CN113761851A - Water conservancy unit engineering quality acceptance data acquisition system based on Internet of things - Google Patents

Abstract

The invention provides a water conservancy unit engineering quality acceptance data acquisition system based on the Internet of things, which comprises: the induction module: the system is used for transmitting fixed frequency band signals to the periphery based on an induction device embedded in a building and acquiring quality acceptance data of the building; visual data acceptance sheet module: the system is used for automatically inputting the building quality acceptance data into a preset form to generate a visual data acceptance table; a data sharing module: and the visual data acceptance table is used for carrying out data sharing through authorized terminal equipment. The invention has the beneficial effects that: the data acquisition position is locked, the guarantee of the authenticity of engineering quality acceptance data information acquisition is realized, the potential safety hazard of data storage is reduced, signal transmission is carried out according to corresponding exclusive equipment, and the safety of quality acceptance data information acquisition and the convenience of checking are guaranteed.

Description

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

Technical Field

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

Background

At present, in the hydraulic engineering industry, in the construction process or at the end of a certain stage, inspection or acceptance is needed, a large number of forms and engineering data need to be filled, various industries in China provide fixed form styles and fill data for checking and accepting engineering construction quality, each project has tens of thousands of forms or even tens of thousands of forms to be filled, and in principle, the data need to be filled in while inspection is carried out on a construction site, but at present, the data are basically filled in by a computer.

The method is characterized in that EXCEL tables are basically filled in before 2005, standalone engineering data software appears on the market after 2005, a tourist client is installed through a downloading program, login is controlled through an encryption lock, the method does not depend on a network, namely a plurality of national template tables are put in the software, and functions are added, so that table filling is more convenient and faster, but can be filled in a computer only, the form is used in construction projects of all industries in the country, but the use of building is the most extensive, and the construction utilization rate of the water conservancy industry is the lowest.

The network version data software appears in the market in 2013, namely on the basis of a mode of single-machine version data software, the network is not required to be controlled by an encryption lock, and the network is used for logging in by using an account and a password, so that online management is realized through account number association, but an installation program still needs to be downloaded, a client 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 water conservancy unit engineering quality acceptance data acquisition system based on the Internet of things, and 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 components:

the induction module: the system is used for transmitting fixed frequency band signals to the periphery based on an induction device embedded in a building and acquiring quality acceptance data of the building;

visual data acceptance sheet module: the system is used for automatically inputting the building quality acceptance data into a preset form to generate a visual data acceptance table;

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

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

a collecting unit: the system is used for transmitting fixed frequency band signals to the periphery through the induction device and acquiring quality acceptance data of the building; wherein,

the quality acceptance data at least comprises time data, the planeness 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;

the data unit is accepted to the building quality: the quality acceptance data is automatically input into a filling form, and the quality acceptance data of the building is recorded in real time.

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

transmitting a data unit: the system is used for fitting the building quality acceptance data to generate corresponding transmission data;

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

a transmission 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, and sending 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 transmission verification signal unit includes:

a find location subunit: the device comprises a sensing device, a control unit and a control unit, wherein the sensing device is used for receiving a verification signal through preset terminal equipment based on a fixed frequency band signal transmitted by the sensing device, removing impurities and filtering the verification signal, determining a filtering signal and locking the position of a sensing chip in the corresponding sensing device;

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

a checking subunit: the device is used for acquiring historical distance data and checking the authenticity of the source data according to the historical distance data; wherein,

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

transmitting a transmission data subunit: and the data processing module is used for passing the verification signal and sending the transmission data to the terminal equipment when the source data is true.

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

a receiving unit: the device comprises a fixed frequency band signal receiving and processing module, a frequency band signal generating module and a frequency band signal processing module, wherein the fixed frequency band signal receiving and processing module is used for receiving and processing a fixed frequency band signal based on preset terminal equipment, generating receiving data and generating a receiving instruction according to the receiving data; wherein,

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

a table unit: the terminal equipment is used for acquiring a preset function acceptance sheet style in the terminal equipment according to the receiving instruction;

checking the recording source data unit: the system comprises a data acquisition module, a data processing module and a data processing module, wherein the data acquisition module is used for acquiring source data, detecting the source data according to the quality acceptance data of the building and determining detection record source data; wherein,

the source data is building quality acceptance data obtained through a preset reverse compiling record style;

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

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

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, including the following steps:

