CN113761851B - Hydraulic unit engineering quality acceptance data acquisition system based on Internet of things - Google Patents

Abstract

The invention provides a hydraulic unit engineering quality acceptance data acquisition system based on the Internet of things, which comprises the following steps: and the induction module is used for: the sensing device is used for transmitting fixed frequency band signals to the periphery based on a pre-buried sensing device in a building, and collecting quality acceptance data of the building; visual data acceptance table module: the method comprises the steps of automatically inputting the building material quality acceptance data into a preset table to generate a visual data acceptance table; and a data sharing module: and the visual data acceptance table is used for sharing data through the authorized terminal equipment. The invention has the beneficial effects that: locking the data acquisition position, not only realizing the guarantee to the engineering quality acceptance data information acquisition authenticity and reducing the potential safety hazard of data storage, but also carrying out signal transmission according to corresponding exclusive equipment, and guaranteeing the safety of quality acceptance data information acquisition and the convenience of checking.

Description

Hydraulic unit engineering quality acceptance data acquisition system based on Internet of things

Technical Field

The invention relates to the technical fields of Internet of things and data information acquisition, in particular to a hydraulic unit engineering quality acceptance data acquisition system based on the Internet of things.

Background

At present, the hydraulic engineering industry needs to check or accept at the end of a construction process or a certain stage, a large amount of forms and engineering data need to be filled, all industries in China provide fixed form patterns and fill data for checking engineering construction quality, each project has tens of thousands of forms or even tens of thousands of forms to fill, in principle, the data need to be checked and filled at a construction site, but are basically filled by a computer at present.

The method is characterized in that the method is basically filled in by using an EXCEL table before 2005, single-machine engineering data software appears on the market after 2005, a client is installed after the client is logged in by a download program and controlled by an encryption lock, a plurality of national template tables are not dependent on a network, and functions are added, so that the table is filled in more conveniently and quickly, but the table can be filled in on a computer only, the form is used in construction projects of all industries in China, but the use of building construction is the most extensive, and the construction utilization rate of the water conservancy industry is the lowest.

Network version data software appears in the market in 2013, namely, on the basis of the mode of single version data software, the network version data software is controlled without an encryption lock, and is logged in by an account and a password, so that on-line management is realized through account association, but an installation program still needs to be downloaded, a client side still exists, a background database does not exist, and the network version data software can only be used on a computer.

Disclosure of Invention

The invention provides a hydraulic unit engineering quality acceptance data acquisition system based on the Internet of things, which aims to solve the problems.

The invention provides a water conservancy unit engineering quality acceptance data acquisition system based on the Internet of things, which is characterized by comprising the following steps:

and the induction module is used for: the sensing device is used for transmitting fixed frequency band signals to the periphery based on a pre-buried sensing device in a building, and collecting quality acceptance data of the building;

visual data acceptance table module: the method comprises the steps of automatically inputting the building material quality acceptance data into a preset table to generate a visual data acceptance table;

and a data sharing module: and the visual data acceptance table is used for sharing data through the authorized terminal equipment.

As an embodiment of the present technical solution, the sensing module includes:

the acquisition unit: the sensing device is used for transmitting signals of fixed frequency bands to the periphery and collecting quality acceptance data of the building; wherein,

the quality acceptance data at least comprises time data, flatness of an excavation surface of a building, bottom elevation, radial dimension, lateral dimension and section dimension;

a table unit: the system is used for generating a corresponding filling form according to the real-time quality acceptance data;

Building mass acceptance data unit: and the quality acceptance data is used for automatically inputting the quality acceptance data into a filling form, and recording the quality acceptance data of the building in real time.

As an embodiment of the present technical solution, the sensing module further includes:

transmitting data units: fitting the building material quality acceptance data to generate corresponding transmission data;

and a verification signal unit: the device is used for generating a corresponding verification signal based on a preset induction chip in the induction device;

and a transmitting verification signal unit: the device is used for removing impurities and filtering the verification signal, determining a filtering signal, transmitting the verification signal to a receiving port at the same time, and transmitting transmission data after the verification signal passes; wherein,

the receiving port at least comprises a mobile phone end and a computer end.

As an embodiment of the present technical solution, the transmitting verification signal unit includes:

searching a position subunit: the device is used for receiving verification signals through preset terminal equipment based on fixed frequency band signals transmitted by the induction device, performing impurity removal and filtering processing on the verification signals, determining filtering signals and locking the positions of induction chips in the corresponding induction devices;

Source data subunit: the method is used for tracing historical transmission data according to the position and generating source data;

a checking subunit: the method comprises the steps of acquiring historical distance data, and checking the authenticity of source data according to the historical distance data; wherein,

the distance data represent the distance value between the sensing device and the terminal equipment;

transmitting the transmission data subunit: and the terminal device is used for passing the verification signal when the source data is real, and sending transmission data to the terminal device.

