Patent Description:
In recent years, with improvement of living standards, people's requirements for a balanced and nutritious diet are getting higher and higher, especially for infants who take breast milk as the main source of nutrition. By detecting and analyzing the content of trace elements in breast milk, such as calcium, zinc, iron, lactose, and protein, mothers can be given appropriate nutritional dietary guidance to ensure the nutritional balance of breast milk. <CIT> directs to a biological test paper detector for correcting a standard curve by a network and a correction method of the biological test paper detector for correcting the standard curve by the network. A sample to be tested and/or a standard sample are/is built in a reaction chamber and fully react(s) within a preset time; a collecting module is configured to collect and acquire signal intensity data after the reaction of the to-be-tested sample and/or a standard sample is finished. A computing module is preconfigured with standard curve parameters and is configured to acquire the signal intensity data and compute a result by comparing the standard curve parameters, so as to obtain the concentration of the to-be-tested sample and/or the standard sample. Old-version standard curve parameters are corrected into new-version standard curve parameters, so that the concentration of the to-be-tested sample and/or the standard sample is obtained conveniently by the computing module according to the comparison with the new-version standard curve parameters, and the potential safety hazards of misinformation, misdiagnosis and the like as the standard curve parameters cannot be corrected timely can be avoided. <CIT> directs to a biochip detecting device for detecting a biochip which has identifying information. The biochip detecting device has a controller, a reader, a storage medium and a detecting module. The reader reading the identifying information, the storage medium saving a detecting information, and the detecting module detecting the biochip are electrically connected to the controller. The controller is suitable for determining the record of the identifying information in the detecting information and modifying the setting of the detecting module automatically according to the identifying information. A biochip detecting method is further provided. A biochip detecting device is used to read identifying information of the biochip to determine whether the biochip could be detected. Besides, the setting of a detecting module is automatically adjusted by a controller. The time for adjusting the setting of the detecting module is saved and the possibility of setup mistake could be reduced. <CIT> directs to a diagnosis testing system. The system comprises a testing terminal, a batch reading module and a batch calibration system, wherein the testing terminal comprises a shell, a test strip detection mechanism and a power supply module; the test strip detection mechanism and the power supply module are arranged in the shell; the test strip detection mechanism is used for detecting a test strip and acquiring an actual test value M survey; the batch reading module is used for reading test strip batch information; the batch calibration system is in signal connection with the test strip detection mechanism and the batch reading module, and is used for correcting the actual test value M survey from the test strip detection mechanism according to batch calibration data corresponding to the batch of test strips so as to acquire a calibration value M judgement. By utilizing the diagnosis testing system, different batches of test bars can be calibrated during actual user application, so that the test result accuracy can be improved.

International patent application <CIT> discloses a device for the analysis of breast milk, comprising: at least one camera to photograph a sampling element, wherein said sampling element comprises one or more arrays of reagents reacting with one or more target molecules present in a sample of said breast milk and presenting one or more arrays with a plurality of spots comprising one or more intensity levels, and wherein said camera is adapted to photograph said plurality of spots; at least one computer adapted to analyze said one or more intensity levels of said spots; and at least one output component for presenting results of said analysis and for providing a recommendation relating to nutritional or immunological needs of an infant fed by said breast milk.

It is an objective of the present disclosure to provide a control method of an analyzer, an analyzer, a detection system, and a storage medium.

The object is achieved by the respective independent claims.

In order to clearly illustrate the technical solutions of the embodiments of the present disclosure, the drawings of the embodiments will be briefly described in the following. It is obvious that the described drawings are only related to some embodiments of the present disclosure and thus are not limitative to the present disclosure.

In order to make objects, technical details and advantages of the embodiments of the present disclosure apparent, the technical solutions of the embodiments of the present disclosure will be described in a clearly and fully understandable way in connection with the drawings related to the embodiments of the present disclosure. Apparently, the described embodiments are just a part but not all of the embodiments of the present disclosure. Based on the described embodiments of the present disclosure herein, those skilled in the art can obtain other embodiment(s), without any inventive work, which should be within the scope of the present disclosure.

Unless otherwise defined, all the technical and scientific terms used herein have the same meanings as commonly understood by one of ordinary skill in the art to which the present disclosure belongs. The terms "first," "second," etc., which are used in the description and the claims of the present application for disclosure, are not intended to indicate any sequence, amount or importance, but distinguish various components. Also, the terms such as "a," "an," etc., are not intended to limit the amount, but indicate the existence of at least one. The terms "comprise," "comprising," "include," "including," etc., are intended to specify that the elements or the objects stated before these terms encompass the elements or the objects and equivalents thereof listed after these terms, but do not preclude the other elements or objects. The phrases "connect," "connected," "coupled," etc., are not intended to define a physical connection or mechanical connection, but may include an electrical connection, directly or indirectly. "On," "under," "right," "left," and the like are only used to indicate relative position relationship, and when the position of the object which is described is changed, the relative position relationship may be changed accordingly.

At present, analysis devices used for detecting the substance content of various liquids (such as breast milk, milk, etc.) are mainly large-scale detection devices, which are expensive and complicated to operate and need special training for operators, and therefore these detection devices are mainly provided in public places such as hospitals or detection institutions. For the liquid that needs to be detected by these detection devices, because the detection process needs to be carried out in public places such as the above-mentioned hospitals or detection institutions, the detection process of the liquid is time-consuming and laborious, which greatly increases the detection cost of the liquid and is inconvenient for frequent detection of the liquid. However, it is particularly important to regularly monitor the substance content of breast milk, milk and other liquids which need to be detected regularly.

In the control method of the analyzer provided by the embodiments of the present disclosure, the detection chip is used to contain the breast milk to be analyzed and the analyzer is used to perform detection and analysis on the detection chip based on the analysis parameter corresponding to or matching the detection chip. Thus, the analysis data of the breast milk to be analyzed can be accurately obtained, for example, the substance content of trace elements or the concentration value of specific components in the breast milk to be analyzed can be accurately obtained, so that the accuracy and reliability of the obtained analysis data may be improved while the detection process is simple and convenient to operate, thereby being helpful for the user to obtain accurate and reliable analysis results.

Hereinafter, some embodiments of the present disclosure will be described in detail with reference to the accompany drawings. It should be noted that the same reference numerals in different drawings are used to refer to the same described elements.

<FIG> is a flowchart of a control method of a breast milk analyzer provided by the present invention. For example, examples of the analyzer, the detection chip, the parameter storage device, or the like involved in the method may refer to descriptions of <FIG>. As illustrated in <FIG>, the method includes the following steps S110~S130.

Step S110: determining whether the analyzer obtains an analysis parameter corresponding to a detection chip used for detection.

Step S120: requesting and obtaining the analysis parameter in a case of being determined that the analyzer does not obtain the analysis parameter.

Step S130: performing detection on the detection chip and analyzing a substance to be analyzed contained in the detection chip by using the analysis parameter to obtain analysis data of the substance to be analyzed in a case of being determined that the analyzer obtains the analysis parameter.

In the claimed invention, the analyzer is configured to perform detection on the detection chip based on the analysis parameter, and the detection chip is configured to contain the breast milk to be analyzed for detection and analysis.

