TWI740234B - Real Food System - Google Patents

Abstract

A real food honesty system is composed of an electronic device, an on-site recording device and an on-site service device. The electronic device constructs an independent random number and a virtual random number to connect to a mesh network, and converts it into a sealed package according to receiving a dynamic image, and stores the sealed package; the field recording device uses a geographic information as a On-site verification, and at the same time a dynamic image of at least one grower cultivating an ecological structure is transmitted on-site, and the dynamic image is combined with the independent random number and uploaded to the mesh network; the on-site service device can read the virtual random number to connect to the The dynamic image in the sealed package is used to capture the quantitative response of an animal kingdom, the environmental health value of the ecological structure, and the emotional response of the animal kingdom to view the ecological structure of the location of the site recording device Product quality.

Description

Real Food System

The present invention relates to a system with farmer’s production history and production and sales history records. It also includes an audio-visual supply and demand record management system photographed according to the actual production and sales process, which allows consumers to obtain more complete food security and safety, especially referring to a real Shicheng present system.

The Internet of Things (IoT) is an information carrier such as the Internet and traditional telecommunications networks. The security issue of resource data sharing and transmission between the Internet of Things, that is, the data protection mechanism, is a very important part of the Internet of Things. Therefore, in recent years In the virtual digital currency, the blockchain technology based on the peer-to-peer network has been gradually introduced into the field of the Internet of Things.

The more common food-related management systems include ISO 22000 food safety management system, FSSC 22000 food safety system certification, SQF food safety quality standards, BRC British food safety standards, TQF Taiwan fine food... etc. Food safety issues are getting more and more attention. The current end customers' quality requirements can only make the food supply chain practitioners more stringent controls and checks.

However, "strict control" and "strict gatekeeping" are not complete It all means "transparent certification, transparent breeding, and transparent growth of foodstuffs".

The purpose of the present invention is to provide a geographic information system that uses videos, images, photos, and images plus a geographic information system to pass the farmer’s self-portrait verification, so that the origin and manufacturing process of the products purchased by each consumer can be made safe and complete. Presented, the audio-visual resume from the farm to the table makes consumers more at ease, the food manufacturers and farmers can see it with their heart, and the brand image is enhanced by the real food system.

The second purpose of the present invention is to provide a "true food presentation system" that combines food safety solutions with nature certification, friendly breeding, fresh food purchases, global transparent central kitchens, and Internet of Things records.

Another object of the present invention is to provide a real-life natural cloud spindle, which uses reality to guide discrimination and judgment so that many things can be cut, and a real food and honesty system that seeks a higher trust model for consumers.

Another purpose of the present invention is to provide a kind of insect certification and animal certification, because the biological chain constructed by the biological nature of the place of origin is actually friendly planting, and the happiness and friendly breeding of animal breeding are guaranteed by the animals themselves. system.

Another purpose of the present invention is to provide a safe and real food system that allows farmers to voluntarily create an environment in line with diverse organisms, and allow these organisms to take selfies every day to pass on the cultivated land.

Another purpose of the present invention is to provide a record of pictures It can easily convey the farmer’s trust and true feelings for the ingredients, making it easier for consumers to obtain the information of the needs. The diversity and realism of all to achieve the purpose of record trust, and allow many consumers to go to the farmland and establish a positive cycle of trust relationship with the farmer. A kind of real food honesty system.

The real food honesty system that can achieve the above-mentioned invention includes: an electronic device that uses a processor to construct an independent random number and a virtual random number to connect to a mesh network, and according to receiving a geographic information A change in a state of a dynamic image is used to update the independent random number and the virtual random number. The independent random number and the virtual random number can be combined into a random number, and then an elastic function is used for the independent random number and the virtual random number. The virtual random number, the geographic information and the dynamic image are transformed into a sealed package, and the sealed package is stored. When the sealed package is read, the electronic device obtains an insect image from the geographic information and the dynamic image Feature or an animal image feature, then an insect image or an animal image will be constructed based on the image feature to increase or decrease in at least one quantitative response, and then an audio feature of emotional expression can be obtained from the dynamic image to obtain a preset plural number An emotional response of an animal kingdom corresponding to this audio feature obtained in an emotional dimension database is a positive emotion or a negative emotion, and then, according to the increase or shrinkage of the number of responses in the animal kingdom, or the animal kingdom’s The emotional response generates an environmental health value; an on-site recording device is connected to the mesh network with a communicator to download the independent random number, and the on-site recording device uses a geographic information as the present Field verification, and at the same time a dynamic image of at least one grower cultivating an ecological structure is transmitted on-site, the geographic information and the dynamic image are combined and the independent random number is uploaded to the mesh network; an on-site service device can read the virtual Random number, and then connect the sealed packet stored by the electronic device in the mesh network with a built-in communication module, so that the virtual random number and the independent random number are combined into a random number to read the Seal the geographic information and the dynamic image in the package, and extract the location of the field recording device from the dynamic image containing the geographic information. The response of the number of the insect image or the animal image is gradually as time increases Get better or worse, or capture the location of the live recording device from the dynamic image. The emotional response of the animal kingdom is to gradually increase or decrease the positive emotion or the negative emotion with the increase of time, so as to examine the ecology Structure of product quality.

