CN116015989A - Method, device and storage medium for processing power consumption of detection device - Google Patents

Abstract

The application relates to a detection device power consumption processing method, a detection device and a storage medium. The method comprises the following steps: the method comprises the steps that the current state of detection equipment bound with target equipment is obtained, the detection equipment obtains detection information for detecting authenticity of the detection equipment through interaction with a cloud server, and a two-dimensional code for a user to scan is generated; and controlling the detection equipment to enter a low-power consumption mode from an operation mode according to the current state meeting preset conditions, wherein the low-power consumption mode comprises the step of carrying out preset low-power consumption processing on the detection equipment. According to the scheme, the power consumption of the detection equipment can be reduced, and the use duration is prolonged.

Description

Method, device and storage medium for processing power consumption of detection device

Technical Field

The application relates to the technical field of the internet of things, in particular to a method, a device and a storage medium for processing power consumption of detection equipment.

Background

At present, the medical industry develops rapidly, and various medical products for meeting the medical requirements of users appear.

In the related art, some detection devices are presented, which can be used for detection of different scenes or uses. However, the related art detection device has problems of high power consumption and long use time.

Disclosure of Invention

In order to solve or partially solve the problems existing in the related art, the application provides a method, a device and a storage medium for processing power consumption of detection equipment, which can reduce the power consumption of the detection equipment and improve the service time.

The first aspect of the present application provides a method for processing power consumption of a detection device, including:

the method comprises the steps that the current state of detection equipment bound with target equipment is obtained, the detection equipment obtains detection information for detecting authenticity of the detection equipment through interaction with a cloud server, and a two-dimensional code for a user to scan is generated;

and controlling the detection equipment to enter a low-power consumption mode from an operation mode according to the current state meeting preset conditions, wherein the low-power consumption mode comprises the step of carrying out preset low-power consumption processing on the detection equipment.

In an embodiment, the performing a preset low power consumption process on the detection device includes: and carrying out preset low-power consumption processing on the detection equipment, wherein at least one of the following steps is carried out on the detection equipment: and controlling the detection equipment to interrupt communication connection with the cloud server, controlling the chip in the main board of the detection equipment to wake up regularly to access the cloud server, and controlling the detection equipment to refresh and display the two-dimensional code according to a preset period.

In an embodiment, the controlling the detection device to enter the low power consumption mode from the operation mode according to the current state meeting a preset condition includes:

and controlling the detection equipment to enter a low-power consumption mode from an operation mode according to the current state that the detection equipment is initialized and the detection information is acquired from the cloud server and the two-dimensional code is generated.

In an embodiment, the detecting device obtains, through interaction with the cloud server, verification information for detecting authenticity of the detecting device, including:

the detection equipment acquires URL information of at least two-dimension codes for detecting authenticity of the detection equipment through interaction with the cloud server so as to refresh and display the two-dimension codes according to a preset period.

In an embodiment, in the interaction process between the detection device and the cloud server, the preset information is selected for interactive transmission.

In an embodiment, the preset information sent by the detection device to the cloud server includes: detecting a device ID of the device and installation information that the device has been installed to the target device;

the step of receiving the preset information returned by the cloud server by the detection equipment comprises the following steps: the method comprises the steps of presetting website information and detection equipment authenticity identification information, wherein the detection equipment authenticity identification information comprises equipment IDs of detection equipment and target equipment and signature fields for describing the authenticity of the detection equipment.

A second aspect of the present application provides a detection apparatus:

the detection equipment comprises a box body, a box cover, a main board and a display; an installation space is formed between the box cover and the box body, the main board is positioned in the installation space, the main board is electrically connected with the display, and the display is positioned on the surface of the box cover;

the detection equipment is bound with the target equipment, acquires detection information for detecting authenticity of the detection equipment through interaction with the cloud server, and generates a two-dimensional code for a user to scan the code and displays the two-dimensional code on the display;

the main board is used for acquiring the current state of the detection equipment bound with the target equipment, and controlling the detection equipment to enter a low-power-consumption mode from an operation mode according to the current state of the detection equipment meeting preset conditions, wherein the low-power-consumption mode comprises the step of carrying out preset low-power-consumption processing on the detection equipment.

In an embodiment, the main board performs a preset low power consumption process on the detection device, including:

the main board performs preset low-power consumption processing on the detection equipment, wherein the preset low-power consumption processing comprises at least one of the following steps: and controlling the detection equipment to interrupt communication connection with the cloud server, controlling the chip in the main board of the detection equipment to wake up regularly to access the cloud server, and controlling the detection equipment to refresh and display the two-dimensional code according to a preset period.

In one embodiment, the display is an ink screen display, and/or,

the chip in the main board adopts a low-power consumption chip.

In one embodiment, the chips in the motherboard are powered by a battery cell, and/or,

and a PMOS switch circuit is arranged in the circuit of the main board.

In an embodiment, the display adopts a local refreshing mode when refreshing and displaying the two-dimensional code.

A third aspect of the present application provides an electronic device, comprising:

a processor; and

a memory having executable code stored thereon which, when executed by the processor, causes the processor to perform the method as described above.

A fourth aspect of the present application provides a computer readable storage medium having stored thereon executable code which, when executed by a processor of an electronic device, causes the processor to perform a method as described above.

