JPH1062518A - Carrier phase noise-suppressing circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enhance the reception sensitivity of a moving body-distinguishing apparatus by lessening leakage wave sent to a reception circuit of a questioning apparatus. SOLUTION: In this carrier phase noise suppressing circuit 6 of a questioning apparatus 1 of a moving body-distinguishing apparatus, an attenuation circuit 61 receives an input of a transmitted wave from the questioning apparatus 1 and attenuates the input transmitted wave as to make the level of an output signal almost equal to the level of a leakage wave to be sent to a synthetic circuit 63. Then, the output signal from the attenuation circuit 61 is sent to a phase-shift circuit 62. Further, the phase of the output from the attenuation circuit 61 is shifted by the phase-shift circuit 62 to be an approximately inverse phase to the phase of the leakage wave sent to the synthetic circuit 63 and the output of the phase-shift circuit is synthesized into a leakage wave to be directly received from a transmitted wave of the questioning apparatus 1 and a reflected wave from an answering apparatus 10 and the leakage wave is almost completely canceled in the synthetic circuit 63 and the output signals of the synthetic circuit 63 is transmitted to a reception circuit.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a carrier phase noise suppressing circuit for suppressing carrier and phase noise in a moving object discriminating apparatus.

[0002]

2. Description of the Related Art A conventional moving object identification apparatus is, for example, shown in FIG.
It was configured as shown. That is, the interrogator 15 is an unmodulated continuous wave or modulated wave (hereinafter also referred to as a transmission wave).
Is radiated as a microwave radio wave from the transmission circuit 2 for transmitting the radio wave via the antenna 3. Transponder 1 mounted on moving object
Numeral 0 indicates that the radio wave from the interrogator 15 is received via the antenna 11, and when the transmission wave is an unmodulated continuous wave, it is stored in the electronic circuit element 13 such as an integrated circuit or memory in the detection / modulation circuit 12. The transmitted wave radiated from the interrogator 15 is modulated by information such as the individual identification code and transmitted back via the antenna 11 (hereinafter also referred to as a reflected wave).

[0005] The interrogator 15 receives the reflected wave from the transponder 10 via the antenna 4 in the receiving circuit 5, reads the information carried on the reflected wave, determines the information in the information processing circuit 53, It determines whether the body can pass or not, and identifies the moving position of the moving body.

[0004] The transponder 10 mounted on the moving body is an interrogator 1
5 is received via the antenna 11, and when the transmission wave is a modulated wave, it is detected by the detection / modulation circuit 12, and when the level is equal to or higher than a predetermined level, the rewriting superimposed on the modulated wave is performed. Based on the code, information such as an individual identification code stored in the electronic circuit element 13 such as an integrated circuit or a memory is rewritten.

[0005] As a conventional mobile unit identification device, for example, as shown in FIG.
To radiate the transmission wave output from the transmission circuit 2 via the circulator 7 and the antenna 34,
There is also a mobile object identification device configured to receive the reflected wave from zero via the antenna 34 and the circulator 7. The mobile object identification device shown in FIG. 6 operates in the same manner as the mobile object identification device shown in FIG.

[0006]

In the above-mentioned conventional mobile object identification device, in the interrogator, the receiving circuit includes a reflected wave and a transmitting wave reduced in isolation between the transmitting antenna and the receiving antenna at the same time. (Hereinafter also referred to as a leaky wave). As the distance between the interrogator and the transponder increases, the level of the reflected wave decreases, but the level of the leaky wave does not change and becomes higher than the level of the reflected wave.

Therefore, the receiving high frequency (for example, 245)
There is a problem that the amplification degree of the amplifier in the signal receiving circuit (around 0 MHz) can be increased only within a range that is not saturated by the leaky wave.

Further, since a transmission wave is generated by the PLL circuit in the transmission circuit, phase noise exists near the transmission wave, and is received by the reception circuit of the interrogator at the same time as the leakage wave. However, as the distance between the interrogator and the transponder increases, the level of the reflected wave becomes lower, which causes a problem that the S / N of the receiving circuit of the interrogator deteriorates.

