KR20070046134A - Data communication apparatus, data communication method and data communication system - Google Patents

Abstract

SSB-modulates a radio frequency signal in accordance with data addressed to the contactless IC card 2, transmits a modulation signal of the single side band or the corresponding radio frequency signal, and transmits the radio frequency signal. When receiving the modulated signal of both sides of the band, the data is demodulated from the modulated signal of the both side bands. As a result, it is possible to accurately demodulate the modulated signal transmitted from the non-contact IC card 2 without being affected by the modulated signal transmitted from the other data communication device 3.

Description

DATA COMMUNICATION APPARATUS, DATA COMMUNICATION METHOD AND DATA COMMUNICATION SYSTEM}

The present invention relates to a data communication apparatus, a data communication method, and a data communication system for performing data communication with a contactless wireless communication device (e.g., a contactless IC card, an RF tag, an electronic tag, a keyless entry).

The conventional data communication apparatus includes an ASK modulator for ASK-modulating an RF signal, which is a radio frequency signal, and outputting the modulated signal, an amplifier for amplifying a modulated signal output from the ASK modulator, and a modulated signal amplified by the amplifier. It is composed of an antenna for transmitting to a contactless wireless communication device.

If a non-contact wireless communication device is provided with a data communication device in the neighborhood (a distance of several tens of centimeters to the data communication device), the non-contact wireless communication device receives the power supply signal (for example, an RF signal) transmitted from the data communication device. The power supply signal is rectified to obtain driving power, and the power is stored in an internal capacitor.

Subsequently, by using the power stored in the capacitor, a modulation signal (for example, a data signal such as a command) transmitted from the data communication device is received to demodulate the data, or the unmodulated signal transmitted from the data communication device is modulated. Processing such as transmitting the modulated signal (e.g., a data signal such as a command) to the data communication device can be performed (see Non-Patent Document 1, for example).

Accordingly, when the data communication device receives the modulated signal transmitted from the non-contact wireless communication device, the data communication device transmits CW (unmodulated continuous wave: RF signal), which is a reaction signal, to the non-contact wireless communication device. When another data communication device is provided at a position of several kilometers from its own position, the modulation signal from another data communication device at a timing of receiving a modulation signal (for example, a data signal such as a command) from the non-contact wireless communication device. (Eg, a data signal such as a command) may be received.

As such, when a modulation signal is received from another data communication device at a timing of receiving a modulation signal from the non-contact radio communication device, the modulation signal becomes an interference wave, so that the demodulated signal accurately transmitted from the non-contact radio communication device can be accurately demodulated. It may become impossible.

In the case where a plurality of data communication devices are provided, if the distance between them is short, different frequencies are allocated to avoid mutual interference, but since the number of assignable frequencies is limited, even if the distance between them is about several kilometers, the same There is a task to assign frequencies.

Moreover, the mutual distance which can avoid mutual interference is about several tens of kilometers.

[Non-Patent Document 1] MWE2003 Microwave Workshop Digest 「Ultra-small RFID Chip: MuChip」, Mitsuo Usami, Hitachi, Ltd., Central Research Institute, 2003, page 235 ~ page 238

Since the conventional data communication apparatus is configured as described above, when the modulated signal is received from another data communication apparatus at the timing of receiving the modulated signal from the non-contact wireless communication device, the modulated signal becomes an interference wave and the non-contact wireless There has been a problem that the demodulated signal transmitted from the communication device cannot be correctly demodulated.

The present invention has been made to solve the above problems, a data communication device capable of accurately demodulating a modulated signal transmitted from a non-contact wireless communication device without being affected by the modulated signal transmitted from another data communication device, It is an object to obtain a data communication method and a data communication system.

The data communication apparatus according to the present invention modulates a radio frequency signal in a single sideband according to data addressed to a contactless wireless communication device, transmits the single sideband modulated signal or the corresponding radio frequency signal, and transmits the radio frequency signal. When transmitting, upon receiving the modulated signals of the two side bands transmitted from the non-contact wireless communication device, the data is demodulated from the modulated signals of the two side bands.

As a result, compared with the case where the data communication device transmits the modulation signals of the two side bands, the influence of the modulation signal transmitted from the other data communication device is reduced or transmitted from the non-contact wireless communication device without any influence. The demodulated signal can be demodulated.

1 is a block diagram showing a data communication system according to a first embodiment of the present invention;

2 is a block diagram showing a data communication device and a contactless IC card according to Embodiment 1 of the present invention;

3 is a configuration diagram showing the inside of an SSB modulation circuit;

4 is a configuration diagram showing the inside of an SSB demodulation circuit;

5 is a flowchart showing a data communication method according to Embodiment 1 of the present invention;

6 is an explanatory diagram showing a spectral distribution;

7 is an explanatory diagram showing a spectral distribution;

8 is an explanatory diagram for explaining processing contents of an SSB modulation circuit;

9 is an explanatory diagram for explaining the processing contents of an SSB modulation circuit;

10 is an explanatory diagram for explaining processing contents of an SSB modulation circuit;

11 is a configuration diagram showing the inside of the SSB modulation circuit;

12 is an explanatory diagram for explaining processing contents of an SSB modulation circuit;

13 is an explanatory diagram for explaining the processing contents of an SSB modulation circuit;

14 is an explanatory diagram for explaining processing contents of an SSB modulation circuit;

15 is an explanatory diagram showing a channel interval of each data communication apparatus;

16 is an explanatory diagram showing a channel interval of each data communication apparatus;

17 is an explanatory diagram showing a spectral distribution.

