KR100894054B1 - Rf reader and detection method for tag thereof - Google Patents

Abstract

An RF reader and a tag detecting method thereof are provide to enable the RF reader to perform a tag detection operation without the control of an MCU(Micro Control Unit). An MCU(200) is operated in a sleep mode during the tag detection operation of an RF reader(100). The first oscillator(400) produces the first oscillation signal. A tag detector(300) enables or disables the first oscillator by a predetermined period, and outputs a tag detection signal according to the first oscillation signal outputted from the enabled first oscillator. A transceiver(500) transmits the tag detection signal to the outside or provides a tag response signal received from the outside to the tag detector. The tag detector comprises the second oscillator, a counter, a switching part and a detection part.

Description

Tag detection method of RF reader and RF reader

An embodiment of the present invention relates to an RF reader, and more particularly, to an RF reader and a tag detection method of the RF reader for performing a tag detection operation for detecting at least one tag located in an RF recognition range.

The RF reader may be configured with an RF reader chip, a transmit / receive chip, and a micro control unit (MCU) capable of controlling the tag, for example, a reading function of an RF tag such as a smart card.

The RF reader may perform a tag detection function in which the MCU compares the voltages of the tag transmit / receive antennas and compares the presence or absence of the RF tag within the RF recognition range.

In the conventional RF reader, since the MCU always operates to compare the presence or absence of the RF tag, the MCU consumes a lot of power.

Accordingly, in the case of an RF reader used in an internal power source such as a small battery, such as a door lock, a locker lock, a toy, etc., the power consumption of the internal power is increased and the RF reader operates normally. A problem arises that can't be done.

An object of the present invention is to provide an RF reader that can reduce power loss.

Another object of the present invention is to provide a tag detection method of the RF reader.

According to an embodiment of the present invention, an RF reader includes a MCU operating in a sleep mode in a tag detection operation, a first oscillator generating a first oscillation signal, and a first oscillator. A tag detector and a tag detection signal are controlled to be enabled or disabled at a predetermined period and output a tag detection signal according to a first oscillation signal output from the enabled first oscillator. And a transmitter / receiver for transmitting a tag response signal to a tag detector or transmitted from the outside.
The tag detector may include a second oscillator generating a second oscillation signal, a counter for counting the second oscillation signal for a predetermined time, a counter for outputting a switching signal according to the counting result, and enabling or disabling the first oscillator according to the switching signal. And a detector configured to output a tag detection signal according to a first oscillation signal output from the switching unit and the enabled first oscillator, and to receive a tag response signal from a transmitter / receiver.
The tag detector provides a tag response signal to the MCU as an interrupt signal, and the MCU is enabled or disabled according to the tag response signal.

According to another aspect of the present invention, there is provided a method of detecting a tag of an RF reader, in which a second oscillator operates to output a second oscillation signal when the MCU is in a sleep mode, and a counter generates a second oscillation signal. Counting the signals at regular intervals, outputting a switching signal according to the counting result, enabling the first oscillator according to the switching signal, outputting the first oscillation signal by the first oscillator, and the tag detector performing the first oscillation signal Outputting the tag detection signal to the outside according to the external terminal, receiving the tag response signal from the outside, and the tag detector provides the tag response signal as the interrupt signal to the MCU, and the MCU is enabled or disabled according to the tag response signal. Steps.

In the RF reader and its tag detection method according to an embodiment of the present invention, the RF reader performs the tag detection operation by itself without the control of the MCU, and operates the MCU only when the tag is detected. ) Can reduce the consumption, and there is an effect that can implement a low-power RFID system. Accordingly, it can be usefully used in door locks, locker locks, toys, etc. in which a small battery is used.

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

1 is a schematic block diagram of an RF reader according to an embodiment of the present invention.

Referring to FIG. 1, the RF reader 100 may include a micro control unit (MCU) 200, a tag detector 300, a first oscillator 400, and a transmitter / receiver 500. . The RF reader 100 may be implemented as a mobile communication terminal such as a mobile phone or a PDA.