As an embodiment of the present technical solution, the visual data acceptance table module includes:

a receiving unit: the method comprises the steps of receiving and processing fixed frequency band signals based on preset terminal equipment, generating received data, and generating a receiving instruction according to the received data; wherein,

the terminal equipment at least comprises a mobile phone end, a tablet end and a computer end;

a table unit: the function acceptance table style preset in the terminal equipment is obtained according to the receiving instruction;

checking the record source data unit: the method comprises the steps of acquiring source data, checking the source data according to building quality acceptance data, and determining check record source data; wherein,

the source data are building quality acceptance data obtained through a preset reverse compiling record pattern;

Statistics content unit: the method is used for carrying out statistical processing on the inspection record source data based on a preset water cloud algorithm to determine statistical content;

acceptance table unit: the method is used for automatically inputting the statistical content based on a preset function acceptance table style, calling the content of the source data on line and generating a corresponding visual data acceptance table.

As an embodiment of the present technical solution, the receiving unit receives and processes a fixed frequency band signal based on a preset terminal device, and includes the following steps:

step S1: based on preset terminal equipment, fixed frequency band signals sent by a chip are collected, and effective frequency band signals are determined:

wherein τ _ij (t) represents an effective frequency band signal from a chip source signal node i to an observation signal node j of the terminal equipment at the time t, wherein the i node represents the source signal node of the chip, and the j node represents the observation signal node of the terminal equipment; i=1, 2,3, …, m, m represents the total number of chip source signal nodes, j=1, 2,3, …, n, n represents the total number of machine side/computer side observation signal nodes, h (t) represents the state variable of the observation signal node channel from the chip source signal node to the terminal device at the time t, r _ij (j) Representing reception of an observation signal node j from a chip source signal node i to an observation signal node j of a terminal device Impact response, s _i (t-j) represents a mixed fixed band signal, G, from the chip source signal node i at time t _ij (t) represents a noise-affected frequency band signal from the chip source signal node i to the observed signal node j of the terminal device at time t;

step S2: monitoring the effective frequency band signal to obtain a monitoring result;

step S3: and carrying out quantization processing on the signals according to the monitoring result to determine processing signals.

As an embodiment of the present technical solution, the step S2 includes:

step SS201: monitoring the effective frequency band signal, judging whether the effective frequency band signal is suitable for a channel state, and generating a judging result:

wherein E represents the judgment result (0 represents the state that the effective frequency band signal is not suitable for the channel, 1 represents the state that the effective frequency band signal is suitable for the channel), r _ij (j) Representing impulse response received from a chip source signal node i to an observation signal node j of the terminal equipment, wherein the i node represents the source signal node of the chip, and the j node represents the observation signal node of the terminal equipment; i=1, 2,3, …, m, m represents the total number of chip source signal nodes, j=1, 2,3, …, n, n represents the total number of machine end/computer end observation signal nodes, τ _ij (t) represents the effective frequency band signal from the chip source signal node i to the observed signal node j of the terminal equipment at time t, G _ij (t) represents a noise-affected frequency band signal from the chip source signal node i to the observed signal node j of the terminal device at time t, L _ie (t) represents the response distance L from the source signal node i to the listening node e, which is listening at time t _ej Representing the response distance of listening node e listening at time t to source signal node j,representing the wavelength of the mixed signal, T representing the period of the wavelength；

Step SS202: when the judgment result e=1, the method can be realized under the condition that the effective frequency band signal in the monitoring process meets the channel state, and the effective frequency band signal is transmitted to a monitoring channel;

step SS203: the signal is quantized through the monitoring channel, and a processing signal is determined;

wherein SIG represents the processing signal, Y represents the expected value of the preset signal sequence, and τ _ij (t) represents the signal from the chip source signal node i to the observed signal node j of the terminal device at time t,represents the average signal, ε, from the chip source signal node i to the observed signal node j of the terminal device at time t _ij Representing the sequence quantization parameter from the chip source signal node i to the observation signal node j of the terminal equipment, wherein m represents the total number of the chip source signal nodes, and n represents the total number of the observation signal nodes of the machine end/the computer end;

Step SS204: when the monitoring result e=0, the monitoring process cannot be realized under the condition that the channel state is satisfied, and the failure monitoring result is fed back to the intelligent terminal.

As an embodiment of the present technical solution, the data sharing module includes:

a connection unit: for connecting different terminal devices;

login verification unit: the terminal device is used for logging in the terminal device through preset authority setting, acquiring an account password and sending a verification message to the corresponding terminal device;

and a verification result unit: the verification message is used for receiving and identifying the verification message, and a verification result is determined;

a data sharing unit: and the method is used for acquiring a visual data chart when the verification result is successfully verified, synchronously associating different terminal devices on line and carrying out on-line data sharing.

As an embodiment of the present technical solution, the system further includes a traceback module, where the traceback module includes:

engineering acceptance unit: after the visual data acceptance table is accepted by the engineering, reading the frequency band signal corresponding to the chip through the terminal equipment based on a preset password mechanism;

acceptance condition unit: the method is used for calling the acceptance condition of the engineering according to the frequency band signal; wherein,

The acceptance situation comprises an acceptance process, an acceptance history record and an acceptance history audit record of the visual data acceptance table;

a judging unit: the method is used for judging whether the acceptance situation is abnormal or not and obtaining a judging result;

and a storage unit: when the acceptance condition is abnormal, transmitting and storing the frequency band signal of the chip and the corresponding visual data acceptance table to a storage module, and feeding back the content of the source data to the terminal equipment;

as an embodiment of the present technical solution, the system further includes a display module; the display module includes:

obtaining building material quality acceptance data units: the method comprises the steps of acquiring and collecting building material quality acceptance data in real time;

and (3) obtaining a visual data chart unit: for acquiring a visual data chart;

acquiring a real-time graph unit: for acquiring a real-time graph;

a selection unit: the method is used for selecting the real-time graph or the visual data chart and displaying the real-time graph or the visual data chart on the control terminal.