1: Electronic device

1a~1g: electronic device

11: processor

12: Random random number table

121, 131: independent random numbers

122, 132: Virtual random numbers

123, 133: Timeline

124, 134: sealed package

2, 2a, 2b: on-site recording device

2a~2g: On-site recording device

21, 21a, 21b: Communicator

221, 231: Geographic Information

222, 232: dynamic image

223, 233: Live timeline

3, 3a, 3b: field service device

3a~3o: Field service device

31, 31a, 31b: communication module

4: Mesh network

5: Blockchain

Figure 1 is a schematic diagram of the hardware of the Zhenshichengxian system of the present invention; Figure 2 is a flow chart of the Zhenshichengxian system using a mesh network architecture; A random random number table of virtual random numbers; Figure 4 is a flowchart of the on-site recording device connected to the mesh network to download the independent random number of the electronic device; Figure 5 is the combination of geographic information and dynamic image uploading the independent random number to the Internet Figure 6 shows the flow chart of combining independent random numbers and virtual random numbers into a sealed package; Figure 7 shows the on-site service device reads the virtual random numbers and then connects them to the mesh network. The sealed packet stored by the electronic device is used to read the flow chart of the dynamic image in the sealed packet; FIG. 8 is the electronic device constructing a random random number table including independent random numbers and a time axis connected to a mesh network Hardware schematic; Figure 9 is a flow chart of an electronic device constructing a random random number table including independent random numbers and a time axis to connect to a mesh network; A random random number table of random numbers and virtual random numbers; FIG. 11 is a random random number table including independent random numbers and a time axis according to the embodiments of FIGS. 8 and 9; The hardware schematic diagram of the system application in the blockchain network; Figure 13 is the flow chart of the electronic device constructing a random random number table including independent random numbers and virtual random numbers to connect to a blockchain network; Figure 14 is the electronic device A flow chart of constructing a random random number table containing independent random numbers and a time axis to connect to a blockchain network; Figure 15 is a flow chart of a field recording device connected to a blockchain network to download independent random numbers of an electronic device; Figure 16 is a flowchart of uploading the independent random number to a blockchain network by combining geographic information and dynamic images; Figure 17 is a flowchart of transforming the combined dynamic image of independent random numbers and virtual random numbers into a sealed package; and Figure 18 Read the virtual random number for the field service device, and then connect the sealed package stored by the electronic device in a blockchain network to read the flow chart of the dynamic image in the sealed package.

Please refer to FIG. 1, the first embodiment of the real food honesty system provided by the present invention mainly includes: an electronic device 1, a field recording device 2 and a field service device 3.

Please refer to FIGS. 3 and 4, the electronic device 1 uses a processor 11 to construct a random random number including an independent random number 121 (independent random number) and a pseudo random number 122 (pseudo random number) Table 12 (Table of random numbers) is connected to a mesh network 4 (or a blockchain network 5), and according to receiving a dynamic image 222 (dynamic image) containing a geographic information 221 image) A change in a state to update the independent random number 121 and the virtual random number 122 (the independent random number 121 and the virtual random number 122 after the update are defined as the independent random number 121(n+1) and the virtual random number 121 (n+1) Random number 122(n+1)); as shown in Figure 6, the independent random number 121 and the virtual random number 122 can be combined into a random number, and then an elastic function is used to make the independent random number 121 and the virtual random number Random number 122, the geographic information The message 221 and the dynamic image 222 are transformed into a hermetic package 124 (that is, a truly binary random bit, such as 1 or 0), and the sealed package 124 is stored, when the sealed package 124 is read (read access) At this time, the electronic device 1 obtains the insect image feature or the animal image feature from the dynamic image 222 of the animal kingdom (Animia) where the location of the field recording device 2 containing the geographic information 221 is located. The image features construct an insect image or an animal image and bring it into an environmental health impact assessment module to obtain at least an increase or decrease in a numerical response (e.g., increase in number, shrink in number, Fixed, unknown quantity), and then from the dynamic image 222 to obtain an emotional expression (emotional expression) audio characteristics (such as frequency, rhythm, volume changes, intensity changes, etc., to find the corresponding emotional response of the animal world), The affect reciprocity of an animal kingdom corresponding to the audio feature is obtained from a plurality of preset emotional dimension databases as a positive emotion or a negative emotion, and then, An environmental health value (environmental health value) is generated according to the increase or shrinkage of the quantitative response of the animal kingdom, or the emotional response of the animal kingdom; to provide the environmental health value of the ecological structure or the animal kingdom The emotional response is gradually getting better or worse with the increase of time. The environmental health value or the emotional response will gradually become worse as the grower uses more pesticides, or gradually get better without using pesticides. The animal kingdom consists of plural kinds of the insects, plural insect groups, and plural kinds of the animals. And the formation of plural animal groups.

The insect image feature or the animal image feature can also reflect the animal kingdom’s response to this through different colors, geometric changes, image changes, speed changes, and different rhythms (such as rotation, nodding, beating...), etc. The emotions, reactions or feelings of the ecological structure, the displayed images can be flat images or three-dimensional images. For example, in an ecological structure, the field is cultivated by natural agricultural methods without pesticides. When multiple insects or multiple animals pass through the on-site recording device 2, corresponding individual image features of the insect or the animal image can be generated respectively, and then transmitted to the electronic The device 1 generates and presents a grouped dynamic image 222 (including a majority of insect images or a majority of animal images) on the field service device 3 with a display accordingly, and the grouped dynamic image 222 (including a majority of insects) The image or most animal images) can be produced by combining a large number of the animal kingdom images, or the animal kingdom can additionally generate the dynamic image 222 (including most insect images or Most animal images), for example, the more insects or animals, the higher the intensity, the stronger the brightness of the flash in the image, etc.

