JP2000059336A - Device and method for generating pilot beacon signal for base station in code division multiple access system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the integration degree of boards and to attain the stabilization of a system by synthesizing the pseudo digital noise signals of I and Q channels, filtering an analog signal provided by D/A conversion, extracting and outputting the signal of a frequency band to be transmitted. SOLUTION: The pseudo noise signal of the I channel from a generator 211 is molded through a molding filter 212, sent out to an equalizer 213 of a first phase, equalized with the phase of a signal on the side of reception and passed through a first up converter 214 and the pseudo noise signal of the Q channel from a generator 215 is passed through a molding filter 216, equalized with the phase of a signal on the side of reception by an equalizer 217 of a second phase and transmitted through a second up converter 218 to a combiner 219 for digital signals. The digital combiner 219 synthesizes the pseudo noise signals of I and Q channels, the analog signal converted by a D/A converter 220 is filtered by a band filter 221 and the beacon signal of a frequency band suitable for the reception side is extracted.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a code division multiple access.
(Code Division Multiple Access)
traffic frequency area (Traffic Frequency Area;
Handoff (h) between base stations with different traffic FA)
and a method for generating a beacon signal used for a CDMA system, and particularly to a code division multiple access (Code
The present invention relates to an apparatus and a method for generating a pilot beacon signal used in a vision multiple access (BS) base station.

[0002]

2. Description of the Related Art FIG. 1 is a block diagram of a conventional apparatus for generating a pilot beacon signal for a base station in a code division multiple access system.
1), the first pulse shaping filter (112), and the first D / A converter
(113), a first low-pass filter (114), a first phase equalizer (115), a second low-pass filter (116), a first upward converter (117), Q channel pseudo noise signal generator (118)
, A second pulse shaping filter (119), and a second D / A converter (1
20), a third low-pass filter (121), a second phase equalizer (122), a fourth low-pass filter (123), and a second upward converter (124). , An analog signal synthesizer (125), a band-pass filter (126), and a power amplifier (127).

The operation of the conventional apparatus for generating a pilot beacon signal for a base station in a code division multiple access system having the same structure as the above will be described in detail. First, a transmission process of an I-channel pseudo noise signal will be described. I channel pseudo noise signal generator (11
If 1) transmits the I-channel pseudo noise signal to the first pulse shaping filter (112), the first pulse shaping filter (11)
2) shapes the transmitted pulse-form I-channel pseudo-noise signal and outputs the shaped I-channel pseudo-noise signal to the first D / A converter (113).

As described above, the first pulse forming filter (11)
The digital I-channel pseudo noise signal shaped in 2) is converted to an analog signal through the first D / A converter (113) and transmitted to the first low-pass filter (114).

At this time, while the digital signal is converted into an analog signal by the first D / A converter (113), unnecessary signal components are generated in the pseudo noise signal of the I channel. The unnecessary components generated in this manner are filtered and removed by the first low-pass filter (114), and the first low-pass filter (114) removes the unnecessary components of the frequency band to be transmitted. An I-channel pseudo noise signal is extracted and transmitted to the first phase equalizer (115).

Then, the phase of the I-channel pseudo-noise signal transmitted from the first low-pass filter (114) is equalized to the phase of the signal on the receiving side, and the second low-pass filter (11
Transmit to 6).

Thus, the second low-pass filter (116)
Is filtered, the second low-pass filter (116) removes unnecessary signal components generated in the phase equalization process, and Only the signal of the frequency band to be transmitted is extracted and transmitted to the first upward converter (117).

Next, the first up converter (117) converts the pseudo-noise signal of the low-frequency I channel transmitted from the second low-pass filter (116) to an intermediate frequency to synthesize an analog signal. To the vessel (125).

Next, the transmission process of the Q-channel pseudo noise signal will be described. If the Q channel pseudo noise signal generator (118) transmits the Q channel pseudo noise signal to the second pulse shaping filter (119), the second pulse shaping filter (119) will transmit the transmitted pulse form. The Q-channel pseudo noise signal is shaped, and the shaped Q-channel pseudo noise signal is output to the second D / A converter (120).

As described above, the second pulse shaping filter (11)
The digital Q-channel pseudo-noise signal shaped by 9) is converted into an analog signal through the second D / A converter (120) and transmitted to the third low-pass filter (121).

At this time, while the digital signal is converted into an analog signal by the second D / A converter (120), unnecessary signal components are generated in the pseudo noise signal of the Q channel. Unnecessary components generated in this way are the third
The low-pass filter (121) filters and removes the signal, and the third low-pass filter (121) extracts a Q-channel pseudo-noise signal of a frequency band to be transmitted and outputs the pseudo-noise signal of the second phase. (122).

