KR20060016016A - Network configuration of base station and optic repeater in a mobile internet service - Google Patents

Abstract

According to an aspect of the present invention, there is provided a network structure of a portable Internet service using a time division duplex (TDD) scheme, the network structure comprising: a remote repeater for transmitting and receiving a mobile communication terminal and Internet service information located in a cell extension area or a shadow area as a wireless RF signal; A donor repeater connected to the remote repeater and an optical cable to transmit and receive internet service information according to a user's request as an optical signal; And a dedicated base station connected to the donor repeater and a wired cable so as to request internet information according to a user's request or to be provided from an internet server, and transmit and receive a donor repeater and a wired RF signal in a time division duplex (TDD). In the case of the mobile internet using the method, it is possible to effectively connect the repeaters used to expand the service area of the mobile internet and to solve the shadow area, thereby minimizing the change of the shape of the base station, and the matching method of the repeater is simple and efficient. The network of base station itself is simpler because it is not coupled with donor repeater, and it is possible to directly connect base station and repeater by wire to remove the malfunction and noise of repeater to realize high quality web service. It provides a network structure of a repeater.

Description

NETWORK CONFIGURATION OF BASE STATION AND OPTIC REPEATER IN A MOBILE INTERNET SERVICE}             

1 is a view showing a connection method of a general CDMA base station and a repeater,

FIG. 2 is a diagram illustrating an example of a cell configuration of a base station and a repeater of FIG. 1;

3 is a diagram illustrating a coupling matching method of a base station and a repeater of FIG. 1,

4 is a view showing a connection method between a dedicated base station and a repeater according to the present invention;

5 is a diagram illustrating a network structure of a base station and a repeater according to the present invention;

6 is a diagram illustrating a matching method between a TDD repeater and a dedicated base station according to the present invention.

        Explanation of symbols on the main parts of the drawings

10: mobile communication terminal 30: remote repeater (Remote)

31: switch means 32: low noise amplifier (LNA)

33: down converter (D / C) 34: first delay

35: A / D converter 36: optical signal processing unit

37: D / A Converter 38: Second Delay

39: up-converter (U / C) 40: power amplifier (PA)

45: optical cable 50: donor repeater

51: optical signal processor 52: D / A converter

53: Up-converter (U / C) 54: Down-converter (D / C)

55: A / D converter 60: coaxial cable

70: dedicated base station 71: down-converter (D / C)

75: upconverter 90: base station

The present invention relates to a network structure of a portable internet repeater, and in particular, when a base station and a portable internet repeater are connected in a portable internet service using a time division duplex (hereinafter referred to as 'TDD') scheme, the base station shape change is minimized and economical. The present invention relates to a network structure of a base station and a repeater in a portable internet service capable of expanding a cell.

Recently, discussions on mobile Internet services in the 2.3 GHz band have been actively conducted, and the mobile Internet is creating a new communication market following CDMA and high-speed internet, as well as the convergence of 'wired and wireless integration' in the current industrial development trend. As a representative of the mold industry, it is expected.

The 2.3GHz band 'portable internet' is a service that enables broadband high-speed internet even in the mid- to low-speed movement, and compared to the conventional wireless LAN and high-speed internet service, the Internet can be used even in a mobile environment (up to 45 km / h). Compared to multimedia mobile phone service such as EVDO, EVS has been spotlighted because its transmission speed can be increased up to 10 times (3 Mbps down).

Representative technologies that provide wireless Internet pilot service based on TDD technology include Japan's PHS technology, ArrayComm's i-busrt technology and IP Wireless's technology.

As PHS in Japan has recently shifted from voice-centric to data-oriented services, PHS demand has been revitalized, but so far, it is based on the technology of ArrayComm's i-Burst and IP Wireless, which aims only at the data services market. Looking at the trend of wireless Internet services, most of the big telecommunications manufacturers have not been active in the development of TDD technology, except for Siemens, which announced the TDD prototype.

The lukewarm attitude of large manufacturers to the development of TDD technology is due to the fact that the current mobile market is formed around the frequency division duplex (FDD) of IMT-2000. Currently, companies such as ArrayComm, IP Wireless, Inter Digital, Navini and Broadstorm are participating in the development of TDD technology, and some companies provide commercial products.