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

wherein, tau_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 moment t, the node i represents a source signal node of the chip, and the node j represents an observation signal node of the terminal equipment; i is 1,2,3, …, m represents the total number of signal nodes of chip source, j is 1,2,3, …, n, n represents the total number of signal nodes observed at the computer end, h (t) represents the state variable of the signal channel of signal node observed from the signal node of chip source to the terminal equipment at the time t, r_ij(j) Representing the impulse response, s, received by an observation signal node j from a chip source signal node i to an observation signal node j of a terminal device_i(t-j) represents a mixed fixed frequency band signal, G, emanating 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 an observation 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 according to the monitoring result, carrying out quantization processing on the signal to determine a processed signal.

As an embodiment of the present invention, the step S2 includes:

step SS 201: monitoring the effective frequency band signal, judging whether the effective frequency band signal is adaptive to a channel state, and generating a judgment result:

wherein E represents the judgment result (0 represents that the effective frequency band signal is not suitable for the channel state, 1 represents that the effective frequency band signal is suitable for the channel state), r_ij(j) Representing an impulse response received from a chip source signal node i to an observation signal node j of the terminal equipment, wherein the node i represents a source signal node of the chip, and the node j represents an observation signal node of the terminal equipment; i is 1,2,3, …, m represents total number of signal nodes of chip source, j is 1,2,3, …, n, n represents terminal/powerTotal number of observation signal nodes, tau, at the brain end_ij(t) represents the effective frequency band signal from the chip source signal node i to the observation signal node j of the terminal equipment at time t, G_ij(t) represents the noise-affected frequency band signal from the chip source signal node i to the observation signal node j of the terminal device at time t, L_ie(t) represents the response distance from the source signal node i to the listening node e, L, listened to at time t_ejRepresenting the response distance of listening node e to source signal node j listening at time t,

represents the mixed signal wavelength, and T represents the period of the wavelength;

step SS 202: when the judgment result E is 1, the effective frequency band signal is transmitted to a monitoring channel, which represents that the effective frequency band signal can be realized under the condition that the effective frequency band signal satisfies the channel state in the monitoring process;

step SS 203: quantizing the signal through the monitoring channel to determine a processed signal;

wherein SIG represents the processed 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 observation signal node j of the terminal device at time t,

representing the average signal, ε, from the chip source signal node i to the observation signal node j of the terminal device at time t_ijRepresenting sequence quantization parameters from a chip source signal node i to an observation signal node j of a terminal device, wherein m represents the total number of the chip source signal nodes, and n represents the total number of the observation signal nodes of a machine end/a computer end;

step SS 204: and when the monitoring result E is 0, the monitoring process cannot be realized under the condition of meeting the channel state, and the failed 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: the system is used for connecting different terminal devices;

a login verification unit: the system comprises a terminal device and a verification server, wherein 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;

a verification result unit: the system is used for receiving and identifying the verification message and determining a verification result;

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

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

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

and an acceptance condition unit: the system is used for calling the acceptance condition of the project according to the frequency band signal; wherein,

the acceptance condition comprises an acceptance process, an acceptance historical record and an acceptance historical audit record of the visual data acceptance table;

a judging unit: the system is used for judging whether the acceptance condition is abnormal or not and acquiring a judgment result;

a storage unit: the chip is used for transmitting and storing the frequency band signal of the chip and the corresponding visual data acceptance table to a storage module when the acceptance condition is not abnormal, 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 comprises:

obtaining a building quality acceptance data unit: the system is used for acquiring and collecting the quality acceptance data of the building in real time;

acquiring a visual data chart unit: for obtaining a visual data chart;

a real-time curve graph obtaining unit: for obtaining a real-time curve graph;

a selection unit: the real-time graph or the visual data chart is selected and displayed on the control terminal.

The beneficial effects of this technical scheme lie in:

the visual form that building mass data that this technical scheme obtained generated can directly show on the webpage, and fill in the content, and the function that single edition software possessed, the webpage version all can be realized, can carry out the form and fill in at cell-phone APP end simultaneously, and cell-phone end and computer end synchronous sharing data content, also can supervise the inspection engineering on line through engineering quality supervision department or first side, on the other hand, this technical scheme is through pre-buried chip in the building, the chip transmission signal, cell-phone APP reads and fills in after the signal, can control the demand that the form was filled in at the scene, can be after cell-phone APP reads the signal, among the engineering intelligent data storage chip of filling in, relevant data content can be looked up to later stage reading chip.

