JP2007074223A - Digital broadcast retransmission system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a digital broadcast retransmission system for retransmitting a broadcast radio wave from a broadcast station to areas incapable of directly receiving the broadcast radio wave from the broadcast station that can retransmit the broadcast radio wave via a plurality of transmission antennas over a wide range and set the same frequency of the retransmitted radio wave as the frequency of the radio wave transmitted from the broadcast station. <P>SOLUTION: Transmitting a received signal from a reception antenna 10 to the two transmission antennas 20, 30 for retransmitting the broadcast radio wave via optical fibers 22, 32 enables the two transmission antennas 20, 30 to retransmit the received signal over the wide range without causing loop oscillation or the like in a transmission path. A radio wave interference area C into which the broadcast radio waves from the transmission antennas 20, 30 both arrive at proper levels can restore the broadcast program without being adversely affected by interference between the broadcast radio waves from the transmission antennas 20, 30 by adjusting the lengths La, Lb of the optical fibers 22, 32 used for the transmission of the received signal to suppress the delay time difference of each broadcast radio wave within a permissible range. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a digital broadcast retransmission system that receives broadcast radio waves from a broadcast station and retransmits the received signal in an area where the broadcast radio waves from the broadcast station cannot be directly received.

Conventionally, as a system to retransmit broadcast radio waves in areas where broadcast radio waves from broadcast stations cannot be directly received, a receiving antenna is installed at a place where broadcast radio waves from broadcast stations can be received. The received signal from the receiving antenna is amplified by an amplifier and transmitted to each part in the area via a coaxial cable wired in the area, and transmitted via a branching device in the middle of the coaxial cable. There is known one in which a broadcast radio wave is retransmitted from the transmitting antenna by connecting an antenna (see, for example, Patent Document 1).
JP 2004-48141 A

  According to the proposed system, even in an area where the broadcast radio wave from the broadcasting station cannot be directly received, the broadcast radio wave retransmitted from the transmission antenna installed in the area can be received. However, since the coaxial cable is used to transmit the received signal, the transmission path cannot be lengthened, and should be adopted when the target area is wide. There was a problem that could not.

  In other words, when a coaxial cable is used for the transmission path of the received signal as in the above system, the received signal attenuates on the transmission path, and even if an amplifier is provided to compensate for the attenuation, the amplification operation of the amplifier Because the received signal deteriorates due to the above, there is a limit to lengthening the transmission path in the above system, and when the target area becomes wider, the received signal is transmitted to the end while ensuring the retransmittable quality as a broadcast wave It will not be possible.

  On the other hand, in order to solve such a problem, for example, the reception signal is transmitted from the reception antenna to the first transmission antenna through a coaxial cable, and the transmission antennas of the second and subsequent stages are connected to the transmission antenna of the previous stage. By connecting a receiving antenna for receiving the transmitted radio wave, the received signal may be transmitted wirelessly from the first transmitting antenna to the last transmitting antenna.

  However, this makes it possible to widen the transmission range of the received signal and retransmit the broadcast radio wave without any problem even if the area to be retransmitted becomes wide. Since the transmission radio wave from the transmission antenna wraps around and the so-called loop oscillation occurs, the frequency of the broadcast radio wave retransmitted from each transmission antenna in the radio interference area is transmitted to the relay reception antenna connected to the transmission antenna. Measures such as changing every time are necessary.

  In order to suppress the loop oscillation in this way, if the frequency of the broadcast radio wave retransmitted from each transmission antenna is set to a frequency different from the broadcast radio wave from the broadcast station, the broadcast radio wave is a so-called analog broadcast In the case of digital broadcasting with various types of information such as channels and programs, broadcast signals can be viewed on the receiving terminal side, although the broadcast program can be viewed simply by changing the channel selection. If the frequency is simply converted, the additional information does not correspond to the frequency of the broadcast radio wave (in other words, the broadcast channel), so that additional measures are required, resulting in an increase in the cost of the entire system.

In other words, in the case of digital broadcasting, if the broadcast signal is simply frequency-converted and retransmitted, the broadcast program cannot be demodulated on the receiving terminal side.
1) Provide a frequency converter for returning the frequency of the received signal to the original frequency on the receiving terminal side.

2) When the received signal is retransmitted, NIT (Network Information Table) information (specifically, data of the modulation frequency) in the broadcast signal is rewritten.
3) When the actual reception frequency does not match the modulation frequency in the NIT information, the reception terminal side ignores the modulation frequency data in the NIT information and demodulates the NIT information obtained by demodulating the actual reception frequency. A so-called frequency conversion pass-through type receiving device having a function of creating a receivable frequency table for associating with program information is installed.

