JP2006279815A - Diversity radio unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent communication quality from being deteriorated due to antenna switching, by controlling a timing to switch antennas during a transmission data term with no trouble in the communication quality. <P>SOLUTION: The diversity radio unit comprises a switching control section 14 for controlling an antenna switching section 12 for switching antennas, and a baseband processing section 6 for generating reference timing information indicative of a reference timing in a data format of a signal to be transmitted from an antenna and switching target information indicative of a timing relative to the reference timing regarding a switching target term with no trouble in the communication quality even if antennas are switched during a term in the data format. The switching control section 14 specifies a timing within the switching target term in the data format of the signal to be transmitted from the antenna based on the reference timing information and the switching target information and controls the antenna switching section 12 so as to switch the antennas in the specified timing within the switching target term. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a diversity radio apparatus.

  In radio communication, the radio wave environment, particularly in mobile communication, becomes a multipath environment due to reflection, diffraction, scattering, etc. by a building or the like, and fading that causes sudden radio wave fluctuation such as a large change in radio wave level occurs. When fading occurs, the radio wave environment deteriorates and communication quality is reduced. Conventionally, a diversity technique is known as one of fading countermeasure techniques. Diversity technology can be applied to either reception or transmission, and the effect can be obtained with a relatively simple configuration. For example, in selection diversity in which one antenna is selected from two antennas, the antenna having the better reception state (for example, the one with the higher reception level) is first selected during reception. At the time of transmission, the antenna having the best reception state at the time of reception is selected.

Also, in the TDMA (Time Division Multiple Access) system and TDD (Time Division Duplex) system, transmission and reception are switched periodically, so when switching from reception to transmission, the transmission antenna selection is judged and the best antenna is switched. (See, for example, Patent Document 1). On the other hand, in the Code Division Multiple Access (CDMA) system and the Frequency Division Duplex (FDD) system, transmission / reception is not switched periodically. If it is determined and satisfied, the antenna is switched.
JP-A-10-32254

  However, in the above-described prior art, for example, when antenna switching is performed at the time of transmission / reception switching, it is necessary to wait until the transmission / reception switching timing even if switching is required. For this reason, antenna switching may not be in time in a radio wave environment with a fast fading cycle.

  On the other hand, when switching antennas based on the antenna selection criteria, switching can be performed as necessary. However, since the conventional technology does not adjust the antenna switching timing, switching occurs regardless of the transmission data format, resulting in distortion of the transmission waveform due to nonlinearity and a decrease in transmission power due to power loss, resulting in modulation accuracy. And characteristics such as output efficiency may deteriorate. In addition, due to switching of the antenna, there is a possibility that a reception signal may be interrupted on the receiving side, or a phase change of the received signal may occur due to an individual difference between the antennas before and after the switching, and the reception characteristics may be deteriorated.

  The present invention has been made in consideration of such circumstances, and its purpose is to reduce communication quality due to antenna switching by adjusting the antenna switching timing in a transmission data period that does not hinder communication quality. It is an object of the present invention to provide a diversity radio apparatus that can be prevented.

  In order to solve the above-described problem, a diversity radio apparatus according to the present invention is a diversity radio apparatus capable of transmitting a signal by selecting one antenna from a plurality of antennas. Antenna switching means for switching to one selected antenna, switching control means for controlling the antenna switching operation of the antenna switching means, and reference timing information indicating a reference timing in a data format of a signal transmitted from the antenna is generated Reference timing information generating means, and switching target information indicating a relative timing with respect to the reference timing for a switching target period which is a period in the data format and does not hinder communication quality even if the antenna is switched. Switching object information generating means for generating, the switching control Stage, based on the reference timing information and the switching target information, and controls the antenna switching means to perform switching of the antenna, characterized in that.

  In the diversity radio apparatus according to the present invention, the switching control means specifies the timing of the switching target period in the data format of the signal transmitted from the antenna based on the reference timing information and the switching target information, The antenna switching means is controlled to switch the antenna at the timing of the specified switching target period.

  In the diversity radio apparatus according to the present invention, the switching target period is a period in which no data is allocated.

  In the diversity radio apparatus according to the present invention, the switching target period is a period in which one of a plurality of identical data is transmitted.

  In the diversity radio apparatus according to the present invention, the switching target period is a period in which unused data is transmitted.

  In the diversity radio apparatus according to the present invention, the switching target period is a period for transmitting known data.

