Automated monitoring method, apparatus, electronic device, and computer-readable storage medium

By designing a multi-level flume system and independently connecting pipelines, the problem of insufficient realism and accuracy in river network simulation was solved, enabling efficient and automated monitoring of river ecological effects and improving the realism and reliability of the simulation.

CN120870487BActive Publication Date: 2026-06-09WATER ENG ECOLOGICAL INST CHINESE ACAD OF SCI

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
WATER ENG ECOLOGICAL INST CHINESE ACAD OF SCI
Filing Date
2025-07-10
Publication Date
2026-06-09

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Abstract

This application provides an automated monitoring method, device, electronic equipment, and computer-readable storage medium. The method is applied to an ecological effect simulation system, which includes a water tank, connecting pipes, and a water supply device. The water tank comprises N levels, wherein the first water tank at the i-th level is at a first height above the horizontal plane that is less than the second height of the second water tank at the (i+1)-th level above the horizontal plane. Each first water tank is connected to at least two second water tanks via connecting pipes. The water supply device supplies water to the uppermost water tank at the N-th level. The method includes: responding to a water quality monitoring command and determining a first target water tank to be monitored; collecting water quality characteristic parameters of the water in the first target water tank at first preset time intervals; and sending a first reminder message if the monitored water quality characteristic parameters do not meet preset water quality requirements. This application can improve the realism and accuracy of river network ecological effect simulation.
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Description

Technical Field

[0001] This application relates to the field of water ecological simulation experimental device technology, and in particular to an automated monitoring method, device, electronic equipment and computer-readable storage medium. Background Technology

[0002] River networks are vital ecosystems, and their connectivity (including longitudinal, lateral, vertical, and temporal dimensions) is crucial for maintaining the structure and function of river ecosystems. Research on the regulation of river network connectivity and its ecological effects is of great significance for river ecological protection, water resource management, and water pollution prevention.

[0003] Among related technologies, methods for studying the ecological effects of river networks mainly include field observation and indoor simulation experiments. Field observation can reflect the real situation, but the influencing factors are complex, making it difficult to accurately control and separate variables, and it is also time-consuming and costly. Traditional indoor simulation experiments (such as using a single flume or a simple parallel flume array) are highly controllable, but they often fail to simulate the complex hierarchical structure and multi-scale characteristics of real river networks. Summary of the Invention

[0004] In view of this, this application provides an automated monitoring method, device, electronic equipment, and computer-readable storage medium, which can improve the realism and accuracy of river network ecological effect simulation.

[0005] The first aspect of this application provides an automated monitoring method applied to a river network-based ecological effect simulation system. The ecological effect simulation system includes a water tank, connecting pipes, and a water supply device. The water tank comprises N levels. Vertically, the first water tank at the i-th level is at a first height from the horizontal plane less than the second height of the second water tank at the (i+1)-th level from the horizontal plane, where N is an integer greater than 2, and i is any integer from 1 to N-1. The number of second water tanks is greater than the number of first water tanks. Each first water tank is connected to at least two second water tanks via the connecting pipes, wherein each second water tank is connected to the first water tank via an independent connecting pipe. The water supply device supplies water to the uppermost water tank at the N-th level. The method includes: responding to a water quality monitoring command and determining a first target water tank to be monitored within the water tank; collecting water quality characteristic parameters of the water in the first target water tank at first preset intervals; and sending a first reminder message if the water quality characteristic parameters do not meet preset water quality requirements.

[0006] In one possible implementation, responding to a water quality monitoring instruction and determining the first target water tank to be monitored in the water tank includes: receiving river network ecological effect monitoring request information sent by a user; determining the first target level to be monitored among N levels based on the river network ecological effect monitoring request information; selecting the first target water tank from the first target level, wherein at least one first target water tank needs to be selected for each first target level.

[0007] In one possible implementation, the water quality characteristic parameters include one or any combination of the following: temperature, pH value, dissolved oxygen, turbidity, and chlorophyll a concentration.

[0008] In one possible implementation, the method further includes: responding to a water level monitoring command to determine a second target water tank to be monitored in the water tank; collecting the water level of the second target water tank every second preset time interval; and sending a second reminder message if the water level is detected to be below the preset water level requirement.

