LU101062B1 - LED lighting as a device for all types of financial transactions - Google Patents

Abstract

The invention provides various connected lighting devices for financial transaction applications in particular using a public channel or a private channel. This device helps ensure secure financial transactions and the use of every LED in a business environment.

Description

LED LIGHTING AS A DEVICE FOR ALL TYPES OF

FINANCIAL TRANSACTIONS Technical area

The present invention relates generally to a device allowing a digitized financial transaction, secure compatible with a conventional financial transaction and compatible with financial transactions using a public chain (hereinafter referred to as CPu) or a private chain (noted hereinafter CPr) or a consortium chain (hereinafter referred to as CCo), more commonly called “Blockchain”, (hereinafter referred to as BC). State of the art

[0002] In the field of the invention, banking transactions are becoming more and more digital. These banking transactions must follow all the technological advances that it is at the level of the security of the transaction, but also that it is at the level of the technological means used to operate these banking transactions.

[0003] In the field of the invention, banking transactions can take place directly between a customer's smartphone and the banking network, but the use of radio waves both upstream and downstream thus increases the risk piracy and involves uncertainty about the geolocation of the transaction due to the limited precision of radio waves.

[0004] In the field of the invention, digitized banking transactions increasingly call on crypto-currencies and technologies from public chains (CPu), private chains (CPr) or Consortium chains (hereinafter referred to as CCo) , also called "blockchain".

[0005] In the field of the invention, cryptocurrency or CPu, CPr and CCo require the use of mining devices to generate new cryptocurrencies, which requires a lot of energy and space, in order to manage large computing capacities.

Object of the invention

[0006] An object of the present invention is to provide an original solution to enable digitalized, secure and geolocated financial transaction applications. General description of the invention

In order to solve the problem mentioned above, the present invention proposes in a first aspect, a method of carrying out secure and geolocated financial transactions by means of LED lighting device (s) connected in a network (004), and equipped with wired or wireless hybrid communication, each LED lighting device comprising a mining system to animate a blockchain (BC) and / or to feed the register of a Public Channel (CPu), a Private Channel ( CPr) or a Chain Consortium (CCo) of one or more crypto-currencies, including a first microcontroller, preferably of the ASIC type, configured to manage one or more BCs and / or to act as a mining node for said BC (s); a connection to a data network; a motherboard; storage means for at least temporarily storing data, in particular data received from the data network, preferably an SSD hard disk; one or more communication transmitter / receiver modules, chosen from a WiFi communication transmitter / receiver module, a Bluetooth communication transmitter / receiver module, an Ethernet communication transmitter / receiver module, a PLC communication transmitter / receiver module and a module fiber optic communication (OF) transmitter / receiver for communication with other LED lighting devices and / or the data network; a permanent unique identifier (UiD), preferably a unique IP address; one or more LEDs as an OLC communication transmitter, preferably LiFi and / or IRDA, a second microcontroller, preferably of the FPGA or ASIC type to manage the data communication by the communication modules.

[0008] Preferably, the method comprises the use of networked LED lighting devices to manage secure and geolocated financial transactions by two distinct methods, either by using a CPu or CPr or CCo (case A), or by a conventional method of data transmission between the authorizing officer of the transaction and a banking network (case B), in the manner of a payment terminal with a credit or debit card. Preferably, the networked LED lighting devices can manage the two cases (A) and (B) in parallel.

Preferably, for case (A), the LED lighting devices act as mining devices of a "blockchain" as a link in the network of miners and are controlled by a central unit to act with each other. the others in order to dynamically adapt the complexity of the calculations to the overall power available or necessary for the CPu, the CPr or the CCo for the BC.

In the method according to the invention, in parallel with financial transactions, the same LED lighting devices can be used for the management of smart contracts in the case of a Public Channel through the mining pool or else to send non-financial data, including digital coupons.

[0011] In a preferred embodiment, the method using a network of LED lighting devices as financial transaction devices, comprises the following steps: (a) each LED lighting device continuously sends an invitation message, comprising its UiD, by an OLC communication protocol, preferably by LiFi and / or IRDA; in the absence of active two-way communication with a mobile device, the WiFi and Bluetooth modules are only activated for the receiver function, (b) when a mobile device receives the invitation message with the UiD from a device LED lighting, the mobile device activates communication via WiFi and / or Bluetooth and transmits by at least one of these protocols an acceptance message comprising the received UID and its own unique identifier, (c) when LED lighting device receives a WiFi and / or Bluetooth acceptance message including its UID, it also activates the transmitter function of the WiFi or Bluetooth transmitter module (s) corresponding to the protocol of the message from acceptance and establishes a two-way communication by this protocol (s) with the mobile device, and

(d) the two-way communication remains active as long as the mobile device receives invitation messages with the UiD of the LED lighting device with which the two-way communication is active and the two-way communication is terminated by the mobile device, when no longer receives an invitation message from the LED lighting device, preferably the two-way communication is terminated after a determined latency time; and in the absence of active communication with a mobile device, the transmitter function of the WiFi and Bluetooth modules are deactivated.

