CN213876801U

CN213876801U - Radio frequency identification label

Info

Publication number: CN213876801U
Application number: CN202023063513.7U
Authority: CN
Inventors: 李成龙; 张飞龙
Original assignee: Shenzhen Shuma Electronic Technology Co ltd
Current assignee: Shenzhen Shuma Electronic Technology Co ltd
Priority date: 2020-12-17
Filing date: 2020-12-17
Publication date: 2021-08-03
Anticipated expiration: 2030-12-17

Abstract

The application provides a radio frequency identification tag, which comprises a coil, a first modulator connected with two ends of the coil, a second modulator connected with two ends of the coil, and demodulators connected with two ends of the coil; the coil is used for receiving a carrier wave; the demodulator is used for determining first data corresponding to the carrier when the carrier is received; the first modulator is used for sending second data corresponding to the first data by adjusting voltage peak values at two ends of the coil when the label is in a first working mode; and the second modulator is used for enabling the resonance frequency points of the tag and the corresponding reader to be consistent by adjusting capacitance values at two ends of the coil when the first working mode is switched to a second working mode so as to send the second data. The embodiment of the utility model provides an in, under the passive condition of low-power consumption, the radio frequency identification function of multiple mode, multiple agreement, a plurality of frequency point is supported to higher performance.

Description

Radio frequency identification label

Technical Field

The application relates to the field of tags, in particular to a radio frequency identification tag.

Background

At present, the automatic identification technology is widely popularized, and particularly, the radio frequency identification technology is an information technology with great development potential which is focused by people. The technology mainly carries out non-contact bidirectional data communication in a radio frequency mode, and reads and writes a recording medium (such as an electronic tag or a radio frequency card) in the radio frequency mode, thereby achieving the purposes of identification and data exchange.

The radio frequency signal coupling type between the reader and the electronic tag includes inductive coupling and electromagnetic backscattering coupling. In the existing scheme, inductive coupling also generally has some problems; for example, the rfid tag cannot perfectly support the data interaction function of multiple modes, multiple protocols, and multiple frequency points while simultaneously achieving low power consumption.

Disclosure of Invention

The application provides a radio frequency identification tag which supports radio frequency identification of multiple modes, multiple protocols and multiple frequency points with high performance under the condition of low power consumption and no source.

In a first aspect, an embodiment of the present invention provides a radio frequency identification tag, which may include:

the modulator comprises a coil, a first modulator connected with two ends of the coil, a second modulator connected with two ends of the coil, and demodulators connected with two ends of the coil;

the coil is used for receiving a carrier wave;

the demodulator is used for determining first data corresponding to the carrier when the carrier is received;

the first modulator is used for sending second data corresponding to the first data by adjusting voltage peak values at two ends of the coil when the label is in a first working mode;

and the second modulator is used for enabling the resonance frequency points of the tag and the corresponding reader to be consistent by adjusting capacitance values at two ends of the coil when the first working mode is switched to a second working mode so as to send the second data.

In the embodiment of the present invention, the received carrier is demodulated by the demodulator to obtain the first data; after the necessary processing of the first data, the second data is fed back to the reader. When the tag is in a first working mode (such as a half-duplex mode HDX), data is fed back by adjusting the voltage peak value at two ends of the coil. When the tag is in a second working mode (such as full duplex mode FDX), data is fed back by adjusting the capacitance value of the two ends of the coil. The content of the data fed back in the different modes is not limited. Different from the prior art, the problem of frequency switching after the first working mode is switched to the second working mode is solved by adjusting the capacitance value of the coil through the second modulator. For example, when the tag switches to HDX mode of operation, the frequency switching problem of the mode change is solved by long-term operation of the second modulator. Further, the demodulation circuit is adapted to accommodate both carrier reception and demodulation for both modes of operation.

In a possible implementation manner, two capacitors may be provided in the second operation mode; the first capacitor may be a tuning capacitor for resonating with the reader; the second capacitor may be a modulation capacitor used when transmitting data, and frequency modulation is performed by adjusting the capacitor to transmit the second data.

In a possible implementation manner, the demodulator includes a switch tube, and the demodulator increases detection sensitivity and reduces delay time through the switch tube, and adapts to the first operating mode and the second operating mode. The demodulation adopts an envelope detection mode, 2 NMOS tubes are added on a basic circuit of the demodulation to be used as switching tubes, so that the detection sensitivity is increased, the delay time is reduced, and the demodulation can work under the condition of higher baud rate

In one possible implementation manner, the tag further includes a trimming circuit connected to two ends of the coil, and the trimming circuit includes one or more capacitors; the trimming circuit is configured to: and changing the capacitance value of the two ends of the coil by switching in the one or more capacitors so as to change the resonant frequency point of the tag. The purpose is to achieve that the resonance frequency of the tag coincides with the resonance frequency of the reader.

