CN114679688A - Management platform and management method for laboratory - Google Patents

Abstract

A management platform and a management method for a laboratory comprise: the system comprises a camera, a controller, a touch screen, a WIFI module and management equipment in a WLAN, wherein the camera, the controller, the touch screen and the WIFI module are arranged in a laboratory; the camera, the touch screen and the WIFI module are connected with the controller, and the controller is connected with the management equipment through the WIFI module; the defects that in the prior art, in the management of a laboratory, the laboratory instruments are randomly and disorderly applied by laboratory personnel, the application of the laboratory instruments cannot be uniformly and normatively managed, and the laboratory message transmission process cannot be operated during the laboratory message transmission period, so that the laboratory message transmission performance is poor are effectively overcome.

Description

Management platform and management method for laboratory

Technical Field

The invention relates to the technical field of laboratory management, in particular to a management platform and a management method for a laboratory.

Background

A Laboratory (Laboratory/Lab) is a place where an experiment is performed. The laboratory is a scientific cradle, is a base of scientific research and a source of scientific development, and plays a very important role in the scientific development. Laboratories can be classified into three categories according to affiliation: the first is a laboratory belonging to or hosted by a university; the second kind of laboratory belongs to national institutions, and some laboratories even belong to international institutions; the third kind of laboratories directly belongs to the industrial enterprise sector and serves the development and research of industrial technologies.

Regardless of the laboratory, the management of the laboratory often involves the laboratory instruments being used by the laboratory personnel, but such use is arbitrary and chaotic, and cannot provide a uniform and standardized management effect for the laboratory instruments.

In the management of a laboratory, many laboratory messages are often involved in the transfer, however, during the laboratory message transfer, no manipulation can be performed on the laboratory message transfer flow, so that the laboratory message transfer performance is poor.

Disclosure of Invention

In order to solve the problems, the invention provides a management platform and a management method for a laboratory, which effectively overcome the defects that in the prior art, in the management of the laboratory, the laboratory instruments are randomly and disorderly operated by laboratory personnel, the laboratory instruments cannot be uniformly and normatively operated by the laboratory personnel, the laboratory message transmission process cannot be operated during the transmission of the laboratory messages, and the transmission performance of the laboratory messages is poor.

To overcome the defects in the prior art, the invention provides a solution for a management platform and a method in a laboratory, which comprises the following steps:

a management platform for a laboratory, comprising:

the system comprises a camera, a controller, a touch screen, a WIFI module and management equipment in a WLAN, wherein the camera, the controller, the touch screen and the WIFI module are arranged in a laboratory;

the camera, the touch screen and the WIFI module are connected with the controller, and the controller is connected with the management equipment through the WIFI module;

the module running on the controller comprises a first transmission module and a second transmission module;

the transmission module I is used for packaging laboratory images and the serial numbers of the laboratories where the cameras are located to form laboratory image messages, and then transmitting the laboratory image messages to the management equipment for display;

the transmission module is used for transmitting a corresponding instruction to the management equipment;

the module running on the management equipment comprises a logging module, a receiving module, a grouping module, a selecting module, a transmitting module III and a reducing module;

the input module is used for storing the experimental personnel information input in advance on the management equipment;

the receiving module is used for transmitting the corresponding laboratory message to the controller and displaying the laboratory message on the touch screen after receiving the instruction;

the clustering module is used for obtaining the message attribute of each laboratory message to cluster the laboratory messages;

the selection module is used for selecting the number of the laboratory message transmission channels for transmitting the group according to the real number of the laboratory messages of each group;

the transfer module is used for determining the number of the laboratory message transfer channels for transferring the laboratory messages of the corresponding group according to the group of the laboratory messages and transferring the laboratory messages of the corresponding group;

the reduction module is configured to obtain a true transmission bandwidth of each laboratory messaging channel and to perform reduction on the transmitted laboratory messages selected according to the true transmission bandwidth of each laboratory messaging channel.

The reduction module is also used for instantly obtaining the real transmission bandwidth S of the laboratory message transmission channel, comparing the real transmission bandwidth S with the corresponding laboratory message transmission bandwidth SS which is set in advance, and determining whether to reduce the residual laboratory message according to the comparison value;

the preset laboratory message transmission bandwidth comprises a preset laboratory message transmission bandwidth I ST and a preset laboratory message transmission bandwidth II SU, and ST is lower than SU;

when S is lower than ST, the laboratory message transmission bandwidth of the laboratory message transmission channel is determined not to meet the specification, and reduction is carried out on the residual laboratory messages;

when ST is less than or equal to S and S is less than or equal to SU, the laboratory messaging bandwidth of the laboratory messaging channel is deemed to meet specifications and no reduction of residual laboratory messages is necessary;

and when the S is higher than the SU, determining that the laboratory message transmission bandwidth of the laboratory message transmission channel does not meet the specification, and changing the number of the laboratory messages transmitted by the laboratory message transmission channel.

The reduction module is also used for decomposing a single laboratory message into a plurality of message pieces by using the number of preset laboratory message bytes when the laboratory message transmission bandwidth of the laboratory message transmission channel is determined not to meet the specification and the reduction of the residual laboratory message is to be executed, executing the reduction of each message piece in sequence, comparing the real capacity H after the reduction of any laboratory message with the corresponding preset laboratory message capacity HI when the reduction is finished, and determining whether the number of the preset laboratory message bytes is corrected or not according to the comparison value;

when H is higher than HI, the single laboratory message reduction is determined to not meet the specification, and the number of preset laboratory message bytes is changed;

when H is lower than or equal to HI, the single laboratory message reduction is determined to meet the specification, and the reduction is performed on the residual undelivered laboratory messages by using the preset number of bytes of the laboratory messages.

The reduction module is further used for deducing a real laboratory message volume interval quantity LH when the laboratory message reduction is determined not to meet the specification and the number of preset laboratory message bytes is changed, setting LH = HI-H, correcting the number of the preset laboratory message bytes according to the real laboratory message volume interval quantity, expressing the corrected number of the preset laboratory message bytes by XX, setting XX = XY {1-LH/H }, and rounding the value of XY {1-LH/H } after decimal point as the value of XX when the value of XY {1-LH/H } is not a natural number, wherein XY is the number of the preset laboratory message bytes.

The reduction module is further configured to, when the number of the preset laboratory message bytes is to be corrected to XX, compare the corrected number XX of the preset laboratory message bytes with the lowest XA of the preset number XA of the laboratory message bytes, determine that the corrected number XX of the preset laboratory message bytes meets the specification when XX is higher than or equal to XA, and decompose the laboratory message by using the corrected number XX of the preset laboratory message bytes, determine that the corrected number XX of the preset laboratory message bytes cannot be used to decompose the laboratory message when XX is lower than XA, and decompose the laboratory message by using the preset number of the laboratory message bytes, and replace the laboratory message transmission channel.

The reduction module is also used for taking out the tail byte of any message slice when decomposing any laboratory message into a plurality of message slices by using the preset number of bytes of the laboratory message, comparing the tail byte with the index code byte, and determining whether to correct the number of bytes of the message slice according to the comparison value;

when the index code information has the tail byte, the number of bytes of the message piece to be changed is determined at first;

when the index code information does not have the tail byte, determining that the number of bytes of the message slice does not need to be changed;

when the tail bytes are to be compared with the last message piece, the tail bytes are replaced with the head bytes of the message piece.