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 will be realized and attained by the structure particularly pointed out in the written description and drawings.

The technical solution of the present invention is further described in detail by the accompanying drawings and embodiments.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

In the drawings:

FIG. 1 is a block diagram of a hydraulic unit engineering quality acceptance data acquisition system based on the Internet of things according to an embodiment of the present invention;

FIG. 2 is a block diagram of a hydraulic unit engineering quality acceptance data acquisition system based on the Internet of things according to an embodiment of the present invention;

FIG. 3 is a block diagram of a hydraulic unit engineering quality acceptance data acquisition system based on the Internet of things according to an embodiment of the present invention;

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

Example 1:

as shown in fig. 1, an embodiment of the present invention provides a hydraulic unit engineering quality acceptance data acquisition system based on the internet of things, including:

the induction module: the system is used for transmitting fixed frequency band signals to the periphery based on an induction device embedded in a building and acquiring quality acceptance data of the building;

visual data acceptance sheet module: the system is used for automatically inputting the building quality acceptance data into a preset form to generate a visual data acceptance table;

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

The working principle of the technical scheme is as follows:

the embodiment of the invention provides a water conservancy unit engineering quality acceptance data acquisition system based on the Internet of things. The engineering quality acceptance data information acquisition system acquires the quality acceptance data of the building based on a chip pre-embedded in the building and transmits a signal to a receiving port; the receiving port at least comprises a mobile phone and a computer, the signal is read through an APP end or a program port in the mobile phone to obtain a preset form, the form is filled according to the real-time environment data to determine the data content of the APP end, a webpage end is used for obtaining the preset form on a webpage through a webpage end in the computer and filling the form to determine the data content of the webpage end, the APP end module and the webpage end module are synchronously associated on line, a chip pre-embedded in the hydraulic engineering building can transmit a fixed frequency band signal, the mobile phone APP can read the signal, a locking position and a corresponding chip are locked, a construction quality self-checking person or a supervision rechecking person can record data of the construction quality inspection record source of the hydraulic engineering unit engineering, the inspection record source data are subjected to statistical processing in a water cloud algorithm mode and are converted into a corresponding industry water conservancy acceptance form, and the content of the source data is called online, and the chip records the distance condition when the data is checked to be recorded each time, so that a basis is provided for judging the authenticity of the source data.

The beneficial effects of the above technical scheme are that:

the embodiment of the invention collects the quality acceptance data of the building through the chip pre-buried in the building, transmits signals to the receiving port and generates the corresponding engineering quality acceptance data information collecting system, can realize diversified data collection, meets the condition that few webpage data are collected, simultaneously reads the signals through the APP end in the mobile phone to obtain the preset form, fills the form according to the quality acceptance data of the building and determines the data content of the APP end, because some data contents can only be filled in on site, the invention adapts to the requirement change of a user through the realization of multiple application and multiple ports, the webpage end is used for obtaining the preset form on the webpage through the webpage end in a computer and filling the form to determine the data content of the webpage end, does not need to download corresponding software on a single machine or the mobile phone, and reduces the operation flow, simplified complicated operation steps to can be simultaneously through the online correlation APP end module of correlation module and webpage end module, realize data sharing, the reading of multi-functional realization user's data not only realizes the automatic acquisition of data, simultaneously, to the swift high efficiency of typing in assurance quality data of data.

Example 2:

this technical scheme provides an embodiment, the response module includes:

a collecting unit: the system is used for transmitting fixed frequency band signals to the periphery through the induction device and acquiring quality acceptance data of the building; wherein,

the quality acceptance data at least comprises time data, the planeness 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;

the data unit is accepted to the building quality: the quality acceptance data is automatically input into a filling form, and the quality acceptance data of the building is recorded in real time.

The working principle of the technical scheme is as follows:

this technical scheme's response module passes through the predetermined response chip in the induction system, gathers the quality acceptance data of building, acquires historical environmental data, calculates environmental data and historical environmental data's variation value, according to variation value and environmental data, records the quality acceptance data of building to through transmitting signal, carry out filtering process to real-time quality acceptance data, and generate corresponding signal, to receiving port transmission the signal, the induction system through the chip reads the quality acceptance data in real time, obtains the change of building quality acceptance data, quality acceptance data can be different according to the chip position, for example: time data, the planeness of the excavation face of the building, the bottom elevation, the radial dimension, the lateral dimension and the section dimension.