Thereafter, the second phase equalizer (122) outputs the Q channel transmitted from the third low-pass filter (121) so that the phases of the signals at the transmitting end and the receiving end are matched. The phase of the pseudo noise signal is equalized with the phase of the signal on the receiving side to
4 Transmit to the low-pass filter (123).

Thus, the fourth low-pass filter (123)
The pseudo-noise signal of the Q channel transmitted to the filter is filtered. At this time, the fourth low-pass filter (123) removes unnecessary signal components generated in the phase equalization process, and transmits again. Only the signal of the frequency band to be extracted is extracted and transmitted to the second upward converter (124).

Next, the second upward converter (124) upwardly converts the pseudo noise signal of the Q channel transmitted from the fourth low-pass filter (123) to an intermediate frequency, and synthesizes an analog signal ( 125).

Through such a process, the I channel and the Q
The channel pseudo-noise signal is converted to an analog signal synthesizer (12
If the signal is transmitted to (5), the analog signal synthesizer (125) synthesizes the transmitted pseudo noise signals of the I channel and Q channel and outputs the synthesized signal to the band-pass filter (126). Then
The band-pass filter (126) is an analog signal synthesizer (12).
5) Filter the signal transmitted from (5), extract the beacon signal in the frequency band suitable for the receiving side, and
(127). In this way, the generated beacon signal is amplified to a sufficient signal by the power amplifier (127) and then transmitted to the receiving side through the antenna.

However, in the case of the conventional pilot beacon signal generating apparatus as described above, functional elements for processing analog signals are used much more often than functional elements for processing digital signals. Analog signal processing functional elements have a complicated structure, so that the degree of integration is extremely low when mounted on a board.Furthermore, analog signal processing functional elements are sensitive to noise, so that the system is stabilized. There was a problem that could not be achieved.

[0017]

SUMMARY OF THE INVENTION Accordingly, the present invention, which has been devised to solve the above-described problems, has a problem that a traffic frequency area (Frequency Area) is reduced in a code division multiple access type wireless communication system. In operation of beacon signals used for handoff between different base stations, functional elements for processing analog signals, which have complicated structures, are adopted, and functional elements for processing digital signals, which have simple structures, are used. It is an object of the present invention to provide an apparatus and a method for generating a pilot beacon signal which can significantly increase the degree of integration when mounted on a board.

[0018]

In order to achieve the above object, the present invention provides a traffic frequency area (Frequency Area).
A base station pilot beacon signal generator for a code division multiple access (Code Division Multiple Access) system that operates a beacon (Beacon) signal used for handoff between different base stations is an I-channel. An I-channel digital signal processing means for processing a digital signal; a Q-channel digital signal processing means for processing a Q-channel digital signal;
Digital signal synthesizing means for synthesizing the I channel and Q channel digital pseudo noise signals transmitted from the I channel digital signal processing means and the Q channel digital signal processing means, and the digital signal synthesizing means. D / A conversion means for converting the synthesized digital signal into an analog signal, band-pass filtering means for filtering the analog signal and extracting a signal in a frequency band to be transmitted, and the band-pass filtering Amplifying means for amplifying the signal output from the means.

According to another aspect of the present invention, there is provided a code for generating a beacon signal used for handoff between base stations having different traffic frequency areas. A method of generating a base station pilot beacon signal of the division multiple access (Code Division Multiple Access) method includes a step of processing an I-channel digital signal, a step of processing a Q-channel digital signal, and a step of processing an I-channel digital signal. Synthesizing the digital signal of the Q channel, converting the synthesized digital signal into an analog signal,
Extracting a signal of a frequency band to be transmitted by filtering the analog signal; and amplifying the extracted signal.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. FIG. 2 is a block diagram showing a configuration of a base station pilot beacon signal generator for a code division multiple access system according to an embodiment of the present invention. A digital signal processing function element for processing and synthesizing the I-channel and Q-channel digital pseudo-noise signals, and receiving the pilot beacon signal after converting the digital signal transmitted from the digital signal processing function element into an analog signal. It is a processing unit for analog signals to be transmitted to the side.

Here, the digital signal processing function element is a first digital signal processing device for processing an I channel digital pseudo noise signal.
It can be broadly divided into a digital signal processing section and a second digital signal processing section for processing a Q channel digital pseudo noise signal.

