RU193854U1 - RFID IDENTIFICATION LABEL - Google Patents

Abstract

The invention relates to integrated circuits for passive radio frequency identification tags. The technical result consists in increasing the response range of the label and ensuring its operability in the conditions of the scatter of the capacitance and inductance of the elements of the resonant LC circuit. The technical result is achieved by the fact that the control and coding schemes of the data are combined into one, consisting of a ZI element, a first information trigger, a second information trigger, an UNIVERSITY element. In this case, the RFID tag contains a resonant capacitor and a power capacitor, an output data modulator, a half-wave rectifier, a device for connecting a resonant inductance coil, a clock pulse extractor, an output data control and coding circuit, a serial access memory circuit. 2 ill.

Description

The invention relates to integrated circuits of passive-action radio-frequency identification tags, transmitting information using an amplitude-modulated radio signal by varying the degree of absorption of energy of waves emitted by a reader. Labels are also powered by radiated energy.

Known passive RFID tags without a supply element, the interaction of which with the reader is based on the principle of mutual induction. When the tag antenna tuned to the radiation frequency of the reader falls into the electromagnetic field created by its antenna, a current is induced in it. The energy received by the tag is dissipated, which leads to a decrease in the amplitude of electromagnetic waves recorded by the reader, see, for example, US patent No. 3810147, NPK 340/280, IPC G01S 9/56, published May 7, 1974 [1].

Such a label is a low-quality LC circuit. It does not allow to distinguish between objects, as it is only able to inform about the fact of its falling into the reading zone.

This disadvantage is absent in the tag, which is a passive transceiver with a once programmable memory, in which a unique number is entered. The tag, getting into the readout field, receives the current induced in the antenna, which is rectified, and enters the tag circuit. Data from the memory controls the key periodically connecting the active resistance parallel to the LC circuit, and this performing amplitude modulation of the wave emitted by the reader. This is how a unique number is transmitted from the tag to the reader. A label that works on this principle is described in the product specification EM4100 - Read Only Contactless Identification Device f. EM Microelectronic - Marin SA, 2004 [2]. In technical essence, it is closest to the claimed utility model.

The RFID tag contains a resonant capacitor and a power capacitor, an output data modulator, a half-wave rectifier, the first and second AC voltage inputs of which, together with the first and second outputs of the output data modulator and the outputs of the resonant capacitor, are respectively connected to the first and second terminals of the device for connecting the resonant inductor , and the outputs of the positive and negative poles of the rectified voltage are respectively connected to the busbars integral and negative poles of the supply voltage and with the first and second terminals of the power capacitor, a clock extractor, the input of which is connected to the first output of the device for connecting a resonant inductor, a control circuit, an encoding circuit for the output data and a read-only memory circuit for sequential access, read permission input which is connected to the corresponding output of the control circuit, and the data output is connected to the corresponding input of the encoding circuit of the output data, in OD control is connected to a corresponding output of the control circuit, and an output connected to the input of the modulator output.

In an analog device, clock pulses are generated by the extractor by converting a sinusoidal voltage induced on the resonant LC circuit by the electromagnetic reading field into a pulsed one with a frequency divided by a certain number of times relative to the radiation frequency of the reader.

The label gives zero and single values of the bits of the output data in the Manchester code, which provides for the inclusion of the modulation mode, the process of more intensive absorption of read field energy, respectively, in the first and second half-cycles of the clock pulses. Reading information from memory, accompanied by an increase in energy consumption, occurs at the beginning of each clock cycle. If at the end of the previous clock the label worked in modulation mode, spending the energy stored in the power capacitor, this energy may not be enough for reading.

Insufficient energy storage for the label’s normal power supply occurs when it is far removed from the reader and in the case of inaccurate tuning of the resonant LC circuit to the readout radiation frequency.

The technical result of the utility model is to increase the response range of the label and ensure its operability in the conditions of the scatter of the capacitance and inductance of the elements of the resonant LC circuit.

