1) Geological Process

The model [2] of the relationship of geologic reserves and ore average grade with ore boundary grade and ore industrial grade is:

View Source\begin{align*} Q_{1}=&f_{1} (p_{1},p_{2})=Q_{0} \\&\times \, \frac {\int _{p_{1}}^{p_{2}} {\varphi (x)g(x)c(x)dx} \!+\!\int _{p_{2}}^{100} {g(x)c(x)dx}}{\int _{p_{a} }^{p_{b}} {\varphi (x)g(x)c(x)dx} \!+\!\int _{p_{b}}^{100} {g(x)c(x)dx}} \tag{1}\\ \varphi (x)=&\left({\frac {x-p_{1}}{p_{2} -p_{1}}}\right)^{\textrm {z}}(p_{1} \le x\le p_{2}) \tag{2}\\ p_{3}=&f_{2} (p_{1},p_{2})=\frac {\int _{p_{1}}^{p_{2}} {x\varphi (x)c(x)dx} +\int _{p_{2}}^{100} {xc(x)dx}}{\int _{p_{1}}^{p_{2}} {\varphi (x)c(x)dx} +\int _{p_{2}}^{100} {c(x)dx}}\tag{3}\end{align*}

2) Mining Process

The ore characteristics and mining methods of each mining area are basically the same for an individual mine. In this case, there was some correlation between the dilution rate and the loss rate in the ore production process [1], and the relationship model is:

View Source\begin{equation*} c_{2} =f_{3} (c_{1})\tag{4}\end{equation*}

The dilution rate is the ratio of the difference between the ore average grade and the mining grade to the ore average grade:

View Source\begin{equation*} c_{2} =(p_{3} -p_{4})/p_{3}\tag{5}\end{equation*}

Rearranging equation (5), the mining grade can be calculated by equation (6):

View Source\begin{equation*} p_{4} =p_{3} (1-c_{2})\tag{6}\end{equation*}

Depending on the amount of metal conserved during mining, it can be calculated that:

View Source\begin{equation*} Q_{2} \times p_{4} =Q_{1} \times (1-c_{1})\times p_{3}\tag{7}\end{equation*}

Combining equations (6) and (7), the equation to calculate the mining amount is:

View Source\begin{equation*} Q_{2} =Q_{1} \frac {1-c_{1}}{1-c_{2}}\tag{8}\end{equation*}

3) Beneficiation Process

The concentration ratio is the ratio of the mining amount to the concentrate amount:

View Source\begin{equation*} c_{3} ={Q_{2}} \mathord {\Big /{ {\vphantom {{Q_{2}} {Q_{3}}}} } } {Q_{3}}\tag{9}\end{equation*}

For an individual mine, the characteristics of the mining ore, the processing technology, the equipment, and the agent can be assumed to be constant. In this case, there are relationships between ore concentration ratio and mining grade, between concentrate grade and mining grade, between concentrate grade and ore concentration ratio, and between concentrate grade and concentrate selling price [26], [27], [28], [29], [30]. These relationships are modeled by equations (10–12):

View Source\begin{align*} c_{3}=&f_{4} (p_{4}) \tag{10}\\ p_{5}=&f_{5} (p_{4},c_{3}) \tag{11}\\ q=&f_{6} (p_{5})\tag{12}\end{align*}

1) Modeling Strategy

Metal mining is conducted as a series of units. To take account of the lack of ore homogeneity, the deposit to be optimized is divided into zones that are optimized according to the ore characteristics. Each optimized zone has its own ore grade distribution. The ore is mined in sequence according to the quality of the optimized zone. However, mining each optimized zone requires decisions to be made regarding the technical indicators for that zone; zones are not isolated, so the decision affects subsequent mining decisions for other zones. Therefore, the dynamic relationships between optimized zones must be considered in optimization.

