JP2004320221A - Fixed wireless access system and instrument thereof - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fixed wireless access system which is capable of transmitting wireless access signals besides ground wave broadcasting signals, BS broadcasting signals, and CS broadcasting signals among a plurality of fixed wireless access means. <P>SOLUTION: The fixed wireless access means is mainly equipped with an FWA antenna 3, an outdoor unit (ODU) 1, and an indoor unit (IDU) 2 connected to the outdoor unit 1 through a single cable 21. A BS converter 4b, a CS converter 5b, and a VHF/UHF booster 7 besides the FWA antenna 3 are connected to the outdoor unit 1. FWA intermediate frequency signals transmitted from the FWA antenna 3 are set in a certain region so as not to interfere with the intermediate frequency signals of VHF, UHF, BS, and CS, and these signals are superimposed so as to use the single cable 21 in common between the ODU 1 and the IDU 2. The ODU 1 generates the power supply voltages of the VHF/UHF booster 7, the BS converter 4b, and the CS converter 5b on the basis of an FWA power supply voltage supplied from the IDU 2, and supplies the power supply voltages to them. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a fixed wireless access system and a fixed wireless access device for transmitting a wireless access signal in addition to a terrestrial broadcast signal, a BS broadcast signal, and a CS broadcast signal between a plurality of fixed wireless access means using the same cable. About.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, a SMATV (Satellite Master Antenna Television) system capable of receiving signals of terrestrial broadcasting (VHF, UHF) and satellite broadcasting (BS, CS) via one cable is known (for example, Patent Document 1). reference). In this SMATV system, since each signal of VHF, UHF, BS, and CS is transmitted via one cable, the indoor unit (IDU: In Door Unit) to the outdoor unit (ODU: Out Door)
The power supply to the unit (Unit) may be considered only for BS and CS.
[0003]
This is because, in the case of VHF and UHF, the power supply voltage is not superimposed and only the RF signal is transmitted, while the power supply voltage of +15 V is required for BS, and the power supply voltage of +11 V or +15 V is required for CS. Because it is needed. Even when a booster is connected for receiving VHF and UHF, the power supply voltage requires only +15 V, so that the cable can be directly connected.
[0004]
Conventionally, a communication satellite signal receiving system that receives a signal from a communication satellite (CS) that can use a plurality of channels is also known (for example, see Patent Document 2).
[0005]
[Patent Document 1]
Japanese Patent No. 2506466
[Patent Document 2]
JP-A-2-140022
[0006]
[Problems to be solved by the invention]
However, in the above conventional example, when a fixed wireless access (FWA) device is newly installed, one cable connecting an outdoor unit (ODU) and an indoor unit (IDU) used in the FWA device is used. The transmission of each signal of VHF, UHF, BS, and CS has not been considered, and the following circumstances exist when one cable is shared. That is, the power supply voltage of the outdoor unit used in the FWA device is −48 V, which is significantly different from the power supply voltages (+15 V, +11 V) used in the outdoor units of BS and CS. Also, the current consumption is much higher than BS and CS. Therefore, it was necessary to provide an external power supply for BS and CS. In the case of CS, it is necessary to supply a different power supply voltage depending on the plane of polarization for polarization identification.
[0007]
The present invention has been made in view of the above-mentioned conventional circumstances, and in addition to the terrestrial broadcast signal, the BS broadcast signal, and the CS broadcast signal, the radio access signal is the same between a plurality of fixed radio access means. It is an object of the present invention to provide a fixed wireless access system and a fixed wireless access device that can be transmitted by a cable.
[0008]
[Means for Solving the Problems]
The fixed radio access system according to the present invention is capable of connecting a radio access antenna for transmitting / receiving a radio access signal and at least one of a terrestrial broadcast booster, a BS broadcast converter, and a CS broadcast converter. Frequency conversion means for frequency-converting a radio access signal transmitted and received by an antenna for terrestrial broadcasting, a terrestrial broadcasting signal output from the terrestrial broadcasting booster, a BS broadcasting signal output from the BS broadcasting converter, or the CS A first fixed wireless access unit having: a combining unit that superimposes and combines a wireless access signal frequency-converted by the first frequency converting unit on a CS broadcast signal output from a broadcasting converter; The terrestrial broadcast signal, the BS broadcast signal or Distribution means for distributing the radio access signal superimposed on the CS broadcast signal; second frequency conversion means for frequency-converting the radio access signal distributed by the distribution means; and a signal to be transmitted to the first fixed radio access means And a second fixed wireless access means having a power supply superimposing means for superimposing a predetermined power supply on the first fixed wireless access means, wherein the first fixed wireless access means and the second fixed wireless access means are connected via the same cable. Then, the signal synthesized by the synthesizing means and the signal on which the predetermined power is superimposed by the power superimposing means are transmitted.
