KR102303980B1 - Method and apparatus for determining voice quality of transmitter - Google Patents

Abstract

The present invention is a method and apparatus for determining the voice quality of a transmission device in a mobile communication system, and more specifically, calculating a bit error rate (BER) using voice quality information extracted from measurement report information received from a terminal. to a method and apparatus. A method for determining the voice quality of a base station for a terminal in a discontinuous transmission (DTX) mode according to an embodiment of the present invention is voice services over adaptive multi-user channels on one slot. , VAMOS), receiving the measurement report information of the first terminal when providing; extracting voice quality information from the received measurement report information; and calculating a bit error rate (BER) based on the configuration state of the first terminal and the second terminal and the extracted voice quality information.

Description

METHOD AND APPARATUS FOR DETERMINING VOICE QUALITY OF TRANSMITTER in a mobile communication system

The present invention is a method and apparatus for determining the voice quality of a transmission device in a mobile communication system, and more specifically, calculating a bit error rate (BER) using voice quality information extracted from measurement report information received from a terminal. to a method and apparatus.

Voice services over adaptive multi-user channels on one slot (VAMOS) is a technology that can double the capacity of voice calls by assigning multiple voice call users to the same physical resource. . The VAMOS is a technology designed to increase the voice capacity of the global system for mobile communications (GSM).

According to whether the terminal supports the VAMOS standard, it can be classified into a basic mode and an advanced mode. The basic mode supports the VAMOS function using the existing GSM terminal, and in the advanced mode, the reception performance can be improved compared to the basic mode based on the terminal supporting the VAMOS support standard.

On the other hand, in determining the voice quality of the terminal in the base station providing the VAMOS as described above, when only the transmission to the terminal to determine the voice quality is considered, the influence of the transmission to the other terminal allocated to one resource There is a problem that cannot be reflected. Therefore, there is a need for a technique for more accurate voice quality determination in consideration of not only the terminal that wants to determine the voice quality but also other terminals to which transmission resources are allocated to one resource.

The present invention has been proposed to solve the above-described problem, and when a transmission device in DTX mode operates voice services over adaptive multi-user channels on one slot, VAMOS, reception from a terminal When determining the voice quality using the voice quality information extracted from one measurement report information, we propose a method of determining the voice quality based on the setting state of two terminals receiving the VAMOS signal and the type of the measurement report information.

In order to achieve the above object, a method for determining the voice quality of a base station for a terminal in a discontinuous transmission (DTX) mode according to an embodiment of the present invention is a one-slot adaptive multi-user channel voice service (voice services over). When providing adaptive multi-user channels on one slot, VAMOS), receiving measurement report information of a first terminal; extracting voice quality information from the received measurement report information; and calculating a bit error rate (BER) based on the configuration state of the first terminal and the second terminal and the extracted voice quality information.

A base station for determining voice quality for a terminal in a discontinuous transmission (DTX) mode according to another embodiment of the present invention includes: a communication unit for transmitting and receiving a signal; and when providing voice services over adaptive multi-user channels on one slot (VAMOS), receive measurement report information of the first terminal, and voice quality information from the received measurement report information and a control unit controlling the calculation of a bit error rate (BER) based on the extracted voice quality information and setting states of the first terminal and the second terminal.

According to an embodiment of the present invention, the base station can determine the voice quality based on the type of measurement report and the setting state for the two terminals receiving the VAMOS signal from the same resource as well as the terminal to determine the voice quality, Due to this, the base station can increase the accuracy in determining the actual voice quality, and there is an effect of stably transmitting a signal.

1 is a diagram illustrating states of two terminals receiving a VAMOS signal in a discontinuous transmission mode.
2 is a diagram illustrating the state of the DTX mode according to time for two terminals receiving a VAMOS signal in a discontinuous transmission mode.
3 is a flowchart for determining, by a transmission device, a voice quality of a terminal receiving a VAMOS signal according to an embodiment of the present invention.
4 is a detailed flowchart of FIG. 3 in which the transmission device determines the voice quality of the terminal receiving the VAMOS signal according to an embodiment of the present invention.
5 is a block diagram illustrating an internal configuration of a transmission apparatus according to an embodiment of the present invention.

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

In describing embodiments in the present specification, descriptions of technical contents that are well known in the technical field to which the present invention pertains and are not directly related to the present invention will be omitted. This is to more clearly convey the gist of the present invention without obscuring the gist of the present invention by omitting unnecessary description.

For the same reason, some components are exaggerated, omitted, or schematically illustrated in the accompanying drawings. In addition, the size of each component does not fully reflect the actual size. In each figure, the same or corresponding elements are assigned the same reference numerals.

Advantages and features of the present invention, and a method for achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only these embodiments allow the disclosure of the present invention to be complete, and common knowledge in the art to which the present invention pertains. It is provided to fully inform the possessor of the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout.