TDD (Time Division Duplex) technology supports bidirectional transmission using the same frequency band, unlike the FDD scheme that uses different frequency bands for uplink and downlink for bidirectional communication. Theoretically, the same data rate support is possible using fewer timeslots than FDD, and the technical nature of the time slot's dynamic allocation makes it suitable for transmission of asymmetric or bursty applications. It is expected to be a very attractive technology for telecom operators who want to provide wireless Internet service.

In the case of the portable Internet, a portable Internet base station and a repeater are required, such as a CDMA mobile communication service. An interest of the present invention is how to use a repeater by connecting a repeater to a base station.

There are many ways to match the repeater with the base station so that it is limited to matching with the digital optical repeater associated with the present invention.

In general, a method of matching a digital optical repeater and a base station is, as shown in FIGS. 1 and 2, a CDMA base station 1 installed in a cell, which is a service area, and is installed adjacent to the base station 1 and coupled with the base station 1. A donor repeater (3) is connected to the ring and transmits and receives an RF signal, and at least one remote repeater (5) connected to the donor repeater (3) by an optical cable to provide an Internet service to a mobile communication terminal in the cell.

When the donor repeater 3 and the base station 1 are matched, a coupling method is used, that is, when the donor repeater 3 and the base station 1 are matched as shown in FIG. A predetermined coupler 1-1 is provided at the antenna port of the base station 1, and the base station 1 and the donor repeater 3 are matched through the coupler 1-1.

In contrast to the case where the FDD type CDMA donor repeater 3 matches the base station 1 with a coupling method, in the case of the TDD method, the transmission time of the optical repeaters 3 and 5 must be linked with the base station. ), A technical problem arises in that the signal from the base station 1 and the preceding signal must be connected to the repeater 3.

Therefore, it can be easily predicted that various complicated problems, such as a delay module, must be inserted into the base station 1 to solve this problem.

In addition, when the base station 1 and the donor repeater 3 are connected using the coupler 1-1, the transmission signal TX and the reception channel ( Isolation of RX) becomes very important, and if the isolation is not solved properly, donor repeater malfunctions or generates a lot of noise, making it difficult to provide high quality web services.

Accordingly, an object of the present invention is to provide a network structure of a base station and a repeater in a portable internet service for more efficiently connecting a base station and a repeater in the case of a portable Internet using a time division duplex (TDD) scheme.

An object of the present invention is to connect the repeaters used to extend the service area of the mobile Internet and to eliminate the shadow area in the case of a portable Internet using the TDD (Time Division Duplex) method to minimize the shape change of the base station and match the repeater The method also provides a network structure of a base station and a repeater in a portable Internet service that can be simply and efficiently performed.

The object of the present invention is to simplify the network of the base station itself by not coupling the base station and the donor repeater, and to carry out the high quality web service by removing the malfunction and noise of the repeater by directly connecting the base station and the repeater by wire. It is to provide a network structure of a base station and a repeater in an Internet service.

An object of the present invention is to connect to the optical repeater using a portable Internet dedicated base station, the signal delay setting of the optical repeater is free, so that all the remote repeater and dedicated base station can transmit and receive at the same time to increase the efficiency of synchronization and signal processing The present invention provides a network structure of a base station and a repeater in a portable Internet service.

Technical means of the present invention for achieving the above object is, in the network structure of a mobile Internet service using a time division duplex (TDD) scheme: wireless communication between the mobile communication terminal 10 located in the cell extension area or the shadow area and the Internet service information; A remote repeater 30 transmitting and receiving an RF signal; A donor repeater 50 connected to the remote repeater 30 and an optical cable 45 to transmit / receive Internet service information according to a user's request as an optical signal; And a dedicated base station 70 connected to the donor repeater 50 via a wired cable so as to request internet information from the internet server or to be provided from the internet server according to a user's request, and to transmit and receive the donor repeater 50 through a wired RF signal. Characterized in that provided.

