KR20180028871A - Near field communication device - Google Patents

Abstract

The present invention relates to a near field communication device. According to the present invention, the near field communication device comprises: an antenna; a transmission amplifier; a matching circuit connected between the antenna and the transmission amplifier; and a transmitter. The transmitter transmits a transmission clock to the matching circuit through the transmission amplifier, extracts an extraction clock from a waveform formed in the matching circuit in response to the transmission clock, stores a phase difference between the transmission clock and the extraction clock and controls transmission of an information signal in accordance with the phase difference through the antenna, the transmission amplifier, and the matching circuit. Therefore, the near field communication device provides improved communication quality.

Description

[0001] NEAR FIELD COMMUNICATION DEVICE [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wireless communication apparatus, and more particularly, to a short range wireless communication apparatus.

Radio Frequency Identification (RFID) refers to a communication method in which a reader located near the reader wirelessly supplies power to the card and communicates with the card wirelessly. Near field communication (NFC) is used as an example of radio frequency identification (RFID). Near field wireless communication (NFC) provides high flexibility in that one communication device can use both the functions of the reader and the functions of the card.

The present invention relates to a method and apparatus for performing near field wireless communication with a center frequency defined in a standard of short range wireless communication (NFC), according to a design process of a short range wireless communication (NFC) NFC) antenna may have different resonance frequencies. If the center frequency and the resonance frequency are different, the communication quality of the short range wireless communication (NFC) apparatus may be degraded.

It is an object of the present invention to provide a short range wireless communication device with improved communication quality.

A short range wireless communication apparatus according to an embodiment of the present invention includes an antenna, a transmission amplifier, a matching circuit, and a transmitter. The transmitter transmits the transmission clock to the matching circuit via the transmission amplifier, extracts the extracted clock from the waveform formed in the matching circuit in response to the transmission clock, stores the phase difference between the transmission clock and the extracted clock, And controls transmission of the information signal through the antenna, the transmission amplifier, and the matching circuit.

A short range wireless communication apparatus according to an embodiment of the present invention includes an antenna, a transmission amplifier, a matching circuit, and a transmitter. The transmitter transmits the transmission clock to the matching circuit through the transmission amplifier, extracts the extracted clock from the waveform formed in the matching circuit in response to the transmission clock, and extracts the resonance frequency of the antenna and matching circuit from the transmission clock and the extraction clock, The difference between the center frequencies of the first and second antennas.

According to the present invention, even if the center frequency and the resonance frequency of the short-range wireless communication apparatus are different, the communication distance is maintained without reduction. Therefore, a short range wireless communication apparatus that provides improved communication quality is provided.

1 shows an example of a short-range wireless communication system.
2 shows an example in which the difference between the center frequency and the resonance frequency affects the communication quality of the short-range wireless communication system.
FIG. 3 shows an example of adjusting the phase to extend the communication distance.
4 shows a short range wireless communication apparatus according to an embodiment of the present invention.
5 shows an example in which the short-range wireless communication apparatus of FIG. 4 performs phase measurement and transmission in the card mode.
6 shows an example of waveforms of a reference clock, a transmission signal, an extracted clock, and a regulated clock when the resonance frequency of the short-range wireless communication apparatus of FIG. 4 coincides with the center frequency of the short-range wireless communication.
FIG. 7 shows examples of waveforms of a reference clock, a transmission signal, an extracted clock, and a regulated clock when the resonance frequency of the short-range wireless communication apparatus of FIG. 4 is the first resonance frequency.
8 shows examples of waveforms of a reference clock, a transmission signal, an extracted clock, and a regulated clock when the resonance frequency of the short-range wireless communication apparatus of FIG. 4 is the second resonance frequency.
9 is a block diagram illustrating an example of the phase control block of FIG.
Fig. 10 shows an example of application of the short-range wireless communication apparatus of Fig.
11 shows an example in which the short-range wireless communication apparatus of Fig. 10 performs phase measurement and transmission in the card mode.
12 shows an application example of the short-range wireless communication apparatus of FIG.
13 is a flowchart illustrating an operation method of a short-range wireless communication apparatus according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail and in detail so that those skilled in the art can easily carry out the present invention.

FIG. 1 shows an example of a Near Field Communication (NFC) system 10. Referring to FIG. 1, a short range wireless communication system 10 includes first and second short range wireless communication (NFC) devices 11, 13. The first short range wireless communication device 11 is connected to the first antenna 12 and the second short range wireless communication device 13 is connected to the second antenna 14. [

Each of the first and second short range wireless communication devices 11 and 13 may operate in a reader mode or a card mode. For example, the first short range wireless communication device 11 may operate in the reader mode and the second short range wireless communication device 13 may operate in the card mode. The first short range wireless communication apparatus 11 in the reader mode may transmit the first signal to the second short range wireless communication apparatus 13 through electromagnetic induction between the first antenna 12 and the second antenna 14. [ The first signal may comprise a continuous wave for delivering power and a first information signal added to the continuous wave for conveying information.