The first digital signal processing section includes an I channel pseudo noise signal generator (211) for generating an I channel digital pseudo noise signal, and an I channel pseudo noise signal generator (211). ), And a first pulse shaping filter (212) for filtering the pseudo noise signal of the I channel transmitted from the first channel, and a phase of the signal output from the first pulse shaping filter (212) is equalized with a phase of the reception side signal. Phase equalizer (213) and first phase equalizer (213) for
And a first up converter (214) for up-converting the output signal of the up-converter.

The second digital signal processing section includes a Q channel pseudo noise signal generator (215) for generating a Q channel digital pseudo noise signal, and a Q channel pseudo noise signal generator (215). ) For shaping the pseudo-noise signal of the Q channel transmitted from the second pulse, and for equalizing the phase of the signal output from the second pulse shaping filter (212) with the phase on the receiving side. A second phase equalizer (217), and a second upward converter (218) for upwardly converting the output signal of the second phase equalizer (217).

The digital signal processing functional element includes an I-channel pseudo-noise signal output from the first upward converter (214) and a Q-channel pseudo noise signal output from the second upward converter (218). A digital signal synthesizer (219) for synthesizing the pseudo noise signal is provided.

The analog signal processing section includes a D / A converter (220) for converting a digital signal transmitted from the digital signal synthesizer (219) into an analog signal, and a D / A converter.
It comprises a band-pass filter (126) for filtering the output signal of the A-converter (220), and a power amplifier (222) for amplifying a signal transmitted from the band-pass filter (126).

As described above, in the present invention, the digital pseudo-noise signals of the I channel and the Q channel are preferentially processed through the digital signal processing function element having a relatively simple configuration, and then are converted to existing ones. By transmitting the pilot beacon signal after much less analog signal processing, compared to the existing analog signal processing that is relatively complicated, it can be integrated on a board. The degree can be significantly increased.

The operation of the apparatus for generating a pilot beacon signal for a base station of the code division multiple access system according to the present invention having the same structure as the above structure will be described in detail as follows.

First, the process of transmitting the pseudo noise signal of the I channel will be described. If the I-channel pseudo-noise signal generator (211) transmits the I-channel pseudo-noise signal to the first pulse shaping filter (212), the first pulse shaping filter (212) transmits the transmitted pulse form. The I-channel pseudo noise signal is shaped, and the shaped I-channel pseudo noise signal is transmitted to the first phase equalizer (213).

Next, the first-phase equalizer (213) is an I-channel pseudo-noise signal transmitted from the first-pulse shaping filter (212) so that the phases of the signals at the transmitting end and the receiving end match. Is equalized with the phase of the signal on the receiving side.
The signal is transmitted to the upward converter (214).

As described above, the pseudo-noise signal of the I channel transmitted to the first upward converter (214) is upwardly converted to an intermediate frequency, and then transmitted to the digital signal synthesizer (219).

Next, the transmission process of the Q channel pseudo noise signal will be described. When the Q-channel pseudo noise signal generator (215) transmits the Q-channel pseudo noise signal to the second pulse shaping filter (216), the second pulse shaping filter (216) transmits the transmitted pulse form. The Q channel pseudo noise signal is shaped, and the shaped Q channel pseudo noise signal is transmitted to the second phase equalizer (217).

Next, a second phase equalizer (217) is provided with a pseudo noise of the Q channel transmitted from the second pulse shaping filter (216) so that the phases of the signals at the transmitting end and the receiving end are matched. The phase of the signal is equalized with the
2 Transmit to the upward converter (218).

As described above, the Q-channel pseudo noise signal transmitted to the second upward converter (218) is upwardly converted to an intermediate frequency, and then transmitted to the digital signal synthesizer (219).

If the digital I-channel and Q-channel pseudo-noise signals are transmitted to the digital signal combiner 219 through the same process, the digital signal combiner 219 transmits the digital I-state. Channel and Q
The pseudo noise signal of the channel is synthesized, and the synthesized digital signal is output to the D / A converter (220). Thus, the digital signal transmitted to the D / A converter (220) is converted to an analog signal, and then transmitted to the band-pass filter (221).

Next, the band pass filter (221) filters the signal transmitted from the D / A converter (220),
A beacon signal in a frequency band suitable for the receiving side is extracted and output to the power amplifier (222). The generated beacon signal is amplified to a sufficient signal by the power amplifier (222) and transmitted to the receiving side through the antenna.

Although the technical idea of the present invention has been specifically described in accordance with the above preferred embodiments, the present invention is not limited to the above embodiments, and various improvements and developments can be added. Also, those skilled in the art of the present invention can fully understand that various embodiments are possible within the scope of the technical idea of the present invention.

