KR0162978B1 - Apparatus and method of measuring sir of received signal in cdma system - Google Patents

Abstract

The present invention relates to an apparatus and a method for measuring a signal-to-interference ratio (SIR) of a received signal in a mobile communication environment employing a code division multiple access system (CDMA). Integrate to a value close to the Doppler period to obtain the magnitude of the signal component from which the interference component has been removed, and then subtract the power magnitude of the signal integrated by the Doppler period from the average power magnitude of the signal integrated in the symbol unit. By obtaining the signal-to-interference ratio, the more accurate signal-to-interference ratio can be measured without using an expensive and precise automatic gain controller, thereby reducing the cost of the receiver and the power control of the present invention. When applied to, it is possible to perform power control based on signal to interference ratio rather than power control based on received signal power. There is an effect that can improve the performance of the system.

Description

Apparatus and method for measuring signal-to-interference ratio for received signal in code division multiple access system.

1 is a structural diagram of a conventional signal-to-interference ratio measuring apparatus.

2 is a structural diagram of an apparatus for measuring a signal to interference ratio according to an embodiment of the present invention.

3 is a flow chart according to an embodiment of the present invention.

4 is a graph of experimental results of the signal to interference ratio measured by the present invention.

* Explanation of symbols for the main parts of the drawings

201: despread modulator 202: integral discharge filter

203: symbol unit power meter 204: average calculator

205: moving average calculator 206: measuring section power meter

207: Signal to Noise Ratio Calculator

The present invention relates to an apparatus and method for measuring a signal to interference ratio (SIR) of a received signal in a mobile communication environment employing a code division multiple access system (CDMA).

In a load division multiple access system, the voice signal of each user is transmitted through various processes at the transmitting end. The signal arriving at the base station receiver through the radio propagation path is a combination of a Doppler shifted magnetic signal due to the movement of the transmitter, a multipath faded magnetic signal due to multiple propagation paths, and signals of other users. Among these signals, a process for extracting only a magnetic signal is performed, and signal components of other users who are not removed in this process are regarded as interference signals.

In the code division multiple access system, the original signal may be recovered from the received signal when the signal-to-interference ratio of the received signal is higher than a predetermined level. However, the signal-to-interference ratio of the received signal varies according to the location of each user, and the base station sets the reference signal-to-interference ratio in order to provide the same quality service to all users. The base station measures the signal-to-interference ratio of each user and compares it with the reference signal-to-interference ratio and requests the user to adjust the output of the user. In this process, accurate measurement of the signal-to-interference ratio of the received signal plays a very important role.

1 is a structural diagram of a conventional apparatus for measuring a signal-to-interference ratio, in which 102 is an encoder, 103 is an orthogonal modulator, 105 is an automatic gain controller, 106 to 108 is a despread modulator, 113 to 115 is an integral discharge filter, and 116 is a maximum value. Each selector is shown.

The audio signal 101 of the transmitter is coded by the encoder 102 and instead transmitted by one of 2 ⁶ orthogonal codes having a length of 64 according to six symbol unit values in the quadrature modulator 103.

Signals passing through the wireless environment of the multipath channel 104 arrive at the base station receiver and pass through an automatic gain adjuster (AGC) 105 so that they are always received at a constant size. Taking a correlation, respectively and outputs the despread modulator (106 to 108) ²⁶ orthogonal code (109 to 112) in respect of an automatic gain adjuster (105), each accumulating the result in the integral discharge filter (113 to 115) . The orthogonal code having the largest value among the accumulated results in the maximum selector 116 is selected as the transmitted signal value.

At this time, the signal-to-interference ratio of the received signal estimates the signal-to-interference ratio as the variation of the output of the constant automatic gain adjuster 105 to the selected maximum value 117. It is assumed that the maximum amount of conversion is a change in signal-to-interference ratio, a look-up table is created, and the signal-to-interference ratio is mapped according to the maximum value. At this time, since the measured maximum value includes interference signals other than signal components, it is difficult to accurately measure the signal-to-interference ratio.

In the conventional code division multiple access system, a very precise automatic gain controller is used to measure the signal-to-interference ratio of a received signal. By maintaining the output of the automatic gain controller at a constant value and measuring the magnitude of the signal after despreading, the signal-to-interference ratio was estimated by the amount of change.

However, the conventional method has a problem that the measured signal-to-interference ratio is very sensitive to the change of the automatic gain controller, and since the signal after despreading includes many interfering signals, accurate signal-to-interference ratio cannot be measured.

In order to solve the above problems, the present invention, after receiving and despreading a signal, performs integration to a value close to the maximum Doppler period of the moving object to obtain the magnitude of the signal component from which the interference component is removed, and then integrates it in symbol units. An object of the present invention is to provide an apparatus and method for measuring a signal-to-interference ratio, which obtains a signal-to-interference ratio by subtracting a power magnitude of a signal integrated by a Doppler period from an average power magnitude of a signal.

