NEAR-FIELD COMMUNICATION (NFC) TAGS OPTIMIZED FOR HIGH PERFORMANCE NFC AND WIRELESS POWER RECEPTION WITH SMALL ANTENNAS
First Claim
1. A device for near-field communication (NFC) and wireless power reception (WPR) using a magnetic field, comprising:
- an antenna resonant circuit that includesan antenna for magnetic flux of the magnetic field to flow therethrough, to thereby receive a NFC signal during the NFC and receive wireless power during the WPR, anda multi-Q antenna matching circuit configured to adjust an impedance of the antenna to thereby adjust a quality factor (Q-factor) of the antenna resonant circuit, the multi-Q antenna matching circuit being configured to switch between a high-Q mode for the WPR and a low-Q mode for the NFC, based on whether strength of the magnetic field is larger than a predetermined threshold.
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Accused Products
Abstract
A device for near-field communication (NFC) and wireless power reception (WPR) using a magnetic field. The device has an antenna resonant circuit. The antenna resonant circuit includes an antenna for magnetic flux of the magnetic field to flow therethrough, to thereby receive a NFC signal during the NFC and receive wireless power during the WPR, and a multi-Q antenna matching circuit configured to adjust an impedance of the antenna to thereby adjust a quality factor (Q-factor) of the antenna resonant circuit. The multi-Q antenna matching circuit is configured to switch between a high-Q mode for the WPR and a low-Q mode for the NFC, based on whether strength of the magnetic field is larger than a predetermined threshold. The device may also include two separate antenna resonant circuits, of which the Q-factors are respectively no higher than 25 and no lower than 50.
23 Citations
20 Claims
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1. A device for near-field communication (NFC) and wireless power reception (WPR) using a magnetic field, comprising:
an antenna resonant circuit that includes an antenna for magnetic flux of the magnetic field to flow therethrough, to thereby receive a NFC signal during the NFC and receive wireless power during the WPR, and a multi-Q antenna matching circuit configured to adjust an impedance of the antenna to thereby adjust a quality factor (Q-factor) of the antenna resonant circuit, the multi-Q antenna matching circuit being configured to switch between a high-Q mode for the WPR and a low-Q mode for the NFC, based on whether strength of the magnetic field is larger than a predetermined threshold.
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2. The device of claim 1, wherein
the high-Q mode is a mode in which the Q-factor of the antenna resonant circuit is no lower than 50, and the low-Q mode is a mode in which the Q-factor of the antenna resonant circuit is no higher than 25.
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3. The device of claim 1, further comprising:
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a demodulator configured to demodulate the NFC signal received by the antenna during the NFC; a data interface configured to transmit the demodulated NFC signal to a first external device; a rectifier-and-regulator configured to convert the wireless power received by the antenna during the WPR to regulated DC (direct current) energy; and an energy harvest interface configured to supply the regulated DC energy to a second external device.
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4. The device of claim 3, wherein
the antenna is further configured to transmit another NFC signal, and has a load connected thereto; -
the device further comprises a load modulator configured to modulate an impedance of the load for transmitting the another NFC signal; and the data interface is further configured to receive data corresponding to the another NFC signal from the first external device, and to send the received data to the load modulator.
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5. The device of claim 3, wherein the load modulator includes a radio frequency (RF) switch that has an isolation value larger than 10 KOhm, an on-resistance value smaller than 50 Ohm, and a switching speed larger than 1 MHz.
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6. The device of claim 3, wherein the rectifier-and-regulator includes a switch for controlling a connection from the rectifier-and-regulator to the energy harvest interface.
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7. The device of claim 1, wherein the multi-Q antenna matching circuit includes an antenna matching circuit and a Q-factor adjustment circuit.
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8. The device of claim 7, wherein the Q-factor adjustment circuit is connected in parallel to the antenna, and includes a Q-factor tuning resistor and a Q-factor tuning switch connected in series.
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9. The device of claim 7, wherein the antenna matching circuit utilizes an impedance transformation topology, and has an insertion loss smaller than ldb.
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10. The device of claim 1, wherein the antenna has
an inductance in a range of 1 uH to 10 uH, an area in a range of 100 mm2 to 5000 mm2, and a Q value higher than 50.
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11. The device of claim 1, wherein the high-Q mode and the low-Q mode are switched in real-time.
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12. A device for concurrent near-field communication (NFC) and wireless power reception (WPR) using a magnetic field, comprising:
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a low-Q antenna resonant circuit configured to perform the NFC, and including a first antenna for magnetic flux of the magnetic field to flow therethrough, to thereby receive a NFC signal for the NFC, and a first antenna matching circuit that is connected to the first antenna and is so configured that a quality factor (Q-factor) of the low-Q antenna resonant circuit is no higher than 25; and a high-Q antenna resonant circuit configured to perform the WPR, and including a second antenna for the magnetic flux of the magnetic field to flow therethrough, to thereby receive wireless power for the WPR, and a second antenna matching circuit that is connected to the second antenna and is so configured that the Q-factor of the high-Q antenna resonant circuit is no lower than 50, wherein the low-Q and high-Q antenna resonant circuits are separate from each other.
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13. The device of claim 12, wherein the low-Q and high-Q antenna resonant circuits are configured to operate simultaneously.
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14. The device of claim 12, further comprising:
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a demodulator connected to the first antenna matching circuit and configured to demodulate the NFC signal received by the first antenna; a data interface configured to transmit the demodulated NFC signal to a first external device; a rectifier-and-regulator connected to the second antenna matching circuit and configured to convert the wireless power received by the second antenna to regulated DC (direct current) energy; and an energy harvest interface configured to supply the regulated DC energy to a second external device.
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15. The device of claim 14, wherein
the second antenna is further configured to transmit another NFC signal, and has a load connected thereto; the device further comprises a load modulator configured to modulate an impedance of the load for transmitting the another NFC signal; and the data interface is further configured to receive data corresponding to the another NFC signal from the first external device, and to send the received data to the load modulator.
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16. The device of claim 15, wherein the load modulator includes a radio frequency (RF) switch that has an isolation value larger than 10 KOhm, an on-resistance value smaller than 50 Ohm, and a switching speed larger than 1 MHz.
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17. The device of claim 14, wherein the rectifier-and-regulator includes a switch for controlling a connection from the rectifier-and-regulator to the energy harvest interface.
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18. The device of claim 12, wherein each of the first and second antenna matching circuits utilizes an impedance transformation topology, and has an insertion loss smaller than ldb.
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19. The device of claim 12, wherein the first antenna has at least one of
an inductance value smaller than 4 uH, a Q value smaller than 50, and a coupling coefficient, with respect to an external antenna coupled thereto, is smaller than 0.1.
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20. The device of claim 12, wherein the second antenna has
an inductance in a range of 1 uH to 10 uH, an area in a range of 100 mm2 to 5000 mm2, and a Q value higher than 50.
Specification