It is an object of the present invention to provide a carrier phase noise suppressing circuit which reduces a leak wave inputted to a receiving circuit of an interrogator, reduces a carrier and a phase noise, and improves a receiving sensitivity of a mobile unit identifying apparatus. With the goal.

[0010]

A carrier phase noise suppression circuit according to the present invention is a carrier phase noise suppression circuit in an interrogator of a mobile unit identification device, which receives a transmission wave output from the interrogator and attenuates the transmission wave. An attenuation circuit that causes the output signal from the attenuation circuit to be phase-shifted; and a phase-shift circuit that outputs a leaky wave directly received from the transmission wave of the interrogator and a reflected wave from the transponder of the moving object identification device. The attenuation circuit attenuates the input transmission wave so that the level of the output signal substantially matches the level of the leaky wave input to the synthesis circuit, and the phase shift circuit controls the synthesis circuit. To shift the output signal of the attenuation circuit so that the phase of the leakage wave is almost opposite to that of the input leak wave, and send the output signal of the synthesis circuit to the reception circuit of the interrogator And it features.

According to the carrier phase noise suppression circuit of the present invention, the transmission wave output from the modulation circuit of the interrogator is input to the attenuation circuit, and the level of the output signal of the attenuation circuit is input to the synthesis circuit. The input transmission wave is attenuated and output so as to substantially match the level of the leaky wave. The output signal from the attenuation circuit is input to the phase shift circuit, and the phase of the output signal from the attenuation circuit is shifted such that the phase of the output signal is substantially opposite to the phase of the leaky wave input to the synthesis circuit. In the combining circuit, the output of the phase shift circuit is combined with the leaky wave directly received from the transmission wave of the interrogator and the reflected wave from the transponder, and the combined output signal is sent to the receiving circuit of the interrogator.

Therefore, the leaky wave is combined with the output from the phase shift circuit in the combining circuit and almost cancelled, and the remaining leaked and reflected waves without being canceled out of the combining circuit are sent to the receiving circuit. In addition, the gain of the high-frequency amplifier of the receiving circuit can be increased, and the S / N of the mobile object identification device can be prevented from deteriorating, so that the reception sensitivity of the mobile object identification device can be improved.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a carrier phase noise suppression circuit according to the present invention will be described with reference to embodiments. FIG. 1 is a block diagram showing a configuration of a moving object identification device including a carrier phase shift noise suppression circuit according to one embodiment of the present invention.

FIG. 5 is a block diagram showing a mobile unit identification apparatus provided with a carrier phase shift noise suppression circuit according to an embodiment of the present invention.
The same reference numerals are given to the same components as those of the moving object identification device shown in FIG.

The transmission circuit 2 in the interrogator 1 is, for example, 24
Carrier oscillator 21 oscillating at a frequency in the 50 MHz band
An amplifier 22 for amplifying the carrier output from the carrier oscillator 21; and a modulation circuit 23 for modulating or non-modulating the carrier amplified by the amplifier 22 based on information from the information processing circuit 53. Is output from the amplifier 22, and the modulated carrier output from the amplifier 22 is modulated or unmodulated in the modulation circuit 23 based on a baseband signal which is information output from the information processing circuit 53. Then, the signal is transmitted via the antenna 3. The reception wave from the transponder 10 based on the transmission wave from the antenna 3 is received by the antenna 4.

The interrogator 1 further includes a carrier phase noise suppression circuit 6. The carrier phase noise suppression circuit 6 includes an attenuation circuit 61 that receives and attenuates an output signal from the modulation circuit 23, a phase shift circuit 62 that shifts a phase of an output signal of the attenuation circuit 61, an output signal of the phase shift circuit 62, and an antenna. And a combining circuit 63 for combining the reflected wave received through the combining circuit 4 with the reflected wave.

