JP6012557B2 - Diversity receiving apparatus and diversity receiving method - Google Patents

Description

  The present invention relates to a diversity receiving apparatus and a diversity receiving method for diversity reception of an orthogonal frequency division multiplexed (hereinafter referred to as OFDM) signal.

The diversity receiver selects a part of the plurality of reception antenna outputs and demodulates a signal obtained by diversity combining these. In this case, the diversity effect can be enhanced by selecting a receive antenna output having a large received power and performing diversity combining.
However, since the diversity effect also depends on the correlation of each received signal, there is a possibility that sufficient diversity gain cannot be obtained depending on the antenna arrangement.

  In response to the above concerns, the diversity receiving device disclosed in Patent Document 1 uses the distance from the transmitting antenna to each receiving antenna, the arrangement interval of the receiving antennas, and the position information of the receiving device to obtain the received signal between the receiving antennas. And the combination of the output of the receiving antennas used for diversity combining is determined based on the spatial correlation value.

JP 2005-348274 A

In the conventional technique represented by Patent Document 1, an optimum antenna combination to be used for diversity combining can be determined in consideration of a spatial correlation value between received signals received by a receiving antenna.
However, in order to determine the antenna combination, it is necessary to acquire information on antenna arrangement from an external device, for example, a GPS (Global Positioning System) or a navigation device.
For this reason, there has been a problem that the scale of the diversity receiver becomes large and complicated, and the cost becomes high.

Further, in Patent Document 1, since an arrangement interval of reception antennas is necessary as information used for determining an antenna combination, the antenna arrangement must be able to calculate a spatial correlation value, and in configuring a diversity receiver. There are restrictions on the antenna arrangement.
Furthermore, every time a diversity receiver is installed in a vehicle or the like, the user needs to set antenna arrangement information in the receiver.
Thus, in patent document 1, there existed a subject that various restrictions generate | occur | produced, when building a diversity receiver.

  The present invention has been made to solve the above-described problems, and provides a diversity receiving apparatus and diversity receiving capable of improving reception performance without preparing a separate apparatus and without being restricted by antenna arrangement. The purpose is to obtain a method.

A diversity receiving apparatus according to the present invention is a diversity receiving apparatus that receives orthogonal frequency division multiplexed signals via a plurality of receiving antennas, a plurality of demodulating sections that respectively demodulate received signals of the plurality of receiving antennas, A correlation estimation unit that calculates an index value corresponding to a correlation between reception signals of each reception antenna based on transmission path information of reception signals of each reception antenna detected by the unit, and a correlation estimation unit among a plurality of reception antennas An antenna combination determination unit that determines a combination of reception antennas to be subjected to diversity combining based on the index value calculated by the receiver, and a reception antenna that is determined as a combination for diversity combining by the antenna combination determination unit from among outputs of a plurality of demodulation units and a diversity combining unit for diversity combining the outputs of the demodulator corresponding to the correlation estimation unit Based on the information about the power of each incoming wave included in the delay profile information corresponding to the received signal of each receiving antenna detected by each demodulator, the power ratio between specific incoming waves is correlated with the received signal of each receiving antenna. you and calculates a corresponding index value.

  According to the present invention, there is an effect that reception performance can be improved without preparing a separate device and without being restricted by antenna arrangement.

It is a block diagram which shows the structure of the diversity receiver which concerns on Embodiment 1 of this invention. 4 is a block diagram showing a configuration of a demodulation unit in Embodiment 1. FIG. 3 is a block diagram showing a configuration of a correlation estimation unit in Embodiment 1. FIG. 3 is a block diagram illustrating a configuration of an antenna combination determination unit in Embodiment 1. FIG. It is a figure which shows the outline | summary of antenna combination determination. It is a block diagram which shows the structure of the correlation estimation part in Embodiment 2 of this invention. It is a block diagram which shows the structure of the correlation estimation part in Embodiment 3 of this invention. It is a block diagram which shows the structure of the demodulation part in Embodiment 4 of this invention. FIG. 10 is a block diagram showing a configuration of a correlation estimation unit in the fourth embodiment.

Embodiment 1 FIG.
1 is a block diagram showing a configuration of a diversity receiving apparatus according to Embodiment 1 of the present invention. The diversity receiver shown in FIG. 1 is a receiver that receives digital broadcasts that are broadcast using orthogonal frequency division multiplexing (OFDM) transmission technology using four receiving antennas 1a to 1d, and includes tuner units 2a to 2d, The gain adjustment units 3a to 3d, the antenna selection units 4a and 4b, the demodulation units 5a to 5d, the diversity combining unit 6, the gain control unit 7, the correlation estimation unit 8 and the antenna combination determination unit 9 are configured.

The receiving antennas 1a to 1d receive the OFDM signals of the channels selected by the tuner units 2a to 2d, respectively.
The tuner units 2a to 2d frequency-convert the OFDM signals received by the receiving antennas 1a to 1d and output IF (intermediate frequency) signals.
The gain adjusting units 3a to 3d give a predetermined gain to the IF signals output from the tuner units 2a to 2d and adjust the IF signals to have a predetermined power value.

In the diversity receiver shown in FIG. 1, among the four receiving antennas 1a to 1d, the outputs of any three receiving antennas are diversity combined and output as first received data, and the remaining one receiving antenna is received. Is output as second received data.
The first received data and the second received data represent different broadcast waves (channels), different programs, and the like.

