EP3311463A1

EP3311463A1 - Electronic device capable of communicating by li-fi

Info

Publication number: EP3311463A1
Application number: EP16733342.6A
Authority: EP
Inventors: Jorge GARCIA-MARQUEZ; Suat TOPSU; Huetzin PEREZ OLIVAS
Original assignee: Oledcomm SAS
Current assignee: Oledcomm SAS
Priority date: 2015-06-18
Filing date: 2016-06-17
Publication date: 2018-04-25
Also published as: FR3037747B1; CN107750474A; US20180159354A1; FR3037747A1; WO2016203008A1

Abstract

An electronic device capable of communicating by Li-Fi and comprising: - at least one light emitting diode (4) intended to emit Li-Fi signals; - energy recovery means (10) intended to recover thermal energy produced by the light emitting diode and to generate, from the recovered thermal energy, a first electrical energy supply of the electronic device.

Description

Electronic device capable of communicating via Li-Fi

An electronic apparatus operable by Li-Fi is adapted to recover a portion of the thermal energy produced by a light-emitting diode used to transmit Li-Fi signals.

BACKGROUND OF THE INVENTION

The use of Li-Fi technology (for "Light Fidelity") to implement wireless communication has many advantages: availability of optical spectrum, absence of electromagnetic interference, cost, etc.

Moreover, thanks in particular to the development of light-emitting diodes (LEDs) with very large switching capabilities and photodiodes with very high response times, it is possible to transmit and receive with Li-Fi data with a much higher throughput than the speed offered for example by WiFi technology (for "ireless Fidelity").

The Li-Fi technology is perfectly adapted to transmit and receive music, videos, internet data, measurement data (temperature, brightness, etc.), alarms (fire, presence of toxic vapors, etc.). to network sensors or other types of devices, etc.

OBJECT OF THE INVENTION The object of the invention is to reduce the power consumption of an electronic device capable of communicating via Li-Fi.

SUMMARY OF THE INVENTION

In order to achieve this goal, there is provided an electronic device capable of communicating via Li-Fi, the electronic apparatus comprising:

at least one light-emitting diode for transmitting Li-Fi signals;

energy recovery means for recovering a thermal energy produced by the light emitting diode and generating from the recovered thermal energy a first electrical power supply of the electronic device.

By using the first electrical energy to at least partially power the electronic device, it reduces the supply of electrical energy required for the operation of the electronic device and therefore the power consumption of the electronic device.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be better understood in the light of the description which follows with reference to the figures of the appended drawings among which:

FIG. 1 shows a partially cutaway view of an electronic apparatus according to a first embodiment of the invention, which is in this case a lighting apparatus of a first type;

FIG. 2 represents energy recovery means of the electronic device according to the first embodiment of the invention;

FIG. 3 represents a general electronic module integrated in the electronic device according to the first embodiment of the invention;

FIG. 4 represents an electronic apparatus according to a second embodiment of the invention, which is in this case a lighting apparatus of a second type;

FIG. 5 represents an electronic device according to a third embodiment of the invention, which is in this case a tablet;

FIG. 6 represents an electronic apparatus according to a fourth embodiment of the invention, which is in this case a measuring apparatus;

FIG. 7 represents an electronic apparatus according to a fifth embodiment of the invention, which is in this case a geolocation apparatus;

FIG. 8 represents an electronic device according to a sixth embodiment of the invention, which is in this case a portable enclosure;

FIG. 9 represents an electronic device according to a seventh embodiment of the invention;

- Figure 10 shows a network of electronic devices of the invention interconnected and communicating with each other by Li-Fi.

DETAILED DESCRIPTION OF THE INVENTION With reference to FIGS. 1 to 3, the electronic device capable of communicating via Li-Fi according to a first embodiment of the invention is here a lighting apparatus of a first type, in which Occurrence of a light-emitting diode lamp or LED lamp 1.

