CN118226777A - Control system and method for multi-state machine supporting multi-optical fiber signal collector - Google Patents

Abstract

The invention discloses a control system of a multi-state machine supporting a multi-fiber signal collector, which comprises a multi-device task scheduling and controller, wherein the multi-device task scheduling and controller comprises a multi-device main task controller, a multi-device rule controller and a multi-device subtask scheduler; the multi-equipment task scheduling and controlling device is at least used for scheduling the tasks of a plurality of equipment and controlling the task scheduling sequence; a multi-device state controller comprising a multi-device state loader, a multi-device state processor, a multi-device state distributor; the multi-device state controller is at least used for controlling the state fed back in the device executing process. The invention can realize the functions of automatic control of multi-equipment wire changing, synchronization, acquisition and the like, and solves the defects that the conventional optical fiber acquisition controller cannot be configured autonomously, cannot expand equipment autonomously and the like.

Description

Control system and method for multi-state machine supporting multi-optical fiber signal collector

Technical Field

The invention relates to the technical field of network data communication safety, in particular to a control system and a method for a multi-state machine supporting a multi-optical fiber signal collector.

Background

At present, the conventional multi-state machine control technical scheme has the following defects:

1) The state of the state machine cannot be set in a self-defined manner;

2) The control flow of the state machine cannot be configured in a self-defined manner;

3) The fiber control and acquisition equipment cannot be dynamically expanded.

Disclosure of Invention

The invention aims to provide a control system and a control method for a multi-state machine supporting a multi-optical fiber signal collector, which can realize the functions of automatic control of wire changing, synchronization, collection and the like of the multi-equipment, solve the defects that a conventional optical fiber collection controller cannot be configured independently, cannot expand equipment autonomously and the like, and are different from the existing multi-state machine control method, the control process can be packaged into an independently operated component, a user can directly integrate the control process into codes for use, and the control system and the control method are convenient to use, are not only suitable for a task state control system for optical fiber signal collection, but also suitable for other control processes with or without task hierarchical structures, and have strong universality.

In order to achieve the above purpose, the following technical scheme is adopted:

A control system for supporting multi-state machine of multi-optical fiber signal collector includes

The multi-device task scheduling and controlling device comprises a multi-device main task controller, a multi-device rule controller and a multi-device sub-task scheduler; the multi-equipment task scheduling and controlling device is at least used for scheduling the tasks of a plurality of equipment and controlling the task scheduling sequence;

A multi-device state controller comprising a multi-device state loader, a multi-device state processor, a multi-device state distributor; the multi-device state controller is at least used for controlling the state fed back in the device executing process.

Further, the multi-device main task controller comprises a multi-device main task flow loading component, a multi-device main task scheduling component and a multi-device main task control component; the multi-equipment main task flow loading component is at least used for loading task flow configuration of different equipment, initializing task flow control information of the different equipment and uniformly loading the task flow control information of the different equipment into a flow control area; the multi-equipment main task scheduling component is at least used for acquiring task flow control information from the flow control area and scheduling processing tasks according to the flow control information; the multi-device main task control component is at least used for executing the instructions of the multi-device main task scheduling component, and acquiring rules or subtask information according to the instructions so as to execute related operations, wherein the related operations comprise management subtasks, synchronization of main task states and management rule information.

Further, the multi-device rule controller comprises a multi-device rule loading component and a multi-device rule control component; the multi-device rule loading component is at least used for standardizing rules of different devices; the multi-device rule control component is configured to control transitions between different devices according to at least a mapping relationship between the devices and the standardized device.

Further, the multi-device subtask scheduler comprises a subtask management component and a subtask scheduling component; the subtask management component is at least used for generating subtasks according to the single wave data transferred by the tasks; the subtask scheduling component is at least used for issuing subtasks according to the main task scheduling instruction.

Further, the multi-device state loader comprises a multi-device state configuration component, a multi-device state analysis component and a multi-device state pool; the multi-equipment state configuration component is at least used for providing configuration standards of equipment states, and meanwhile, when each equipment state is configured, the multi-equipment state configuration component needs to correspond to the normalized state; the multi-device state analysis component is at least used for loading the states of the multi-devices when the multi-device state analysis component is started and combining the states into standardized state information; the multi-device state pool is at least used for unified format memory to be provided for the multi-device state processor.

Further, the multi-device state processor comprises a multi-device state synchronization component, a multi-device state control component and a multi-device state distribution component; the multi-device state synchronization component is at least used for synchronizing the states of the main task and the subtasks; the multi-device state control component is at least used for synchronizing states among various devices; the multi-device state distribution component is at least for scheduling distribution processes among devices.

