KR100515416B1 - Common power control channel control method in mobile communication system - Google Patents

Abstract

The present invention relates to a common power control channel control method in a mobile communication system.

The present invention includes the steps of receiving a data rate, a start offset value, a subchannel selection signal, and receiving a power control signal through an I channel and a Q channel; Determining a range of effective power control subchannels according to the data rate, start offset value, and subchannel selection signal; And storing and outputting a power control signal selectively in an I channel and a Q channel input buffer based on the start offset value.

Accordingly, the present invention provides a buffer resource of a system by storing and outputting a power control signal through an input buffer having a resource within a range of a valid power control subchannel regardless of a data rate in a common power control channel in a mobile communication system. In addition to reducing the efficiency of the buffer, the efficiency of using the buffer is improved.

Description

Common power control channel control method in mobile communication system {COMMON POWER CONTROL CHANNEL CONTROL METHOD IN MOBILE COMMUNICATION SYSTEM}

The present invention relates to a common power control channel (CPCCH) in a mobile communication system, in particular, when implementing a common power control channel in a mobile communication system, a range of effective power control subchannel regardless of data rate The present invention relates to a method for controlling a common power control channel in a mobile communication system that minimizes buffer resources of a system and improves efficiency of buffer use by storing and outputting a power control signal through an input buffer having internal resources. .

FIG. 1 is a block diagram illustrating a configuration of a common power control channel in a conventional mobile communication system. As shown in FIG. 1, a start offset value allocated to a common power control subchannel index from '0' to 'N-1' is shown. A first multiplexer 10 for receiving and multiplexing a power control signal through an I channel having an initial offset; A second multiplexer 11 for receiving and multiplexing a power control signal through a Q channel having a start offset value assigned as a common power control subchannel index from 'N' to '2N-1'; Relative offset calculator (Relative) for controlling the first and second multiplexers (10,11) by determining the start offset value at the start of the transmission of the power control signal input to the first and second multiplexers (10,11) Offset Calculation 12), the operation of the conventional apparatus configured as described above will be described with reference to the table of FIG.

One power control channel has an offset value of N bits in both the I and Q channels to determine the start channel of the power control signal transmission.

And, the index of common power control subchannels from '0' to '2N-1' is assigned to the N bit offset value of each channel, and from '0' to 'N-1', common power control for I channel. The subchannels are indexed, and from 'N' to '2N-1', the common power control subchannels are indexed to the Q channel.

That is, the start offset value of the I channel has the same value as the index of the common power control subchannel from '0' to 'N-1', and the start offset value of the Q channel is the index of the common power control subchannel. It is '0' when 'N' and 'N-1' when the index is '2N-1'.

Accordingly, the first multiplexer 10 receives and multiplexes the power control signal input through the I channel as a start offset value allocated to the common power control subchannel index from '0' to 'N-1', and secondly. The multiplexer 11 receives and multiplexes the power control signal input through the Q channel as a start offset value assigned as a common power control subchannel index from 'N-1' to '2N-1'.

In addition, the power control signals multiplexed through the first and second multiplexers 10 and 11 may include symbol repetition, mapping, channel gain, etc. according to the presence or absence of transmit diversity (TD). Output after processing

In this case, the relative offset calculator 12 may control the power control signals inputted to the first and second multiplexers 10 and 11 to start transmission for processing of the symbol repetition, mapping, and channel gain. The start offset value of the channel is determined, and accordingly, the first and second multiplexers 10 and 11 are controlled to multiplex and output a power control signal input through the determined power control subchannel.

In general, the data rate of the common power control channel is 800 bps, 400 bps, 200 bps, as shown in FIG. 2, and the number of power control subchannels required in each case is the sum of the I and Q channels. There are 24, 48, and 96, each having the same number of power control subchannels for the I and Q channels.

In addition, the periods corresponding to the data rates are 1.25 ms, 2.5 ms, and 5 ms.

