JP6247024B2 - Relay device and relay system - Google Patents

Description

  The present invention relates to a relay device that relays an OFDM signal used for wireless transmission of a broadcast signal in television broadcasting or the like, and in particular, a sneak signal superimposed on a reception signal when a transmission radio wave from a transmission antenna wraps around the reception antenna. The present invention relates to a relay apparatus including a sneak canceller that removes a received signal.

2. Description of the Related Art Conventionally, an SFN-type relay apparatus that relays an OFDM signal such as terrestrial digital broadcast without frequency conversion (in other words, channel conversion) is known.
In this type of relay device, the delay profile of the sneak signal is measured in order to prevent the occurrence of problems such as oscillation due to the transmission signal sneaking to the receiving side, and reception is performed according to the measured delay profile. A sneak canceller is provided to remove a sneak signal component from the signal (see, for example, Patent Documents 1, 2, and 3).

JP 2002-271295 A JP 2004-80668 A JP 2011-103647 A

By the way, the relay device is used not only to retransmit a transmission signal from a broadcasting station but also to retransmit a transmission signal retransmitted from another relay device.
For example, when a broadcast signal is transmitted to a specific area far away from the broadcast station, a plurality of relay devices are arranged with an interval between the broadcast station and the specific region, and the broadcast signal is transmitted by each relay device. Are sequentially relayed.

  In this case, since each relay apparatus is provided with a wraparound canceller, each relay apparatus can remove a sneak signal superimposed on the received signal when a transmission signal retransmitted by itself is circulated.

  However, in the wraparound canceller, the wraparound signal can be suppressed to a low level that does not affect the television broadcast, but the wraparound signal cannot be completely removed.

  As a result, if relay devices of the same specification are used, the sneak signal cannot be sufficiently reduced in the subsequent relay device, and the quality of signals to be relayed, such as TV broadcast signals, may be reduced. It was.

  In other words, if the specifications of the relay device are the same, the delay time until the received signal received by the receiving antenna is output to the transmitting antenna as a transmission signal for retransmission is substantially the same, and the same for each relay device. A sneak signal with a delay characteristic is generated.

  Therefore, in this case, the cancellation signal for removing the sneak signal generated in each relay device has substantially the same delay characteristics, and the subsequent relay device itself cannot be removed in the subsequent relay device. The remaining signal component of the sneak signal is combined with the remaining signal component of the sneak signal that could not be removed by the preceding relay device.

  As a result, the signal level of the unnecessary signal component having substantially the same delay characteristics as the sneak signal generated in each relay device increases in the subsequent relay device. When the unnecessary signal component exceeds the cancellation performance of the wraparound canceller, the receiving device that receives the transmission signal from the subsequent relay device can normally receive and demodulate a desired signal such as a television broadcast signal. It becomes impossible.

  The present invention has been made in view of these problems, and in a relay apparatus provided with a wraparound canceller, even if a plurality of distributed arrangements are sequentially relayed by each relay apparatus, the remaining signal components of the wraparound signal are accumulated. The purpose is to be able to prevent it.

The invention according to claim 1, which has been made to achieve the above object, is a relay apparatus that receives an OFDM signal by a receiving antenna and retransmits the received signal from the transmitting antenna.
A sneak canceller for removing a sneak signal superimposed on the received signal by sneaking a transmission radio wave from the transmitting antenna to the receiving antenna;
An output means for outputting the reception signal from which the sneak signal has been removed by the sneak canceller to the transmission antenna as a transmission signal for retransmission;
With
The wraparound canceller is
A broadcast signal of a broadcast channel to be relayed is selected from reception signals received by the reception antenna, a delay profile of a sneak signal included in the broadcast signal is obtained, and a cancel signal is generated from the delay profile. Then, the sneak signal is removed from the received signal by adding the cancel signal and the received signal,
The output means includes
The sneak signal is removed by the sneak canceller and the transmission signal output to the transmission antenna is delayed by a preset delay amount, and a delay unit capable of adjusting the delay amount,
Is provided.

The invention according to claim 2 is a relay system comprising a plurality of relay devices for relaying broadcast signals composed of OFDM signals transmitted from a broadcast station, wherein the plurality of relay devices sequentially relay the broadcast signals. And
As the plurality of relay devices, including a relay apparatus according to claim 1, the delay amount of the delay unit in each of the relay devices, respectively, by being set to a different amount of delay, to the broadcast signal at the relay devices The generation timing of the wraparound signal to be superimposed is configured to be different for each relay device .