In the conventional diversity receiver, the gain control unit 7 controls the first antenna selection unit 4a based on the reception power information of the reception antennas 1a to 1d input via the demodulation units 5a to 5d. Outputs of desired three gain adjustment units are output to the demodulation units 5a to 5c.
For example, when the first received data is required to have higher quality than the second received data, control is performed so as to select three outputs of the gain adjustment unit having a large received power.

In the diversity receiving apparatus according to the present invention, the antenna combination determination unit 9 determines the antenna combination to be used for diversity combining, and a control signal indicating this antenna combination is output to the first and second antenna selection units 4a and 4b. .
The first antenna selection unit 4a selects the output of the gain adjustment unit corresponding to the antenna combination indicated by the control signal from the outputs of the gain adjustment units 3a to 3d and outputs the selected output to the demodulation units 5a to 5c.
On the other hand, the second antenna selection unit 4b outputs outputs from gain adjustment units other than the three gain adjustment units selected by the first antenna selection unit 4a indicated by the control signal among the outputs of the gain adjustment units 3a to 3d. Is output to the demodulator 5d.
Diversity combining section 6 outputs the output of the demodulation section corresponding to each received signal of the antenna combination determined by antenna combination determining section 9 among the signals received by receiving antennas 1a to 1d in subcarrier units of the OFDM received signal. (Each output of the demodulating units 5a to 5c) is diversity-combined and output as first received data.

The correlation estimation unit 8 corresponds to the correlation between the reception signals received by the reception antennas 1a to 1d based on the transmission path information (for example, delay profile information and subcarrier power information) detected by the demodulation units 5a to 5d. The index value is calculated and output to the antenna combination determination unit 9.
Note that the correlation estimation unit 8 operates at a timing when all of the receiving antennas 1a to 1d receive OFDM signals from broadcasting stations of the same channel.
That is, the correlation estimation unit 8 operates at a timing at which the reception signals input to all of the demodulation units 5a to 5d are reception signals from broadcast stations of the same channel.
For example, when viewing digital broadcast video content with the first received data and searching for information on the back program as needed with the second received data, there is a period in which all of the receiving antennas 1a to 1d receive the same channel. Therefore, the correlation estimation unit 8 operates during this period.

  In the first embodiment, the case where diversity combining is performed by selecting three antenna outputs from the four receiving antennas 1a to 1d has been shown. However, in diversity combining, two antenna outputs are used. There may be. Further, the number of receiving antennas is not limited to four.

  FIG. 2 is a block diagram showing the configuration of the demodulation unit in the first embodiment, and shows the configuration of the demodulation units 5a to 5d. As shown in FIG. 2, the demodulation units 5 a to 5 d include a synchronization reproduction unit 50, an FFT (Fast Fourier Transform) unit 51, a received power detection unit 52, a transmission path estimation unit 53, an equalization unit 54, and a delay profile detection unit 55. It is configured with.

The synchronization reproducing unit 50 reproduces the carrier frequency and symbol timing of the received signal to establish synchronization between the transmission side and the reception side. The FFT unit 51 performs a predetermined number of points of Fourier transform on the output of the synchronous reproduction unit 50 and outputs a reception signal for each subcarrier.
Based on the output of the FFT unit 51, the transmission path estimation unit 53 estimates the characteristics of the transmission path from the transmission antenna to the demodulation units 5a to 5d via the reception antenna. If the transmission path is correctly estimated, each subcarrier can be demodulated by dividing the output of the FFT unit 51 by the transmission path estimation result. The equalization unit 54 outputs the result of dividing the output of the FFT unit 51 by the output of the transmission path estimation unit 53 as demodulated data.

The delay profile detection unit 55 detects the delay profile of the transmission line based on the amplitude characteristic and phase characteristic of the transmission line output from the transmission line estimation unit 53.
The delay profile represents the arrival time difference and the reception power level of all arrival waves from the transmission antenna to the reception antenna.
A delay profile can be detected by performing inverse Fourier transform on the transmission path estimation result.

  FIG. 3 is a block diagram showing the configuration of the correlation estimation unit in the first embodiment. As shown in FIG. 3, the correlation estimation unit 8 inputs each delay profile information detected by the demodulation units 5a to 5d, and an index value corresponding to the correlation between received signals from the output results of two different delay profiles. Is a correlation estimation unit, and includes cross-correlation calculation units 80a to 80f.

Based on the delay profile information detected by the demodulating units 5a and 5b, the cross-correlation calculating unit 80a correlates information on the received signals input to the demodulating units 5a and 5b among the received signals of the receiving antennas 1a to 1d ( An index value corresponding to the correlation) is calculated.
When the delay profile detection results are the same, it means that the received signals input to the demodulation units 5a and 5b are signals of the same path, and thus the correlation becomes the largest.
Therefore, the index value calculated by the cross-correlation calculation unit 80a is information proportional to the correlation between the reception signals input to the demodulation units 5a and 5b.

Similarly, the cross-correlation calculation unit 80b calculates an index value corresponding to the correlation between the reception signals input to the demodulation units 5c and 5d, and the cross-correlation calculation unit 80c receives the receptions input to the demodulation units 5a and 5c. An index value corresponding to the correlation between signals is calculated.
The cross-correlation calculating unit 80d calculates an index value corresponding to the correlation between the reception signals input to the demodulation units 5b and 5d, and the cross-correlation calculation unit 80e is a reception signal input to the demodulation units 5a and 5d. An index value corresponding to the correlation is calculated.
Finally, the cross-correlation calculation unit 80f calculates an index value corresponding to the correlation between the reception signals input to the demodulation units 5b and 5c.