The beneficial effects of this technical scheme lie in:

the visual form generated by the building mass data obtained by the technical scheme can be directly displayed on a webpage, the content is filled, the functions owned by single software are realized by the webpage, meanwhile, the form filling can be carried out at the mobile phone APP end, the mobile phone end and the computer end synchronously share the data content, and the engineering quality supervision department or the first party can supervise and check the engineering on line.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention may be realized and attained by the structure particularly pointed out in the written description and drawings.

The technical scheme of the invention is further described in detail through the drawings and the embodiments.

Drawings

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention.

In the drawings:

fig. 1 is a diagram of a module of a hydraulic unit engineering quality acceptance data acquisition system based on the internet of things in an embodiment of the invention;

fig. 2 is a diagram of a module of a hydraulic unit engineering quality acceptance data acquisition system based on the internet of things in an embodiment of the invention;

fig. 3 is a diagram of a module of a hydraulic unit engineering quality acceptance data acquisition system based on the internet of things in an embodiment of the invention;

Detailed Description

The preferred embodiments of the present invention will be described below with reference to the accompanying drawings, it being understood that the preferred embodiments described herein are for illustration and explanation of the present invention only, and are not intended to limit the present invention.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are 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 one or more such feature. In the description of the present invention, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

Example 1:

according to fig. 1, an embodiment of the present invention provides a hydraulic unit engineering quality acceptance data collection system based on the internet of things, including:

and the induction module is used for: the sensing device is used for transmitting fixed frequency band signals to the periphery based on a pre-buried sensing device in a building, and collecting quality acceptance data of the building;

visual data acceptance table module: the method comprises the steps of automatically inputting the building material quality acceptance data into a preset table to generate a visual data acceptance table;

and a data sharing module: and the visual data acceptance table is used for sharing data through the authorized terminal equipment.

The working principle of the technical scheme is as follows:

the embodiment of the invention provides a hydraulic unit engineering quality acceptance data acquisition system based on the Internet of things, which is used for acquiring quality acceptance data of a building based on a pre-buried sensing device in the building, automatically inputting the quality acceptance data of the building into a preset table to generate a visual data chart, and carrying out data sharing on the visual data chart through authorized terminal equipment. The engineering quality acceptance data information acquisition system acquires quality acceptance data of a building based on a chip embedded in the building and transmits signals to the receiving port; the receiving port at least comprises a mobile phone and a computer, the signals are read through an APP end or a program port in the mobile phone, a preset form is obtained, the form is filled according to the real-time environment data, the data content of the APP end is determined, the webpage end is used for obtaining the preset form on a webpage through the webpage end in the computer, the form is filled, the data content of the webpage end is determined, an APP end module and a webpage end module are synchronously associated on line, a chip embedded in a hydraulic building can emit signals with fixed frequency bands, the mobile phone APP can read the signals, the locking position and the corresponding chip, a construction quality self-checking personnel or a supervision and review personnel can carry out the entry of hydraulic engineering unit engineering construction quality check record source data, the check record source data is subjected to statistical processing in a water cloud algorithm mode, the check record source data is converted into a corresponding hydraulic industry check list mode, the content of the source data is accessed on line, and the chip records the distance condition when each check data is recorded, so that the basis is provided for judging the authenticity of the source data.

The beneficial effects of the technical scheme are that:

according to the embodiment of the invention, the mass acceptance data of the building are acquired through the pre-embedded chip in the building, the signal is transmitted to the receiving port, the corresponding engineering quality acceptance data information acquisition system is generated, diversified data acquisition can be realized, the condition that current webpage data are rarely collected is met, meanwhile, the signal is read through the APP end in the mobile phone, the preset form is acquired, the form is filled according to the mass acceptance data of the building, the APP end data content is determined, and as some data content can only be filled in the field, the multi-port implementation is realized, the requirement change of a user is adapted, the webpage end is used for acquiring the preset form on the webpage through the webpage end in a computer, the form filling is carried out, the webpage end data content is determined, the corresponding software is not needed to be downloaded in the single machine or the mobile phone, the operation procedure is reduced, the simplified complex operation steps are realized, meanwhile, the data sharing is realized through the on-line association of the APP end module and the webpage end module, the data reading of the user is realized, the data is realized, the automatic acquisition of the data is realized, and the quality data is ensured to be recorded quickly and efficiently.

Example 2:

the technical scheme provides an embodiment, the sensing module includes:

the acquisition unit: the sensing device is used for transmitting signals of fixed frequency bands to the periphery and collecting quality acceptance data of the building; wherein,

the quality acceptance data at least comprises time data, flatness of an excavation surface of a building, bottom elevation, radial dimension, lateral dimension and section dimension;

a table unit: the system is used for generating a corresponding filling form according to the real-time quality acceptance data;

building mass acceptance data unit: and the quality acceptance data is used for automatically inputting the quality acceptance data into a filling form, and recording the quality acceptance data of the building in real time.