The beneficial effects of the above technical scheme are that:

this technical scheme is through pre-buried chip in the building, gathers building quality acceptance data in real time to the change value of real-time calculation building quality acceptance data, through signal acquisition, not only data acquisition is accurate, and the collection speed is high-efficient, can real-time recording dynamic building data.

Example 3:

this technical scheme provides an embodiment, the response module still includes:

transmitting a data unit: the system is used for fitting the building quality acceptance data to generate corresponding transmission data;

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

a transmission 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, and sending 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:

this technical scheme's response module is right building quality inspection data carries out filtering process, and generate corresponding signal, can remove noise and noise in the signal, to receiving port transmission the signal, receiving port includes cell-phone end and computer end at least, can be through fixed frequency channel, and the received signal is gone to the mode of information conductance such as bluetooth, wiFi, based on the response chip of predetermineeing in the induction system, generates corresponding verification signal, carries out edulcoration, filtering process to verification signal, confirms filtering signal, simultaneously to receiving port transmission verification signal to after verification signal passes through, send transmission data, verification signal is used for guaranteeing the authority nature of carrying, improves the efficiency of safe transport.

The beneficial effects of the above technical scheme are that:

this technical scheme is through carrying out filtering to building quality acceptance data and handling, and generate corresponding signal, to receiving port transmission signal reception signal generates corresponding data content and sends the APP end, can be at the webpage and generate data to on sending the cell-phone, not only convenient convenience provides a high-efficient, safe transport mode, can be with the abundant data content that shows of multiform simultaneously.

Example 4:

this technical solution provides an embodiment, where the transmission verification signal unit includes:

a find location subunit: the device comprises a sensing device, a control unit and a control unit, wherein the sensing device is used for receiving a verification signal through preset terminal equipment based on a fixed frequency band signal transmitted by the sensing device, removing impurities and filtering the verification signal, determining a filtering signal and locking the position of a sensing chip in the corresponding sensing device;

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

a checking subunit: the device is used for acquiring historical distance data and checking the authenticity of the source data according to the historical distance data; wherein,

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

transmitting a transmission data subunit: and the data processing module is used for passing the verification signal and sending the transmission data to the terminal equipment when the source data is true.

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

the chip of this technical scheme records the distance condition when checking data entry at every turn, for judging the source data authenticity provides the foundation, and based on the fixed frequency channel signal of induction system transmission, through predetermined terminal equipment, receive the verification signal, it is right the verification signal carries out edulcoration, filtering processing, confirms the filtering signal to the position of the induction chip in the induction system that the locking corresponds obtains historical distance data, checks the authenticity of source data, and proctor or project legal person can reverse the compiling record pattern on line, looks over the source data, and audits the signature to checking the receipt result. The supervisor checks the source data of important hidden or key parts in a spot check mode, after the unit project acceptance is completed, the authority user can read the frequency band signal of the chip through the mobile phone APP, the acceptance condition of the unit project is called, the content of the source data is indexed, and safer and more confidential point-to-point transmission is achieved.

Example 5:

this technical scheme provides an embodiment, visual data acceptance sheet module includes:

a receiving unit: the device comprises a fixed frequency band signal receiving and processing module, a frequency band signal generating module and a frequency band signal processing module, wherein the fixed frequency band signal receiving and processing module is used for receiving and processing a fixed frequency band signal based on preset terminal equipment, generating receiving data and generating a receiving instruction according to the receiving data; wherein,

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

a table unit: the terminal equipment is used for acquiring a preset function acceptance sheet style in the terminal equipment according to the receiving instruction;

checking the recording source data unit: the system comprises a data acquisition module, a data processing module and a data processing module, wherein the data acquisition module is used for acquiring source data, detecting the source data according to the quality acceptance data of the building and determining detection record source data; wherein,

the source data is building quality acceptance data obtained through a preset reverse compiling record style;

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

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

The working principle of the technical scheme is as follows:

the visual data chart module of the technical scheme receives and processes the signal based on preset terminal equipment to generate received data, and generates a receiving instruction according to the received data; the terminal equipment comprises Android, an iOS and a PC end; acquiring a preset table in the terminal equipment according to the received instruction; the automatic entry unit is used for automatically entering the building quality data into the form and determining filling contents; the technical scheme is that the filling content and the forms are transmitted to a functional unit, and corresponding visual data charts are generated; 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 data content unit, determines the webpage data content and draws a visual data chart module.