The apparatus of the present invention for achieving the above object comprises: despreading modulation means for receiving a pilot signal from a transmitting end and performing despreading according to an orthogonal code input from the outside; Integral discharge filtering means for receiving the despread signal from the despreading modulation means and performing integration in modulation symbol units; Symbol unit power measurement means for receiving an integrated value in modulation symbol units from the integral discharge filtering means and measuring power in symbol units; An average calculating means for receiving an output of the symbol unit power measuring means and calculating an average received power value for a predetermined time; Moving average calculating means for receiving an integrated value in modulation symbol units from the integral discharge filtering means and performing integration for the predetermined time; Measurement section power measurement means for receiving the output of the moving average calculation means and calculating the measurement section power to obtain power of only a signal component; And receiving the average received power from the average calculating means, receiving the power of only the signal from the measuring section power measuring means, and subtracting the power of only the signal from the average received power to obtain the interference signal power. And a signal-to-interference ratio calculating means for dividing by to obtain a signal-to-interference ratio for the received signal.

The method of the present invention for achieving the above object is a signal-to-interference ratio measuring method applied to a signal-to-interference ratio measuring apparatus for a received signal in a code division multiple access system, when receiving a pilot signal from the transmitter is used in the transmitter A first step of performing integration in symbol units after performing despreading according to an orthogonal code; A second step of measuring power in symbol units after the first step and calculating an average received power value for a predetermined time; A third step of integrating a value integrated in modulation symbol units for the predetermined time after performing the first step, and calculating power of only a signal component by calculating a measurement interval power; And after performing the second and third steps, obtain the interference signal power by subtracting the power of only the signal from the average received power, and then dividing the power of only the signal by the interference signal power to obtain a signal-to-interference ratio for the received signal. It is characterized by including the fourth step.

Hereinafter, with reference to the accompanying drawings will be described an embodiment according to the present invention;

2 is a structural diagram of an apparatus for measuring a signal-to-interference ratio according to an embodiment of the present invention, where 201 is a despread modulator, 202 is an integral discharge filter, 203 is a symbol unit power meter, 204 is an average calculator, and 205 is a moving average calculator. 206 denotes a measurement interval power meter, and 207 denotes a signal-to-noise ratio calculator.

In a code division multiple access system, when a user transmits a pilot signal having the same value ('1') together with a voice signal, the receiver performs coherent demodulation.

The pilot signal always has the same information, and is transmitted by being spread with a unique orthogonal code for each user in symbol units like a voice signal. The transmitted pilot information is received in the form of path delay and size conversion at the receiving end according to the user's environment due to multipath fading. After despreading using the orthogonal code used at the transmitting end and passing the integrator in the spread modulation symbol unit, it includes many interference signals in addition to the report component.

When the signal is observed in terms of frequency, the impulse signal inherent in the pilot signal includes a frequency shifted component by the Doppler shift caused by the movement of the transmitter and a noise component due to interference in the band by the modulation symbol rate.

In order to remove this interference component, when the integration is performed for a long time not exceeding the correlation time of the fading channel, most of the noise component due to the interference is removed. The signal power to interference power ratio of the received signal can be calculated from the ratio of the power due to the interference to the signal power.

Looking at the specific embodiment through Figure 2 as follows.

The despreading modulator 201 receives a pilot signal from a transmitting end and despreads according to an orthogonal code input from the outside. The integral discharge filter 202 receives the despread signal from the despreading modulator 201 and performs the integration in units of modulation symbols.

The symbol unit power meter 203 receives an integrated value from the integral discharge filter 202 in units of power modulation symbols and measures power in symbols.

The average calculator 204 receives the output of the symbol unit power meter 203 and calculates an average received power value for a predetermined period (less than a correlation time of a fading channel). This average received power value is an average of a predetermined period of sum of signal power and interference power.

The moving average calculator 205 receives an integrated value from the integral discharge filter 202 in units of power modulation symbols and continuously performs integration for a predetermined period (less than a correlation time of a fading channel). The measurement section power meter 206 receives the output of the moving average calculator 205 and calculates the measurement section power to obtain power of only a signal component. That is, the long-time integration in the moving average calculator 205 acts as a narrow bandwidth filter in terms of frequency, so that the noise signal existing in the band of the Doppler shift of the pilot channel is removed, thereby obtaining power of only a signal. Can be.

The signal-to-interference ratio calculator 207 receives the average received power from the average calculator 204, receives the power of only the signal from the measurement interval power meter 206, and subtracts the power of only the signal from the average received power. After obtaining power, the signal-to-interference ratio for the received signal is obtained by dividing the power of only the signal by the interference signal power. Reverse closed-loop power control can be performed with this signal-to-interference ratio.

