JP2004128720A - Indoor retransmission system and indoor retransmission apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an indoor retransmission system wherein an ISDB-T receiver can simply receive a TV broadcast at a place such as the inside of a building or a room which a television radio wave hardly reaches. <P>SOLUTION: A retransmission apparatus 6 uses a reception antenna 7 installed in a room 2a which an ISDB-T radio wave reaches to receive an ISDB-T signal transmitted from a base station and gives the signal to an amplifier unit 8. An amplifier 12 of the amplifier unit 8 amplifies the ISDB-T signal received by the reception antenna 7 and an AGC circuit 13 adjusts the amplified signal to have a prescribed level such as a level for a weak electric field, and a retransmission antenna 9 installed in a room 2b which no radio wave reaches retransmits the resulting signal to an ISDB-T receiver 4. The ISDB-T receiver 4 uses an antenna 5 to receive the radio wave retransmitted from a retransmission antenna 9 of the retransmission apparatus 6 to allow a user to view the ISDB-T broadcast program. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an indoor retransmission system and an indoor retransmission device that enable viewing on a portable television or the like in a place where television waves are difficult to reach, such as in a building or indoors.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, when viewing a television broadcast on a portable television or the like in a place where radio waves do not easily reach, such as in a building or a room, a TV terminal provided on a wall or the like, that is, a TV terminal (F-type cable) connected to a CATV line. For example, means for directly connecting an antenna terminal of a portable television to the connector), frequency conversion of a signal taken out from the TV terminal, level adjustment, and retransmission to an indoor portable television by an antenna are used.
[0003]
However, when the antenna terminal of the portable TV is directly connected to the TV terminal as in the above-described conventional case, the portability is significantly impaired, and a dedicated system is used when the frequency of a CATV broadcast signal is converted and retransmitted. Required.
[0004]
At present, terrestrial television broadcasting is analog television broadcasting, and since 2003, terrestrial digital television broadcasting (ISDB-T: Integrated Services Digital Broadcasting for Terrestrial Television Broadcasting) using the UHF band has started. It is scheduled. The ISDB-T uses an OFDM (Orthogonal Frequency Division Multiplexing) signal having a characteristic that is strong against interference of radio waves such as a multipath and a wraparound, so that a single frequency network (SFN) can be realized. .
[0005]
However, when the above single frequency network (SFN) is realized, if the broadcast wave is retransmitted as it is for distribution from the master station to the relay station, signal deterioration due to sneak from the transmission antenna to the reception antenna of the relay station, particularly sneak. When the loop gain becomes 1 or more, oscillation occurs. In order to cope with such a problem, various schemes have been proposed in which a relay station is provided with a filter for canceling a roundabout (for example, see Patent Documents 1 and 2).
[0006]
[Patent Document 1]
Japanese Patent Application Laid-Open No. 2002-101032
[Patent Document 2]
JP-A-2002-158634
[Problems to be solved by the invention]
However, in the above-described conventional method, it is necessary to perform processing such as modulation / demodulation of the ISDB-T signal, frequency conversion, loop-back cancellation for each channel, and the configuration becomes very complicated.
[0009]
INDUSTRIAL APPLICABILITY The present invention makes it possible to easily receive a television broadcast by a portable television or the like indoors by utilizing the resistance to multipath and wraparound of an OFDM signal by ISDB-T in a place where television waves are difficult to reach, such as in a building or indoors. It is an object to provide an indoor retransmission system and an indoor retransmission device.
[0010]
[Means for Solving the Problems]
An indoor retransmission system according to the present invention receives a terrestrial digital television broadcast transmitted from a base station by a receiving antenna installed in a place where radio waves can reach, and amplifies the terrestrial digital television broadcast by an amplification device having an AGC circuit. The transmitted signal is retransmitted by a retransmission antenna installed in a room where radio waves from the base station are difficult to reach.
[0011]
Also, the indoor retransmission device according to the present invention is installed in a location where radio waves can reach, a receiving antenna for receiving terrestrial digital television broadcast transmitted from a base station, and amplifying a signal received by the receiving antenna. And a retransmission antenna that is installed in a room where radio waves from the base station are difficult to reach, and retransmits a signal amplified by the amplification device.
