KR100848351B1 - RFID device and method for controlling amplitude of output signal - Google Patents

Abstract

An RFID device capable of adjusting the magnitude of an output signal is disclosed. The RFID device includes an RFID connector connected with a host connector for a data interface; Microprocessor; A transmission block for receiving a first data signal, converting the first data signal into a second data signal having a predetermined voltage level in response to the first control signal; And a reception block for receiving tag information generated in response to the second data signal, wherein the microprocessor outputs the first control signal based on an output signal adjustment command and receives the first data signal. The signal is output to the transmission block through predetermined signal processing. The microprocessor includes a pulse width modulation (PWM) control circuit for converting a duty cycle of the first control signal based on an output signal adjustment command.

RFID, electronic tag

Description

RFID device and method for controlling amplitude of output signal

BRIEF DESCRIPTION OF THE DRAWINGS In order to better understand the drawings cited in the detailed description of the invention, a brief description of each drawing is provided.

1 is a block diagram of a general RFID system.

2 is a block diagram illustrating an RFID device according to an embodiment of the present invention.

3 shows a block diagram of a circuit for converting an output signal magnitude of an RFID device using a PWM control circuit.

4 is a flowchart illustrating a method of controlling the magnitude of an output signal according to an embodiment of the present invention.

The present invention relates to an RFID recognition device, and more particularly to an RFID device that can adjust the size of the output signal.

Radio Frequency Identification (RFID), or radio frequency identification technology, was developed in the mid-20th century and used in inventory management and supply chain management in the late 1990s. RFID refers to a method of identifying an individual product using frequency.

1 is a configuration diagram of a general RFID system 10. Referring to FIG. 1, the RFID system 10 includes a tag 100, an RFID device 200, and a host 300.

The tag 10 is attached to a product to store predetermined data. The RFID device 200 is connected to the host 300 (eg, a personal digital assistant (PDA) or a mobile phone, etc.) to perform data communication, and identifies the tag 10 using a radio frequency communication method.

The RFID device 200 may include a microprocessor in which a universal asynchronous receiver / transmitter (UART) is embedded to communicate data with the host 300.

In the RFID device 200 identifying the tag 100, the magnitude of the data signal output from the RFID device 200 is proportional to the distance at which the tag can be identified. That is, when the size of the data signal is large, a farther away tag can be recognized.

However, when the size of the data signal increases, the power consumption of the RFID device 200 increases.

Accordingly, there is a need for an RFID device 200 that can reduce power consumption by selectively varying the size of a data signal output from the RFID device 200 according to the distance between the RFID device 200 and the tag 100. .

Accordingly, a technical object of the present invention is to provide an RFID device capable of selectively varying the size of a data signal according to the distance between the RFID device and a tag, thereby providing a method of reducing power consumption in the RFID device. It is.

According to the present invention, an RFID device includes: an RFID connector connected to a host connector for a data interface; Microprocessor; A transmission block for receiving a first data signal, converting the first data signal into a second data signal having a predetermined voltage level in response to the first control signal; And a reception block for receiving tag information generated in response to the second data signal, wherein the microprocessor outputs the first control signal based on an output signal adjustment command and receives the first data signal. The signal is output to the transmission block through predetermined signal processing.

The microprocessor includes a pulse width modulation (PWM) control circuit for converting a duty cycle of the first control signal based on an output signal adjustment command.

The transmission block includes an LPF for receiving and filtering the first data signal; A modulation circuit for receiving the filtered first data and modulating and outputting the filtered first data signal in response to a local oscillation frequency; A filter circuit which receives the first control signal, converts it into an analog signal, and outputs a second control signal; And a power amplifier circuit for receiving the modulated first data signal, converting the signal to a predetermined voltage level in response to the second control signal, and outputting the second data signal.

The filter circuit is an R-C filter circuit. The first control signal is a digital signal having a predetermined duty cycle.

According to an aspect of the present invention, there is provided a method for adjusting an output signal size of an RRFID device, the method including: receiving an output signal adjustment command input from a host; Outputting a first control signal in response to the output signal adjustment command; Receiving the first control signal, converting the received first control signal into an analog signal, and outputting a second control signal; And receiving the modulated first data signal, converting the signal to a predetermined voltage level in response to the second control signal, and outputting a second data signal. The first control signal is a digital signal having a predetermined duty cycle.

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings which illustrate preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings denote like reference numerals.

2 shows a block diagram of an RFID device according to an embodiment of the present invention. 2, the radio frequency identification (RFID) device 300 includes an RFID connector 310, a power supply block 320, a microprocessor 330, a frequency synthesis circuit 340, a transmission block 350, And a reception block 360 and an antenna 370.

The RFID connector 310 receives data and an output signal control command (CMD) input from a host (for example, a PDA or a mobile phone) and outputs the command to the microprocessor 330.

The output signal adjustment command CMD is a signal for converting the magnitude (or level) of an output signal of the RFID device (that is, a data signal output to recognize tag information).

The host may generate an output signal adjustment command CMD according to a preset condition or at the request of a user. To this end, the host may provide a menu for the user to adjust the output signal of the RFID device 300.

The power supply block 320 includes a battery 321 and a power supply control unit 322. When the RFID device 300 is powered on, the microprocessor 330, the frequency synthesis block 340, and the transmission block are provided. And supplies power to circuits such as 350 and receive block 360.

The microprocessor 330 performs data communication with the host (eg, PDA or mobile phone) through the RFID connector 310 and performs predetermined signal processing on the data and output signal conversion command (CMD) input from the host. To print.

In this case, a communication protocol using a universal asynchronous receiver / transmitter (UART) is used as the communication protocol between the microprocessor 330 and the host, and the microprocessor 330 includes a UART control circuit (not shown) for data communication. To control.

