KR20020078064A - Reverse power control method of mobile communication system applied variable value - Google Patents

Abstract

PURPOSE: A method for controlling reverse power using variables in a mobile system is provided to rapidly and exactly execute reverse power control in a fast fading environment by applying 4 variables, or power control bits of '11', '10', '01', and '00', and increasing or decreasing the transmit power of a mobile station by +1dB or -1dB. CONSTITUTION: A base station sets up a reference SNR(Signal to Noise Ratio) to compare with the SNR of a received signal in order to effectively carry out reverse power control(S1). The base station receives a signal through a reverse traffic channel from a mobile station every 1.25ms and calculates the SNR of the received signal(S2). The base station compares the reference SNR with the calculated SNR of the received signal(S3). In case that the calculated SNR is larger than the reference SNR, the base station judges whether the calculated SNR is consecutively larger than the reference SNR(S4). If the calculated SNR is consecutively larger than the reference SNR, the base station transmits a power control bit of '11' among 4 variables to the mobile station through a forward traffic channel(S5). However, in case that the calculated SNR is not consecutively larger than the reference SNR, the base station transmits a power control bit of '10' among 4 variables to the mobile station(S6).

Description

REVERSE POWER CONTROL METHOD OF MOBILE COMMUNICATION SYSTEM APPLIED VARIABLE VALUE}

The present invention relates to a reverse power control method of a mobile communication system using a variable value. In particular, in the case of reverse power control of a mobile communication system, in four cases, two modulation symbols of a forward power control group can be made. The present invention relates to a reverse power control method of a mobile communication system using a variable value to adjust the transmit power of a mobile station to quickly and accurately perform reverse power control even in a fast fading environment having rapid changes.

In general, a mobile communication system employing a code division multiple access (CDMA) scheme transmits and receives data to and from a mobile station 1 and the mobile station 1 wirelessly, as shown in FIG. And a base station 2 for controlling data transmission, a control station 3 and an exchange station 4 for transmitting and receiving data to and from the base station 2 and controlling data transmission and reception with the base station 2.

In the mobile communication system configured as described above, in order to solve the source interference problem caused by all mobile stations in the cell using the same frequency band, reverse power control is performed to adjust the transmission power of the mobile station.

This reverse power control is one of the important technologies of the CDMA method for maintaining a good call quality, such as preventing power waste by transmitting power of a proper transmission signal from the mobile station.

The reverse power control includes an open loop power control, a closed loop power control, and an outer loop power control, and the double closed circuit power control is an error occurring in the open circuit power control. In order to correct the error, the base station transmits two modulation symbols of the forward power control group to the mobile station so that the mobile station adjusts the transmission power according to the two modulation symbols.

That is, in the closed circuit power control, the base station compares the signal-to-noise ratio (Eb / No) of the received signal with the reference signal-to-noise ratio from the reverse traffic channel shown in FIG. 2 received at the mobile station every 1.25 ms. A symbol value is determined, and the determined modulation symbol value is inserted into a forward traffic channel as shown in FIG. 2 and transmitted to the mobile station.

The mobile station then receives the two modulation symbol values over a forward traffic channel and increases or decreases the transmit power of the mobile station by a predetermined unit in accordance with the received modulation symbol values.

FIG. 3 is a diagram illustrating respective mobile stations located in different fading environments, and since mobile station A transmits and receives to a base station in a good wireless environment, there is no sudden change in electric field strength. Good call quality can be maintained even if control is performed.

On the other hand, mobile station B is in a fast fading environment due to various surrounding buildings, so there is a sudden change in electric field strength. Accordingly, the base station receives error-prone traffic signals from the mobile station B, and thus performs fast power up and down control. It is necessary to keep the currency.