Such a measure is necessary, and such a measure leads to an increase in the cost of the entire retransmission system, including devices installed on the receiving terminal side.
The present invention has been made in view of these problems, and in a system that retransmits a broadcast radio wave transmitted from a broadcast station in an area where it cannot directly receive the broadcast radio wave, the object of the retransmission Even if the area is large, broadcast radio waves can be retransmitted to the entire area using multiple transmission antennas, and the frequency of broadcast radio waves to be retransmitted from each transmission antenna can be received from the broadcasting station. An object is to enable setting to the same frequency as the broadcast radio wave transmitted to the terminal.

  In order to achieve the above object, the invention according to claim 1 is provided with a receiving antenna for receiving a broadcast wave of a digital broadcast transmitted from a broadcast station, and in an area where the broadcast wave cannot be directly received. And a transmission antenna for retransmitting the digital broadcast broadcast radio wave based on a reception signal from the reception antenna and a transmission means for transmitting the reception signal from the reception antenna to the transmission antenna in the area. The digital broadcast re-transmission system includes a plurality of transmission antennas distributed in the region as the transmission antenna, and the transmission means converts a reception signal from the reception antenna into an optical signal. An E / O converter, a distributor for distributing an optical signal from the E / O converter to each of the transmission antennas, and a plurality of optical signals distributed by the distributor A plurality of optical fibers that transmit to the transmitting antennas, and a plurality of Os that convert optical signals transmitted to the transmitting antennas through the plurality of optical fibers into electrical signals and input the electrical signals to the transmitting antennas. / E converter, and within a radio wave interference area where a plurality of broadcast radio waves retransmitted from at least two transmission antennas reach a signal level capable of receiving the digital broadcast, each broadcast radio wave The delay time of the reception signal from the reception antenna to each of the transmission antennas is set so that the difference in delay time is within a preset allowable range.

  As described above, in the digital broadcast retransmission system according to the present invention, a plurality of transmission antennas are distributed and arranged in an area where a broadcast radio wave is to be retransmitted, and a reception signal is transmitted from the reception antenna to each transmission antenna via an optical fiber. It is trying to transmit via. For this reason, it is possible to suppress the attenuation and quality degradation of the received signal that occur in the transmission path, and to transmit the received signal satisfactorily to each transmitting antenna even when the transmission path becomes longer. For this reason, even if the area where the broadcast radio wave is to be retransmitted is wide or distributed over a wide range, the broadcast radio wave can be retransmitted to the entire area via a plurality of transmission antennas.

  In addition, each transmission antenna transmits a reception signal via an optical fiber, so that loop oscillation due to wraparound of broadcast radio waves transmitted from each transmission antenna does not occur. There is no need to change the frequency of the broadcast radio wave transmitted from the transmitting antenna from the original frequency.

  Therefore, according to the present invention, the frequency of the broadcast radio wave transmitted from each transmission antenna can be set to the same frequency as the broadcast radio wave transmitted from the broadcast station to the receiving terminal. On the receiving terminal side that receives the broadcast radio wave, various functions (such as an automatic recording function based on the electronic program guide) based on the additional information included in the broadcast radio wave can be used as they are.

  In addition, when the reception signal from the reception antenna is transmitted to the transmission antenna through the optical fiber as in the present invention, the transmission antenna has only a delay time that occurs when the reception signal passes through the optical fiber, In the present invention, the received signal is transmitted after being delayed. In the present invention, the delay time is within the radio wave interference area where the broadcast radio waves from two or more transmission antennas reach a signal level at which digital broadcasting can be received. Since the delay time difference between these broadcast radio waves is set to be within a preset allowable range, digital broadcasts cannot be received (in other words, viewing broadcast programs) within the radio wave interference area. Can be prevented.

  In other words, in the present invention, the transmission antennas are distributed and arranged in the area where the broadcast radio wave is to be retransmitted, so that the broadcasts transmitted from two (or more) transmission antennas in the area. A radio wave arrives at a signal level at which digital broadcasting can be received, and a radio wave interference region where the retransmitted radio waves interfere with each other is generated.

  However, in digital broadcasting, the broadcast radio wave modulation method is set so that it is possible to prevent the receiving terminal from being unable to view the broadcast program due to multipath interference caused by reflected waves (for example, digital terrestrial broadcasting). OFDM), even if a radio wave interference area occurs where broadcast waves transmitted from two (or more) transmission antennas interfere with each other, the difference in delay time of each broadcast radio wave is within an allowable range within that area. If it is within, a desired broadcast program can be restored at the receiving terminal without any problem.

