JP3420009B2 - Radio wave reception system - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an improvement in a television radio wave reception system, in particular, for eliminating a fading phenomenon caused by fluctuation of an optical fiber for transmission. The present invention is not limited to a television radio wave reception system, and further relates to improvement of a radio wave reception system using an optical fiber in the field of mobile communication.

[0002]

2. Description of the Related Art In a television relay broadcasting station in which a transmitting station and a receiving station are separated from each other, a transmission system using an optical cable has been proposed instead of a transmission system using a conventional coaxial cable.

FIG. 11 is a block diagram showing the basic structure of such a transmission system. Reference numeral 1 denotes a TV radio wave, which is received by the antenna 2 and outputs a voltage corresponding to the strength of the TV radio wave. 3 is a light intensity modulator, and the antenna 2
Output voltage is applied to give a change in light intensity proportional to the applied voltage. The receiving station 4 including the antenna 2 and the light intensity modulator 3 and the transmitting station 5 including the light sources 6a and 6b, the photodetector 7 and the amplifier 8 are located at a distance of several km, and the optical fibers 9 and 10 are provided between them. Connected by. With the light intensity modulator 3,
The TV radio wave converted into the change in light is converted into an electric signal by the photodetector 7, and is output 11 as a TV signal via the amplifier 8.

In such a system, the light intensity modulator 3
As the above, a ferroelectric light intensity modulator using the electro-optic effect is used. Specifically, an optical intensity modulator in which a Mach-Zehnder type optical waveguide is formed on a lithium niobate substrate is used. The modulator adopts a polarization input type configuration using the r33 coefficient from the viewpoint of modulation efficiency, and the modulation degree of the light output changes according to the polarization state of the incident light.

On the other hand, the light source 6 for outputting linearly polarized light and the modulator 3 are connected by an optical fiber 9. When a polarization plane-maintaining optical fiber (hereinafter referred to as “PMF”) is used as the optical fiber 9, the incident polarized light to the light intensity modulator 3 is
Although it can be kept almost constant, PMF is very expensive and has poor cost performance when used for several kilometers. On the other hand, when a single mode optical fiber (hereinafter referred to as "SMF") is used, it is remarkably advantageous in terms of cost, but polarization of the optical fiber output is caused by mechanical and temperature fluctuations of the optical fiber. The state fluctuates, and a so-called fading phenomenon occurs in which the TV signal fluctuates.

[0006]

The problem is to prevent the influence of optical fiber fluctuation when the SMF is used.
In the conventional example, a so-called non-polarized light source is used in which two light sources 6a and 6b are used as light sources and the polarizations of the respective outputs are orthogonal to each other. In this case, there are problems that it is necessary to maintain the orthogonality of the polarization directions of both light sources, that the light outputs of both light sources be matched, that the utilization efficiency is half of the total light output, and that the light sources generate heat. In addition, the light source is very expensive, and there are drawbacks such as poor cost performance.

[0007]

The present invention is directed to a receiving end having an antenna for receiving radio waves and a light intensity modulator to which a voltage corresponding to the intensity of the radio waves received by the antenna is applied, a light source and an optical device. In a radio wave receiving method in which a transmission end including a detector is connected by a single mode optical fiber, at the transmission end, scrambles the polarization of the light source, so that the polarization state of the light source light changes periodically, The polarization state is detected, and the polarization state is controlled according to the detected polarization state. The present invention includes a receiving end including an antenna for receiving radio waves and a light intensity modulator to which a voltage corresponding to the intensity of radio waves received by the antenna is applied.
A transmission end including a light source and a photodetector, in a radio wave reception system connected by a single mode optical fiber, at the transmission end, a polarization scrambler, so that the polarization state of the light source light periodically changes, A control means for detecting the polarization state and controlling the polarization state according to the detected polarization state is provided.