In one possible implementation, the first modulator includes a load; the first modulator is specifically configured to: controlling the load to be connected into the coil, and reducing voltage peak values at two ends of the coil; or controlling the load not to be connected into the coil, and recovering the voltage peak value at two ends of the coil.

In one possible implementation manner, the tag further comprises a gap clock recovery circuit, and a gap demodulator connected with the gap clock recovery circuit; the gap clock recovery circuit is connected with two ends of the coil; the gap demodulator is connected with two ends of the coil; the gap demodulator comprises a capacitor (the capacitor is a filter with a variable time constant; optionally, a resistor, etc.); the gap clock recovery circuit is used for generating a first clock signal; the gap demodulator is configured to: when the carrier is not received and the first clock signal exists, determining a corresponding time constant according to a preset reference current and the capacitance value of the capacitor so as to control the voltage of the capacitor to be within a threshold range.

In one possible implementation, the tag further comprises a peak detection circuit connected to one end of the coil; the peak value detection circuit is used for detecting whether the coil reaches the preset voltage peak value. The tag further comprises a resonant circuit, a resonant switch and a counter; the counter is used for counting to judge whether a preset moment is reached or not; and under the condition that the label does not receive the carrier wave, when the preset moment is reached and the coil reaches the preset voltage peak value, the resonance switch is conducted to charge the resonance circuit.

In one possible implementation, the tag further comprises a rectifier bridge; the rectifier bridge is connected with two ends of the coil; the rectifier bridge is used for: generating a direct current signal according to the carrier wave; the direct current signal is used for supplying power to the tag.

In a second aspect, an embodiment of the present invention provides a radio frequency identification tag (or referred to as radio frequency identification electronic tag, electronic tag), which may include:

a coil, a gap clock recovery circuit and a gap demodulator; the gap clock recovery circuit is connected with the gap demodulator; the gap clock recovery circuit is connected with two ends of the coil; the gap demodulator is connected with two ends of the coil; the gap demodulator comprises a filter with a variable time constant; alternatively, the filter may be a resistor or a capacitor, etc. The coil is used for receiving a carrier wave; when the electronic tag is in the gap mode, the gap clock recovery circuit is used for: generating a first clock signal; the first clock signal is used for inputting the gap demodulator; when the carrier is not received and the first clock signal is present, the gap demodulator is to: and determining a corresponding time constant according to a preset reference current and the capacitance value of the capacitor so as to control the voltage of the capacitor to be within a threshold range.

The embodiment of the utility model provides an in, in the identification area that electronic tags is in the reading ware that corresponds, electronic tags passes through the coil and receives the signal that reads the ware and send. When a gap exists in an actually transmitted signal or a signal transmitted by a reader is abnormal, a first clock signal is generated through a gap clock recovery circuit, and the clock signal is input to a gap demodulator connected with the gap clock recovery circuit; at this time, when the carrier (i.e., the signal sent by the reader) is not received yet and the first clock signal exists, the gap demodulator is configured to determine the time constant according to the preset parameter (e.g., the reference current, the capacitance value of the capacitor), and control the voltage of the capacitor to be within the normal range. Compared with the prior art, the embodiment of the utility model can ensure that the electronic tag can stably and normally operate under the condition of a gap in the signal sent by the reader through the cooperation of the gap clock recovery circuit and the gap demodulator, so as to deal with the condition of the gap or the abnormal condition of the reader and maintain the stability of the radio frequency identification tag; the gap mode is provided on the basis of the normal working mode so as to deal with emergency and support various working modes, protocols and frequency points. The gap pattern may be a signal processing pattern in which the electronic tag should have a gap with respect to a carrier wave transmitted by the reader.

Alternatively, when the carrier is not received by the electronic tag (e.g., the antenna portion of the electronic tag) and the first clock signal is not present, the gap demodulator may not operate properly, typically without other circuit components. For example, when the gap clock recovery circuit works normally and the electronic tag receives the carrier, the gap clock recovery circuit can generate a clock signal from the carrier, and the clock signal is input to the gap demodulator for demodulation.

In a possible implementation manner, when the carrier is received and the voltage is not within the threshold range, the gap demodulator is further configured to demodulate first data corresponding to the carrier. For example, when the voltage reaches the upper limit of a certain threshold range, the output of the first clock signal (e.g., CLK 1) is inverted, so that the data (which may correspond to the first data) sent by the reader can be demodulated. Specifically, when the reader modulates, the clock signal does not turn over within a period of time, and at the moment, the capacitor voltage reaches a certain threshold value after a certain time, so that the output is turned over, and the tag can demodulate data sent by the reader. For a detailed description of the process, refer to fig. 4 and the related description.