The LED lamp 1 has an envelope inside which are integrated a panel 3 of first light-emitting diodes 4, a light-emitting diode driver 5 (or LED driver), second light-emitting diodes 6, a first photodiode 7, a second photodiode 8, a plurality of sensors and detectors 9, energy recovery means 10 and an electronic module 11.

The panel 3 of first light-emitting diodes 4 comprises a heat-conducting plate 13 on which the first light-emitting diodes 4 are arranged.

The first light-emitting diodes 4 are adapted to emit Li-Fi signals in the visible spectrum.

The LED driver 5 is used to power the light-emitting diodes 4, which allows the LED lamp 1 to illuminate its environment.

The second light-emitting diodes 6 are adapted to emit Li-Fi signals in the infrared spectrum.

The first photodiode 7 is adapted to receive Li-Fi signals in the visible spectrum and the second photodiode 8 is adapted to receive Li-Fi signals in the infrared spectrum.

The plurality of sensors and detectors 9 comprises several sensors and detectors among the following sensors and detectors: temperature sensor, humidity sensor, anemometer type sensor, power consumption sensor, particle detector, infrared presence detector, detector motion sensor, proximity sensor, biometric sensor (iris image, etc.), brightness sensor, smoke detector, sensor radiometric parameters, photometric parameters sensor, etc.

The plurality of sensors and detectors 9 perform various measurements of parameters of the environment of the LED lamp 1.

The energy recovery means 10 are intended to recover a thermal energy produced by the first light-emitting diodes 4 of the panel 3 of the LED lamp 1, and to generate from the recovered thermal energy a first electrical power supply. of the LED lamp 1.

The energy recovery means 10 comprise a Peltier thermoelectric cell 16, a thermal energy recovery unit 17 and a heat sink 18.

By "Peltier-type thermoelectric cell" is meant more specifically a cell for generating by a Peltier effect, called the Seebeck effect, an electric potential difference from a temperature difference.

The thermoelectric cell 16 comprises a set of semiconductors 20 comprising semiconductors doped with N-type doping and semiconductors doped with P-type doping. The semiconductors are arranged between a hot plate 21 and a cold plate 22 heat conducting.

The hot plate 21 is positioned so that a heat produced by the first light-emitting diodes 4 of the panel 3 heats the hot plate 21.

In this case, the panel 3 of first diodes electroluminescent 4 is placed directly on the hot plate 21 of the thermoelectric cell 16.

The heat sink 18, here a finned radiator, is itself arranged to establish a heat conduction relationship with the cold plate 22 of the thermoelectric cell 16 to promote cooling of the cold plate 22.

In this case, the cold plate 22 of the thermoelectric cell is placed directly on one face of a base 24 of the heat sink 18.

Thus, when the first light-emitting diodes 4 are energized, a temperature difference between the hot plate 21 and the cold plate 22 is established. The semiconductor assembly 20 then generates by Seebeck effect a potential difference between the two conductive tabs 25a and 25b.

The two conductive tabs 25 are connected to the thermal energy recovery unit 17 by two electrical wires 26. The thermal energy recovery unit 17 generates from this potential difference an electric supply voltage and a voltage. electric supply current which constitutes the first electrical power supply of the LED lamp 1.

With reference to FIG. 3, the electronic module 11 comprises a generic module 101 adapted to equip different electronic devices or devices capable of communicating via Li-Fi. The generic module 101 thus equips the LED lamp 1 but also other electronic devices visible in Figures 4 to 10 of the application and described later in this description. The generic module 101 of the LED lamp 1 is powered by the first electrical power supply.

The generic module 101 comprises an electrical card on which are mounted a number of electrical components grouped into a processing module 102, a first Li-Fi reception module 103, a second Li-Fi reception module 104, a transmission module Li-Fi 105, a memory module 106, a user interface 107, an external control interface 108, a measurement interface 109 and a light energy recovery module 110.

The processing module 102 comprises a microcontroller 113 and components enabling the operation of the microcontroller 113 (clock, etc.). The microcontroller 113 is connected to all the different modules and interfaces listed above. The microcontroller 113 manages the operation of these modules and interfaces, controls the transmission and reception of Li-Fi signals by the LED lamp 1, and performs a number of processing on data from these modules and interfaces and on the signals Li-Fi.

