KR101382795B1 - Radio Frequency IDentification receiver/transceiver device - Google Patents

Abstract

RFID transmitting and receiving device according to an embodiment includes a first phase synchronization circuit for supplying a first oscillation signal; A second phase synchronization circuit for supplying a second oscillation signal in a band corresponding to a frequency difference between the first oscillation signal and the reception signal; A first mixer for mixing the received signal with the first oscillation signal to generate a first mixed signal; A balloon circuit for separating the first mixed signal into an I signal and a Q signal; And a second mixer and a third mixer for mixing the separated I and Q signals with the second oscillation signal to generate an I baseband reception signal and a Q baseband reception signal, respectively.

According to the embodiment, the influence of the interference signal can be minimized to improve the data recognition rate, and the sufficient energy of the tag can be supplied by extending the energy signal section transmitted with the data signal. In addition, the SNR can be improved by minimizing the DC offset phenomenon, and the damage of the circuit elements can be prevented.

RFID transceiver, phase synchronization circuit, mixer, balloon circuit, energy signal

Description

RFID transceiver device {Radio Frequency IDentification receiver / transceiver device}

An embodiment discloses an RFID transceiver.

Nowadays, ubiquitous network technology is attracting attention of many people. Ubiquitous network technology means a technology that makes it possible to connect to various networks smoothly regardless of time and place.

An example of such ubiquitous network technology is RFID technology, and among them, RFID technology introduced in commerce is representative.

In the case of the RFID reader, the radio wave environment is severely changed, and the change of the received signal is greatly changed, such as the phase of the tag signal according to the change of the external environment. It greatly affects the recognition rate of the tag.

For example, when a large number of tags exist in an area where a plurality of RFID readers are installed, tag signals using the same frequency band may be simultaneously received by the RFID readers. In this case, interference between tag signals may occur and the RFID reader may The signal cannot be processed.

In addition, when a transmission signal of another RFID reader or its own transmission signal is transmitted together with the reception signal, an interference phenomenon occurs and a tag recognition rate is significantly lowered.

This interference causes signal loss, and energy signals are not sufficiently delivered to the tag.

In addition, since a signal carrying data and a signal used as tag energy are transmitted through the same frequency band, supply of energy is not smooth and reception sensitivity is lowered.

When data signal and energy signal are transmitted together through the same frequency band and even interference signal is generated, DC offset phenomenon is caused and signal to noise ratio (SNR) is lowered, which affects circuit operation and shortens equipment life. There is a problem.

The embodiment provides an RFID transceiver device which can maintain a stable communication state by minimizing the influence of an interference signal on a transmission / reception signal.

The embodiment provides an RFID transceiver device which can smoothly supply energy signals and improve reception sensitivity.

RFID transmitting and receiving device according to an embodiment includes a first phase synchronization circuit for supplying a first oscillation signal; A second phase synchronization circuit for supplying a second oscillation signal in a band corresponding to a frequency difference between the first oscillation signal and the reception signal; A first mixer for mixing the received signal with the first oscillation signal to generate a first mixed signal; A balloon circuit for separating the first mixed signal into an I signal and a Q signal; And a second mixer and a third mixer for mixing the separated I and Q signals with the second oscillation signal to generate an I baseband reception signal and a Q baseband reception signal, respectively.

According to the embodiment, the following effects can be obtained.

First, the data recognition rate can be improved by minimizing the influence of the interference signal, and sufficient tag energy can be supplied by extending the energy signal section transmitted with the data signal.

Second, the signal to noise ratio (SNR) can be improved by minimizing the DC offset phenomenon, and the damage of the circuit device can be prevented.

Third, since the signal is processed through the frequency loop method, the effects of the interference signal and the noise signal can be minimized and gain characteristics and filtering characteristics can be improved.

An RFID transceiver according to an embodiment will be described with reference to the accompanying drawings. In the embodiment, the RFID transceiver is an RFID reader that uses a UHF signal in a 900 MHz band as a carrier signal and communicates with a tag. .

1 is a block diagram schematically showing the components of the RFID transceiver 100 according to the embodiment.

1, an RFID transceiver 100 according to an embodiment includes an antenna 101, a first signal separator 105, a low noise amplifier (LNA) 110, a first mixer 115, Attenuator 125, Channel Filter 130, Balloon Circuit 135, Second Mixer 140, Third Mixer 145, First ADC 150, Second ADC 155, Control Unit 160, First A synthesizer 170, a fourth mixer 175, a fifth mixer 180, a second signal separator 185, a second synthesizer 190, a transmission filter 192, and a power amplifier (PA) ( 194).