  Therefore, in the present invention, by adjusting the delay time of the received signal from the receiving antenna to each transmitting antenna, the difference between the delay times of a plurality of broadcast radio waves reaching the radio interference area is restored on the receiving terminal side. The desired broadcast program can be reliably viewed in an area where the broadcast radio wave is to be retransmitted within the allowable range.

  In order to set the delay time of the received signal from the receiving antenna to each transmitting antenna as described above, a delay circuit for delaying the received signal is provided in the transmission system of the received signal to each transmitting antenna, The delay time by the delay circuit may be adjusted. However, in this case, not only the system configuration becomes complicated, but also the adjustment work of the delay time is required. As described, in the transmission means, the delay time of the received signal from the receiving antenna to each transmitting antenna is adjusted by adjusting the length of the optical fiber from the distributor to the O / E converter on each transmitting antenna side. It should be set.

  In other words, by adjusting the length of the optical fiber that forms the transmission path of the received signal from the receiving antenna to the transmitting antenna in this way, the delay of a plurality of broadcast radio waves reaching the radio interference area from the plurality of transmitting antennas is adjusted. If the time difference is kept within an allowable range, it is not necessary to provide a delay circuit in the transmission system of the reception signal to each transmission antenna, and the present invention can be realized with a very simple configuration.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a system configuration diagram showing the overall configuration of a retransmission system to which the present invention is applied.
In the digital broadcast retransmission system of the present embodiment, the broadcast wave of the terrestrial digital broadcast distributed in the UHF band from the television broadcast station is blocked by the terrain or the building, and cannot be directly received. Built to retransmit broadcast radio waves in the area.

  For this reason, the re-transmission system of this embodiment is installed in a place where a UHF band broadcast wave (broadcast wave of terrestrial digital broadcast) transmitted from a television broadcast station that performs terrestrial digital broadcast can be received. A receiving antenna 10 for receiving broadcast radio waves and a region A and B divided into two regions to be retransmitted are installed in the regions A and B at a receiving terminal for receiving terrestrial digital broadcasts. Two transmission antennas 20 and 30 are provided for retransmitting broadcast radio waves at an appropriate level capable of receiving and demodulating terrestrial digital broadcasting.

  Further, in the digital broadcast retransmission system of the present embodiment, an E / O that converts a reception signal from the reception antenna 10 into an optical signal as transmission means for transmitting the reception signal from the reception antenna 10 to each of the transmission antennas 20 and 30. A converter 12, a distributor 14 for distributing the optical signal from the E / O converter 12 to each of the transmission antennas 20 and 30, and an optical signal distributed by the distributor 14 for each of the transmission antennas 20, The optical fibers 22 and 32 that transmit up to 30 and the optical signals transmitted to the transmitting antennas 20 and 30 through the optical fibers 22 and 32 are converted into electric signals and input to the transmitting antennas 20 and 30. O / E converters 24 and 34 are provided.

  In this embodiment, the transmission antennas 20 and 30 have the same specifications and the same characteristics (gain, directivity, etc.), and the O / E converters 24 and 34 convert the optical signals into the same signals. It is configured to transmit broadcast waves of substantially the same level from each transmission antenna 20, 30 by converting it into a level electric signal and outputting it to each transmission antenna 20, 30.

  Further, although the transmission antenna 30 is installed at a position farther away from the reception antenna 10 than the transmission antenna 20, in the present embodiment, the same broadcast is simultaneously transmitted from each of the transmission antennas 20 and 30 without causing a time difference. The lengths La and Lb of the optical fibers 22 and 32 extending from the distributor 14 to the O / E converters 24 and 34 are set to be substantially the same so that the radio wave is transmitted.

  Thus, according to the digital broadcast re-transmission system of this embodiment, the received signal from the receiving antenna 10 is converted into an optical signal by the E / O converter 12, and the optical signal is further converted by the distributor 14 to 2 By distributing, the received signal is transmitted via the optical fibers 22 and 32 to the two transmitting antennas 20 and 30 arranged in the area where the broadcast radio wave is to be retransmitted.

  For this reason, according to the present embodiment, it is possible to suppress the attenuation and quality degradation of the received signal that occur in the transmission path of the received signal from the receiving antenna 10 to each of the transmitting antennas 20 and 30, and to retransmit the broadcast radio wave. Even if the transmission path (in other words, the optical fibers 22 and 32) becomes long, the reception signals can be transmitted to the transmission antennas 20 and 30 satisfactorily.

