAs is stronger.

(5) In terms of the algorithm generalizability, COEAs is obviously better than the traditional methods. The limited mathematical principles make it difficult to extend the three traditional methods to more complex generalizability designs, and thus, the feasibility of calculation is poor. Howerve, COEAs has revealed stronger generalizability.

(6) In terms of the possibility of getting the best solution, COEAs is also better than the traditional methods. Because evolutionary algorithm is a probabilistic algorithm, multiple tests can be conducted to obtain better results for optimal sample sizes. Under some conditions, COEAs can determine better solutions, which, however, is impossible for three traditional methods.

(7) These results suggest that COEAs is superior to three traditional methods in estimating the optimal sample size problem under the budget constraints in GT. It is recommended that researchers use COEAs in future research to determine an optimal sample size in their psychological measurement and evaluation.

Key words: Generalizability Theory, budget constraints, estimating the optimal sample size, Constrained Optimization Evolutionary Algorithms

中图分类号:

B841

黎光明, 秦越. (2022). 一种基于进化算法的概化理论最佳样本量估计新方法：兼与三种传统方法比较. 心理学报, 54(10), 1262-1276.

LI Guangming, QIN Yue. (2022). A new method for estimating the optimal sample size in generalizability theory based on evolutionary algorithm: Comparisons with three traditional methods. Acta Psychologica Sinica, 54(10), 1262-1276.