Because there may be differences in the materials of different production batches of detection chips, and accordingly, there may be differences in the biological or chemical reaction conditions and reaction results on different production batches of detection chips, analysis parameters corresponding to or matching different batches of detection chips need to be used in the process of obtaining analysis data by using the analyzer. According to the control method of the analyzer provided by the embodiments of the present disclosure, by ensuring that the analysis parameter used in analyzing the breast milk to be analyzed is the analysis parameter corresponding to or matching the detection chip being used, the possible adverse effects, caused by the difference in the material of the detection chip, on the process of obtaining the analysis data of the breast milk to be analyzed may be reduced or avoided. Thus, the accuracy and reliability of the obtained analysis data may be improved while the detection process is simple and convenient to operate by using the detection chip, thereby being helpful for the user to obtain accurate and reliable analysis results, and satisfying the requirements of the user to achieve self-detection and self-analysis of the substance to be analyzed.

For example, the detection chip of the embodiments of the present disclosure may be a chip which can achieve integration or basic integration of basic operation units such as sample preparation, biological and chemical reactions, separation and detection, or the like, and has a size of several square centimeters. For example, the detection chip may be a microfluidic chip. Therefore, the breast milk to be analyzed contained in the detection chip can complete different biological or chemical reaction processes in the detection chip. The analyzer may use detection methods such as laser induced fluorescence, mass spectrum, ultraviolet, chemi-luminescence, or the like to detect the products, so as to obtain detection data, and the analyzer may use the analysis parameter to acquire the analysis data as required according to the detection data. For example, the analysis data may include information such as the content or concentration value of a specific component in the breast milk to be analyzed.

For example, in some embodiments of the present disclosure, the analysis parameter includes a calculation curve for acquiring the analysis data based on the detection data of the detection chip.

According to the claimed invention, the detection chip is detected by using an optical method to obtain the concentration value of a specific component in the breast milk to be analyzed, the analyzer performs optical detection on the detection chip to obtain the detection data. For example, the detection data may be such as an absorbance value of the breast milk to be analyzed, and the analysis parameter may be a standard curve reflecting the relationship between the concentration value and the absorbance value of the component in the breast milk to be analyzed. Therefore, after the absorbance value of the breast milk to be analyzed is obtained through optical detection on the detection chip, the absorbance value is brought into the standard curve, so that the concentration value of the component in the breast milk to be analyzed corresponding to the absorbance value is obtained through calculation.

According to the claimed invention, in the process of detecting the detection chip by using the optical method, the concentration values of different components in the breast milk to be analyzed are detected and analyzed by light with different wavelengths, so that the concentration values of various components in the breast milk to be analyzed are detected and analyzed simultaneously by light with different wavelengths, thereby shortening the time required for the detection process and reducing the detection cost. For example, the concentration values of lactose, fat, calcium, protein, and other components in the breast milk can be detected at the same time, so as to facilitate monitoring the concentration values of different components in the breast milk at any time to determine whether the expected indices are achieved.

<FIG> is a schematic diagram of a detection chip provided by some embodiments of the present disclosure, and <FIG> are schematic diagrams of an analyzer provided by some embodiments of the present disclosure and detection with the analyzer on a detection chip. It should be noted that the embodiments of the present disclosure do not limit the type of detection chip, the appearance and mechanical structure of the analyzer, or the like, as long as the control method of the present disclosure can be applied.

For example, as illustrated in <FIG>, the exemplary breast milk analyzer <NUM> includes a first housing <NUM>, a second housing <NUM>, and a chip placement structure <NUM>. The chip placement structure <NUM> is located in the first housing <NUM> for placing the detection chip <NUM>. For example, the detection chip <NUM> is a microfluidic detection chip, which includes at least one (for example, two or more) detection region. Upon the breast milk to be analyzed being injected into the detection chip, the breast milk to be analyzed flows into the at least one detection region through an injection port and a flow channel. The first housing <NUM> and the second housing <NUM> of the analyzer <NUM> can be turned on or turned off at one side, which is convenient for the user to place and retrieve the detection chip <NUM>. Upon the analyzer <NUM> being used to perform detection on the detection chip <NUM> injected with the breast milk to be analyzed, the first housing <NUM> and the second housing <NUM> can avoid interference caused by external light.

The analyzer <NUM> further includes a detection portion <NUM>, for example the detection portion <NUM> is provided in the first housing <NUM> and below the chip placement structure <NUM>. For example, the detection chip <NUM> placed on the chip placement structure <NUM> can be detected through the detection portion <NUM>, so as to obtain the analysis data of the substance to be analyzed contained in the detection chip <NUM>.

During the using process, the first housing <NUM> and the second housing <NUM> may be opened first, the detection chip <NUM> can be placed on the chip placement structure <NUM>, the breast milk to be analyzed can be injected into the detection chip <NUM>, and then the first housing <NUM> and the second housing <NUM> may be closed, so that the analyzer <NUM> can detect the detection chip <NUM>. After the detection is completed and the analysis data is obtained, the first housing <NUM> and the second housing <NUM> can be opened again, and the detection chip <NUM> can be taken out.

It should be noted that the structure of the detection chip <NUM> illustrated in <FIG> is only an example, and the embodiments of the present disclosure do not limit the specific structure of the detection chip <NUM>.

For example, in the process of performing detection on the detection chip <NUM> including a plurality of detection regions <NUM> through the detection portion <NUM>, the detection portion <NUM> can be rotated with the rotation driving device <NUM>, so as to perform detection on different detection regions <NUM> of the detection chip <NUM>. For example, the plurality of detection regions <NUM> may be used for detecting and analyzing the contents, concentration values, or the like of different components in the breast milk to be analyzed, so that simultaneous detection and analysis of the contents or concentration values of multiple components in the breast milk to be analyzed can be achieved by the analyzer <NUM>.

In the method illustrated in <FIG>, after it is determined that the analyzer has obtained the analysis parameter corresponding to or matching the detection chip used for detection, the analyzer continues to perform a subsequent detection operation on the detection chip to obtain the analysis data. In the case of being determined that the analyzer does not obtain the analysis parameter, the analyzer sends out a request for obtaining the analysis parameter, and the analyzer then continues to perform the subsequent detection operation after ensuring that the analysis parameter is obtained. Therefore, it can ensure that the analyzer analyzes the breast milk to be analyzed by using the analysis parameter matched with the detection chip being used, thereby improving the accuracy and reliability of the obtained analysis data and helping the user to obtain accurate and reliable analysis results.

For example, in some embodiments of the present disclosure, obtaining the analysis parameter includes: allowing the analyzer to be in signal connection with a parameter storage device storing the analysis parameter through the communication interface, and reading and storing the analysis parameter, so that the analyzer can obtain the analysis data matched with the detection chip.

<FIG> is a flowchart of a specific example of Step S120 illustrated in <FIG>.

As illustrated in <FIG>, in the case of being determined that the analyzer does not obtain the analysis parameter corresponding to the detection chip used for detection, Step S120 includes step S <NUM> and may optionally include Step S <NUM>.

Step S121: requesting to obtain the analysis parameter.

For example, the analyzer may send out a request for obtaining the analysis parameter by displaying an image, making a sound, vibrating, or other methods. Alternatively, the analyzer may also send out the request for obtaining the analysis parameter through other devices, such as being in signal connection with the analyzer, by displaying an image, making a sound, vibrating, or other methods, and the embodiments of the present disclosure are not limited in this aspect.