The interrogator 1 further includes a receiving circuit 5. The receiving circuit 5 includes an amplifier 51 as a high-frequency amplifier for amplifying an output signal from the combining circuit 63, and an amplifier 2
And a demodulation circuit 52 that receives the output signal from the amplifier 2, converts the frequency of the output signal of the amplifier 51 into a frequency that can be easily processed, demodulates the signal, and outputs the demodulated output signal to the signal processing circuit 53.

In the interrogator 1 configured as described above, when the reflected wave from the transponder 10 is received and distinct information is identified in the transponder 10, the modulating circuit 23 receives the reflected wave from the information processing circuit 53. The carrier signal is transmitted without modulation based on the output baseband signal. Therefore, in this case, the carrier output from the carrier oscillator 21 and amplified by the amplifier 22 are not modulated by the modulation circuit 23, output from the modulation circuit 23, and radiated from the antenna 3 as a transmission wave. The transmission wave is received by the transponder 10 via the antenna 4, and the transmission wave is modulated by, for example, the FSK modulation method or the PSK modulation method based on the individual information assigned to the transponder 10, and is transmitted through the antenna 4. It is sent back as a reflected wave.

When individual information stored in the electronic circuit element 13 such as the memory of the transponder 10 is rewritten, the carrier amplified by the amplifier 22 is transferred to the information processing circuit 53.
For example, based on the baseband signal output from
The signal is K-modulated and emitted from the antenna 3 as a transmission wave. The transmission wave is received by the transponder 10 via the antenna 4 and the individual information assigned to the transponder 10
The information is updated to information based on the K modulation signal. The modulation method in this case is not limited to ASK, but may be FSK, PSK, or the like.

On the other hand, the modulation output signal output from the modulation circuit 23 is attenuated by the attenuation circuit 61, and the signal attenuated by the attenuation circuit 61 is phase-shifted by the phase shift circuit 62.

The transponder 10 that has received the transmission wave radiates a reflected wave obtained by modulating the transmission wave based on the individual information stored in the electronic circuit element 13 and assigned to the transponder 10. Received by antenna 4. At the same time, the leaked wave is received by the antenna 4. The reflected wave and the leaked wave received by the antenna 4 are combined with the output signal from the phase shift circuit 62 in the combining circuit 63.

The synthesized output signal output from the synthesizing circuit 63 is amplified by the amplifier 51, and the signal output from the amplifier 51 is converted into a signal having a frequency which can be easily processed by the demodulation circuit 52 based on the output signal from the amplifier 22. The frequency-converted signal is demodulated and sent to the information processing circuit 53, where it is determined whether the demodulated signal is information such as an individual identification code assigned to the transponder 10. An output based on the identification result is output from the information processing circuit 53.

As described above, the leaked wave is received by the antenna 4 simultaneously with the reception of the reflected wave. On the other hand, the modulated wave from the modulation circuit 23 is supplied to the carrier phase noise suppression circuit 6, attenuated in the attenuation circuit 61, phase-shifted in the phase shift circuit 62, and the output signal from the phase shift circuit 62 is Is combined with the reflected wave and the leaked wave, and cancels with the received leaked wave. However, since the reflected wave is modulated in the transponder 10, it is output from the combining circuit 63 as it is. Synthesis circuit 6
The output signal output from 3 is amplified by the amplifier 51, demodulated by the demodulation circuit 52, and the individual identification code assigned to the transponder 10 is identified. Therefore, the provision of the carrier phase noise suppression circuit 6 does not affect information of the transponder 10 such as an individual identification code.

Now, the carrier frequency fc = 2450 MH
z, transmission power P ₀ = 10 dBm, isolation Pi between antenna 3 and antenna 4 = 30 dB, frequency shift Δf of reflected wave = 32 kHz, data speed = 4 kb
ps, gain of the amplifier 51 = 40 dB, P1 of the amplifier 51
dB (1 dB compression point input power) = 0
dBm.