The antenna 101 receives a signal from a tag or other reader.

The first signal separation unit 105 is connected to the antenna 101 to separate the transmission and reception signal, and transmit the separated received signal to the low noise amplifier 110 or transmits the transmission signal transmitted from the power amplifier 194 antenna 101 To pass).

The first signal separator 105 may be provided as a semiconductor switching device such as a single pole double throw (SPDT).

The low noise amplifier 110 amplifies the noise of the received signal lowered due to attenuation and noise.

The first mixer 115 receives the first oscillation signal from the first phase synchronization circuit 120, mixes the received signal transmitted from the low noise amplifier 110 and the first oscillation signal to correspond to the frequency difference between the two signals. A first mixed signal of a band is generated.

The first mixer 115 is provided as a single mixer element.

In an embodiment, since the first oscillation signal supplied from the first phase synchronization circuit 120 has a 901 MHz frequency band, and the received signal has a 900 MHz frequency band, the first mixed signal has a difference between two signals, that is, a 1 MHz frequency. You have a band.

The attenuator 125 attenuates the power of the first mixed signal when it exceeds the signal specification or amplifies the original power level.

The channel filter 130 filters the noise signal generated in the process of generating the first mixed signal and removes signals other than the 1 MHz bandwidth.

As the channel is filtered as described above, when the tag signals are restored in the second mixer 140 and the third mixer 145, interference with adjacent reader signals or other tag signals may be excluded and the tag recovery rate may be improved.

The channel filter 130 may be provided, for example, as a saw (SAW) filter.

The balloon circuit 135 converts the phase of the first mixed signal into an I signal (eg, "E sin omega t") and a Q signal (eg "E cos omega t").

The second mixer 140 and the third mixer 145 are dual mixers and receive a second oscillation signal from the second phase synchronizer circuit 165.

The second oscillation signal has a band corresponding to the frequency difference between the first oscillation signal and the reception signal. Since the first oscillation signal has a band of 901 MHz and the reception signal has a 900 MHz band, the second oscillation signal has a frequency of 1 MHz. Has a band.

The second mixer 140 generates an I baseband reception signal by mixing an I signal having a phase difference of 90 degrees, that is, an I first mixed signal with a second oscillation signal, and the third mixer 145 generates a Q signal, that is, Q The first mixed signal is mixed with the second oscillation signal to generate a Q baseband received signal.

2 is a graph measuring signal types processed by the second mixer 140 and the third mixer 145 according to an embodiment.

Referring to FIG. 2, the carrier signal E of the 1 MHz band of the I first mixed signal and the Q first mixed signal is canceled from the second oscillation signal of the 1 MHz band, and has a data signal having a bandwidth of 40 KHz to 160 KHz ( Only D) can be extracted.

As described above, the RFID transceiver 100 according to the embodiment is a method of restoring a tag signal by configuring two phase synchronization circuits 120 and 165 in a loop type circuit, and using one phase synchronization circuit as in the prior art. Therefore, the tag signal can be restored more stably than the method of converting the RF signal into a baseband signal.

For example, the frequency loop scheme may exclude the influence of the DC offset component generated in the process of lowering the band of the RF signal to the baseband signal band.

The first ADC 150 is connected to the second mixer 140 to convert the I baseband received signal into an I digital received signal, and the second ADC 155 is connected to the third mixer 145 to Converts the Q baseband received signal to a Q digital received signal.

The controller 160 receives the I digital received signal and the Q digital received signal, processes the digital signal on the application layer, and interprets tag information.

In addition, the controller 160 includes a communication protocol to control wireless communication with the tag, and generates reader information to configure a digital transmission signal.

In this case, the controller 160 converts a data format to analyze a device identification code of a tag signal and processes a filtering operation to extract necessary information. For example, a field programmable gate array (FPGA) circuit or a digital signal processing (DSP) is used. Can be implemented using a circuit.

The first synthesizer 170 receives the second oscillation signal from the second phase synchronizer circuit 165 and receives the transmission signal from the control unit 160 to synthesize the two signals.

3 is a graph illustrating a form in which a transmission signal and an energy extension signal are synthesized by the first synthesizer 170 according to an embodiment.