The technical result is achieved by the fact that in the RFID tag, which contains a resonant capacitor and a power capacitor, an output data modulator, a half-wave rectifier, the first and second AC voltage inputs of which, together with the first and second outputs of the output data modulator and the outputs of the resonant capacitor, are respectively connected to the first and the second conclusions of the device for connecting a resonant inductor, and the outputs of the positive and negative poles of the rectified voltage respectively, are connected to the buses of the positive and negative poles of the supply voltage and to the first and second terminals of the power capacitor, a clock extractor, the input of which is connected to the first output of the device for connecting a resonant inductance coil, a control circuit, an encoding circuit for the output data, and a serial memory circuit access, the read permission input of which is connected to the output of the control circuit, the input of clock pulses together with the input of the clock pulse the control circuits are connected to the output of the clock extractor, and the data output is connected to the input of the output data coding circuit, the output of which is connected to the input of the output data modulator, the control and data coding circuits are combined into one consisting of a memory element, the output of which is the read permission output the first information trigger, the data input of which is connected to the data output of the read-only memory circuit of the sequential access device, and the synchronization input is connected to the output of the element ZI of the second information trigger, the data input of which is connected to the output of the first information trigger, the IDENTITY element, the first input of which is connected to the output of the second information trigger, the second input together with the dynamic synchronization input along the front of the second information trigger are connected to the output of the extractor clock pulses, and the output is connected with the first inverse input of the ZI element and with the input of the output data modulator, the clock extractor additionally has double clock outputs constant and quadruple frequency, respectively, they are connected directly to the second and to the third inverted input GI element.

The indicated implementation of the RFID tag allows reading only when the modulation is off, when it can receive more energy from the reading electromagnetic field for power.

The distinguishing features of the utility model is the implementation of the control circuit and coding of the output data.

The utility model is illustrated by the drawings of FIG. 1 depicting an electrical circuit for an RFID tag, and FIG. 2 with voltage plots on the nodes of the device circuit.

The RFID tag contains a resonant capacitor C _RES and a capacitor C _PIT power, an output data modulator, a half-wave rectifier, the first and second AC voltage inputs of which, together with the first and second outputs of the output data modulator and the terminals of the capacitor C _{RES, are} respectively connected to the first and second terminals L1 _RES and L2 _RES device for connecting the resonant inductor, and the outputs of the positive and negative poles of the rectified voltage are respectively connected busbars of positive and negative poles of _{the PIT} + U and -U _PIT supply voltage and with first and second terminals of the capacitor C _ICUs clock extractor whose input is connected to the first terminal L1 _RES device for connecting the resonant inductor, the control circuit and encoding the output data a read-only memory circuit of a serial access ROM. The control and coding scheme for the output data consists of a ZI element 1, the first D-flip-flop 2, whose data input D is connected to the data output DO of the ROM circuit, and the synchronization input C is connected to the output of the element 1 and to the RD input of the read permission of the ROM circuit, the second D-flip-flop 3, the data input D of which is connected to the output of flip-flop 2, of element 4 UNIVERSALITY, the first input of which is connected to the output of flip-flop 3, the second input, together with the dynamic input C of synchronization along the front of flip-flop 3, are connected to the output F _{C of the} extractor clock pulses and input m C sync ROM circuit, and an output connected to the first inverted input of the element 1 and to the input MOD modulator output data outputs 2F _C and 4F _C clock pulses double and quadruple frequency extractor respectively connected to second direct and to the third inverted input element 1.

The device operates as follows.

When a tag enters the readout field on an oscillating circuit formed by a capacitor C _REZ and acting as an antenna with an external resonant inductor L, a sinusoidal alternating voltage is applied via electromagnetic induction through a half-wave rectifier to the + U _PIT and -U _PIT buses, providing all the elements of the device supply voltage, smoothed capacitor C _PIT .