[0009] In one possible implementation, the step of responding to a water level monitoring command and determining the second target water tank to be monitored in the water tank includes: receiving river network water level monitoring request information sent by a user; determining the second target level to be monitored among N levels based on the river network water level monitoring request information; and selecting the second target water tank from the second target level, wherein at least one second target water tank needs to be selected for each second target level.

[0010] In one possible implementation, the method further includes: responding to a water flow rate monitoring command to determine a third target water tank to be monitored in the water tank; collecting the water flow rate at the outlet of the third target water tank every third preset time interval; and sending a third reminder message if the water flow rate is detected to be inconsistent with the preset water flow rate requirement.

[0011] In one possible implementation, the step of responding to a water flow velocity monitoring command and determining the third target water tank to be monitored in the water tank includes: receiving river network water flow velocity monitoring request information sent by a user; determining the third target level to be monitored among N levels based on the river network water flow velocity monitoring request information; and selecting the third target water tank from the third target level, wherein at least one third target water tank needs to be selected for each third target level.

[0012] Secondly, this application also provides an automated monitoring device applied to a river network-based ecological effect simulation system. The ecological effect simulation system includes a water tank, connecting pipes, and a water supply device. The water tank comprises N levels. In the vertical direction, the first water tank at the i-th level is at a first height from the horizontal plane less than the second water tank at the (i+1)-th level, where N is an integer greater than 2, and i is any integer between 1 and N-1. The number of second water tanks is greater than the number of first water tanks. For each first water tank, there are at least two second water tanks. The connection is made through the connecting pipes, wherein each of the second water tanks is connected to the first water tank through an independent connecting pipe; the water supply device is used to supply water to the uppermost water tank located in the Nth level; the automated monitoring device includes: a determination module, a data acquisition module, and a monitoring module; the determination module is used to respond to water quality monitoring instructions and determine the first target water tank to be monitored in the water tanks; the data acquisition module is used to acquire water quality characteristic parameters of the water in the first target water tank at first preset time intervals; the monitoring module is used to send a first reminder message when the water quality characteristic parameters are detected to not meet the preset water quality requirements.

[0013] Thirdly, embodiments of this application also provide an electronic device, the electronic device including a processor and a memory, the memory being used to store instructions, and the processor being used to call the instructions in the memory, causing the electronic device to execute the automated monitoring method as described in the first aspect.

[0014] Fourthly, embodiments of this application also provide a computer-readable storage medium that stores computer instructions that, when executed on an electronic device, cause the electronic device to perform the automated monitoring method as described in the first aspect.

[0015] Compared with related technologies, this application has at least the following advantages: By setting the water tank to include N levels, and in the vertical direction, the first water tank at the i-th level is at a lower height from the horizontal plane than the second water tank at the (i+1)-th level. That is, there is a height difference between adjacent levels of water tanks, allowing water in higher-level tanks to automatically flow into lower-level tanks due to the height difference. This achieves the simulation of the river network's hierarchical structure and multi-scale characteristics, ensuring the realism of the river network simulation system. By setting the number of second water tanks at higher levels to be greater than the number of first water tanks at lower levels, and by connecting at least two second water tanks to the first water tank via independent connecting pipes, the simulation of the river network's hierarchical structure and multi-scale characteristics is further achieved, thereby further improving the realism of the river network simulation system. By collecting water quality characteristic parameters of the first target water tank and sending a first reminder message when the water quality characteristic parameters do not meet the preset water quality requirements, the ecological effect simulation system can more realistically simulate the actual environment of the river network, thereby further improving the realism and reliability of the river network ecological effect simulation.

[0016] Furthermore, the aforementioned automated monitoring methods, devices, electronic equipment, and computer-readable storage media enable automatic monitoring of water quality within the ecological effect simulation system, thereby improving the accuracy of river network ecological effect simulation. Attached Figure Description

[0017] Figure 1 This is a flowchart illustrating the steps of an automated monitoring method provided in an embodiment of this application.

[0018] Figure 2 A schematic diagram of the functional modules of an ecological effect simulation system provided in an embodiment of this application.