Step S122: allowing the analyzer to be in signal connection with a parameter storage device storing the analysis parameter through the communication interface, and reading and storing the analysis parameter.

For example, the analyzer includes a communication interface. According to the type of communication interface, the analyzer and the parameter storage device can be directly connected through the communication interface to achieve signal connection, or can also be connected through connection media such as a data line, a signal line, or the like to achieve signal connection, or the signal connection between the analyzer and the parameter storage device can also adopt wireless communication connection or other suitable signal connection methods, and the embodiments of the present disclosure are not limited in this aspect. The communication interface is a part of a communication device, and the communication device may be dedicated to communication with the parameter storage device, and may also be reused for communication for other purposes.

<FIG> is a schematic diagram of a parameter storage device provided by some embodiments of the present disclosure, and <FIG> is a schematic diagram of a signal connection method between an analyzer and a parameter storage device provided by some embodiments of the present disclosure.

For example, as illustrated in <FIG>, the parameter storage device <NUM> may be a USB flash drive, the communication interface <NUM> of the analyzer <NUM> is a USB interface, and the analyzer <NUM> correspondingly includes a USB control device as the communication device. Therefore, by directly inserting the data interface <NUM> of the parameter storage device <NUM> into the communication interface <NUM> provided on the surface of the analyzer <NUM>, the signal connection between the analyzer <NUM> and the parameter storage device <NUM> can be achieved, so as to allow the analyzer <NUM> to read and store the analysis parameter stored in the parameter storage device <NUM>.

For example, as illustrated in <FIG>, the parameter storage device <NUM> includes a housing <NUM> and further includes a control circuit, a memory (not shown), or the like provided in the housing <NUM>. The analysis parameter is stored in the memory. The control circuit is configured to establish the signal connection between the parameter storage device <NUM> and the analyzer <NUM>, and is further configured to read the analysis parameter from the memory, so as to transmit the read analysis parameter to the analyzer <NUM> through the communication interface <NUM> upon the parameter storage device <NUM> being in signal connection with the analyzer <NUM>. For example, the control circuit includes a processor.

For example, a material of the housing <NUM> may be thermoplastic elastomer (TPE) or other suitable materials, such as a material that can protect the control circuit, memory, or the like provided in the housing <NUM>, and the embodiments of the present disclosure are not limited in this aspect.

For example, in some embodiments of the present disclosure, the communication interface <NUM> of the analyzer <NUM> illustrated in <FIG> is further configured to charge the analyzer <NUM>. Therefore, the communication interface <NUM> can provide various functions such as charging, data reading and writing, etc., and improve the utilization rate of the communication interface <NUM>, thereby improving the overall operation performance of the analyzer <NUM> and improving the user experience. At the same time, because the communication interface <NUM> is usually provided on the surface of the analyzer <NUM>, the communication interface <NUM> with multiple functions may also facilitate optimizing the design of the analyzer <NUM>, thereby further improving the user experience. As mentioned above, for example, the communication interface <NUM> is a USB interface, which may be of the Type-A, Type-B, Type-C, etc. Therefore, the communication interface <NUM> can have both the communication function and the charging function. The embodiments of the present disclosure are not limited thereto, and the above-mentioned communication interface may also be a lighting interface, etc..

It should be noted that, in some other embodiments of the present disclosure, the analyzer <NUM> may use, for example, a battery built in the analyzer <NUM> for power supply. In other embodiments, the analyzer <NUM> may also be electrically connected to an external power supply by using a wire for power supply. For example, the external power supply may be a transformer, so as to convert the daily electricity (e.g., 220V or 110V) into the voltage type (e.g., direct current) and the voltage (e.g., 5V or <NUM>. 5V) required by the analyzer, thereby omitting the charging process of the analyzer <NUM> for convenience of the user. The embodiments of the present disclosure are not limited thereto.

It should be noted that, in the process of performing detection on the detection chip by using the analyzer <NUM>, the analyzer <NUM> can be opened and the detection chip can be placed on a supporting table (for example, the chip placement structure <NUM>) inside the analyzer <NUM>, so as to achieve the detection and analysis of the breast milk to be analyzed contained in the detection chip.

It should be noted that, in the embodiments of the present disclosure, the signal connection method between the analyzer and the parameter storage device, the type of the parameter storage device, etc. include but are not limited to the above situations.

For example, according to the communication interfaces of different types of analyzers, the above-mentioned parameter storage device may also be a storage device such as a hard disk, a floppy disk, a magneto-optical disk, etc.; or, the above-mentioned parameter storage device may also be an electronic device with a storage function, such as a mobile phone, a computer, etc., and may be in signal connection with the communication interface of the analyzer through such as a signal line, a data line, or the like. The embodiments of the present disclosure are not limited thereto.

For example, in some embodiments of the present disclosure, the communication interface of the analyzer may also be a wireless communication interface, and accordingly, the parameter storage device may be a first mobile terminal. For example, the wireless communication interface may include the mobile hotspot (WiFi), Bluetooth, near field communication (NFC), mobile communication (such as <NUM>/<NUM>/<NUM>/<NUM>), etc. The first mobile terminal may be a mobile terminal with a wireless communication function, such as a mobile phone, a computer, or the like, and may also be an IC card (such as a contactless IC card). Therefore, the signal connection between the analyzer and the parameter storage device is achieved by wireless communication, so that the analyzer and the parameter storage device can move relatively flexibly with each other, thereby providing convenience for the user to operate, carry, etc..

<FIG> is a flowchart of another control method of an analyzer provided by some embodiments of the present disclosure. For example, as illustrated in <FIG>, the method includes the following steps S210~S250.

Step S210: prompting to check whether the analysis parameter currently obtained corresponds to the detection chip used for detection.

For example, after the analyzer is turned on and completes self-inspection, upon detecting that the analysis parameter is stored in the analyzer, the analyzer sends out a check prompt to the user by displaying an image, making a sound, or other methods, or the analyzer may also send out the check prompt to the user through other devices, such as being in signal connection with the analyzer, by displaying an image, making a sound, or other methods. For example, the analyzer displays an identification code (for example, including a number or a letter) corresponding to the analysis parameter for the user to check, and the embodiments of the present disclosure are not limited in this aspect.

Step S220: determining whether the analyzer obtains the analysis parameter corresponding to the detection chip used for detection.

For example, after receiving the prompt in Step S210, the user checks whether the analysis parameter currently obtained by the analyzer corresponds to the analysis parameter of the detection chip to be used for the current detection, and provides a check result to the analyzer or such as a mobile terminal in signal connection with the analyzer, so that the analyzer can determine whether the analysis parameter corresponding to the detection chip used for the detection is obtained. For example, an identification code corresponding to the analysis parameter is printed on an outer packaging or a surface of the detection chip to be used for the comparison by the user.

