KR20100086176A - Front-end filter module for reapeaters - Google Patents

Abstract

PURPOSE: A filter module device installed in a front-end of a repeater is provided to protect service frequency bands by minimizing the interference occurring between heterogeneous services. CONSTITUTION: A SAW(Surface Acoustic Wave) notch filter of a first filter unit(610) attenuates a first guard band existing between a transmission end band and the other bands, wherein the first guard band is extracted from a signal transmitted from an antenna. A SAW notch filter of a second filter unit(620) attenuates a second guard band existing between a receiving end band and the other bands, wherein the second guard band is extracted from a signal transmitted from a repeater.

Description

Filter module device installed in front of repeater {Front-end Filter Module for Reapeaters}

The present invention relates to a device located at an antenna terminal of a relay device and a base station, which separates heterogeneous services and attenuates only some frequency bands or passes only a specific frequency band at frequencies transmitted and received. Specifically, the present invention relates to a repeater front-end filter module using surface acoustic wave elements that suppress interference from adjacent bands between the same service method or another service method.

The frequency of the mobile communication is spaced at a constant frequency to prevent cross-confusion between different services, and as shown in (a) or (b) of FIG. It is separated from operators and also has a certain guard band to minimize interference between operators. However, in the conventional repeater system, due to the complexity of the system and the increase in the output of the repeater for quality service, spurious signals are generated as shown in FIG. 2, which affects the service frequency ranges of other operators. This increase in the unnecessary signal leads to oscillation of the repeater, and causes the function of the repeater to deteriorate. The solution is to install a new repeater system that implements a selectable filter that suppresses third-party frequency. However, the development and installation of a new repeater with a good selectivity filter is a costly and timely investment.

In order to solve this problem, conventionally, a solution in the IF band has been sought. However, a solution in the IF band is inevitable because a design change or reconfiguration of the repeater system is inevitable. In addition, since the implementation of a filter having a high attenuation is difficult in various service bands, which are RF bands, which are currently several kilohertz, there is a need for a proposal of a new technology to solve this problem.

The present invention has been proposed to overcome the problems of the prior art as described above, and provides a filter module device that is installed in front of the repeater.

The filter module device according to an embodiment of the present invention for achieving the above object, is installed between the antenna and the repeater, in the RF band, for interference with the signal transmitted from the antenna to the repeater and for the signal transmitted from the repeater to the antenna A filter module device for removing interference, comprising: a first filter unit including a surface acoustic wave notch filter for attenuating a first boundary band existing between a transmission end band and another band adjacent to the transmission end band from a signal received from the antenna ; And a second surface acoustic wave notch filter for attenuating a second boundary band existing between the receiving end band and the other band adjacent to the receiving end band from the signal received from the repeater.

The filter module device according to an embodiment of the present invention is a module device for maximizing attenuating only a specific frequency band in a service band and minimizing interference between heterogeneous services, and can be attached to the outside of an existing repeater and a base station. To provide. In addition, it has the advantage of protecting the service frequency band by minimizing the interference that can occur between heterogeneous services, and can be maximized for convenience by connecting to an antenna port located outside the relay device and the base station. In addition, it is possible to reduce the cost incurred in the collection and re-installation and reproduction of the repeater and base station for configuring a filter for passing heterogeneous service bands inside the apparatus.

Typical surface acoustic wave devices are widely used as band pass filters in mobile communication portable terminals, repeaters, and base stations, which are mobile communication systems. Mobile communication portable terminals are widely used in the form of resonators or filters. Meanwhile, in the case of the relay system and the base station, a filter of high selectivity is used in the intermediate frequency band. In the surface acoustic wave device of the dual RF frequency band, LiNbO ₃ and LiTaO ₃ having large electromechanical coefficients are mainly used in order to have low loss and high isolation of transmit / receive bands. The surface acoustic wave resonator on the substrate can block the desired band by increasing the number of resonators, but the frequency selectivity is remarkably different from that of the IF surface acoustic wave filter.

On the other hand, the RF surface acoustic wave resonator on the quartz substrate has a higher selectivity than the previous LiNbO ₃ or LiTaO _3. There is a feature that can minimize the interference of radio waves of other companies in the frequency band. Therefore, conventional surface acoustic wave filters using crystals have been used only as a narrow band notch filter and an oscillator for transmission and reception for public use.

In the embodiment of the present invention, by using the surface acoustic wave resonator using the above-mentioned quartz substrate, it is possible to provide a filter module device that implements attenuation filter with high frequency selectivity in the RF band, and is installed in front of the repeater.