  Further, since the transmission signals are transmitted to the transmission antennas 20 and 30 via the optical fibers 22 and 32, loop oscillation due to the sneak in of the broadcast radio waves transmitted from the transmission antennas 20 and 30 does not occur. In order to prevent the loop oscillation, it is not necessary to change the frequency of the broadcast radio wave transmitted from each of the transmission antennas 20 and 30 from the original frequency.

  Therefore, according to the present embodiment, the frequency of the broadcast radio wave transmitted from each of the transmission antennas 20 and 30 can be set to the same frequency as the broadcast radio wave transmitted from the broadcast station. On the receiving terminal side that receives the broadcast radio wave from 30, it is possible to use various functions based on additional information included in the broadcast radio wave (such as an automatic recording function based on an electronic program guide) as it is.

  In the present embodiment, the lengths La and Lb of the optical fibers 22 and 32 from the distributor 14 to the O / E converters 24 and 34 are substantially the same. , 30 can be made to coincide with each other so that the time difference generated in the broadcast radio wave transmitted from each of the transmission antennas 20, 30 can be made sufficiently small.

  For this reason, even if there is a radio wave interference area C where the broadcast radio waves transmitted from the transmission antennas 20 and 30 are at appropriate levels and the broadcast radio waves interfere with each other, the transmission antennas are included in the radio wave interference area C. The broadcast program can be restored from these broadcast radio waves without any problem without being affected by the interference of the broadcast radio waves from 20 and 30.

  In other words, in the case of digital terrestrial broadcasting, in order to modulate the broadcast signal by the OFDM (Orthogonal Frequency Division Multiplexing) method and to suppress interference due to multipath interference caused by broadcast radio waves that arrive later than the original broadcast radio waves Since the guard interval (so-called GI) is set, if the time difference between the broadcast radio waves from the transmitting antennas 20 and 30 generated in the radio wave interference area C exceeds this guard interval, the receiving terminal side The desired broadcast program cannot be restored.

  In a general optical fiber, the delay time per km is about 4.9 μs. Therefore, for example, when the guard interval is 31.5 μs (broadcast of MODE 1), the optical fibers 22 and 32 are located at the same distance from the transmitting antennas 20 and 30 in the radio wave interference region C. If the difference between the lengths La and Lb exceeds about 6.4 km (= 31.5 / 4.9), the broadcast program cannot be restored due to the interference of the broadcast radio waves from the transmitting antennas 20 and 30. Furthermore, at the points where the distances from the transmitting antennas 20 and 30 are different in the radio wave interference region C, the difference between the lengths La and Lb of the optical fibers 22 and 32 is 6 due to the difference in the delay time due to the spatial propagation of the broadcast radio wave. It is impossible to restore a broadcast program even if it is shorter than 4 km.

  Similarly, at a point where the distance from each of the transmission antennas 20 and 30 is the same in the radio wave interference region C, the guard interval is 63 μs. (Mode 2 broadcast), when the difference between the lengths La and Lb of the optical fibers 22 and 32 exceeds about 12.9 km, the broadcast program can be restored, and the guard interval is 126 μs. In the case of (mode 3 broadcast), if the difference between the lengths La and Lb of the optical fibers 22 and 32 exceeds about 25.7 km, the broadcast program can be restored.

  However, in the present embodiment, the lengths La and Lb of the optical fibers 22 and 32 are adjusted so that the time difference between broadcast radio waves transmitted from the transmission antennas 20 and 30 is sufficiently small (substantially zero). Therefore, the time difference of the broadcast radio waves from the transmitting antennas 20 and 30 generated in the radio wave interference area C does not exceed the allowable guard interval, and the receiving terminal installed in the radio wave interference area C Thus, it becomes possible to prevent the broadcast program from being unable to be restored.

As mentioned above, although one Embodiment of this invention was described, this invention is not limited to the said embodiment, A various aspect can be taken.
For example, in the above embodiment, the length of the optical fibers 22 and 32 is adjusted in order to set the delay time of the reception signal from the reception antenna 10 to reach each transmission antenna 20 and 30. As shown by a dotted line in FIG. 1, reception is performed on a transmission path (in the figure, on a coaxial cable from the O / E converter 24 to the transmission antenna 20) that transmits a reception signal to the transmission antenna 20 close to the reception antenna 10. A delay circuit 40 that delays the signal may be provided, and the delay time of the received signal may be adjusted by the delay circuit 40.

