KR100325637B1 - Service method of different types of wireless communication systems and apparatus thereof - Google Patents

Abstract

The present invention relates to a service method and apparatus for a heterogeneous mobile communication system, the configuration comprising: a) generating heterogeneous forward communication signals, respectively; b) allocating the heterogeneous forward communication signals with a time difference; c) synthesizing and amplifying the allocated signals with time difference in the forward communication channel by step b); d) the forward communication signals amplified in step c) are transmitted at different time intervals through heterogeneous heterogeneous IS-95A base stations and IS-95C base stations when installed and serviced at the same location. Space and time diversity can be configured by distributing the signal and sending the signal to the transmitter of the IS-95C base station through the delay means and sending the signal of the IS-95C base station to the IS-95A base station through the delay means.

Description

SERVICE METHOD OF DIFFERENT TYPES OF WIRELESS COMMUNICATION SYSTEMS AND APPARATUS THEREOF}

The present invention relates to a mobile communication system, and more particularly, to implement a diversity in simultaneously communicating heterogeneous mobile communication systems having different data rates and frequencies, thereby improving performance according to reception and transmission. A service method and apparatus therefor.

TIA Subcommittee TR-45.5 proposed TIA / EIA / IS-2000 (IS-95C), which is an improvement on TIA / EIA-95B. Telecommunications service companies will upgrade their current service system, IS-95A, competitively with the enactment of TIA / EIA / IS-2000.

Therefore, there are various ways to reduce the installation cost of the IS-95C system by using the mobile communication system that has been established to the maximum, and it can be implemented in various ways as shown in the previously applied patent No. 99-33390.

However, the communication service system between IS-95A and IS-95A / C, which is a pre-applied heterogeneous base station, usually tries to improve the reception performance by spatial diversity with multiple reception antennas, but it is caused by time difference due to different propagation paths. There is no proper preparation for the degradation of transmission and reception performance.

Therefore, the present invention transmits the signal of the IS-95A base station to the transmitting end of the IS-95C base station through distribution and delay means when the heterogeneous IS-95A base station and the IS-95C base station are installed and serviced at the same location. It is an object of the present invention to provide a service method and apparatus for a heterogeneous mobile communication system capable of configuring spatial and time diversity by sending a signal to a base station through a delay means.

Another object of the present invention is to provide a service method and apparatus for a heterogeneous mobile communication system which can improve reception performance due to time diversity along with spatial diversity by adding delay means to one of two receiving ends. There is this.

A forward transmission method of a heterogeneous mobile communication system according to the present invention for achieving the above object comprises the steps of: a) generating heterogeneous forward communication signals, respectively; b) allocating the heterogeneous forward communication signals with a time difference; c) synthesizing and amplifying the allocated signals with time difference in the forward communication channel by step b); d) forwarding the amplified forward communication signals in step c) through heterogeneous time, characterized in that it comprises the step of transmitting.

A reverse receiving method of a heterogeneous mobile communication system according to the present invention comprises the steps of: a) receiving heterogeneous reverse communication signals with time difference and space difference; b) separating the heterogeneous reverse communication signals according to an allocated channel; c) processing each of the reverse communication signals separated in step b). The reverse communication signals may have different data rates and frequencies.

1 is a block diagram of heterogeneous base stations according to an embodiment of the present invention.

<Description of Symbols for Major Parts of Drawings>

100: IS-95A communication channel processing unit 111: IS-95A digital processing unit

113: IS-95A intermediate frequency unit 115: IS-95A frequency conversion unit

200: IS-95C communication channel processing unit 300: IS-95A transceiver

310: IS-95A transmitter 330: first IS-95A receiver

350: second IS-95A receiver 311: first IS-95A / C synthesizer

313: IS-95A high power amplifier 400: IS-95C transceiver

500: Transmission delay unit 510: IS-95A transmission delay unit

530: IS-95C transmission delay unit

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

1 is a block diagram illustrating an IS-95A and an IS-95C common base station according to an embodiment of the present invention. The IS-95A and IS-95C common base stations presented here are installed at the same location and location.

1, IS-95A and IS-95C common base station according to the present invention is IS-95A communication channel processing unit 100, IS-95C communication channel processing unit 200, IS-95A transceiver 300 IS- It comprises a 95C transceiver 400 and a transmission delay processing unit 500.

The IS-95A communication channel processing unit 100 generates an IS-95A forward communication signal and processes an IS-95A reverse communication signal from the IS-95A transceiver 300 which will be described later.

In this case, the IS-95A communication channel processing unit 100 is generally composed of a plurality of communication channel processing units to process IS-95A forward and reverse communication signals. It is.