2) Objective Function

Profit calculations do not usually consider the time value of money, so using profits to calculate the return on investment of funds is not fruitful. Net present value not only considers the time value of a fund, but also facilitates the calculation of return on investment. We therefore used net present value as the measure of the economic benefit of metal mine production to be optimized. The objective function of the technical indicator optimization model of metal mine production based on the economic benefit is therefore:

View Source\begin{equation*} \max \theta =\sum \limits _{i=1}^{N} {\theta _{i}}\tag{13}\end{equation*}

Since the mining decision of the optimized zone mined first affects the starting time of the mining of subsequent optimized zones, the net present value is a function of time. Therefore, the net present value of each optimization zone is not independent but has a dynamic relationship with the net present values of other optimized zones. When the starting time of mining is 0, the calculation process for the net present value of optimized zone $i$ is as follows.

1. Calculate the mining time $t_{i}$ of optimized zone $i$ :

   $$\begin{equation*} t_{i} =\frac {Q_{2,i}}{Qz}\tag{14}\end{equation*}$$ View Source\begin{equation*} t_{i} =\frac {Q_{2,i}}{Qz}\tag{14}\end{equation*} where $Q_{2,i}$ is the total mining quantity of optimized zone $i$ , and $Qz$ is the annual production capacity.

2. The mining start time $T_{1,i}$ of optimized zone $i$ is the sum of the mining times of each previously optimized zone, and is calculated by equation (15):

   $$\begin{equation*} T_{1,i} =\sum \limits _{j=1}^{j=i-1} {t_{j}}\tag{15}\end{equation*}$$ View Source\begin{equation*} T_{1,i} =\sum \limits _{j=1}^{j=i-1} {t_{j}}\tag{15}\end{equation*}

3. The mining end time $T_{2,i}$ of optimized zone $i$ is:

   $$\begin{equation*} T_{2,i} =\sum \limits _{j=1}^{j=i} {t_{j}}\tag{16}\end{equation*}$$ View Source\begin{equation*} T_{2,i} =\sum \limits _{j=1}^{j=i} {t_{j}}\tag{16}\end{equation*}

4. The total profit $G_{i}$ of optimized zone $i$ is:

   $$\begin{equation*} G_{i} =Q_{3,i} \ast q_{i} -Q_{2,i} \ast h\tag{17}\end{equation*}$$ View Source\begin{equation*} G_{i} =Q_{3,i} \ast q_{i} -Q_{2,i} \ast h\tag{17}\end{equation*} where $Q_{3,i}$ is the concentrate amount in optimized zone $i$ ; $q_{i}$ is the selling price of the concentrate in optimized zone $i$ ; and $h$ is the total production cost per unit of ore.

5. The average annual profit $g_{i}$ of optimized zone $i$ is:

   $$\begin{equation*} g_{i} =\frac {G_{i}}{t_{i}}\tag{18}\end{equation*}$$ View Source\begin{equation*} g_{i} =\frac {G_{i}}{t_{i}}\tag{18}\end{equation*}

6. Total net present value of optimized zone $i$ is:

   $$\begin{align*} \theta _{i} =\begin{cases} \frac {g_{i} ^{\ast} (T_{2,i} -T_{1,i})}{(1+d)^{T_{_{1,i}}^{^{-}}}} \textrm {}T_{1,i}^{-}=T_{2,i}^{-} \\ g_{i} ^{\ast} \left ({{\begin{array}{l} \frac {(T_{1,i}^{-}+1-T_{1,i})}{(1+d)^{T_{_{1,i}} ^{^{-}}}}+\frac {1}{(1+d)^{T_{_{1,i}}^{^{-}}+1}}+ \\ \cdots +\frac {1}{(1+d)^{T_{2,i}^{-}-1}}+\frac {(T_{2,i} -T_{2,i} ^{-})}{(1+d)^{T_{2,i}^{-}}} \\ \end{array}} }\right) else \\ \end{cases}\tag{19}\end{align*}$$ View Source\begin{align*} \theta _{i} =\begin{cases} \frac {g_{i} ^{\ast} (T_{2,i} -T_{1,i})}{(1+d)^{T_{_{1,i}}^{^{-}}}} \textrm {}T_{1,i}^{-}=T_{2,i}^{-} \\ g_{i} ^{\ast} \left ({{\begin{array}{l} \frac {(T_{1,i}^{-}+1-T_{1,i})}{(1+d)^{T_{_{1,i}} ^{^{-}}}}+\frac {1}{(1+d)^{T_{_{1,i}}^{^{-}}+1}}+ \\ \cdots +\frac {1}{(1+d)^{T_{2,i}^{-}-1}}+\frac {(T_{2,i} -T_{2,i} ^{-})}{(1+d)^{T_{2,i}^{-}}} \\ \end{array}} }\right) else \\ \end{cases}\tag{19}\end{align*} where $T_{1,i}^{-}$ is the integer part of $T_{1,i}$ ; $d$ is the annual discount rate; and $T_{2,i}^{-}$ is the integer part of $T_{2,i}$ .

