阅读说明：本技术 谱图监控系统、方法及谱图采集器 (Spectrogram monitoring system and method and spectrogram collector ) 是由 王石平 李健 王青 杨震宇 李彬 陈建华 于 2021-08-24 设计创作，主要内容包括：本发明提供一种谱图监控系统、方法及谱图采集器。所述谱图监控系统包括：谱图采集器,与对应的化学品测量分析设备通信相连,用于不间断地采集所述化学品测量分析设备输出的化学品谱图；近端监控子系统,与所述谱图采集器通信相连,用于对所述谱图采集器获取到的化学品谱图进行比对分析以判断其中是否存在嫌疑谱图,并在分析得到所述嫌疑谱图时上报远端监控子系统；远端监控子系统,与所述近端监控子系统通信相连,用于根据所述近端监控子系统的上报生成相应的处理方案。所述谱图监控系统能够提升谱图比对和分析的效率。(The invention provides a spectrogram monitoring system and method and a spectrogram collector. The spectrogram monitoring system comprises: the spectrogram collector is in communication connection with the corresponding chemical measurement and analysis equipment and is used for uninterruptedly collecting a chemical spectrogram output by the chemical measurement and analysis equipment; the near-end monitoring subsystem is in communication connection with the spectrogram collector and is used for comparing and analyzing the chemical spectrogram acquired by the spectrogram collector to judge whether a suspected spectrogram exists or not and reporting the suspected spectrogram to the far-end monitoring subsystem when the suspected spectrogram is obtained through analysis; and the far-end monitoring subsystem is in communication connection with the near-end monitoring subsystem and is used for generating a corresponding processing scheme according to the report of the near-end monitoring subsystem. The spectrogram monitoring system can improve the efficiency of spectrogram comparison and analysis.)

1. A spectrogram monitoring system, comprising:

the spectrogram collector is in communication connection with the corresponding chemical measurement and analysis equipment and is used for uninterruptedly collecting a chemical spectrogram output by the chemical measurement and analysis equipment;

the near-end monitoring subsystem is in communication connection with the spectrogram collector and is used for comparing and analyzing the chemical spectrogram acquired by the spectrogram collector to judge whether a suspected spectrogram exists in the chemical spectrogram and reporting the suspected spectrogram to the far-end monitoring subsystem when the suspected spectrogram is obtained through analysis;

and the far-end monitoring subsystem is in communication connection with the near-end monitoring subsystem and is used for generating a corresponding processing scheme according to the report of the near-end monitoring subsystem.

2. The spectrogram monitoring system of claim 1, wherein said spectrogram collector comprises:

the connection state monitoring module is used for monitoring the connection state between the spectrogram collector and the chemical measurement and analysis equipment;

the alarm module is connected with the connection state monitoring module and used for giving an alarm when the spectrogram collector is disconnected with the chemical measuring and analyzing equipment;

and the network transmission module is in communication connection with the chemical measurement and analysis equipment and the near-end monitoring subsystem and is used for acquiring a chemical spectrogram output by the chemical measurement and analysis equipment and reporting the chemical spectrogram to the near-end monitoring subsystem.

3. The spectrogram monitoring system of claim 2, wherein said spectrogram harvester further comprises:

the external power supply connecting module is used for being connected with an external power supply so as to supply power to the spectrogram collector;

the battery is used for supplying power to the spectrogram collector when an external power supply is disconnected;

the alarm module is also in communication connection with the external power supply module and used for giving an alarm when the external power supply is disconnected.

4. The spectrogram monitoring system according to claim 2 or 3, wherein said spectrogram collector is disposed on said chemical measurement and analysis apparatus, and said spectrogram collector further comprises:

the positioning module is used for acquiring the position of the spectrogram collector;

the alarm module is also in communication connection with the positioning module and used for giving an alarm when the position of the spectrogram collector changes.

5. The spectrogram monitoring system of any one of claims 1-4, wherein: and the near-end monitoring subsystem reports the suspected spectrogram to the far-end monitoring subsystem when the suspected spectrogram is obtained, and the far-end monitoring subsystem performs secondary analysis on the suspected spectrogram and generates a corresponding processing scheme according to an analysis result.

6. The spectrogram monitoring system of any one of claims 1-4, wherein: and the near-end monitoring subsystem generates alarm information of a corresponding category when the suspected spectrogram is obtained, and reports the alarm information to the far-end monitoring subsystem, and the far-end monitoring subsystem generates a corresponding processing scheme according to the alarm information.