[0009]
Therefore, between the first fixed wireless access means and the second fixed wireless access means, not only the terrestrial broadcast signal, the BS broadcast signal, and the CS broadcast signal, but also the wireless access signal can be transmitted by the same cable. As a result, when installing the first fixed wireless access unit and the first fixed wireless access unit, a system can be constructed without newly installing a cable.
[0010]
Further, in the fixed wireless access system according to the present invention, the first fixed wireless access means includes a power supply voltage of the BS broadcast converter and a power supply voltage of the CS broadcast converter according to a superimposed signal transmitted from the second fixed wireless access means. A power supply voltage generation circuit for generating at least one of the power supply voltages; Therefore, an external power supply for the BS broadcast converter and the CS broadcast converter is not required, so that the installation time can be reduced and the installation cost can be reduced.
[0011]
Further, in the fixed wireless access system of the present invention, the second fixed wireless access means has a detection means for detecting a polarization identification signal from a CS broadcast decoder connected to the second fixed wireless access means, The power supply superimposing means superimposes the predetermined power on a signal obtained by frequency-converting the polarization identification signal detected by the detection means, and sends the signal to the first fixed wireless access means. A power supply voltage generation circuit for generating a power supply voltage of the CS broadcast converter based on the polarization identification signal obtained by frequency-converting the signal transmitted from the second fixed wireless access means. For this reason, even if a CS broadcast converter that needs to supply a plurality of different polarization planes and supply different power supply voltages according to the polarization planes is provided, it can be handled without providing a new external power supply.
[0012]
Further, the fixed wireless access device of the present invention is a fixed wireless access device to which at least one of a terrestrial broadcast booster, a BS broadcast converter, and a CS broadcast converter can be connected, and transmits and receives wireless access signals. First frequency conversion means for frequency-converting a radio access signal transmitted and received by a radio access antenna; a terrestrial broadcast signal output from the terrestrial broadcast booster; a BS broadcast signal output from the BS broadcast converter; Combining means for superposing and combining the radio access signal frequency-converted by the first frequency converting means with the CS broadcast signal output from the CS broadcast converter.
[0013]
The fixed wireless access device according to the present invention further includes a distribution unit that distributes a radio access signal from a signal in which a radio access signal is superimposed on a terrestrial broadcast signal, a BS broadcast signal, or a CS broadcast signal, and the distribution unit distributes the radio access signal. A second frequency conversion unit for converting the frequency of the radio access signal and a power supply superimposing unit for superimposing a predetermined power supply on a signal to be sent out are provided.
[0014]
Further, the fixed wireless access system of the present invention includes a wireless access antenna for transmitting and receiving a wireless access signal, a first frequency conversion means for frequency-converting a wireless access signal transmitted and received by the wireless access antenna, Conversion means, and a terrestrial broadcast booster, a BS broadcast converter, and / or a CS broadcast converter to which a terrestrial broadcast signal output from the terrestrial broadcast booster can be connected; A first combiner for superimposing and outputting a radio access signal frequency-converted by the first frequency conversion means on a BS broadcast signal output from the CS broadcast signal or a CS broadcast signal output from the CS broadcast converter; From the signal transmitted from the coupler, the terrestrial broadcast signal, the BS broadcast signal or the CS A second coupler having distribution means for distributing the radio access signal superimposed on the signal, and power supply superimposing means for superimposing a predetermined power supply on the signal to be sent to the first coupler; And a second frequency conversion means for frequency-converting the radio access signal distributed by the distribution means having the first coupling and the second coupling via the same cable between the first coupling and the second coupling. The signal superimposed by the one coupler and the signal superimposed with the predetermined power by the power superimposing means of the second coupler are transmitted.
