CN116030599A - Slope monitoring device control method, slope monitoring device and storage medium - Google Patents

Abstract

The invention discloses a slope monitoring equipment control method, slope monitoring equipment and a storage medium, wherein the slope monitoring equipment control method comprises the following steps: s10, waking up the system according to a wake-up mode, and collecting slope monitoring data; s20, judging a slope early warning grade according to slope monitoring data; s30, setting the wake-up time of the next period of the system according to the slope early warning level, and uploading slope monitoring data at regular time; s40, turning off a system power supply, entering a standby mode, waking up the system after the system wake-up time, and collecting slope monitoring data of the next period. The technical scheme of the invention aims to reduce the power consumption of the slope monitoring equipment and increase the duration of the slope monitoring equipment.

Description

Slope monitoring device control method, slope monitoring device and storage medium

Technical Field

The invention relates to the field of slope monitoring equipment, in particular to a slope monitoring equipment control method, slope monitoring equipment and a storage medium.

Background

The current slope monitoring equipment generally refers to equipment for monitoring the speed, direction and the like of slope displacement in order to grasp the moving condition of slope rocks and find out the damage sign of the slope; because the slope monitoring equipment is usually in an automatic monitoring mode, the slope monitoring equipment needs to always keep monitoring on the slope condition, so that the power consumption of the slope monitoring equipment is higher, and the endurance time of the slope monitoring equipment can be reduced.

Disclosure of Invention

The invention mainly aims to provide a control method of slope monitoring equipment, the slope monitoring equipment and a storage medium, and aims to reduce power consumption of the slope monitoring equipment and increase the endurance time of the slope monitoring equipment.

In order to achieve the above purpose, the invention provides a control method of slope monitoring equipment, comprising the following steps:

s10, waking up the system according to a wake-up mode, and collecting slope monitoring data;

s20, judging a slope early warning grade according to slope monitoring data;

s30, setting the wake-up time of the next period of the system according to the slope early warning level, and uploading slope monitoring data at regular time;

s40, turning off a system power supply, entering a standby mode, waking up the system after the system wake-up time, and collecting slope monitoring data of the next period.

Optionally, the wake-up system according to the wake-up mode specifically collects slope monitoring data as follows:

waking up the system through a manual mode, and collecting surface displacement data and surface inclination data;

and waking up the system through an automatic mode, and collecting surface displacement data and surface inclination data.

Optionally, selecting an awake mode wake-up system, and collecting slope monitoring data further includes the following steps:

judging whether to turn on a Bluetooth module power supply according to the wake-up mode;

if the system is awakened by the manual mode, starting a Bluetooth module power supply and debugging equipment parameters;

if the system is awakened by the automatic mode, the Bluetooth module power supply is not started.

Optionally, the step of judging the slope early warning level according to the slope monitoring data specifically comprises the following steps:

presetting a plurality of early warning threshold intervals, wherein each early warning threshold interval corresponds to one slope early warning grade;

judging which early warning threshold interval the collected slope monitoring data are in;

and determining the slope early warning grade according to the early warning threshold interval corresponding to the slope monitoring data.

Optionally, the step of setting a wake-up time of a next period according to the slope early-warning level and uploading the slope monitoring data at regular time specifically includes:

setting the interval time from the standby mode to automatic awakening of the system according to the early warning level;

and setting the time period for uploading the slope monitoring data by the system according to the early warning level.

Optionally, the uploading the slope monitoring data further includes:

judging whether the wireless communication module is normal or not;

if the wireless communication module is normal, uploading the slope monitoring data to a server terminal and storing the slope monitoring data as historical data;

if the wireless communication module is abnormal, storing the slope monitoring data to a backup area, and repeating the step of judging whether the wireless communication module is normal or not after waiting for the next system wakeup.

Optionally, the system power is turned off, a standby mode is entered, and the system is awakened after the system awakening time elapses, and the next period of slope monitoring data is collected specifically as follows:

after the side slope monitoring data are collected and uploaded, a system power supply is turned off, and a standby mode is entered;

starting timing after entering a standby mode, and stopping timing after the timing time reaches the wake-up time;

and after stopping timing, automatically waking up the system and continuously collecting slope monitoring data.

