CN116008246A - Device for controlling raman spectrometer - Google Patents

Abstract

The device for controlling the Raman spectrometer comprises an image acquisition and analysis unit, a processing unit, a human-computer interface unit and a carrier control unit. The image acquisition and analysis unit acquires image information of an object to be detected and divides the image information into a plurality of blocks, and each block is provided with corresponding block information. The processing unit is electrically connected with the image capturing and analyzing unit and compares the block information in the image capturing and analyzing unit with a preset image information numerical range or a threshold value to determine whether the corresponding block has a first priority analysis level. The human-computer interface unit is electrically connected with the image acquisition analysis unit and the processing unit, and respectively receives user input for each block with a first priority analysis level so as to record whether each block has a second priority analysis level. The object carrying control unit is electrically connected with the man-machine interface unit, controls the position of an object to be detected aiming at the block with the second priority analysis grade, and enables the block to carry out Raman spectrum detection, so that man-machine interaction between a user and the Raman spectrometer is enhanced.

Description

Device for controlling raman spectrometer

Technical Field

The present invention relates to a control device, and more particularly, to a device for controlling a raman spectrometer.

Background

The current main microorganism detection technology comprises biochemical detection, matrix assisted laser desorption ionization time of flight (MALDI-TOF) mass spectrum detection, raman spectrum detection and the like. The biochemical detection requires a long time of microorganism culture, and different microorganisms may need a specific biological reaction method for identification, so that direct, rapid and accurate microorganism detection cannot be achieved. MALDI-TOF mass spectrometry detection is carried out by using mass/charge ratio patterns of proteins generated in a vacuum flight tube after different protein samples of a microorganism to be detected are ionized, and the detection is faster than biochemical detection, but different microorganisms possibly have similar protein patterns to influence the identification accuracy; in addition, MALDI-TOF mass spectrometry equipment is expensive, the operating environment is demanding, and subsequent use of consumables and maintenance costs are high, limiting its versatility for microbiological detection.

Compared with a MALDI-TOF mass spectrometer, the Raman spectrometer has the advantages of low equipment cost, simpler environmental requirements and the like, and is suitable for detecting a wide range of microorganism types (such as bacteria, fungi, viruses and the like). Moreover, along with the increasing strong image identification function of artificial intelligence, the artificial intelligence can be combined with the detection result of a Raman spectrometer, so that the microorganism type can be accurately and rapidly identified, and the subsequent clinical diagnosis and treatment guidance can be provided.

Disclosure of Invention

The present invention provides a device for controlling a raman spectrometer whereby the control of the raman spectrometer is enhanced.

In order to solve the above-mentioned problems, one of the technical solutions adopted by the present invention is to provide a device for controlling a raman spectrometer, which includes an image capturing and analyzing unit, a processing unit, a man-machine interface unit, and a carrier control unit. The image capturing and analyzing unit is used for obtaining image information of an object to be detected and dividing the image information into a plurality of blocks, wherein each block is provided with corresponding block information. The processing unit is electrically connected with the image acquisition and analysis unit. The processing unit compares one block information with a preset image information numerical range or threshold value to determine whether the corresponding block has a first priority analysis level. The human-computer interface unit is electrically connected with the image acquisition and analysis unit and the processing unit. The human-computer interface unit receives a user input for each block with the first priority analysis level to record whether each block has the second priority analysis level. The object carrying control unit is electrically connected with the man-machine interface unit. The object carrying control unit controls the position of the object to be detected aiming at the block with the second priority analysis grade, and enables the block with the second priority analysis grade to carry out Raman spectrum detection.

Preferably, the processing unit compares the block information with a predetermined image information numerical range or a threshold value to determine whether the corresponding block has the first priority analysis level, when the block information falls within the predetermined image information numerical range, the processing unit determines that the corresponding block has the first priority analysis level, and when the block information does not fall within the predetermined image information numerical range, the processing unit determines that the corresponding block does not have the first priority analysis level.

