JP2011082950A - Method and apparatus for shortening delay time in cdma/wcdma based noise removal repeater - Google Patents

Abstract

A method for reducing a delay time of a repeater for removing noise of a received signal in a CDMA / WCDMA based mobile communication system is provided.
A CDMA / WCDMA denoising repeater demodulates a signal received through a receiving antenna, remodulates the demodulated signal, and a spreading factor used in the demodulation and modulation steps is received through the receiving antenna. A diffusion coefficient lower than the diffusion coefficient used for signal diffusion is used. Such a CDMA / WCDMA noise elimination repeater uses a spreading factor lower than the spreading factor of the received signal and demodulates and modulates the digital signal, thereby despreading the digital signal during the demodulation and modulation process in the repeater and The time required for diffusion can be reduced. Accordingly, it is possible to reduce a window size for searching for a terminal signal in the base station, thereby improving the base station terminal searching efficiency and increasing the network design flexibility.
[Selection] Figure 2

Description

  The present invention relates to a method and apparatus for reducing delay time in a code division multiple access (CDMA) / wideband code division multiple access (WCDMA) -based noise reduction repeater, and more particularly, to a CDMA / WCDMA noise reduction repeater The present invention relates to a method for reducing demodulation time by using a low spreading factor in a demodulator and a repeater using such a method.

  Generally, in a mobile communication system, a repeater is installed in order to extend a service area of a base station or eliminate a shadow area. However, the repeater does not only receive desired relay signals (base station and terminal signals to be relayed) but also unwanted reception noise (such as other base station signals and channel noise in the vicinity) during the processing. There is a disadvantage of being amplified and sent out.

  FIG. 1 schematically shows a configuration of a general mobile communication repeater (110). The repeater generally includes a reception antenna (102) that receives a signal from a base station or a terminal, a band pass filter (112) for removing unnecessary signals from a signal received through the reception antenna (102), It includes an amplifier (114) that amplifies the signal that has passed through the band pass filter (112) to a predetermined level, and a transmission antenna (104) that transmits the signal amplified in the amplifier.

  At this time, the bandpass filter (112) constituting the conventional repeater simply performs a function of passing a signal in the band and blocking the signal outside the band. Cannot be removed. Furthermore, since the realistic bandpass filter (112) is not ideal, out-of-band signals are not completely removed, and thus noise existing in out-of-band signals cannot be completely removed. Therefore, the existing repeater has a problem that reception noise is not completely removed, and a part of the repeater is amplified and transmitted.

  In order to compensate for the disadvantages of the repeater as described above, a technique for removing received noise can be considered. One of them is a noise removal repeater that removes noise through a separate digital demodulation and modulation process in the repeater. It is.

  According to the above-described noise removal repeater, noise components can be effectively removed from the relay signal. However, when the noise removal repeater is actually applied to a CDMA / WCDMA-based system, a digital demodulation and modulation process is performed. Therefore, since it takes a lot of time to spread and despread the digital signal, there is a possibility that a delay time occurs in the noise reduction repeater. Therefore, in the CDMA / WCDMA-based repeater, it is possible to solve the problem of time delay that may occur when implementing a configuration for removing noise through a separate digital demodulation and modulation process in the repeater. Objective.

  A repeater for removing noise in a CDMA / WCDMA based mobile communication system according to the present invention is configured to demodulate a signal received through a receiving antenna, and to demodulate the demodulated signal. A modulation unit and a synchronization signal detection unit configured to supply a synchronization signal detected from a signal received through a reception antenna to the demodulation unit and the modulation unit, and a spreading coefficient used by the demodulation unit and the modulation unit is relayed Lower than the spreading factor used to spread the signal received by the receiver.

  In an embodiment according to the present invention, the digital data demodulated in the demodulator may be quantized and a noise remover configured to remove noise from the demodulated digital data may be further included.

  In one embodiment according to the present invention, the synchronization signal detection unit may be configured to supply a synchronization signal received by a separate external interface to the demodulation unit, the noise removal unit, and the modulation unit.

  Also, in one embodiment according to the present invention, a downlink conversion unit configured to convert a signal received by the repeater into a baseband signal, and a digital configured to convert the baseband signal into a digital signal. A converter, an analog converter configured to convert the signal modulated in the modulator into a baseband analog signal, and an uplink converter configured to convert the baseband analog signal into a high-frequency signal The demodulator may be further configured to demodulate the digital signal, and the synchronization signal detector may be further configured to detect the synchronization signal from the signal received by the repeater.