The second short range wireless communication apparatus 13 can acquire the power from the continuous wave of the first signal. The second short range wireless communication device 13 may obtain information from the first information signal of the first signal. The second short range wireless communication apparatus 13 may add a second information signal for transmitting information to the continuous wave of the first signal and may transmit the second information signal to the first short range wireless communication apparatus 11. For example, the second short range wireless communication device 13 may communicate a second signal to the first short range wireless communication device 11 through electromagnetic induction between the second antenna 14 and the first antenna 12 .

By way of example, the center frequency of short-range wireless communications may be determined by the standard of short-range wireless communications and may be 13.56 MHz. The resonance frequency of the first antenna 12 of the first short range wireless communication apparatus 11 can be determined according to the design purpose of the manufacturer of the first short range wireless communication apparatus 11 and according to the design process of the manufacturer. Likewise, the resonance frequency of the second antenna 14 of the second short-range wireless communication device 13 may be determined according to the design purpose of the manufacturer of the second short-range wireless communication device 13 and according to the manufacturer's design process.

The resonant frequencies of the first and second antennas 12 and 14 of the first and second short range wireless communication devices 11 and 13 are determined by the design of the manufacturer or by the errors of the design process of the manufacturers, It may be different from the center frequency of communication. If the resonance frequency and the center frequency are different, the communication quality of the short-range wireless communication system 10 may be degraded.

FIG. 2 shows an example in which the difference between the center frequency and the resonance frequency affects the communication quality of the short-range wireless communication system 10. In Fig. 2, the horizontal axis indicates the resonance frequency (Fres), and the vertical axis indicates the communication distance (D) capable of short-range wireless communication, for example, the maximum communication distance or the average communication distance. The first line L1 shows the change of the communication distance D in accordance with the resonance frequency Fres in the short-range wireless communication system 10.

1 and 2, the communication distance D has a maximum value when the resonance frequency Fres and the center frequency FC coincide with each other. The communication distance D decreases as the resonance frequency Fres becomes higher than the center frequency FC and the communication distance D decreases as the resonance frequency Fres becomes lower than the center frequency FC. That is, when the resonance frequency Fres is different from the center frequency FC, the communication distance D is decreased, and therefore the communication quality of the short-range wireless communication system 10 is deteriorated.

The decrease in the communication distance D is due to the phase delay of the transmitted signal due to the path delay associated with the antenna 12 or 14 when the resonant frequency Fres is different from the center frequency FC , And is delayed or advanced without being aligned at 0 degree. That is, when the phase of the transmission signal is adjusted when the resonance frequency Fres and the center frequency FC are different, the communication distance D can be extended.

FIG. 3 shows an example of adjusting the phase to extend the communication distance D. Referring to Fig. 3, a second line L2 is further shown in addition to Fig. The second line L2 shows the communication distance D when the phase of the transmission signal is adjusted according to the difference between the center frequency FC and the resonance frequency Fres.

Illustratively, when the resonance frequency Fres coincides with the center frequency FC, the transmission signal can be transmitted in the fundamental phase? D. For example, the fundamental phase [theta] d may be 0 degrees or 180 degrees.

When the resonance frequency Fres is lower than the center frequency FC, the phase of the transmission signal can be adjusted according to the first phase adjustment PA1. For example, as the resonance frequency (Fres) decreases, the phase of the transmitted signal can be delayed or increased. For example, when the resonance frequency Fres is lowered to the first resonance frequency Fres1, the phase of the transmission signal can be adjusted to the first phase? 1.

When the resonance frequency Fres becomes higher than the center frequency FC, the phase of the transmission signal can be adjusted according to the second phase adjustment PA2. For example, as the resonance frequency (Fres) decreases, the phase of the transmitted signal can be advanced or reduced. For example, if the resonance frequency Fres2 is increased to the second resonance frequency Fres2, the phase of the transmission signal can be adjusted to the second phase? 2.

When the first phase adjustment (PA1) and the second phase adjustment (PA2) are performed, a Communication Distance Extension (CDE) may occur. It is the first line L1 that the communication distance D is reduced even if the resonance frequency Fres and the center frequency FC are different as shown by the second line L2. ≪ / RTI > Therefore, the communication quality of the short-range wireless communication system 10 is improved.

