CN112669044A - Environment health and product quality establishing system - Google Patents

Abstract

An environment health and product quality establishing system is composed of an electronic device, a field recording device and a field service device. The electronic device constructs an independent random number and a virtual random number, connects to a mesh network, converts the independent random number and the virtual random number into a sealed packet according to received field data, and stores the sealed packet; the field recording device uses geographic information as field verification and transmits field data of at least one grower cultivating a ecological structure on the field at the same time, and the field data is combined with the independent random number and uploaded to the mesh network; the field service device can read in the virtual random number to connect with the field data in the sealed package so as to know the quantity reaction of at least one animal kingdom of the position of the field recording device and the environmental health value of the ecological structure so as to inspect the product quality of the ecological structure.

Description

Environment health and product quality establishing system

Technical Field

The invention relates to a real food presentation system and a real food honest and conscientious system with farmer's production record and production and marketing record, which further comprise an audio-visual supply and demand record management system shot according to the actual production and marketing process, so that consumers can obtain more complete food guarantee and safety, in particular to an environment health and product quality establishment system.

Background

The internet of things (IoT) is an information bearer such as the internet and a traditional telecommunication network, and a security issue of resource data sharing and transmission between internet of things, that is, a data protection mechanism, is a very important part of the internet of things, so in recent years, in virtual digital currency, a block chain (Blockchain) technology designed based on a peer-to-peer network has been gradually introduced into the field of internet of things.

The food related management system is more commonly an ISO 22000 food safety management system, an FSSC 22000 food safety system certification, an SQF food safety quality standard, a BRC British food safety standard, a TQF Taiwan good food … and the like. The food safety problem is receiving more and more extensive attention, and the quality requirement of the terminal customer can only make the practitioners of the food supply chain more strictly control and keep track of at present.

However, "strict control" and "strict clearance" are not completely equivalent to "transparent authentication, transparent cultivation, transparent food material growth".

Disclosure of Invention

The invention aims to provide an environment health and product quality building system which utilizes a film, an image, a photo and an image and the geographic information of a geographic information system, enables the production place and the manufacturing procedure of a product purchased by each consumer to be presented safely and completely through self-timer verification of farmers, enables the consumers to feel more reassurance by audio-video resume from farms to dining tables, and improves brand image by people seeing the food manufacturers and the farmers with great mind.

The invention further aims to provide a real food presentation system of a food safety solution scheme combining natural authentication, friendly cultivation, fresh food material purchase, global transparent central kitchen and Internet of things records.

Another objective of the present invention is to provide a natural cloud spindle with real presentation, which utilizes real guiding to distinguish and judge many things to cut them and find a "true food honesty system" with a higher trust model for consumers.

It is still another object of the present invention to provide an insect certification, animal certification, weed certification, an environmental health and product quality establishment system in which the creativity of the production site constructs a bio-chain which is really friendly to plant, and the pleasant and friendly breeding of the animal breeding is ensured by the animals themselves.

Still another object of the present invention is to provide a safe environmental health and product quality building system for farmers to voluntarily create environments conforming to diverse organisms and to make the organisms autodyne daily to deliver planting land.

Another objective of the present invention is to provide an environmental health and product quality establishment system, in which the records of pictures can easily convey the trust and truth of food materials by farmers, so that consumers can more easily obtain all diversification and reality of required information to achieve the purpose of recording trust, and more so that many consumers can go to farmlands and farmers to establish forward cycle of trust.

The system for establishing environmental health and product quality for achieving the above objects of the invention comprises:

an electronic device, which uses a processor to construct an independent random number and a virtual random number connected to a mesh network, and updates the independent random number and the virtual random number according to a change of a state of receiving field data, wherein the independent random number and the virtual random number can be combined into a set close to a random number, then the random number and the field data are converted into a sealed package by using an elastic function, the sealed package is stored, when the sealed package is read, the electronic device obtains a quantitative response presented by a quantitative characteristic of at least one animal world of the field recording device at the position of the field recording device from the field data, and the environmental health value of the ecological structure of the field recording device is obtained by bringing the quantitative response of the animal world into an environmental health evaluation module;

a site recording device, connecting a communicator with the mesh network to download the independent random number, wherein the site recording device takes geographic information as site verification and transmits site data of at least one grower cultivating an ecological structure on site, the site data combines the independent random number and uploads the independent random number to the mesh network, and the site data at least comprises the quantity characteristics and an observed quantity type of the animal kingdom of site performance;

the field service device can read in the virtual random number, and then a built-in communication module is connected with the sealed package stored by the electronic device in the mesh network, so that the virtual random number and the independent random number are combined into a set close to a random number to read the field data in the sealed package, and the quantity response of the animal kingdom of the position of the field recording device and the environmental health value of the ecological structure of the field recording device are known from the field data to inspect the product quality of the ecological structure.

