KR101003733B1 - Antenna combiner for multi-wireless communication service - Google Patents

Abstract

The present invention relates to an antenna coupler for multiple wireless communication services, and more particularly, to an antenna coupler for multiple wireless communication services including a 3dB hybrid coupler and a multiplexer.

The antenna coupler according to the present invention includes a multiplexer and a coupler, and a service antenna and each operator for transmitting and receiving a code division multiple access (CDMA) signal, a personal communication system (PCS) signal, and a wide band code division multiple access (WCDMA) signal. Combining and distributing respective signals between the CDMA / WCDMA dual repeater, the PCS repeater, and the PCS / WCDMA dual repeater, and two input / output ports for signal input / output of the antenna and the CDMA / WCDMA dual repeater, PCS repeater and PCS / It is characterized by having three input / output ports for signal input / output of a WCDMA dual repeater.

CDMA, PCS, WCDMA, Splitter, Multiplexer, Hybrid Coupler, Link Antenna, Service Antenna

Description

Antenna combiner for multi-wireless communication service

The present invention relates to an antenna coupler for multiple wireless communication services, and more particularly, to an antenna coupler for multiple wireless communication services including a 3dB hybrid coupler and a multiplexer.

Recently, with the evolution and development of wireless communication, wireless communication services are being developed into wireless communication services using various frequency bands.

The wireless communication is a CDMA / PCS wireless mobile communication service that provides voice-oriented services, a wide band code division multiple access (WCDMA) wireless mobile communication service that enables not only voice but also video calls. WiBro (Wireless Broadband Service) for services has become a variety of wireless mobile communication services.

Since each wireless communication service must use a different frequency band, each wireless mobile communication terminal (MS) must be equipped to receive each service, and each base transceiver station (BTS) must be installed. Do it.

In addition, radio shaded areas such as areas far away from base stations, underground shopping malls, tunnels, underground parking lots, buildings, etc. are installed to enable wireless communication services to service users in the shaded areas. That is, each repeater is installed in a shaded area or a shielded space, and receives each base station signal through a link antenna and then amplifies and radiates it back to a service antenna. Enable the use of wireless communication services in the radio shadow area.

1 is a configuration diagram briefly showing an in-building service using a repeater.

As shown in FIG. 1, the repeater 110 receives and amplifies the base station 100 signal through the link antenna 111, and then the service antennas 113 and 114 of different floors of the distributor 112 and the building. Transmit to the terminal (120, 121) through, and amplifies the signals of the terminal (120, 121) received through the service antenna (113, 114) and transmits through the link antenna 111 to the base station (100).

2 briefly illustrates a configuration of a multi-radio communication service using a conventional repeater.

A company CDMA / WCDMA dual repeater 220 shown in Figure 2 receives the 869 ~ 894MHz CDMA base station signal and 2130 ~ 2149MHz WCDMA base station signal through the link antenna 225 to amplify the service antenna (250, 251) After transmitting to the terminal, and amplifies the terminal signal received through the service antenna (250 증폭 251) and transmits the 824 ~ 849MHz CDMA terminal signal and 1940 ~ 1959MHz WCDMA terminal signal through the link antenna 225 to the base station.

The company B PCS repeater 210 receives and amplifies the 1861-1870 MHz PCS base station signal through the link antenna 215 and transmits the signal to the terminal through the service antennas 250 and 251 and through the service antennas 250 and 251. After amplifying the received terminal signal, a 1771 to 1780 MHz PCS terminal signal is transmitted to the base station through the link antenna 215.

The company C PCS / WCDMA dual repeater 200 receives and amplifies a 1840-1859 MHz PCS base station signal and a 2151-2170 MHz WCDMA base station signal through the link antenna 205, and transmits the signals to the terminal through the service antennas 250 and 251. After amplifying the terminal signal received through the service antennas 250 and 251, the 1750 to 1769 MHz PCS terminal signal and the 2151 to 2170 MHz WCDMA terminal signal are transmitted to the base station through the link antenna 205.

Here, the multiplexer 230 is used to combine the A company repeater 220 signal, the B company repeater 210 signal, and the C company repeater 200 signal to the service antennas 250 and 251 used in common. . Splitter 240 is also used to distribute signals to service antennas 250 and 251 at different floors or in different locations.

When the multiplexer 230 is used for multiple wireless communication services, the cost is reduced by one third compared to three antennas using each antenna and each antenna feeder cable. Most wireless carriers prefer to use a multiplexer 230 and a splitter 240 to share an antenna and an antenna feed cable.