As shown in FIG. 4, the record on spot device 2 (record on spot device) is connected to the mesh network 4 (or the blockchain network 5) with a communicator 21 to download the independent random number 121, and the spot record The device 2 uses the geographic information 221 (geographic information) of a geographic information system (GIS) for positioning, or the global positioning information of a global positioning satellite (GPS) for positioning, or a global positioning satellite ( GPS) Global positioning data and the geographic information 221 of a geographic information system (GIS) are used as field verification and live transmission at the same time whether at least one planter uses a natural agriculture method to cultivate (cultivation) ) A dynamic image 222 of the ecological structure, the combination of the geographic information 221 and the dynamic image 222, the independent random number 121 is uploaded to the mesh network 4 (or the blockchain network 5); the dynamic image 222 includes at least the real estate of the insect image feature of the animal kingdom of the live action, or the increase or shrinkage of the quantitative character of the animal image feature. Or the emotion of the animal kingdom responds to the actual situation of the increase or decrease of positive emotions, or the true condition of the increase or decrease of negative emotions; as shown in Fig. 7, in a field service device 3 with a display ( field service device) can read the virtual random number 122, and then connect the electronic device in the mesh network 4 (or the blockchain network 5) with a built-in communication module 31 (communication module) 1. The sealed packet 124 stored in 1 makes the virtual random number 122 and the independent random number 121 combined into a random number, so as to read the geographic information 221 and the dynamic image 222 in the sealed packet 124, and from containing the The dynamic image 222 of the geographic information 221 captures the location of the field recording device 2 and the numerical response of the insect image or the animal image is gradually getting better or worse with the increase of time, or from The dynamic image 222 captures the location of the scene recording device 2 and the emotional response of the animal kingdom gradually increases or decreases with the increase of time. To the emotion, or gradually increase or decrease the negative emotion with the increase of time, in order to examine the product quality of the ecological structure.

Please refer to FIG. 8, the second embodiment of the real food honesty system provided by the present invention mainly includes: an electronic device 1, a field recording device 2 and a field service device 3.

Referring to FIGS. 8 and 11, the electronic device 1 uses a processor 11 to construct a random random number table 12 including an independent random number 121 and a time axis 123, which is connected to a mesh network 4 ( Or a blockchain network 5), and update the independent random number 121 and the time axis 123 according to a change in a state of a dynamic image 222 including a geographic information 221 and a live time axis 223 (after the update) The independent random number 121 and the 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 random number , And then use an elastic function to convert the independent random number 121, the time axis 123, the geographic information 221, the dynamic image 222, and the live time axis 223 into a sealed packet 124 (that is, a real binary random bit, such as 1 or 0), and store the sealed package 124. When the sealed package 124 is read, the electronic device 1 retrieves one of the locations of the field recording device 2 including the geographic information 221 and the field time axis 223 The dynamic image 222 of the animal kingdom acquires the insect image feature or the animal image feature therein, and then constructs an insect image or an animal image based on the image feature and brings it into an environmental health impact assessment module to obtain at least an increase in the number of responses Or shrinking (for example: increase in quantity, fixed quantity, shrinking quantity, unknown quantity), then An audio feature of an emotional expression can be obtained from the dynamic image 222, and the emotional response of an animal world corresponding to the audio feature can be obtained from a plurality of preset emotional dimension databases as a positive emotion or a negative emotion , And then, based on the increase or shrinkage of the quantitative response of the animal kingdom, or the emotional response of the animal kingdom, an environmental health value (environmental health value) is generated; to provide the environmental health value of the ecological structure or The emotional response of the animal kingdom is gradually getting better or worse with the increase of time. The environmental health value or the emotional response will gradually become worse as the grower uses more pesticides, or gradually get better without using pesticides. If the number in the animal kingdom is an increase or a fixed number, the environmental health value is gradually improved because no pesticides are used. If the quantitative response of the animal kingdom is shrinking or unknown, it means that the increase in pesticide use has gradually worsened the environmental health value. The animal kingdom is formed by plural kinds of insects, plural insect groups, plural kinds of animals, and plural animal groups.

The electronic device 1 obtains from the dynamic image 222 the audio feature of at least one emotional expression of the animal kingdom at the location of the live recording device 2 to obtain the audio feature corresponding to the predetermined emotional dimension database The emotional response of an animal kingdom of is an increase or decrease of a positive emotion, or an increase or decrease of a negative emotion, and the emotional response of the animal kingdom of the ecological structure where the site recording device 2 is located is known It is gradually getting better or getting worse over time. The environmental health value or the emotional response will gradually become worse as the grower uses more pesticides, or the grower does not use pesticides. The gradient is good. If the emotional response of the animal kingdom is well-being or excitement, the environmental health value is gradually getting better. If the emotional response of the animal kingdom is panic, aggressive, and hopelessness, the environmental health value is gradually getting worse.

In the present invention, the sound records of different terrestrial animals of cats, dogs, cows, sheep, and horses are collected; in the first stage, the different terrestrial animals are classified according to a systematic zoology, such as: Contents such as morphology, classification, evolution and economic significance are classified in the form of system zoology. The second level is followed by the emotional analysis based on the sound level and distinguishing the animal. At the same time, acoustic analysis is performed on the recorded terrestrial animal sounds, and the sound frequency is used to understand the sounds of different terrestrial animals. An emotion expression rule (emotion display rule) of the audio characteristics of the A, through the emotion expression rule to distinguish the positive emotion or the negative emotion. The positive emotions are: well-being or excitement. The negative emotions are: panic, aggressive, and hopelessness. The location of the scene recording device 2 is an audio feature of emotional expression obtained in the dynamic image 222 of an animal world (Animia), such as the emotional response of the animal world is the positive emotion well-being (well-being) Or excited (excitation), then the environmental health value is gradually improved or the use of pesticides is reduced. If the emotional response of the animal kingdom is panic, aggressive, and hopelessness of the negative emotion, then the environmental health value is a judgment that the environmental health value is gradually getting worse or the use of pesticides is increasing.