  In one embodiment according to the present invention, the uplink conversion unit may be configured to uplink convert the baseband analog signal into a signal of a frequency band different from the signal received through the reception antenna.

  A method for removing signal noise in a CDMA / WCDMA digital repeater according to the present invention includes a demodulation step for demodulating a signal received through a reception antenna, a modulation step for modulating the demodulated signal in the demodulation step, and a reception antenna. Using the synchronization signal detected from the signal received through the demodulation step and the modulation step, the spreading factor used in the demodulation step and the modulation step is lower than the spreading factor of the signal received through the receiving antenna.

  In an embodiment according to the present invention, it may further include a noise removal step of quantizing the demodulated signal in the demodulation step and removing noise from the demodulated signal in the demodulation step.

  In one embodiment according to the present invention, the synchronization signal detection step may include using a synchronization signal received by a separate external interface in a demodulation step, a noise removal step, and a modulation step.

  According to the present invention, there is an effect of improving the performance of a repeater by effectively removing reception noise included in a received radio signal. In addition, in the CDMA / WCDMA based system noise removal repeater, the delay time in the noise removal repeater can be reduced by reducing the time required for despreading and spreading of the digital signal during the digital demodulation and modulation process. . Accordingly, the window size for searching for the terminal signal in the base station can be reduced, the search efficiency of the terminal of the base station can be increased, and the flexibility of the network design can be increased.

FIG. 1 is a general conceptual diagram of a noise elimination repeater. FIG. 2 is a configuration diagram of a noise elimination repeater according to an embodiment of the present invention. FIG. 3 shows the process of despreading using the same spreading coefficient as the spreading factor of the received signal. FIG. 4 shows a process of performing despreading using the spreading factor 4 regardless of the spreading factor of the received signal. FIG. 5 is a flowchart illustrating an operation process of the noise reduction repeater according to the embodiment of the present invention.

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

  FIG. 2 is a block diagram illustrating an exemplary noise elimination repeater according to the present invention.

  Referring to FIG. 2, the noise reduction repeater includes a reception antenna (202), a first conversion unit (210), a signal processing unit (220), a second conversion unit (230), and a transmission antenna (204). The first converter (210) converts the radio signal received from the receiving antenna (202) into a baseband digital signal via the downlink converter (212) and the digital converter (214). At this time, the radio signal r received by the receiving antenna (202) is in a form in which the relay signal s to be relayed by the repeater and the reception noise n to be removed are mixed. The signal processor (220) demodulates the digital received signal r = s + n output from the first converter (210), then removes the received noise n and remodulates only the remaining relay signal s. , To the second conversion unit (230). Such a signal processing unit (220) includes a digital demodulation unit (222), a noise removal unit (224), a digital modulation unit (226), and a synchronization signal detection unit (228). The digital demodulator (222) demodulates the baseband digital signal transmitted from the first converter (210) to restore the digital data. The noise removal unit (224) removes the reception noise n from the digital data demodulated by the digital demodulation unit (222) through a method such as quantization.

An embodiment of a method for removing noise will be described below. However, this method is not necessarily used. In addition, the method of removing noise may change depending on a modulation scheme such as QPSK or quadrature amplitude modulation (QAM). The following four types of data are possible with QPSK.

Here, by applying the following mathematical formula, it is _possible to remove s _demod by removing n _demod , which is a noise component, from r _demod .

  Thereafter, the digital modulation unit (226) modulates the signal from which the reception noise n is removed by the noise removal unit (224), generates a transmission signal, and transmits the transmission signal to the second conversion unit (230). The synchronization signal detection unit (228) detects a synchronization signal from the baseband digital signal transmitted from the first conversion unit (210), and performs a digital demodulation unit (222), a noise removal unit (224), and a digital modulation unit ( 226). The synchronization signal detection unit (228) can also receive the synchronization signal through a separate external interface and supply it to the digital demodulation unit (222), the noise removal unit (224), and the digital modulation unit (226). The second conversion unit (230) receives the transmission signal from which the reception noise n is removed in the signal processing unit (220), and converts the transmission signal into a radio signal through the analog conversion unit (232) and the uplink conversion unit (234). Then, it transmits through a transmitting antenna. The uplink conversion unit (234) can also up-convert the analog signal into a signal having a frequency band different from that of the radio signal received from the reception antenna (202).

  In the embodiments of the present invention, a WCDMA (Wideband Code Multiple Access) mobile communication system has been described. However, the present invention is not limited to this and is applicable to all CDMA-based mobile communication systems. can do. Although the unidirectional relay route is described here, in the case of a bidirectional relay route, it can be easily expanded by configuring with two unidirectional relay routes.