3 schematically shows a filter module and its frequency characteristic according to an embodiment of the present invention. The filter module comprises a band pass filter 310; Surface acoustic wave notch filter 320; Low noise amplifier 330; And an impedance matching element 340. The first band pass filter is a filter that passes a specific pass band as shown in (b) of FIG.

In the present specification, the pass band means a specific service frequency band, and means a frequency band to be passed for each service, that is, a transmitter band or a receiver band. The transmit end band means a frequency band of an allocated transmitter, and the receiver end band means a frequency band of an assigned receiver. For example, the band pass filter may be a filter that passes only a frequency of a transmitting end or a receiving end assigned to each operator in a specific service band.

The surface acoustic wave notch filter is a filter that attenuates a signal between the pass band and the other band, as shown in FIG. For example, it is a filter so that the frequency band between each provider does not influence each other between frequency bands allocated to each provider in a specific service band. Herein, the specific service may be a homogeneous service or a heterogeneous service.

The low noise amplifier is to compensate for gain loss by the band pass filter and the surface acoustic wave notch filter. The gain of the low noise amplifier can be adjusted differently according to each embodiment.

The impedance matching device performs impedance matching between the band pass filter, the surface acoustic wave notch filter, and the low noise amplifier, thereby minimizing mutually reflected signals.

4 schematically shows a filter module and its frequency characteristic according to another embodiment of the present invention. The filter module may include a first surface acoustic wave notch filter 410; First band pass filter 420; Low noise amplifier 430; A second surface acoustic wave notch filter 440; And an impedance matching element 450.

The first passband filter is a filter that passes a specific band, as shown in (b) of FIG. The first surface acoustic wave notch filter is a filter that cuts off a boundary band between another band adjacent to the specific band on the low frequency side and the specific band.

In the present specification, the boundary band refers to a band existing between a transmitter end band, a receiver end band, and another band that should not pass, as mentioned above. The first boundary band and the second boundary band are displayed by dividing the respective boundary bands, and mean the boundary bands of the transmitting end band and the receiving end band, respectively. In the first boundary band and the second boundary band, there is a boundary band of a high frequency side and a boundary band of a low side based on a transmitting end band and a receiving end band, respectively. This means that there are boundary bands on both the left and right sides of each pass band in the frequency domain. Here, the numbers such as the first and the second do not limit the embodiment of the present invention, and indicate that there are a plurality of boundary bands according to the plurality of passbands to be passed in the embodiment of the present invention.

The second surface acoustic wave notch filter is a filter that cuts off a boundary band between another band adjacent to the specific band at a high frequency side and the specific band. As such, the boundary bands may be blocked to improve the separation between the bands. In FIG. 4B, the band to be passed is filled in, and the band to be blocked is left empty.

The low noise amplifier is to compensate for gain loss caused by the first band pass filter, the first surface acoustic wave notch filter, and the second surface acoustic wave notch filter. The gain of the low noise amplifier may vary according to each embodiment. The impedance matching element may perform impedance matching between the first band pass filter, the first surface acoustic wave notch filter, the second surface acoustic wave notch filter, and the low noise amplifier, thereby minimizing reflected signals between the components. It was made.

The position and number of surface acoustic wave notch filters disclosed in FIG. 4 are arbitrary. In the embodiment of FIG. 4, two surface acoustic wave notch filters are used. However, only one surface acoustic wave notch filter may be provided, or two or more surface acoustic wave notches may be provided. In addition, the position provided may also vary depending on the design, and the attenuation band of the surface acoustic wave notch filter may also vary. For example, two or more surface acoustic wave notch filters that attenuate the same band may be provided.

FIG. 5 is a frequency characteristic of a band in which the center frequency of the second generation of CDMA is 836 MHz by using the filter module of FIG. 4. Figure 5 (a) shows the measurement waveform to see the separation or attenuation of the band and the neighboring band, Figure 5 (b) is enlarged to see the gain adjustment by the low noise amplifier It is displayed.

Hereinafter, a filter module device for implementing through the present invention using the filter unit described above will be described.

Filter module device installed in the front end of the repeater according to another embodiment of the present invention, the filter unit; A first duplexer unit; And a second duplexer portion. The filter unit passes either a signal transmitted from the antenna to the repeater or a signal transmitted from the repeater to the antenna.

When the filter unit is provided at the transmitting end and passes the transmitting end band, the first duplexer unit may transmit a signal transmitted from the repeater received from the second duplexer unit to the antenna and transmit a signal input from the antenna to the filter unit. have. The second duplexer unit may receive a signal filtered by the filter unit and transmit a signal input from a repeater to the first duplexer unit. The filter unit may filter the transmitting end signal received from the antenna and transmit the filtered signal to the second duplexer unit. Here, the transmitting end signal or the receiving end signal means a signal transmitted in the transmitting end band or the receiving end band. For example, the transmitting end signal or the receiving end signal may include a plurality of allocated signals such as a CDMA carrier.