FIG. 4 is a block diagram showing a configuration of the antenna combination determination unit in the first embodiment. As shown in FIG. 4, the antenna combination determination unit 9 includes a first maximum value pair detection unit 90, a first selection unit 91, a second maximum value pair detection unit 92, a correlation result determination unit 93, and antenna control information. A selection unit 94, a power comparison result determination unit 95, and a power difference detection unit 96 are provided.
Each output (index value corresponding to the correlation) of the correlation estimation unit 8 represents the correlation between signals received by two different receiving antennas, and the larger the value, the higher the correlation.
In general, it is known that the diversity gain increases as the correlation between received signals used for spatial diversity combining decreases.
Therefore, the antenna combination determination unit 9 determines three reception antennas having a small correlation between the reception signals among the reception antennas 1a to 1d, and outputs a control signal for specifying them.

The first maximum value pair detection unit 90 detects the maximum value from the index values (six) corresponding to the correlations input from the correlation estimation unit 8, and determines the combination of receiving antennas corresponding to the maximum values. Based on this, the antenna combination to be used for diversity combining is determined.
FIG. 5 is a diagram showing an outline of antenna combination determination. The correlation value shown in FIG. 5 is an index value corresponding to the correlation output by the correlation estimation unit 8. For example, the value corresponding to the correlation between the reception signals of the reception antennas 1 a and 1 b is “0.9”. The value corresponding to the correlation between the reception signals 1a and 1c is "0.3", the value corresponding to the correlation between the reception signals of the reception antennas 1a and 1d is "0.1", and the reception signals of the reception antennas 1b and 1c The value corresponding to the correlation between them is “0.5”, the value corresponding to the correlation between the reception signals of the reception antennas 1b and 1d is “0.2”, and corresponds to the correlation between the reception signals of the reception antennas 1c and 1d. The value is “0.8”.

In the case of FIG. 5, the first maximum value pair detection unit 90 includes a combination of reception antennas 1a and 1b having the maximum correlation between reception signals, and a reception antenna 1c that does not include the reception antennas 1a and 1b selected by this combination. , 1d are specified.
Subsequently, the first maximum value pair detection unit 90 selects one of the remaining reception antennas 1c and 1d so that the combination of the reception antennas 1a and 1b having the maximum correlation between the reception signals is not used for diversity combining. A combination including these is determined as an antenna combination candidate to be used for diversity combining.
That is, the first maximum value pair detection unit 90 allows the combination of the reception antennas 1a and 1c (correlation “0.3”), the combination of the reception antennas 1a and 1d (correlation “0.1”), and the reception antennas 1b and 1c. Control signals indicating the combination (correlation “0.5”) and the combination of the receiving antennas 1 b and 1 d (correlation “0.2”) are generated and output to the first selection unit 91 and the correlation result determination unit 93. Is done.

The first selection unit 91 selects four outputs specified by the control signal input from the first maximum value pair detection unit 90 among the six outputs of the correlation estimation unit 8 and selects the second maximum value pair. The data is output to the detection unit 92.
The second maximum value pair detection unit 92 detects the maximum value from the outputs (index values) of the correlation estimation unit 8 selected by the first selection unit 91, and determines the antenna combination from which the maximum value was obtained. The control signal indicating the antenna combination of the determination result is output to the correlation result determination unit 93.

The correlation result determination unit 93 is a first determination unit that determines a combination of reception antennas to be subjected to diversity combining based on the index value calculated by the correlation estimation unit 8 among the reception antennas 1a to 1d.
First, the correlation result determination unit 93 uses the four antenna combinations specified by the control signal input from the first maximum value pair detection unit 90 and the control signal input from the second maximum value pair detection unit 92. A reception antenna that is not used for diversity combining is determined using one specified antenna combination.
Next, the correlation result determination unit 93 selects a reception antenna that is determined not to be used for diversity combining among the reception antennas in the four antenna combinations specified by the control signal input from the first maximum value pair detection unit 90. The remaining combinations of receiving antennas are determined as combinations to be used for diversity combining, and a control signal indicating the antenna combination is generated and output to the antenna control information selection unit 94.
For example, in the case of FIG. 5, the second maximum value pair detection unit 92 determines the combination of the antennas 1b and 1c having the maximum correlation of “0.5”.
At this time, the correlation result determination unit 93 uses the reception antenna 1b selected for both of the two antenna combinations having the maximum correlation detected by the first and second maximum value pair detection units 90 and 92 for diversity combining. The remaining receiving antennas 1a, 1c and 1d excluding the receiving antenna 1b are determined as antenna combinations to be used for diversity combining.

The antenna control information selection unit 94 is a combination determination unit that finally determines an antenna combination to be subjected to diversity combining from the antenna combinations determined by the correlation result determination unit 93 and the power comparison result determination unit 95, respectively.
That is, the antenna control information selection unit 94 determines the antenna combination (combination based on correlation) and the power comparison result determination specified by the control signal from the correlation result determination unit 93 based on the power difference detection result by the power difference detection unit 96. From the antenna combinations (combinations based on the received power difference) specified by the control signal from unit 95, the antenna combination to be used for diversity combining is finally determined.
A control signal indicating the antenna combination determined here is output from the antenna control information selection unit 94 to the first and second antenna selection units 4a and 4b, respectively.