Based on the features described with reference to Fig. 3, the present invention provides a near field wireless communication device that detects the difference between the resonance frequency Fres and the center frequency FC itself, and controls the phase of the transmission signal according to the detection result to provide. Hereinafter, for the sake of brevity, the technical idea of the present invention will be described with reference to an example of a short-range wireless communication apparatus operating in a card mode. However, the technical idea of the present invention is not limited to the card mode, and can also be applied to the reader mode.

4 shows a short range wireless communication apparatus 100 according to an embodiment of the present invention. Illustratively, the components associated with the transmission function associated with the present invention among the components of the short-range wireless communication device 100 are shown in FIG. 4, a short range wireless communication apparatus 100 includes a transmitter 110, a transmission amplifier 120, a matching circuit 130, and an antenna 140. The short-

Transmitter 110 may operate in a phase detection mode and a transmission mode. In the phase detection mode, the transmitter 110 may transmit the transmit clock CLKt to the transmit amplifier 120. [ The transmitter 110 may extract the extracted clock CLKe from the waveforms formed in the antenna 140 and the matching circuit 130 in response to the transmission clock CLKt. The transmitter 110 may store information on the phase difference between the transmission clock CLKt and the extracted clock CLKe. In the transmission mode, the transmitter 110 can adjust the phase of the transmission signal according to information on a pre-stored phase difference.

The transmitter 110 includes an orbital clock generation block 111, a multiplexer 112, a clock extraction block 113, a comparison and selection block 114, a phase lookup table 115, and a phase control block 116 .

The reference clock generation block 111 may generate the reference clock CLKr. For example, the reference clock CLKr may have a center frequency determined by the standard of the short-range wireless communication. For example, the reference clock CLKr may have a center frequency of 13.56 MHz. The reference clock CLKr is passed to multiplexer 112 and compare and select block 114.

The multiplexer 112 receives the reference clock CLKr from the reference clock generation block 111 and the adjusted clock CLKa from the phase control block 116. [ In the phase measurement mode, the multiplexer 112 can output the reference clock CLKr as the transmission clock CLKt. The transmit clock (CLKt) may be transmitted to the transmit amplifier (120). In the transmit mode, the multiplexer 112 may output the adjusted clock CLKa. The transmission information IF can be added to the adjusted clock CLKa. The adjusted clock CLKa to which the transmission information IF is added can be transmitted to the transmission amplifier 120 as the information detection SIGi.

The clock extraction block 113 may extract the extracted clock CLKe from the waveform formed in the antenna 140 and the matching circuit 130. [ For example, the clock extraction block 113 may output the extracted clock CLKe having the same phase as that of the waveform formed in the antenna 140 and the matching circuit 130. The extracted clock CLKe is transferred to the comparison and selection block 114 and the phase control block 116. [

The comparison and selection block 114 may compare the reference clock CLKr and the extracted clock CLKe in the phase measurement mode. For example, in the phase measurement mode, the multiplexer 112 outputs the reference clock CLKr as the transmission clock CLKt, so that the comparison and selection block 114 selects the transmission clock CLKt and the extracted clock CLKe May be considered as comparing the phases of the signal. The comparison and selection block 114 can detect the phase difference ?? between the reference clock CLKr and the extracted clock CLKe according to the comparison result. The detected phase difference ?? may include information on the difference between the center frequency FC and the resonance frequency formed by the antenna 140 and the matching circuit 130 as shown in FIG.

3 and 4, the decrease in the communication distance D is caused by a path delay occurring when the resonance frequency Fres and the center frequency FC are different from each other. The path delay can be quantified by the phase difference [Delta] [theta] between the reference clock CLKr and the extracted clock CLKe. That is, the difference between the resonance frequency and the center frequency can be quantified by the magnitude and sign of the phase difference [Delta] [theta].

In the phase measurement mode, the comparison and selection block 114 can refer to the phase lookup table 115 to obtain the phase selection information? S corresponding to the phase difference ??. The phase selection information? S includes information on how much the phase of the transmission signal (for example, the information signal SIGi) should be adjusted in the transmission mode.

As described with reference to Fig. 4, the phase value to be adjusted when the resonance frequency Fres is different from the center frequency FC can be quantified. The phase lookup table 115 may store a plurality of phase selection information corresponding to a plurality of phase differences and a plurality of phase differences in the form of a table. The comparison and selection block 114 may refer to the phase lookup table 115 to obtain the phase selection information? S corresponding to the phase difference ??. The phase selection information [theta] s may be transmitted to the phase control block 116. [

In the phase measurement mode, the phase control block 116 may store the phase selection information [theta] s. In the transmission mode, the phase control block 113 may output the adjusted clock CLKa by adjusting the extracted clock CLKe according to the phase selection information [theta] s.