The microprocessor 330 includes a pulse width modulation (PWM) control circuit 331. The PWM control circuit unit 331 receives an output signal adjustment command CMD input from the host, and in response to the received output signal adjustment command CMD, the duty cycle of the output signal of the PWM control circuit 331. The duty cycle is converted to output the first control signal S _D.

The frequency synthesizing circuit 340 generates and outputs a local oscillation frequency LO based on the frequency control signal S _f output from the microprocessor 330. The frequency synthesizing circuit 340 may be implemented using a phase locked loop (PLL) circuit.

The transmission block 350 includes a low pass filter (LPF) 351, a modulation circuit 352, a filter circuit 353, and a power amplification circuit 354. The LPF 351 receives and filters the first data signal S ₀ output from the microprocessor 330.

The modulation circuit 352 receives the filtered first data S ₁ and receives the filtered first received in response to the local oscillation frequency LO output from the frequency synthesizing circuit 340 (eg, PLL). The data signal S ₁ is modulated and output as the second data signal S ₂ .

The filter circuit 353 receives the first control signal S _D output from the PWM control circuit 331, converts the first control signal SD into an analog signal, and outputs the second control signal S _A.

The first control signal S _D is a digital signal having a predetermined duty cycle, and the second control signal S _A is a control signal obtained by converting the first control signal S _D into an analog signal.

The power amplification circuit 354 receives the modulated data signal S ₂ , and in response to the second control signal S _A received through the filter circuit 353, the modulated first data signal S 2. S ₂ ) is converted into a second data signal S ₃ having a predetermined voltage level and output.

The antenna 390 is the second data signal (S ₃₎ receiving and outputting the received second data signal (S ₃₎ with a tag (not shown), and the second data signal (S ₃₎ In response, tag information T ₀ output from a tag (not shown) is received and output to the reception block 360.

The RFID device 300 may further include an isolator 380 to prevent a phenomenon in which the tag information T0 received from the tag is input to the transmission block 350.

The receive block 360 includes a demodulation circuit 361, an amplifying circuit 362, and an ADC 363 (Analog-to-Digital Converter). The demodulation circuit 361 receives the tag information T ₀ input through the antenna, and receives the received tag information T in response to a local oscillation frequency LO output from the frequency synthesizing circuit 340. ₀ ) is demodulated to a predetermined signal and output.

The amplifying circuit 362 amplifies and outputs the demodulated tag information T ₁ to a predetermined voltage level, and the ADC 363 receives the amplified tag information T ₂ and receives the amplified signal. Tag information T ₂ is converted into digitized tag information T ₃ and output to the microprocessor 330.

3 is a block diagram of a circuit for converting an output signal size of an RFID device using a PWM control circuit, and FIG. 4 is a flowchart illustrating a method of controlling an output signal size of an RFID device according to an embodiment of the present invention. .

2 to 4, the PWM control circuit 331 may output a PWM output signal having a predetermined duty cycle in response to the output signal adjustment command CMD input from the host. _D ) is output to the filter circuit 353 (S410, S420). At this time, the first control signal (S _D) is a digital signal.

However, since the power amplification circuit 354 operates in response to the analog signal, it is necessary to convert the output signal of the PWM to an analog signal level.

Therefore, the filter circuit 353 receives the first control signal S _D , which is a digital signal, converts it into a second control signal S _A , which is an analog signal, and outputs the same. In this case, the filter circuit 353 may be implemented as an RC filter circuit.

The power amplifier 354 receives the modulated first data signal S ₂ received through the modulation circuit 352, and the second control signal S _A received through the filter circuit 353. In response to the signal amplitude (or signal level) of the modulated first data signal S ₂ is converted and output as the second data signal S ₃ (S440).

Accordingly, the RFID device 300 according to the present invention uses the PWM control circuit 331 provided in the microprocessor 330 without having a separate digital-to-analog converter (DAC). ) Can be used to selectively adjust the size of the output signal.

Although the invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

As described above, the RFID device according to the present invention may selectively convert the magnitude of the output signal of the RFID device according to the distance from the tag. In addition, since the size of the output signal can be selectively converted, power consumption in the RFID device can be reduced.

Claims (7)

An RFID connector connected with a host connector for a data interface; A microprocessor that outputs the first control signal based on an output signal adjustment command, receives the first data signal, and outputs the first control signal to the transmission block after predetermined signal processing; A transmission block for receiving a first data signal, converting the first data signal into a second data signal having a predetermined voltage level in response to the first control signal; And A reception block for receiving tag information generated in response to the second data signal, The microprocessor, And a pulse width modulation (PWM) control circuit for converting a duty cycle of the first control signal based on the output signal adjustment command. delete The method of claim 1, The transmission block is, LPF for receiving and filtering the first data signal; A modulation circuit for receiving the filtered first data and modulating and outputting the filtered first data signal in response to a local oscillation frequency; A filter circuit converting the first control signal output from the PWM control circuit into an analog signal and outputting the second control signal; And And a power amplifier circuit for receiving the modulated first data signal, converting the modulated first data signal to a predetermined voltage level and outputting the second data signal. The method of claim 3, And the filter circuit is an R-C filter circuit. The method according to claim 1 or 3, The first control signal, RFID device which is a digital signal having a predetermined duty cycle. Receiving an output signal adjustment command input from a host; Outputting a first control signal whose duty cycle is converted in response to the output signal adjustment command; Receiving the first control signal, converting the received first control signal into an analog signal and outputting the second control signal; And And receiving the modulated first data signal, converting the signal to a predetermined voltage level in response to the second control signal, and outputting a second data signal. The method of claim 6, The first control signal, A method for adjusting the output signal size of an RFID device, which is a digital signal having a predetermined duty cycle.

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