Since the data rates of the common power control channel are 800 bps, 400 bps, and 200 bps, a buffer is needed to store the power control signals input through the subchannels according to the number of power control subchannels 24, 48, and 96. The common power control channel includes a buffer for storing power control signals input through 96 power control subchannels and stores the input power control signals.

Even if the data rate of the common power control channel changes, the buffer stores all the power control signals input through the power control subchannel, and is then controlled by a controller of the system, and controls a certain number of powers during the period according to the data rate. Output the power control signal through the subchannel.

That is, in general, the common power control channel has periods of 1.25 ms, 2.5 ms, and 5 ms at data rates of 800 bps, 400 bps, and 200 bps, respectively, so that up to 24, 48, 96 power control subchannels are present during each period. Transmit the power control signal through.

For example, when the data rate is 200 bps, since the largest channel resource is required for power control signal transmission through the common power control channel, the size of the buffer can also store the power control signal input through 96 subchannels. To the extent possible, it uses the most buffer resources.

The buffer stores all power control signals input through 96 subchannels, and then controls power through a predetermined number of power control subchannels for a period of 1.25 ms according to a data rate under the control of a controller of the system. Outputs a signal and deletes a power control signal that does not output.

Then, the relative offset calculator 12 determines the start offset value to start the transmission of the power control signal stored in the buffer to control the first and second multiplexers 10 and 11.

 The first and second multiplexers 10 and 11 select power control subchannels of I and Q channels to be multiplexed based on the determined start offset value under the control of the relative offset calculator 12. The power control signal inputted through the selected power control subchannel is multiplexed.

As described above, in the conventional technology, the common power control channel in the mobile communication system is allocated according to the data rate after storing all the power control signals inputted through the power control subchannel in the buffer, even if the data rate varies. When the data rate is high, the remaining resources of the unused buffers are wasted when the data rate is high, and when the data rate is low, unnecessary power control signals are stored in the buffer, thereby reducing the buffer usage efficiency. Due to the hardware implementation, there was a problem that the system volume and manufacturing cost increases.

Accordingly, the present invention has been proposed to solve the above-mentioned problems. In the common power control channel in a mobile communication system, power is supplied through an input buffer having resources within a range of a power control subchannel effective regardless of data rate. The purpose of the present invention is to provide a method of minimizing a buffer resource of a system required by storing and outputting a control signal and improving the efficiency of using a buffer.

According to an aspect of the present invention, there is provided a data transmission rate, a start offset value, a subchannel selection signal, and a power control signal through an I channel and a Q channel; Determining a range of effective power control subchannels according to the data rate, start offset value, and subchannel selection signal; And storing the power control signal selectively in the I channel and the Q channel input buffer based on the start offset value.

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

3 is a block diagram showing the configuration of a device implementing the common power control channel control method in the mobile communication system according to the present invention. As shown therein, the I-channel and Q-channel input buffers (30, 31), the first and the first channel are shown. It consists of two multiplexers 32 and 33 and a relative offset calculation unit 34.

The I and Q channel input buffers 30 and 31 receive a data rate, a start offset value, a sub channel selection signal, and the like from a control unit of the system, and determine a range of a valid power control subchannel to determine an I channel within the range. And storing the power control signal input through the Q channel, and outputting the power control signal through a power control subchannel allocated to a predetermined number of start offset values.

That is, the output cycle of the stored data and the number of power control subchannels are determined by the data rate and the start offset value input from the control unit of the system, and the start offset value that is started during transmission is specified. Optionally stores a valid power control subchannel to be transmitted around the specified start offset value in a buffer.

The first and second multiplexers 32 and 33 multiplex power control signals input through the I and Q channel input buffers 30 and 31, and the first and second multiplexers 32 and 33. The multiplexed power control signal is output through the process of symbol repetition, mapping, channel gain, etc. according to the presence or absence of transmit diversity (TD).

In this case, the relative offset calculator 34 controls the power control signal to be transmitted for processing the symbol repetition, mapping, channel gain, etc. with respect to the power control signals input to the first and second multiplexers 32 and 33. A start offset value of the subchannel is determined, and accordingly, the first and second multiplexers 32 and 33 are controlled to multiplex and output a power control signal input through the determined power control subchannel.

