基于效益风险均衡的径流组分模型优选准则

doi:10.11988/ckyyb.20240228

摘要/Abstract

摘要：

径流组成成分识别是水文分析的一项重要内容,但目前在组分模型形式选择方面仍缺乏统一的准则,导致建模时组分类型及分离顺序难以确定。考虑突变、趋势、周期成分等组分类型,构建不同的线性叠加模型对变化长度径流序列的组成成分进行动态识别,在分析不同模型的识别精度及其随时间变化特征的基础上,提出了基于效益风险均衡的径流组分模型选择准则。以金沙江下游屏山站1956—2010年的径流序列为实例,对所提模型选择准则进行了应用分析。结果表明,径流成分识别受到模型形式和序列长度的共同影响,识别精度越高的模型在应对序列长度变化时具有相对越低的稳定性,所提准则为径流组分模型选择提供了一种均衡考量识别精度(效益)和稳定性(风险)的思路。

关键词: 径流组分模型, 选择准则, 线性叠加模型, 效益风险均衡, 变化径流序列

Abstract:

[Objectives] Identification of runoff components is a key aspect of hydrological analysis and is crucial for understanding the evolution patterns of watershed water resources. Traditional runoff component models are often constructed based on the criterion of maximizing the extraction accuracy of deterministic components for the runoff series of a given length. However, a unified criterion for selecting model forms that adapt to variations in runoff series length over time is still lacking, making it difficult to determine the types of runoff components and the order of their separation during modeling. To address this, this study proposes a selection criterion for runoff component models based on the balance between benefits and risks. [Methods] Based on the diagnosis and quantitative description of evolution characteristics such as mutations, trends, and periodicities using time-series variability detection methods—the Mann-Kendall test, sliding T-test, Pettitt test, Standard Normal Homogeneity test, Buishand test, and periodogram—different forms of linear superposition models were developed by combinations and extraction sequences of the identified components, such as mutation, trend, and periodicity. These models were then employed to dynamically identify the components of runoff sequences with varying lengths. The accuracy of deterministic component identification was used to represent the “benefits” achieved by the model in runoff component recognition, while the magnitude of fluctuations in model accuracy under varying runoff sequences (i.e., stability) was regarded as the “risk”. A weighting coefficient representing the decision-maker’s preferences was introduced as a balancing variable to construct a benefit-risk balance indicator. Subsequently, runoff component models were optimized based on the criterion of minimizing this benefit-risk balance indicator. [Results] Using the runoff sequence from 1956 to 2010 at the Pingshan Station on the lower reaches of the Jinsha River as a case study, variable-length runoff sequences (with sample sizes ranging from 30 to 55) were constructed, starting from 1956 and ending in any year from 1986 to 2010. Runoff component identification was conducted under different model forms, and the proposed benefit-risk balance criterion was applied for model selection analysis. The results indicated mutual offsetting among components such as mutations, trends, and periodicities in the runoff sequence, and the same runoff sequence could be characterized by multiple models, each representing distinct compositional forms of runoff components. Runoff component identification was jointly influenced by both the model form and the sequence length; models with higher identification accuracy exhibited relatively lower stability when responding to changes in sequence length. For instance, models incorporating periodic components demonstrated superior fitting accuracy compared to those containing only trend or mutation terms, which in turn outperformed multi-year average models, while the stability of accuracy changes followed the opposite trend. If the decision-making objective was to achieve a more adequate fitting, models that sequentially separate mutations and periodic components are prioritized; conversely, if the objective was to maintain more stable accuracy with varying sequence lengths, models that identify only mutation or trend terms were more advantageous. [Conclusions] A novel approach is proposed in this study for selecting component models of variable-length runoff sequences by balancing identification accuracy (benefit) and stability (risk). Both the accuracy and stability indicators proposed in the criterion can be flexibly defined according to decision-making needs, facilitating decision-makers in comprehensively considering their preferences for model accuracy and stability under varying conditions to optimize model selection.