图/表 6

参考文献 30

[1]	Brennan, R. L. (2001). Generalizability theory. New York, NY: Springer.
[2]	Clayson, P. E., Carbine, K. A., Baldwin, S. A., Olsen, J. A., & Larson, M. J. (2021). Using generalizability theory and the erp reliability analysis (era) toolbox for assessing test-retest reliability of erp scores part 1: Algorithms, framework, and implementation. International Journal of Psychophysiology, 166, 174-187. doi: 10.1016/j.ijpsycho.2021.01.006 URL
[3]	Cleary, T. A., & Linn, R. L. (1969). Error of measurement and the power of a statistical test. British Journal of Mathematical and Statistical Psychology, 22(1), 49-55. doi: 10.1111/j.2044-8317.1969.tb00419.x URL
[4]	Cronbach, L. J., Gleser, G. C., Nanda, H., & Rajaratnam, N. (1972). The dependability of behavioral measurements: Theory of generalizability for scores and profiles. American Educational Research Journal, 11(1), 1-23. doi: 10.3102/00028312011001001 URL
[5]	Diao, X., Liu, Y., Cao, J., & Shang, Y. (2017). Reviews of multiobjective ant colony optimization. Computer Science, 44(10), 7-13.
	[刁兴春, 刘艺, 曹建军, 尚玉玲. (2017). 多目标蚁群优化研究综述. 计算机科学, 44(10), 7-13.] doi: 10.11896/j.issn.1002-137X.2017.10.002
[6]	Ding, Q., & Yin, X. (2017). Research survey of differential evolution algorithms. CAAI Transactions on Intelligent Systems, 12(4), 431-442.
	[丁青锋, 尹晓宇. (2017). 差分进化算法综述. 智能系统学报, 12(4), 431-442.]
[7]	Goldstein, Z., & Marcoulides, G. A. (1991). Maximizing the coefficient of generalizability in decision studies. Educational & Psychological Measurement, 51(1), 79-88.
[8]	Jutkowitz, E., Alarid-Escudero, F., Kuntz, K. M., & Jalal, H. (2019). The curve of optimal sample size (coss): A graphical representation of the optimal sample size from a value of information analysis. Pharmaco Economics. 37(7), 871-877. doi: 10.1007/s40273-019-00770-z URL
[9]	Li, G. (2019a). Psychological measurement. Beijing, China: Tsinghua Universiy Publishing House.
	[黎光明. (2019a). 心理测量. 北京: 清华大学出版社.]
[10]	Li, G. (2019b). Estimation of optimal sample size under budget constraints for generalization theory based on LaGrange multiplier method. Statistics & Decision, 527(11), 13-16.
	[黎光明. (2019b). 基于拉格朗日乘法的概化理论预算限制下最佳样本量估计. 统计与决策, 527(11), 13-16.]
[11]	Li, G., Chen, Z., & Zhang, M. (2020). Estimating the best sample size of teaching level evaluation for college teachers under budget constraints in generalizability theory. Psychological Development and Education, 36(3), 378-384.
	[黎光明, 陈子豪, 张敏强. (2020). 高校教师教学水平评价概化理论预算限制下最佳样本量估计. 心理发展与教育, 36(3), 378-384.]
[12]	Li, G., & Ou, X. (2020). Comparing of LaGrange multiplication and Cauchy-Schwarz inequality for optimal sample size estimation. Statistics & Decision, 552(12), 29-33.
	[黎光明, 欧旭伦. (2020). 拉格朗日乘法与柯西不等式最佳样本量估计比较. 统计与决策, 552(12), 29-33.]
[13]	Li, L., Li, G., Chang, L., & Gu, T. (2021). Survey of constrained evolutionary algorithms and their applications. Computer Science, 48(4), 1-13. doi: 10.11896/jsjkx.200600151
	[李笠, 李广鹏, 常亮, 古天龙. (2021). 约束进化算法及其应用研究综述. 计算机科学, 48(4), 1-13.]
[14]	Liu, Y., Zhang, M., & Zhen, F. (2020). Estimating the best sample size for students’ evolution of teaching——Based on the application of LaGrange multiplier method. Journal of Psychological Science, 43(4), 857-863.
	[刘颖, 张敏强, 甄锋泉. (2020). 学生评教研究的最佳样本量估算——基于拉格朗日乘数法的应用. 心理科学, 43(4), 857-863.]
[15]	Luo, Z., & Guo, X. (2014). The optimal size of material in psychological experiment: The applications of multivariate generalizability theory. Acta Psychologica Sinica, 46(6), 876-884. doi: 10.3724/SP.J.1041.2014.00876 URL
	[罗照盛, 郭小军. (2014). 认知行为实验研究中最佳素材容量的选择与确定:多元概化理论应用. 心理学报, 46(6), 876-884.]
[16]	Marcoulides. G. A. (1993). Maximizing power in generalizability studies under budget constraints. Journal of Educational Statistics, 18(2), 197-206.
[17]	Marcoulides, G. A., & Goldstein, Z. (1990). The optimization of generalizability studies with resource constraints. Educational & Psychological Measurement, 50(4), 761-768.
[18]	Meyer, P. J., Liu, X., & Mashburn, A. J. (2014). A practical solution to optimizing the reliability of teaching observation measures under budget constraints. Educational and Psychological Measurement, 74(2), 280-291. doi: 10.1177/0013164413508774 URL
[19]	Neri, F., & Tirronen, V. (2010). Recent advances in differential evolution: A survey and experimental analysis. Artificial Intelligence Review, 33(1-2), 61-106. doi: 10.1007/s10462-009-9137-2 URL
[20]	Qi, S., Dai, H., & Ding, S. (2002). Modern educational and psychological measurement. Beijing, China: Higher Education Press.
	[漆书青, 戴海崎, 丁树良. (2002). 现代教育与心理测量学原理. 北京: 高等教育出版社.]
[21]	Sanders, P. F. (1992). Alternative solutions for optimization problems in generalizability theory. Psychometrika, 57(3), 351-356. doi: 10.1007/BF02295423 URL
[22]	Sanders, P. F., Theunissen, T. J., & Baas, S. M. (1989). Minimizing the number of observations: A generalization of the Spearman Brown formula. Psychometrika, 54(4), 587-589. doi: 10.1007/BF02296398 URL
[23]	Stuart, A. (1954). A simple presentation of optimum sampling results. Journal of the Royal Statistical Society. Series B: Methodological, 16(2), 239-241.
[24]	Truong, Q. C., Choo, C., Numbers, K., Merkin, A. G., Brodaty, H., Kochan, N. A., Sachdev, P. S., Feigin, V. L., & Medvedev, O. N. (2021). Applying generalizability theory to examine assessments of subjective cognitive complaints: Whose reports should we rely on - participant versus informant? International Psychogeriatrics, 4, 1-11.
[25]	Vispoel, W. P., Xu, G., & Kilinc, M. (2020). Expanding G- theory models to incorporate congeneric relationships: Illustrations using the big five inventory. Journal of Personality Assessment, 103(1), 429-442. doi: 10.1080/00223891.2020.1808474 URL
[26]	Woodward, J., & Joe, G. (1973). Maximizing the coefficient of generalizability in multi-facet decision studies. Psychometrika, 38(2), 173-181. doi: 10.1007/BF02291112 URL
[27]	Yang, Z., & Chang, L. (2003). Generalizability theory and its applications. Beijing, China: Educational Science Publishing House.
	[杨志明, 张雷. (2003). 测评的概化理论及其应用. 北京: 教育科学出版社.]
[28]	Zhang, J., & Lin, C. K. (2016). Generalizability theory with one-facet nonadditive models. Applied Psychological Measurement, 40(6), 367-386. doi: 10.1177/0146621616651603 pmid: 29881060
[29]	Zheng, F., & Gao, X. (2018). A sufficient condition for conditional extreme value in using Lagrange multiplier method. Studies in College Mathematics, 21(2), 41-43.
	[郑芳英, 高雪芬. (2018). 拉格朗日乘子法求条件极值的充分条件. 高等数学研究, 21(2), 41-43.]
[30]	Zhu, Y., Fung, S., & Xin, T. (2013). Improving dependability of new HSK writing test Scores: A generalizability theroy based approach. Journal of Psychological Science, 36(2), 479-488.
	[朱宇, 冯瑞龙, 辛涛. (2013). 新HSK书写成绩可靠性影响因素的概化理论分析. 心理科学, 36(2), 479-488.]