The working principle of the technical scheme is as follows:

according to the technical scheme, the induction module collects quality acceptance data of a building through an induction chip preset in an induction device, acquires historical environment data, calculates a change value of the environment data and the historical environment data, records the quality acceptance data of the building according to the change value and the environment data, performs filtering processing on the real-time quality acceptance data through transmitting signals, generates corresponding signals, transmits the signals to a receiving port, reads the quality acceptance data in real time through the induction device of the chip, and obtains the change of the quality acceptance data of the building, wherein the quality acceptance data can be different according to the position of the chip, such as: time data, flatness of an excavation surface of a building, elevation of the bottom, radial dimension, lateral dimension and section dimension.

The beneficial effects of the technical scheme are that:

according to the technical scheme, the chip is embedded in the building, the building material quality acceptance data are collected in real time, the change value of the building material quality acceptance data is calculated in real time, and through signal collection, the data collection is accurate, the collection speed is high-efficient, and dynamic building data can be recorded in real time.

Example 3:

the present technical solution provides an embodiment, the sensing module further includes:

transmitting data units: fitting the building material quality acceptance data to generate corresponding transmission data;

and a verification signal unit: the device is used for generating a corresponding verification signal based on a preset induction chip in the induction device;

and a transmitting verification signal unit: the device is used for removing impurities and filtering the verification signal, determining a filtering signal, transmitting the verification signal to a receiving port at the same time, and transmitting transmission data after the verification signal passes; wherein,

the receiving port at least comprises a mobile phone end and a computer end.

The working principle of the technical scheme is as follows:

the induction module of the technical scheme carries out filtering processing on the building quality acceptance data, generates corresponding signals, can remove noise and noise in the signals, transmits the signals to the receiving port, and the receiving port at least comprises a mobile phone end and a computer end, can receive the signals in a mode of information transmission such as Bluetooth, wiFi and the like through a fixed frequency band, generates corresponding verification signals based on an induction chip preset in the induction device, carries out impurity removal and filtering processing on the verification signals, determines the filtering signals, transmits the verification signals to the receiving port at the same time, transmits transmission data after the verification signals pass, and is used for guaranteeing the authority of conveying and improving the efficiency of safe conveying.

The beneficial effects of the technical scheme are that:

according to the technical scheme, the building material quality acceptance data is subjected to filtering processing, the corresponding signal is generated, the signal receiving signal is transmitted to the receiving port, the corresponding data content is generated and transmitted to the APP end, the data can be generated on a webpage and transmitted to the mobile phone, the method is convenient and fast, an efficient and safe conveying mode is provided, and meanwhile, the data content can be displayed in various forms.

Example 4:

the technical scheme provides an embodiment, the transmission verification signal unit includes:

searching a position subunit: the device is used for receiving verification signals through preset terminal equipment based on fixed frequency band signals transmitted by the induction device, performing impurity removal and filtering processing on the verification signals, determining filtering signals and locking the positions of induction chips in the corresponding induction devices;

source data subunit: the method is used for tracing historical transmission data according to the position and generating source data;

a checking subunit: the method comprises the steps of acquiring historical distance data, and checking the authenticity of source data according to the historical distance data; wherein,

the distance data represent the distance value between the sensing device and the terminal equipment;

Transmitting the transmission data subunit: and the terminal device is used for passing the verification signal when the source data is real, and sending transmission data to the terminal device.

The working principle and beneficial effects of the technical scheme are as follows:

according to the technical scheme, the chip records the distance condition of each time of checking data recording, provides a basis for judging the authenticity of source data, receives a verification signal through a preset terminal device based on a fixed frequency band signal emitted by an induction device, performs impurity removal and filtering treatment on the verification signal, determines a filtering signal, locks the position of an induction chip in a corresponding induction device, acquires historical distance data, checks the authenticity of the source data, and can reversely compile a recording pattern on line, check the source data and check and sign the checking result by a supervisor or a project legal person. And a supervisor checks the source data of the important hidden or key parts in a spot check mode, and after the unit engineering acceptance is finished, the authority user can read the frequency band signal of the chip through the mobile phone APP, call the acceptance condition of the unit engineering, index the content of the source data and achieve safer and more secret point-to-point transmission.

Example 5:

the technical scheme provides an embodiment, visual data acceptance table module includes:

A receiving unit: the method comprises the steps of receiving and processing fixed frequency band signals based on preset terminal equipment, generating received data, and generating a receiving instruction according to the received data; wherein,

the terminal equipment at least comprises a mobile phone end, a tablet end and a computer end;

a table unit: the function acceptance table style preset in the terminal equipment is obtained according to the receiving instruction;

checking the record source data unit: the method comprises the steps of acquiring source data, checking the source data according to building quality acceptance data, and determining check record source data; wherein,

the source data are building quality acceptance data obtained through a preset reverse compiling record pattern;

statistics content unit: the method is used for carrying out statistical processing on the inspection record source data based on a preset water cloud algorithm to determine statistical content;

acceptance table unit: the method is used for automatically inputting the statistical content based on a preset function acceptance table style, calling the content of the source data on line and generating a corresponding visual data acceptance table.