Preferably, the human-machine interface unit comprises a first mode module and a second mode module. The first mode module includes a first mode in which the first mode module provides a first indication to a user for each block having a first priority analysis level, and the first mode module automatically records whether each block has a second priority analysis level for a user input corresponding to the first indication. The second mode module includes a second mode in which the second mode module provides a second indication to the user as to whether each block determined by the user has the first priority analysis level, and the second mode module correspondingly determines whether to record whether each block determined by the user has the second priority analysis level for a user input corresponding to the second indication.

Preferably, the device for controlling a raman spectrometer further comprises a laser measurement control unit, and the laser measurement control unit is electrically connected with the man-machine interface unit and the carrier control unit.

Preferably, the human-machine interface unit comprises a third mode module and a fourth mode module. The third mode module includes a third mode in which the third mode module provides a third indication to the user for each tile having the first priority analysis level, the third mode module automatically records whether each tile has the second priority analysis level and transmits tile information having the second priority analysis level to the laser measurement control unit for user input corresponding to the third indication, the laser measurement control unit analyzes to determine whether the tile information having the second priority analysis level has the third priority analysis level and transmits the tile information having the third priority analysis level to the third mode module, and the third mode module automatically records whether each tile has the third priority analysis level for the corresponding third mode module. The fourth mode module includes a fourth mode in which the fourth mode module transmits the block information determined by each user to have the second priority analysis level to the laser measurement control unit, the laser measurement control unit analyzes to determine whether the block information having the second priority analysis level has the third priority analysis level and transmits to the fourth mode module, the fourth mode module provides a fourth indication to the user as to whether each block determined by the user has the third priority analysis level, and the fourth mode module correspondingly records whether each block has the third priority analysis level for a user input corresponding to the fourth indication.

Preferably, the device for controlling a raman spectrometer further comprises a cleaning control unit electrically connected to the human-machine interface unit.

Preferably, the cleaning control unit performs an automatic control to clean the detection space within the raman spectrometer.

Preferably, the human-machine interface unit comprises a fifth mode module. The fifth mode module comprises a fifth mode, in which the fifth mode module provides a fifth indication to a user for the use times of the substrate carrying the object to be detected, the times of the carrying platform of the Raman spectrometer entering and exiting the detection space of the Raman spectrometer or the time of the Raman spectrometer in a continuous starting state, and the fifth mode module correspondingly determines whether to clean the detection space of the Raman spectrometer for the user input corresponding to the fifth indication.

The device for controlling the Raman spectrometer has the advantages that the device can automatically compare the system to determine whether the corresponding block has the first priority analysis grade or not, and the user inputs the technical scheme of confirming whether each block has the second priority analysis grade or not, so that man-machine interaction between the user and the Raman spectrometer is enhanced, control of the Raman spectrometer is improved, measurement time is shortened, and detection results are optimized.

For a further understanding of the nature and the technical aspects of the present invention, reference should be made to the following detailed description of the invention and the accompanying drawings, which are provided for purposes of reference only and are not intended to limit the invention.

Drawings

FIG. 1 is a functional block diagram of an apparatus for controlling a Raman spectrometer according to a first embodiment of the invention

Fig. 2 is a user interface schematic diagram of an apparatus for controlling a raman spectrometer according to a first embodiment of the present invention.

Fig. 3 is a first full-automatic mode flowchart of a first full-automatic mode module of an apparatus for controlling a raman spectrometer according to a first embodiment of the present invention.

Fig. 4 is a first mode flow chart of a first mode module of an apparatus for controlling a raman spectrometer according to a first embodiment of the present invention.

Fig. 5 is a second mode flowchart of a second mode module of the apparatus for controlling a raman spectrometer according to the first embodiment of the present invention.

Fig. 6 is a functional block diagram of an apparatus for controlling a raman spectrometer according to a second embodiment of the present invention.