[0019] Figure 3 This is a flowchart illustrating another step of the automated monitoring method provided in one embodiment of this application.

[0020] Figure 4 This is another flowchart of the automated monitoring method provided in an embodiment of this application.

[0021] Figure 5 This is a functional block diagram of an automated monitoring device provided in an embodiment of this application.

[0022] Figure 6 This is a schematic diagram of the structure of an electronic device provided in an embodiment of this application. Detailed Implementation

[0023] To better understand the above-mentioned objectives, features, and advantages of this application, the application will be described in detail below with reference to the accompanying drawings and specific embodiments. It should be noted that, unless otherwise specified, the embodiments and features described in these embodiments can be combined with each other.

[0024] The following description sets forth many specific details to provide a full understanding of this application. The described embodiments are only some, not all, of the embodiments of this application.

[0025] Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used herein in the specification of this application is for the purpose of describing particular embodiments only and is not intended to be limiting of this application.

[0026] It should be further noted that, in this document, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such a process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one..." does not exclude the presence of other identical elements in the process, method, article, or apparatus that includes that element.

[0027] In this application, "at least one" means one or more, and "more than one" means two or more. "And / or" describes the relationship between related objects, indicating that three relationships can exist. For example, A and / or B can represent: A alone, A and B simultaneously, or B alone, where A and B can be singular or plural. The terms "first," "second," "third," "fourth," etc. (if present) in the specification, claims, and drawings of this application are used to distinguish similar objects, not to describe a specific order or sequence.

[0028] In the embodiments of this application, the terms "exemplary" or "for example" are used to indicate that something is an example, illustration, or description. Any embodiment or design that is described as "exemplary" or "for example" in the embodiments of this application should not be construed as being more preferred or advantageous than other embodiments or design. Specifically, the use of the terms "exemplary" or "for example" is intended to present the relevant concepts in a specific manner.

[0029] For ease of understanding, exemplary descriptions of some concepts related to the embodiments of this application are provided for reference.

[0030] River networks, also known as river systems, refer to the complex water system structure formed by the interconnection of main channels, tributaries, and waterways at various levels. They are of significant value in natural geography, ecology, and technology. River networks typically exhibit a dendritic structure, consisting of main channels, multiple tributaries, and capillary-like waterways, similar to the human vascular system.

[0031] Please refer to Figure 1 , Figure 1 This is a flowchart illustrating the steps of an embodiment of the automated monitoring method of this application. Depending on different requirements, the order of the steps in this flowchart can be changed, and some steps can be omitted. The automated monitoring method of this application is applied to... Figure 2 The system shown is a simulation system of ecological effects based on river networks.

[0032] Please refer to Figure 2 This is a functional module diagram of the ecological effect simulation system provided in the embodiments of this application. For ease of explanation, the functional module diagram of the ecological effect simulation system only shows the parts related to the embodiments of this application. Those skilled in the art will understand that the illustrated structure does not constitute a limitation on the system, and may include more or fewer components than shown, or combine certain components, or have different component arrangements.

[0033] The ecological effect simulation system 10 includes a water tank 11, connecting pipes 12, and a water supply device 13. The water tank 11 includes N levels. In the vertical direction, the first water tank in the i-th level is at a first height from the horizontal plane less than the second water tank in the (i+1)-th level is at a second height from the horizontal plane, where N is an integer greater than 2, and i is any integer between 1 and N-1. The number of second water tanks is greater than the number of first water tanks. Each first water tank is connected to at least two second water tanks through connecting pipes 12, wherein each second water tank is connected to the first water tank through an independent connecting pipe 12. The water supply device 13 is used to supply water to the uppermost water tank in the N-th level, or to supply water to the lowermost water tank in the 1-th level.