Further, the multi-device state distributor comprises a line changing device state transmitter and a plurality of collecting device state transmitters; the line changing equipment state transmitter is at least used for communicating with line changing equipment; the acquisition device status transmitter is at least for communicating with an acquisition device.

A control method of a multi-state machine supporting a multi-optical fiber signal collector adopts the control system, and comprises the following steps:

s1: loading task flow configuration through a multi-device main task flow loading component;

S2: loading state configuration through a multi-device state configuration component and a multi-device state analysis component and caching the state configuration into a state pool area;

s3: starting a task scheduling function through the multi-equipment main task scheduling component and the multi-equipment main task control component;

s4: starting a rule control function through the multi-device rule loading component and the multi-device rule control component;

s5: a subtask scheduling function is started through the subtask management component and the subtask scheduling component;

s6: starting the multi-device state processor through the multi-device state synchronization component, the multi-device state control component and the multi-device state distribution component;

s7: the multi-device state distributor is started.

By adopting the scheme, the invention has the beneficial effects that:

The invention can realize the functions of automatic control of line changing, synchronization, acquisition and the like of multiple devices, overcomes the defects that the conventional optical fiber acquisition controller cannot be configured autonomously, cannot expand devices autonomously and the like, is different from the existing multi-state machine control method, can package the control process into an independently operated component, can be directly integrated into codes by a user for use, is convenient to use, is not only suitable for a task state control system for optical fiber signal acquisition, but also suitable for other control processes with or without task hierarchical structures, and has strong universality.

Drawings

FIG. 1 is a schematic block diagram of the present invention;

FIG. 2 is a schematic block diagram of a multi-device task scheduler and controller of the present invention;

FIG. 3 is a schematic block diagram of a multi-device state controller of the present invention;

FIG. 4 is a process flow diagram of a multi-device state processor of the present invention;

Fig. 5 is a flow chart of the method of the present invention.

Detailed Description

The invention will be described in detail below with reference to the drawings and the specific embodiments.

Referring to FIGS. 1-4, the present invention provides a control system for a multi-state machine supporting a multi-fiber signal collector, in one embodiment, comprising

The multi-device task scheduling and controlling device comprises a multi-device main task controller, a multi-device rule controller and a multi-device sub-task scheduler; the multi-equipment task scheduling and controlling device is at least used for scheduling the tasks of a plurality of equipment and controlling the task scheduling sequence;

A multi-device state controller comprising a multi-device state loader, a multi-device state processor, a multi-device state distributor; the multi-device state controller is at least used for controlling the state fed back in the device executing process.

The invention mainly realizes the aim of automatically collecting signals of the optical fiber, and in the embodiment, the invention consists of two parts, namely a multi-device task scheduling and controller and a multi-device state controller; the task scheduling function of a plurality of devices can be realized through the multi-device task scheduling and controller, the task scheduling sequence is controlled, the multi-device state controller mainly controls the state fed back in the device executing process, the multi-device task scheduling and controller triggers specific events through the specific states, the multi-device task scheduling and controller executes specific task scheduling and controlling work through the specific events, and the multi-device task scheduling and controlling device is shown in the reference figure 1 and further comprises a terminal acquisition device and a line changing control device, wherein the terminal acquisition device and the line changing control device are peripheral devices, and before optical fiber signal acquisition, the designated optical fiber needs to be switched to a port of the corresponding acquisition device through the line changing control device so as to be used by the acquisition device.

In one embodiment, the multi-device master task controller includes a multi-device master task flow loading component, a multi-device master task scheduling component, and a multi-device master task control component; the multi-equipment main task flow loading component is at least used for loading task flow configuration of different equipment, initializing task flow control information of the different equipment and uniformly loading the task flow control information of the different equipment into a flow control area; the multi-equipment main task scheduling component is at least used for acquiring task flow control information from the flow control area and scheduling processing tasks according to the flow control information; the multi-device main task control component is at least used for executing the instructions of the multi-device main task scheduling component, and acquiring rules or subtask information according to the instructions so as to execute related operations, wherein the related operations comprise management subtasks, synchronization of main task states and management rule information.

Meanwhile, the multi-device rule controller comprises a multi-device rule loading component and a multi-device rule control component; the multi-device rule loading component is at least used for standardizing rules of different devices; the multi-device rule control component is configured to control transitions between different devices according to at least a mapping relationship between the devices and the standardized device.