Key words: runoff component model, model selection criterion, linear superposition model, benefit-risk balance, variable-length runoff sequences

中图分类号:

TV21水资源调2查与水利规划

丁小玲, 胡维忠, 唐海华, 罗斌, 冯快乐. 基于效益风险均衡的径流组分模型优选准则[J]. raybet体育在线院报, 2025, 42(6): 21-28.

DING Xiao-ling, HU Wei-zhong, TANG Hai-hua, LUO Bin, FENG Kuai-le. Optimal Selection Criterion for Runoff Component Models Based on Benefit-Risk Balance[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(6): 21-28.

图/表 8

表1 不同分离顺序和组合方式的径流成分识别方案

Table 1 Runoff component identification schemes under different separation orders and combination methods

成分类别	方案名称	分离顺序和组合方式	输入时间序列
突变成分	mutation	基于实测序列识别突变成分	$X (t)$
突变成分	T-mutation	实测序列剔除趋势项后识别突变成分	$X (t) - T (t)$
趋势成分	trend	基于实测序列识别趋势成分	$X (t)$
趋势成分	M-trend	实测序列剔除突变项后识别趋势成分	$X (t) - M (t)$
周期成分	period	基于实测序列的距平序列识别周期成分	$X (t)$
	M-period	实测序列剔除突变项后识别周期成分	$X (t) - M (t)$
	m-t-period	实测序列依次剔除突变和趋势项后识别周期成分	$X (t) - M (t) - T (t)$
	t-period	实测序列剔除趋势项后识别周期成分	$X (t) - T (t)$
	t-m-period	实测序列依次剔除趋势和突变项后识别周期成分	$X (t) - T (t) - M (t)$

表1 不同分离顺序和组合方式的径流成分识别方案

Table 1 Runoff component identification schemes under different separation orders and combination methods

成分类别	方案名称	分离顺序和组合方式	输入时间序列
突变成分	mutation	基于实测序列识别突变成分	$X (t)$
突变成分	T-mutation	实测序列剔除趋势项后识别突变成分	$X (t) - T (t)$
趋势成分	trend	基于实测序列识别趋势成分	$X (t)$
趋势成分	M-trend	实测序列剔除突变项后识别趋势成分	$X (t) - M (t)$
周期成分	period	基于实测序列的距平序列识别周期成分	$X (t)$
	M-period	实测序列剔除突变项后识别周期成分	$X (t) - M (t)$
	m-t-period	实测序列依次剔除突变和趋势项后识别周期成分	$X (t) - M (t) - T (t)$
	t-period	实测序列剔除趋势项后识别周期成分	$X (t) - T (t)$
	t-m-period	实测序列依次剔除趋势和突变项后识别周期成分	$X (t) - T (t) - M (t)$

表2 基于不同成分识别方案构建的径流组分模型

Table 2 Runoff component models constructed based on different component identification schemes

序号	模型名称	模型识别的确定性成分
1	M(mut_tre_period)	突变+趋势+周期+均值
2	M(tre_mut_period)	趋势+突变+周期+均值
3	M(mut_period)	突变+周期+均值
4	M(tre_period)	趋势+周期+均值
5	M(period)	周期+均值
6	M(mut_trend)	突变+趋势+均值
7	M(tre_mutation)	趋势+突变+均值
8	M(mutation)	突变+均值
9	M(trend)	趋势+均值
10	M(mean)	均值(多年平均值)

图1 Mutation和T-Mutation方案的变化径流序列突变成分对比

Fig.1 Comparison of mutation components in altered runoff sequences under Mutation and the T-Mutation schemes

图2 Trend和M-Trend方案的变化径流序列趋势成分对比

Fig.2 Comparison of trend components in altered runoff sequences under Trend and the M-Trend schemes

图3 5种不同方案的变化径流序列周期性识别结果对比

Fig.3 Comparison of periodicity identification results for variable runoff sequences across five different schemes