[0012]
According to the above configuration, there is no need to perform processing such as modulation / demodulation of terrestrial digital television signals, frequency conversion, and loop-around cancellation for each channel, and a terrestrial digital television signal transmitted from a base station can be received with a simple system configuration. It can be re-transmitted into a room where radio waves do not easily reach, and even in a room where radio waves do not reach easily, a terrestrial digital television broadcast receiver such as a portable television can easily view terrestrial digital television broadcasts. In addition, it is possible to prevent oscillation due to the retransmission radio wave wraparound, and to always keep the level of the retransmission radio wave at the optimum level.
[0013]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0014]
(1st Embodiment)
FIG. 1 is a block diagram showing the overall configuration of an indoor retransmission system using digital terrestrial television broadcasting (ISDB-T) according to the first embodiment of the present invention.
[0015]
In FIG. 1, reference numeral 1 denotes a building such as a building or a house, which is provided with a plurality of rooms 2a and 2b. The room 2a is a place where the radio wave of ISDB-T reaches, and the room 2b is a place where the radio wave of ISDB-T does not reach, such as a bath, a toilet, a basement, etc., which is partitioned by the wall 3.
[0016]
When viewing the ISDB-T with the ISDB-T receiver 4 such as a portable television in the room 2b where the radio wave of the ISDB-T does not reach, the retransmitting device 6 is installed in the rooms 2a and 2b. The retransmitting device 6 includes a receiving antenna 7 for receiving ISDB-T radio waves, an amplifying device 8 for amplifying a signal received by the receiving antenna 7, and a signal amplified by the amplifying device 8 in the room 2b. It consists of a retransmission antenna 9 for retransmission.
[0017]
The receiving antenna 7 and the amplifying device 8 are installed in a room 2a to which a television wave can reach, and the retransmission antenna 9 is installed in a room 2b to which a TV wave does not reach. In this case, the output end of the amplification device 8 is connected to the retransmission antenna 9 through the wall 3 by a coaxial cable. The receiving antenna 7 is set to match the polarization plane of the ISDB-T signal transmitted from the base station, and the retransmission antenna 9 is set with the polarization plane inclined at 90 ° with respect to the receiving antenna 7.
[0018]
For example, when the polarization plane of the receiving antenna 7 is set to vertical polarization (or horizontal polarization), the polarization plane of the retransmission antenna 9 is set to horizontal polarization (or vertical polarization). When the polarization plane of the receiving antenna 7 is set to the right-hand circular polarization (or left-hand circular polarization), the polarization plane of the retransmission antenna 9 is set to the left-hand circular polarization (or right-hand circular polarization). . That is, by changing the polarization plane of the radio wave reaching the reception antenna 7 from the ISDB-T base station and the polarization plane of the radio wave to be retransmitted from the retransmission antenna 9, the retransmission wave is hardly wrapped around the reception antenna 7. I do. Further, the antenna 5 of the ISDB-T receiver 4 is adjusted so as to have an optimum polarization plane with respect to the retransmission antenna 9. As the transmission or retransmission signal (ISDB-T signal), a modulation signal based on OFDM (Orthogonal Frequency Division Multiplexing) having a characteristic that is strong against interference of radio waves such as multipath and wraparound is used.
[0019]
The amplifying device 8 includes an amplifier 12 and an AGC circuit 13 as shown in FIG. Amplifier 12 amplifies the signal input from receiving antenna 7 and outputs the amplified signal to AGC circuit 13 and retransmission antenna 9. For example, when a dipole antenna is used as the receiving antenna 7 and a radio wave of 470 MHz is received, the antenna coefficient is said to be about 13 dB. And a total loss of about 26 dB. Therefore, the gain of the amplifier 12 need only be 26 dB or more.
[0020]
As shown in FIG. 3, the AGC circuit 13 envelope-detects the input signal of the amplifier 12 and converts the signal into a DC signal. The AGC circuit 13 envelope-detects the output signal of the amplifier 12 to detect the DC signal. , A variable attenuator 17 for adjusting the output voltage level of the second envelope detector 16, an output voltage of the first envelope detector 15 and a variable attenuator 17. The differential amplifier 18 adjusts the output level of the amplifier 12 by outputting to the amplifier 12 a voltage value corresponding to the difference between the output voltages of the second envelope detector 16 adjusted by the above.
