JP2005175675A - Wireless transmission system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a wireless transmission system capable of effectively suppressing spurious radiation caused in an optical transmission interval without deteriorating the characteristic of a desired signal. <P>SOLUTION: A first wireless unit 20A of a base station apparatus 10 boosts a spectral level of a wireless transmission signal through expansion processing of a band pass filter 24 and thereafter transmits the signal to an optical fiber 40. On the other hand, a second wireless unit 60A of an antenna site passes the wireless transmission signal transmitted via the optical fiber 40 through a band pass filter 61 to apply band limit processing to the signal, thereby suppressing the spurious radiation, up-converts the wireless transmission signal whose spurious radiation is suppressed, amplifies the power of the signal by a transmission power amplifier 70 and emits the signal from an antenna 80. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a wireless transmission system that transmits a wireless signal using an optical transmission path between a base station apparatus and an antenna of a mobile communication system, for example.

  2. Description of the Related Art In mobile communication systems typified by cellular phone systems, attention has been focused on a system in which a base station device and an antenna are connected by an optical fiber and a radio signal is optically transmitted through the optical fiber. This system is called a ROF (Radio On Fiber) system, and there is no need to install a base station device near the antenna, and there is an advantage that peripheral devices for the antenna can be easily and miniaturized.

  FIG. 5 shows an example of such a conventional system. In the figure, a radio transmission signal output from a base station apparatus (BTS) 1 is input to a transmission / reception (TRX) unit 2, which is suitable for A / D conversion by a down converter (D-CONV) 2 a. The frequency is converted into a baseband or intermediate frequency signal, and then converted into a digital signal by an analog / digital converter (A / D) 2b. The digital transmission signal is converted into an optical signal by an electrical / optical converter (E / O) 3 and then transmitted to the antenna site via the optical fiber 4.

  At the antenna site, an optical signal transmitted through the optical fiber 4 is converted into a digital transmission signal by an optical / electrical converter (O / E) 5 and then input to the TRX unit 6. In the TRX unit 6, the input digital transmission signal is converted into an analog signal by a digital / analog converter (D / A) 6 a, frequency-converted by an up-converter (U-CONV) 6 b, and then a radio transmission signal again. Then, after being amplified to a predetermined transmission power level by the transmission power amplifier (PA) 7, it is radiated from the antenna 8.

  On the other hand, as another configuration of the ROF system, a system has been proposed in which a radio base station and a control station of a mobile communication system are connected by an optical fiber, and a radio signal is optically transmitted between the two stations by an optical fiber. (For example, refer to Patent Document 1).

JP 2001-85925 A

  However, in any of the above systems, when a transmission error occurs due to, for example, vibration or noise in the optical fiber transmission section, a spurious is generated due to this transmission error, and this spurious is directly transmitted by the transmission power amplifier 7. The power is amplified and radiated from the antenna 8. For this reason, a radio signal on which high-frequency noise is superimposed is emitted, which may cause interference and violate the Radio Law.

  In order to avoid this problem, an error correction function may be provided. However, transmission errors that are expected to occur include not only random errors and errors with low frequency of occurrence, but also errors with continuity such as burst errors, and all errors must be assumed. In order to cope with such a situation, a very complicated and expensive error correction function must be prepared, which is not realistic.

  As another method for avoiding the above problem, it is conceivable to provide a filter for removing spurious on the output side of the optical fiber. However, it is necessary to prepare a filter having a steep characteristic in order to completely remove spurious. When such a filter is used, not only spurious but also a part of the desired signal is attenuated. Degradation of characteristics

  The present invention has been made paying attention to the above circumstances, and its purpose is to perform wireless transmission capable of effectively attenuating spurious generated in the optical transmission section without degrading the characteristics of the desired signal. To provide a system.

