KR100886666B1 - System and method for controlling transmission power in rfid reader - Google Patents

Abstract

A transmission power control system and a method thereof in an RFID reader for removing a phenomenon in which the wave form of the RF received signal is distorted or which is buried in the noise of the leakage signal are provided to improve the receive sensitivity and prevent a reception end or distortion of the RF reception signal. A transmission power control system determines whether the RF transmission signal is transmitted to the RFID tag(S310). The transmission power control system branches a part of the combining signal of the leakage signal and RF receiving signal off(S320). The transmission power control system measures the strength of the branched combining signal(S330). The transmission power control system determines whether the intensity of the branched combining signal is chosen(S340). The drive amplifier is strong RF transmission signal(S350, S360).

Description

Transmission power control system in the RFID reader and transmission power control method in the RFID reader {SYSTEM AND METHOD FOR CONTROLLING TRANSMISSION POWER IN RFID READER}

The present invention is to prevent the receiving end from saturating due to the leakage signal flowing into the receiving end of the RFID reader without transmitting to the RFID tag when transmitting the RF transmission signal from the transmitting end of the RFID reader, to improve the reception sensitivity of the RFID reader, A transmission power control system and a transmission power control method in an RFID reader for controlling transmission of a transmission signal.

The present invention is derived from the research conducted as part of the IT new growth engine core technology development project of the Ministry of Information and Communication and the Ministry of Information and Telecommunications Research and Development. [Task management number: 2006-S-023-02, Title: RFID system advancement technology development] .

Today, RFID technology provides access control, commute management, logistics management, parking management, intelligent bus card systems, u-Healthcare, u-Museum, book loan management, and product information such as food, medicine, and records, and genuine wine wines. It is widely used in various fields such as verification.

RFID (Radio Frequency Identification) is an automatic recognition technology that processes information by identifying RFID tags in a non-contact way through radio frequency.The RFID system is an RFID reader that reads and decrypts functions, and RFID with embedded unique information. It consists of a tag (Radio Identification Tag), operation software, and a network, and recognizes, tracks, and manages an object or animal with an RFID tag by identifying unique information input to the RFID tag.

In the conventional RFID reader, since the RF transmission signal is transmitted to the RFID tag and then obtains information from the RF reception signal reflected from the RFID tag, both the transmission and reception signals are communicated at the same frequency. Send / receive signal with RFID tag by using.

1 is a diagram illustrating a configuration of an RFID reader.

According to FIG. 1, a conventional RFID reader includes a transmitter 110, a drive amplifier (DA) 120, a power amplifier (PA) 130, a circulator 140, an antenna ( ANT) 150, a receiver 160, and a baseband signal processor 170.

The transmitting end 110 processes modulation and amplification of data to be transmitted by the RFID tag, the driving amplifier 120 amplifies the RF transmission signal to a medium size, and the power amplifier 130 amplifies the transmission output to the maximum. Do it. In addition, the circulator 140 separates the RF transmission signal to be transmitted to the RF tag and the RF reception signal received from the RF tag, and the antenna 150 transmits / receives an RFID tag, an RF transmission signal, and an RF reception signal. The receiver 160 demodulates the received RF received signal to restore original data, and the baseband signal processor 170 processes the transmit / receive data.

The RF transmission signal output from the transmitter 110 is properly amplified by the driving amplifier 120, amplified by the maximum RF transmission signal through the power amplifier 130, and transferred to the antenna 150 through the circulator 140. do. In this case, a part of the RF transmission signal, that is, the leakage signal may flow into the receiving end 160.

When the RF transmission signal is transmitted to the RFID tag, the leakage signal flowing into the receiver 160 is classified into two types. One is an RF transmission signal flowing directly from the transmitting end 110 to the receiving end 160 by the isolation characteristic of the circulator 140.

In general, the circulator 140 is directed from the first port 141 to the second port 142, the second port 142 from the third port 143, or the third port 143 from the first port ( The signal is transmitted in the direction 141 and does not transmit the signal in the opposite direction of each direction, but some signals may be introduced in the reverse direction.

That is, based on the circulator 140, the first port 141 is on the transmitting end 110 side, the second port 142 is on the antenna 150 side, and the third port 143 is on the receiving end ( When connected to the 160 side, the signal should not flow in the direction from the port 1 (141) to the port 3 (143), but the signal actually flows, the leakage signal for the RF transmission signal is generated. As the power and strength of the leakage signal increase, the receiver 160 easily saturates even a small signal.