The reduction module is further configured to, when it is determined that the laboratory message transmission bandwidth of the laboratory message transmission channel does not meet the specification and the number of laboratory messages transmitted by the laboratory message transmission channel is to be changed, represent the changed number of real laboratory messages by G, set G = { GH/Q } {1+ { S-SU }/SU }, and when the value of { GH/Q } {1+ { S-SU }/SU } is an unnatural number, round the value of { GH/Q } {1+ { S-SU }/SU } after a decimal point, as the value of G, where GH is the total number of laboratory messages of a group and Q is the number of transmission channels of the corresponding laboratory messages.

A method of managing a management platform for a laboratory, comprising:

step 1: the camera transmits the acquired laboratory image to the controller, the controller packages the laboratory image and the serial number of the laboratory where the camera is located to form a laboratory image message, and then the laboratory image message is transmitted to the management equipment to be displayed;

step 2: on the management equipment, the experimenter enters the experimenter information in advance and stores the experimenter information on the management equipment;

the experimenter messages comprise experimenter numbers, account names of experimenters, departments to which the experimenters belong and mobile phone numbers of the experimenters.

And 3, step 3: when laboratory experiment equipment is used by an experimenter, the account name of the experimenter and the mobile phone number of the experimenter are input on an input interface of the experimental equipment, and the experimental equipment information is displayed on the experimental equipment after the account name and the mobile phone number are checked to be correct;

the method for checking the errors comprises the following steps: if the experimental device finds that the account name and the mobile phone number of the experimenter in the stored experimenter message are respectively consistent with the entered account name and the mobile phone number of the experimenter, the result is correct.

And 4, step 4: the laboratory image information, the laboratory equipment information or the laboratory personnel information is laboratory information;

the experimental equipment information comprises an experimental equipment number, an experimental equipment name, an experimental equipment total number, an online or offline state of the experimental equipment, an online number of the experimental equipment, an offline number of the experimental equipment, a reserved time length of the experimental equipment, an average daily application time of the experimental equipment, an average time of each application of the experimental equipment and a real application time length of the experimental equipment.

And 5: when experimenters want to check the laboratory messages, the corresponding buttons for checking the laboratory messages are clicked on the interactive interface of the touch screen, signals of the clicked buttons are transmitted to the controller, the controller transmits corresponding instructions to the management equipment, and the management equipment receives the instructions and transmits the corresponding laboratory messages to the controller and displays the laboratory messages on the touch screen;

the method for the management device to transmit the corresponding laboratory message to the controller in the step 5 specifically includes:

step 5-1: obtaining the message attribute of each laboratory message to perform clustering on the laboratory messages;

step 5-2: selecting the number of the laboratory message transmission channels for transmitting the group according to the real number of the laboratory messages of each group;

step 5-3: determining the number of laboratory message transmission channels for transmitting the laboratory messages of the corresponding group according to the group of the laboratory messages, and transmitting the laboratory messages of the corresponding group;

step 5-4: the actual delivery bandwidth of each laboratory messaging channel is obtained and the delivered laboratory messages are reduced in accordance with the actual delivery bandwidth of each laboratory messaging channel.

In step 5-4, instantly obtaining a real transmission bandwidth S of the laboratory message transmission channel, comparing the real transmission bandwidth S with a corresponding laboratory message transmission bandwidth SS which is set in advance, and determining whether to reduce the residual laboratory message according to a comparison value;

the preset laboratory message transmission bandwidth comprises a preset laboratory message transmission bandwidth I ST and a preset laboratory message transmission bandwidth II SU, wherein ST is lower than SU;

when S is lower than ST, the laboratory message transmission bandwidth of the laboratory message transmission channel is determined not to meet the specification, and reduction is carried out on the residual laboratory messages;

when ST is less than or equal to S and S is less than or equal to SU, the laboratory messaging bandwidth of the laboratory messaging channel is deemed to meet specifications and no reduction of residual laboratory messages is necessary;

and when the S is higher than the SU, determining that the laboratory message transmission bandwidth of the laboratory message transmission channel does not meet the specification, and changing the number of the laboratory messages transmitted by the laboratory message transmission channel.

When the laboratory message transmission bandwidth of the laboratory message transmission channel is determined not to meet the specification and residual laboratory messages are to be reduced, decomposing a single laboratory message into a plurality of message pieces by using the number of preset laboratory message bytes, reducing each message piece in sequence, comparing the real capacity H of any one reduced laboratory message with the corresponding preset laboratory message capacity HI when the reduction is finished, and determining whether the number of the preset laboratory message bytes is corrected or not according to the comparison value;

when H is higher than HI, the single laboratory message reduction is determined not to meet the specification, and the number of preset laboratory message bytes is changed;

when H is lower than or equal to HI, the single laboratory message reduction is determined to meet the specification, and the reduction is performed on the residual undelivered laboratory messages by using the preset number of bytes of the laboratory messages.

When the laboratory message reduction is determined not to meet the specification and the number of preset laboratory message bytes is changed, deducing a real laboratory message volume interval quantity LH, setting LH = HI-H, correcting the number of the preset laboratory message bytes according to the real laboratory message volume interval quantity, expressing the corrected number of the preset laboratory message bytes by XX, setting XX = XY {1-LH/H }, and when the value of XY {1-LH/H } is not a natural number, rounding the value of XY {1-LH/H } after a decimal point to obtain a value serving as the value of XX, wherein XY is the number of the preset laboratory message bytes.

When the number of the preset laboratory message bytes is to be corrected to XX, comparing the corrected number XX of the preset laboratory message bytes with the lowest amount XA of the preset number XA of the laboratory message bytes, when XX is higher than or equal to XA, determining that the corrected number XX of the preset laboratory message bytes meets the standard, decomposing the laboratory message by using the corrected number XX of the preset laboratory message bytes, when XX is lower than XA, determining that the corrected number XX of the preset laboratory message bytes cannot be used for decomposing the laboratory message, decomposing the laboratory message by using the corrected number XX of the preset laboratory message bytes, and replacing the laboratory message transmission channel.

When any laboratory message is decomposed into a plurality of message pieces by using the preset number of bytes of the laboratory message, taking out the tail bytes of any message piece, comparing the tail bytes with the index code bytes, and determining whether the number of bytes of the message piece is corrected or not according to a comparison value;

when the index code information has the tail byte, the number of bytes of the message piece to be changed is initially determined;

when the index code information does not have the tail byte, determining that the number of bytes of the message slice does not need to be changed;

when the tail byte is to be compared with the last message piece, the tail byte is replaced with the head byte of the message piece.

When the laboratory message transmission bandwidth of the laboratory message transmission channel is determined not to meet the specification and the number of laboratory messages transmitted by the laboratory message transmission channel is to be changed, the changed real laboratory message transmission number is represented by G, G = { GH/Q } {1+ { S-SU }/SU } is set, and when the value of { GH/Q } {1+ { S-SU }/SU } is an unnatural number, the value of the small-point value of { GH/Q } {1+ { S-SU }/SU } is rounded up to the value of G, where GH is the total number of laboratory messages in a group and Q is the number of transmission channels of corresponding laboratory messages.