Drawings

FIG. 1 is a hardware schematic of the environmental health and product quality establishment system of the present invention;

FIG. 2 is a flow chart of the system for establishing environmental health and product quality using mesh network architecture;

FIG. 3 is a table of random numbers including independent random numbers and virtual random numbers, depicted in accordance with the embodiment of FIG. 1;

FIG. 4 is a flow chart of a field recording device connecting to the mesh network to download an independent random number of electronic devices;

FIG. 5 is a flow chart of the combination of geographic information, field data, and the uploading of the independent random number to a mesh network;

FIG. 6 is a flow chart of the conversion of the combined field data of the independent random number and the virtual random number into a sealed package;

FIG. 7 is a flowchart of a field service device reading in a pseudo-random number and then connecting to the sealed package stored by an electronic device in the mesh network to read field data in the sealed package;

FIG. 8 is a hardware schematic of an electronic device implementing a random number table comprising independent random numbers and timelines connected to a mesh network;

FIG. 9 is a flowchart of an electronic device implementing a random number table including independent random numbers and timelines for connecting to a mesh network;

FIG. 10 is a table of random numbers including independent random numbers and virtual random numbers according to the embodiment of FIGS. 1 and 2;

FIG. 11 is a table of random numbers including independent random numbers and time axes according to the embodiment shown in FIGS. 8 and 9;

FIG. 12 is a hardware schematic of the environmental health and product quality establishment system of the present invention applied to a blockchain;

FIG. 13 is a flowchart of an electronic device implementing a random number table including independent random numbers and pseudo random numbers connected to a blockchain network;

FIG. 14 is a flowchart of an electronic device implementing a random number table comprising independent random numbers and time axes connected to a blockchain network;

FIG. 15 is a flow chart of a field recording device connecting to the blockchain network to download independent random numbers for an electronic device;

FIG. 16 is a flow chart of the independent random number upload to the blockchain network in combination with geographic information, field data;

FIG. 17 is a flow chart of the conversion of the combined field data of the independent random number and the virtual random number into a sealed package; and

fig. 18 is a flowchart of the field service device reading in a pseudo random number and then connecting the sealed package stored in the electronic device in the blockchain network to read the field data in the sealed package.

Description of reference numerals: 1-an electronic device; 1 a-1 g-an electronic device; 11-a processor; 12-a random number table; 121. 131-independent random number; 122. 132-virtual random number; 123. 133-time axis; 124. 134-sealing the bag; 2. 2a, 2 b-field recording means; 2 a-2 g-field recording device; 21. 21a, 21 b-communicator; 221. 231 — the geographic information; 222. 232-field data; 3. 3a, 3 b-field service device; 3 a-3 o-field service devices; 31. 31a, 31 b-a communication module; 4-mesh network; 5-Block chain.

Detailed Description

Referring to fig. 1, a first embodiment of the system for establishing environmental health and product quality provided by the present invention mainly includes: an electronic device 1, a field recording device 2 and a field service device 3.

Referring to fig. 3 and 4, the electronic device 1(electronic device) uses a processor 11 to construct a random number Table 12(Table of random numbers) including an independent random number 121(independent random number) and a virtual random number 122(pseudo random number) to be connected to a mesh Network 4(mesh Network) (or a block chain Network (block chain Network)), and updates the independent random number 121 and the virtual random number 122 according to a change of a state of receiving a field data 222 (the updated independent random number 121 and the updated virtual random number 122 are defined as the independent random number 121(n +1) and the virtual random number 122(n + 1)); as shown in fig. 6, the independent random number 121 and the virtual random number 122 can be combined into a set close to a random number (random number), and then an elastic function is used to convert the random number and the field data 222 into a sealed package 124 (i.e. a true binary random bit, such as 1 or 0), and the sealed package 124 is stored, when the sealed package 124 is read (read access), the electronic device 1 knows from the field data 222 that a number response (numerical response) is added or shrunk to a number feature (quantitative character) of at least one animal boundary (animal) at the location of the field recording device 2, and brings the number response (e.g. number added, number shrunk, fixed number, unknown number) of the animal boundary into an environmental health impact evaluation module (environmental health impact evaluation module) to know that the environmental health impact module (environmental health impact) 2 records an environmental health value (environmental health) of the field recording device 2 along with the increase of the environmental health feature (environmental health record) of the field recording device Gradually becomes better or worse with increasing; the kingdom of animals is formed by a multiplicity of species of the insect, a multiplicity of insect populations, a multiplicity of species of the animal, and a multiplicity of animal populations.