The technical scheme that this application provided can include following beneficial effect:

according to the technical scheme, the detection equipment can acquire the current state of the detection equipment bound with the target equipment, acquire the detection information for detecting the authenticity of the detection equipment through interaction with the cloud server, and generate the two-dimensional code for a user to scan, so that the authenticity of the detection equipment can be conveniently detected, and the authenticity of the bound target equipment can be obtained according to the authenticity detection of the detection equipment; in addition, according to the fact that the current state of the detection equipment meets preset conditions, the detection equipment is controlled to enter a low-power-consumption mode from an operation mode, wherein the low-power-consumption mode comprises the step of carrying out preset low-power-consumption processing on the detection equipment. After the preset condition is met, the detection equipment is controlled to enter a low-power-consumption mode from an operation mode, and the preset low-power-consumption processing is carried out on the detection equipment, so that the resource consumption can be reduced, the power consumption of the detection equipment is reduced, and the service time of the detection equipment is prolonged.

Further, when the detection device interacts with the cloud server, at least two-dimension code URL information for detecting authenticity of the detection device can be obtained simultaneously so as to refresh and display the two-dimension code according to a preset period. Through once only obtaining a plurality of two-dimensional code URL information and storing to local, just can be with the interaction of high in the clouds server, just can refresh the display according to a plurality of two-dimensional code URL information directly from local, can refresh according to predetermineeing the cycle moreover, need not to continuously refresh the display, also further reduced the consumption of check out test set.

Furthermore, a local refreshing mode can be adopted when the two-dimension code is refreshed and displayed, the display is an ink screen display, a chip in the main board is a low-power chip, a chip in the main board is powered by a battery cell, and a PMOS (P-channel metal oxide semiconductor) switch circuit is arranged in a circuit of the main board. Through comprehensive use in various modes, the power consumption of the detection equipment is further reduced, and the use time of the detection equipment is prolonged.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the application.

Drawings

The foregoing and other objects, features and advantages of the application will be apparent from the following more particular descriptions of exemplary embodiments of the application as illustrated in the accompanying drawings wherein like reference numbers generally represent like parts throughout the exemplary embodiments of the application.

Fig. 1 is a schematic flow chart of a method for processing power consumption of a detection device according to an embodiment of the present application;

FIG. 2 is a flow chart illustrating a method for detecting device power consumption processing according to another embodiment of the present application;

fig. 3 is an external schematic view of a detection apparatus shown in an embodiment of the present application;

FIG. 4 is a schematic rear view of a detection device shown in an embodiment of the present application;

FIG. 5 is a schematic diagram of an application of the detection device shown in an embodiment of the present application;

fig. 6 is a schematic structural diagram of a detection apparatus shown in an embodiment of the present application;

fig. 7 is a schematic structural diagram of an electronic device according to an embodiment of the present application.

Detailed Description

Embodiments of the present application will be described in more detail below with reference to the accompanying drawings. While embodiments of the present application are shown in the drawings, it should be understood that the present application may be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art.

The terminology used in the present application is for the purpose of describing particular embodiments only and is not intended to be limiting of the present application. As used in this application and the appended claims, the singular forms "a," "an," and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It should also be understood that the term "and/or" as used herein refers to and encompasses any or all possible combinations of one or more of the associated listed items.

It should be understood that although the terms "first," "second," "third," etc. may be used herein to describe various information, these information should not be limited by these terms. These terms are only used to distinguish one type of information from another. For example, a first message may also be referred to as a second message, and similarly, a second message may also be referred to as a first message, without departing from the scope of the present application. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present application, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

In the related art, some detection devices are presented, which can be used for detection of different scenes or uses. However, the related art detection device has problems of high power consumption and long use time. In order to solve the problems, the application provides a power consumption processing method of detection equipment, which can reduce the power consumption of the detection equipment and improve the service time.

The following describes the technical scheme of the embodiments of the present application in detail with reference to the accompanying drawings.

Fig. 1 is a flow chart of a method for processing power consumption of a detection device according to an embodiment of the present application.

Referring to fig. 1, the method of the present application may include:

s101, acquiring the current state of detection equipment bound with target equipment, acquiring detection information for detecting authenticity of the detection equipment through interaction with a cloud server by the detection equipment, and generating a two-dimensional code for a user to scan.

The detecting device may obtain, through interaction with the cloud server, verification information for detecting authenticity of the detecting device itself, including: the detection equipment acquires URL information of at least two-dimension codes for detecting authenticity of the detection equipment through interaction with the cloud server, so that the two-dimension codes can be refreshed and displayed according to a preset period.

The display adopts an ink screen display, and/or the chip in the main board adopts a low-power consumption chip. The ink screen display adopts static ink, and consumes no power during display and only consumes power during refresh.

The chips in the main board are powered by adopting the battery core, and/or a PMOS switch circuit is arranged in the circuit of the main board. The battery core directly supplies power to the chip, compared with a common power consumption product, the battery core can omit intermediate voltage stabilization or other operations on voltage processing, so that the power consumption of the part can be reduced. After the PMOS switch circuit is arranged, leakage current consumption conditions of all components of the detection device and peripheral circuits of the detection device are avoided, static power consumption of all components in a standby mode can be fundamentally solved, and accordingly, the power consumption of the PMOS switch circuit is only increased, but the static power consumption of the PMOS switch circuit is far lower than that of the components and the peripheral circuits of the components under the condition that the components are not turned off.

S102, controlling the detection equipment to enter a low-power-consumption mode from an operation mode according to the current state meeting preset conditions, wherein the low-power-consumption mode comprises the step of carrying out preset low-power-consumption processing on the detection equipment.

Wherein, preset low power consumption processing is carried out to the detection equipment, includes: performing preset low-power consumption processing on the detection equipment, wherein the preset low-power consumption processing comprises at least one of the following steps: the method comprises the steps of controlling the detection equipment to be in communication connection with a cloud server, controlling a chip in a main board of the detection equipment to be awakened at regular time to access the cloud server, and controlling the detection equipment to refresh and display the two-dimensional code according to a preset period.