  The relay apparatus according to claim 1 includes: a wraparound canceller that removes a sneak signal from a received signal; and an output unit that outputs the received signal from which the sneak signal has been removed by the sneak canceller to a transmission antenna as a retransmission trust transmission signal. Is provided.

The output unit is provided with a delay unit that delays the transmission signal by a preset delay amount, and the delay unit is configured to be able to adjust the delay amount.
Therefore, according to the relay apparatus of the present invention, the delay characteristic of the sneak signal with respect to the relay target signal, which is generated when the transmission signal transmitted by the relay apparatus itself wraps around, can be arbitrarily set via the delay unit.

  For this reason, if a relay system in which a plurality of relay devices sequentially relay a signal to be relayed using the relay device of the present invention is constructed, the delay characteristics of the sneak signal in each relay device can be set to different characteristics. it can.

In this case, the remaining signal components for which the sneak signal could not be removed by each relay device are combined by the subsequent relay device, thereby preventing the quality of the signal to be relayed from deteriorating.
The relay system according to claim 2 is configured to sequentially relay a broadcast signal composed of an OFDM signal transmitted from a broadcast station using a plurality of the relay apparatuses of the present invention described above, and each relay The delay amounts of the delay units in the apparatus are set to different delay amounts.

  Therefore, according to the relay system of the present invention, the delay characteristic of the sneak signal in each relay apparatus is set to a different characteristic, and the remaining signal components that could not be removed by each relay apparatus are the subsequent stage components. It is possible to prevent the quality of a signal to be relayed from being deteriorated by being synthesized by the relay device.

It is a block diagram showing the structure of the relay apparatus of embodiment. It is explanatory drawing showing the structure of the relay system of embodiment, and the delay profile of the input / output signal with respect to each relay apparatus.

Embodiments of the present invention will be described below with reference to the drawings.
As shown in FIG. 1, the relay device 2 according to the present embodiment uses a receiving antenna 4 to transmit broadcast waves (that is, OFDM signals) of area broadcasting performed using one segment (so-called one-segment) of terrestrial digital broadcasting. Receiving, amplifying the received signal by the amplifier circuit 20 and outputting the amplified signal to the transmission antenna 6 to retransmit the broadcast signal from the transmission antenna 6 without changing the broadcast channel (in other words, the broadcast frequency). This is an SFN relay device.

  The relay apparatus 2 according to the present embodiment includes a sneak canceller 10 that removes a sneak signal superimposed on a reception signal when a transmission radio wave from the transmission antenna 6 sneaks to the reception antenna 4.

The wraparound canceller 10 includes a cancel signal generator 30 and an adder 14.
The cancel signal generation unit 30 obtains a delay profile of the sneak signal and generates a cancel signal from the delay profile. Similar to the one described in Patent Document 3, a discrete Fourier transform unit 32, an amplitude spectrum calculation unit 34, The reciprocal calculation unit 36, the inverse discrete Fourier transform unit 38, the correction processing unit 40, and the cancellation error calculation unit 42 are configured.

  That is, first, the relay apparatus 2 selects a broadcast signal of a broadcast channel to be relayed (in other words, a wraparound signal removal target) from the reception signals received by the reception antenna 4. An A / D converter 12 is provided for converting the frequency into an OFDM signal of the band and converting the OFDM signal into digital data.

The cancel signal generator 30 receives the baseband OFDM signal converted into digital data by the A / D converter 12.
The discrete Fourier transform unit 32 extracts a spectrum on the frequency axis of the OFDM signal by performing a discrete Fourier transform on the OFDM signal after A / D conversion input from the A / D conversion unit 12.

  The amplitude spectrum calculation unit 34 calculates the amplitude S (n) of each spectrum for each spectrum extracted by the discrete Fourier transform unit 32, samples the absolute value for a certain period, and calculates an average value (time average value). ) Calculate S (n) tav.

  Then, the reciprocal calculation unit 36 averages the time average value S (n) tav for each spectrum calculated by the amplitude spectrum calculation unit 34 within the frequency band of the OFDM signal, and within the band obtained by the averaging. By dividing the average value Av by the time average value S (n) tav of each spectrum, the reciprocal Av / S (n) tav of the time average value S (n) tav of each spectrum is calculated.

The inverse discrete Fourier transform unit 38 calculates a delay profile of the wraparound signal by performing inverse discrete Fourier transform on the calculation result obtained by the reciprocal number calculation unit 36.
Further, the correction processing unit 40 extracts 0 to N / 2 data from the delay profile composed of N data calculated by the inverse discrete Fourier transform unit 38, and adds the extracted data to the extracted data. The delay profile is corrected by multiplying by a predetermined correction coefficient (value “2” in the present embodiment).