  In order to achieve the above object, the present invention provides a first wireless unit provided corresponding to a first wireless device on a transmitting side and a second wireless provided corresponding to a second wireless device on a receiving side. In a wireless transmission system that transmits a wireless signal to and from a unit via an optical transmission line, a band-limiting filter having a preset band-limiting characteristic is provided in the second wireless unit on the receiving side. Then, the band of the radio signal transmitted through the optical transmission path is limited by the band limiting filter and then output to the second radio apparatus. On the other hand, the first wireless unit on the transmission side is provided with a band pass filter having a band pass characteristic that is opposite to the band limit characteristic of the band limit filter. Then, the band of the radio signal transmitted from the first radio apparatus is expanded by the band pass filter and then transmitted to the optical transmission line.

  Therefore, according to the present invention, in the first radio unit on the transmission side, the spectrum level of the radio signal is lifted by the band pass filter and then transmitted to the optical transmission line. On the other hand, in the radio unit on the reception side, the optical transmission is performed. The radio signal transmitted through the path is band-limited by the band-limiting filter. For this reason, it is possible to sufficiently suppress the spurious generated in the optical transmission line section while suppressing the characteristic deterioration of the desired signal.

  In addition, in the present invention, it is not necessary to provide a complicated and expensive error correction function that assumes any error, and it is not necessary to provide an expensive filter having a steep characteristic for removing spurious, so that the configuration is simple and inexpensive. System can be provided.

Moreover, the following can be considered as a specific configuration related to the present invention.
The first configuration is a multi-carrier wireless transmission system that transmits a wireless signal using a plurality of carriers, and each of a plurality of band limiting filters having a band limiting characteristic set in advance is provided on a receiving-side radio unit. Provided corresponding to the carrier. Then, the multiplexed radio signal transmitted through the optical transmission path is separated for each carrier, and then the radio signals of the separated carriers are band-limited by the plurality of band-limiting filters and then demodulated. On the other hand, the transmission-side radio unit is provided with a plurality of band-pass filters having band-pass characteristics that are opposite to the band-limiting characteristics of the plurality of band-limiting filters. Then, the modulated radio signals of the plurality of carriers are each subjected to band expansion by the plurality of band pass filters, and then multiplexed and transmitted to the optical transmission line.

  According to such a configuration, in the radio unit on the transmission side, the radio signal of each carrier is band-extended by the band-pass filter having band-pass characteristics set in advance for each carrier, and then multiplexed and multiplexed. On the other hand, in the radio unit on the receiving side transmitted to the transmission path, the multiplexed radio signal transmitted through the optical transmission path is separated for each carrier, and then the band limitation for which the band limitation characteristic is set for each carrier. Each band is limited by the filter. For this reason, it is possible to reduce spurious not only for individual carriers but also for all transmission bands including valleys between carriers. Therefore, it is possible to surely suppress spurious generated in the optical transmission line section while suppressing deterioration of the characteristics of the radio signal of each carrier.

  The second configuration is a multi-carrier radio transmission system that transmits a radio signal using a plurality of carriers, and the radio unit on the receiving side has one band limitation that has a band limitation characteristic that covers the entire transmission band. Provide a filter. Then, the multiplexed radio signal transmitted through the optical transmission line is band-limited to all bands by passing through the band limiting filter, and the band-limited multiplexed radio signal is separated for each carrier. Demodulate later. On the other hand, the transmission-side radio unit is provided with one band-pass filter having a band-pass characteristic that is opposite to the band-limiting characteristic of the one band-limiting filter. Then, after the modulated radio signals of a plurality of carriers are multiplexed, the multiplexed radio signal is passed through the band pass filter so that the band is expanded and transmitted to the optical transmission line. .

  According to such a configuration, the band extending process and the band limiting process on the transmitting side and the receiving side are performed by one band pass filter and band limiting filter, respectively. For this reason, it is possible to suppress spurious by using only a small number of band pass filters and band limiting filters, thereby keeping the circuit scale extremely small and suppressing the quality degradation of the desired signal within an allowable range. The radiation characteristics of the multicarrier radio signal can be improved.