The other is the impedance matching between the circulator 140 and the antenna 150 is not achieved, the RF is not transmitted from the antenna 150 to the RFID tag, the RF is reflected from the antenna 150 is introduced into the receiver 160 It is a transmission signal. If impedance is not matched between the signal lines to be interconnected, reflection occurs, and the reflected RF transmission signal passes through the signal path from the port 2 142 of the circulator 140 toward the port 3 143 to the receiving end 160. ), It becomes a leakage signal.

In this case, the RF reception signal transmitted from the RFID tag in response to the transmitted RF transmission signal, and the reflected RF transmission signal, that is, the leakage signal, are port 3 (143) from port 2 (142) of the circulator 140. ), The receiver 160 is easily saturated because it is combined with each other without being distinguished from each other and is directly transmitted to the receiver 160.

In addition, due to the influence of the leakage signal on the RF transmission signal, the waveform of the RF reception signal received by the receiver 160 is distorted, making it difficult to determine the RF reception signal. In general, since the power of the RF reception signal itself transmitted from the RFID tag is low, the circuit sensitivity of the receiver 160 is also set low. Therefore, even if the power of the leakage signal is lower than the circuit sensitivity of the receiving terminal 160, the receiving terminal 160 of the RFID reader may be saturated and paralyze the receiving function, and as the power of the leakage signal increases, Since the power is relatively small, there is a problem that the waveform of the RF received signal is distorted or buried in the noise of the leaked signal, and thus cannot be restored.

Accordingly, in the present invention, when the RF transmission signal is transmitted, the waveform of the RF reception signal is distorted or buried in the noise of the leakage signal due to the leakage signal that is not transmitted to the RFID tag and flows into the receiving end of the RFID reader. It is proposed a new technology that can solve the problem that can not be restored, and improve the reception sensitivity of the RFID reader by preventing the receiver from easily saturated.

The present invention has been made to solve the above problems, due to the leakage signal for the RF transmission signal flowing into the receiving end of the RFID reader, the waveform of the RF reception signal is distorted or buried in the noise (noise) of the leakage signal It is an object of the present invention to provide a transmission power control system and a transmission power control method in an RFID reader that can solve a problem that cannot be restored and improve the reception sensitivity of an RFID reader by preventing the receiving end from being easily saturated.

In addition, the present invention is to control the transmission power in the RFID reader in order to solve the conventional problem due to the leakage signal flowing into the receiving end of the RFID reader, which is not transmitted to the RFID tag when transmitting the RF transmission signal at the transmitting end of the RFID reader. An object of the present invention is to provide a transmission power control system and a transmission power control method in an RFID reader.

In addition, the present invention measures the strength of the combined signal of the leakage signal and the RF reception signal for the RF transmission signal flowing into the receiver to control the gain (output) of the driving amplifier according to the strength of the RFID so that the receiver is not saturated An object of the present invention is to provide a transmission power control system and a transmission power control method in a reader.

In addition, the present invention measures the strength of the leakage signal that the RF transmission signal to be transmitted to the RFID tag to the receiving end of some RFID reader and controls the gain (output) of the driving amplifier according to the intensity so that the receiving end is not saturated. An object of the present invention is to provide a transmission power control system and a transmission power control method in an RFID reader.

In order to achieve the above object and solve the problems of the prior art, the transmission power control system in the RFID reader according to an embodiment of the present invention, power detection means for detecting a leakage signal of the RF transmission signal transmitted to the RFID tag And a combiner for branching the detected leakage signal, and control means for controlling the transmission of the RF transmission signal such that the strength of the branched signal is maintained within a predetermined limit intensity.

In a method of controlling a transmission power in an RFID reader according to an embodiment of the present invention, analyzing the RF transmission signal transmitted to an RFID tag, detecting a leakage signal for the RF transmission signal, and detecting the detected leakage signal. Branching, measuring the strength of the branched signal, and controlling the transmission of the RF transmission signal such that the measured strength of the branched signal is maintained within a predetermined threshold intensity. It is done.

According to the present invention, due to the leakage signal for the RF transmission signal flowing into the receiving end of the RFID reader, the waveform of the RF reception signal is distorted or buried in the noise (noise) of the leakage signal to solve the problem that can not be restored, By preventing the receiver from easily saturating, it is possible to improve the reception sensitivity of the RFID reader.