项目	单价	单位成本
评教问卷工本费	1元/份	${{c}_{12}}$= 0.4元
被试费	8元/份
评教问卷邮递费	1元/份

项目	单价	单位成本
评教问卷工本费	1元/份	${{c}_{12}}$= 0.4元
被试费	8元/份
评教问卷邮递费	1元/份

条件组合	样本量组合
	20 × 5					20 × 10
	概化系数	最佳样本量n_i	最佳样本量n_r	设计花费	分析用时/s	概化系数	最佳样本量${{n}_{i}}$	最佳样本量n_r	设计花费	分析用时/s
微分优化法	0.819773870	13.1667055	6.4872856	100	0.002	0.85970836	18.9712839	7.26671699	150	0.0060
微分优化法	0.814549990	13	6	96.2	0.002	0.85844574	19	7	148.2	0.0060
拉格朗日法	0.819773870	13.1667055	6.4872856	100	0.006	0.85970836	18.9712839	7.26671699	150	0.0079
拉格朗日法	0.814549990	13	6	96.2	0.006	0.85844574	19	7	148.2	0.0079
柯西不等式法	0.819773870	13.1667055	6.4872856	100	0.006	0.85970836	18.9712839	7.26671699	150	0.0078
柯西不等式法	0.814549990	13	6	96.2	0.006	0.85844574	19	7	148.2	0.0078
约束进化算法	0.818306752	14.0492881	5.2942692	99.9	9.795	0.85935208	18.5389829	7.67551280	149.9	10.072
约束进化算法	0.814821502	14	5	98	9.795	0.86328631	19	8	155.8	10.072
条件组合	样本量组合
	40 × 5					40 × 10
	概化系数	最佳样本量n_i	最佳样本量n_r	设计花费	分析用时/s	概化系数	最佳样本量n_i	最佳样本量n_r	设计花费	分析用时/s
微分优化法	0.889393370	24.28057970	8.09258899	200	0.0034	0.906841124	29.4206630	8.74357291	250	0.00350
微分优化法	0.888094949	24	8	196.8	0.0034	0.906658958	29	9	249.4	0.00350
拉格朗日法	0.889393370	24.28057970	8.09258899	200	0.0027	0.906841124	29.4206630	8.74357291	250	0.00223
拉格朗日法	0.888094949	24	8	196.8	0.0027	0.906658958	29	9	249.4	0.00223
柯西不等式法	0.889393370	24.28057970	8.09258899	200	0.0025	0.906841124	29.4206630	8.74357291	250	0.00454
柯西不等式法	0.888094949	24	8	196.8	0.0025	0.906658958	29	9	249.4	0.00454
约束进化算法	0.888315630	24.01884929	8.03969713	200	9.9540	0.906071456	31.1473389	7.49944160	250	9.75300
约束进化算法	0.888094949	24	8	196.8	9.9540	0.903522912	31	7	241.8	9.75300