As shown in fig. 4, the on-site recording device 2 (recorded on spot device) uses a communicator 21 to connect to the mesh network 4 (or the block chain network) to download the independent random number 121, the on-site recording device 2 uses the geographic information 221(geographic information) of a Geographic Information System (GIS) for positioning, or uses the global positioning information (global positioning information) of a Global Positioning Satellite (GPS) for positioning, or uses the global positioning information of a Global Positioning Satellite (GPS) and the geographic information 221 of a Geographic Information System (GIS) for on-site verification (field verification) while transmitting (field verification) at least one planter (player) of a natural agricultural cultivation (future) biological structure (biological structure) 222, the field verification device 222 is combined with the independent random number to the mesh network 4 (or the block chain network) to download the independent random number 121), as shown in fig. 5; the field data 222 includes at least the quantitative feature (quantitative character) of the animal kingdom of a field performance (live action) and the true status (real state) of an Observed quantitative category (Kind of quantitative Observed);

as shown in fig. 7, the field service device 3(field service device) can read the pseudo random number 122, and then connect a communication module 31(communication module) built in to the packet 124 stored in the electronic device 1 in the mesh network 4 (or the block chain network), so that the pseudo random number 122 and the independent random number 121 are combined into a set close to a random number, to read the field data 222 in the sealed package 124 and to know from the field data 222 that the field recording device 2 is located where the numerical response (numerical response) of the animal kingdom is getting better or worse with time, the environmental health value of the on-site recording apparatus 2 is known to be gradually better or worse with time to check the product quality of the ecological structure.

Referring to fig. 8, a second embodiment of the system for establishing environmental health and product quality provided by the present invention mainly includes: an electronic device 1, a field recording device 2 and a field service device 3.

The electronic device 1 is configured by a processor 11 to construct a random number table 12 including an independent random number 121 and a time axis 123(time axis) and connected to a mesh network 4 (or a blockchain network), and updates the independent random number 121 and the time axis 123 according to a change of a state of receiving a field data 222 (the updated independent random number 121 and the updated time axis 123 are defined as the independent random number 121(n +1) and the time axis 123(n +1)), the independent random number 121 and the time axis 123 can be combined into a set close to a random number, and then converts the random number and the field data 222 into a sealed packet 124 (i.e. true binary random bits, such as 1 or 0) by using an elastic function, and stores the sealed packet 124, and when the sealed packet 124 is read (read access), the electronic device 1 knows a quantity characteristic of at least one animal world where the field data 222 is located The increase or atrophy of the animal kingdom represents a quantitative response, and the quantitative response (such as quantitative increase, quantitative atrophy, fixed quantitative, unknown quantitative) of the animal kingdom is brought into an environmental health influence evaluation module to know that an environmental health value of the ecological structure of the field recording device 2 is gradually improved or gradually reduced along with the increase of time; the kingdom of animals is formed by a multiplicity of species of the insect, a multiplicity of insect populations, a multiplicity of species of the animal, and a multiplicity of animal populations.

The on-site recording device 2 uses a communicator 21 to connect with the mesh network 4 (or the blockchain network) to download the independent random number 121, the on-site recording device 2 uses the geographic information 221 of a geographic information system for positioning, the global positioning data of a global positioning satellite and the geographic information 221 of a geographic information system as well as a time axis 123 of the on-site recording device 2 for on-site verification and transmits on-site data 222 of whether at least one grower cultivates an ecological structure by a natural farming method, the on-site data 222 combines the independent random number 121 and uploads the combined independent random number 121 to the mesh network 4 (or the blockchain network), and the on-site data 222 at least comprises the quantity characteristic and an observed quantity type of the animal field performing on site;

the field service device 3 can read the time axis 123, and then connect the sealed package 124 stored in the electronic device 1 in the mesh network 4 (or the block chain network) with a built-in communication module 31, so that the time axis 123 and the independent random number 121 are combined into a set close to a random number to read the field data 222 in the sealed package 124, and learn from the field data 222 containing the time axis 123 that the quantity response of the animal boundary at the location of the field recording device 2 becomes better or worse gradually with time, and learn that the environmental health value of the ecological structure of the field recording device 2 becomes better or worse gradually with time, so as to inspect the product quality of the ecological structure.

The electronic device 1 can prevent the deviation from occurring by combining the quantity characteristic of the animal kingdom and the observed quantity category of the field data 222 using the elasticity function. For example, within the field data 222, some animals may be able to direct the results in a desired direction. The elastic function may protect the real state (real estate) of the animal world of the field data 222. The invention is based on the selection of a plurality of this kingdom of animals, for example: selecting a plurality of the insects and insect groups of the plurality of species in the animal kingdom, selecting 3-5 sets of the field data 222 within a continuous time (continuous time), selecting a 1 st insect, a 2 nd insect … … an nth insect, or an n +1 st insect (if the 1 st insect is a plurality) in each set, dividing the selected 1 st insect into 3 sets, then extracting the 1 st insect in each set, and so on until at least one insect (i.e., the 1 st insect) in the field data 222 is obtained, wherein the field data 222 shows that the insect (i.e., the 1 st insect) is the quantitative characteristic of the position of the field recording device 2 and the real condition (real state) of the observed quantitative species. This allows the electronic device 1 to tolerate the presence of a large number of blind spots of the field data 222, while filtering out the deviation numbers in terms of the random number generation.

