KR100419789B1 - Apparatus for Interexchanging Multi-Path of Mobile Communication System using Delay Process - Google Patents

Abstract

The present invention relates to a multipath relay apparatus of a mobile communication system using a delay processing method for reducing multipath fading using a delay processing method and providing excellent call quality. It is configured to adjust the multipath fading by implementing the delay difference between the receiving paths of the repeaters using a similar medium frequency bandpass filter. In addition, it is possible to connect an antenna having a delay characteristic and an antenna having no delay characteristic to a repeater, or delay processing a signal received through a TTLNA and another antenna, which transmits a signal received through one antenna without delay processing. The delay TTLNA is connected to a repeater. Therefore, according to the present invention, by implementing the delay difference between the receiving paths of the repeaters using the intermediate frequency bandpass filter having only the delay characteristics, the infrastructure investment cost can be reduced by improving the reception sensitivity of the mobile communication and the service of the base station. It is effective to widen the area or provide sufficient quality service to the radio shadow area.

Description

Apparatus for Interexchanging Multi-Path of Mobile Communication System using Delay Process

The present invention relates to a multipath relay device of a mobile communication system, and more particularly, to a multipath relay of a mobile communication system using a delay processing method for providing excellent call quality using multipath fading using a delay processing method. Relates to a device.

In general, in mobile communication, when a call is made to a mobile terminal, a low power wireless signal is transmitted to a base station located closest to the base station, which transmits a signal to an exchange. In mobile communication, each subscriber is classified by radio frequency, and the service area is divided into small cells. The frequency can be reused as long as it does not interfere with neighboring cells, by keeping the output to a minimum. Recently, mobile communication methods using satellites have been attempted, and using satellites can provide services anywhere in the world.

In the mobile communication system, it is required to continuously reduce the size of the cell and to expand the base station accordingly in order to accommodate the increase rate of subscribers and to satisfy the high quality service needs. However, such base station expansion adds a significant investment burden to the mobile service provider. On the other hand, because the base station equipment is generally large in weight and volume, the base station can not be installed anywhere. In other words, even if there is a point of optimizing the network such as minimizing fading while making a large area visible, it is often difficult to establish a base station in consideration of various limitations of the base station equipment and often only to install a small unit. . In addition, since the distribution of traffic is often uneven in each region, and the time or day of the traffic fluctuates depending on regions, it is not economical to add expensive base stations at all points.

In order to solve the problems caused by the investment burden and the expansion of the base station, various methods of installing a repeater connected to the base station have been disclosed. The relay is a part of the resources allocated to the base station to receive a signal from the neighboring terminal to transmit in real time to the base station or to transmit the signal received from the base station to the outside, it serves to relay the signal between the base station and the mobile terminal . By utilizing such a repeater, a mobile communication service provider can reduce infrastructure investment costs, expand a service area of a base station, or provide sufficient quality service to a radio shadow area.

1 is a diagram illustrating an example of a path difference and a time delay for a transmission / reception signal between a base station and a terminal, and the terminal 30 receives a signal transmitted from one of the repeaters 20 and the base station 10 or It will also receive signals sent from other repeaters. As shown in FIG. 1, the time required for the signal transmitted from the base station 10 to reach the terminal 30 directly is τ ₁ , and the signal transmitted from the base station 10 passes through the repeater 20. If the time required to reach the terminal 30 is τ ₂ (in this case, the multipath transmission by the reflected wave is ignored), the delay time between the base station 10 and the repeater 20 and the repeater 20 Due to its system delay time, τ ₁ and τ ₂ do not have the same value and are as different as Δτ (τ ₂ -τ ₁ ). That is, a signal directly transmitted from the base station 10 first arrives at the terminal 30, and after a delay time of Δτ passes, the signal transmitted via the repeater 20 reaches the terminal 30. .

In order to solve this problem, the repeater 20 has a delay function for placing a time difference between paths by varying a signal transmission path to improve call quality during signal processing, and in a general repeater 20, a circuit Instead of implementing a delay function, a delay of time is formed by forming two paths by a spatial diversity method using an external antenna, and a method of combining signals of the two paths is used. That is, the repeater 20 converts a signal of the RF band received from the signal processing side into an easy-to-process intermediate frequency band, and processes three signals (or four from the base station antenna diversity). The time delay is implemented by the spatial diversity method using the antenna.

However, such a conventional delay processing method has various problems. First, since the processing frequency band is converted to the IF frequency, which is a low frequency band different from the received RF frequency band, to process a signal, a separate frequency converter is added to complicate the construction of the repeater and increase the cost accordingly. Second, since the spatial diversity method of delaying operation using two different antennas is used, space and installation cost for installing two antennas are increased. Third, the conventional diversity scheme is typically used to expand the system capacity, but there is a problem that it is difficult to apply the diversity scheme within the main antenna of the CDMA repeater or tower top amplifier.