In detail, the dedicated base station 70 includes: a down converter 71 which receives the RF signal transmitted from the donor repeater 50 and converts it into an IF signal; And an up-converter 75 which receives the Internet information provided from the Internet server and converts it into an RF signal, wherein the donor repeater 50 receives an optical signal from an optical cable 45 connected to the remote repeater 30. An optical signal processor 51 for receiving and converting the signal into an electrical signal; A D / A converter 52 for converting a digital signal output from the optical signal processor 51 into an analog signal; An up-converter 53 for converting an analog signal output from the D / A converter 52 into an amplification and RF signal and transmitting the converted signal to a dedicated base station 70; A down converter (54) for receiving an RF signal output from the dedicated base station (70) through a coaxial cable (60) and converting it into an IF signal; And an A / D converter 55 for converting an analog signal output from the down converter into a digital signal and outputting the digital signal to the optical signal processing unit 51. The remote repeater 30 is configured to a predetermined control signal. Switch means 31 for receiving the Internet information requested by the mobile communication terminal 10 through the antenna or transmitting to the mobile communication terminal 10 through the antenna; A low noise amplifier 32 which removes and amplifies the noise of the RF signal input through the receiving channel of the switch means 31; A down converter 33 for converting an RF signal output through the low noise amplifier 32 into an IF signal; A delay unit 34 for delaying the IF signal output through the down converter for a predetermined time; An A / D converter 35 for converting an IF signal output through the delay unit 34 into a digital signal; An optical signal processor 36 for receiving an IF signal output through the A / D converter 35, converting and amplifying the optical signal into an optical signal, and transmitting the amplified signal to a donor repeater 50; A D / A converter 37 for converting the optical signal of the donor repeater 50 received through the optical signal processor 36 into an analog signal; A delay unit 38 for delaying the IF signal output through the D / A converter 37 for a predetermined time; An up-converter 39 for converting an IF signal output through the delay unit 38 into an RF signal; And a power amplifier 40 for amplifying the power of the RF signal output from the upconverter and outputting the power to the transmission channel of the switch means 31.

In addition, the remote repeater 30, a plurality of remote repeaters 30 can be connected in series, a plurality of remote repeaters 30, a delay built in each remote repeater 30 to send information at the same time The delay time of 34 is characterized by being set differently.

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

4 is a diagram illustrating a connection method between a dedicated base station and a repeater of a portable Internet using a time division duplex (TDD) scheme according to the present invention, and FIG. 5 illustrates a network structure of a base station and a repeater according to the present invention. 30), the donor repeater 50, the dedicated base station 70 and the base station 90.

The remote repeater 30 is configured to transmit and receive the mobile communication terminal 10 located in the cell extension area or the shadow area and the Internet service information as a wireless RF signal, the donor repeater 50 is a remote repeater 30 and an optical cable ( 45) is configured to transmit and receive the Internet service information according to the user's request with an optical signal, the dedicated base station 70 is connected to the donor repeater 50 and the coaxial cable 60 is connected to the Internet information according to the user's request Is requested to the Internet server or provided from the Internet server is configured to transmit and receive with the donor repeater 50 in a wired RF signal.

The base station 90 is configured to provide a portable Internet service to a predetermined mobile communication terminal in a corresponding cell independently of the dedicated base station 70.

In general, in order to expand the cell managed by the mobile Internet base station 90 or service the shadow area, the repeater 3 is used as shown in FIG. 3, but the mobile Internet network using the time division duplex (TDD) method of the present invention. In the dedicated base station 70 to connect the repeater 50 and the cable 60 directly to expand the cell or to eliminate the shaded area.

That is, the donor repeater 50 and the remote repeater 30 should be used to expand the cell managed by the mobile internet base station 90 or service the shadow area during the mobile internet service, and the donor repeater 50 is being serviced. 5 does not match with the base station 90, using a predetermined dedicated base station 70 as shown in FIG. 5 to form a network with the optical repeater (50, 30) is supported cascade (Cascade) to change the shape of the base station 90 By minimizing the cost and minimizing the cost of light leasing, cells can be economically expanded and the shadow area can be eliminated.

The optical repeater (50, 30) is divided into a donor repeater 50 and a remote repeater 30, the method of connecting the remote repeater 30, the donor repeater 50 and the dedicated base station 70 is shown in FIG. same. At this time, the matching between the donor repeater 50 and the dedicated base station 70 is a 2.3 GHz RF signal. Compared with Fig. 3, this RF signal corresponds to the front end of the power amplifier 1-2 and the rear end of the low noise amplifier 1-3.

In addition, a plurality of remote repeaters 30-1 and 30-3 may be connected to the donor repeater 50 in parallel, and another remote repeater 30-2 is connected to each of the remote repeaters 30-1 and 30-3. , ...) (30-4, ...) can be connected in series.

6 is a diagram illustrating a matching method between a TDD repeater and a dedicated base station according to the present invention, wherein the dedicated base station 70 receives a RF signal transmitted from a donor repeater 50 and converts it into an IF signal. It consists of a converter 71 and an up-converter 75 which receives Internet information provided from a predetermined Internet server and converts it into an RF signal.