Energy management means 114 are programmed in the microcontroller 113.

The first Li-Fi receiver module 103 comprises a first Li-Fi signal receiver 116 and a second Li-Fi signal receiver 117. The first receiver 116 is a visible light receiver. The second receiver 117 is an infrared light receiver.

The first receiver 116 is connected to the first photodiode 7 of the LED lamp 1. The second receiver 117 is connected to the second photodiode 8 of the lamp. LED 1.

The first receiver 116 and the second receiver 117 each comprise acquisition means and means for shaping the Li-Fi signals received by the photodiodes to which they are connected, which make it possible to transform the received Li-Fi signals into signals digital data usable by the microcontroller 113.

The first receiver 116 and the second receiver 117 have a low power consumption, and are adapted to receive data with a low rate, at a frequency between 0 and 100 kHz here.

The second Li-Fi receiving module 104 comprises a third Li-Fi signal receiver 118. The third receiver 118 is connected to the first photodiode 7 and the second photodiode 8 of the LED lamp 1 adapted to receive signals L1. Fi. The third receiver 118 has a greater electric power consumption than that of the first receiver 116 and the second receiver 117. The third receiver 118 is adapted to receive data at an intermediate or high rate, that is to say substantially larger than that of the first receiver 116 and the second receiver 117.

The Li-Fi transmission module 105 includes a first Li-Fi signal transmitter 120 and a second Li-Fi signal transmitter 121. The first transmitter 120 is a visible light emitter. The second transmitter 121 is an infrared light emitter.

The first transmitter 120 is connected to the light-emitting diodes 4 of the LED lamp 1 adapted to emit Li-Fi signals in the visible spectrum. The second receiver 121 is connected to the second light-emitting diodes 6 of the LED lamp.

The first transmitter 120 and the second transmitter 121 each comprise shaping means in the electrical card making it possible to transform data to be transmitted produced by the microcontroller 113 into data that can be used by the light-emitting diodes to emit the Li-Fi signals.

The first transmitter 120 and the second transmitter 121 have a relatively high electric power consumption, and are adapted to transmit data at a high rate.

The memory module 106 here comprises an EEPROM type memory (for "Electrically Programmable Erawable Read Only Memory").

The user interface 107 makes it possible to connect to the generic module 101 a display and an indicator LED, to provide information to a user, as well as a keyboard and a push button, so that the user can control the generic module 101 or perform settings on the generic module 101 or on the device.

Note that in the case of the LED lamp 1, the user interface is not used.

The external control interface 108 is an interface that allows the generic module 101 to control a separate device from the device in which the generic module 101 or a module separate from the generic module 101 is integrated, said separate device or separate module being connected at the external control interface 108. The external control interface 108 also allows separate device or separate module to control the generic module 101.

Note that in the case of the LED lamp 1, the user interface is not used.

The measurement interface 109 makes it possible for it to connect to the generic module 101 the sensors and detectors of the list presented earlier, and to acquire the data measured by these different sensors and detectors.

Here, the measurement interface is connected to the plurality of sensors and detectors 9 of the LED lamp 1 via input ports 122 of the measurement interface.

The measurement interface 109 further includes an analog-to-digital converter 123 connected to the microcontroller 13. The analog-to-digital converter 123 converts analog voltages and currents resulting from the measurements made by the sensors and detectors connected to the measurement interface 109. in digital signals usable by the microcontroller 113.

The light energy recovery module 110 comprises a light energy recovery unit 124, a light energy conversion unit 125 and a light energy storage unit 126. The light energy recovery unit 124 is intended to be connected to a photovoltaic cell (or a plurality of photovoltaic cells grouped into a photovoltaic solar module) which transforms an incident light power into electrical energy. The light energy conversion unit 125 shapes a voltage generated by this electrical energy to store it in the light energy storage unit 126. The energy storage 126 supplies the microcontroller 113 and the whole of the generic module 101 via a power management method managed by the energy management means 114 programmed in the microcontroller 113. It is noted that the recovery unit of FIG. light energy 124 is also connected to the microcontroller 113 via an input 128 thereof.