Fig. 7 is a second full-automatic mode flowchart of a second full-automatic mode module of an apparatus for controlling a raman spectrometer according to a second embodiment of the present invention.

Fig. 8 is a third mode flowchart of a third mode module of an apparatus for controlling a raman spectrometer according to a second embodiment of the present invention.

Fig. 9 is a fourth mode flowchart of a fourth mode module of an apparatus for controlling a raman spectrometer according to a second embodiment of the present invention.

Fig. 10 is a functional block diagram of an apparatus for controlling a raman spectrometer according to a third embodiment of the present invention.

Fig. 11 is a fifth mode flowchart of a fifth mode module of an apparatus for controlling a raman spectrometer according to a third embodiment of the present invention.

Detailed Description

The following embodiments of the present invention are described in terms of specific examples, and those skilled in the art will appreciate the advantages and effects of the present invention from the disclosure provided herein. The invention is capable of other and different embodiments and its several details are capable of modification and variation in various respects, all from the point of view and application, all without departing from the spirit of the present invention. The drawings of the present invention are merely schematic illustrations, and are not intended to be drawn to actual dimensions. The following embodiments will further illustrate the related art content of the present invention in detail, but the content provided is not intended to limit the scope of the present invention.

First embodiment

Referring to fig. 1, a first embodiment of the present invention provides a device D for controlling a raman spectrometer, which may be disposed inside or outside a raman spectrometer, comprising: an image capturing and analyzing unit 1, a processing unit 2, a man-machine interface unit 3 and a load control unit 4.

The image capturing and analyzing unit 1 is used for capturing an object M to be detected to obtain image information IMG of the object M to be detected. The image capturing and analyzing unit 1 may comprise an optical sensing element such as, but not limited to, a charge coupled device (charge coupled device, CCD) or a complementary metal oxide semiconductor (complementary metal-oxide semiconductor, CMOS) image sensor. In an embodiment, the image capturing and analyzing unit 1 is connected to an optical lens, the optical lens captures an image of the object M, and the image capturing and analyzing unit 1 can analyze the image of the object M to obtain an image information IMG, and divide the image information IMG into a plurality of blocks, and each block has corresponding block information. For example, the image information IMG may be an optical feature of the object M, such as an outline, brightness, color, etc., but the invention is not limited thereto. Still further, the tile information may be optical characteristics of the tile, such as brightness, color, gray scale value, color tile density, color tile area, etc., but the invention is not limited thereto.

The processing unit 2 is electrically connected to the image capturing and analyzing unit 1. The processing unit 2 may compare the plurality of blocks of the image information IMG with a predetermined image information numerical range to determine a first priority analysis level of each block. For example, the predetermined image information value range may be a predetermined luminance value range, and the predetermined luminance value range is an image gray-scale value ranging from 120 to 250, and the processing unit 2 records one of the blocks as having the first priority analysis level when the block information value of the one of the blocks falls within the predetermined luminance value range, i.e. the block image gray-scale value ranges from 120 to 250. When the block information value of another block of the plurality of blocks does not fall within the predetermined brightness value range, i.e. the block image gray scale value is less than 120 or greater than 250, the processing unit 2 records the another block of the plurality of blocks as not having the first priority analysis level. It should be noted that, in the present embodiment, although the numerical range is used as a basis for comparison, in other embodiments, a threshold value may be used as a basis for comparison, which is not limited by the present invention.

In addition, the device D for controlling the raman spectrometer may further include a database (not shown) that is electrically or communicatively connected to the processing unit 2 and the human-machine interface unit 3. The database can store various biological or non-biological image information or Raman spectrum patterns, and can be used for comparing and analyzing with the object M to predict or determine the classification of the object M.