In case (A), the method further preferably comprises the following steps: (e) when the two-way communication is active, the client, as the authorizing officer of a transaction, sends a financial order, in particular for the purchase of a product, by means of a mobile application to the LED lighting device with which it is in bidirectional communication, this financial order comprising as primary data an order to purchase a product, the number of credit necessary for this purchase, the place of purchase, the identity of the customer and the UID of his mobile device, as well as the date and time of purchase, this primary data being sent to the entire BC at destination of the operator, (f) then, a transaction corresponding to the financial order is entered in a common register of the BC, the information of the transfer operation is sent to at least one of the LED lighting devices for verification of the validity of the transaction, (g) when the transaction is considered valid by the CB, a new block is created, entered in the common register and added to the series of existing blocks, and the network sends the validation of its transaction to the authorizing officer of the transaction.

In case (B), the method preferably further comprises the following steps: (e) when two-way communication is active, the client as the authorizing officer of a transaction, a financial order, in particular for the purchase of a product, through a mobile application to the LED lighting device with which it is in two-way communication, this financial order comprising as primary data an order to purchase a product, the number of credits required at this purchase, the place of purchase, the identity of the customer and the UID of his mobile device, as well as the date and time of purchase, this primary data being sent through the network to a central server which in turn transmits it to a bank server, (f) the bank server sends the validation of the transaction via the network to the authorizing officer of the transaction.

When the mobile device has sent an acceptance message by means of the two WiFi and Bluetooth protocols, the two-way communication is generally done by one of these protocols, preferably according to the data rate exchanged, particularly preferred bidirectional communication is via Bluetooth for speeds below 2 Mbit / s and WiFi for higher speeds.

[0015] Advantageously, the two-way communication comprises sending data from storage means included in the LED lighting device or from a data network to which the LED lighting device is connected, in particularly transaction data, but also geolocation data or other data permitted and requested by the mobile device.

[0016] In preferred variants of the method, the management of the steps mentioned above is carried out by an application on the mobile device.

[0017] The invention relates, in a second aspect, to an LED lighting device comprising a mining system for animating a blockchain (BC) and / or for feeding the register of a Public Channel (CPu), of a Private Chain (CPr) or of a Consortium Chain (CCo) of one or more crypto-currencies, including a first microcontroller, preferably of the ASIC type, configured to manage one or more BCs and / or to act as a node mining for said BC (s); a connection to a data network; a motherboard; storage means for at least temporarily storing data, in particular data received from the data network, preferably an SSD hard disk; one or more communication transmitter / receiver modules, chosen from a WiFi communication transmitter / receiver module, a Bluetooth communication transmitter / receiver module, an Ethernet communication transmitter / receiver module, a PLC communication transmitter / receiver module and a transmitter module / fiber optic communication (OF) receiver for communication with other LED lighting devices and / or the data network; a permanent unique identifier (UiD), preferably a unique IP address; one or more LEDs as an OLC communication transmitter, preferably LiFi and / or IRDA, a second microcontroller, preferably of the FPGA or ASIC type to manage the data communication by the communication modules.

The connection of the LED lighting devices to the data network is preferably configured for connection to a wired network, preferably by line powerline (CPL), by optical fiber (OF) or by Ethernet, in particular by an IP protocol.

Advantageously, the LED lighting devices are in the form of a floor lamp, a hanging lamp, a panel, a tube preferably T5, T8, etc. .., a ceiling light , a wall light, a down-light or a projector, or in the form of a bulb suitable for common sockets, preferably E27, E14, GU10, B22d or B15d.

[0020] It is more advantageous if the LED lighting devices further include other transmitter / receiver communication modules, in particular transmitter / receiver communication modules of the following communication technologies: ZigBee, Zwave, RFID, LORA and / or SIGFOX.

The invention therefore relates in particular to a hybrid communication method between one or more LED lighting devices, according to the second aspect of the present invention and a mobile device, preferably a smartphone (SP) or a tablet, preferably one or more LED lighting devices and a central server for communication to the outside of the LED lighting network. Each LED lighting device includes one or more LEDs as an OLC communication transmitter, preferably LiFi and / or IRDA, an FPGA or ASIC type microcontroller to manage OLC communication, a WiFi communication transmitter / receiver module, a transmitter module / Bluetooth communication receiver, a permanent unique identifier (UiD), preferably a unique IP address, a data processing system from a PLC signal, a data processing system from a POE signal, a mining system dedicated for a CPu or a CPr or a CCo including a motherboard for example with PCI connectors, to be linked for example to a graphics card, a processor, an SSD hard drive, a WiFi module for the connection between lighting devices LED, an ASIC to manage cryptocurrency. A mobile device that can be used in the method comprises an OLC communication receiver, preferably LiFi and / or IRDA, in particular the OLC communication receiver is a camera, a WiFi communication transmitter / receiver module and / or a communication transmitter / receiver module. Biuetooth communication.

The OLC-compatible LED lighting devices, in particular VLC / LiFi and / or IRDA, are in the form of LED bulbs or LED lamps, with or without a high support, comprising LEDs of the type PAR, LED tubes, in particular of types T5, T8, etc., LED panels, Down-Light LEDs, preferably integrated in a waterproof case according to protection standards IP54 or higher according to standard EN 60529.

In general, the present invention therefore proposes the use of these LED lighting devices for a financial transaction by two distinct methods, either a method using a CPu or CPr or CCo (case A), or by a conventional method of transmitting data between the authorizing officer of the transaction and the banking network (case B).