In one possible implementation manner, the electronic tag further includes a rectifier bridge; the rectifier bridge is connected with two ends of the coil; the rectifier bridge is used for: generating a direct current signal according to the carrier wave; the direct current signal is used for supplying power to the electronic tag. Wherein the carrier is a radio frequency energy, which may be in the form of a specific alternating current signal; the ac signal is received by an antenna (corresponding to the aforementioned coil). Alternatively, the transponder chip comprised by the radio frequency identification tag may be a passive chip; and the working current of the sub-modules in the chip needs to meet the requirement of low power consumption. For example, the operating current of the whole analog part circuit may be lower than a certain value, such as 3ua, 4ua, 5ua or 6 ua.

In a possible implementation manner, the electronic tag further comprises an amplitude limiter connected to two ends of the coil; and the amplitude limiter is used for controlling the energy coupled by the electronic tag to be in a preset energy range. In the radio frequency identification system, the distance between the reader and the transponder is different in different devices, and different application scenes are generally different. In order to prevent the chip from getting too much energy due to too close distance, a protection circuit or a leakage path can be added to the tag or the chip according to specific equipment and application scenarios. For example, the limiter may include a bleeding path (a bleeding resistor circuit or a bleeding loop) to control the energy obtained by coupling, so as to prevent the chip in the tag from being damaged, and to protect the chip.

In a possible implementation manner, the electronic tag further includes a trimming circuit connected to two ends of the coil; the trimming circuit is used for adjusting the resonant frequency point of the electronic tag by changing capacitance values at two ends of the coil so as to maintain the performance of the electronic tag.

In a possible implementation manner, the electronic tag further includes a clock recovery circuit connected to two ends of the coil; the clock recovery circuit is used for generating a second clock signal through voltage comparison at two ends of the coil; the second clock signal is a clock signal varying within a preset clock signal range. For example, in order to prevent the generated second clock signal from generating glitches, which may cause the digital circuit to run away, the clock recovery circuit may include a comparator with hysteresis to compare voltages across the inductors. Wherein the second clock signal generated by the voltage comparison is a substantially stable clock signal.

In a possible implementation manner, the electronic tag further comprises a demodulator connected to two ends of the coil; when the carrier wave is received and the electronic tag is not in the gap mode, the demodulator is used for determining second data corresponding to the carrier wave by demodulating the waveform of the carrier wave. Specifically, the demodulator may acquire the second data included in the carrier wave by determining a waveform of the carrier wave. The specific content of the second data and the specific content of the first data may be the same or different, and the embodiment of the present invention does not limit this. The gap pattern may be a signal processing pattern in which the electronic tag should have a gap with the carrier transmitted by the reader.

In a possible implementation manner, the electronic tag further includes a first modulator connected to two ends of the coil, and a second modulator connected to two ends of the coil; the first modulator is used for controlling the amplitude of the inductor (which can be the aforementioned voltage peak value) to influence the third data fed back by the electronic tag; the second modulator is used for changing the resonant frequency through the capacitance value of the inductor so as to influence the third data. Wherein the first modulator may be an amplitude shift keying modulator and the second modulator may be a frequency shift keying modulator.

In a possible implementation manner, the electronic tag further comprises a peak detection circuit connected with one end of the coil; the peak detection circuit comprises a switching tube;

the peak value detection circuit is used for detecting whether the coil reaches a peak value;

when the peak value is reached, the peak detection circuit is further configured to: and switching on the switching tube, and charging an LC parallel resonance circuit in the electronic tag to reduce power consumption. For example, a switching tube in the peak detection circuit is turned on, and then the charging can reduce the loss of charge neutralization, thereby achieving the effect of lowest power consumption.

Optionally, when the electronic tag is not in the gap mode, the electronic tag may receive a carrier wave sent by a reader through an antenna, and obtain data corresponding to the carrier wave; after the acquired data are processed, the data in the corresponding form are sent to the reader after being modulated, and data interaction with the reader is formed.

In a third aspect, an embodiment of the present invention provides a radio frequency identification device, which may include: the transponder chip comprises a transponder chip, a coil connected with the transponder chip, a plurality of capacitors and an inductor. Wherein the transponder chip may include a gap clock recovery circuit and a gap demodulator; the gap clock recovery circuit is connected with the gap demodulator; the gap clock recovery circuit is connected with two ends of the coil; the gap demodulator is connected with two ends of the coil; the gap demodulator may include a capacitor;

the coil is used for receiving a carrier wave;

when the electronic tag is in the gap mode, the gap clock recovery circuit is used for: generating a first clock signal; the first clock signal is used for inputting the gap demodulator;

when the carrier is not received and the first clock signal is present, the gap demodulator is to: and determining a corresponding time constant according to a preset reference current and the capacitance value of the capacitor so as to control the voltage of the capacitor to be within a threshold range.