[0015]
Therefore, when the first frequency conversion means and the second frequency conversion means have already been introduced, by providing the first coupler and the second coupler, the terrestrial wave between the first coupler and the second coupler is provided. In addition to the broadcast signal, the BS broadcast signal, and the CS broadcast signal, a wireless access signal can be transmitted through the same cable.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
(1st Embodiment)
FIG. 1 is a diagram showing a schematic configuration of a fixed wireless access system for explaining a first embodiment of the present invention. As shown in the figure, a fixed wireless access (FWA) system according to the present embodiment mainly includes a FWA antenna 3 corresponding to a wireless access antenna described in the claims and a first fixed wireless access means. , An outdoor unit (ODU: Out Door Unit) 1, a cable 21, and an indoor unit (IDU: In Door Unit) 2 corresponding to the second fixed wireless access means. In addition, the BS antenna 4a and the BS BS converter 4b corresponding to a broadcast converter, CS antenna 5a and CS converter 5b corresponding to a CS broadcast converter, VHF / UHF antenna 6, VHF / UHF booster 7 corresponding to a terrestrial broadcast booster, and a BS decoder 8 and CS decoder corresponding to CS broadcast decoder 9, a television (TV) 10, are provided to the computer 11.
[0017]
The outdoor unit 1 is connected to the FWA antenna 3, a BS converter 4b, a CS converter 5b, and a VHF / UHF booster 7, and is connected to the indoor unit 2 via a cable 21. The BS antenna 4a is connected to the BS converter 4b, the CS antenna 5a is connected to the CS converter 5b, and the VHF / UHF antenna 6 is connected to the VHF / UHF booster 7. On the other hand, a BS decoder 8, a CS decoder 9 and a personal computer 11 are connected to the indoor unit 2, and the TV 10 is also connected by a VHF / UHF cable 10a. The TV 10 is connected to a BS decoder 8 and a CS decoder 9.
[0018]
Hereinafter, an outdoor unit (ODU) 1 and an indoor unit (IDU) 2 will be mainly described among the components included in the fixed wireless access system of the present embodiment.
[0019]
First, the outdoor unit 1 will be described with reference to FIGS. FIG. 2 is a diagram showing a signal system superimposed on an internal configuration of an outdoor unit provided in the fixed wireless access system shown in FIG. FIG. 3 is a diagram showing a power supply system superimposed on the internal configuration of the outdoor unit provided in the fixed wireless access system shown in FIG. As shown in FIGS. 2 and 3, the outdoor unit 1 includes a FWA antenna terminal 112, a BS / UHF / VHF input terminal 113, a CS input terminal 114, an ODU input / output terminal 111, It has a FWA ODU circuit 118 corresponding to one frequency conversion means, power supply superposition circuits 119 and 120, a synthesis distribution circuit 115 corresponding to synthesis means, a control circuit 116, and a power supply conversion circuit 117 corresponding to power supply voltage generation means. .
[0020]
The wireless access signal received by the FWA antenna 3 (hereinafter referred to as “received FWA signal”) is input to the FWA antenna terminal 112. Further, the FWAIF circuit 118 outputs to the FWA antenna 3 a transmission FWA signal obtained by converting the FWAIF signal into a predetermined frequency. The BS / UHF / VHF input terminal 113 receives a signal received by the BS antenna 4a and converted by the BS converter 4b and a signal received by the VHF / UHF antenna 6 and frequency-converted by the VHF / UHF booster 7. Is entered. In the following description, these two signals are collectively referred to as “BS / UHF / VHF signal”. Further, a signal received by the CS antenna 5a and converted by the CS converter 5b is input to the CS input terminal 114. In the following description, this signal is referred to as a “CS signal”.
[0021]
The FWA ODU circuit 118 converts a received FWA signal input from the FWA antenna terminal 112 to a predetermined frequency and outputs the same, or converts an FWAIF signal transmitted from an indoor unit (IDU) 2 described later to a predetermined frequency. The signal is output to the FWA antenna terminal 112. The FWAIF signal output from the FWA ODU unit 118 is input to the combining and distributing circuit 115. The FWAIF signal is a signal transmitted between the FWA ODU circuit 118 and the FWA IDU circuit 125. The FWA ODU unit 118 outputs a wireless access signal obtained by converting the FWAIF signal transmitted from the combining and distributing circuit 115 to a predetermined frequency from the FWA antenna terminal 112.
[0022]
The power supply superposition circuit 119 superimposes the power supply voltage (+15 V) obtained from the power supply conversion circuit 117 on the BS signal and outputs the signal to the BS / UHF / VHF input terminal 113. The power supply superimposing circuit 120 superimposes the power supply voltage (+15 V or +11 V) obtained from the power supply conversion circuit 117 and outputs the superposed power supply voltage to the CS input terminal 114.