The working principle of the technical scheme is as follows:

the visual data chart module of the technical scheme receives and processes the signals based on preset terminal equipment, generates received data and generates a receiving instruction according to the received data; the terminal equipment comprises Android, iOS and a PC terminal; acquiring a preset form in the terminal equipment according to the receiving instruction; the automatic input unit is used for automatically inputting the building quality data to the form and determining filling content; transmitting the filling content and the form to a functional unit, and generating a corresponding visual data chart; and a supervisor checks the source data of the important hidden or key parts in a spot check mode, finally displays the webpage function table through a webpage end data content unit, determines the webpage end data content and draws a visual data chart module.

The beneficial effects of the technical scheme are that:

according to the technical scheme, the webpage end data content in different forms is displayed through functional selection of the webpage end data content, the display form is enriched, the multifunctional and flexible data content is provided, and the visual data chart can be displayed.

Example 6:

the technical scheme provides an embodiment, the receiving unit receives and processes the fixed frequency band signal based on a preset terminal device, and the method comprises the following steps:

step S1: based on preset terminal equipment, fixed frequency band signals sent by a chip are collected, and effective frequency band signals are determined:

wherein τ _ij (t) represents an effective frequency band signal from a chip source signal node i to an observation signal node j of the terminal equipment at the time t, wherein the i node represents the source signal node of the chip, and the j node represents the observation signal node of the terminal equipment; i=1, 2,3, …, m, m represents the total number of chip source signal nodes, j=1, 2,3, …, n, n represents the total number of machine side/computer side observation signal nodes, h (t) represents the state variable of the observation signal node channel from the chip source signal node to the terminal device at the time t, r _ij (j) Representing the impulse response received by the observed signal node j from the chip source signal node i to the observed signal node j of the terminal device, s _i (t-j) represents a mixed fixed band signal, G, from the chip source signal node i at time t _ij (t) represents a noise-affected frequency band signal from the chip source signal node i to the observed signal node j of the terminal device at time t;

step S2: monitoring the effective frequency band signal to obtain a monitoring result;

step S3: and carrying out quantization processing on the signals according to the monitoring result to determine processing signals.

The working principle of the technical scheme is as follows:

the receiving unit of the technical scheme is used for receiving and processing the signals based on preset terminal equipment, and acquiring signals tau from a chip source signal node i to an observation signal node j of the terminal equipment at time t based on the terminal equipment _ij (t) listening to said signal to obtainTaking a monitoring result; and carrying out quantization processing on the signals according to the monitoring result to determine processing signals.

The beneficial effects of the technical scheme are that:

according to the technical scheme, the safety of monitoring data is ensured through processing the real-time environment data, the monitoring data is displayed on line to a monitor in a multi-element mode, the online association of the data is monitored in a flexible and strong-operability online monitoring mode, and the sharing of the data is realized, so that the integration and linkage of the data are realized, and unnecessary repeated operation is avoided. According to the technical scheme, the safety of the monitoring data is ensured through the processing of the real-time environment data, the monitoring data is displayed on line to the monitor in a multi-element mode, the monitor can monitor on line, and a flexible and strong-operability on-line monitoring mode is provided.

Example 7:

the technical solution provides an embodiment, and the step S2 includes:

step SS201: monitoring the effective frequency band signal, judging whether the effective frequency band signal is suitable for a channel state, and generating a judging result:

wherein E represents the judgment result (0 represents the state that the effective frequency band signal is not suitable for the channel, 1 represents the state that the effective frequency band signal is suitable for the channel), r _ij (j) Representing impulse response received from a chip source signal node i to an observation signal node j of the terminal equipment, wherein the i node represents the source signal node of the chip, and the j node represents the observation signal node of the terminal equipment; i=1, 2,3, …, m, m represents the total number of chip source signal nodes, j=1, 2,3, …, n, n represents the total number of machine end/computer end observation signal nodes, τ _ij (t) represents the effective frequency band signal from the chip source signal node i to the observed signal node j of the terminal equipment at time t, G _ij (t) represents a noise-affected frequency band signal from the chip source signal node i to the observed signal node j of the terminal device at time t, L _ie (t) generationThe response distance from the source signal node i to the monitoring node e monitored at the time t is shown as L _ej Representing the response distance of listening node e listening at time t to source signal node j, Representing the wavelength of the mixed signal, T representing the period of the wavelength;

step SS202: when the judgment result e=1, the method can be realized under the condition that the effective frequency band signal in the monitoring process meets the channel state, and the effective frequency band signal is transmitted to a monitoring channel;

step SS203: the signal is quantized through the monitoring channel, and a processing signal is determined;

wherein SIG represents the processing signal, Y represents the expected value of the preset signal sequence, and τ _ij (t) represents the signal from the chip source signal node i to the observed signal node j of the terminal device at time t,represents the average signal, ε, from the chip source signal node i to the observed signal node j of the terminal device at time t _ij Representing the sequence quantization parameter from the chip source signal node i to the observation signal node j of the terminal equipment, wherein m represents the total number of the chip source signal nodes, and n represents the total number of the observation signal nodes of the machine end/the computer end;

step SS204: when the monitoring result e=0, the monitoring process cannot be realized under the condition that the channel state is satisfied, and the failure monitoring result is fed back to the intelligent terminal.

