KR20010111335A - Transmitting and receiving interface device of CDMA base station by using optic line - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmission / reception interface device of a base station in a code division multiple access (CDMA) mobile communication system. The interface device according to the prior art is a PMU (Pico-BTS) connected to a base station. Due to the high transmission loss between the Master Unit and the PRU (Pico-BTS Remote Unit), it cannot provide high quality service to small shadow areas, and only one secondary relay is connected to one main relay. Therefore, when there are many small shadow areas, there is a problem that the system installation cost increases.

The present invention has been made in order to solve the above problems, by reducing the transmission path loss by converting and transmitting the transmission signal between the main relay and the secondary relay to an optical signal, and then restore and supply to the original signal again, one It is possible to connect a large number of secondary relays to a remote relay and use it to provide high quality service.A single primary relay can control multiple secondary relays so that remote status monitoring is easy. Provides a transmission and reception interface device of a CD base station using.

Description

Transmitting and receiving interface device of CDMA base station by using optic line}

In the base station system according to the prior art, when there is an obstacle in the service area, a shadow area that is difficult to reach is generated. This shadow area is unnecessarily increased due to various factors such as the increase of subscribers and the change of features. There is a problem that subscribers who live in the shadow area or use the mobile terminal do not receive high quality service.

1 is a functional block diagram of a base station system according to the prior art. In Figure 1, the main relay and the secondary relay connected to the base station is configured to be connected to the antenna and the minimum distance to the separate enclosure, the data signal (not shown) of the CDA mobile communication system is The baseband system is converted into baseband (I-Inha) and Q (Quadrature) signals, which are the baseband output signals of the PMU (1) of the base station system, together with the GPS (Global Positioning System) signal. Is supplied to the secondary repeater (PRU) 10. The secondary repeater of the base station system receives an input signal and modulates the signal into a signal designated by a base station controller (BSC) to form a channel, which is a high frequency signal by a power amplifier (PA; Power Amplifier) 14. After being amplified to a high output, it is applied to a transmitting antenna and transmitted through a wireless transmission path. The high frequency signal transmitted in this way is received by the subscriber by a portable terminal (not shown), on the contrary, the signal transmitted from the portable terminal is received by the antenna 17 at the receiving end of the base station system. The received signal is passed through the band pass filter 16, amplified by the low noise amplifier 19, and then downconverted to an intermediate frequency and transmitted to the main relay of the base station system.

FIG. 2 is a block diagram of the RF stage of FIG. 1. In FIG. 2, a combiner for transmitting a plurality of channel (FA) signals, in which a data signal of a CDA mobile communication system is modulated into a high frequency signal by a carrier signal corresponding to each channel, to one common antenna. ) And a power amplifier 14 for amplifying the signal passing through the combiner, and an antenna 17 for transmitting a signal applied from the power amplifier to the portable terminal. The power amplifier generally uses a linear power amplifier (LPA) or a high power amplifier (HPA). On the contrary, the signal transmitted from the portable terminal is applied to the low noise amplifier 19, amplified, and then applied to the distributor to be distributed for each channel.

On the other hand, Figure 3 is a functional block diagram of the optical repeater according to the prior art receives the transmission signal extracted by the directional coupler of the base station received by the main relay device to convert the optical signal transmitted through the optical line and then to the secondary repeater at a remote location After demodulating to a high frequency signal, amplified and transmitted to the mobile terminal, the signal transmitted from the mobile terminal is low noise amplified by the secondary repeater, and then converted into an optical signal and transmitted to an optical line. Demodulate a high frequency signal and transmit it to the base station through the base station's directional coupler. At this time, it is difficult to identify the abnormality of the equipment because it uses an independent relay device that can not be controlled in the base station, there is a problem that you need to go directly to the place where the relay device is installed to change the system settings because remote control is impossible.

The present invention has been made in order to solve the problems of the prior art as described above, so that a part of the base station apparatus can be installed in a shaded area so as to provide a service even in a shaded area where radio waves of the base station do not reach. It is a technical problem to provide a transmission / reception interface device of this base station.

1 is a functional block diagram of a base station system according to the prior art.

FIG. 2 is a block diagram of the RF stage of FIG. 1. FIG.

3 is a functional block diagram of an optical repeater according to the prior art.

4 is a diagram showing the configuration of a transmission and reception interface device of a CDA base station using an optical line according to the present invention.

5 is a diagram illustrating a configuration of a main relay device of a transmission / reception interface device of a CDA base station using an optical line according to the present invention.

6 is a view showing the configuration of a sub-relay device of a transmission and reception interface device of a CDA base station using an optical line according to the present invention.

* Explanation of symbols for the main parts of the drawings

1. Primary relay of base station system 10. Secondary relay of base station system

100. Main relay of transmitting and receiving interface device

200. Second relay of transmission and reception interface device

103. Modulator 104, 207. Optical signal converter

105,206. Surveillance / Remote Controller 106, 205. Signal Division Multiplexer

107, 203. Electrical signal converters 108. Frequency recoverers

204. Demodulator 208. Frequency converter

In order to solve the above technical problem, a transmission / reception interface device of a CDA base station using an optical line according to the present invention includes a modulator for receiving and modulating a GPS reference signal and an I, Q signal, which are outputs of a main relay of the base station; An optical signal converter for modulating the modulated high frequency signal into an optical transmission signal; An optical cable for transmitting an optical transmission signal applied from the optical signal converter; An electrical signal converter for restoring a light reception signal applied from the optical cable to a high frequency signal; A demodulator for restoring a high frequency signal to an original signal; A frequency converter for downconverting the signal received from the mobile terminal to the intermediate frequency; It includes a monitoring / remote controller for controlling the primary relay and the secondary relay of the base station.