The power comparison result determination unit 95 is a second determination unit that determines a combination of reception antennas to be diversity-combined based on the power value of the reception signal among the reception antennas 1a to 1d. That is, the power comparison result determination unit 95 inputs demodulated data corresponding to the received signals received by the receiving antennas 1a to 1d from the demodulating units 5a to 5d, and compares the power of these demodulated data, thereby diversity. The antenna combination to be used for combining is determined.
For example, if three reception antenna outputs with large reception power are used for diversity combining, the top three powers are specified from among the outputs of the demodulation units 5a to 5d, and antenna combinations corresponding to these outputs are specified. Is generated and output to the antenna control information selection unit 94.

  The power difference detection unit 96 inputs the output of the demodulation units 5a to 5d, that is, the demodulated data corresponding to the reception signals received by the reception antennas 1a to 1d, and receives between the reception signals of the reception antennas 1a to 1d. The comparison result between the power difference between the demodulated data corresponding to the power difference and a predetermined threshold is output to the antenna control information selection unit 94 as the power difference detection result.

Based on the power difference detection result input from the power difference detection unit 96, the antenna control information selection unit 94 determines that the power difference between the demodulated data corresponding to the reception power difference between the reception signals of the reception antennas 1a to 1d is a predetermined threshold value. Is greater than the antenna combination determined by the power comparison result determination unit 95 based on the power difference, the antenna combination finally used for diversity combining is determined.
On the other hand, when the power difference between the demodulated data corresponding to the reception power difference between the reception signals of the reception antennas 1a to 1d is equal to or less than a predetermined threshold, the correlation result determination unit 93 determines based on the correlation between the reception signals. The antenna combination is finally determined as the antenna combination to be used for diversity combining.

Although the case where three reception antennas are selected by the correlation result determination unit 93 and the power comparison result determination unit 95 as the antenna combination to be used for diversity combining has been shown, two reception antennas should be selected. Also good.
In this case, the correlation result determination unit 93 determines that the antenna combination corresponding to the smallest output value (index value) among the six outputs of the correlation estimation unit 8 is the antenna combination to be used for diversity combining. .

As described above, according to the first embodiment, the demodulation units 5a to 5d demodulate the outputs of the reception antennas 1a to 1d, respectively, and the correlation estimation unit 8 detects each of the demodulation units 5a to 5d. Based on the transmission path information of the reception signals of the reception antennas 1a to 1d, an index value corresponding to the correlation between the reception signals of the reception antennas 1a to 1d is calculated. Based on the index value calculated by the correlation estimation unit 8, the combination of receiving antennas to be subjected to diversity combining is determined, and the diversity combining unit 6 uses the antenna combination determining unit 9 among the outputs of the demodulation units 5a to 5d. Diversity combining is performed on the outputs of the demodulation units corresponding to the receiving antennas determined as combinations to be combined.
In this way, it is possible to diversity combine the output of an appropriate antenna combination having a large diversity gain without preparing a separate device.
In addition, an index value corresponding to the correlation between the reception signals is calculated based on the transmission path information of the reception signals of the reception antennas 1a to 1d, and an appropriate antenna combination is selected based on the calculated index value. Therefore, it is possible to improve reception performance by diversity reception without being restricted by antenna arrangement.

Moreover, according to this Embodiment 1, the correlation estimation part 8 is based on the delay profile information corresponding to the received signal of each receiving antenna 1a-1d which each demodulating part 5a-5d detected. An index value corresponding to the correlation between 1d received signals is calculated.
In this way, the correlation between the reception signals of the reception antennas 1a to 1d is determined based on the information such as the arrival time difference between the arrival waves from the transmission antenna to the reception antenna and the reception power level included in the delay profile information. Corresponding appropriate index values can be calculated.

Furthermore, according to this Embodiment 1, the antenna combination determination part 9 determines the combination of the receiving antenna which should carry out diversity combining based on the index value which the correlation estimation part 8 calculated among the receiving antennas 1a-1d. Correlation result determination unit 93, power comparison result determination unit 95 that determines a combination of reception antennas to be subjected to diversity combining based on the power value of the reception signal among reception antennas 1a to 1d, correlation result determination unit 93, and power A power difference detection unit 96 that determines a combination of reception antennas for performing diversity combining from among the combinations of reception antennas determined by the comparison result determination unit 95, respectively.
With this configuration, it is possible to appropriately determine the antenna combination to be used for diversity combining.

Embodiment 2. FIG.
Embodiment 2 shows a case where the arrival time difference between specific arrival waves included in the delay profile information is calculated as an index value corresponding to the correlation.
FIG. 6 is a block diagram showing the configuration of the correlation estimation unit in the second embodiment of the present invention. As shown in FIG. 6, the correlation estimation unit 8A according to the second embodiment includes delay time difference calculation units 81a to 81d and time difference difference calculation units 82a to 82f.

The delay profile detection result (delay profile information) output from the delay profile detection unit 55 of the demodulation units 5a to 5d includes information on the arrival time difference of the incoming waves. If the arrival time difference is different between the signals received by the respective receiving antennas 1a to 1d, it means that these correlations are small.
Therefore, the arrival time difference can be used as an index value corresponding to the correlation between the reception signals of the reception antennas 1a to 1d.

  The delay time difference calculation units 81a to 81d calculate arrival time differences between specific arrival waves based on the delay profile information respectively input from the delay profile detection units 55 of the demodulation units 5a to 5d. For example, the delay time difference between the arriving waves is calculated using the earliest preceding wave among the arriving waves detected by the delay profile detecting unit 55 as a reference. That is, the earliest incoming wave and each incoming wave that follows this are identified, and the delay time difference of each incoming wave with respect to the earliest incoming wave is calculated as the arrival time difference.

