WO2010137287A1 - Receiving apparatus and receiving method - Google Patents

Abstract

When a receiving apparatus receives a digital signal to which no guard intervals have been added, the receiving apparatus decides a pseudo guard interval on the basis of the maximum transport delay time between the digital signal transmitting and receiving sides and then selects, as effective symbols, the symbols of sections obtained by removing the pseudo guard intervals from the received signal.

Description

Receiving apparatus and receiving method

The present invention relates to a receiving apparatus and a receiving method for receiving a digital signal such as an OFDM signal.

In digital wireless communication such as digital TV broadcasting and wireless LAN, by multi-carrier modulation, by orthogonal frequency division multiplexing (hereinafter abbreviated as “OFDM”) that transmits and receives a large amount of digital data at a low symbol rate. Transmission systems are widely used.

In a conventional OFDM signal transmission system, the symbol on the transmission side is improved in order to improve the bit error rate (hereinafter abbreviated as “BER”) by preventing intersymbol interference caused by reflected wave delay or the like. A method is used in which a guard interval (hereinafter abbreviated as “GI”) is added for transmission every time.

However, the method of adding a GI has a drawback that the data transmission rate is lowered and the transmission efficiency is deteriorated because the redundancy is increased by the GI.

As a method for improving the deterioration of transmission efficiency, an OFDM signal is transmitted without adding a GI, and a reception signal correction process is performed on the reception side to eliminate intersymbol interference caused by a reflected wave delay, and then a demodulation process is performed. A technique for performing this has been proposed (see, for example, Patent Document 1).

FIG. 11 is a block diagram of a conventional receiving apparatus. A conventional receiving apparatus 100 includes an antenna 111, a reception processing unit 112, a correction processing unit 101, and a demodulation processing unit 102.

The reception processing unit 112 performs processing such as down-conversion on a single carrier signal received via the antenna 111, extracts an OFDM signal to which no GI is added, and outputs a sampled signal sequence.

The correction processing unit 101 includes an FFT (Fast Fourier Transform) unit 113, an FDE (Frequency Domain Evaluation) unit 114, an IFFT (Inverse Fast Fourier Transform) unit 115, a setting unit 116, and a selection unit 116. Yes. The FFT unit 113 performs fast Fourier transform (hereinafter abbreviated as “FFT”) for each predetermined section of the sampled signal sequence to obtain a plurality of frequency signal sequences. The FDE unit 114 performs signal correction processing by frequency domain equalization (hereinafter abbreviated as “FDE”) for each frequency signal series. IFFT section 115 performs an inverse Fourier transform (hereinafter abbreviated as “IFFT”) on the corrected frequency signal sequence to obtain a corrected signal sequence. The setting unit 116 sets these processing sections. The selection unit 117 selects a predetermined part of the correction signal series. The demodulation processing unit 102 includes an FFT unit 121 and a demodulation unit 118, demodulates the correction signal sequence, and outputs received data.

However, the conventional receiving apparatus has a drawback that the configuration of the correction processing unit 101 is complicated and large as shown in FIG.

JP 2006-304192 A

The receiving apparatus of the present invention includes a reception processing unit, a symbol acquisition unit, and an effective symbol selection unit. The reception processing unit receives a transmission signal in a symbol section composed of a symbol sequence having a predetermined time width. The symbol acquisition unit acquires a symbol from the transmission signal received by the reception processing unit. The effective symbol selection unit removes, from the symbol section, a symbol guard section (hereinafter, abbreviated as “pseudo GI”) as a pseudo guard interval (hereinafter, abbreviated as “pseudo GI”) from the symbol acquired by the symbol acquisition unit. Select as a valid symbol.

With such a configuration, the receiving apparatus can receive the digital signal satisfactorily by removing the intersymbol interference caused by the reflected wave delay with a simple configuration.

The reception method of the present invention includes a reception processing step, a symbol acquisition step, and an effective symbol selection step. The reception processing step receives a transmission signal in a symbol section composed of a sequence of symbols having a predetermined time width. In the symbol acquisition step, a symbol is acquired from the transmission signal received in the reception step. The effective symbol selection step removes the interval in front of the symbol interval from the symbol interval as a pseudo GI with respect to the symbol acquired in the symbol acquisition step, and selects symbols in the remaining interval as effective symbols.

