KR100537081B1 - Method and apparatus for wireless traffic load measurement in Multi-Operator Integrated Base Station System - Google Patents

Abstract

The present invention relates to an apparatus and method for measuring a wireless traffic load of an integrated base station system. The present invention relates to a wireless communication base station system in which two or more carriers of an IMT-2000 WCDMA mobile communication system operate in common, and have a digital signal processing function. The control device is operated separately for each carrier, and the RF / IF device with high frequency (RF) signal processing and intermediate frequency (IF) signal processing is integrated and operated for each carrier. In the integrated base station system controlled by the RNC), the carrier control unit measures the RF reception power of each carrier as an uplink wireless traffic load required for the RNC to effectively allocate a channel by using a radio resource for each carrier. It is supposed to be delivered to the base station (RNC) or network management unit (NMS),

Accordingly, it is possible to measure the RF reception power of each carrier in the integrated base station system using a simple circuit, and the carrier control station (RNC) of each carrier measures the radio traffic load of each carrier to control the rock lock and the radio channel assignment. It is possible to efficiently operate an integrated base station system by using the Rx.

Description

Apparatus and method for measuring wireless traffic load in integrated base station system {Method and apparatus for wireless traffic load measurement in Multi-Operator Integrated Base Station System}

The present invention relates to an IMT-2000 WCDMA mobile communication system, and more particularly, to an apparatus and method for measuring a wireless traffic load in an integrated base station system.

In general, a cellular mobile communication system is composed of a terminal for transmitting and receiving user information, a base station system for relaying these signals through appropriate processing, a base control station for controlling a plurality of base station systems, and a mobile switching station for configuring a core network. The base station system directly determines the wireless coverage representing the service area.

However, in the past, many operators (carriers) operate cellular cellular communication systems and invest base station systems in the same service area in a redundant manner, which not only wastes a lot of resources at the national level but also environmental problems. In addition, the overlapping investment of such base station equipment may be more severe in areas where the volume of call changes greatly (eg, subway stations, office dense areas, etc.) depending on the time of day.

Therefore, in order to solve such a problem, it is possible to use resources more effectively by integrating and operating a base station system operating for each carrier.

However, in the case of simply integrating and operating an existing base station system, when there is a call request, the uplink, that is, the terminal, required for the rock lock control by the Radio Network Controller (RNC) of the carrier controlling the base station system is required. There is a problem that the RF reception power, which is a measure of the radio traffic load of the radio communication path toward the base station, cannot be measured for each carrier.

In particular, in the conventional rock lock control method of the 2G mobile communication system, when there is a call request, it is possible to simply check whether there is an extra code or a free channel element that is divided into a general call and a handover. Fixed Channel Allocation Strategy (FCA), which allocates channels when there is one, not only does not dynamically adjust radio channel and interference characteristics and dynamically adapts to changing mobile communication environment. It has the disadvantage of not being effective.

Accordingly, an object of the present invention is to overcome the above-described problems, and an object of the present invention is to integrate and operate a mobile communication base station system operated by two or more carriers of an IMT-2000 WCDMA mobile communication system into one base station. In order to solve these problems, a wireless control apparatus having a common signal among mobile communication base station systems operated by carriers and having a digital signal processing function is separated and operated by each carrier, and has a high frequency (RF) signal processing function and an intermediate frequency (IF) signal processing function. The RF / IF device is to be integrated and operated for each carrier, and the base station (RNC) effectively utilizes radio resources when calling for each carrier in an integrated base station system controlled by the base station of each carrier. As the uplink radio traffic load required for channel allocation, The present invention provides an apparatus and method for measuring a wireless traffic load of an integrated base station system, which can be used to effectively manage a base station system by transferring carriers to a base station (RNC) or a network management unit (NMS).

The wireless traffic load measuring apparatus of the integrated base station system for achieving the object of the present invention, the wireless control device having a digital signal processing function is difficult to share among the mobile communication base station system operated by the carrier, and separately operated for each carrier, An RF / IF device having a high frequency (RF) signal processing function and an intermediate frequency (IF) signal processing function is integrated and operated for each carrier, and is inputted from the base station of each carrier through the radio controller. Combine the transmit power of each of the I-channel and Q-channel into a power combiner, and then transmit to the terminal through a duplexer and antenna that separates the transmitted / received signals by I / Q modulation, automatic gain control, filtering, and amplification, and the antenna and duplexer After amplifying, filtering, I / Q demodulation, and amplifying the radio signal transmitted from the terminal received through the An integrated base station system configured to distribute power of an I-channel and a Q-channel to be delivered to the radio controller, the integrated base station system comprising: a plurality of reception power measurement units measuring RF reception power of each carrier at a rear end of the power divider; And comparing the measured RF reception power value of each carrier with a reference threshold value to determine whether an uplink radio traffic is overloaded, and the result of the overload determination and the RF reception power value are known through the wireless control device using a data communication link. It is composed of a microprocessor to deliver to the control station (RNC) or directly to the network management unit (NMS) using a separate CDMA RF modem to determine the result of the overload.