The transmitter 110 has been described as including various blocks. The blocks included in the transmitter 110 may be implemented in hardware such as a semiconductor circuit or an integrated circuit, software driven in an integrated circuit, or a combination of hardware and software.

The transmission amplifier 120 amplifies a signal transmitted from the transmitter 110 and transmits the amplified signal to the matching circuit 130.

The matching circuit 130 may provide impedance matching to the antenna 140. The matching circuit 130 includes an inductor L and first to fourth capacitors C4. The first end of the inductor L is connected to the output of the transmit amplifier 120 and the second end is connected to the first ends of the first and second capacitors C1 and C2. The second end of the first capacitor C1 is connected to the ground electrode to which the ground voltage is supplied. The second end of the second capacitor C2 is connected to the first ends of the third and fourth capacitors C3 and C4 and the antenna 140. [ The second end of the third capacitor C3 is connected to the ground electrode. The second end of the fourth capacitor C4 is connected to the clock extraction block 113 of the transmitter 110. [

FIG. 5 shows an example in which the short-range wireless communication apparatus 100 of FIG. 4 performs phase measurement and transmission in the card mode. 5, the horizontal axis indicates the time T and the vertical axis indicates the service mode SM, the operation sequence SQ, the transmission signal TXS, and the reception signal RXS of the short-range wireless communication apparatus 100.

4 and 5, the service mode SM of the short-range wireless communication apparatus 100 is switched from the OFF state to the ON state at the first time T1. For example, the short-range wireless communication apparatus 100 may be powered on or the short-range wireless communication apparatus 100 may be activated.

After the service mode SM is switched to the ON state, the transmitter 110 may enter the phase measurement mode. In the phase measurement mode, the operation sequence SQ enters the radiation interval RI at the second time T2, and the operation sequence SQ enters the calculation interval CI at the third time T3. In the emission period RI and the calculation period CI, the transmitter 110 can output the reference clock CLKr as the transmission clock CLKt. The transmission clock CLKt forms a waveform in the antenna 140 and the matching circuit 130 and a radio signal corresponding to the formed waveform can be radiated from the antenna 140. [ If the waveform stabilizes during the emission interval RI, the phase difference [Delta] [theta] is calculated during the calculation interval CI, as described with reference to FIG. The transmitter 110 may store the phase selection information [theta] s in the phase control unit 116. [

When the phase measurement mode ends, the transmitter 110 can enter the transmission mode. After the transmitter 110 enters the transmission mode, a signal radiated from an external reader may be received at the antenna 140 at the fourth time T4 as the reception signal RXS. For example, the received signal RXS may be a continuous wave. The received signal RXS is received via a receiver (not shown) and may be used to power the short-range wireless communication device 100.

At a fifth time T5, the received signal RXS may include received information. For example, the received signal RXS may be in the form of receiving information added to a continuous wave. As reception information is received, the operation sequence SQ can enter the reception section RX. During the reception interval RX, the received information may be interpreted at the receiver. When the reception section RX ends, the reception signal RXS can be restored to a continuous wave having no reception information.

At a sixth time T6, the transmitter 110 may perform the transmission to transmit the transmission information in response to the analyzed reception information during the reception interval RX. The phase control block 116 may output the clock extracted from the extracted clock CLKe, for example, the continuous wave of the received signal RXS, in accordance with the phase selection information? S and output it as the adjusted clock CLKa. The information signal SIGi to which the transmission information IF is added to the adjusted clock CLKa can be radiated as the transmission signal TXS through the antenna 140. [

6 shows the relationship between the reference clock CLKr, the transmission signal TXS and the extracted clock CLKe when the resonance frequency Fres of the short-range wireless communication apparatus 100 of FIG. 4 coincides with the center frequency FC of the short- ), And the adjusted clock (CLKa). Referring to FIGS. 3, 4 and 6, when the center frequency FC and the resonance frequency Fres coincide with each other, a phase change due to the path delay does not occur. Therefore, the phase of the waveform of the transmission signal TXS coincides with the phase of the reference clock CLKr. The phase of the extracted clock CLKe extracted from the transmission signal TXS also coincides with the reference clock CLKr. Therefore, the phase difference [Delta] [theta] is 0, and the phase selection information [theta] s for compensating the phase difference [Delta] [theta] indicates no phase adjustment. Thus, the adjusted clock CLKa has the same phase as the extracted clock CLKe. That is, in the transmission mode, the phase control block 116 can output the extracted clock CLKe extracted from the continuous wave of the received signal RXS (see FIG. 5) with the adjusted clock CLKa without phase adjustment.

