JP6985833B2 - Data processing equipment, control systems, data processing methods and programs - Google Patents

Description

The present invention relates to a data processing apparatus, a control system, a data processing method and a program.

Conventionally, for the purpose of advancing production control technology in plants, distributed control systems (DCS: Distributed Control System) that continuously control processes such as manufacturing and data processing devices to support the functions have been proposed. ing. In the example shown in FIG. 3, the process control system 9 is configured in the plant PL. The process control system 9 includes control devices 70-1 and 70-2 for controlling processes 80-1 and 80-2, and a data processing device 90. In the data processing device 90, the process data collection unit 120 collects process data including the process value of each process. The process value includes an output value from the process acquired via the sensors 82-1 and 82-2 and an input value to the process supplied to the actuators 84-1 and 84-2.

Attempts are being made to use the collected process data to improve plant operations. For example, application to optimization between processes by plant data (plant big data) acquired from control systems installed in large-scale factories, sophistication of control / prediction functions, brand change support, DCS update, function addition, etc. Is expected. Therefore, in the data processing device 90 shown in FIG. 3, the process data analysis unit 122 that analyzes the process data, the process optimization unit 130 that optimizes the control parameters in the process, the identified process, and the obtained control parameters are used. A process simulation unit 140 for calculating a process value in each process is provided. These functions support the work of engineers involved in operational improvement such as operational monitoring and adjustment of operational status.

Fumiaki Uozumi, Osamu Kaneko and Shigeru Yamamoto, “Fictitious Reference Iterative Tuning of Disturbance Observers for Attenuation of the Effect of Periodic Unknown Exogenous Signals”, 11th IFAC (International Federation of Automatic Control) International Workshop on Adaptation and Learning in Control and Signal Processing, July 3-5, 2013

However, even an engineer who is familiar with the operation and behavior of a process may require a considerable amount of work (man-hours) in the process of obtaining a solution for improving the operation. If man-hours that are directly linked to labor costs are required, it can be a cause that does not lead to actual business in terms of cost effectiveness. Further, the cause of the increase in man-hours is that a large number of processes are usually provided in the plant, and mutual interference occurs between the processes. Therefore, it is desirable to reduce the amount of work related to improving plant operations such as data identification, analysis work, and simulation work that have a major effect on process fluctuations.

The present invention has been made in view of the above points, and an object of the present invention is to provide a data processing device, a control system, a data processing method, and a program capable of reducing the work related to the operation improvement of the plant.

(1) The present invention has been made to solve the above problems, and one aspect of the present invention is a machine with respect to an input value for at least one process and an actually measured output value which is an output value from the process. The output prediction model generation unit that performs training to generate the output prediction model of the process, calculates the predicted output value that is the predicted value of the output value based on the output prediction model and the input value, and calculates the predicted output value. A data processing device including a control parameter information generation unit that defines control parameters of a control device that controls the process so that the difference between the output value and the target value of the output value from the process is reduced.

(2) Another aspect of the present invention is the above-mentioned data processing apparatus, which is an input value for a second process separate from the first process, which is the process, and an actual measurement output, which is an output value from the second process. The process identification unit that calculates the transfer function of the second process based on the value is further provided, and the control parameter information generation unit is the first based on the transfer function of the second process and the input value for the second process. The predicted output value from the two processes is calculated, and the control parameter for each process is determined so that the difference between the predicted output value and the target value in each process is reduced.

(3) Another aspect of the present invention is the above-mentioned data processing apparatus, in which a cost value indicating the magnitude of the deviation between the predicted output value and the target value for each process of the first process and the second process is calculated. Then, the cost value obtained as the sum of the multiplication values obtained by multiplying the cost value for each process by the weighting coefficient is used as an evaluation function, and the control parameters for each process are determined so that the evaluation function is reduced.

(4) Another aspect of the present invention is the above-mentioned data processing apparatus, in which a square error is used as a cost value for each process.

(5) Another aspect of the present invention is the above-mentioned data processing apparatus, in which the degree of contribution to the output value from the process to be analyzed is predetermined from the process data for each process including the input value and the output value. It is further provided with a process data analysis unit that specifies an input value higher than the contribution of the above or an output value of another process and extracts valid data including the specified input value or output value.

(6) Another aspect of the present invention is the above-mentioned data processing apparatus, and the output prediction model is an output prediction model expressed by a neural network.

(7) Another aspect of the present invention is a control system including the above-mentioned data processing device and a control device for controlling the process.

(8) Another aspect of the present invention is a data processing method in a data processing apparatus, wherein machine learning is performed on an input value for at least one process and an actually measured output value which is an output value from the process. The output prediction model generation process for generating the output prediction model of the process, the predicted output value which is the predicted value of the output value is calculated based on the output prediction model and the input value, and the predicted output value and the process are used. It is a data processing method including a control parameter information generation process that defines a control parameter of a control device that controls the process so that a difference between an output value and a target value is reduced.

(9) In another aspect of the present invention, the computer of the data processing device is subjected to machine learning on the input value for at least one process and the actually measured output value which is the output value from the process to predict the output of the process. An output prediction model generation procedure for generating a model, a predicted output value which is a predicted value of the output value based on the output prediction model and the input value, and a target of the predicted output value and the output value from the process. This is a program for executing a control parameter information generation procedure that defines control parameters of a control device that controls the process so that the difference from the target value is reduced.

According to the present invention, it is possible to reduce the work related to the improvement of the operation of the plant.

It is a block diagram which shows one configuration example of the process control system which concerns on this embodiment. It is explanatory drawing which shows the calculation example of the output prediction model and the control parameter which concerns on this embodiment. It is a block diagram which shows one configuration example of the conventional process control system.