The operation mode of the detection device may include an operation mode and a low power consumption mode. Wherein the low frequency use is controlled in the run mode. In this mode of operation, all components of the detection device are operating normally. Detecting that the equipment is connected with the cloud server when networking is performed, wherein the equipment belongs to an operation mode; and the detection device is in a low power consumption mode when the detection device is not contacted with the cloud server and only needs to be refreshed.

The method comprises the steps that the detection equipment is controlled to enter a low-power consumption mode from an operation mode according to the current state, wherein the detection equipment is initialized and the detection information is acquired from a cloud server and a two-dimensional code is generated.

Because the cloud server can transmit a plurality of two-dimension code URL information to the detection equipment for storage at one time, the detection equipment can reduce the frequency of acquiring the two-dimension code URL information with the cloud server, the two-dimension code URL information stored locally can be directly utilized for refreshing and displaying the two-dimension code, and the two-dimension code URL information can be refreshed according to a preset period, so that the power consumption can be reduced.

When the two-dimensional code is refreshed and displayed, a local refreshing mode can be adopted, and compared with a global refreshing method in the related art, the smaller the proportion of the screen picture occupied by the local refreshing is, the shorter the power supply on time is, and the power consumption is correspondingly reduced.

According to the embodiment, the detection equipment can acquire the current state of the detection equipment bound with the target equipment, acquire the detection information for detecting the authenticity of the detection equipment through interaction with the cloud server, and generate the two-dimensional code for a user to scan the code, so that the authenticity of the detection equipment can be conveniently detected, and the authenticity of the bound target equipment can be simultaneously known according to the authenticity detection of the detection equipment; in addition, the detection equipment is controlled to enter a low-power-consumption mode from an operation mode according to the fact that the current state of the detection equipment meets preset conditions, wherein the low-power-consumption mode comprises the step of carrying out preset low-power-consumption processing on the detection equipment. After the preset conditions are met, the detection equipment is controlled to enter a low-power-consumption mode from an operation mode, and the preset low-power-consumption processing is carried out on the detection equipment, so that the resource consumption can be reduced, the power consumption of the detection equipment is reduced, and the service time of the detection equipment is prolonged.

Fig. 2 is a flow chart illustrating a method for processing power consumption of a detection device according to another embodiment of the present application.

Before introducing the power consumption processing method of the detection device of the present application, the detection device provided in the embodiment of the present application is introduced, and the power consumption processing method of the present application may be applied to the detection device.

The detection equipment comprises a box body, a box cover, a main board and a display; an installation space is formed between the box cover and the box body, the main board is positioned in the installation space, the main board is electrically connected with the display, and the display is positioned on the surface of the box cover; the detection equipment is bound with the target equipment, acquires detection information for detecting authenticity of the detection equipment through interaction with the cloud server, and generates a two-dimensional code for a user to scan the code and displays the two-dimensional code on the display; the main board is used for acquiring the current state of the detection equipment bound with the target equipment, and controlling the detection equipment to enter a low-power-consumption mode from an operation mode according to the current state of the detection equipment meeting preset conditions, wherein the low-power-consumption mode comprises the step of carrying out preset low-power-consumption processing on the detection equipment.

The detection device of the present application can be seen in fig. 3, 4 and 6. The detection device in this application may be referred to as an authentication cartridge. The verification box can be externally connected with target equipment, and the target can be the equipment of the Internet of things. Referring to fig. 6, the inspection apparatus 60 may include a case body 61, a case cover 62, an anti-disassembly inspection assembly 63, a main board 64, a communication module 65, and a display 66, wherein the display 66 may be a low power consumption display, and the main board 64 may be an internet of things main board.

The box cover 62 may be connected to the box 61, for example, may be detachably connected to the box 61, and forms an installation space with the box 61. The main board 64 and the communication module 65 are located in the installation space. A display 66 is located on the surface of the cover 62. The box 61 is connected to the target device in a predetermined manner.

The main board 64 may be disposed in an installation space formed between the box cover 62 and the box body 61, and connected to the anti-disassembly component 63, for example, may be electrically connected. The main board 64 can establish communication connection with the cloud server through the communication module 65, obtain the inspection information and the configuration information returned by the cloud server, generate the two-dimension code for the user to scan the code according to the inspection information, and display the two-dimension code on the display 66. In addition, the motherboard 64 may wake up related components, such as a chip of the motherboard 64, periodically according to configuration information returned by the cloud server, and may refresh the two-dimensional code of the display 66 periodically according to the returned inspection information.

The motherboard 64 is also used to detect an initialization configuration of the device 60. The motherboard 64 may upload various data information of the detection device 60 to the cloud server, for example, may upload initialization information to the cloud server, and receive the verification information returned by the cloud server for verifying that the detection device 60 is true or false. Wherein the initialization information includes at least a device ID of the detection device 60 and installation information that the detection device 60 has been installed to the target device. Further, the initialization information may include parameters of a device ID of the detection device 60, GPS (Global Positioning System ) location information, installation information that the detection device 60 has been installed to the target device, time information, and the like. The cloud server assigns a device code to the detection device 60 according to the initialization information received from the detection device 60, where the device code may be a unique identification code of the detection device 60. The cloud server further binds the device code of the detection device 60 with the external target device of the detection device 60 according to the obtained target device information of the external target device of the detection device, generates verification information for detecting authenticity of the detection device 60, and sends the verification information to the main board 64, so as to verify authenticity of the detection device 60, and can obtain whether the external target device passes genuine authentication according to authenticity of the detection device 60. Wherein the target device information of the target device includes at least a device ID of the target device. The verification information may be, for example, two-dimensional code URL (uniform resource locator, uniform resource locator system) information. The two-dimension code URL comprises preset website information and detection equipment authenticity identification information, wherein the detection equipment authenticity identification information comprises equipment IDs of detection equipment and target equipment, a time stamp describing the validity period of the two-dimension code and a signature field used for describing the authenticity of the detection equipment. The preset website information can be stored in a preset path in advance, and the preset website information and the identification information of the detection equipment can be combined to generate the two-dimension code URL.