The multi-equipment subtask scheduler comprises a subtask management component and a subtask scheduling component; the subtask management component is at least used for generating subtasks according to the single wave data transferred by the tasks; the subtask scheduling component is at least used for issuing subtasks according to the main task scheduling instruction.

The multi-device task scheduling and controlling device is mainly responsible for the cooperative work capability before a plurality of tasks and the control among the multi-tasks, and mainly comprises a multi-device main task controller, a multi-device rule controller and a multi-device subtask scheduler.

1) Multi-device master task controller

The tasks in the multi-equipment main task controller are mainly input by a user or generated by a system (the tasks mainly comprise main tasks, sub-tasks and rules), and most of the main tasks are optical fiber signal acquisition tasks, wherein the main tasks are groups of the sub-tasks and mainly correspond to unified acquisition types, the acquisition types are divided into light acquisition, fast acquisition, slow acquisition, snapshot acquisition and the like, and one main task can only correspond to one acquisition type.

The subtasks are automatically generated by the main task, and the subtasks are generated according to the number of the single waves selected by the system, and one subtask corresponds to only one single wave line; the rules are attached to the main task and mainly generated by user input, and the rules are mainly issued along with the subtasks; the rules mainly comprise five-tuple rules, character string rules, compound rules and the like.

The multi-device main task controller mainly comprises a multi-device main task flow loading component, a multi-device main task scheduling component and a multi-device main task control component.

The multi-device main task flow loading component mainly comprises the following functions: and the task flow configuration is responsible for loading task flow configuration of different devices and initializing task flow control information of the different devices so as to finally provide the task flow control information for the multi-device master task scheduling component.

The task flows of different devices can be loaded through configuration files, and the configuration files comprise the following main parameter names: device ID, device name, task type ID, task type name, task control flow, etc.; the device ID and the device name mainly refer to information of the acquisition device, the task types refer to all task types supported by the acquisition device, the task control flow refers to execution sequence of different task types, and the multi-device main task scheduling component can automatically execute all tasks according to related parameters.

The task flow control information of different devices is loaded into a unified flow control area through a device main task flow loading component, and a multi-device main task scheduling component acquires the task flow control information from the flow control area so as to schedule processing tasks according to the control information.

The multi-device main task control component is responsible for executing the instructions of the multi-device main task scheduling component, and performs related operations according to the instructions to obtain rules or subtask information, where the related operations include: managing subtasks, synchronizing the state of the main tasks and managing rule information; the management subtask is mainly responsible for generating subtask information, managing subtask states and the like; the synchronous main task state is mainly responsible for updating the main task state according to different subtask states; the management rule information is mainly responsible for loading different rules according to the subtask information.

2) Multi-device rule controller

The multi-device rule controller comprises a multi-device rule loading component and a multi-device rule control component; because different devices support different rules, the multi-device rule controller can load the component to normalize the rules of different devices according to the multi-device rules, and the multi-device rule control component controls the conversion between different devices and the normalized devices mainly according to the mapping relation between the different devices and the normalized devices.

Meanwhile, the multi-device rule loading component supports standardized parameter configuration, the rule types mainly comprise five-tuple rules, character string rules, compound rules and the like, and the parameters cover device names, rule parameters corresponding to devices and the like; when the system is initialized, the multi-device rule loading component loads rules supported by all devices according to configuration information and normalizes data to provide the data for a third party to use; and judging whether the corresponding rule exists in the main task scheduling process, if so, loading the corresponding rule and submitting the rule to sub-task processing.

3) Multi-device subtask scheduler

The multi-device subtask scheduler comprises a subtask management component and a subtask scheduling component; the subtask management component is mainly responsible for generating subtasks according to the single wave data transmitted by the tasks, and the subtask scheduling component is mainly responsible for issuing the subtasks according to the main task scheduling instructions.

In one embodiment, the multi-device state loader comprises a multi-device state configuration component, a multi-device state parsing component and a multi-device state pool; the multi-equipment state configuration component is at least used for providing configuration standards of equipment states, and meanwhile, when each equipment state is configured, the multi-equipment state configuration component needs to correspond to the normalized state; the multi-device state analysis component is at least used for loading the states of the multi-devices when the multi-device state analysis component is started and combining the states into standardized state information; the multi-device state pool is at least used for unified format memory to be provided for the multi-device state processor.