  In short, according to the present invention, in the transmission-side wireless unit, after extending the band of the wireless transmission signal according to the band-pass characteristic that is opposite to the band-limiting characteristic of the band-limiting filter provided in the reception-side wireless unit, the optical transmission line By transmitting to the wireless transmission system, it is possible to provide a wireless transmission system capable of effectively attenuating spurious generated in the optical transmission section without degrading the characteristics of the desired signal.

(First embodiment)
FIG. 1 is a block diagram showing a first embodiment of a wireless transmission system according to the present invention. The system of this embodiment is an ROF system in which a base station apparatus of a mobile communication system and an antenna site are connected by an optical transmission path, and a radio signal is transmitted through this optical transmission path.

  In the figure, a first radio unit 20A and a second radio unit 60A are provided at sites on the base station apparatus (BTS) 10 side and the antenna 80 side, respectively, and these first and second radio units 20A, 60A is connected by an optical transmission line. The optical transmission line includes an electrical / optical converter (E / O) 30 provided on the output side of the first wireless unit 20A and an optical / electrical circuit provided on the input side of the second wireless unit 60A optical fiber 40. It comprises a converter (O / E) 50 and an optical fiber 40 that connects between the electrical / optical converter 30 and the optical / electrical converter 50.

  First, the first radio unit 20A includes a down converter (D-CONV) 21, an analog / digital converter (A / D) 22, a low-pass filter (LPF) 23, and a band-pass filter (1 / H ( ω)) 24. The down converter 21 converts the radio transmission signal output from the base station apparatus 10 into a baseband or intermediate frequency signal suitable for A / D conversion. The analog / digital converter 22 converts the transmission signal frequency-converted by the down converter 21 into a digital signal. The low-pass filter 23 removes unnecessary harmonic components contained in the digital transmission signal output from the analog / digital converter 22.

  The band pass filter 24 has a band pass characteristic (transfer function 1 / H (ω) that is opposite to the band limit characteristic (transfer function H (ω)) of the band limit filter 61 provided in the second radio unit 60A described later. )). Then, the band of the digital transmission signal that has passed through the low-pass filter 23 is expanded according to the transfer function 1 / H (ω), and the band-expanded digital transmission signal is sent to the electrical / optical converter 30. Output. The electrical / optical converter 30 converts the digital transmission signal output from the bandpass filter (inverse characteristic filter) 24 from an electrical signal to an optical signal and transmits the optical signal to the optical fiber 40.

  On the other hand, the second radio unit 60 </ b> A includes a band limiting filter 61, a digital / analog converter (D / A) 62, and an up converter (U-CONV) 63. The band limiting filter 61 has a band limiting characteristic set in advance in order to remove spurious generated in the transmission process by the optical fiber 40. And the process which restrict | limits the zone | band of the digital transmission signal converted into the electrical signal from the optical signal by the optical / electrical converter 50 according to the said band pass characteristic is performed.

  The digital / analog converter 62 converts the digital transmission signal band-limited by the band-limiting filter 61 into an analog signal. The up-converter 63 frequency-converts the analog transmission signal output from the digital / analog converter 62 to a radio frequency signal, and supplies the frequency-converted radio transmission signal to a transmission power amplifier (PA) 70. The transmission power amplifier 70 amplifies the radio transmission signal to a predetermined transmission power level, supplies it to the antenna 80, and radiates it from the antenna 80 toward a mobile communication terminal existing in a cell (not shown).

Next, the operation of the wireless transmission system configured as described above will be described. FIG. 2 is a transmission characteristic diagram used for explaining the operation.
The radio transmission signal output from the base station apparatus 10 is input to the first radio unit 20A, where it is first frequency-converted by the down converter 21 into a baseband or intermediate frequency signal suitable for A / D conversion. The analog / digital converter 22 converts the signal into a digital signal. The digital transmission signal is input to the band-pass filter 24 after unnecessary harmonic components are removed by the low-pass filter 23.