The IS-95A communication channel processing unit 100 includes an IS-95A digital processing unit 111, an IS-95A intermediate frequency unit 113, and an IS-95A frequency conversion unit 115.

The IS-95A digital processor 111 generates a baseband IS-95A digital call signal having a call and overhead information. The overhead information has pilot channel information, paging channel information, and synchronization channel information. The IS-95A digital processor 111 converts the baseband digital call signal into an IS-95A analog signal.

The IS-95A intermediate frequency unit 113 converts the baseband IS-95A communication signal from the IS-95A digital processing unit 111 into an intermediate frequency signal.

The IS-95A frequency converter 115 converts an intermediate frequency signal from the IS-95A intermediate frequency unit 113 into an IS-95A forward communication signal having a high frequency and provides the IS-95A transceiver 300. .

Accordingly, the IS-95A communication channel processing unit 100 generates and processes the IS-95A forward communication signal and the reverse communication signal from the IS-95A frequency converter 115, respectively.

The transmission delay processing unit 500 includes an IS-95A transmission delay unit 510 and an IS-95C transmission delay unit 530.

The IS-95A transmission delay unit 510 delays the forward communication signal from the IS-95A frequency converter 115 to a second IS-95 A / C transmitter 410 to be described later. The IS-95C transmission delay unit 530 delays the forward communication signal from the IS-95C frequency converter 215 for a predetermined time and supplies it to the first IS-95A / C transmitter 310 to be described later.

Therefore, the first IS-95A / C transmitter 310 transmits the IS-95A forward communication signal from the IS-95A communication channel processor 100 and the IS-95C forward communication from the IS-95C communication channel processor 300. The signal is synthesized and amplified with a certain time difference.

The IS-95A transceiver 300 is a first IS-95A / C for synthesizing and amplifying the IS-95A forward communication signal and the IS-95C forward communication signal from the IS-95C transmission delay processing unit 530 to be described later. The transmitter 310 includes a first IS-95A receiver 330 and a second IS-95A receiver 350 for receiving and distributing the IS-95A reverse communication signals.

In this case, the first IS-95A receiver 330 and the second IS-95A receiver 350 are configured to receive a reverse communication signal by spatial diversity.

The first IS-95A / C transmitter 310 performs a first IS-95A / C synthesizer 311, an IS-95A high power amplifier 313, and an IS to synthesize and amplify the IS-95A forward communication signals. -95A transmit band filter 315.

The first IS-95A / C synthesizer 311 synthesizes a forward communication signal from the IS-95A frequency converter 115 and a forward communication signal from the IS-95C frequency converter 215 to be described later. Generates a -95A / C composite forward communication signal and provides the generated IS-95A / C composite forward communication signal to the IS-95A high power amplifier 313.

The IS-95A high power amplifier 313 linearly amplifies the IS-95A / C synthesized forward communication signal from the IS-95A / C synthesizer 311.

The IS-95A transmit band filter 315 filters the amplified IS-95A / C synthesized forward communication signal from the IS-95A high power amplifier 313 and transmits it through the IS-95A transmit antenna 316.

The first IS-95A receiver 330 receives a first reception band filter 335 and a first low noise amplifier 333 to receive IS-95A reverse communication signals from the IS-95A first receiving antenna 336. , And a first IS-95A distributor 331.

The first IS-95A receiving band filter 335 filters IS-95A reverse communication signals from the first IS-95A receiving antenna 336 and provides the first low-noise amplifier 333.

The first low noise amplifier 333 amplifies IS-95A reverse communication signals from the first receive band filter 335 and provides the IS-95A reverse communication signals to the first IS-95A distributor 331. do.

Then, the first IS-95A splitter 331 distributes and allocates the IS-95A reverse communication signals from the first receive band filter 335 to the IS-95A communication channel processor 100 according to a corresponding channel. .

The second IS-95A receiving unit 350 processes the IS-95A reverse communication signal by delaying the predetermined time to receive the IS-95A receiving delay unit 356, the second receiving band filter 355, and the second low noise amplifier ( 353, and a second IS-95A distributor 351.

The IS-95A receiving delay unit 356 receives the IS-95A reverse communication signals from the second IS-95A receiving antenna 356 after a predetermined time delay process and supplies them to the second IS-95A receiving band filter 355. do.

The second IS-95A receive band filter 355 filters the IS-95A reverse communication signals from the second IS-95A receive antenna 356 and provides the second low-noise amplifier 353.

The second low noise amplifier 353 amplifies IS-95A reverse communication signals from the second receive band filter 355 and provides the IS-95A reverse communication signals to the second IS-95A distributor 351. do.