FIG. 1A is a block diagram showing a configuration of a receiving apparatus according to Embodiment 1 of the present invention. FIG. 1B is a block diagram showing an internal configuration of the symbol selection unit in Embodiment 1 of the present invention. FIG. 2 is a conceptual diagram for explaining symbol intervals in the first embodiment of the present invention. FIG. 3 is a conceptual diagram for explaining the maximum delayed reflected wave in the first embodiment of the present invention. FIG. 4 is a flowchart for explaining the processing flow of the receiving apparatus according to Embodiment 1 of the present invention. FIG. 5 is a block diagram showing a configuration of another example receiving apparatus according to Embodiment 1 of the present invention. FIG. 6A is a block diagram showing a configuration of a receiving apparatus according to Embodiment 2 of the present invention. FIG. 6B is a conceptual diagram for explaining a pseudo guard interval candidate table (hereinafter, abbreviated as “pseudo GI candidate table section”) according to Embodiment 2 of the present invention. FIG. 7 is a flowchart for explaining a processing flow of a pseudo guard interval setting unit (hereinafter, abbreviated as “pseudo GI setting unit”) according to the second embodiment of the present invention. FIG. 8 is a block diagram showing a configuration of another example receiving apparatus according to Embodiment 2 of the present invention. FIG. 9 is a block diagram showing the configuration of the receiving apparatus according to Embodiment 3 of the present invention. FIG. 10 is a flowchart for explaining the processing flow of the receiving apparatus according to Embodiment 3 of the present invention. FIG. 11 is a block diagram showing a configuration of a conventional receiving apparatus.

(Embodiment 1)
Embodiments of the present invention will be described below in detail with reference to the drawings. In all the embodiments, an OFDM signal is described as an example of a received signal. However, other digital signals that may cause noise at the beginning of the received signal due to intersymbol interference due to reflected delay waves are used. In contrast, the receiving apparatus and the receiving method according to the embodiment of the present invention can be applied.

FIG. 1A is a block diagram showing a configuration of receiving apparatus 10A in the first embodiment. FIG. 1B is a block diagram showing an internal configuration of the symbol selection unit 33 according to Embodiment 1 of the present invention.

The reception processing unit 12 performs processing such as down-conversion on the single carrier signal received via the antenna 11, takes out the OFDM signal to which no GI is added, and outputs a sampled signal sequence. That is, the reception processing unit 12 receives a transmission signal in a symbol section composed of a sequence of symbols having a predetermined time width. The symbol interval will be described in detail later.

As shown in FIG. 1B, the symbol selection unit 33 includes a symbol acquisition unit 33A and an effective symbol selection unit 33B. The symbol acquisition unit 33A acquires symbols in a symbol section having a predetermined time width from the sampling signal sequence output from the reception processing unit 12. Then, the effective symbol selection unit 33B removes, as a pseudo GI, a front section in which intersymbol interference due to reflected wave delay occurs from the symbol section. Then, the effective symbol selection unit 33B selects and outputs the remaining section symbols as effective symbols. FIG. 2 is a conceptual diagram for explaining symbol intervals in the first embodiment of the present invention. FIG. 2 illustrates the relationship among symbol intervals, pseudo GIs, and intervals having valid symbols. As shown in FIG. 2, the symbol section is composed of a pseudo GI and a section having an effective symbol. The pseudo GI is a front section in which inter-symbol interference due to reflected wave delay may occur in the symbol section as described above. Behind that, there is a section having an effective symbol.

The FFT unit 34 performs an FFT process on the effective symbol output from the effective symbol selection unit 33B, converts it into a multicarrier signal sequence as an effective conversion demodulated symbol, and outputs it.

The demodulator 35 demodulates the effective conversion demodulated symbol output from the FFT unit 34 and outputs it as received data.

