• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    PURPOSE: A base station device of code division multiple access(CDMA) system with an active antenna is provided to simplify a structure of a base station and guarantee the more subscriber capacities by increased sector and gain. CONSTITUTION: A base station device of code division multiple access(CDMA) system with an active antenna includes a transceiver(110) installed inside a house, for up-converting a CDMA modulating signal to be transmitted to a subscriber and down-converting a received signal into an intermediate frequency. An indoor device(120) installed inside the house, transmits the receiving channel of the transceiver(110) into a butler matrix section(130) adding a direct current(DC). The butler matrix section(130) installed outside the house, generates a beam forming signal to transmit by giving a phase difference in the transmitting signal of the indoor device(120) and outputs the receiving signal converted into a reverse channel signal for each sector. An active high frequency module(140) installed outside the house, copies the beam forming signal of the butler matrix section(130) on spaces in a predetermined beam-width and angle, and amplifies the receiving reverse channel signal from the subscriber in a constant power level to transmit the signal to the butler matrix section(130).
    公开号:KR20000060229A
    申请号:KR1019990008364
    申请日:1999-03-12
    公开日:2000-10-16
    发明作者:오치욱;박홍준
    申请人:김영환;현대전자산업 주식회사;
    IPC主号:
    专利说明:

    Code division multiple access base station apparatus using active antenna {BTS of CDMA form application of the active antenna}
    BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a code division multiple access (CDMA) base station (BTS), and more particularly, to a base station apparatus employing an outdoor multi-beam active antenna having a built-in transmission and reception amplifier.
    In a mobile communication system such as a code division multiple access (CDMA) digital cellular system (DCS) and a personal digital communication system (PCS), a base station typically installs a omni-directional antenna or a sector antenna outdoors and uses a high power amplifier indoors. And an indoor low noise amplifier connected to the antenna receiver.
    1 schematically shows a single sector base station apparatus in a general CDMA mobile communication system having the above configuration.
    As shown, the antennas 11 and 12 and 13 installed outdoors, the transmission and reception filter and the low noise amplifier 20 installed indoors, the high output amplifier 30, the noise generator 40, and the transceiver A shelf 50, a GPS receiver 60, a digital shelf 70, a base station controller 80, and a failure diagnosis monitoring device 90 are provided.
    In the general single-sector base station apparatus configured as described above, the transmission signal output from the transceiver shelf 50 in the forward link is amplified by the high output amplifier 30, and then transmitted through a transmission / reception filter and a transmission filter in the low noise amplifier 20 to be installed outdoors. Is transmitted via the antenna 11.
    In addition, the reverse link is received through the reception antennas 12 and 13 installed outdoors, and the received signal passes through a reception filter in the indoor and reception filters and the low noise amplifier 20, and then is predetermined by the low noise amplifier 20. After being amplified to a level, it is delivered to the transceiver shelf 50.
    Here, the transceiver shelf 50 converts the IF signal output from the digital shelf 70 to UHF and inversely converts the received UHF signal to the IF signal.
    However, in the base station apparatus of the general CDMA mobile communication system, an omnidirectional antenna or a sector antenna is installed outdoors, and a high power amplifier and a low noise amplifier are installed indoors. In this case, when the distance between the indoor equipment and the outdoor antenna increases, Since the loss is large, economical loss occurs because a relatively high power high power amplifier and a low noise amplifier must be used.
    In addition, since the high power amplifier and the high noise amplifier must be selectively applied according to the distance between the indoor equipment and the outdoor antenna, the inconvenience of installing the base station occurred.
    Therefore, the present invention has been proposed to solve various problems occurring in the base station apparatus of the general mobile communication system as described above.
    SUMMARY OF THE INVENTION An object of the present invention is to provide a base station apparatus to which an outdoor multi-beam active antenna having a built-in transmission and reception amplifier is applied.