Then, the second IS-95A splitter 351 distributes and allocates the IS-95A reverse communication signals from the second receive band filter 355 to the IS-95A communication channel processing unit 100 according to the corresponding channel. .

Accordingly, spatial diversity and time diversity are applied to the reverse IS-95A communication signal allocated to the IS-95A communication channel processing unit 100.

The IS-95C communication channel processing unit 200 generates an IS-95C forward communication signal and processes an IS-95C reverse communication signal from the IS-95C transceiver 400 which will be described later.

In this case, the IS-95C communication channel processing unit 200 is generally composed of a plurality of communication channel processing units for processing IS-95C forward and reverse communication signals, but the example shown in the present invention is configured through a single communication channel processing unit. It is shown.

The IS-95C communication channel processing unit 200 processes each of IS-95C forward and reverse communication signals input through IS-95C transmit / receive channels allocated for IS-95C service.

The IS-95C communication channel processing unit 200 includes an IS-95C digital processing unit 211, an IS-95C intermediate frequency unit 213, and an IS-95C frequency converter 215.

The IS-95C digital processor 211 generates a baseband IS-95C digital call signal having a call and overhead information. The overhead information includes pilot channel information, paging channel information, sync channel information, and the like. The IS-95C digital processor 211 converts the baseband digital call signal into an IS-95C analog signal.

The IS-95C intermediate frequency unit 213 converts the baseband IS-95C communication signal from the IS-95C digital processor 211 into an intermediate frequency signal.

The IS-95C frequency converter 215 converts the intermediate frequency signal from the IS-95C intermediate frequency unit 213 into an IS-95C forward communication signal of high frequency and provides the IS-95C transceiver 400. .

In addition, the IS-95A forward communication signal delayed by the IS-95A frequency converter 115 and the IS-95A transmission delay unit 510 for a predetermined time is provided to the IS-95C transceiver 400. That is, the IS-95A forward communication signal delayed by the IS-95A transmission delay processor 510 for a predetermined time is supplied to the first IS-95A / C transmitter 410.

On the other hand, the IS-95C forward communication signal generated from the IS-95C communication channel processing unit 200 is supplied to the second IS-95A / C transmitter 410, a predetermined time through the IS-95C transmission delay unit 530 The delay is processed and supplied to the first IS-95A / C transmitter 310. At this time, the forward communication signal is processed with a certain time difference.

The IS-95C transceiver 400 is a second IS-95C transmitter 410 for synthesizing and amplifying the IS-95C forward communication signal and the IS-95A forward communication signal; And a first IS-95C receiver 430 and a second IS-95A receiver 450 for receiving and distributing spaces.

In this case, the first IS-95C receiver 430 and the second IS-95C receiver 450 are configured to receive a reverse communication signal by spatial diversity.

In order to synthesize and amplify the IS-95C forward communication signal and the IS-95A forward communication signal, the second IS-95C transmitter 410 may include a second IS-95A / C synthesizer 411 and an IS-95C high output amplifier. 413, and an IS-95C transmission band filter 415.

The IS-95A forward communication signal is a signal delayed for a predetermined time from the IS-95C forward communication signal.

The second IS-95A / C synthesizer 411 synthesizes the IS-95C forward communication signal and the IS-95A forward communication signal to generate an IS-95 A / C synthesized forward communication signal, and generates the IS- A 95 A / C synthesized forward communication signal is provided to the IS-95C high power amplifier 413.

The IS-95C high power amplifier 413 linearly amplifies the IS-95 A / C synthesized forward communication signal from the IS-95C synthesizer 411.

The IS-95C transmit band filter 415 filters the amplified IS-95 A / C synthesized forward communication signal from the IS-95C high power amplifier 413 and transmits it through the IS-95C transmit antenna 416. .

The first IS-95C receiver 430 receives a first reception band filter 435 and a first low noise amplifier 433 to receive IS-95C reverse communication signals from the IS-95C first reception antenna 436. , And a first IS-95C distributor 431.

The first IS-95C receive band filter 435 filters IS-95C reverse communication signals from the first IS-95C receive antenna 436 and provides the first low-noise amplifier 433.

The first low noise amplifier 433 amplifies IS-95C reverse communication signals from the first receive band filter 435 and provides the IS-95C reverse communication signals to the first IS-95C distributor 431. do.

Then, the first IS-95C splitter 431 allocates the IS-95C reverse communication signals from the first receive band filter 435 to the IS-95C communication channel processor 200 according to a corresponding channel.

The second IS-95C receiving unit 450 is configured to distribute the IS-95C reverse communication signals from the IS-95C second receiving antenna 456 after a predetermined time delay process. A second reception band filter 455, a second low noise amplifier 453, and a second IS-95C divider 451.