For example, the user can directly press or dial a corresponding button or switch provided on the analyzer to provide a verification result, and the analyzer generates a control signal to perform a corresponding operation according to the received verification result. For example, the analyzer may also be in signal connection with a mobile terminal with a remote control function, such as an infrared remote controller or the like. After the user provides the verification result to the mobile terminal, the mobile terminal generates a corresponding control signal and transmits the control signal to the analyzer, so that the analyzer can perform a corresponding operation according to the control signal. For example, the user may feed back the verification result by pressing a button on the infrared remote controller. For example, according to the actual structure and functional design of the analyzer, the user may also provide the verification result through the touch screen or other input devices on the analyzer or mobile terminal, or may also provide the verification result by voice through an audio device of the analyzer or mobile terminal. In the embodiments of the present disclosure, an applicable method of obtaining the verification result may be selected according to the structure, function, or the like of the analyzer and associated equipment, and the embodiments of the present disclosure are not limited in this aspect.

For example, upon checking whether the analysis parameter currently obtained corresponds to the detection chip used for detection, the user may check whether the parameter storage device storing the analysis parameter matches with the detection chip. For example, it can be checked whether the identification codes provided on the detection chip and the parameter storage device correspond to each other. For example, it can be checked whether the same set of codes are printed on the detection chip and the parameter storage device. Alternatively, for example, the equipment with a scanning function may be used to scan the identifications such as bar codes or two-dimensional codes on the detection chip and the parameter storage device for verification. Alternatively, in the case where the parameter storage device has a display function, it may also be checked by looking up the display information provided by the parameter storage device, and the embodiments of the present disclosure are not limited thereto.

For example, because the analysis parameter stored in the parameter storage device needs to be matched with the detection chip, the parameter storage device may be batch-bound with the corresponding detection chip at the time of delivery, so that the parameter storage devices of different batches cannot be used universally, thereby ensuring that the analysis parameter used for detecting and analyzing the breast milk to be analyzed corresponds to the detection chip being used. For example, for the convenience of the user, the detection chip and the corresponding parameter storage device may be placed in the same packaging box for thes user.

Step S230: requesting to obtain a new analysis parameter in a case where the analysis parameter currently obtained does not correspond to the detection chip used for detection.

Step S240: obtaining the analysis parameter corresponding to the detection chip used for detection.

Step S250: performing detection on the detection chip and analyzing the substance to be analyzed contained in the detection chip by using the analysis parameter to obtain analysis data of the substance to be analyzed.

For example, as illustrated in <FIG>, in the case where it is determined that the analyzer has obtained the analysis parameter corresponding to the detection chip used for detection by checking that the analysis parameter currently obtained corresponds to the detection chip used for detection, the operation of Step S250 is directly performed after Step S220. In the case where it is determined that the analysis parameter currently obtained does not correspond to the detection chip used for detection after checking, and then it is determined that the analyzer does not obtain the analysis parameter corresponding to the detection chip used for detection, the operation of Step S230 is performed after Step S220.

In the above exemplary method, Step <NUM> does not need to be performed before Step S220, but may also be performed after Step <NUM>, that is, the analyzer may either perform the self-inspection after starting up and then detect whether the analysis parameter is obtained, or perform the self-inspection after detecting whether the analysis parameter is obtained.

It should be noted that, the specific contents of Step S230 and Step S240 may refer to the descriptions of Step S121 and Step S122 in <FIG>, respectively, the specific contents of Step S250 may refer to the descriptions of Step S130 in <FIG>, and repeated contents are omitted herein.

For example, in some embodiments of the present disclosure, the analyzer further includes at least one micro switch, and the control method of the analyzer provided by the embodiments of the present disclosure further includes: detecting an operation applied to the micro switch, and generating a control signal according to the operation. The control signal is used for an interaction process of the analyzer.

For example, a control signal may be provided to the analyzer by controlling such as the switch state, rotation angle, or touch sensing of the micro switch, so that the analyzer can execute corresponding operation steps according to the control signal, thereby achieving the interaction process between the analyzer and the user or other equipment, and further achieving the control of the analyzer through the interactive operation.

For example, taking the control method of the analyzer illustrated in <FIG> as an example, after checking whether the analysis parameter currently obtained corresponds to the detection chip used for detection, the user may provide a control signal to the analyzer by operating the micro switch, so that the analyzer can determine whether the analyzer has obtained the analysis parameter corresponding to the detection chip used for detection according to the control signal, so as to select the subsequent step to be performed.

In some other embodiments of the present disclosure, in addition to controlling the micro switch, the control signal may also be provided to the analyzer in other ways, so as to achieve the interaction process between the analyzer and the user or other equipment, and the embodiments of the present disclosure are not limited in this aspect. For example, the control signal used for the interaction process of the analyzer may also be generated and provided by a mobile terminal being in signal connection with the analyzer and with a remote control function, so as to achieve the interaction process between the analyzer and the mobile terminal, or achieve the interaction process between the analyzer and the user through the mobile terminal, and the embodiments of the present disclosure are not limited in this aspect.

For example, in some embodiments of the present disclosure, the micro switch may be the micro switch <NUM> of the analyzer <NUM> as illustrated in <FIG>. For example, as illustrated in <FIG>, the micro switch <NUM> protrudes outwards from a surface of the analyzer <NUM> and has a long strip shape, and the micro switch <NUM> is configured to be capable of being operated in at least two directions. For example, the micro switch <NUM> may be operated in multiple directions, such as an up-down direction, a left-right direction, or the like, and may even be operated in both the up-down direction and the left-right direction, and the embodiments of the present disclosure are not limited in this aspect.

For example, the micro switch <NUM> may has a strip shape similar to the rabbit-ear shape illustrated in <FIG>, which is convenient for the user to operate the micro switch <NUM>, and facilitates the optimization of the design of the analyzer <NUM>, thereby improving the user experience.

For example, the number of micro switches of the analyzer may be two as illustrated in <FIG>, or may also be one, three, four or more, etc. For example, the micro switch in the analyzer may be provided at an upper part of the analyzer as illustrated in <FIG>, or may also be provided at other suitable positions on the analyzer, and the embodiments of the present disclosure are not limited in this aspect.

For example, in some embodiments of the present disclosure, generating the control signal according to the operation applied to the micro switch includes: generating different control signals for interaction according to operations of the micro switch in different directions. Therefore, the analyzer can achieve different interactive functions through different control signals generated based on the operations applied to the micro switch, thereby achieving flexible control of the analyzer through cross operation, improving the operating performance of the analyzer, and optimizing the user experience of the analyzer.

For example, taking the analyzer <NUM> in the above embodiments as an example, the micro switch <NUM> can be operated in different directions, such as the up-down direction, left-right direction, etc., to provide, for example, a control signal for determining whether the analyzer obtains the analysis parameter corresponding to the detection chip used for detection, a control signal for switching the working state of the analyzer <NUM> (for example, a control signal for turning on or turning off the analyzer <NUM>, allowing the analyzer <NUM> to enter a sleep state, etc.), or other suitable control signals used for interaction. The embodiments of the present disclosure are not limited in this aspect.

For example, in some embodiments of the present disclosure, the analyzer further includes a display device, and the control method of the analyzer provided by some embodiments of the present disclosure further includes: displaying the analysis data through the display device, or allowing the display device to display different interactive operation interfaces according to the control signal.

For example, the display device may display the above-mentioned analysis data, so that the user can intuitively obtain the analysis data through the display device. Alternatively, the display device may be used to provide a display image corresponding to Step S210 in <FIG> described above, or may display an interactive operation interface corresponding to Step S230 in <FIG> described above according to the control signal, and the embodiments of the present disclosure are not limited in this aspect.