In a possible implementation manner, when the carrier is received and the voltage is not within the threshold range, the gap demodulator is further configured to demodulate first data corresponding to the carrier. For example, when the voltage reaches the upper limit of a certain threshold range, the output of the first clock signal (e.g., CLK 1) is inverted, so that the data (which may correspond to the first data) sent by the reader can be demodulated.

In one possible implementation manner, the electronic tag further includes a rectifier bridge; the rectifier bridge is connected with two ends of the coil; the rectifier bridge is used for: generating a direct current signal according to the carrier wave; the direct current signal is used for supplying power to the interior of the chip. Wherein the carrier is a radio frequency energy, which may be in the form of a specific alternating current signal; the ac signal is received by an antenna (corresponding to the aforementioned coil). Alternatively, the transponder chip comprised by the radio frequency identification tag may be a passive chip; and the working current of the sub-modules in the chip needs to meet the requirement of low power consumption. For example, the operating current of the whole analog part circuit may be lower than a certain value, such as 3ua, 4ua, 5ua or 6 ua.

In a possible implementation manner, the electronic tag further includes a trimming circuit connected to two ends of the coil; the trimming circuit is used for adjusting the resonant frequency point of the chip by changing the capacitance values at the two ends of the coil so as to maintain the performance of the chip and avoid the performance reduction of the chip. When the inductance and the capacitance at the periphery of the chip are mismatched, the resonant frequency point of the chip is inconsistent with the resonant frequency point of a reader (reader), so that the performance of the chip is reduced; in order to improve the situation, a trimming circuit can be added in the chip, and the resonant frequency point of the chip is changed by changing the capacitance values at two ends of the inductor, so that the performance of the chip is not reduced due to mismatch of the peripheral inductor and the capacitor.

In a possible implementation manner, the electronic tag further includes a clock recovery circuit connected to two ends of the coil; the clock recovery circuit is used for generating a second clock signal through voltage comparison at two ends of the coil; the second clock signal is a clock signal varying within a preset clock signal range. The second clock signal and the first clock signal can be recovered from the magnetic field received by the tag antenna, and the frequencies of the two signals are consistent, but the rising edge and the falling edge are different. For example, in order to prevent the generated second clock signal from generating glitches, which may cause the digital circuit to run away, the clock recovery circuit may include a comparator with hysteresis to compare voltages across the inductors. Wherein the second clock signal generated by the voltage comparison is a substantially stable clock signal.

In a possible implementation manner, the electronic tag further comprises a demodulator connected to two ends of the coil; when the carrier wave is received and the electronic tag is not in the gap mode, the demodulator is used for determining second data corresponding to the carrier wave by demodulating the waveform of the carrier wave. Specifically, the demodulator may acquire the second data included in the carrier wave by determining a waveform of the carrier wave. The specific content of the second data and the specific content of the first data may be the same or different, and the embodiment of the present invention does not limit this.

In a possible implementation manner, the electronic tag further includes a first modulator connected to two ends of the coil, and a second modulator connected to two ends of the coil; the first modulator is used for controlling the amplitude of the inductor (which can be the aforementioned voltage peak value) to influence the third data fed back by the electronic tag; the second modulator is used for changing the resonant frequency through the capacitance value of the inductor so as to influence the third data. Wherein the first modulator may be an amplitude shift keying modulator ASK and the second modulator may be a frequency shift keying modulator FSK. For example, when operating in the HDX mode, the transponder sends data (which may be the third data) to the reader after the calculation process of the data demodulated by the demodulator circuit. For another example, when operating in the FDX mode, the reader demodulates the data (which may be the third data) transmitted by the transponder by changing the resonant frequency by changing the capacitance between the two ends of the inductor. The third data is affected by different factors in different modes; in this embodiment, the data fed back to the reader by the transponder may be the third data.

In a fourth aspect, an embodiment of the present invention provides another radio frequency identification device, including a function of any one of the modules or circuits in the first aspect; the radio frequency identification device has the functions related to the radio frequency identification tag, such as demodulating and modulating a signal lamp.

In a fifth aspect, an embodiment of the present invention provides a radio frequency identification chip, which may include a rectifier bridge, a limiter, a trimming circuit, an FSK modulator, a load modulator (such as a modulator for ASK), a Clock recovery circuit, a Demodulator, a Peak detector (Peak detector), a resonant flip-flop (resonant trigger), a GAP Clock recovery circuit (GAP Clock generator), a GAP Demodulator (GAP Demodulator), a Power-on reset (POR), a Low dropout regulator (Low dropout regulator, LDO), a current reference (current reference), a charged Erasable Programmable read-only memory (EEPROM), a digital module, and a Shift register (Shift register).