A wireless traffic load measuring method of an integrated base station system for achieving the object of the present invention comprises the steps of: reading the RF received power value measured for each carrier by a microprocessor installed in the RF / IF device of the integrated base station system; The RF received power value read by the microprocessor for each carrier is compared with a reference threshold of the uplink radio traffic load required for a base station (RNC) to allocate a channel, and the RF received power value for each carrier is larger than this reference threshold. Determining that the radio traffic of the current uplink is overloaded if it is determined to be large; If the wireless traffic of the uplink is currently overloaded, the microprocessor transmits the overload determination result to the base station through the radio controller through the data communication link, or the overload determination result using a separate CDMA RF modem. Direct delivery to the network management unit (NMS); And if the current uplink radio traffic is not overloaded, the microprocessor transmits an RF received power value to a base station (RNC) via the radio controller using a data communication link.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an embodiment illustrating an IMT-2000 (WCDMA) mobile communication system to which an integrated base station system according to the present invention is applied.

Referring to FIG. 1, an IMT-2000 (WCDMA) mobile communication system services wireless communication between a terminal, an IP phone, a general telephone, a call center, and the like, and operates a switching center (CN) and a base station (RNC) for each carrier. 110, 120, an integrated base station system (100, 100a) controlled by the base station (RNC) 110, 120, SGSN (Serving GPRS Support Node) as a packet network switching equipment, the Internet to relay the communication between the terminal and the IP phone through the SGSN And a PSTN mobile net for relaying communication between the terminal and the general telephone or call center.

The integrated base station system (100, 100a) determines the radio service area for each carrier, the base station (RNC) 110, 120 is operated for each carrier, and the mobile communication wireless network while exchanging information with a plurality of integrated base station system (100) The control center (CN) serves to exchange information with the exchange station (CN) located in another area.

In particular, the integrated base station system (100, 100a) is connected to the base station control station (RNC; 110,120) of heterogeneous manufacturers for direct management of the operation maintenance center with the base station control station (RNC; 110,120) for performing a state management function, etc. It performs radio channel control function, radio transmitter management function, radio control function, etc., which can be adapted to host system which can be adapted, and the radio channel control block is composed of radio control device and RF / IF device. It is intended to be easily performed.

2 is a block diagram showing an integrated base station system (100, 100a) according to the present invention.

2, the integrated base station system (100, 100a) is a RF / IF apparatus 200 for processing and transmitting a radio signal to a high frequency and an intermediate frequency in order to communicate with the terminal, and a radio signal for receiving or transmitting from the terminal It communicates with the carrier-specific radio controllers 211 and 212 and the carrier-based base station (RNC) 110, 120 to relay various transmission / reception signals between the radio controllers 211, 212 and the base station (RNC) 110, 120. It consists of a radio controller 210 composed of carrier-specific connections 213 and 214.

3 is a block diagram illustrating an apparatus for measuring a wireless traffic load included in the RF / IF device 200 of the integrated base station system 100 or 100a according to the present invention.

In FIG. 3, the transmission signals from the radio controllers 211 and 212 of the radio controller 210 serving as the baseband signal processing units of the integrated base station systems 100 and 100a for the two carriers are I-channel and Q-. After the channel is input to the transmitting side of the RF / IF device 200, the baseband signals of the two carriers are merged by I / Q modulation. This merge is sent to the I / Q modulator. The receiver performs amplification for signal preservation while the I / Q channel is separated from the transmitter, and divides the power for each carrier in the low-IF state, which is an analog signal of intermediate frequency, and measures the RF reception power of the radio signal. At the same time, the I / Q channel information is sent to the radio controllers 211 and 212 which process the baseband signals of the two carriers A and B.

Referring to FIG. 3, the RF / IF device 200 is an I-channel and a Q-channel input from the base station RNC 110 and 120 of each carrier A and B through the radio controller 210. I / Q modulator 302 which combines the respective transmit powers by the carrier-specific power combiners 301 and 301a, and combines the transmit power combined with the locally controlled VCO (Voltage Controlled Oscillator) and PLL (Phase Locked Loop) synthesizer. After modulation, the automatic gain controller 303 automatically adjusts to an appropriate gain level, and the bandpass filter 304 passes only signal components that span the bandwidth of the corresponding WCDMA mobile communication system. And then amplifies the signal level of the filtered RF transmission power through the amplifier 305 whose amplification is controlled by the automatic level adjuster 306 and transmits the signal to the terminal via a duplexer 307 and an antenna separating the transmission and reception signals. do.