The field recording device 2 is connected to the mesh network 4 (or the blockchain network 5) through a communicator 21 to download the independent random number 121, and the field recording device 2 is the geographic information of a geographic information system. 221 for positioning, or the global positioning data of a global positioning satellite for positioning, or the global positioning data of a global positioning satellite and the geographic information of a geographic information system 221 plus a field time axis of the field recording device 2 223 is used as on-site verification and the site transmits a dynamic image 222 of whether at least one grower cultivates an ecological structure using a natural agricultural method. The geographic information 221, the dynamic image 222 and the on-site timeline 223 are combined and the independent random number 121 is uploaded to The mesh network 4 (or the blockchain network 5), the dynamic image 222 includes at least the insect image feature of the animal kingdom performed live, or the increase in the quantitative character of the animal image feature Or the true state of shrinking. Or the emotion of the animal kingdom responds to the actual situation of the increase or decrease of positive emotions, or the true condition of the increase or decrease of negative emotions; the timeline can be read into the field service device 3 with a display 123. Connect a built-in communication module 31 to the sealed packet 124 stored in the electronic device 1 in the mesh network 4 (or the blockchain network 5), so that the time axis 123 is connected to the The independent random number 121 is combined into a random number to read the time axis 123 and the dynamic image 222 in the sealed package 124, and extract the dynamic image 222 from the geographic information 221 and the live time axis 223 Where the field recording device 2 is located, the quantitative response of the animal kingdom is gradually getting better or worse with the increase of time; or from the dynamic image 222 Capture the emotional response of the animal kingdom at the location of the scene recording device 2 to gradually increase or decrease the positive emotion with the increase of time, or gradually increase or decrease the negative emotion with the increase of time, to view the Product quality of ecological structure.

The electronic device 1 uses the elastic function to perform the insect image feature of the animal kingdom, or the animal image feature, or the emotional response combination of the dynamic image 222 to prevent the occurrence of deviation. For example, in the dynamic image 222, some animals may lead the result in the desired direction. The elastic function can protect the real estate of the animal kingdom of the dynamic image 222. The present invention selects a majority of the animal kingdom, for example, selects plural kinds of the insects and plural insect groups in the animal kingdom, and then selects 3 to 5 groups of the dynamic images 222 in a continuous time. Then select one type 1 insect, one type 2 insect in each group... an n type insect, or a majority of type n+1 insects (if the type 1 insect is a majority), and then select the The number of category 1 insects is divided into 3 groups, and then the majority of the category 1 insects in each group are extracted, and so on until at least one insect (that is, the category 1 insect) in the dynamic image 222 can be obtained. The image 222 will show that the insect (that is, the first type of insect) is the image feature of the insect at the location of the field recording device 2, or the image feature of the animal, or the real estate of the emotional response. This approach enables the electronic device 1 to tolerate the existence of a large number of blind spots in the dynamic image 222, and in terms of generating the dynamic image 222, this approach can filter out the number of deviations.

In addition, the elastic function is to select the majority of the animal kingdom, for example: select the plural species of the animal and the majority of the plural animal groups in the animal kingdom, and then select 3 to 5 groups of the dynamics in a continuous time (continuous time) Image 222, and then select a category 1 animal, a category 2 animal...an n category animal, or a majority of n+1 category animals (if the category 1 animal is a majority) in each group, and then The number of animals in the first category is selected and divided into 3 groups, and then the majority of the animals in the first category in each group is selected, and so on until at least one animal in the dynamic image 222 (that is, the first animal) is obtained. The dynamic image 222 will show that the animal (ie, the first type animal) is the insect image feature at the location of the field recording device 2, or the animal image feature, or the real estate of the emotional response. This approach enables the electronic device 1 to tolerate the existence of a large number of blind spots in the dynamic image 222, and in terms of generating the dynamic image 222, this approach can filter out the number of deviations.

The electronic device 1 may include Internet access functions (for example, a smart phone); however, it may also be a personal digital assistant (PDA), a desktop computer, a notebook computer, and a tabular computer (tabular computer). ). In this 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 can be at least electrically coupled to the network system, the storage medium, and the input/output device.

The network system can support wireless signal transmission of at least one of the following systems: a global system for mobile communications communication, GSM), a fourth generation communications system (Fourth Generation Communications System), a 5th generation mobile networks (5th generation mobile networks), a long term evolution (LTE) network, and a wireless compatible Authentication (wireless fidelity, Wi-Fi) system, a worldwide interoperability for microwave access system, a mesh network 4 and a blockchain network 5.

The independent random number 121 of the electronic device 1 is unpredictable, so it is impossible to repeatedly generate two identical series of the independent random number 121. The independent random number 121 can only be generated by the process of randomly receiving the dynamic image 222, for example, according to the on-site recording device to receive a dynamic image 222 a change in the state to update the independent random number 121 (the independent random number after the update) 121 is defined as the independent random number 121(n+1)). The independent random number 121 sequence is generated by an independent random number generator, and is based on the natural occurrence of the positive emotion or the negative emotion of the emotional response of the insect or the animal in nature (autogeny) The natural random characteristics of the phenomenon and the real random source. For the independent random number generator, there is no initial sequence or initial number, which can eliminate the period problem of pseudo-randomness and is difficult to crack at the same time.

At present, the virtual random number 122 applied by the electronic device 1 is usually calculated by some mathematical formula. The virtual random number 122 is generated by a pseudo random number generator (pseudo random number generator), which is generated by a pseudo random number generator. Starting from the initial state, the virtual random number 122 is generated through a certain algorithm. Once the algorithm and seed are given, the output sequence is determined, and there is a certain The periodicity. The virtual random number 122 sequence generally has relatively good random statistical characteristics. It is generated by a mathematical algorithm and is close to a true random sequence in some statistical characteristics, but it is periodic and predictable. The virtual random number 122 is easy to obtain and convenient to use, and is generally used in applications such as simulation, commerce, and sales.