[0023]
Further, the combining and distributing circuit 115 includes a FWAIF signal output from the FWA ODU circuit 118, a BS / UHF / VHF signal input to the BS / UHF / VHF input terminal 113 and obtained through the power supply superimposing circuit 119, and a CS input terminal. It combines the signals of the CS signal input from 114 and obtained through the power supply superimposing circuit 120. The signal synthesized by the synthesis distribution circuit 115 is output from the ODU input / output terminal 111 and sent out to the indoor unit 2 via the cable 21. The combining and distributing circuit 115 distributes an FWA control signal, which will be described later, from a signal transmitted from the indoor unit 2 and input via the cable 21 and the ODU input / output terminal 111, and outputs the FWA control signal to the control circuit 116.
[0024]
Further, upon detecting the FWA control signal distributed by the combining / distributing circuit 115, the control circuit 116 controls the power supply conversion circuit 117 so that the power supply superposition circuits 119 and 120 superimpose the power supply voltage indicated by the detected FWA control signal. It sends out a signal. The power supply conversion circuit 117 outputs each power supply voltage based on the control signal from the control circuit 116 to the power supply superposition circuits 119 and 120. When the polarization identification signal obtained by converting the FWA control signal detected by the control circuit 116 represents a vertical polarization by the superposition of the power supply voltages in the power supply voltage superimposing circuits 119 and 120, the power supply voltage of +11 V is applied. The power is supplied to the CS converter 5b, and a power supply voltage of +15 V is supplied to the CS converter 5b when representing horizontal polarization.
[0025]
Next, the indoor unit 2 will be described with reference to FIGS. FIG. 4 is a diagram in which a signal system is overlapped with an internal configuration of an indoor unit included in the fixed wireless access system shown in FIG. FIG. 5 is a diagram showing a power supply system superimposed on the internal configuration of the indoor unit provided in the fixed wireless access system shown in FIG. As shown in FIGS. 4 and 5, the indoor unit 2 includes a FWA input / output terminal 121, a BS / UHF / VHF output terminal 122, a CS output terminal 123, an IDU input / output terminal 124, FWAIDU circuit 125 corresponding to the second frequency conversion means, power supply detection circuit 126, power supply detection circuit 132 corresponding to the detection means, combined distribution circuit 127 corresponding to the distribution means, and power supply superposition circuit corresponding to the power supply superposition means 128, a control circuit 129, and a power supply circuit 130.
[0026]
The signal transmitted from the outdoor unit 1 is input from the IDU input / output terminal 124 via the cable 21 and is input to the combining / distributing circuit 127 via the power supply superimposing circuit 128. The combining / distributing circuit 127 distributes the input signal into a FWAIF signal, a BS / UHF / VHF signal, and a CS signal. The FWAIF signal is output to the FWAIDU circuit 125, the BS / UHF / VHF signal is output from the BS / UHF / VHF output terminal 122 via the power detection circuit 126, and the CS signal is output via the power detection circuit 130 to the CS output terminal 123. Output from The BS signal output from the BS / UHF / VHF output terminal 122 is supplied to the BS decoder 8, and the UHF / VHF signal is supplied to the TV 10 via the cable 10a. The CS signal output from the CS output terminal 123 is supplied to the CS decoder 9.
[0027]
The FWAIDU circuit 125 performs frequency conversion or the like on the FWAIF signal, and the frequency-converted signal is output from the FWA input / output terminal 121. The signal output from the FWA input / output terminal 121 is sent to the personal computer 11. Further, the FWAIDU circuit 125 receives the FWA signal output from the personal computer 11 via the FWA input / output terminal 121. The FWAIDU circuit 125 performs frequency conversion or the like on the FWA signal and outputs a FWAIF signal.
[0028]
The power detection circuit 126 detects a power supply voltage supplied from the coder 8 to the BS converter 4b at the BS, and a BS power supply signal relating to the detected power supply voltage is sent to the control circuit 129. The power detection circuit 132 detects the polarization identification signal from the CS decoder 9 as the power supply voltage supplied from the coder 9 to the CS converter 5b in the CS, and the detected polarization identification signal is transmitted to the control circuit 129. Sent to
[0029]
Further, the control circuit 129 performs frequency conversion on the FWA signal input to the FWAIDU circuit 125, information on the power supply voltage detected by the power supply detection circuit 126, and the polarization identification signal detected by the power supply detection circuit 132. And an FWA control signal to the power supply superimposing circuit 128. The power supply circuit 130 supplies a power supply voltage of a predetermined voltage of, for example, −48 V to the power supply superimposing circuit 128. The power supply superimposing circuit 128 superimposes the power supply voltage supplied from the power supply circuit 130 on the FWA control signal output from the control circuit 129. A signal obtained by superimposing in the power supply superimposing circuit 128 is output from the IDU input / output terminal 124 and transmitted to the outdoor unit 1 via the cable 21.