The invention also provides slope monitoring equipment, which comprises:

the inclination sensor is used for acquiring and outputting surface inclination data;

the stay cord sensor is used for collecting and outputting surface displacement data;

the input end of the communication processing module is connected with the output end of the inclination sensor and the output end of the pull rope sensor, a slope monitoring equipment control program is stored in the communication processing module, and the slope monitoring equipment control program realizes the slope monitoring equipment control method when being executed by the communication processing module.

Optionally, the communication processing module includes:

a memory storing the slope monitoring device control program;

the input end of the processor is connected with the output end of the inclination sensor and the output end of the pull rope sensor, the processor is also connected with the memory, and the slope monitoring equipment control program realizes the slope monitoring equipment control method when being executed by the processor.

The invention also proposes a storage medium having stored thereon a computer program which, when executed by a processor, implements the steps of a slope monitoring apparatus control method as described above.

According to the technical scheme, the wake-up mode wake-up system can be selected, and slope monitoring data are collected; judging the slope early warning grade according to the collected slope monitoring data; setting the wake-up time of the next period of the system according to the slope early warning grade, and uploading slope monitoring data at regular time; and finally, turning off a system power supply, entering a standby mode, waking up the system after the system wake-up time, and collecting slope monitoring data of the next period; by collecting slope monitoring data at intervals, the slope monitoring equipment does not need to be started all the time, so that the power consumption of the slope monitoring equipment is reduced. The invention aims to reduce the power consumption of slope monitoring equipment and increase the endurance time of the slope monitoring equipment.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings may be obtained according to the structures shown in these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a diagram showing the steps of a method for controlling a slope monitoring apparatus according to an embodiment of the present invention;

fig. 2 is a schematic functional block diagram of an embodiment of the slope monitoring apparatus according to the present invention.

Reference numerals illustrate:

reference numerals	Name of the name	Reference numerals	Name of the name
				10	Inclination sensor	30	Communication processing module
20	Pull rope sensor

The achievement of the objects, functional features and advantages of the present invention will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

It should be noted that, if directional indications (such as up, down, left, right, front, and rear … …) are included in the embodiments of the present invention, the directional indications are merely used to explain the relative positional relationship, movement conditions, etc. between the components in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indications are correspondingly changed.

In addition, if there is a description of "first", "second", etc. in the embodiments of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present invention.

The invention provides a control method of slope monitoring equipment.

Referring to fig. 1, in an embodiment of the present invention, the slope monitoring apparatus control method includes the steps of:

s10, waking up the system according to a wake-up mode, and collecting slope monitoring data;

s20, judging a slope early warning grade according to slope monitoring data;

s30, setting the wake-up time of the next period of the system according to the slope early warning level, and uploading slope monitoring data at regular time;

s40, turning off a system power supply, entering a standby mode, waking up the system after the system wake-up time, and collecting slope monitoring data of the next period.

In this embodiment, with respect to step S10, after the different wake-up modes are selected, the slope monitoring data may be collected, for example, the wake-up mode may include manual wake-up or automatic wake-up, the automatic wake-up mode may be set to automatically wake-up the system to collect the slope monitoring data at intervals of a period of time, and the automatic wake-up mode may be set to automatically operate after the system is started for the first time; the manual wake-up mode can be used under the condition that the automatic wake-up mode fails or is special, for example, a user wants to know the specific condition of the slope monitoring data, and the system is not woken up, and the manual wake-up mode can be adopted to wake up the system to collect the slope monitoring data; the manual wake-up can be performed by an external device connection system or a manual control system in a power-on mode and the like to control the system to change from the standby mode to the working mode. The system is awakened by different awakening modes, so that the system can be suitable for different conditions, for example, an automatic awakening mode can be used for the condition that a user is inconvenient to monitor, and the system is automatically awakened to acquire slope monitoring data; the manual wake-up mode can be used for emergency, and slope monitoring data are collected through the manual forced wake-up system. And the slope monitoring data collected by the manual awakening system and the automatic awakening system are the same.