In addition, according to the present invention, by measuring the strength of the combined signal of the leakage signal and the RF reception signal for the RF transmission signal flowing into the receiving end and by controlling the gain (output) of the driving amplifier according to the intensity, It is possible to prevent the saturation of the receiver due to the leakage signal and the waveform distortion of the RF reception signal, to improve the reception sensitivity of the RFID reader, and to solve the difficulty of restoring the RF reception signal due to the noise of the leakage signal.

In addition, according to the present invention, the RF transmission signal to be transmitted to the RFID tag by measuring the strength of the leakage signal flowed into the receiving end of some RFID reader by controlling the gain (output) of the driving amplifier according to the intensity, RF transmission It is possible to prevent the saturation of the receiver due to the leakage signal of the signal and the waveform distortion of the RF reception signal, to improve the reception sensitivity of the RFID reader, and to solve the difficulty of restoring the RF reception signal due to the noise of the leakage signal.

Hereinafter, a transmission power control system and a transmission power control method in an RFID reader according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a diagram illustrating a configuration of an RFID reader including a transmission power control system according to an embodiment of the present invention.

The RFID reader illustrated in FIG. 2 includes a transmitter 110, a drive amplifier (DA) 120, a power amplifier (PA) 130, a circulator 140, and an antenna ANT. 150, the receiver 160, the baseband signal processor 170, and the transmit power control system 300 according to the present invention.

In order to receive the tag information from the RFID tag, the transmitter 110 performs a function of generating an RF transmission signal for modulating or amplifying data and transmitting the tag information to the RFID tag.

In addition, the receiving end 160 performs a function of filtering the RF received signal received from the RFID tag and demodulating the RF received signal into data in a form for processing by the baseband signal processor 170.

In addition, the baseband signal processing unit 170 processes the received data restored by the receiving end 160, or performs the function of processing the transmission data transmitted from the transmitting end (110).

In addition, the driving amplifier 120 functions to amplify the RF transmission signal generated by the transmitting terminal 110 to a predetermined level and transfer the power amplifier 130 to the power amplifier 130. In addition, the power amplifier 130 may drive the driving amplifier 120. Amplifies the RF transmission signal received from the maximum) or the level required by the RFID reader.

In this case, the driving amplifier 120 may amplify the RF transmission signal according to a control signal received from the control means 340 of the transmission power control system 300. That is, the control means 340 of the transmission power control system 300 may control the transmission power of the RFID reader by adjusting the gain of the driving amplifier 120 and the output of the driving amplifier 120.

In addition, the circulator 140 performs a function of branching or combining the RF transmission signal to be transmitted by the transmitter 110. That is, the circulator 140 transmits the RF transmission signal from the transmitting end 110 to the antenna 150 (from the first port 141 to the second port 142). In addition, the circulator 140 performs a function of applying the RF received signal received through the antenna 150 to the receiving end 160 (port 2 142 to port 3 143).

In addition, the antenna 150 transmits an RF transmission signal generated by the transmitter 110 to an RFID tag. In addition, the antenna 150 performs a function of receiving an RF received signal including tag information in response to the transmitted RF transmission signal from the RFID tag.

In one embodiment of the present invention, the transmission power control system 300 is a leakage signal of the RF transmission signal flowing into the receiver 160 through the port 143 of the circulator 140 and the RF received from the RFID tag. By controlling the gain of the driving amplifier 120 and the output of the driving amplifier 120, the transmission power of the RFID reader is controlled by controlling the gain of the driving amplifier 120 and the output of the driving amplifier 120 so that the signal strength measured by partially branching the combined signal of the received signal is maintained within the predetermined limit intensity. Function can be performed.

The transmission power control system 300 includes a combiner 310, a power detector 320, an analog-to-digital converter (ADC) 330, and a control means (Ctrl) 340. Can be.

The combiner 310 performs a function of branching a leakage signal of the RF transmission signal transmitted to the RFID tag and a part of the combined signal of the RF reception signal from the RFID tag in response to the RF transmission signal according to a provided condition. .

That is, the RF transmission signal is transmitted from the transmitter 110 and flows into the receiver 160 through the port 143 of the circulator 140 through the driving amplifier 120 and the power amplifier 130 or the circulator. When the RF transmission signal transmitted to the antenna 150 through the second port 142 of the 140 is reflected and introduced into the receiving end 160 through the third port 143 of the circulator 140, the combiner ( 310 is a condition for providing a combined signal of the leakage signal of the RF transmission signal flowing into the receiver 160 through the port 143 of the circulator 140 and the RF reception signal received from the RFID tag. For example, 30% may be branched to the power detection means 320.