The invention has the beneficial effects that:

the camera transmits the acquired laboratory image to the controller, the controller packages the laboratory image and the serial number of the laboratory where the camera is located to form a laboratory image message, and then the laboratory image message is transmitted to the management equipment to be displayed; therefore, the real-time monitoring and management effect on the laboratory is achieved. On the management equipment, the experimenter enters the experimenter information in advance and stores the experimenter information on the management equipment; the experimenter messages comprise experimenter numbers, account names of experimenters, departments to which the experimenters belong and mobile phone numbers of the experimenters. The experimenter number is a unique identification code allocated to the experimenter, namely an index code of the experimenter message; when laboratory experiment equipment is used by an experimenter, the account name of the experimenter and the mobile phone number of the experimenter are input on an input interface of the experimental equipment, and the experimental equipment information is displayed on the experimental equipment after the account name and the mobile phone number are checked to be correct; the laboratory image information, the laboratory equipment information or the laboratory personnel information is laboratory information; when experimenters want to check the laboratory messages, the corresponding buttons for checking the laboratory messages are clicked on the interactive interface of the touch screen, signals of the clicked buttons are transmitted to the controller, the controller transmits corresponding instructions to the management equipment, and the management equipment receives the instructions and transmits the corresponding laboratory messages to the controller and displays the laboratory messages on the touch screen; therefore, in the management of a laboratory, the laboratory instruments can be orderly and orderly applied by laboratory personnel, and the application of the laboratory instruments can be uniformly and normally managed by people.

Preferably, when the reduction of the transmitted laboratory messages is performed according to the real transmission bandwidth selectivity of each laboratory message transmission channel, the corresponding preset laboratory message transmission bandwidth is selected by the group of the laboratory messages transmitted through each laboratory message transmission channel, the real transmission bandwidth of the laboratory message transmission channel and the corresponding preset laboratory message transmission bandwidth are compared, and the reduction of the remaining non-transmitted laboratory messages is performed according to the comparison value, so as to increase the real transmission bandwidth of the laboratory message transmission channel, the real transmission bandwidth of each laboratory message transmission channel can be efficiently known through the manipulation of the real transmission bandwidth of each laboratory message transmission channel through the instant comparison, and the corresponding number of the laboratory message transmission channels is selected according to the number of the laboratory messages of each group, the laboratory message transmission performance can be effectively guaranteed; and secondly, when the real transmission bandwidth of the laboratory message transmission channel does not meet the standard, the residual laboratory message which is not transmitted is reduced, the capacity of the laboratory message can be efficiently reduced, the laboratory message transmission bandwidth in one second is increased, the laboratory message transmission performance can be further ensured, and the laboratory message transmission bandwidth is efficiently increased.

Preferably, the present application defines the number of the preset laboratory message transmission channels as a pair, when the transmitted laboratory messages are reduced according to the real transmission bandwidth selectivity of each laboratory message transmission channel, the corresponding preset laboratory message transmission bandwidth is selected by the group of the laboratory messages transmitted through each laboratory message transmission channel, the real transmission bandwidth of the laboratory message transmission channel and the corresponding preset laboratory message transmission bandwidth are compared, and the remaining non-transmitted laboratory messages are reduced according to the comparison value selected to increase the real transmission bandwidth of the laboratory message transmission channel, through the instant comparison, the laboratory message transmission condition can be efficiently known through the manipulation of the real transmission bandwidth of each laboratory message transmission channel, and according to the number of the laboratory messages of each group, the number of the laboratory message transmission channels with the corresponding number is selected, the laboratory message transmission performance can be efficiently guaranteed, and the capacity of the laboratory message can be efficiently reduced by reducing the residual laboratory message which is not transmitted when the real transmission bandwidth of the laboratory message transmission channels does not meet the standard, so that the laboratory message transmission bandwidth in one second is increased, the laboratory message transmission performance can be further guaranteed, and the laboratory message transmission bandwidth is efficiently increased.

Preferably, when the laboratory message reduction is determined not to meet the specification and the number of the preset laboratory message bytes is changed, the number of the preset laboratory message bytes is reduced by performing the proofreading on the number of the preset laboratory message bytes to increase the number of the message pieces, the reduction performance can be enhanced by reducing the number of the preset laboratory message bytes, the reduced capacity of a message piece can be efficiently reduced, the reduced capacity of a single laboratory message can be efficiently reduced, the capacity of the residual undelivered laboratory message is reduced, the performance of transferring the laboratory message in one second is efficiently increased, and the transfer bandwidth of the laboratory message is efficiently increased.

Preferably, according to the method, by setting the minimum quantity of the byte number of the laboratory messages set in advance, when the message pieces are reduced, the residual laboratory messages which are not transmitted can be correctly reduced, and when the byte number of the laboratory messages set in advance is calibrated, the byte number of the laboratory messages set in advance after calibration can be accurately grasped, so that the problem that the byte number of the laboratory messages is too low due to the fact that the byte number of the laboratory messages set in advance is too high is solved, the decomposition of the laboratory messages can be accurately performed, and the transmission bandwidth of the laboratory messages is efficiently increased.

Preferably, when the decomposition is performed on a laboratory message, by comparing the tail byte of any message slice with the index code byte, when the index code byte is similar to the tail byte, the index code information in the laboratory message information is initially determined to be decomposed, and by changing the number of words of the message slice, the index code information in the laboratory message is ensured, so that the completeness of the index code of the laboratory message during the transmission can be ensured, the performance of laboratory message transmission is enhanced, and the laboratory message transmission bandwidth is efficiently increased.

Preferably, the present application selects a plurality of bytes towards the adjacent message pieces through the tail bytes of any message piece, and selects a plurality of bytes to ensure that the index code information in any message piece is not decomposed, so as to ensure the completeness of the index code of the laboratory message during the delivery, improve the performance of the laboratory message delivery, and efficiently increase the delivery bandwidth of the laboratory message.

Preferably, in the method, b bytes are selected from adjacent message pieces through tail bytes of any message piece, and c bytes are selected from the message pieces located by the user synchronously, so that the index code information in any message piece is not decomposed, and synchronously, b + c is the number of bytes of the index code byte information, so that each message piece is accurately decomposed, the completeness of the index code of the laboratory message during the transmission period can be guaranteed, the laboratory message transmission performance is improved, and the laboratory message transmission bandwidth is efficiently increased.

The defects that in the prior art, in the management of a laboratory, the laboratory instruments are randomly and disorderly applied by laboratory personnel, the application of the laboratory instruments cannot be uniformly and normatively managed, and the laboratory message transmission process cannot be operated during the laboratory message transmission period, so that the laboratory message transmission performance is poor are effectively overcome.

Drawings

FIG. 1 is a block diagram of the modules of the present invention operating on a controller.

Fig. 2 is a block diagram of modules of the present invention that run on a management device.

Fig. 3 is a flow chart of steps 1 through 5 of the present invention.

FIG. 4 is a flow chart of step 5-1 through step 5-4 of the present invention.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings and examples.

A management platform for a laboratory comprising:

the system comprises a camera, a controller, a touch screen, a WIFI module and management equipment in a WLAN, wherein the camera, the controller, the touch screen and the WIFI module are arranged in a laboratory; the controller can be a single chip microcomputer or an ARM chip, and the management equipment can be a notebook computer, a PDA or a smart phone.

The camera, the touch screen and the WIFI module are connected with the controller, and the controller is connected with the management equipment through the WIFI module;

as shown in fig. 1, the modules running on the controller include a first transfer module and a second transfer module;

the transmission module I is used for packaging laboratory images and the serial numbers of the laboratories where the cameras are located to form laboratory image messages, and then transmitting the laboratory image messages to the management equipment for display;

the transmission module is used for transmitting a corresponding instruction to the management equipment;

as shown in fig. 2, the modules running on the management device include a logging module, a receiving module, a grouping module, a selecting module, a transmitting module iii and a reducing module;

the input module is used for storing the experimental personnel information input in advance on the management equipment;

the receiving module is used for transmitting the corresponding laboratory message to the controller and displaying the laboratory message on the touch screen after receiving the instruction;

the clustering module is used for obtaining the message attribute of each laboratory message to cluster the laboratory messages;

the selection module is used for selecting the number of the laboratory message transmission channels for transmitting the group according to the real number of the laboratory messages of each group;

the transfer module is used for determining the number of the laboratory message transfer channels for transferring the laboratory messages of the corresponding group according to the group of the laboratory messages and transferring the laboratory messages of the corresponding group;

the reduction module is used for obtaining the real transmission bandwidth of each laboratory message transmission channel and executing reduction on the transmitted laboratory messages according to the real transmission bandwidth of each laboratory message transmission channel.