Since the multiplexer 230 is composed of the respective filters 201, 202, 203, 204, 211, 212, 221, 222, 223, 224, the Wilkinson Power Combiner or Tee Although it has the advantage of lower insertion loss than using a T-Junction Combiner, it has a disadvantage that the price is considerably increased due to the increase in the outer size and the number of internal filters.

Furthermore, as shown in FIG. 2, when the company A's WCDMA transmit / receive frequencies are 2130 to 2149 MHz and 1940 to 1959 MHz, and the company C's WCDMA transmit / receive frequencies are 2151 to 2170 MHz and 1961 to 1980 MHz, the frequency separation of the A company and the C company is considerably close to 2 MHz. As described above, in order to fabricate a multiplexer having a close frequency separation between the internal filters, the number of internal filters is increased, thereby increasing the size of the multiplexer and increasing the price of the multiplexer.

Also, if Company B's PCS transmit / receive frequency is 1861 ~ 1870MHz, 1771 ~ 1780MHz, and Company C's PCS transmit / receive frequency is 1840 ~ 1859MHz, 1750 ~ 1769MHz, the frequency separation of Company B and C will be close to 2MHz. As described above, in order to fabricate a multiplexer having close frequency separation of the internal filters, the number of internal filters is increased, thereby increasing the size of the multiplexer and increasing the price of the multiplexer.

An object of the present invention for solving the above-mentioned problems is to simplify the internal structure of the multiplexer by combining a 3dB hybrid coupler and a multiplexer to facilitate the manufacture, and to reduce the size of the multiplexer to reduce the price.

The antenna combiner according to the present invention for solving the above problems, is composed of a multiplexer and a coupler, and the CDMA (Code Division Multiple Access) signal / PCS (Personal Communication System) signal / WCDMA (Wideband Code Division Multiple Access) signal Combining and distributing signals between a service antenna for transmitting and receiving and a CDMA / WCDMA dual repeater, a PCS repeater, and a PCS / WCDMA dual repeater of each service provider, and two input / output ports for signal input / output of the antenna and the CDMA / WCDMA dual And three input / output ports for signal input and output of the repeater, the PCS repeater, and the PCS / WCDMA dual repeater.

Here, the multiplexer is preferably configured to include a 824 ~ 894 MHz band filters, 1940 ~ 2149 MHz band filters, 1771 ~ 1870 MHz band filters, 1750 ~ 1859 MHz band filters and 1961 ~ 2170 MHz band filters.

Here, it is preferable that the coupler use a 3dB hybrid coupler.

In addition, the antenna combiner according to the present invention is composed of a multiplexer and a coupler, a service antenna for transmitting and receiving a CDMA (Code Division Multiple Access) signal / PCS (Personal Communication System) signal / WCDMA (Wideband Code Division Multiple Access) signal And combining and distributing respective signals between the CDMA repeater / PCS repeater / WCDMA repeater of each service provider, and two input / output ports for signal input / output of the antenna and 5 for signal input / output of the CDMA repeater / PCS repeater / WCDMA repeater. It is characterized by having two input / output ports.

Here, the multiplexer is preferably configured to include a 824 ~ 894 MHz band filters, 1940 ~ 2149 MHz band filters, 1771 ~ 1870 MHz band filters, 1750 ~ 1859 MHz band filters and 1961 ~ 2170 MHz band filters.

Here, it is preferable that the coupler use a 3dB hybrid coupler.

According to the above-described configuration of the present invention, in order to use the antenna used in each repeater in multiple wireless communication services in common to integrate the 3dB hybrid coupler and multiplexer to simplify the internal structure of the multiplexer and reduce the size of the antenna combiner Can be.

Hereinafter, with reference to the accompanying drawings looks at the structure and effect of the antenna coupler for multiple wireless communication service according to the present invention.

[Configuration of Multiple Wireless Communication Service Using Three Repeaters]

3 is a block diagram of a multi-radio communication service when using a CDMA, PCS and WCDMA repeater of a multi-radio communication operator applying an antenna combiner according to the present invention.

As shown in FIG. 3, the A company 0.8 GHz Code Domain Multiple Access (CDMA) /2.0 GHz Wide band Code Domain Multiple Access (WCDMA) dual band repeater 320 is connected to the A company through the link antenna 323 to 869 to 894 MHz. Receives and amplifies the CDMA base station signal and the 2130 to 2149 MHz WCDMA base station signal and transmits the same to the CDMA or WCDMA terminal through the service antennas 350 and 351, and the 824 to 849 MHz CDMA terminal signal received through the service antennas 350 and 351. After amplifying the 1940 ~ 1959MHz WCDMA terminal signal and transmits to the A company CDMA base station and the WCDMA base station through the link antenna (323).