As described above, in the present embodiment, after removing a section where intersymbol interference due to reflected wave delay occurs from the symbol section of the received signal as a pseudo GI, an effective symbol is selected from the remaining sections and demodulated. Therefore, the correction processing unit 101 as shown in FIG. 11 is not necessary, and high-quality received data can be obtained with an extremely simple configuration.

The receiving apparatus 10A in the present embodiment removes the pseudo GI from the symbol interval as a fixed length, selects and outputs an effective symbol from the remaining interval, and performs an FFT process. That is, a section where the delay of the reflected wave received by the antenna 11 is maximum is set as a fixed value of the pseudo GI, and the influence of intersymbol interference due to the reflected wave is reduced by removing this fixed value section.

Next, a method of calculating the maximum delay section when setting the pseudo GI as a fixed length will be described with reference to FIG. FIG. 3 is a conceptual diagram for explaining the maximum delayed reflected wave in the first embodiment of the present invention. In order to simplify the calculation, the height of the transmission point 60 and the reception point 61 from the ground 59 is the same, and the height is represented by h. The maximum delay among the reflected waves from the ground 59 received at the reception point 61 is the reflected wave reflected at the intermediate point 62 on the ground 59 corresponding to the intermediate point between the transmission point 60 and the reception point 61. is there. The reflected wave in this case is defined as the maximum delayed reflected wave. The maximum transmission delay time is the transmission delay time of the maximum delayed reflected wave. Accordingly, the maximum transmission delay time is the maximum transmission delay time of the transmission signal between the transmission unit (transmission point 60) that transmits the transmission signal and the reception processing unit 12 (reception point 61) that receives the transmission signal. It is time to become.

Here, it is assumed that the direct wave path length (reception distance) from the transmission point 60 to the reception point 61 is Dd. If the path length of the maximum delayed reflected wave is Dr, the distance between the transmission point 60 and the intermediate point 62 is Dr / 2. Similarly, the distance between the intermediate point 62 and the receiving point 61 is also Dr / 2. Here, the path length Dr of the maximum delayed reflected wave is expressed by Expression (1). In addition, the symbol in () in the following formula | equation shows a meter with a unit.

Dr = 2 × ((Dd / 2) ² + h ² ) ^1/2 (m) (1)
Therefore, the path difference D between the direct wave and the maximum delayed reflected wave is
D = Dr−Dd (m) (2)
It becomes. When the maximum transmission delay time, which is the transmission delay time of the maximum delayed reflected wave, is Td, the maximum transmission delay time Td is obtained by Expression (3).

Td = D / C (seconds) (3)
C represents the speed of light, and the value is 3 × 10 ⁸ (m / sec).

As described above, if the section having the maximum transmission delay time Td from the beginning of the symbol section is removed as a pseudo GI, the obstacle due to the reflected wave is reduced.

Also, since the time length Ts of the symbol section is the reciprocal of the transmission symbol rate Sr, it is as shown in Equation (4).

Ts = 1 / Sr (second / symbol) (4)
Therefore, the pseudo GI length Lp is as shown in Equation (5).

Lp = Td / Ts = Td × Sr (symbol) (5)
Since the transmission symbol rate Sr, the reception distance Dd, and the height h of the transmission point 60 and the reception point 61 are predetermined values, the pseudo GI length Lp corresponding to the reception distance Dd is expressed by (3) and (5) as ( Dr−Dd) × Sr / C, which is calculated as a fixed value.

Next, the processing flow of the receiving apparatus 10A in the present embodiment will be described. FIG. 4 is a flowchart for explaining the processing flow of receiving apparatus 10A according to Embodiment 1 of the present invention. As shown in FIG. 4, the reception method of this embodiment includes at least a reception processing step (step S10), a symbol acquisition step (step S11), and an effective symbol selection step (step S12). Further, an FFT step (step S13) and a demodulation step (step S14) are further provided.

In the reception processing step, the reception processing unit 12 performs processing such as down-conversion on the single carrier signal received via the antenna 11, takes out the OFDM signal to which no GI is added, and outputs a sampled signal sequence. In other words, the reception processing step receives a transmission signal in a symbol section composed of a symbol sequence having a predetermined time width (step S10).