The signature field comprises a binding relation between the detection device and the target device, genuine information of the target device, and one or a combination of the following items: GPS information of the detection device, association mechanism information associated with the detection device or the target device. Therefore, after the subsequent user scans the two-dimensional code, the information in the signature field can be displayed for the user to identify authenticity and know related information. The signature field can be set by related personnel in the cloud server according to the requirements.

The detection device 60 stores the two-dimensional code URL information locally, and can generate a two-dimensional code according to the two-dimensional code URL information and display the two-dimensional code on the display 66 for the user to scan the code for verification, so as to complete the initialization configuration of the detection device 60.

The cloud server may also send configuration information (operation configuration parameter information) of the detection device 60 to the motherboard 64 for use in periodically waking up related components.

The anti-disassembly detecting component 63 may be mounted on the box cover 62, for example, may be embedded on the back of the box cover 62. The anti-disassembly detecting assembly 63 is used to check whether the detecting device 60 is still mounted on an external target device, such as an internet of things device, i.e., to check whether the verification cartridge is disassembled. The detection device 60 can be externally connected to the target device through the anti-disassembly detection component 63, and the anti-disassembly detection component 63 is electrically connected with the main board 64.

The communication module 65 may be a 4G module assembly or a 5G module assembly, which is not limited in this application. In this embodiment, the communication module 65 may be a 4G communication module, for example, a 4G CAT1 module, and may be a mobile network in different operations.

Referring to fig. 4, wherein the disassembly prevention detecting assembly 63 may include a key part 631 disposed at the back of the cover 62 of the detecting device 60, the key part 631 is in a sprung state before being mounted to the target device, and when the detecting device 60 is mounted to the target device surface, the key part 631 at the back of the detecting device 60 is in a pressed state, indicating that the detecting device 60 has been mounted to the target device. If the detection device 60 is detached from the target device, the button part 631 will return to the sprung state, and if the main board 64 detects the state change, a detachment alarm message is sent to the cloud server in the background to prompt the detection device 60 to be detached. The detachment alarm information may include detachment information of the detection device 60, including, for example, GPS information, detachment status information, detachment time information, and the like of the detection device 60.

Further, in order to more stably mount the sensing device 60 to the target device, the anti-disassembly sensing assembly 63 may further include a sized adhesive member 632 provided at the back of the cover 62 of the sensing device at the same time, and further adhered to the target device by the adhesive member 632 when the sensing device 60 is mounted to the surface of the target device. The adhesive parts 632 may be provided in 1 or 2 or more, and when provided in 2, may be located at both sides of the key part 631, respectively. The size of the adhesive means 632 can be set as desired.

Further, referring to fig. 3, in order to more stably mount the detecting device 60 to the target device (see fig. 5), the anti-disassembly detecting assembly 63 may further include a strap 633, a snap structure 634 may be provided on the strap 633, the detecting device 60 is tied to the target device by the strap 633 when the detecting device 60 is mounted to the surface of the target device, the strap 633 may be adjusted in length, and then the detecting device 60 is tied to the target device by the snap structure 634. It should be noted that, instead of the fastening structure 634, a velcro may be provided to connect two ends of the binding band, or the fastening structure 634 and the velcro may be provided at the same time. The magic tape, also called as sticking buckle tape, is a commonly used connecting auxiliary material and two sides of a molecule mother.

It can be found that the detection device, namely the verification box, of the application does not influence the original structure of the external device. The verification box is provided with the functions of disassembly prevention, verification, display and the like. When the cloud server sets the inspection information, the information such as the association attribute, the association mechanism, the association equipment and the like of the verification box can be set, so that the information can be displayed for the user to identify authenticity and know related information after the user scans the two-dimensional code. According to the method, the device and the system, the verification box enters the low-power mode from the operation mode through the post-control verification box meeting the preset condition, the detection equipment is subjected to the preset low-power processing, so that the resource consumption can be reduced, the power consumption of the verification box is reduced, and the service time of the verification box is prolonged. By utilizing the verification box, the identification and detection problems of medical equipment counterfeit products in the medical industry can be solved, potential damage to consumers can be reduced, and the recognition of genuine products of users can be molded.

Referring to fig. 2, the method of the present application may include:

s201, the detection equipment is externally connected with the target equipment, communication connection is established between the detection equipment and the cloud server, initialization information is sent to the cloud server, and the detection equipment is manufactured by adopting low-power consumption components.

The detection device in this example may be a verification box and the target device may be a medical product device.

The detection device may include a case body, a case cover, an anti-disassembly detection assembly, a main board, a communication module, and a display. In order to reduce the power consumption of the detection device, the partial component parts can be manufactured by adopting low-power-consumption parts.

Wherein the display is a low power display, such as an ink screen display.