The beneficial effects of the above technical scheme are that:

according to the technical scheme, the webpage data contents in different forms are displayed by selecting the functions of the webpage data contents, the display forms are enriched, multifunctional and flexible data contents are provided, and the visualized data chart can be displayed.

Example 6:

the technical scheme provides an embodiment, wherein 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 the chip are collected, and effective frequency band signals are determined:

wherein, tau_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 moment t, the node i represents a source signal node of the chip, and the node j represents an observation signal node of the terminal equipment; i is 1,2,3, …, m represents the total number of signal nodes of chip source, j is 1,2,3, …, n, n represents the total number of signal nodes observed at the computer end, h (t) represents the state variable of the signal channel of signal node observed from the signal node of chip source to the terminal equipment at the time t, r_ij(j) Representing the impulse response, s, received by an observation signal node j from a chip source signal node i to an observation signal node j of a terminal device_i(t-j) represents a mixed fixed frequency band signal, G, emanating from the chip source signal node i at time t_ij(t) represents the time from the chip source signal node i to the terminal equipmentObserving noise influence frequency band signals of the signal node j;

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

step S3: and according to the monitoring result, carrying out quantization processing on the signal to determine a processed signal.

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 the signals tau from a chip source signal node i to an observation signal node j of the terminal equipment at the moment t based on the terminal equipment_ij(t) monitoring the signal to obtain a monitoring result; and according to the monitoring result, carrying out quantization processing on the signal to determine a processed signal.

The beneficial effects of the above technical scheme are that:

according to the technical scheme, the safety of the monitored data is ensured by processing the real-time environment data, the monitored data is displayed to a supervising party on line in a diversified manner, the online association of the data is monitored in an online supervising manner with flexibility and strong operability, the sharing of the data is realized, 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 by processing the real-time environment data, the monitoring data is displayed to the monitoring party on line in a diversified manner, the monitoring party can monitor on line, and an on-line monitoring manner with flexibility and strong operability is provided.

Example 7:

the present technical solution provides an embodiment, where in the step S2, the method includes:

step SS 201: monitoring the effective frequency band signal, judging whether the effective frequency band signal is adaptive to a channel state, and generating a judgment result:

wherein E represents the judgment result (0 represents that the effective frequency band signal is not suitable for the channel state, and 1 represents the effective frequency band signalAdapting to channel conditions), r_ij(j) Representing an impulse response received from a chip source signal node i to an observation signal node j of the terminal equipment, wherein the node i represents a source signal node of the chip, and the node j represents an observation signal node of the terminal equipment; i is 1,2,3, …, m represents the total number of signal nodes of chip source, j is 1,2,3, …, n, n represents the total number of observation signal nodes of terminal/computer terminal, tau_ij(t) represents the effective frequency band signal from the chip source signal node i to the observation signal node j of the terminal equipment at time t, G_ij(t) represents the noise-affected frequency band signal from the chip source signal node i to the observation signal node j of the terminal device at time t, L_ie(t) represents the response distance from the source signal node i to the listening node e, L, listened to at time t_ejRepresenting the response distance of listening node e to source signal node j listening at time t,

represents the mixed signal wavelength, and T represents the period of the wavelength;

step SS 202: when the judgment result E is 1, the effective frequency band signal is transmitted to a monitoring channel, which represents that the effective frequency band signal can be realized under the condition that the effective frequency band signal satisfies the channel state in the monitoring process;

step SS 203: quantizing the signal through the monitoring channel to determine a processed signal;

wherein SIG represents the processed 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 observation signal node j of the terminal device at time t,

representing the average signal, ε, from the chip source signal node i to the observation signal node j of the terminal device at time t_ijRepresenting observation signals from chip source signal node i to terminal equipmentSequence quantization parameters of a number node j, m represents the total number of chip source signal nodes, and n represents the total number of observation signal nodes at a machine end/a computer end;

step SS 204: and when the monitoring result E is 0, the monitoring process cannot be realized under the condition of meeting the channel state, and the failed monitoring result is fed back to the intelligent terminal.