[0034] Specifically, Figure 2 In the ecological effect simulation system 10 shown, the water tanks 11 comprise six levels, with the number of water tanks 11 decreasing progressively from the highest level (i.e., the 6th level) of 32: the 5th level has 16 water tanks 11, the 4th level has 8 water tanks 11, the 3rd level has 4 water tanks 11, the 2nd level has 2 water tanks 11, and the 1st level has 1 water tank 11. Figure 2As can be seen, on the one hand, the water supply device 13 is used to supply water to the water tank 11 located in the 6th level (i.e., the uppermost water tank); on the other hand, for two adjacent levels, the two water tanks 11 in the higher level are connected to one water tank 11 in the lower level through independent connecting pipes 12. With this arrangement, the uppermost water tank can simulate the source stream, and the water tank 11 in the 1st level (i.e., the lowermost water tank) can simulate the outlet of the main stream, ensuring the authenticity of the river network ecological effect simulation system 10.

[0035] It should be noted that this embodiment does not specifically limit the number of water tanks 11 in each level, or the connection relationship between water tanks in adjacent levels. The number of water tanks can be set according to the actual needs of simulating the real situation of the river network, thereby ensuring the authenticity of the simulation of the river network ecological effect.

[0036] The specific process of this embodiment is as follows: Figure 1 As shown, it includes the following steps:

[0037] S101, responding to the water quality monitoring command, identifies the first target water tank to be monitored in the water tank.

[0038] In some embodiments, the first target flume is determined by: receiving river network ecological effect monitoring request information sent by the user; determining the first target level to be monitored among N levels based on the river network ecological effect monitoring request information; selecting the first target flume from the first target level, wherein at least one first target flume needs to be selected for each first target level.

[0039] Understandably, users determine the tributaries in the river network that need to be monitored based on the real environmental conditions of the river network simulated by the ecological effect simulation system, and then send the river network ecological effect monitoring request information to the ecological effect simulation system based on the corresponding flume of the tributary.

[0040] S102, collect water quality characteristic parameters of the water in the first target water tank at first preset time intervals.

[0041] In some embodiments, the first preset duration is not specifically limited and can be set according to actual needs. When the first preset duration is set to 0, water quality characteristic parameters of the water in the first target water tank are collected in real time.

[0042] In some embodiments, water quality characteristic parameters include one or any combination of the following: temperature, pH value, dissolved oxygen, turbidity, and chlorophyll a concentration.

[0043] In some embodiments, a water quality monitoring sensor is installed inside the water tank, enabling the sensor to collect water quality characteristic parameters.

[0044] S103: If the water quality characteristic parameters are detected to be inconsistent with the preset water quality requirements, the first reminder message is sent.

[0045] In some embodiments, the type of the first reminder message is not specifically limited and can be set according to actual needs. For example, reminders can be given via voice broadcast or via text reminder.

[0046] Compared with related technologies, the embodiments of this application have at least the following advantages: By setting the water tank to include N levels, and in the vertical direction, the first water tank at the i-th level is at a first height from the horizontal plane less than the second water tank at the (i+1)-th level is at a second height from the horizontal plane. That is, there is a height difference between water tanks at adjacent levels, allowing water in the higher-level water tanks to automatically flow into the lower-level water tanks due to the height difference. This achieves the simulation of the river network's hierarchical structure and multi-scale characteristics, ensuring the realism of the river network simulation system. By setting the number of second water tanks at higher levels greater than the number of first water tanks at lower levels, and by setting at least two second water tanks connected to the first water tanks via independent connecting pipes, the simulation of the river network's hierarchical structure and multi-scale characteristics is further achieved, thereby further improving the realism of the river network simulation system. By collecting water quality characteristic parameters of the first target water tank and sending a first reminder message when the water quality characteristic parameters do not meet the preset water quality requirements, the ecological effect simulation system can more realistically simulate the actual environment of the river network, thereby further improving the realism and reliability of the river network ecological effect simulation.

[0047] Please refer to Figure 3 , Figure 3 This is a flowchart illustrating the steps of an embodiment of the automated monitoring method of this application. Depending on different needs, the order of the steps in this flowchart can be changed, and some steps can be omitted. This automated monitoring method is applied to the aforementioned ecological effect simulation system.

[0048] This embodiment is a further improvement on the aforementioned embodiment. The main improvement lies in the following: In this embodiment, the method further includes: responding to a water level monitoring command to determine a second target water tank to be monitored in the water tank; collecting the water level of the second target water tank every second preset time interval; and sending a second reminder message when the monitored water level does not meet the preset water level requirements. This approach enables the ecological effect simulation system to more realistically simulate the actual environment of the river network, thereby further improving the realism and accuracy of the river network ecological effect simulation.