Alternatively, when the filter unit is provided at the receiving end to pass the receiving end, the first duplexer unit may receive a signal filtered by the filter unit and transmit a signal input from an antenna to the second duplexer unit. The second duplexer unit may transmit a signal received from the first duplexer unit to a repeater and transmit a signal received from the repeater to the filter unit. The filter unit may filter the signal received from the repeater and transmit the filtered signal to the first duplexer unit.

The filter unit attenuates boundary bands existing between other bands adjacent to the transmitting end band and the receiving end band to block interference from other bands.

The two duplexers are disposed with the filter unit interposed therebetween, one of which is connected to the antenna side and one to the repeater side. The filter module device according to this embodiment includes only one filter part. In the embodiment of the present invention, the reason for having only one filter unit is to attenuate the boundary band in only one band of the transmitting end or the receiving end, and the other band outputs the input signal as it is without filtering by the filter part. By adjusting the position and the number of filter units provided, it is possible to implement a filter module device that meets the design criteria. That is, the filter unit may be installed in at least one of a path from the antenna to the repeater or a path from the repeater to the antenna, thereby reducing the boundary band.

6 shows a filter module device 600 installed in front of a repeater according to an embodiment of the present invention. The filter module device may be installed at the front of the repeater to block the boundary band by using the filter module according to the embodiment shown in FIG. 3 or 4 to improve frequency separation. The filter module device may include a first filter unit 610; A second filter unit 620; A first duplexer unit 630; And a second duplexer unit 640, which is installed between the antenna and the repeater, and may remove interference from the signal transmitted from the antenna to the repeater and interference from the repeater to the antenna in the RF band. . FIG. 6 shows that the first filter part is located in the path of the transmitter and the second filter part is located in the path of the receiver. Looking at Figure 6, it can be seen that there is a port (port) capable of input and output at both ends. Each port is connected to a duplexer, which allows for both input and output. The right port is connected to the repeater side and the left port is connected to the base station antenna side.

The filter module device 600 of FIG. 6 is configured as one independent case or module, and the filter module device is connected to the front end of the repeater as shown in 810 of FIG. 8. Since 820 corresponds to a conventional repeater, according to an exemplary embodiment of the present invention, the frequency of each boundary band can be attenuated without changing or reconfiguring the conventional repeater. As a result, it is possible to reduce interference between service bands between service providers of the same service band or between service bands between providers of heterogeneous service bands. That is, the boundary band between each band may be attenuated through the filter unit so as to prevent interference between the respective bands in the RF band instead of the IF band.

7 shows a filter module apparatus 700 installed in front of a repeater according to an embodiment of the present invention. FIG. 7 illustrates the filter unit of the filter module device 600 of FIG. 6 in detail. The filter module device 700 includes: a first duplexer unit transmitting a signal received from an antenna to a transmitting end and transmitting a signal received from the receiving end to an antenna; A second duplexer unit which transmits the signal received from the repeater to the receiving end and transmits the signal received from the transmitting end to the repeater; A first filter unit including a surface acoustic wave notch filter for attenuating a first boundary band existing between a transmitting end band and another band adjacent to the transmitting end band from a signal received from the antenna, and a signal transmitted from a repeater And a second filter unit including a surface acoustic wave notch filter for attenuating a second boundary band existing between the receiving end band and the other band adjacent to the receiving end band, and installed between the antenna and the repeater, Interference between the transmitter signal and the receiver signal can be eliminated.

The first filter unit 710 may include a first band pass filter 711 for passing a signal received from the antenna; A first surface acoustic wave notch filter (713) for attenuating a first boundary band existing between the transmitting end band and another band adjacent to the transmitting end band; And a first low noise amplifier 712 to compensate for gain loss due to the first band pass filter and the first surface acoustic wave notch filter. The first surface acoustic wave notch filter may include a surface acoustic wave notch filter configured to block a band having a frequency lower than that of the transmitting end band of the first boundary band; And a surface acoustic wave notch filter for blocking a band having a frequency higher than that of the transmitting end band of the first boundary band.

The second filter unit 720 includes a second band pass filter 721 for passing a signal transmitted from the repeater to the antenna; A second surface acoustic wave notch filter 723 for attenuating a second boundary band existing between the receiving end band and another band adjacent to the receiving end band; And a second low noise amplifier 722 for compensating for gain loss due to the second band pass filter and the second surface acoustic wave notch filter. The second surface acoustic wave notch filter may include a surface acoustic wave notch filter configured to block a band having a frequency lower than that of the receiver end band of the second boundary band; And a surface acoustic wave notch filter for blocking a band having a frequency higher than that of the receiving end band among the second boundary bands.