The transmitter / receiver 500 communicates with the outside via an antenna and provides a tag detection signal T_D provided from the tag detector 300 to a plurality of tags (not shown) located outside, for example, within an RF recognition range, Alternatively, the tag detector 300 may provide the tag response signal R_S transmitted in response to the tag detection signal T_D from at least one tag among the plurality of tags.

The tag detector 300 performs a tag detection operation for providing a tag detection signal T_D to the transmitter / receiver 500 according to the first oscillation signal OSC1 provided from the first oscillator 400 or transmits from a tag. According to the tagged response signal R_S, a reading operation of reading information from a tag may be performed.

The tag detector 300 may control the first oscillator 400 to be enabled / disabled at a predetermined cycle. The tag detector 300 may output the tag detection signal T_D according to the first oscillation signal OSC1 output from the enabled first oscillator 400. The output tag detection signal T_D may be transmitted to the outside through the transmitter / receiver 500 and perform a tag detection operation of detecting at least one tag among a plurality of tags positioned within an RF recognition range.

In addition, the tag detector 300 may control the MCU 200 to be enabled / disabled according to the tag response signal R_S provided from the transmitter / receiver 500. For example, the MCU 200 may operate in a sleep mode, for example, a sleep mode in which no operation is performed because the operation power is cut off during the tag detection operation of the RF reader 100. At this time, when an external tag is detected according to the tag detection operation of the tag detector 300 described above, that is, the tag response signal R_S is transmitted from the outside, the tag detector 300 generates an MCU according to the tag response signal R_S. A signal capable of operating 200, for example, an interrupt signal I_S, may be output. The MCU 200 may start an operation according to the interrupt signal I_S and may be converted to a reading mode. The MCU 200 in the reading mode may perform a reading operation of reading the information from the detected tag by controlling the tag detector 300, the first oscillator 400, or the transmitter / receiver 500. The above-described operation of the tag detector 300 will be described in detail later with reference to FIGS. 3 and 4.

The MCU 200 may operate in a sleep mode during the tag detection operation of the tag detector 300, and start an operation according to the interrupt signal I_S provided from the tag detector 300 to operate in the reading mode.

The first oscillator 400 may be controlled by the tag detector 300 in a tag detection operation, and may generate a first oscillation signal OSC1 and provide it to the tag detector 300.

FIG. 2 is a schematic block diagram of the tag detector shown in FIG. 1.

Referring to FIG. 2, the tag detector 300 may include a detector 310, a second oscillator 320, a counter 330, and a switching unit 340.

The detector 310 may generate and output tag detection signals T_D1 and T_D2 according to the first oscillation signal OSC1 provided from the first oscillator 400. The detector 310 may include a first detector 311, a second detector 313, and a merge unit 315.

The first detector 311 may output the first detection signal T_D1 according to the first oscillation signal OSC1. The first detector 311 may perform a tag detection operation for comparing the first detection signal T_D1 and the first tag response signal R_S1 transmitted from an external tag according to the first detection signal T_D1. have.

The second detector 313 may output the second detection signal T_D2 according to the first oscillation signal OSC1. The second detector 313 may perform a tag detection operation comparing the second detection signal T_D2 with the second tag response signal R_S2 transmitted from an external tag according to the second detection signal T_D2. have.

The detector 310 may operate at least one of the first detector 311 or the second detector 313 according to the first oscillation signal OSC1, and accordingly, the detector 310 may operate the first detection signal ( Only at least one detection signal among the T_D1 or the second detection signal T_D2 may be output as the tag detection signal TD.

The merge unit 315 is a tag response signal R_S transmitted by an external tag in response to the first detection signal T_D1 or the second detection signal T_D2, for example, the first tag response signal R_S1 or the second. The tag response signal R_S2 may be merged.

The second oscillator 320 may operate according to a control signal CNT provided from the outside, and output the second oscillation signal OSC2. For example, the second oscillator 320 may start operation according to the control signal CNT for the RF reader to start operation in the tag detection mode. The second oscillator 320 may generate and output a second oscillation signal OSC2. Here, the second oscillation signal OSC2 may be a signal having a slower period than the first oscillation signal OSC1 generated from the first oscillator 400, for example, a frequency lower than the first oscillation signal OSC1. Here, the second oscillation signal OSC2 may have a frequency of 100 k to 1 MHz, and the first oscillation signal OSC1 may be approximately 13.56 MHz.