The working principle of the technical scheme is as follows:

the signal processing unit in the technical scheme performs quantization processing on the signal according to the monitoring result to determine the signal processing, acquires the monitoring result E and judges whether the monitoring result meets the channel state 0 or 1, when the monitoring result E is 1, the signal processing unit can realize the monitoring process under the condition of meeting the channel state, acquires the signal according to the monitoring result, and the signal acquisition unit acquires the signal tau transmitted by the chip through the terminal equipment_ij(t), the monitoring unit is used for monitoring the signal to obtain a monitoring result; the signal processing unit is used for carrying out quantization processing on the signals according to the monitoring result, determining the processed signals, acquiring and monitoring the processed signals, improving the safety of data information, carrying out quantization processing on the signals, determining the processed signals SIG, filtering the signals and generating a filtering result when the monitoring result E is 0, representing that the monitoring process cannot be realized under the condition of meeting the channel state, and ensuring that the real-time environment data does not exceed the abnormal range when the real-time environment data does not exceed the threshold range of the preset ideal environment data.

The beneficial effects of the above technical scheme are that:

the technical scheme is that the signals are quantized according to the monitoring result to determine the processing of the signals, and comprises the steps of obtaining the monitoring result, judging whether the monitoring result meets a channel state E, when the monitoring result E is equal to 1, representing that the monitoring process can be realized under the condition of meeting the channel state, obtaining the signals according to the monitoring result, quantizing the signals to determine a processing signal SIG, when the monitoring result E is equal to 0, representing that the monitoring process cannot be realized under the condition of meeting the channel state, filtering the signals, generating a filtering result, and filtering the signals with noise not reaching the standard, so that clear and flexible data acquisition is realized, the environmental data is monitored in real time, and the safety of the monitored data is ensured.

Example 8:

as shown in fig. 2, the present technical solution provides an embodiment, where the data sharing module includes:

a connection unit: the system is used for connecting different terminal devices;

a login verification unit: the system comprises a terminal device and a verification server, wherein 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;

a verification result unit: the system is used for receiving and identifying the verification message and determining a verification result;

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

The working principle of the technical scheme is as follows:

the technical scheme includes logging in an APP (application) end of a mobile phone based on a preset account password, acquiring the account password according to a verification unit, logging in a webpage end of a computer, and simultaneously sending a verification message to the APP end of the mobile phone; finally, receiving and identifying the verification message through a verification result unit based on the APP terminal, and determining a verification result; meanwhile, according to the on-line association unit, when the verification result is successful, synchronizing the on-line association APP terminal module and the webpage terminal module, and determining the shared data content; a 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 on line in real time to a supervision engineering department, can display the information through a real-time curve graph, collects real-time quality acceptance data, acquires corresponding time of the real-time quality acceptance data, draws a corresponding real-time curve according to the real-time quality acceptance data and the time, displays the corresponding real-time curve on a mobile phone of a supervision party, can display the data through a data table, is convenient for a user to record, generates a data table according to the real-time quality acceptance data, transmits the data table to a supervision port, can also select the real-time curve graph, the data table or the sector statistical chart through other diversified modes such as a sector statistical chart or other modes, and displays the data table or the sector statistical chart on a control terminal of the supervision party through a selected function button.

The beneficial effects of the above technical scheme are that:

this technical scheme is equipped with special storage module and is used for saving a large amount of quality acceptance data, because quality acceptance data is the omnidirectional monitoring of whole day, so the information content is very huge, need be equipped with special memory block and save quality acceptance data to can follow the excavation of carrying out effective information in a large amount of quality acceptance data, and pass through safe verification, guarantee user login information's safety.

Example 9:

as shown in fig. 3, the present technical solution provides an embodiment, where the system further includes a trace back module, where the trace back module includes:

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

and an acceptance condition unit: the system is used for calling the acceptance condition of the project according to the frequency band signal; wherein,

the acceptance condition comprises an acceptance process, an acceptance historical record and an acceptance historical audit record of the visual data acceptance table;

a judging unit: the system is used for judging whether the acceptance condition is abnormal or not and acquiring a judgment result;

a storage unit: and the chip is used for transmitting and storing the frequency band signals of the chip and the corresponding visual data acceptance table to a storage module when the acceptance condition is not abnormal, and feeding back the content of the source data to the terminal equipment.