For example, the display device may be any product or component with a display function, such as an LCD display device, an OLED display device, a QLED display device, an electronic paper display device, etc., and the embodiments of the present disclosure are not limited in this aspect. In addition, the display device may also have such as a touch function, so as to facilitate the user to operate and view the operation process.

For example, in some embodiments of the present disclosure, the analysis data obtained by the analyzer includes a plurality of items (for example, a plurality of components or different parameters of each component), and displaying the analysis data through the display device described above includes: switching a display page of the display device according to the control signal so as to display different items in the analysis data. Therefore, in the case where the analysis data includes a plurality of items, the analyzer may flexibly display the plurality of items on different pages through the display device, for example, the display pages providing different items may be sequentially displayed according to the control signal, or the display page including a specific item may be displayed according to the control signal, and the embodiments of the present disclosure are not limited in this aspect.

For example, in some embodiments of the present disclosure, the analyzer further includes a communication device, and the control method of the analyzer provided by the embodiments of the present disclosure further includes: allowing the analyzer to be in signal connection with a second mobile terminal through the communication device, and receiving the control signal provided by the second mobile terminal or providing the analysis data to the second mobile terminal.

For example, the second mobile terminal may be a device with a communication function, such as a mobile phone, a computer, a server, a remote controller, etc. For example, the signal connection between the second mobile terminal and the analyzer may be wired communication connection implemented through a signal line, a data line, etc., and may also be wireless communication connection using such as the mobile hotspot (WiFi), Bluetooth, near field communication (NFC), mobile communication (such as <NUM>/<NUM>/<NUM>/<NUM>), etc. For example, the second mobile terminal may be implemented as the same terminal device as the above-mentioned first mobile terminal, or may also be provided separately, and the embodiments of the present disclosure are not limited in this aspect.

Because the analyzer includes the communication device connected with the second mobile terminal, the analyzer may provide different operation modes, including an online mode and an offline mode. The online mode allows the analyzer to be connected with a mobile terminal such as a mobile phone, a computer (such as a tablet computer), or the like, so as to interact with the user depending on the mobile terminal, and upload detection and analysis data to the mobile terminal. The offline mode allows the analyzer to independently interact with the user and provide detection and analysis results without being connected to the mobile terminal.

For example, the communication device may be such as a USB interface or the like, so as to achieve the signal connection between the analyzer and the second mobile terminal through wired communication connection, or the communication device may also be the above-mentioned wireless communication interface such as the mobile hotspot (WiFi), Bluetooth, near field communication (NFC), mobile communication (such as <NUM>/<NUM>/<NUM>/<NUM>), etc., and the embodiments of the present disclosure are not limited in this aspect.

For example, in the case where the analyzer receives the control signal provided by the second mobile terminal through the communication device, the second mobile terminal may apply the control signal to the analyzer through signal connection, so as to control the analyzer to achieve different interactive functions, control the display image provided by the display device of the analyzer, etc., so that the analyzer can be controlled through interactive operations.

For example, in the case where the analyzer provides the analysis data to the second mobile terminal, the second mobile terminal may be a mobile device with a storage function. After receiving the analysis data, for example, the mobile device stores the analysis data in a memory for subsequent use, or the mobile device transmits the analysis data to another device which is difficult to achieve direct signal connection with the analyzer, thereby achieving sharing or real-time uploading of the analysis data. For example, the second mobile terminal may also be a mobile device with a display function, so that the analysis data may also be displayed on the second mobile terminal.

For example, in some embodiments of the present disclosure, the control method of the analyzer further includes: determining whether to establish the signal connection between the analyzer and the second mobile terminal through the communication device, and selecting an operation mode. For example, the analyzer determines whether to establish the signal connection between the analyzer and the second mobile terminal through the communication device, and prompts the user to select the offline mode in the case of being determined that the analyzer is not connected to the second mobile terminal, or prompts the user to re-select (switch) the operation mode in the case that the user has selected the online mode.

For example, in some embodiments of the present disclosure, the second mobile terminal has a display function, and the control method of the analyzer further includes: displaying the analysis data and/or an analysis result provided based on the analysis data through the second mobile terminal, or displaying an interactive operation interface through the second mobile terminal for generating the control signal.

For example, the second mobile terminal may be configured to have a relatively large display screen, so as to provide a more impeccable display image compared with the analyzer, so that the user can intuitively obtain more complete and abundant information related to the analysis data through the second mobile terminal. For example, in the case of the analysis data including a plurality of items, the plurality of items may be displayed simultaneously through the display screen of the second mobile terminal, so that the user can obtain the required analysis data more intuitively through the second mobile terminal, thereby improving the user experience. For example, the second mobile terminal may also provide the analysis result based on the analysis data in the display page providing the analysis data, so that the user can obtain more information related to the analysis data at the same time.

For example, in the case of the analysis data and the analysis result provided based on the analysis data being displayed through the second mobile terminal, the analysis data may be the content or concentration value of one or more components in the breast milk, and the analysis result may be professional nutrition matching, dietary guidance, clinical advice, etc., provided based on the substance content analysis of the breast milk. For example, the analysis result may be directly given by such as an application program (APP) installed on the second mobile terminal, or the analysis result may be obtained by uploading the analysis data to a server through the second mobile terminal and searching and querying through the server, and the embodiments of the present disclosure are not limited in this aspect.

For example, in the case of the interactive operation interface being displayed by the second mobile terminal for generating the control signal, the interactive operation interface displayed by the second mobile terminal may be a prompt page or a request page that is sent to the user, such as the interactive operation pages corresponding to Step S210 and Step S230 in <FIG>, so that the user may perform corresponding operations according to the display information provided by the second mobile terminal, and the analyzer or equipment being in signal connection with the analyzer can generate the corresponding control signal based on the applied operation, thereby achieving the control of the analyzer through the interactive operation.

<FIG> is a flowchart of still another control method of an analyzer provided by some embodiments of the present disclosure. For example, as illustrated in <FIG>, the method includes the following steps.

Step S310: determining whether the analyzer obtains the analysis parameter corresponding to the detection chip used for detection.

Step S320: requesting and obtaining the analysis parameter in the case of being determined that the analyzer does not obtain the analysis parameter.

Step S330: displaying an interactive operation interface through the display device in the case of being determined that the analyzer has obtained the analysis parameter.

Step S340: detecting an operation applied to the micro switch, generating a control signal according to the operation, and determining whether to establish signal connection between the analyzer and the second mobile terminal through the communication device according to the control signal.

Step S350: establishing the signal connection between the analyzer and the second mobile terminal through the communication device in the case of being determined to establish the signal connection between the analyzer and the second mobile terminal through the communication device.

Step S360: performing detection on the detection chip, and analyzing the substance to be analyzed contained in the detection chip by using the analysis parameter to obtain analysis data of the substance to be analyzed.

Step S370: providing the analysis data to the second mobile terminal, and displaying the analysis data and an analysis result provided based on the analysis data through the second mobile terminal.

Step S380: in the case where the analyzer is not in signal connection with the second mobile terminal through the communication device, performing detection on the detection chip, and analyzing the substance to be analyzed contained in the detection chip by using the analysis parameter to obtain analysis data of the substance to be analyzed.