  As described above, the band-pass filter 24 has a band characteristic that is opposite to the band-limiting characteristic (transfer function H (ω)) of the band-limiting filter 61 provided in the second radio unit 60A at the antenna site. It has a pass characteristic (transfer function 1 / H (ω)), and the input digital transmission signal is subjected to processing for extending the band according to the transfer function 1 / H (ω). By this band expansion processing, the levels of the desired wave spectrum D and the sampling image I of the digital transmission signal are raised as indicated by P1 and P2 in FIG. The digital transmission signal output from the band pass filter 24 is converted from an electric signal to an optical signal by the electric / optical converter 30 and then transmitted to the optical fiber 40.

  On the other hand, at the antenna site, the optical signal transmitted through the optical fiber 40 is converted into an electrical signal by the optical / electrical converter 50 and then input to the second radio unit 60A. In the second radio unit 60A, the input digital transmission signal is first input to the band limiting filter 61, and band limiting is performed according to a band limiting characteristic (transfer function H (ω)) preset by the band limiting filter 61. Processing is performed. As a result, during the transmission by the optical fiber 40, for example, spurious generated in the transmission signal as shown in FIG. 2C is removed as shown in FIG.

The above operation is expressed as follows. That is, if the transmission signal is S (ω) and the spurious is N (ω), the filter processing is multiplied on the frequency axis, so the output of the bandpass filter 24 is
S (ω) * (1 / H (ω))
It becomes. When spurious occurs in the optical transmission section, the second radio unit 60A at the antenna site
S (ω) * (1 / H (ω)) + N (ω)
Is input.
However, this signal is passed through the band limiting filter 61 of the transfer function H (ω) and subjected to band limiting processing.
S (ω) + N (ω) * H (ω)) = S (ω)
Signal, that is, a signal in which spurious N (ω) is suppressed is output.

  The digital transmission signal subjected to the band limiting process as described above is converted into an analog signal by the digital / analog converter 62 and then converted into a radio frequency signal by the up converter 63. The frequency-converted radio transmission signal is amplified to a predetermined transmission power level by the transmission power amplifier 70 and then radiated from the antenna 80 toward a mobile communication terminal existing in a cell (not shown).

  As described above, in the first embodiment, the first radio unit 20A on the base station apparatus 10 side transmits the spectrum level of the radio transmission signal to the optical fiber 40 after lifting the spectrum level by the extension processing of the band pass filter 24. . On the other hand, in the second radio unit 60A at the antenna site, the radio transmission signal transmitted through the optical fiber 40 is subjected to band limitation processing through the band limitation filter 61, thereby suppressing spurious noise. After up-converting the received radio transmission signal, the power is amplified by the transmission power amplifier 70 and radiated from the antenna 80.

  Therefore, spurious generated in the optical transmission line section can be sufficiently suppressed while suppressing the characteristic deterioration of the desired signal. In addition, it is not necessary to provide a complicated and expensive error correction function that assumes any error, and it is not necessary to provide an expensive filter having a steep characteristic for removing spurious noise. Can be provided.

(Second Embodiment)
A second embodiment of the present invention is a multi-carrier wireless transmission system that transmits a wireless signal using a plurality of carriers, and has a band limit set in advance in a second wireless unit provided at an antenna site. A plurality of band limiting filters having characteristics are provided corresponding to each carrier, and the multiplexed radio signal transmitted via the optical fiber is separated for each carrier, and then band-limited individually by each band limiting filter. On the other hand, the first radio unit on the base station apparatus side is provided with a plurality of band pass filters having band pass characteristics that are opposite to the band limit characteristics of the plurality of band limit filters. Then, the modulated radio signals of a plurality of carriers are individually band expanded by the plurality of band pass filters, and then multiplexed and transmitted to the optical fiber.

FIG. 3 is a block diagram showing a second embodiment of the wireless transmission system according to the present invention. In the figure, the same parts as those in FIG.
The first radio unit 20B provided on the base station apparatus 10 side is prepared corresponding to a down converter (D-CONV) 21, an analog / digital converter (A / D) 22, and four carriers. Four quadrature modulators 231 to 234, low-pass filters (LPF) 231 to 234 and band-pass filters (1 / H (ω)) 241 to 244 are provided, and a multiplexing circuit 26 is further provided.