The peak detection circuit, the resonance trigger and the peripheral LC parallel resonance circuit form a self-excited resonator (Transponder self-oscillator). For example, when operating in the FDX mode, the chip needs a low power consumption self-oscillating circuit to maintain the inductor-capacitor resonance since the reader has stopped transmitting the carrier wave. When the reader stops transmitting the carrier, the voltage across the inductor will drop because of the energy consumed between the LCs due to the series resistance of the inductor, and the inductor transmitting the data. In order to maintain long-time LC resonance, energy needs to be continuously acquired from a VCC capacitor, so that after a certain time, PG enables a switching tube to be conducted, and VCC charges an LC circuit; in the self-excited resonator, time can be calculated by a counter, and a peak value detection circuit detects a peak value of a certain section of the coil. When the two conditions are met, the PG conducts the switch tube to charge the LC circuit, and the circuit has the advantages of low power consumption, operation at a resonant frequency point and the like because a driving circuit is not needed.

Optionally, the LDO may provide a low supply voltage for the on-chip digital part. For specific connection relationships between each circuit and each module, reference may be made to the description in the foregoing aspects, and details are not described here again.

In a sixth aspect, an embodiment of the present invention provides a radio frequency identification system, including a reader and a transponder; the reader comprises a reader chip, a microprocessor MCU and other necessary components such as a necessary capacitor and a necessary coil; the transponder comprises a transponder chip and necessary components such as a capacitor, a coil and the like on the periphery. The reader sends a certain energy signal, and the responder feeds back corresponding data according to the energy signal after receiving the energy signal.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings used in the embodiments or the description of the prior art will be briefly described below.

Fig. 1 is a schematic view of an application scenario of a radio frequency identification tag according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram corresponding to the demodulation function in the GAP mode provided by the embodiment of the present invention;

fig. 3 is a schematic structural diagram of a gap clock recovery circuit according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a gap demodulator according to an embodiment of the present invention;

fig. 5 is a schematic diagram of a module structure of a transponder chip according to an embodiment of the present invention;

fig. 6 is a schematic structural diagram of a demodulator according to an embodiment of the present invention.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. It should be apparent that the described embodiments are only some of the embodiments of the present application, and not all embodiments. All other embodiments that can be derived by a person skilled in the art from the embodiments given herein without making any creative effort shall fall within the protection scope of the present application.

The terms "first," "second," "third," and "fourth," etc. in the description and claims of this application and in the accompanying drawings are used for distinguishing between different objects and not for describing a particular order. Furthermore, the terms "include" and "have," as well as any variations thereof, are intended to cover non-exclusive inclusions. For example, a process, method, system, article, or apparatus that comprises a list of steps or elements is not limited to only those steps or elements listed, but may alternatively include other steps or elements not listed, or inherent to such process, method, article, or apparatus.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the application. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. It is explicitly and implicitly understood by one skilled in the art that the embodiments described herein can be combined with other embodiments.

First, partial names related to embodiments of the present invention are explained.

(1) Resonant frequency, which refers to the frequency at which a circuit containing a capacitor and an inductor, if connected in parallel, may occur over a small period of time: the voltage of the capacitor is gradually increased, while the current is gradually reduced; the current of the inductor gradually increases, and the voltage of the inductor gradually decreases.

(2) A Demodulator (Demodulator) is a device that restores a low-frequency digital signal modulated in a high-frequency digital signal by a digital signal processing technique. Demodulators are widely used for the transmission and reproduction of information such as broadcast (audio signals), television (video signals) and the like. Demodulators are typically used in pairs with modulators that process digital signals onto high frequency signals for transmission, and demodulators that restore the digital signals to their original signals.

(3) Envelope detection (envelope-demodulation) is a vibration signal processing method based on filtering detection, and particularly has strong capability of identifying initial faults and fault signals with low signal-to-noise ratio. The peak points of the high-frequency signal of a certain time length are connected to obtain an upper (positive) line and a lower (negative) line, and the two lines are called envelope lines. The envelope reflects the curve of the amplitude variation of the high frequency signal. For constant amplitude high frequency signals, the two envelopes are parallel lines. When a high frequency signal is amplitude modulated (i.e., amplitude modulated) with a low frequency signal, the low frequency signal becomes the envelope of the high frequency signal.

(4) A Shift Register (Shift Register) is a sequential logic circuit that can be used to store or transfer data in binary form. It loads incoming data and then shifts or "shifts" it to its output on each clock cycle.

(5) Baud rate, which is understood to be how many symbols of data a device transmits (or receives) in one second, is a measure of the symbol transmission rate, which represents the number of transmitted symbols per unit time (the transmitted symbol rate).

