KR100409118B1 - Method for Allocating Compensated Transmission Velocity in Mobile Communication System - Google Patents

Abstract

The present invention relates to a method for assigning a compensated transmission rate in a mobile communication system.

Therefore, in the present invention, the terminal converts the received electric field strength into digitized data and reports the value to the base station, and the base station calculates a data rate control (DRC) value using the data value. The process consists of measuring the transmission rate, comparing the current average transmission rate with the calculated transmission rate, and then assigning a compensated transmission rate when the transmission rate is lower than the average value.

Accordingly, the present invention can improve the data transmission speed of a subscriber having a low data transmission rate by changing only the algorithm between the terminal and the base station without configuring an additional system in the mobile communication system.

Description

Compensated transmission rate allocation method in mobile communication system {Method for Allocating Compensated Transmission Velocity in Mobile Communication System}

The present invention relates to a transmission rate allocation method in a mobile communication system, and more particularly, to a method of allocating a compensated transmission rate by comparing a transmission rate obtained by calculating a digitized electric field strength sent from a terminal to an average transmission rate of a base station. It is about.

In the current 1xEV-DO mobile communication system, the forward direction is defined to be capable of 2.4576Mbps and the reverse direction is possible to 153.6kbps.

In particular, 1xEV-DO is optimized for high-speed packet transmission and uses the CDMA channel 1.25MHz, which is the same frequency band as current CDMA ONE or CDMA2000 systems.

According to Qualcomm's test results, about 15 people can transmit data of average 670kbps to one base station. This maximizes the use of the wireless section and system by dynamically allocating the transmission rate of the subscriber and making the most of the dormant mode, which is a unique characteristic of packet data.

In 1xEV-DO system, the omni-directional transmission speed is determined by the data rate control (DRC) value calculated by the propagation environment of the terminal, that is, the electric field strength. The terminal accurately measures the signal to noise ratio (SNR), that is, the carrier to interface (C / I) of the pilot channel, and requests the data transmission rate of the omni-directional data to the base station through the DRC channel. When this is received by the base station, one of 12 packet formats (38.4 kbps to 2.4576 Mbps) is allocated.

1 illustrates a transmission rate allocation process in a conventional mobile communication system.

Referring to FIG. 1, the terminal 110 calculates a DRC value by measuring an electric field strength of a forward pilot channel, and requests an omnidirectional data transmission rate from the base station 120 using the DRC channel. )

When the base station 120 receives this, one of 12 packet formats (38.4 kbps to 2.4576 Mbps) is allocated. In addition, the base station 120 transmits data to the terminal 110 at a transmission rate corresponding to the received DRC value.

The forward packet format is transmitted in units of 26.67 ms, and each packet has 16 slots. 1,2,3,4 or 16 slots can be used depending on the transmission speed. When the terminal 110 receives the packet in all directions, the terminal transmits a NAK until the third response. From the fourth, if it is received normally, it sends ACK or NAK.

In fact, in 1xEV-DO, the transmission speed is determined by reporting the electric field strength of the terminal on a packet basis.

As such, in the omni-directional channel of 1xEV-DO, there are pilot channels and control channels that are periodic at a fixed total energy level, and the remaining parts are dynamically allocated time slots according to the distribution and propagation environment of the subscriber. . In addition, the transmission speed is determined by the electric field strength of the terminal. That is, when the surrounding radio wave environment of the subscriber is poor, the subscriber's terminal requires a low transmission rate from the base station, so the data transmission rate is low. This means that unless the subscriber's radio environment is improved, the transmission rate is inevitably low.

Accordingly, an object of the present invention is to provide a method for compensating and allocating a transmission rate of a base station in a mobile communication system.

In order to achieve the above object, the present invention obtains a transmission rate by receiving the electric field strength of a subscriber as digitized data in a mobile communication system, and compensates for a transmission rate of a subscriber having a low transmission rate compared to an average transmission rate of a base station. It features.