Fig. 7 is a graph showing the relationship between the reference clock CLKr, the transmission signal TXS, the extracted clock CLKe, and the control signal CLKe when the resonance frequency Fres of the local area wireless communication apparatus 100 of Fig. 4 is the first resonance frequency Fres1. Lt; RTI ID = 0.0 > (CLKa). ≪ / RTI > 3, 4 and 7, when the resonance frequency Fres is the first resonance frequency Fres1, the resonance frequency Fres is smaller than the center frequency FC. Therefore, the phase of the waveform of the transmission signal TXS is delayed relative to the phase of the reference clock CLKr. The phase of the extracted clock CLKe extracted from the transmission signal TXS is also delayed with respect to the reference clock CLKr. Illustratively, the phase of the waveform of the transmission signal TXS and the phase of the extracted clock CLKe may be delayed by 90 degrees from the reference clock CLKr. Therefore, the phase difference [Delta] [theta] is 90 degrees (90 degrees), and the phase selection information [theta] s for compensating the phase difference [theta] indicates a 90 degree decrease (or advancement). Accordingly, the adjusted clock signal CLKa has a phase advanced by 90 degrees with respect to the extracted clock signal CLKe. That is, in the transmission mode, the phase control block 116 can advance the phase of the extracted clock CLKe extracted from the continuous wave of the received signal RXS (see FIG. 5) by 90 degrees and output it as the adjusted clock CLKa .

8 shows a relationship between the reference clock CLKr, the transmission signal TXS, the extracted clock CLKe, and the adjustment frequency Fres2 when the resonance frequency Fres of the short-range wireless communication apparatus 100 of Fig. 4 is the second resonance frequency Fres2. Lt; RTI ID = 0.0 > (CLKa). ≪ / RTI > 3, 4 and 8, when the resonance frequency Fres is the second resonance frequency Fres2, the resonance frequency Fres is larger than the center frequency FC. Therefore, the phase of the waveform of the transmission signal TXS is advanced relative to the phase of the reference clock CLKr. The phase of the extracted clock CLKe extracted from the transmission signal TXS is also advanced with respect to the reference clock CLKr. Illustratively, the phase of the waveform of the transmission signal TXS and the phase of the extraction clock CLKe may be advanced 90 degrees from the reference clock CLKr. Therefore, the phase difference [Delta] [theta] is -90 degrees (-90 degrees), and the phase selection information [theta] s for compensating the phase difference [Delta] [theta] indicates a 90 degree increase (or delay). Therefore, the adjusted clock CLKa has a phase delayed by 90 degrees with respect to the extracted clock CLKe. That is, in the transmission mode, the phase control block 116 can output the extracted clock CLKa by delaying the phase of the extracted clock CLKe extracted from the continuous wave of the received signal RXS (see FIG. 5) by 90 degrees .

FIG. 9 is a block diagram illustrating an example of the phase control block 116 of FIG. 4 and 9, the phase control block 116 includes a phase locked loop 116a, a phase splitter 116b, and a clock selector 116c.

The phase locked loop 116a may output a fixed phase clock CLK1 having the same frequency as the extracted clock CLKe and having the same phase as the extracted clock CLKe in the transmission mode. For example, the phase locked loop 116a may generate a fixed phase clock CLK1 (see FIG. 5) having the same phase as the phase of the continuous wave of the received signal RXS or the received signal RXS before the transmission sequence Can be output. When the fixed phase clock CLK1 is outputted, the phase locked loop 116a can maintain the phase of the fixed phase clock CLK1 even when the phase of the extracted clock CLKe changes. That is, even if the transmission signal TXS and the reception signal RXS are synthesized in the transmission sequence TX to change the phase of the extracted clock CLKe, the phase locked loop 116a can maintain the fixed phase clock CLKl have.

The phase splitter 116b may receive the fixed phase clock CLK1 and output a plurality of clocks CLK1 to CLKn having the same frequency as the fixed phase clock CLK1 and having different phases. For example, the phase splitter 116b may comprise a plurality of delays D connected in series. The delay amount of each of the delay units D may be smaller than 1/4 period of the fixed phase clock CLK1. The fixed phase clock CLK1 may be input to the first delay D. The phase splitter 116b can output the outputs of the phase locked clock CLK1 and the delays D as a plurality of clocks CLK1 to CLKn, respectively.

The clock selector 116c may select one of the plurality of clocks CLK1 to CLKn as the adjusted clock CLKa according to the phase selection information? S.

Illustratively, the phase lock loop 116a may be removed in the phase control block 116. [ When the phase locked loop 116a is removed, the phase splitter 116b may generate a plurality of clocks CLK1 to CLKn from the extracted clock CLKe.