Also, the elastic function is selected from a plurality of animal kingdoms, such as: selecting a plurality of types of the animals and a plurality of groups of animals in the animal kingdom, selecting 3-5 groups of the field data 222 within a continuous time (continuous time), selecting a 1 st animal, a 2 nd animal … … an nth animal or a plurality of n +1 th animals (if the 1 st animal is a plurality), dividing the selected 1 st animal into 3 groups, extracting a plurality of the 1 st animals in each group, and so on until at least one animal (i.e., the 1 st animal) in the field data 222 is obtained, wherein the field data 222 shows that the animal (i.e., the 1 st animal) is the quantitative feature of the position of the field recording device 2 and the real condition (real state) of the observed quantitative species. This allows the electronic device 1 to tolerate the presence of a large number of blind spots of the field data 222, while filtering out the deviation numbers in terms of the random number generation.

Then, the elasticity function selects a majority of weeds, selects 3 to 5 sets of the field data 222 within a continuous time (continuous time), then selects a majority of a 1 st weed, a 2 nd weed … … an nth weed, or an n +1 th weed (if the 1 st weed is a majority) in each set, divides the number of the 1 st weed selected into 3 sets and extracts a majority of the 1 st weed in each set, and so on until at least one weed (i.e., the 1 st weed) in the field data 222 is finally available, the field data 222 indicating that the weed (i.e., the 1 st weed) is the real status of the quantitative characteristic and the observed quantitative characteristic of the location where the field recording device 2 is located (real status). This allows the electronic device 1 to tolerate the presence of a large number of blind spots of the field data 222, while filtering out the deviation numbers in terms of the random number generation.

The electronic device 1 may include an internet access function (e.g., a smart phone); however, it may also be a Personal Digital Assistant (PDA), desktop computer, notebook computer, tablet computer (tablet computer). In the present embodiment, the electronic device 1 includes the processor 11, a network system, a storage medium and an input/output (I/O) device. The processor 11 may be electrically coupled to at least the network system, the storage medium, and the input/output device.

The network system may support wireless signal transmission of at least one of the following systems: a global System for mobile communication (GSM), a Fourth Generation mobile communication System (Fourth Generation communication System), a 5th Generation mobile communication network (5th Generation mobile networks), a Long Term Evolution (LTE) network, a wireless-fidelity (Wi-Fi) System, a worldwide interoperability for microwave access (worldwide interoperability for microwave access) System, a mesh network 4 and a block network.

The individual random numbers 121 of the electronic device 1 are unpredictable, and it is not possible to repeatedly generate two identical series of the individual random numbers 121. The independent random number 121 can be generated only by a process of randomly receiving the field data 222, for example, updating the independent random number 121 according to a change in a state of receiving a field data 222 by the field recorder (the independent random number 121 after updating is defined as the independent random number 121(n + 1)). The sequence of independent random numbers 121 is generated by an independent random number generator (independent random number generator) relying on natural randomness and true randomness of the increase or atrophy of the number features of the insects, animals or weeds and the increase or atrophy of the observed number species for their naturally occurring (autogeney) phenomenon. For the independent random number generator, no initial sequence or initial number exists, so that the problem of periodicity of the pseudo-randomness can be eliminated, and the independent random number generator is difficult to crack.

The virtual random number 122 currently applied by the electronic device 1 is usually the virtual random number 122 generated by some mathematical formula calculation, i.e. generated by a virtual random number generator (pseudo random number generator), which starts from an initial state and generates the virtual random number 122 by a certain algorithm. Once given the algorithm and seed, the output sequence is determined with a certain periodicity. The sequence of virtual random numbers 122 generally has a relatively good random statistical property, and is generated by a mathematical algorithm that approximates a true random sequence in some statistical property, but is periodic and predictable. The virtual random number 122 is readily available and convenient to use, and is typically used in simulation, commerce, vending, and other situations.

Fig. 2 and 9 illustrate a mesh network 4 architecture according to an embodiment of the present invention. Referring to fig. 2 and 9, the mesh network 4 includes the electronic device 1, two field recording devices 2a, 2b and two field service devices 3a, 3b, wherein the field recording devices 2a, 2b and the field service devices 3a, 3b have similar components, features and functions as the electronic device 1. In the present embodiment, the mesh network 4 is illustrated as a proximity-based network (proximity-based) architecture with a three-level hierarchical architecture.

Fig. 2 is a flowchart illustrating a method for sharing the field data 222, 232 in the mesh network 4 according to an embodiment of the present invention, wherein the embodiment may include a plurality of scenarios. The electronic apparatus 1 is a root node of the mesh network 4 and is also a group owner (group owner) of the mesh network 4. The electronic device 1 can be used as a root node (root node) and share the field data 222, 232 in the storage medium and generate the independent random number 121 and the virtual random number 122 (or the time axis 123).