The ink screen display adopts static ink, and consumes no power during display and only consumes power during refresh. The screen may generally display a two-dimensional code and a box number. In the embodiment of the application, the ink screen display is selected, and the ink screen display generally only supports two-color or three-color display, so that the power consumption of the ink screen display is low in various displays. Electronic ink is a liquid material in which are suspended a number of microcapsules of a size comparable to the diameter of a human hair, each microcapsule consisting of positively charged particles and negatively charged particles. The electronic ink can be printed on the surface of glass, fiber or even paper medium by adopting a certain process, and the carriers carrying the electronic ink are also subjected to special treatment, and a simple pixel control circuit is constructed for each pixel in the carriers, so that the electronic ink can display required images and characters.

In addition, the ink screen can still keep the last refreshing content under the condition of power failure, the power supply of the ink screen is only turned on when the refreshing display task exists, the refreshing display is refreshed, then the refreshing is completed, the refreshing is turned off immediately, and the power consumption time depends on the time used for the refreshing task.

The chip in the main board can be a low-power chip. For example, some chips can achieve very low power consumption, and can reach a single digit uA level at the lowest.

Wherein the power management of the verification box can be set to reduce the power consumption. For example, the chips in the motherboard are powered by a battery cell, and/or PMOS switch circuits are provided in the circuits of the motherboard.

Setting power management of the verification box to reduce power consumption may include:

1) The battery core directly supplies power to the chip, compared with a common power consumption product, the battery core can omit intermediate voltage stabilization or other operations on voltage processing, so that the power consumption of the part can be reduced.

2) For displays, communication modules and the like of the verification box, a PMOS (positive channel Metal Oxide Semiconductor, n-type substrate, p-channel metal oxide semiconductor field effect transistor) switch circuit is added from the input side of the battery core, so that in the standby mode, leakage current consumption conditions of all components of the verification box and peripheral circuits of the components are avoided, static power consumption of all the components in the standby mode can be fundamentally solved, and accordingly, the power consumption of the PMOS switch circuit is only increased, but the static power consumption of the PMOS switch circuit is far lower than that of the components and the components in the condition that the periphery of the components is not turned off.

The circuit in the main board can be a CMOS (Complementary Metal Oxide Semiconductor, complementary metal-oxide-semiconductor integrated) circuit as far as possible, and has the greatest advantages of micro power consumption (static power consumption is almost zero), and the secondary advantages of large output logic level swing, thus having strong anti-interference capability.

In the step S201, the detection device and the cloud server establish communication connection through the communication module, and send initialization information to the cloud server, where the initialization information at least includes a device ID of the detection device and installation information that the detection device has been installed to the target device. Further, the initialization information may include parameters of a device ID of the detection device, GPS location information, installation information that the detection device 60 has been installed to the target device, time information, and the like.

S202, the cloud server binds the detection equipment with the target equipment according to the received initialization information and the acquired target equipment information of the target equipment externally connected with the detection equipment, generates verification information for verifying authenticity of the detection equipment, and sends at least two pieces of verification information to the detection equipment.

The cloud server receives initialization information sent by the detection device, and assigns a device code to the detection device, wherein the device code can be a unique identification code of the detection device. The cloud server further binds the equipment code of the detection equipment with the target equipment externally connected with the detection equipment according to the acquired target equipment information of the target equipment externally connected with the detection equipment, generates the detection information for detecting the authenticity of the detection equipment and sends the detection information to the detection equipment, and is used for verifying whether the externally connected target equipment passes the genuine authentication according to the authenticity of the detection equipment. The verification information may be, for example, two-dimensional code URL (uniform resource locator, uniform resource locator system) information. The two-dimension code URL comprises preset website information and detection equipment authenticity identification information, wherein the detection equipment authenticity identification information comprises equipment IDs of detection equipment and target equipment, a time stamp describing the validity period of the two-dimension code and a signature field used for describing the authenticity of the detection equipment. The preset website information can be stored in a preset path in advance, and the preset website information and the identification information of the detection equipment can be combined to generate the two-dimension code URL. The signature field comprises a binding relation between the detection device and the target device, genuine information of the target device, and one or a combination of the following items: GPS information of the detection device, association mechanism information associated with the detection device or the target device. Therefore, after the subsequent user scans the two-dimensional code, the information in the signature field can be displayed for the user to identify authenticity and know related information. The signature field can be set by related personnel in the cloud server according to the requirements.

In addition, the verification information can also be provided with information such as the association attribute, association mechanism, association equipment and the like of the detection equipment. Therefore, after the subsequent user scans the two-dimensional code, the information can be displayed for the user to identify the authenticity and know the related information.

The cloud server can also send configuration information (operation configuration parameter information) of the detection equipment to the detection equipment for periodically waking up related components.

And S203, the detection equipment receives the detection information sent by the cloud server and stores the detection information in the local area, and a two-dimensional code for a user to scan is generated according to the detection information and is displayed on a display of the detection equipment.

The detection equipment receives the verification information for verifying the authenticity of the detection equipment and the related configuration information sent by the cloud server, generates a two-dimensional code for a user to scan the code according to the verification information, displays the two-dimensional code on a display, and completes the initialization configuration of the verification box.

It should be noted that, in addition to the initialization stage, the detection device may also acquire the cloud server inspection information from the cloud server at regular time.

In the interaction process of the detection equipment and the cloud server, the method and the device can control the size of the transmission data of the detection equipment and the cloud server and the transmission interaction frequency, and set a low-frequency use mode, so that power consumption is reduced.