[0049] The specific process of this embodiment is as follows: Figure 3 As shown, it includes the following steps:

[0050] S301, in response to a water quality monitoring instruction, identifies the first target water tank to be monitored in the water tank.

[0051] S302, collect water quality characteristic parameters of the water in the first target water tank at first preset time intervals.

[0052] S303: If the water quality characteristic parameters are detected to be inconsistent with the preset water quality requirements, the first reminder message will be sent.

[0053] S301 to S303 in this embodiment are similar to S101 to S103 in the previous embodiment. To avoid repetition, they will not be described again here.

[0054] S304, responding to the water level monitoring command, identifies the second target water tank to be monitored in the water tank.

[0055] In some embodiments, the determination of the second target water tank includes: receiving river network water level monitoring request information sent by a user; determining the second target level to be monitored in N levels based on the river network water level monitoring request information; and selecting the second target water tank from the second target level, wherein at least one second target water tank needs to be selected for each second target level.

[0056] Specifically, based on the real environmental conditions of the river network simulated by the ecological effect simulation system, users determine the tributaries in the river network that need to be monitored, and then send the river network water level monitoring request information to the ecological effect simulation system based on the corresponding flume of the tributary.

[0057] S305, collects the water level of the second target water tank every second preset time interval.

[0058] In some embodiments, the second preset duration is not specifically limited and can be set according to actual needs. When the second preset duration is set to 0, the water level of the second target water tank is collected in real time.

[0059] In some embodiments, a water level gauge is installed in the water tank so that the water level gauge can collect the water level of the water tank.

[0060] S306: If the water level is detected to be below the preset water level requirement, a second reminder message is sent.

[0061] In some embodiments, the type of the second reminder message is not specifically limited and can be set according to actual needs. For example, reminders can be given via voice broadcast or via text reminder.

[0062] Compared with related technologies, the embodiments of this application have at least the following advantages: By setting the water tank to include N levels, and in the vertical direction, the first water tank at the i-th level is at a first height from the horizontal plane less than the second water tank at the (i+1)-th level is at a second height from the horizontal plane. That is, there is a height difference between water tanks at adjacent levels, allowing water in the higher-level water tanks to automatically flow into the lower-level water tanks due to the height difference. This achieves the simulation of the river network's hierarchical structure and multi-scale characteristics, ensuring the realism of the river network simulation system. By setting the number of second water tanks at higher levels greater than the number of first water tanks at lower levels, and by setting at least two second water tanks connected to the first water tanks via independent connecting pipes, the simulation of the river network's hierarchical structure and multi-scale characteristics is further achieved, thereby further improving the realism of the river network simulation system. By collecting water quality characteristic parameters of the first target water tank and sending a first reminder message when the water quality characteristic parameters do not meet the preset water quality requirements, the ecological effect simulation system can more realistically simulate the actual environment of the river network, thereby further improving the realism and reliability of the river network ecological effect simulation.

[0063] Please refer to Figure 4 , Figure 4 This is a flowchart illustrating the steps of an embodiment of the automated monitoring method of this application. Depending on different needs, the order of the steps in this flowchart can be changed, and some steps can be omitted. This automated monitoring method is applied to the aforementioned ecological effect simulation system.

[0064] This embodiment is a further improvement on the aforementioned embodiment. The main improvement lies in the following: In this embodiment, the method further includes: responding to a water flow velocity monitoring command to determine a third target water tank to be monitored; collecting the water flow velocity at the outlet of the third target water tank every third preset time interval; and sending a third reminder message if the monitored water flow velocity does not meet the preset water flow velocity requirement. This approach enables the ecological effect simulation system to more realistically simulate the actual environment of the river network, thereby further improving the realism and reliability of the river network ecological effect simulation.

[0065] The specific process of this embodiment is as follows: Figure 4 As shown, it includes the following steps:

[0066] S401, in response to a water quality monitoring command, identifies the first target water tank to be monitored in the water tank.

[0067] S402, collect water quality characteristic parameters of the water in the first target water tank at first preset time intervals.