The counter 330 performs an operation of counting the second oscillation signal OSC2 provided from the second oscillator 320. For example, the counter 330 may count the second oscillation signal OSC2 for a predetermined time and output the switching signal CS according to the counting result.

The switching unit 340 may output the enable signal ES or the disable signal DS according to the switching signal CS provided from the counter 330. The enable signal ES or the disable signal DS output from the switching unit 340 may control the operation of the first oscillator 400.

For example, when the switching unit 340 outputs the enable signal ES, the first oscillator 400 may operate according to the enable signal ES to output the first oscillation signal OSC1. The output first oscillation signal OSC1 may be provided to the detector 310, and the detector 310 may output a tag detection signal T_D for detecting an external tag according to the first oscillation signal OSC1. .

In addition, when the switching unit 340 outputs the disable signal DS, the first oscillator 400 may stop the operation according to the disable signal DS. Since the first oscillator 400 does not operate, the first oscillator signal OSC1 is not generated, and thus the detector 310 may not output the tag detection signal T_D.

Meanwhile, the enable signal ES or the disable signal DS output from the switching unit 340 may have a predetermined time interval. In other words, the counter 330 repeatedly counts the second oscillation signal OSC2 for a predetermined time to output the switching signal CS, and the switching unit 340 alternately enables the signal according to the switching signal CS. (ES) and the disable signal DS may be output.

3 is a flowchart illustrating a tag detection operation of the RF reader illustrated in FIG. 1, and FIG. 4 is a waveform diagram of a tag detection operation of the RF reader illustrated in FIG. 1.

1 to 4, in the tag detection operation of the RF reader 100, the MCU 200 may operate in a sleep mode (S10). That is, when the RF reader 100 attempts to perform a tag detection operation for detecting a tag located within an RF recognition range, the MCU 200 enters a sleep mode and does not perform any operation.

When the MCU 200 is in the sleep mode, the second oscillator 320 of the tag detector 300 may perform an operation and generate a second oscillation signal OSC2 (S20). As illustrated in FIG. 4, the second oscillation signal OSC2 may have a slower period, for example, a lower frequency than the first oscillation signal OSC1.

When the second oscillator 320 operates to output the second oscillation signal OSC2, the counter 330 may count this for a predetermined time and output the switching signal CS based on the counting result.

For example, as shown in FIG. 4, the counter 330 counts the second oscillation signal OSC2 during the time t0-t4 of the time axis t, and outputs at least four counting results, for example, the switching signal CS. can do.

For example, the counter 330 may count the second oscillation signal OSC2 during the time t0-t1 of the time axis t, and accordingly, may output the switching signal CS at time t1 of the time axis t. .

The switching unit 340 may output the enable signal ES or the disable signal DS according to the switching signal CS output from the counter 330. An example in which the switching unit 340 outputs the enable signal ES according to the switching signal CS output at the time t1 of t) will be described.

When the enable signal ES is output from the switching unit 340, the first oscillator 400 may operate according to the enable signal ES and generate and output the first oscillation signal OSC1 ( S30).

While the first oscillation signal OSC1 is output from the first oscillator 400, for example, during the time t1-t2 of the time axis t, the second oscillator 320 continues to operate, and accordingly, the counter 330 Can count this for a certain time, for example, time t1-t2 of the time axis t. In addition, the counter 330 may output the switching signal CS according to the counting result at the time t2 of the time axis t, and the switching unit 340 may display the switching signal CS according to the switching signal CS from the counter 330. The enable signal DS may be output.

That is, the counter 330 may output the switching signal CS at regular time intervals while counting the second oscillation signal OSC2, and the switching unit 340 may have a constant time interval output from the counter 330. The enable signal ES or the disable signal DS capable of enabling or disabling the first oscillator 400 may be output according to the switching signal CS.