EMBODIMENT OF THE INVENTION Hereinafter, in order to demonstrate this invention in detail, the best form for implementing this invention is demonstrated according to attached drawing.

(Example 1)

1 is a block diagram showing a data communication system according to a first embodiment of the present invention.

In the figure, the data communication device 1 corresponds to, for example, a reader / writer (questioner) and the like, and includes a power supply signal (CW: unmodulated continuous wave), a data signal (modulation wave) such as a command, or a reaction signal. (CW: unmodulated continuous wave) is transmitted to the non-contact IC card 2. FIG.

When the non-contact IC card 2, which is a non-contact wireless communication device, receives the power supply signal transmitted from the data communication device 1, the built-in capacitor is charged by the power supply signal, and then stored in the capacitor. By using the charge as a power source, for example, a process of receiving a data signal (modulation wave) transmitted from the data communication device 1 and demodulating the data, or modulating the data addressed to the data communication device 1, Processing for transmitting the modulated signal to the data communication device 1 is performed.

The data communication device 3 is a data communication device provided in the vicinity of the data communication device 1. However, the configuration of the data communication device 3 is the same as that of the data communication device 1.

Fig. 2 is a block diagram showing a data communication device and a contactless IC card according to the first embodiment of the present invention.

In the figure, the data transmitter 11 of the data communication device 1 outputs transmission data such as a command to be transmitted to the contactless IC card 2, shaping data for power supply, or shaping data for reaction.

The RF signal oscillator 12 has no frequency f ₁ when the data output from the data transmitter 11 is transmission data such as a command or when the data output from the data transmitter 11 is standard data for reaction. Oscillates a modulated signal (radio frequency signal). In addition, when the data output from the data transmitter 11 is shaping data for power supply, an unmodulated signal (radio frequency signal) of frequency f ₂ is oscillated. In addition, the RF signal oscillator 12 constitutes a radio frequency signal oscillation means.

When the transmission data is output from the data transmitter 11, the changeover switch 13 outputs an unmodulated signal of frequency f ₁ oscillated from the RF signal oscillator 12 to the SSB modulation circuit 14, and the data transmitter 11. When the output data from the shaping data for power supply or the shaping data for reaction is outputted, an unmodulated signal of frequency f ₂ or an unmodulated signal of frequency f ₁ generated from the RF signal oscillator 12 is output to the level adjuster 15. do.

In accordance with the transmission data output from the data transmitter 11, the SSB modulation circuit 14 modulates an SSB (Single Side Band) modulated signal of the frequency f ₁ oscillated from the RF signal oscillator 12, and the single sideband Output the modulated signal. In addition, the SSB modulation circuit 14 constitutes a modulation means.

The level adjuster 15 adjusts the peak power of the unmodulated signal of frequency f ₁ or frequency f ₂ oscillated from the RF signal oscillator 12, and outputs the peak power of the unmodulated signal from the SSB modulation circuit 14. It is larger than the peak power of the modulated signal.

When the transmission data is output from the data transmitter 11, the changeover switch 16 outputs the modulated signal output from the SSB modulation circuit 14 to the amplifier 17, and the shaped data for power supply from the data transmitter 11. Alternatively, when the shaping data for reaction is output, the unmodulated signal output from the level adjuster 15 is output to the amplifier 17.

The amplifier 17 amplifies the modulated signal or the unmodulated signal output from the changeover switch 16.

The circulator 18 outputs the modulated signal or the unmodulated signal output from the amplifier 17 to the antenna 19, while the modulated signal of the two side bands received by the antenna 19 is sent to the SSB demodulation circuit 20. Output

The antenna 19 transmits the modulated signal or unmodulated signal amplified by the amplifier 17 to the contactless IC card 2, while receiving the modulated signals of both sidebands transmitted from the contactless IC card 2. Moreover, the circulator 18 and the antenna 19 are comprised by the transmission means and the reception means.

The SSB demodulation circuit 20 demodulates data from the modulation signals of the two side bands received by the antenna 19. In addition, the SSB demodulation circuit 20 constitutes a demodulation means.

The antenna 21 of the contactless IC card 2 receives a modulated signal or an unmodulated signal transmitted from the data communication device 1. If the reception signal of the antenna 21 is an unmodulated signal having a frequency f _2, the charging circuit 22 rectifies the unmodulated signal to obtain driving power, and stores the driving power in the capacitor 23.

The modulation / demodulation circuit 24 is driven by using the power stored in the capacitor 23 of the charging circuit 22, and if the received signal of the antenna 21 is a modulated signal having a frequency f ₁ , data such as a command from the modulated signal is sent. Is demodulated and processed according to the data. If the received signal of the antenna 21 is an unmodulated signal of frequency f ₁ , the unmodulated signal is modulated with data addressed to the data communication device 1, and the modulated signal is output to the antenna 21.

FIG. 3 is an example of configuration diagram when the SSB modulation circuit 14 is constituted by a digital circuit, and in the drawing, the local oscillator 31 oscillates a local oscillation signal of 10 MHz, for example. The SSB modulator 32 is composed of ninety-degree phase shifters 32a and 32b, multipliers 32c and 32d, and an adder 32e, and uses a digital signal that is data output from the data transmitter 11. SSB modulates the local oscillation signal oscillated from the local oscillator 31.