The human-computer interface unit 3 is electrically connected with the image capturing and analyzing unit 1 and the processing unit 2. As shown in fig. 2, the human-machine interface unit 3 may include a user interface, which may be used to store and display user interface configuration data related to image information IMG or block information, and the user interface may be a device with a Liquid-crystal display (LCD) or an Organic light-emitting diode (OLED) display, etc., which is not limited to this. For example, as shown in fig. 2, the user interface may be configured with a display module 31, and the display module 31 may display a real-time image or a non-real-time image of the object M through a screen of the display for providing a reference to a user. In addition, the human-computer interface unit 3 may receive user input from a user through an input device of a keyboard, a mouse, a touch pad or a touch screen, which is not limited to the present invention. The user interface may further configure the human-computer interface control module 32, and through the human-computer interface control module 32, different stages in the detection process of the object to be detected M may be controlled, for example, different stages in the detection process may include a detection start function, a detection end function, an image control function of the display module 31 displaying the object to be detected M, etc., and the configuration of the human-computer interface control module 32 may be adjusted according to the user requirement, which is not limited by the present invention. In addition, the man-machine interface control module 32 may be further configured with a manual control unit for controlling the movement (including moving in/out of the raman spectrometer) of the stage carrying the object M to be detected during the detection, the laser parameter (including laser energy, time, number of times of receiving and sending, etc.), the laser detector temperature, and the measurement mode (including fast, accurate, highly accurate, etc.). The configuration of the manual control unit of the user can be adjusted according to the user's requirement, and the invention is not limited thereto.

In addition, the user interface may further configure an object to be measured configuration module 33 for displaying a configuration mode of the object to be measured M and providing a rapid positioning function of the object to be measured M. The user interface may be further configured with a raman spectrum graphic module 34, and the raman spectrum graphic module 34 may display a real-time raman spectrum graphic image or a non-real-time raman spectrum graphic image of the object M to be measured. The user interface may be further configured with a raman spectrum prediction result display module 35, where the raman spectrum prediction result display module 35 may display the raman spectrum prediction result of the object to be measured M, so as to provide the user with a determination of whether to perform subsequent raman spectrum result analysis.

Further, the human-machine interface unit 3 may include a first full-automatic mode module, and the first full-automatic mode module includes a first full-automatic mode. In detail, as shown in fig. 3, in the first full-automatic mode, the first full-automatic mode module of the human-machine interface unit 3 automatically determines and records whether each block has the first priority analysis level according to the analysis result of the processing unit 2, then automatically records the sampling area having the second priority analysis level, and transmits a first full-automatic control signal ACS1 to the carrier control unit 4 to control the sampling area to perform displacement through the carrier control unit 4, and performs raman spectrum analysis according to the image information IMG or the block information including the sampling area. That is, in the first full-automatic mode, the human-machine interface unit 3 may automatically complete all raman spectrum detection processes. It should be noted that, the determination of the first priority analysis level herein is to identify whether there is a block or a sufficient number of samples in the block according to the analysis image information IMG or the block information, for example; the second priority analysis level is determined, for example, by identifying the sample density in the block based on the analysis image information IMG or the block information. However, the invention is not limited thereto, and the basis for determining whether the first priority analysis level or the second priority analysis level is provided can be changed according to the user's requirement.

Furthermore, the human-machine interface unit 3 may further comprise a first mode module and a second mode module. The first mode module comprises a first mode, and the first mode is a semi-automatic measurement mode. The second mode module comprises a second mode, and the second mode is a manual measurement mode of a user.

As shown in fig. 4, in the first mode, the first mode module of the human-computer interface unit 3 automatically determines and records whether each block has a first priority analysis level according to the analysis result of the processing unit 2, and provides a first indication to the user. Then, for a user input corresponding to the first instruction, the first mode module of the human-computer interface unit 3 correspondingly and automatically records the sampling area with a second priority analysis level, and transmits a first control signal CS1 to the object-carrying control unit 4 to control the sampling area to displace through the object-carrying control unit 4, and performs raman spectrum analysis according to the image information IMG or the block information of the sampling area.