Referring to FIG. 3, among the signal sections synthesized by the first synthesizer 170, an “A” section is an energy signal section and a “B” section is a tag signal loading section. By combining the second oscillation signal with the transmission signal, it can be seen that the energy signal section "A" is extended by 1 MHz, which is the bandwidth of the second oscillation signal.

The synthesized transmission signal is transmitted to the tag, and the tag signal generated from the tag also forms such a signal.

Therefore, when the tag signal is received through the antenna 101, the influence of the interference signal and the DC offset component can be minimized through the above-described signal processing method of the receiver, that is, the frequency loop method.

The section “C” shown in FIG. 3 means an area of the tag signal that remains after the energy signal is canceled.

The second signal separator 185 may be implemented as a phase shift circuit such as, for example, a balloon circuit, and receives the second oscillation signal supplied from the second phase synchronizer circuit 165 to generate the first and second oscillation signals. Separate into 2 oscillation signals.

The fourth mixer 175 generates an I RF transmission signal by mixing the transmission signal synthesized in the first synthesizer and the I second oscillation signal, and the fifth mixer 180 generates Q and the transmission signal synthesized in the first synthesizer. The second oscillation signal is mixed to generate a Q RF transmission signal.

Therefore, in the digital signal state, the transmission signal synthesized with the second oscillation signal may be modulated into an RF transmission signal having an extended energy signal section.

The second synthesizer 190 combines the I RF transmission signal and the Q RF transmission signal into one RF transmission signal.

The transmission filter 192 filters the RF transmission signal by removing noise components generated during the mixing and synthesis process, and the power amplifier 194 amplifies the filtered transmission signal to a transmittable power level to form a first signal separation unit. Forward to 105.

The first signal separation unit 105 branches the RF transmission signal to the antenna 101 side, and the branched RF transmission signal is transmitted through the antenna 101.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood that various modifications and applications other than those described above are possible. For example, each component specifically shown in the embodiments of the present invention can be modified and implemented. It is to be understood that all changes and modifications that come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

1 is a block diagram schematically illustrating the components of an RFID transceiver device according to an embodiment.

FIG. 2 is a graph measuring signal shapes processed by a second mixer and a third mixer according to an embodiment. FIG.

3 is a graph measuring a form in which a transmission signal and an energy extension signal are synthesized by a first synthesizer according to an embodiment.

Claims (8)

A first phase synchronization circuit for supplying a first oscillation signal; A second phase synchronization circuit for supplying a second oscillation signal in a band corresponding to a frequency difference between the first oscillation signal and the reception signal; A first mixer for mixing the received signal with the first oscillation signal to generate a first mixed signal; An attenuator connected to an output of the first mixer to attenuate power of the first mixed signal; A channel filter connected to an output of the attenuator and filtering a noise signal from the first mixed signal; A balloon circuit connected to an output terminal of the channel filter to separate the first mixed signal into an I signal and a Q signal; And And a second mixer and a third mixer for mixing the separated I and Q signals with the second oscillation signal to generate an I baseband reception signal and a Q baseband reception signal, respectively. The method according to claim 1, antenna; And a first signal separation unit connected to the antenna to separate a transmission / reception signal and transferring the separated reception signal to the first mixer. The method according to claim 1, A first synthesizer for synthesizing the second oscillation signal and the transmission signal; A second signal separator for separating the second oscillation signal into an I second oscillation signal and a Q second oscillation signal; And a fourth mixer and a fifth mixer for mixing the synthesized transmission signal with the separated I second oscillation signal and the Q second oscillation signal, respectively, to generate an I transmission signal and a Q transmission signal. The method of claim 3, The first oscillation signal is 901MHz, The second oscillation signal is 1MHz, The transmitting and receiving signal is a RFID transceiver device of the 900MHz band signal. The method of claim 3, And a second synthesizer for synthesizing the I transmission signal and the Q transmission signal into one transmission signal. The method according to claim 1, A first ADC connected to the second mixer to convert the I baseband received signal into an I digital received signal; A second ADC connected to the third mixer to convert the Q baseband received signal into a Q digital received signal; And And a controller which receives the I digital received signal and the Q digital received signal, processes the data into a received signal, and generates a transmitted signal. 3. The method of claim 2, RFID transceiver device comprising a low noise amplifier connected between the first signal separator and the first mixer. 6. The method of claim 5, A transmission filter connected to an output terminal of the second synthesizer; And RFID transceiver device comprising a power amplifier connected to the transmission filter.

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