The D / A converter 33 converts the digital modulated signal output from the SSB modulator 32 into an analog signal.

The RF signal oscillator 34 oscillates a radio frequency signal of, for example, 940 MHz. The multiplier 35 multiplies the modulated signal after the D / A conversion by the D / A converter 33 and the radio frequency signal oscillated from the RF signal oscillator 34, and outputs the modulated signal of both side bands.

The band pass filter 36 removes the single side band of the modulated signal output from the multiplier 35 and outputs the single side band modulated signal.

4 is a configuration diagram showing the inside of the SSB demodulation circuit 20, in which the RF signal oscillator 41 oscillates a radio frequency signal of, for example, 950 MHz. The single sideband eliminator 42 is composed of multipliers 42a and 42b, over 90 degree phasers 42c and 42d, adders 42e and low pass filters 42f and 42g, and a radio oscillated from the RF signal oscillator 41. Using the frequency signal, the single side band of the modulated signal of both side bands received by the antenna 19 is removed.

The single side band regenerator 43 reproduces the single side band removed by the single side band remover 42 from the modulated signal output from the single side band remover 42, and outputs the modulated signal of both side bands. The DSB demodulator 44 performs DSB (Double Side Band) demodulation on the modulation signals of the two side bands output from the single side band regenerator, and demodulates data addressed to itself.

Next, the operation will be described.

In the first embodiment, as described later, when the data communication device 1 or the data communication device 3 transmits a modulated signal, the modulated signal of the single side band is transmitted. 6, two frequency bands sandwiching a radio frequency signal serving as a carrier are occupied.

At this time, even when the contactless IC card 2 transmits data to the data communication device 1, since the modulated signals of both side bands are transmitted using almost the same frequency band, the non-contact IC card 2 uses both side bands. At the timing of transmitting the modulated signal to the data communication apparatus 1, when the other data communication apparatus 3 transmits the modulated signal of both side bands, the modulated wave becomes an interference wave and the data communication apparatus 1 The reception accuracy of the modulated signal from the non-contact IC card 2 deteriorates.

In the first embodiment, even if another data communication device 3 transmits a modulation signal at the timing when the contactless IC card 2 transmits the modulation signals of both side bands to the data communication device 1, the modulation waves interfere with each other. In order to prevent a wave, as shown in FIG. 7, the modulation signal transmitted by the data communication apparatus 1 and the data communication apparatus 3 is made into the modulation signal of a single side band.

It demonstrates concretely below.

5 is a flowchart illustrating a data communication method according to Embodiment 1 of the present invention. The non-contact IC card 2 is not equipped with a power source such as a battery, and cannot be started unless power is supplied from the outside.

Therefore, the data communication device 1 supplies power to the noncontact IC card 2 in a noncontact state before transmitting data such as a command.

That is, the data transmitter 11 of the data communication apparatus 1 converts the shaping data for power supply into the RF signal oscillator 12, the changeover switches 13 and 16, and the SSB modulation before outputting transmission data such as a command. Output to the circuit 14 (step ST1).

Here, the formal data for power supply is not meaningful data, such as a control command, and is not intended for information transfer. Therefore, the content of the data may be any data, but transmission data such as a command, It is preferable that the data can be clearly distinguished from the standard data for the reaction.

When the RF signal oscillator 12 of the data communication device 1 receives data from the data transmitter 11, the RF signal oscillator 12 determines whether the data is standardized data for power supply, transmitted data such as a command, or standardized data for reaction. Check (step ST2, ST7).

When the RF signal oscillator 12 recognizes that the data output from the data transmitter 11 is standard data for power supply, the RF signal oscillator 12 oscillates an unmodulated signal having a frequency f ₂ allocated in advance (step ST3).

When the changeover switch 13 of the data communication device 1 receives data from the data transmitter 11, it is checked whether the data is standardized data for power supply, transmitted data such as a command, or standardized data for reaction. do.

When the changeover switch 13 recognizes that the data output from the data transmitter 11 is standard data for power supply, the unmodulated signal of frequency f ₂ oscillated from the RF signal oscillator 12 is supplied to the level regulator 15. Output

When the level adjuster 15 of the data communication device 1 receives the unmodulated signal having the frequency f ₂ oscillated from the RF signal oscillator 12, the level adjuster 15 adjusts the peak power of the unmodulated signal and peaks the unmodulated signal. The power is made larger than the peak power of the modulated signal output from the SSB modulation circuit 14 (step ST4).

That is, the peak power of the unmodulated signal oscillated from the RF signal oscillator 12 is adjusted so that the peak power of the unmodulated signal for power supply becomes larger than the peak power of the modulated signal for data transmission.

When the switch 16 of the data communication device 1 receives the data from the data transmitter 11, it confirms whether the data is standardized data for power supply, transmitted data such as a command, or standardized data for reaction. do.

The changeover switch 16 outputs the unmodulated signal output from the level adjuster 15 to the amplifier 17 when the data outputted from the data transmitter 11 is recognized as standardized data for power supply.

When the amplifier 17 of the data communication device 1 receives the unmodulated signal of frequency f ₂ from the switching switch 16, it amplifies the unmodulated signal (step ST5).

When the circulator 18 of the data communication device 1 receives the amplified unmodulated signal from the amplifier 17, the circulator 18 outputs the unmodulated signal to the antenna 19.