2 and 9 show a mesh network 4 architecture according to an embodiment of the present invention. 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 The devices 3a, 3b have similar elements, features and functions to the electronic device 1. In this embodiment, the mesh network 4 is enumerated as a proximity-based network architecture with a three-level hierarchical architecture.

FIG. 2 is a flowchart of a method for sharing the dynamic images 222 and 232 on the mesh network 4 according to an embodiment of the present invention. The present embodiment may include multiple scenarios. The electronic device 1 is the root node of the mesh network 4 and also the group owner of the mesh network 4. The electronic device 1 can be used as a root node, and share the dynamic images 222, 232 in the electronic device 1, and generate the independent random numbers 121, 131 and the virtual random numbers 122, 132 (or FIG. 9 The timeline 123, 133).

The field recording devices 2a and 2b are a first layer child node 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 of the electronic device 1 and downloads the independent random number 121, 131. The electronic device 1 can automatically transmit the independent random numbers 121 and 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 Join the mesh network 4. The on-site recording devices 2a, 2b are at least one video, or at least one image, or at least one continuous image, or at least one digital image (digital image) taken by a smart phone or a tablet computer. ), or at least one photo, or at least one image (picture), or at least one still picture (still picture) plus the geographic information 221, 231 of a geographic information system for positioning, or the global positioning of a global positioning satellite Data 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 at least one image or at least one image of the farmer (grower) is used to verify the farmer (planting)者) The ecological structure cultivated by himself, let each consumer observe (watch) whether the farmer (grower) cultivates the farmer (grower) according to the natural farming method, the geographic information 221, 231 and the dynamics of the ecological structure of the farmer (grower) The images 222 and 232 are combined with the independent random numbers 121 and 131 and uploaded to the mesh network 4.

Allow the consumer to purchase the origin and production process of the farmer's (grower) product, so that the food safety is fully presented by the dynamic images 222, 232, which show the biological structure of the ecological structure (farm). Chain, the animal kingdom is based on the positive emotion or the negative emotion of the insect image feature, or the animal image feature, or the insect or the emotional response of the animal, and let the insect or the animal itself guarantee friendly planting, the Dynamic image 222, 232 presentation Insect certification, or animal certification, or the positive emotion or negative emotion of the animal kingdom’s emotional response to the dining table can make the consumer feel more at ease and enhance the brand image more transparently.

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 through the mesh network 4 for processing, The processor 11 first performs edge detection on a series of the image or the image, and then obtains the edge binary image and then uses the processor 11 to learn. After the learning is completed, it uses motion detection (motion detection). detection) The algorithm detects the moving insect or animal to capture the moving insect or part of the animal, and then merges the insect or the animal’s part through a block multiplexer And then remove the shadow by a shadow merge method to obtain the quantitative characteristics of the insect or animal in nature.

When the farmer A downloads the independent random number 121 from the root node of the electronic device 1 in a first geographic location using the first-level child node of the field recording device 2a, and then the geographic location of the first geographic location The information 221 is combined with the dynamic image 222 and the independent random number 121 is uploaded to the root node or the electronic device 1.

However, another farmer B downloads the independent random number 131 from the root node of the electronic device 1 in a second geographic location using the first-level child node of the field recording device 2b, and then the second geographic location The geographic information 231 of the location is combined with the dynamic image 232, and the independent random number 131 is uploaded to the root section Point or this electronic device 1.

The field service device 3a and the field service device 3b are the second layer child nodes of the electronic device 1 and read the virtual random numbers 122, 132 (or the time axis 123, 133 of FIG. 9). ). The on-site service devices 3a and 3b are a consumer, a store, a dealer, a spreader, a value trader, a market maker, and a market maker. A smart phone or tablet owned by a price taker; when the consumer, the store, the dealer, the spread trader, the stock-identifying trader, the market creator, and the price taker Use a camera on the smartphone or the tablet to read a bar code symbol or a bar code data formed by the virtual random number 122, 132 (or the time axis 123, 133 in Figure 9) (barcode data) or a bar-coded label to connect the built-in communication module 31a, 31b to the sealed package 124, 134 stored in the electronic device 1 in the mesh network 4; As shown in FIG. 7, when the consumer C uses the field service device 3a of the consumer C from the store in a third geographic location (or an nth geographic location, or an n+1 geographic location) ( A camera on the smart phone or the tablet computer reads the virtual random number 122 to connect to the sealed package 124 stored in the electronic device 1 in the mesh network 4, and then reads the sealed package 124 The dynamic image 222 captures the live recording device 2a at a first geographic location where the number of the insects reflects the life of the captured insects History and insect structure, insect morphology (insect morphology), insect ecology (insect ecology), or whether colonial insects (colonial insects) increase or decrease, for example: insects belong to the class of insects in taxonomy, regardless of type or number It is the most in the animal kingdom. Take this insect as an example. The development process of an insect undergoes a series of changes, called metamorphosis. Depending on the degree of metamorphosis, it can be classified as: complete metamorphosis, incomplete metamorphosis, and no metamorphosis. Metamorphosis (ametabolic). The life history of the insect is divided into egg stage, juvenile stage, (pupa stage), and adult stage. The completely metamorphic insect has the pupal stage, while the incompletely metamorphic and non-metamorphic insects do not have the pupal stage. The quantitative characteristics of the insect, for example, belong to a completely metamorphic butterfly, which was a caterpillar when it was young, and pupas when it grows up, and finally emerges into a butterfly with beautiful wings. 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 appendages. For example, the head generally has antennae, and the chest often has 3 pairs of walking feet and 2 pairs. wing.