For example, the switching signal CS output from the counter 330 at time t1 of the time axis t may control the enable signal ES to be output from the switching unit 340. The switching signal CS output from the counter 330 at time t2 may control the disable signal DS to be output from the switching unit 340.

Meanwhile, the first oscillator 400 may start an operation at time t1 of the time axis t by the enable signal ES output from the switching unit 340, and output the first oscillation signal OSC1. The disable signal DS output from the switching unit 340 may stop the operation at time t2 of the time axis t.

When the first oscillator 400 operates to output the first oscillation signal OSC1 (S30), the detector 310 may perform a tag detection operation according to the first oscillation signal OSC1 (S40). For example, the detector 310 may output the tag detection signal T_D during the time t1-t2 of the time axis t according to the first oscillation signal OSC1. The transmitter / receiver 500 may transmit the tag detection signal T_D provided from the detector 310 to a plurality of tags externally located, for example, within an RF recognition range, through an antenna.

After the transmitter / receiver 500 transmits the tag detection signal T_D to the outside, if the tag response signal R_S is not received from the external tag, the tag detector 300 includes the second oscillator 320 described above. The operation may be repeated from operation S20 of generating the second oscillation signal OSC2.

For example, if the tag response signal R_S is not received from the external tag according to the tag detection signal T_D transmitted to the outside during the time t1-t2 of the time axis t, the counter 330 of the tag detector 300 is used. The second oscillation signal OSC2 may be counted again during the time t2-t3 of the time axis t.

The counter 330 may output the counting result, that is, the switching signal CS at the time t3 of the time axis t, and the switching unit 340 may output the enable signal ES according to the switching signal CS. Can be.

The first oscillator 400 may start an operation at time t3 of the time axis t by the enable signal ES output from the switching unit 340 to output the first oscillation signal OSC1 (S30). . In this case, the first oscillator 400 may be in a state in which the operation of the previous switching unit 340 is stopped by the disable signal DS output from the switching unit 340 at the time t2 of the time axis t. .

While the first oscillation signal OSC1 is output from the first oscillator 400, for example, during the time t3-t4 of the time axis t, the second oscillator 320 continues to operate, and accordingly, the counter 330 Can count this for a certain time, for example time t3-t4 of the time axis t. In addition, the counter 330 may output the switching signal CS according to the counting result at the time t4 of the time axis t, and the switching unit 340 may display the switching signal CS according to the switching signal CS from the counter 330. The enable signal DS may be output.

Accordingly, the first oscillator 400 may start the operation at the time t3 of the time axis t by the enable signal ES output from the switching unit 340 to output the first oscillation signal OSC1. The operation may be stopped at a time t4 of the time axis t by the disable signal DS output from the switching unit 340.

When the first oscillator 400 operates to output the first oscillation signal OSC1 (S30), the detector 310 may perform a tag detection operation according to the first oscillation signal OSC1 (S40). For example, the detector 310 may output the tag detection signal T_D during the time t3-t4 of the time axis t according to the first oscillation signal OSC1. The transmitter / receiver 500 may transmit the tag detection signal T_D provided from the detector 310 to a plurality of tags externally located, for example, within an RF recognition range, through an antenna.

Meanwhile, after the transmitter / receiver 500 transmits the tag detection signal T_D to the outside, when the tag response signal R_S is received from the external tag, the tag detector 300 controls the operation of the MCU 200. The interrupt signal I_S can be output (S50).

For example, the tag detection signal T_D is transmitted from the tag detector 310 to the outside through the transmitter / receiver 500 during the time t3-t4 of the time axis t, and in response thereto, the time t3-t4 of the time axis t. If the tag response signal R_S is received from the external tag through the transmitter / receiver 500, the tag detector 300 may output the interrupt signal I_S according to the received tag response signal R_S.

The interrupt signal I_S is provided to the MCU 200, and the MCU 200 receives information from a tag detected in response to the interrupt signal I_S, that is, information from an RF tag transmitting the tag response signal R_S. An operation may be performed (S60).