As such, the first filter unit and the second filter unit may be provided to attenuate signals in each of the transmission band band and the reception band and neighboring boundary bands, thereby preventing interference between the pass band and other bands that the repeater intends to transmit. have. In addition, each filter unit may include a plurality of surface acoustic wave notch filters to reduce the boundary band.

Each surface acoustic wave notch filter includes: a plurality of surface acoustic wave resonators independently disposed on a quartz substrate; A ceramic package packaging the plurality of surface acoustic wave resonators; And an external matching element configured to match between each of the plurality of surface acoustic wave resonators outside the package. The surface acoustic wave notch filter is fabricated on a quartz substrate, since the frequency response characteristic must attenuate each boundary band even in an RF band of 2 GHz. On the quartz substrate, a surface acoustic wave resonator is disposed and packaged. The surface acoustic wave resonators in the packaging are not electrically connected. After packaging, the matching elements are electrically connected and matched by using a matching element, a capacitor or an inductor. Matching outside the package after packaging is intended to reduce interference between each resonator and to facilitate matching of frequency response characteristics.

In FIG. 7, one surface acoustic wave notch filter is used for each filter module. However, as described above, one or more surface acoustic wave notch filters may be used to block a plurality of boundary bands or may overlap the same boundary band.

8 is a view showing that the filter module device 810 according to an embodiment of the present invention is installed in the entire repeater system. The filter module device 810 is installed at the front end of the conventional repeater 820, it is easy to improve the attenuation effect of the boundary band without changing the design in the conventional repeater 820.

9 illustrates a filter module device 900 installed at a front end of a repeater providing heterogeneous service bands according to an exemplary embodiment of the present invention. Recently, the frequency of dealing with two types of service bands within one repeater is increasing. The filter module is placed for selective attenuation only in one service band where the attenuation of the boundary band is required within heterogeneous service bands, and the other service bands allow the signal to pass without loss.

It includes diplexers 950 and 960 that use low frequency or high pass filters using inductors and capacitors to separate the heterogeneous services at each input and output stage and reduce mutual interference even when the signal is input in the reverse direction. Within the required service band, duplexers 930 and 940 were used again to increase the separation between the transmitter and receiver. In addition, gain loss can be adjusted by inserting low noise amplifiers 912 and 922. Impedance matching can be configured between the first band pass filter, the surface acoustic wave notch filter, and the low noise amplifier to minimize reflectance for each device. .

Also, although not shown, a duplexer and a filter module device including two filter modules are also inserted in the path (lowest path in FIG. 9) to pass without loss in FIG. Boundary band attenuation can be improved.

FIG. 10 is a diagram illustrating frequency characteristics of the filter module device of FIG. 9. FIG. 10A is a diagram illustrating frequency characteristics of the filter module device 900 of FIG. 9. It can be seen that the filter module device for attenuating the region c of FIG. Region c in FIG. 10 is a portion where the boundary band is attenuated using the surface acoustic wave attenuation filter. The 800 MHz band, region a of FIG. 10, corresponds to the bottom path that does not require attenuation of FIG. 9, and region b of FIG. 10 corresponds to a path where only the low noise amplifier of FIG. 9 exists.

FIG. 10B is an enlarged view of region c of FIG. 10A. By using the low noise amplifier, it can be seen that the gain of the pass band (a region) is close to about 0 dB, and that the attenuation portion (b region) is present by the surface acoustic wave attenuation filter. This is the attenuation of the right boundary band (b region), and compared with the left boundary band, it can be seen that the attenuation is increased. As such, it is possible to overcome the problems of the prior art through the effect of the embodiment of the present invention.

The present invention described above is limited to the above-described embodiments and the accompanying drawings as various changes and modifications can be made within the scope without departing from the technical spirit of the present invention for those skilled in the art. It doesn't happen.

1 is a diagram illustrating allocation of mobile communication frequencies for different services.

2 is a diagram showing problematic features in current repeater systems.

3 is a schematic block diagram and frequency characteristics of a filter unit according to an exemplary embodiment of the present invention.

4 is a schematic block diagram and frequency characteristics of a filter unit according to another embodiment of the present invention;

FIG. 5 is a diagram illustrating frequency characteristics of a filter module actually manufactured for a CDMA second generation service. FIG.

6 is a block diagram of a filter module device according to another embodiment of the present invention;

7 is a block diagram of a filter module device according to another embodiment of the present invention;

8 is a diagram illustrating an application example of a filter module device in a heterogeneous service according to another embodiment of the present invention.

