RU2124809C1 - Device and method for monitoring of emission power using work load message - Google Patents

Abstract

FIELD: cellular communication network. SUBSTANCE: device has transmitter with variable attenuator and unit for detection of power to be emitted. Corresponding method involves triggering said unit for detection of power to be emitted, receiving measured value of emission power, comparison of emission power to corresponding value for idle channel, and regulation of variable attenuator in order to increase or decrease emission power of said transmitter by level of difference between two said values, in case if they differ. Pilot signal channel, synchronization signal channel and pager channel are used as idle channel. EFFECT: compensation of emission error in transmitter by means of comparison of constant value of idle channel power to measured emission power in channel, generation of optimal emission power. 6 cl, 2 dwg

Description

 The present invention relates to a method and apparatus for monitoring transmission power for a mobile cellular communication system. More specifically, this device relates to a tracking device and a method for optimizing transmission power, in accordance with which the transmission power of the channel is measured and compensated if no workload messages are detected.

State of the art
Typically, mobile cellular communication systems monitor the level of transmitted and received signals to optimize system throughput. One such signal tracking technique is based on the use of a transmit power tracking loop.

 Code Division Multiple Access (CDMA) is one of the methods widely used in modern mobile cellular communication systems. This description describes a mobile cellular communication system using the CDMA method. In a CDMA system, the transmit power of the base station should be constant, although the hardware used may change over time.

 Since the transmission power of each signal transmitted between the base station and the terminal is controlled in a CDMA system, the workload (traffic) changes. In order to check whether the current value of the transmit power by the base station is precisely set, this transmit power is calculated taking into account all the elements that affect the transmit power, including the amount of traffic, traffic activity, digital gain, channel overhead information , amplification for transmission at the radio frequency, and then the obtained value is compared with the real value.

 When this operation is performed, the data processed by each processor is collected by a specific processor, which performs processing in accordance with some algorithm for tracking transmit power. To use the results of the algorithm, a message about the change in gain must be transmitted to the processor, which controls the gain during transmission.

The above-described known method for calculating transmit power can be represented by the following formula:
((PiG) ² + (SyG) ² + (PaG) ² = ((TG) ² • VA)) (1)
Where
PiG is the digital gain of the pilot channel, SyG is the digital gain of the clock channel, PaG is the digital gain of the paging channel, TG is the digital gain of the traffic channel, and VA is the speech activity of the traffic channel. PiG, SyG and PaG for non-productive load channels have constant values determined during system installation. TG and VA are variables that change as power is controlled with a predetermined time period (20 ms in this example). The amount of traffic is thus a variable. When tracking transmission power using formula (1), the corresponding operations must be performed every 20 ms. This mode of operation leads to a significant load on the transmitter.

 With the described known method using a transmission power tracking loop in a CDMA system, a large amount of data is transmitted between a plurality of processors, the processors perform complicated processing algorithms when monitoring the transmission power. Such a large amount of processed data and complex processing algorithms lead to high computational costs in the system. This problem of unnecessarily high load can be solved by increasing the time interval between operations performed in the transmission power tracking loop. However, nevertheless, a large amount of data is transferred between the processors during operations in the transmission power monitoring loop, without reducing the amount of data or computational operations performed, so that interference may occur between the units that make up the system.

 To solve the above problem, the transmit power can be calculated using fixed values for the channels according to formula (1). If the transmit power of a CDMA system transmitter is monitored using PiG, SyG, and SyG gains of the overhead channels, such as the pilot channel, the clock channel, and the paging channel, then the above problem could be solved. Using this method, the transmit power of the transmitter of the base station is measured using the above fixed values. Since the transmit power of the base station transmitter is calculated from the already known overhead channel information, data transfer or processing operations to calculate the transmit power are no longer required when performing operations in the transmit power tracking loop by measuring the transmit power of the channels and comparing the measured transmit power with constant power transmit channels overhead when traffic messages are not detected. When using this method, the transmission power of the channel is constant when there is no traffic, therefore, there is no need to synchronize the blocks with each other every 20 ms.

SUMMARY OF THE INVENTION
An object of the present invention is to provide a device and method for generating optimum transmit power in a mobile cellular communication system by comparing a reference transmit power with a measured value for a channel where no traffic messages are detected.