In the symbol acquisition step, the symbol acquisition unit 33A extracts a symbol in a symbol section having a predetermined time width from the sampled signal sequence output from the reception processing unit 12 (step S11).

In the effective symbol selection step, the effective symbol selection unit 33B removes, as a pseudo GI, a front section where intersymbol interference due to reflected wave delay occurs from the symbol section. Then, the effective symbol selection step selects and outputs the symbols in the remaining section as effective symbols (step S12).

In the FFT step, the FFT unit 34 performs FFT processing on the effective symbol output from the effective symbol selection unit 33B, converts it into a multicarrier signal sequence, and outputs it (step S13).

In the demodulation step, the demodulator 35 demodulates the multicarrier signal sequence output from the FFT unit 34 and outputs it as received data (step S14).

As described above, in the reception method of the present embodiment, the effective symbol selection unit 33B removes the pseudo GI from the symbol interval as a fixed length, selects and outputs an effective symbol from the remaining interval, and performs FFT processing. That is, by setting the interval in which the delay of the reflected wave received by the antenna 11 is maximum as a fixed value of the pseudo GI and removing this fixed value interval, the influence of intersymbol interference due to the reflected wave can be reduced. .

FIG. 5 is a block diagram showing a configuration of another example of receiving apparatus 10B according to Embodiment 1 of the present invention. The configuration of the receiving apparatus 10B in another example is that a pseudo guard interval setting unit 41 is further provided in addition to the configuration of the receiving apparatus 10A illustrated in FIG. 1A. In FIG. 5, the pseudo GI setting unit 41 calculates a fixed value Lp corresponding to the reception distance Dd when the receiving apparatus 10B is installed, and initially sets it as a pseudo GI. The fixed value Lp may be calculated from the equations (3) and (5) as described above.

The reception processing unit 12 performs processing such as down-conversion on the single carrier signal received via the antenna 11, takes out an OFDM signal without GI addition, and outputs it as a sampled signal sequence.

As shown in FIG. 1B, the symbol selection unit 33 includes a symbol acquisition unit 33A and an effective symbol selection unit 33B. The symbol acquisition unit 33A acquires symbols in a symbol section having a predetermined time width from the sampling signal sequence output from the reception processing unit 12. Then, the effective symbol selection unit 33B removes the pseudo GI length Lp set by the pseudo GI setting unit 41 from the symbol section. Then, the effective symbol selection unit 33B selects and outputs symbols in the remaining section with less delay wave interference as effective symbols.

The FFT unit 34 performs an FFT process on the effective symbol output from the effective symbol selection unit 33B based on the pseudo GI set by the pseudo GI setting unit 41, and outputs a multicarrier signal sequence as an effective conversion demodulated symbol.

The demodulator 35 demodulates the effective conversion demodulated symbol output from the FFT unit 34 and outputs received data.

According to another example of receiving apparatus 10B in the present embodiment configured as described above, pseudo GI length Lp corresponding to the maximum transmission delay time corresponding to the reception distance is calculated and initially set when receiving apparatus 10B is installed. Thus, an effective symbol can be output. Therefore, it is possible to receive a digital signal satisfactorily by removing intersymbol interference caused by reflected wave delay with a simple configuration.

(Embodiment 2)
FIG. 6A is a block diagram showing a configuration of receiving apparatus 10C according to Embodiment 2 of the present invention. In the second embodiment, a description will be given of a receiving apparatus 10C that can dynamically cope with a change in reception environment by selecting an optimum value from a plurality of pseudo GI candidate values. The receiving apparatus 10C according to the present embodiment is different from the receiving apparatus 10A shown in FIG. 1A in that a pseudo GI setting unit 51, a bit error rate calculation unit (hereinafter abbreviated as “BER calculation unit”) 36, and a pseudo GI candidate. The table portion 52 is further provided. In FIG. 6A, blocks having the same functions and operations as those in FIG. 5 are denoted by the same reference numerals, and detailed description thereof is omitted. FIG. 6B is a conceptual diagram for explaining the pseudo GI candidate table unit 52 according to Embodiment 2 of the present invention.