The IS-95C receiving delay unit 456 provides the IS-95C reverse communication signals from the second IS-95C receiving antenna 457 to the second IS-95C receiving band filter 455 after a predetermined time delay processing. . The second IS-95C receive band filter 455 filters the reverse communication signals delayed for a predetermined period of time and provides the reverse communication signals to the second low noise amplifier 453.

The second low noise amplifier 453 amplifies IS-95C reverse communication signals from the second receive band filter 455 and provides the IS-95C reverse communication signals to the second IS-95C distributor 451. do.

Then, the second IS-95C splitter 451 allocates the IS-95C reverse communication signals from the second receive band filter 455 to the IS-95C communication channel processor 200 according to a corresponding channel.

Accordingly, the reverse communication signals allocated to the IS-95C communication channel processing unit 200 have different spaces and times in the first IS-95A receiving unit 430 and the second IS-95C receiving unit 450, respectively.

As described above, the present invention can achieve performance by receiving and transmitting by implementing diversity when heterogeneous mobile communication systems having different data rates and frequencies communicate at the same time.

In addition, although the present invention has been described in detail with reference to the above embodiments, the present invention is not limited thereto, and modifications and improvements thereof can be made without departing from the ordinary knowledge of those skilled in the art.

Claims (18)

a) generating heterogeneous forward communication signals, respectively; b) allocating the heterogeneous forward communication signals with a time difference; c) synthesizing and amplifying respective heterogeneous forward communication signals allocated at time difference by step b); and d) transmitting a heterogeneous forward communication signal amplified in step c). The forward signal of the heterogeneous mobile communication system according to claim 1, wherein the forward signals have different data rates and frequencies and are delayed by a predetermined time for a communication signal allocated to a different type than a signal allocated to the same type. Transmission method. a) receiving heterogeneous reverse communication signals with a time difference and a space difference; b) separating the heterogeneous reverse communication signals according to an allocated channel; c) processing the reverse communication signals separated in step b), the reverse reception method of a heterogeneous mobile communication system. 4. The method of claim 3, wherein the reverse communication signals have different data rates and frequencies and are received in the same type. a) means for generating heterogeneous forward communication signals, respectively; b) means for allocating the heterogeneous forward communications signals at different times; c) means for synthesizing and amplifying respective heterogeneous forward communication signals assigned at time difference by means of b); and d) transmitting the heterogeneous forward communication signal amplified by the c) means. The forward signal of the heterogeneous mobile communication system according to claim 5, wherein the forward signals have different data rates and frequencies and are delayed by a predetermined time for a communication signal allocated to a different type than a signal allocated to the same type. Transmission device. a) means for receiving heterogeneous reverse communication signals with a time difference and a space difference; b) means for separating the heterogeneous reverse communications signals according to an assigned channel; c) means for processing each of the reverse communication signals separated by means of b). The apparatus of claim 7, wherein the reverse communication signals have different data rates and frequencies and are received in the same type. An IS-95A communication channel processing unit 100 for generating an IS-95A forward channel signal to be transmitted through at least one transmission channel and processing an IS-95A reverse channel signal input through the reception channel; An IS-95C communication channel processor 200 for generating an IS-95C forward channel signal to be transmitted through at least one transmission channel and processing an IS-95C reverse channel signal input through a reception channel; A transmission delay unit for delaying the IS-95C forward channel signal from the IS-95A communication channel processing unit 100 and the IS-95C forward channel signal from the IS-95C communication channel processing unit 200 respectively; 500); The IS-95A forward channel signal from the IS-95A communication channel processing unit 100 and the delayed IS-95C forward channel signal from the transmission delay processing unit 500 are synthesized and amplified to produce an IS-95A / C forward communication signal. An IS-95A transceiver 300 for generating and receiving a reverse signal through at least two receiving terminals based on an input IS-95A reverse communication signal; And The IS-95C forward channel signal from the IS-95C communication channel processing unit 200 and the delayed IS-95A forward channel signal from the transmission delay processing unit 500 are synthesized and amplified to produce an IS-95A / C forward communication signal. And an IS-95C transceiver for receiving and generating a reverse signal through at least two receiving terminals based on an IS-95C reverse communication signal inputted thereto. 