For example, the number of inspection information returned by the cloud server and the interval duration for acquiring the inspection information may be set. For example, the cloud server can transmit a plurality of two-dimension code URL information to the detection device for storage at one time, so that the detection device can reduce the frequency of acquiring the two-dimension code URL information with the cloud server. That is, the cloud server can transmit a plurality of two-dimensional code information to the detection device for storage at one time, so that the detection device can reduce the times of acquiring the two-dimensional code information with the cloud server. For example, 10 two-dimensional codes are sent to the detection equipment for storage at a time, and the detection equipment can be used in ten days later.

In the embodiment of the application, in the interaction process of the detection device and the cloud server, the preset information can be selected for interactive transmission. For example, the detection device and the cloud server only transmit core information. For example, the preset information sent by the detection device to the cloud server includes: detecting a device ID of the device and installation information that the device has been installed to the target device; the step of receiving preset information returned by the cloud server by the detection equipment comprises the following steps: the method comprises the steps of presetting website information and detection equipment authenticity identification information, wherein the detection equipment authenticity identification information comprises equipment IDs of detection equipment and target equipment and signature fields for describing the authenticity of the detection equipment.

The method can also adopt a compression mode for transmission so as to reduce the content and the size of data information to be transmitted. After data compression processing, the transmission is faster, the transmission time is reduced, and the use power consumption is also reduced.

In this embodiment of the present application, the communication between the detection device and the cloud server includes multiple types of communication, including, for example, the following 4 types but not limited thereto:

1) At the time of initialization, initialization information of the detection device is transmitted, including a unique ID code of the detection device, a device code, and the like.

2) And transmitting configuration information of the cloud server to the detection equipment.

3) And transmitting the related information of the timing wake-up and detachment interface and the reported GPS information.

4) And transmitting detection information such as two-dimension code URL information sent by the cloud server.

In the transmission process of the information, only the characteristic field can be transmitted, and the same field is spliced, so that the network transmission time length is reduced. In addition, from the aspect of security, an authentication mechanism can be defined for the network interfaces of the detection device and the cloud server, and the related network interfaces can be accessed after authentication.

S204, the detection device acquires the current state of the detection device bound with the target device.

The operation mode of the detection device may include an operation mode and a low power consumption mode. Wherein the low frequency use is controlled in the run mode. In this mode, all components of the detection device are operating normally. Detecting that the equipment is connected with the cloud server when networking is performed, wherein the equipment belongs to an operation mode; and the detection device is in a low power consumption mode when the detection device is not contacted with the cloud server and only needs to be refreshed.

The motherboard of the detection device may monitor and obtain the current state of the detection device.

S205, controlling the detection equipment to enter a low-power-consumption mode from an operation mode according to the fact that the current state meets preset conditions, wherein the low-power-consumption mode comprises the step of carrying out preset low-power-consumption processing on the detection equipment.

Wherein, preset low power consumption processing is carried out to the detection equipment, includes: performing preset low-power consumption processing on the detection equipment, wherein the preset low-power consumption processing comprises at least one of the following steps: the method comprises the steps of controlling the detection equipment to be in communication connection with a cloud server, controlling a chip in a main board of the detection equipment to be awakened at regular time to access the cloud server, and controlling the detection equipment to refresh and display the two-dimensional code according to a preset period.

The detection device can be initialized according to the current state of the detection device, and the detection device can acquire the detection information from the cloud server and generate the two-dimensional code, so that the detection device is controlled to enter a low-power consumption mode from an operation mode.

The detection device is in a low power consumption mode when the detection device is not contacted with the background server and only needs to be refreshed. In the low power consumption mode, other components except the core component of the detection equipment can be kept in normal operation, and the other components can be in a closed mode so as to improve the endurance time of the detection equipment. That is, the detection device is optimized for software power consumption, simply speaking, the detection device can work less and the detection device can sleep.

The detection equipment is controlled to be in communication connection with the cloud server, so that power consumption of the detection equipment can be reduced. Because the detection equipment does not need to send data to or acquire data from the cloud server any more, the connection with the cloud server is not needed to be maintained, the use power consumption of the detection equipment can be reduced, and the low power consumption processing of one mode of the detection equipment is realized.

The chip in the main board of the timing wake-up detection device is controlled to access the cloud server, so that the power consumption of the detection device can be reduced. The method and the device can wake related components in the detection equipment at regular time according to the configuration information, for example, a chip in a main board of the detection equipment at regular time wakes up to access the cloud server. For example, controlling a chip in a main board of the detection device to enter a sleep mode, and waking up the chip in the main board of the detection device to access the cloud server after reaching a preset time length or timing. The chip in the main board enters the sleep mode, and after the chip in the main board of the detection device is awakened at regular time, the chip in the main board accesses the cloud server, so that the resource consumption of the chip in the main board can be reduced, and the low-power consumption processing of one mode of the method is realized. For example, in the standby mode, the control chip enters the sleep mode, only the operation of the CPU Clock and the anti-disassembly key Clock is guaranteed, and the RTC (real_time Clock) always operates in the deep sleep mode, so that the chip in the main board does not need to keep the operation mode after entering the sleep mode, the power consumption in the sleep mode is greatly reduced, the cloud service is accessed after waiting for a regular wake-up, and the normal use power consumption is generated at the moment. Wherein the RTC is an integrated circuit, commonly referred to as a clock chip. The real-time clock chip is one of the most widely used consumer electronic products in daily life. The real-time clock chip mainly adopts a crystal oscillator with higher precision as a clock source. Some clock chips may be powered by a battery in order to operate when the main power supply is powered down.