[0021]
The AGC circuit 13 performs an envelope detection of the input signal of the amplifier 12 by the first envelope detector 15, converts the signal into a DC signal, inputs the DC signal to the differential amplifier 18, and converts the output signal of the amplifier 12 into the second signal. Envelope detection is performed by an envelope detector 16 to convert the signal into a DC signal, which is input to a differential amplifier 18 via a variable attenuator 17. The differential amplifier 18 outputs to the amplifier 12 a voltage value corresponding to the difference between the output voltage of the first envelope detector 15 and the output voltage of the second envelope detector 16 adjusted by the variable attenuator 17. Then, the output level of the amplifier 12 is adjusted. Therefore, the output voltage value of the amplifier 12 can be arbitrarily adjusted by changing the output voltage value of the differential amplifier 18 by variably setting the attenuation amount of the variable attenuator 17.
[0022]
The AGC circuit 13 adjusts the output voltage level of the amplifier 12 by the variable attenuator 17 and transmits a signal retransmitted from the retransmission antenna 9 to a “significantly weak radio station” described in, for example, Article 6 of the Radio Law Enforcement Regulations. Adjustment is made so as to satisfy the electric field strength of 35 μV / m (frequency 322 MHz to 10 GHz).
[0023]
Another role of the AGC circuit 13 is to detect the occurrence of wraparound oscillation and adjust the electric field strength of a signal output from the retransmission antenna 9 so as to suppress the oscillation.
[0024]
In the above configuration, the retransmitting device 6 receives the ISDB-T signal transmitted from the base station by the receiving antenna 7 installed in the room 2a, and inputs the ISDB-T signal to the amplifying device 8. The amplifying device 8 amplifies the ISDB-T signal received by the receiving antenna 7 with the amplifier 12 and adjusts the ISDB-T signal to a predetermined level, for example, the level of a weak electric field by the AGC circuit 13. Retransmit to T receiver 4. The ISDB-T receiver 4 receives the radio wave retransmitted from the retransmission antenna 9 of the retransmission device 6 by the antenna 5 to view the ISDB-T broadcast.
[0025]
As described above, the ISDB-T signal transmitted from the base station is received by the retransmitting device 6 and retransmitted into the room 2b, so that the ISDB-T receiver 4 is in a room where radio waves from the base station do not reach. Also in 2b, it is possible to receive the retransmitted radio wave and view the ISDB-T broadcast in a stable state.
[0026]
Further, by changing the polarization planes of the receiving antenna 7 and the retransmitting antenna 9 of the retransmitting device 6, the configuration is such that the retransmitted signal is less likely to wrap around the input side of the amplifying device 8 and the oscillation due to the wraparound is reliably prevented. it can.
[0027]
Furthermore, since the AGC circuit 13 is provided in the amplifying device 8 and the signal level from the amplifier 12 to the retransmission antenna 9 is adjusted, it is possible to always transmit the radio wave of the optimum level to the ISDB-T receiver 4. .
[0028]
Further, as described above, retransmission from the retransmitting device 6 with a weak electric field and retransmission in a room where radio waves do not easily leak can reliably prevent radio waves from leaking out of the room. Furthermore, since a guard interval is provided in the ISDB-T signal, there is an advantage that even if a radio wave leaks out of the room, it does not easily interfere with other devices.
[0029]
(2nd Embodiment)
Next, a second embodiment of the present invention will be described.
FIG. 4 is a block diagram showing an overall configuration of an indoor retransmission system using ISDB-T according to the second embodiment of the present invention. The second embodiment shows a case where ISDB-T radio waves from a base station do not reach not only the room 2b such as a bath, a toilet, and a basement in the building 1 but also the room 2a.
[0030]
In the second embodiment, as shown in FIG. 4, the first retransmitting device 6a is installed at the boundary between the inside and the outside of the room 2a, and the second retransmission is performed at the boundary between the room 2a and the room 2b. The device 6b is installed. The retransmitting devices 6a and 6b include a receiving antenna 7, an amplifying device 8, and a retransmitting antenna 9 similarly to the retransmitting device 6 shown in the first embodiment. The amplifying device 8 includes the amplifier 12 and the AGC circuit 13 as shown in FIG.