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

the technical scheme includes that the system also comprises a judging module, a storage module and a display module, wherein the judging module is used for judging whether the real-time environment data exceeds a preset threshold range of ideal environment data or not and acquiring a judging result, the real-time environment data is used for monitoring some values around a building in real time, and when the real-time environment data does not exceed the preset threshold range of the ideal environment data, the real-time environment data is ensured not to exceed an abnormal range, and the real-time environment data is transmitted to the storage module; and when the real-time environment data exceeds the preset threshold range of the ideal environment data, generating abnormal data and sending the abnormal data to the mobile phone. According to the technical scheme, the chip is embedded in the building, the environmental data are collected in real time, the change value of the environment is calculated in real time, and meanwhile, the environmental data can be mined in a self-adaptive and self-learning manner, and the acceptance condition of the project is called.

Example 10:

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

obtaining a building quality acceptance data unit: the system is used for acquiring and collecting the quality acceptance data of the building in real time;

acquiring a visual data chart unit: for obtaining a visual data chart;

a real-time curve graph obtaining unit: for obtaining a real-time curve graph;

a selection unit: the real-time graph or the visual data chart is selected and displayed on the control terminal.

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

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

As will be appreciated by one skilled in the art, 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, 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 flow diagrams and/or block diagrams, and combinations of flows and/or blocks in the flow diagrams 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 changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (10)

1. The utility model provides a hydraulic unit engineering quality acceptance data acquisition system based on thing networking which characterized in that includes:

the induction module: the system is used for transmitting fixed frequency band signals to the periphery based on an induction device embedded in a building and acquiring quality acceptance data of the building;

visual data acceptance sheet module: the system is used for automatically inputting the building quality acceptance data into a preset form to generate a visual data acceptance table;

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

2. The internet of things-based hydraulic unit engineering quality acceptance data acquisition system of claim 1, wherein the induction module comprises:

a collecting unit: the system is used for transmitting fixed frequency band signals to the periphery through the induction device and acquiring quality acceptance data of the building; wherein,

the quality acceptance data at least comprises time data, the planeness 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;

the data unit is accepted to the building quality: the quality acceptance data is automatically input into a filling form, and the quality acceptance data of the building is recorded in real time.

3. The internet of things-based hydraulic unit engineering quality acceptance data acquisition system of claim 2, wherein the sensing module further comprises:

transmitting a data unit: the system is used for fitting the building quality acceptance data to generate corresponding transmission data;

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

a transmission 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, and sending transmission data after the verification signal passes; wherein,

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

4. The Internet of things-based hydraulic unit engineering quality acceptance data acquisition system of claim 3, wherein the emission verification signal unit comprises:

a find location subunit: the device comprises a sensing device, a control unit and a control unit, wherein the sensing device is used for receiving a verification signal through preset terminal equipment based on a fixed frequency band signal transmitted by the sensing device, removing impurities and filtering the verification signal, determining a filtering signal and locking the position of a sensing chip in the corresponding sensing device;

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

a checking subunit: the device is used for acquiring historical distance data and checking the authenticity of the source data according to the historical distance data; wherein,

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

transmitting a transmission data subunit: and the data processing module is used for passing the verification signal and sending the transmission data to the terminal equipment when the source data is true.

5. The internet of things-based hydraulic unit engineering quality acceptance data acquisition system of claim 1, wherein the visual data acceptance sheet module comprises:

a receiving unit: the device comprises a fixed frequency band signal receiving and processing module, a frequency band signal generating module and a frequency band signal processing module, wherein the fixed frequency band signal receiving and processing module is used for receiving and processing a fixed frequency band signal based on preset terminal equipment, generating receiving data and generating a receiving instruction according to the receiving data; wherein,

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

a table unit: the terminal equipment is used for acquiring a preset function acceptance sheet style in the terminal equipment according to the receiving instruction;

checking the recording source data unit: the system comprises a data acquisition module, a data processing module and a data processing module, wherein the data acquisition module is used for acquiring source data, detecting the source data according to the quality acceptance data of the building and determining detection record source data; wherein,

the source data is building quality acceptance data obtained through a preset reverse compiling record style;