[0030]
In the fixed wireless access system having such a configuration, when the FWA signal from the personal computer 11 is transmitted as a wireless access signal from the FWA antenna 3 via the outdoor unit 2, the cable 21, and the indoor unit 1, the wireless access signal is The responded received FWA signal is received by the FWA antenna 3 and input to the personal computer 11 via the outdoor unit 1, the cable 21, and the indoor unit 2.
[0031]
A VHF / UHF terrestrial broadcast signal is received by a VHF / UHF antenna 6, frequency-converted by a VHF / UHF booster 7, and input to the TV 10 via the outdoor unit 1, the cable 21 and the indoor unit 2. You. The BS signal is received by the BS antenna 4a, converted by the BS converter 4b, and sent to the BS decoder 8 via the outdoor unit 1, the cable 21, and the indoor unit 2. The CS signal is received by the CS antenna 5a, converted by the CS converter 5b, and sent to the CS decoder 9 via the outdoor unit 1, the cable 21, and the indoor unit 2.
[0032]
On the other hand, when the power supply voltage is supplied to the CS converter 5b, the indoor unit 2 detects the polarization identification signal from the CS decoder 9 and transmits an FWA control signal obtained by frequency-converting the polarization identification signal to the outdoor unit 1. . When detecting the frequency-converted FWA control signal, the outdoor unit 1 converts the FWA control signal into a polarization identification signal, and determines whether the polarization identification signal is a vertical polarization signal or a horizontal polarization signal. A different predetermined power supply voltage is supplied to the CS converter 5b.
[0033]
FIG. 6 shows a VHF / UHF signal, a signal obtained by frequency-converting a BS signal (BS-IF signal), a signal obtained by frequency-converting a CS signal (CS-IF signal), an FWAIF signal obtained by converting a received FWA signal to a predetermined frequency, and FIG. 3 is a diagram illustrating a frequency distribution of an FWA control signal and the like. The FWAIF signal is used in a frequency band that does not interfere with each of the VHF / UHF signal, the BS-IF signal, and the CS-IF signal. The polarization identification signal detected by the indoor unit 2 is converted into an AC component FWA control signal that does not interfere with the DC voltage, and is sent to the outdoor unit 1.
[0034]
As described above, according to the fixed wireless access system of the present embodiment, the FWA is connected between the outdoor unit 1 and the indoor unit 2 via one cable 21 so as not to interfere with each signal of VHF, UHF, BS, and CS. Control signals can be transmitted. For this reason, when installing the fixed wireless access device, no new cable is required and no external power supply for outdoor equipment is required, so that the installation time can be reduced and the installation cost can be reduced.
[0035]
(Second embodiment)
In the second embodiment, means substantially the same as the FWA ODU circuit 118 of the outdoor unit 1 described in the first embodiment and means substantially the same as the FWA IDU circuit 125 of the indoor unit 2 have already been introduced. A fixed wireless access system in which an outdoor coupler and an indoor coupler, which will be described later, are provided to superimpose the FWA control signal and the VHF, UHF, BS, and CS signals will be described.
[0036]
FIG. 7 is a diagram showing a schematic configuration of a fixed wireless access system for explaining a second embodiment of the present invention. In the figure, the same reference numerals are given to the same parts as those in FIG. 1 described in the first embodiment, and the description will be omitted. In the fixed wireless access system of the second embodiment shown in FIG. 7, mainly the FWA antenna 3, the FWA ODU unit 12, the outdoor coupler 14 corresponding to the first coupler in the claims, the cable 51, , An indoor coupler 15 corresponding to the second coupler, and a FWAIDU unit 13. In addition, a BS antenna 4a and a BS converter 4b, a CS antenna 5a and a CS converter 5b, a VHF / UHF antenna 6, and a VHF / A UHF booster 7, a BS decoder 8, a CS decoder 9, a television (TV) 10, and a personal computer 11 are provided.