Hereinafter, embodiments of the data processing apparatus, process control system, data processing method, and program of the present invention will be described with reference to the drawings.

(Process control system)
First, a configuration example of the process control system according to the present embodiment will be described.
FIG. 1 is a block diagram showing a configuration example of the process control system 1 according to the present embodiment.
The process control system 1 includes a data processing device 10 and a plurality of control devices 70 (controllers). In the example shown in FIG. 1, the number of control devices 70 is two. Further, in the following description, the plurality of control devices 70, their components, and related devices are distinguished from, for example, control devices 70-1, 70-2, etc. by using child numbers. When the individual control devices 70 are not distinguished, they are simply referred to as control devices 70. The number of control devices 70 is not necessarily limited to two, and may be three or more.
Further, the data processing device 10 and the control device 70 are connected to each other so as to be able to communicate with each other via a network. The network is composed of any or a combination of the Internet, a public communication network, a local area network (LAN), and a dedicated line. Further, the network may be wireless or wired.

The process control system 1 further includes a monitoring device (not shown). The monitoring device is, for example, an HMI (Human Machine Interface) for an engineer to monitor the operating state of a process and set various setting values for controlling the operating state. The monitoring device is connected to the network and receives an output value, which is a measured value indicating the state of each process of the plant PL, from each control device 70 at predetermined time (for example, 1 minute). The monitoring device includes, for example, a display unit (not shown) that displays measured values at each time point. The monitoring device includes an operation input unit (not shown) that sets a target value of a process to be a control target according to an operation. The monitoring device transmits the set target value to the control device 70 to be set. In this way, the process control system 1 is configured as a DCS in which a plurality of control devices 70 are distributed and arranged.

The data processing device 10 has a function of acquiring process data indicating a process value indicating the state of each process 80 from each control device 70 and supporting the operation improvement of the process 80 based on the acquired process data. The process value includes an input value, an output value, and a target value as a control target of the process 80. The data processing device 10 performs machine learning on an input value to at least one process 80 to be analyzed and an actually measured output value which is an output value from the process 80, and an output prediction showing an input / output relationship in the process 80. Generate a model. Further, the data processing device 10 calculates a predicted output value, which is a predicted value of the output value, based on the output prediction model and the input value. The data processing device 10 determines (optimized) control parameters so that the difference between the predicted output value and the control target value for the process 80 is reduced. Further, the data processing device 10 calculates an input value and an output value in the process by using the generated output prediction model and control parameters (simulation). The data processing device 10 provides the control device 70 that controls the process with respect to the determined control parameters.

The control device 70 determines the operating state of the process based on the output value input from the sensor 82 provided in the plant PL at predetermined time intervals and the target value received from the monitoring device as the measured value indicating the state of the process 80. Control continuously in time (continuous control). The control device 70 includes a control calculation unit 72. The control calculation unit 72 is, for example, a PID controller that executes PID control. The PID control is a method of calculating the sum of the proportional term P, the integral term I, and the differential term D as an operation amount, and outputting the obtained operation amount to the actuator 84 that controls the process. The proportional term P is obtained by multiplying the deviation obtained by subtracting the output value from the target value at that time by a predetermined proportional gain K _P. Integral term I is obtained by multiplying a predetermined integral gain K _I to the integral value obtained by integrating the deviation of up to that point. Differential term D is obtained by multiplying a predetermined differential gain K _D on the differential value obtained by differentiating the difference at that time. These proportional gain K _P , integral gain K _I, and differential gain K _D correspond to the control parameters of PID control. The control calculation unit 72 outputs the calculated operation amount as an input value to the process 80 to the actuator 84 provided in the plant PL. The control device 70 transmits the output value from the process 80 input from the sensor 82, the input value to the process 80 to be output to the actuator 84, and the data processing device 10 at predetermined time intervals.

The sensor 82 detects the state of the process 80. The sensor 82 is, for example, a temperature sensor for detecting temperature, a pressure sensor for detecting pressure, a flow meter for detecting flow rate, an ammeter for detecting current, a voltmeter for detecting voltage, and the like. The sensor 82 sequentially outputs an output value indicating the detected state to the control device 70.
The actuator 84 operates according to an input value input from the control device 70. The state of the process 80 changes depending on the operation. Generally, the larger the input value is, the larger the operating amount of the actuator 84 is. Actuators include, for example, pumps, compressors, valves, motors, motor drives and the like.

In the example shown in FIG. 1, the control devices 70-1 and 70-2 control the processes 80-1 and 80-2, respectively. In processes 80-1 and 80-2, the number of channels of the input value and the output value is one channel, respectively. One control loop is formed for each of the sensor 82-1, the set of the control device 70-1 and the actuator 84-1 and the set of the sensor 82-2, the control device 70-2 and the actuator 84-2. In this example, the number of input value channels and the number of output value channels in each control loop are one channel, respectively. The number of control loops in processes 80-1 and 80-2 is one. In general, the number of input value channels and the number of output value channels per control loop are independent for each control loop and can be two or more. Further, the number of control loops per process is independent for each process and can be two or more. The number of processes installed in the plant can be 3 or more.

(Data processing device)
Next, the functional configuration of the data processing device 10 according to the present embodiment will be described.
The data processing device 10 includes a process data collection unit 20, a process data analysis unit 22, a process optimization unit 30, a process simulation unit 40, a second process data analysis unit 52, an output prediction model generation unit 54, and the like. It is configured to include a control parameter information generation unit 56. The data processing device 10 includes an operation input unit such as a keyboard and a pointing device, a display unit such as an LCD (Liquid Crystal Display), an input / output interface, and a data input / output unit such as a communication interface. Realized as a computer (not shown) including an arithmetic circuit such as a CPU (Central Processing Unit), a storage medium such as a RAM (Random Access Memory), and a ROM (Read-only Memory). May be done. In that case, the arithmetic circuit realizes the functions of the above-mentioned parts by reading the control program stored in the storage medium in advance at the time of startup and executing the process indicated by the instruction described in the control program.