Step S390: displaying the analysis data through the display device, and switching a display page of the display device according to a control signal, so as to display different items in the analysis data.

For example, in some embodiments of the present disclosure, the control method of the analyzer further includes: performing equipment detection on the analyzer to determine whether the analyzer satisfies a condition for performing detection on the detection chip.

For example, the analyzer first performs self-inspection after starting up to determine whether the analyzer meets the conditions for performing detection on the detection chip, and in the case of being determined that the analyzer meets the conditions for performing detection on the detection chip, the analyzer will perform subsequent detection and analysis operations. For example, in the case of being determined that the analyzer meets the conditions for performing detection on the detection chip, the corresponding method illustrated in <FIG>, <FIG> or <FIG> is continued to be executed to achieve the control of the analyzer. In the case where the analyzer does not meet the conditions for performing detection on the detection chip, prompt warning is given and the analyzer is requested to be tested or repaired, so that the analyzer can meet the conditions for performing detection on the detection chip. Therefore, the analyzer can be ensured to be in a normal and stable working state upon the analyzer being used for performing detection on the detection chip, thereby ensuring the accuracy and reliability of the obtained analysis data.

For example, the equipment detection performed on the analyzer includes detection of detecting the light path of the analyzer, detection of the environment temperature, humidity, and other conditions, etc..

In the claimed invention, the substance to be analyzed is a breast milk sample. By using the control method of the analyzer provided by the embodiments of the present disclosure, accurate and convenient detection and analysis of the breast milk can be achieved, thereby obtaining accurate contents of various components in the breast milk. Therefore, the user can complete the detection and analysis process of the breast milk sample on the user's own through the control method of the analyzer provided by the present invention, and can accurately and quickly obtain the content of each component in the breast milk. For example, the user can further acquire such as dietary guidance, nutrition matching suggestions, or the like provided based on the content of each component in the breast milk, thereby improving the user experience.

Hereinafter, with reference to the analyzer <NUM> and the parameter storage device <NUM> illustrated in <FIG>, the case where the second mobile terminal is a mobile phone is taken as an example to describe a specific example of the control method of the analyzer provided by some embodiments of the present disclosure.

For example, upon the analyzer being used to detect and analyze breast milk for the first time, the analyzer can be started by short pressing one micro switch of the analyzer. For example, the micro switch may be a switch having a rabbit-ear shape on the right side of the user upon watching the display screen of the analyzer, such as the micro switch <NUM> illustrated in <FIG>. In order to distinguish the plurality of micro switches on the analyzer, the micro switch is hereinafter referred to as the first switch. After the first switch is pressed by the user for short time, the analyzer starts and is in a working state. If the first switch is pressed by the user for long time, the analyzer will shut down.

After the analyzer is started, the above steps of equipment detection are performed on the analyzer to determine whether the analyzer meets the conditions for performing detection on the detection chip. For example, the equipment detection process can be completed by the analyzer under the control of the control device inside the analyzer. For example, the analyzer detects the detecting light path of the analyzer, the detection environment temperature, humidity and other conditions, or the like according to the control signal generated by the control device. In the case that the analyzer does not meet the conditions for performing detection on the detection chip, the control device generates a corresponding control signal, so that the analyzer may send a prompt warning to the user and request the analyzer to be tested or repaired. In the case where it is determined that the analyzer meets the conditions for performing detection on the detection chip, the equipment detection process ends, and the display device (e.g. display screen) of the analyzer displays the equipment name of the analyzer, such as "breast milk analyzer," according to the control signal of the control device.

According to the control signal sent by the control device, the analyzer automatically detects whether it is used for the first time. If the analyzer is determined to be powered on for the first time, a request for acquiring the analysis parameter is sent to the user through the display screen, for example, the analyzer prompts such as "Please insert the parameter storage device" or "Please connect the parameter storage device" may be displayed to the user through the display screen. For example, the parameter storage device may be the parameter storage device <NUM> illustrated in <FIG>. After receiving the request sent by the analyzer, the user inserts the parameter storage device <NUM> into the communication interface <NUM> of the analyzer <NUM> as illustrated in <FIG>, so that the parameter storage device <NUM> is in signal connection with the analyzer <NUM>. For example, the communication interface <NUM> is a B-type USB interface, which can be used for reading and writing data and charging the analyzer <NUM>. After the analyzer is in signal connection with the parameter storage device, the analyzer automatically identifies and reads the corresponding analysis parameter from the parameter storage device, for example, the analysis parameter may be a standard curve reflecting the relationship between the concentration values and the absorbance values of a component in the breast milk to be analyzed. After the analyzer reads and stores the analysis parameter, the algorithm for calculating the analysis data stored in the memory of the control device will be automatically updated to ensure the accuracy and reliability of the analysis data obtained by using the analyzer. After it is determined that the analyzer has obtained the analysis parameter corresponding to the detection chip used for detection, the display screen displays "Analysis parameter has been updated," and after a short stay, the interface of breast milk selection stage is displayed, that is, the subsequent breast milk selection operation stage is entered.

If it is determined that the analyzer is not powered on for the first time after self-inspection, the user will be promoted to check whether the analysis parameter currently obtained corresponds to the detection chip used for detection through the display screen, for example, "Please check detection parameter" will be displayed through the display screen. After checking that the code on the parameter storage device or the code displayed on the display screen is consistent with the code on the detection chip and operating to determine that the analysis parameter currently obtained corresponds to the detection chip used for detection, the user short presses the first switch. After detecting the operation that the user short presses the first switch, the control device of the analyzer generates a control signal to allow the analyzer to jump to a detection selection mode, for example, the user can select the "online" mode or the "offline" mode through the display screen.

For example, the user can select the mode (e.g., move the cursor on the display screen) by short pressing the left-ear switch (e.g., the micro switch adjacent to the micro switch <NUM> illustrated in <FIG>) adjacent to the first switch, and confirm by short pressing the first switch. After detecting the user's short pressing of the first switch, the control device of the analyzer generates a control signal according to the operation, and determines whether to establish signal connection between the analyzer and the mobile terminal such as a mobile phone according to the control signal, thereby achieving the interactive operation between the user and the analyzer. For example, the display screen displays two choices: "offline use" (i.e., an offline mode) or "APP use" (i.e., an online mode).

If the user selects the "offline use", the analyzer will enter the breast milk selection operation stage according to the generated control signal. If the user selects the "APP use," the signal connection between the analyzer and the mobile phone is established through the communication device of the analyzer. In this case, the user needs to open the corresponding APP on the mobile phone, and open the Bluetooth equipment to select the analyzer, or open the WIFI to select the analyzer through an intelligent gateway, so as to establish the signal connection between the mobile phone and the analyzer. If the signal connection between the mobile phone and the analyzer is successfully established, the mobile phone displays that the connection is successful, and the analyzer enters the breast milk selection operation stage according to the generated control signal. If the signal connection between the mobile phone and the analyzer fails, the mobile phone displays that the connection is failed, prompts the user to try the signal connection again, and provides the user with possible reasons for the signal connection failure. If the signal connection between the mobile phone and the analyzer fails for many times, the analyzer allows the user to select, through the display screen, whether to short press the first switch to select the "offline use" mode, that is, whether to choose not to establish the signal connection between the analyzer and the mobile phone. If the user selects the "offline use" mode, the analyzer will enter the breast milk selection operation stage according to the generated control signal.