The power detecting unit 320 serves to detect a leakage signal of the RF transmission signal transmitted to the RFID tag. In addition, the power detecting means 320 performs a function of measuring the signal strength at the receiving end 160 in the RFID reader for introducing the leakage signal and the RF received signal.

That is, when the leakage signal of the RF transmission signal flowing into the receiving end 160 and a part of the combined signal of the RF received signal received from the RFID tag are received by branching, the power detecting means 320 may perform the branched combined signal. The power of the branched combined signal can be measured by measuring the amount of the signal and converting the measured amount into a voltage, through which the power detecting means 320 can predict and calculate the signal strength at the receiving end 160. Will be.

In this case, the power of the branched combined signal measured and converted by the power detection unit 320 is an analog signal, and may be converted into a digital signal through the analog-to-digital converter 330.

Further, as described above, the power detecting means independently measures the signal strength of the leakage signal or the strength of the RF received signal, as well as the branched signal strength of the combined signal (the signal in which the leakage signal and the RF received signal are combined). It may be.

The control means 340 controls the transmission of the RF transmission signal to the RFID tag in consideration of the measured signal strength.

That is, the control means 340 adjusts the strength of the RF transmission signal so that the measured signal strength is maintained within a predetermined limit intensity, and the control amplifier 340 adjusts the strength of the adjusted RF transmission signal by the drive amplifier 120 in the RFID reader. Control to send to the RFID tag.

The threshold strength may be an average or maximum signal strength of an RF received signal received from an RFID tag, and the threshold strength may be set to include a strength of a leakage signal in a range that has little influence on the restoration of the RF received signal. Can be.

For example, when the leakage signal of the RF transmission signal flowing into the receiving end 160 and a part of the combined signal of the RF reception signal received from the RFID tag are branched according to the provided condition, the control means 340 is the branched coupling Adjust the strength of the RF transmission signal transmitted to the RFID tag so that the strength of the signal is within a predetermined limit intensity, and the RF tuned signal is adjusted by the drive amplifier 120 in the RFID reader to the RFID tag Can be controlled to send.

That is, when the strength of the branched combined signal is greater than or equal to the predetermined limit strength, the control means 340 may determine that the strength of the leakage signal in the branched combined signal exceeds the limit. In this case, since the leakage signal is generated when the RF transmission signal is transmitted to the RFID tag, the strength of the leakage signal may be regarded as being proportional to the strength (ie, transmission power) of the RF transmission signal transmitted to the RFID tag. Accordingly, the control means 340 adjusts the strength of the RF transmission signal transmitted to the RFID tag and controls the drive amplifier 120 to transmit the adjusted RF transmission signal to the RFID tag, thereby generating the strength of the leakage signal. May be reduced so that the strength of the branched combined signal is maintained within a predetermined limit strength.

For example, when the strength of the branched combined signal is greater than or equal to a predetermined threshold intensity, the control means 340 measures and records the strength of the RF transmission signal amplified by the driving amplifier 120, and then directly When transmitting the RF transmission signal to the RFID tag, the strength of the RF transmission signal to be amplified by the driving amplifier 120 may be set to be less than or equal to the strength of the recorded RF transmission signal, and drive a control signal associated with the amplification strength of the set RF transmission signal. By transmitting to the amplifier 120, the driving amplifier 120 may be controlled to amplify the RF transmission signal by the set intensity to be sent to the RFID tag.

Therefore, according to the present invention, the strength of the combined signal of the leakage signal and the RF reception signal for the RF transmission signal flowing into the receiver 160 is measured and the gain (output) of the driving amplifier 120 is controlled according to the intensity. Thus, the saturation of the receiver 160 due to the leakage signal of the RF transmission signal and the waveform distortion of the RF reception signal can be prevented, the reception sensitivity of the RFID reader can be improved, and the difficulty of restoring the RF reception signal due to the noise of the leakage signal can be solved. .

In addition, according to another embodiment of the present invention, the transmission power control system 300 receives a leakage signal of an RF transmission signal flowing into the receiving terminal 160 through the port 143 of the circulator 140 and an RFID tag. The gain of the driving amplifier 120 and the output of the driving amplifier 120 such that the signal strength measured by partially branching a leakage signal that does not include tag information among the combined signals of the received RF received signals is maintained within a predetermined limit strength. By adjusting the, it is possible to perform a function of controlling the transmission power of the RFID reader.