Company B's 1.8 GHz Personal Communication System (PCS) repeater 310 receives and amplifies the Company B's 1861-1870 MHz PCS base station signal through a link antenna 313 and transmits it to the PCS terminal through service antennas 350 and 351. After amplifying the 1771-1780 MHz PCS terminal signal received through the service antennas 350 and 351, the signal is transmitted to the B-company PCS base station through the link antenna 313.

The company C's 1.8GHz PCS / 2.0GHz WCDMA dual band repeater 300 receives and amplifies the company C's PCS base station signal and the WCDMA base station signal through the link antenna 303, and then 1840 ~ 1859MHz through the service antennas 350 and 351. Transmit to PCS or 2151 ~ 2170MHz WCDMA terminal, amplify 1750 ~ 1769MHz PCS terminal signal and 1961 ~ 1980MHz WCDMA terminal signal received through service antenna (350, 351) And WCDMA base station.

Here, the A company CDMA / WCDMA dual band repeater 320 signal, the Company B PCS repeater 310 signal and the Company C PCS / WCDMA dual band repeater 300 signal to combine the antenna to send and receive to the service antenna (350, 351) The combiner 340 is inserted.

The antenna combiner 340 for the multi-radio communication service includes two input / output ports for the signal input / output of the service antennas 350 and 351 and a company CDMA / WCDMA dual band repeater 320 and a company B PCS repeater 310 and a company C. It has three input / output ports for signal input / output of the PCS / WCDMA repeater 300.

The antenna combiner 340 for the multiple wireless communication service of the present invention is composed of a multiplexer 331 and a 3dB hybrid coupler 330, the multiplexer 331 is a 824 ~ 894 MHz band filter 321, 1940 ~ 2149 MHz band filter ( 322, a 1771-1870 MHz band filter 311, a 1750-1859 MHz band filter 301, and a 1961-2170 MHz band filter 302.

In the conventional configuration as shown in FIG. 2, in order to service wireless communication signals of three different operators by sharing a feed line with an antenna, a total of 10 internal filters 201, 202, 203, 204, 211, 212, Although a multiplexer 230 and a distributor 240 including 223, 224, 221, and 222 are required, when using the antenna combiner 340 for multiple wireless communication services of the present invention, a total of five internal filters 301, 302, Only the multiplexer 331 consisting of 311, 321, and 322 and one hybrid coupler 330 are needed, so the structure of the multiplexer is simplified and the size is reduced to 1/2, and the cost of sharing the antenna and the feeder is 1 /. Decreases to two.

[Configuration of Multiple Wireless Communication Service Using Five Repeaters]

4 shows five input / output ports and two service antennas 470 and 471 connected to five repeaters 400, 410, 420, 430 and 440 to combine and send five repeater signals to the service antennas 470 and 471. This is an example of service using an antenna combiner 460 composed of two connected input / output ports.

The A company 0.8 GHz Code Domain Multiple Access (CDMA) repeater 440 shown in FIG. 4 receives and amplifies the service antennas 470 and 471 after receiving and amplifying the A company 869 to 894 MHz CDMA base station signals through the link antenna 442. It transmits to the CDMA terminal through, and amplifies the 824 ~ 849MHz CDMA terminal signal received through the service antenna (470, 471) and transmits through the link antenna 442 to the company A CDMA base station.

The A company's 2.0 GHz Wide Band Code Domain Multiple Access (WCDMA) repeater 430 receives and amplifies the A company's 2130 to 2149 MHz WCDMA base station signal through the link antenna 432, and then the WCDMA terminal through the service antennas 470 and 471. After amplifying the 1940 ~ 1959MHz WCDMA terminal signal received through the service antenna (470, 471) and transmits through the link antenna 432 to the company WCDMA base station.

Company B's 1.8 GHz Personal Communication System (PCS) repeater 420 receives and amplifies the Company B's 1861-1870 MHz PCS base station signal through a link antenna 422 and transmits it to the PCS terminal through service antennas 470 and 471. After amplifying the 1771-1780 MHz PCS terminal signal received through the service antennas 470 and 471, the signal is transmitted to the B-company PCS base station through the link antenna 422.