In the breast milk selection operation stage, the user selects a stage where the substance to be analyzed (i.e., breast milk) belongs. For example, stages include: "colostrum (<NUM>~<NUM> days), transitional milk (<NUM>~<NUM> days), and mature milk (after <NUM> days). " In the "offline use" mode, the above stages are displayed on the display screen of the analyzer, and the user can select the breast milk stage through the left-ear switch and confirm the breast milk stage selection by short pressing the right-ear switch. The analyzer enters the breast milk detection stage according to the generated control signal. In the "APP use" mode, the above stages are displayed on the screen of the mobile phone through the APP of the mobile phone, the user can select on the mobile phone, and the analyzer enters the breast milk detection stage after receiving the control signal generated by the mobile phone.

In the breast milk detection stage, "Please open the cover and put in the chip to start detection" is displayed on the display screen of the analyzer. The user can put the detection chip into the analyzer according to the operating instructions, drip the breast milk into the detection chip, and close the upper cover of the analyzer. In the "APP use" mode, "Please open the cover and put in the chip to start detection" will be displayed synchronously on the screen of the mobile phone, and more detailed legend operation steps will be provided at the same time, which is convenient for the user to operate. The analyzer generates a control signal according to the operation of closing the upper cover of the analyzer. After determining that the detection chip has been placed in the correct position, the breast milk has been dripped into the detection chip sufficiently, and the detection chip has been filled with liquid, the breast milk is detected and analyzed based on the analysis parameter to acquire the analysis data of the breast milk.

After the breast milk is detected and analyzed, the obtained analysis data is played on the display screen of the analyzer. For example, the analysis data may include six indicators, which are automatically displayed in turn on the display screen, and each indicator is displayed on the display screen for about <NUM> seconds. In the process of displaying the analysis data, the user can short press the first switch to switch the automatic carousel mode to a manual page turning mode to view the six indicators. After the six indicators are displayed in turn on the display screen for one time, a downloaded QR code of a mobile APP may be displayed on the display screen, so that the user can acquire the mobile APP by scanning the downloaded QR code. After the downloaded QR code stays on the display screen for a short time, the interactive operation interface of "detect again" and "view the result again" may be displayed on the display screen. The user can select through the left-ear switch and short press the right-ear switch for confirmation. If the user selects "detect again," the analyzer jumps the display page to the interface of the breast milk selection stage interface according to the control signal. If the user selects "view the result again," the analyzer jumps the display page to the page that six indicators are displayed in turn according to the control signal. At this point, all interactive processes of detecting and analyzing the breast milk with the analyzer are completed.

In the "APP use" mode, the analysis data, such as the above-mentioned six indicators, and the analysis result based on the analysis data, such as recommended recipes, diet nursed back to health, etc., may be displayed on the screen of the mobile phone, so that the user can obtain more information related to the analysis data and understand the analysis data more intuitively.

The claimed invention further provides an analyzer, according to appended claim <NUM>.

The analyzer provided by the embodiments of the present disclosure can reduce or avoid the possible adverse effects of the difference in the material of the detection chip on the obtained analysis data of the breast milk to be analyzed by ensuring that the analysis parameter being used is the analysis parameter corresponding to or matched with the detection chip being used in the case of analyzing the substance to be analyzed, thereby improving the accuracy and reliability of the obtained analysis data while achieving the simple and convenient operation of the detection process by using the detection chip, so as to help the user to acquire accurate and reliable analysis results and meet the requirements of the user for self-inspection and self-analysis of the breast milk to be analyzed.

<FIG> is a schematic block diagram of an analyzer provided by some embodiments of the present disclosure.

For example, as illustrated in <FIG>, the analyzer <NUM> includes a detection portion <NUM>, a control device <NUM>, at least one micro switch <NUM>, a display device <NUM>, and at least one communication device <NUM>.

The detection portion <NUM> is configured to perform detection on the detection chip <NUM> and receive detection data of the detection chip <NUM>.

The detection portion <NUM> includes a light source and a dedicated or general-purpose circuit, chip or device. For example, the detection portion <NUM> may include a photoelectric detection circuit board or the like to achieve detection of optical parameters of the breast milk to be analyzed contained in the detection chip <NUM>. For example, the detection portion <NUM> may refer to the corresponding description about the detection portion <NUM> of the analyzer <NUM> in the above-mentioned embodiments.

The control device <NUM> is configured to determine whether an analysis parameter corresponding to the detection chip <NUM> used for detection is obtained and request to obtain the analysis parameter in a case where the analysis parameter is not obtained, and the control device <NUM> is further configured to, in a case of being determined that the analysis parameter is obtained, allow the detection portion <NUM> to perform detection on the detection chip <NUM> to obtain the detection data, and analyze the detection data by using the analysis parameter to obtain analysis data of breast milk to be analyzed contained in the detection chip <NUM>.

For example, the control device <NUM> is further configured to detect an operation applied to a micro switch <NUM> and generate a control signal according to the operation. The control signal is used for the interaction process of the analyzer <NUM>.

For example, the micro switch <NUM> protrudes outwards from a surface of the analyzer <NUM> and has a long strip shape, and the micro switch <NUM> is configured to be capable of being operated in at least two directions. The control device <NUM> is further configured to generate different control signals for interaction according to operations of the micro switch <NUM> in different directions. For example, the micro switch <NUM> may refer to the corresponding description of the micro switch <NUM> of the analyzer <NUM> in the above-mentioned embodiments.

For example, the display device <NUM> is configured to display the analysis data or display different interactive operation interfaces according to the control signal.

For example, the display device <NUM> may be any component with a display function, such as a liquid crystal panel, an OLED panel, an electronic paper display device, etc., and the embodiments of the present disclosure are not limited in this aspect.

For example, the communication device <NUM> includes a communication interface and is configured to allow the analyzer <NUM> to be in signal connection with a parameter storage device or a mobile terminal, such as a second mobile terminal <NUM>, so as to allow the analyzer <NUM> to receive a control signal provided by the second mobile terminal <NUM> or allow the analyzer <NUM> to provide the analysis data to the second mobile terminal <NUM>. For example, the analyzer <NUM> may include two communication devices, wherein the first communication device includes a communication interface used for signal connection with the parameter storage device to obtain the analysis parameter, and the second communication device is used for connection with a mobile terminal to achieve online detection. The two communication devices are of different types, for example, the first communication device is a USB device, which also has a charging function, while the second communication device is a wireless communication device, which does not have a charging function. In the case where the parameter storage device is also a mobile terminal, the analyzer <NUM> may include one communication device, which is used for obtaining the analysis parameter and online detection.

For example, the signal connection between the analyzer <NUM> and the second mobile terminal <NUM> can be established through the communication device <NUM> of the analyzer <NUM> and the communication device <NUM> of the second mobile terminal <NUM>.

For example, the communication device <NUM> and the communication device <NUM> may be dedicated or general-purpose circuits, chips or devices, and the embodiments of the present disclosure are not limited thereto.