Accordingly, the invention using the conventional as been made in view of solving the various problems, the first object is a passband, a similar and transit delay characteristic difference is the intermediate frequency band filter, the attenuation characteristic of the present invention as described above The present invention provides a multipath repeater for a mobile communication system using a delay processing method for controlling delay of a multipath by implementing delay differences between reception paths of repeaters.

It is a second object of the present invention to provide a multipath relay apparatus of a mobile communication system using a delay processing method for adjusting multipath fading by using a delay characteristic of an antenna or a tower top low noise amplifier (TTLNA).

1 is a diagram illustrating an example of a path difference and a time delay for a transmission / reception signal between a base station and a terminal;

2 is a block diagram of a multi-path relay device according to a first embodiment of the present invention,

3 is a block diagram of a multi-path relay device according to a second embodiment of the present invention,

4 is a block diagram of a multi-path relay device according to a third embodiment of the present invention,

5 is an internal configuration diagram of a repeater according to an embodiment of the present invention,

6 is an internal configuration diagram of a TTLNA according to the present invention,

7a and 7b is an internal configuration of the delay TTLNA according to the present invention,

8A is an installation diagram using a multipath relay device according to a fourth embodiment of the present invention;

8B is a configuration diagram of a multipath relay device according to a fourth embodiment of the present invention;

9A is an installation diagram using a multipath relay device according to a fifth embodiment of the present invention;

9B is a configuration diagram of a multipath relay device according to a fifth embodiment of the present invention;

10A is an installation diagram using a multipath relay device according to a sixth embodiment of the present invention;

10B is a configuration diagram of a multipath relay device according to a sixth embodiment of the present invention;

11A is an installation diagram using a multipath relay device according to a seventh embodiment of the present invention,

11B is a configuration diagram of a multipath relay device according to a seventh embodiment of the present invention.

♣ Explanation of symbols for the main parts of the drawing ♣

310: delay characteristic antenna 320: antenna without delay characteristic

330, 430: repeater 370, 470: base station

410: delay TTLNA 420: TTLNA

In order to achieve the above object, the present invention provides a multipath relay apparatus of a mobile communication system for relaying transmission and reception signals between a base station and a terminal, the first duplexer for switching a transmission and reception path of a signal transmitted from a base station and a signal transmitted from a terminal. Wow; A first LNA connected to the first duplexer and amplifying only the original signal while suppressing a noise component of the received signal switched to the first duplexer by entering an arbitrary reception path; A first local oscillator coupled to the first LNA, the first local oscillator generating a stable and constant frequency to convert frequencies; A first mixer coupled to the first LNA and the first local oscillator, for mixing the RF signal amplified in the first LNA and the frequency generated in the first local oscillator and converting the frequency into an intermediate frequency signal; A first BPF connected to the first mixer, the first BPF having a frequency pass band and an attenuation characteristic and maintaining a predetermined delay characteristic; A second mixer coupled to the first local oscillator and the first BPF and converting the filtered IF signal into an RF signal; A second BPF connected to a second mixer, for removing a leaked local oscillation signal, an IF signal, or an intermodulated signal among the RF signals converted by the second mixer; A third BPF for passing a frequency of a predetermined band among the received signals flowing into another reception path and removing other frequencies; A second LNA connected to the third BPF and amplifying only the original signal while suppressing a noise component of the filtered received signal; A second local oscillator coupled to the second LNA, the second local oscillator generating a stable and constant frequency to convert frequencies; A third mixer connected to the second LNA and the second local oscillator, and mixing the RF signal amplified by the second LNA and the frequency generated by the second local oscillator to convert the frequency signal into an intermediate frequency signal; A fourth BPF connected to the third mixer, the fourth BPF having a frequency pass band and an attenuation characteristic and maintaining a predetermined delay characteristic; A fourth mixer connected to the second local oscillator and the fourth BPF and converting the filtered IF signal into an RF signal; A fifth BPF connected to a fourth mixer and removing the leaked local oscillation signal, IF signal, or intermodulated signal among the RF signals converted by the fourth mixer; A first attenuator coupled to a fifth BPF and configured to adjust a gain of the filtered RF signal; A first combiner coupled to the second BPF and the first attenuator, the first combiner coupling each received signal introduced through different paths; A first power amplifier connected to the first combiner for amplifying and outputting the signal coupled by the first combiner to a signal having a constant amplitude; A second duplexer coupled to the first power amplifier, the second duplexer transmitting an amplified signal to the base station and switching a signal introduced from the base station; And a second power amplifier connected to the second duplexer and amplifying a received signal switched by the second duplexer and transferring the received signal to the first duplexer.

