KR19980013942A - Transmission power tracking method using traffic message - Google Patents

Abstract

The transmitter power of the mobile communication system is maintained in the optimized state. In order to achieve the above object, a transmission power tracking method according to an embodiment of the present invention includes a transmitter including a variable attenuator and a circuit for detecting a transmission power of the transmitter. When there is no traffic message, And controls the variable attenuator of the transmitter when the transmission power is not equal to the value of the overhead channel to increase or decrease the transmission power of the transmitter by an error amount.

Description

Transmission power tracking method using traffic message

In general, a mobile communication system tracks the strength of signals transmitted and received in order to optimize the capacity of the system. One of them is a Transmit Power Tracking Loop (TPTL). Among the above mobile communication systems, a CDMA (Code Division Multiplexing Access) system is used. Here, it is assumed that the mobile communication system is a CDMA system. In the CDMA system as described above, it is necessary to accurately know the transmission power so that the transmission power of the base station can always be maintained constant regardless of the hardware change with time.

Since the CDMA system always performs transmission power control between the base station and the terminal, the output of each traffic always changes. Therefore, in order to check whether the current transmission power of the base station is correct, the number of traffic at the measurement time, the traffic activity of each traffic, the digital gain, the overhead channel information, All the factors affecting the transmission power should be collected and calculated, and then the calculated and actual values should be compared. In order to achieve this, data processed by each call processor must be collected in a processor that performs a transmission power tracking algorithm, and a message requesting a gain change to a processor that controls the transmission gain must be transmitted to reflect the performance result.

The conventional transmission power calculation method performed as described above is expressed by Equation (1).

In Equation (1), PiG is the pilot channel digital gain of the pilot channel, SyG is the pilot channel digital gain of the synchronization channel, PaG is the paging channel digital gain of the paging channel, TG is the traffic channel digital gain of the traffic channel, and VA is the traffic channel voice activity of the traffic channel. In Equation (1), PiG, SyG, and PaG output through the overhead channel are constant values determined at system setting. The values of TG and VA are changed every time transmission power control is performed in units of a set period (assumed to be 20 ms in this case) as variable elements, and the number of traffic also changes occasionally. Therefore, when the transmission power is tracked in accordance with Equation (1) and Equation (1), it is performed every 20ms period in which the transmission power control is performed.

Therefore, in the conventional TPTL method performed in the CDMA system, a large amount of data has to be moved between several processors, and the algorithm for tracking the transmission power is also complicatedly performed between the respective processors. Since the calculation amount is large and complex, There was a problem that the load was applied. In general, the characteristics of the communication system do not change suddenly. Therefore, in order to solve the above problems, a method of measuring the TPTL by widening the time period of performing the TPTL can be used. However, such a method also has a problem in that communication can be disturbed between the other blocks constituting the system because the data is moved intensively at the moment of execution without decreasing the amount of data or the calculation amount itself.

In order to solve the above problem, there may be a method of measuring using a set value of channels having a fixed value in Equation (1). That is, if the transmission output of the CDMA transmitter can be tracked using the gains PiG, SyG and PaG of the overhead channel (pilot channel, synchronization channel, paging channel) in Equation 1, the above problem can be solved . In this case, the transmission power of the base station transmitter may be measured using the set values. That is, since the transmission output of the overhead channel of the base station transmitter is a known value, when the transmission power of the corresponding channel is measured without traffic, the measured transmission power is compared with the overhead channel value, No separate data movement or process is required. Also, when the transmission power is controlled by the TPTL method, the value is always constant as long as there is no traffic.

Accordingly, it is an object of the present invention to provide an apparatus and method for controlling transmission power in an optimized state by measuring a transmission power of a corresponding channel in a mobile communication system without a traffic message and comparing the transmission power with a reference value.

It is another object of the present invention to provide a CDMA transmission system that measures a transmission power of a channel when there is no traffic message, compares the measured value with an overhead channel value to obtain an error, compensates a transmission error value of the transmitter, And to provide a device and a method capable of controlling the display device.