  Among them, the quadrature modulators 231 to 234 perform quadrature modulation on the digital transmission signal output from the analog / digital converter 22 in correspondence with the four series of carriers. Input to the pass-pass filters (LPF) 231 to 234. The low-pass filters (LPF) 231 to 234 remove unnecessary wave components contained in the modulated four-sequence digital transmission signals.

  Each of the bandpass filters 241 to 244 has a bandpass characteristic (transmission) that is opposite to the bandlimiting characteristic (transfer function H (ω)) of each of the bandlimiting filters 611 to 614 provided in the second wireless unit 60B described later. Function 1 / H (ω)). Then, the band of the four series of digital transmission signals that have passed through the low-pass filters 231 to 234 is expanded according to the transfer function 1 / H (ω). The signal is input to the multiplexing circuit 26.

  The multiplexing circuit 26 frequency-multiplexes the input four series of digital transmission signals into one series of signals, and outputs the multiplexed one series of digital transmission signals to the electrical / optical converter 30. The electrical / optical converter 30 converts the multiplexed digital transmission signal output from the multiplexing circuit 26 from an electrical signal to an optical signal and transmits it to the optical fiber 40.

  On the other hand, the second radio unit 60B provided at the antenna site includes a separation circuit 64, four band-limiting filters 611 to 614 and quadrature demodulators 651 to 654 prepared for four carriers. Furthermore, a synthesizer 66, a digital / analog converter (D / A) 62, and an up converter (U-CONV) 63 are provided.

  The separation circuit 64 separates the multiplexed digital transmission signal converted from the optical signal into the electric signal by the optical / electrical converter 50 into four series of digital transmission signals. Each of the band limiting filters 611 to 614 has a band limiting characteristic (transfer function H (ω)) preset for each carrier in order to suppress spurious generated in the transmission process by the optical fiber 40. Then, processing for limiting the band of each digital transmission signal output from the separation circuit 64 in accordance with the band pass characteristic (transfer function H (ω)) is performed.

  Each of the quadrature demodulators 651 to 654 performs quadrature demodulation on the four series of digital transmission signals that have passed through the band limiting filters 611 to 614, and inputs the demodulated digital transmission signals to the synthesizer 66. The synthesizer 66 synthesizes the inputted four series of digital transmission signals to generate one series of digital transmission signals, and outputs the generated digital transmission signals to the digital / analog converter 62.

Next, the operation of the wireless transmission system configured as described above will be described.
The radio transmission signal output from the base station apparatus 10 is input to the first radio unit 20B, where it is frequency converted into a baseband or intermediate frequency signal suitable for A / D conversion by the down converter 21, The analog / digital converter 22 converts the digital signal. This digital transmission signal is quadrature-modulated by quadrature modulators 231 to 234 corresponding to four carriers. The modulated four-sequence digital transmission signals are input to band-pass filters 241 to 244 after unnecessary wave components are removed by low-pass filters (LPF) 231 to 234 for each sequence.

  As described above, the bandpass filters 241 to 244 are bandpass characteristics (transfer functions) that are inverse to the bandlimiting characteristics of the bandlimiting filters 611 to 614 provided in the second radio unit 60B at the antenna site. 1 / H (ω)), and the input digital transmission signal of each series is subjected to processing for extending the band according to the transfer function 1 / H (ω). By this band expansion processing, the level of the desired wave spectrum and the sampling image of each series of digital transmission signals is raised as shown in FIG.

  The four series of digital transmission signals output from the band-pass filters 241 to 244 are frequency-multiplexed into one series of digital transmission signals by the multiplexing circuit 26, and the multiplexed digital transmission signals are converted into electric / optical converters. After being converted from an electrical signal into an optical signal by 30, it is transmitted to the optical fiber 40.