The detection device is controlled to refresh and display the two-dimensional code according to a preset period, so that the power consumption of the detection device can be reduced. The detection device can refresh the display at regular time according to the configuration information, namely refresh the display two-dimensional code according to a preset period. In the low-power consumption mode, the control detection equipment regularly refreshes and displays the two-dimensional code, namely, the dynamic two-dimensional code is used. Because the detection device locally stores a large number of two-dimensional codes, the detection device can locally refresh the two-dimensional codes periodically. For example, the present application may set a set period, such as refreshing the two-dimensional code again every two days. Because the detection equipment does not need the display to continuously refresh, for example, the two-dimension code is refreshed in real time, the two-dimension code is only refreshed and displayed at intervals, and therefore the use power consumption of the detection equipment can be reduced, and the low power consumption processing of one mode of the detection equipment is realized. In addition, the static code can be changed into the dynamic code by regularly refreshing and displaying the two-dimensional code. Since the static code is defective and easy to forge, the two-dimensional code is refreshed periodically, so that the forge can be avoided and the safety of the two-dimensional code can be improved even if the dynamic two-dimensional code is used.

In addition, the present application may employ a local refresh approach for detecting refresh policies on a display of a device. Compared with the global refreshing method in the related art, the local refreshing is to display only the content position, and the smaller the proportion of the screen picture occupied by the local refreshing is, the shorter the power on time is, and the power consumption is correspondingly reduced. The screen of the whole display is relatively large, and the partial refreshing is to display only the content position, so that the content of the screen interface of the whole display is not needed to be displayed, the use power consumption of the detection equipment can be reduced, and the low power consumption processing of one mode of the method is realized.

It should be noted that, the detection device may acquire the inspection information returned by the cloud server from the cloud server during initialization, or may acquire the inspection information from the cloud server at regular time. It should be further noted that in the embodiment of the present application, the battery used by the detection device may be a lithium-ion battery and super capacitor combination or a lithium-manganese battery, so that the self-discharge rate is lower, and a more stable voltage can be provided for the module. For example, a disposable lithium-manganese battery is selected. Compared with ternary lithium battery, the lithium-manganese battery has the advantages of low self-discharge rate and annual discharge rate of 1-2%. The main reason for selecting the battery is that the maintenance operation is reduced in consideration of the hope of a user, and the battery is generally used for only one year. But this application is not limited to the selection of battery, for example also can use chargeable lithium cell, can increase solar energy conversion board on the shell in addition for can charge the inside battery under the condition of satisfying, bigger extension duration. In this embodiment of the application, the battery can be disposed inside a box of a detection device, such as an authentication box, and the fastening manner is tightly connected with the box body, and is generally not detachable.

In the embodiment of the application, for network connection, if the condition of bad network state or network disconnection occurs, for example, if the area signal is bad and the network interface cannot be accessed, the network access requirement can be kept, and automatic connection is always initiated until reconnection is performed, so that the network access purpose is achieved. The reconnection can be performed at preset intervals, for example, at four intervals of 5 minutes, 10 minutes, 30 minutes and 1 hour, and the reconnection can be performed at the frequency until the network is normally accessed.

In summary, according to the embodiment of the application, after the preset condition is met, the detection device is controlled to enter the low-power-consumption mode from the operation mode, and the preset low-power-consumption processing is performed on the detection device, so that the resource consumption can be reduced, the power consumption of the detection device is reduced, and the service life of the detection device is prolonged. Furthermore, through once obtaining a plurality of two-dimensional code URL information and storing the information in the local area, the interaction with the cloud server is not needed, the two-dimensional code can be refreshed and displayed directly from the local area according to the plurality of two-dimensional code URL information, the refreshing can be performed according to a preset period, the display is not needed to be continuously refreshed, and the power consumption of the detection equipment is further reduced. In addition, a local refreshing mode can be adopted when the two-dimension code is refreshed and displayed, the display is an ink screen display, a chip in the main board is a low-power-consumption chip, the chip in the main board is powered by a battery cell, and a PMOS (P-channel metal oxide semiconductor) switch circuit is arranged in a circuit of the main board. Through comprehensive use in various modes, the power consumption of the detection equipment is further reduced, and the use time of the detection equipment is prolonged.

Fig. 7 is a schematic structural diagram of an electronic device according to an embodiment of the present application. The electronic device may be, for example, but not limited to, a detection device.

Referring to fig. 7, the electronic device 1000 includes a memory 1010 and a processor 1020.

The processor 1020 may be a central processing unit (Central Processing Unit, CPU), but may also be other general purpose processors, digital signal processors (Digital Signal Processor, DSP), application specific integrated circuits (Application Specific Integrated Circuit, ASIC), field programmable gate arrays (Field-Programmable Gate Array, FPGA) or other programmable logic devices, discrete gate or transistor logic devices, discrete hardware components, or the like. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like.

Memory 1010 may include various types of storage units, such as system memory, read Only Memory (ROM), and persistent storage. Where the ROM may store static data or instructions that are required by the processor 1020 or other modules of the computer. The persistent storage may be a readable and writable storage. The persistent storage may be a non-volatile memory device that does not lose stored instructions and data even after the computer is powered down. In some embodiments, the persistent storage device employs a mass storage device (e.g., magnetic or optical disk, flash memory) as the persistent storage device. In other embodiments, the persistent storage may be a removable storage device (e.g., diskette, optical drive). The system memory may be a read-write memory device or a volatile read-write memory device, such as dynamic random access memory. The system memory may store instructions and data that are required by some or all of the processors at runtime. Furthermore, memory 1010 may comprise any combination of computer-readable storage media including various types of semiconductor memory chips (e.g., DRAM, SRAM, SDRAM, flash memory, programmable read-only memory), magnetic disks, and/or optical disks may also be employed. In some implementations, memory 1010 may include readable and/or writable removable storage devices such as Compact Discs (CDs), digital versatile discs (e.g., DVD-ROMs, dual-layer DVD-ROMs), blu-ray discs read only, super-density discs, flash memory cards (e.g., SD cards, min SD cards, micro-SD cards, etc.), magnetic floppy disks, and the like. The computer readable storage medium does not contain a carrier wave or an instantaneous electronic signal transmitted by wireless or wired transmission.