The working principle of the technical scheme is as follows:

the signal processing unit of the technical scheme carries out quantization processing on the signals according to the monitoring result, determines the processing signals, acquires the monitoring result E, and judges whether the monitoring result meets the channel state 0 or not 1, when the monitoring result e=1, it represents that the monitoring process can be implemented under the condition of meeting the channel state, according to the monitoring result, the signal is obtained, and the signal acquisition unit acquires the signal τ sent by the chip through the terminal device _ij (t) the monitoring unit is used for monitoring the signal to obtain a monitoring result; the processing signal unit is used for carrying out quantization processing on the signals according to the monitoring result, determining processing signals, acquiring and monitoring the processing signals, improving the safety of data information, carrying out quantization processing on the signals, determining processing signals SIG, when the monitoring result E=0, representing that the monitoring process can not be realized under the condition of meeting the channel state, filtering the signals, generating a filtering result, and timely filtering out abnormal data when the real-time environment data does not exceed the preset threshold range of ideal environment data, wherein the real-time environment data is obtained by monitoring some values around a building in real time.

The beneficial effects of the technical scheme are that:

according to the technical scheme, the signals are subjected to quantization processing according to the monitoring result, the signals are determined to be processed, the monitoring result is obtained, whether the monitoring result meets the channel state E is judged, when the monitoring result E=1, the monitoring process can be realized under the condition that the channel state is met, the signals are obtained according to the monitoring result, the signals are subjected to quantization processing, the signals SIG are determined to be processed, when the monitoring result E=0, the monitoring process cannot be realized under the condition that the channel state is met, the signals are filtered, the filtering result is generated, and the signals which are not up to standard in noise are filtered, so that clear and flexible data acquisition is realized, environmental data are monitored in real time, and the safety of the monitored data is ensured.

Example 8:

according to fig. 2, the present technical solution provides an embodiment, where the data sharing module includes:

a connection unit: for connecting different terminal devices;

login verification unit: the terminal device is used for logging in the terminal device through preset authority setting, acquiring an account password and sending a verification message to the corresponding terminal device;

and a verification result unit: the verification message is used for receiving and identifying the verification message, and a verification result is determined;

a data sharing unit: and the method is used for acquiring a visual data chart when the verification result is successfully verified, synchronously associating different terminal devices on line and carrying out on-line data sharing.

The working principle of the technical scheme is as follows:

according to the technical scheme, based on a preset account password, an APP (application) end of a mobile phone is logged in, the account password is obtained according to a verification unit, a webpage end of a computer is logged in, and a verification message is sent to the APP end of the mobile phone; finally, based on the APP end, the verification result unit receives and identifies the verification message and determines a verification result; simultaneously, according to the online association unit, when the verification result is verified successfully, synchronizing an online association APP end module and a webpage end module, and determining shared data content; sharing unit: the method is used for synchronously sharing data content between the APP end of the mobile phone and the webpage of the computer. The system of the technical scheme also comprises a display module; the display module can display relevant information of a building to a supervision engineering department on line in real time, can display the relevant information through a real-time graph, can acquire real-time quality acceptance data, can acquire corresponding time of the real-time quality acceptance data, can draw a corresponding real-time graph according to the real-time quality acceptance data and the time, can display the corresponding real-time graph on a mobile phone of a supervision party, can be displayed through a data table, is convenient for a user to record, can generate the data table according to the real-time quality acceptance data, can be transmitted to a supervision port, can also select the real-time graph or the data table or the fan-shaped statistical graph through other various modes, such as the fan-shaped graph statistical graph, or the fan-shaped statistical graph through a selected function button, and can be displayed on a control terminal of the supervision party.

The beneficial effects of the technical scheme are that:

the technical scheme is provided with the special storage module for storing a large amount of quality acceptance data, and the quality acceptance data is monitored in an all-day and all-around mode, so that the information quantity is very huge, the special storage module is required to store the quality acceptance data, effective information can be mined from a large amount of quality acceptance data, and the safety of user login information is ensured through safety verification.

Example 9:

according to fig. 3, the present technical solution provides an embodiment, where the system further includes a traceback module, and the traceback module includes:

engineering acceptance unit: after the visual data acceptance table is accepted by the engineering, reading the frequency band signal corresponding to the chip through the terminal equipment based on a preset password mechanism;

acceptance condition unit: the method is used for calling the acceptance condition of the engineering according to the frequency band signal; wherein,

the acceptance situation comprises an acceptance process, an acceptance history record and an acceptance history audit record of the visual data acceptance table;

a judging unit: the method is used for judging whether the acceptance situation is abnormal or not and obtaining a judging result;

and a storage unit: and the frequency band signal and the corresponding visual data acceptance table of the chip are transmitted and stored to the storage module when the acceptance condition is abnormal, and the content of the source data is fed back to the terminal equipment.