  In the diversity radio apparatus according to the present invention, the switching target period is a period for transmitting a positive response signal to be returned to the communication partner.

  In the diversity radio apparatus according to the present invention, the reference timing information generating means generates reference timing information indicating a reference timing in baseband processing, and the switching control means includes the reference timing information and the switching It has a means which corrects the change for the delay time on wireless processing to the timing of the change object period specified based on object information.

  According to the present invention, it is possible to adjust the antenna switching timing in a transmission data period that does not hinder communication quality. As a result, it is possible to prevent deterioration in communication quality due to antenna switching.

Hereinafter, embodiments of the present invention will be sequentially described with reference to the drawings.
[First Embodiment]
FIG. 1 is a block diagram showing a configuration of a diversity radio apparatus according to the first embodiment of the present invention. The diversity radio apparatus shown in FIG. 1 includes two antennas ANT1 and ANT2, and performs radio transmission using one of the antennas during transmission. During reception, radio reception is performed using both antennas ANT1 and ANT2.

  In FIG. 1, the radio signals received by the antennas ANT1 and ANT2 are respectively input to the corresponding reception radio units 4 via the connected antenna duplexers 2 and subjected to radio reception processing. The reception signal subjected to radio reception processing by the reception radio unit 4 is subjected to baseband processing by the baseband (BB) processing unit 6 and then input to the upper layer processing unit 8.

  At the time of transmission, the data signal output from the upper layer processing unit 8 is input to the BB processing unit 6 and subjected to baseband processing, and then input to the transmission radio unit 10 for radio transmission processing. A transmission signal subjected to radio transmission processing by the transmission radio unit 10 is input to an antenna switching unit (antenna switching means) 12. The antenna switching unit 12 switches the output destination to one of the antenna duplexers 2 of the antennas ANT1 and ANT2 according to the antenna switching instruction signal input from the switching control unit (switching control means) 14 and outputs a transmission signal. Thereafter, the transmission signal is wirelessly transmitted from the selected antenna via the antenna duplexer 2.

  The antenna selection unit 16 determines the antenna selection based on the reception information input from the BB processing unit 6, selects a transmission antenna, and outputs an antenna selection signal indicating the selection result to the switching control unit 14. Note that the reception information used for the antenna selection determination may be the reception information of the own device or may receive feedback of the reception information of the communication partner.

  The switching control unit 14 outputs an antenna switching instruction signal to the antenna switching unit 12 based on the information input from the BB processing unit 6 and the information input from the upper layer processing unit 8. FIG. 2 shows a processing flow relating to the antenna switching control of the present embodiment. FIG. 3 shows a timing chart of the operation according to the antenna switching control of the present embodiment.

  FIG. 3A shows a reference timing in the data format of transmission data input from the BB processing unit 6 to the transmission radio unit 10. The reference timing is, for example, the beginning timing of the transmission data format. The BB processing unit 6 generates a reference timing signal indicating the reference timing (reference timing information generating unit). The switching control unit 14 receives the reference timing signal from the BB processing unit 6. FIG. 3B shows transmission data input from the BB processing unit 6 to the transmission radio unit 10. A period indicated by a symbol P in the transmission data is a switching target period. The switching target period P is a period in which there is substantially no influence on the communication quality even if the antenna is switched during the period. FIG. 3C shows an antenna selection signal input from the antenna selection unit 16 to the switching control unit 14.

  FIG. 3D shows a first switching timing signal that is an internal signal of the switching control unit 14. The first switching timing signal is a switching timing corresponding to the input timing of transmission data input from the BB processing unit 6 to the transmission radio unit 10. The first switching timing is delayed from the reference timing by the timing adjustment time Tsbb. The timing adjustment time Tsbb is a delay time from the reference timing from when the antenna selection signal is input to the switching control unit 14 to the first switching target period P.

  FIG. 3E shows a second switching timing signal that is an internal signal of the switching control unit 14. The second switching timing signal is a switching timing corresponding to the input timing of the transmission signal input from the transmission radio unit 10 to the antenna switching unit 12. The second switching timing is delayed from the first switching timing by the timing correction time Td. The timing correction time Td is a delay time corresponding to the processing time required for the wireless transmission process in the transmission wireless unit 10.