In addition, the donor repeater 50 receives an optical signal from the optical cable 45 connected to the remote repeater 30 and converts and converts the optical signal into an electrical signal and outputs the optical signal from the optical signal processor 51. A D / A converter 52 for converting a digital signal into an analog signal, and an up-converter for converting an analog signal output from the D / A converter 52 into an amplification and an RF signal and transmitting it to a dedicated base station 70 ( 53), a down converter 54 which receives the RF signal output from the dedicated base station 70 through the coaxial cable 60 and converts it into an IF signal, and an analog signal output from the down converter 54. The A / D converter 55 converts the signal to the optical signal processor 51 and outputs the converted signal.

And, the remote repeater 30 is switched in accordance with a predetermined control signal to form a transmission and reception channel switch means for receiving the Internet information requested by the mobile communication terminal 10 through the antenna or transmits to the mobile communication terminal 10 ( 31), a low noise amplifier 32 for removing and amplifying the noise of the RF signal input through the receiving channel of the switch means 31, and converts the RF signal output through the low noise amplifier 32 into an IF signal Down converter 33, a delay unit 34 for delaying the IF signal output through the down converter 33 for a predetermined time, and an IF signal output through the delay unit 34 for converting the digital signal into a digital signal. An optical signal processor 36 for receiving an IF signal output through the A / D converter 35 and the A / D converter 35, converting and amplifying an optical signal to a donor repeater 50, and the optical signal; The optical signal of the donor repeater 50 received through the signal processor 36 A D / A converter 37 for converting to a log signal, a delayer 38 for delaying the IF signal outputted through the D / A converter 37 for a predetermined time, and an output from the delayer 38. An up-converter 39 for converting an IF signal into an RF signal, and a power amplifier 40 for amplifying the power of the RF signal output from the up-converter 39 and outputting the signal to the transmission channel of the switch means 31. .

The donor repeater 50 configured as described above converts the RF signal input from the dedicated base station 70 through the cable 60 to the down-converter 54 into an IF signal, and then digitally through the A / D converter 55. After the signal is converted into a digital optical signal through the optical signal processing unit 51 is transmitted to the remote repeater 30 through the optical cable 45.

The remote repeater 30 receives the digital optical signal transmitted from the donor repeater 50 through the optical signal processing unit 36 and converts the digital optical signal into an analog signal through the D / A converter 37, and the predetermined delay unit 38 After a predetermined time delay through the up converter 39 converts into an RF signal and transmits it to a mobile communication terminal 10 such as a notebook, a handheld, a PDA, a mobile phone, etc. located in a shaded area or a service extension area.

And, the remote repeater 30 can be connected in series with a plurality of other remote repeater 30 as shown in Figure 5, wherein all the remote repeater 30 is a delay setting function which is a unique function of each remote repeater 30 All remote repeaters 30 send and receive information at the same time. That is, the plurality of remote repeaters 30 may be connected in series through the optical signal processing unit 36, and the plurality of remote repeaters 30 simultaneously transmit information to the donor repeater 50 or the mobile communication terminal 10 in the cell. The delay times of the delays 34 and 38 built in each of the remote repeaters 30 are set differently in order to transmit the.

The operation of the network configured as described above is briefly described as follows.

The plurality of remote repeaters 30 respectively receive Internet service request information through a antenna from a mobile communication terminal 10 such as a notebook, handheld, PDA, mobile phone, etc. located in a corresponding shadow area or service extension area.

Each remote repeater 30 amplifies the received RF signal low noise through the low noise amplifier 32 and converts it back to the IF signal through the down-converter 33 according to a predetermined delay time through the delay 34 After the delay, the signal is converted into a digital signal through the A / D converter 35. The digital signal is converted into a digital optical signal through the optical signal processor 36 and simultaneously transmitted to the donor repeater 50 together with the optical signal of another remote repeater 30.

The donor repeater 50 receives the optical signal transmitted from each remote repeater 30 through the optical cable 45, converts the analog signal through the D / A converter 52, and then converts the RF signal through the up-converter 53. The signal is converted into a signal and then transmitted to the dedicated base station 70.

The dedicated base station 70 converts the RF signal transmitted from the donor repeater 50 into an IF signal through the down-converter 71 and accesses the corresponding Internet server through a predetermined exchange according to the requested internet address. After receiving the request information from the Internet server and converts the RF signal through the up-converter 75 and delivers to the donor repeater 50 through the cable 60 again.