Regarding step S20, the side slope early warning level may be determined according to the collected side slope monitoring data, for example, the side slope monitoring data may be a surface gradient of the side slope, where the greater the surface gradient is, the higher the side slope early warning level is, the higher the dangerous level of the side slope is, and the smaller the surface gradient is, the lower the side slope early warning level is, and the lower the dangerous level of the dangerous side slope is; the corresponding relation between the slope monitoring data and the slope early warning level can be set according to actual conditions, for example, for a region with loose geology, the lower surface gradient can be corresponding to the higher slope early warning level, and for a region with tight geology, the higher surface gradient can be corresponding to the lower slope early warning level.

Regarding step S30, the system wake-up time of the next period may be set according to different early warning levels, so as to collect slope monitoring data of the next period by the wake-up system at regular time. For example, the higher the early warning level is, the higher the dangerous degree is, the slope monitoring data needs to be collected frequently so as to avoid accidents, and the shorter the wake-up time of the next period of the system is, namely the shorter the time from standby to wake-up is; the lower the early warning level is, the lower the danger level is, the lower the probability of accident is, the slope monitoring data do not need to be collected frequently, and the longer the wake-up time of the next period of the system is, namely the longer the time from standby to wake-up is. And the higher the early warning level is, the shorter the awakening time is, and the more times of collecting slope monitoring data and uploading the data are provided, so that the monitoring on the slope condition can be kept.

Regarding step S40, after the side slope monitoring data is collected, the system power can be turned off, and the standby mode is entered, and only the most basic power is reserved; and the system can start timing after entering a standby mode, automatically awaken the system after the timing time reaches the preset awakening time, start collecting slope monitoring data of the next period, enter a standby mode after uploading the slope monitoring data, wait for the next awakening, and repeatedly circulate.

According to the scheme, slope monitoring data can be acquired at intervals, the time length of a standby mode is determined according to the actual dangerous degree of the slope, the slope can be monitored all the time, the overall power consumption of the slope monitoring equipment is reduced, and the overall working time of the slope monitoring equipment is prolonged.

According to the technical scheme, the wake-up mode wake-up system can be selected, and slope monitoring data are collected; judging the slope early warning grade according to the collected slope monitoring data; setting the wake-up time of the next period of the system according to the slope early warning grade, and uploading slope monitoring data at regular time; and finally, turning off a system power supply, entering a standby mode, waking up the system after the system wake-up time, and collecting slope monitoring data of the next period; by collecting slope monitoring data at intervals, the slope monitoring equipment does not need to be started all the time, so that the power consumption of the slope monitoring equipment is reduced. The invention aims to reduce the power consumption of slope monitoring equipment and increase the endurance time of the slope monitoring equipment.

In an embodiment, the wake-up system according to the wake-up mode collects slope monitoring data specifically as follows:

waking up the system through a manual mode, and collecting surface displacement data and surface inclination data;

and waking up the system through an automatic mode, and collecting surface displacement data and surface inclination data.

In this embodiment, the system may be awakened in a manual mode, or in an automatic mode, and the surface displacement data and the surface inclination data may be collected after the system is awakened. The manual mode can comprise power-on awakening and magnetic control awakening, wherein the power-on awakening can be used when the slope monitoring equipment is started for the first time, and the magnetic control awakening can be used in the operation process of the slope monitoring equipment. The magnetic control awakening means that a magnet is used for approaching the slope monitoring equipment, the slope monitoring equipment can awaken from a standby state, and slope monitoring data are collected. The automatic mode is that the slope monitoring equipment collects slope monitoring data and uploads the slope monitoring data to the server terminal, then enters a standby mode, automatically wakes up after a preset wake-up time, collects slope monitoring data of the next period and uploads the slope monitoring data to the server terminal, and the automatic mode can automatically operate after the system is started for the first time in a reciprocating cycle; in the standby process of the automatic mode, the system can be awakened to collect slope monitoring data through the magnetic control awakening of the manual mode, and then the next period enters the automatic awakening mode.

In an embodiment, the wake-up mode wake-up system is selected, and the collecting slope monitoring data further includes the following steps:

judging whether to turn on a Bluetooth module power supply according to the wake-up mode;

if the system is awakened by the manual mode, starting a Bluetooth module power supply and debugging equipment parameters;

if the system is awakened by the automatic mode, the Bluetooth module power supply is not started.