  Then, based on the delay profile corrected by the correction processing unit 40, the cancellation error calculation unit 42 generates a cancellation signal (digital data) for removing the sneak signal from the received signal.

  Next, the adder 14 adds the cancellation signal generated by the cancellation signal generation unit 30 to the baseband OFDM signal converted into digital data by the A / D conversion unit 12, thereby generating the OFDM signal. The sneak signal is removed.

Then, the OFDM signal from which the sneak signal is removed by the adder 14 is input to the D / A conversion unit 18 via the delay unit 16.
The D / A converter 18 performs D / A conversion of the baseband OFDM signal after removal of the sneak signal input via the delay unit 16 into an analog signal, and up-converts the analog signal to the original broadcast channel. As a result, the broadcast signal from which the wraparound signal is removed is generated and output to the amplifier circuit 20.

As a result, the broadcast signal after removal of the sneak signal is amplified to a predetermined transmission level by the amplifier circuit 20 and then retransmitted from the transmission antenna 6.
Here, the delay unit 16 delays the D / A conversion timing of the OFDM signal by the D / A conversion unit 18 by a predetermined delay amount by delaying the OFDM signal after removal of the sneak signal by a predetermined delay amount.

  The delay unit 16 varies the delay time of the OFDM signal generated in each relay device 2 when sequentially relaying broadcast signals of one-segment area broadcasting using the plurality of relay devices 2, so that each relay device 2 This is for setting the delay characteristic of the generated sneak signal to a different one.

  For this reason, the delay unit 16 is provided with a delay amount setting unit 17 that is operated by the user. When the user operates the delay amount setting unit 17, the delay amount of the OFDM signal by the delay unit 16 is reduced. It can be set arbitrarily.

  However, the variable range of the delay amount by the delay amount setting unit 17 is set within a sufficiently small range so that the delay time of the OFDM signal in the relay apparatus 2 does not exceed the guard interval and the SFN is not broken. Has been.

  For example, when the distance from the broadcasting station to the relay station, between the relay stations, and from the relay station to the receiving terminal is 1 km and the broadcast signal of the UHF channel 49 is relayed in five stages, the transmission space (1 km from the broadcasting station to the receiving terminal) The delay time of the broadcast signal generated in × 6) is “3.4 μs × 6”. Note that 3.4 μs is the time required for a broadcast radio wave to pass 1 km through free space.

  Therefore, in order to transmit a broadcast signal from the broadcast station to the receiving terminal without exceeding the guard interval (126 μs), the delay time at each relay station is 21.1 μs (= (126 μs−3.4 μ × 6 ) ÷ 5) Set below.

Therefore, in this case, the variable range of the delay amount by the delay amount setting unit 17 may be set so that the delay time of the OFMD signal in the relay apparatus 2 is 21.1 μs or less.
As described above, the relay apparatus 2 according to the present embodiment includes the delay unit 16 as an output unit that outputs the reception signal from which the sneak signal has been removed by the sneak canceller 10 to the transmission antenna 6 as a transmission signal for retransmission. An amplifier circuit 20 is provided. The delay unit 16 is configured to be able to adjust the delay amount of the transmission signal (OFDM signal).

  Therefore, according to the relay device 2 of the present embodiment, the delay characteristic of the sneak signal generated when the transmission signal transmitted by the relay device 2 itself wraps around can be arbitrarily set via the delay unit 16.

  For this reason, as shown in FIG. 2, when the relay apparatus 2 of the present embodiment is used, a relay system in which a plurality of relay apparatuses 2a, 2b,. The delay characteristics of the sneak signal DS with respect to the relay target signal US in each relay apparatus 2a, 2b,... Can be set to different characteristics.

  In this way, if the delay characteristics of the sneak signal DS with respect to the relay target signal US in each relay apparatus 2a, 2b,... Are set to different characteristics, the sneak signal could not be removed by the first relay apparatus 2a in the previous stage. The remaining signal component (residual component) is combined (added) to the sneak signal DS by the second relay device 2b in the subsequent stage, and it is possible to prevent the quality of the broadcast signal to be relayed from deteriorating.

  In other words, as shown in the “conventional” signal waveform of FIG. 2, when relay devices having the same delay characteristics are used for the first relay device 2a and the second relay device 2b, each relay device 2a, 2b As a sneak signal DS for the relay target signal US received by the antennas 4a and 4b, a sneak signal having the same delay characteristic is generated.