The reduction module is also used for instantly obtaining the real transmission bandwidth S of the laboratory message transmission channel, comparing the real transmission bandwidth S with the corresponding laboratory message transmission bandwidth SS which is set in advance, and determining whether to reduce the residual laboratory message according to the comparison value;

the preset laboratory message transmission bandwidth comprises a preset laboratory message transmission bandwidth I ST and a preset laboratory message transmission bandwidth II SU, and the ST is lower than the SU;

when S is lower than ST, the laboratory message transmission bandwidth of the laboratory message transmission channel is determined not to meet the specification, and reduction is carried out on the residual laboratory messages;

when ST is less than or equal to S and S is less than or equal to SU, the laboratory messaging bandwidth of the laboratory messaging channel is deemed to meet specifications and no reduction of residual laboratory messages is necessary;

and when the S is higher than the SU, determining that the laboratory message transmission bandwidth of the laboratory message transmission channel does not meet the specification, and changing the number of the laboratory messages transmitted by the laboratory message transmission channel.

The reduction module is also used for decomposing a single laboratory message into a plurality of message pieces by using the number of preset laboratory message bytes when the laboratory message transmission bandwidth of the laboratory message transmission channel is determined not to meet the specification and the reduction of the residual laboratory message is to be executed, executing the reduction of each message piece in sequence, comparing the real capacity H after the reduction of any laboratory message with the corresponding preset laboratory message capacity HI when the reduction is finished, and determining whether the number of the preset laboratory message bytes is corrected or not according to the comparison value;

when H is higher than HI, the single laboratory message reduction is determined to not meet the specification, and the number of preset laboratory message bytes is changed;

when H is lower than or equal to HI, the single laboratory message reduction is deemed to meet the specification and the reduction is performed on the remaining undelivered laboratory messages using the preset number of bytes of laboratory messages.

The reduction module is further used for deducing a real laboratory message volume interval quantity LH when the laboratory message reduction is determined not to meet the specification and the number of preset laboratory message bytes is changed, setting LH = HI-H, correcting the number of the preset laboratory message bytes according to the real laboratory message volume interval quantity, expressing the corrected number of the preset laboratory message bytes by XX, setting XX = XY {1-LH/H }, and rounding the value of XY {1-LH/H } after decimal point as the value of XX when the value of XY {1-LH/H } is not a natural number, wherein XY is the number of the preset laboratory message bytes.

The reduction module is further configured to, when the number of the preset laboratory message bytes is to be corrected to XX, compare the corrected number XX of the preset laboratory message bytes with the lowest XA of the preset number XA of the laboratory message bytes, determine that the corrected number XX of the preset laboratory message bytes meets the specification when XX is higher than or equal to XA, and decompose the laboratory message by using the corrected number XX of the preset laboratory message bytes, determine that the corrected number XX of the preset laboratory message bytes cannot be used to decompose the laboratory message when XX is lower than XA, and decompose the laboratory message by using the preset number of the laboratory message bytes, and replace the laboratory message transmission channel.

The reduction module is also used for taking out the tail byte of any message slice when decomposing any laboratory message into a plurality of message slices by using the preset number of bytes of the laboratory message, comparing the tail byte with the index code byte, and determining whether to correct the number of bytes of the message slice according to the comparison value;

when the index code information has the tail byte, the number of bytes of the message piece to be changed is initially determined;

when the index code information does not have the tail byte, determining that the number of bytes of the message slice does not need to be changed;

when the tail byte is to be compared with the last message piece, the tail byte is replaced with the head byte of the message piece.

The reduction module is further configured to, when it is determined that the laboratory message transmission bandwidth of the laboratory message transmission channel does not meet the specification and the number of laboratory messages transmitted by the laboratory message transmission channel is to be changed, represent the changed number of real laboratory messages by G, set G = { GH/Q } {1+ { S-SU }/SU }, and when the value of { GH/Q } {1+ { S-SU }/SU } is an unnatural number, round the value of { GH/Q } {1+ { S-SU }/SU } after a decimal point, as the value of G, where GH is the total number of laboratory messages of a group and Q is the number of transmission channels of the corresponding laboratory messages.

A method of managing a management platform for a laboratory, comprising:

as shown in fig. 3, step 1: the camera transmits the acquired laboratory image to the controller, the controller packages the laboratory image and the serial number of the laboratory where the camera is located to form a laboratory image message, and then the laboratory image message is transmitted to the management equipment to be displayed; therefore, the real-time monitoring and management effect on the laboratory is achieved. The laboratory number is a unique identification code assigned to the laboratory, i.e., an index code for the laboratory image message.

Step 2: on the management equipment, the experimenter enters the experimenter information in advance and stores the experimenter information on the management equipment;

the experimenter messages comprise experimenters, account names of experimenters, departments to which the experimenters belong and mobile phone numbers of the experimenters. The experimenter number is a unique identification code allocated to the experimenter, namely an index code of the experimenter message.

And step 3: when laboratory experiment equipment is used by an experimenter, the account name of the experimenter and the mobile phone number of the experimenter are input on an input interface of the experimental equipment, and the experimental equipment information is displayed on the experimental equipment after the account name and the mobile phone number are checked to be correct;

the method for checking the errors comprises the following steps: if the experimental device finds that the account name and the mobile phone number of the experimenter in the stored experimenter message are respectively consistent with the entered account name and the mobile phone number of the experimenter, the result is correct.

And 4, step 4: the laboratory image information, the laboratory equipment information or the laboratory personnel information is laboratory information;

the experimental equipment information comprises an experimental equipment number, an experimental equipment name, an experimental equipment total number, an online or offline state of the experimental equipment, an existing online number of the experimental equipment, an existing offline number of the experimental equipment, a reserving time length of the experimental equipment, an average daily operating time of the experimental equipment, an average time usage of the experimental equipment and a real operating time length of the experimental equipment. The experiment equipment number is a unique identification code provided for the experiment equipment, namely an index code of the experiment equipment message. The total number of the experimental equipment is the total number of all experimental equipment in a laboratory; the current online number of the experimental equipment is that when the state of the experimental equipment which is selected to be taken out and is not online is refreshed to be online, the current online number of the experimental equipment with the initial quantity of zero is increased by one, the current offline number of the experimental equipment is increased by one, the online state is the state of the experimental equipment, the state of the experimental equipment is not online, the state of the experimental equipment is not used, the reserving times of the experimental equipment is in the state that the experimental equipment is used, the reserving times of the experimental equipment are reserved for the experimental equipment, the reserving duration of the experimental equipment is the reserving duration of the experimental equipment in the state that the experimental equipment is used, the average daily using times of the experimental equipment is the total number of times when the daily state of the experimental equipment is refreshed to be online divided by the number of the experimental equipment, the average each time of the experimental equipment is the daily using time of the experimental equipment, each time of the experimental equipment is accumulated and divided by the number of the experimental equipment, the time spent each time of the experimental equipment is the real application time of the experimental equipment, the real application time of the experimental equipment is the time spent between the time spent by the experimental equipment from the application of the experimental equipment to the time spent on returning the experimental equipment after the application is finished, the current online number of the experimental equipment is reduced by one when the experimental equipment is returned after the application is finished, and the current offline number of the experimental equipment is increased by one.