That is, conventionally, two modulation symbols of the forward power control group have two fixed values of '00' and '11', so that when the signal-to-noise ratio of the received signal is higher than the reference signal-to-noise ratio, the modulation symbol of '11' The value was punctured in the forward traffic channel and transmitted to the mobile station. When the signal-to-noise ratio of the received signal was lower than the reference signal-to-noise ratio, the modulation symbol value of '00' was punctured in the forward traffic channel and transmitted to the mobile station.

Accordingly, the mobile station reduces the transmission power by -1 dB when receiving the modulation symbol value of '11', and increases the transmission power by +1 dB when receiving the modulation symbol value of '00'. Was adjusted.

However, when performing the power compensation by adjusting the transmission power of the mobile station at regular intervals of -1dB or + 1dB through two modulation symbols as in the prior art, it is not relatively abrupt due to shadowing caused by buildings or the like. Although it is possible to cope with the fading change, there is a problem that it is difficult to cope quickly and accurately in a fast fading environment having a sudden change, and thus it is impossible to maintain a good quality call.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is a variable value of four cases that can be made by two modulation symbols of a forward power control group in reverse power control of a mobile communication system, that is, '11', ' By applying power control bits of 10 ',' 01 ',' 00 'to increase and decrease the transmit power of mobile station by -2dB, -1dB, + 1dB, + 2dB unit, it is possible to quickly and accurately in fast fading environment with rapid change. The present invention provides a reverse power control method of a mobile communication system using a variable value to perform reverse power control to provide a good call quality.

1 is a block diagram of a general mobile communication system;

FIG. 2 is a diagram illustrating a structure of a reverse traffic channel and a forward traffic channel showing positions of power control bits in reverse power control; FIG.

3 shows each mobile station located in a different fading environment;

4 is a diagram illustrating a reverse power control method of a mobile communication system to which a variable value according to the present invention is applied.

<Description of the symbols for the main parts of the drawings>

1 mobile station 2 base station

3: control station 4: switching station

The reverse power control method of the mobile communication system applying the variable value of the present invention for achieving the above object comprises the step of setting a reference signal to noise ratio for comparing the signal to noise ratio of the received signal at the base station, and After performing the reference signal-to-noise ratio setting step, the base station receives the received signal from the mobile station every 1.25 ms, and calculates the signal-to-noise ratio of the received signal for calculating the signal-to-noise ratio of the received signal, and the reference signal-to-noise ratio set in the reference signal-to-noise ratio setting step. And a signal-to-noise ratio comparison step of comparing the signal-to-noise ratio of the received signal calculated in the signal-to-noise ratio calculation step of the received signal, and the signal-to-noise ratio calculation step of the received signal calculated in the signal-to-noise ratio calculation step of the received signal. Noise ratio is the above reference When the signal-to-noise ratio of the received signal is continuously higher than the reference signal-to-noise ratio, if the signal-to-noise ratio of the received signal is higher than the reference signal-to-noise ratio set in the step, the power control bit of '11' is transmitted to the mobile station, and the signal-to-noise ratio of the received signal is If it is not continuously higher than the reference signal-to-noise ratio, the power control bit transmission step for reducing the transmission power for transmitting a power control bit of '10' to the mobile station, and the comparison result of the signal-to-noise ratio comparison step, the calculation of the signal-to-noise ratio calculation of the received signal When the signal-to-noise ratio of the received signal is lower than the reference signal-to-noise ratio set in the reference signal-to-noise ratio setting step, if the signal-to-noise ratio of the received signal is not continuously lower than the reference signal-to-noise ratio, transmit a power control bit of '01' to the mobile station. , Signal stand of the received signal If the ratio is continuously lower than the reference signal-to-noise ratio, the power control bit transmission step for increasing the transmission power for transmitting a power control bit of '00' to the mobile station, and the power control bit transmission step for reducing the transmission power at the mobile station A transmission power reduction control step of reducing the transmission power by -2 dB when receiving the power control bit of '11' and reducing the transmission power by -1 dB when receiving the power control bit of '10'; When the mobile station receives the power control bit of '01' transmitted in the power control bit transmission step for increasing the transmission power, the transmission power is increased in units of +1 dB and the power control bit of '00' is received. Is characterized in that the transmission power increase adjustment step of increasing the transmission power in + 2dB units.