  Hereinafter, the operation principle of the signal processing unit 220 will be described in detail with reference to FIG. 3 and the principle of WCDMA band spreading and despreading.

  In a WCDMA system using N channels, assuming that a signal subjected to band spreading using a spreading coefficient 256 is received by a repeater, an input signal r input to the signal processing unit 220 is given by the following equation: Expressed.

Here, a ₁ , a ₂ , a ₃ ,..., A _N are transmission data, w ₁ , w ₂ , w ₃ ,..., W _N are spreading codes, and E is reception noise. Generally, each data _{a 1, a 2, a 3} , ..., in order to extract _{a N,} spreading codes _w 1 to the received signal _{r, w 2, w 3,} ..., after multiplication by _{w N,} 1 Each element is averaged over one symbol period.

  The method of extracting each data is as shown in FIG. In the above example, a spreading code having a spreading coefficient of 256 is used. In this case, one symbol of the spreading code is a chip, and 256 chips are required to extract one data symbol. Since the WCDMA chip rate is 3.84 Mcps, 256 chips are required to extract one data symbol, and 66.67 μs is required to receive 256 chips. That is, the repeater delay time is increased by 66.67 μs. In the present invention, in order to reduce the time required for extracting data symbols, a separate spreading coefficient used in the signal processing unit (220) is determined regardless of the spreading coefficient of the received data.

FIG. 4 exemplarily shows a despreading process when the diffusion coefficient is 4. When a spreading factor of 4 is used, a spreading code w ₁ ′ of length 4 is generated, and a signal x obtained by despreading the input signal r can be expressed by the following equation. it can.

As a feature of spreading _{code, w 1, w 2, w} 3, ..., when dividing the _{w N} spreading code of length 4, or each of which is identical to _{w 1} ', or perpendicular, or code The opposite code. That is, Σw ₁ w ₁ ′ takes one value among −4, 0, and +4. Further, a ₁ , a ₂ , a ₃ ,..., A _N are binary values, and thus have one value among −B, O, and + B, respectively. Therefore, in Equation 2, ^a _n / 4Σw _n w ₁ ′ has one value among −B, O, and + B, and the despread signal x ₁ has a noise component (an integer multiple of B) 1 / 4ΣEw ₁ ′) is added. That is, the output for each channel of the digital demodulator (222) has a form in which a noise component is added to an integral multiple of B. Using this, the noise removing unit (224) can remove the noise component by a method such as quantizing the output of the digital demodulating unit (222) to an integral multiple of B. Hereinafter, an embodiment of a method for removing noise will be described.

  A signal x in which a noise component is added to an integral multiple of B can be expressed as the following equation.

Here, n is an integer and ε represents a noise component. When the following quantization formula is applied to Formula 5, the signal x _q from which the noise component is removed can be obtained.

  Here, round (x / B) is an integer closest to x / B. Thereafter, the digital modulation unit (226) can also remodulate the signal from which the noise component has been removed by the noise removal unit (224) by using the same diffusion coefficient as that used in the digital demodulation unit (222). it can.

  As can be seen from the above, the demodulation time required in the digital demodulator (222) can be shortened by adjusting the diffusion coefficient used in the signal processor (220). In addition, when a low spreading factor is used, the number of channels that need to be processed is reduced, and hardware resources can be saved. However, as in the above example, the spreading coefficient does not necessarily have to be 4, and may be adjusted as necessary within a range in which the orthogonality between spreading codes can be maintained.

  Table 1 below shows that if the input signal is a signal spread with a chip rate of 3.84 Mcps and a spreading factor (256), the spreading factor selected by the signal processing unit (220) is the demodulation time and the channel to be processed. It shows how it affects numbers.

  Furthermore, since noise due to phase variation and frequency variation, fading signal and other base station signal is removed in the demodulation process, there is an effect of reducing noise even without the noise removal unit (224). Therefore, it is possible to implement a repeater that does not include the noise removal unit 224 according to the required specifications.