[0037]
An FWA antenna 3 is connected to the FWA ODU unit 12. The outdoor coupler 14 is connected to the FWA ODU unit 12, the BS converter 4b, the CS converter 5b, and the VHF / UHF booster 7, and is connected to the indoor coupler 15 via the cable 51. It should be noted that a BS antenna 4a is connected to the BS converter 4b, as in the first embodiment, a CS antenna 5a is connected to the CS converter 5b, as in the first embodiment, and a VHF / UHF booster 7 is connected to the VHF / UHF booster 7. As in the first embodiment, a VHF / UHF antenna 6 is connected.
[0038]
On the other hand, to the indoor coupler 15, the BS decoder 8, the CS decoder 9, and the FWAIDU unit 13 are connected, and the TV 10 is also connected by the VHF / UHF cable 10a. The TV 10 is connected to a BS decoder 8 and a CS decoder 9. In addition, a personal computer 11 is connected to the FWAIDU unit 13.
[0039]
Hereinafter, the FWA ODU unit 12, the outdoor coupler 14, the indoor coupler 15, and the FWAIDU unit 13 will be mainly described among the components included in the fixed wireless access system of the present embodiment.
[0040]
First, the FWA ODU unit 12 will be described. The FWA ODU unit 12 is substantially similar to the FWA ODU circuit 118 included in the outdoor unit 1 described in the first embodiment, and converts a received FWA signal input from the FWA antenna 3 into a predetermined frequency and outputs the signal. Things. Note that the received FWA signal converted to a predetermined frequency is referred to as a “FWAIF signal” as in the first embodiment. The FWAIF signal output from the FWA ODU unit 12 is input to the outdoor coupler 14. Further, the FWA ODU unit 12 sends out a radio access signal obtained by converting the FWAIF signal sent from the outdoor coupler 14 to a predetermined frequency to the FWA antenna 3.
[0041]
Next, the outdoor coupler 14 will be described with reference to FIG. FIG. 8 is a diagram showing an internal configuration of an outdoor coupler included in the fixed wireless access system shown in FIG. As shown in the figure, the outdoor coupler 14 is different from the outdoor unit 1 of the first embodiment in that a power supply superposition circuit 135 is provided instead of the FWA ODU circuit 118, and an FWA input terminal is provided instead of the FWA antenna terminal 112. The output terminal 133 is provided with an outdoor input / output terminal 131 instead of the ODU input / output terminal 111, the combination distribution circuit 201 is provided instead of the combination distribution circuit 115, and the power supply conversion circuit 203 is provided instead of the power supply conversion circuit 117.
[0042]
The FWAIF signal transmitted from the FWA ODU unit 12 is input to the FWA input / output terminal 133. The power supply superimposing circuit 135 superimposes the power supply voltage (−48 V) obtained from the power supply conversion circuit 203 and outputs it to the FWA input / output terminal 133. Further, the combining / distributing circuit 201 receives the FWAIF signal input to the FWA input / output terminal 133 and obtained through the power supply superimposing circuit 135 and the FWAIF signal input to the BS / UHF / VHF input terminal 113 and obtains the signal via the power superimposing circuit 119. It combines the BS / UHF / VHF signal and the CS signal input from the CS input terminal 114 and obtained via the power supply superimposing circuit 120. The signal synthesized by the synthesis distribution circuit 201 is output from the outdoor input / output terminal 131 and sent to the outdoor coupler 14. The combining / distributing circuit 201 distributes an FWA control signal, which will be described later, from a signal transmitted from the indoor coupler 15 and input via the outdoor input / output terminal 131, and outputs the FWA control signal to the control circuit 116. The power supply conversion circuit 203 outputs each power supply voltage based on a control signal from the control circuit 116 to the power supply superposition circuits 135, 119, and 120.
[0043]
Next, the indoor coupler 15 will be described with reference to FIG. FIG. 9 is a diagram showing an internal configuration of an indoor coupler included in the fixed wireless access system shown in FIG. As shown in the figure, the indoor coupler 15 is different from the indoor unit 2 of the first embodiment in that an indoor input / output terminal 144 is provided instead of the IDU input / output terminal 124, and the FWA input / output terminal 121 Instead, an FWA input / output terminal 141 is provided, and no FWAIDU circuit 125 is provided.