[0024] Particularly preferably, the same LED lighting devices can manage the two cases (A and B) in parallel.

[0025] In the case of the use of LED lighting devices as mining devices for a CPu or CPr or CCo (case A), remember that each LED lighting device acts as a link in the network of miners and all the LED lighting devices interact with each other in order to dynamically adapt the complexity of the calculations to the overall power available.

[0026] Furthermore, the present invention proposes that in the case of a Public Channel, each space concerned makes its LED lighting devices available as a more or less extensive mining pool, managed by the manager of this network, to the whole of the CPu outside this space concerned. In the event that this network of LED lighting devices is only used for a Private Channel, all of the blocks remain confined to the specific network of the space concerned.

[0027] Thus, in the case of a Public Channel, the network of LED lighting devices in the space concerned is open to the entire Public Channel, that is to say outside the concerned space. As a result, this network of LED lighting devices which acts as a mining pool, acts for the overall CPu like a miner, but with a very great computing power, decentralized, since this miner (the manager of this network of LED lighting devices) can manage several mining pools at different locations, for example a chain of stores, which will operate its entire network of LED lighting devices as so many mining pools and thus offer the Chain Publishes a very great force of calculation.

[0028] The present invention therefore provides the following steps in the case of a type A financial transaction, using LED lighting devices as a mining pool for a CPu or CPr or CCo:

[0029] In parallel with the operation of the CPu or of the CPr or of the CCo, the LED lighting device must first ensure a connection with the mobile device of the authorizing officer of the banking transaction.

To do this (a) the LED lighting device permanently sends an invitation message, including its UiD, by an OLC communication protocol, preferably by LiFi and / or IRDA; in the absence of active two-way communication with a mobile device, the WiFi and Bluetooth modules are only activated for the receiver function, (b) when a mobile device receives the invitation message with 'UiD from a device of LED lighting, the mobile device activates communication via WiFi and / or Bluetooth and transmits by at least one of these protocols an acceptance message comprising the received UID and its own unique identifier, (c) when a device d The LED lighting receives a WiFi and / or Bluetooth acceptance message including its UID, it also activates the transmitter function of the WiFi or Bluetooth transmitter module (s) corresponding to the protocol of the acceptance message and establishes bidirectional communication by this protocol (s) with the mobile device, and (d) the bidirectional communication remains active as long as the mobile device receives invitation messages with the UiD of the LED lighting device with which the communicati bidirectional is active and this is terminated by the mobile device, when it no longer receives an invitation message from the LED lighting device, preferably the termination of the bidirectional communication takes place after a determined latency time; and in the absence of active communication with a mobile device, the transmitter function of the WiFi and Bluetooth modules are deactivated.

Active two-way communication, the customer through his dedicated mobile application (such as the store's mobile application) sends a financial order (such as the purchase of a product) to the LED lighting device, this data primary, including the purchase order and the number of credits necessary for this purchase, but also the place of purchase, the identity of the authorizing officer and the UID of his mobile device, as well as the date and time purchase are sent directly to the entire CPu or CPr or CCo to the store's financial manager.

[0032] Then, transaction software records each transfer operation in a register common to all of the CPu or the CPr or the CCo. The information of the transfer from the wallet of the authorizing officer to that of the financial manager of the store is sent to a network node, one of the LED lighting devices, and all of the LED lighting devices of the CPu or the CPr or the CCo, but also in the case of a CPu, to all the members of the CPu located outside this own network of LED lighting devices, to check whether the transaction is valid.

When the transaction is validated by the CPu or the CPr or the CCo, a new block is created, entered in the common register and added to the series of existing blocks. And the transaction authorizer receives the validation of his transaction from the network.

[0034] As a variant, this mining pool, consisting of the LED lighting devices of the spaces concerned, can be used for any application other than financial transactions, for smart contracts for example.

According to a variant, the present invention therefore proposes the following steps in the case of a type B financial transaction: (a) each LED lighting device permanently sends an invitation message, including its UiD, by an OLC communication protocol, preferably by LiFi and / or IRDA; in the absence of active two-way communication with a mobile device, the WiFi and Bluetooth modules are only activated for the receiver function, (b) when a mobile device receives the invitation message with the UiD from a device LED lighting, the mobile device activates communication via WiFi and / or Bluetooth and transmits by at least one of these protocols an acceptance message comprising the received UID and its own unique identifier, (c) when a device LED lighting receives a WiFi and / or Bluetooth acceptance message including its UID, it also activates the transmitter function of the WiFi or Bluetooth transmitter module (s) corresponding to the protocol of the acceptance message and establishes bidirectional communication by this protocol (s) with the mobile device, and (d) bidirectional communication remains active as long as the mobile device receives invitation messages with the UID of the LED lighting device with which the communication bidirectional ion is active and this is terminated by the mobile device, when it no longer receives an invitation message from the LED lighting device, preferably the termination of the bidirectional communication takes place after a determined latency time; and in the absence of active communication with a mobile device, the transmitter function of the WiFi and Bluetooth modules are deactivated.

Active two-way communication, the customer through his dedicated mobile application (such as the store's mobile application) sends a financial order (such as the purchase of a product) to the LED lighting device, and this again The data generated is sent through the network to the central server which in turn transmits it to the bank server.