  On the other hand, at the antenna site, the optical signal transmitted through the optical fiber 40 is converted into an electrical signal by the optical / electrical converter 50 and then input to the second radio unit 60B. In the second radio unit 60 </ b> B, the input multiplexed digital transmission signal is first separated into four series of digital transmission signals by the separation circuit 64 and then input to the band limiting filters 611 to 614. Each of the band limiting filters 611 to 614 has a band limiting characteristic (transfer function H (ω)) for suppressing spurious for each carrier, and the four input digital transmission signals that are input are respectively the transfer function H. Band limiting processing is performed according to (ω). As a result, spurious generated in the transmission signal during transmission by the optical fiber 40 is suppressed for each carrier.

  The digital transmission signals subjected to band limitation processing for each sequence as described above are orthogonally demodulated by orthogonal demodulators 651 to 654, respectively, and then synthesized by a synthesizer 66 to become one series of digital transmission signals. The synthesized digital transmission signal is converted into an analog signal by the digital / analog converter 62, then frequency-converted to a radio frequency signal by the up-converter 63, and further transmitted to a predetermined transmission power level by the transmission power amplifier 70. After being amplified, it is radiated from the antenna 80 toward a mobile communication terminal existing in a cell (not shown).

  As described above, according to the second embodiment, in the first radio unit 20B provided on the base station apparatus 10 side, four series of digital transmission signals generated for each carrier are set for each carrier. The band is expanded by the bandpass filters 241 to 244 having the inverse characteristics (transfer function 1 / H (ω)), and then multiplexed and transmitted to the optical fiber 40. On the other hand, in the second radio unit 60B at the antenna site, after the multiplexed digital transmission signal transmitted through the optical fiber 40 is separated for each carrier, the band limiting characteristic (transfer function H (ω )) Is band-limited by the band-limiting filters 611 to 614 set.

  Therefore, spurious can be attenuated for all transmission bands including valleys between carriers as well as individual carriers. Therefore, it is possible to surely suppress spurious generated in the optical transmission line section while suppressing deterioration of the characteristics of the radio signal in each carrier.

(Third embodiment)
In the third embodiment of the present invention, the second radio unit at the antenna site is provided with one band limiting filter having band limiting characteristics covering the entire transmission band, and multiplexed via an optical fiber. By passing the digital transmission signal through the band limiting filter, the entire band is band-limited collectively, and the band-limited multiplexed digital transmission signal is separated for each carrier and then demodulated. On the other hand, the first radio unit on the base station apparatus side is provided with one band pass filter having a band pass characteristic that is opposite to the band limit characteristic of the band limit filter of the antenna site. Then, after the modulated digital transmission signals of a plurality of carriers are multiplexed, the multiplexed digital transmission signal is passed through the band pass filter so that the band is expanded and transmitted to the optical fiber. .

FIG. 4 is a block diagram showing a third embodiment of the wireless transmission system according to the present invention. In the figure, the same parts as those in FIG.
In the first radio unit 20C provided on the base station apparatus 10 side, a multiplexing circuit 26 is arranged immediately after the low-pass filters (LPF) 231 to 234. Further, the multiplexing circuit 26 and the electric / optical converter 30 are connected to each other. One band pass filter (1 / H ′ (ω)) 27 is arranged between them. The multiplexing circuit 26 frequency-multiplexes the four series of digital transmission signals output from the low-pass filters (LPF) 231 to 234 into one series of signals, and band-passes the multiplexed one series of digital transmission signals. Input to the filter 27.

  The band pass filter 27 is a band pass characteristic (transfer function 1 / H ′) that is opposite to the band limit characteristic (transfer function H ′ (ω)) of the band limit filter 67 provided in the second radio unit 60C described later. (ω)). Then, a process of expanding all the bands of one series of multiplexed digital transmission signals output from the multiplexing circuit 26 in accordance with the transfer function 1 / H ′ (ω) is performed, and this one series of band expanded. The digital transmission signal is output to the electric / optical converter 30. The electrical / optical converter 30 converts the multiplexed digital transmission signal output from the multiplexing circuit 26 from an electrical signal to an optical signal and transmits it to the optical fiber 40.

  On the other hand, in the second radio unit 60C provided at the antenna site, a band limiting filter (H ′ (ω)) 67 is disposed immediately after the optical / electrical converter 50, and this band limiting filter (H ′ ( ω)) 67 and a separation circuit 64 are arranged between the quadrature demodulators 651 to 654.