The field recording devices 2a, 2b are first layer child nodes (first layer child nodes) of the electronic device 1. When the farmer a uses the field recording device 2a and the farmer B uses the field recording device 2B as the first layer child node (first layer child node) of the electronic device 1 and downloads the independent random numbers 121, 131. The electronic device 1 can automatically transmit the independent random numbers 121, 131 to authorize the field recording device 2a and the field recording device 2b to join the mesh network 4, or prohibit the field recording device 2a and the field recording device 2b from joining the mesh network 4. The site recording devices 2a, 2b are a smart phone or a tablet computer, which is used by a farmer to self-shoot at least one video, or at least one image (image), or at least one continuous image (continuous image), or at least one digital image (digital image), or at least one photo, or at least one image (picture), or at least one static image (still picture) and the geographic information 221, 231 of a geographic information system for positioning, or the global positioning data of a global positioning satellite and the geographic information 221, 231 of a geographic information system for positioning, and verify the ecological structure of the farmer (farmer) by self-shooting at least one image, or at least one image of the farmer (farmer) and let each consumer observe whether the farmer (farmer) cultivates the site data 222 of the ecological structure of the farmer (farmer) by the natural method, 232 combine the independent random numbers 121, 131 for uploading to the mesh network 4.

The production place and the manufacturing process of the farmer (grower) purchased by the consumer are enabled, food safety and completeness are shown by the field data 222 and 232, the field data 222 and 232 show a biological chain constructed by the biology of the ecological structure (farm), the animal kingdom is enabled to ensure friendly planting by the increase or the atrophy of the quantity characteristics of the insects, the animals and the weeds or the increase or the atrophy of the observed quantity and variety by the insects, the animals or the weeds, and the audio-visual record of the insect certification, the animal certification and the weed certification to the dining table, which is shown by the field data 222 and 232, can enable the consumer to feel more reassuring and the brand image to be improved and more transparent.

The farmer continuously captures the image or the image by the smart phone or the tablet computer, and transmits the image or the image to the processor 11 of the electronic device 1 via the mesh network 4 for processing, the processor 11 first detects edges of a series of images or images, then learns the edge (edge) binary image by the processor 11, and detects the moving insects or animals by using a motion detection algorithm after learning, capturing the moving insect or animal parts, merging the insect or animal parts by a block multiplexer (block multiplexer), then, the number of the insects, animals or weeds in nature is increased or shrunk, or the number of the observed species is increased or shrunk, by performing shadow removal by a shadow merge method (shadow merge).

When the farmer a downloads the independent random number 121 from the root node of the electronic device 1 at a first geographical location with the first-tier child node of the field recording device 2a, the geographical information 221 of the first geographical location and the field data 222 are combined with the independent random number 121 and uploaded to the root node or the electronic device 1.

The other farmer B downloads the independent random number 131 from the root node of the electronic device 1 at a second geographic location by using the first-tier child node of the field recording device 2B, and then uploads the independent random number 131 to the root node or the electronic device 1 by combining the geographic information 231 of the second geographic location and the field data 232.

The field service device 3a and the field service device 3b are the second layer child node (second layer child node) of the electronic device 1 and read the pseudo random numbers 122, 132 (or the time axes 123, 133). The field service devices 3a and 3b are a smart phone or a tablet computer owned by a Consumer (Consumer), a store, a disc dealer, a Price trader (spaaders), a goods trader (Value trader), a Market creator (Market maker), and a Price acceptor (Price maker); when the consumer, the store, the merchant, the price difference trader, the identification trader, the market creator, or the price acceptor uses a camera on the smart phone or the tablet computer to read in a bar code symbol (bar code symbol), or a bar code data (bar code data), or a bar code label (bar-coded label) formed by the virtual random numbers 122, 132 (or the time axes 123, 133), the built-in communication modules 31a, 31b are connected with the sealed packages 124, 134 stored by the electronic device 1 in the mesh network 4;

as shown in fig. 7, when the customer C reads the pseudo random number 122 from the store at a third geographic location (or an nth geographic location, or an n +1 th geographic location) using a camera on the on-site service device 3a (the smart phone or the tablet computer) of the customer C to connect the sealed package 124 stored by the electronic device 1 in the mesh network 4, and then reads the field data 222 in the sealed package 124 to know the number of the insects in a first geographic location of the on-site recording device 2a in response to the number of insects in the first geographic location to know the increase or decrease of the life history and insect structure, insect morphology (insect morphology), insect ecology (insect ecology), or whether there is a colony of insects (colony) such as: insects are taxonomically classified as insects, and are the largest within the kingdom of animals, regardless of species or quantity. Taking the insect as an example, the development process of an insect undergoes a series of changes called metamorphosis (metamorphis), which can be classified into: complete metamorphosis (complete metamorphism), incomplete metamorphosis (incomplete metamorphism), and ametabolic (ametabolic). The life history of the insect is divided into egg phase, juvenile phase, (pupal phase), adult phase, the insect with complete metamorphosis has pupal phase, while the insect with incomplete metamorphosis and non-metamorphosis does not have pupal phase. The quantitative characteristics of the insect are for example: belongs to a completely metamorphic butterfly, which is a caterpillar in the hour, becomes pupa after growing up, and finally becomes a butterfly with beautiful wings after eclosion. The quantitative characteristics of the insect include recording the structure of the adult body, its head, chest, abdomen, and the growth history and life history of the appendages, for example, the head generally has an antennal, the chest often has 3 pairs of feet and 2 pairs of wings.