In this embodiment, the system needs to be configured and debugged by a manual mode wake-up system, and the bluetooth module needs to be started for configuration and debugging, such as device parameter debugging; the automatic mode wake-up system does not need to configure and debug equipment, so that the Bluetooth module does not need to be started. Therefore, according to different wake-up modes, whether the power supply of the Bluetooth module is started or not can be selected, when the system is awakened in the manual mode, the power supply of the Bluetooth module is started, the system is started only in the current acquisition period, after the current period is ended, the system is awakened in the automatic mode, and the power supply of the Bluetooth module is also closed. Thus, the overall power consumption of the system can be saved.

In an embodiment, the determining the slope early warning level according to the slope monitoring data specifically includes:

presetting a plurality of early warning threshold intervals, wherein each early warning threshold interval corresponds to one slope early warning grade;

judging which early warning threshold interval the collected slope monitoring data are in;

and determining the slope early warning grade according to the early warning threshold interval corresponding to the slope monitoring data.

In this embodiment, a plurality of early warning threshold intervals may be preset, and each early warning threshold interval corresponds to a slope early warning level; when the collected slope monitoring data belongs to a certain early warning threshold value interval, the current slope early warning level is the early warning level corresponding to the early warning threshold value interval. The early warning threshold interval can be set by surface displacement data of the side slope or by surface inclination of the side slope, the surface displacement can be detected by the pull rope sensor 20 or other devices with the same function, and the surface inclination can be detected by the inclination sensor 10 or other devices with the same function. The specific corresponding relation between the slope monitoring data and the slope early warning level can be set according to actual conditions. For example, the larger the surface displacement is, the higher the early warning level is, and the higher the danger of the side slope is; or the larger the surface gradient is, the higher the early warning level is, and the higher the danger of the side slope is.

In an embodiment, the setting the wake-up time of the next period according to the slope early-warning level and the uploading the slope monitoring data at regular time specifically includes:

setting the interval time from the standby mode to automatic awakening of the system according to the early warning level;

and setting the time period for uploading the slope monitoring data by the system according to the early warning level.

In this embodiment, the interval time from the standby mode to the automatic wake-up of the system and the time period of uploading the slope monitoring data by the system can be set according to the early warning level, for example, the higher the early warning level is, the higher the dangerous degree of the slope is, the shorter the interval time from the standby mode to the automatic wake-up of the set system is, and the slope monitoring data needs to be frequently collected and uploaded; the lower the early warning level is, the lower the dangerous level of the slope is, the longer the interval time from the standby mode to the automatic awakening is, and the slope monitoring data does not need to be frequently collected and uploaded; the corresponding relation between the early warning level and the slope monitoring data as well as the data reporting period can refer to the following table, and the specific corresponding relation can be set according to the actual situation, so that the scheme is not limited.

In an embodiment, the uploading the slope monitoring data further includes:

judging whether the wireless communication module is normal or not;

if the wireless communication module is normal, uploading the slope monitoring data to a server terminal and storing the slope monitoring data as historical data;

if the wireless communication module is abnormal, storing the slope monitoring data to a backup area, and repeating the step of judging whether the wireless communication module is normal or not after waiting for the next system wakeup.

In this embodiment, when uploading the slope monitoring data, the state of the wireless communication module is first determined, and if the communication quality of the wireless communication module in the current sampling period is good, the slope monitoring data can be directly uploaded to the server terminal; the user can inquire slope monitoring data through a server terminal, and the server terminal can be a computer and other equipment; if the wireless communication module in the sampling period has poor communication quality and cannot upload data normally, the acquired data can be stored in a backup area; and after the communication module is communicated and recovered to normal, detecting whether backup data needing to be uploaded exists or not when the communication module is communicated and recovered to normal, if so, reporting the backup data to a server, and storing the backup data as historical data after the backup data is successfully uploaded. If the communication module is damaged, the communication module cannot be recovered to be normal. The stored backup data and the historical data can be derived from the detection equipment by manually utilizing a Bluetooth communication mode, and the subsequent data analysis requirements can be met.