In addition, the present invention provides a multipath relay apparatus of a mobile communication system for relaying transmission and reception signals between a base station and a terminal, comprising: a seventh duplexer for switching transmission and reception paths of a signal transmitted from a base station and a signal transmitted from a terminal; An eighth LNA connected to a seventh duplexer and amplifying only an original signal while suppressing a noise component of a received signal switched to the seventh duplexer by flowing into an arbitrary receiving path; A fourth local oscillator for generating a stable and constant frequency to convert the frequency; A seventh mixer connected to the eighth LNA and the fourth local oscillator, for mixing the RF signal amplified in the eighth LNA and the frequency generated in the fourth local oscillator to convert the frequency signal into an intermediate frequency signal; A second attenuator coupled to the seventh mixer, the second attenuator adjusting the gain of the mixed intermediate frequency signal; A second power divider coupled to the second attenuator and distributing a gain adjusted signal; A seventeenth BPF for passing a frequency of a predetermined band among the received signals flowing into another reception path and removing other frequencies; A ninth LNA connected to a seventeenth BPF and amplifying only an original signal while suppressing a noise component of the filtered received signal; An eighth mixer connected to the ninth LNA and the fourth local oscillator, for mixing the RF signal amplified in the ninth LNA and the frequency generated in the fourth local oscillator to convert the frequency signal into an intermediate frequency signal; An eighteenth BPF coupled to the eighth mixer and delaying the intermediate frequency signal converted by the eighth mixer; A third power divider connected to the eighteenth BPF and distributing a delayed intermediate frequency signal; A third combiner coupled to the second power divider and the third power divider, the third combiner coupling intermediate frequency signals having different delay characteristics and propagated in different power distribution paths; A nineteenth BPF coupled to the third combiner and configured to determine frequency bands and attenuation characteristics of the intermediate frequency signal coupled by the third combiner; A ninth mixer connected to the nineteenth BPF and the fourth local oscillator, for mixing the intermediate frequency signal filtered by the nineteenth BPF and the frequency generated by the fourth local oscillator to upconvert to an RF signal; A sixth power amplifier connected to a ninth mixer and amplifying the up-converted RF signal into a signal having a constant amplitude; An eighth duplexer connected to a sixth power amplifier, the eighth duplexer transmitting an amplified signal to the base station and switching a signal introduced from the base station; A fourth combiner coupled to the second power divider and the third power divider, the fourth combiner coupling an intermediate frequency signal having different delay characteristics and transmitted in different power-distributed paths; A twenty BPF coupled to a fourth coupler and configured to determine frequency bands and attenuation characteristics of the intermediate frequency signal coupled by the fourth coupler; A tenth mixer coupled to the twentieth BPF and the fourth local oscillator, for mixing the intermediate frequency signal filtered by the twentieth BPF and the frequency generated by the fourth local oscillator and upconverting the RF signal to an RF signal; A seventh power amplifier connected to the tenth mixer and amplifying the up-converted RF signal into a signal having a constant amplitude; A ninth duplexer connected to a seventh power amplifier and transmitting an amplified signal to the base station and switching a signal introduced from the base station; A fifth combiner coupled to the eighth duplexer and the ninth duplexer, for coupling a received signal switched by the eighth duplexer and the ninth duplexer; And an eighth power amplifier connected to the fifth coupler and amplifying the combined received signal to be delivered to the seventh duplexer.

Hereinafter, a preferred embodiment of a multipath relay apparatus of a mobile communication system using a delay processing method according to the present invention will be described in detail with reference to the accompanying drawings.

(Example 1)

2 is a configuration diagram of a multipath relay apparatus 200 according to a first embodiment of the present invention.

The first duplexer 205 of the relay device 200 switches the transmission / reception paths of the signal transmitted from the base station and the signal transmitted from the terminal. The first duplexer 205 serves as a bandpass filter using microwave dielectric phase dielectric properties to separate and transmit a transmission / reception frequency. In other words, the duplexer is an RF component that separates transmission and reception frequencies to pass frequencies in a desired band, and filters out only necessary radio waves and removes unnecessary ones. Compared with other filters, the duplexer has the advantage of high separation to size and excellent stability against temperature changes at high frequencies. A first low noise amplifier (LNA) 210 is connected to the first duplexer 205 and receives noise components of the received signal switched by the first duplexer 205 along a receiving path (eg, the first receiving path). It is a low noise amplifier that amplifies only the original signal in a suppressed state to improve the strength of the received signal. The first LNA 210 used in the relay device 200 needs to have a wide range of available power, and when a part of a circuit including an active device does not operate, it is preferable that the first LNA 210 can operate even though performance is reduced. The first local oscillator 215 is connected to the first LNA 210 and serves to generate a stable and constant frequency to convert the frequency. Here, the first local oscillator 215 can set the oscillation frequency freely by the designer's choice. The first mixer 220 is connected to the first LNA 210 and the first local oscillator 215, and the RF signal amplified by the first LNA 210 and the frequency generated by the first local oscillator 215 are used. It mixes and converts to an intermediate frequency (IF) signal. The first BPF 225 is connected to the first mixer 220 and is a band pass filter for passing a frequency of a predetermined band and removing other frequencies, and the second mixer 230 is a first local oscillator 215. ) And the first BPF 225, and convert the filtered IF signal into an RF signal. The second BPF 245 is connected to the second mixer 230 and filters to remove leaked local oscillation signals, IF signals, or intermodulated signals among the RF signals converted by the second mixer 230. to be.