Moreover, when the consumer D reads the pseudo random number 132 from the store at a fourth geographic location (or an nth geographic location, or an n +1 th geographic location) using a camera on the field service device 3b (the smart phone or the tablet computer) of the consumer D to connect the sealed package 134 stored in the electronic device 1 in the mesh network 4, the field data 232 in the sealed package 134 is read to know the number of the insects in a second geographic location of the field recording device 2b reflecting the life history of the insects, insect structure, insect morphology (insect morphology), insect ecology (insect ecology), or whether there is an increase or decrease of colony insects (colony insects).

And the electronic device 1 can detect the actions of the field recording device 2a, the field recording device 2b, the field service device 3a and the field service device 3b leaving the mesh network 4. The electronic device 1 can manage the above procedures by the random number table 12. Fig. 10 is a random number diagram including the random number table 12 according to the embodiment of fig. 1-2, wherein the random number table 12 illustrates a plurality of different stages of updating the field data 222, 232 in the mesh network 4, and wherein the random number table 12 includes, but is not limited to, a plurality of sets of independent random numbers 121, 131, a plurality of sets of independent random numbers 121(n), 131(n), a plurality of sets of independent random numbers 121(n +1), 131(n +1), and a plurality of sets of virtual random numbers 122, 132, a plurality of sets of virtual random numbers 122(n), 132(n), a plurality of sets of virtual random numbers 122(n +1), 132(n + 1).

Fig. 11 is a diagram of random numbers including the random number table 12 according to the embodiment of fig. 8 to 9, wherein the random number table 12 includes, but is not limited to, a plurality of groups of independent random numbers 121, 131, a plurality of groups of independent random numbers 121(n), 131(n), a plurality of groups of independent random numbers 121(n +1), 131(n +1), and a plurality of groups of time axes 123, 133, a plurality of groups of time axes 123(n), 133(n), and a plurality of groups of time axes 123(n +1), 133(n + 1).

The processor 11 of the electronic device 1 can update the independent random numbers 121, 131 according to the change of the status of the field recording device 2a or the field recording device 2 b. For example, in one scenario, after the status of the field recording device 2a or the field recording device 2b changes, fig. 10 and 11 show that the independent random numbers 121, 131 and the virtual random numbers 122, 132 (or the time axes 123, 133) are updated, and the updated independent random numbers 121, 131 and the virtual random numbers 122, 132 (or the time axes 123, 133) are defined as the independent random numbers 121(n +1), 131(n +1) and the virtual random numbers 122(n +1), 132(n +1) (or the time axes 123(n +1), 133(n + 1)). Referring to fig. 5, after the field recording device 2a or the field recording device 2b completes the field transmission of the field data 222, 232, the communicator 21a, 21b of the field recording device 2a or the field recording device 2b can transmit the report back to the electronic device 1 in a reverse direction according to a path in a corresponding routing information base (routing information base). After the notification, the electronic device 1 also uploads the uncertainty of the uploading time of the field data 222, 232 in the random number table 12, so that the field recording device 2a or the field recording device 2b, which is the first-layer child node of the electronic device 1, can use time to make a random number seed, and download the updated independent random numbers 121(n +1), 131(n +1), or provide the field service device 3a and the field service device 3b as the second-layer child node (second layer child) of the electronic device 1 to read the virtual random numbers 122(n +1), 132(n +1) (or the time axes 123(n +1), 133(n + 1)). If the random number table 12 is to be made more random, it is able to collect real random events, such as establishing a random pool, and continuously collecting physical random information in the system, such as input/output devices such as keyboard, mouse, network signal, system time, program ID, interrupt time … …, when the random number table 12 requests to update the independent random numbers 121, 131 (the independent random numbers 121, 131 after updating are defined as the independent random numbers 121(n +1), 131(n +1)) or the virtual random numbers 122, 132 (the virtual random numbers 122, 132 after updating are defined as the virtual random numbers 122(n +1), 132(n +1)) (or the time axes 123, 133 after updating are defined as the time axes 123(n +1), 133(n +1))), the processor 11 of the electronic device 1 can obtain information from the random pool, and is calculated by the electronic device 1 and then returned, such random number can meet the requirement of true randomness in cryptography, that is, the random sample is not reproducible. The independent random number 121 of the electronic device 1 can be updated from "00110101" to "01010011", and the independent random number 131 of the electronic device 1 can be updated from "01000110" to "10110010".