[0031]
In the first retransmitting device 6a, the receiving antenna 7 is installed outside the building 1, and the amplifying device 8 and the retransmitting antenna 9 are installed in the room 2a. In this case, the receiving antenna 7 is set to match the polarization plane of the ISDB-T signal transmitted from the base station, and the retransmission antenna 9 is set to have a different polarization plane from that of the receiving antenna 7.
[0032]
In the second retransmitting device 6b, the receiving antenna 7 and the amplifying device 8 are installed in the room 2a, and the retransmitting antenna 9 is installed in the room 2b. In this case, the reception antenna 7 and the retransmission antenna 9 are set to have different polarization planes. Note that the receiving antenna 7 of the second retransmitting device 6b matches the polarization plane of the retransmitting antenna 9 of the first retransmitting device 6a.
[0033]
In the above configuration, the first retransmitting device 6a receives the ISDB-T signal transmitted from the base station by the receiving antenna 7 installed outside the building 1, and inputs the ISDB-T signal to the amplifying device 8. The amplifying device 8 amplifies the ISDB-T signal received by the receiving antenna 7 with the amplifier 12 and adjusts the ADB circuit 13 to a predetermined level, for example, the level of a weak electric field, and retransmits the signal from the retransmitting antenna 9 into the room 2a. I do.
[0034]
The ISDB-T receiver 4 in the room 2a receives the radio wave retransmitted from the retransmission antenna 9 of the first retransmission device 6a by the antenna 5 to watch the ISDB-T broadcast.
[0035]
Further, the second retransmitting device 6b receives the radio wave retransmitted into the room 2a from the retransmitting antenna 9 of the first retransmitting device 6a by the receiving antenna 7, amplifies the radio wave by the amplifying device 8, Retransmission is performed from the retransmission antenna 9 to the ISDB-T receiver 4 in the room 2b. The ISDB-T receiver 4 receives the radio wave retransmitted from the retransmission antenna 9 of the second retransmission device 6b by the antenna 5 to watch the ISDB-T broadcast.
[0036]
Even if the ISDB-T radio wave transmitted from the base station does not reach the rooms 2a and 2b in the building 1, the first retransmitting device 6a and the second retransmitting device 6b are installed. Accordingly, in both the room 2a and the room 2b, the radio wave retransmitted from the first retransmitting device 6a or the second retransmitting device 6b can be received by the ISDB-T receiver 4, and the broadcast of the ISDB-T can be performed. You can watch.
In addition, in the second embodiment, the same effects as in the first embodiment can be obtained.
[0037]
Next, a specific configuration example of the retransmission devices 6 and 6b will be described.
FIG. 5A is a side view showing a specific configuration example of the retransmitting devices 6 and 6b, and FIG. 5B is a perspective view of the same. The receiving antenna 7 uses, for example, a dipole antenna or a pattern antenna, and is installed in parallel to the wall 3 in the room 2a at a constant interval, and its polarization plane is applied to the ISDB-T signal transmitted from the base station. Match. For example, when the ISDB-T signal transmitted from the base station is a horizontal polarization (or a vertical polarization), the polarization plane of the receiving antenna 7 is set according to the horizontal polarization (or the vertical polarization). An amplifying device 8 is installed on the wall 3 below the receiving antenna 7. Further, one or a plurality of, for example, three reflectors 21a to 21c are installed between the reception antenna 7 and the wall 3 at an angle of 90 ° with respect to the polarization plane of the reception antenna 7, and the reflection plate 21a to 21c from the adjacent room 2b is set. The retransmission signal, that is, the retransmission signal from the retransmission antenna 9 whose details will be described later, is reflected as shown by an arrow a.
[0038]
In the room 2b, a retransmission antenna 9 is installed near the wall 3, and its polarization plane is adjusted to a polarization different from that of the reception antenna 7, that is, a vertical polarization (or a horizontal polarization). Further, a plurality of reflectors 22a to 22c are installed between the retransmission antenna 9 and the wall 3 at an angle of 90 ° with respect to the polarization plane of the retransmission antenna 9, and the signal from the chamber 2a is reflected as shown by an arrow b. I do.