Company C 1.8 GHz PCS repeater 410 receives and amplifies the Company C 1840-1859 MHz PCS base station signal through link antenna 412, and transmits the signal to PCS terminal through service antennas 470 and 471, and service antenna 470. And amplifies the 1750-1769 MHz PCS terminal signal received through 471, and transmits the signal to the PCS base station of the Company C through the link antenna 412.

The company C's 2.0 GHz WCDMA repeater 400 receives and amplifies the company C's 2151-2170 MHz WCDMA base station signal through the link antenna 402 and transmits the signals to the 2151-2170 MHz WCDMA terminal through the service antennas 470 and 471. After amplifying the 1961 to 1980 MHz WCDMA terminal signals received through the antennas 470 and 471, the signals are transmitted to the WCDMA base station via the link antenna 402.

Here, the antenna combiner (CDMA repeater 440 and WCDMA repeater 430 signal, the B company PCS repeater 420 signal, the C company PCS repeater 410 and WCDMA repeater 400 signal to combine and send to the antenna antenna combiner ( 460 is inserted, the antenna coupler 460 is composed of a multiplexer 451 consisting of a total of five filters (401, 411, 421, 431, 441) and a hybrid coupler 450 and two service antennas (470, Two input / output ports for signal input / output of 471) and five input / output ports for signal input / output of five repeaters 400, 410, 420, 430, and 440 are provided.

Antenna combiner 460 for multiple wireless communication services of the present invention is composed of a multiplexer 451 and a 3dB hybrid coupler 450, the multiplexer 451 is a 824 ~ 894 MHz band filter 441, 1940 ~ 2149 MHz band filter ( 431, a 1771-1870 MHz band filter 421, a 1750-1859 MHz band filter 411, and a 1961-2170 MHz band filter 401.

When the antenna coupler 460 of the present invention is used, only five filters 401, 411, 421, 431, and 441 are required inside the multiplexer 451 coupled with the hybrid coupler 450, so that the number of filters and the antenna coupler 460 are required. ) Reduces the size of half to half the cost of sharing antennas and feeders.

Although the preferred embodiments of the present invention have been described above with reference to the accompanying drawings, the above-described technical configuration of the present invention may be embodied by those skilled in the art to which the present invention pertains without changing its technical spirit or essential features of the present invention. It will be appreciated that the present invention may be practiced as. Therefore, the above-described embodiments are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the appended claims rather than the detailed description, and the meaning and scope of the claims and All changes or modifications derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

1 is a system configuration diagram of an in-building service using a wireless communication repeater.

2 briefly illustrates a configuration of a multiple wireless communication service using three wireless communication repeaters.

3 is a block diagram of a multi-radio communication service when using a total of three CDMA, PCS and WCDMA repeaters to which the antenna combiner according to the present invention is applied.

4 is a block diagram of a multi-radio communication service when using a total of five CDMA, PCS, WCDMA repeaters to which the antenna combiner according to the present invention is applied.

Claims (6)

Consists of a multiplexer and a coupler, CDMA / WCDMA dual repeater, PCS repeater, and PCS / WCDMA dual repeater with service antenna for transmitting / receiving code division multiple access (CDMA) signals / personal communication system (PCS) signals / wide band code division multiple access (WCDMA) signals Combining and distributing each signal in between, And two input / output ports for signal input / output of the antenna and three input / output ports for signal input / output of the CDMA / WCDMA dual repeater, a PCS repeater, and a PCS / WCDMA dual repeater. The method of claim 1, The multiplexer comprises a 824 ~ 894 MHz band filter, 1940 ~ 2149 MHz band filter, 1771 ~ 1870 MHz band filter, 1750 ~ 1859 MHz band filter and 1961 ~ 2170 MHz band filter, antenna combiner for multiple wireless communication services. The method of claim 1, And the coupler is a hybrid coupler. Consists of a multiplexer and a coupler, Each signal is transmitted between a service antenna that transmits and receives a code division multiple access (CDMA) signal, a personal communication system (PCS) signal, a wide band code division multiple access (WCDMA) signal, and a CDMA repeater, a PCS repeater, and a WCDMA repeater of each operator. Combine and distribute, And two input / output ports for signal input / output of the antenna and five input / output ports for signal input / output of the CDMA repeater / PCS repeater / WCDMA repeater. The method of claim 4, wherein The multiplexer comprises a 824 ~ 894 MHz band filter, 1940 ~ 2149 MHz band filter, 1771 ~ 1870 MHz band filter, 1750 ~ 1859 MHz band filter and 1961 ~ 2170 MHz band filter, antenna combiner for multiple wireless communication services. The method of claim 4, wherein And the coupler is a hybrid coupler.

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