Hereinafter, with reference to the accompanying drawings will be described in detail the characteristics and operating principles of each part of the transmission and reception interface device of the CD base station using the optical line according to the present invention. 4 to 6 are diagrams showing the configuration of a transmission / reception interface device of a CD-A base station according to the present invention, a diagram showing a configuration of a main relay device, and a diagram showing a configuration of a secondary relay device. The main relay device 100 of the transmission and reception interface device of the CD base station receives the reference signal output by the GPS receiver of the base station is converted into an optical transmission signal by the optical converter 104, the converted optical transmission signal is a signal The signal is transmitted to the remote signal division multiplexer 205 via the optical multiplex via the division multiplexer 106. The transmitted signal is demodulated by the electrical signal converter 203 into a high frequency signal.

In addition, in FIG. 5, when the I-base signal (I) (In-Phase) signal 3 and Q (Quadrature) signal 4 of the baseband signal is applied to the main relay device 100 of the transmission and reception interface device, the modulator 103 After modulating the CD signal, the optical converter 104 converts the optical transmission signal into an optical transmission signal. The converted optical transmission signal is passed through the signal division multiplexer 106 to the remote signal division multiplexer 205 via an optical line. Is delivered to. The transmitted signal is recovered by the electrical signal converter 203 and the demodulator 204 into an I (In-Phase) signal 3 and a Q (Quadrature) signal 4 which are baseband signals of the original base station. Supplied to the secondary relay of the base station, the supplied signal is amplified by the power amplifier 14 via the frequency converter 13 and passed through the band pass filter 16 to the space by the antenna 17.

On the contrary, the high frequency signal transmitted from the portable terminal is received through the transmit / receive shared antenna 17 and the diversity antenna 23, applied to the low noise amplifiers 19 and 21, amplified, and then flows into the frequency converters 18 and 20. Downconverted to intermediate frequency and output. The intermediate frequency output by the frequency converter is converted into an optical signal by the optical converter 207 to be sent to the optical line, and the intermediate frequency output by the frequency converter 20 is sent by the secondary optical device of the interface device. It is frequency-converted through the frequency converter 208 of 200 and sent to the optical converter 207. The two signals sent to the optical conversion device are converted into an optical transmission signal and output through the signal division multiplexer 205 through the optical line to the main relay device 100 of the transmission / reception interface device. The signal is transmitted to the electrical signal converter 107, and the electrical signal converter converts the optical signal into the original signal and transmits it to the main relay of the base station for communication.

The present invention relates to a relay device used to solve a radio wave shadow area of a mobile communication system, and by using an optical cable, it is possible to transmit a high frequency signal without power loss and without influence of electrical noise regardless of the distance of a base station shadow area. It is effective to reduce the system installation cost by installing only the secondary relay device of the base station system in the shaded area, and the monitoring and remote control port is formed so that the operator can remotely monitor and control from the base station controller without going to the site. Has an effect that can be implemented.

Claims (3)

In the relay device for solving the radio shadow area of the mobile communication system, A modulator that receives and modulates a GPS reference signal, an in-phase, and a quadrature (Q) signal, which are outputs of a main relay of a base station; An optical signal converter for modulating the modulated high frequency signal into an optical transmission signal; An optical cable for transmitting an optical transmission signal applied from the optical signal converter; An electrical signal converter for restoring a light reception signal applied from the optical cable to a high frequency signal; A demodulator for restoring a high frequency signal to an original signal; A frequency converter for downconverting the signal received from the portable terminal to an intermediate frequency; A monitoring / remote controller for controlling the primary relay and the secondary relay of the base station, A modulated optical signal is converted from the modulator to the CD signal using the I (In-Phase) and Q (Quadrature) signals, which are baseband signals, and are then transmitted to a remote site through an optical line through a signal division multiplexer. , In the remote area, the CDA base station using the optical line is relayed using an electrical signal converter for converting the optical signal from the signal splitter multiplexer into an electrical signal and a demodulator for demodulating the electric signal into a CDM baseband signal. Transceiver interface device. The method of claim 1, The GPS reference signal from the base station is The second path is divided by the distributor 101 provided in the main relay device so that the first path is used as a reference signal of the PLL Synthesizer 102 provided in the main relay device 100 of the transmission / reception interface device. The second path is converted into an optical transmission signal by the optical converter 104 and passed through a signal division multiplexer 106 to a signal division multiplexer 205 at a remote location via an optical line. The signal is converted into an electrical signal by the electrical signal converter 203, and then restored to a high frequency signal and distributed to the divider 201 so that the first path is a synthesizer 202 provided in the secondary relay 200 of the transmission / reception interface device. ) As a reference signal, The second path is transmitted to the synthesizer (11) of the sub-relay device (10) of the base station system using the same reference signal, the transmission and reception interface device of the CD base station using the optical line. The method of claim 1, In a system using a relay device at a remote location of a CDA mobile communication base station, Monitoring / remote controllers 105 and 206 between the primary relay device 1 of the base station, the primary relay device 100 of the transmission / reception interface device, the secondary relay device 200 of the transmission / reception interface device, and the secondary relay device 10 of the base station system, respectively. Transmitting and receiving interface device of the CD base station using an optical line, characterized in that configured to enable the remote monitoring and control of all relay devices in the base station controller using.