The third BPF 250 is a filter for passing a frequency of a predetermined band of the received signal flowing into the multipath relay 200 seen through another path (for example, the second receiving path) and removing other frequencies. Subsequent signal transmission paths are amplified by the second LNA 255 in the same manner as described above, converted into IF signals by the second local oscillator 260 and the third mixer 265, and the fourth BPF ( 270 and the fourth mixer 275 are filtered and converted into an RF signal, and then filtered by the fifth BPF 280. However, the difference between the first receiving path and the second receiving path is that the first attenuator 285 is included in the second receiving path to adjust the gain of the signal introduced through the different paths. However, the first attenuator 285 may be included in the first receive path or may be included in the first receive path and the second receive path, respectively. In addition, the first BPF 225 and the fourth BPF 270 may implement the same passband, attenuation characteristics, and the like, and may implement only the delay characteristics to be different from each other (for example, two chips or more).

The first coupler 290 is connected to the second BPF 245 and the first attenuator 285 and serves to couple the respective received signals introduced into different paths. The first power amplifier 292 is connected to the first coupler 290, and amplifies and outputs the signal coupled by the first coupler 290 into a signal having a constant amplitude. The second duplexer 295 is connected to the first power amplifier 292 and transmits the amplified signal to the base station and switches the signal introduced from the base station, and the second duplexer 295 is the first duplexer. The function and operation are the same as those of 205. The second power amplifier 297 is connected to the second duplexer 295 and amplifies the received signal switched by the second duplexer 295 and transfers the received signal to the first duplexer 205. That is, the signal flowing into the multipath relay 200 viewed from the terminal is transmitted to the base station by the second duplexer via the first reception path or the second reception path, and is transmitted to the multipath relay 200 viewed from the base station. The incoming signal is transmitted to the terminal via the second duplexer 295, the second power amplifier 297, and the first duplexer 205.

(Example 2)

3 is a configuration diagram of a multipath repeater according to a second embodiment of the present invention, in which the antenna 310 having a delay characteristic and the two diversity antennas 320 and 340 are repeaters 330. ), And two diversity antennas 350 and 360 are connected to the base station 370. In this embodiment, the multi-path fading is controlled by using the antenna 310 having the delay characteristic and the antenna 320 having the delay characteristic for the signal flowing into the repeater 340. Example 1 is a method of adding a delay characteristic in the repeater, Example 2 is a method using a general repeater as it is and using an antenna having a delay characteristic. Here, the delay difference between the delay antenna 310 and the general antenna 320 is preferably implemented by more than a predetermined chip (for example, two chips). The internal configuration of the repeater 330 when using an antenna having a delay characteristic and an antenna having no delay characteristic will be described later in detail with reference to FIG. 5.

(Example 3)

4 is a configuration diagram of a multipath repeater according to a third embodiment of the present invention, in which the multipath repeater includes a tower top low noise amplifier (TTLNA) having a delay characteristic in any one of two reverse signal reception antennas. Tower Top Low Noise Amplifier (410) is connected and the other TTLNA 420 having no delay characteristics is connected to each of the delay TTLNA 410 and TTLNA 420 to the repeater 430. The rest of the configuration is the same as that of the second embodiment. The present embodiment adjusts multipath fading by using a delayed TTLNA 410 having a delay characteristic and a TTLNA 420 having no delay characteristic to a signal flowing into the receiving antenna of the repeater 430. Since Embodiment 3 implements the delay characteristic as a separate module, it is distinguished from Embodiment 2 in which the delay characteristic is adjusted in the antenna itself. The internal configuration of the repeater 430 of this embodiment will be described in detail later with reference to FIG. 5, and the internal configurations of the TTLNA 420 and delayed TTLNA 410 will be described in detail later with reference to FIGS. 6, 7A and 7B.

5 is an internal configuration diagram of repeaters 330 and 430 according to an embodiment of the present invention (ie, Embodiment 2 and Embodiment 3). As illustrated in FIG. 5, the repeaters 330 and 430 may include a third duplexer 510 and a receive path (eg, a second path) for switching transmission and reception paths of signals transmitted from the base stations 370 and 470 and signals transmitted from the terminal. A third LNA 520 for improving the strength of the received signal by amplifying only the original signal while suppressing a noise component of the received signal switched by the third duplexer 510 along a third receive path; A fourth LNA that amplifies the signal filtered by the sixth BPF 530 and the sixth BPF 530 that pass a frequency of a predetermined band among the received signals flowing through the fourth reception path) and remove other frequencies. 540, a second combiner 550 for combining respective received signals introduced into different paths (eg, the third and fourth receive paths), and a signal coupled by the second combiner 550 having a constant amplitude. Third power amplifier 560 to amplify and output the signal, the amplified signal Is transmitted to the base station (370, 470) and the third duplexer (510) by amplifying the received signal switched in the fourth duplexer (570) and the fourth duplexer (570) for switching the incoming signal from the base station (370, 470) It comprises a fourth power amplifier 580 for transmitting to. In the repeaters 330 and 430 of the second and third embodiments, since multipath fading is compensated by an antenna having a delay characteristic or a TTLNA, the repeaters 330 and 430 do not need to perform a separate delay process.