[0068] S403: If the water quality characteristic parameters are detected to be inconsistent with the preset water quality requirements, the first reminder message will be sent.

[0069] S401 to S403 of this embodiment are similar to S101 to S103 of the previous embodiment. To avoid repetition, they will not be described again here.

[0070] S403, responding to the water flow velocity monitoring command, identifies the third target water tank to be monitored in the water tank.

[0071] In some embodiments, determining the third target flume includes: receiving river network flow velocity monitoring request information sent by a user; determining the third target level to be monitored among N levels based on the river network flow velocity monitoring request information; and selecting the third target flume from the third target level, wherein at least one third target flume needs to be selected for each third target level.

[0072] Specifically, based on the real environmental conditions of the river network simulated by the ecological effect simulation system, users determine the tributaries in the river network that need to be monitored, and then send the river network water flow velocity monitoring request information to the ecological effect simulation system based on the corresponding flume of the tributary.

[0073] S404, collect the water flow rate at the outlet of the third target water tank every third preset time interval.

[0074] In some embodiments, the size of the third preset duration is not specifically limited and can be set according to actual needs. When the third preset duration is set to 0, the water flow rate at the outlet of the third target water tank is collected in real time.

[0075] S405: If the water flow rate is detected to be below the preset water flow rate requirement, a third reminder message is sent.

[0076] In some embodiments, the type of third-party reminder information is not specifically limited and can be set according to actual needs. For example, reminders can be given via voice broadcast or text reminder.

[0077] Compared with related technologies, the embodiments of this application have at least the following advantages: By setting the water tank to include N levels, and in the vertical direction, the first water tank at the i-th level is at a first height from the horizontal plane less than the second water tank at the (i+1)-th level is at a second height from the horizontal plane. That is, there is a height difference between water tanks at adjacent levels, allowing water in the higher-level water tanks to automatically flow into the lower-level water tanks due to the height difference. This achieves the simulation of the river network's hierarchical structure and multi-scale characteristics, ensuring the realism of the river network simulation system. By setting the number of second water tanks at higher levels greater than the number of first water tanks at lower levels, and by setting at least two second water tanks connected to the first water tanks via independent connecting pipes, the simulation of the river network's hierarchical structure and multi-scale characteristics is further achieved, thereby further improving the realism of the river network simulation system. By collecting water quality characteristic parameters of the first target water tank and sending a first reminder message when the water quality characteristic parameters do not meet the preset water quality requirements, the ecological effect simulation system can more realistically simulate the actual environment of the river network, thereby further improving the realism and reliability of the river network ecological effect simulation.

[0078] Based on the same idea as the automated monitoring method in the above embodiments, this application also provides an automated monitoring device. This automated monitoring is applied to the above-described river network-based ecological effect simulation system and can be used to execute the above-described automated monitoring method. For ease of explanation, the structural schematic diagram of the automated monitoring device embodiment only shows the parts related to the embodiments of this application. Those skilled in the art will understand that the illustrated structure does not constitute a limitation on the device, and it may include more or fewer components than shown, or combine certain components, or have different component arrangements.

[0079] like Figure 5 As shown, the automated monitoring device 50 includes a determination module 501, a data acquisition module 502, and a monitoring module 503. In some embodiments, these modules can be programmable software instructions stored in a memory and executable by a processor. It is understood that in other embodiments, these modules can also be program instructions or firmware embedded in a processor.

[0080] The determination module 501 is used to respond to a water quality monitoring command and determine the first target water tank to be monitored in the water tank.

[0081] The acquisition module 502 is used to acquire water quality characteristic parameters of the water in the first target water tank at first preset time intervals;

[0082] The monitoring module 503 is used to send a first reminder message when the water quality characteristic parameters are detected to not meet the preset water quality requirements.

[0083] Please refer to point 6. Figure 6 This is a schematic diagram of an embodiment of the electronic device of this application.

[0084] In some embodiments, processor 601 may be a central processing unit (CPU), microprocessor, or other data processing chip, used to run program code stored in memory 602 or process data, such as the river network-based ecological effect simulation system of the present invention.