The banking server then returns the authorization or not, to the mobile application of the authorizing officer of the banking transaction either by 4G, or by using the same path and returns the banking authorization in parallel to the store server or hypermarket or shopping center depending on the situation.

[0038] Alternatively, the LED lighting device can also send non-financial data, such as digital coupons for a hypermarket or shopping center through the LED lighting network, but in a targeted fashion. These other data are also managed by the digital manager, owner of the network of LED lighting devices. Brief description of the drawings

[0039] Other features and characteristics of the invention will emerge from the detailed description of some advantageous embodiments presented below, by way of illustration, with reference to the accompanying drawings. These show:

[0040] FIG. 1 is a representative vision of the financial transaction solution, thanks to LED lighting, using among other things the dedicated LiFi technology for invention.

[0041] FIG. 2a and 2b schematically represent a financial transaction which takes place either conventionally or through a Public Chain or a Private Chain.

[0042] FIG. 3 is a representative view of an embodiment of the hybrid communication protocol between a connected LED lighting and a mobile device.

[0043] FIG. 4 is a schematic representation of an embodiment of the transmission of digital data of a financial transaction using a public channel or a private channel.

[0044] FIG. 5 is a schematic representation of an embodiment of the digital data transmission of a conventional financial transaction between a customer in use, a banking management center and the customer's mobile application.

[0045] FIG. 6 is a schematic representation of an embodiment of the management of a financial transaction according to the type of situation and according to the nature of the financial transaction.

[0046] FIG. 7 is a detailed view of one embodiment of the invention in an indoor space, of medium area such as a store, showing the interconnection between the cloud and the intelligent lighting network.

[0047] FIG. 8 is a schematic representation of an embodiment of the invention, in an interior space, with an average surface area such as a store, showing the interconnection of light points, acting here as mining devices to supply a public channel or a private chain, in the case of a financial transaction, with a central server and a global management server.

[0048] FIG. 9 is a detailed view of one embodiment of the invention in an indoor, upper surface space such as a hypermarket, showing the interconnection between the cloud and the intelligent lighting network.

[0049] FIG. 10 is a schematic representation of an embodiment of the invention, in an interior space, of upper surface such as a hypermarket, showing the interconnection of light points, here acting as mining devices to supply a public channel or a private chain, in the case of a financial transaction, with a central server and a global management server.

[0050] FIG. 11 is a detailed view of an embodiment of the invention in an interior or semi-exterior space, of the shopping center type, or any other commercial surface (duty free, train station, etc.), showing the interconnection between the cloud and the smart lighting network.

[0051] FIG. 12 is a schematic representation of an embodiment of the invention, in an interior or semi-exterior space, of the shopping center type, or any other commercial surface (duty free, train station), showing the interconnection of light points, acting here as mining devices to supply a public chain or a private chain, in the case of a financial transaction, with a central server and a global management server.

[0052] FIG. 13 is a representative view of one embodiment of the various main components of typical connected LED lights used in the context of this invention.

[0053] FIG. 14 is a schematic view of an embodiment of the various electronic modules inside the control block of the intelligent management of the connected LED lighting, depending on the nature of the connection of this block.

[0054] FIG. 15 is another schematic view of an embodiment of the various electronic modules inside the control block of the intelligent management of the connected LED lighting, depending on the nature of the connection of this block.

[0055] FIG. 16 is another schematic view of an embodiment of the different electronic modules inside the control block of the intelligent management of connected LED lighting, depending on the nature of the connection of this block.

[0056] FIG. 17 is a schematic view of an embodiment of the various electronic modules constituting the part dedicated to the control of the mining system within the intelligent management unit of the connected LED lighting.

[0057] FIG. 18 is a schematic view of an embodiment of the various electronic modules constituting the part dedicated to the communication system, with a mobile device such as a smartphone, including LiFi technology, within the intelligent management unit of the connected LED lighting. Description of a preferred execution

FIG.1 is a general view of a person (002) who carries out a dematerialized financial transaction, digitized, within a clothing store (001). The customer (002) positions himself in front of a clothing stall (003) and under the lighting network with LED lighting devices (004) and thanks to communication technologies including LiFi technology (100), the user will be able to carry out a banking transaction to acquire his purchase, without going through the sellers. The validated transaction will be viewed by the customer and by the cashiers on their control device (005).

[0059] FIG. 2a and 2b illustrate and describe the operating mode of the financial transaction according to the type of transaction. Thus, the user, through a mobile application (rated SP), sends a payment request. Two cases arise, either the financial transaction uses cryptocurrency such as bitcoin, Ethereum or any other type of crypto-currency (case A), or the financial transaction uses a more traditional digital network with a connection to the store's banking network (case B). In case A, either the transaction is done through a CPu (case A1), or through a CPr (case A2). The use of a CPu or a CPr is decided by the seller. In both cases, the SP sends its financial transaction request to the chain, the chain verifies, stores the transaction and returns the authorization after verification to the SP to validate the transaction, the same request is sent back to the store checkout. LiFi technology is there to secure the transaction but also to geolocate the financial transaction. Thus, the I'D of the LED lighting device used for the transaction is stored in the CPu or the CPr or the CCo, as well as in the SP which was used for the banking transaction. In a more advanced case, the exchange of data between the LED lighting device and the SP (up and / or down) can be done totally or in part by optical communication technology (Optical light communication) including LiFi technology. .