9 is a block diagram of a filter module device for providing heterogeneous services according to another embodiment of the present invention.

10 is a view showing the frequency characteristics of the filter module device of FIG.

Claims (14)

A filter module device installed between an antenna and a repeater, the RF module removes interference on a signal transmitted from an antenna to a repeater and an interference on a signal transmitted from a repeater to an antenna in an RF band. A first filter unit including a surface acoustic wave notch filter for attenuating a first boundary band existing between a transmission end band and another band adjacent to the transmission end band from a signal received from the antenna; And And a second filter unit including a surface acoustic wave notch filter for attenuating a second boundary band existing between a receiving end band and another band adjacent to the receiving end band from a signal received from the repeater. The method of claim 1, The first filter unit, A first bandpass filter for passing the signal received from the antenna; A first surface acoustic wave notch filter for attenuating the first boundary band; And And a first low noise amplifier for compensating for gain losses due to the first bandpass filter and the first surface acoustic wave notch filter. The method of claim 2, The first surface acoustic wave notch filter, A surface acoustic wave notch filter for attenuating a boundary band having a frequency lower than that of the transmitting end band among the first boundary bands; And a surface acoustic wave notch filter configured to attenuate a boundary band having a frequency higher than that of the transmitting end band among the first boundary bands. The method of claim 1, The second filter unit, A second band pass filter for passing the signal received from the repeater; A second surface acoustic wave notch filter for attenuating the second boundary band; And And a second low noise amplifier for compensating for gain losses due to the second bandpass filter and the second surface acoustic wave notch filter. The method of claim 4, wherein The second surface acoustic wave notch filter, A surface acoustic wave notch filter for attenuating a boundary band having a frequency lower than that of the receiving end band among the second boundary bands; And a surface acoustic wave notch filter configured to attenuate a boundary band having a frequency higher than that of the receiver end band among the second boundary bands. The method according to claim 3 or 5, Each surface acoustic wave notch filter, A plurality of surface acoustic wave resonators independently disposed on the quartz substrate; A ceramic package packaging the plurality of surface acoustic wave resonators; And And a matching element for matching between each of the plurality of surface acoustic wave resonators outside of the package. In the filter module device is installed between the antenna and the repeater, to remove interference in the RF band, the signal transmitted from the antenna to the repeater, And a filter unit including a surface acoustic wave notch filter for attenuating a boundary band existing between a transmitting end band and another band adjacent to the transmitting end band from a signal received from the antenna. The method of claim 7, wherein The filter unit, A band pass filter for passing the signal received from the antenna; A surface acoustic wave notch filter for attenuating the boundary band adjacent to the transmitting end band of the boundary bands; And And a low noise amplifier for compensating for gain losses due to the band pass filter and the surface acoustic wave notch filter. The method of claim 8, The surface acoustic wave notch filter, A surface acoustic wave notch filter for attenuating a boundary band having a frequency lower than that of the transmitting end band among the boundary bands; And a surface acoustic wave notch filter configured to attenuate a boundary band having a frequency higher than that of the transmitter end band among the boundary bands. 10. The method of claim 9, Each surface acoustic wave notch filter, A plurality of surface acoustic wave resonators independently disposed on the quartz substrate; A ceramic package packaging the plurality of surface acoustic wave resonators; And And a matching element for matching between each of the plurality of surface acoustic wave resonators outside of the package. In the filter module device is installed between the antenna and the repeater, to remove the interference to the signal transmitted from the repeater to the antenna in the RF band, And a filter unit including a surface acoustic wave notch filter for attenuating a boundary band existing between a receiving end band and another band adjacent to the receiving end band from a signal received from the repeater. The method of claim 11, The filter unit, A band pass filter for passing the signal received from the repeater; A surface acoustic wave notch filter that attenuates the boundary band adjacent to the receiving end band of the boundary bands; And And a low noise amplifier for compensating for gain losses due to the band pass filter and the surface acoustic wave notch filter. The method of claim 12, The surface acoustic wave notch filter, A surface acoustic wave notch filter for attenuating a boundary band having a frequency lower than that of the receiver end band among the boundary bands; And And a surface acoustic wave notch filter configured to attenuate a boundary band having a frequency higher than that of the receiver end band among the boundary bands. The method of claim 13, Each surface acoustic wave notch filter, A plurality of surface acoustic wave resonators independently disposed on the quartz substrate; A ceramic package packaging the plurality of surface acoustic wave resonators; And And a matching element for matching between each of the plurality of surface acoustic wave resonators outside of the package.

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