6 is an internal configuration diagram of the TTLNA 420 according to the present invention, in which the TTLNA 420 having no delay characteristic passes a frequency of a predetermined band among the reverse signals coming from the terminal and removes the other frequencies. 610, a fifth LNA 620 that amplifies the signal filtered by the seventh BPF 610 to improve the strength of the received signal, and an eighth BPF 630 that filters the intermodulated signal among the amplified signals. And a ninth BPF 640 for passing a frequency of a predetermined band among the forward signals flowing from the base station 470 and removing other frequencies. That is, the signal flowing into the TTLNA 420 is filtered or amplified and transferred to the corresponding path, and does not have a delay characteristic.

7A and 7B are internal configuration diagrams of the delay TTLNA 410 according to the present invention, and show two embodiments of the delay TTLNA 410. As shown in FIG. 7A, one embodiment of the delay TTLNA 410 is a tenth BPF 710 for passing a frequency of a predetermined band among the reverse signals coming from a terminal and removing other frequencies. To delay the signal amplified by the sixth LNA 720 and the sixth LNA 720 by a predetermined time (for example, two chips or more) to amplify the signal filtered by the tenth BPF 620 in order to improve the The first delay element 730, the eleventh BPF 740 for filtering the intermodulated signal of the amplified signal and the forward signal from the repeater 430 pass a frequency of a predetermined band of the other signal to remove the other frequency 12 BPF (750) is configured. That is, the signal introduced into the delayed TTLNA 410 through the antenna is filtered and amplified by the tenth BPF 710 and the sixth LNA 720, and the delayed signal by the first delay element 730 is obtained. It is transmitted to the repeater 430 of FIG. 4 through the 11 BPF (740). Here, the signal introduced from the repeater 430 is filtered by the twelfth BPF 750 and transmitted to the terminal through the antenna.

As shown in FIG. 7B, another embodiment of the delay TTLNA 410 is a thirteenth BPF 755 which passes a frequency of a predetermined band among the reverse signals coming from the terminal and removes other frequencies. A seventh LNA 760 for amplifying the signal filtered by the thirteenth BPF 755 to improve the third local oscillator 765 and a seventh LNA 760 for generating a stable and constant frequency for converting the frequency. A fifth mixer 770 for mixing the amplified RF signal and the frequency generated by the third local oscillator 765 and converting it into an IF signal, and passing a frequency of a predetermined band (for example, 70 to 160 MHz) The second delay element 780 and the second delay element 780 delay the signal filtered by the fourteenth BPF 775 to remove the frequency by the fourteenth BPF 775 by a predetermined time (for example, two chips or more). The IF signal delayed by using a third local oscillator 765. Sixth mixer 785 for converting to an RF signal, a fifteenth BPF 790 for removing a leaked local oscillation signal, an IF signal, or an intermodulated signal, etc., from among the RF signals converted by the sixth mixer 785; The sixteenth BPF 795 is configured to pass a frequency of a predetermined band among the forward signals flowing from the repeater 430 and to remove other frequencies. That is, the signal introduced into the delayed TTLNA 410 through the antenna is filtered and amplified by the thirteenth BPF 755 and the seventh LNA 760, and the third local oscillator 765 and the fifth mixer 770 are decoded. After the conversion to the IF signal through the 14 BPF (775), the second delay element 780 and the sixth mixer 785 delayed by a predetermined time is converted into an RF signal, through the 15 BPF (790) It is delivered to the repeater 430 of FIG. Here, the signal introduced from the repeater 430 is filtered by the sixteenth BPF 795 and transmitted to the terminal through the antenna.

(Example 4)

8A is an installation diagram using the multipath relay 800 according to the fourth embodiment of the present invention, and FIG. 8B is a configuration diagram of the multipath relay 800 according to the fourth embodiment of the present invention. As shown in FIG. 8A, the reverse signals transmitted from the terminals are input to the service antennas 810 and 820 of each repeater, and the signals of the two input paths are each delayed by two or more chips in the repeater 800. And coupled to each receiving antenna 840 and 850 of the base station 860 through the base station side antenna 830 of the repeater 800.

Since the multipath relay 800 according to the fourth embodiment is substantially the same as the multipath relay 200 according to the first embodiment, only the differences are described without describing the same components. The difference between the multipath relay 800 of the fourth embodiment and the multipath relay 200 according to the first embodiment is that the multipath relay 200 of the first embodiment has a stable and constant frequency to convert the frequency. Although generating the first local oscillator 215 and the second local oscillator 260 are separately configured, it is implemented by being integrated into one local oscillator 870 of the multipath relay 800 of the fourth embodiment. The components are the same except for the combined position of the local oscillator 870. Maintains the delay difference between the two reverse paths by using the respective BPFs 225 and 270 that adjust the two signals input to the reverse signal section of the multipath relay 800 such that the delay difference is two chips or more. The difference in gain between the two paths is adjusted using the first attenuator 285 for adjusting the gain of the incoming signal. Here, the first attenuator 285 may be located anywhere in the reverse receiving path, and the BPFs 225 and 270 having different delay characteristics may be disposed between the respective up / down conversion mixers 220, 230, and 265 and 275. It is located at. Since the operation of the multipath relay apparatus 800 of the fourth embodiment is the same as that of the multipath relay apparatus 200 of the first embodiment, it will not be described here.