 In addition, an object of the invention is to provide a device and method for generating stable transmission power by comparing a constant channel power of an overhead load with a measured transmission power of a channel where no traffic messages are detected and compensating for transmission errors in the transmitter.

 To solve these problems of the present invention, there is provided a method for monitoring transmission power for a mobile cellular communication system comprising a transmitter with a variable attenuator and a transmitter power determination unit. The method includes initiating said block in the absence of traffic messages, receiving transmit power, comparing the transmit power with the corresponding value for the overhead channel, and controlling the variable attenuator to increase or decrease the transmit power of the radio signal by the difference between the two values if the two values do not match.

Brief Description of the Drawings
The invention is illustrated by the example of its implementation, illustrated by drawings, which show the following:
FIG. 1 is a block diagram of a transmission system for monitoring transmission power in accordance with the invention;
FIG. 2 is a flowchart of a power tracking method according to the invention.

Detailed Description of a Preferred Embodiment
As shown in FIG. 1, the main controller 11 is a main processor that performs operations in a transmit power tracking loop. The main controller 11 compares the transmit power, measured under the condition that no traffic messages are detected, with the corresponding value for the overhead channel, and then compensates for the error. Signal processing unit 12 is a digital unit receiving an RF signal from a transmitter of a base station. The signal processing unit 12, which consists of a channel element, a modem and a signal processing controller, imposes modulation of digital signals on the transmitted signals. The transmitting unit 13 receives the transmitted signal from the signal processing unit 12, converts it with increasing frequency to form a radio frequency signal. The transmitting unit 13 contains a variable attenuator 10 at its output terminal. The variable attenuator 10 controls the amplification of the radio frequency signal in accordance with the control commands generated by the main controller 11. The amplifier 14 amplifies the radio frequency signal transmitted by the transmitting unit 13. The amplifier 14 is a linear power amplifier. A communication device 15 connecting the amplifier 14 to the antenna outputs a radio frequency signal from the amplifier 14. As a communication device 15, a directional coupler can be used. The unit for determining the transmitted power 16 determines the electric power of the radio frequency signal transmitted by the communication device 15.

 In FIG. 2 is a flowchart illustrating an error compensation procedure after measuring a transmission power of a radio frequency signal generated by a transmitter in accordance with the present invention. The main controller processes in accordance with this procedure.

With reference to the transmission power tracking procedure illustrated in FIG. 1 and 2, the operation of the preferred embodiment of the present invention is described below. In the method using the transmit power tracking loop of the invention, the controller obtains a fixed transmit power when no traffic messages are detected in the transmitter, and then it is determined whether to adjust the transmit power. With this method, there is no need to perform complex data manipulations or calculations, since the transmission power is monitored by comparing the transmission power values that are already known and measured. In a preferred embodiment, the transmit power is calculated using the following formula:
((PiG) ² + (SyG) ² + (PaG) ² ) (2)
Where
PiG is the digital gain of the pilot channel, SyG is the digital gain of the clock channel, PaG is the digital gain of the paging channel. PiG, SyG, and PaG for non-performing download channels have constant values defined during system installation. Therefore, due to the fact that the transmission power of the base station, which is constant in the absence of traffic, is already known, the tracking procedure in the transmission power circuit can be effectively performed if there is no traffic.

 In a preferred embodiment of the invention, the channel element transmits information when there is frequency in the channel in the absence of traffic to the controller 11, which is a processor that performs the tracking procedure in the transmit power loop. The main controller 11 performs this procedure when it receives messages about the absence of traffic messages. The main controller 11 uses the current transmit power value determined by the transmit power determination unit 16, checks whether the value of the received transmit power and the power value of the overhead channel are matched by comparing them, and then adjusts the variable attenuator 10 in the transmitting unit 13 to compensate for the error.