In case B, the SP receives as previously "iD of the lamp by LiFi, the SP returns the ID of the lamp by any type of communication (OLC or radio frequency (RF)) to establish a communication. transaction corresponds to a payment order (case B1), or the transaction is only to credit a digital wallet for example (case B2). In both cases, the SP sends a payment order or a credit request either by RF or by OLC to the lamp. The information then goes to the network through the LED and connect to the banking network to validate or not the request, then the authorization is returned until the LED which returns the Authorization to the SP As before, in the case of a purchase request, the authorization and the purchase confirmation are also sent in parallel to the cash register.

[0061] FIG. 3 is a zoom on the connectivity between the LED lighting device (200) and the mobile device (007), more particularly the mobile application, called

SP (008a). The LED lighting device (200) is powered and connected to the network to the box (201). Each light can send a WiFi signal (110) and / or a Bluetooth signal, for example via Bluetooth.5® technology (120) and continuously send a LiFi signal (130). This LiFi signal includes a UiD address or identifier, but may also include a financial request. The LED lighting device has a UiD address preferably consisting of an iPV6 address appended with the LiFi UiD address (006). On the smartphone (007), the mobile application (008a) is turned on and a colored dot (008b) indicates the reception level of the LiFi signal (on or off). Each LED lighting device has its own UiD, in particular in order to be able to assign it to specific content or to Internet access. Another object of this invention relates to the downloading of these contents, only if the LiFi signal is recognized by the mobile application.

[0062] FIG. 4 illustrates the validation order process for a financial transaction using a blockchain (case A of Fig. 2). Thus, when the user (002) sends his payment request under the network of LED lighting devices (100), all the information is sent to the BC (010). This chain is managed by a "mining pool" which is none other than the network of LED lighting devices. The BC is connected to an external Cloud network (011) connected to a manager (012) who will validate or not the financial transaction. Then its agreement will follow the reverse path (121), Cloud (011), complete the BC register (010) and finally transmit the agreement through the LED (100) to the customer's SP (002).

[0063] FIG. 5 shows the data flow, in the case of a classic transaction (case B of Fig. 2) without the use of a BC. The data are conveyed to a banking center (009), then after processing, analysis of the data, they are sent back to the transaction authorizing officer (002), through the lighting network (100) and particularly to the application. customer's mobile (008). LiFi technology allows the bank to know the user, the exact location of the financial transaction and to perform this operation with an additional means of security, in addition to other technologies (facial recognition on the SP, activation key on the SP, etc.).

[0064] FIG. 6 illustrates the fact that several consumption sites (013, 014) can be linked by the same Cloud data management platform

(011), under the control of the same operator (012) and regardless of the type of financial transaction, classic or through a PO. In the case of a BC, the greater the number of sites under the control of the same management platform, the stronger the chain will be because the “mining pool” will be high thanks to the network of LED lighting devices. all the bigger. And even in a traditional transaction, all transactions can be managed by the same operator.

[0065] The following figures, FIG. 7 to 12, describe, for each type of space studied, the compatibility of the LED network to make it possible to carry out banking transactions, either traditional or to animate, supply a CPu or a CPr, case A or case B. Indeed, in the two cases the originality comes from the network of LED lighting devices interconnected with one another and connected to an external network, which will manage both LED lighting, but above all digital data flows and transaction flows.

[0066] FIG. 7 illustrates an interior surface of medium surface such as a store, constituted by a network of LED lighting devices (200), interconnected to an internal central server (400), by means of a wired network, for example of the PLC type (power line carrier) or POE (Power Over Ethernet) (005), which will then send the data to the banking network (009) (in the case of a classic financial transaction, case B). In this context, each LED lighting device has its own UID (210) which acts as a geolocation element to define the location of the banking transaction and secure each transaction through LiFi. But these information points can also convey other information to the customer, for example geomarketing information.

[0067] FIG. 8 represents the mining pool formed by the network of LED lighting devices (200) where each LED lighting device acts as a mining entity, identified (210) by a UID, interconnected between them by a wired network, by example of the CPL (line carrier) or POE (Power Over Ethernet) (005) type, thus allowing communication between each LED lighting device and increasing the performance of the CPu or of the CPr or the CCo. This network is then connected to a central processing unit (CPU) (400) which is the communication point between the network of internal LED lighting devices on this surface and the management system (SG) of the BC (300). The communication (430) (0101062 between 'UC (400) and the SG (300) can be of different types wired (CPL, POE) or wireless (4G / WiFi). The SG can therefore be a delocalized server (303 , a small central unit such as a laptop 302, or a large central unit with high computing power 301).

[0068] FIG. 9 illustrates, for the case of a classic financial transaction, case B, a larger interior surface such as a hypermarket (013), constituted by a network of LED lighting devices (500), interconnected to an internal central server (400), by means of a wired network, for example of the CPL (line powerline) or POE (Power Over Ethernet) type, which will then send the data to the banking network (009). In this context, each LED lighting device has its own UID (510) which acts as a geolocation element to define the location of the bank transaction and to secure each transaction through LiFi. But these information points can also convey geomarketing information to the customer, even more real for a hypermarket. The LED lighting devices above the cash registers (501) are preferably more dedicated to the exchange of financial data.

