延安市宝塔区土壤养分地球化学评价中的变权效果

doi:10.11720/wtyht.2020.1532

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Abstract

Based on the theory of variable weight, the authors used the weight of the state vector measured by the divergence degree to regulate the demand force, the weight of the variable state vector identified by the adjustment degree regulated the supply force, and the weight level of the adjustment weight weighed the balance point between the two so as to select the appropriate state. Change vector, a comprehensive evaluation model of soil nutrient geochemical transformation power, was constructed to solve the problem of evaluation distortion due to the difficulty of highlighting the restrictive effect of nutrient element. The results show that the method is easy to operate and can reflect the changing law of soil nutrient element. The weight vector of product and sum state is difficult to control because of its adjustment degree, and its application range is limited. However, the adjustment degree of exponential state variable vector varies with parameters, the adjustment effect is easy to control, and the application is wide, and it has a good change effect. The soil nutrient data in the pagoda area has low dispersion and high equilibrium. The comprehensive determination of the weight adjustment level is 0.8, the power parameter α= 2.524 8, and the weight is transferred to N and Corg. The penalty is reasonable, and the comprehensive evaluation level of soil nutrients is scientifically adjusted. The grade changes from second class to third class, 42 third class to fourth class, and 131 fourth class to fifth grade, and N and Corg are identifiedas the short plate elements of soil nutrients in the pagoda area which overall limit the improvement of soil nutrient quality.The results obtained by the authors providea necessary basis for scientific improvement of the soil under local conditions.

Key words： state variable weights vector dispersion degree adjustment degree soil nutrient assessment level of adjusting weights

Received: 10 November 2019 Published: 28 August 2020

:	P596
	S153.6

Corresponding Authors: Tuo LIU E-mail: 331559202@qq.com;379937608@qq.com

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	Peng WANG
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Cite this article:

Peng WANG,Tuo LIU. Variational weight effect in the geochemical evaluation of soil nutrients in Baota District of Yan'an City[J]. Geophysical and Geochemical Exploration, 2020, 44(4): 847-854.

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https://www.wutanyuhuatan.com/EN/10.11720/wtyht.2020.1532 OR https://www.wutanyuhuatan.com/EN/Y2020/V44/I4/847

类别	均衡函数	状态变权向量	变权向量
常权		S₁(X)=S₂(X)=…=S_m(X)	w_j(X_j)=w_j
积型	$B (X) = ∏ j = 1 m x j α (α ∈ [0,1])$	$S I (x 1, x 2, …, x m) ? ∏ i = 1, i ≠ j m x j$	$w j (x 1, x 2, …, x m) = w j x j ∑ j = 1 m w j x j$
和型	$B (X) = ∑ j = 1 m x j α (α ∈ [0,1])$	S_j(x₁,x₂,…,x_m)= $x j α$	$w j (X) = w j x j α - 1 / ∑ j = 1 m w j x j α - 1$
指数型	B(X)=e^-^αx(α≥0)	S_j(x₁,x₂,…,x_m)= $e - α (x j - n)$	w_j(X_j)=w_j/[w_j+(1-w_j)e^-^α]

Common state variable vector

Location of the study area

仿真方案	状态变权向量S_j(X)		变权向量w_j(X_j)
仿真方案	类型	参数α值	变权向量w_j(X_j)
常权	和型	1	w_j
和型1	和型	0.6	$w j x j α - 1 / ∑ j = 1 m w j x j - 0.4$
和型2	和型	0.2	$w j x j α - 1 / ∑ j = 1 m w j x j - 0.8$
积型	和型	0	$w j x j - 1 / ∑ j = 1 m w j x j - 1$
指数3	指数型	3	w_j/[w_j+(1-w_j)e^-3]
指数2	指数型	2	w_j/[w_j+(1-w_j)e^-2]
指数1	指数型	1	w_j/[w_j+(1-w_j)e^-1]

State variable weight vector and variable weight vector of different simulation schemes

Evaluation results of different simulation schemes

Statistics of weight adjustment of soil sample evaluation grades with different simulation schemes

Dispersion of soil nutrient data

Statistical of regulation frequency for different simulation schemes

Level of adjusting weights of different simulation schemes

Statistics on changes in soil sample evaluation grade adjustment

Comparison between variable weight evaluation and constant weight evaluation

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