[0044]
The signal transmitted from the outdoor coupler 14 is input from the indoor input / output terminal 144 via the cable 51 and is input to the combining / distributing circuit 127 via the power supply superimposing circuit 128. The combining / distributing circuit 127 distributes the input signal into a FWAIF signal, a BS / UHF / VHF signal, and a CS signal. Unlike the first embodiment, the FWAIF signal is output from the FWA input / output terminal 141. The signal output from the FWA input / output terminal 141 is sent to the FWAIDU unit 13.
[0045]
Further, the control circuit 205 converts the frequency of the information on the power supply voltage detected by the power supply detection circuit 126 and the polarization identification signal detected by the power supply detection circuit 132 and outputs the FWA control signal to the power supply superimposition circuit 128. Is what you do. A signal obtained by superimposing in the power supply superimposing circuit 128 is output from the indoor input / output terminal 144 and transmitted to the outdoor coupler 14 via the cable 51.
[0046]
Next, the FWAIDU unit 13 will be described. The FWAIDU unit 13 is substantially the same as the FWAIDU circuit 125 included in the indoor unit 2 described in the first embodiment, and performs frequency conversion and the like on the FWAIF signal output from the indoor coupler 15. is there. The frequency-converted signal is sent to the personal computer 11. Further, the FWAIDU unit 13 receives an FWA signal output from the personal computer 11. The FWAIDU unit 13 performs frequency conversion and the like on the FWA signal and outputs a FWAIF signal.
[0047]
In the fixed wireless access system having such a configuration, when the FWA ODU unit 12 and the FWA IDU unit 13 have already been introduced, the indoor coupler 14 and the outdoor coupler 15 are installed, and these are connected by one cable 51. Thus, the FWA control signal can be transmitted so as not to interfere with the VHF, UHF, BS, and CS signals. Further, even when an outdoor commercial power supply is used for the UHF / VHF booster 7, a power supply voltage can be supplied from the FWA ODU unit 12, so that an external power supply for outdoor equipment is not required. Further, when the distance between the FWA ODU unit 12 and another antenna is long, it is not necessary to route the cable more than necessary.
[0048]
【The invention's effect】
According to the fixed wireless access system of the present invention, between the first fixed wireless access means and the second fixed wireless access means, not only the terrestrial broadcast signal, the BS broadcast signal, and the CS broadcast signal but also the wireless access signal are the same. Can be transmitted over the cable. As a result, when installing the first fixed wireless access means and the first fixed wireless access means, a system can be constructed without newly installing a new cable.
[Brief description of the drawings]
FIG. 1 is a diagram showing a schematic configuration of a fixed wireless access system for explaining a first embodiment of the present invention;
FIG. 2 is a diagram showing a signal system superimposed on an internal configuration of an outdoor unit provided in the fixed wireless access system shown in FIG.
FIG. 3 is a diagram showing a power supply system superimposed on an internal configuration of an outdoor unit provided in the fixed wireless access system shown in FIG.
4 is a diagram showing a signal system superimposed on an internal configuration of an indoor unit included in the fixed wireless access system shown in FIG.
FIG. 5 is a diagram showing a power supply system superimposed on an internal configuration of an indoor unit included in the fixed wireless access system shown in FIG. 1;
FIG. 6 shows a VHF / UHF signal, a signal obtained by frequency-converting a BS signal (BS-IF signal), a signal obtained by frequency-converting a CS signal (CS-IF signal), an FWAIF signal obtained by converting a received FWA signal to a predetermined frequency, and The figure which shows the frequency distribution of an FWA control signal etc.
FIG. 7 is a diagram showing a schematic configuration of a fixed wireless access system for explaining a second embodiment of the present invention;
8 is a diagram showing an internal configuration of an outdoor coupler included in the fixed wireless access system shown in FIG.
9 is a diagram showing an internal configuration of an indoor coupler included in the fixed wireless access system shown in FIG.