The process data collection unit 20 receives the process value for each control loop at each time every predetermined time from the control devices 70-1 and 70-2 via the network. The process value includes an input value, an output value, and a target value as a control target. Here, the input and the output mean the input to the process and the output from the process, respectively. That is, the input value corresponds to the amount of operation to the actuator 84 output from the control device 70, and the output value corresponds to the measured value input from the sensor 82 to the control device 70. The process data collection unit 20 accumulates the received process values in chronological order. Therefore, the process data collection unit 20 stores process data indicating a time series of process values for each control loop corresponding to each process. When a large number of processes are installed in the plant PL, the process data is formed as plant big data containing a large amount of process values. When collecting process data, the process data collection unit 20 uses, for example, an OPC (OLE: Object Linking and Embedding for Process Control), which is a standard for process data communication. Since the data format is unified to the format specified in OPC, the data processing device 10 defines the data received from the control device 70 and the monitoring device in the OPC regardless of the manufacturer or internal configuration of the device. It can be used by the above procedure.

In the following description, the input values and output values collected by the process data collection unit 20 are referred to as actual measurement input values and actual measurement output values, respectively, and input values (predictive input) calculated by the process simulation unit 40 and other units. It may be distinguished from the value) and the output value (predicted output value). The number of channels of the input value and the number of channels of the output value are not necessarily limited to one channel, and may be a plurality of channels. The channel of the input value may be referred to as an input channel, and the number of channels of the input value may be referred to as the number of input channels. The channel of the output value may be called the output channel, and the number of channels of the output value may be called the number of output channels.

The process data analysis unit 22 analyzes the process data stored in the process data collection unit 20. The process data analysis unit 22 analyzes the characteristics of each of the input value and the output value of each control loop, and calculates an index value indicating the characteristics. The process data analysis unit 22 may specify, for example, a process corresponding to a control loop in which the fluctuation amount of the output value with respect to the input value is larger than a predetermined amount, or corresponds to the control loop in which the fluctuation starts earliest. The process may be specified. The process data analysis unit 22 may use a non-linear analysis method or a linear analysis method. As a linear analysis method, for example, a method such as frequency analysis or principal component analysis can be used. The process data analysis unit 22 may display an index value indicating the variable component and other characteristics obtained by the analysis, and a time series of the input value and the output value on the display unit (not shown).

The process data analysis unit 22 may specify the process instructed by the operation signal input from the operation input unit (not shown) as the process to be analyzed.
The process data analysis unit 22 may display the calculated index value and the like on the display unit (not shown) in addition to the input value, the output value, and the target value for each control loop.
Further, the process data analysis unit 22 further optimizes the control parameters of the control loop instructed by the operation signal input from the operation input unit (shown in the figure) among the control loops displaying the input values and the like. It may be specified as a control loop related to the process of. As a result, a user such as an engineer who visually observes the displayed data can select a process related to the control loop to be optimized for the control parameters. The process data analysis unit 22 notifies the process optimization unit 30 of the specified process.

The process optimization unit 30 mainly identifies the analysis target process notified from the process data analysis unit 22. The process optimization unit 30 optimizes the control parameters related to the analysis target process. Here, the optimization means to reduce the magnitude of the deviation of the output value from the target value in a global manner, and the magnitude of the deviation may temporarily increase in the optimization. When valid data is input from the second process data analysis unit 52, the process optimization unit 30 may use the input valid data for optimizing control parameters.
The process optimization unit 30 includes a frequency analysis unit 32, a process identification unit 34, and a control parameter optimization unit 36.

The frequency analysis unit 32 reads the process data of the control loop related to the process to be analyzed from the process data collection unit 20, and analyzes the frequency characteristics of the output value indicated by the read process data. The frequency analysis unit 32 determines, for example, a frequency component whose main component is a frequency component in which the ratio of the power for each frequency to the total value of the powers of all the frequencies to be processed is a predetermined ratio or more. The frequency analysis unit 32 may analyze the frequency characteristics of the sensitivity function (described later) and determine the main component thereof. When valid data is input from the second process data analysis unit 52, the frequency analysis unit 32 may use the input valid data related to the analysis target process as the analysis target instead of the read process data. The frequency analysis unit 32 outputs the frequency component information indicating the frequency component of the frequency determined as the main component to the control parameter optimization unit 36.

The process identification unit 34 reads the process data of the control loop related to the process to be analyzed from the process data collection unit 20, and uses the input value and output value of the control loop indicated by the read process data to generate a transmission function of the control loop. To identify. When valid data is input from the second process data analysis unit 52, the valid data related to the input analysis target process may be the processing target instead of the read process data.
For example, the process identification unit 34 applies a transfer function to the input value to calculate the predicted output value, which is the predicted value of the output value, so that the magnitude of the difference between the calculated predicted output value and the output value becomes small. , Calculate the parameters of the transfer function. The order of the transfer function is set in advance in the process identification unit 34. For example, a mean square error can be used as an index of the magnitude of the difference. The calculated transfer function parameters constitute an output prediction model in the control loop corresponding to the process to be processed. The process identification unit 34 outputs the calculated transfer function parameters as an output prediction model to the control parameter optimization unit 36 and the process simulation unit 40.