From the above, since the transmission output P ₀ is 10 dBm and the isolation Pi between the antennas 3 and 4 is 30 dB, the transmission output P ₀ (10 dB)
m), the power value Pc of the leakage wave becomes −20 dBm. If the leaked wave is input to the amplifier 51 as it is, the amplifier 51 is saturated. However, in the carrier phase noise suppression circuit 6, the phase shift angle θ of the phase shift circuit 62 is a value at which the phase difference from the leaked wave becomes 180 degrees when the transmission frequency (carrier frequency) is 2450 MHz, that is, from the synthesis circuit 63. Is adjusted to a value at which the power value of the signal of the carrier frequency of 2450 MHz is minimized.

Further, a synthesizing circuit 63 is provided via a phase shift circuit 62.
The power value of the modulated wave input to the antenna 4 is adjusted by the attenuation circuit 61 so as to be the same as the power value of the leaky wave input to the antenna 4.

When adjusted as described above, according to the experimental results, the power of the leaky wave could be suppressed by 30 dB or more by the combined output from the combining circuit 63 that received the output from the phase shift circuit 62. This value depends on the accuracy of the oscillation frequency of the carrier oscillator 21, the accuracy of the phase shift of the phase shift circuit 62, and the accuracy of the attenuation of the attenuation circuit 61.

As described above, since the power value of the leaky wave output from the combining circuit 63 is suppressed by 30 dB or more, the suppression of this 30 dB and the isolation Pi (between the antennas 3 and 4) are performed. = 30 dB), the isolation is substantially 60 dB in total, and the leakage wave at the input end of the amplifier 51 is reduced by -50 dB. Therefore, the gain of the amplifier 51 is 50 at the maximum.
dB is possible. However, the gain of the amplifier 51 is 4
0 dB, which is below P1 dB with a margin when the gain of the amplifier 51 is 40 dB. Thus, there is a margin of 10 dB, the amplifier 51 does not saturate, and the problem of saturation is solved.

As for the phase noise, the frequency shift of the reflected wave is 32 kHz, and the S / N degradation becomes a problem
This is noise near 2 kHz. The carrier phase noise suppression circuit 6 suppresses the carrier and also reduces the phase noise near the carrier. FIG. 2 is a characteristic diagram showing a carrier suppression value with respect to a frequency. In FIG. 2, it is a carrier suppression measured value in the carrier phase noise suppression circuit 6,
It is -30 dB when the carrier frequency is 2450 MHz, and the carrier frequency is 2450 to 2450 MHz.
When the carrier suppression value is changed to 435 MHz in the decreasing direction, the carrier suppression value decreases. When the carrier suppression value is changed from 2450 to 2465 MHz in the increasing direction, the carrier suppression value decreases.

The characteristics of the noise reduction value after demodulation with respect to the carrier frequency are as shown in FIG. The noise reduction value is adjusted to be the maximum value (-14.6 dB in this example) at a carrier frequency of 2450 MHz. When the carrier frequency is changed from 2450 to 2435 MHz in the decreasing direction, the noise reduction value deteriorates and 2450
The noise reduction value is degraded when the frequency is changed in the increasing direction from to 2465 MHz.

Further, if noises other than the phase noise, such as noise figure of an amplifier, temperature noise of an antenna, and noise of other circuits such as a digital circuit are reduced, the noise reduction value is further improved.

According to the moving object identification apparatus provided with the carrier phase noise suppression circuit 6 according to the embodiment of the present invention, the noise is reduced by 14.6 dB. On the other hand, if the distance between the interrogator 1 and the transponder 10 is r (m) and the wavelength of the radio wave is λ (m), the propagation loss of the radio wave in the air is round-trip, so that the free space propagation loss L (DB) is L = 40 log [λ / (4
πr)]. Since noise reduction = loss reduction,
The enlarged value Δr of the response distance is 10 to the power of (14.6 / 40), and ΔrΔ2.3 times.