[0069] FIG. 10 shows the mining pool, case A, formed by the network of LED lighting devices (500) with a larger interior surface such as a hypermarket, where each LED lighting device acts as a mining entity, identified (510) by a UID, interconnected with each other by a wired network, for example of the CPL (power line carrier) or POE (Power Over Ethernet) type, thus allowing communication between each LED lighting device and increasing performance of the CPu or the CPr. This network is then connected to a central unit (UC) (400) which is the point of communication between the network of LED lighting devices internal to this surface and the management system (SG) of the BC (300). The communication (430) between the UC (400) and the SG (300) can be of different types wired (CPL, POE) or wireless (4G / WiFi). The SG can therefore be a delocalized server (303, a small central unit such as a laptop computer 302, or a large central unit with high computing power (301).

NOT

[0070] FIG. 11 illustrates, for the case of a classic financial transaction, case B, a mega-surface of much larger size such as a shopping center (014), constituted by a network of LED lighting devices (600), interconnected to a server internal central office (400), via a wired network, for example of the CPL (power line carrier) or POE (Power Over Ethernet) (005) type, which will then send the data to the banking network (009). In this context, each LED lighting device has its own UID (510) which acts as a geolocation element to define the location of the bank transaction and to secure each transaction through LiFi. But these information points can also convey geomarketing information to the customer, even more real for a shopping center.

[0071] FIG. 12 represents the mining pool, case A, formed by the network of LED lighting devices (600) with a much larger mega-area like a shopping center, where each LED lighting device acts as an entity of mining, identified by a UID (610), interconnected with each other by a wired network, for example of the CPL (line powerline) or POE (Power Over Ethernet) (620) type, thus allowing communication between each lighting device LED and increase the performance of the CPu or CPr. This network is then connected to a central unit (UC) (400) which is the point of communication between the network of LED lighting devices internal to this surface and the management system (SG) of the BC (300). The communication (430) between the UC (400) and the SG (300) can be of different types wired (CPL, POE) or wireless (4G / WiFi). The SG can therefore be a delocalized server (303, a small central unit such as a laptop computer 302, or a large central unit with high computing power (301).

FIG. 13 is a zoom on the different electronic modules within the different types of LED lighting devices (200). The LED lighting device (200) can be any type of mounting LED, such as panel (PL) (017), tube (TL) (015), downlight (DL) (016) or any other type of LED. Each type of LED lighting device includes a smart box (201), home to all data management, whether for the DL (163), TL (153) or PL (173). This box is then connected to a more or less specific current transformer (202), (161) for the DL, (151) for the TL, (171) PL, and connected between them by one or more dedicated cables (212). The transformer is connected to the network through a dedicated cable (005) providing among other things a voltage of 220 V.

[0073] FIG. 14 details the different modules that may be present inside the smart box or control unit (201). This intelligent box generally contains two main electronic modules (023 and 021), which can be on two separate electronic cards or on a single single or multilayer electronic card (020), supplied in low voltage and data, by a dedicated module ( 024), itself powered by a dedicated external cable (012). Only the module (023) is connected to the LED through an LED power supply module (019). Module 019 and module 023 are interconnected by means of a printed circuit or connector or any other solution (028). The 023 module is dedicated to the management of the LED (brightness, colorimetry, etc.) and integrates the communication module to the end user, including the LiFi communication module. Module 021 is dedicated to the financial part and in particular to the management of the CB. This module is preferably based on a pelletizer module (022) in order to convert the heat released by the module into electrical energy. The two modules (021) and (023) are interconnected with each other by means of a printed circuit or a connector or any other solution (232). In this case, the two modules are supplied with data and low voltage current by POE, 029 for supplying module 023, 030 for supplying module 021, both supplied through module 024 and through cable 012 which is a POE cable in this case.

[0074] FIG. 15 details the different modules that may be present inside the smart box or control unit (201). This smart box contains two main electronic modules (023 and 021), which can be on two separate electronic cards or on a single single or multi-layer electronic card (020), supplied in low voltage and data, by a dedicated module (027) , itself powered by a dedicated external cable (012). Only the module (023) is connected to the LED through an LED power supply module (019). Module 019 and module 023 are interconnected by means of a printed circuit or connector or any other solution (028). The 023 module is dedicated to LED management (brightness, colorimetry, etc.) and integrates the communication module to the end user, including the LiFi communication module. Module 021 is dedicated to the financial part and in particular to the management of the CPu or the CPr. This module p010106 is preferably based on a pelletier module (022) in order to convert the heat released by the module into electrical energy. The two modules (021) and (023) are interconnected with each other by means of a printed circuit or a connector or any other solution (232). In this case, the two modules are supplied with data and low voltage current by CPL, 035 for the supply of the 023 module, 036 for the supply of the dedicated module 021, both supplied through the 027 module and by the through cable 012 which is a powerline cable in this case.