The RF / IF device 200 filters the radio signals transmitted from the terminal received via the antenna and the duplexer 307 to suppress RF signal components other than the reception frequency by the RF SAW filter 309, and low noise. After amplifying to an intermediate frequency (IF) signal level by the amplifier 308 and the IF SAW band pass filter 310, only a specific intermediate frequency (IF) signal component is passed through the device design, and then the filtered RF received signal is subjected to I / Q. The demodulator 311 demodulates the I-channel and the Q-channel, amplifies them through the I-channel amplifier 312 and the Q-channel amplifier 313, and then the signal components of each of the two carriers A and B Since it is a signal component transmitted from the terminals in the service area, power is distributed between the I-channel and the Q-channel for each carrier through the power splitters 313 and 313a to be separately operated for each carrier of the radio controller 210. Transfer to the wireless control unit 212.

In this case, the RF / IF device 200 does not have a constant input power for the filtering signal passed only a specific intermediate frequency (IF) signal component by the IF SAW band filter 310, so that it is a constant input signal A function of amplifying to a level may be added, and the low noise amplifier 308 for receiving includes a mixer using a local oscillating VCO and a PLL synthesizer used in the I / Q modulator 302 of the transmitter.

The carrier-specific reception power measuring units 314 and 315 of the RF / IF device 200 are connected to the rear ends of the carrier-specific power dividers 313 and 313a to measure the RF reception power for each carrier.

The microprocessor 316 of the RF / IF device 200 controls the operation of the automatic gain controller 303, and at the same time, based on the carrier-specific RF reception power values measured by the reception power measurement units 314 and 315. It is determined whether the uplink radio traffic is overloaded by comparing with a threshold value, and the overload determination result and the RF reception power value are each carrier-based known control station (RNC) 110,120 via the radio controller 210 using the data communication link. ) Or directly to the network management unit (NMS) using a separate CDMA RF modem 317.

For reference, FIG. 3 illustrates the RF / IF device 200 of the integrated base station system (100, 100a) assuming two carriers (A, B) for convenience of description of the embodiment according to the present invention. RF / IF device 200 of the integrated base station system (100, 100a) according to the invention includes a range that can be changed to measure the RF reception power in a similar concept without special modification even when including two or more carriers.

The apparatus for measuring the wireless traffic load of the integrated base station system 100 or 100a according to the present invention configured as described above operates as follows.

4 is a flowchart illustrating a method for measuring a wireless traffic load of an integrated base station system according to the present invention.

Referring to FIG. 4, first, the microprocessor 316 installed in the RF / IF device 200 of the integrated base station system 100 or 100a is an RF reception power for each carrier measured by the reception power measurement units 314 and 315. Read the value (S10).

Subsequently, the microprocessor 316 compares the RF received power value read for each carrier with the reference threshold of the uplink radio traffic load required for the RNC 110 and 120 to allocate the channel. If it is determined that the value is larger than this reference threshold, it is determined that the wireless traffic of the current uplink is overloaded (S12).

At this time, if the wireless traffic of the current uplink is determined to be overloaded, the microprocessor 316 uses the data communication link directly connected to the backboard lines of the integrated base station systems 100 and 100a to determine the result of the overload. The control unit 210 transmits the information to the base station RNC 110 and 120 or the overload determination result directly to the network management unit NMS using a separate CDMA RF modem 317 (S14).

On the other hand, if it is determined that the current uplink radio traffic is not overloaded, the microprocessor 316 transmits an RF received power value to the base station via the radio controller 210 using the data communication link. RNC; and forwards to 110, 120 (S16).

On the other hand, the microprocessor 316 included in the RF / IF device 200 of the integrated base station system (100, 100a) as described above, the wireless control device 210 by using the data communication link to determine the overload determination result and the RF reception power value When a request is generated for each carrier to a carrier control station (RNC: 110, 120) by the carrier, the base control station (RNC: 110, 120) is a microprocessor (316). Using the overload determination result received from the RF reception power value and the RF lock power control is performed by the method as shown in FIG.

Referring to FIG. 5, the base station (RNC) 110, 120 performs an initialization operation for executing rock lock control and wireless channel allocation (S20), and then monitors the radio coverage and capacity of the integrated base station system 100,100a. After setting the traffic load threshold (P _threshold ) to allow in the WCDMA mobile communication system (S22), if a call request occurs for each carrier (S24), the most recent RF received from the microprocessor 316 is received. The power value P is read (S26).

Subsequently, the base station (RNC) 110,120 compares the most recent RF received power value P with a traffic load threshold P _threshold (S28) so that the RF received power value P is a traffic load threshold. If the value is smaller than the P _threshold , the call request is accepted and a new channel is allocated (S29). If the RF received power value P is greater than or equal to the traffic load threshold (P _threshold ), the call request is rejected (S29a).