条件组合	样本量组合
	20 × 5					20 × 10
	概化系数	最佳样本量n_i	最佳样本量n_r	设计花费	分析用时/s	概化系数	最佳样本量${{n}_{i}}$	最佳样本量n_r	设计花费	分析用时/s
微分优化法	0.819773870	13.1667055	6.4872856	100	0.002	0.85970836	18.9712839	7.26671699	150	0.0060
微分优化法	0.814549990	13	6	96.2	0.002	0.85844574	19	7	148.2	0.0060
拉格朗日法	0.819773870	13.1667055	6.4872856	100	0.006	0.85970836	18.9712839	7.26671699	150	0.0079
拉格朗日法	0.814549990	13	6	96.2	0.006	0.85844574	19	7	148.2	0.0079
柯西不等式法	0.819773870	13.1667055	6.4872856	100	0.006	0.85970836	18.9712839	7.26671699	150	0.0078
柯西不等式法	0.814549990	13	6	96.2	0.006	0.85844574	19	7	148.2	0.0078
约束进化算法	0.818306752	14.0492881	5.2942692	99.9	9.795	0.85935208	18.5389829	7.67551280	149.9	10.072
约束进化算法	0.814821502	14	5	98	9.795	0.86328631	19	8	155.8	10.072
条件组合	样本量组合
	40 × 5					40 × 10
	概化系数	最佳样本量n_i	最佳样本量n_r	设计花费	分析用时/s	概化系数	最佳样本量n_i	最佳样本量n_r	设计花费	分析用时/s
微分优化法	0.889393370	24.28057970	8.09258899	200	0.0034	0.906841124	29.4206630	8.74357291	250	0.00350
微分优化法	0.888094949	24	8	196.8	0.0034	0.906658958	29	9	249.4	0.00350
拉格朗日法	0.889393370	24.28057970	8.09258899	200	0.0027	0.906841124	29.4206630	8.74357291	250	0.00223
拉格朗日法	0.888094949	24	8	196.8	0.0027	0.906658958	29	9	249.4	0.00223
柯西不等式法	0.889393370	24.28057970	8.09258899	200	0.0025	0.906841124	29.4206630	8.74357291	250	0.00454
柯西不等式法	0.888094949	24	8	196.8	0.0025	0.906658958	29	9	249.4	0.00454
约束进化算法	0.888315630	24.01884929	8.03969713	200	9.9540	0.906071456	31.1473389	7.49944160	250	9.75300
约束进化算法	0.888094949	24	8	196.8	9.9540	0.903522912	31	7	241.8	9.75300

条件组合	样本量组合
	5×15×5						5×15×10
	概化系数	最佳样本量n_i	最佳样本量n_o	最佳样本量n_r	设计花费	分析用时/s	概化系数	最佳样本量n_i	最佳样本量n_o	最佳样本量n_r	设计花费	分析用时/s
微分优化法	0.87817495	2.3127595	82.202016	4.2080120	800	0.012	0.88471850	2.5147869	80.646650	4.4376697	900	0.022
微分优化法	0.86539109	2	82	4	656	0.012	0.88810806	3	81	4	972	0.022
拉格朗日法	0.92365199	5.6781953	27.620465	6.6991252	1050.7	0.004	0.92652447	5.9837807	28.622702	6.9407586	1188.8	0.006
拉格朗日法	0.92704140	6	28	7	1176	0.004	0.92713459	7	34	8	1218	0.006
约束进化算法	0.88528957	5.7857628	49.674564	2.7834917	799.9	5.207	0.91616891	11.913346	10.781614	6.9123128	1000	5.218
约束进化算法	0.89205920	6	50	3	900	5.207	0.91748451	12	11	7	924	5.218
条件组合	样本量组合
	5×25×5						5×25×10
	概化系数	最佳样本量n_i	最佳样本量n_o	最佳样本量n_r	设计花费	分析用时/s	概化系数	最佳样本量n_i	最佳样本量n_o	最佳样本量n_r	设计花费	分析用时/s
微分优化法	0.89293562	2.682893	80.032004	4.657285	1000	0.032	0.89277702	2.7866442	79.717925	4.9517096	1100	0.041
微分优化法	0.90227221	3	80	5	1200	0.032	0.89713009	3	80	5	1200	0.041
拉格朗日法	0.93024553	6.187979	29.937401	7.132465	1321.3	0.008	0.92911955	6.3653751	30.705416	7.4224466	1450.7	0.009
拉格朗日法	0.92881883	6	30	7	1260	0.008	0.92562861	6	31	7	1302	0.009
约束进化算法	0.92295047	4.401688	23.866680	9.518668	994.8	5.203	0.92338934	6.1970158	23.784237	7.4631270	1098	5.350
约束进化算法	0.92057362	4	24	10	960	5.203	0.92043541	6	24	7	1008	5.350