10. The apparatus of claim 9, wherein the transmission delay unit (500) comprises: an IS-95A transmission delay unit (510) for delayed transmission processing of the IS-95A forward channel signal of the IS-95A frequency converter (115); And A heterogeneous communication system comprising an IS-95C transmission delay unit (530) for delayed transmission processing of the IS-95C forward channel signal of the IS-95C frequency converter (215). The IS-95A forward / receive unit 300 is an IS-95A forward communication signal from the IS-95A frequency converter 115 and an IS-95C forward from the IS-95C transmission delay unit 530. A first IS-95A / C transmitter 310 for synthesizing and amplifying a communication signal; A first IS-95A receiver 330 for receiving IS-95A reverse communication signals from the IS-95A first receiving antenna 336; And And a first IS-95A receiver (330) for delaying and distributing the IS-95A reverse communication signal from the IS-95 second receiving antenna (357) for a predetermined time. 12. The apparatus of claim 11, wherein the first IS-95A / C transmitter 310 transmits a forward communication signal from the IS-95A frequency converter 115 and a forward communication signal from the IS-95C frequency converter 215. A first IS-95A / C synthesizer 311 for synthesizing to generate an IS-95A / C synthesized forward communication signal; An IS-95A high power amplifier (313) for linearly amplifying the IS-95A / C synthesized forward communication signal from the first IS-95A / C synthesizer (311); And An IS-95A transmit band filter 315 for filtering the amplified IS-95A / C synthesized forward communication signal from the IS-95A high output amplifier 313 and transmitting it through the IS-95A transmit antenna 316. Heterogeneous communication system, characterized in that. 12. The receiver of claim 11, wherein the first IS-95A receiver 330 is a first IS-95A receive band filter 335 for filtering IS-95A reverse communication signals from the first IS-95A receiving antenna 336. ; A first low noise amplifier 333 for amplifying IS-95A reverse communication signals from the IS-95A receive band filter 335; And And a first IS-95A distributor (331) for allocating IS-95A reverse communication signals from the first low noise amplifier (333) to the IS-95A communication channel processing unit (100). The IS-95A receiving delay unit of claim 11, wherein the second IS-95A receiving unit 350 performs a time delay processing of IS-95A reverse communication signals from the second IS-95A receiving antenna 357. 356); A second reception band filter 355 for filtering the delayed IS-95A reverse communication signals from the IS-95A reception delay unit 356; A second low noise amplifier 353 for amplifying IS-95A reverse communication signals from the second receive band filter 355; And And a second IS-95A distributor (351) for allocating IS-95A reverse communication signals from the second low noise amplifier (353) to the IS-95A communication channel processing unit (100). The IS-95C forward / receiver unit 400 is an IS-95C forward communication signal from the IS-95C frequency converter 215 and an IS-95A forward direction from the IS-95A transmission delay processor 510. A second IS-95A / C transmitter 410 for synthesizing and amplifying a communication signal; A first IS-95C receiver 430 for distributing IS-95A reverse communication signals from the IS-95C first receiving antenna 436; And And a second IS-95C receiver 450 for delaying and distributing the IS-95C reverse communication signal from the IS-95C second receiving antenna 457 for a predetermined time. 16. The apparatus of claim 15, wherein the second IS-95A / C transmitter 410 transmits a forward communication signal from the IS-95C frequency converter 215 and a forward communication signal from the IS-95A frequency converter 215. A first IS-95A / C synthesizer 411 for synthesizing to generate an IS-95A / C synthesized forward communication signal; An IS-95C high power amplifier (413) for linearly amplifying the IS-95A / C synthesized forward communication signal from the first IS-95A / C synthesizer (411); And An IS-95C transmitband filter 415 for filtering and amplifying the amplified IS-95A / C synthesized forward communication signal from the IS-95C high output amplifier 413 and transmitting it through the IS-95C transmit antenna 416. Heterogeneous communication system, characterized in that. 16. The receiver of claim 15, wherein the first IS-95C receiver 430 is a first IS-95C receive band filter 435 for filtering IS-95C reverse communication signals from the first IS-95C receive antenna 436. ; A first low noise amplifier 433 for amplifying IS-95C reverse communication signals from the IS-95C receive band filter 435; And And a first IS-95C distributor (431) for allocating IS-95C reverse communication signals from the first low noise amplifier (433) to the IS-95C communication channel processor (200). The IS-95C receiving delay unit of claim 15, wherein the second IS-95C receiving unit 450 is configured to delay the IS-95C reverse communication signals from the second IS-95C receiving antenna 457 for a predetermined time. 456); A second reception band filter 455 for filtering the delayed IS-95C reverse communication signals from the IS-95C reception delay unit 456; A second low noise amplifier 453 for amplifying IS-95C reverse communication signals from the second receive band filter 455; And And a second IS-95C distributor (451) for allocating IS-95C reverse communication signals from the second low noise amplifier (453) to the IS-95C communication channel processing unit (200).