When the antenna 19 of the data communication device 1 receives the amplified non-modulated signal from the circulator 18, the antenna 19 radiates the unmodulated signal as a power supply signal to the air, thereby transmitting the non-modulated signal to the contactless IC card. To (2) (step ST6).

The antenna 21 of the non-contact IC card 2 receives an unmodulated signal of frequency f ₂ transmitted from the data communication device 1.

The charging circuit 22 of the non-contact IC card 2 obtains driving power by rectifying the unmodulated signal if the received signal of the antenna 21 is a non-modulated signal of frequency f ₂ , and obtains the driving power. Accumulate in the capacitor 23.

Next, when the data communication device 1 transmits data to the contactless IC card 2, the data transmitter 11 of the data communication device 1 transmits the transmission data such as a command to the RF signal oscillator 12, Output to the changeover switches 13 and 16 and the SSB modulation circuit 14 (step ST1).

When the RF signal oscillator 12 of the data communication device 1 receives data from the data transmitter 11, the RF signal oscillator 12 determines whether the data is standardized data for power supply, transmitted data such as a command, or standardized data for reaction. Check (step ST2, ST7).

When the RF signal oscillator 12 recognizes that the data output from the data transmitter 11 is transmission data such as a command, the RF signal oscillator 12 oscillates an unmodulated signal having a frequency f ₁ allocated in advance (step ST8).

When the switch 13 of the data communication device 1 receives the data from the data transmitter 11, it confirms whether the data is standardized data for power supply, transmitted data such as a command, or standardized data for reaction. do.

When the changeover switch 13 recognizes that the data output from the data transmitter 11 is the transmission data, it outputs the unmodulated signal of frequency f ₁ oscillated from the RF signal oscillator 12 to the SSB modulation circuit 14.

When the SSB modulation circuit 14 of the data communication device 1 receives data from the data transmitter 11, the SSB modulation circuit 14 determines whether the data is shaping data for power supply, transmission data such as a command, or shaping data for reaction. Check it.

When the SSB modulation circuit 14 recognizes that the data output from the data transmitter 11 is transmission data such as a command, the frequency oscillated from the RF signal oscillator 12 in accordance with the transmission data output from the data transmitter 11. The unmodulated signal of f ₁ is SSB-modulated, and the modulated signal of the single side band is output to the changeover switch 16 (step ST9).

The specific processing contents of the SSB modulation circuit 14 are as follows.

The transmission data output from the data transmitter 11 is "cosωt", and the local oscillation signal oscillated from the local oscillator 31 is "Acosω _c t".

The 90 degree idealizer 32a of the SSB modulator 32 advances the phase of the transmission data output from the data transmitter 11 by 90 degrees, and outputs "-sinωt".

The 90 degree idealizer 32b of the SSB modulator 32 advances the phase of the local oscillation signal oscillated from the local oscillator 31 by 90 degrees, and outputs "-Asinω _c t".

Since it is relatively difficult for the SSB modulator 32 to digitally generate an SSB modulated signal immediately in the 950 MHz band, the local oscillator 31 is allowed to oscillate, for example, a 10 MHz local oscillation signal.

The multiplier 32c of the SSB modulator 32 multiplies the transmission data " cosωt " output from the data transmitter 11 and the local oscillation signal " Acosω _c t " oscillated from the local oscillator 31, which is the multiplication result. "Acos omega tcos omega _c t" is output.

The multiplier 32d of the SSB modulator 32 multiplies " -sin omega t " output from the 90 degree or more phaser 32a and " -Asin omega _c t " output from the 90 degree or more phaser 32b, and the result of the multiplication " Output Asinωt · sinω _c t ”.

The adder 32e of the SSB modulator 32 adds "Acos omega t cos omega _c t" output from the multiplier 32c and "Asin omega t sino _c t" output from the multiplier 32d, and is shown in FIG. , (not the upper sideband and the lower wave modulation signal of Taiwan), single sideband modulation signal and generates a _{"Acos (ω c -ω) t} " as described.

When the SSB modulator 32 generates a digitally modulated signal, the D / A converter 33 converts the modulated signal into an analog signal.

When the multiplier 35 receives the D / A-converted modulated signal by the D / A converter 33, the multiplier 35 multiplies the modulated signal by oscillation from the RF signal oscillator 34, for example, a 940 MHz radio frequency signal. 9, a 930 MHz modulated signal and a 950 MHz modulated signal are output.

The bandpass filter 36 removes the 930 MHz modulated signal from the modulated signal output from the multiplier 35 and outputs a 950 MHz modulated signal (modulated signal of one side band) to the switching switch 16 ( See FIG. 10).

When the switch 16 of the data communication device 1 receives the data from the data transmitter 11, it confirms whether the data is standardized data for power supply, transmitted data such as a command, or standardized data for reaction. do.

When the changeover switch 16 recognizes that the data output from the data transmitter 11 is transmission data such as a command, it outputs the modulation signal of the single side band output from the SSB modulation circuit 14 to the amplifier 17.

When the amplifier 17 of the data communication device 1 receives the modulation signal of the single side band from the switching switch 16, it amplifies the modulation signal (step ST5).

When the circulator 18 of the data communication device 1 receives the amplified modulated signal from the amplifier 17, the circulator 18 outputs the modulated signal to the antenna 19.