In the second mode, as shown in fig. 5, the human interface unit 3 determines the sampling area according to the user input. In one embodiment, after the hmi unit 3 receives a user input (corresponding to a sampling area to be selected by the user), the second mode module of the hmi unit 3 provides a second indication to the user according to whether the image information IMG or the tile information of the sampling area has the first priority analysis level. Then, for a user indication corresponding to the second indication, the second mode module of the human-computer interface unit 3 correspondingly determines whether the sampling area is recorded with a second priority analysis level, and transmits a second control signal CS2 to the object-carrying control unit 4 according to whether the sampling area is recorded with the second priority analysis level, so as to control the position of the object to be detected M through the object-carrying control unit 4, so that the sampling area with the second priority analysis level is displaced, and raman spectrum analysis is performed according to image information IMG or block information including the sampling area. In an embodiment, the second indication provided by the second mode module of the human-machine interface unit 3 is provided with the first priority analysis level according to the image information IMG or the block information of the area range, so that the content of the second indication may be "the record sampling area is determined to have the second priority analysis level by the user". In another embodiment, the second indication provided by the second mode module of the human-machine interface unit 3 is "the image information IMG or the tile information according to the area range does not have the first priority analysis level", so the content of the second indication may be "the user is recommended not to record the sampling area to have the second priority analysis level". However, the user may determine whether to input the user indication corresponding to the second indication according to the requirement without the content of the second indication, and the user may reselect the sampling area and execute the operation of the second mode again. In addition, the second indication can be adjusted according to the actual requirement, which is not limited in the present invention.

The object carrying control unit 4 is electrically connected with the man-machine interface unit 3. In the first mode, the first mode module of the human-machine interface unit 3 automatically records the sampling area with the second priority analysis level according to the user input corresponding to the first instruction, and transmits the first control signal CS1 to the load control unit 4. Or, in the second mode, the second mode module of the human-machine interface unit 3 records the sampling area with the second priority analysis level according to the user input corresponding to the second instruction, and transmits the second control signal CS2 to the load control unit 4. Thereby, the carrier control unit 4 controls the moving object to be measured M so that the sampling area with the second priority analysis level is subjected to raman spectrum detection. The carrier control unit 4 is connected to a carrier arranged in the raman spectrometer, and the carrier is driven by a stepping motor or a servo motor. In a preferred embodiment, the load control unit 4 is connected to a servo motor driven load stage. In addition, the carrier connected to the carrier control unit 4 may be a single-axis carrier or a multi-axis carrier. In a preferred embodiment, the carrier connected to the carrier control unit 4 is a multi-axis carrier. In a preferred embodiment, the carrier to which the load control unit 4 is connected is a three-axis carrier. Furthermore, the size and shape of the carrier can be adjusted according to the actual requirement, and the area and shape of the region carrying the object to be measured M on the carrier can be adjusted according to the actual requirement, which is not limited by the present invention.

However, the above examples are only one possible embodiment and are not intended to limit the present invention.

Second embodiment

The second embodiment differs from the first embodiment in that the laser measurement control unit, that is, the apparatus for controlling a raman spectrometer of the present invention may have a laser measurement control unit. In addition, it should be noted that, the other structures of the device D for controlling a raman spectrometer provided in the second embodiment are similar to those of the first embodiment, and are not repeated here.

Referring to fig. 6, in this embodiment, the apparatus D for controlling a raman spectrometer according to the present invention may further include a laser measurement control unit 5. The laser measurement control unit 5 is electrically connected with the man-machine interface unit 3 and the object carrying control unit 4. The laser measurement control unit 5 analyzes the image information IMG or the block information of the sampling area recorded with the second priority analysis level in response to the user input of the first instruction or the second instruction, and determines the laser measurement related parameters of the sampling area.