As described above, the apparatus and method for measuring a wireless traffic load of an integrated base station system according to the present invention may first measure RF reception power for each carrier while operating base station systems of different carriers as one integrated base station system. The base station (RNC) of each carrier that controls the integrated base station system can effectively allocate the channel to each carrier when the carrier requests each channel, and secondly, it can be integrated using a relatively simple circuit without the addition of complicated devices. In the base station system, the RF reception power of each carrier can be measured, and thirdly, the integrated base station system can be efficiently operated by measuring the wireless traffic load for each carrier and using the lock control and the radio channel allocation.

What has been described above is just one embodiment for implementing the apparatus and method for measuring the wireless traffic load of the integrated base station system according to the present invention, the present invention is not limited to the above-described embodiment, the scope of the claims Without departing from the gist of the present invention, any person of ordinary skill in the art will have the technical spirit of the present invention to the extent that various modifications can be made.

1 is an embodiment illustrating an IMT-2000 (WCDMA) mobile communication system to which an integrated base station system according to the present invention is applied;

2 is a block diagram illustrating an integrated base station system according to the present invention;

3 is a block diagram showing an apparatus for measuring a wireless traffic load of an integrated base station system according to the present invention;

4 is a flowchart illustrating a method for measuring a wireless traffic load of an integrated base station system according to the present invention;

5 is a flowchart illustrating a channel allocation method of a base station using a wireless traffic load measured by a wireless traffic load measuring apparatus of an integrated base station system according to the present invention.

<Description of the symbols for the main parts of the drawings>

100,100a: integrated base station system 110,120: base station (RNC)

200: RF / IF device 210: wireless control device

211, 212: wireless control unit 213, 214: connection unit

301,301a: power combiner 302: I / Q modulator

303: automatic gain controller 304: bandpass filter

305: amplifier 306: automatic level adjuster

307: duplexer 308: low noise amplifier

309: RF SAW filter 310: IF SAW band filter

311: I / Q demodulator 312,312a: amplifier

313,313a: Power divider 314,315: Received power measuring unit

316: microprocessor 317: CDMA RF modem

Claims (4)

Among the mobile communication base station systems operated by carriers, the wireless control device that is difficult to share and has a digital signal processing function is separated and operated by each carrier, and has an RF signal processing function and an RF signal processing function. / IF device is integrated operation for each carrier, combining the transmission power of each of the I-channel and Q-channel input from the base station (RNC) of each carrier through the radio control device to the power combiner, and then I / Q Modulation, automatic gain control, filtering, and amplification are transmitted to the terminal through a duplexer and an antenna that separates transmission and reception signals, and amplification, filtering, I / Q demodulation, And after amplifying and distributing the power of the I-channel and the Q-channel for each carrier through the power divider to transmit the power to the radio controller. In A plurality of reception power measurement units measuring RF reception power for each carrier at a rear end of the power divider; And When the measured RF reception power value of each carrier is compared with a reference threshold, if it is determined that the RF reception power value of each carrier is larger than the reference threshold value, the wireless traffic of the current uplink is determined to be overloaded, and the overload determination result and the RF reception power are determined. The microprocessor is configured to transfer a value to a base station (RNC) via the radio control device using a data communication link or directly to a network management unit (NMS) using a separate CDMA RF modem. Wireless traffic load measurement apparatus of the integrated base station system further comprises. delete The method of claim 1, wherein the microprocessor is The overload determination result and the RF reception power value are transmitted to the base station via the radio control device using the data communication link, thereby allowing the base station to consider the radio coverage and capacity of the integrated base station system. After setting the traffic load threshold to be allowed in the WCDMA mobile communication system, if a request is generated for each carrier, the RF receive power is compared with the traffic load threshold after reading the most recent RF received power received from the microprocessor. If the RF received power is less than the traffic load threshold, the mobile station accepts the call request and allocates a new channel, and rejects the call request if the RF received power is more than the traffic load threshold. Measuring device. Reading the RF reception power value measured for each carrier through the power divider by a microprocessor installed in the RF / IF device of the integrated base station system; The RF received power value read by the microprocessor for each carrier is compared with a reference threshold of the uplink radio traffic load required for a base station (RNC) to allocate a channel, and the RF received power value for each carrier is larger than this reference threshold. Determining that the radio traffic of the current uplink is overloaded if it is determined to be large; If the wireless traffic of the uplink is currently overloaded, the microprocessor transmits the overload determination result to the base station through the radio controller through the data communication link, or the overload determination result using a separate CDMA RF modem. Direct delivery to the network management unit (NMS); And If the wireless traffic of the current uplink is not overloaded, the microprocessor transmits an RF received power value to a base station (RNC) via the radio controller through a data communication link; Wireless traffic load measurement method of an integrated base station system, characterized in that consisting of.