According to an aspect of the present invention, there is provided a transmission power tracking method including: a transmitter including a variable attenuator; and a circuit for detecting a transmission power of the transmitter, And a controller for controlling the variable attenuator of the transmitter to increase or decrease the transmission power of the transmitter by an error amount .

1 is a diagram showing a configuration of a transmitter system for tracking transmission power according to an embodiment of the present invention;

Figure 2 is a flow chart illustrating the operation of tracking transmit power in a transmitter system in accordance with an embodiment of the present invention.

FIG. 1 is a block diagram of a transmitter for tracking transmission power in a mobile communication system in the absence of traffic according to an embodiment of the present invention. The controller 11 is a main processor for performing the TPTL, do. The controller 11 performs a control operation to compensate for an error by comparing the measured transmission power with an overhead channel value when there is no traffic message. The signal processing unit 12 is a digital unit excluding a RF part in a base station transmitter and includes a channel element, a modem, and a controller. The signal processing unit 12 modulates a digital signal to be transmitted in a transmission form and outputs the modulated signal. The transmitter 13 receives the transmission signal output from the signal processor 12, upconverts the input transmission signal, and outputs the RF signal. The transmitter 13 has a variable attenuator 10 at its output end, and the variable attenuator 10 adjusts the gain of the RF signal output by the control data output from the controller 11. The amplifying unit 14 amplifies and outputs the RF signal output from the transmitting unit 13. The amplification unit 14 may use a linear power amplifier. The coupling unit 15 is connected between the amplification unit 14 and the antenna, and separates and outputs the RF signal output from the amplification unit 14. The coupling unit 15 may use a directional coupler. A transmit power detector 16 detects the power of a transmission RF signal output from the combining unit 15 and outputs the detected power.

2 is a flowchart illustrating a process of detecting a transmission power of an RF signal finally output from a transmitter and correcting the error when an error occurs according to an embodiment of the present invention. The flow chart of FIG. 2 is performed by the controller 11.

The operation of the embodiment of the present invention will be described with reference to the transmitter configuration of FIG. 1 and the transmission power tracking algorithm of FIG. 2. The TPTL according to the present invention transmits a known value in the absence of traffic in the transmitter and detects whether or not an error has occurred in the transmission power. In other words, it is not necessary to move or calculate complex data to track the transmission power, but merely compare the known and actual measured values. In the embodiment of the present invention, the transmission power is calculated as shown in Equation (2).

In Equation 2, PiG is the pilot channel digital gain of the pilot channel, SyG is the pilot channel digital gain of the synchronization channel, and PaG is the paging channel digital gain of the paging channel. In Equation (2), PiG, SyG, and PaG output through the overhead channel are constant values determined at system setting. Therefore, as described above, since the transmission output of the base station in the absence of traffic is already known and its value is always constant as long as there is no traffic, the TPTL can be efficiently performed in the absence of traffic using the overhead channel value .

To this end, in the embodiment of the present invention, when there is no traffic at a frequency in the channel element in the previous TPTL structure, this information is transmitted to the controller 11 which is a processor that performs TPTL. At this time, if it is notified that the traffic message is absent, the controller 11 executes the TPTL. When the TPTL is executed, the current transmission power detection value output from the transmission output detection unit 16 is input, and the detected transmission power is compared with the overhead channel value to check whether the theoretical value and the actual value coincide with each other. The variable attenuator 10 of the transmitter 13 is controlled to correct the error value.

The controller 11 checks the traffic message output from the channel element of the signal processor 12 in step 211. [ If it is notified that there is no traffic message in the channel element of the signal processing unit 12, the controller 11 detects it in step 213 and controls the transmission power detector 16 corresponding to step 215 to transmit the transmission power of the RF signal output from the transmitter , And performs TPTL. When the TPTL is performed, the control unit 11 outputs the attenuation control data of the corresponding channel, the transmitting unit 13 generates the RF signal of the corresponding channel, and the variable attenuator 13 outputs the attenuation control data according to the attenuation control data Adjusts the gain of the transmission signal and outputs it. The transmission power detector 16 detects the transmission power output from the combining unit 15 and outputs the detected transmission power to the controller 11. In step 217, the controller 11 receives the power detection value of the actually measured transmission RF signal output from the transmission power detector 16. In step 219, the controller 11 compares the measured transmission power value with the overhead channel value of the system. At this time, if the measured value and the channel value of the overhead are compared with each other, the controller 11 detects normal transmission power, and in step 231, the current attenuation control data is maintained as it is, and the TPTL terminates and returns.