  In the above embodiment, the lengths La and Lb of the optical fibers 22 and 32 extending from the distributor 14 to the O / E converters 24 and 34 have been described as being substantially the same. The re-transmission system is configured to transmit substantially the same level of broadcast radio waves from the transmission antennas 20 and 30, and the propagation distance of the broadcast radio waves from the transmission antennas 20 and 30 to the radio wave interference area C is substantially the same. Because there is.

  For this reason, as shown in FIG. 2, for example, a high output / unidirectional transmission antenna 21 is used instead of the transmission antenna 20, and a low output / omnidirectional transmission antenna 31 is used instead of the transmission antenna 30. In a re-transmission system that is used and has different propagation distances L1 and L2 of broadcast waves from the transmission antennas 21 and 31 to the radio wave interference area C, the difference in the propagation distances L1 and L2 of the broadcast waves Since a difference occurs in the delay time, the lengths La and Lb of the optical fibers 22 and 32 extending from the distributor 14 to the respective O / E converters 24 and 34 (or from the receiving antenna 10) so as to cancel the difference. What is necessary is just to adjust the delay time of each signal generated on the transmission path to each transmitting antenna 21, 31.

  Next, in the above embodiment, a system for retransmitting a broadcast wave of terrestrial digital broadcast has been described. However, the present invention is not limited to terrestrial digital broadcast such as CS digital broadcast, BS digital broadcast, and mobile broadcast. Even in a system that retransmits broadcast radio waves to an area where the broadcast radio waves do not reach, the same effect can be obtained by applying the same as in the above embodiment. Note that the area to be retransmitted of the broadcast radio wave is not limited to the ground, but may be in a building such as an underground mall or a tunnel.

  In the above embodiment, the reception signal from the reception antenna 10 has been described as being transmitted from the transmission antennas 20 and 30 without performing frequency conversion or the like. However, for example, as in mobile broadcast, a broadcast station (mobile broadcast) In addition to broadcast radio waves (CDM / S band in mobile broadcasts) delivered from the satellite to the receiving terminal on the user side, broadcast radio waves (TDM in mobile broadcasts) that differ in modulation method and frequency due to re-transmission credit by so-called gap filler (Ku band) is distributed, the broadcast wave for the gap filler is received by the receiving antenna 10, and a broadcast signal for distribution to the receiving terminal on the user side is generated from the received signal, The broadcast signal may be transmitted to a plurality of transmission antennas 20 and 30 via an optical fiber.

  Even in this manner, in a region where the transmission antennas 20 and 30 are installed, the broadcast signal can be received and demodulated using a general receiving terminal for users.

It is a block diagram showing the structure of the whole digital broadcast re-transmission system of embodiment. It is a block diagram showing the other structural example of a digital broadcast re-transmission system.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Reception antenna, 12 ... E / O converter, 14 ... Distributor, 20, 30, 21, 31 ... Transmission antenna, 22, 32 ... Optical fiber, 24, 34 ... O / E converter, 40 ... Delay circuit .

Claims (2)

A receiving antenna for receiving a broadcast wave of a digital broadcast transmitted from a broadcasting station;
Installed in an area where the broadcast radio waves cannot be directly received, and in the area, a transmission antenna for retransmitting the broadcast radio waves of the digital broadcast based on a reception signal from the reception antenna;
Transmission means for transmitting a reception signal from the reception antenna to the transmission antenna;
A digital broadcast retransmission system comprising:
As the transmission antenna, comprising a plurality of transmission antennas distributed in the region,
The transmission means includes
An E / O converter that converts a received signal from the receiving antenna into an optical signal;
A distributor for distributing an optical signal from the E / O converter to each of the transmission antennas;
A plurality of optical fibers for transmitting a plurality of optical signals distributed by the distributor to the transmitting antennas;
A plurality of O / E converters that convert an optical signal transmitted to each of the transmission antennas via the plurality of optical fibers into an electric signal and input the electric signal to each of the transmission antennas;
In addition, within a radio wave interference area where a plurality of broadcast radio waves retransmitted from at least two transmission antennas reach a signal level at which the digital broadcast can be received, a delay time difference between the broadcast radio waves A digital broadcast retransmission system, wherein a delay time of a reception signal from the reception antenna to each of the transmission antennas is set so as to be within a set allowable range.   In the transmission means, the delay time of the received signal from the receiving antenna to each transmitting antenna is set by adjusting the length of the optical fiber from the distributor to the O / E converter on each transmitting antenna side. The digital broadcast re-transmission system according to claim 1, wherein:

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