The combiner 310 receives tag information among the leakage signal of the RF transmission signal flowing into the receiver 160 through the port 143 of the circulator 140 and the combined signal of the RF reception signal received from the RFID tag. Branches a leak signal that does not contain.

The tag information is various information input in advance regarding an object or an animal to which an RFID tag is attached, and the RFID reader identifies a unique information of the RFID tag included in the tag information by using a radio frequency to which the RFID tag is attached. Recognize and manage things or animals.

Since the tag information is included in the RF reception signal received in response to the RF transmission signal transmitted to the RFID tag and received by the RFID reader, the combiner 310 distinguishes the leakage signal from the RF reception signal by determining whether the tag information is present. It is possible to branch only the leakage signal.

The power detecting unit 320 measures the strength of the leakage signal of the RF transmission signal transmitted to the RFID tag.

That is, the leakage signal is branched among the leakage signal of the RF transmission signal flowing into the receiver 160 through the port 143 of the circulator 140 and the combined signal of the RF reception signal received from the RFID tag. When received, the power detecting means 320 measures the amount of the leakage signal, and converts the measured amount into a voltage to measure the power of the leakage signal, through which the power detecting means 320 is the receiving end ( The signal strength at 160 can be predicted and calculated.

In this case, the power of the leakage signal measured and converted by the power detection unit 320 is an analog signal, and may be converted into a digital signal through the analog-to-digital converter 330.

The control means 340 controls the transmission of the RF transmission signal to the RFID tag in consideration of the measured strength of the leaked signal.

That is, the control means 340 adjusts the strength of the RF transmission signal so that the strength of the measured leakage signal is maintained within a predetermined threshold intensity, and the RF adjusted by the drive amplifier 120 in the RFID reader. The transmission signal may be controlled to be transmitted to the RFID tag.

The threshold strength may be set to a strength of the leakage signal within a range that has little effect on the restoration of the RF reception signal, a waveform, or a reception sensitivity set to detect the RF reception signal of the receiver 160.

For example, the leakage signal is branched among the leakage signal of the RF transmission signal flowing into the receiver 160 through the port 143 of the circulator 140 and the RF signal received from the RFID tag. Then, the control means 340 adjusts the strength of the RF transmission signal transmitted to the RFID tag, so that the strength of the branched leakage signal is maintained within a predetermined limit strength, and in the drive amplifier 120 in the RFID reader The RF signal may be controlled to be transmitted to the RFID tag.

That is, when the strength of the branched leak signal is greater than or equal to the predetermined threshold strength, the control means 340 makes it difficult to restore the distortion of the branched leakage signal by distorting the waveform of the RF received signal, and the receiving end 160 It can be determined that saturation is difficult to determine the RF received signal. Since the leakage signal is generated when the RF transmission signal is transmitted to the RFID tag, the strength of the leakage signal may be regarded as being proportional to the strength (ie, transmission power) of the RF transmission signal transmitted to the RFID tag. Accordingly, the control means 340 adjusts the strength of the RF transmission signal transmitted to the RFID tag and controls the driving amplifier 120 to transmit the adjusted RF transmission signal to the RFID tag, thereby generating the strength of the leakage signal. It can be reduced so that the strength of the branched leakage signal is maintained within a predetermined limit strength.

For example, when the strength of the branched leakage signal is greater than or equal to a predetermined threshold intensity, the control means 340 measures and records the intensity of the RF transmission signal amplified by the driving amplifier 120, and then directly When transmitting the RF transmission signal to the RFID tag, the strength of the RF transmission signal to be amplified by the driving amplifier 120 may be set to be less than or equal to the strength of the recorded RF transmission signal, and drive a control signal associated with the amplification strength of the set RF transmission signal. By transmitting to the amplifier 120, the driving amplifier 120 may be controlled to amplify the RF transmission signal by the set intensity to be sent to the RFID tag.

Therefore, according to the present invention, the RF transmission signal to be transmitted to the RFID tag by measuring the strength of the leakage signal flowed into the receiving end of some RFID reader by controlling the gain (output) of the driving amplifier according to the intensity, RF transmission It is possible to prevent the saturation of the receiver due to the signal leakage signal and the waveform distortion of the RF reception signal, to improve the reception sensitivity of the RFID reader, and to solve the difficulty of restoring the RF reception signal due to the noise of the leakage signal.