7. The spectrogram monitoring system of any one of claims 1-6, wherein: and the near-end monitoring subsystem compares and analyzes the chemical spectrogram acquired by the spectrogram acquisition unit according to a reference spectrogram atlas library so as to judge whether the suspected spectrogram exists or not.

8. The spectrogram monitoring system of claim 1, wherein: the spectrogram collector is also in communication connection with the remote monitoring subsystem and is used for reporting the acquired chemical spectrogram to the remote monitoring subsystem; the remote monitoring subsystem is also used for comparing and analyzing the chemical spectrogram acquired by the spectrogram acquisition device to judge whether a suspected spectrogram exists or not and generating a corresponding processing scheme when the suspected spectrogram is obtained through analysis.

9. A spectrogram collector, comprising:

the connection state monitoring module is used for monitoring the connection state between the spectrogram collector and the chemical measuring and analyzing equipment;

the alarm module is connected with the connection state monitoring module and used for giving an alarm when the spectrogram collector is disconnected with the chemical measuring and analyzing equipment;

and the network transmission module is in communication connection with the chemical measurement and analysis equipment and the near-end monitoring subsystem and is used for uninterruptedly acquiring a chemical spectrogram output by the chemical measurement and analysis equipment and reporting the chemical spectrogram to the near-end monitoring subsystem.

10. A spectrogram monitoring method, comprising:

continuously collecting a chemical spectrogram output by chemical measurement and analysis equipment by using a spectrogram collector;

comparing and analyzing the chemical spectrogram acquired by the spectrogram acquisition device to judge whether a suspected spectrogram exists in the chemical spectrogram; and when the suspected spectrogram is obtained through analysis, reporting the suspected spectrogram to a remote monitoring subsystem so that the remote monitoring subsystem generates a corresponding processing scheme.

Technical Field

The invention relates to a monitoring system, in particular to a spectrogram monitoring system, a spectrogram monitoring method and a spectrogram collector.

Background

New Psychoactive Substances (NPS) are also called third generation drugs, which are extremely dangerous to human body. NPS is often developed by means of chemical synthesis, the research and development period is fast, the concealment is strong, the law enforcement striking difficulty is large, and a riding opportunity is provided for lawbreakers.

In practice, after a lawbreaker develops and synthesizes a new psychoactive substance, a chemical measurement and analysis device is usually used for detection, so as to judge whether the chemical structure of the product is consistent with the expectation or not according to the obtained chemical spectrogram. In addition, the parties often do not meet the needs of the transaction, and one common approach is to provide the buyer with a chemical profile of the new psychoactive substance generated in a chemical measurement and analysis device to prove the authenticity and purity of the substance. Therefore, the chemical spectrogram generated by collecting and monitoring the chemical measurement and analysis equipment of each enterprise and public institution becomes an important means and method for identifying the illegal development and sale of new mental active substances.

The main identification modes of the current chemical spectrogram are as follows: the spectrogram data of the compound reported by enterprises are identified one by one in a manual comparison mode of professional qualified researchers, the comparison work has very high requirements on the identification staff, the professional is required to have the working experience of spectrogram resolution of the chemical spectrogram of the compound, and the professional is familiar with the synthesis and characteristic peak data of the novel psychoactive substance standard substance. A professional manually checks and compares spectrograms, and the daily work efficiency is estimated to be about 20. The amount of chemical spectrograms generated in Shanghai every year exceeds 100 thousands, the control requirements of the state on new psychoactive substances cannot be met by adopting a manual comparison mode, manual comparison is only carried out on spectrograms with information clues at present, other spectrograms are compared only in a spot check mode, and the mode is to find a suspected spectrogram which is not different from a large sea fishing needle from millions of chemical spectrograms. Therefore, how to construct a system capable of automatically monitoring a chemical spectrogram has become one of the technical problems that those skilled in the relevant art need to solve.

In addition, the chemical spectrogram monitoring system needs to completely acquire all spectrograms generated by enterprises and public institutions to ensure the effectiveness of the monitoring result, and how to realize the purpose is a great problem in the system construction process.

Moreover, because the chemical spectrogram reacts on the molecular structure of the chemical, the chemical belongs to the core trade secret of chemical development enterprises and public institutions, particularly biopharmaceutical enterprises, each spectrogram for self-developing the chemical is the core intellectual property right of the enterprise, and many enterprises and public institutions (particularly foreign enterprises) are unwilling to cooperate due to the worry about the leakage of the chemical spectrogram, so that how to avoid the intellectual property right of the enterprise from being leaked during the chemical spectrogram monitoring also belongs to a big problem in the system construction process.