  In FIG. 2, when the switching control unit 14 receives an antenna selection signal from the antenna selection unit 16 (step S1), the switching control unit 14 generates a first switching timing signal obtained by delaying the antenna selection signal by the timing adjustment time Tsbb (step S1). S2) (switching object information generating means). Next, the selected antenna is determined based on the antenna selection signal (step S3). Next, a predetermined timing correction time Td corresponding to the antenna of the determination result is selected (step S4 or S5). Next, a second switching timing signal is generated by delaying the first switching timing signal by the selected timing correction time Td (step S6) (delay time in radio processing with respect to the timing of the specified switching target period Means to compensate for minute fluctuations). Next, the second switching timing signal is output to the antenna switching unit 12 as an antenna switching instruction signal (step S7).

  Thereby, the antenna switching instruction signal is input to the antenna switching unit 12 in accordance with the switching target period P at the input timing of the transmission signal input to the antenna switching unit 12. As a result, since antenna switching is performed during the switching target period, deterioration of communication quality due to antenna switching is prevented.

FIG. 4 shows various examples of the switching target period P.
FIGS. 4A-1 and 4A-2 are cases where repetitive data exists in one transmission data format at the upper layer level. At this time, the period of the repetitive portion is set as the switching target period P because even if data is lost due to antenna switching, the same data exists in the same data format and thus has little influence.

  FIGS. 4B-1 and 4B-2 illustrate a case where there is an unused data period in the transmission data format at the upper layer level. The unused data period is, for example, data necessary for establishing communication such as telephone number information and terminal (base station) information, and transmitting unnecessary (unused) data after establishing communication. A period. The unused data period is designated as a switching target period P because there is no problem even if antenna switching is performed.

  The switching control unit 14 is notified of the type and timing of the switching target period P at the higher layer level, such as when there is repetitive data or an unused data period, as data accompanying information. The accompanying information of data includes, for example, type information Ia and switching target information Ib. The type information Ia consists of 2 bits, “00” indicates data that is not to be switched, “01” indicates unused data that is not transmitted, and “10” indicates data that repeatedly transmits the same data. The switching target information Ib consists of 1 bit, “0” indicates no switching target, and “1” indicates the switching target. The type information Ia is generated by the upper layer processing unit 8. The type information Ia is notified to the BB processing unit 6 and the switching control unit 14. The switching target information Ib is generated by the BB processing unit 6 as timing information indicating relative timing with respect to the reference timing. Since the BB processing unit 6 generates transmission data according to a predetermined data format, the BB processing unit 6 grasps a relative timing with respect to a reference timing for a specific period in the data format.

  FIG. 4C shows a case where a period in which no data is allocated is set in advance in the transmission data format. Since there is no problem even if antenna switching is performed during a period in which no data is allocated, it is set as a switching target period P. Since the timing of the switching target period P at this time is known, the switching control unit 14 is configured to generate timing information of the switching target period P.

  In addition to the above, the upper layer level switching target period P includes, for example, a period in which a positive response signal (ACK signal or the like) to be returned to the communication partner is transmitted. This is because a response signal such as ACK has only an effect of starting retransmission even if it is not normally received by the communication partner. The switching target period P can also be the timing at which the communication partner changes, such as during a handover.

  4D and 4E show the switching target period P at the physical layer level. The physical layer level switching target period P includes, for example, a period in which known data (for example, a training signal or a unique word UW) is transmitted to the communication partner. Further, a period in which no data is allocated at the physical layer level is also a switching target period P. Information on the type and timing of the switching target period P at the physical layer level is generated by the BB processing unit 6 and notified to the switching control unit 14. Alternatively, the switching control unit 14 may be configured to generate the type and timing information of the switching target period P at the physical layer level.

  Note that the switching control unit 14 may select the switching target period P to be actually used from among the various switching target periods P described above according to the priority. The priority for each type of the switching target period P is set in the switching control unit 14 in advance. For example, the period in which data is not transmitted is given the highest priority, and the period in which data is repeatedly transmitted is lowered in priority.

  As described above, according to the present embodiment, the antenna switching timing can be adjusted in a transmission data period that does not hinder communication quality. As a result, it is possible to prevent deterioration in communication quality due to antenna switching. Moreover, since the antenna switching timing is corrected for each antenna, the accuracy of the antenna switching timing is improved.

Further, since the transmission antenna and the transmission radio unit operate in a one-to-one relationship, the transmission power can be concentrated on one antenna, and there is no loss of transmission power, and high communication quality can be maintained.
Further, the addition of the configuration related to the adjustment of the antenna switching timing is small-scale and can be realized based on the conventional configuration, so that there is little influence on the power consumption, cost, mounting area, and the like.