The transmission power control system 300 may be included in the RFID reader as shown in FIG. 2 or may perform transmission power control of the RFID reader outside of the RFID reader.

As an actual implementation example of the RFID reader system of the present invention, the RFID reader system may be implemented in a chip form.

3 is a flowchart illustrating a transmission power control method in an RFID reader according to an embodiment of the present invention.

The transmission power control method in the RFID reader may be implemented by the transmission power control system in the RFID reader of the present invention. In addition, in the following description of FIG. 3, FIG. 3 will be described with reference to FIG. 2.

In step S310, the transmission power control system determines whether the RF transmission signal is transmitted to the RFID tag, and when the RF transmission signal is transmitted to the RFID tag, in step S320, the transmission power control system combines the leakage signal and the RF reception signal. Branch off part of the signal.

The combiner 310 branches the leakage signal of the RF transmission signal sent to the RFID tag and a part of the combined signal of the RF reception signal from the RFID tag in response to the RF transmission signal according to the provided condition.

That is, the RF transmission signal is transmitted from the transmitter 110 and flows into the receiver 160 through the port 143 of the circulator 140 through the driving amplifier 120 and the power amplifier 130 or the circulator. When the RF transmission signal transmitted to the antenna 150 through the second port 142 of the 140 is reflected and introduced to the receiving end 160 through the third port 143 of the circulator 140, the combiner ( 310 is a condition for providing a combined signal of the leakage signal of the RF transmission signal flowing into the receiver 160 through the port 143 of the circulator 140 and the RF reception signal received from the RFID tag. For example, 30% may be branched to the power detection means 320.

In operation S330, the transmission power control system measures the strength of the branched combined signal.

The power detecting unit 320 measures the leakage signal of the RF transmission signal transmitted to the RFID tag and the signal strength at the receiving end 160 in the RFID reader that receives the RF reception signal from the RFID tag in response to the RF transmission signal. Measure

That is, when the leakage signal of the RF transmission signal flowing into the receiving end 160 and a part of the combined signal of the RF received signal received from the RFID tag are received by branching, the power detecting means 320 may perform the branched combined signal. The power of the branched combined signal can be measured by measuring the amount of the signal and converting the measured amount into a voltage, through which the power detecting means 320 can predict and calculate the signal strength at the receiving end 160. Will be.

In this case, the power of the branched combined signal measured and converted by the power detection unit 320 is an analog signal, and may be converted into a digital signal through the analog-to-digital converter 330.

In step S340, the transmission power control system determines whether the strength of the branched combined signal is greater than or equal to the predetermined threshold strength, and if the strength of the branched combined signal is greater than or equal to the predetermined threshold strength, the transmission power control system performs RF in steps S350 to S360. The intensity of the transmission signal is adjusted so that the driving amplifier transmits the intensity-adjusted RF transmission signal.

The control means 340 controls the transmission of the RF transmission signal to the RFID tag in consideration of the measured signal strength.

That is, the control means 340 adjusts the strength of the RF transmission signal so that the measured signal strength is maintained within a predetermined limit intensity, and the control amplifier 340 adjusts the strength of the adjusted RF transmission signal by the drive amplifier 120 in the RFID reader. Control to send to the RFID tag.

The threshold strength may be an average or maximum signal strength of an RF received signal received from an RFID tag, and the threshold strength may be set to include a strength of a leakage signal in a range that has little influence on the restoration of the RF received signal. Can be.

When the leakage signal of the RF transmission signal flowing into the receiving end 160 and a part of the combined signal of the RF reception signal received from the RFID tag are branched according to the provided condition (ratio), the control means 340 combines the branched coupling. Adjust the strength of the RF transmission signal transmitted to the RFID tag so that the strength of the signal is within a predetermined limit intensity, and the RF tuned signal is adjusted by the drive amplifier 120 in the RFID reader to the RFID tag Can be controlled to send.

That is, when the strength of the branched combined signal is greater than or equal to the predetermined limit strength, the control means 340 may determine that the strength of the leakage signal in the branched combined signal exceeds the limit. In this case, since the leakage signal is generated when the RF transmission signal is transmitted to the RFID tag, the strength of the leakage signal may be regarded as being proportional to the strength (ie, transmission power) of the RF transmission signal transmitted to the RFID tag. Accordingly, the control means 340 adjusts the strength of the RF transmission signal transmitted to the RFID tag and controls the driving amplifier 120 to transmit the adjusted RF transmission signal to the RFID tag, thereby generating the strength of the leakage signal. May be reduced so that the strength of the branched combined signal is maintained within a predetermined limit strength.