[0075] FIG. 16 details the different modules that may be present inside the smart box or control unit (201). This smart box contains two main electronic modules (023 and 021), which can be on two separate electronic cards or on a single single or multilayer electronic card (020), supplied in low voltage and data, by two dedicated data modules ( 025) and current (026), itself supplied by a dedicated external cable (212). Only the module (023) is connected to the LED through an LED power supply module (019). Module 019 and module 023 are interconnected by means of a printed circuit or connector or any other solution (028). The 023 module is dedicated to the management of the LED (brightness, colorimetry, etc.) and integrates the communication module to the end user, including the LiFi communication module. Module 021 is dedicated to the financial part and in particular to CB management. This module is preferably based on a pelletizer module (022) in order to convert the heat released by the module into electrical energy. The two modules (021) and (023) are interconnected with each other by means of a printed circuit or a connector or any other solution (232). In this case, the two modules are supplied with data and low voltage current separately. A first module (025) supplies the module 023 with data through a printed circuit or a dedicated connector or cable (031), and in the same way the module 021 through the connectors 033, and with low voltage current through the module (026) and connectors (either printed circuit board or connector or dedicated cable) 034 for module 021 and 032 for module 023. The two modules 025 and 026 are | supplied directly by the cable 212 which has the low voltage power and data cables.

[0076] FIG. 17 details the different modules that may be present inside the smart box or control unit (021). This module is equipped in such a way that it is compatible with all types of PLC, POE or mixed data and current power supplies, and thus has a module to receive the data or POE (037) and a module to receive the current. or CPL (038). A module is also dedicated to the connection with the 023 (047) module. All modules and components are on a single or multi-layer PCB (printed circuit) (035). The main module (039) therefore makes it possible to manage all types of financial transactions, in particular crypto-currencies. Therefore, module 039 is like a small central unit. It can therefore contain a motherboard (040) with PCI connectors, to be linked to a graphics card (041), a processor (042), an SSD hard drive (043), a WiFi module (044) for the connection between LED lighting devices, an ASIC (045) and data extraction module (046) from the 037 and / or 038 modules. The module (047) allows data to be sent back to the 023 module.

[0077] FIG. 18 details the different modules that may be present inside module 023. This module contains a single or multi-layer PCB (printed circuit) (217). As for the 021 module, this module is equipped in such a way that it is compatible with all types of power supplies CPL, POE or mixed data and current, and thus has a module to receive data or POE (049) and a module to receive the current or the CPL (050). The 051 module is the module which allows the connection with the 021 module. The module (048) allows the connection with the LED through a low voltage power cable (028) and among other things allows the modulation of the LED to transmit data to through LiFi technology. This module contains a main component, a microcontroller (218) such as an FPGA component. The wireless communication modules are Bluetooth, preferably V5®, the latest generation of Bluetooth module (219), and a WiFi module (220). These two modules make it possible to obtain two mesh communication networks with different throughput levels. A LiFi module (221) is integrated on this PCB. This LiFi module allows sending data at low speed with a kind of modulation read by a camera of a smartphone. A PLC module (222) is also designed for this electronic card. A POE module (224) is also designed for this electronic card. A memory, for example in the form of an SD memory card (223) is also located on the PCB for storing permanent or temporary data.

This memory card can act as a buffer for streaming content.

Finally, a module dedicated to lighting management in colorimetry and brightness or for person detection (225).

Claims (14)