In addition, according to the setting of the system operator, the data rate of the common power control channel can be changed to 800 bps, 400 bps, and 200 bps. In the case of 200 bps, power control signals are transmitted through 96 power control subchannels during a 5 ms period. Therefore, power control signals are transmitted through 24 power control subchannels during a period of 1.25 ms.

When the data rate is 400 bps, power control signals must be transmitted through 48 power control subchannels during a period of 2.5 ms. Therefore, power control signals are also transmitted through 24 power control subchannels during a period of 1.25 ms. Done.

In addition, the power control signal transmitted through the 24 power control subchannels is equal to the data amount of the power control signal through the 24 power control subchannels to be transmitted for a period of 1.25 ms when the data rate is 800 bps. .

That is, during the same period, the same bit data is transmitted regardless of the data rate of the common power control channel, and in general, the number of power control subchannels required for 1.25 ms is 24 at all data rates.

Therefore, the I and Q channel input buffers 30 and 31 store the power control signals input through the I and Q channels within the range of the effective power control subchannel determined by the controller regardless of the data rate. The stored power control signal is output based on the start offset value selected by the controller.

Here, the range of the effective power control subchannel is determined within the range of the number of power control subchannels in which the I channel and the Q channel transmitted during the period when the data rate is maximum, and the range is within the storage capacity of the buffer. Is determined.

For example, when the data rate is 800bps, the data transmission period is 1.25ms, and since the number of the power control subchannels in which I and Q channels are 24 is 24, the I and Q channel input buffers 30 31 stores and then outputs a power control signal transmitted through 24 valid power control subchannels every 1.25 ms.

Meanwhile, referring to the flowchart of FIG. 4, an operation process of the present invention will be described. First, the I channel and Q channel input buffers 30 and 31 select a data rate, a start offset value for each channel, and a sub channel from the control unit of the system. Receive a signal (S40).

The I and Q channel input buffers 30 and 31 receive a power control signal through the I and Q channels (S41).

Storing the power control signal input through the I channel and the Q channel only within a range of the effective power control subchannel, centered on the start offset value specified according to the input data rate, start offset value, and subchannel selection signal; The stored power control signal is output (S42, S43).

As described above, the present invention provides a system by storing and outputting a power control signal through an input buffer having a resource within a range of a valid power control subchannel regardless of a data rate in a common power control channel in a mobile communication system. In addition to reducing the buffer resources of the system, the efficiency of using the buffer is improved.

1 is a block diagram showing a configuration of a common power control channel in a conventional mobile communication system.

2 is a table showing the period and number of subchannels according to data rate in a common power control channel in a conventional mobile communication system.

Figure 3 is a block diagram showing the configuration of an apparatus implementing the common power control channel control method in the mobile communication system of the present invention.

4 is a flowchart illustrating an operation process of a method of controlling a common power control channel in a mobile communication system of the present invention.

*** Description of the symbols for the main parts of the drawings ***

30: I channel input buffer 31: Q channel input buffer

32: first multiplexer 33: second multiplexer

34: relative offset calculation unit

Claims (3)

Receiving a data rate, a start offset value, a subchannel selection signal, and receiving a power control signal through an I channel and a Q channel; Determining a range of effective power control subchannels according to the data rate, start offset value, and subchannel selection signal; And storing and outputting a power control signal selectively in an I channel and a Q channel input buffer based on the start offset value. The method of claim 1, wherein the valid power control subchannel is determined within a storage capacity range of an I-channel and a Q-channel input buffer. The I-channel and Q-channel input buffers according to claim 1 or 2, wherein the I-channel and Q-channel input buffers are the number of power control subchannels of the I-channel and the Q-channel transmitted during the period when the data rate is maximum, regardless of the variable data rate. The storage capacity is determined by the sum of the common power control channel control method in a mobile communication system.