Next, one application scenario of the radio frequency electronic tag provided in the embodiment of the present invention is described. Referring to fig. 1, fig. 1 is a schematic view of an application scenario of a radio frequency identification tag according to an embodiment of the present invention; as shown in fig. 1, the application scenario may include a microprocessor MCU, a reader chip and a transponder chip, which are illustrated as a coupling type of inductive coupling. Specifically, the MCU is connected to the reader chip and is configured to perform data interaction with the reader chip, or control the reader to transmit data content or further process data acquired by the reader. The reader chip sends a certain energy signal (namely energy shown in figure 1) through components such as coils arranged on the periphery, and covers a certain area range; the reader chip transmits a signal (i.e., the data shown in fig. 1) within its range at a certain frequency or data transmission frequency; after the transponder chip is within the signal coverage of the reader, it can obtain specific energy, not only provide power for some circuits in the chip, but also demodulate the received signal, and then modulate the signal meeting the requirement and feed back the re-modulated signal (i.e. the data' shown in fig. 1) to the reader chip through the peripheral coil. VCC and GND are exemplary labels in fig. 1 for the capacitances connected to the transponder chip.

It should be noted that the application scenario is only an exemplary scenario description; the embodiment of the utility model provides an application scene that relates to includes but not limited to above-mentioned application scene.

Referring to fig. 2, fig. 2 is a schematic structural diagram of the demodulation function in the GAP mode according to an embodiment of the present invention; as shown in fig. 2, a gap clock recovery circuit and a gap demodulator may be included; the gap clock recovery circuit is connected with the gap demodulator; the gap clock recovery circuit is connected with two ends of the coil; the gap demodulator is connected with two ends of the coil; the gap demodulator includes a capacitance;

the coil is used for receiving a carrier wave;

The LC circuit in fig. 2 and the LC circuits in the following embodiments are common knowledge in the art, and are not described herein again.

The embodiment of the utility model provides an in, in the identification area that electronic tags is in the reading ware that corresponds, electronic tags passes through the coil and receives the signal that reads the ware and send. When a gap exists in an actually transmitted signal or a signal transmitted by a reader is abnormal, a first clock signal is generated through a gap clock recovery circuit, and the clock signal is input to a gap demodulator connected with the gap clock recovery circuit; at this time, when the carrier (i.e., the signal sent by the reader) is not received yet and the first clock signal exists, the gap demodulator is configured to determine the time constant according to the preset parameter (e.g., the reference current, the capacitance value of the capacitor), and control the voltage of the capacitor to be within the normal range. Compared with the prior art, the embodiment of the utility model can solve the abnormal situation of the corresponding gap or the reader through the cooperation of the gap clock recovery circuit and the gap demodulator, so as to maintain the stability of the radio frequency identification tag; and a gap mode is also provided on the basis of the normal working mode so as to deal with emergency and support various working modes, protocols and frequency points.

Referring to fig. 3, fig. 3 is a schematic structural diagram of a gap clock recovery circuit according to an embodiment of the present invention; as shown in fig. 3, when operating in the GAP mode, the GAP clock recovery circuit is configured to generate a clock signal from a carrier, clock the digital portion, and input a demodulation signal to the GAP demodulator. This circuit adds a latch function (latch) so that CLK1 (a clock signal) does not erroneously toggle when read modulates.

Referring to fig. 4, fig. 4 is a schematic structural diagram of a gap demodulator according to an embodiment of the present invention; as shown in fig. 4, when the READER is not modulated, CLK1 is a Clock generated by the GAP Clock recovery circuit GAP Clock generator, CLK1 always exists, and by setting an appropriate reference current Iref and the capacitance value of the capacitor C0, an appropriate time constant is selected so that the voltage of the capacitor C0 is always below the threshold of the specific circuit component; when the reader modulates, the CLK1 will not turn over for a period of time, and at this time, the voltage of the capacitor will charge above the threshold of the specific circuit component (for example, a schmitt trigger, or Smith) after a certain period of time, which causes the output to turn over, thereby demodulating the data sent by the reader.

In a possible implementation manner, the electronic tag further includes a first modulator connected to two ends of the coil, and a second modulator connected to two ends of the coil; the first modulator is used for controlling the amplitude of the inductor so as to influence third data fed back by the electronic tag; the second modulator is used for changing the resonant frequency through the capacitance value of the inductor so as to influence the third data. The first modulator may be an amplitude-shift keying (ASK) modulator, and the second modulator may be a frequency-shift keying (FSK) modulator.

In a possible implementation manner, the electronic tag further comprises a peak detection circuit connected with one end of the coil; the peak detection circuit comprises a switching tube; the peak value detection circuit is used for detecting whether the coil reaches a peak value; when the peak value is reached, the peak detection circuit is further configured to: and switching on the switching tube, and charging an LC parallel resonance circuit in the electronic tag to reduce power consumption. For example, a switching tube in the peak detection circuit is turned on, and then the charging can reduce the loss of charge neutralization, thereby achieving the effect of lowest power consumption.