  FIG. 5 is a flowchart illustrating an operation process of the noise removal repeater according to the embodiment of the present invention. Hereinafter, an operation process of the noise removal repeater according to the embodiment of the present invention will be described with reference to FIG. The first converter (210) converts the radio signal received by the receiving antenna (202) into a baseband signal, and converts it again into a digital signal (step 504). Thereafter, the synchronization signal detector (228) detects a synchronization signal necessary for modulation and demodulation from the digital signal (step 506). The digital demodulator (222) includes a process of despreading the digital signal converted by the first converter (210) with the diffusion coefficient D based on the synchronization signal detected by the synchronization signal detector (228). A WCDMA demodulation process is performed (step 508). At this time, the spreading factor D is a value determined by the repeater, different from the spreading factor of the received radio signal. The noise removing unit (224) removes a noise component from the demodulated signal (step 510). At this time, it is considered that the demodulated signal may include a plurality of channel signals. The signal from which noise has been removed undergoes the WCDMA modulation process in the digital modulation unit (226) (step 512), but uses the spreading coefficient D used in the digital demodulation unit (222). Thereafter, the second conversion unit (230) converts the signal modulated by the digital modulation unit (226) into an analog signal, and then converts the signal again into a radio signal having a frequency to be transmitted (step 514), and the transmission antenna (204). ) (Step 516).

  The above-described CDMA / WCDMA-based denoising repeater according to the present invention is configured to demodulate a signal received through the receiving antenna using a spreading factor lower than that of the signal received through the receiving antenna. A demodulator, and a modulation unit configured to modulate the demodulated signal using the same spreading factor as the spreading factor used in the demodulator, demodulating the digital signal using a low spreading factor, Modulation can reduce the time required for despreading and spreading of the digital signal during the demodulation and modulation process in the repeater.

  The embodiment of the present invention described above is not necessarily limited to the apparatus and method, and may be implemented through a computer program that implements functions corresponding to the embodiment of the present invention. Such implementation can be easily implemented by a person having ordinary knowledge in the technical field to which the present invention belongs based on the above-described embodiment.

102: Receive antenna
104: Transmitting antenna 110: Conventional mobile communication repeater
112: Band pass filter 114: Amplifier
202: Receive antenna 204: Transmit antenna
210: First converter 212: Down converter
214: Digital conversion unit 220: Signal processing unit
222: Digital demodulation unit 224: Noise removal unit
226: Digital modulation unit 228: Synchronization signal detection unit
230: Second conversion unit 232: Analog conversion unit
234: Up-conversion unit

Claims (8)

In a repeater for removing received signal noise in a CDMA / WCDMA-based mobile communication system,
A demodulator configured to demodulate a signal received through the receive antenna;
A modulation unit configured to modulate a signal demodulated in the demodulation unit; and a synchronization signal detected from a signal received through the reception antenna is configured to be supplied to the demodulation unit and the modulation unit. Including a synchronization signal detector,
The CDMA / WCDMA noise removal repeater, wherein a spreading factor used by the demodulator and the modulator is lower than a spreading factor used for spreading a signal received through the receiving antenna.   The CDMA / WCDMA noise removal repeater according to claim 1, further comprising a noise removal unit configured to quantize a signal demodulated in the demodulation unit and remove noise from the signal demodulated in the demodulation unit. .   The CDMA / WCDMA noise removal according to claim 2, wherein the synchronization signal detection unit is configured to supply a synchronization signal received by a separate external interface to the demodulation unit, the noise removal unit, and the modulation unit. Repeater. A downlink converter configured to convert a signal received through the receiving antenna into a baseband signal;
A digital converter configured to convert the baseband signal into a digital signal;
An analog conversion unit configured to convert the signal modulated in the modulation unit into a baseband analog signal; and an uplink conversion unit configured to convert the baseband analog signal into a high-frequency signal. ,
The demodulator is further configured to demodulate the digital signal;
The CDMA / WCDMA noise removal repeater according to claim 1, wherein the synchronization signal detection unit is further configured to detect a synchronization signal from a signal received through the reception antenna.   5. The CDMA / WCDMA noise removal relay according to claim 4, wherein the uplink conversion unit is further configured to up-convert the baseband analog signal into a signal of a frequency band different from a signal received by the repeater. vessel. A demodulation step for demodulating a signal received through the receiving antenna;
A modulation step of modulating the signal demodulated in the demodulation step, and a step of using a synchronization signal detected from a signal received through the receiving antenna in the demodulation step and the modulation step,
A noise removal method in a CDMA / WCDMA digital repeater, wherein a spreading factor used in the demodulation step and the modulation step is lower than a spreading factor of a signal received through the receiving antenna.   The noise removal method in a CDMA / WCDMA digital repeater according to claim 6, further comprising a noise removal step of quantizing the signal demodulated in the demodulation step and removing noise from the signal demodulated in the demodulation step.   The noise in the CDMA / WCDMA digital repeater according to claim 7, wherein the synchronization signal detection step includes a step of using a synchronization signal received by a separate external interface in the demodulation step, the noise removal step, and the modulation step. Removal method.

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