For example, when the strength of the branched combined signal is greater than or equal to a predetermined threshold intensity, the control means 340 measures and records the strength of the RF transmission signal amplified by the driving amplifier 120, and then directly When transmitting the RF transmission signal to the RFID tag, the strength of the RF transmission signal to be amplified by the driving amplifier 120 may be set to be less than or equal to the strength of the recorded RF transmission signal, and drive a control signal associated with the amplification strength of the set RF transmission signal. By transmitting to the amplifier 120, the driving amplifier 120 may be controlled to amplify the RF transmission signal by the set intensity to be sent to the RFID tag.

Therefore, according to the present invention, the strength of the combined signal of the leakage signal and the RF reception signal for the RF transmission signal flowing into the receiver 160 is measured and the gain (output) of the driving amplifier 120 is controlled according to the intensity. This prevents the saturation of the receiver 160 caused by the leakage signal of the RF transmission signal and the waveform distortion of the RF reception signal, the reception sensitivity of the RFID reader, and the difficulty of restoring the RF reception signal due to the noise of the leakage signal. do.

4 is a flowchart illustrating a transmission power control method in an RFID reader according to another embodiment of the present invention.

The transmission power control method in the RFID reader may be implemented by the transmission power control system in the RFID reader of the present invention. In addition, in the following description of FIG. 4, FIG. 4 will be described with reference to FIG. 2.

In step S410, the transmission power control system determines whether an RF transmission signal is transmitted to the RFID tag. When the RF transmission signal is transmitted to the RFID tag, in step S420, the transmission power control system analyzes the transmitted RF transmission signal. Detect a leakage signal for the RF transmission signal. In addition, in step S420, the transmission power control system branches the detected leak signal, that is, a leak signal that does not include tag information.

The combiner 310 receives tag information among the leakage signal of the RF transmission signal flowing into the receiver 160 through the port 143 of the circulator 140 and the combined signal of the RF reception signal received from the RFID tag. Branch leakage signal not included.

The tag information is various information input in advance regarding an object or an animal to which an RFID tag is attached, and the RFID reader identifies a unique information of the RFID tag included in the tag information by using a radio frequency to which the RFID tag is attached. Recognize and manage things or animals.

Since the tag information is included in the RF reception signal received in response to the RF transmission signal transmitted to the RFID tag and received by the RFID reader, the combiner 310 distinguishes the leakage signal from the RF reception signal by determining whether the tag information is present. It is possible to branch only the leakage signal.

In step S430, the transmission power control system measures the strength of the branched leakage signal.

The power detecting means 320 measures the strength of the leakage signal of the RF transmission signal transmitted to the RFID tag.

That is, the leakage signal is branched among the leakage signal of the RF transmission signal flowing into the receiver 160 through the port 143 of the circulator 140 and the combined signal of the RF reception signal received from the RFID tag. When received, the power detecting means 320 measures the amount of the leakage signal, and converts the measured amount into a voltage to measure the power of the leakage signal, through which the power detecting means 320 receives the receiving end ( The signal strength at 160 can be predicted and calculated.

In this case, the power of the leakage signal measured and converted by the power detection unit 320 is an analog signal, and may be converted into a digital signal through the analog-to-digital converter 330.

In step S440, the transmission power control system determines whether the strength of the branched leak signal is greater than or equal to the predetermined threshold strength, and if the strength of the branched leak signal is greater than or equal to the predetermined threshold strength, the transmission power control system performs RF in steps S450 to S460. By adjusting the strength of the transmission signal, the driving amplifier controls the intensity adjusted RF transmission signal.

The control means 340 controls the transmission of the RF transmission signal to the RFID tag in consideration of the measured strength of the leaked signal.

That is, the control means 340 adjusts the strength of the RF transmission signal so that the strength of the measured leakage signal is maintained within a predetermined threshold intensity, and the RF adjusted by the drive amplifier 120 in the RFID reader. The transmission signal may be controlled to be transmitted to the RFID tag.

The threshold strength may be set to a strength of the leakage signal within a range that has little effect on the restoration of the RF reception signal, a waveform, or a reception sensitivity set to detect the RF reception signal of the receiver 160.