Hereinafter, a reverse power control method of a mobile communication system to which a variable value according to the present invention is applied will be described in detail with reference to the accompanying drawings.

4 is a diagram illustrating a reverse power control method of a mobile communication system to which a variable value according to the present invention is applied.

First, in the step of setting the reference signal-to-noise ratio (S1), the base station sets a reference signal-to-noise ratio for comparison with the signal-to-noise ratio of the received signal in order to effectively perform the reverse power control.

After the reference signal-to-noise ratio setting step S1, the process proceeds to the signal-to-noise ratio calculation step S2 of the received signal. The base station receives the received signal according to the reverse traffic channel from the mobile station every 1.25 ms, and calculates the signal-to-noise ratio of the received signal. .

After the signal-to-noise ratio calculation step (S2) of the received signal proceeds to the signal-to-noise ratio comparison step (S3) to calculate the reference signal-to-noise ratio set in the reference signal-to-noise ratio setting step (S1) and the signal-to-noise ratio calculation step (S2) of the received signal. The signal-to-noise ratio of the received signal is compared.

When the signal-to-noise ratio of the received signal calculated in the signal-to-noise ratio calculation step (S2) of the received signal is higher than the reference signal-to-noise ratio set in the reference signal-to-noise ratio setting step (S1) as a result of the comparison in the signal-to-noise ratio comparison step (S3) Proceeding to the confirmation step S4, it is determined whether it is continuously high.

As a result of the confirmation of the continuous checking step (S4), if the signal-to-noise ratio of the received signal calculated in the signal-to-noise ratio calculation step (S2) of the received signal is continuously higher than the reference signal-to-noise ratio set in the reference signal-to-noise ratio setting step (S1) The power control bit '11' transmission step (S5) proceeds to step S5 of the four modulation values that can be made into two modulation symbols of the forward power control group of '11' modulation symbol value, that is, the power control bit in the forward traffic channel And transmits to the mobile station if it is not continuously high, and proceeds to the power control bit '10' transmission step (S6), where '10' of the four variable values that can be made by the two modulation symbols of the forward power control group. A modulation symbol value, i.e., a power control bit, is punctured in the forward traffic channel and transmitted to the mobile station.

As a result of the comparison in the signal-to-noise ratio comparison step S3, when the signal-to-noise ratio of the received signal calculated in the signal-to-noise ratio calculation step S2 of the received signal is lower than the reference signal-to-noise ratio set in the reference signal-to-noise ratio setting step S1, continuous The process proceeds to the checking step S7 to determine whether it is continuously low.

As a result of the confirmation of the continuous checking step (S7), if the signal-to-noise ratio of the received signal calculated in the signal-to-noise ratio calculation step (S2) of the received signal is not continuously lower than the reference signal-to-noise ratio set in the reference signal-to-noise ratio setting step (S1) The power control bit '01' is transmitted to the step S8 and the modulation symbol value of '01', that is, the power control bit, is converted into the forward traffic channel. And transmits to the mobile station, and if it is continuously low, proceeds to the power control bit '00' transmission step (S9), where '00' of the four variable values that can be generated by the two modulation symbols of the forward power control group A modulation symbol value, i.e., a power control bit, is punctured in the forward traffic channel and transmitted to the mobile station.

After the power control bits '11', '10', '01', and '00' transmission steps (S5, S6, S8 and S9), the mobile station proceeds to the transmission power adjusting step (S10) and the mobile station controls the power control bits '11'. In the case of receiving the power control bit of '11' transmitted in the transmission step S5, the transmission power is reduced in units of -2 dB, and the power of the '10' transmitted in the power control bit '10' transmission step S6. When receiving the control bit, the transmit power is reduced by -1dB.