Note that in the case of the LED lamp, the light energy recovery module 110 is not used.

With reference to FIG. 4, the electronic device capable of communicating via Li-Fi according to a second embodiment of the invention is here a lighting apparatus of a second type 130.

The lighting apparatus of a second type 130 here comprises a housing 131 and a tubular LED lamp 132 to which the housing 131 is connected.

The housing 131 integrates the generic module 101 previously described, an LED driver 133 for supplying the LED lamp 132, a rechargeable battery 134 and a charging circuit associated with the battery 134.

The LED lamp 132 comprises a photodiode 136 adapted to receive Li-Fi signals in the visible spectrum and a photodiode 137 adapted to receive Li-Fi signals in the infrared spectrum. The photodiodes 136, 137 are integrated in the LED lamp 132.

The LED lamp 132 also comprises one or more light-emitting diodes 138 adapted to emit Li-Fi signals in the visible spectrum and one or more light-emitting diodes 139 adapted to emit light-emitting diodes. Li-Fi signals in the infrared spectrum. The one or more light emitting diodes 139 are integrated into a deu ^¬ xth end of the LED lamp 132.

Finally, the LED lamp 132 comprises energy recovery means 135 for recovering a thermal energy produced by the light-emitting diodes 138 and 139. The energy recovery means 135 are similar to the energy recovery means 10. described earlier for the LED lamp 1. The first electrical energy generated by the energy recovery means 135 is used here to store electricity in the battery 134 which supplies the generic module 101. It is noted that the generic module 101 can also be powered by a power outlet.

The generic module 101 is connected to the LED lamp

The cables 140 connect the generic module 101 to the energy recovery means 135. The cables 140 also connect the photodiodes 136, 137 of the LED lamp 132 to the first receiver 116, to the second receiver 117 and to the third receiver 117. The cables 140 finally connect the light-emitting diodes 138, 139 of the LED lamp 132 to the first transmitter 120 and the second transmitter 121 of the Li-Fi signals of the generic module 101.

A plurality of sensors and detectors 141 among the sensors and detectors mentioned earlier are connected to the measurement interface 109 of the generic module 101 via second cables 142. The sensors and the detectors 141 perform various measurements of the parameters of the environment of the luminaire 130.

With reference to FIG. 5, the electronic device capable of communicating via Li-Fi according to a third embodiment of the invention is here a mobile device type mobile phone or tablet or laptop, in this case a tablet 150.

The tablet 150 comprises a photodiode 151 adapted to receive Li-Fi signals in the visible spectrum and a photodiode 152 adapted to receive Li-Fi signals in the infrared spectrum.

The tablet 150 further comprises a light-emitting diode 153 adapted to emit Li-Fi signals in the visible spectrum and a light-emitting diode 154 adapted to emit Li-Fi signals in the infrared spectrum.

The tablet 150 also comprises energy recovery means 156 intended to recover a thermal energy produced by the light-emitting diodes 153 and 154. The energy recovery means 156 are similar to the energy recovery means 10 described earlier for the LED lamp 1. The first electrical energy generated by the energy recovery means 156 is used here to feed the generic module 101.

The generic module 101 is connected to the tablet 150 via connectors which connect the photodiodes 151, 152 of the tablet 150 to the first receiver 116, to the second receiver 117 and to the third receiver 118 of the Li-Fi signals of the generic module 101, and the electroluminescent diodes 153, 154 of the tablet 150 to the first transmitter 120 and the second transmitter 121 of Li-Fi signals of the generic module 101. This generic module 101 can also be integrated in the tablet 150. The tablet 150 further includes a plurality of sensors and detectors 155 among the sensors and detectors discussed earlier. The sensors and the detectors 155 are connected to the measurement interface 109 of the generic module 1. The sensors and the detectors 155 make various measurements of the parameters of the environment of the tablet 150.