It should be noted that the internal architecture of the chip shown in the embodiment of the present invention is only an exemplary description; the present application relates to the description of the content including, but not limited to, the functions, types, and connection relationships of the above modules.

Please refer to fig. 5, fig. 5 is a schematic diagram of a module structure of a transponder chip according to an embodiment of the present invention; as shown in fig. 5, may include a rectifier Bridge (Bridge) 1, a Limiter (Limiter) 2, a Trimming circuit (Trimming) 3, an FSK modulator 4, a load modulator (such as an ASK modulator) 5, a Clock recovery circuit (Clock generator) 6, a Demodulator (Demodulator) 7, a GAP Clock recovery circuit (GAP Clock generator) 10, a GAP Demodulator (GAP Demodulator) 11, a Power-on reset (POR) 12, a Low dropout linear regulator (LDO) 13, a current reference (current reference) 14, a charged Erasable Programmable read only memory (EEPROM) 15, a digital module/digital circuit (digital) 16, and a Shift register (Shift) 17; it will be appreciated that the Peak detector circuit (Peak detector) 8, the resonant trigger (resonant trigger) 9 and the switches, counters etc. form the free running oscillator of the chip. When the chip is in the FDX working mode, the reader stops sending the carrier wave, and the inductance-capacitance resonance can be maintained through the self-oscillation circuit with low power consumption.

The rectifier bridge 1 is used for converting an alternating current signal received by an antenna (namely a coil) into a direct current signal VCC, and the VCC provides a power supply for the interior of a chip; because the chip generally works passively, the working current of the sub-modules in the chip needs low power consumption, and the working current of the whole analog part circuit is lower than 3 uA. Optionally, the chip may be an active or semi-active electronic tag to adapt to different scenarios and specific requirements.

And the amplitude limiter 2 is used for avoiding the damage of the chip coupling caused by excessive energy, and protecting the chip by providing a leakage path.

The trimming circuit 3 is used for changing the capacitance values at two ends of the inductor when mismatch (mismatch) occurs in the peripheral inductor and capacitor so as to change the resonant frequency point of the chip, thereby preventing the performance of the chip from being reduced due to mismatch of the peripheral inductor and capacitor.

The FSK modulator 4 is used for changing the capacitance value between two ends of the inductor to change the resonant frequency when the chip works in the FDX mode; the reader demodulates the data transmitted by the transponder through the change of the resonance frequency. For example, when FSK-DATA =1, the resonance frequency will follow a decrease due to the increase in capacitance across the inductance; when FSK-DATA =0, the capacitance value returns to the original value, and the resonance frequency also returns to the original value.

The load modulator 5 is used for calculating the data demodulated by the demodulator by the responder when the chip works in the HDX mode, and then sending the data to the reader; i.e. the transponder sends data to the reader via the load modulator. For example, in the HDX mode, when ASK-DATA =1, a load is connected across the inductor, which causes the amplitude of the inductor to decrease a lot; when ASK-DATA =0, the amplitude does not decrease between the inductances due to no load applied. Then, the reader can demodulate the data sent by the transponder through the change of the amplitude of the inductance.

And the clock recovery circuit 6 is used for comparing the voltages at two ends of the inductor through the comparator with hysteresis so as to generate a stable clock signal (corresponding to the second clock signal).

The demodulator 7 is used for demodulating the waveform transmitted by the reader to obtain data transmitted by the reader, and then transmitting the data to a digital circuit (digital). Optionally, please refer to fig. 6, fig. 6 is a schematic structural diagram of a demodulator according to an embodiment of the present invention; as shown in FIG. 6, the demodulator circuit adopts an envelope detection mode, and on the basis, two NMOS tubes can be added as switching tubes, so that the detection sensitivity is increased, the delay time is reduced, and the demodulator circuit can work under the condition of higher baud rate. In the demodulator circuit, R1, R2, R3, R4; when the reader is not modulated, the two NMOSs are conducted in turn, and then VP is always higher than VN; when the reader modulates and transmits data, the amplitude (namely, the voltage peak value) of two ends (respectively corresponding to two end nodes of the COIL) of COIL1/COIL2 is reduced, so that the two NMOS are not conducted, and at the moment, VP is reduced to be below VN, so that the data transmitted by the reader can be demodulated from waveforms at two ends of the inductor, and the data transmission between the transponder and the reader is realized.

And the peak value detection circuit 8 is used for detecting the voltage peak value of the Coil2, and at the peak value, PG (referring to a signal output by the peak value detection circuit; the signal can be used for driving the grid electrode of a MOSFET) turns on a switch tube to charge the LC circuit, and the charge can reduce the charge neutralization loss at the moment, thereby achieving the effect of lowest power consumption.