When the antenna 19 of the data communication device 1 receives the amplified modulated signal from the circulator 18, the antenna 19 radiates the modulated signal to the air as a data signal, thereby transmitting the modulated signal to the contactless IC card 2. (Step ST6).

The antenna 21 of the non-contact IC card 2 receives the modulated signal of the single side band transmitted from the data communication device 1.

The modulation and demodulation circuit 24 of the non-contact IC card 2 is driven using the power stored in the capacitor 23 of the charging circuit 22 when the antenna 21 receives a modulation signal of a single side band. The envelope of the modulation signal of the single side band is detected, and data such as a command is demodulated from the modulation signal, and processing according to the data is performed.

Next, when the data communication device 1 receives data from the non-contact IC card 2, the data transmitter 11 of the data communication device 1 transmits the shaping data for reaction to the RF signal oscillator 12, Output to the changeover switches 13 and 16 and the SSB modulation circuit 14 (step ST1).

Here, the format data for reaction is not meaningful data, such as a control command, for example, and is not intended to convey information. Therefore, the content of the data may be any data, but transmission data such as a command or electric power may be used. It is preferable that the data be clearly distinguishable from the standard data for supply.

When the RF signal oscillator 12 of the data communication device 1 receives data from the data transmitter 11, the RF signal oscillator 12 determines whether the data is standardized data for power supply, transmitted data such as a command, or standardized data for reaction. Check (step ST2, ST7).

If the RF signal oscillator 12 recognizes that the data output from the data transmitter 11 is the stereotyped data for reaction, the RF signal oscillator 12 oscillates an unmodulated signal having a frequency f ₁ allocated in advance (step ST10).

When the changeover switch 13 of the data communication device 1 receives data from the data transmitter 11, it is checked whether the data is standardized data for power supply, transmitted data such as a command, or standardized data for reaction. do.

The changeover switch 13 outputs the unmodulated signal of frequency f ₁ oscillated from the RF signal oscillator 12 to the level adjuster 15, if it is recognized that the data output from the data transmitter 11 is the format data for reaction. do.

When the level adjuster 15 of the data communication device 1 receives the unmodulated signal of the frequency f ₁ oscillated from the RF signal oscillator 12, the level adjuster 15 adjusts the peak power of the unmodulated signal and peaks the unmodulated signal. The power is made larger than the peak power of the modulated signal output from the SSB modulation circuit 14 (step ST11).

That is, the peak power of the unmodulated signal oscillated from the RF signal oscillator 12 is adjusted so that the peak power of the unmodulated signal for reaction becomes larger than the peak power of the modulated signal for data transmission.

When the switch 16 of the data communication device 1 receives the data from the data transmitter 11, it confirms whether the data is standardized data for power supply, transmitted data such as a command, or standardized data for reaction. do.

The changeover switch 16 outputs the unmodulated signal output from the level adjuster 15 to the amplifier 17 when it recognizes that the data output from the data transmitter 11 is the format data for reaction.

When the amplifier 17 of the data communication device 1 receives the unmodulated signal of frequency f ₁ from the switch 16, it amplifies the unmodulated signal (step ST5).

When the circulator 18 of the data communication device 1 receives the amplified unmodulated signal from the amplifier 17, the circulator 18 outputs the unmodulated signal to the antenna 19.

When the antenna 19 of the data communication device 1 receives the unmodulated signal after amplification from the circulator 18, the antenna 19 radiates the unmodulated signal as a reaction signal to the air, thereby transmitting the unmodulated signal to a non-contact IC card ( 2) (step ST6).

The antenna 21 of the non-contact IC card 2 receives an unmodulated signal of frequency f ₁ transmitted from the data communication device 1.

The modulation and demodulation circuit 24 of the non-contact IC card 2 is driven using the power stored in the capacitor 23 of the charging circuit 22 if the reception signal of the antenna 21 is a non-modulation signal of frequency f ₁ . The data addressed to the data communication device 1 is modulated, and a modulated signal having a frequency f ₁ (modulated signals of both bands) is output to the antenna 21.

As a result, the modulated signal of both side bands is transmitted from the non-contact IC card 2 to the data communication device 1 as a data signal.

The antenna 19 of the data communication device 1 receives a modulated signal of both side bands which is a data signal transmitted from the non-contact IC card 2.

That is, at the timing of transmitting the unmodulated signal of frequency f ₁ , which is a reaction signal, a modulated signal of both side bands, which is a data signal, is received.

When the antenna 19 of the data communication device 1 receives a modulated signal of both side bands as a data signal, another data communication device 3 may transmit a modulated signal, but as shown in FIG. 7. Since the other data communication device 3 transmits only the modulation signal of the lower band (the configuration of the data communication device 3 is the same as that of the data communication device 1), it transmits from the contactless IC card 2. Of the modulated signals, the modulated signal of the upper band is not interfered with the modulated signal transmitted from the other data communication device 3.

The SSB demodulation circuit 20 of the data communication device 1 demodulates data from modulated signals of both sidebands received by the antenna 19.

That is, the SSB demodulation circuit 20 demodulates data from the modulation signal of the upper band which does not interfere with the modulation signal transmitted from the other data communication device 3 among the modulation signals transmitted from the non-contact IC card 2.

The specific processing contents of the SSB demodulation circuit 20 are as follows.

The modulation signal of the two side bands received by the antenna 19 is " A ₁ cos (ω _c + ω ₁ ) t + A ₂ cos (ω _c -ω ₂ ) t ”, which is oscillated from the RF signal oscillator 41. The radio frequency signal is called "cosω _c t".