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

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

6. The Internet of things-based hydraulic unit engineering quality acceptance data acquisition system of claim 5, wherein 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 the chip are collected, and effective frequency band signals are determined:

wherein, tau_ij(t) represents the effective frequency band signal from the chip source signal node i to the observation signal node j of the terminal equipment at the time of t, and the node i represents the chipThe j node represents an observation signal node of the terminal equipment; i is 1,2,3, …, m represents the total number of signal nodes of chip source, j is 1,2,3, …, n, n represents the total number of signal nodes observed at the computer end, h (t) represents the state variable of the signal channel of signal node observed from the signal node of chip source to the terminal equipment at the time t, r_ij(j) Representing the impulse response, s, received by an observation signal node j from a chip source signal node i to an observation signal node j of a terminal device_i(t-j) represents a mixed fixed frequency band signal, G, emanating 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 an observation 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 according to the monitoring result, carrying out quantization processing on the signal to determine a processed signal.

7. The IOT-based hydraulic unit engineering quality acceptance data collection system of claim 6, wherein the step S2 includes:

step SS 201: monitoring the effective frequency band signal, judging whether the effective frequency band signal is adaptive to a channel state, and generating a judgment result:

wherein E represents the judgment result (0 represents that the effective frequency band signal is not suitable for the channel state, 1 represents that the effective frequency band signal is suitable for the channel state), r_ij(j) Representing the impulse response received by an observation signal node j when the observation signal node j is from a chip source signal node i to the observation signal node j of the terminal equipment, wherein the node i represents a source signal node of a chip, and the node j represents an observation signal node of the terminal equipment; i is 1,2,3, …, m represents the total number of signal nodes of chip source, j is 1,2,3, …, n, n represents the total number of observation signal nodes of terminal/computer terminal, tau_ij(t) represents the slave core at time tEffective frequency band signal G from chip source signal node i to observation signal node j of terminal equipment_ij(t) represents the noise-affected frequency band signal from the chip source signal node i to the observation signal node j of the terminal device at time t, L_ie(t) represents the response distance from the source signal node i to the listening node e, L, listened to at time t_ejRepresenting the response distance of listening node e to source signal node j listening at time t,

represents the mixed signal wavelength, and T represents the period of the wavelength;

step SS 202: when the judgment result E is 1, the effective frequency band signal is transmitted to a monitoring channel, which represents that the effective frequency band signal can be realized under the condition that the effective frequency band signal satisfies the channel state in the monitoring process;

step SS 203: quantizing the signal through the monitoring channel to determine a processed signal;

wherein SIG represents the processed 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 observation signal node j of the terminal device at time t,

representing the average signal, ε, from the chip source signal node i to the observation signal node j of the terminal device at time t_ijRepresenting sequence quantization parameters from a chip source signal node i to an observation signal node j of a terminal device, wherein m represents the total number of the chip source signal nodes, and n represents the total number of the observation signal nodes of a machine end/a computer end;

step SS 204: and when the monitoring result E is 0, the monitoring process cannot be realized under the condition of meeting the channel state, and the failed monitoring result is fed back to the intelligent terminal.

8. The internet of things-based hydraulic unit engineering quality acceptance data acquisition system of claim 1, wherein the data sharing module comprises:

a connection unit: the system is used for connecting different terminal devices;

a login verification unit: the system comprises a terminal device and a verification server, wherein 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;

a verification result unit: the system is used for receiving and identifying the verification message and determining a verification result;

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

9. The internet of things-based hydraulic unit engineering quality acceptance data acquisition system of claim 1, further comprising a traceability module, wherein the traceability module comprises:

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

and an acceptance condition unit: the system is used for calling the acceptance condition of the project according to the frequency band signal; wherein,

the acceptance condition comprises an acceptance process, an acceptance historical record and an acceptance historical audit record of the visual data acceptance table;

a judging unit: the system is used for judging whether the acceptance condition is abnormal or not and acquiring a judgment result;

a storage unit: and the chip is used for transmitting and storing the frequency band signals of the chip and the corresponding visual data acceptance table to a storage module when the acceptance condition is not abnormal, and feeding back the content of the source data to the terminal equipment.

10. The internet of things-based hydraulic unit engineering quality acceptance data acquisition system of claim 1, further comprising a display module; the display module comprises:

obtaining a building quality acceptance data unit: the system is used for acquiring and collecting the quality acceptance data of the building in real time;

acquiring a visual data chart unit: for obtaining a visual data chart;

a real-time curve graph obtaining unit: for obtaining a real-time curve graph;

a selection unit: the real-time graph or the visual data chart is selected and displayed on the control terminal.

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