In addition, when the consumer D uses the field service device 3b (the smartphone Or a camera on the tablet computer) reads the virtual random number 132 to connect to the sealed package 134 stored in the electronic device 1 in the mesh network 4, and then reads the dynamic image in the sealed package 134 222, 232 capture the number of insects of the field recording device 2b at a second geographic location and reflect the life history of the captured insects With the increase or decrease of insect structure, insect morphology, insect ecology, or whether there are colonial 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 through the random number table 12. 10 is a schematic diagram of random numbers including the random number table 12 according to the embodiments of FIGS. 1 to 2, wherein the random number table 12 shows the updated dynamic images 222 and 232 in the mesh network 4 A number of different stages, and the random random number table 12 includes complex independent random numbers 121, 131, complex independent random numbers 121(n), 131(n), complex independent random numbers 121(n+1), 131(n+1) and complex number of virtual random numbers 122, 132, complex number of virtual random numbers 122(n), 132(n), complex number of virtual random numbers 122(n+1), 132(n+1), But it is not limited to this.

11 is a schematic diagram of random numbers including the random random number table 12 according to the embodiments of FIGS. 8-9, wherein the random random number table 12 includes complex independent random numbers 121, 131, and complex independent random numbers 121 ( n), 131(n), complex number independent random numbers 121(n+1), 131(n+1) and complex number time axis 123, 133, complex number time axis 123(n), 133(n), complex number The group time axis 123(n+1), 133(n+1), but not limited to this.

The processor 11 of the electronic device 1 can update the independent random numbers 121 and 131 according to the change of the state of the field recording device 2a or the field recording device 2b. For example, in a situation, in the scene recording device 2a Or after the state of the on-site recording device 2b changes, FIGS. 10 and 11 illustrate updating the independent random numbers 121, 131 and the virtual random numbers 122, 132 (or the time axis 123, 133 in FIG. 11), and the updated The independent random numbers 121, 131 and the virtual random numbers 122, 132 (or the time axis 123, 133 in FIG. 11) are defined as the independent random numbers 121(n+1), 131(n+1) and the virtual random numbers. The numbers 122(n+1), 132(n+1) (or the time axis 123(n+1), 133(n+1) in FIG. 11). Referring to FIG. 5, after the field recording device 2a or the field recording device 2b transmits the dynamic images 222, 232 on site, the field recording device 2a or the communicator 21a, 21b of the field recording device 2b can be based on the corresponding The path in a routing information base is reported back to the electronic device 1 by reverse transmission. After being notified, the electronic device 1 also uses the uncertainty of the upload time of the dynamic images 222 and 232 in the random random number table 12, so that time can be used as a random number seed to be the first of the electronic device 1. The field recording device 2a or the field recording device 2b of the layer child node downloads and updates the independent random number 121(n+1), 131(n+1), or for the field service device 3a and the field service device 3b As the second layer child node of the electronic device 1, read the virtual random numbers 122(n+1), 132(n+1) (or the time axis 123(n+1) of FIG. 11 ), 133(n+1)). If you want to make the random random number table 12 more random, you can collect truly random events, such as creating a random pool, and continuously collecting physical random information in the system, such as keyboards, mice, and network signals. Waiting for input and output devices, system time, program ID, interruption time..., when the random random number table 12 requests to update the independent random number 121, 131 (after the update The independent random number 121, 131 is defined as the independent random number 121(n+1), 131(n+1)) or the virtual random number 122, 132 (the virtual random number 122, 132 after the update is defined as the Virtual random number 122(n+1), 132(n+1)) (or the time axis 123, 133 in Figure 11 (the time axis 123, 133 after the update is defined as the time axis 123(n+1), 133(n+1))), the processor 11 of the electronic device 1 can obtain information from the random pool and return it after being calculated by the electronic device 1. Such random numbers can conform to the true randomness of cryptography. Requirements, that is, random samples cannot be reproduced. 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".

The Zhenshichengxian system provided by the present invention is applied to the technology of a blockchain network 5. Please refer to FIG. 12, which is a blockchain architecture applied by the method of the present invention. The blockchain of this embodiment The network 5 includes a plurality of nodes that communicate with each other, and each node can be the electronic device 1. In this embodiment, among all the nodes in the blockchain network 5, the electronic devices 1a~1g can be defined as A source node, the field recording devices 2a~2g are a physical node, and the field service devices 3a~3o are a hypermedia node.

As shown in FIG. 13, the original node of the electronic device 1 is to construct the independent random numbers 121, 131 and the virtual random numbers 122, 132 (or the time axis 123, 133, as shown in FIG. 14), receive or The nodes where the geographic information 221, 231 and the dynamic image 222, 232 are read (or include the location as shown in FIG. 14) Management information 221, 231 and the nodes of the dynamic images 222, 232 of the scene time axis 223, 233). Wherein, the original node is the electronic device 1 with high computing capability.

The on-site recording devices 2a, 2b are at least one video, or at least one image, or at least one continuous image, or at least one digital image (digital image) taken by a smart phone or a tablet computer. ), or at least one photo, or at least one image (picture), or at least one still picture (still picture) plus 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 of a geographic information system 221, 231) for positioning, and the farmer (grower) uses the field recording device 2a, 2b to verify the self-portrait, allowing each consumer to observe ( watch) Whether the farmer (grower) uses the natural farming method to cultivate the geographic information 221, 231 and the dynamic images 222, 232 of the farmer's (grower) ecological structure and upload it to the blockchain network 5, so that consumers Purchase the origin and production process of the farmer's (grower) product, so that the food safety is presented by the dynamic images 222, 232. The dynamic images 222, 232 show the biological chain constructed by the biological nature of the ecological structure (farm). The image feature, or the animal image feature, or the positive emotion or the negative emotion of the insect or the emotional response of the animal, allowing the insect or the animal to ensure friendly planting. The dynamic image 222, 232 presents the insect Certification, or animal certification, or the positive emotion or negative emotion of the animal kingdom’s emotional response to the dinner table can provide consumers with more peace of mind and improve the brand image. L More transparent.