3) Constraints

1. The boundary grade is not higher than the industrial grade:

   $$\begin{equation*} p_{1,i} \le p_{2,i}\tag{20}\end{equation*}$$ View Source\begin{equation*} p_{1,i} \le p_{2,i}\tag{20}\end{equation*} where $p_{1,i}$ is the boundary grade of optimized zone $i$ , and $p_{2,i}$ is the industrial grade of optimized zone $i$ .

2. The concentrate grade is not less than the minimum smelting grade:

   $$\begin{equation*} p_{5,i} \ge p_{y}\tag{21}\end{equation*}$$ View Source\begin{equation*} p_{5,i} \ge p_{y}\tag{21}\end{equation*} where $p_{5,i}$ is the concentrate grade of optimized zone $i$ , and $p_{y}$ is the lowest smelting grade.

4) Optimization Model

Combining the above objective function and constraints, the technical indicator optimization model for metal mine production to maximize economic benefit is:

View Source\begin{align*} \begin{cases} \max \theta =\sum \limits _{i=1}^{N} {\theta _{i}} \\ s.t.{\begin{array}{c} {p_{1,i} \le p_{2,i}} \\ {p_{5,i} \ge p_{y}} \\ \end{array}} \\ \end{cases}\tag{22}\end{align*}

1) Relationship Between Orebody Weight and Grade

A scatter plot of the orebody weight and copper grade was plotted from the 204 items of orebody weight and grade data collected from the Yinshan copper mine, as shown in Figure 3. There was no correlation between orebody weight and copper grade. The results show that there was no relationship between orebody weight and copper grade and that orebody weight was not affected by copper grade. We therefore used the average value of the orebody weight for the ore weight function of the Yinshan copper mine. The mathematical function is:

View Source\begin{equation*} g_{1} (\text {x})=2.85\tag{23}\end{equation*}

FIGURE 3.

Scatter plot of orebody weight and copper grade of the Yinshan copper mine.

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2) Probability Density Function of the Copper Grade Distribution

The copper grade distribution was fitted using kernel density estimation based on the characteristics and attributes of the data without any prior knowledge. This method provided better fitting of the probability density function than parameter estimation. Kernel density estimation was used to fit the probability density distribution of the Yinshan copper mine ore grade. Fitting did not result in a particular function or mathematical expression. Figure 4 shows that kernel density estimation well fitted the ore grade distribution.

FIGURE 4.

Fitting results of copper grade distribution in the Yinshan copper mine (optimized zones 1–5) for comparison.

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3) Relationship Between Loss Rate and Dilution Rate

Aiming for an ore body of −48 to −192 m in the Yinshan copper mine, open-pit mining was used. The copper dilution and loss rates were collected for 64 items of open-pit mining data. Scatter plots of the copper dilution rate and loss rate were plotted, as shown in Figure 5. It can be seen from Figure 5 that there was no correlation between copper dilution rate and loss rate. The correlation coefficient between copper dilution rate and loss rate was −0.0771, and the F-test was significant at a level of 0.5449, which was >0.05. There was therefore no relationship between copper dilution rate and loss rate. In the subsequent optimization, the values used for both dilution rate (2%) and loss rate (9%) were the planned values.

FIGURE 5.

Scatter plot of the copper loss rate and dilution rate of the Yinshan copper mine.