Referring to fig. 12, which is a block chain architecture applied to the method of the present invention, the block chain 5 of the present embodiment includes a plurality of nodes (nodes) that communicate with each other, each node may be the electronic device 1, and in the present embodiment, the electronic devices 1a to 1g are defined as a source node, the field recording devices 2a to 2g are physical nodes, and the field service devices 3a to 3o are hypermedia nodes (hypermedia nodes) from all the nodes in the block chain 5.

As shown in fig. 13, the original nodes of the electronic device 1 are nodes that construct the independent random numbers 121, 131 and the virtual random numbers 122, 132 (or the time axes 123, 133, as shown in fig. 14), receive or read the field data 222, 232. Wherein the original node is the electronic device 1 with high computing power.

The site recording devices 2a, 2b are a smart phone or a tablet computer, which is used by a farmer to self-shoot at least one video, or at least one image (image), or at least one continuous image (continuous image), or at least one digital image (digital image), or at least one photo, or at least one image (picture), or at least one static image (still picture) and the geographic information 221, 231 of a geographic information system (or the global positioning data of a global positioning satellite, or the global positioning data of a global positioning satellite and the geographic information 221, 231 of a geographic information system), and the farmer (grower) uses the site recording devices 2a, 2b to self-shoot to verify that each consumer observes (watch) whether the farmer (grower) cultivates the ecological structure of the farmer (grower) by the natural method through the site data 222, the local data of the ecological structure of the farmer (grower), 232 are uploaded to the blockchain 5, so that the consumer can purchase the product production place and process of the farmer (grower), the food safety and integrity are shown by the field data 222, 232, the field data 222, 232 show the bio-chain constructed by the biology of the ecological structure (farm), the insect, the animal or the weed can be ensured to be friendly by the increase or the atrophy of the number characteristic of the insect, the animal or the weed or the increase or the atrophy of the observed number and variety, and the audio-visual history of the insect authentication, the animal authentication and the weed authentication shown by the field data 222, 232 to the dining table can ensure that the consumer is more comfortable and the brand image is improved and more transparent.

When the farmer a downloads the independent random number 121 from the original node at a first geographical location by using the physical node of the site recording device 2a, the geographical information 221 of the first geographical location and the site data 222 are combined with the independent random number 121 and uploaded to the original node or the node.

The other farmer B downloads the independent random number 131 from the original node in a second geographic location by using the physical node of the site recording device 2B, and then uploads the independent random number 131 to the original node or the node by combining the geographic information 231 of the second geographic location and the site data 232. Meanwhile, an updated field data 222, 232 is re-transmitted to the original node of the electronic device 1, so as to provide the original node of the electronic device 1 with the field data 222, 232 to update the nodes of the independent random numbers 121, 131 and the virtual random numbers 122, 132 (or the time axes 123, 133).

After the system architecture applied by the method of the present invention is described, please refer to fig. 15 to fig. 18, to describe the process of the step of the method for transmitting the field data 222, 232 of the blockchain 5 with high security, first referring to fig. 15, the original node of the electronic device 1 broadcasts the independent random numbers 121, 131 into the blockchain 5, so that the physical nodes of the field recording device 2a and the field recording device 2b in the blockchain 5 can receive the independent random numbers 121, 131, wherein the independent random numbers 121, 131 include a random number and a transmission data, the value of the independent random numbers 121, 131 should be at least an odd number of five or more, or the value of the independent random numbers 121, 131 should be at least an even number of four or more, in this embodiment, five is taken as an example, and the transmission data is binary code, such as 01001.

As detailed in fig. 16, when the field data 222, 232 of the physical nodes of the field recording device 2a and the field recording device 2b are broadcast into the blockchain 5, the remaining nodes in the blockchain 5 will receive the field data 222, 232, so that the received nodes will forward the field data 222, 232 to one of the other nodes of the blockchain 5 of the electronic device 1, and when the original node of the electronic device 1 receives a change of the field data 222, 232 again, the independent random numbers 121, 131 and the virtual random numbers 122, 132 (or the time axes 123, 133) will be updated.

As shown in fig. 17, the hypermedia nodes of the field service device 3a and the field service device 3b can read the pseudo random numbers 122, 132 (or the time axes 123, 133) in the original node, combine the pseudo random numbers 122, 132 (or the time axes 123, 133) and the independent random numbers 121, 131 into a set of approximate random numbers, then convert the random numbers and the field data 222, 232 into a sealed package 124, 134(hermetic package) by using an elastic function, store the sealed package 124, 134, and read the field data 222, 232 in the original node when the sealed package 124, 134 is read (read access). Wherein the hypermedia node directly designates the high-capability operation node in the blockchain 5 as the hypermedia node according to a user operation signal of a user operation.