Disclosure of Invention

In view of the above-mentioned shortcomings in the prior art, an object of the present invention is to provide a spectrogram monitoring system, method and spectrogram collector, which are used to solve the above-mentioned problems in the prior art.

To achieve the above and other related objects, a first aspect of the present invention provides a spectrogram monitoring system, comprising: the spectrogram collector is in communication connection with the corresponding chemical measurement and analysis equipment and is used for uninterruptedly collecting a chemical spectrogram output by the chemical measurement and analysis equipment; the near-end monitoring subsystem is in communication connection with the spectrogram collector and is used for comparing and analyzing the chemical spectrogram acquired by the spectrogram collector to judge whether a suspected spectrogram exists in the chemical spectrogram and reporting the suspected spectrogram to the far-end monitoring subsystem when the suspected spectrogram is obtained through analysis; and the far-end monitoring subsystem is in communication connection with the near-end monitoring subsystem and is used for generating a corresponding processing scheme according to the report of the near-end monitoring subsystem.

In an embodiment of the first aspect, the spectrogram collector comprises: the connection state monitoring module is used for monitoring the connection state between the spectrogram collector and the chemical measurement and analysis equipment; the alarm module is connected with the connection state monitoring module and used for giving an alarm when the spectrogram collector is disconnected with the chemical measuring and analyzing equipment; and the network transmission module is in communication connection with the chemical measurement and analysis equipment and the near-end monitoring subsystem and is used for acquiring a chemical spectrogram output by the chemical measurement and analysis equipment and reporting the chemical spectrogram to the near-end monitoring subsystem.

In an embodiment of the first aspect, the spectrogram collector further comprises: the external power supply connecting module is used for being connected with an external power supply so as to supply power to the spectrogram collector; the battery is used for supplying power to the spectrogram collector when an external power supply is disconnected; the alarm module is also in communication connection with the external power supply module and used for giving an alarm when the external power supply is disconnected.

In an embodiment of the first aspect, the spectrum collector is disposed on the chemical measurement and analysis apparatus, and the spectrum collector further includes: the positioning module is used for acquiring the position of the spectrogram collector; the alarm module is also in communication connection with the positioning module and used for giving an alarm when the position of the spectrogram collector changes.

In an embodiment of the first aspect, the near-end monitoring subsystem reports the suspected spectrogram to the far-end monitoring subsystem when the suspected spectrogram is obtained, and the far-end monitoring subsystem performs secondary analysis on the suspected spectrogram and generates a corresponding processing scheme according to an analysis result.

In an embodiment of the first aspect, the near-end monitoring subsystem generates alarm information of a corresponding category when the suspect spectrogram is acquired, and reports the alarm information to the far-end monitoring subsystem, and the far-end monitoring subsystem generates a corresponding processing scheme according to the alarm information.

In an embodiment of the first aspect, the near-end monitoring subsystem performs a comparison analysis on the chemical spectrogram acquired by the spectrogram acquirer according to a reference spectrogram library to determine whether the suspected spectrogram exists therein.

In an embodiment of the first aspect, the spectrum collector is further communicatively connected to the remote monitoring subsystem, and configured to report the collected chemical spectrum to the remote monitoring subsystem; the remote monitoring subsystem is also used for comparing and analyzing the chemical spectrogram acquired by the spectrogram acquisition device to judge whether a suspected spectrogram exists or not and generating a corresponding processing scheme when the suspected spectrogram is obtained through analysis.

A second aspect of the present invention provides a spectrogram collector, comprising: the connection state monitoring module is used for monitoring the connection state between the spectrogram collector and the chemical measuring and analyzing equipment; the alarm module is connected with the connection state monitoring module and used for giving an alarm when the spectrogram collector is disconnected with the chemical measuring and analyzing equipment; and the network transmission module is in communication connection with the chemical measurement and analysis equipment and the near-end monitoring subsystem and is used for uninterruptedly acquiring a chemical spectrogram output by the chemical measurement and analysis equipment and reporting the chemical spectrogram to the near-end monitoring subsystem.