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4) Relationship Between Mining Grade and Concentrate Ratio

The scatter plot for 630 items of ore dressing data, mining grade and concentrate ratio, that were collected from the Yinshan copper mine is shown in Figure 6. It can be seen from the figure that mining grade is exponentially related to concentrate ratio. The exponential function was used for regression fitting, and the correlation coefficient was −0.8445. The F test was significant at the level $1.89\times 10 ^{-172}$ . Since the significance level was much less than 0.05, the regression was significant and the regression model can be applied. The exponential function used to fit the relationship between mining grade and concentrate ratio is equation (24):

View Source\begin{equation*} c_{3} =136\ast e^{-2.29^{\ast} p_{4}}\tag{24}\end{equation*}

FIGURE 6.

Exponential function fitting the relationship between mining grade and concentration ratio for the Yinshan copper mine.

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5) Concentrate Grade

A BP neural network [34], [35], [36], [37] was used to determine the relationships between copper mining grade and concentrate grade and between concentrate ratio and concentrate grade in the Yinshan copper mine. A total of 630 data items were collected; the training sample consisted of the first 530 data items, and the test sample was the remaining 100 items; mining grade and concentrate ratio were used as inputs, and the copper ore concentrate grade was the output. There were two nodes in both the input and hidden layers and one node in the output layer. The transfer functions used in the training function, input layer and output layer were respectively traingdm, tansigand purelin. The learning rate was 0.1, training error accuracy was 0.001, and the maximum number of iterations was 2500. The fitting diagram of copper concentrate grade produced by the BP neural network is shown in Figure 7.

FIGURE 7.

Fitting results of the copper ore concentrate grade of the Yinshan copper mine using BP neural network.

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Figure 7 shows that for the fitting, the coefficient of determination $R^{2}$ was 0.939, mean absolute error MAE was 0.258, and root mean square error RMSE was 0.307. $R^{2}$ was >0.9, and both MAE and RMSE were <0.5. These results indicate that the BP neural network well fitted the model of the relationships of copper mining grade with concentrate grade and concentrate ratio with concentrate grade in the Yinshan copper mine.

6) Copper Ore Concentrate Price

The market transaction price of copper ore concentrate is based mainly on a 20% concentrate grade (#1 grade), and the price of any other copper ore concentrate grade is a function of this price. The price adjustment factors and the compensation prices are shown in Table 3. The copper ore concentrate price $q$ is calculated by equation (25):

View Source\begin{equation*} q=f_{6} (p_{5})=k_{1} \times p_{5} \times \lambda +k_{2}\tag{25}\end{equation*}

TABLE 3 Compensation Prices and Price Adjustment Coefficients of Different Copper Concentrate Grades

1) Decision Variables

In the model of relationships between the technical indicators of the Yinshan copper mine described in Subsection A, Section III, boundary grade, industrial grade, loss rate, and dilution rate are independent variables and are not affected by other indicators; geological ore reserves, ore average grade, mining grade, mining amount, concentration ratio, concentrate grade, concentrate amount, and ore mining grade are dependent variables. When the value of an independent variable has been determined, the value of any variable dependent on it has also been influenced. Therefore, the independent variable is the decisive variable in optimization.

The dilution rate and loss rate depend on ore body characteristics and mining technology, which are basically unchanged over a short period of time. These two variables were therefore taken to be constant for each optimization zone, and the values are the planned values. Dilution rate was 2% and loss rate was 9%. Boundary grade and industrial grade of each optimization unit are thus the decision variables of the optimization model; there are 10 decision variables for the five optimization zones.

2) Setting Parameters

The parameters of the AADE algorithm were set as follows. The dimension $D_{T}$ of the decision variable was set to 10; the initialization population size $NP$ was set to 50; the maximum number of iterations $G_{\max }$ was set to 100; and the adaptive control parameters $\psi$ , $\varphi$ , $\delta _{l}$ and $\delta _{u}$ were respectively set to 0.7, 0.1, 0, and 1. Encoding of the related evolutionary algorithms was real number encoding. The parameters of the Yinshan copper mine and the AADE algorithm are given in Table 4.

TABLE 4 Parameters of Yinshan Copper Mine and AADE Algorithm