The control parameter optimization unit 36 optimizes the control parameters of the control device 70 related to the process to be analyzed based on the frequency component information input from the frequency analysis unit 32 and the parameters of the transfer function. The control parameter optimization unit 36 uses, for example, an FRIT (Fictitious Reference Iterative Tuning) algorithm when optimizing the control parameters. The control parameter optimization unit 36 calculates the sensitivity function from the transfer function represented by the input parameter. The sensitivity function is a function that indicates the degree of disturbance contribution or attenuation to the output value. The sensitivity function corresponds to the reciprocal of the value obtained by adding 1 to the multiplication value of the calculated transfer function and the transfer function indicating the input / output characteristics of the control device 70. Then, the control parameter optimization unit 36 determines, for example, whether or not the main component has a peak characteristic having a gain larger than that of other frequency bands, and if it has the peak characteristic, at the center frequency having the largest gain. The damping factor function is defined so that the damping factor is the largest. The control parameter optimization unit 36 determines whether or not the control parameter optimization unit 36 has a low frequency pass characteristic, which is a characteristic in which the gain is larger than that in the higher frequency band. When it has a low frequency passing characteristic, the main component is a low frequency component lower than a predetermined frequency. In that case, the control parameter optimization unit 36 determines the attenuation factor function so that the attenuation factor is the largest in the DC component. The order of the attenuation factor function and the maximum value of the attenuation factor are set in advance in the control parameter optimization unit 36.

The control parameter optimization unit 36 calculates the target sensitivity function by multiplying the sensitivity function by the attenuation factor function. Then, the control parameter optimization unit 36 recursively calculates the control parameter so that the magnitude of the difference between the sensitivity function, which is a function of the control parameter, and the target function is reduced. When the cost value indicating the magnitude of the difference becomes smaller than the threshold value of the predetermined cost value, the control parameter optimization unit 36 stops the calculation of the control parameter. The control parameter optimization unit 36 outputs the calculated control parameters to the process simulation unit 40. The initial value of the control parameter may be a preset initial value or a control parameter input in association with the readjustment request from the process simulation unit 40. The method by which the control parameter optimization unit 36 calculates the control parameter is described in detail in Japanese Patent Application No. 2017-2451.

The process simulation unit 40 includes a plant equipment information holding unit 42 and a process calculation unit 44.
The plant equipment information holding unit 42 stores plant equipment information. The plant equipment information is information about the control device 70 and the field equipment for each control loop of each process installed in the plant PL. The plant equipment information is acquired from, for example, the control device 70 for each control loop, the set of the sensor 82 and the actuator 84, the control method used by the control device 70 for the control calculation, the target value set in the control device 70, and the sensor 82. Information such as the type of input value and the type of output value acquired from the actuator 84 is included.

The process calculation unit 44 uses an output prediction model for one or more processes and control parameters for each control loop of each process, and inputs values (prediction input values) to each process every predetermined time (for example, 1 second). ) And the output value (predicted output value) from that process (simulation). The process calculation unit 44 specifies, for example, a process to be simulated as a process designated by an operation signal input from an operation input unit (not shown). The process calculation unit 44 refers to the plant equipment information for the specified process, and specifies the types of the control device 70, the input value, the output value, and the target value for each control loop related to the process. The process calculation unit 44 calculates the output prediction value from the input prediction value for each specified process using the output prediction model of the process. The output prediction model of each process is input from the output prediction model generation unit 54 or the process identification unit 34. The output prediction model input from the output prediction model generation unit 54 is generated based on machine learning as described later. Further, the process calculation unit 44 uses the control parameters input from the control parameter information generation unit 56 or the control parameter optimization unit 36 for each specified process, and the predicted output value (measured value) input to the control device 70. The input predicted value (corresponding to the predicted value of the manipulated variable) to the process is calculated from the predicted value (corresponding to the predicted value of) and the target value. For a process having a plurality of control loops, a plurality of control devices 70 are combined in parallel. Further, a plurality of control devices 70 may be combined in parallel for one process. That is, the predicted output value from one process can be input to each of the plurality of control devices 70, and the predicted output value from each control device 70 can be input as the predicted input value to the one process.

When the number of processes to be simulated is a plurality, some or all the processes may be able to set a combination in series by an instruction of an operation signal from an operation input unit (not shown). That is, the predicted output value from one process can be input as the predicted input value to another process. In this way, the process calculation unit 44 can perform a simulation in which a plurality of processes and a plurality of control devices 70 are combined. In addition, a transfer function model and a machine learning model can be combined as an output prediction model for each process.

The process calculation unit 44 calculates a cost value indicating the magnitude of the deviation between the predicted output value and the target value for each process as an index indicating the control state of the process calculated by the simulation. When the number of channels of the predicted output value is one, the square error can be used as the cost value. Further, when the number of channels of the predicted output value related to the simulation is 2 or more, the weighted square error can be used as the cost value. The weighted squared error is the sum of the multiplication values obtained by multiplying the squared value of the deviation between the predicted output value and the target value for each channel and the weighting coefficient corresponding to the channel. The weighted square error indicates that the smaller the value is, the better the control state is, and the larger the value is, the worse the control state is. Further, the process calculation unit 44 may output the index to a display unit (not shown). The process calculation unit 44 may output the time series of the predicted input value and the predicted output value calculated for each control loop corresponding to each process to the display unit (not shown).
When an operation signal indicating a control parameter readjustment request is input from the operation input unit (not shown), the process calculation unit 44 converts the calculated control parameter into the control parameter optimization unit 36 or the control parameter information generation unit. 56 may be notified accompanying the readjustment request.