First, the function of the pseudo GI candidate table unit 52 will be described. The pseudo GI candidate table unit 52 is provided with a ratio of symbol intervals to a predetermined number of pseudo GI sections, and sequentially outputs them. In this case, the predetermined number is four. Specifically, as shown in the pseudo GI candidate table 52A in FIG. 6B, pseudo GI candidate values in which the ratio of the pseudo GI section to the symbol section is 1/4, 1/8, 1/16, and 1/32, respectively. The pseudo GI candidate table unit 52 has Lp1, Lp2, Lp3, and Lp4.

FIG. 7 is a flowchart 51A for explaining the processing flow of the pseudo GI setting unit 51 in the second embodiment of the present invention. As shown in FIG. 7, first, the pseudo GI setting unit 51 sets one of a predetermined number of candidate values as a pseudo GI. When selecting the pseudo GI, the pseudo GI setting unit 51 selects the pseudo GI candidate values from the pseudo GI candidate table 52A in the order of decreasing the ratio of the pseudo GI to the symbol section (Lp4 → Lp3 → Lp2 → Lp1). select. That is, the pseudo GI setting unit 51 sets a minimum candidate value as a new pseudo GI among candidate values larger than the previously selected candidate value among a predetermined number of candidate values.

In the pseudo GI setting step, the selected pseudo GI candidate value, which is one of a predetermined number of candidate values, is set as a pseudo GI for the symbol selection unit 33 (step S17). In the effective symbol selection step, the symbol selection unit 33 selects and outputs an effective symbol based on the set pseudo GI (step S12a). In the FFT step, the FFT unit 34 performs FFT processing on the effective symbol, demodulates the effective conversion symbol, and outputs the demodulated symbol to the demodulation unit 35 (step S13). In the demodulating step, the demodulator 35 demodulates the FFT-processed effective conversion symbol and outputs the effective conversion demodulated symbol as received data (step S14).

In the BER calculation step, the BER calculation unit 36 calculates the BER of the effective conversion demodulated symbol output from the demodulation unit 35. Then, the BER calculation unit 36 outputs the BER to the pseudo GI setting unit 51 (step S15). Thereafter, the pseudo GI setting unit 51 compares and determines the calculated BER with a predetermined BER (step S16).

When the BER is larger than the predetermined BER (“Yes” in step S16), the process returns to step S17 in which the next largest pseudo GI candidate value is set from the pseudo GI candidate table 52. Then, BER is calculated by a series of subsequent steps (step S15), and compared with a predetermined BER (step S16). That is, when the BER calculated by the BER calculation unit 36 is larger than the predetermined BER, the pseudo GI setting unit 51 selects a candidate value different from the previously selected candidate value from the predetermined number of candidate values as a new pseudo GI. Then, the effective symbol selection unit 33B selects an effective symbol based on the new pseudo GI. The predetermined BER may be set to a BER that allows the received data to be considered substantially error-free.

The above processing is repeated until Lp1 is selected as the pseudo GI candidate value. If the BER becomes equal to or lower than a predetermined BER during the process, the symbol selection unit uses the pseudo GI candidate value at that time as the pseudo GI. The setting is made for 33 and the process is terminated. Note that, even if the maximum Lp1 is selected as the pseudo GI candidate value, if the BER does not fall below the predetermined BER, Lp1 is set as the pseudo GI to the symbol selection unit 33, and the process ends.

In the present embodiment, the pseudo GI is not initially set as a fixed length as in the first embodiment, but the pseudo GI is appropriately set so that the BER becomes equal to or lower than a predetermined BER in accordance with a change in the reception environment. Dynamically selected. Therefore, by selecting an optimum value from a plurality of pseudo GI candidate values, it is possible to dynamically cope with changes in the reception environment.

In this embodiment, the pseudo GI candidate table 52A is configured with four pseudo GI candidate values. However, the number of pseudo GI candidate values need not be limited to this, and can be increased or decreased according to the implementation status. is there.