    Base station apparatus according to the present invention for achieving the above object,
    A transceiver installed indoors and configured to upconvert the CDMA modulated signal to be transmitted to the subscriber and downconvert the received signal to an intermediate frequency;
    An indoor device installed in the indoor unit and adding DC to a transmission channel received from the transceiver, and transmitting the DC to the butler matrix unit, and transmitting the signal received from the butler matrix unit to the transceiver;
    A butler matrix unit which is installed outdoors and gives a phase difference to a transmission signal obtained from the indoor device to generate and transmit a beamforming signal, and converts the received signal into a reverse channel signal for each sector;
    Copies the beam forming signal installed in the outdoors and transmitted from the butler matrix to the space at a predetermined beam width and direction angle, receives the reverse channel signal transmitted from the subscriber, amplifies the signal to a predetermined power level, and transmits the signal to the butler matrix. It consists of an active high frequency module.
    1 is a schematic diagram of a base station apparatus of a general CDMA mobile communication system;
    2 is a block diagram of a code division multiple access method base station apparatus using an active antenna according to the present invention;
    Figure 3 is a detailed block diagram of the indoor device of Figure 2;
    4 is a detailed block diagram of the array antenna unit of FIG.
    <Description of the code | symbol about the principal part of drawing>
    110: transceiver
    120: indoor device
    130: Butler Matrix
    140: active high frequency module
    141 to 144: first to fourth array antenna units
    Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention according to the technical spirit as described above in detail.
    2 is a block diagram of a CDMA base station apparatus to which an active antenna according to the present invention is applied.
    As shown, the transceiver 110 is installed indoors and up-converts the CDMA modulated signal to be transmitted to the subscriber, and the received signal is down-converted to an intermediate frequency, and the transmission is installed indoors and transmitted from the transceiver 110. The DC device is added to the channel and transferred to the butler matrix unit 130, and the signal received from the butler matrix unit 130 is transmitted to the transceiver, and the indoor device 120 is installed outdoors and the indoor device 120 is installed. A butler matrix unit 130 which generates and transmits a beamforming signal by giving a phase difference to a transmission signal obtained by the second signal, and converts the received signal into a reverse channel signal for each sector and outputs the reverse channel signal for each sector; Copies the beamforming signal transmitted from the receiver into the space with a predetermined beam width and directivity angle, and receives the reverse channel signal transmitted from the subscriber. It is composed of an active high frequency module 140 that amplifies the power level and delivers to the Butler matrix unit 130.
    In the drawing, reference numeral 150 denotes a dummy rod additionally connected, and 160, 170, and 180 denote three beams corresponding to alpha, beta, and gamma sectors.
    In FIG. 2, the dotted upper part is an outdoor device, and the lower dotted line is an indoor device.
    As shown in FIG. 3, the indoor device 120 includes a power supply unit 121 for converting a commercial AC power supplied from the outside into a DC power supply satisfying an input condition of the active high frequency module 140, and the power supply. The first to third power and the signal combiner (122 to 124) for combining the DC power supplied from the supply unit 121 and the transmission CDMA signal obtained from the transceiver 110.
    In addition, the active high frequency module 140 includes a first to fourth array antenna units 141 to 144 having a transmitting and receiving antenna element and a transmitting and receiving amplifier and being horizontally arranged to form a beam radiation pattern.
    The first array antenna unit 141 may include a transmission amplifier 141a for amplifying the input beamforming signal to a predetermined level and a transmission band filter for filtering the beamforming signal amplified by the transmission amplifier 141a into a predetermined band. 141b, a transmission antenna 141c for copying the beamforming signal output from the transmission bandpass filter 141b into a space at a predetermined beam width and directivity angle, and a reception antenna for receiving a CDMA reverse channel signal transmitted by a subscriber. 141d, a reception band filter 141e for band filtering the CDMA reverse channel signal received by the reception antenna 141d, and a CDMA reverse channel signal output from the reception band filter 141e to a predetermined level. It consists of the receiving amplifier 141f which outputs.
    The CDMA base station apparatus employing the active antenna according to the present invention configured as described above has different operations depending on the forward link and the reverse link, which will be described below separately.
    First, the data to be transmitted in the forward link, that is, three (alpha, beta, gamma) CDMA modulated intermediate frequencies of 4.95Mhz, the reception frequency of the terminal of the service subscriber (DCS: 869 ~ 894 Mhz, PCS: 1840 ~ 1870 Mhz) Upconvert to.