The working principle and beneficial effects of the technical scheme are as follows:

the technical scheme system further comprises the steps of judging whether the real-time environment data exceeds a preset threshold range of ideal environment data, acquiring a judging result, monitoring some values around a building in real time by the real-time environment data, and transmitting the real-time environment data to a storage module by ensuring that the real-time environment data does not exceed an abnormal range when the real-time environment data does not exceed the preset threshold range of the ideal environment data; when the real-time environment data exceeds the preset threshold range of ideal environment data, generating abnormal data and sending the abnormal data to a mobile phone. According to the technical scheme, the chip is embedded in the building, environmental data are collected in real time, the change value of the environment is calculated in real time, meanwhile, the environmental data can be mined in a self-adaptive and self-learning mode, and the acceptance condition of engineering is called.

Example 10:

the technical scheme provides an embodiment, and the system further comprises a display module; the display module includes:

obtaining building material quality acceptance data units: the method comprises the steps of acquiring and collecting building material quality acceptance data in real time;

And (3) obtaining a visual data chart unit: for acquiring a visual data chart;

acquiring a real-time graph unit: for acquiring a real-time graph;

a selection unit: the method is used for selecting the real-time graph or the visual data chart and displaying the real-time graph or the visual data chart on the control terminal.

The working principle and beneficial effects of the technical scheme are as follows:

the technical scheme comprises a display module, wherein the display module comprises a building material quality acceptance data acquisition unit, a visual data graph acquisition unit, a real-time graph acquisition unit, a storage unit and a selection unit, and the building material quality acceptance data is acquired and acquired in real time; obtaining a visual data chart; acquiring a real-time graph; the storage unit is used for storing the building quality acceptance data, recording a corresponding visual data chart and a real-time graph, and determining storage data; and selecting a real-time graph or a visual data chart based on the building quality acceptance data, and displaying the real-time graph or the visual data chart on a control terminal.

It will be appreciated by those skilled in the art that embodiments of the present invention may be provided as a method, system, or computer program product. Accordingly, the present invention may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present invention may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, magnetic disk storage, optical storage, and the like) having computer-usable program code embodied therein.

The present invention is described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems) and computer program products according to embodiments of the invention. It will be understood that each flow and/or block of the flowchart illustrations and/or block diagrams, and combinations of flows and/or blocks in the flowchart illustrations and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present invention without departing from the spirit or scope of the invention. Thus, it is intended that the present invention also include such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims (4)

1. Water conservancy unit engineering quality acceptance data acquisition system based on thing networking, its characterized in that includes:

and the induction module is used for: the sensing device is used for transmitting fixed frequency band signals to the periphery based on a pre-buried sensing device in a building, and collecting quality acceptance data of the building;

visual data acceptance table module: the method comprises the steps of automatically inputting the building material quality acceptance data into a preset table to generate a visual data acceptance table;

And a data sharing module: the visual data acceptance table is used for sharing data through authorized terminal equipment; the sensing module comprises:

the acquisition unit: the sensing device is used for transmitting signals of fixed frequency bands to the periphery and collecting quality acceptance data of the building; wherein,

the quality acceptance data at least comprises time data, flatness of an excavation surface of a building, bottom elevation, radial dimension, lateral dimension and section dimension;

a table unit: the system is used for generating a corresponding filling form according to the real-time quality acceptance data;

building mass acceptance data unit: the quality acceptance data are automatically input into a filling form, and the quality acceptance data of the building are recorded in real time;

the sensing module further includes:

transmitting data units: fitting the building material quality acceptance data to generate corresponding transmission data;

and a verification signal unit: the device is used for generating a corresponding verification signal based on a preset induction chip in the induction device;

and a transmitting verification signal unit: the device is used for removing impurities and filtering the verification signal, determining a filtering signal, transmitting the verification signal to a receiving port at the same time, and transmitting transmission data after the verification signal passes; wherein,

The receiving port at least comprises a mobile phone end and a computer end; the transmission verification signal unit comprises:

searching a position subunit: the device is used for receiving verification signals through preset terminal equipment based on fixed frequency band signals transmitted by the induction device, performing impurity removal and filtering processing on the verification signals, determining filtering signals and locking the positions of induction chips in the corresponding induction devices;

source data subunit: the method is used for tracing historical transmission data according to the position and checking source data;

a checking subunit: the method comprises the steps of acquiring historical distance data, and checking the authenticity of source data according to the historical distance data; wherein,

the distance data represent the distance value between the sensing device and the terminal equipment;

transmitting the transmission data subunit: the terminal device is used for transmitting the transmission data to the terminal device through the verification signal when the source data is real-time;

the visual data acceptance table module comprises:

a receiving unit: the method comprises the steps of receiving and processing fixed frequency band signals based on preset terminal equipment, generating received data, and generating a receiving instruction according to the received data; wherein,

the terminal equipment at least comprises a mobile phone end, a tablet end and a computer end;