FIG. 8 is a block diagram showing a configuration of another example of receiving apparatus 10D according to Embodiment 2 of the present invention. The receiving apparatus 10D of FIG. 8 is different from the receiving apparatus 10C of FIG. 6A in that it further includes a selection instruction unit 53.

The reception processing unit 12 performs processing such as down-conversion on the single carrier signal received via the antenna 11, takes out an OFDM signal without GI addition, and outputs it as a sampled signal sequence.

When a pseudo GI selection instruction is given from the selection instructing unit 53, the pseudo GI setting unit 51 selects an optimal pseudo GI from the pseudo GI candidate table unit 52 and sends it to the symbol selection unit 33 as shown in FIG. Set for

Note that the pseudo GI selection instruction timing to the pseudo GI setting unit 51 by the selection instruction unit 53 may be any of the following timings (a) to (e). Therefore, the optimum pseudo GI can be dynamically selected as necessary.

(A) At initial setting of device (b) At power-on of device (c) At reception channel search (d) At monitoring of BER for received data (e) Other predetermined timing The symbol selection unit 33 is a reception processing unit Symbols in a symbol section having a predetermined time width are acquired from the sampled signal sequence output by 12. Then, the symbol selection unit 33 removes the pseudo GI selected by the pseudo GI setting unit 51 from the symbol interval, selects the symbols in the remaining interval with little delay wave interference as effective symbols, and outputs them.

The FFT unit 34 performs FFT processing on the effective symbols output from the symbol selection unit 33 and outputs the result as a multicarrier signal sequence.

The demodulator 35 demodulates the multicarrier signal sequence output from the symbol selector 33 and outputs it as received data.

As described above, the receiving device 10D can dynamically select an optimal pseudo GI as necessary. Therefore, the receiving device 10D can obtain high-quality received data according to the situation.

As described above, in the present embodiment, the pseudo GI selected by the pseudo GI setting unit 51 is removed from the symbol section, and the remaining section symbols with little delay wave interference are demodulated as effective symbols. Therefore, high quality received data can be obtained.

(Embodiment 3)
FIG. 9 is a block diagram showing a configuration of receiving apparatus 10E according to Embodiment 3 of the present invention. The receiving device 10E in the present embodiment includes a switching unit 37 and an effective pseudo guard interval storage unit (hereinafter abbreviated as “effective pseudo GI storage unit”) 38, compared to the receiving device 10C illustrated in FIG. 6A. Furthermore, it is different. 9, blocks having the same functions and operations as those in FIG. 6A are denoted by the same reference numerals, and detailed description thereof is omitted.

The switching unit 37 has a function of enabling or disabling the BER calculation unit 36 at a predetermined timing. That is, whether or not to output the BER output from the BER calculation unit 36 to the pseudo GI setting unit 51 is controlled at a predetermined timing. Here, as described in the second embodiment, the predetermined timing may be any of the following timings (a) to (e).

(A) At the time of initial setting of the device (b) At the time of power-on of the device (c) At the time of receiving channel search (d) At the time of monitoring BER for received data (e) Other predetermined timings The pseudo GI used by the symbol selection unit 33B to select an effective symbol is stored as an effective pseudo GI. When the BER calculation unit 36 is enabled by the switching unit 37 and the BER calculated by the BER calculation unit 36 is greater than a predetermined BER, the effective pseudo GI used last time by the pseudo GI setting unit 51a Different candidate values are selected from a predetermined number of candidate values and stored in the effective pseudo GI storage unit 38 as new effective pseudo GIs. Note that the predetermined number of candidate values are included in the pseudo GI candidate table unit 52 as described above.

With the configuration as described above, the receiving apparatus 10E according to the present embodiment can dynamically select an optimal pseudo GI as necessary. Further, since the effective pseudo GI storage unit 38 stores the current effective pseudo GI, it is possible to quickly select an effective pseudo GI candidate value that can further improve the BER. Therefore, it is possible to provide a receiving apparatus that can remove intersymbol interference caused by reflected wave delay with a simple configuration and can receive a good digital signal.