And 5: when experimenters want to check the laboratory messages, the corresponding buttons for checking the laboratory messages are clicked on the interactive interface of the touch screen, signals of the clicked buttons are transmitted to the controller, the controller transmits corresponding instructions to the management equipment, and the management equipment receives the instructions and transmits the corresponding laboratory messages to the controller and displays the laboratory messages on the touch screen;

in detail, the step 5 includes: when laboratory information such as laboratory image information, laboratory equipment information or laboratory personnel information is checked by a laboratory worker, clicking a corresponding button marked with a character of the laboratory image information, a character of the laboratory equipment information or a character of the laboratory personnel information on an interactive interface of a touch screen, transmitting a signal of the clicked button to a controller, transmitting a corresponding instruction for checking the laboratory image information, the instruction for checking the laboratory equipment information or the instruction for checking the laboratory personnel information to a management device by the controller, and transmitting the laboratory information such as the laboratory image information, the laboratory equipment information or the laboratory personnel information stored correspondingly to the controller and displaying the laboratory information on the touch screen by the management device after receiving the instruction;

as shown in fig. 4, the method for the management device to transmit the corresponding laboratory message to the controller in step 5 specifically includes:

step 5-1: obtaining the message attribute of each laboratory message to perform clustering on the laboratory messages;

in detail, the present application performs clustering on laboratory messages by obtaining message attributes, where the message attributes include index codes, byte amounts of the laboratory messages, or collective structures of the laboratory message bytes, preferably, within the present application, clustering is performed on each laboratory message by extracting the index code in each laboratory message in sequence, as, the index code '246' as the number of the laboratory is the group one or the index code '135' as the number of the laboratory is the group two or the index code '789' as the number of the laboratory is the group three, by obtaining the index code in each laboratory message, the group of each laboratory message is divided into a group one, a group two and a group three, on the other hand, the index code can be set according to the real requirement, and only the purpose of performing the group cutting on the laboratory message can be achieved.

Step 5-2: selecting the number of the laboratory message transmission channels for transmitting the group according to the real number of the laboratory messages of each group;

in detail, in the present application, the number of the corresponding laboratory message transmission channels for transmitting the group of the laboratory messages is selected according to the total number of the laboratory messages of the group of the laboratory messages, and the number of the laboratory message transmission channels can be accurately selected according to the actual number of the laboratory messages of the group, so as to ensure the transmission performance during the transmission of the laboratory messages.

Step 5-3: determining the number of laboratory message transmission channels for transmitting the laboratory messages of the corresponding group according to the group of the laboratory messages, and transmitting the laboratory messages of the corresponding group;

step 5-4: the actual delivery bandwidth of each laboratory messaging channel is obtained and the delivered laboratory messages are reduced in accordance with the actual delivery bandwidth of each laboratory messaging channel. The method of reduction can be the RLE algorithm.

In step 5-4, the real transmission bandwidth of each laboratory message transmission channel is obtained immediately, the real transmission bandwidth is compared with the preset laboratory message transmission bandwidth, if the real transmission bandwidth is lower than the preset laboratory message transmission bandwidth, the residual laboratory messages which are not transmitted are determined to be reduced, if the real transmission bandwidth is determined to be in the preset laboratory message transmission bandwidth interval, the residual laboratory messages which are not transmitted are determined not to be reduced, and if the real transmission bandwidth is determined to be higher than the preset laboratory message transmission bandwidth, the transmitted laboratory message number of the laboratory message channel is determined to be changed.

In detail, when the present application performs reduction of transmitted laboratory messages according to the real transmission bandwidth selectivity of each laboratory message transmission channel, the group of laboratory messages transmitted through each laboratory message transmission channel selects a corresponding preset laboratory message transmission bandwidth, when the group of laboratory messages transmitted through the laboratory message transmission channel is a group, the corresponding preset laboratory message transmission bandwidth is a preset laboratory message transmission bandwidth one, and when the laboratory messages are transmitted through each laboratory message transmission channel, the real transmission bandwidth of each laboratory message transmission is instantly obtained, the real transmission bandwidth of each laboratory message transmission channel and the corresponding preset laboratory message transmission bandwidth are compared, in detail, when the group of laboratory messages transmitted through the laboratory message transmission channel is a group one, comparing the real transmission bandwidth of the laboratory messaging channel with the corresponding laboratory messaging bandwidth set in advance, and the like, and performing reduction on the residual laboratory messages which are not transmitted according to the comparison value selected to increase the real transmission bandwidth of the laboratory messaging channel.

That is, when the present application performs reduction on the transmitted laboratory messages according to the real transmission bandwidth selectivity of each laboratory message transmission channel, the corresponding preset laboratory message transmission bandwidth is selected by the group of the laboratory messages transmitted through each laboratory message transmission channel, the real transmission bandwidth of the laboratory message transmission channel and the corresponding preset laboratory message transmission bandwidth are compared, and reduction is performed on the remaining non-transmitted laboratory messages according to the comparison value, so as to increase the real transmission bandwidth of the laboratory message transmission channel, the real transmission bandwidth of each laboratory message transmission channel can be efficiently known through manipulation of the real transmission bandwidth of each laboratory message transmission channel through instant comparison, and the corresponding number of the laboratory message transmission channels is selected according to the number of the laboratory messages of each group, the laboratory message transmission performance can be effectively guaranteed; and secondly, when the real transmission bandwidth of the laboratory message transmission channel does not meet the standard, the residual non-transmitted laboratory messages are reduced, so that the capacity of the laboratory messages can be efficiently reduced, the laboratory message transmission bandwidth in one second is increased, the laboratory message transmission performance can be further ensured, and the laboratory message transmission bandwidth is efficiently increased.

That is, in step 5-4, a real transmission bandwidth S of the laboratory message transmission channel is obtained immediately, the real transmission bandwidth S is compared with a corresponding laboratory message transmission bandwidth SS set in advance, and it is determined whether to perform reduction on the residual laboratory message according to the comparison value;

the preset laboratory message transmission bandwidth comprises a preset laboratory message transmission bandwidth I ST and a preset laboratory message transmission bandwidth II SU, wherein ST is lower than SU;

when S is lower than ST, the laboratory message transmission bandwidth of the laboratory message transmission channel is determined not to meet the specification, and reduction is carried out on the residual laboratory messages;

when ST is less than or equal to S and S is less than or equal to SU, the laboratory messaging bandwidth of the laboratory messaging channel is deemed to meet specifications and no reduction of residual laboratory messages is necessary;

and when the S is higher than the SU, determining that the laboratory message transmission bandwidth of the laboratory message transmission channel does not meet the specification, and changing the number of the laboratory messages transmitted by the laboratory message transmission channel.

That is, the present application defines the number of the preset laboratory message transmission channels as a pair, when the transmitted laboratory messages are reduced according to the real transmission bandwidth selectivity of each laboratory message transmission channel, the corresponding preset laboratory message transmission bandwidth is selected by the group of the laboratory messages transmitted through each laboratory message transmission channel, the real transmission bandwidth of the laboratory message transmission channel and the corresponding preset laboratory message transmission bandwidth are compared, and the remaining non-transmitted laboratory messages are reduced according to the comparison value selected to increase the real transmission bandwidth of the laboratory message transmission channel, through the instant comparison, the laboratory message transmission condition can be efficiently known through the manipulation of the real transmission bandwidth of each laboratory message transmission channel, and according to the number of the laboratory messages of each group, the number of the laboratory message transmission channels with the corresponding number is selected, the laboratory message transmission performance can be efficiently guaranteed, and the capacity of the laboratory message can be efficiently reduced by reducing the residual laboratory message which is not transmitted when the real transmission bandwidth of the laboratory message transmission channels does not meet the standard, so that the laboratory message transmission bandwidth in one second is increased, the laboratory message transmission performance can be further guaranteed, and the laboratory message transmission bandwidth is efficiently increased.