The multiplier 42a of the single sideband eliminator 42 multiplies the modulated signal of both sidebands received by the antenna 19 and the radio frequency signal oscillated from the RF signal oscillator 41, and the multiplication result "( the _{a 1/2) cosω 1 t} + (a 2/2) cosω 2 t " outputs.

The 90 degree idealizer 42c of the single side band eliminator 42 advances the phase of the radio frequency signal oscillated from the RF signal oscillator 41 by 90 degrees, and outputs "-sinω _c t".

The multiplier 42b of the single sideband eliminator 42 receives the modulation signals " A ₁ cos (ω _c + ω ₁ ) t + A ₂ cos (ω _c -ω ₂ ) t of the _two side bands received by the antenna 19. "of the multiplier, and the multiplication _{result" (a 1/2) sinω} 1 t- (a 2/2) " , and a 90-degree phase is 90 advanced radio frequency signal by the phase shifter (42c)" -sinω _c t Output sinω ₂ t ".

90 proceeds in the single sideband eliminator 42, Fig phase shifter (42d) is the multiplication result of the multiplier (42a) is also a phase of _{"(A 1/2) sinω} 1 t- (A 2/2) sinω 2 t" 90 to, and outputs the _{"(a 1/2) cosω} 1 t- (a 2/2) cosω 2 t".

The adder 42e of the single-side band eliminator 42 adds the multiplication result of the multiplier 42a and the output of the 90-degree or more phaser 42d, thereby removing the lower band of the modulated signal received by the antenna 19. , Outputs a modulation signal "A ₁ cosω ₁ t" in which only the upper band is left.

When the sideband regenerator 43 receives the modulation signal "Acosωt" of the upper sideband from the sideband eliminator 42, for example, by symmetrically copying the waveform of the upper sideband modulation signal to the lower sideband side, modulation of the lower sideband is performed. The signal is reproduced to output a modulated signal of both side bands.

When the DSB demodulator 44 receives the modulated signals of the two side bands from the single side band regenerator 43, the DSB demodulator 44 demodulates the data addressed by itself by demodulating the modulated signals of the two side bands.

As apparent from the above, according to the first embodiment, the radio frequency signal is SSB modulated according to the data addressed to the contactless IC card 2 to transmit a single sideband modulation signal or the corresponding radio frequency signal. When the radio frequency signal is transmitted, upon receiving the modulated signal of both side bands transmitted from the non-contact IC card 2, the data communication apparatus modulates the both side bands because the data communication device is configured to demodulate the data. In comparison with the case of transmitting a signal, the influence of the modulated signal transmitted from the other data communication device 3 can be reduced or the demodulated signal transmitted from the contactless IC card 2 can be demodulated without any influence at all. It has an effect.

Further, according to the first embodiment, since the modulation signal of the single side band is extracted from the modulation signals of the two side bands received by the antenna 19, and the data is demodulated from the modulation signal of the single side band, another data communication is performed. The data is demodulated only from the modulated signal which is not interfering with the modulated signal transmitted from the apparatus 3, which has the effect of more accurately demodulating.

In the first embodiment, the data communication apparatuses 1 and 3 transmit the modulated signal of the lower band, and the data is transmitted from the modulated signal of the upper band among the modulated signals of the two bands transmitted from the non-contact IC card 2. Although demodulation was shown, the data communication apparatuses 1 and 3 transmit the modulation signal of the upper sideband, and demodulate data from the modulation signal of the lower sideband among the modulation signals of the two sidebands transmitted from the non-contact IC card 2. As shown in FIG. You may do so.

In the first embodiment, the SSB demodulation circuit 20 of the data communication device 1 shows the SSB demodulation of the modulation signals of the two side bands received by the antenna 19, but the modulation signals of the both side bands are DSB. The data may be demodulated to demodulate.

In this case, since the modulated signal of the lower band which is being interfered by the modulated wave by the other data communication apparatus 3 is also included as a demodulation object, the modulated signal of the two side bands received by the antenna 19 is SSB demodulated. Although the demodulation accuracy of the data is deteriorated, the modulation signal of the upper band is not subjected to interference, so that the demodulation accuracy of the data is lower than that of the case where the other data communication device 3 transmits the modulated signal of both bands. Is improved.

In addition, when DSB demodulating the modulated signals of the two side bands received by the antenna 19, the circuit configuration of the demodulation circuit of the data communication device 1 can be simplified.

Further, in the first embodiment, when the data output from the data transmitter 11 is transmission data such as a command, or shaping data for reaction, the RF signal oscillator 12 oscillates an unmodulated signal of frequency f ₁ . Although it was shown, the non-modulated signals of different frequencies may be oscillated. For example, if the data output from the data transmitter 11 is transmission data such as a command, the RF signal oscillator 12 oscillates an unmodulated signal of frequency f ₁ , and the data output from the data transmitter 11 is intended for reaction. The RF signal oscillator 12 may cause the RF signal oscillator 12 to oscillate an unmodulated signal of frequency f ₃ .

Also, when data output from the data transmitter 11 is the fixed form data for power supply, RF signal oscillator 12 is Despite receive respect to that oscillates the unmodulated signal having a frequency f _2, the output from the data transmitter 11 The RF signal oscillator 12 may be configured to oscillate an unmodulated signal of frequency f ₁ as in the case where the data thus obtained is transmission data such as a command, or shaping data for reaction.