According to the present invention, in a radio wave receiving system, a polarization scrambler is provided at a transmission end and a polarization state is detected so that the polarization state of the light source light periodically changes, and the polarization state is detected according to the detected polarization state. , Control means for controlling the polarization state,
Branching means for sending the optical output of the polarization scrambler to a receiving end and branching a part of the optical output; polarization monitoring means for detecting the polarization state of the branched light split by the branching means; By monitoring means,
A polarization control means for controlling the polarization drive means is provided according to the detected polarization state of the branched light, and the polarization monitor means is an oscillator having a frequency f2 lower than the drive frequency f1 of the polarization scrambler. Piezoelectric element driving means for driving a piezoelectric element, a single mode optical fiber that changes the polarization state of the branched light from the branching means according to the driving frequency of the piezoelectric element, and one direction of output light from the single mode optical fiber , A second photodetector for photoelectrically converting the light transmitted from the polarizer, and a filter means for passing only the frequency f2 component of the output from the second photodetector. And is provided. According to the present invention, in a radio wave reception system, a polarization scrambler is provided at a transmission end, and the light source light is made to have a predetermined polarization direction and made incident on the polarization scrambler, and a frequency f1 that is at least twice the frequency of the received radio wave
And a polarization drive means for driving the polarization scrambler,
Branching means for sending the optical output of the polarization scrambler to a receiving end and branching a part of the optical output; polarization monitoring means for detecting the polarization state of the branched light split by the branching means; By monitoring means,
A polarization control means for controlling the polarization drive means is provided according to the detected polarization state of the branched light, and the polarization monitor means is an oscillator having a frequency f2 lower than the drive frequency f1 of the polarization scrambler. Piezoelectric element driving means for driving a piezoelectric element, a single mode optical fiber that changes the polarization state of the branched light from the branching means according to the driving frequency of the piezoelectric element, and one direction of output light from the single mode optical fiber , A second photodetector for photoelectrically converting the light transmitted from the polarizer, and a filter means for passing only the frequency f2 component of the output from the second photodetector. And is provided. According to the present invention, in the radio wave receiving system, the polarization control means receives the signal of the frequency f2 from the polarization monitor means and detects a signal amplitude of the frequency f2, and a direct current output from the detection means. And a comparing means for comparing with the reference value of and outputting a DC voltage according to the difference. According to the present invention, in the radio wave reception system, the polarization driving means amplifies an oscillator having a frequency f1 and an output voltage of the oscillator, and a gain variable for varying the amplification degree by receiving a comparison output from the polarization controlling means. And an amplifier. The present invention is characterized in that, in the radio wave reception system, the averaging means for averaging the outputs from the photodetectors is provided. According to the present invention, in a radio wave receiving system, an optical waveguide branch portion formed by an optical waveguide and a branched optical waveguide portion formed by an optical waveguide are provided on a lithium niobate substrate on which the polarization scrambler is formed. And a polarization control unit driven at a frequency f2.

According to the present invention, with the above-mentioned configuration, only one light source is required, no delicate adjustment as in the prior art is required, the influence of heat generation is reduced, and the cost can be reduced. It was

[0010]

Embodiments of the present invention will be described in detail with reference to the drawings. Hereinafter, in the drawings, portions having the same function are indicated by the same numbers, the dotted line portion is an optical fiber, and the solid line portion is a conducting wire.

FIG. 1 shows a block diagram of an embodiment of the present invention. The light source 6 is an LD-excited YAG laser, which is a linearly polarized laser with a relative noise intensity RIN value of −170 dBm / Hz and a low noise of 1.3 μm. The polarization of the light from the light source 6 is held by the PMF 13 and the polarization scrambler 1
2 is input with a predetermined polarization. Polarization scrambler 12
Is an optical waveguide type modulator of lithium niobate, and the polarization state of the optical output changes according to the drive voltage 38 from the polarization drive means 18.

FIG. 9 is an explanatory view of the polarization scrambler. More specifically, FIG. 9 (a) shows the time variation of the polarization state of the scrambler and its output light, and FIG.
FIG. 7B is a diagram showing a time change of polarization on the Boincare sphere 20. In the polarization scrambler 12, 4 for each azimuth of different electro-optic coefficients r13 and r33.
When light is incident in a polarization direction of 5 ° and an AC voltage of frequency f1 is applied in the z-axis direction, the polarization state of the output changes as shown by the locus of a closed curve 21 on the Boincare sphere 20 at the cycle of frequency f1. To do. In FIG. 9, the closed curve 21 indicates the state P,
The locus which changes to L, Q, and R and returns to P is shown. Which closed curve is taken depends on the applied AC voltage value. The average degree of polarization in the period 1 / f1 period is evaluated as a DOP value.