Similar to the first embodiment, in the present embodiment, the human-machine interface unit 3 may also include a second fully-automatic mode module, and the second fully-automatic mode module includes a second fully-automatic mode. In detail, as shown in fig. 7, in the second full-automatic mode, the second full-automatic mode module of the human-machine interface unit 3 automatically determines and records whether each block has the first priority analysis level according to the analysis result of the processing unit 2, and then automatically records the sampling area having the second priority analysis level and transmits the sampling area to the laser measurement control unit 5. The laser measurement control unit 5 performs analysis according to the image information IMG or the block information of the sampling area having the second priority analysis level, automatically determines whether to record the sampling area having the third priority analysis level, and transmits a second full-automatic control signal ACS2 to the carrier control unit 4 to control the sampling area to perform displacement through the carrier control unit 4, and performs raman spectrum analysis according to the image information IMG or the block information including the sampling area. That is, in the second full-automatic mode, the human-machine interface unit 3 and the laser measurement control unit 5 can automatically complete all raman spectrum detection processes. It should be noted that, the determination of the first priority analysis level herein is to identify whether there is a block or a sufficient number of samples in the block according to the analysis image information IMG or the block information, for example; the second priority analysis level is determined by, for example, identifying the sample density in the block according to the analysis image information IMG or the block information; the third priority analysis level is determined by, for example, identifying the color, gray level distribution, etc. in the block based on the analysis image information IMG or the block information. However, the invention is not limited thereto, and the basis for determining the first priority analysis level, the second priority analysis level, and the third priority analysis level may be changed according to the needs of the user.

In this embodiment, the hmi unit 3 may further include a third mode module and a fourth mode module. The third mode module includes a third mode, the third mode is a semi-automatic measurement mode, and the first half of the third mode has the first mode hidden, or the second half of the third mode can be operated in series with the first mode. The fourth mode module comprises a fourth mode, and the fourth mode is a manual measurement mode of a user.

As shown in fig. 8, in the third mode, the third mode module of the human-machine interface unit 3 automatically determines and records whether each block has the first priority analysis level according to the analysis result of the processing unit 2, and provides a third indication to the user, and for the user input corresponding to the third indication, the third mode module of the human-machine interface unit 3 automatically records the sampling area having the second priority analysis level and transmits the sampling area to the third mode module of the human-machine interface unit 3. The third mode module of the human-machine interface unit 3 then transmits the image information IMG or the block information recorded in the sampling area having the second priority analysis level to the laser measurement control unit 5. The laser measurement control unit 5 analyzes based on the image information IMG or the block information of the sampling region having the second priority analysis level, and determines whether the sampling region has the third priority analysis level. Then, the laser measurement control unit 5 transmits a third indication signal to the third mode module of the human-machine interface unit 3. The third mode module of the human-computer interface unit 3 automatically records the sampling area with the third priority analysis level, and transmits a third control signal CS3 to the object-carrying control unit 4 to control the displacement of the sampling area with the third priority analysis and the like through the object-carrying control unit 4, and performs raman spectrum analysis according to the image information IMG or the block information including the sampling area.

As shown in fig. 9, in the fourth mode, the fourth mode module of the human-computer interface unit 3 receives a user input (corresponding to a sampling area to be selected by the user) from the user to determine that the recorded sampling area has the second priority analysis level, and the laser measurement control unit 5 performs analysis according to the image information IMG or the block information of the sampling area having the second priority analysis level, and determines whether the sampling area has the third priority analysis level. Then, the laser measurement control unit 5 transmits a fourth indication signal to the fourth mode module of the human-machine interface unit 3, and the fourth mode module of the human-machine interface unit 3 provides a fourth indication to the user. Then, for a user input corresponding to the fourth instruction, the fourth mode module of the human-computer interface unit 3 correspondingly determines whether the sampling area is recorded with the third priority analysis level, and transmits a fourth control signal CS4 to the object-carrying control unit 4 according to whether the sampling area is recorded with the third priority analysis level, so as to control the position of the object to be detected M through the object-carrying control unit 4, so that the sampling area with the third priority analysis level is displaced, and raman spectrum analysis is performed according to the image information IMG or the block information including the sampling area. In an embodiment, the fourth indication provided by the fourth mode module of the human-computer interface unit 3 is "the image information IMG or the tile information according to the area range has the third priority analysis level", so the content of the fourth indication may be "the record sampling area has the third priority analysis level determined by the user. In another embodiment, the fourth indication provided by the fourth mode module of the human-computer interface unit 3 is "the image information IMG or the tile information according to the area range does not have the third priority analysis level", so the content of the fourth indication may be "the user is recommended not to record the sampling area having the third priority analysis level". However, the user may determine whether to input the user indication corresponding to the fourth indication according to the requirement without the content of the fourth indication, and the user may reselect the sampling area and execute the fourth mode operation again. In addition, the fourth indication can be adjusted according to the actual requirement, which is not limited by the present invention.