In an embodiment, the system power is turned off, the system enters a standby mode, and the system is awakened after the system awakening time, and the collecting of slope monitoring data of the next period is specifically:

after the side slope monitoring data are collected and uploaded, a system power supply is turned off, and a standby mode is entered;

starting timing after entering a standby mode, and stopping timing after the timing time reaches the wake-up time;

and after stopping timing, automatically waking up the system and continuously collecting slope monitoring data.

In this embodiment, after the slope monitoring data is collected and uploaded, the power supply of the main module of the system, such as the communication module, may be turned off, and the system enters a standby mode, at this time, the system starts to count time, and stops counting after the counted time reaches the wake-up time, and the wake-up time may be set according to the above embodiment; and after the timing is stopped, the system is automatically awakened, the power supply of the main module of the system is started, slope monitoring data of the next period are collected, and the slope monitoring data are uploaded to the server terminal. The system can repeat the process in the automatic mode, and can reduce the power consumption of the system in the standby mode, so that the overall power consumption of the slope monitoring equipment can be reduced, and the working time is prolonged.

The invention also provides slope monitoring equipment.

Referring to fig. 1 and 2, in one embodiment, the slope monitoring apparatus includes:

an inclination sensor 10, the inclination sensor 10 being for collecting and outputting surface inclination data;

a pull-cord sensor 20, the pull-cord sensor 20 for collecting and outputting surface displacement data;

the input end of the communication processing module 30 is connected with the output end of the inclination sensor 10 and the output end of the pull rope sensor 20, and a slope monitoring device control program is stored in the communication processing module 30, and when the slope monitoring device control program is executed by the communication processing module 30, the slope monitoring device control method is realized.

In this embodiment, the tilt sensor 10 may be composed of a low power consumption MPU6500 six-axis motion processing sensor, an operating current of 3.2mA, and a low power accelerometer mode current: 0.98Hz was 6.37uA,31.25Hz was 17.75uA. Acceleration awakening is supported, and when sudden dangerous situations occur, the monitor can be quickly awakened to enter a working state and respond in real time; and the device can also be composed of other devices with the same functions, and can be specifically selected according to the time situation. The pull rope sensor 20 can be an AD sampling circuit designed by a low-power-consumption AD7791 chip, and an SPI communication interface is used, so that a 4-20mA two-wire system current signal circuit or an RS485 communication circuit used by a conventional pull rope sensor 20 in the market is abandoned; the low power pull-cord sensor 20 has an overall quiescent current of about 427uA. The communication processing module 30 may be configured by a processor, a memory, and other devices, and the communication processing module 30 may store therein a slope monitoring device control program, which when executed by the communication processing module 30, may implement the slope monitoring device control method described above. It can be understood that when the slope monitoring device enters the standby mode, the power supply of the pull rope sensor 20 and the communication processing module 30 can be turned off, and the tilt sensor 10 enters the low power consumption mode, because the tilt sensor 10 has the function of waking up the device abnormally, and needs to be always powered, when the device is in abnormal movement, the tilt sensor 10 can detect and wake up the slope monitoring device.

In one embodiment, the communication processing module 30 includes:

a memory storing the slope monitoring device control program;

and the input end of the processor is connected with the output end of the inclination sensor 10 and the output end of the stay rope sensor 20, the processor is also connected with the memory, and the slope monitoring equipment control program realizes the slope monitoring equipment control method when being executed by the processor.

In this embodiment, the memory may be an E2PROM or DDR3 memory, and the memory may store a slope monitoring device control program; the processor may be a digital signal processor (Digital Signal Processor, DSP for short), a programmable logic device (ProgrammableLogic Device, PLD for short), a field programmable gate array (FieldProgrammable Gate Array, FPGA for short), a microprocessor, an MCU single-chip or other electronic components.

In an embodiment, the slope monitoring device may further include a power module, a power supply control module, and the like, where the power module may be a circuit designed by using TPS63900 devices or other devices, and the power module may supply power to devices such as the inclination sensor 10, the pull rope sensor 20, and the communication processing module 30, and the power supply control module mainly functions to turn off power supply of some modules when data is collected or the system goes to sleep, for example: the Bluetooth module, the communication module and the stay cord sensor 20 module are powered off during sleep, so that the modules do not consume electric quantity in the sleep process.