At this time, it will be understood that each block of the flowchart diagrams and combinations of the flowchart diagrams may be performed by computer program instructions. These computer program instructions may be embodied in a processor of a general purpose computer, special purpose computer, or other programmable data processing equipment, such that the instructions performed by the processor of the computer or other programmable data processing equipment are not described in the flowchart block(s). It creates a means to perform functions. These computer program instructions may also be stored in a computer-usable or computer-readable memory that may direct a computer or other programmable data processing equipment to implement a function in a particular manner, and thus the computer-usable or computer-readable memory. It is also possible that the instructions stored in the flow chart block(s) produce an article of manufacture containing instruction means for performing the function described in the flowchart block(s). The computer program instructions may also be mounted on a computer or other programmable data processing equipment, such that a series of operational steps are performed on the computer or other programmable data processing equipment to create a computer-executed process to create a computer or other programmable data processing equipment. It is also possible that instructions for performing the processing equipment provide steps for performing the functions described in the flowchart block(s).

Additionally, each block may represent a module, segment, or portion of code that includes one or more executable instructions for executing specified logical function(s). It should also be noted that in some alternative implementations it is also possible for the functions recited in blocks to occur out of order. For example, two blocks shown one after another may in fact be performed substantially simultaneously, or it is possible that the blocks are sometimes performed in the reverse order according to the corresponding function.

At this time, the term '~ unit' used in this embodiment means software or hardware components such as FPGA or ASIC, and '~ unit' performs certain roles. However, '-part' is not limited to software or hardware. The '~ unit' may be configured to reside on an addressable storage medium or may be configured to refresh one or more processors. Thus, as an example, '~' denotes components such as software components, object-oriented software components, class components, and task components, and processes, functions, properties, and procedures. , subroutines, segments of program code, drivers, firmware, microcode, circuitry, data, databases, data structures, tables, arrays, and variables. The functions provided in the components and '~ units' may be combined into a smaller number of components and '~ units' or further separated into additional components and '~ units'. In addition, components and '~ units' may be implemented to play one or more CPUs in a device or secure multimedia card.

The transmission device transmitting the VAMOS signal may determine the voice quality of the terminal using a measurement report (MR) received from the terminal. The transmitting apparatus may include a base station that transmits data to the terminal in a VAMOS state. In the present invention, the transmission device and the base station may be used interchangeably. In the case of a dedicated control channel (DCCH) among channels transmitting signal information between the transmission device and the terminal, a standalone dedicated control channel (SDCCH) transmitting signal information and an associated control channel (associated control channel) control channel, ACCH). The SDCCH is a dedicated channel used for service re-request, subscriber authentication, encryption initialization, and equipment confirmation. In addition, the ACCH includes a slow associated control channel (SACCH) and a fast associated control channel (FACCH).

The SACCH is a unidirectional or bidirectional channel. The terminal may receive a power control message through the SACCH during a call in the downlink, and in the uplink, the terminal may transmit the measurement report to the base station through the SACCH. The importance of the SACCH performing the above functions in the UE is very high. Therefore, when the terminal does not receive the SACCH for more than a predetermined period, the voice call received from the base station may be disconnected. In addition, the FACCH is used to transmit information such as signal information in the downlink when the terminal is in a call.

As mentioned above, the terminal may transmit the measurement report to the base station in the transmission period of the SACCH. The measurement report may include measurement report information. The 'measurement report information' indicates measurement information on a signal received by the terminal from the base station. The 'measurement report information' may include RXLEV information, which is information on the signal level of the received signal, and RXQUAL information, which is 'voice quality information'. The RXLEV information indicates the strength of a signal, for example, may indicate the magnitude of a voice signal, and may have an integer value between 0 and 63. In addition, the RXQUAL information, which is the 'voice quality information', may indicate the quality of a voice signal transmitted to the terminal, and more specifically indicate a bit error rate (BER).

The 'bit error rate' refers to the number of bits in which an error occurs in the process of being transmitted with respect to the number of received bits. In general, the transmission device may adjust the transmission of the signal based on the bit error rate. The adjustment may include at least one of control of transmit signal strength and link adaptation. For example, when the bit error rate is high, the data rate is lowered to reduce errors occurring in the packet, and when the bit error rate is low, the environment in which errors occur in the packet is small. Send data by increasing the data rate.

The 'RXQUAL information' may have an integer value between 0 and 7, and as shown in Table 1 below, the bit error rate (BER) of the signal received by the terminal may be calculated according to the value of the RXQUAL information. . As shown in Table 1 below, when RXQUAL is 0, it corresponds to the lowest bit error rate, so the voice quality is the best, and when RXQUAL is 7, it corresponds to the highest bit error rate, indicating that the voice quality is the worst. .