The DOP value is defined by the following equation (1). ^{DOP = (<S1> 2 +} <S2> 2 + <S3> 2) 1/2 / S0 (1) where, <S1> is the time average value of the horizontal polarization component, <S2> is 45 ° polarization <S3> is the time average value of the left-handed circularly polarized light component, and S0 is the incident light intensity. The smaller the DOP value, the more unpolarized the light is.

FIG. 8 is a diagram showing the dependency of the DOP value on the applied voltage. The DOP value increases as the applied voltage deviates from the optimum value (V _s ).

The characteristics of the polarization scrambler 12 have temperature dependence, and it is necessary to adjust the applied voltage according to the ambient temperature. The polarization monitor means 16 and the polarization control means 1 of FIG.
7. The light branching means 15 and the polarization driving means 18 are feedback control means for automatically applying the optimum voltage depending on the temperature, and branch a part of the output light from the polarization scrambler 12, The polarization state is detected, a control voltage corresponding to the polarization state is output, and the voltage 38 applied to the polarization scrambler 12 is adjusted so that the polarization state is always kept in the non-polarization state.

The other light from the optical branching means 15 is SMF.
9 and is sent to the light intensity modulator 3 of the receiving station 4. In the light intensity modulator 3, the television radio wave 1 received by the antenna 2 is added as a change in the intensity of light as an optical signal, and SM
It is returned to the photodetector 7 provided in the transmitting station 5 via F10. The output from the photodetector 7 passes through the TV radio signal,
Low-pass filter 19 that does not pass higher frequency components
Are averaged, and only the television radio signal is output as the output 11.

The effect of the polarization scrambler will be described with reference to FIG.
explain in detail. For convenience of explanation, the television radio signal is a digital signal (FIG. 7A) having a period T3 (T3 (= 1 / f3) >> T1 (= 1 / f1)), and 100% light intensity modulation is obtained. 7 (b), (c), and (d) show the case where the DOP value is optimum and the optical fiber 9 has fluctuations when the DOP value is optimum and there is no fluctuation in the fiber 9 (generally, The fluctuations f4 << f3) indicate the output from the photodetector 7 when the DOP value deviates from the optimum value and there is fluctuation in the optical fiber 9. The vertical line indicates the scramble frequency f1 and its envelope. Line 24 shows peak-to-peak (pp) transmission, D as in Figure 7 (d).
When the OP value deviates from the optimum value, the symmetry of the envelope of the signal disappears, and as a result, the average value fluctuates. When these are passed through a low-pass filter 19 that cuts the f1 component, the waveforms shown in FIGS. 7 (b '), (c'), and (d ') are obtained. 7B 'and 7C' show the same waveforms 25 and 26 as the applied signal 22, showing that the influence of the fluctuation of the optical fiber 9 is eliminated. But DO
When the P value deviates from the optimum value, the fluctuation component is superimposed on the television signal as shown in FIG. 7 (d '). As described above, since only a single polarization component is extracted from the polarization components scrambled at the frequency f1, the extracted light (that is, the output of the light intensity modulator 3) contains the intensity modulation component at the frequency f1. Then, the average value of the f1 component becomes the signal component. That is, in this system, the light utilization rate is 50
% (-3 dB).

Next, the method of controlling the polarization scrambler in the embodiment of the present invention will be described in detail. Figure 2
FIG. 2 is a block diagram detailing a portion related to polarization scrambler control in FIG. 1. A part (about 1%) of the output from the polarization scrambler 12 is branched by the optical branching means 15 and enters the polarization monitoring means 16. The polarization monitor means 16 adds a polarization fluctuation corresponding to the fluctuation of the optical fiber of the transmission line, and the piezoelectric element 27 has the SMF 3 on the outer circumference thereof.
0 is wound, and distortion is generated in the radial direction according to the applied low-frequency f2 voltage, and thus the refractive index change in the radial direction is given to the SMF 30, and the polarization state of the output light from the SMF 30 is changed. is there. An oscillator 28 having a frequency f2 lower than that of television radio waves and an amplifier 2 for driving the piezoelectric element 27
9, a polarizer 31 that transmits only polarized light in a certain direction out of the output light from the SMF 30 and sends it to the second photodetector, a second photodetector 32, and the second photodetector 32. Low-pass filter 33 that transmits only the f2 component of the output of
It consists of and.