The donor repeater 50 converts the RF signal transmitted from the dedicated base station 70 into an IF signal through the down converter 54, and then converts it into a digital signal through the A / D converter 55, and converts the digital signal again. The optical signal processor 51 converts the optical signal to the remote repeater 30.

The remote repeater 30 converts the optical signal transmitted from the donor repeater 50 into an electrical signal through the optical signal processor 36 and then converts the optical signal into an analog signal through the D / A converter 37.

The analog signal is delayed for a predetermined time by the delay unit 38 and then output to the up-converter 39. The analog signal is converted back to the RF signal through the up-converter 39, and then the power amplifier 40 and the switch means 31 It transmits to the mobile communication terminal 10 at the same time as another remote repeater 30 through.

Although specific embodiments of the present invention have been described and illustrated in the foregoing, various modifications may be made by those skilled in the art, such as changing the type of cable connecting the dedicated base station, the donor repeater and the remote repeater, or the connection method of the remote repeaters, respectively. It is obvious that there is a possibility. Such modified embodiments should not be understood individually from the technical spirit or the prospect of the present invention, but should fall within the claims appended to the present invention.

Therefore, in the present invention, in the case of a portable Internet using a TDD (Time Division Duplex) method, it is possible to effectively connect the repeaters used to expand the service area of the portable Internet and to eliminate the shadow area, thereby minimizing the shape change of the base station and matching the repeaters. The method is simple and efficient, and the network of the base station itself is simpler by not coupling the base station and the donor repeater, and by connecting the base station and the repeater directly by wire, the malfunction and noise of the repeater are eliminated and the high-quality web You can implement a service.

In addition, when the dedicated base station is used, the signal delay setting of the optical repeater is free, so that all the remote repeaters and the dedicated base station can transmit and receive at the same time, and there are various advantages such as synchronization and signal processing efficiency and design.

Claims (5)

In the network structure of portable Internet service using time division duplex (TDD) method: A remote repeater for transmitting and receiving mobile communication terminal and Internet service information located in a cell extension area or a shadow area as a wireless RF signal; A donor repeater connected to the remote repeater and an optical cable to transmit and receive internet service information according to a user's request as an optical signal; And The base station and the repeater in the mobile Internet service provided with; a dedicated base station connected to the donor repeater and wired cable requesting Internet information according to a user's request to the Internet server or provided from an internet server, and transmitting and receiving in a wired RF signal with the donor repeater. Network structure. The method of claim 1, wherein the dedicated base station, A down converter receiving the RF signal transmitted from the donor repeater and converting the signal into an IF signal; And an up-converter for receiving the Internet information provided from the Internet server and converting the converted Internet signal into an RF signal. The method according to claim 1, wherein the donor repeater, An optical signal processor for receiving an optical signal from an optical cable connected to the remote repeater and converting the optical signal into an electrical signal; A D / A converter for converting the digital signal output from the optical signal processor into an analog signal; An up-converter for converting the analog signal output from the D / A converter into an amplification and RF signal and transmitting it to a dedicated base station; A down converter receiving an RF signal output from the dedicated base station through a coaxial cable and converting the signal into an IF signal; And an A / D converter for converting an analog signal output from the down converter into a digital signal and outputting the digital signal to an optical signal processing unit. The method according to claim 1, wherein the remote repeater, Switch means for switching according to a predetermined control signal to form a transmission and reception channel to receive the Internet information requested by the mobile communication terminal through the antenna or to transmit to the mobile communication terminal; A low noise amplifier for removing and amplifying noise of the RF signal input through the receiving channel of the switch means; A down converter converting the RF signal output through the low noise amplifier into an IF signal; A first delayer configured to delay an IF signal output through the down converter for a predetermined time; An A / D converter for converting an IF signal output through the first delay unit into a digital signal; An optical signal processor for receiving an IF signal output through the A / D converter, converting and amplifying the optical signal to a donor repeater; A D / A converter for converting an optical signal of a donor repeater received through the optical signal processor into an analog signal; A second delayer for delaying the IF signal output through the D / A converter for a predetermined time; An up-converter for converting an IF signal output through the second delay unit into an RF signal; And a power amplifier for amplifying the power of the RF signal output from the upconverter and outputting the amplified power to the transmission channel of the switch means. The method according to claim 1, wherein the remote repeater, A plurality of remote repeaters can be connected in series, but the delay time of the delays built into each remote repeater is set differently so that a plurality of remote repeaters can transmit information at the same time. Network structure.

Images