(Example 5)

9A is an installation diagram using the multipath relay 900 according to the fifth embodiment of the present invention, and FIG. 9B is a configuration diagram of the multipath relay 900 according to the fifth embodiment of the present invention. In the fifth embodiment, the diversity path is added to the forward path of the multipath relay 800 of the fourth embodiment to add two antennas (four in total) in both the forward and reverse directions.

In order to add another diversity path, the reverse diversity BPF 250 of the multipath relay 800 of the fourth embodiment is switched to a fifth duplexer 865 which serves to switch the transmission / reception path of the incoming signal. Replace and combine a first power divider 875 that distributes the signal amplified by the first power amplifier 292. The first power divider 875 distributes the amplified signal to the second duplexer 295 and the sixth duplexer 880, respectively, and each of the duplexers 295 and 880 is applied from the first power divider 875. The received signal is transmitted to the base station 970 through the corresponding antennas 930 and 940. In addition, the forward signal transmitted from the base station 970 is introduced into the duplexer (295, 880) through the respective antenna (930, 940), each duplexer (295, 880) is the received forward signal of each power amplifier (297, 885). Each of the power amplifiers 297 and 885 amplifies the applied signal and delivers it to the corresponding duplexers 205 and 865. Except for the above description, the components and operations of the multipath relay 800 of the fourth embodiment and the multipath relay 900 of the fifth embodiment are the same. As a result, the fifth embodiment extends the transmission and reception signals between the multipath relay 900 and the base station 970 through a diversity path, thereby increasing the signal transmission rate between them.

(Example 6)

10A is an installation diagram using the multipath relay 1000 according to the sixth embodiment of the present invention, and FIG. 10B is a configuration diagram of the multipath relay 1000 according to the sixth embodiment of the present invention. In the sixth embodiment, the reverse signals received from the terminal side antennas 1110 and 1120 are combined to have a delay characteristic of two chips or more in the repeater 1000, respectively. It is a structure implemented to transmit to the base station (1170, 1200). In the present embodiment, the reverse signal input from the terminal may be transmitted to the base stations of different operators, and conversely, the forward signal transmitted from the base stations of different operators may be received and transmitted to the terminal. Since the functions of the internal components constituting the multipath relay apparatus 1000 according to the sixth embodiment have been described above, the connection relations and signal flows of the respective components will be mainly described.

The reverse signal introduced to one antenna (eg, 1110) of the multipath relay 1000 is switched by the seventh duplexer 1201 to be amplified by the eighth LNA 1202, and then to the seventh mixer 1203. Down-converted to the IF signal. Here, downconversion to the IF signal is achieved by mixing the frequency generated by the fourth local oscillator 1204 and the signal amplified by the eighth LNA 1202. The IF signal mixed by the seventh mixer 1203 is adjusted by the second attenuator and transmitted to the second power divider 1206.

The reverse signal introduced to another antenna (eg, 1120) of the multipath relay 1000 is filtered by a frequency of a predetermined band by the seventeenth BPF 1207, and amplified by the ninth LNA 1208. Downconverted to the IF signal by the mixer 1209. Here, downconversion to the IF signal is achieved by mixing the frequency generated by the fourth local oscillator 1204 and the signal amplified by the ninth LNA 1208. The IF signal mixed by the eighth mixer 1209 is delayed by two or more chips by the eighteenth BPF 1210 and transmitted to the third power divider 1211. Here, in order to implement a delay characteristic of two chips or more, the general eighteen BPF 1210 may be used as well as a general delay element.

The third combiner 1212 combines IF signals transmitted in different paths distributed in the second power divider 1206 and the third power divider 1211 and have different delay characteristics to the 19th BPF 1213. The 19th BPF 1213 filters the transferred IF signal to the ninth mixer 1214, and the ninth mixer 1214 up-converts the down-converted IF signal to an RF signal. Here, the up-conversion to the RF signal is achieved by mixing the frequency generated by the fourth local oscillator 1204 and the signal filtered by the ninth BPF 1213. The up-converted RF signal is amplified by the sixth power amplifier 1215 and transmitted to one base station (eg, 1170) through the eighth duplexer 1216.

Similarly, the fourth combiner 1217 combines IF signals transmitted in different paths distributed in the second power divider 1206 and the third power divider 1211 with different delay characteristics to the 20th BPF 1218. The twentieth BPF 1218 filters the transferred IF signal to the tenth mixer 1219, and the tenth mixer 1219 up-converts the down-converted IF signal to an RF signal. Here, the up-conversion to the RF signal is achieved by mixing the frequency generated by the fourth local oscillator 1204 and the signal filtered by the tenth BPF 1219. The up-converted RF signal is amplified by the seventh power amplifier 1220 and transmitted to another base station (eg, 1200) through the ninth duplexer 1221. The nineteenth BPF 1213 and the twentieth BPF 1218 have frequency bands and attenuation characteristics required by each operator, and the frequency bands and attenuation characteristics may be changed according to the repeaters implemented.