However, the longest response distance is 4 m in the conventional mobile object identification device shown in FIG. 5, and the longest response distance is provided in the mobile object identification device having the carrier phase noise suppression circuit 6 according to the embodiment of the present invention. Is 4 (m) × 2.3 = 9.2
(M), the range of use of the mobile object identification device is expanded.

Next, a description will be given of a case where a carrier phase noise suppressing circuit according to an embodiment of the present invention is provided in a moving object identification device using a circulator 7 as shown in FIG. FIG. 4 is a block diagram showing a configuration in which the carrier phase noise suppression circuit 6 according to the embodiment of the present invention is provided in the moving object identification device shown in FIG. 6 using the circulator 7.

As shown in FIG. 4, the output of the transmitting circuit 2 is supplied to a circulator 7 and also to a carrier phase noise suppressing circuit 6, and a combined circuit of the reflected wave via the circulator 7 and the carrier phase noise suppressing circuit 6 is provided. At 63, the signals are combined and the combined output is supplied to the receiving circuit 5.

Therefore, the operation in the case shown in FIG.
And the description is omitted to avoid duplication. In addition, instead of the circulator 7,
The same applies to the case where a directional coupler is used.

[0037]

As described above, according to the carrier phase noise suppression circuit according to the present invention, since the leaky wave is suppressed, it is possible to increase the gain of the high-frequency amplifier of the receiving circuit. Since the gain of the low-frequency amplifier that amplifies the demodulated output signal of the low-frequency amplifier can be reduced, it is possible to design a circuit that ignores the noise figure of the low-frequency amplifier. As a result, a low-cost low-frequency amplifier can be used.

Further, according to the carrier phase noise suppressing circuit of the present invention, since the phase noise is suppressed, the S / N of the moving object identification device provided with the carrier phase noise suppressing circuit of the present invention is good. That is, the distance between the interrogator and the transponder of the mobile object identification device can be increased. As a result, the range of use of the mobile object identification device is expanded.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of a mobile object identification device including a carrier phase noise suppression circuit according to an embodiment of the present invention.

FIG. 2 is a characteristic diagram showing carrier suppression characteristics of the carrier phase noise suppression circuit according to one embodiment of the present invention.

FIG. 3 is a characteristic diagram showing noise reduction characteristics of the carrier phase noise suppression circuit according to one embodiment of the present invention.

FIG. 4 is a block diagram illustrating a configuration of another moving object identification device including a carrier phase noise suppression circuit according to one embodiment of the present invention.

FIG. 5 is a block diagram showing a configuration of a conventional moving object identification device.

FIG. 6 is a block diagram showing a configuration of another conventional moving object identification device.

[Explanation of symbols]

 Reference Signs List 1 interrogator 2 transmission circuit 3, 4, 11, and 34 antenna 5 reception circuit 6 carrier phase noise suppression circuit 7 circulator 10 transponder 21 carrier oscillator 22 and 51 amplifier 23 modulation circuit 52 demodulation circuit 53 information processing circuit 61 attenuation circuit 62 transfer Phase circuit 63 Synthesis circuit

Claims (1)

[Claims] 1. A carrier phase noise suppression circuit in an interrogator of a mobile unit identification device, comprising: an attenuation circuit for inputting and attenuating a transmission wave output from the interrogator; and a phase shifter for an output signal from the attenuation circuit. A phase shift circuit, and a combining circuit that combines a leaky wave directly received from the transmission wave of the interrogator and a reflected wave from the transponder of the moving object identification device with an output signal of the phase shift circuit. The input transmission wave is attenuated so that the level of the output signal substantially matches the level of the leaky wave input to the synthesis circuit, and the phase shift circuit is set to be almost in phase with the phase of the leaky wave input to the synthesis circuit. Phase shift the output signal of the attenuation circuit,
And a carrier phase noise suppressing circuit for sending an output signal of the combining circuit to a receiving circuit of the interrogator.