    The three up-converted transmission frequencies are input to the first to third power sources and the signal combiners 122 to 124 in the indoor device 120, and the indoor device 120 is externally input from the power supply unit 121. The commercial AC power is converted into a DC voltage required by the butler matrix unit 130 and supplied to the first to third power sources and the signal combiners 122 to 124, respectively. The first to third power and signal combiners 122 to 124 combine the three CDMA forward channel signals obtained from the transceiver 110 and the DC power to the Butler matrix unit 130 installed in the outdoor device.
    The butler matrix unit 130 installed in the outdoors is configured of the beams formed by the array antenna units 141 to 144 having three horizontal arrays of three transmission channel signals (alpha, beta, and gamma sectors) to be transmitted. The transmission angle is transmitted to the active high frequency module 140 by giving a phase difference to the three transmission signals so that the directivity angles are the same as the beams 160, 170, and 180 shown in FIG. 2. Here, the butler matrix unit 130 has four input terminals and four output terminals, also referred to as a 4 * 4 butler matrix, and commercial items have been developed. In addition, the butler matrix unit 130 outputs a beam forming signal through all output terminals regardless of the number of signals input to the input terminal.
    Next, the first to fourth array antenna units 141 to 144 in the active high frequency module 140 are devices in which actual transmit / receive antenna elements and transmit / receive amplifiers are built, and operate as array antennas arranged in four horizontally. Since the internal configurations and operations of the first to fourth array antenna units 141 to 144 are identical to each other, only one array antenna unit (herein, referred to as a first array antenna) will be described below.
    That is, the first array antenna unit 141 amplifies the beamforming signal transmitted from the butler matrix unit 130 at the transmission amplifier 141a to a constant power level, and at the predetermined level in the transmission band filter 141b. The power amplified beamforming signal is filtered to a set band to remove the spurious signal. The beam forming signal from which the spurious signal is removed is radiated in the space at a beam width (30 degrees) and a direction angle determined by the transmitting antenna 141c.
    In other words, one array antenna unit copies a CDMA channel corresponding to one sector onto a space having a width of 30 degrees. Therefore, since one array antenna unit has an alpha, beta, and gamma 90-degree propagation region, when using 4 array antennas as in the present invention, it is possible to cover a 360-degree propagation region at 4 * 90 degrees.
    Next, in the reverse radiation link, the CDMA reverse channel signal transmitted by the subscriber is received in each array antenna unit in the active high frequency module 140. Here, as shown in FIG. 4, the first array antenna unit 141, which is one array antenna unit, receives the CDMA reverse channel signal transmitted by the subscriber from the reception antenna 141d, and the reception band filter 141e The reverse channel signal received by the reception antenna 141d is filtered into a predetermined band. The CDMA reverse channel signal filtered in the set band is amplified to a constant power level in the reception amplifier 141f and then transferred to the butler matrix unit 130 at the rear stage.
    The butler matrix unit 130 uses a 4 * 4 butler matrix as in the transmission butler matrix, and among the three input terminals, received signals of alpha, beta, and gamma are received, and each of the received signals is alpha, It converts the beta and gamma sector CDMA reverse channel signals to the indoor device 120. The signal input to the remaining input terminal 1 is transmitted to the dummy load 150.
    Unlike the forward link processing, the indoor device 120 installed indoors passes the input CDMA reverse channel signal for each sector as it is and transmits it to the transceiver 110 at the rear end.
    The transceiver 110 receives the received signal (DCS: 824 ~ 849Mhz, PCS: 1750 ~ 1780Mhz) and down-converts to an intermediate frequency of 4.95Mhz and transmits it to the demodulator in the rear stage.
    In other words, the radiation pattern of the multi-beam active antenna applied to the present invention is composed of three single beams having a beam width of 30 degrees, has a total propagation range of 90 degrees, and the sector antenna used in the existing CDMA type DCS / PCS base station. The propagation area of 360 degrees is divided into alpha, beta, and gamma sectors. When the multi-beam active antenna according to the present invention is applied to an existing CDMA DCS / PCS system, a 90-degree propagation region is divided into three parts such as an alpha, beta, and gamma sector to have a propagation region. Thus, four active antennas cover 360 degrees. can do. As a result, a total of 360-degree propagation area is divided into 12 sectors, and thus a CDMA channel is transmitted and received. Thus, compared to a CDMA system employing a sector antenna, increased sectors and gains can be expected, thereby securing more subscriber capacity.