A third aspect of the present invention provides a spectrogram monitoring method, including: continuously collecting a chemical spectrogram output by chemical measurement and analysis equipment by using a spectrogram collector; comparing and analyzing the chemical spectrogram acquired by the spectrogram acquisition device to judge whether a suspected spectrogram exists in the chemical spectrogram; and when the suspected spectrogram is obtained through analysis, reporting the suspected spectrogram to a remote monitoring subsystem so that the remote monitoring subsystem generates a corresponding processing scheme.

As described above, the spectrogram monitoring system described in one or more embodiments of the present invention has the following advantages:

the spectrogram monitoring system comprises a spectrogram collector, a near-end monitoring subsystem and a far-end monitoring subsystem, wherein the spectrogram collector can uninterruptedly collect chemical spectrograms output by chemical measurement and analysis equipment, so that the system can be ensured to completely obtain all spectrograms generated by enterprises and public institutions.

The near-end monitoring subsystem is arranged at a near end (such as in an office of an enterprise and public institution) and is used for comparing and analyzing the chemical spectrogram acquired by the spectrogram acquirer and reporting the chemical spectrogram to the far-end monitoring subsystem only when a suspected spectrogram is obtained through analysis, so that a normal chemical spectrogram of the enterprise and public institution cannot be transmitted to the outside of the office, and the risk of intellectual property leakage does not exist.

Moreover, the near-end monitoring subsystem can automatically compare and analyze chemical spectrograms, and the process basically does not need manual participation, so that the spectrogram comparing and analyzing efficiency can be greatly improved, and the control requirements of a supervision department on new psychoactive substances are met.

Drawings

Fig. 1 is a schematic structural diagram of a spectrum monitoring system according to an embodiment of the present invention.

Fig. 2A is a schematic structural diagram of a spectrogram collector in an embodiment of the spectrogram monitoring system of the present invention.

Fig. 2B is another schematic structural diagram of a spectrogram collector in an embodiment of the spectrogram monitoring system of the present invention.

Fig. 2C is a schematic structural diagram of a network transmission module of the spectrogram monitoring system in an embodiment of the present invention.

Fig. 3 is a flow chart of the spectrum monitoring method according to an embodiment of the invention.

Description of the element reference numerals

1 spectrogram monitoring system

111-114 spectrogram collector

1111 connection state monitoring module

1112 alarm module

1113 network transmission module

11131 spectrogram acquiring unit

11132 encryption unit

11133 spectrogram transmitting unit

11134 quality criterion quality of spectrogram processing

1114 external power supply connection module

1115 battery

1116 positioning module

121, 122 near-end monitoring subsystem

13 remote monitoring subsystem

21 ~ 24 chemicals measurement and analysis equipment

S31-S34

Detailed Description

The embodiments of the present invention are described below with reference to specific embodiments, and other advantages and effects of the present invention will be easily understood by those skilled in the art from the disclosure of the present specification. The invention is capable of other and different embodiments and of being practiced or of being carried out in various ways, and its several details are capable of modification in various respects, all without departing from the spirit and scope of the present invention. It is to be noted that the features in the following embodiments and examples may be combined with each other without conflict.

It should be noted that the drawings provided in the following embodiments are only for illustrating the basic idea of the present invention, and the drawings only show the components related to the present invention rather than being drawn according to the number, shape and size of the components in actual implementation, and the type, number and proportion of the components in actual implementation may be changed arbitrarily, and the layout of the components may be more complicated. Moreover, in this document, relational terms such as "first," "second," and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions.

Chemical spectrogram monitoring is one of important means for fighting new psychoactive substance crimes, however, in the prior art, the chemical spectrogram needs to be compared manually, the efficiency is low, and all chemical spectrograms of enterprises and public institutions are difficult to obtain, and the risk of leakage of intellectual property rights exists. To solve the problems, referring to fig. 1, a spectrogram monitoring system 1 is provided in an embodiment of the present invention, where the spectrogram monitoring system 1 includes spectrogram collectors 111 to 114, near-end monitoring subsystems 121 to 122, and a far-end monitoring subsystem 13, where the spectrogram collectors 111 to 114 are respectively connected to chemical measurement and analysis devices 21 to 24, the spectrogram collectors 111 to 113, the chemical measurement and analysis devices 21 to 23, and the near-end monitoring subsystem 121 are located at a near-end 1 (e.g., enterprise 1), the spectrogram collector 114, the chemical measurement and analysis device 24, and the near-end monitoring subsystem 122 are located at a near-end 2 (e.g., enterprise 2), and the far-end monitoring subsystem 13 is located at a far-end (e.g., a monitoring department).