With reference to FIG. 6, the electronic device capable of communicating via Li-Fi according to a fourth embodiment of the invention is here a measuring device 160. The measuring device 160 is part of a network of sensors in which he performs measurements and acts as a repeater.

The measuring apparatus 160 comprises photodiodes, light-emitting diodes, the generic module 101, a plurality of sensors and detectors 162, a battery 163 and a recharging circuit associated with the battery 163, and energy recovery means. 169.

The photodiodes comprise a photodiode 164 adapted to receive Li-Fi signals in the visible spectrum and a photodiode 165 adapted to receive Li-Fi signals in the infrared spectrum.

The light-emitting diodes comprise a light-emitting diode 166 adapted to emit Li-Fi signals in the visible spectrum and a light-emitting diode 167 adapted to emit Li-Fi signals in the infrared spectrum.

The photodiodes 164, 165 of the measuring apparatus 160 are respectively connected to the first receiver 116, the second receiver 117 and both to the third receiver 118 of Li-Fi signals of the generic module 101, and the light-emitting diodes 166, 167 of the measuring apparatus 160 are connected to the first transmitter 120 and to the second transmitter 121 of Li-Fi signals of the generic module 101.

The energy recovery means comprise thermal energy recovery means 169 intended to recover a thermal energy produced by the light-emitting diodes 166 and 167, as well as a photovoltaic solar module 161 comprising a plurality of photovoltaic cells.

The energy recovery means 169 are similar to the energy recovery means 10 described earlier for the LED lamp 1. The electrical energy generated by the energy recovery means 169 is used here to feed the generic module. 101.

The photovoltaic solar module 161, connected to the light energy recovery unit 124 of the generic module 101, is intended to generate from a light energy a second electrical energy intended to feed the measuring apparatus 160. energy recovery means 161 and 169 will store this energy in the form of electric charges in the battery 163 used by the module 101.

The measuring apparatus 160 is thus powered by the battery 163, by the first electrical energy generated by the energy recovery means 169 and by the second electrical energy resulting from the light energy recovered by means of the photovoltaic solar module 161 connected to the light energy recovery unit 124 of the generic module 101.

It is noted that the measuring apparatus 160 can also be powered by a mains plug.

The sensors and the detectors 162 are connected to the measurement interface 109 of the generic module 101 and make various measurements of the parameters of the environment of the measuring device 160.

With reference to FIG. 7, the electronic device capable of communicating via Li-Fi according to a fifth embodiment of the invention is here a geolocation apparatus 170.

The geolocation apparatus 170 comprises a geolocation module, energy recovery means, photodiodes, light-emitting diodes, the generic module 101, a plurality of sensors and detectors 172, a battery 173 and an associated recharging circuit on the battery, as well as a display 174.

The photodiodes comprise one or more photodiodes 175 adapted to receive Li-Fi signals in the visible spectrum and one or more photodiodes 176 adapted to receive Li-Fi signals in the infrared spectrum.

The light-emitting diodes comprise a light-emitting diode 177 adapted to emit Li-Fi signals in the visible spectrum and a light-emitting diode 178 adapted to emit Li-Fi signals in the infrared spectrum.

The photodiodes 175, 176 of the geolocation apparatus 170 are connected to the first receiver 116, the second receiver 117 and the third receiver 118 of signals Li-Fi of the generic module 101, and the light-emitting diodes 177, 178 of the geolocation 170 are connected to the first transmitter 120 and to the second x 121 transmitter of signals Li-Fi of the generic module 1.

The energy recovery means comprise thermal energy recovery means 179 intended to recover a thermal energy produced by the light-emitting diodes 177 and 178, as well as a photovoltaic solar module 171 comprising a plurality of photovoltaic cells.

The energy recovery means 179 are similar to the energy recovery means 10 described earlier for the LED lamp 1. The first electrical energy generated by the energy recovery means 179 is stored in the battery 173. The Generic module 101 is powered by the battery 173.