The time difference difference calculation unit 82a is based on the delay time information about each delay time difference calculated by the delay time difference calculation unit 81a and the delay time difference calculation unit 81b, and the correlation information between the received signals input to the demodulation units 5a and 5b The corresponding index value) is calculated.
For example, when the delay profile detection results are the same at the outputs of the demodulation units 5a and 5b, the reception signals of the reception antennas 1a and 1b input to the demodulation units 5a and 5b receive incoming waves having the same delay time. Means that For this reason, it can be determined that the correlation between the reception signals of the reception antennas 1a and 1b is large. On the other hand, if the delay times of the incoming waves are different, it can be determined that the correlation is small.

Therefore, the time difference difference calculation unit 82a obtains the delay time difference between the most preceding arrival wave and the most delayed arrival wave from the output of the delay time difference calculation unit 81a, and the most preceding arrival wave from the output of the delay time difference calculation unit 81b. A delay time difference from the delayed arrival wave is obtained, an absolute value of the difference between these delay time differences is calculated, and a conversion is performed so that the larger the value is, the smaller the value is, between the reception signals of the reception antennas 1a and 1b. Is output as an index value corresponding to the correlation.
In addition, as a method for converting the delay time difference so that the absolute value of the difference in delay time is larger, the difference is smaller, for example.

The time difference difference calculation unit 82b obtains a delay time difference between the most preceding arrival wave and the most delayed arrival wave from the outputs of the delay time difference calculation units 81c and 81d, respectively, and calculates the absolute value of the difference between these delay time differences. Then, conversion is performed so that the larger the value, the smaller the value, and an index value corresponding to the correlation between the reception signals of the reception antennas 1c and 1d is output.
Similarly, the time difference difference calculation unit 82c calculates and outputs an index value corresponding to the correlation between the reception signals of the reception antennas 1a and 1c from the outputs of the delay time difference calculation units 81a and 81c.
Similarly, the time difference difference calculation unit 82d calculates and outputs an index value corresponding to the correlation between the reception signals of the reception antennas 1b and 1d from the outputs of the delay time difference calculation units 81b and 81d.
Similarly, the time difference difference calculation unit 82e calculates and outputs an index value corresponding to the correlation between the reception signals of the reception antennas 1a and 1d from the outputs of the delay time difference calculation units 81a and 81d.
Similarly, the time difference difference calculation unit 82f calculates and outputs an index value corresponding to the correlation between the reception signals of the reception antennas 1b and 1c from the outputs of the delay time difference calculation units 81b and 81c.
Note that the index value output by the time difference difference calculation unit increases as the correlation between received signals increases.

  The antenna combination determination unit 9 determines an antenna combination to be used for diversity combining based on each index value input from the correlation estimation unit 8A. This operation is the same as in the first embodiment.

  As described above, according to the second embodiment, the correlation estimation unit 8A calculates the arrival time difference between specific arrival waves as an index value based on the information about the arrival time of each arrival wave included in the delay profile information. To do. By doing so, it is possible to calculate an appropriate index value corresponding to the correlation between the reception signals of the respective reception antennas 1a to 1d.

Embodiment 3 FIG.
Embodiment 3 shows a case where a power ratio between specific arriving waves is calculated based on information about the power of each arriving wave included in the delay profile information, and this is used as an index value corresponding to the correlation. Yes.
FIG. 7 is a block diagram showing the configuration of the correlation estimation unit according to Embodiment 3 of the present invention. As shown in FIG. 7, the correlation estimation unit 8B according to the third embodiment includes D / U (Desired / Undesired) calculation units 83a to 83d and D / U difference calculation units 84a to 84f.

The delay profile detection result (delay profile information) output from the delay profile detection unit 55 of the demodulation units 5a to 5d includes information on the power of the incoming wave.
When the power of the incoming wave is different between the signals received by the respective receiving antennas 1a to 1d, it means that these correlations are small.
Therefore, an index value corresponding to the correlation between the reception signals of the reception antennas 1a to 1d can be obtained by detecting the difference in the power of the incoming waves.

The D / U calculators 83a to 83d calculate the power ratio between the incoming waves based on the delay profile information respectively input from the delay profile detector 55 of the demodulator 5a to 5d.
For example, among the arriving waves detected by the delay profile detection unit 55, the power ratio of each arriving wave is calculated with reference to the power of the earliest arriving wave, and information on the delay time and the power ratio of each arriving wave is output.

The D / U difference calculation unit 84a uses the power ratio information of each arriving wave calculated by the D / U calculation unit 83a and the D / U calculation unit 83b to generate a signal between the reception signals input to the demodulation units 5a and 5b. Correlation information (an index value corresponding to the correlation) is calculated.
For example, when the delay profile detection results of the outputs of the delay profile detection unit 55 of the demodulation units 5a and 5b are the same, the reception signals of the reception antennas 1a and 1b input to the demodulation units 5a and 5b have the same delay. It means that incoming waves with the same power ratio in time are being received.
For this reason, it can be determined that the correlation between the reception signals of the reception antennas 1a and 1b is large. On the contrary, if the power ratios between the incoming waves having the same delay time are different from each other, it can be determined that the correlation is small.