Next, the spectrogram monitoring system 1 will be described in detail by taking the spectrogram collector 111, the near-end monitoring subsystem 121, and the far-end monitoring subsystem 13 as examples.

Specifically, the spectrogram collector 111 corresponds to the chemical measurement and analysis device 21, and is in communication connection with the chemical measurement and analysis device 21, and the spectrogram collector 111 is configured to continuously collect the chemical spectrogram output by the chemical measurement and analysis device 21. The chemical measurement and analysis device 21 is, for example, a nuclear magnetic resonance spectrometer.

The near-end monitoring subsystem 121 is communicatively connected to the spectrum collector 111, and configured to compare and analyze the chemical spectrum acquired by the spectrum collector 111 to determine whether a suspected spectrum exists therein, and report the suspected spectrum to the far-end monitoring subsystem 13 when the suspected spectrum is obtained through analysis.

The remote monitoring subsystem 13 is a poison-forbidden platform, is deployed in supervision departments such as a poison-forbidden office and a public security bureau, and is configured to generate a corresponding processing scheme according to the report of the near-end monitoring subsystem 121. For example, the reported result is checked, or a professional is arranged to go to the home for treatment.

As can be seen from the above description, in this embodiment, the spectrum collector 111 can continuously collect the chemical spectrum outputted by the chemical measurement and analysis device 21, so that when all the chemical measurement and analysis devices of a certain unit are connected to the spectrum collector, the near-end monitoring subsystem 121 can obtain all the chemical spectrums generated by the unit, thereby avoiding situations such as missing report and hiding of the chemical spectrums.

In addition, the near-end monitoring subsystem 121 is arranged at the near end of the enterprise and public institution and only reports the suspected spectrogram to the far end when the suspected spectrogram is obtained through analysis, so that the related workers at the far end only obtain the suspected spectrogram and cannot obtain the normal spectrogram of an enterprise, the method can greatly avoid the risk of spectrogram intellectual property leakage, and the enthusiasm of participation of the enterprise and public institution is improved.

Moreover, the near-end monitoring subsystem 121 can automatically compare and analyze chemical spectrograms, and the process does not need manual participation basically, so that the spectrogram comparing and analyzing efficiency can be greatly improved, and the control requirements of a supervision department on new psychoactive substances are met.

Referring to fig. 2A, in an embodiment of the invention, the spectrogram collector 111 includes a connection status monitoring module 1111, an alarm module 1112, and a network transmission module 1113.

The connection state monitoring module 1111 is in communication connection with the chemical measurement and analysis device 21, and is configured to monitor a connection state between the spectrogram collector 111 and the chemical measurement and analysis device 21. The connection state monitoring module 1111 may implement the monitoring of the connection state by using an existing circuit (for example, a control circuit including chips such as a CPU, a DSP, and an FPGA) and a method, and a specific implementation manner is not described herein in detail.

The alarm module 1112 is connected to the connection status monitoring module 1111 in a communication manner, and is configured to alarm when the spectrogram collector 111 is disconnected from the chemical measurement and analysis apparatus 21. For example, the connection status monitoring module 1111 may send an alarm signal to the alarm module 1112 when detecting that the connection between the spectrum collector 1111 and the chemical measurement and analysis apparatus 21 is disconnected, and the alarm module 1112 alarms after receiving the alarm signal. The alarm module 1112 may include a speaker, an LED lamp, a wireless communication module, and the like, and is configured to send out a sound alarm signal and a light alarm signal, and send a mobile phone alarm short message, and the like, but the present invention is not limited thereto, and in a specific application, the alarm module 1112 may include any device capable of playing a role in alarm or warning.

The network transmission module 1113 is communicatively connected to the chemical measurement and analysis device 21, and is configured to continuously obtain a chemical spectrogram output by the chemical measurement and analysis device 21 and send the chemical spectrogram to the near-end monitoring subsystem 121.