FIG. 4 shows how the output of the filter 33 changes according to the voltage applied to the polarization scrambler 12. The f2 component becomes minimum at the optimum applied voltage (Vs), and the f2 component increases as it deviates from Vs.
The fluctuation added to the SMF 30 via the piezoelectric element 27 is
It is equivalent to the fluctuation of the transmission line 9 and that the frequency f2 component is small means that the polarization scrambler is effectively functioning. That is, the voltage 38 applied to the polarization scrambler 12 may be controlled so that the output of the filter 33 is minimized.

Further, referring to FIG. 2, the polarization driving means 18
Is an oscillator 34 having a frequency f1, a thermostatic bath 35 for stabilizing the output of the oscillator 34, an amplifier for amplifying the output of the oscillator 34, and a gain variable amplifier whose gain is changed according to the size of the control means 37. And 36. Of frequency f1,
A voltage V38 whose amplitude is changed according to the control means 37 is output and applied to the polarization scrambler 12.

The voltage of the control means 37 is the same as that of the polarization control means 17.
The polarization control means 17 receives the output from the filter 33, squares the detector 39, rectifies the detected output, a peak hold circuit 40, a reference value 42, and the reference value. 42 and the peak hold value, and a comparison circuit 41 that outputs a DC voltage corresponding to the difference as a control signal 37. The reference value 42 means a DOP value allowed by the system, and a DOP value equal to or less than the reference value.
The polarization scrambler 12 is driven so that the value is always obtained.

The filter 33, the detection circuit 39, the peak hold circuit 40, etc. are ordinary circuits, and may have the same function, for example, an integrator, a synchronous detection circuit, and an averaging circuit, respectively. Of course.

As described above, according to the present invention, the polarized light from the light source is scrambled by the polarization scrambler 12, and the light source can be made non-polarized. Further, by using a part of the output light from the polarization scrambler 12, the polarization state is monitored, and feedback control is always performed so that the DOP value is equal to or lower than the reference value. A light source can be realized.

FIG. 3 shows another example of a stress applying method for monitoring fluctuations. This is a so-called squeezer type polarization modulator in which the SMF 30 is pressed against the metal 31 by the piezoelectric element 27 ', and can be used as a substitute for the piezoelectric element 27 in FIG.

The system according to the present invention has a great advantage in that it is remarkably advantageous in terms of cost and does not require delicate adjustment as in the conventional example.

FIG. 5 shows another embodiment of the present invention. This is a method in which polarization modulation of frequency f2 for monitoring the polarization state is superimposed on the polarization scrambler 12 as a pilot signal, and the superposition circuit 42 adds the signals of frequencies f1 and f2.

The branched light is directly reflected by the polarizer 31.
The light enters the photodetector 32 via the filter 33 and only the frequency f2 component is extracted by the filter 33. The gain of the variable gain amplifier 36 is controlled via the polarization controller 17 so as to minimize the f2 component. In this case, the return light from the light intensity modulator 3 also contains a component of frequency f2,
As the averaging circuit 19, here, a bandpass filter 43 that does not pass the frequency components f1 and f2 but only the frequency component of the television radio wave is used.

FIG. 6 is a diagram showing a third embodiment which is a modification of the polarization monitor means. A first polarization scrambler portion 45, an optical waveguide branch portion 46, and a second polarization scrambler portion 47 on the branched optical waveguide portion are provided on a lithium niobate substrate 44. The first polarization scrambler is driven at frequency f1 and the second polarization scrambler is driven at frequency f2. Similar to the above, the frequency f2
The drive voltage of the frequency f1 is feedback-controlled so that the component becomes the minimum.