Meanwhile, the multi-device state processor comprises a multi-device state synchronization component, a multi-device state control component and a multi-device state distribution component; the multi-device state synchronization component is at least used for synchronizing the states of the main task and the subtasks; the multi-device state control component is at least used for synchronizing states among various devices; the multi-device state distribution component is at least for scheduling distribution processes among devices.

The multi-equipment state distributor comprises a line changing equipment state transmitter and a plurality of acquisition equipment state transmitters; the line changing equipment state transmitter is at least used for communicating with line changing equipment; the acquisition device status transmitter is at least for communicating with an acquisition device.

The multi-device state controller is mainly responsible for unified state management under the condition of multi-device task execution, aims to ensure the normalization of the whole acquisition flow of the system and ensure the normal operation of the whole acquisition flow, and mainly comprises a multi-device state loader, a multi-device state processor and a multi-device state distributor.

1) Multi-device state loader

The multi-device state loader is mainly responsible for loading the states of all devices according to the configuration information, normalizing the states of all the devices, and finally writing the states into a state pool for a processor to use.

The normalized main task state comprises the following steps: uncommitted, committed, executing, completed, paused; the normalized subtask states include: uncommitted, committed, line not changed, line changed, issued, executing, failed, successful.

The multi-device state loader mainly comprises a multi-device state configuration component, a multi-device state analysis component and a multi-device state pool; the multi-device state configuration component provides a configuration standard of the device states, and the configuration standard is required to correspond to the normalized states when each device state is configured; the multi-device state analysis component is specially responsible for loading multi-device states during starting and combining the multi-device states into standardized state information; the multi-device state pool is a unified memory area provided for the multi-device state processor.

2) Multi-device state processor

The multi-device state processor is mainly responsible for synchronizing, controlling and distributing multi-device states and mainly comprises a multi-device state synchronizing component, a multi-device state control component and a multi-device state distributing component.

The multi-device state synchronization component is responsible for synchronizing the states of the main task and the sub-tasks, and mainly updates the state of the main task according to the states of all the sub-tasks; the system submits all sub-task states to be updated to a submitted state, and the main task state is also updated to the submitted state; when any one of the subtask states of a certain main task is not changed, issued and executing, the state of the main task is updated into the executing state; when all subtasks in the main task are failed or succeeded, the main task state is a completed state; the suspended state in the main task is manually interfered, and when a user manually determines the suspended state, the main task is in the suspended state after the current subtask is executed, and the main task needs to be manually started.

The multi-device state control component is primarily responsible for synchronizing states among multiple devices, and determining a current sub-task state if all devices in the sub-task execute to a particular state.

Subtask state determination process: uncommitted is a system default state; the committed state is a state before execution is ready to begin; the wire replacement is not performed, namely, the system issues a wire replacement instruction to wire replacement equipment, and the wire replacement is waited for; the line replacement is a state that the line replacement equipment successfully replaces the line to be executed; issued refers to the state of issued execution instructions to each device awaiting execution; in execution, representing that each device is collecting data; failure represents failure of at least one of the collection devices to collect data; has successfully indicated that all devices have acquired and returned.

The multi-device state distribution assembly is mainly responsible for scheduling the distribution process between the multi-device state distribution assembly and each device, and the multi-device state distribution assembly is required to perform unified analysis protocol and coordinate the distribution process due to different communication protocols between different devices.

3) Multi-device state distributor

The multi-device state distributor is mainly responsible for transmitting and receiving communication data of the front-end device; one device usually corresponds to one state distributor and serves as a communication service side of the front-end device acquisition function; the line changing device state transmitter in the multi-device state distributor is responsible for communicating with the line changing device; the acquisition equipment state transmitter is in charge of communicating with the acquisition equipment; when data is acquired for a certain optical fiber, the acquisition processing can be performed after the line is successfully replaced by the line replacing equipment.

As shown in fig. 5, a control method of a multi-state machine supporting a multi-fiber signal collector is further provided, and the control system is adopted, and includes the following steps:

s1: loading task flow configuration through a multi-device main task flow loading component;

S2: loading state configuration through a multi-device state configuration component and a multi-device state analysis component and caching the state configuration into a state pool area;

s3: starting a task scheduling function through the multi-equipment main task scheduling component and the multi-equipment main task control component;

s4: starting a rule control function through the multi-device rule loading component and the multi-device rule control component;

s5: a subtask scheduling function is started through the subtask management component and the subtask scheduling component;

s6: starting the multi-device state processor through the multi-device state synchronization component, the multi-device state control component and the multi-device state distribution component;

s7: the multi-device state distributor is started.