That is, when it is determined that the laboratory message transmission bandwidth of the laboratory message transmission channel does not meet the specification and reduction is to be performed on the residual laboratory messages, a single laboratory message is decomposed into a plurality of message pieces by using the number of the laboratory message bytes set in advance, reduction is performed on each message piece in sequence, when the reduction is completed, the real capacity H of any one of the laboratory messages after the reduction is compared with the corresponding laboratory message capacity HI set in advance, and it is determined whether to correct the number of the laboratory message bytes set in advance according to the comparison value;

when H is higher than HI, the single laboratory message reduction is determined not to meet the specification, and the number of preset laboratory message bytes is changed;

when H is lower than or equal to HI, the single laboratory message reduction is determined to meet the specification, and the reduction is performed on the residual undelivered laboratory messages by using the preset number of bytes of the laboratory messages.

In detail, when the present application performs reduction on a single laboratory message, a laboratory message is decomposed into a plurality of message pieces by using the number of previously set laboratory message bytes, where the number of previously set laboratory message bytes can be three, five or six, and preferably, in the present application, the number of previously set bytes is set to five, and when the number of bytes in a laboratory message in the remaining undelivered laboratory message is twenty-three, the laboratory message is cut into five message pieces, and reduction is performed on each message piece, respectively, to achieve reduction on any one laboratory message, thereby reducing the capacity of a laboratory message, and when the number of previously set bytes is selected, selection can be performed according to the group of real laboratory messages; in detail, the laboratory message size set in advance here is selected depending on the number of bytes of the real laboratory message, as if the laboratory message size set in advance can be set to 2 when the number of real bytes of a laboratory message is twenty¹⁰A bit, and when the number of actual bytes of a single laboratory message is thirty, the preset laboratory message capacity can be set to (3/2) × 2¹⁰The bit can also select the corresponding preset laboratory message capacity according to the real condition of the laboratory message.

That is, when it is determined that the reduction of the laboratory message does not satisfy the specification and the number of the laboratory message bytes set in advance is to be changed, the actual laboratory message volume interval amount LH is derived, LH = HI-H is set, the number of the laboratory message bytes set in advance is corrected based on the actual laboratory message volume interval amount, the corrected number of the laboratory message bytes set in advance is represented by XX, XX = XY {1-LH/H } is set, and when the value of XY {1-LH/H } is not a natural number, the value obtained by rounding off the value of XY {1-LH/H } after the decimal point is taken as the value of XX, where XY is the number of the laboratory message bytes set in advance.

That is, when the present application determines that the laboratory message reduction does not meet the specification and the number of the preset laboratory message bytes is to be changed, the number of the preset laboratory message bytes is reduced by performing the proofreading on the number of the preset laboratory message bytes to increase the number of the message pieces, and the number of the preset laboratory message bytes is reduced to enhance the reduction performance, thereby efficiently reducing the reduced capacity of a message piece, and thus efficiently reducing the reduced capacity of a single laboratory message, and thus reducing the capacity of the remaining undelivered laboratory message, thereby efficiently increasing the performance of transferring the laboratory message in one second, and efficiently increasing the laboratory message transfer bandwidth.

That is, when the number of previously set laboratory message bytes is to be collated to XX, the collated number XX of previously set laboratory message bytes and the lowest number XA of previously set laboratory message bytes are collated, when XX is higher than or equal to XA, the collated number XX of previously set laboratory message bytes is determined to satisfy the specification and the laboratory message is decomposed by the collated number XX of previously set laboratory message bytes, when XX is lower than XA, it is determined that the laboratory message cannot be decomposed by the collated number XX of previously set laboratory message bytes and the laboratory message is decomposed by the previously set number of laboratory message bytes and the laboratory message is replaced with the laboratory message transmission channel.

That is to say, the present application sets the minimum number of bytes of the laboratory message set in advance, when the message slice is reduced, the reduction can be executed by using the correct residual laboratory message which is not transmitted, and when the byte number of the laboratory message set in advance is calibrated, the byte number of the laboratory message set in advance after calibration can be accurately grasped, so that the problem that the byte number of the laboratory message set in advance is too low and the decomposition number of the laboratory message is too high is solved, thereby the decomposition of the laboratory message can be accurately executed, and the transmission bandwidth of the laboratory message can be efficiently increased.

That is, when any laboratory message is decomposed into a plurality of message pieces by using the previously set number of bytes of the laboratory message, the tail byte of any message piece is taken out, the tail byte is compared with the index code byte, and it is determined whether the number of bytes of the message piece is corrected or not according to the comparison value;

when the index code information has the tail byte, the number of bytes of the message piece to be changed is initially determined;

when the index code information does not have the tail byte, determining that the number of bytes of the message slice does not need to be changed;

here, when the tail byte is to be compared with the last message piece, the tail byte is replaced with the head byte of the message piece.

That is, when the present application decomposes a laboratory message, by comparing the tail byte of any message piece with the index code byte, when the index code byte is similar to the tail byte, the index code information in the laboratory message information is initially determined to be decomposed, and by varying the number of words of the message piece, the index code information in the laboratory message is secured, so that the completeness of the index code during the transfer of the laboratory message can be secured, the performance of the laboratory message transfer can be enhanced, and the laboratory message transfer bandwidth can be efficiently increased.

That is, when the index code information has the tail byte and the number of bytes of the message piece is initially determined to be changed, V bytes are selected from the tail first byte of any message piece toward the adjacent message piece, the V bytes are compared with the canonical index code byte, if the similarity between the V bytes and the canonical index code byte is higher than or equal to eighty-five percent, the number of bytes of any message piece is determined to be increased, where the increased number of bytes is V, and if the similarity between the V bytes and the canonical index code byte is lower than eighty-five percent, the message piece is determined to have no index code and the number of bytes of the message piece does not need to be changed;

selecting V bytes from the second byte at the tail of any message chip to the adjacent message chip, comparing the V bytes with the standard index code byte, if the similarity between the V bytes and the standard index code byte is more than or equal to eighty-five percent, determining that the number of bytes of any message chip is increased, wherein the number of the increased bytes is V-1, and if the similarity between the V bytes and the standard index code byte is less than eighty-five percent, determining that the message chip does not have an index code, and not changing the number of bytes of the message chip;

selecting V bytes from the O-th byte at the tail of any message slice towards the adjacent message slice, comparing the V bytes with the standard index code byte, if the similarity between the V bytes and the standard index code byte is more than or equal to eighty-five percent, determining that the number of bytes of any message slice is increased, wherein the increased number of bytes is V-O, if the similarity between the V bytes and the standard index code byte is less than eighty-five percent, determining that no index code exists in the message slice, and not changing the number of bytes of the message slice, wherein O is less than V, and V is less than or equal to the number of bytes which are set in advance.

That is, the present application selects a plurality of bytes towards the adjacent message pieces through the tail bytes of any message piece, and selects a plurality of bytes to ensure that the index code information in any message piece is not decomposed, so as to ensure the completeness of the index code during the transfer of the laboratory message, improve the performance of the laboratory message transfer, and efficiently increase the laboratory message transfer bandwidth.