Upon reaching the supply voltage sufficient for the level to work, the clock extractor starts converting the positive half-periods of the sinusoidal voltage at the output of L1 _REZ into rectangular pulses following with the readout radiation frequency, and repeatedly divide their frequency to the values 4F _C , 2F _C and F _C , corresponding to quadruple, doubled and actually the frequency F _C clock pulses synchronizing the operation of the device. All these pulses go to the control and coding circuit of the output data. In this case, the edges of the pulses following the frequency F _C coincide in time with the edges of the pulses of frequency 2F _C , the edges and decays of which occur simultaneously with the edges of the pulses 4F _C.

The read address of the ROM is changed in a cyclic sequence along the edge of each clock pulse F _C , which starts the next clock cycle of the device. Element 1 generates a read signal RD from ROM. High - active RD signal level always corresponds to the low - passive state of the MOD signal. The RD pulse is always shifted relative to the beginning of the measure or its middle by half the period of the 4F _C frequency. This should be enough to complete the process of selecting the next memory cell in the ROM before the appearance of an RD pulse.

If a logical unit is contained in the ROM memory cell at the selected address, a positive DO pulse appears at the ROM output, which repeats the RD pulse in time. If the cell contains a logical zero, the DO output remains low.

The state at the DO output is recorded in trigger 2, synchronized by a high level of the RD pulse, and stored in it until the next RD pulse, at the beginning of each cycle, this state is recorded in trigger 3 synchronized by the pulse front F _C and remains in it for the entire clock period .

Element 4 generates a modulation signal in accordance with the Manchester code. Since the duration of the pulses of the clock frequency F _C is equal to the pause duration between them, during the single state of trigger 3, the active signal MOD at the output of element 4 UNIVERSALITY will be generated in the first half of the clock period, and during the zero state of trigger 3 - in the second.

In the active state, the signal MOD modulator of the output data more intensively absorbs the energy of the read field, which leads to a decrease in the amplitude of the sinusoidal voltage U _L1-L2 between the terminals L1 _REZ and L2 _REZ . When the amplitude of the sinusoidal voltage drops below the minimum operating voltage between the + U _PIT and -U _PIT buses, a half-wave rectifier stops adding charge to the _PIT capacitor C and the device can be operated only due to the energy stored in it.

To ensure the operability of the RFID tag at a large distance from the reader and when the resonant LC circuit is inaccurately tuned to its radiation frequency, reading information from the memory circuit, accompanied by increased current consumption, is performed only when the modulation is turned off, when the device can receive maximum energy from external electromagnetic field.

Claims (1)

An RFID tag comprising a resonant capacitor and a power capacitor, an output data modulator, a half-wave rectifier, the first and second AC voltage inputs of which, together with the first and second outputs of the output data modulator and the outputs of the resonant capacitor, are respectively connected to the first and second terminals of the device for connecting the resonant coil inductances, and the outputs of the positive and negative poles of the rectified voltage, respectively, are connected to the busbars the positive and negative poles of the supply voltage and with the first and second terminals of the power capacitor, a clock extractor, the input of which is connected to the first output of the device for connecting a resonant inductor, a control circuit, an encoding circuit for the output data and a read-only memory circuit for sequential access, read permission input which is connected to the output of the control circuit, the input of the clock pulses together with the input of the clock pulses of the control circuit are connected to the output of the ext a clock pulse generator, and the data output is connected to the input of the output data encoding circuit, the output of which is connected to the input of the output data modulator, characterized in that the control and data encoding circuits are combined into one, consisting of a memory element, the output of which is the read permission output of the first information a trigger, the data input of which is connected to the data output of the read-only memory circuit of the sequential access device, and the synchronization input is connected to the output of the ZI element of the second information of the second trigger, the data input of which is connected to the output of the first information trigger, the IDENTITY element, the first input of which is connected to the output of the second information trigger, the second input together with the dynamic synchronization input along the front of the second information trigger are connected to the output of the extractor clock pulses, and the output is connected to the first with an inverse input of the ZI element and with the input of the output modulator, the clock extractor additionally has double and quadruple clock outputs that they are connected respectively to the second and the third direct inverse inputs GI element.

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