The invention also proposes a storage medium having stored thereon a computer program which, when executed by a processor, implements the steps of a slope monitoring apparatus control method as described above.

The foregoing description is only of the optional embodiments of the present invention, and is not intended to limit the scope of the invention, and all the equivalent structural changes made by the description of the present invention and the accompanying drawings or direct/indirect application in other related technical fields are included in the scope of the invention.

Claims (10)

1. The slope monitoring equipment control method is characterized by comprising the following steps of:

s10, waking up the system according to a wake-up mode, and collecting slope monitoring data;

s20, judging a slope early warning grade according to slope monitoring data;

s30, setting the wake-up time of the next period of the system according to the slope early warning level, and uploading slope monitoring data at regular time;

s40, turning off a system power supply, entering a standby mode, waking up the system after the system wake-up time, and collecting slope monitoring data of the next period.

2. The control method of the slope monitoring device according to claim 1, wherein the wake-up system according to the wake-up mode is specifically configured to collect the slope monitoring data:

waking up the system through a manual mode, and collecting surface displacement data and surface inclination data;

and waking up the system through an automatic mode, and collecting surface displacement data and surface inclination data.

3. The slope monitoring apparatus control method of claim 2, wherein the wake-up mode wake-up system is selected, and the collecting the slope monitoring data further comprises the steps of:

judging whether to turn on a Bluetooth module power supply according to the wake-up mode;

if the system is awakened by the manual mode, starting a Bluetooth module power supply and debugging equipment parameters;

if the system is awakened by the automatic mode, the Bluetooth module power supply is not started.

4. The slope monitoring apparatus control method according to claim 1, wherein the determining the slope early warning level based on the slope monitoring data is specifically:

presetting a plurality of early warning threshold intervals, wherein each early warning threshold interval corresponds to one slope early warning grade;

judging which early warning threshold interval the collected slope monitoring data are in;

and determining the slope early warning grade according to the early warning threshold interval corresponding to the slope monitoring data.

5. The method for controlling a slope monitoring device according to claim 1, wherein the step of setting a wake-up time of a next period according to a slope early-warning level and uploading the slope monitoring data at regular time is specifically as follows:

setting the interval time from the standby mode to automatic awakening of the system according to the early warning level;

and setting the time period for uploading the slope monitoring data by the system according to the early warning level.

6. The slope monitoring apparatus control method of claim 5, wherein uploading the slope monitoring data further comprises:

judging whether the wireless communication module is normal or not;

if the wireless communication module is normal, uploading the slope monitoring data to a server terminal and storing the slope monitoring data as historical data;

if the wireless communication module is abnormal, storing the slope monitoring data to a backup area, and repeating the step of judging whether the wireless communication module is normal or not after waiting for the next system wakeup.

7. The slope monitoring apparatus control method of claim 1, wherein the system power is turned off, the system enters a standby mode, and the system is awakened after a system awakening time elapses, and the next period of slope monitoring data is collected specifically as follows:

after the side slope monitoring data are collected and uploaded, a system power supply is turned off, and a standby mode is entered;

starting timing after entering a standby mode, and stopping timing after the timing time reaches the wake-up time;

and after stopping timing, automatically waking up the system and continuously collecting slope monitoring data.

8. A slope monitoring device, characterized in that the slope monitoring device comprises:

the inclination sensor is used for acquiring and outputting surface inclination data;

the stay cord sensor is used for collecting and outputting surface displacement data;

the input end of the communication processing module is connected with the output end of the inclination sensor and the output end of the pull rope sensor, a slope monitoring device control program is stored in the communication processing module, and the slope monitoring device control program realizes the slope monitoring device control method according to any one of claims 1-7 when being executed by the communication processing module.

9. The slope monitoring device of claim 8, wherein the communication processing module comprises:

a memory storing the slope monitoring device control program;

the input end of the processor is connected with the output end of the inclination sensor and the output end of the stay rope sensor, the processor is also connected with the memory, and the slope monitoring equipment control program realizes the slope monitoring equipment control method according to any one of claims 1-7 when being executed by the processor.

10. A storage medium having stored thereon a computer program which when executed by a processor performs the steps of the slope monitoring apparatus control method of any one of claims 1 to 7.

Images