In this case, the changeover switches 13 and 16 and the level adjuster 15 are unnecessary.

In the first embodiment, the data communication device 1 supplies power to the contactless IC card 2 and the contactless IC card 2 is driven using the power. It is not necessary to supply power to the contactless IC card 2, and the contactless IC card 2 may be driven by using another electric power (for example, obtaining power from a built-in battery).

(Example 2)

In the first embodiment, the SSB modulation circuit 14 outputs the single side band modulated signal to the switching switch 16. However, when the SSB modulating circuit 14 outputs the single side band modulated signal, the SSB modulation circuit 14 outputs the single side band modulated signal. The carrier signal may be included in the modulated signal for output.

That is, as shown in FIG. 11, the adder 32f of the SSB modulation circuit 14 adds the transmission data "cosωt" and the direct current component "B" output from the data transmitter 11, and "" is the addition result. By outputting cosωt + B " to multiplier 32d, the adder 32e of SSB modulator 32 outputs " A {cos (ω _c -ω) t + Bcosω _c t} ".

As a result, the signal output from the adder 32e of the SSB modulator 32, as shown in Fig. 12, includes a carrier component in a portion having a frequency of 10 MHz.

In addition, as shown in FIG. 13, the signal output from the multiplier 35 of the SSB modulation circuit 14 includes a carrier component in a portion having frequencies of 930 MHz and 950 MHz.

In addition, as shown in FIG. 14, the signal output from the bandpass filter 36 of the SSB modulation circuit 14 includes a carrier component in a portion having a frequency of 950 MHz.

As apparent from the above, according to the second embodiment, when the SSB modulation circuit 14 outputs the modulation signal of the single side band, the non-contact IC card 2 is configured to include the carrier signal in the modulation signal. Even if the modulation and demodulation circuit 24 is a circuit for DSB modulation (not for SSB modulation), the envelope of the modulation signal of the single side band can be detected, and data such as a command can be demodulated from the modulation signal. Effect.

(Example 3)

In the first embodiment, the data communication device 1 and the data communication device 3 transmit the modulated signals of the same frequency, but the interference between the data communication device 1 and the data communication device 3 is prevented. To this end, the data communication device 1 and the data communication device 3 may transmit modulated signals of different frequencies. That is, the frequency of the radio frequency signal oscillated from the RF signal oscillator 12 of the data communication devices 1 and 3 may be different.

In this manner, even when the data communication device 1 and the data communication device 3 transmit modulated signals of different frequencies, harmonics are also transmitted when the modulated wave is transmitted. As shown in FIG. It is necessary to empty the interval of, for example, 300 mm or more. 15 shows a spectrum when the data transmission apparatuses 1 and 3 transmit the modulated signals of both side bands by performing DSB modulation without performing SSB modulation.

Therefore, when the number of data communication devices 1 and 3 increases to a large number, the frequency band occupied by the data communication system increases, but since the frequency band which can actually occupy is limited, the channel interval of each data communication device is limited. If it is not narrowed, the number of installable data communication devices cannot be increased.

Therefore, in the third embodiment, the channel interval of each data communication device is narrowed as follows to increase the number of installable data communication devices.

That is, in the third embodiment, when each data communication device performs SSB modulation and transmits the modulated signal of the single side band, as shown in Fig. 16, by alternately changing the single side band not transmitted (data of ch1). Communication device → do not transmit the modulation signal (LSB) of the lower band, data communication device of ch2 → do not transmit the modulation signal (USB) of the upper band, data communication device of the lower band → modulation signal (LSB) of the lower band. Not transmitted), and the response band from the contactless IC card 2 in the adjacent channel can be accessed or shared.

Specifically, when the data communication device ch2 transmits the lower band modulated signal LSB and does not transmit the upper band modulated signal USB, as shown in FIG. (the frequency of ch2 <the frequency of ch3, and ch2 and ch3 are called frequencies of the adjacent band), and the upper band modulated signal USB is transmitted without transmitting the lower band modulated signal LSB.

Also, the data communication apparatus of ch1 (frequency of ch1 <frequency of ch2, and ch1 and ch2 are called frequencies of adjacent bands) does not transmit the lower band modulated signal (LSB) but the upper band modulated signal (USB). To transmit.

In this case, since harmonics do not appear in the response bands from the non-contact IC card 2 at ch2 and ch3, that is, the USB of ch2 and the LSB of ch3, the area occupied by harmonics (for example, 100 kHz) needs to be emptied. Disappears. Therefore, let the distance between ch2 and ch3 approach 200ms.

In addition, the LSB of ch2 and the USB of ch1 are not the response band from the noncontact IC card 2 (ch2 is the response band of USB, and ch1 is the response band of chB). Since the response from (2) is not affected, the distance between ch1 and ch2 should be approached to about 200 ms.

As apparent from the above, according to the third embodiment, for example, in the case where the data communication device ch2 transmits the lower band modulated signal LSB and does not transmit the upper band modulated signal USB, ch1 and ch3, for example. Data communication device is configured to transmit the modulation signal (USB) of the upper band without transmitting the modulation signal (LSB) of the lower band. It has the effect of increasing the number.