When the farmer A downloads the independent random number 121 from the original node using the physical node of the field recording device 2a in a first geographic location, and then combines the geographic information 221 of the first geographic location with the dynamic image 222 The independent random number 121 (or the geographic information 221, the dynamic image 222, and the live timeline 223 in FIG. 14 combined with the independent random number 121) are uploaded to the original node or the node.

The other farmer B downloads the independent random number 131 from the original node using the physical node of the field recording device 2b in a second geographic location, and then the geographic information 231 of the second geographic location and the dynamic The image 232 is combined with the independent random number 131 (or the geographic information 231, the dynamic image 232, and the live timeline 233 in FIG. 14 are combined with the independent random number 131) and uploaded to the original node or the node. At the same time, rebroadcast an updated dynamic image 222, 232 to the original node of the electronic device 1 to provide the original node of the electronic device 1 for the dynamic image 222, 232 to update the independent random numbers 121, 131 and the The nodes of the virtual random numbers 122 and 132 (or the time axis 123 and 133 in FIG. 14).

After describing the system architecture applied by the method of the present invention, please refer to FIGS. 15 to 18 to illustrate the high security of the dynamic image 222, 232 transmission method of the blockchain network 5 of the present invention. For the process flow, please refer to Fig. 15 first. The original node of the electronic device 1 broadcasts the independent random numbers 121 and 131 to the blockchain network 5 so that the The physical node of the field recording device 2a and the field recording device 2b can receive the independent random numbers 121, 131, wherein the independent random numbers 121, 131 include a random random number and a transmission data, the independent random numbers 121, 131 The value of should be at least five or more than an odd number, or the independent random numbers 121 and 131 should be at least four or more than an even number. In this embodiment, five is used as an example for illustration, and the transmission data is Binary code, such as 01001.

As shown in detail in FIG. 16, when the dynamic images 222, 232 of the physical node of the field recording device 2a and the field recording device 2b are broadcast to the blockchain network 5, The other nodes will also receive it. Therefore, the received node will forward the dynamic image 222, 232 to one of the other nodes of the electronic device 1 in the blockchain network 5. When the original node of the electronic device 1 again When a change of the dynamic images 222 and 232 is received, the independent random numbers 121 and 131 and the virtual random numbers 122 and 132 (or the time axis 123 and 133) are updated again.

As shown in FIG. 17, the hypermedia node of the field service device 3a and the field service device 3b can first read the virtual random number 122, 132 (or the time axis 123, 133) in the original node, Combine the virtual random numbers 122, 132 (or the time axis 123, 133) and the independent random numbers 121, 131 into a random number, and then use an elastic function to combine the independent random numbers 121, 131 and the virtual random number. Random numbers 122, 132, the geographic information 221, 231 and the dynamic images 222, 232 are converted into a sealed package 124, 134, and the sealed package 124, 134 is stored, when the sealed package 124, 134 is read (read access ) To read the original The dynamic images 222 and 232 in the node. Wherein, the hypermedia node directly designates a high-capacity computing node in the blockchain network 5 as the hypermedia node according to a user operation signal operated by a user.

Then with reference to FIG. 18, the virtual random numbers 122, 132 (or the time axis 123, 133) broadcast by the original node of the electronic device 1 can be used by at least two of the field service device 3a and the field service device 3b. The hypermedia node reads in, so that the hypermedia node of the field service device 3a and the field service device 3b is connected to the electronic device 1 again with the virtual random number 122, 132 (or the time axis 123, 133) In the original node, the original node of the electronic device 1 receives the same virtual random number 122, 132 (or the time axis 123, 133) again, and the electronic device 1 causes the virtual random number 122, 132 (or the Time axis 123, 133) and the independent random number 121, 131 are combined into a random number to read the dynamic image 222, 232 in the original node, and extract the field recording device 2a from the dynamic image 222, 232 , The location of 2b, the quantitative response of the animal kingdom, and the environmental health value of the ecological structure of the field recording device 2a, 2b and the emotional response of the animal kingdom. Wherein, the hypermedia node can be used by the original node of the electronic device 1 to designate a node with stronger computing power in the blockchain network 5 as the field service device 3a and The hypermedia node of the field service device 3b, or the dynamic images 222, 232 of the physical node of the field recording device 2a and the physical node of the field recording device 2b are preferentially broadcast among all nodes of the blockchain network 5; After the physical nodes of the field recording device 2a and the field recording device 2b respectively forward the dynamic images 222 and 232 to the original node of the electronic device 1, when the supers The media node receives the number of updates to update the dynamic images 222 and 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, and the electronic device 1 receives a dynamic A change in the state of images 222 and 232 to update the independent random numbers 121 and 131 and the virtual random numbers 122 and 132 (or the time axis 123 and 133), and at the same time update the node positions of the independent random numbers 121 and 131 Send a report signal to the original node of the electronic device 1. For example, when the independent random numbers 121 and 131 and the virtual random numbers 122 and 132 (or the time axis 123 and 133) are updated, the original node of the electronic device 1 will notify the field service device 3a and the field service device 3b. The hypermedia node is updated. At this time, the dynamic images 222 and 232 updated by the original node truly become the hypermedia node to be read by the field service device 3a and the field service device 3b.