In addition, each signal input from each of the base stations 1170 and 1200 is combined by the fifth combiner 1222, amplified by the eighth power amplifier 1223, and transmitted to the terminal through the seventh duplexer 1201. do.

(Example 7)

11A is an installation diagram using a multipath relay device 1300 according to a seventh embodiment of the present invention, and FIG. 11B is a configuration diagram of the multipath relay device 1300 according to the seventh embodiment of the present invention. The seventh embodiment extends to the sixth embodiment and is a structure of a multipath relay having an integrated delay characteristic capable of communicating with three different base stations. Since the multipath relay apparatus 1300 according to the seventh embodiment is almost the same as the multipath relay apparatus 1000 according to the sixth embodiment, the same components will not be described, and only differences will be described.

The multipath relay device 1300 according to the seventh embodiment transmits a signal from a terminal to a base station 1440 of a C operator through a base station side antenna (eg, 1350). The sixth combiner 1450, the 21st BPF 1460, the eleventh mixer 1470, the ninth power amplifier 1480, and the tenth duplexer 1490 are added to the path relay 1000. That is, the sixth combiner 1450 combines IF signals transmitted in different paths distributed in the second power divider 1206 and the third power divider 1211 and have different delay characteristics to the 21st BPF 1460. In addition, the 21st BPF 1460 filters the transferred IF signal to the eleventh mixer 1470, and the eleventh mixer 1470 upconverts the downconverted IF signal into an RF signal. Here, the up-conversion to the RF signal is performed by mixing the frequency generated by the fourth local oscillator 1204 of FIG. 10B and the signal filtered by the 21st BPF 1460. The upconverted RF signal is amplified by the ninth power amplifier 1480 and transmitted to another base station (eg, 1440) through the tenth duplexer 1490. Except for the above description, the components and operations of the multipath relay device 1300 of the seventh embodiment and the multipath relay device 1000 of the sixth embodiment are the same.

The above description is only for explaining one embodiment, and the present invention is not limited to the above-described embodiment and can be variously changed within the scope of the appended claims. For example, the shape and structure of each component specifically shown in the embodiments of the present invention may be modified.

As described above, according to the multi-path relay apparatus of the mobile communication system using the delay processing method according to the present invention, by implementing the delay difference between the receiving path of the repeater using the intermediate frequency bandpass filter having only the delay characteristics, By improving the reception sensitivity of mobile communication, infrastructure investment cost can be reduced, and the service area of the base station can be expanded or the service of sufficient quality can be provided to the radio shadow area.

In addition, by connecting an antenna or a TTLNA having a delay characteristic to a conventional general repeater, there is an effect that can implement the delay characteristics while using the existing repeater as it is.

Claims (13)