The photovoltaic solar module 171, connected to the light energy recovery unit 124 of the generic module 101, is intended to generate from a light energy a second electrical energy intended to charge the battery 173 of the measuring apparatus Geolocation 170.

Note that the geolocation device 170 can also be powered by a power outlet.

The sensors and detectors 172 of the geolocation apparatus 170 are connected to the measurement interface 109 of the generic module 101 and make various measurements of the environment parameters of the geolocation apparatus.

The display 174 is connected to the user interface 107 of the generic module 101 and makes it possible to display various information, among which geolocation data produced by the geolocation apparatus 170 and the measurement data.

With reference to FIG. 8, the electronic device capable of communicating via Li-Fi according to a sixth embodiment of the invention is here a portable enclosure 180 of the Bluetooth speaker type.

The portable enclosure 180 comprises a speaker 181, photodiodes, light-emitting diodes, energy recovery means 186, and a generic module 101.

The photodiodes comprise a photodiode 182 adapted to receive Li-Fi signals in the visible spectrum and a photodiode 183 adapted to receive Li-Fi signals in the infrared spectrum.

The light-emitting diodes comprise a light-emitting diode 184 adapted to emit Li-Fi signals in the visible spectrum and a light-emitting diode 185 adapted to emit Li-Fi signals in the infrared spectrum.

The photodiodes 182, 183 of the portable enclosure 180 are connected to the first receiver 116, the second receiver 117 and the third receiver 118 of Li-Fi signals of the generic module 101, and the light-emitting diodes 184, 185 of the portable enclosure 180 are connected to the first transmitter 120 and the second transmitter 121 of Li-Fi signals of the generic module 101.

The energy recovery means 186 are intended to recover a thermal energy produced by the light-emitting diodes 184 and 185. The energy recovery means 186 are similar to the energy recovery means 10 described earlier for the LED lamp. 1. The first electrical energy generated by the energy recovery means 186 is used here to feed the generic module 101.

With reference to FIG. 9, the electronic device capable of communicating via Li-Fi according to a seventh embodiment of the invention 190 comprises photodiodes, light-emitting diodes, a generic module 101, a display 191, a keyboard 192 and energy recovery means 197.

The photodiodes comprise a photodiode 193 adapted to receive Li-Fi signals in the visible spectrum and a photodiode 194 adapted to receive Li-Fi signals in the infrared spectrum.

The light-emitting diodes comprise a light-emitting diode 195 adapted to emit Li-Fi signals in the visible spectrum and a light-emitting diode 196 adapted to emit Li-Fi signals in the infrared spectrum.

The photodiodes 193, 194 of the electronic apparatus 190 are connected to the first receiver 116, to the second receiver 117 and to the third receiver 118 of signals Li-Fi of the generic module 101, and the light-emitting diodes 195, 196 of the electronic device 190. are connected to the first transmitter 120 and the second transmitter 121 of Li-Fi signals respectively of the generic module 101.

The energy recovery means 197 are intended to recover a thermal energy produced by the light-emitting diodes 194 and 195. The energy recovery means 197 are similar to the energy recovery means 10 described earlier for the LED lamp. 1. The first electrical energy generated by the energy recovery means 197 is used here to feed the generic module 101.

The display 191 is connected to the user interface 107 of the generic module 101 and makes it possible to display various information concerning, for example, the communication of this apparatus with the apparatuses 130 and 150.

The display 191 here comprises an electrically modulating material of the electrochromic, electrophoretic or liquid crystal type. Such displays are described, for example, in E. Runnerstrom, A. Llordés, S. D. Lounis and D. J. Milliron, "Nanostructures electronic smart Windows: traditional materials and NIR-selective plasmonic nanocrystals," Chem. Commun., 50, 10555 (2014), and in C.G. Granqvist, "Oxide electrochromics: an introduction to devices and materials," Solar Energy Materials & Solar Cells, 99, 1-13 (2012).

The keyboard 192 is connected to the user interface 107 of the generic module and allows a user to make various settings on the generic module 101 and on the electronic device 190.