The present invention converts the received electric field strength into digitized data and reports the value to the base station, and the base station calculates a data rate control (DRC) value using the data value to determine the transmission rate. Measure, compare the current average transmission rate with the calculated transmission rate, and assign a compensated transmission rate if the average transmission rate is lower than the average value.

That is, the present invention calculates a DRC value by receiving the information on the radio wave environment of the terminal and calculating the DRC value, which is lower than the average value compared to the average transmission rate calculated in consideration of the distribution and the radio wave environment of the subscribers distributed in the base station. In this case, an improved transmission rate is allocated by compensating for the transmission rate.

To this end, in the present invention, the terminal converts the received electric field strength into digitized data and reports the value to the base station, and the base station calculates a DRC value using the data value to measure the transmission rate and Comparing with the current average transmission rate and then lowering the average value, a process of allocating a compensated transmission rate is necessary.

More specifically, the present invention includes the steps of converting the radio wave environment into digitized data in the terminal and transmitting to the base station; Converting, by a base station, data transmitted from the terminal into a data rate control value and storing the data in a buffer; Obtaining an average transmission rate at the base station and comparing the average transmission rate with a transmission rate determined by a data rate control value stored in the buffer; Compensating for the transmission rate if the transmission rate compared at the base station is lower than the average transmission rate; Transmitting data to the terminal at the compensated transmission rate.

1 is a conventional transmission rate allocation procedure diagram.

2 is a compensated transmission rate allocation procedure in accordance with the present invention.

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

2 is a compensated transmission rate allocation procedure diagram according to the present invention.

Referring to FIG. 2, in operation 211, the terminal 210 measures a received electric field strength received through a pilot channel and converts it to digitized data. In step 212, the terminal 210 transmits the converted data value to the base station 220 through the DRC channel.

Then, in step 213, the base station 220 calculates a DRC value using the received data, and in step 214, the base station 220 stores the value in a buffer.

In step 215, the base station 220 calculates an average transmission rate value for every packet in consideration of the distribution of subscribers around the base station and the propagation environment. In step 216, the base station 220 retrieves the DRC value stored in the buffer and compares it with the average transmission speed of the base station. In step 217, the base station 220 compensates if the transmission speed is lower than the average value. Assign the baud rate.

That is, the base station 220 retrieves the DRC value stored in the buffer and allocates transmission rates corresponding to 12 packet formats (2.4576 Mbps at 38.4 kbps). In this case, the above-mentioned method for allocating a transmission rate is the same as the conventional method. That is, each packet has 16 slots, and the transmission rate is allocated using 1,2,4,8 or 16 slots according to the transmission rate. The value assigned to the transmission rate is compared with the average transmission rate already calculated.

As such, when the compared transmission rate is lower than the average transmission rate, the base station 220 compensates for the transmission rate, improves the transmission rate, and transmits data to the terminal 210 at the improved transmission rate. Like the existing algorithm, it is repeated every packet to determine the optimal data rate.

As described above, the present invention can improve the data transmission speed of a subscriber having a low data transmission rate by changing only an algorithm between a terminal and a base station without configuring an additional system in a mobile communication system.

Claims (2)

In the compensated transmission rate allocation method in a mobile communication system, The terminal converts the received electric field strength into digitized data and reports the value to the base station; The base station calculates a data rate control (DRC) value using the data value, measures the transmission rate, compares the current average transmission rate with the calculated transmission rate, and then Assigning a compensated transmission rate in a low case. The method of claim 1, wherein assigning the compensated transmission rate comprises: Converting, at the terminal, a radio wave environment into digitized data and transmitting the same to a base station; Converting, by the base station, data transmitted from the terminal into a data rate control value and storing the data in a buffer, obtaining an average transmission rate at the base station and comparing the data rate with the transmission rate determined by the data rate control value stored in the buffer; And compensating for the transmission rate when the transmission rate by the data rate control value is lower than the average transmission rate, and transmitting the data to the terminal at the compensated transmission rate.