The second process data analysis unit 52 reads the process data from the process data collection unit 20, and each input channel for the fluctuation of the output value for each output channel of the control loop corresponding to each of the processes of interest as the processing target (attention process). Calculate the contribution of the input value of. For example, the absolute value of the correlation coefficient is used as an index indicating the degree of contribution. The absolute value of the correlation coefficient is an index indicating that the larger the value, the higher the contribution to the fluctuation of the output value. The second process data analysis unit 52 may specify a process instructed by an operation signal input from an operation input unit (not shown) as an analysis target process. The second process data analysis unit 52 identifies an input channel having an input value whose contribution degree calculated for each output channel is larger than a predetermined contribution degree. That is, the input channel related to the input value having a high contribution degree is specified for each output channel. Hereinafter, an input value having a high degree of contribution may be referred to as a high contribution input value, and an input channel related to an input value having a high degree of contribution may be referred to as a high contribution channel.

The second process data analysis unit 52 may calculate the correlation coefficient as the contribution of the output value of each output channel from another process (hereinafter, other process) to the output value of each output channel in the process of interest. .. The second process data analysis unit 52 specifies an output value in which the absolute value of the calculated correlation coefficient is higher than the threshold value of the predetermined correlation coefficient as a high contribution output value (inter-process correlation). The second process data analysis unit 52 determines the other process and the output channel related to the high contribution output value as the high contribution process and the high contribution channel, respectively. Therefore, if there is little interference between processes, high-contribution processes may not be detected.

The second process data analysis unit 52 specifies a time point at which the deviation of the output value from the target value changes significantly in any of the output channels as a change time point. The output channel to be specified at the time of fluctuation is not limited to the output channel in the process of interest, and may include the output channel from the high-contribution process. The second process data analysis unit 52 determines, for example, whether or not the amount of change from the deviation at the time immediately preceding the deviation at the time of interest (at the time of attention) as the processing target is larger than the threshold value of the predetermined amount of change. The second process data analysis unit 52 specifies the time of interest determined to be large as the fluctuation time, and sets the other time as the non-variation time. Then, the second process data analysis unit 52 specifies a fluctuation time point in which the duration of the non-variation time point up to the specified fluctuation time point is longer than the predetermined duration time as the fluctuation start time point. The fluctuation start time is the time when the deviation is significantly changed after the situation where the deviation is small continues for a predetermined duration or longer. The fluctuation start time point corresponds to, for example, when the target value is changed, when a disturbance is added to the output value from the process, and the like. The second process data analysis unit 52 specifies a period including a predetermined period from the start of fluctuation as an analysis period. The process data during this analysis period is convenient for analyzing the input / output relationship of the process because the response of the process in response to the significant fluctuation of the deviation is observed. The length of the analysis period may be longer than the time from the time when the significant fluctuation of the deviation occurs to the time when the amount of change in the output value from each process converges to less than the predetermined amount of change. The second process data analysis unit 52 extracts data indicating the process values within the analysis period specified for the analysis target process and the high contribution process from the process data from the process data read out as valid data. The second process data analysis unit 52 outputs the extracted valid data to the output prediction model generation unit 54 and the control parameter information generation unit 56.

The output prediction model generation unit 54 specifies an input value set and an output value set from valid data input from the second process data analysis unit 52, and performs machine learning on the specified input value set and output value set. The input value set includes the input value of each high-contribution channel of the process to be analyzed and the input value of each high-contribution channel of the high-contribution process corresponding to the process to be analyzed. On the other hand, the output value set includes the output value of each output channel of the process to be analyzed. Here, the output prediction model generation unit 54 refers to the plant equipment information and specifies the type of the input value of each channel included in the specified input value set and the type of the output value included in the output value set. The output prediction model generation unit 54 generates an output prediction model showing a function mapped to the output value set with respect to the input value set by machine learning. The output prediction model generation unit 54 sets the model parameters constituting the output prediction model so that the deviation between the output value of each output channel calculated by operating the output prediction model from the input value set and the target output value becomes small. Calculate recursively. As the target output value, the output value (measured output value) for each output channel indicated by the valid data is used. That is, the valid data input from the second process data analysis unit 52 is used as the teacher data in the generation of the output prediction model. The output prediction model generation unit 54 performs, for example, deep learning as a machine learning method. Deep learning is machine learning using a multi-layered neural network. The output prediction model generation unit 54 determines that the model has converged and performs learning when the cost value indicating the magnitude of the deviation between the output value from each output channel and the target output value becomes less than a predetermined cost value. Stop. After that, the output prediction model generation unit 54 outputs an output prediction model consisting of parameters calculated by learning to the process simulation unit 40 and the control parameter information generation unit 56.

The neural network is composed of an input layer, an intermediate layer and an output layer. The input layer and the output layer have one or a plurality of input ends and output ends, respectively. The middle layer has a plurality of nodes. A multi-layered neural network refers to a neural network having two or more intermediate layers. In learning, the output prediction model generation unit 54 calculates the parameters of the activation function that gives the relationship between the input value and the output value at each of the input end, the node, and the output end as model parameters. As the activation function, for example, a ramp function, a soft sign, or the like is used. The output prediction model generation unit 54 uses, for example, a weighted sum of squares of deviations between the output value calculated from the input value set and the target output value as the cost value used for determining the convergence.
If the second process data analysis unit 52 does not detect the high contribution process, the input value of each high contribution channel of the high contribution process is not included in the input value set. In addition, the input value set may include input values of all input channels of the process to be analyzed.

Valid data is input to the control parameter information generation unit 56 from the second process data analysis unit 52, and the output prediction model is input from the output prediction model generation unit 54. The output prediction model generation unit 54 refers to the plant equipment information and specifies the control device 70 of each control loop related to the analysis target process and the high contribution process, its control method, the target value, the input value, and the type of the output value. .. The control parameter information generation unit 56 optimizes at least the control parameters of the control device 70 related to the analysis target process. Here, the control parameter information generation unit 56 sets an input value for each input channel related to each process from the actually measured output value and the target value for each output channel of the analysis target process and the high contribution process indicated by the valid data. calculate. When calculating the control input value, the control method (for example, PID control) applied by the control device 70 related to each process is used.