(Example 4)

In the third embodiment, for example, when the data communication device ch2 transmits the modulation signal LSB of the lower band and does not transmit the modulation signal USB of the upper band, the data communication devices ch1 and ch3 are lower. Although the transmission of the modulation signal USB of the upper band is shown without transmitting the modulation signal LSB of the wave band, among the data communication systems, a data communication device to which a radio frequency signal having the lowest frequency is assigned is assigned to the lower band band. The data communication apparatus which transmits the modulation signal USB of the upper band without transmitting the modulation signal LSB, and is assigned the radio frequency signal having the highest frequency, does not transmit the modulation signal USB of the upper band. The modulation signal LSB may be transmitted.

Accordingly, the communication bandwidth can be increased by reducing the guard bandwidth provided at the boundary between the radio frequency band allocated to the data communication system and the radio frequency band of another use (for example, a cellular phone) adjacent to the radio frequency band. Effect.

(Example 5)

Although not specifically mentioned in the first embodiment, each data communication device is provided with a regulation such that when a data of a frequency band corresponding to a single sideband not transmitted by another data communication device is provided, Do not transmit modulated signals or radio frequency signals.

As a result, as shown in FIG. 17, each data communication device exhibits an effect that the interference from the noncontact IC card 2 addressed to the other data communication device can be prevented.

As described above, the data communication device according to the present invention is suitable for use in a non-contact type wireless communication device or the like that can not be started unless a power source such as a battery is mounted and power is supplied from the outside.

Claims (12)

Radio frequency signal oscillating means for oscillating a radio frequency signal; Modulation means for single sideband modulating the radio frequency signal oscillated from the radio frequency signal oscillation means and outputting the modulated signal of the single side band in accordance with data addressed to the contactless wireless communication device; Transmitting means for transmitting a modulated signal output from said modulating means or a radio frequency signal oscillated from said radio frequency signal oscillating means; Receiving means for receiving a modulated signal of both side bands transmitted from the non-contact wireless communication device when a radio frequency signal is being transmitted from the transmitting means; Demodulation means for demodulating data from the modulated signal received by said receiving means Data communication device having a. The method of claim 1, A single sideband modulator for single sideband modulating a digital signal representing data addressed to a contactless wireless communication device by a digital circuit, a D / A converter for converting a digital modulated signal by the single sideband modulator into an analog signal, and the D And a modulating means using a multiplier for multiplying the modulated signal after conversion by the / A converter and a radio frequency signal, and a filter for removing a single sideband of the multiplied signal output from the multiplier. . The method of claim 1, The demodulation means extracts a modulation signal of a single side band from a modulation signal of both side bands received by the receiving means, and demodulates data from the modulation signal of the single side band. The method of claim 3, wherein Demodulation means, If the modulated signal output from the modulating means is a modulated signal of the upper band, the modulated signal of the lower band is extracted from the modulated signal of the two side bands received by the receiving means, If the modulated signal outputted from the modulating means is a modulated signal of the lower band, extracting the modulated signal of the upper band from the modulated signal of the two bands received by the receiving means. Data communication device, characterized in that. The method of claim 3, wherein A single sideband eliminator that removes the single sideband of the modulated signal of both sidebands received by the receiving means, and outputs a modulated signal of the single sideband, and the single sideband eliminator Demodulation means using a single side band regenerator for reproducing the single side band and outputting modulation signals of both side bands, and a data demodulator for demodulating data from the modulated signals of the two side bands output from the single side band regenerator A data communication device. The method of claim 1, And a modulating means outputs a modulated signal including a carrier component when outputting a modulated signal of a single side band. When the radio frequency signal is modulated according to the data addressed to the contactless radio communication device, the radio frequency signal is transmitted and the radio frequency signal is transmitted while the radio frequency signal is transmitted. A data communication method for demodulating data from modulated signals of both side bands when receiving a modulated signal of both side bands from a communication device. When the radio frequency signal is modulated on one side band according to the data to be transmitted, the modulated signal on the one side band or the radio frequency signal is transmitted, and the modulated signal on both side bands is received while the radio frequency signal is being transmitted. A data communication device for demodulating data from modulated signals of the two side bands; When receiving the modulation signal of the single sideband transmitted from the data communication device, demodulating data from the modulation signal, and receiving the radio frequency signal transmitted from the data communication device, both sides of the data addressed to the data communication device are received. A non-contact type radio communication device that modulates a wave band and transmits modulation signals of both side bands to the data communication device. Data communication system having a. The method of claim 8, When a plurality of data communication devices are provided, radio frequency signals having different frequencies from each other are assigned to each data communication device. The method of claim 9, Each data communication device does not transmit the modulation signal of the upper band unless another data communication device to which an adjacent band radio frequency signal is allocated transmits the modulation signal of the upper band and does not transmit the modulation signal of the lower band. If the lower band modulated signal is transmitted and the other data communication device transmits the lower band modulated signal and the upper band modulated signal is not transmitted, the lower band modulated signal is transmitted without transmitting the modulated signal of the lower band. Data communication system, characterized in that. The method of claim 9, The data communication apparatus to which the radio frequency signal having the lowest frequency is assigned transmits the modulation signal of the upper band without transmitting the modulation signal of the lower band, and the data communication apparatus to which the radio frequency signal having the highest frequency is assigned is the upper band A modulated signal of the lower band is transmitted without transmitting a modulated signal of the subband. The method of claim 8, Each data communication device does not transmit a signal in a frequency band corresponding to a single sideband not transmitted by another data communication device.

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