[0039]
A hole 23 is formed in the wall 3 in the vicinity of the lower side of the amplifying device 8, a coaxial cable 24 is inserted into the hole 23, and the output end of the amplifying device 8 is connected to the retransmission antenna 9. I do. Instead of using the hole 23 formed in the wall 3 as described above, the output end of the amplification device 8 and the retransmission antenna 9 may be connected to each other through the coaxial cable 24 in the gap between the doors.
[0040]
By disposing the amplifying device 8 on the receiving antenna 7 side as described above, it is possible to minimize the retransmission signal that goes around the input side of the amplifying device 8.
[0041]
Further, by changing the polarization planes of the receiving antenna 7 and the retransmitting antenna 9, the amount of radio waves circulating from the retransmitting antenna 9 to the receiving antenna 7 can be minimized.
[0042]
Further, a plurality of reflectors 21a to 21c are installed between the receiving antenna 7 and the wall 3 at an angle of 90 ° with respect to the polarization plane of the receiving antenna 7, and a retransmission signal from the retransmission antenna 9 provided in the adjacent room. Is reflected, for example, when the wall 3 is thin and the radio wave from the retransmission antenna 9 leaks, it is possible to prevent the radio wave from entering the reception antenna 7.
[0043]
Further, a plurality of reflectors 22a to 22c are installed between the retransmission antenna 9 and the wall 3 at an angle of 90 ° with respect to the polarization plane of the retransmission antenna 9, and the signal from the room 2a is reflected, whereby the wall 3 is reflected. And the sensitivity of the receiving antenna 7 can be increased when radio waves leak from the room 2a.
[0044]
Next, another configuration example of the reception antenna 7 and the retransmission antenna 9 used in the retransmission devices 6 and 6b will be described with reference to FIG.
FIG. 6 is a side view showing a configuration example of the retransmission devices 6 and 6b. A dipole antenna is used as the reception antenna 7 and the retransmission antenna 9, and the reception antenna 7 is perpendicular to the wall 3 in the room 2 a, and the retransmission antenna 9 is perpendicular to the wall 3 in the room 2 b. Installed in That is, the receiving antenna 7 and the retransmitting antenna 9 are installed so as to be located on a straight line with the wall 3 interposed therebetween.
[0045]
An amplifying device 8 is installed below the receiving antenna 7 on the wall 3 in the chamber 2a. Then, a hole 23 is formed in the wall 3 in the vicinity of the lower side of the amplification device 8, a coaxial cable 24 is inserted into the hole 23, and the output end of the amplification device 8 is connected to the retransmission antenna 9. I do.
[0046]
Since the dipole antenna has a large radiation in the front direction and little radiation to the side, by installing the receiving antenna 7 and the retransmitting antenna 9 in a straight line as described above, It is possible to minimize the amount of radio waves circulating from the antenna 9 to the receiving antenna 7.
[0047]
Next, still another configuration example of the reception antenna 7 and the retransmission antenna 9 used in the retransmission devices 6 and 6b will be described with reference to FIG.
FIG. 7 is a side view showing a configuration example of the retransmission devices 6 and 6b.
A dipole antenna is used as the reception antenna 7 and the retransmission antenna 9. The receiving antenna 7 is installed vertically to the ceiling 31 near the wall 3 in the room 2a, and the retransmission antenna 9 is installed vertically to the ceiling 31 near the wall 3 in the room 2b.
[0048]
Then, one or a plurality of rectangular reflectors 32 are installed in the same direction as the receiving antenna 7 between the wall 3 and the receiving antenna 7 in the chamber 2a. The reflector 32 is set longer than the receiving antenna 7 and operates as a reflecting element of the receiving antenna 7.
[0049]
One or more rectangular reflectors 33 are installed between the wall 3 in the chamber 2b and the retransmission antenna 9 in the same direction as the retransmission antenna 9. The reflector 33 is set longer than the retransmission antenna 9 and is operated as a reflection element of the retransmission antenna 9.
[0050]
As described above, the reflection plate 32 is provided on the reception antenna 7 and the reflection plate 33 is provided on the retransmission antenna 9, and each is operated as a reflection element, so that the amount of radio waves circulating from the retransmission antenna 9 to the reception antenna 7 is obtained. Can be minimized, and the gains of the reception antenna 7 and the retransmission antenna 9 can be improved.