[0037]

As described above, the apparatus for generating a beacon signal for a pilot base station of the code division multiple access system according to the present invention has a function of processing an analog signal having a complicated structure and being sensitive to noise in a radio communication system. By using a small number of elements and mainly using a functional element for processing a digital signal having a simple structure, there is an effect that the degree of integration can be increased and the system can be stabilized when mounted on a board.

[Brief description of the drawings]

FIG. 1 is a configuration block diagram of a conventional code-division multiplexing base station pilot beacon signal generating apparatus.

FIG. 2 is a block diagram illustrating a configuration of an apparatus for generating a pilot beacon signal for a base station using a code division multiple access system according to an embodiment of the present invention.

[Explanation of symbols]

 111, 211 I-channel pseudo noise signal generator 112, 212 First pulse shaping filter 113 First D / A converter 114 First low pass filter 115, 213 First phase equalizer 116 Second low pass filter 117,214 1st up converter 118,215 Q channel pseudo noise signal generator 119,216 2nd pulse shaping filter 120 2nd D / A converter 121 3rd low pass filter 122,217 2nd phase equalizer 123 4th Low pass filter 124,218 Second upward converter 125 Analog signal synthesizer 126,221 Band pass filter 127,222 Power amplifier 219: Digital signal synthesizer 220: D / A converter

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Gung Shun Mo, 462-4, Tamin-dong, Yuseong-gu, Daejeon, Republic of Korea 1 Ekispo Apartment 105-1606

Claims (6)

[Claims] 1. An apparatus for generating a pilot beacon signal for a base station of a code division multiple access system, which operates a beacon signal used for handoff between base stations having different traffic frequency ranges, processes an I-channel digital signal. Processing means for processing an I-channel digital signal, processing means for processing a Q-channel digital signal for processing a Q-channel digital signal, processing means for processing the I-channel digital signal, and processing the Q-channel digital signal Digital signal synthesizing means for synthesizing digital pseudo noise signals of the I channel and Q channel transmitted from the means, and D / A conversion for converting the digital signal synthesized by the digital signal synthesizing means into an analog signal Means for filtering and transmitting said analog signal Generation of a code division multiple access base station pilot beacon signal including a band-pass filtering unit for extracting a signal in a frequency band, and an amplification unit for amplifying a signal output from the band-pass filtering unit apparatus. 2. An I-channel digital signal processing unit, comprising: a pseudo-noise signal generating unit for generating the I-channel digital pseudo-noise signal; and an I-channel digital signal transmitted from the pseudo-noise signal generating unit. Pulse shaping means for shaping the digital pseudo noise signal; phase equalizing means for equalizing the phase of the I-channel pseudo noise signal shaped by the pulse shaping means; and the phase equalization Up-conversion means for up-conversion of the I-channel pseudo-noise signal equalized through the means to an intermediate frequency band signal, and a code division multiple access base station pilot beacon signal of claim 1 including Generator. 3. The Q-channel digital signal processing means includes: a pseudo-noise signal generating means for generating the Q-channel digital pseudo-noise signal; and a Q-channel digital signal transmitted from the pseudo-noise signal generating means. Pulse shaping means for filtering and shaping the pseudo noise signal, phase equalizing means for equalizing the phase of the Q channel pseudo noise signal shaped by the pulse shaping means, and the phase equalization Up-conversion means for up-conversion of the Q-channel pseudo-noise signal equalized through the means into an intermediate-frequency band signal, and a code division multiple access base station pilot beacon signal according to claim 1, Generator. 4. A method for generating a base station pilot beacon signal of a code division multiple access system for generating a beacon signal used for handoff between base stations having different traffic frequency ranges, comprising the steps of: Processing the Q channel digital signal; synthesizing the I channel digital signal and the Q channel digital signal; converting the synthesized digital signal into an analog signal; A method for generating a code division multiple access type base station pilot beacon signal, comprising: filtering a signal to extract a signal in a frequency band to be transmitted; and amplifying the extracted signal. 5. The method of processing an I-channel digital signal, comprising the steps of: generating an I-channel digital pseudo-noise signal; shaping the I-channel digital pseudo-noise signal; 5. The code division multiple access base according to claim 4, comprising a step of equalizing the phase of the pseudo noise signal of step (a) and a step of upwardly converting the equalized pseudo noise signal of the I channel into a signal of an intermediate frequency band. A method of generating a station pilot beacon signal. 6. The method of processing the Q-channel digital signal, comprising: generating a Q-channel digital pseudo-noise signal; shaping the Q-channel digital pseudo-noise signal; The code division multiple access method according to claim 4, comprising: equalizing the phase of the pseudo noise signal of the channel; and up-converting the equalized pseudo noise signal of the Q channel to a signal in the intermediate frequency band. A method of generating a base station pilot beacon signal.