In the multi-path relay device of a mobile communication system for relaying the transmission and reception signal between the base station and the terminal, A first duplexer for switching transmission / reception paths of a signal transmitted from a base station and a signal transmitted from a terminal; A first LNA connected to the first duplexer and amplifying only an original signal in a state in which a noise component of the received signal switched by the first duplexer is introduced into an arbitrary reception path; A first local oscillator coupled to the first LNA and generating a stable and constant frequency for converting frequency; A first mixer coupled to the first LNA and a first local oscillator, for mixing an RF signal amplified by the first LNA and a frequency generated by the first local oscillator and converting the frequency into an intermediate frequency signal; A first BPF connected to the first mixer and having a frequency pass band and an attenuation characteristic and maintaining a predetermined delay characteristic; A second mixer connected to the first local oscillator and the first BPF and converting the filtered IF signal into an RF signal; A second BPF connected to the second mixer and removing a leaked local oscillation signal, an IF signal, or an intermodulated signal among the RF signals converted by the second mixer; A third BPF for passing a frequency of a predetermined band among the received signals flowing into another reception path and removing other frequencies; A second LNA connected to the third BPF and configured to amplify only the original signal while suppressing a noise component of the filtered received signal; A second local oscillator connected to the second LNA, the second local oscillator generating a stable and constant frequency to convert a frequency; A third mixer connected to the second LNA and a second local oscillator, the third mixer converting an RF signal amplified by the second LNA and a frequency generated by the second local oscillator into an intermediate frequency signal; A fourth BPF connected to the third mixer, the fourth BPF having a frequency pass band and an attenuation characteristic and maintaining a predetermined delay characteristic; A fourth mixer connected to the second local oscillator and the fourth BPF and converting the filtered IF signal into an RF signal; A fifth BPF connected to the fourth mixer and removing a leaked local oscillation signal, an IF signal, or an intermodulated signal among the RF signals converted by the fourth mixer; A first attenuator connected to the fifth BPF and configured to adjust a gain of the filtered RF signal; A first coupler coupled to the second BPF and the first attenuator and configured to couple respective received signals introduced into different paths; A first power amplifier connected to the first coupler and amplifying and outputting the signal coupled by the first coupler to a signal having a predetermined amplitude; A second duplexer coupled to the first power amplifier for transmitting an amplified signal to a base station and switching a signal introduced from the base station; And A second power amplifier connected to the second duplexer and configured to amplify a received signal switched by the second duplexer and transmit the amplified received signal to the first duplexer. Device. The multi-path relay apparatus of claim 1, wherein the first attenuator is connected to the second BPF or the second BPF and the fifth BPF, respectively. The multipath relay apparatus of claim 1, wherein the first BPF and the fourth BPF maintain a predetermined delay difference. delete delete delete delete delete delete delete In the multi-path relay device of a mobile communication system for relaying the transmission and reception signal between the base station and the terminal, A seventh duplexer for switching transmission / reception paths of a signal transmitted from a base station and a signal transmitted from a terminal; An eighth LNA connected to the seventh duplexer and configured to amplify only the original signal while suppressing noise components of the received signal switched by the seventh duplexer by entering an arbitrary reception path; A fourth local oscillator for generating a stable and constant frequency to convert frequencies; A seventh mixer connected to the eighth LNA and a fourth local oscillator, and converting the RF signal amplified by the eighth LNA and the frequency generated by the fourth local oscillator into an intermediate frequency signal; A second attenuator connected to the seventh mixer, the second attenuator adjusting the gain of the mixed intermediate frequency signal; A second power divider coupled to the second attenuator and distributing a gain adjusted signal; A seventeenth BPF for passing a frequency of a predetermined band among the received signals flowing into another receiving path and removing other frequencies; A ninth LNA connected to the seventeenth BPF and amplifying only an original signal while suppressing a noise component of the filtered received signal; An eighth mixer connected to the ninth LNA and a fourth local oscillator, for mixing the RF signal amplified by the ninth LNA and the frequency generated by the fourth local oscillator and converting the frequency into an intermediate frequency signal; An eighteenth BPF connected to the eighth mixer and delaying the intermediate frequency signal converted by the eighth mixer; A third power divider connected to the eighteenth BPF and distributing a delayed intermediate frequency signal; A third combiner coupled to the second power divider and the third power divider, the third combiner coupling intermediate frequency signals having different delay characteristics and transmitted in different power distribution paths; A nineteenth BPF connected to the third combiner and determining a frequency band and attenuation characteristics of the intermediate frequency signal coupled by the third combiner; A ninth mixer connected to the nineteenth BPF and a fourth local oscillator, for mixing the intermediate frequency signal filtered by the nineteenth BPF and the frequency generated by the fourth local oscillator to up-convert to an RF signal; A sixth power amplifier connected to the ninth mixer and amplifying the up-converted RF signal into a signal having a constant amplitude; An eighth duplexer connected to the sixth power amplifier and transmitting an amplified signal to a base station and switching a signal introduced from the base station; A fourth combiner coupled to the second power divider and the third power divider, the fourth combiner coupling intermediate frequency signals having different delay characteristics and transmitted in different power distribution paths; A 20th BPF connected to the fourth combiner and configured to determine a frequency band and attenuation characteristics of the intermediate frequency signal coupled by the fourth combiner; A tenth mixer connected to the twentieth BPF and the fourth local oscillator, for mixing the intermediate frequency signal filtered by the twentieth BPF and the frequency generated by the fourth local oscillator to up-convert to an RF signal; A seventh power amplifier connected to the tenth mixer and amplifying the up-converted RF signal into a signal having a constant amplitude; A ninth duplexer connected to the seventh power amplifier and transmitting an amplified signal to a base station and switching a signal introduced from the base station; A fifth combiner coupled to the eighth duplexer and a ninth duplexer, for coupling a received signal switched by the eighth and ninth duplexers; And And an eighth power amplifier connected to the fifth combiner and configured to amplify the combined received signal and transfer the combined received signal to the seventh duplexer. The method of claim 11, A sixth combiner coupled to the second power divider and the third power divider, the sixth combiner coupling intermediate frequency signals having different delay characteristics and transmitted in different power distribution paths; A twenty-first BPF coupled to the sixth combiner, for determining a frequency band and attenuation characteristics of the intermediate frequency signal coupled by the sixth combiner; An eleventh mixer connected to the twenty-first BPF and a fourth local oscillator, for mixing the intermediate frequency signal filtered by the twenty-first BPF and the frequency generated by the fourth local oscillator to up-convert to an RF signal; A ninth power amplifier connected to the eleventh mixer and amplifying the upconverted RF signal into a signal having a constant amplitude; And A tenth duplexer coupled to the ninth power amplifier, the tenth duplexer transmitting an amplified signal to a base station and switching a signal introduced from the base station, And the fifth combiner combines the received signals switched by the eighth, ninth and tenth duplexers and transfers them to the eighth power amplifier. The method of claim 11, And the second attenuator and the eighteenth BPF exchange positions between the two attenuators and the eighteenth BPF.