The memory 1010 has stored thereon executable code that, when processed by the processor 1020, can cause the processor 1020 to perform some or all of the methods described above.

Furthermore, the method according to the present application may also be implemented as a computer program or computer program product comprising computer program code instructions for performing part or all of the steps of the above-described method of the present application.

Alternatively, the present application may also be embodied as a computer-readable storage medium (or non-transitory machine-readable storage medium or machine-readable storage medium) having stored thereon executable code (or a computer program or computer instruction code) which, when executed by a processor of an electronic device (or cloud server, etc.), causes the processor to perform some or all of the steps of the above-described methods according to the present application.

The embodiments of the present application have been described above, the foregoing description is exemplary, not exhaustive, and not limited to the embodiments disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the various embodiments described. The terminology used herein was chosen in order to best explain the principles of the embodiments, the practical application, or the improvement of technology in the marketplace, or to enable others of ordinary skill in the art to understand the embodiments disclosed herein.

Claims (13)

1. A method for processing power consumption of a detection device, comprising:

the method comprises the steps that the current state of detection equipment bound with target equipment is obtained, the detection equipment obtains detection information for detecting authenticity of the detection equipment through interaction with a cloud server, and a two-dimensional code for a user to scan is generated;

and controlling the detection equipment to enter a low-power consumption mode from an operation mode according to the current state meeting preset conditions, wherein the low-power consumption mode comprises the step of carrying out preset low-power consumption processing on the detection equipment.

2. The method of claim 1, wherein the performing the preset low power consumption process on the detection device includes:

and carrying out preset low-power consumption processing on the detection equipment, wherein at least one of the following steps is carried out on the detection equipment: and controlling the detection equipment to interrupt communication connection with the cloud server, controlling the chip in the main board of the detection equipment to wake up regularly to access the cloud server, and controlling the detection equipment to refresh and display the two-dimensional code according to a preset period.

3. The method according to claim 1, wherein controlling the detection device to enter a low power consumption mode from an operation mode according to the current state meeting a preset condition comprises:

And controlling the detection equipment to enter a low-power consumption mode from an operation mode according to the current state that the detection equipment is initialized and the detection information is acquired from the cloud server and the two-dimensional code is generated.

4. The method according to claim 1, wherein the detecting device obtains the verification information for detecting the authenticity of the detecting device through interaction with the cloud server, including:

the detection equipment acquires URL information of at least two-dimension codes for detecting authenticity of the detection equipment through interaction with the cloud server, so that the two-dimension codes can be refreshed and displayed according to a preset period.

5. The method according to any one of claims 1 to 4, wherein:

and in the interaction process of the detection equipment and the cloud server, selecting preset information for interactive transmission.

6. The method according to claim 5, wherein:

the preset information sent by the detection device to the cloud server includes: detecting a device ID of the device and installation information that the device has been installed to the target device;

the step of receiving the preset information returned by the cloud server by the detection equipment comprises the following steps: the method comprises the steps of presetting website information and detection equipment authenticity identification information, wherein the detection equipment authenticity identification information comprises equipment IDs of detection equipment and target equipment and signature fields for describing the authenticity of the detection equipment.

7. A detection apparatus, characterized in that:

the detection equipment comprises a box body, a box cover, a main board and a display; an installation space is formed between the box cover and the box body, the main board is positioned in the installation space, the main board is electrically connected with the display, and the display is positioned on the surface of the box cover;

the detection equipment is bound with the target equipment, acquires detection information for detecting authenticity of the detection equipment through interaction with the cloud server, and generates a two-dimensional code for a user to scan the code and displays the two-dimensional code on the display;

the main board is used for acquiring the current state of the detection equipment bound with the target equipment, and controlling the detection equipment to enter a low-power-consumption mode from an operation mode according to the current state of the detection equipment meeting preset conditions, wherein the low-power-consumption mode comprises the step of carrying out preset low-power-consumption processing on the detection equipment.

8. The apparatus according to claim 7, wherein the main board performs a preset low power consumption process on the inspection apparatus, including:

the main board performs preset low-power consumption processing on the detection equipment, wherein the preset low-power consumption processing comprises at least one of the following steps: and controlling the detection equipment to interrupt communication connection with the cloud server, controlling the chip in the main board of the detection equipment to wake up regularly to access the cloud server, and controlling the detection equipment to refresh and display the two-dimensional code according to a preset period.

9. The detection apparatus according to claim 8, wherein:

the display may be an ink screen display, and/or,

the chip in the main board adopts a low-power consumption chip.

10. The detection apparatus according to claim 8 or 9, characterized in that:

the chips in the main board are powered by the battery core, and/or,

and a PMOS switch circuit is arranged in the circuit of the main board.

11. The detection apparatus according to claim 8, wherein:

and the display adopts a local refreshing mode when refreshing and displaying the two-dimensional code.

12. An electronic device, comprising:

a processor; and

a memory having executable code stored thereon, which when executed by the processor, causes the processor to perform the method of any of claims 1-6.

13. A computer readable storage medium having stored thereon executable code which when executed by a processor of an electronic device causes the processor to perform the method of any of claims 1-6.

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