The control parameter information generation unit 56 specifies an input value set including the input value of the high contribution channel and the output value of the high contribution channel from each calculated input channel, and the input output prediction model is input for the specified input value set. Is used to calculate the output value set. The output value set contains the predicted output value of each output channel of the process to be analyzed. The machine learning model used to calculate the output value set may be of the same type as the machine learning model used to generate the output prediction model. The input value set used when calculating the output value set may include the input value of the same input channel as the input value set used for generating the output prediction model. The control parameter information generation unit 56 relates to the control loops of the analysis target process and the high contribution process so as to reduce the cost value indicating the magnitude of the deviation between the predicted output value and the target value of each output channel of the analysis target process. The control parameters of the control device 70 are calculated. Therefore, the control parameter is learned with the reward that the predicted output value approaches the target value. The control parameter information generation unit 56 outputs the calculated control parameters to the process calculation unit 44. The initial value of the control parameter may be a preset initial value or a control parameter input in association with the readjustment request from the process simulation unit 40.

The control parameter information generation unit 56 calculates, as a cost value, a weighted sum of squares between the predicted output value and the deviation output channel for each output channel of the analysis target process and the high contribution process corresponding to the analysis target process. May be good. The weighting coefficient for each output channel is set in advance in the control parameter information generation unit 56. As a result, the control parameters are optimized for the entire analysis target process and the high-contribution process.
Further, the control parameter optimization unit 36 may calculate the control parameters of the control device 70 related to the high contribution process in parallel, or may have already calculated them. In that case, the control parameter information generation unit 56 does not have to calculate the control parameters of the control device 70 related to the high contribution process. The control parameter information generation unit 56 may use the control parameters calculated by the control parameter optimization unit 36 in the calculation of the control input value.

The control parameter information generation unit 56 may notify the process calculation unit 44 of the high-contribution process corresponding to the analysis target process. Therefore, when the process to be simulated is specified, the process calculation unit 44 can specify the high-contribution process corresponding to the process. Further, the process calculation unit 44 acquires the output prediction model related to the notified high contribution process from the process identification unit 34 or the output prediction model generation unit 54. The process calculation unit 44 acquires the control parameters of the control device 70 related to the notified high contribution process from the control parameter optimization unit 36 or the control parameter information generation unit 56.
When the operation signal indicating the parameter application instruction is input from the operation input unit (not shown), the control parameter information generation unit 56 transmits the calculated control parameter to the corresponding control device 70. The control calculation unit 72 of the control device 70 uses the control parameters received from the control parameter information generation unit 56 for the control calculation.

Next, an output prediction model and a calculation example of control parameters will be described.
FIG. 2 is an explanatory diagram showing an output prediction model and a calculation example of control parameters.
In the example shown in FIG. 2, the control devices 70-1 to 70-3 (not shown), the sensors 82-1 and 82-2, and the actuator 84-, each of which has control calculation units 72-1 to 72-3 in the plant PL, are shown. 1 to 84-3 are installed. The control calculation units 72-1 to 72-3 are PID controllers that execute PID control, respectively. Between sensor 82-1, control calculation unit 72-1 and actuator 84-1, between sensor 82-1, control calculation unit 72-3 and actuator 84-3, sensor 82-2, control calculation unit 72-2 and actuator 84. A control loop is formed between -2. The control loop including the sensor 82-1, the control calculation unit 72-1 and the actuator 84-1 is called a control loop 1. The control loop including the sensor 82-1, the control calculation unit 72-3, and the actuator 84-3 is called a control loop 2. The control loop including the sensor 82-2, the control calculation unit 72-2, and the actuator 84-2 is called a control loop 3. Of the control loops 1 to 3, control loops 1 and 2 correspond to process 1, and control loop 3 corresponds to process 2. The sensor 82-1 is shared between the control loops 1 and 2 corresponding to the process 1. The sensor 82-1 is independent of the sensor 82-3 related to the control loop 3 corresponding to the process 2.

The plant PL is, for example, a chemical plant. Process 1 is a complex process, such as a process in a reactor. Process 2 is a relatively simple process such as the process in the tank constituting the reactor. Therefore, in this example, the output prediction model of processes 1 and 3 is used as a machine learning model, and the output prediction model of process 2 is used as a transfer function model.

The process data collection unit 20 acquires a process value consisting of a set of input values, output values, and target values for each control loop corresponding to each process from the control devices 70-1 to 70-3 (FIG. 1) at predetermined time intervals. do. In this example, the number of input channels and the number of output channels are 1 each in each process.
The second process data analysis unit 52 outputs the output values of the control loops 1 and 2 corresponding to the process 1 as the process to be analyzed, the input values of the control loops 1 and 2, or the output of the control loop 3 corresponding to the process 2 as another process. Calculate the correlation coefficient with the value. The second process data analysis unit 52 identifies the input values of the control loops 1 and 2 as high contribution input values to the output values from the control loops 1 and 2 based on the calculated correlation coefficient, and from the control loop 2 The output value from the control loop 3 is specified as the high contribution output value from the process 2 which is a high contribution process to the output value. The second process data analysis unit 52 specifies the fluctuation time point from the output value of each of the control loops 1 to 3, and determines the analysis period based on the specified fluctuation time point. The second process data analysis unit 52 extracts valid data including the process values of processes 1 and 2 within the specified analysis period.