That is, when the index code information has the tail byte and the number of bytes of the message piece is preliminarily determined to be changed, selecting b bytes from the head byte of the tail of any message chip to the adjacent message chip, selecting c bytes from the message chip where the user is located, comparing the byte formed by b + c with the standard index code byte, if the similarity of the V bytes to the canonical index code byte is greater than or equal to eighty-five percent, it is assumed that the number of bytes of any of the message pieces is to be added, where the number of added bytes is V, if the similarity between V bytes and the byte of the standard index code is less than eighty five percent, the message is determined to have no index code, and b + c = F-1 is set without changing the number of bytes of the message piece, where F denotes the number of bytes of the index code information.

That is, b bytes are selected from adjacent message pieces through tail bytes of any message piece, and c bytes are selected from the message pieces located by the user synchronously, so that the index code information in any message piece is not decomposed, and synchronously, b + c is the number of bytes of the index code byte information, so that each message piece is accurately decomposed, the completeness of the index code of the laboratory message during the transmission period can be guaranteed, the laboratory message transmission performance is improved, and the laboratory message transmission bandwidth is efficiently increased; in detail, in the present application, when the number of bytes of the index code information is five, any message piece except the tail message piece is selected, and a byte is selected from the tail byte of the message piece toward the adjacent message piece, synchronously, three bytes are selected toward the message piece where the user is located, or two bytes are selected toward the adjacent message piece, synchronously, two bytes are selected toward the message piece where the user is located, or three bytes are selected toward the adjacent message piece, and synchronously, one byte is selected toward the message piece where the user is located.

That is, when it is determined that the laboratory message transmission bandwidth of the laboratory message transmission channel does not meet the specification and the number of laboratory messages transmitted by the laboratory message transmission channel is to be changed, the changed number of real laboratory messages is represented by G, and G = { GH/Q } {1+ { S-SU }/SU }, and when the value of { GH/Q } {1+ { S-SU }/SU } is an unnatural number, the value obtained by rounding up the value of { GH/Q } {1+ { S-SU }/SU } after a decimal point is taken as the value of G, where GH is the total number of laboratory messages of a group and Q is the number of transmission channels of the corresponding laboratory message.

The present invention has been described above by way of examples, and it will be apparent to those skilled in the art that the present disclosure is not limited to the above-described examples, and various changes, modifications and alterations can be made without departing from the scope of the present invention.

Claims (10)

1. A management platform for a laboratory, comprising:

the system comprises a camera, a controller, a touch screen, a WIFI module and management equipment in a WLAN, wherein the camera, the controller, the touch screen and the WIFI module are arranged in a laboratory;

the camera, the touch screen and the WIFI module are connected with the controller, and the controller is connected with the management equipment through the WIFI module;

the module running on the controller comprises a first transmission module and a second transmission module;

the transmission module I is used for packaging laboratory images and the serial numbers of the laboratories where the cameras are located to form laboratory image messages, and then transmitting the laboratory image messages to the management equipment for display;

the transmission module is used for transmitting a corresponding instruction to the management equipment;

the module running on the management equipment comprises a logging module, a receiving module, a grouping module, a selecting module, a transmitting module III and a reducing module;

the input module is used for storing the experimental personnel information input in advance on the management equipment;

the receiving module is used for transmitting the corresponding laboratory message to the controller and displaying the laboratory message on the touch screen after receiving the instruction;

the clustering module is used for obtaining the message attribute of each laboratory message to cluster the laboratory messages;

the selection module is used for selecting the number of the laboratory message transmission channels for transmitting the group according to the real number of the laboratory messages of each group;

the transfer module is used for determining the number of the laboratory message transfer channels for transferring the laboratory messages of the corresponding group according to the group of the laboratory messages and transferring the laboratory messages of the corresponding group;

the reduction module is used for obtaining the real transmission bandwidth of each laboratory message transmission channel and reducing the transmitted laboratory messages according to the real transmission bandwidth of each laboratory message transmission channel;

the reduction module is also used for instantly obtaining a real transmission bandwidth S of the laboratory message transmission channel, comparing the real transmission bandwidth S with a corresponding laboratory message transmission bandwidth SS which is set in advance, and determining whether to reduce the residual laboratory message according to a comparison value;

the preset laboratory message transmission bandwidth comprises a preset laboratory message transmission bandwidth I ST and a preset laboratory message transmission bandwidth II SU, and ST is lower than SU;

when S is lower than ST, the laboratory message transmission bandwidth of the laboratory message transmission channel is determined not to meet the specification, and reduction is carried out on the residual laboratory messages;

when ST is less than or equal to S and S is less than or equal to SU, the laboratory messaging bandwidth of the laboratory messaging channel is deemed to meet specifications and no reduction of residual laboratory messages is necessary;

and when the S is higher than the SU, determining that the laboratory message transmission bandwidth of the laboratory message transmission channel does not meet the specification, and changing the number of the laboratory messages transmitted by the laboratory message transmission channel.

2. The management platform for laboratories as claimed in claim 1, wherein said reduction module is further configured to, when it is determined that the laboratory messaging bandwidth of the laboratory messaging channel does not meet the specification and reduction is to be performed on the residual laboratory messages, decompose a single laboratory message into a plurality of message pieces by using the number of bytes of the laboratory message set in advance, perform reduction on each message piece in sequence, compare the real capacity H of any one of the laboratory messages after reduction with the corresponding laboratory message capacity HI set in advance when reduction is completed, and determine whether to correct the number of bytes of the laboratory message set in advance according to the comparison value;

when H is higher than HI, the single laboratory message reduction is determined to not meet the specification, and the number of preset laboratory message bytes is changed;

when H is lower than or equal to HI, the single laboratory message reduction is determined to meet the specification, and the reduction is performed on the residual undelivered laboratory messages by using the preset number of bytes of the laboratory messages.

3. The management platform for laboratories according to claim 1, wherein said reduction module is further configured to derive a real laboratory message volume interval LH, set LH = HI-H, and correct the number of the laboratory message bytes set in advance according to the real laboratory message volume interval LH, when it is determined that the laboratory message reduction does not satisfy the specification and the number of the laboratory message bytes set in advance is to be changed, set XX = XY {1-LH/H }, where the corrected number of the laboratory message bytes set in advance is represented by XX, and set XX = XY {1-LH/H }, and when the value of XY {1-LH/H } is not a natural number, rounding the value of XY {1-LH/H } after a decimal point as the value of XX, where XY is the number of the laboratory message bytes set in advance;

the reduction module is further configured to, when the number of the preset laboratory message bytes is to be corrected to XX, compare the corrected number XX of the preset laboratory message bytes with the lowest XA of the preset number XA of the laboratory message bytes, determine that the corrected number XX of the preset laboratory message bytes meets the specification when XX is higher than or equal to XA, and decompose the laboratory message by using the corrected number XX of the preset laboratory message bytes, determine that the corrected number XX of the preset laboratory message bytes cannot be used to decompose the laboratory message when XX is lower than XA, and decompose the laboratory message by using the preset number of the laboratory message bytes, and replace the laboratory message transmission channel.