With reference to FIG. 10, a plurality of electronic devices capable of communicating via Li-Fi of the invention 240 are here interconnected in a network extending into a work space illuminated by lamps 241 positioned on the ceiling of the workspace. Each electronic apparatus 240 includes energy recovery means such as the energy recovery means 10 described earlier.

Among these electronic devices 240, there is a computer screen 240a, a printer 240b, a computer portable 240c, a 240d mobile phone, a 240e thermometer, etc.

The network is managed by a server 242 which is connected to the lamps 241 for transmitting and receiving LID signals.

Each electronic device 240 comprises a generic module of the invention 101 and is adapted, on the one hand, to exchange Li-Fi signals with the other devices 240 of the network, and on the other hand to exchange Li-Fi signals with the server. 242 via the lamps 241.

The invention is not limited to the particular embodiment which has just been described, but, on the contrary, covers any variant within the scope of the invention as defined by the claims.

Claims

REVENDICA IONS

An electronic apparatus capable of communicating via Li-Fi, the electronic apparatus comprising:

at least one electroluminescent diode (4;

138, 139; 153, 154; 166, 167; 177, 178; 184, 185; 195, 196) for transmitting Li-Fi signals;

energy recovery means (10) for recovering a thermal energy produced by the light-emitting diode and for generating from the recovered heat energy a first electrical power supply of the electronic apparatus.

2. Electronic device according to claim

1, wherein the energy recovery means comprises a Peltier thermoelectric cell (16) comprising a set of semiconductors (20) disposed between a hot plate (21) and a conductive cold plate (22). heat, the hot plate (21) being arranged in such a way that a heat generated by the light-emitting diode heats the hot plate (21) and establishes a temperature difference between the hot plate (21) and the cold plate (22) .

3. Electronic device according to claim

2, wherein the energy recovery means further comprises a heat sink (18) arranged to establish a heat conduction relationship with the cold plate (22).

An electronic apparatus according to claim 3, further comprising a battery (134; 163; 173) in which the first electrical energy is stored.

5. Electronic device according to one of the preceding claims, wherein the electronic device comprises an electronic module (11) for controlling the light-emitting diode to emit Li-Fi signals, the electronic module being powered at least partially by the first electric energy.

An electronic apparatus according to claim 5, wherein the electronic apparatus comprises a first light-emitting diode (4; 138; 153; 166; 177; 184; 195) adapted to transmit Li-Fi signals in the visible spectrum and a second light-emitting diode adapted to emit Li-Fi signals in the infrared spectrum (6; 139; 154; 167; 178; 185; 196), and wherein the electronic module (11) comprises a first transmitter (120) connected to the first light-emitting diode for emitting Li-Fi signals in visible light and a second emitter (121) connected to the second light-emitting diode for emitting Li-Fi signals in infrared light.

7. Electronic device according to one of claims 5 or 6, wherein the electronic device comprises a photodiode and wherein the electronic module comprises a receiver (116, 117) connected to the photodiode for receiving Li-Fi signals.

8. Electronic device according to one of claims 5 to 7, wherein the electronic device comprises a sensor and wherein the electronic module comprises a measurement interface connected to the sensor for acquiring measurements made by the sensor.

9. Electronic device according to one of claims 5 to 8, wherein the electronic module (11) comprises a generic module (101) adapted to equip different electronic devices or devices capable of communicating via Li-Fi.

10. An electronic apparatus according to one of the preceding claims, wherein the energy recovery means further comprises a photovoltage cell (161; 171) for generating from a light energy a second electrical energy of power supply of the electronic device.

An electronic apparatus according to one of the preceding claims, the electronic apparatus being a lighting apparatus (1; 130), or a mobile telephone or tablet type mobile apparatus (150), or a measuring apparatus (160). , or a geolocation apparatus (170), or a portable speaker (180).

12. A network comprising a plurality of electronic devices (240) according to one of the preceding claims, the electronic devices being interconnected and communicating with each other by Li-Fi.