As can be seen from the above description, in this embodiment, the spectrogram collector 111 includes a connection status monitoring module 1111, an alarm module 1112, and a network transmission module 1113, where the connection status monitoring module 1111 is configured to monitor a connection status between the spectrogram collector 111 and the chemical measurement and analysis apparatus 21, and the alarm module 1112 may alarm when the spectrogram collector 111 is disconnected from the chemical measurement and analysis apparatus 21, so as to avoid an enterprise or public institution from detaching the spectrogram collector privately or disconnecting the spectrogram collector so as to intentionally miss some chemical spectrograms, thereby ensuring that the spectrogram collector 111 and the chemical measurement and analysis apparatus 21 are online all the time, and therefore, through the connection status monitoring module 1111 and the alarm module 1112, the network transmission module 1113 can be ensured to obtain all the chemical spectrograms output by the chemical measurement and analysis apparatus 21 and send them to the near-end monitoring subsystem 121, it is beneficial for the near-end monitoring subsystem 121 to continuously acquire and monitor all chemical spectrograms generated by the chemical spectrogram measuring and analyzing device 21.

In practical application, related personnel may also disable the spectrum collector 111 by powering off the spectrum collector 111, so as to achieve the purpose of missing report of part of chemical spectrums. To address this problem, referring to fig. 2B, in an embodiment of the present invention, the spectrogram collector 111 further includes an external power connection module 1114 and a battery 1115, wherein the external power connection module 1114 and the battery 1115 are electrically connected (not shown in the figure) to the connection status monitoring module 1111, the alarm module 1112, and the network transmission module 1113, respectively, so as to supply power to the relevant modules.

Specifically, the external power connection module 1114 is configured to connect with an external power source to supply power to each module in the spectrogram collector 111, and the power connection module 1114 includes, for example, a power socket and/or a power line with a power plug. The battery 1115 is used for supplying power to each module in the spectrogram collector 111 when an external power supply is disconnected, and the battery 1115 is, for example, a lithium battery. In addition, the alarm module 1112 is also connected to the external power connection module 1114 for alarming when the external power is disconnected.

As can be seen from the above description, in this embodiment, the spectrogram collector 111 is normally powered by an external power source, and when the external power source is turned off, the spectrogram collector 111 is switched to use the battery 1115 to supply power and send an alarm signal to the alarm module 1112 to alarm the alarm module 1112. By the method, the situation that related personnel illegally cut off the spectrogram collector 111 can be effectively avoided, and the fact that the spectrogram collector 111 can obtain all chemical spectrograms output by the chemical measurement and analysis equipment 21 is further ensured.

Optionally, referring to fig. 2C, the network transmission module 1113 in this embodiment may include a spectrogram collecting unit 11131, an encrypting unit 11132, and a spectrogram sending unit 11133. The spectrum acquiring unit 11131 is connected to the chemical measurement and analysis device 21 in communication, and is configured to acquire a chemical spectrum output by the chemical measurement and analysis device 21. The encryption unit 11132 is communicatively connected to the spectrogram acquiring unit 11131, and is configured to encrypt the chemical spectrogram acquired by the spectrogram acquiring unit 11131. The spectrum transmitting unit 11133 is communicatively connected to the encrypting unit 11132 and the near-end monitoring subsystem 121, and is configured to transmit the encrypted chemical spectrum to the near-end monitoring subsystem 121.

In this embodiment, the chemical spectrogram acquired by the spectrogram acquiring unit 11131 is encrypted by the encrypting unit 11132, and then the encrypted chemical spectrogram is transmitted to the near-end monitoring subsystem 121 by the spectrogram transmitting unit 11133, so that there is no need to worry about the fact that the spectrogram is compromised or stolen.

Optionally, the network transmission module 1113 may further include a spectrogram processing unit 11134, and at this time, the spectrogram obtaining unit 11131 is connected to the encryption unit 11132 through the spectrogram processing unit 11134. The spectrum processing unit 11134 is configured to perform regularization processing on the chemical spectrum acquired by the spectrum acquiring unit 11131.

Optionally, the network transmission module 1113 may be connected to the chemical measurement and analysis device 21 and the near-end monitoring subsystem 121 by using wired communication or wireless communication. For example, an RJ45 interface, a wireless network card, or the like may be configured on the network transmission module 1113 to implement the communication connection with the chemical measurement and analysis device 21 and the near-end monitoring subsystem 121.

Optionally, the spectrum collector 111 is disposed on the chemical measurement and analysis apparatus 21, and the spectrum collector 111 further includes a positioning module 1116. The positioning module 1116 is configured to acquire a current position of the spectrogram collector 111, and in this embodiment, the alarm module 1112 is further communicatively connected to the positioning module 1116 and configured to alarm when the position of the spectrogram collector 111 acquired by the positioning module 1116 changes.