4. The management platform for the laboratory, according to claim 1, wherein said reduction module is further configured to, when any laboratory message is decomposed into a plurality of message pieces by using the number of bytes of the laboratory message set in advance, extract the tail bytes of any message piece, perform comparison between the tail bytes and the index code bytes, and determine whether to correct the number of bytes of the message piece according to the comparison value;

when the index code information has the tail byte, the number of bytes of the message piece to be changed is initially determined;

when the index code information does not have the tail byte, determining that the number of bytes of the message slice does not need to be changed;

when the tail bytes are to be compared with the last message piece, replacing the tail bytes with the head bytes of the message piece;

the reduction module is further configured to, when it is determined that the laboratory message transmission bandwidth of the laboratory message transmission channel does not meet the specification and the number of laboratory messages transmitted by the laboratory message transmission channel is to be changed, represent the changed number of real laboratory messages by G, set G = { GH/Q } {1+ { S-SU }/SU }, and when the value of { GH/Q } {1+ { S-SU }/SU } is an unnatural number, round the value of { GH/Q } {1+ { S-SU }/SU } after a decimal point, as the value of G, where GH is the total number of laboratory messages of a group and Q is the number of transmission channels of the corresponding laboratory messages.

5. A method of managing a management platform for a laboratory, comprising:

step 1: the camera transmits the acquired laboratory image to the controller, the controller packages the laboratory image and the serial number of the laboratory where the camera is located to form a laboratory image message, and then the laboratory image message is transmitted to the management equipment to be displayed;

and 2, step: on the management equipment, the experimenter enters the experimenter information in advance and stores the experimenter information on the management equipment;

and step 3: when laboratory experiment equipment is used by an experimenter, the account name of the experimenter and the mobile phone number of the experimenter are input on an input interface of the experimental equipment, and the experimental equipment information is displayed on the experimental equipment after the account name and the mobile phone number are checked to be correct;

and 4, step 4: the laboratory image information, the laboratory equipment information or the laboratory personnel information is laboratory information;

and 5: when experimenters want to check the laboratory messages, the corresponding buttons for checking the laboratory messages are clicked on the interactive interface of the touch screen, signals of the clicked buttons are transmitted to the controller, the controller transmits corresponding instructions to the management equipment, and the management equipment receives the instructions and transmits the corresponding laboratory messages to the controller and displays the laboratory messages on the touch screen;

the method for the management device to transmit the corresponding laboratory message to the controller in the step 5 specifically includes:

step 5-1: obtaining the message attribute of each laboratory message to perform clustering on the laboratory messages;

step 5-2: selecting the number of the laboratory message transmission channels for transmitting the group according to the real number of the laboratory messages of each group;

step 5-3: determining the number of laboratory message transmission channels for transmitting the laboratory messages of the corresponding group according to the group of the laboratory messages, and transmitting the laboratory messages of the corresponding group;

step 5-4: the actual delivery bandwidth of each laboratory messaging channel is obtained and the delivered laboratory messages are reduced in accordance with the actual delivery bandwidth of each laboratory messaging channel.

6. The management method for the management platform of the laboratory according to claim 5, wherein the experimenter messages comprise experimenter numbers, account names of experimenters, departments to which the experimenters belong, and mobile phone numbers of the experimenters;

the method for checking the error comprises the following steps: if the experimental device finds that the account name and the mobile phone number of the experimenter in the stored experimenter message are respectively consistent with the entered account name and the mobile phone number of the experimenter, the result is correct;

the experimental equipment information comprises an experimental equipment number, an experimental equipment name, an experimental equipment total number, an online or offline state of the experimental equipment, an existing online number of the experimental equipment, an existing offline number of the experimental equipment, a reserving time length of the experimental equipment, an average daily operating time of the experimental equipment, an average time usage of the experimental equipment and a real operating time length of the experimental equipment.

7. The method as claimed in claim 5, wherein in step 5-4, a real transmission bandwidth S of the laboratory messaging channel is obtained, the real transmission bandwidth S is compared with a corresponding preset laboratory messaging bandwidth SS, and whether to reduce the residual laboratory message is determined according to the comparison value;

the preset laboratory message transmission bandwidth comprises a preset laboratory message transmission bandwidth I ST and a preset laboratory message transmission bandwidth II SU, wherein ST is lower than SU;

when S is lower than ST, the laboratory message transmission bandwidth of the laboratory message transmission channel is determined not to meet the specification, and reduction is carried out on the residual laboratory messages;

when ST is less than or equal to S and S is less than or equal to SU, the laboratory messaging bandwidth of the laboratory messaging channel is deemed to meet specifications and no reduction of residual laboratory messages is necessary;

and when the S is higher than the SU, determining that the laboratory message transmission bandwidth of the laboratory message transmission channel does not meet the specification, and changing the number of the laboratory messages transmitted by the laboratory message transmission channel.

8. The management method for a management platform of a laboratory according to claim 7, wherein when it is determined that the laboratory message transmission bandwidth of the laboratory message transmission channel does not satisfy the specification and reduction is to be performed on the residual laboratory messages, a single laboratory message is decomposed into a plurality of message pieces by using the number of the previously set laboratory message bytes, and reduction is performed on each message piece in sequence, and when the reduction is completed, the real capacity H of any one of the laboratory messages after reduction is compared with the corresponding previously set laboratory message capacity HI, and it is determined whether to correct the number of the previously set laboratory message bytes according to the comparison value;

when H is higher than HI, the single laboratory message reduction is determined to not meet the specification, and the number of preset laboratory message bytes is changed;

when H is lower than or equal to HI, the single laboratory message reduction is determined to meet the specification, and the residual undelivered laboratory messages are reduced by using the preset number of bytes of the laboratory messages;

when the laboratory message reduction is determined not to meet the specification and the number of preset laboratory message bytes is changed, deducing a real laboratory message volume interval quantity LH, setting LH = HI-H, correcting the number of the preset laboratory message bytes according to the real laboratory message volume interval quantity, expressing the corrected number of the preset laboratory message bytes by XX, setting XX = XY {1-LH/H }, and when the value of XY {1-LH/H } is not a natural number, rounding the value of XY {1-LH/H } after a decimal point to obtain a value serving as the value of XX, wherein XY is the number of the preset laboratory message bytes.

9. The management method for a management platform of a laboratory according to claim 8, when the previously set number of bytes of laboratory message is to be collated to XX, the collated previously set number of bytes of laboratory message XX is collated with the previously set minimum number of bytes of laboratory message XA, when XX is higher than or equal to XA, the byte number of the corrected laboratory message set in advance is considered to meet the specification, and the decomposition is performed on the laboratory message with the corrected number XX of bytes of the laboratory message set in advance, when XX is lower than XA, it is determined that the collation of the number of previously set bytes of laboratory message cannot be used to perform the parsing of the laboratory message, and decomposing the laboratory message by using the preset number of bytes of the laboratory message, and replacing the laboratory message transmission channel.

10. The management method for a management platform of a laboratory according to claim 9, wherein when any laboratory message is decomposed into a plurality of message pieces by a previously set number of bytes of the laboratory message, a tail byte of any message piece is taken out, the tail byte and an index code byte are collated, and it is determined whether or not the number of bytes of the message piece is collated based on a collation value;

when the index code information has the tail byte, the number of bytes of the message piece to be changed is initially determined;

when the index code information does not have the tail byte, determining that the number of bytes of the message slice does not need to be changed;

when the tail bytes are compared to be the tail message pieces, replacing the tail bytes with the head bytes of the message pieces;

when the laboratory message transmission bandwidth of the laboratory message transmission channel is determined not to meet the specification and the number of the laboratory messages transmitted by the laboratory message transmission channel is changed, the changed real laboratory message transmission number is represented by G, G = { GH/Q } {1+ { S-SU }/SU } is set, and when the value of { GH/Q } {1+ { S-SU }/SU } is an unnatural number, the value obtained by rounding off the value of the small number point of GH/Q } {1+ { S-SU }/SU } is taken as the value of G, wherein GH is the total number of the laboratory messages of a group and Q is the number of the transmission channels of the corresponding laboratory messages.

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