The resonant trigger 9 can be referred to the description of the foregoing fourth aspect relating to the self-excited resonator, and is not described herein again.

And the digital module 16 is used for calculating to obtain a corresponding data result according to one or more of preset data, a secret key, a mode, a protocol and the like.

The functions of the power-on reset circuit 12, the low dropout linear regulator 13, the current reference source 14, the charged erasable programmable read only memory 15, the shift register 17 and other devices are the same as or similar to those of a general radio frequency identification tag, and will not be described in further detail.

It should be noted that the internal architecture of the chip shown in the embodiment of the present invention is only an exemplary description; the present application relates to the description of the content including, but not limited to, the functions, types, and connection relationships of the above modules. The foregoing functional architectures and corresponding embodiments shown in fig. 1-6 are exemplary descriptions. The embodiment of the utility model provides a framework that possesses multi-functional wrist-watch of car intelligent key includes but not limited to above-mentioned several kinds of functional architecture.

The radio frequency tag architecture and the modules provided by the embodiments of the present invention are described above, and the working states of the partial modules related to the embodiments of the present invention under the multi-mode are listed below.

Please refer to table 1, where table 1 is a working state table of the module under the multi-mode provided in the embodiment of the present invention; the reference numbers in table 1 correspond to the module numbers in fig. 5 described above.

As shown in Table 1, on indicates that the module is in an active state and off indicates that the module is not active (or is asleep). Among them, specific 3 patterns are listed, including HDX, FDX, and GAP. The embodiment of the present invention is described by taking the above modes as examples, but the specific operation mode is not limited to the above 3 modes. Therefore, on the basis of the basic working mode, the HDX, FDX and GAP modes are provided, so that the chip supports multiple modes, can meet various conditions and meet diversified requirements.

The above description is only for the specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily conceive various equivalent modifications or substitutions within the technical scope of the present application, and these modifications or substitutions should be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims

1. A radio frequency identification tag, comprising:

the coil is used for receiving a carrier wave;

when the carrier is received, the demodulator is used for determining first data corresponding to the carrier;

when the label is in a first working mode, the first modulator is used for sending second data corresponding to the first data by adjusting voltage peak values at two ends of the coil;

when the first working mode is switched to a second working mode, the second modulator is used for enabling the resonance frequency points of the tag and the corresponding reader to be consistent by adjusting capacitance values of two ends of the coil so as to send the second data.

2. The tag of claim 1, wherein the demodulator comprises a switch tube; the demodulator is used for increasing detection sensitivity and reducing delay time through the switch tube, and is suitable for the first working mode and the second working mode.

3. The tag of claim 1, further comprising a trimming circuit connected to both ends of the coil, the trimming circuit comprising one or more capacitors; the trimming circuit is configured to:

and controlling to access the one or more capacitors to change the capacitance value of the two ends of the coil so as to adjust the resonant frequency point of the tag.

4. The tag of claim 1, wherein the first modulator comprises a load; the first modulator is further configured to:

controlling the load to be connected into the coil, and reducing voltage peak values at two ends of the coil; alternatively, the first and second electrodes may be,

and controlling the load not to be connected into the coil, and recovering the voltage peak value at two ends of the coil.

5. The tag of claim 1, further comprising a gap clock recovery circuit, a gap demodulator coupled to the gap clock recovery circuit; the gap clock recovery circuit is connected with two ends of the coil; the gap demodulator is connected with two ends of the coil; the gap demodulator includes a capacitance;

the gap clock recovery circuit is used for generating a first clock signal;

when the carrier is not received and the first clock signal is present, the gap demodulator is to:

and determining a corresponding time constant according to a preset reference current and the capacitance value of the capacitor so as to control the voltage of the capacitor to be within a threshold range.

6. The tag of claim 5, wherein the gap demodulator is further configured to determine the first data when the carrier is received and the voltage is not within the threshold range.

7. The tag of claim 1, further comprising a limiter connected to both ends of the coil; and the amplitude limiter is used for controlling the energy coupled by the tag to be in a preset energy range.

8. The tag of claim 1, further comprising a clock recovery circuit connected to both ends of the coil;

the clock recovery circuit is used for generating a second clock signal through comparison of voltages at two ends of the coil; the second clock signal is a clock signal varying within a preset clock signal range.

9. The tag of claim 1, further comprising a peak detection circuit connected to one end of the coil; and the peak value detection circuit is used for detecting whether the coil reaches the voltage peak value at the two ends.

10. The tag of claim 9, further comprising a resonant circuit, a resonant switch and a counter; the counter is used for counting to judge whether a preset moment is reached or not;

and under the condition that the label does not receive the carrier wave, when the preset moment is reached and the voltage at the two ends of the coil reaches the voltage peak value at the two ends, the resonance switch is switched on to charge the resonance circuit.