Therefore, the D / U difference calculation unit 84a obtains the power ratio between the incoming waves having the same delay time from the outputs of the D / U calculation unit 83a and the D / U calculation unit 83b, and calculates the absolute difference between these power ratios. The sum of the values is calculated, converted so as to be smaller as the value is larger, and output as an index value corresponding to the correlation between the reception signals of the receiving antennas 1a and 1b.
As a method of converting the power ratio difference so that the sum of the absolute values of the absolute values is larger, the value is smaller.

The D / U difference calculation unit 84b obtains the power ratio between the incoming waves having the same delay time from the outputs of the D / U calculation units 83c and 83d, and calculates the sum of the absolute values of the differences between these power ratios. The conversion is performed so that the larger the value is, the smaller the value is, and the index value corresponding to the correlation between the reception signals of the reception antennas 1c and 1d is output.
Similarly, the D / U difference calculation unit 84c calculates and outputs an index value corresponding to the correlation between the reception signals of the reception antennas 1a and 1c from the outputs of the D / U calculation units 83a and 83c.
Similarly, the D / U difference calculation unit 84d calculates and outputs an index value corresponding to the correlation between the reception signals of the reception antennas 1b and 1d from the outputs of the D / U calculation units 83b and 83d.
Similarly, the D / U difference calculation unit 84e calculates and outputs an index value corresponding to the correlation between the reception signals of the reception antennas 1a and 1d from the outputs of the D / U calculation units 83a and 83d.
Similarly, the D / U difference calculation unit 84f calculates and outputs an index value corresponding to the correlation between the reception signals of the reception antennas 1b and 1c from the outputs of the D / U calculation units 83b and 83c.
Note that the index value output by the D / U difference calculation unit increases as the correlation between received signals increases.

  The antenna combination determination unit 9 determines an antenna combination to be used for diversity combining based on each index value input from the correlation estimation unit 8B. This operation is the same as in the first embodiment.

The calculation of the correlation (index value) based on the power ratio between the incoming waves may be performed as follows.
The D / U difference calculation unit 84a calculates the power ratio between the arrival wave with the highest reception power and the arrival wave with the second reception power among the arrival waves detected by the delay profile detection unit 55, and these The information regarding the delay time of the incoming wave and the power ratio is output to the D / U difference calculation unit 84a and the D / U calculation units 83b to 83d.
The D / U calculators 83b to 83d identify incoming waves having the same delay time as those calculated by the D / U calculator 83a among the incoming waves detected by the delay profile detector 55. These power ratios are calculated and output as power ratio information.
The D / U difference calculation unit 84a specifies the power ratio between the incoming waves from the outputs of the D / U calculation units 83a and 83b, calculates the absolute value of the difference between these power ratios, and the larger this value, the greater the value. Conversion is performed so as to be a small value, and an index value corresponding to the correlation between the reception signals of the reception antennas 1a and 1b is output. Similarly, the D / U difference calculation units 84b to 84f calculate an index value corresponding to the correlation between received signals.

  As described above, according to the third embodiment, the correlation estimation unit 8B calculates the power ratio between specific arriving waves as an index value based on the information regarding the power of each arriving wave included in the delay profile information. . Also by doing in this way, it is possible to calculate an appropriate index value corresponding to the correlation between the reception signals of the reception antennas 1a to 1d.

Embodiment 4 FIG.
In the first to third embodiments, the case where the index value corresponding to the correlation between the reception signals of the reception antennas is calculated using the delay profile information has been described, but in the fourth embodiment, based on the subcarrier power. A configuration for calculating an index value corresponding to the correlation will be described.
FIG. 8 is a block diagram showing the configuration of the demodulation unit in the fourth embodiment of the present invention, and shows the configuration of the demodulation units 5a-1 to 5d-1. As shown in FIG. 8, the demodulation units 5 a-1 to 5 d-1 include a synchronization reproduction unit 50, an FFT unit 51, a received power detection unit 52, a transmission path estimation unit 53, an equalization unit 54, and a subcarrier power detection unit 56. It is configured with.
In FIG. 8, the same components as those in FIG.

The subcarrier power detection unit 56 calculates received power for each subcarrier of the OFDM signal based on the amplitude characteristic of the transmission path output from the transmission path estimation unit 53, and outputs it as subcarrier power information.
The subcarrier power detection unit 56 may be configured to use transmission path estimation results for some subcarriers.

FIG. 9 is a block diagram showing the configuration of the correlation estimation unit in the fourth embodiment. As shown in FIG. 9, correlation estimation unit 8C in the fourth embodiment includes inter-subcarrier power difference calculation units 85a to 85f and data conversion units 86a to 86f.
When the subcarrier power detection results (subcarrier power information) output from the subcarrier power detection units 56 of the demodulation units 5a-1 to 5d-1 are different among the reception signals of the reception antennas 1a to 1d, the correlation between the signals is Mean small.
Therefore, an index value corresponding to the correlation between the reception signals of the reception antennas 1a to 1d can be obtained by detecting the power difference between the subcarriers.

The inter-subcarrier power difference calculation unit 85a is input to the demodulation units 5a-1 and 5b-1 based on the subcarrier power information output from the subcarrier power detection unit 56 of the demodulation units 5a-1 and 5b-1. A data converter that calculates an absolute value of a power difference between subcarriers corresponding to received signals of the receiving antennas 1a and 1b, and calculates a sum of the absolute values over a plurality of subcarriers in the same symbol. To 86a. Note that the larger the value of the output signal from the inter-subcarrier power difference calculation unit 85a, the smaller the correlation between received signals.
Therefore, the data conversion unit 86a receives the output signal from the intersubcarrier power difference calculation unit 85a, performs conversion so that the larger the input value, the smaller the value, and the received signal between the reception antennas 1a and 1b. Output as an index value corresponding to the correlation.
In addition, as a method of converting the output signal from the inter-subcarrier power difference calculation unit 85a so that the output signal becomes smaller as the value becomes larger, for example, conversion to an inverse number is conceivable.