However, if the comparison result shows that the measured value of the transmission power differs from the overhead channel value, the control unit 11 detects that the transmission power error has occurred in step 221, generates the attenuation control data corresponding to the error value in step 223, To the variable attenuator 13 of the transmitter 13. Here, the attenuation control data is data in which the gain of the frequency is increased or decreased by an error so as to compensate for the error with the set transmission power. Then, the variable attenuator 13 adjusts the frequency gain of the corresponding RF signal by the attenuation control data. Then, the gain-adjusted RF signal is applied to the transmission power detector 16 by the coupling unit 15, and the transmission power detector 16 detects the transmission power of the RF signal and transmits the detected transmission power to the controller 11. At this time, the transmission power of the RF signal output from the transmission power detector 16 is in a state in which the gain is adjusted by the attenuation control data.

Then, the controller 11 performs steps 225 through 229 to compare the transmission power value of the adjusted RF signal with the overhead channel value to check whether they match. This is to match the transmit power of the RF signal with the overhead channel value in the absence of traffic messages.

As described above, in the embodiment of the present invention in which the transmitter of the mobile communication system tracks the transmission power and controls the transmission power in an optimized state, it checks the presence or absence of a traffic message, receives the current transmission power of the corresponding transmitter when there is no traffic message , And compares the received transmission power with the set overhead channel value. If the two values do not match, the transmission power of the transmitter is optimized by controlling the output gain of the transmitter by increasing or decreasing by a corresponding error amount. Therefore, the transmission power tracking method according to the embodiment of the present invention compensates the transmission power by comparing an already known value and an actually measured value without performing movement or calculation of complicated data for tracking transmission power, It is possible to maintain the transmission power in an optimized state in a short time.

Claims (6)

A transmission power tracking apparatus of a mobile communication system, comprising: a circuit connected to an output terminal of a transmitter for detecting a transmission power of a transmitter; when there is no traffic message, the transmission power detection circuit drives the transmission power detection circuit to receive current transmission power, And comparing the transmission power with a value of an overhead channel to control the variable attenuator of the transmitter when the transmission power is not identical to increase or decrease the transmission power of the transmitter by an error amount. The apparatus of claim 1, wherein the overhead channel is a pilot channel, a synchronization channel, and a paging channel. A transmission power tracking apparatus for a mobile communication system, the apparatus comprising: a signal processing unit having channel elements and outputting a presence or absence of a traffic message; a variable attenuator for up-converting a signal output from the signal processing unit, And a variable attenuator for adjusting the gain of the transmission signal by the attenuation control data, a coupling unit connected to an output terminal of the transmitter, and a power detector for detecting power of a transmission signal output from the coupling unit during tracking control A transmission power detector for detecting a transmission power from the transmission power detector when the channel element indicates that there is no traffic message in the channel element and comparing the transmission power with an overhead channel value to control the variable attenuator, And a control section for increasing or decreasing the transmission power of the transmitter by an error amount Transmit power tracking system of a mobile communication system, characterized by. The apparatus of claim 3, wherein the overhead channel is a pilot channel, a synchronization channel, and a paging channel. A transmission power tracking method of a mobile communication system including a transmitter having a variable attenuation and a circuit for detecting a transmission power of the transmitter, the method comprising: operating the transmission power detection circuit when there is no traffic message, And comparing the transmission power with a value of an overhead channel to control the variable attenuator to increase or decrease the transmission power of an RF signal output from the transmitter by an error amount. Tracking method. The method of claim 1, wherein the overhead channel is a pilot channel, a synchronization channel, and a paging channel.