 The main controller 11 analyzes the traffic message transmitted by the channel element in the signal processing unit 12 (step 211). If the main controller 11 receives a message about the absence of traffic from the signal processing unit 12 (step 213), it initiates a tracking procedure in the transmit power circuit by controlling the transmit power determination unit 16 to determine the transmit power of the radio frequency signal generated by the transmitter (step 215). The main controller 11 sends attenuation control commands for the corresponding channel to the variable attenuator 10. The transmitting unit 13 generates a channel radio frequency signal, and the variable attenuator 10 adjusts the gain of the transmitted signal in accordance with the attenuation control data. The transmit power determination unit 16 determines the transmit power transmitted by the communication device 15, and transmits information about it to the main controller. The main controller 11 receives the value of the transmit power of the radio frequency signal, which is actually measured by the transmit power determination unit 16 (step 217). It compares the measured transmit power with the corresponding value for the overhead channel (step 219). If it is determined at step 219 that the two values are the same, then the main controller 11 determines that the transmit power is normal (step 221) and stores the current attenuation control data to its previous value (step 231), and then is reset to re-initiate the above procedure.

 If the measured value and the constant value for the overhead channel do not match, then the main controller 11 determines that an error has occurred (step 221), and sends the attenuation control data corresponding to the error value to the variable attenuator 10 in the transmitting unit 13 (step 223) . Attenuation control to compensate for the error is carried out by increasing or decreasing the signal of the corresponding frequency by the amount of error. The variable attenuator 10 adjusts the gain of the RF signal in accordance with attenuation control commands. The radio frequency signal adjusted by the gain is transmitted to the transmit power determination unit 16 by the communication device 15. The transmit power determination unit 16 measures the transmit power of the radio frequency signal, the gain of which is adjusted, and transmits the result to the main controller 11. The main controller 11 performs steps 225 to 229, which are consistent with steps 217 to 221, for adjusting the transmit power of the radio frequency signal to ensure matching with a fixed value for the channel unproductive load.

 As described above, the present invention provides a comparison of a fixed value for a non-productive load channel with a transmitter transmit power value in the absence of traffic messages therein. If these two values do not coincide, then the transmission power is increased or decreased by the difference between the above two values to optimize the transmission power of the radio frequency signal generated by the transmitter. The present invention eliminates the need for complex data manipulation and calculations, which allows you to generate optimal transmit power quickly and without overloading the system.

 It should be borne in mind that the present invention is not limited to the specific option disclosed above in the framework of the best mode of implementation. The present invention is not limited to the specific embodiments disclosed in the description, but only as defined in the claims.

Claims (6)

 1. A transmission power tracking device for a mobile cellular communication system comprising a transmitter with a variable attenuator and a transmit power determination unit for said transmitter, characterized in that it is capable of activating said transmit power determination unit in the absence of a work load, transmit power reception, comparing this transmit power with the corresponding value for the non-production load channel and control the variable attenuator to increase or smart sheniya transmitter transmit power by the difference of said two values if they do not coincide.  2. The device according to claim 1, characterized in that the pilot channel, the sync channel, and the paging channel are used as the channel of unproductive load.  3. A transmit power tracking device for a mobile cellular communication system, characterized in that it comprises a signal processing unit including a channel element for checking a work load message, a transmitter having a variable attenuator and providing an increase in the frequency of the signal from said signal processing unit for generating a radio frequency signal the transmitted signal, and the variable attenuator is configured to adjust the gain of the transmitted signal in accordance with the control commands is weakened eat, a communication device connected to the output terminal of the transmitter, a unit for determining the transmitted power passing through the communication device, in the process of monitoring, the main controller for receiving information about the transmit power from the unit for determining the transmitted power, when the channel element determines the absence of workload, comparison of transmit power with the appropriate value for the overhead channel and control of the variable attenuator to increase or decrease the transmit power of the transmitter by the difference between the transmit power and the corresponding value of the overhead channel.  4. The device according to claim 3, characterized in that the pilot signal channel, the synchronization channel and the paging channel are used as the said channel of unproductive load.  5. A method for tracking transmission power for a mobile cellular communication system comprising a transmitter with a variable attenuator and a unit for determining transmitted power, characterized in that it includes the steps in which the said unit for determining transmitted power in the absence of a workload is activated, a measured value of the transmit power is obtained, compared transmit power with the corresponding value for the overhead channel and adjust the variable attenuator to increase or decrease the power before chi said radio transmitter on the magnitude of the difference of said two values if the two values do not coincide.  6. The method according to claim 5, characterized in that the pilot channel, the sync channel, and the paging channel are used as said overhead channel.

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