FIG. 10 is a diagram showing a fourth embodiment.
In this embodiment, the light intensity modulator 48 is a reflection type modulator, and the transmitting station 5 and the receiving station 4 have a single SMF.
Connected at 49. The optical signal on which the television radio signal from the light intensity modulator 48 is superimposed propagates in the SMF 49 in the reverse direction, and is separated in the optical circulator 50. The procedure after the separation, the polarization scrambler function and the control are the same as those of the embodiment shown in FIGS. With this configuration, the same effect as that of the embodiment can be obtained.

[0030]

The effect of depolarizing the polarized light of the light source by using the polarization scrambler will be described with reference to FIGS. 12 and 13. FIG. 12 is a diagram showing the waveform of the detected television signal output 11 in the embodiment of the present invention using the polarization scrambler. 100 denotes a carrier wave, 101 and 102 denote envelopes of the carrier wave 100 which is a video signal, and 103 denotes
Average level, height 1 proportional to the amount of light to the detector 7
Have 04. Reference numeral 105 indicates the image amplitude. As shown in the figure, due to the effect of the polarization scrambler, the average level 1
03 keeps a constant level. FIG. 13 shows FIGS.
In ten embodiments of the present invention, a polarization scrambler 12
It is a figure which shows the waveform of the television signal output 11 when the function of is stopped. Average level 1 due to fiber fluctuations
06 fluctuates between the maximum point 107 and the minimum point 109.
The height 108 at the maximum point 107 is twice the height 104 in FIG. As shown, the image amplitude 105 changes according to the height of the average level 106, and the amplitude becomes 0 at the minimum point 109. That is, a fading phenomenon occurs in which the image amplitude changes due to the fluctuation of the fiber, which is a slow change in time. However, as described with reference to FIG. 12, if the polarization scrambler is used to depolarize the light source, the signal amplitude becomes 1/2, but a constant average level 103 that is not affected by fiber fluctuation is obtained. To be

As described above in detail, according to the present invention, a non-polarized light source which does not depend on the ambient temperature can be constructed at low cost, and a stable and inexpensive television radio wave reception system can be realized.

Although the television radio wave receiving system has been described in each of the above-described embodiments, the same configuration can be applied to the mobile communication field and the same effect can be obtained.

[Brief description of drawings]

FIG. 1 is a block diagram of a first embodiment of a radio wave receiving system according to the present invention.

FIG. 2 is a block diagram of a feedback unit of the first embodiment of the radio wave receiving system according to the present invention.

FIG. 3 is a squeezer type polarization modulator.

FIG. 4 is a diagram showing the dependence of the output of the filter 33 on the applied voltage 38.

FIG. 5 is a diagram showing a second embodiment.

FIG. 6 is a diagram showing a third embodiment.

FIG. 7 is a diagram illustrating the function of a polarization scrambler.

FIG. 8 is a diagram showing a relationship between a DOP value and an applied voltage.

FIG. 9 is a diagram showing a state of output polarization of a polarization scrambler.

FIG. 10 is a diagram showing a fourth embodiment.

FIG. 11 is a diagram showing a principle configuration of a conventional radio wave receiving system.

FIG. 12 is a television signal output waveform based on the system of the present invention.

FIG. 13 shows a television signal output waveform for a system without a polarization scrambler.

[Explanation of symbols]

1 TV radio wave 2 antenna 3,48 Light intensity modulator 9,10,49 SMF 6,6 'YAG laser 7,32 photo detector 12,44 Polarization scrambler 15 Optical branch 16 Polarization monitor means 17 Polarization control means 18 Polarization driving means 27,27 'Piezoelectric element 33,43 Filter

─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Sakuhisa Iwaiwa 2-2-1 Jinnan, Shibuya-ku, Tokyo Inside the Japan Broadcasting Corporation Broadcasting Center (72) Hiroki Fujio 2-2-1, Jinnan, Shibuya-ku, Tokyo Japan Broadcasting Corporation Broadcast Center (72) Inventor Tadashi Ishikawa 2-2, Jinnan 2-chome, Shibuya-ku, Tokyo Japan Broadcasting Corporation Broadcast Center (56) Reference JP 9-8737 (JP, A) JP JP 6-85749 (JP, A) JP 7-168218 (JP, A) JP 5-91048 (JP, A) JP 8-54590 (JP, A) Shimozu Shinichi et al. Low DOP: LiNbO3 polarization scrambler, Proceedings of IEICE General Conference, Electronics 1, Japan, The Institute of Electronics, Information and Communication Engineers, March 10, 1995, C- 281, P281 (58) Fields investigated (Int.Cl. ⁷ , DB name) H04B 10/00-10/28 H04J 14/00-14/08 H04N 7/22