[Second Embodiment]
FIG. 5 is a block diagram showing a configuration of a diversity radio apparatus according to the second embodiment of the present invention. In FIG. 5, parts corresponding to those in FIG. 1 are given the same reference numerals, and explanation thereof is omitted. In the second embodiment, a function of adjusting the timing correction time Td described above is provided.

  The diversity wireless device shown in FIG. 5 is provided with a temperature sensor 20. The temperature detected by the temperature sensor 20 is notified to the switching control unit 14. The switching control unit 14 has a timing correction time table that stores the timing correction time Td for each antenna corresponding to the temperature. FIG. 6 shows a configuration example of the timing correction time table. As shown in FIG. 6, in the timing correction time table, the timing correction time Td of each antenna is set in advance for each use condition (temperature range in this embodiment). The timing correction time table is created by measuring the delay time for each antenna in advance for each use condition.

  The switching control unit 14 reads the timing correction time Td of each antenna under the use condition (temperature range) matching the temperature notified from the temperature sensor 20 from the timing correction time Td and uses it for correcting the antenna switching timing.

  In the above-described embodiment, the antenna switching timing is corrected according to the usage temperature of the diversity wireless device. However, correction according to other usage conditions may be performed. For example, the timing correction time Td for each carrier frequency is tabulated and held in the switching control unit 14, and the switching control unit 14 reads the timing correction time Td of the carrier frequency actually used from the timing correction time table and uses it. It may be. The carrier frequency actually used is notified from the upper layer processing unit 8 or the like.

  According to the second embodiment described above, it is possible to appropriately correct the antenna switching timing in response to a change in the usage environment of the diversity wireless device.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes design changes and the like within a scope not departing from the gist of the present invention.

It is a block diagram which shows the structure of the diversity radio | wireless apparatus which concerns on the 1st Embodiment of this invention. It is a processing flow figure concerning antenna change control of the embodiment. It is a timing chart figure of operation concerning antenna switching control of the embodiment. It is a figure for demonstrating the various examples of the switching object period P which concern on this invention. It is a block diagram which shows the structure of the diversity radio | wireless apparatus which concerns on the 2nd Embodiment of this invention. It is a figure which shows the structural example of the timing correction time table which concerns on the same embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 2 ... Antenna sharing device, 4 ... Reception radio | wireless part, 6 ... Baseband (BB) process part, 8 ... Upper layer process part, 10 ... Transmission radio | wireless part, 12 ... Antenna switching part, 14 ... Switching control part, 16 ... Antenna Selection unit, 20 ... temperature sensor, ANT1, ANT2 ... antenna

Claims (8)

A diversity radio apparatus capable of transmitting a signal by selecting one antenna from a plurality of antennas,
Antenna switching means for switching to one antenna selected from the plurality of antennas;
Switching control means for controlling the antenna switching operation of the antenna switching means;
Reference timing information generating means for generating reference timing information indicating a reference timing in a data format of a signal transmitted from the antenna;
Switching object information generating means for generating switching object information indicating a relative timing with respect to the reference timing for a switching object period which is a period in the data format and does not hinder communication quality even if the antenna is switched. And
The switching control means controls the antenna switching means to perform antenna switching based on the reference timing information and the switching target information.
A diversity radio apparatus characterized by the above. The switching control means specifies the timing of the switching target period in the data format of the signal transmitted from the antenna based on the reference timing information and the switching target information, and at the timing of the specified switching target period, Controlling the antenna switching means to perform switching,
The diversity radio apparatus according to claim 1.   The diversity radio apparatus according to claim 1, wherein the switching target period is a period in which data is not allocated.   The diversity radio apparatus according to claim 1, wherein the switching target period is a period in which one data among a plurality of identical data is transmitted.   The diversity radio apparatus according to claim 1, wherein the switching target period is a period in which unused data is transmitted.   The diversity radio apparatus according to claim 1, wherein the switching target period is a period when transmitting known data.   The diversity radio apparatus according to claim 1, wherein the switching target period is a period in which a positive response signal to be returned to the communication partner is transmitted. The reference timing information generating means generates reference timing information indicating a reference timing on baseband processing,
The switching control means includes means for correcting a fluctuation corresponding to a delay time in wireless processing with respect to a timing of a switching target period specified based on the reference timing information and the switching target information.
The diversity radio apparatus according to claim 1, wherein:

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