The inter-subcarrier power difference calculation unit 85b is input to the demodulation units 5c-1 and 5d-1 based on the subcarrier power information output from the subcarrier power detection unit 56 of the demodulation units 5c-1 and 5d-1. The data converter 86b calculates the absolute value of the power difference between the subcarriers corresponding to the received signals of the receiving antennas 1c and 1d, and calculates the sum of the absolute values over a plurality of subcarriers in the same symbol. Output to.
The data conversion unit 86b performs conversion so that the larger the signal value from the subcarrier power difference calculation unit 85b is, the smaller the value is, and outputs it as an index value corresponding to the correlation between the reception signals of the reception antennas 1c and 1d. .
Similarly, the data converter 86c converts the output signal from the inter-subcarrier power difference calculator 85c, calculates an index value corresponding to the correlation between the received signals of the receiving antennas 1a and 1c, and outputs it. The data converter 86d converts the output signal from the inter-subcarrier power difference calculator 85d, calculates an index value corresponding to the correlation between the received signals of the receiving antennas 1b and 1d, and outputs the calculated index value. The data conversion unit 86e converts the output signal from the inter-subcarrier power difference calculation unit 85e to calculate and output an index value corresponding to the correlation between the reception signals of the reception antennas 1a and 1d. The data conversion unit 86f converts the output signal from the inter-subcarrier power difference calculation unit 85f to calculate and output an index value corresponding to the correlation between the reception signals of the reception antennas 1b and 1c.
Note that the index value output from the data converter increases as the correlation between received signals increases.

Since the output of the correlation estimator 8C can be handled in the same manner as the correlation estimators 8, 8A, and 8B shown in the first to third embodiments, the antenna combination determination unit 9 is similar to the first embodiment. Based on each index value input from the correlation estimation unit 8C, it is possible to determine an antenna combination to be used for diversity combining.
In the first to third embodiments, the delay profile detection unit 55 of the demodulation units 5a to 5d obtains delay profile information by performing inverse Fourier transform on the power of the subcarrier.
On the other hand, in Embodiment 4, since the power of the subcarrier is used as it is, the configuration required for inverse Fourier transform is not required in demodulation sections 5a-1 to 5d-1, and the configuration of the entire diversity receiving apparatus is simplified. can do.

  As described above, according to the fourth embodiment, the correlation estimator 8C uses the power between subcarriers corresponding to the reception signals of the reception antennas 1a to 1d detected by the demodulation units 5a-1 to 5d-1. Based on the difference, an index value corresponding to the correlation between the reception signals of the reception antennas 1a to 1d is calculated. By doing in this way, the effect similar to Embodiment 1 can be acquired. Further, since the configuration for detecting the delay profile is unnecessary, the configuration of the entire diversity receiving apparatus can be simplified.

  In the present invention, within the scope of the invention, any combination of each embodiment, any component of each embodiment can be modified, or any component can be omitted in each embodiment. .

  1a to 1d receiving antenna, 2a to 2d tuner unit, 3a to 3d gain adjusting unit, 4a first antenna selecting unit, 4b second antenna selecting unit, 5a to 5d, 5a-1 to 5d-1 demodulating unit, 6 Diversity combining unit, 7 gain control unit, 8, 8A to 8C correlation estimation unit, 9 antenna combination determination unit, 50 synchronization reproduction unit, 51 FFT unit, 52 received power detection unit, 53 transmission path estimation unit, 54 equalization unit, 55 delay profile detection unit, 56 subcarrier power detection unit, 80a to 80f correlation calculation unit, 81a to 81d delay time difference calculation unit, 82a to 82f time difference difference calculation unit, 83a to 83d D / U calculation unit, 84a to 84f D / U difference calculation unit, 85a to 85f subcarrier power difference calculation unit, 86a to 86f data conversion unit, 90 first maximum value pair detection , 91 first selection portion, 92 second maximum value pair detecting unit, 93 correlation result determination unit, 94 an antenna control information selecting unit, 95 power comparison result judging unit, 96 power difference detection unit.

Claims (6)