Accordingly, the tag detection operation of the RF reader 100 may be completed, and the second oscillator 320 and the counter 330 of the tag detector 300 may complete the tag detection operation of the RF reader 100, for example. It may be disabled at time t4 of time axis t.

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

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 schematic block diagram of an RF reader according to an embodiment of the present invention.

FIG. 2 is a schematic block diagram of the tag detector shown in FIG. 1.

3 is a flowchart illustrating a tag detection operation of the RF reader illustrated in FIG. 1.

4 is a waveform diagram illustrating a tag detection operation of the RF reader illustrated in FIG. 1.

Claims (13)

An RF reader for performing a tag detection operation for detecting at least one tag located in the RF recognition range, The MCU operating in a sleep mode in the tag detection operation of the RF reader; A first oscillator for generating a first oscillation signal; A tag detector which controls the first oscillator to be enabled or disabled at a predetermined cycle and outputs a tag detection signal according to the first oscillation signal output from the enabled first oscillator. ); And A transmitter / receiver for transmitting the tag detection signal to the outside or providing a tag response signal received from the outside to the tag detector, The tag detector, A second oscillator for generating a second oscillation signal; A counter for counting the second oscillation signal for a predetermined time and outputting a switching signal according to a counting result; A switching unit for enabling or disabling the first oscillator according to the switching signal; And A detection unit configured to output the tag detection signal according to the first oscillation signal output from the enabled first oscillator, and to receive the tag response signal from the transmitter / receiver, The tag detector provides the tag response signal to the MCU as an interrupt signal, and the MCU is enabled or disabled according to the tag response signal. delete According to claim 1, The period of the second oscillation signal is slower than the first oscillation signal. According to claim 1, The first oscillator signal has a frequency of 13.56MHz, the second oscillator signal has a frequency of 100k ~ 1MHz RF reader. The method of claim 1, wherein the detection unit, A first detector configured to output a first detection signal according to the first oscillation signal; And A second detector configured to output a second detection signal according to the first oscillation signal, And the detector outputs at least one of the first detection signal and the second detection signal as the tag detection signal according to the first oscillation signal. The method of claim 5, The detector further includes a merge unit for merging the tag response signal provided from the outside according to the output of the first detection signal or the second detection signal. According to claim 1, And the MCU converts from the sleep mode to a reading mode in response to the interrupt signal to read information transmitted from the at least one tag. According to claim 1, The second oscillator and the counter are disabled when the tag detection operation of the RF reader is completed. In the tag detection operation of the RF reader for detecting at least one tag located in the RF recognition range, When the MCU is in a sleep mode, operating the second oscillator to output a second oscillation signal; A counter counting the second oscillation signal at regular intervals and outputting a switching signal according to a counting result; Enabling a first oscillator according to the switching signal, wherein the first oscillator outputs a first oscillation signal; A tag detector outputting a tag detection signal to the outside according to the first oscillation signal, and receiving a tag response signal from the outside; And And the tag detector provides the tag response signal to the MCU as an interrupt signal, and the MCU is enabled or disabled according to the tag response signal. The method of claim 9, wherein when the MCU is in the sleep mode, the second oscillator of the tag detector operates to output the second oscillation signal. The method of claim 2, wherein the second oscillator outputs the second oscillation signal having a period slower than that of the first oscillation signal. The method of claim 9, wherein the tag detector outputs a first detection signal or a second detection signal as the tag detection signal. The tag detector outputs a tag detection signal to the outside according to the first oscillation signal, wherein the tag detector outputs at least one of the first detection signal and the second detection signal according to the first oscillation signal. Tag detection operation method of the RF reader to output to the outside as a tag detection signal. The RF reader of claim 9, wherein when the MCU is enabled according to the tag response signal, the MCU is switched from the sleep mode to a reading mode and reads information transmitted from the at least one tag. Tag detection method. The tag detector of claim 9, wherein after the tag detector outputs the tag detection signal to the outside according to the first oscillation signal, the tag response signal is not received from the outside to the tag detector. The method of detecting a tag of the RF reader may further include: outputting a second oscillation signal by operating the second oscillator.

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