3 is a flowchart according to an embodiment of the present invention.

When the receiving end receives the pilot signal from the transmitting end (301), the despreading is performed according to the orthogonal code used in the transmitting end (302), and then integration is performed in symbol units (303).

After the integration is performed in the symbol unit (303), the power is measured in the symbol unit (306), and the average received power value is calculated (307) for a predetermined period (less than the correlation time of the fading channel).

After integrating in symbol units (303), the integrated value in units of power modulation symbols is continuously integrated for a predetermined interval (less than the correlation time of the fading channel) (304), and the measurement interval power is calculated to calculate power of only a signal component. Obtain (305). That is, since the integration for a long time serves as a narrow bandwidth filter in terms of frequency, the noise signal existing in the band of the Doppler shift of the pilot channel is eliminated, thereby obtaining power of only the signal.

After performing the average received power calculation process 307 and the signal only power measurement process 305, the power of only the signal is obtained by subtracting the power of only the signal from the average received power (308) and then the power of only the signal is the interference signal. The signal-to-interference ratio for the received signal is obtained by dividing by the power (309).

4 is a graph of the experimental results of the signal-to-interference ratio measured by the present invention, and shows the results of experiments in an additive Gaussian white noise environment.

The power magnitude of the signal component from which the noise component due to the integrated effect is removed during the long measurement period is extracted to the same magnitude 402 as the transmitted magnitude. In addition, the magnitude 403 of the interference signal power expressed by the difference between the magnitude of the signal calculated in symbol units and the magnitude of the signal component power is constant according to the change in the signal-to-noise ratio (E _b / N _o ) of the additive Gaussian white noise. Indicated. Thus, the measured signal-to-interference ratio 401 matches the signal-to-noise ratio (Eb / No) of additive Gaussian white noise, thus demonstrating the feasibility of the present invention.

As described above, the present invention can measure a more accurate signal-to-interference ratio without using an expensive and accurate automatic gain controller to measure a signal-to-interference ratio for a received signal in a code division multiple access system having a pilot channel. There is an economic effect that can reduce the cost, and when applying the present invention to the power control, it is possible to perform the power control based on the signal-to-interference ratio rather than the power control based on the received signal power, thereby improving the performance of the system. It has an effect.

Claims (5)

Despreading modulation means (201) for receiving a pilot signal from a transmitting end and performing despreading according to an orthogonal code input from the outside; Integral discharge filtering means (202) for receiving the despread signal from the despreading modulation means (201) and performing integration in modulation symbol units; Symbol unit power measurement means (203) for receiving the integrated value in modulation symbol units from the integrated discharge filtering means (202) and measuring power in symbol units; An average calculating means (204) for receiving an output of the symbol unit power measuring means (203) and calculating an average received power value for a predetermined time; A moving average calculating means (205) for receiving an integrated value from the integral discharge filtering means (202) in units of modulation symbols and performing integration for the predetermined time; Measurement section power measurement means (206) for receiving the output of the moving average calculation means (205) to calculate the measurement section power to obtain the power of only the signal component; And receiving the average received power from the average calculating means 204 and the power of only the signal from the measuring section power measuring means 206, and subtracting the power of only the signal from the average received power to obtain the interference signal power. And a signal-to-interference ratio calculating means (207) for dividing the power of the signal by the interference signal power to obtain a signal-to-interference ratio for the received signal. The apparatus of claim 1, wherein the predetermined time is less than a correlation time of a fading channel. The apparatus of claim 1, wherein said signal-to-interference ratio calculating means (207) outputs the calculated value of the signal-to-interference ratio to perform reverse closed loop power control. In a signal-to-interference ratio measuring method applied to a signal-to-interference ratio measuring apparatus for a received signal in a code division multiple access system, when a pilot signal is received from a transmitter, a symbol unit is performed after despreading according to an orthogonal code used by the transmitter. First steps 301 to 303 for performing an integration with; After performing the first steps 301 to 303, the power is measured in symbol units, and the second steps 306 and 307 for calculating an average received power value for a predetermined time are performed after the first steps 301 to 303. A third step (304, 305) of integrating a value integrated in the modulation symbol unit for the predetermined time, calculating power of a measurement component by calculating a measurement interval power, and the second step (306, 307) and the third step ( After performing 304, 305), subtract the power of only the signal from the average received power to obtain the interference signal power, and then divide the power of only the signal by the interference signal power to obtain a signal-to-interference ratio for the received signal (308, 309). Signal to interference ratio measurement method comprising a. The method of claim 4, wherein the predetermined time is less than a correlation time of a fading channel.