However, the above examples are only one possible embodiment and are not intended to limit the present invention.

Third embodiment

The third embodiment differs from the first or second embodiment in that the cleaning control unit, that is, the apparatus for controlling a raman spectrometer of the present invention may have a cleaning control unit. In addition, it should be noted that, the other structures of the device D for controlling a raman spectrometer provided in the third embodiment are similar to those of the first embodiment or the second embodiment, and are not repeated here.

Referring to fig. 10, in this embodiment, the apparatus D for controlling a raman spectrometer according to the present invention may further include a cleaning control unit 6. The cleaning control unit 6 is electrically connected to the human-machine interface unit 3.

In one embodiment, the cleaning control unit 6 may automatically transmit a cleaning control signal CCS to a cleaning unit disposed in the raman spectrometer after each start of the raman spectrometer, so that the cleaning unit cleans a detection space in the raman spectrometer. The cleaning unit may include an ultraviolet module, which is not limited in the present invention.

In an embodiment, the human-machine interface unit 3 may further include a fifth mode module, and the fifth mode module includes a fifth mode. As shown in fig. 11, in the fifth mode, after the carrier is moved away from the detection space of the raman spectrometer each time, the cleaning control unit 6 may transmit a fifth indication signal to the fifth mode module of the human-machine interface unit 3 according to the number of times of using a substrate carrying the object M to be detected, the number of times the carrier enters and exits the detection space of the raman spectrometer, or the time of the raman spectrometer in the continuously started state, and the fifth mode module of the human-machine interface unit 3 provides a fifth indication according to the fifth indication signal. For a user input corresponding to the fifth instruction, the fifth mode module of the human-machine interface unit 3 determines whether to transmit a fifth control signal CS5 to the cleaning control unit 6, so that the cleaning control unit 6 transmits the cleaning control signal CCS to the cleaning unit in the raman spectrometer to clean the detection space in the raman spectrometer.

However, the above examples are only one possible embodiment and are not intended to limit the present invention.

In addition, the first mode module, the second mode module, the third mode module, the fourth mode module and the fifth mode module may be software, firmware, hardware or a combination of software, firmware and hardware which can achieve the above functions.

Advantageous effects of the embodiment

The device for controlling the Raman spectrometer has the advantages that the device for controlling the Raman spectrometer can be used for acquiring the image information of an object to be detected through the image acquisition analysis unit, dividing the image information into a plurality of blocks, wherein each block is provided with corresponding block information, the processing unit compares the block information with a preset image information numerical range or threshold value to determine whether the corresponding block is provided with a first priority analysis grade, and the human-computer interface unit receives a user input for each block with the first priority analysis grade so as to record whether each block is provided with a second priority analysis grade.

The above disclosure is only a preferred embodiment of the present invention and is not intended to limit the claims of the present invention, so that all equivalent technical changes made by the application of the specification and the drawings of the present invention are included in the claims of the present invention.