[0051]
Although the specific configuration examples of the retransmitting devices 6 and 6b are shown in FIGS. 5 to 7, the first retransmitting device 6a shown in FIG. 4 can be similarly configured. is there. That is, the first retransmitting device 6a can be configured similarly to the retransmitting devices 6 and 6b, except that the amplifier 12 is provided on the retransmission antenna 9 side.
[0052]
【The invention's effect】
As described above, according to the present invention, a retransmitting device is provided in a building or the like where radio waves are difficult to reach, and an ISDB-T signal from a base station is received by a receiving antenna installed at a position where radio waves can be received. After amplifying the signal, the radio wave from the base station does not reach or is difficult to reach, so it is retransmitted from the retransmission antenna installed in the room, so modulation and demodulation of ISDB-T signal, frequency conversion, loop-around cancellation for each channel, etc. There is no need to perform processing, retransmission of the entire UHF band can be realized with a simple system configuration, and the ISDB-T signal can be easily viewed only with an ISDB-T receiver such as a portable television. Further, it is possible to prevent oscillation caused by the retransmission signal wraparound, and to always maintain the level of the retransmission radio wave at the optimum level.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an overall configuration of an indoor retransmission system according to a first embodiment of the present invention.
FIG. 2 is a block diagram showing a detailed configuration example of the amplification device according to the embodiment.
FIG. 3 is an exemplary block diagram showing a detailed configuration example of an AGC circuit according to the embodiment;
FIG. 4 is a block diagram showing an overall configuration of an indoor retransmission system according to a second embodiment of the present invention.
FIG. 5A is a side view showing a specific configuration example of a retransmission device in the indoor retransmission system of the present invention, and FIG. 5B is a perspective view of the same.
FIG. 6 is a side view showing another specific configuration example of the retransmission device in the indoor retransmission system of the present invention.
FIG. 7 is a side view showing still another specific configuration example of the retransmission device in the indoor retransmission system of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Building 2a, 2b ... Room 3 ... Wall 4 ... ISDB-T receiver 5 ... Antenna 6 ... Retransmitting device 6a ... First retransmitting device 6b ... Second retransmitting device 7 ... Receiving antenna 8 ... Amplification Apparatus 9 Retransmission antenna 12 Amplifier 13 AGC circuit 15 First envelope detector 16 Second envelope detector 17 Variable attenuator 18 Differential amplifiers 21a to 21c, 22a to 22c Reflection Plate 23 ... Hole 24 provided in wall ... Coaxial cable 31 ... Ceiling 32, 33 ... Reflector

Claims (8)

A terrestrial digital television broadcast transmitted from a base station is received by a receiving antenna installed in a place where radio waves can reach, and is amplified by an amplifying device having an AGC circuit. An indoor retransmission system characterized in that retransmission is performed from a retransmission antenna installed in a room that is difficult to reach. 2. The indoor retransmission system according to claim 1, wherein the transmission or retransmission signal uses a modulation signal based on OFDM having resistance to multipath. A receiving antenna that is installed in a place where radio waves can reach and receives a terrestrial digital television broadcast transmitted from a base station, an amplifying device that amplifies a signal received by the receiving antenna, and a radio wave from the base station. An indoor retransmission device, comprising: a retransmission antenna that is installed in a room that is difficult to reach and that retransmits a signal amplified by the amplification device. 4. The indoor retransmitting apparatus according to claim 3, wherein the amplifying apparatus comprises an amplifier for amplifying a signal received by a receiving antenna, and an AGC circuit for adjusting a level of an output signal of the amplifier. The indoor retransmitting device according to claim 3 or 4, wherein the retransmitting antenna is set to have a different polarization plane from that of the receiving antenna, and a radio wave from the retransmitting antenna to the receiving antenna is blocked. The indoor retransmitting device according to any one of claims 3 to 5, further comprising: a reflecting plate that reflects a radio wave from the retransmitting antenna to the receiving antenna. The retransmission antenna and the reception antenna are constituted by dipole antennas, and the retransmission antenna and the reception antenna are arranged so as to be located on the same straight line, thereby preventing a radio wave from entering. An indoor retransmission device according to any one of the preceding claims. The indoor retransmission apparatus according to any one of claims 3 to 7, wherein the transmission or retransmission signal uses a modulation signal based on OFDM having resistance to multipath.

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