  For this reason, in the second relay device 2b in the subsequent stage among the first relay device 2a and the second relay device 2b, the residual components included in the transmission signal transmitted from the transmission antenna 6a of the first relay device 2a are substantially the same. A sneak signal DS is generated at the timing.

  Therefore, the reception antenna 4b of the second relay device 2b receives a reception signal including an unnecessary signal component obtained by adding the residual component included in the transmission signal from the first relay device 2a and the sneak signal DS from the transmission antenna 6b. Will be entered.

  Therefore, even if the sneak signal DS is removed by the sneak canceller 10 in the second repeater 2b, an unnecessary signal component obtained by synthesizing the residual components generated in the first repeater 2a and the second repeater 2b is transmitted to the transmission antenna 6b. Will be output, and the quality of the transmission signal (broadcast signal) will deteriorate.

  In the third relay device that receives and retransmits the transmission signal from the second relay device 2b and the relay device in the subsequent stage, the unnecessary signal component obtained by synthesizing the residual components further increases, so that the transmission signal (broadcast signal) In some cases, the relay device may oscillate.

  However, if the delay characteristics of the relay apparatuses 2a, 2b,... Are set to different characteristics using the relay apparatus 2 of the present embodiment, the second relay apparatus as shown in the signal waveform of the “embodiment” in FIG. The sneak signal DS generated in 2b is generated at a different timing from the residual component included in the transmission signal from the first relay apparatus 2a in the previous stage, and the signal level of the unnecessary signal component does not increase.

  Therefore, if the relay system shown in FIG. 2 is constructed using the relay device 2 of the present embodiment and the delay characteristics of the relay devices 2a, 2b,. It is possible to prevent the quality of the broadcast signal from being deteriorated and to distribute the high-quality broadcast signal to the end of the relay system.

As mentioned above, although embodiment of this invention was described, this invention is not limited to the said embodiment, In the range which does not deviate from the summary of this invention, a various aspect can be taken.
For example, in the above-described embodiment, the case where the present invention is applied to the relay apparatus 2 that relays a broadcast signal of an area broadcast by one seg has been described. However, the present invention is not limited to the above-described implementation if the relay apparatus 2 relays an OFDM signal. The same effect can be obtained by applying in the same manner as the embodiment.

  In the above embodiment, the wraparound canceller 10 has been described as having the same configuration as that described in Patent Document 3, but the wraparound canceller 10 can remove (more specifically, reduce) the sneak signal. Any signal that generates a cancel signal may be used.

  2 ... relay device, 2a ... first relay device, 2b ... second relay device, 4, 4a, 4b ... reception antenna, 6, 6a, 6b ... transmission antenna, 10 ... sneak canceller, 12 ... A / D converter, DESCRIPTION OF SYMBOLS 14 ... Adder, 16 ... Delay part, 17 ... Delay amount setting part, 18 ... D / A converter, 20 ... Amplifier circuit, 30 ... Cancel signal generation part, 32 ... Discrete Fourier transform part, 34 ... Amplitude spectrum calculation part , 36... Reciprocal calculation unit, 38. Inverse discrete Fourier transform unit, 40... Correction processing unit, 42.

Claims (2)

A relay device that receives an OFDM signal at a receiving antenna and retransmits the received signal from a transmitting antenna,
A sneak canceller for removing a sneak signal superimposed on the received signal by sneaking a transmission radio wave from the transmitting antenna to the receiving antenna;
An output means for outputting the reception signal from which the sneak signal has been removed by the sneak canceller to the transmission antenna as a transmission signal for retransmission;
With
The wraparound canceller is
A broadcast signal of a broadcast channel to be relayed is selected from reception signals received by the reception antenna, a delay profile of a sneak signal included in the broadcast signal is obtained, and a cancel signal is generated from the delay profile. Then, the sneak signal is removed from the received signal by adding the cancel signal and the received signal,
The output means includes
The sneak signal is removed by the sneak canceller and the transmission signal output to the transmission antenna is delayed by a preset delay amount, and a delay unit capable of adjusting the delay amount,
A relay device characterized in that is provided. A relay system comprising a plurality of relay devices for relaying broadcast signals composed of OFDM signals transmitted from a broadcast station, wherein the plurality of relay devices sequentially relay the broadcast signals,
As the plurality of relay devices, including a relay apparatus according to claim 1, the delay amount of the delay unit in each of the relay devices, respectively, by being set to a different amount of delay, to the broadcast signal at the relay devices A relay system characterized in that the generation timing of the wraparound signal to be superimposed is different for each relay device .