As can be seen from the above description, the spectrogram collector 111 can collect the current position by using the positioning function of the positioning module 1116, and since the spectrogram collector 111 is bound to the chemical measurement and analysis device 21, it can be determined whether the chemical measurement and analysis device 21 has been moved, and an alarm is given when the chemical measurement and analysis device 21 is moved.

In an embodiment of the present invention, the spectrogram collector 111 further includes a display screen and/or a key. Wherein, the display screen is an LCD screen, for example. Based on the display screen and the keys, the user can realize human-computer interaction operation with the spectrogram collector 111, for example: configuring various parameters, inquiring acquired and reported spectrogram information and the like. In addition, the display screen can also be used for displaying system maintenance states, such as: system running state, network state, heartbeat online state, and the like.

In an embodiment of the present invention, the spectrogram collector 111 further includes a USB interface, and has built-in functions of GPS, WIFI, 4G/5G, and the like.

In an embodiment of the present invention, the near-end monitoring subsystem 121 performs comparison analysis on the chemical spectrogram obtained by the spectrogram collector 111 according to a reference spectrogram library to determine whether the suspected spectrogram exists therein.

Specifically, the near-end monitoring subsystem 121 may use an artificial intelligence algorithm to establish a study and judgment model algorithm for the evolution and mixture of new psychoactive substances, and perform artificial intelligence comparison and analysis with a new psychoactive substance reference spectrogram as a standard to determine whether a suspected spectrogram exists. The artificial intelligence algorithm is, for example, a neural network algorithm, an AI classification algorithm, and the like, and in practical application, by training a corresponding artificial intelligence model by using appropriate training data, the trained artificial intelligence model can realize the comparison and analysis, and finally judge whether a suspected spectrogram exists.

Optionally, in this embodiment, the reference spectrum library is obtained as follows: and (3) carrying out artificial synthesis on a plurality of new psychoactive substances which are popular at present, detecting on nuclear magnetic equipment to generate the reference substance spectrogram, and further constructing the reference substance spectrogram library.

In an embodiment of the present invention, when the near-end monitoring subsystem 121 obtains the suspected spectrogram, it reports the suspected spectrogram to the far-end monitoring subsystem 13, and the far-end monitoring subsystem 13 performs secondary analysis on the suspected spectrogram and generates a corresponding processing scheme according to an analysis result. The remote monitoring subsystem 13 may also implement the secondary analysis by using an artificial intelligence algorithm, which is similar to the near monitoring subsystem 121 in a specific manner and will not be described herein in any greater detail. In addition, the remote monitoring subsystem 13 may also implement the secondary analysis manually, for example, forward the suspected spectrogram to a corresponding worker for auditing, and at this time, the worker only needs to audit the suspected spectrogram, so that the workload is greatly reduced.

In an embodiment of the present invention, when the suspected spectrogram is obtained, the near-end monitoring subsystem 121 generates alarm information of a corresponding category, and reports the alarm information to the far-end monitoring subsystem 13, and the far-end monitoring subsystem 13 generates a corresponding processing scheme according to the alarm information. For example, the near-end monitoring subsystem 121 may classify a chemical profile as similar to a new psychoactive substance profile by: normal spectrogram, light suspect spectrogram, moderate suspect spectrogram, heavy suspect spectrogram, etc., generate alarm information of corresponding grade based on the category of suspect spectrogram and send to the remote monitoring subsystem 13, and the remote monitoring subsystem 13 may generate a corresponding processing scheme according to the grade of the alarm information, for example, arrange manual review of spectrogram, arrange workers to handle at home, etc.

In an embodiment of the present invention, the near-end monitoring subsystem further includes a storage module, and the storage module stores one or a combination of the following databases: spectrogram metadata library, spectrogram comparison library, abnormal spectrogram library, chemical reference library and spectrogram related unit library. The spectrogram metadata base is used for storing and managing original spectrogram data output by spectrogram measuring and analyzing equipment so as to trace back after an abnormality is found. The spectrogram comparison library is a normalized database formed by converting spectrogram metadata and is used for performing intelligent spectrogram comparison. The abnormal spectrogram library is used for storing abnormal spectrograms, wherein corresponding inspection units, personnel information and the like are input, for example, spectrograms with similarity exceeding a preset threshold value can be stored in the abnormal spectrogram library after the detection spectrogram is compared with spectrograms in a reference substance library. The chemical reference substance library is a reference substance spectrogram library of the novel psychoactive substance and belongs to a standard spectrogram library. The spectrogram related unit library is established by corresponding supervision departments and comprises a chemical measurement and analysis equipment enterprise and public institution information library, a submission unit information library, a spectrogram abnormal unit library and the like.