If the dynamic images 222, 232 of the physical node of the field recording device 2a and the field recording device 2b are uploaded to the blockchain network 5 through priority broadcasting, they are both the field service device 3a and the field service device 3b. The embodiment of the hypermedia node can read the virtual random numbers 122, 132 (or the time axis 123, 133) to specify which of the original hypermedia nodes of the field service device 3a and the field service device 3b is The node will become the field service device 3a and the hypermedia node of the field service device 3b. Factors are determined; for example, whether the electronic device 1 of the node is in an idle state when the dynamic image 222, 232 is received, or whether the signal between the original node of the electronic device 1 and another original node is smooth during broadcasting, or No collision with other signals, etc., can affect the speed at which the hypermedia node of the field service device 3a and the field service device 3b receives the dynamic images 222, 232 of the electronic device 1; therefore, in order to improve the scene The randomness of the hypermedia node selection of the service device 3a and the field service device 3b is also due to the fact that the independent random number 121, 131 and the virtual random number 122, 132 (or the time axis 123, 133) are selected according to this embodiment. The numerical value limits the number of physical nodes of the field recording device 2a and the field recording device 2b to the original node of the electronic device 1, and relatively increases the hypermedia of the field service device 3a and the field service device 3b. The uncertainty of the number and location of nodes makes it difficult for an attacker to locate the hypermedia nodes of the field service device 3a and the field service device 3b participating in each verification process.

To sum up, this case is not only innovative in terms of spatial form, but also can enhance the above-mentioned multiple functions compared with conventional items. It should fully meet the requirements of novel and progressive statutory invention patents. An application is filed in accordance with the law. Please approve this case. Patent applications for inventions, to encourage invention, to the sense of virtue.

1: Electronic device

11: processor

12: Random random number table

121, 131: independent random numbers

122, 132: Virtual random numbers

124: Sealed bag

2: On-site recording device

21: Communicator

221: the geographic information

222: Motion Picture

3: Field service device

31: Communication module

4: Mesh network

Claims (2)

A real food honesty system includes: an electronic device that uses a processor to construct an independent random number and a virtual random number connected to a mesh network, and receives a dynamic image and a status including a geographic information One change is to update the independent random number and the virtual random number, the independent random number and the virtual random number can be combined into a random number, and then use an elastic function to update the independent random number, the virtual random number, and the geographic random number. The information and the dynamic image are converted into a sealed package, and the sealed package is stored. When the sealed package is read, the electronic device obtains an insect image feature or an animal image from the dynamic image containing the geographic information Feature, and then construct an insect image or an animal image based on the image feature to increase or decrease in at least one quantitative response, and then an audio feature of emotional expression can be obtained from the dynamic image to obtain a plurality of preset emotional dimension data An emotional response of an animal kingdom corresponding to this audio feature obtained in the database is a positive emotion or a negative emotion, and then a response is generated according to the increase or shrinkage of the quantitative response of the animal kingdom, or the emotional response of the animal kingdom. Environmental health value; an on-site recording device that uses a communicator to connect to the mesh network to download the independent random number. The on-site recording device uses a geographic information as on-site verification, and transmits on-site at least one grower to cultivate an ecological A dynamic image of the structure, the geographic information and the dynamic image are combined and the independent random number is uploaded to the mesh network; an on-site service device can read the virtual random number, and then use a built-in link The communication module is connected to the sealed packet stored by the electronic device in the mesh network, so that the virtual random number and the independent random number are combined into a random number, so as to read the geographic information in the sealed packet and the Dynamic image, and extract the location of the field recording device from the dynamic image containing the geographic information. The quantitative response of the insect image or the animal image is gradually getting better or worse with the increase of time, or from The dynamic image captures the location of the live recording device and the emotional response of the animal kingdom is to gradually increase or decrease the positive emotion or the negative emotion with the increase of time, so as to examine the product quality of the ecological structure. A real food system includes: an electronic device constructed with a processor including an independent random number and a time axis connected to a mesh network, and based on receiving a geographic information and a live time axis A change in the state of a dynamic image is used to update the independent random number and the time axis, the independent random number and the time axis can be combined into a random number, and then an elastic function is used to use the independent random number, the time axis, The geographic information, the dynamic image, and the on-site timeline are converted into a sealed package, and the sealed package is stored. When the sealed package is read, the electronic device reads the dynamics from the geographic information and the on-site timeline. The image acquires an insect image feature or an animal image feature, and then constructs an insect image or an animal image based on the image feature and brings it into an environmental health impact assessment module to obtain at least one quantitative response increase or atrophy. Obtain an audio feature of emotional expression from the dynamic image, so as to obtain the plural emotions from the preset An emotional response of an animal kingdom corresponding to this audio feature obtained in the thread orientation database is a positive emotion or a negative emotion, and then, according to the increase or shrinkage of the number of responses in the animal kingdom, or the animal kingdom’s The emotional response generates an environmental health value; an on-site recording device is connected to the mesh network with a communicator to download the independent random number, in order to use a geographic information plus an on-site timeline for on-site verification and at least on-site transmission Whether a grower uses a natural farming method to cultivate a dynamic image of an ecological structure, the geographic information, the dynamic image, and the on-site timeline are combined and the independent random number is uploaded to the mesh network; an on-site service device can be read Enter the time axis, and then connect the sealed packet stored by the electronic device in the mesh network with a built-in communication module, so that the time axis and the independent random number are combined into a random number for reading The time axis and the dynamic image in the sealed package, and the location of the field recording device is retrieved from the dynamic image containing the geographic information and the scene time axis, and the response of the quantity of the animal kingdom is over time The increase gradually becomes better or gradually becomes worse, or the emotional response of the animal kingdom is to gradually increase or decrease the positive emotion or the negative emotion with the increase of time by capturing the location of the live recording device from the dynamic image to view The product quality of this ecological structure.

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