    As described above, according to the present invention, a multi-beam active antenna having a built-in transmit and receive amplifier is applied to a conventional CDMA DCS / PCS system, and thus, a transmission high power amplifier (HPA) or a reception unit installed indoors is used. The need for a low noise amplifier (LNA) has the advantage of simplifying the configuration of the entire base station system.
    In addition, since the multi-beam active antenna according to the present invention manages the propagation area by 12 sectors by 30 degrees, it is possible to expect increased sectorization gain and to accommodate more subscribers in terms of subscriber capacity. There is.
    权利要求:
    Claims (5)
    [1" claim-type="Currently amended] A base station apparatus of a CDMA mobile communication system,
    A transceiver installed indoors and configured to upconvert the CDMA modulated signal to be transmitted to the subscriber and downconvert the received signal to an intermediate frequency;
    An indoor device installed in the indoor unit and adding DC to a transmission channel received from the transceiver, and transmitting the DC to the butler matrix unit, and transmitting the signal received from the butler matrix unit to the transceiver;
    A butler matrix unit which is installed outdoors and gives a phase difference to a transmission signal obtained from the indoor device to generate and transmit a beamforming signal, and converts the received signal into a reverse channel signal for each sector;
    Copies the beamforming signal installed in the outdoors and transmitted from the butler matrix unit to the space at a predetermined beam width and directivity angle, receives the reverse channel signal transmitted from the subscriber, amplifies it to a constant power level, and transmits the signal to the butler matrix unit. Code division multiple access type base station apparatus using an active antenna, characterized in that configured to include an active high frequency module.
    [2" claim-type="Currently amended] The apparatus of claim 1, wherein the indoor device comprises: a power supply unit for converting a commercial AC power supplied from the outside into a DC power supply satisfying an input condition of an active high frequency module, a DC power supplied from the power supply unit, and a transceiver obtained from the transceiver; Code division multiple access type base station apparatus using an active antenna, characterized in that the first to third power source and signal combiner for combining the transmission CDMA forward channel signal.
    [3" claim-type="Currently amended] The active antenna of claim 1, wherein the active high frequency module comprises first, fourth, and fourth antenna elements which are arranged horizontally and are arranged horizontally to form a beam radiation pattern. Applied code division multiple access base station apparatus.
    [4" claim-type="Currently amended] The apparatus of claim 3, wherein the first to fourth array antenna units comprise: a transmission amplifier for amplifying the input beamforming signal to a predetermined level; a transmission band filter for filtering the beamforming signal amplified by the transmission amplifier into a predetermined band; A transmission antenna for copying a beamforming signal output from the transmission bandpass filter to a space at a predetermined beam width and directivity angle, a reception antenna for receiving a CDMA reverse channel signal transmitted by a subscriber, and a CDMA reverse direction received from the reception antenna A code division multiple access type base station apparatus using an active antenna, comprising: a reception band filter for band-filtering a channel signal; and a reception amplifier for amplifying and outputting a CDMA reverse channel signal output from the reception band filter to a predetermined level. .
    [5" claim-type="Currently amended] 5. The code division multiple access method base station apparatus according to claim 4, wherein the propagation region of the transmitting antenna has a propagation region of 90 degrees at 30 degrees per sector.
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    同族专利:
    公开号 | 公开日
    KR100292714B1|2001-06-15|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    法律状态:
    1999-03-12|Application filed by 김영환, 현대전자산업 주식회사
    1999-03-12|Priority to KR1019990008364A
    2000-03-01|Priority claimed from JP2000056327A
    2000-10-16|Publication of KR20000060229A
    2001-06-15|Application granted
    2001-06-15|Publication of KR100292714B1
    优先权:
    申请号 | 申请日 | 专利标题
    KR1019990008364A|KR100292714B1|1999-03-12|1999-03-12|BTS of CDMA form application of the active antenna|
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