A table unit: the function acceptance table style preset in the terminal equipment is obtained according to the receiving instruction;

checking the record source data unit: the method comprises the steps of acquiring source data, checking the source data according to building quality acceptance data, and determining check record source data; wherein,

the source data are building quality acceptance data obtained through a preset reverse compiling record pattern;

statistics content unit: the method is used for carrying out statistical processing on the inspection record source data based on a preset water cloud algorithm to determine statistical content;

acceptance table unit: the method comprises the steps of automatically inputting the statistical content based on a preset function acceptance table style, calling the content of source data on line, and generating a corresponding visual data acceptance table;

the receiving unit receives and processes the fixed frequency band signal based on a preset terminal device, and comprises the following steps:

step S1: based on preset terminal equipment, fixed frequency band signals sent by a chip are collected, and effective frequency band signals are determined:

wherein τ _ij (t) represents an effective frequency band signal from a chip source signal node i to an observation signal node j of the terminal equipment at the time t, wherein the i node represents the source signal node of the chip, and the j node represents the observation signal node of the terminal equipment; i=1, 2,3, …, m, m represents the total number of chip source signal nodes, j=1, 2,3, …, n, n represents the total number of machine side/computer side observation signal nodes, h (t) represents the state variable of the observation signal node channel from the chip source signal node to the terminal device at the time t, r _ij (j) Representing the impulse response received by the observed signal node j from the chip source signal node i to the observed signal node j of the terminal device, s _i (t-j) represents a mixed fixed band signal, G, from the chip source signal node i at time t _ij (t) represents a noise-affected frequency band signal from the chip source signal node i to the observed signal node j of the terminal device at time t;

step S2: monitoring the effective frequency band signal to obtain a monitoring result;

step S3: according to the monitoring result, carrying out quantization processing on the signals to determine processing signals; the step S2 includes:

step SS201: monitoring the effective frequency band signal, judging whether the effective frequency band signal is suitable for a channel state, and generating a judging result:

wherein E represents the judgment result (0 represents the state that the effective frequency band signal is not suitable for the channel, 1 represents the state that the effective frequency band signal is suitable for the channel), r _ij (j) Representing the impulse response received by the observed signal node j from the chip source signal node i to the observed signal node j of the terminal deviceThe i node represents a source signal node of the chip, and the j node represents an observation signal node of the terminal equipment; i=1, 2,3, …, m, m represents the total number of chip source signal nodes, j=1, 2,3, …, n, n represents the total number of machine end/computer end observation signal nodes, τ _ij (t) represents the effective frequency band signal from the chip source signal node i to the observed signal node j of the terminal equipment at time t, G _ij (t) represents a noise-affected frequency band signal from the chip source signal node i to the observed signal node j of the terminal device at time t, L _ie (t) represents the response distance L from the source signal node i to the listening node e, which is listening at time t _ej Representing the response distance of listening node e listening at time t to source signal node j,representing the wavelength of the mixed signal, T representing the period of the wavelength;

step SS202: when the judgment result e=1, the method can be realized under the condition that the effective frequency band signal in the monitoring process meets the channel state, and the effective frequency band signal is transmitted to a monitoring channel;

step SS203: the signal is quantized through the monitoring channel, and a processing signal is determined;

wherein SIG represents the processing signal, Y represents the expected value of the preset signal sequence, and τ _ij (t) represents the signal from the chip source signal node i to the observed signal node j of the terminal device at time t,represents the average signal, ε, from the chip source signal node i to the observed signal node j of the terminal device at time t _ij Represents the sequence quantization parameter from the chip source signal node i to the observation signal node j of the terminal equipment, m represents the total number of the chip source signal nodes, and n represents the observation signal node of the machine end/computer end The total number of points;

step SS204: when the monitoring result e=0, the monitoring process cannot be realized under the condition that the channel state is satisfied, and the failure monitoring result is fed back to the intelligent terminal.

2. The system for acquiring quality acceptance data of hydraulic unit engineering based on the internet of things as set forth in claim 1, wherein the data sharing module comprises:

a connection unit: for connecting different terminal devices;

login verification unit: the terminal device is used for logging in the terminal device through preset authority setting, acquiring an account password and sending a verification message to the corresponding terminal device;

and a verification result unit: the verification message is used for receiving and identifying the verification message, and a verification result is determined;

a data sharing unit: and the method is used for acquiring a visual data chart when the verification result is successfully verified, synchronously associating different terminal devices on line and carrying out on-line data sharing.

3. The system for acquiring quality acceptance data of hydraulic unit engineering based on the internet of things as set forth in claim 1, wherein the system further comprises a tracing module, the tracing module comprises:

engineering acceptance unit: after the visual data acceptance table is accepted by the engineering, reading the frequency band signal corresponding to the chip through the terminal equipment based on a preset password mechanism;

Acceptance condition unit: the method is used for calling the acceptance condition of the engineering according to the frequency band signal; wherein,

the acceptance situation comprises an acceptance process, an acceptance history record and an acceptance history audit record of the visual data acceptance table;

a judging unit: the method is used for judging whether the acceptance situation is abnormal or not and obtaining a judging result;

and a storage unit: and the frequency band signal and the corresponding visual data acceptance table of the chip are transmitted and stored to the storage module when the acceptance condition is abnormal, and the content of the source data is fed back to the terminal equipment.

4. The system for acquiring the quality acceptance data of the hydraulic unit engineering based on the internet of things according to claim 1, wherein the system further comprises a display module; the display module includes:

obtaining building material quality acceptance data units: the method comprises the steps of acquiring and collecting building material quality acceptance data in real time;

and (3) obtaining a visual data chart unit: for acquiring a visual data chart;

acquiring a real-time graph unit: for acquiring a real-time graph;

a selection unit: the method is used for selecting the real-time graph or the visual data chart and displaying the real-time graph or the visual data chart on the control terminal.