Claims (6)

(57) [Claims] 1. A receiving end including an antenna for receiving a radio wave and a light intensity modulator to which a voltage corresponding to the intensity of the radio wave received by the antenna is applied, and a transmitting end including a light source and a photodetector. In a radio wave reception system in which a single mode optical fiber is connected to a polarization scrambler at the transmission end, the polarization state is detected so that the polarization state of the light source light changes periodically, and the detected polarization state According to the control means for controlling the polarization state and the optical output of the polarization scrambler is transmitted to the receiving end, the branching means for branching a part of the optical output, and the branched light branched by the branching means. Polarization monitor means for detecting the polarization state, and polarization control means for controlling the polarization drive means according to the polarization state of the branched light detected by the polarization monitor means are provided. The polarization monitor means is an oscillator having a frequency f2 lower than the drive frequency f1 of the polarization scrambler, the piezoelectric element driving means for driving the piezoelectric element, and the polarization state of the branched light from the branching means. A single-mode optical fiber that changes according to the drive frequency of the element, a polarizer that transmits only one-directional polarized light of the output light from the single-mode optical fiber, and a second photoelectric converter that photoelectrically converts the light transmitted from the polarizer. A radio wave reception system comprising: a photodetector; and a filter means for passing only the frequency f2 component of the output from the second photodetector. 2. A receiving end including an antenna for receiving radio waves and a light intensity modulator to which a voltage corresponding to the intensity of the radio waves received by the antenna is applied, and a transmitting end including a light source and a photodetector. In a radio wave reception system in which a single mode optical fiber is connected, a polarization scrambler is provided at the transmitting end, and the light source light is directed in a predetermined polarization direction and is incident on the polarization scrambler, and the frequency of the received radio wave is A polarization driving means for driving the polarization scrambler at a frequency f1 which is more than double, a branching means for transmitting the optical output of the polarization scrambler to a receiving end, and a part of the optical output for branching; Polarization monitor means for detecting the polarization state of the split branched light, and the polarization driving means according to the polarization state of the split light detected by the polarization monitoring means. A polarization control means for controlling the step is provided, and the polarization monitor means is an oscillator having a frequency f2 lower than the drive frequency f1 of the polarization scrambler, a piezoelectric element drive means for driving a piezoelectric element, and a branching means. A single-mode optical fiber that changes the polarization state of the branched light according to the driving frequency of the piezoelectric element, a polarizer that transmits only one direction of the output light from the single-mode optical fiber, and a polarizer that transmits the polarized light. A radio wave reception system comprising: a second photodetector for photoelectrically converting the above-mentioned light; and a filter means for passing only the frequency f2 component of the output from the second photodetector. 3. The polarization control means receives a signal of frequency f2 from the polarization monitor means and detects a signal amplitude of frequency f2, a DC output from the detection means, and a predetermined reference value. 3. The radio wave receiving system according to claim 2, further comprising: a comparing unit that compares the values and outputs a DC voltage according to the difference. 4. The polarization driving means includes an oscillator having a frequency f1 and a variable gain amplifier that amplifies an output voltage of the oscillator and changes its amplification degree by receiving a comparison output from the polarization control means. The radio wave receiving system according to claim 2, wherein the radio wave receiving system is provided. 5. The radio wave receiving system according to claim 2, further comprising averaging means for averaging the output from the photodetector. 6. An optical waveguide branch portion formed of an optical waveguide and a branched optical waveguide portion formed on the lithium niobate substrate on which the polarization scrambler is formed, and a frequency f2 is provided in the branched optical waveguide portion. 6. A polarization control means driven by means of.
The radio wave reception system described in paragraph.