5, the waveforms formed in the antenna 140 and the matching circuit 130 are a combination of the reception signal RXS and the transmission signal TXS, and the waveform of the transmission signal TXS is dominant It can be dominant. Therefore, the extracted clock CLKe can follow the transmission signal TXS. The transmission signal TXS is extracted as the extracted clock CLKe and the extracted clock CLKe is adjusted by the clock selector 116c to be output as the adjusted clock CLKa and the adjusted clock CLKa is outputted as the transmission signal TXS, the clock adjustment by the clock selector 116c may be accumulated every clock cycle. In order to prevent such a phenomenon, the clock selector 116c can dynamically select a plurality of clocks (CLK1 to CLKn). For example, the clock selector 116c may select a clock designated by the clock selection information? S among the clocks CLK1 to CLKn as a start clock, and then select another clock every clock cycle. For example, every clock cycle, the clock selector 116c may select the output of a further later stage retarder or the output of a further leading edge retarder.

10 shows an application example of the short-range wireless communication apparatus 100 of FIG. 10, the short range wireless communication apparatus 200 includes a transmitter 210, a transmission amplifier 220, a matching circuit 230, and an antenna 240.

The transmit amplifier 220, the matching circuit 230 and the antenna 240 are the same as the transmit amplifier 120, the matching circuit 130 and the antenna 140 of FIG. Therefore, detailed description is omitted.

The transmitter 210 includes a phase locked loop 211, a multiplexer 212, a clock extraction clock 213, a compare and select block 214, a phase lookup table 215, and a phase control block 216.

The phase locked loop 211 can output a fixed phase clock CLK1 having the same frequency as the extracted clock CLKe and having the same phase as the extracted clock CLKe in the phase measurement mode.

The multiplexer 212 may transmit the fixed phase clock CLKl in the phase measurement mode to the transmission amplifier 220 as the transmission clock CLKt. The multiplexer 212 may output the adjusted clock (CLKa) in the transmission mode. The transmission information IF may be added to the adjusted clock CLKa and transmitted to the transmission amplifier 212 as the information signal SIGi.

The clock extraction block 213, the comparison and selection block 214, the phase lookup table 215, and the phase lookup table 212, except that the clock extraction block 213 also conveys the extracted clock CLKe to the phase locked loop 211. [ Control block 216 operates identically to clock extraction block 113, comparison and selection block 114, phase lookup table 115, and phase control block 116 of FIG. Therefore, redundant description is omitted.

11 shows an example in which the short-range wireless communication apparatus 200 of FIG. 10 performs phase measurement and transmission in the card mode. 11, the horizontal axis indicates the time T and the vertical axis indicates the service mode SM, the operation sequence SQ, the transmission signal TXS, and the reception signal RXS of the short-range wireless communication apparatus 200. In FIG.

10 and 11, the service mode SM of the short-range wireless communication apparatus 200 is switched from the OFF state to the ON state at the first time T1. For example, the short-range wireless communication device 200 may be powered on or the short-range wireless communication device 200 may be activated.

After the service mode SM is switched to the ON state, a signal radiated from an external reader may be received at the antenna 240 at the fourth time T2 as the received signal RXS. For example, the received signal RXS may be a continuous wave. The received signal RXS is received via a receiver (not shown) and may be used to power the short-range wireless communication device 200.

After the receive signal RXS begins to be received and before the receive sequence RX begins, the transmitter 210 may enter the phase measurement mode. In the phase measurement mode, the operation sequence SQ enters the radiation interval RI at the third time T3 and the operation sequence SQ enters the calculation interval CI at the fourth time T4. The phase locked loop 211 of the transmitter 210 receives the fixed phase clock CLK1 having the same phase as the phase of the continuous wave of the reception signal RXS or the reception signal RXS Can be output. The transmitter 210 can output the fixed phase clock CLK1 as the transmission clock CLKt. The transmission clock CLKt forms a waveform in the antenna 240 and the matching circuit 230 and a radio signal corresponding to the formed waveform can be radiated from the antenna 240. [ If the waveform is stable during the emission interval RI, the phase difference [Delta] [theta] is calculated during the calculation interval CI, as described with reference to Figures 4 and 10. [ The transmitter 210 may store the phase selection information [theta] s in the phase control unit 216. [

At a fifth time T5, the received signal RXS may include received information. For example, the received signal RXS may be in the form of receiving information added to a continuous wave. As reception information is received, the operation sequence SQ can enter the reception section RX. During the reception interval RX, the received information may be interpreted at the receiver. When the reception section RX ends, the reception signal RXS can be restored to a continuous wave having no reception information.