图4 不同模型的变化径流序列拟合精度对比

Fig.4 Comparison of fitting accuracy for variable runoff sequences across different models

表3 不同模型的变化径流序列拟合精度统计指标

Table 3 Statistical indicators of fitting accuracy for variable runoff sequences across different models

模型名称	均值		标准差
模型名称	PC	RMSE/ (m³·s^-1)	PC	RMSE/ (m³·s^-1)
M(m-t-period)	0.56	557	0.16	59
M(t-m-period)	0.54	567	0.15	55
M(M-period)	0.57	569	0.13	65
M(t-period)	0.54	568	0.15	56
M(Period)	0.56	575	0.12	63
M(M-trend)	0.23	658	0.18	17
M(T-mutation)	0.18	669	0.15	18
M(mutation)	0.40	661	0.08	17
M(trend)	0.11	684	0.05	23
M(mean)	—	689	—	25

表4 基于不同权重系数 α的模型效益风险均衡指标对比

Table 4 Comparison of benefit-risk balance indicators for models based on different weighting coefficients

精度指标	模型名称	不同权重系数 $α$ 的模型效益风险均衡指标对比
精度指标	模型名称	0	0.2	0.5	0.8	1
PC	M(m-t-period)	0.16	0.02	-0.20	-0.42	-0.56
	M(t-m-period)	0.15	0.01	-0.20	-0.40	-0.54
	M(M-period)	0.13	-0.01	-0.22	-0.43	-0.57
	M(t-period)	0.15	0.01	-0.20	-0.40	-0.54
	M(period)	0.12	-0.02	-0.22	-0.42	-0.56
	M(M-trend)	0.18	0.10	-0.03	-0.15	-0.23
	M(T-mutation)	0.15	0.08	-0.02	-0.11	-0.18
	M(mutation)	0.08	-0.02	-0.16	-0.30	-0.40
	M(trend)	0.05	0.02	-0.03	-0.08	-0.11
RMSE	M(m-t-period)	59	159	308	457	557
	M(t-m-period)	55	157	311	465	567
	M(M-period)	65	166	317	468	569
	M(t-period)	56	158	312	466	568
	M(period)	63	165	319	473	575
	M(M-trend)	17	145	338	530	658
	M(t-mutation)	18	148	344	539	669
	M(mutation)	17	146	339	532	661
	M(trend)	23	155	354	552	684
	M(mean)	25	158	357	556	689

表4 基于不同权重系数 α的模型效益风险均衡指标对比

Table 4 Comparison of benefit-risk balance indicators for models based on different weighting coefficients

精度指标	模型名称	不同权重系数 $α$ 的模型效益风险均衡指标对比
精度指标	模型名称	0	0.2	0.5	0.8	1
PC	M(m-t-period)	0.16	0.02	-0.20	-0.42	-0.56
	M(t-m-period)	0.15	0.01	-0.20	-0.40	-0.54
	M(M-period)	0.13	-0.01	-0.22	-0.43	-0.57
	M(t-period)	0.15	0.01	-0.20	-0.40	-0.54
	M(period)	0.12	-0.02	-0.22	-0.42	-0.56
	M(M-trend)	0.18	0.10	-0.03	-0.15	-0.23
	M(T-mutation)	0.15	0.08	-0.02	-0.11	-0.18
	M(mutation)	0.08	-0.02	-0.16	-0.30	-0.40
	M(trend)	0.05	0.02	-0.03	-0.08	-0.11
RMSE	M(m-t-period)	59	159	308	457	557
	M(t-m-period)	55	157	311	465	567
	M(M-period)	65	166	317	468	569
	M(t-period)	56	158	312	466	568
	M(period)	63	165	319	473	575
	M(M-trend)	17	145	338	530	658
	M(t-mutation)	18	148	344	539	669
	M(mutation)	17	146	339	532	661
	M(trend)	23	155	354	552	684
	M(mean)	25	158	357	556	689

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