[0085] In some embodiments, processor 601 may be a single server or a group of servers. The server group may be centralized or distributed. In some embodiments, processor 601 may be local or remote. In some embodiments, processor 601 may be implemented on a cloud platform. In one embodiment, the cloud platform may include a private cloud, public cloud, hybrid cloud, community cloud, distributed cloud, intranet, multi-cloud, etc., or any combination thereof.

[0086] In some embodiments, memory 602 may be an internal storage unit of electronic device 600, such as a hard disk or memory of electronic device 600. In other embodiments, memory 602 may also be an external storage device of electronic device 600, such as a plug-in hard disk, smart media card (SMC), secure digital (SD) card, flash card, etc. equipped on electronic device 600.

[0087] Furthermore, the memory 602 may include both internal storage units of the electronic device 600 and external storage devices. The memory 602 is used to store application software and various types of data installed on the electronic device 600.

[0088] In some embodiments, display 603 may be an LED display, a liquid crystal display, a touch-sensitive liquid crystal display, or an OLED (Organic Light-Emitting Diode) touchscreen. Display 603 is used to display information from electronic device 600 and to display a visual user interface. Components 601-603 of electronic device 500 communicate with each other via a system bus.

[0089] In one embodiment, when processor 601 executes the automated monitoring program in memory 602, the following steps can be implemented:

[0090] In response to a water quality monitoring command, the first target water tank to be monitored in the water tank is determined;

[0091] Water quality characteristic parameters of the water in the first target water tank are collected at first preset time intervals;

[0092] If the water quality characteristic parameters are detected to be inconsistent with the preset water quality requirements, a first reminder message will be sent.

[0093] It should be understood that when the processor 601 executes the automated monitoring program in the memory 602, in addition to the functions mentioned above, it can also perform other functions, as detailed in the description of the corresponding method embodiments above.

[0094] Furthermore, this embodiment of the invention does not specifically limit the type of electronic device 600 mentioned. Electronic device 600 can be a mobile phone, tablet computer, personal digital assistant (PDA), wearable device, laptop computer, or other portable electronic device. Exemplary embodiments of portable electronic devices include, but are not limited to, portable electronic devices running iOS, Android, Microsoft, or other operating systems. The aforementioned portable electronic device can also be other portable electronic devices, such as a laptop computer with a touch-sensitive surface (e.g., a touch panel). It should also be understood that in some other embodiments of the invention, electronic device 600 may not be a portable electronic device, but rather a desktop computer with a touch-sensitive surface (e.g., a touch panel).

[0095] Accordingly, this application also provides a computer-readable storage medium for storing computer-readable programs or instructions. When the programs or instructions are executed by a processor, they can implement the steps or functions of the automated monitoring methods provided in the above-described method embodiments.

[0096] Those skilled in the art will understand that all or part of the processes of the methods described in the above embodiments can be implemented by a computer program instructing related hardware (such as a processor, controller, etc.), and the computer program can be stored in a computer-readable storage medium. The computer-readable storage medium may be a disk, optical disk, read-only memory, or random access memory, etc.

[0097] The above provides a detailed description of the automated monitoring method, apparatus, electronic device, and computer-readable storage medium provided in this application. Specific examples have been used to illustrate the principles and implementation methods of this application. The descriptions of the above embodiments are only for the purpose of helping to understand the method and core ideas of this application. At the same time, those skilled in the art will recognize that there will be changes in the specific implementation methods and application scope based on the ideas of this application. Therefore, the content of this specification should not be construed as a limitation of this application.