At a sixth time T6, the transmitter 110 may perform the transmission to transmit the transmission information in response to the analyzed reception information during the reception interval RX. The phase control block 216 may output the clock extracted from the extracted clock CLKe, for example, the continuous wave of the received signal RXS, in accordance with the phase selection information? S and output it as the adjusted clock CLKa. The information signal SIGi to which the transmission information IF is added to the adjusted clock CLKa can be radiated as the transmission signal TXS through the antenna 240. [

The short range wireless communication apparatus 100 described with reference to FIGS. 4 and 5 detects the phase selection information? S itself before the short range wireless communication is started using the reference clock generation block 111, And the short range wireless communication apparatus 100 described with reference to FIG. 11 can detect the phase selection information? S using the received signal RXS after the short range wireless communication starts.

FIG. 12 shows an example of application of the short-range wireless communication apparatus 200 of FIG. Referring to FIG. 12, the short range wireless communication apparatus 300 includes a transmitter 310, a transmission amplifier 320, a matching circuit 330, and an antenna 340.

The transmission amplifier 320, the matching circuit 330 and the antenna 340 are the same as the transmission amplifier 120, the matching circuit 130, and the antenna 140 of FIG. Therefore, detailed description is omitted.

The transmitter 310 includes a clock extraction clock 313, a compare and select block 314, a phase lookup table 315, and a phase control block 316. As described with reference to FIG. 9, the phase control block 316 may include a phase locked loop (PLL).

The phase locked loop PLL outputs a fixed phase clock CLKl having the same frequency as the extracted clock CLKe and having the same phase as the extracted clock CLKe in the phase measurement mode as the transmission clock CLKt to the transmission amplifier 320 Can be output. The phase locked loop (PLL) can output the adjusted clock (CLKa) in which the phase of the fixed phase clock (CLK1) is adjusted in accordance with the phase selection information (? S) in the transmission board. The transmission information IF may be added to the adjusted clock signal CLKa and transmitted to the transmission amplifier 320 as the information signal SIGi.

The clock extraction block 313, the comparison and selection block 314, the phase lookup table 315 and the phase control block 216 are identical to the clock extraction block 113, comparison and selection block 114, Table 115, and phase control block 116, respectively. Therefore, redundant description is omitted.

The transmitter 210 of FIG. 10 includes a phase locked loop 211 that generates a fixed phase clock (CLK1) in phase measurement mode. Thus, phase lock loop 116a may or may not be provided in phase control block 216 as described with reference to FIG. On the other hand, the transmitter 310 of FIG. 12 may use the phase locked loop (PLL) of the phase control block 316 in both phase measurement mode and transmission.

13 is a flowchart illustrating an operation method of a short-range wireless communication apparatus according to an embodiment of the present invention. 4, 10, 12, and 13, the transmitter 110, 210, or 310 of the short-range wireless communication apparatus 100, 200, or 300 transmits the basic clock to the transmission clock CLKt in step S110 can do. The basic clock may be a reference clock CLKr generated by the reference clock generator 111 or a fixed phase clock CLKl generated by the phase locked loop 211 or PLL.

In step S120, the transmitter 110, 210, or 310 may extract a clock, for example, an extracted clock CLKe from the transmission signal TXS.

In step S130, the transmitter 110, 210, or 310 may compare the reference clock CLKr or CLKl with the extracted clock CLKe.

In step S140, the transmitter 110, 210, or 310 may store the phase difference information of the reference clock CLKr or CLK1 and the extracted clock CLKe, for example, the phase selection information? S or the phase difference? have.

In step S150, the transmitter 110, 210, or 310 may receive an external signal. For example, the transmitter 110, 210 or 310 may receive a continuous wave from an external short range wireless communication device.

In step S160, the transmitter 110, 210, or 310 may extract the clock from the received external signal.

In step S170, the transmitter 110, 210, or 310 may adjust the phase of the extracted clock CLK according to the phase difference information.

In step S180, the transmitter 110, 210, or 310 may transmit the information signal in synchronization with the adjusted clock signal CLKa.

14 is a block diagram illustrating a mobile device 1000 in accordance with an embodiment of the present invention. 14, a mobile device 1000 includes an application processor 1010, a codec 1020, a speaker 1030, a microphone 1040, a display device 1050, a camera 1060, a modem 1070, Device 1080, a random access memory 1090, and a proximity wireless communication (NFC) device 1100.