[Explanation of symbols]
1 outdoor unit (ODU)
2 indoor unit (IDU)
3 FWA antenna
4a BS antenna
4b BS converter
5a CS antenna
5b CS converter
9 CS decoder
12 FWA ODU section
13 FWAIDU section
14 Outdoor coupler
15 Indoor coupler
21, 51 cable
111 ODU input / output terminal
112 FWA antenna terminal
113 BS / UHF / VHF input terminal
114 CS input terminal
115,127,201 Combination distribution circuit
116,129,205 Control circuit
117,203 Power supply conversion circuit
118 FWA ODU circuit
119, 120, 128, 135 Power supply superposition circuit
121 FWA input / output terminal
122 BS / UHF / VHF output terminal
123 CS output terminal
124 IDU input / output terminal
125 FWAIDU circuit
126, 132 Power supply detection circuit
131 Outdoor input / output terminal
133 FWA input / output terminal

Claims (6)

A radio access antenna for transmitting and receiving a radio access signal;
A first frequency conversion unit to which at least one of a terrestrial broadcast booster, a BS broadcast converter and a CS broadcast converter can be connected, and a frequency conversion means for frequency-converting a radio access signal transmitted and received by the radio access antenna; The first frequency converter converts the terrestrial broadcast signal output from the terrestrial broadcast booster, the BS broadcast signal output from the BS broadcast converter, or the CS broadcast signal output from the CS broadcast converter. First fixed wireless access means having combining means for superimposing and combining the wireless access signals thus obtained,
Distributing means for distributing a radio access signal superimposed on the terrestrial broadcast signal, the BS broadcast signal or the CS broadcast signal from a signal transmitted from the first fixed radio access means, and a radio distributed by the distributing means A second fixed radio access means having a second frequency conversion means for converting the frequency of an access signal, and a power supply superimposing means for superposing a predetermined power supply on a signal transmitted to the first fixed radio access means,
Between the first fixed wireless access means and the second fixed wireless access means, via the same cable, a signal synthesized by the synthesizing means and a signal on which the predetermined power is superimposed by the power superimposing means. Fixed wireless access system for transmitting. The fixed wireless access system according to claim 1,
The first fixed wireless access means,
A fixed wireless access system having a power supply voltage generating means for generating at least one of a power supply voltage of the BS broadcast converter and a power supply voltage of the CS broadcast converter according to a superimposed signal transmitted from the second fixed wireless access means. The fixed wireless access system according to claim 2,
The second fixed wireless access means has a detection means for detecting a polarization identification signal from a CS broadcast decoder connected to the second fixed wireless access means, and the power supply superimposing means is detected by the detection means. The predetermined power supply is superimposed on a signal obtained by frequency-converting the polarization identification signal, and transmitted to the first fixed wireless access unit,
The power supply voltage generating means included in the first fixed wireless access means, based on the polarization identification signal obtained by frequency-converting the signal transmitted from the second fixed wireless access means, Fixed wireless access system that generates power supply voltage. A fixed wireless access device to which at least one of a terrestrial broadcast booster, a BS broadcast converter, and a CS broadcast converter can be connected,
First frequency conversion means for frequency-converting a radio access signal transmitted and received by a radio access antenna for transmitting and receiving a radio access signal;
The first frequency converter converts the terrestrial broadcast signal output from the terrestrial broadcast booster, the BS broadcast signal output from the BS broadcast converter, or the CS broadcast signal output from the CS broadcast converter. Combining means for superimposing and combining the wireless access signals thus obtained,
A fixed wireless access device comprising: Distribution means for distributing a radio access signal from a signal obtained by superimposing a radio access signal on a terrestrial broadcast signal, a BS broadcast signal or a CS broadcast signal;
Second frequency conversion means for frequency-converting the radio access signal distributed by the distribution means,
Power supply superimposing means for superimposing a predetermined power supply on a signal transmitted to the outside;
A fixed wireless access device comprising: A radio access antenna for transmitting and receiving a radio access signal;
First frequency conversion means for frequency-converting a radio access signal transmitted and received by the radio access antenna,
The first frequency conversion means, and a terrestrial broadcast booster, at least one of a BS broadcast converter and a CS broadcast converter can be connected, and a terrestrial broadcast signal output from the terrestrial broadcast booster; A first coupler for superimposing a radio access signal frequency-converted by the first frequency conversion means on a BS broadcast signal output from a BS broadcast converter or a CS broadcast signal output from the CS broadcast converter; ,
Distributing means for distributing a radio access signal superimposed on the terrestrial broadcast signal, the BS broadcast signal or the CS broadcast signal from a signal transmitted from the first coupler, and a signal transmitted to the first coupler. A second coupler having power supply superimposing means for superimposing a predetermined power supply;
A second frequency converter for frequency-converting the radio access signal distributed by the distributor provided in the second coupler;
The signal superimposed by the first coupler and the predetermined power supply by the power superimposing means of the second coupler between the first coupler and the second coupler via the same cable. A fixed wireless access system that transmits a signal on which is superimposed.

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