  The band limiting filter 67 has a band limiting characteristic (transfer function H ′ (ω)) that is collectively set for the transmission band including all carriers in order to suppress spurious generated in the transmission process by the optical fiber 40. . Then, a process of collectively limiting the band of the multiplexed digital transmission signal converted by the optical / electrical converter 50 according to the band pass characteristic (transfer function H ′ (ω)) is performed.

  The separation circuit 64 separates the multiplexed digital transmission signal band-limited by the band limitation filter 67 into four series of digital transmission signals. Each of the quadrature demodulators 651 to 654 performs quadrature demodulation on the four series of digital transmission signals separated by the separation circuit 64 and inputs the demodulated digital transmission signals to the synthesizer 66. The synthesizer 66 synthesizes the inputted four series of digital transmission signals to generate one series of digital transmission signals, and outputs the generated digital transmission signals to the digital / analog converter 62.

  With this configuration, the radio transmission signal output from the base station apparatus 10 is input to the first radio unit 20C, where the downconverter 21 has a baseband or intermediate frequency suitable for A / D conversion. After frequency conversion into a signal, the analog / digital converter 22 converts the signal into a digital signal. This digital transmission signal is quadrature-modulated by quadrature modulators 231 to 234 corresponding to four carriers. The modulated four-sequence digital transmission signals are frequency-multiplexed by the multiplexing circuit 26 after unnecessary wave components are removed by low-pass filters (LPF) 231 to 234 for each sequence, and one-sequence multiplexed digital transmission is performed. A signal is input to the band-pass filter 27.

As described above, the band-pass filter 27 is a band having an inverse characteristic to the band-limiting characteristic (transfer function H ′ (ω)) of the band-limiting filter 67 provided in the second radio unit 60C at the antenna site. It has a pass characteristic (transfer function 1 / H ′ (ω)), and the inputted multiplexed digital transmission signal is subjected to processing for extending the band according to the transfer function 1 / H ′ (ω). By this band expansion processing, the level of the desired wave spectrum and the sampling image of the multiplexed digital transmission signal is raised collectively.
The multiplexed digital transmission signal output from the band pass filter 27 is converted from an electrical signal to an optical signal by the electrical / optical converter 30 and then transmitted to the optical fiber 40.

  On the other hand, in the second radio unit 60 </ b> C provided at the antenna site, the multiplexed digital transmission signal output from the optical / electrical converter 50 is first input to the band limiting filter 67. Each of the band limiting filters 67 has a band limiting characteristic (transfer function H ′ (ω)) for suppressing spurious for the transmission band including all carriers as described above. The multiplexed digital transmission signal is band-limited according to the transfer function H ′ (ω). As a result, the spurious generated in the transmission signal during the transmission by the optical fiber 40 is collectively suppressed for the entire transmission band.

  The multiplexed digital transmission signal band-limited by the band-limiting filter 67 is separated into four series of digital transmission signals by the separation circuit 64 and then orthogonally demodulated by the orthogonal demodulators 651 to 654. Then, the signal is synthesized by the synthesizer 66 into one series of digital transmission signals, converted into an analog signal by the digital / analog converter 62, and then converted into a radio frequency signal by the up-converter 63. Further, after being amplified to a predetermined transmission power level by the transmission power amplifier 70, it is radiated from the antenna 80 toward a mobile communication terminal existing in a cell (not shown).

  As described above, according to the third embodiment, in the first radio unit 20C provided on the base station apparatus 10 side, four sequences of digital transmission signals generated for each carrier are multiplexed into one sequence. After that, the band is expanded by the band-pass filter 26 having the inverse characteristic (transfer function 1 / H ′ (ω)) and then transmitted to the optical fiber 40. On the other hand, in the second radio unit 60C at the antenna site, the multiplexed digital transmission signal transmitted through the optical fiber 40 has a band limiting characteristic (transfer function H ′ ( The band is limited in a lump by a band limiting filter 67 having ω)), and then separated for each carrier and demodulated.