The application processor 1010 may operate an operating system that runs the mobile device 1000 and may run various applications on the operating system. The codec 1020 can code and decode a video signal or an image signal. The codec 1020 can perform a task related to the processing of a voice signal or a video signal by delegating it from the application processor 1010. [

The speaker 1030 can play back a voice signal transmitted from the codec 1020. The microphone 1040 detects an external sound, converts the sound into an electrical voice signal, and outputs the voice signal to the codec 1020. The display device 1050 can play back a video signal transmitted from the codec 1020. The camera 1060 can convert a scene in the visual field into an electrical video signal and output the video signal to the codec 1020. [

The modem 1070 can communicate with an external device wirelessly or by wire. The modem 1070 can transmit data to an external device or request data to an external device at the request of the application processor 1010. [ The storage device 1080 may be the primary storage of the mobile device. The storage device 1080 is used to store data for a long time and can retain the stored data even when the power is removed. The random access memory 1090 may be the main memory of the mobile device 1000. The random access memories 1090 can be used by master devices such as the application processor 1010, the modem 1070, the codec 1020, and the like to temporarily store data.

The NFC apparatus 1100 may be the near field communication apparatus 100, 200 or 300 described with reference to FIGS. The NFC apparatus 1100 can operate as a reader or a card. The NFC apparatus 1100 can detect the phase difference and adjust the phase of the transmission clock according to the detected phase difference. Thus, the accuracy of the NFC apparatus 1100 is improved and the reliability of the mobile apparatus 1000 is improved.

The user input interface 1110 may include various devices for receiving input from a user. For example, the user input interface 1110 may be any device that receives input directly from a user, such as a touch panel, a touch screen, a button, a keypad, or the like, or a user action, such as an optical sensor, proximity sensor, gyroscope sensor, Lt; RTI ID = 0.0 > indirectly < / RTI >

The above description is a concrete example for carrying out the present invention. The present invention includes not only the above-described embodiments, but also embodiments that can be simply modified or easily changed. In addition, the present invention includes techniques that can be easily modified by using the above-described embodiments.

10; Short-range wireless communication system
11, 13; Short range wireless communication device
12, 14; antenna
100, 200, 300; Short range wireless communication device
110, 210, 310; transmitter
120, 220, 320; antenna
130, 230, 330; Matching circuit
140, 240, 340; antenna

Claims (10)

antenna;
A transmit amplifier;
A matching circuit coupled between the antenna and the transmit amplifier; And
A transmission clock is transmitted to the matching circuit through the transmission amplifier, an extraction clock is extracted from a waveform formed in the matching circuit in response to the transmission clock, a phase difference between the transmission clock and the extraction clock is stored, And a transmitter for controlling transmission of an information signal through the antenna, the transmission amplifier, and the matching circuit according to the phase difference. The method according to claim 1,
Wherein the transmitter includes a comparison and selection block that compares the phase of the extracted clock with the phase of the transmission clock and generates phase selection information corresponding to the phase difference according to the comparison result. 3. The method of claim 2,
Wherein the transmitter further comprises a phase lookup table storing phase selection information corresponding to each of the phase differences and the phase differences,
Wherein the comparing and selecting block generates the phase selection information from the phase lookup table using the phase difference. The method according to claim 1,
Wherein the transmitter operates in one of a phase measurement mode and a transmission mode,
Wherein the transmitter comprises a phase control block for storing information on the phase difference in the phase measurement mode. 5. The method of claim 4,
Wherein in the transmission mode, the phase control block adjusts the phase of the extracted clock according to information on the phase difference, and outputs the adjusted clock as a controlled clock. 6. The method of claim 5,
The transmitter includes a reference clock generating block for outputting a reference clock; And
And a multiplexer for selecting the reference clock as the transmission clock in the phase measurement mode and transmitting the selected clock to the transmission amplifier in the phase measurement mode and selecting the adjusted clock in the transmission mode and transmitting the selected clock to the transmission amplifier. The method according to claim 6,
Wherein transmission information is added to the adjusted clock while the adjusted clock is transmitted to the transmit amplifier. 6. The method of claim 5,
Wherein the phase control block comprises:
A phase locked loop outputting a phase locked clock fixed to a phase of the extracted clock;
A phase splitter for adjusting a phase of the phase locked clock to generate a plurality of clocks having different phases; And
And a clock selector for selecting one of the plurality of clocks as the adjusted clock using information on the phase difference. 6. The method of claim 5,
Wherein the phase control block comprises:
A phase splitter for adjusting a phase of the extracted clock to generate a plurality of clocks having different phases; And
And a clock selector for selecting one of the plurality of clocks as the adjusted clock using information on the phase difference,
Wherein the clock selected using the information on the phase difference among the plurality of clocks changes as the cycle of the extracted clock progresses. antenna;
A transmit amplifier;
A matching circuit coupled between the antenna and the transmit amplifier; And
A transmission clock is transmitted to the matching circuit through the transmission amplifier, an extraction clock is extracted from a waveform formed in the matching circuit in response to the transmission clock, and the extracted clock is extracted from the transmission clock and the extraction clock, And a transmitter for detecting a difference between a resonant frequency of the transmission clock and a center frequency of the transmission clock.

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