After the starting is successful, all components in the whole system cooperatively work to be in a self-management state, and the method is different from the existing multi-state machine control method, the control process can be packaged into independently operated components, a user can directly integrate the components into codes for use, the use is convenient, and meanwhile, the method is not only suitable for a task state control system for optical fiber signal acquisition, but also suitable for other control processes with or without task hierarchical structures, and has strong universality.

The foregoing description of the preferred embodiment of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.

Claims (8)

1. The control system of the multi-state machine supporting the multi-optical fiber signal collector is characterized by comprising a multi-device task scheduling and controller, wherein the multi-device task scheduling and controller comprises a multi-device main task controller, a multi-device rule controller and a multi-device subtask scheduler; the multi-equipment task scheduling and controlling device is at least used for scheduling the tasks of a plurality of equipment and controlling the task scheduling sequence;

A multi-device state controller comprising a multi-device state loader, a multi-device state processor, a multi-device state distributor; the multi-device state controller is at least used for controlling the state fed back in the device executing process.

2. The control system of a multi-state machine supporting a multi-fiber signal collector according to claim 1, wherein the multi-device master task controller comprises a multi-device master task flow loading component, a multi-device master task scheduling component, a multi-device master task control component; the multi-equipment main task flow loading component is at least used for loading task flow configuration of different equipment, initializing task flow control information of the different equipment and uniformly loading the task flow control information of the different equipment into a flow control area; the multi-equipment main task scheduling component is at least used for acquiring task flow control information from the flow control area and scheduling processing tasks according to the flow control information; the multi-device main task control component is at least used for executing the instructions of the multi-device main task scheduling component, and acquiring rules or subtask information according to the instructions so as to execute related operations, wherein the related operations comprise management subtasks, synchronization of main task states and management rule information.

3. The control system of a multi-state machine supporting a multi-fiber signal collector of claim 2, wherein the multi-device rule controller comprises a multi-device rule loading component, a multi-device rule control component; the multi-device rule loading component is at least used for standardizing rules of different devices; the multi-device rule control component is configured to control transitions between different devices according to at least a mapping relationship between the devices and the standardized device.

4. The control system of a multi-state machine supporting a multi-fiber signal collector of claim 3, wherein the multi-device subtask scheduler comprises a subtask management component, a subtask scheduling component; the subtask management component is at least used for generating subtasks according to the single wave data transferred by the tasks; the subtask scheduling component is at least used for issuing subtasks according to the main task scheduling instruction.

5. The control system of a multi-state machine supporting a multi-fiber signal collector of claim 4, wherein the multi-device state loader comprises a multi-device state configuration component, a multi-device state parsing component, a multi-device state pool; the multi-equipment state configuration component is at least used for providing configuration standards of equipment states, and meanwhile, when each equipment state is configured, the multi-equipment state configuration component needs to correspond to the normalized state; the multi-device state analysis component is at least used for loading the states of the multi-devices when the multi-device state analysis component is started and combining the states into standardized state information; the multi-device state pool is at least used for unified format memory to be provided for the multi-device state processor.

6. The control system of a multi-state machine supporting a multi-fiber signal collector of claim 5, wherein the multi-device state processor comprises a multi-device state synchronization component, a multi-device state control component, a multi-device state distribution component; the multi-device state synchronization component is at least used for synchronizing the states of the main task and the subtasks; the multi-device state control component is at least used for synchronizing states among various devices; the multi-device state distribution component is at least for scheduling distribution processes among devices.

7. The control system of a multi-state machine supporting a multi-fiber signal collector of claim 6, wherein the multi-device state distributor comprises a line-changing device state transmitter, a plurality of collection device state transmitters; the line changing equipment state transmitter is at least used for communicating with line changing equipment; the acquisition device status transmitter is at least for communicating with an acquisition device.

8. A method of controlling a multi-state machine supporting a multi-fiber signal collector using the control system of claim 7, comprising the steps of:

s1: loading task flow configuration through a multi-device main task flow loading component;

S2: loading state configuration through a multi-device state configuration component and a multi-device state analysis component and caching the state configuration into a state pool area;

s3: starting a task scheduling function through the multi-equipment main task scheduling component and the multi-equipment main task control component;

s4: starting a rule control function through the multi-device rule loading component and the multi-device rule control component;

s5: a subtask scheduling function is started through the subtask management component and the subtask scheduling component;

s6: starting the multi-device state processor through the multi-device state synchronization component, the multi-device state control component and the multi-device state distribution component;

s7: the multi-device state distributor is started.