  Therefore, the band extension process and the band limiting process in the first and second radio units 20C and 60C are performed by the single band pass filter 26 and the band limiting filter 67, respectively. For this reason, it is possible to suppress spurious noise using only the minimum number of bandpass filters, thereby improving the radiation characteristics of the radio signal while reducing the circuit scale and keeping the quality degradation of the desired signal within an allowable range. be able to. In particular, when applied to a mobile communication system that transmits 15 carriers as in the CDMA (Code Division Multiple Access) 2000 system, the circuit scale of the wireless unit is reduced to 1/15 compared to the second embodiment. Can be very effective.

(Other embodiments)
In each of the above embodiments, the case where the wireless signal is digitized and optically transmitted between the first wireless unit and the second wireless unit has been described as an example. However, the wireless signal is optically transmitted as an analog signal. May be. In this case, an analog filter may be used as the band pass filter and the band limiting filter.

  In each of the above embodiments, the ROF system that transmits a radio signal between the base station apparatus and the antenna site via an optical fiber has been described as an example. However, the invention is not limited thereto, and the optical signal is transmitted between the control station and the base station apparatus. The present invention can also be applied to an ROF system that transmits a radio signal through a fiber. In other words, the transmission side and reception side devices may be any devices as long as they transmit and receive wireless signals.

  Further, in each of the above embodiments, the transmission power amplifier is provided between the radio unit at the antenna site and the antenna. However, the transmission power amplifier may be omitted in a system having a low transmission power level. In addition, the configurations of the first and second wireless units, the transfer function of the band limiting filter and the transfer function of the band pass filter which is the inverse characteristic filter thereof are variously modified and implemented without departing from the scope of the present invention. it can.

  In short, the present invention is not limited to the above-described embodiments as they are, and can be embodied by modifying the components without departing from the scope of the invention in the implementation stage. Moreover, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the above embodiments. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, you may combine suitably the component covering different embodiment.

1 is a block diagram showing a first embodiment of a wireless transmission system according to the present invention. The transmission characteristic figure used for operation | movement description of the system shown in FIG. The block diagram which shows 2nd Embodiment of the radio transmission system concerning this invention. The block diagram which shows 3rd Embodiment of the radio transmission system concerning this invention. The figure which shows the structure of the conventional ROF system.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Base station apparatus (BTS), 20A, 20B, 20C ... Base station apparatus side radio unit, 21 ... Down converter (D-CONV), 22 ... Analog / digital converter (A / D), 23, 231 234: Low-pass filter (LPF), 24, 241-244, 27: Band-pass filter, 251-254: Quadrature modulator, 26: Multiplexer, 30: Electric / optical converter (E / O), 40 ... Optical fiber, 50 ... Optical / electrical converter (O / E), 60A, 60B, 60C ... Radio unit at antenna site, 61,611-614,67 ... Band limiting filter, 62 ... Digital / analog converter (D / A), 63 ... Upconverter (U-CONV), 64 ... Separation circuit, 651 to 654 ... Quadrature demodulator, 66 ... Synthesizer, 70 ... Transmission power amplifier, 80 ... Antenna.

Claims (1)

Between the first wireless unit provided corresponding to the first wireless device on the transmitting side and the second wireless unit provided corresponding to the second wireless device on the receiving side via the optical transmission path A wireless transmission system for transmitting wireless signals,
The second wireless unit is:
An optical receiving circuit for receiving a radio signal transmitted through the optical transmission path;
A band limiting filter that limits a band of a radio signal received by the optical receiving circuit according to a preset band limiting characteristic, and outputs the band limited radio signal to the second radio apparatus;
The first wireless unit is:
A band-pass filter having a band-pass characteristic that is opposite to a band-limiting characteristic included in the band-limit filter, and extending a band of a radio signal transmitted from the first radio apparatus according to the band-pass characteristic;
A wireless transmission system comprising: an optical transmission circuit configured to transmit a wireless signal whose band has been expanded by the bandpass filter to the optical transmission line.

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