For example, the second mobile terminal <NUM> further includes a processor <NUM> and a memory <NUM>, and the memory <NUM> includes one or more computer program modules. The one or more computer program modules are stored in the memory <NUM> and configured to be executed by the processor <NUM>, and the one or more computer program modules include instructions for transmitting the control signal to the analyzer <NUM> or receiving and storing the analysis data provided by the analyzer <NUM>.

For example, the processor <NUM> may be a central processing unit (CPU), a digital signal processor (DSP), or other processing units with data processing capability and/or program execution capability, such as a field programmable gate array (FPGA). For example, the central processing unit (CPU) may be X86 or ARM architecture. The processor <NUM> may be a general-purpose processor or a special-purpose processor, and may control other components in the second mobile terminal <NUM> to perform desired functions.

For example, the memory <NUM> may include any combination of one or more computer program products, which may include various forms of computer-readable storage media, such as the volatile memory and/or nonvolatile memory. For example, the volatile memory may include a random access memory (RAM) and/or cache. The nonvolatile memory may include such as the read-only memory (ROM), hard disk, erasable programmable read-only memory (EPROM), portable compact disk read-only memory (CD-ROM), USB memory, flash memory, or the like. One or more computer program modules may be stored on the computer-readable storage medium, and the processor <NUM> may execute the one or more computer program modules to achieve various functions of the second mobile terminal <NUM>. The computer-readable storage medium may also store various applications and data as well as data used and/or generated by the applications.

For example, the analyzer <NUM> also includes a communication interface, which is located on a surface of the analyzer <NUM> and is configured to establish the signal connection between the analyzer <NUM> and the parameter storage device that stores the analysis parameter, so that the analyzer can read and store the analysis parameter. For example, the communication interface may refer to the communication interface <NUM> illustrated in <FIG>.

For example, the communication interface may be a USB interface or a wireless communication interface.

For example, the communication interface may also be configured to charge the analyzer <NUM>.

For example, the parameter storage device may also be implemented by the second mobile terminal <NUM>, that is, the parameter storage device and the second mobile terminal <NUM> can be the same equipment with a storage function, and the embodiments of the present disclosure are not limited in this aspect.

For example, the detection portion <NUM>, the micro switch <NUM>, the display device <NUM>, and the communication device <NUM> may all be in signal connection with the control device <NUM>.

For example, the control device <NUM> includes a processor <NUM> and a memory <NUM>, and the memory <NUM> includes one or more computer program modules. The one or more computer program modules are stored in the memory <NUM> and configured to be executed by the processor <NUM>, and the one or more computer program modules include instructions for implementing the control method of the analyzer provided by any one of the embodiments of the present disclosure.

For example, the processor <NUM> may be a central processing unit (CPU), a digital signal processor (DSP), or other processing units with data processing capability and/or program execution capability, such as a field programmable gate array (FPGA). For example, the central processing unit (CPU) can be X86 or ARM architecture. The processor <NUM> may be a general-purpose processor or a special-purpose processor, and may control other components in the control device <NUM> or other components in the analyzer <NUM> to perform desired functions.

For example, the memory <NUM> may include any combination of one or more computer program products, which may include various forms of computer-readable storage media, such as the volatile memory and/or nonvolatile memory. For example, the volatile memory may include a random access memory (RAM) and/or cache. The nonvolatile memory may include such as the read-only memory (ROM), hard disk, erasable programmable read-only memory (EPROM), portable compact disk read-only memory (CD-ROM), USB memory, flash memory, or the like. One or more computer program modules may be stored on the computer-readable storage medium, and the processor <NUM> may execute the one or more computer program modules to achieve various functions of the analyzer <NUM>. The computer-readable storage medium may also store various applications and data as well as data used and/or generated by the applications. The specific functions and technical effects of the analyzer <NUM> may refer to the above description about the control method of the analyzer, and details are not described herein again.

It should be noted that, in the embodiments of the present disclosure, the control device <NUM> may be hardware, software, firmware, and any feasible combination thereof. For example, the control device <NUM> may be a dedicated or general circuit, chip or device, or a combination of a processor and a memory. The embodiments of the present disclosure do not limit the specific implementation form of the control device <NUM>.

For example, the functions or technical effects of the analyzer provided by the embodiments of the present disclosure may refer to the corresponding descriptions of the control method of the analyzer in the above embodiments, and details are not described herein again.

It should be noted that the analyzer <NUM> may also include other components, such as a supporting portion, a photoelectric signal conversion circuit, etc. These components may adopt existing conventional components, and details are not described herein again.

At least one embodiment of the present disclosure further provides a detection system, which includes at least one detection chip and the analyzer provided by any one of the embodiments of the present disclosure, for example, may include the analyzer <NUM> or the analyzer <NUM> in the above embodiments.

For example, at least one detection chip can be built into the analyzer when in use.

At least one embodiment of the present disclosure further provides a detection system, which includes an analyzer, at least one detection chip, and a parameter storage device provided by any one of the embodiments of the present disclosure, for example, may include the analyzer <NUM> or the analyzer <NUM>, the detection chip <NUM> or the detection chip <NUM>, and the parameter storage device <NUM> in the above embodiments. The parameter storage device stores the analysis parameter, and is configured to be in signal connection with the analyzer through the communication interface of the analyzer, so that the analyzer can read and store the analysis parameter.

For example, the parameter storage device provided by the embodiments of the present disclosure can be any product or component with a storage function, such as a USB flash memory mover, a hard disk, a floppy disk, an optical disk, a mobile phone, a tablet computer, a notebook computer, a digital photo frame, a navigator, a contact IC card, a non-contact IC card, etc. The embodiments of the present disclosure are not limited thereto.

The present invention further provides a storage medium for storing non-transitory computer readable according to appended claim <NUM>.

<FIG> is a schematic diagram of a storage medium provided by some embodiments of the present disclosure.

As illustrated in <FIG>, the storage medium <NUM> is used to store non-transitory computer readable instructions <NUM>. Upon the non-transitory computer readable instructions <NUM> being executed by a computer, one or more steps in the control method of the analyzer according to the above-described embodiments can be performed.

For example, the storage medium <NUM> may be the memory <NUM> in the analyzer <NUM> illustrated in <FIG>, and the corresponding description about the memory <NUM> in the analyzer <NUM> illustrated in <FIG> may be referred to, which will not be repeated herein.

For the present disclosure, the following statements should be noted:.

Claim 1:
A control method of an analyzer for analyzing breast milk, wherein the analyzer (<NUM>) is configured to perform detection on a detection chip (<NUM>) based on an analysis parameter, the detection chip (<NUM>) is configured to contain the breast milk to be analyzed for detection and analysis, and the control method comprises:
determining whether the analyzer obtains the analysis parameter corresponding to the detection chip used for detection (S110) by a control device of said analyzer;
requesting and obtaining the analysis parameter in a case of being determined that the analyzer does not obtain the analysis parameter (S120); and
performing detection on the detection chip and analyzing the breast milk to be analyzed contained in the detection chip by using the analysis parameter to obtain analysis data of the breast milk to be analyzed in a case of being determined that the analyzer obtains the analysis parameter (S130), in the process of detecting the detection chip by using the analysis parameter, the concentration values of different components in the breast milk to be analyzed are detected and analyzed by light with different wavelengths, so that the concentration values of the components in the breast milk to be analyzed are detected and analyzed simultaneously by light with different wavelengths.