Claims

1. An automated monitoring method, characterized in that, An ecological effect simulation system based on river networks is applied, the ecological effect simulation system including a water tank, connecting pipes and a water supply device; The water tank includes N levels. In the vertical direction, the first water tank located at the i-th level is at a first height from the horizontal plane, which is less than the second water tank located at the (i+1)-th level is at a second height from the horizontal plane. Here, N is an integer greater than 2, and i is any integer between 1 and N-1. The number of the second water tanks is greater than the number of the first water tanks. For each of the first water tanks, it is connected to at least two of the second water tanks via the connecting pipe, wherein each of the second water tanks is connected to the first water tank via an independent connecting pipe; The water supply device is used to supply water to the uppermost water tank located in the Nth level; The method includes: In response to a water quality monitoring command, the first target water tank to be monitored in the water tank is determined; Water quality characteristic parameters of the water in the first target water tank are collected at first preset time intervals; If the water quality characteristic parameters are detected to be inconsistent with the preset water quality requirements, a first reminder message is sent; the step of responding to the water quality monitoring command and determining the first target water tank to be monitored in the water tank includes: Receive user requests for monitoring the ecological effects of the river network; Based on the river network ecological effect monitoring needs information, determine the first target level to be monitored from among the N levels; The first target tank is selected from the first target level, wherein at least one first target tank needs to be selected for each first target level.

2. The automated monitoring method according to claim 1, characterized in that, The water quality characteristic parameters include one or any combination of the following: Temperature, pH value, dissolved oxygen, turbidity, and chlorophyll a concentration.

3. The automated monitoring method according to claim 1, characterized in that, The method further includes: In response to a water level monitoring command, the second target water tank to be monitored in the water tank is determined; The water level of the second target water tank is collected every second preset time interval; If the water level is detected to be below the preset water level requirement, a second reminder message will be sent.

4. The automated monitoring method according to claim 3, characterized in that, The response to the water level monitoring command, determining the second target water tank to be monitored in the water tank, includes: Receive user requests for river network water level monitoring; Based on the river network water level monitoring requirements, determine the second target level to be monitored from among the N levels; Select the second target tank from the second target level, wherein at least one second target tank needs to be selected for each second target level.

5. The automated monitoring method according to claim 1, characterized in that, The method further includes: In response to the water flow velocity monitoring command, the third target water tank to be monitored in the water tank is determined; The water flow rate at the outlet of the third target water tank is collected every third preset time interval; If the water flow rate is detected to be below the preset water flow rate requirement, a third reminder message will be sent.

6. The automated monitoring method according to claim 5, characterized in that, The response to the water flow velocity monitoring command, determining the third target water tank to be monitored in the water tank, includes: Receive user requests for river network water flow velocity monitoring; Based on the river network water flow velocity monitoring requirements, determine the third target level to be monitored from among the N levels; The third target tank is selected from the third target level, wherein at least one third target tank needs to be selected for each third target level.

7. An automated monitoring device, characterized in that, An ecological effect simulation system based on river networks is applied, the ecological effect simulation system including a water tank, connecting pipes and a water supply device; The water tank includes N levels. In the vertical direction, the first water tank located at the i-th level is at a first height from the horizontal plane, which is less than the second water tank located at the (i+1)-th level is at a second height from the horizontal plane. Here, N is an integer greater than 2, and i is any integer between 1 and N-1. The number of the second water tanks is greater than the number of the first water tanks. For each of the first water tanks, it is connected to at least two of the second water tanks via the connecting pipe, wherein each of the second water tanks is connected to the first water tank via an independent connecting pipe; The water supply device is used to supply water to the uppermost water tank located in the Nth level; The automated monitoring device includes: a determination module, a data acquisition module, and a monitoring module; The determining module is used to respond to a water quality monitoring command and determine a first target water tank to be monitored in the water tank; the process of responding to a water quality monitoring command and determining the first target water tank to be monitored in the water tank includes: Receive user requests for monitoring the ecological effects of the river network; Based on the river network ecological effect monitoring needs information, determine the first target level to be monitored from among the N levels; The first target tank is selected from the first target level, wherein at least one first target tank needs to be selected for each first target level; The acquisition module is used to acquire water quality characteristic parameters of the water in the first target water tank at first preset time intervals; The monitoring module is used to send a first reminder message when it detects that the water quality characteristic parameters do not meet the preset water quality requirements.

8. An electronic device, the electronic device comprising a processor and a memory, characterized in that, The memory is used to store instructions, and the processor is used to call the instructions in the memory to cause the electronic device to execute the automated monitoring method as described in any one of claims 1 to 6.

9. A computer-readable storage medium, characterized in that, The computer-readable storage medium stores computer instructions that, when executed on an electronic device, cause the electronic device to perform the automated monitoring method as described in any one of claims 1 to 6.