Referring to fig. 18, the pseudo random numbers 122, 132 (or the time axes 123, 133) broadcasted by the original node of the electronic device 1 can be read by the hypermedia nodes of at least two of the field service device 3a and the field service device 3b, so that the hypermedia nodes of the field service device 3a and the field service device 3b are connected to the original node of the electronic device 1 again by the pseudo random numbers 122, 132 (or the time axes 123, 133), so that the original node of the electronic device 1 receives the same pseudo random numbers 122, 132 (or the time axes 123, 133) again, and the electronic device 1 combines the pseudo random numbers 122, 132 (or the time axes 123, 133) and the independent random numbers 121, 131 into a set close to a random number to read the field data 222, 232 in the original node, and from the field data 222, 232, the quantity of the animal kingdom of the location of the field logging device 2a, 2b is known, together with the environmental health value of the ecological structure of the field logging device 2a, 2 b. Wherein, the hypermedia node can directly designate the node with stronger computing power in the blockchain 5 as the hypermedia node of the field service device 3a and the field service device 3b according to a user operation signal operated by a user from the original node of the electronic device 1, or preferentially broadcast the field data 222, 232 of the entity node of the field recording device 2a and the field recording device 2b in all nodes of the blockchain 5;

after the physical nodes of the field recording device 2a and the field recording device 2b respectively forward the field data 222, 232 to the original node of the electronic device 1, when the hypermedia nodes of the field service device 3a and the field service device 3b receive the updated amount of the field data 222, 232 uploaded by the original node of the electronic device 1 and the physical nodes of the field recording device 2a and the field recording device 2b, the electronic device 1 updates the independent random numbers 121, 131 and the virtual random numbers 122, 132 (or the time axes 123, 133) according to a change in a state of receiving the field data 222, 232, and simultaneously sends a report signal to the original node of the electronic device 1 according to the node position of updating the independent random numbers 121, 131. If the independent random numbers 121, 131 and the pseudo random numbers 122, 132 (or the time axes 123, 133) are updated, the original node of the electronic device 1 will notify the field service device 3a and the field service device 3b that the hypermedia node is updated, and the field data 222, 232 updated by the original node actually becomes the hypermedia node to be read by the field service device 3a and the field service device 3 b.

If the virtual random numbers 122, 132 (or the time axes 123, 133) can be read in for the embodiments of the hypermedia nodes of the field service device 3a and the field service device 3b while uploading the field data 222, 232 of the physical nodes that preferentially broadcast the field recording device 2a and the field recording device 2b to the blockchain 5, to specify which of the original nodes will become the hypermedia nodes of the field service device 3a and the field service device 3b, depending on a variety of factors; if the electronic device 1 of the node is in an idle state when the field data 222 and 232 are received, or if a signal from the original node of the electronic device 1 to another original node is unobstructed during broadcasting, or if there is or there is no collision with other signals, etc., the speed at which the hypermedia nodes of the field service device 3a and the field service device 3b receive the field data 222 and 232 of the electronic device 1 can be affected; therefore, in order to improve the randomness of the hypermedia node selection of the field service device 3a and the field service device 3b, in addition, according to the values of the independent random numbers 121 and 131 and the virtual random numbers 122 and 132 (or the time axes 123 and 133), the present embodiment limits the number of the physical nodes of the field recording device 2a and the field recording device 2b to the original nodes of the electronic device 1, and relatively improves the uncertainty of the number and the location of the hypermedia nodes of the field service device 3a and the field service device 3b, so that it is difficult for an attacker to locate which nodes the hypermedia nodes of the field service device 3a and the field service device 3b respectively participate in each verification process.

Claims (1)

1. An environmental health and product quality establishment system, comprising:

an electronic device, which uses a processor to construct an independent random number and a virtual random number connected to a mesh network, and updates the independent random number and the virtual random number according to a change of a state of receiving field data, wherein the independent random number and the virtual random number can be combined into a set close to a random number, then the random number and the field data are converted into a sealed package by using an elastic function, the sealed package is stored, when the sealed package is read, the electronic device obtains a quantitative response presented by a quantitative characteristic of at least one animal world of the field recording device at the position of the field recording device from the field data, and the environmental health value of the ecological structure of the field recording device is obtained by bringing the quantitative response of the animal world into an environmental health evaluation module;

a site recording device, connecting a communicator with the mesh network to download the independent random number, wherein the site recording device takes geographic information as site verification and transmits site data of at least one grower cultivating an ecological structure on site, the site data combines the independent random number and uploads the independent random number to the mesh network, and the site data at least comprises the quantity characteristics and an observed quantity type of the animal kingdom of site performance;

the field service device can read in the virtual random number, and then a built-in communication module is connected with the sealed package stored by the electronic device in the mesh network, so that the virtual random number and the independent random number are combined into a set close to a random number to read the field data in the sealed package, and the quantity response of the animal kingdom of the position of the field recording device and the environmental health value of the ecological structure of the field recording device are known from the field data to inspect the product quality of the ecological structure.

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