Claims (8)

1. An apparatus for controlling a raman spectrometer, the apparatus for controlling a raman spectrometer comprising:

the image acquisition and analysis unit is used for acquiring image information of an object to be detected and dividing the image information into a plurality of blocks, wherein each block is provided with corresponding block information;

the processing unit is electrically connected with the image acquisition and analysis unit and is used for comparing one piece of block information with a preset image information numerical range or threshold value so as to determine whether the corresponding block has a first priority analysis grade or not;

the human-computer interface unit is electrically connected with the image acquisition analysis unit and the processing unit, and is used for respectively receiving a user input for each block with the first priority analysis level so as to record whether each block has the second priority analysis level; a kind of electronic device with high-pressure air-conditioning system

And the object carrying control unit is electrically connected with the human-computer interface unit, controls the position of the object to be detected aiming at the block with the second priority analysis grade, and enables the block with the second priority analysis grade to carry out Raman spectrum detection.

2. The apparatus for controlling a raman spectrometer according to claim 1, wherein the processing unit compares the block information with the predetermined image information numerical range or a threshold value to determine whether the corresponding block has the first priority analysis level, when the block information falls within the predetermined image information numerical range, the processing unit determines that the corresponding block has the first priority analysis level, and when the block information does not fall within the predetermined image information numerical range, the processing unit determines that the corresponding block does not have the first priority analysis level.

3. The apparatus for controlling a raman spectrometer according to claim 1, wherein the human-machine interface unit comprises a first mode module and a second mode module, the first mode module comprising a first mode; in the first mode, the first mode module provides a first indication to a user for each of the blocks having the first priority analysis level, and the first mode module automatically records whether each of the blocks has the second priority analysis level for user input corresponding to the first indication; the second mode module includes a second mode in which the second mode module provides a second indication to the user as to whether each of the blocks determined by the user has the first priority analysis level, and the second mode module correspondingly determines whether to record each of the blocks determined by the user as to whether each of the blocks has the second priority analysis level for a user input corresponding to the second indication.

4. The apparatus for controlling a raman spectrometer according to claim 3, wherein said apparatus for controlling a raman spectrometer further comprises:

and the laser measurement control unit is electrically connected with the man-machine interface unit and the object carrying control unit.

5. The apparatus for controlling a raman spectrometer according to claim 4, wherein the human-machine interface unit comprises a third mode module and a fourth mode module; the third mode module includes a third mode in which the third mode module provides a third instruction to the user for each of the blocks having the first priority analysis level, the third mode module automatically records whether each of the blocks has the second priority analysis level and transmits the block information having the second priority analysis level to the laser measurement control unit for user input corresponding to the third instruction, the laser measurement control unit analyzes to determine whether the block information having the second priority analysis level has a third priority analysis level and transmits the block information having the third priority analysis level to the third mode module, and the third mode module automatically records whether each of the blocks has the third priority analysis level correspondingly; the fourth mode module includes a fourth mode in which the fourth mode module transmits the tile information determined by each of the users to the laser measurement control unit, the laser measurement control unit analyzes whether the tile information determined to have the second priority analysis level has the third priority analysis level and transmits to the fourth mode module, the fourth mode module provides a fourth indication to the user as to whether each of the tiles determined by the users has the third priority analysis level, and the fourth mode module correspondingly records whether each of the tiles has the third priority analysis level for a user input corresponding to the fourth indication.

6. The apparatus for controlling a raman spectrometer according to any one of claims 1 to 5, wherein the apparatus for controlling a raman spectrometer further comprises:

and the cleaning control unit is electrically connected with the human-computer interface unit.

7. The apparatus for controlling a raman spectrometer according to claim 6, wherein said cleaning control unit performs an automatic control to clean a detection space within said raman spectrometer.

8. The apparatus according to claim 6, wherein the human-machine interface unit includes a fifth mode module including a fifth mode in which the fifth mode module provides a fifth indication to the user for a number of uses of a substrate carrying the object to be measured, a number of times a stage of the raman spectrometer enters and exits the detection space of the raman spectrometer, or a time for which the raman spectrometer is continuously activated, the fifth mode module correspondingly determining whether to clean the detection space of the raman spectrometer for a user input corresponding to the fifth indication.

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