Claims 1. Method of carrying out secure and geolocated financial transactions by means of LED lighting device (s) connected in a network (004), and equipped with wired or wireless hybrid communication, each LED lighting device comprising a mining system to run a blockchain (BC) and / or to feed the register of a Public Chain (CPu), a Private Chain (CPr) or a Chain Consortium (CCo) of one or more crypto-currencies, including a first microcontroller, preferably of the ASIC type, configured to manage one or more BCs and / or to act as a mining node for said BC or said BCs; a connection to a data network; a motherboard; storage means for at least temporarily storing data, in particular data received from the data network, preferably an SSD hard disk; one or more communication transmitter / receiver modules, chosen from a WiFi communication transmitter / receiver module, a Bluetooth communication transmitter / receiver module, an Ethernet communication transmitter / receiver module, a PLC communication transmitter / receiver module and a module fiber optic communication (OF) transmitter / receiver for communication with other LED lighting devices and / or the data network; a permanent unique identifier (UiD), preferably a unique IP address; one or more LEDs as an OLC communication transmitter, preferably LiFi and / or IRDA, a second microcontroller, preferably of the FPGA or ASIC type to manage the data communication by the communication modules. 2. The method of claim 1, wherein the number of LED lighting devices is greater than 3, preferably 5 to 1000, and wherein said LED lighting devices form a mesh network for managing secure financial transactions and geolocated by at least two distinct processes, either by using a CPu or CPr or CCo (case (A)), or by a conventional method of data transmission between the authorizing officer of the transaction and a banking network (case (B)) , preferably the networked LED lighting devices can manage the two cases (A) and (B) in parallel. 3. The method of claim 2, wherein, for case (A), the LED lighting devices act as mining devices of a "blockchain" as a link in the network of miners and are controlled by a central unit. to interact with each other in order to dynamically adapt the complexity of the calculations to the overall power available or required for the CPu, the CPr or the CCo for the BC. 4. Method according to any one of claims 1 to 3, wherein, in parallel with financial transactions, the same LED lighting devices are used for the management of smart contracts in the case of a Public Channel through the mining pool or to send data other than financial data, in particular digital coupons. The method according to any of claims 1 to 4, wherein the method of using the array of LED lighting devices as financial transaction devices comprises the following steps: (a) each LED lighting device. permanently sends an invitation message, including its UiD, by an OLC communication protocol, preferably by LiFi and / or IRDA; in the absence of active two-way communication with a mobile device, the WiFi and Bluetooth modules are only activated for the receiver function, (b) when a mobile device receives the invitation message with the UID of a device d LED lighting, the mobile device activates communication via WiFi and / or Bluetooth and transmits by at least one of these protocols an acceptance message comprising the UiD received and its own unique identifier, (c) when a device LED lighting receives a WiFi and / or Bluetooth acceptance message including its UiD, it also activates the transmitter function of the WiFi or Bluetooth transmitter module (s) corresponding to the protocol of the acceptance message and establishes a two-way communication by this protocol (s) with the mobile device, (d) the two-way communication remains active as long as the mobile device receives invitation messages with the UID of the LED lighting device with which the communication bidirectional is active and this is terminated by the mobile device, when it no longer receives an invitation message from the LED lighting device, preferably the termination of the bidirectional communication takes place after a determined latency time; and in the absence of active communication with a mobile device, the transmitter function of the WiFi and Bluetooth modules are deactivated. 6. Method according to claim 5 further comprising the following steps: (e) when the two-way communication is active, the client as the authorizing officer of a transaction, sends a financial order, in particular for the purchase of a product. , by means of a mobile application to the LED lighting device with which it is in two-way communication, this financial order comprising as primary data an order to purchase a product, the number of credits necessary for this purchase, the place of purchase, the identity of the customer and the UID of his mobile device, as well as the date and time of purchase, this primary data being sent to the entire BC to the operator , (f) then, a transaction corresponding to the financial order is entered in a common register of the BC, the information of the transfer operation is sent to at least one of the LED lighting devices for verification of the validity of the transaction, (g) when the transa The ction is considered valid by the CB, a new block is created, entered in the common register and added to the series of existing blocks, and the network sends the validation of its transaction to the authorizing officer of the transaction. 7. Method according to claim 5, further comprising the following steps: (e) when the two-way communication is active, the customer as the authorizing officer of a transaction, a financial order, in particular for the purchase of a product. , by means of a mobile application to the LED lighting device with which it is in two-way communication, this financial order comprising as primary data an order to purchase a product, the number of credits necessary for this purchase, the place of purchase, the identity of the customer and the UID of his mobile device, as well as the date and time of purchase, this primary data being sent through the network to a central server which transmits it in turn to a banking server, (f) the banking server sends the validation of the transaction via the network to the authorizing officer of the transaction. 8. Method according to any one of claims 1 to 7, in which, when the mobile device has sent an acceptance message by means of the two WiFi and Bluetooth protocols, the two-way communication takes place by one of these protocols, preferably as a function of the data rate exchanged, particularly preferably the bidirectional communication is done by Bluetooth for rates lower than 2 Mbit / s and by WiFi for higher rates. 9. A method according to any one of claims 1 to 8, wherein the two-way communication comprises sending data from storage means included in the LED lighting device or from a data network to which the LED lighting device is connected, in particular transaction data, but also geolocation or other data permitted and requested by the mobile device. 10. A method according to any one of claims 1 to 9, wherein the management of the steps of claims 5 to 7 is performed by an application | on the mobile device. 11. LED lighting device comprising a mining system to animate a blockchain (BC) and / or to feed the register of a Public Chain (CPu), a Private Chain (CPr) or a Consortium Chain ( CCo) of one or more cryptocurrencies, including a first microcontroller, preferably of ASIC type, configured to manage one or more BCs and / or to act as a mining node for said BC or said BCs; a connection to a data network; a motherboard; storage means for at least temporarily storing data, in particular data received from the data network, preferably an SSD hard disk; one or more communication transmitter / receiver modules, chosen from a WiFi communication transmitter / receiver module, a Bluetooth communication transmitter / receiver module, an Ethernet communication transmitter / receiver module, a PLC communication transmitter / receiver module and a transmitter module / fiber optic communication (OF) receiver for communication with other LED lighting devices and / or the data network; a permanent unique identifier (UiD), preferably a unique IP address; one or more LEDs as an OLC communication transmitter, preferably LiFi and / or IRDA, a second microcontroller, preferably of the FPGA or ASIC type to manage the data communication by the communication modules. 12. LED lighting device according to claim 11, wherein the connection to the data network is configured for connection to a wired network, preferably by power line carrier (PLC), by optical fiber (OF) or by Ethernet. , in particular by an IP protocol. 13. LED lighting device according to any one of claims 11 or 12, in the form of a lamppost, a hanging lamp, a panel, a tube preferably T5, T8, etc. .., a ceiling light, a wall lamp, a down-light or a projector, or in the form of a bulb suitable for common sockets, preferably E27, E14, GU10, B22d or B15d. 14. LED lighting device according to one of claims 11 to 13, further comprising transmitter / receiver communication modules of the following communication technologies: ZigBee, Zwave, RFID, LORA and / or SIGFOX.