FIG. 10 is a flowchart for explaining the processing flow of receiving apparatus 10E according to Embodiment 3 of the present invention. The processing flow of the receiving device 10E in the present embodiment is compared with the processing flow of the receiving device 10A shown in FIG. 4 from the determination step (step S20) subsequent to the BER calculation step (step S15) to the pseudo GI setting step ( The steps up to step S17a) are different. Also, the same steps as those in the processing flow of the receiving apparatus 10C illustrated in FIG. 7 are denoted by the same reference numerals, and detailed description thereof is omitted. In the following, the steps different from these will be mainly described.

As shown in FIG. 10, in the processing flow of the receiving device 10E, compared with the processing flow of the receiving device 10C shown in FIG. 7, a determination step (step S20) as a switching step and an effective pseudo GI storage step (step S17b). ).

In the BER rate calculation step, the BER calculation unit 36 calculates the BER of the effective conversion demodulated symbol output from the demodulation unit 35 (step S15). The switching step switches whether to enable or disable the BER output in the BER rate calculating step at a predetermined timing (step S20). That is, when the BER is invalidated (“No” in step S20), the series of processes is terminated.

On the other hand, when the BER is validated (“Yes” in step S20), the process proceeds to a valid pseudo GI storage step (step S17b). In the effective pseudo GI storage step, the pseudo GI used to select an effective symbol in the effective symbol selection step is stored in the effective pseudo GI storage unit 38 as an effective pseudo GI. That is, when the BER output in the BER calculation step is validated by the switching step (“Yes” in step S20), and the BER calculated in the BER calculation step is larger than the predetermined BER, A candidate value different from the effective pseudo GI used last time in the GI setting step is selected from a predetermined number of candidate values and stored in the effective pseudo GI storage unit 38 as a new effective pseudo GI. Next, in the pseudo GI setting step, a new effective pseudo GI is set (step S17a).

By the method as described above, the reception method according to the present embodiment can dynamically select the optimum pseudo GI as necessary. Further, since the effective pseudo GI storage unit 38 stores the current effective pseudo GI, it is possible to quickly select an effective pseudo GI candidate value that can further improve the BER. Therefore, it is possible to provide a reception method capable of eliminating the intersymbol interference caused by the reflected wave delay with a simple configuration and receiving a good digital signal.

The present invention can be applied to reception demodulation in a digital signal receiving system, particularly a digital signal receiving system transmitted without adding a GI.

10A, 10B, 10C, 10D, 10E Receiver 11 Antenna 12 Reception processing unit 33 Symbol selection unit 33A Symbol acquisition unit 33B Effective symbol selection unit 34 Fast Fourier transform unit (FFT unit)
35 demodulator 36 bit error rate calculator (BER calculator)
37 switching unit 38 effective pseudo guard interval storage unit (effective pseudo GI storage unit)
41, 51, 51a Pseudo guard interval setting unit (pseudo GI setting unit)
52 pseudo guard interval candidate table part (pseudo GI candidate table part)
53 Selection instruction part

Claims (12)