The output prediction model generation unit 54 is an output consisting of the output values of the control loops 1 and 2 corresponding to the process 1 for the input value set consisting of the input values of the control loops 1 and 2 included in the valid data and the output values from the process 3. Perform machine learning on value sets. By machine learning, a neural network model (NN model n01) that maps an input value set to an output value set is generated as an output prediction model of process 1.
On the other hand, the process identification unit 34 (FIG. 1) calculates the transfer function t02, which maps to the output value of the control loop 3 with respect to the input value of the control loop 3, as the output prediction model of the process 2.

The control parameter information generation unit 56 determines the control parameters p01 and p02 in the control calculation units 72-1 and 72-3 so that the deviation between the predicted output value and the target value becomes small for the control loops 1 and 2 related to the process 1. .. The control parameter information generation unit 56 calculates the average squared error as a cost value indicating the magnitude of the deviation. The root-mean-squared error is, for example, the sum of squares of the deviation A1'with respect to the target value of the predicted output value A1 from the control loop 1 and the deviation A2'with respect to the target value of the predicted output value A2 from the control loop 2.
The control parameter optimization unit 36 (FIG. 1) determines the control parameter p03 in the control calculation unit 72-2 so that the deviation between the predicted output value and the target value is small for the control loop 3 related to the process 2. The control parameter P01～p03, respectively proportional gain _{K P,} the integral gain _{K I,} include differential gain _{K D.}

In the example shown in FIG. 2, the process calculation unit 44 simulates the input value and the output value for the processes 1 and 2.
The process calculation unit 44 uses the control calculation units p01, p02, and p03 from the predicted output values input to the control calculation units 72-1, 72-3, and 72-2, respectively, and the set target values, to control the control calculation unit 72-. Calculate the predicted input value output from 1, 72-3, 72-2.
The process calculation unit 44 specifies an input value set including the predicted input value input from the control calculation units 72-1 and 72-3 and the predicted output value A2 output from the process 2. The process calculation unit 44 calculates the predicted output value A1 from the input value set specified by using the NN set n01 (NN model calculation). The predicted output value A1 is output to the control calculation units 72-1, 72-2, and 72-3. On the other hand, the process calculation unit 44 calculates the prediction output value A2 from the prediction input value input from the control calculation unit 72-2 using the transfer function t02 (transfer function model calculation).

As described above, the second process data analysis unit 52 extracts data having a high contribution that has a major influence on the process fluctuation as valid data. The obtained valid data is provided to the output prediction model generation unit 54 and the control parameter information generation unit 56, and can improve the efficiency and accuracy of the analysis.
The output prediction model generation unit 54 can generate a machine learning model as an output prediction model that expresses the input / output relationship. As a result, the process calculation unit 44 can predict the input / output of a complicated process such as a transfer function model that cannot be identified by a conventional method by simulation. Further, the process calculation unit 44 can predict the input / output between a plurality of processes by simulation in combination with the output prediction model identified by the conventional method.
According to the control parameter information generation unit 56, reinforcement learning of the control parameters is performed so that the predicted output value predicted by the generated output prediction model is closer to the target value which is the control target.

Therefore, according to the above-described embodiment, complicated input / output relationships in the plant are analyzed by utilizing machine learning from the process data. In addition, since data with a high degree of contribution to process fluctuations is identified, notable data is narrowed down. Therefore, the amount of work in engineering can be significantly reduced.
Here, for a complicated process that cannot be identified by the conventional method or that cannot obtain sufficient accuracy, an output prediction model that shows the input / output relationship with higher accuracy is generated. From the generated output prediction model, more embodiable analysis results, for example, input / output indicating the control state in a desired process and its index are derived. Therefore, the engineer can easily grasp the state of the identified process.
Further, more appropriate control parameters can be obtained by reinforcement learning of control parameters based on input / output derived by the output prediction model generated by machine learning. Therefore, the work related to the adjustment of control parameters by the engineer is reduced.

Although the embodiments of the present invention have been described above with reference to the drawings, the specific configuration is not limited to the above, and various design changes and the like are made without departing from the gist of the present invention. It is possible.
For example, the data processing device may be realized by a computer. In that case, the program for realizing each control function is recorded on a computer-readable recording medium, the program recorded on the recording medium is read by the computer system, and the program is executed by an arithmetic processing circuit such as a CPU. May be realized by. The term "computer system" as used herein is a computer system built into each device, and includes hardware such as an OS and peripheral devices. Further, the "computer-readable recording medium" refers to a portable medium such as a flexible disk, a magneto-optical disk, a ROM, or a CD-ROM, and a storage device such as a hard disk built in a computer system. Further, a "computer-readable recording medium" is a medium that dynamically holds a program for a short time, such as a communication line when a program is transmitted via a network such as the Internet or a communication line such as a telephone line. In that case, a program may be held for a certain period of time, such as a volatile memory inside a computer system serving as a server or a client. Further, the above-mentioned program may be for realizing a part of the above-mentioned functions, and may be further realized for realizing the above-mentioned functions in combination with a program already recorded in the computer system. Further, the computer system described above may be configured as a computing resource which is a component of a cloud computing system capable of transmitting and receiving various data to and from each other via a network.
Further, a part or all of the above devices may be realized as an integrated circuit such as an LSI (Large Scale Integration). Each functional block of each device may be made into a processor individually, or a part or all of them may be integrated into a processor. Further, the method of making an integrated circuit is not limited to the LSI, and may be realized by a dedicated circuit or a general-purpose processor. Further, when an integrated circuit technology that replaces LSI appears due to the progress of semiconductor technology, an integrated circuit based on the technology may be used.