A diversity receiver for receiving orthogonal frequency division multiplexed signals via a plurality of receiving antennas,
A plurality of demodulation units that respectively demodulate the reception signals of the plurality of reception antennas;
A correlation estimation unit that calculates an index value corresponding to a correlation between the reception signals of the reception antennas based on transmission path information of the reception signals of the reception antennas detected by the demodulation units;
Among the plurality of reception antennas, an antenna combination determination unit that determines a combination of reception antennas to be subjected to diversity combining based on the index value calculated by the correlation estimation unit;
A diversity combining unit that diversity combines the outputs of the demodulation units corresponding to the reception antennas determined by the antenna combination determination unit as a combination for diversity combining among the outputs of the plurality of demodulation units ,
The correlation estimation unit calculates a power ratio between specific arrival waves based on information on power of each arrival wave included in delay profile information corresponding to a reception signal of each reception antenna detected by each demodulation unit. diversity receiver you and calculates the index value corresponding to the correlation between the received signal of the receiving antenna.   A diversity receiver for receiving orthogonal frequency division multiplexed signals via a plurality of receiving antennas,
  A plurality of demodulation units that respectively demodulate the reception signals of the plurality of reception antennas;
  A correlation estimation unit that calculates an index value corresponding to a correlation between the reception signals of the reception antennas based on transmission path information of the reception signals of the reception antennas detected by the demodulation units;
  Among the plurality of reception antennas, an antenna combination determination unit that determines a combination of reception antennas to be subjected to diversity combining based on the index value calculated by the correlation estimation unit;
  A diversity combining unit that diversity combines the outputs of the demodulation units corresponding to the reception antennas determined by the antenna combination determination unit as a combination for diversity combining among the outputs of the plurality of demodulation units,
  The correlation estimation unit calculates an index value corresponding to a correlation between reception signals of the reception antennas based on a power difference between subcarriers corresponding to reception signals of the reception antennas detected by the demodulation units. A diversity receiver characterized in that:   A diversity receiver for receiving orthogonal frequency division multiplexed signals via a plurality of receiving antennas,
  A plurality of demodulation units that respectively demodulate the reception signals of the plurality of reception antennas;
  A correlation estimation unit that calculates an index value corresponding to a correlation between the reception signals of the reception antennas based on transmission path information of the reception signals of the reception antennas detected by the demodulation units;
  Among the plurality of reception antennas, an antenna combination determination unit that determines a combination of reception antennas to be subjected to diversity combining based on the index value calculated by the correlation estimation unit;
  A diversity combining unit that diversity combines the outputs of the demodulation units corresponding to the reception antennas determined by the antenna combination determination unit as a combination for diversity combining among the outputs of the plurality of demodulation units,
  The antenna combination determination unit
  A first determination unit that determines a combination of reception antennas to perform diversity combining based on the index value calculated by the correlation estimation unit among the plurality of reception antennas;
  A second determination unit that determines a combination of reception antennas to be subjected to diversity combining based on a power value of a reception signal among the plurality of reception antennas;
  A diversity receiving apparatus, comprising: a combination determining unit that determines a combination of receiving antennas for performing diversity combining from among the combinations of receiving antennas determined by the first and second determining units. A diversity reception method for receiving orthogonal frequency division multiplexed signals via a plurality of reception antennas,
A plurality of demodulation units respectively demodulating the reception signals of the plurality of reception antennas;
A step of calculating an index value corresponding to a correlation between the reception signals of the respective reception antennas based on transmission path information of the reception signals of the respective reception antennas detected by the respective demodulation units;
An antenna combination determining unit determining, among the plurality of receiving antennas, a combination of receiving antennas to be subjected to diversity combining based on the index value calculated by the correlation estimating unit;
A diversity combining unit, diversity combining the output of the demodulation unit corresponding to the receiving antenna determined as a combination in which the antenna combination determination unit performs diversity combining among the outputs of the plurality of demodulation units ,
In the step of calculating the index value, the correlation estimation unit is specified based on information on power of each incoming wave included in delay profile information corresponding to the reception signal of each reception antenna detected by each demodulation unit diversity reception how to characterized in that the power ratio of the incoming waves of calculating the as an index value corresponding to the correlation between the received signal of each receiving antenna.   A diversity reception method for receiving orthogonal frequency division multiplexed signals via a plurality of reception antennas,
  A plurality of demodulation units respectively demodulating the reception signals of the plurality of reception antennas;
  A step of calculating an index value corresponding to a correlation between the reception signals of the respective reception antennas based on transmission path information of the reception signals of the respective reception antennas detected by the respective demodulation units;
  An antenna combination determining unit determining, among the plurality of receiving antennas, a combination of receiving antennas to be subjected to diversity combining based on the index value calculated by the correlation estimating unit;
  A diversity combining unit that performs diversity combining of outputs of the demodulation units corresponding to the reception antennas determined by the antenna combination determination unit as a combination for diversity combining among outputs of the plurality of demodulation units;
  In the step of calculating the index value by the correlation estimation unit, based on the power difference between subcarriers corresponding to the reception signals of the reception antennas detected by the demodulation units, the reception signals of the reception antennas A diversity receiving method characterized by calculating an index value corresponding to the correlation between the two.   A diversity reception method for receiving orthogonal frequency division multiplexed signals via a plurality of reception antennas,
  A plurality of demodulation units respectively demodulating the reception signals of the plurality of reception antennas;
  A step of calculating an index value corresponding to a correlation between the reception signals of the respective reception antennas based on transmission path information of the reception signals of the respective reception antennas detected by the respective demodulation units;
  An antenna combination determining unit determining, among the plurality of receiving antennas, a combination of receiving antennas to be subjected to diversity combining based on the index value calculated by the correlation estimating unit;
  A diversity combining unit, diversity combining the output of the demodulation unit corresponding to the receiving antenna determined as a combination in which the antenna combination determination unit performs diversity combining among the outputs of the plurality of demodulation units,
  In the step of determining the combination of the receiving antennas,
  A first determination unit of the antenna combination determination unit determining a combination of reception antennas to be diversity-combined based on the index value calculated by the correlation estimation unit among the plurality of reception antennas;
  A second determining unit of the antenna combination determining unit determining a combination of receiving antennas to perform diversity combining based on a power value of a received signal among the plurality of receiving antennas;
  A step of determining a combination of receiving antennas for performing diversity combining from among the combinations of receiving antennas determined by the first and second determining units, respectively. A diversity receiving method as a feature.

Images