1. A reception processing unit that receives a transmission signal in a symbol section composed of a sequence of symbols having a predetermined time width;
   A symbol acquisition unit for acquiring the symbol from the transmission signal received by the reception processing unit;
   An effective symbol selection unit that removes the symbol symbol interval from the symbol interval as a pseudo guard interval and selects the remaining symbols as effective symbols for the symbol acquired by the symbol acquisition unit; Receiver device.
2. The receiving apparatus according to claim 1, wherein the pseudo guard interval is a fixed value.
3. The receiving apparatus according to claim 1, wherein the pseudo guard interval is a maximum transmission delay time of the transmission signal between a transmission unit that transmits the transmission signal and the reception processing unit that receives the transmission signal.
4. A pseudo guard interval setting unit that sets one of a predetermined number of candidate values as the pseudo guard interval;
   A fast Fourier transform unit that fast Fourier transforms the effective symbol selected by the effective symbol selection unit based on the pseudo guard interval set by the pseudo guard interval setting unit, and outputs the symbol as an effective conversion symbol;
   A demodulator that demodulates the effective transform symbol output by the fast Fourier transform unit and outputs the demodulated symbol as an effective transform demodulated symbol;
   A bit error rate calculation unit for calculating a bit error rate of the effective conversion demodulated symbol output by the demodulation unit;
   Further comprising
   When the bit error rate calculated by the bit error calculation unit is larger than a predetermined bit error rate, the pseudo guard interval setting unit selects a candidate value different from the previously selected candidate value from the predetermined number of candidate values. The receiving apparatus according to claim 1, wherein the effective symbol selection unit selects and sets an effective symbol based on the new pseudo guard interval.
5. A switching unit that enables or disables the bit error rate calculation unit at a predetermined timing; and
   An effective pseudo guard interval storage unit that stores a pseudo guard interval used by the effective symbol selection unit to select an effective symbol as an effective pseudo guard interval;
   Further comprising
   When the bit error rate calculation unit is enabled by the switching unit and the bit error rate calculated by the bit error rate calculation unit is larger than the predetermined bit error rate, the pseudo guard interval setting unit 5. The reception according to claim 4, wherein a candidate value different from the previously used effective pseudo guard interval is selected from the predetermined number of candidate values and stored in the effective pseudo guard interval storage unit as a new effective pseudo guard interval. apparatus.
6. The said pseudo guard interval setting part sets the minimum candidate value among the said candidate values larger than the candidate value selected last time among the said predetermined number of candidate values as said new pseudo guard interval. The receiving device according to any one of the above.
7. A reception processing step of receiving a transmission signal of a symbol section composed of a sequence of symbols having a predetermined time width;
   A symbol acquisition step of acquiring the symbol from the transmission signal received in the reception step;
   An effective symbol selection step for removing the symbol section acquired in the symbol acquisition step from the symbol section as a pseudo guard interval, and selecting a symbol in the remaining section as an effective symbol.
   Receiving method.
8. The reception method according to claim 7, wherein the pseudo guard interval is a fixed value.
9. The reception method according to claim 7, wherein the pseudo guard interval is a maximum transmission delay time of the transmission signal between a transmission unit that transmits the transmission signal and the reception processing unit that receives the transmission signal.
10. A pseudo guard interval setting step for setting one of a predetermined number of candidate values as the pseudo guard interval;
    A fast Fourier transform step of fast Fourier transforming the effective symbol selected in the effective symbol selection step based on the pseudo guard interval set in the pseudo guard interval setting step, and outputting as an effective transform symbol;
    Demodulating the effective transform symbol output in the fast Fourier transform step and outputting as an effective transform demodulated symbol;
    A bit error rate calculating step of calculating a bit error rate of the effective conversion demodulated symbol output in the demodulation step;
    Further comprising
    When the bit error rate calculated in the bit error calculation step is larger than a predetermined bit error rate, a candidate value different from the candidate value previously selected in the pseudo guard interval setting step is selected from the predetermined number of candidate values. The reception method according to claim 7, wherein a new pseudo guard interval is set and a valid symbol is selected based on the new pseudo guard interval in the effective symbol selection step.
11. A switching step for switching whether to enable or disable the bit error output in the bit error rate calculation step at a predetermined timing; and
    An effective pseudo guard interval storage step for storing, in the effective pseudo guard interval storage unit, a pseudo guard interval used to select an effective symbol in the effective symbol selection step;
    Further comprising
    The bit error rate output in the bit error rate calculation step is enabled by the switching step, and the bit error rate calculated in the bit error rate calculation step is greater than the predetermined bit error rate. If it is larger, the effective pseudo guard interval is selected as a new effective pseudo guard interval by selecting a candidate value different from the effective pseudo guard interval previously used in the pseudo guard interval setting step from the predetermined number of candidate values. The reception method according to claim 10, wherein the reception method is stored in a storage unit.
12. 12. The pseudo guard interval setting step sets a minimum candidate value as a new pseudo guard interval among candidate values larger than the previously selected candidate value among the predetermined number of candidate values. The receiving method according to any one of the above.

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