1 ... Process control system, 10 ... Data processing device, 20 ... Process data collection unit, 22 ... Process data analysis unit, 30 ... Process optimization unit, 32 ... Frequency analysis unit, 34 ... Process identification unit, 36 ... Control parameter optimization Chemical unit, 40 ... process simulation unit, 42 ... plant equipment information holding unit, 44 ... process calculation unit, 52 ... second process data analysis unit, 70 (70-1, 70-2, 70-3) ... control device, 72 (72-1, 72-2, 72-3) control calculation unit, 82 (82-1, 82-2, 82-3) ... Sensor, 84 (84-1, 84-2, 84-3) ... Actuator

Claims (10)

An output prediction model generating unit generating an output prediction model of the first process performs machine learning for at least the a input value for one of the first process is the output value from the first process the measured output value,
A process identification unit that calculates the transfer function of the second process based on the input value for the second process separate from the first process and the measured output value which is the output value from the second process.
The predicted output value, which is the predicted value of the output value from the first process, is calculated based on the output prediction model and the input value for the first process, and the transfer function of the second process and the input value for the second process are calculated. The predicted output value from the second process is calculated based on the above, and the magnitude of the deviation between the predicted output value for each process of the first process and the second process and the target value which is the target of the output value is shown. A control device that calculates the cost value and controls the process so that the evaluation function is reduced by using the cost value obtained as the sum of the multiplication values obtained by multiplying the cost value for each process by the weighting coefficient as the evaluation function. Control parameter information generation unit that defines the control parameters for each process of
A data processing device. The data processing apparatus according to claim 1 , wherein a square error is used as a cost value for each process. From the process data for each process including the input value and the output value, the input value whose contribution to the output value from the process to be analyzed is higher than the predetermined contribution or the output value of another process is specified and specified. The process data analysis unit that extracts valid data including the input value or output value
The data processing apparatus according to claim 1 or 2 , further comprising. An output prediction model generator that generates an output prediction model of the process by performing machine learning on the input value for at least one process and the measured output value which is the output value from the process.
The predicted output value, which is the predicted value of the output value, is calculated based on the output prediction model and the input value, so that the difference between the predicted output value and the target value of the output value from the process is reduced. A control parameter information generator that defines the control parameters of the control device that controls the process.
From the process data for each process including the input value and the output value, the input value whose contribution to the output value from the process to be analyzed is higher than the predetermined contribution or the output value of another process is specified and specified. A process data analysis unit that extracts valid data that is valid data including input values or output values and is used for the machine learning.
A data processing device. The output prediction model is an output prediction model expressed by a neural network.
The data processing apparatus according to any one of claims 1 to 4. The data processing device according to any one of claims 1 to 5 , a control device for controlling the process, and the like.
Control system with. It is a data processing method in a data processing device.
An output prediction model generation process of generating an output prediction model of the first process performs machine learning for at least the a input value for one of the first process is the output value from the first process the measured output value,
A process identification process that calculates the transfer function of the second process based on the input value for the second process that is separate from the first process and the measured output value that is the output value from the second process.
Based on the input value for the output prediction model and the first process calculates the predicted value is predicted output value of the output value from the first process, the input value and the transfer function of the second process for the second process The predicted output value from the second process is calculated based on the above, and the magnitude of the deviation between the predicted output value for each process of the first process and the second process and the target value which is the target of the output value is shown. A control device that calculates the cost value and controls the process so that the evaluation function is reduced by using the cost value obtained as the sum of the multiplication values obtained by multiplying the cost value for each process by the weighting coefficient as the evaluation function. Control parameter information generation process that defines the control parameters for each process,
Data processing method. On the computer of the data processing device,
An output prediction model generating step of generating an output prediction model of the first process performs machine learning against the measured output value is an output value from the first process as input values for at least one of the first process,
A process identification procedure for calculating the transfer function of the second process based on the input value for the second process separate from the first process and the measured output value which is the output value from the second process.
The predicted output value, which is the predicted value of the output value from the first process, is calculated based on the output prediction model and the input value for the first process, and the transfer function of the second process and the input value for the second process are calculated. The predicted output value from the second process is calculated based on the above, and the magnitude of the deviation between the predicted output value for each process of the first process and the second process and the target value which is the target of the output value is shown. A control device that calculates the cost value and controls the process so that the evaluation function is reduced by using the cost value obtained as the sum of the multiplication values obtained by multiplying the cost value for each process by the weighting coefficient as the evaluation function. Control parameter information generation procedure that defines the control parameters for each process of
A program to execute. It is a data processing method in a data processing device.
An output prediction model generation process that generates an output prediction model of the process by performing machine learning on the input value for at least one process and the measured output value which is the output value from the process.
The predicted output value, which is the predicted value of the output value, is calculated based on the output prediction model and the input value, so that the difference between the predicted output value and the target value of the output value from the process is reduced. The control parameter information generation process that defines the control parameters of the control device that controls the process, and
From the process data for each process including the input value and the output value, the input value whose contribution to the output value from the process to be analyzed is higher than the predetermined contribution or the output value of another process is specified and specified. A process data analysis process for extracting valid data used for the machine learning, which is valid data including input values or output values.
Data processing method. On the computer of the data processing device,
An output prediction model generation procedure for generating an output prediction model of the process by performing machine learning on the input value for at least one process and the actually measured output value which is the output value from the process.
The predicted output value, which is the predicted value of the output value, is calculated based on the output prediction model and the input value, so that the difference between the predicted output value and the target value of the output value from the process is reduced. The control parameter information generation procedure that defines the control parameters of the control device that controls the process, and
From the process data for each process including the input value and the output value, the input value whose contribution to the output value from the process to be analyzed is higher than the predetermined contribution or the output value of another process is specified and specified. A process data analysis procedure for extracting valid data used for the machine learning, which is valid data including input values or output values, and
A program to execute.

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