If the leakage signal is branched among the leakage signal of the RF transmission signal flowing into the receiver 160 through the port 143 of the circulator 140 and the RF reception signal received from the RFID tag, the leakage signal is controlled. The means 340 adjusts the strength of the RF transmission signal sent to the RFID tag so that the strength of the branched leakage signal is maintained within a predetermined limit strength, and the intensity adjustment in the drive amplifier 120 in the RFID reader The RF transmission signal may be controlled to be transmitted to the RFID tag.

That is, when the strength of the branched leak signal is greater than or equal to the predetermined threshold strength, the control means 340 makes it difficult to restore the distortion of the branched leakage signal by distorting the waveform of the RF received signal, and the receiving end 160 It can be determined that saturation makes the determination of the RF reception signal difficult. Since the leakage signal is generated when the RF transmission signal is transmitted to the RFID tag, the strength of the leakage signal may be regarded as being proportional to the strength (ie, transmission power) of the RF transmission signal transmitted to the RFID tag. Accordingly, the control means 340 adjusts the strength of the RF transmission signal transmitted to the RFID tag and controls the driving amplifier 120 to transmit the adjusted RF transmission signal to the RFID tag, thereby generating the strength of the leakage signal. It can be reduced so that the strength of the branched leakage signal is maintained within a predetermined limit strength.

For example, when the strength of the branched leakage signal is greater than or equal to a predetermined threshold intensity, the control means 340 measures and records the intensity of the RF transmission signal amplified by the driving amplifier 120, and then directly When transmitting the RF transmission signal to the RFID tag, the strength of the RF transmission signal to be amplified by the driving amplifier 120 may be set to be less than or equal to the strength of the recorded RF transmission signal, and drive a control signal associated with the amplification strength of the set RF transmission signal. By transmitting to the amplifier 120, the driving amplifier 120 may be controlled to amplify the RF transmission signal by the set intensity to be sent to the RFID tag.

Therefore, according to the present invention, the RF transmission signal to be transmitted to the RFID tag by measuring the strength of the leakage signal flowed into the receiving end of some RFID reader by controlling the gain (output) of the driving amplifier according to the intensity, RF transmission It is possible to prevent the saturation of the receiver due to the leakage signal of the signal and the waveform distortion of the RF reception signal, to improve the reception sensitivity of the RFID reader, and to solve the difficulty of restoring the RF reception signal due to the noise of the leakage signal.

While specific embodiments of the present invention have been described so far, various modifications are possible without departing from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by those equivalent to the scope of the claims.

1 is a diagram illustrating a configuration of an RFID reader.

2 is a diagram illustrating a configuration of an RFID reader including a transmission power control system according to an embodiment of the present invention.

3 is a flowchart illustrating a transmission power control method in an RFID reader according to an embodiment of the present invention.

4 is a flowchart illustrating a transmission power control method in an RFID reader according to another embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

110: transmitting end

120: Drive Amplifier (DA)

130: power amplifier (PA)

140: circulator 150: antenna (ANT)

160: receiver 170: baseband signal processing unit

300: transmission power control system 310: Coupler

320: power detector (Power Detector)

330: analog-to-digital converter (ADC)

340: control means (Ctrl)

Claims (6)

Power detection means for detecting a leakage signal of the RF transmission signal transmitted to the RFID tag; An antenna of the RFID reader for receiving an RF reception signal from the RFID tag in response to the RF transmission signal; A combiner for branching a combined signal of the detected leakage signal and the received RF received signal; And Control means for controlling the intensity of the RF transmission signal to be transmitted to the RFID tag so that the strength of the branched combined signal measured by the power detection means is less than a threshold intensity Transmission power control system comprising a. The method of claim 1, The power detection means, And measuring the strength of the leakage signal or the strength of the RF received signal. delete delete Analyzing the RF transmission signal transmitted to the RFID tag and detecting a leakage signal for the RF transmission signal; Receiving an RF received signal from the RFID tag in response to the RF transmitted signal; Branching the combined signal of the detected leakage signal and the received RF received signal; Measuring the strength of the branched combined signal; And Controlling the intensity of the RF transmission signal to be transmitted to the RFID tag such that the measured strength of the combined signal is less than a threshold intensity; Transmission power control method comprising a. The method of claim 5, Measuring the strength of the leakage signal or the strength of the RF received signal Transmission power control method further comprises.

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