In an embodiment of the present invention, the near-end monitoring subsystem is further configured to provide various services for supporting business applications, including various services required for completing intelligent comparison, a service for performing real-time monitoring on a spectrogram collector, an information security service for providing security protection functions such as encryption and decryption, desensitization processing, and the like for system data, and the like.

In an embodiment of the present invention, the spectrogram collector is further communicatively connected to the remote monitoring subsystem, and configured to report the chemical spectrogram collected by the spectrogram collector to the remote monitoring subsystem; the remote monitoring subsystem is also used for comparing and analyzing the chemical spectrogram acquired by the spectrogram acquisition device to judge whether a suspected spectrogram exists or not and generating a corresponding processing scheme when the suspected spectrogram is obtained through analysis. In this embodiment, the method for the remote monitoring subsystem to perform comparison analysis on the chemical spectrogram is similar to that of the near monitoring subsystem, and is not described herein in detail for saving the description.

Based on the description of the spectrogram monitoring system, the invention also provides a spectrogram collector. Specifically, in an embodiment of the present invention, the spectrogram collector includes a connection status monitoring module, an alarm module, and a network transmission module. The structure and function of the spectrogram collector are the same as those of the spectrogram collector 111 shown in fig. 2A or fig. 2B, and are not described herein in detail for saving the description.

Based on the description of the spectrogram monitoring system, the invention also provides a spectrogram monitoring method. Referring to fig. 3, in an embodiment of the present invention, the spectrogram monitoring method includes:

and S31, continuously collecting the chemical spectrogram output by the chemical measurement and analysis equipment by using the spectrogram collector.

And S32, comparing and analyzing the chemical spectrogram obtained by the spectrogram collector to judge whether a suspected spectrogram exists.

And S33, reporting the suspected spectrogram to a remote monitoring subsystem when the suspected spectrogram is obtained through analysis, so that the remote monitoring subsystem generates a corresponding processing scheme.

The spectrogram monitoring method described in this embodiment corresponds to the relevant function module of the spectrogram monitoring system shown in fig. 1, and is not described herein in detail to save the description.

The protection scope of the spectrogram monitoring method of the present invention is not limited to the execution sequence of the steps listed in this embodiment, and all the schemes of adding, subtracting, and replacing steps in the prior art according to the principles of the present invention are included in the protection scope of the present invention.

The invention also provides a spectrogram monitoring system, which can realize the spectrogram monitoring method of the invention, but the realization device of the spectrogram monitoring method of the invention comprises but is not limited to the structure of the spectrogram monitoring system listed in the embodiment, and all structural modifications and substitutions in the prior art made according to the principle of the invention are included in the protection scope of the invention.

The spectrogram monitoring system comprises a spectrogram collector, a near-end monitoring subsystem and a far-end monitoring subsystem, wherein the spectrogram collector can uninterruptedly collect chemical spectrograms output by chemical measurement and analysis equipment, so that the system can be ensured to completely obtain all spectrograms generated by enterprises and public institutions.

In addition, the near-end monitoring subsystem is arranged at a near end (for example, in an office of an enterprise and public institution), and is used for comparing and analyzing the chemical spectrogram acquired by the spectrogram acquirer and reporting the chemical spectrogram to the far-end monitoring subsystem only when a suspected spectrogram is obtained through analysis, so that a normal chemical spectrogram of the enterprise and public institution cannot be transmitted to the outside of the office, and the risk of intellectual property leakage does not exist.

Moreover, the near-end monitoring subsystem can automatically compare and analyze chemical spectrograms, and the process basically does not need manual participation, so that the spectrogram comparing and analyzing efficiency can be greatly improved, and the national control requirements on new psychoactive substances are met.

In conclusion, the present invention effectively overcomes various disadvantages of the prior art and has high industrial utilization value.

The foregoing embodiments are merely illustrative of the principles and utilities of the present invention and are not intended to limit the invention. Any person skilled in the art can modify or change the above-mentioned embodiments without departing from the spirit and scope of the present invention. Accordingly, it is intended that all equivalent modifications or changes which can be made by those skilled in the art without departing from the spirit and technical spirit of the present invention be covered by the claims of the present invention.