When the mobile station receives the power control bit of '01' transmitted in the power control bit '01' transmission step (S8), the mobile station increases the transmission power in + 1dB units and transmits the power control bit '00'. When receiving the power control bit of '00' transmitted in S9, the transmission power is increased in units of +2 dB.

As described above, in the present invention, since the delay time of the power control command is two power control groups (2.5 ms) (where the minimum unit 1.25 ms in which power control takes place is called a power control group (comprised of 24 modulation symbols)). The power control bit received at is the power compensation value for the transmission signal transmitted from the base station 2.5ms ago.

Therefore, when the signal-to-noise ratio of the first received signal is lower than the reference signal-to-noise ratio, the base station is not sure whether the current radio environment is short Term fading, so it sends a + 1dB increase command to the mobile station. For example, if the signal-to-noise ratio of the received signal is continuously low, the current radio environment is regarded as short-term fading, and a + 2dB increase command is transmitted to the mobile station to prevent burst error to reduce the error from the reference signal-to-noise ratio. do.

After that, if the signal-to-noise ratio of the received signal is higher than the reference signal-to-noise ratio, a -1 dB decrease command is transmitted to the mobile station, and if it is continuously increased, the call quality capacity of other mobile stations in the base station can be kept good. Make sure

As described above, the present invention is a variable value of four cases that can be made of two modulation symbols of the forward power control group in the reverse power control of the mobile communication system, that is, '11', '10', '01', The power control bit of '00' is applied to increase and decrease the mobile station's transmit power in -2dB, -1dB, + 1dB, + 2dB units so that the reverse power control can be quickly and accurately adjusted even in the fast fading environment with rapid change. It can be performed, thereby reducing the error of the reference signal-to-noise ratio can provide a good call quality.

Claims (1)

A reference signal-to-noise ratio setting step of setting a reference signal-to-noise ratio for comparison with a signal-to-noise ratio of a received signal at a base station; A signal-to-noise ratio calculation step of receiving a received signal from the mobile station every 1.25ms at the base station after performing the reference signal-to-noise ratio setting step, and calculating the signal-to-noise ratio of the received signal; A signal-to-noise ratio comparison step of comparing the signal-to-noise ratio of the received signal calculated in the signal-to-noise ratio calculation step of the received signal with the reference signal-to-noise ratio set in the reference signal-to-noise ratio setting step; When the signal-to-noise ratio of the received signal calculated in the signal-to-noise ratio calculation step of the received signal is higher than the reference signal-to-noise ratio set in the reference signal-to-noise ratio setting step, the signal-to-noise ratio of the received signal is the reference. Transmitting power for transmitting a power control bit of '11' to the mobile station if it is continuously higher than the signal-to-noise ratio, and transmitting a power control bit of '10' to the mobile station if the signal-to-noise ratio of the received signal is not continuously higher than the reference signal-to-noise ratio. Power control bit transmission step for reduction, When the signal-to-noise ratio of the received signal calculated in the signal-to-noise ratio calculation step of the received signal is lower than the reference signal-to-noise ratio set in the reference signal-to-noise ratio setting step, the signal-to-noise ratio of the received signal is the reference. Transmitting power for transmitting the power control bit of '01' to the mobile station if it is not continuously lower than the signal-to-noise ratio, and transmitting the power control bit of '00' to the mobile station if the signal-to-noise ratio of the received signal is continuously lower than the reference signal-to-noise ratio. Power control bit transmission step for increase, When the mobile station receives the power control bit of '11' transmitted in the power control bit transmission step for reducing the transmission power, the transmission power is decreased by -2 dB, and when the power control bit of the '10' is received. A transmit power reduction control step of reducing transmit power in units of -1 dB; When the mobile station receives the power control bit of '01' transmitted in the power control bit transmission step for increasing the transmission power, the transmission power is increased by +1 dB, and when the power control bit of 00 'is received, the + A reverse power control method of a mobile communication system using a variable value, characterized in that the control step of increasing the transmission power to increase the transmission power in 2dB units.