RXQUAL BER 0 0.001 One 0.003 2 0.006 3 0.011 4 0.023 5 0.045 6 0.090 7 0.181

The 'voice quality information', RXQUAL, may have two types: RXQUAL_Full and RXQUAL_Sub. For the above two types, RXQUAL_Full may be referred to as 'first type of voice quality information' and RXQUAL_Sub may be referred to as 'second type of voice quality information'. The RXQUAL_Full may be determined by calculating a BER for all data bursts during the transmission period (20 msec) of the SACCH. In addition, the RXQUAL_Sub may be determined by calculating a BER for only the fast associated control channel (FACCH) and the SACCH transmitted during the transmission period of the SACCH.

In addition, in the discontinuous transmission (DTX) mode of the base station, there are an active state period, which is a period in which a voice signal received by the terminal, and an inactive state period, which is a silence period. In the active state period, the terminal includes both RXQUAL_Full and RXQUAL_Sub in the measurement report information and delivers it to the base station, and in the inactive state period, only RXQUAL_Sub is included in the measurement report information and transmits to the base station.

When the base station receives the measurement report information generated in a section in which the state of the DTX mode for the terminal is active, the BER of the downlink signal transmitted to the terminal using RXQUAL_Full in the transmitted measurement report information to calculate On the other hand, when receiving the measurement report information generated in the period in which the state of the DTX mode for the terminal is inactive, the BER of the downlink signal transmitted to the terminal is calculated using RXQUAL_Sub in the transmitted measurement report information. . The calculation of the BER follows Table 1 mentioned above.

1 is a flowchart for a transmitting device to determine the voice quality of a terminal receiving a VAMOS signal.

The base station corresponding to the transmission device determines whether to transmit a signal to the terminal in a discontinuous transmission (DTX) mode in step S100. When transmitting a signal to the terminal in the DTX mode, the base station determines whether the measurement report (MR) received from the terminal in step S110 is a general measurement report (MR) or an enhanced measurement report (EMR) can decide The general measurement report (MR) may be referred to as 'first type of measurement report information', and the enhanced measurement report (EMR) may be referred to as 'second type of measurement report information'.

The 'enhanced measurement report (EMR)' may include bit error probability (BEP) as voice quality information. The BEP may be referred to as 'third type of voice quality information' included in the measurement report. The BEP is determined by calculating only the BER for the successfully transmitted data burst.

When it is determined that the terminal reports EMR, the base station may calculate a BER using a mean BEP of the BEP in step S120. The mean BEP may have an integer value ranging from 0 to 31, and the BER may be calculated according to Table 2 below.

mean BEP BER 0 28.185 One 22.388 2 17.783 3 14.125 4 11.220 5 8.913 6 7.080 7 5.623 8 4.466 9 3.548 10 2.818 11 2.238 12 1.778 13 1.413 14 1.122 15 0.891 16 0.708 17 0.563 18 0.447 19 0.356 20 0.282 21 0.224 22 0.179 23 0.142 24 0.113 25 0.089 26 0.070 27 0.056 28 0.044 29 0.035 30 0.027 31 0.023

In addition, when it is determined that the terminal reports the MR, the base station may calculate the BER using RXQUAL_Full in step S225. Table 1 above can be used to calculate the BER corresponding to RXQUAL_Full, which is the same as described above.

When the base station determines not to transmit a signal to the terminal in a discontinuous transmission (DTX) mode in step S100, the base station may determine whether the terminal reports MR or EMR in step S150. When it is determined that the UE transmits the EMR, in step S160, the UE may calculate the BER using the mean BEP in the same manner as in step S120. That is, using the mean BEP value having an integer value from 0 to 31, the BER can be calculated according to Table 2 above.

If it is determined to receive the MR from the terminal, the BER may be calculated using RXQUAL_Full or RXQUAL_Sub according to the state of the DTX mode for the terminal in step S165, which is the same as described above. That is, the base station calculates the BER of the downlink signal transmitted to the terminal by using RXQUAL_Full in the transmitted measurement report information in a section in which the state of the DTX mode for the terminal is active. On the other hand, in the period in which the state of the DTX mode for the terminal is inactive, the BER of the downlink signal transmitted to the terminal is calculated using RXQUAL_Sub in the transmitted measurement report information.

2 is a diagram illustrating the state of the DTX mode according to time for two terminals receiving a VAMOS signal in a discontinuous transmission mode.

As mentioned above, when calculating the BER for RXQUAL for the terminal receiving the VAMOS signal from the base station, the BER is calculated using RXQUAL_Full in the period in which the DTX mode state for the terminal is active, and RXQUAL_Sub in the inactive state. Calculate the BER using At this time, the VAMOS signal is transmitted in the same resource, that is, the time slot (time slot) of the two signals. In this case, the signal received by the terminal may include a voice signal, SACCH and FACCH data. In the case of the period in which the state of the DTX mode for the terminal is active, the voice signal is transmitted, and in the case of the period in which the state of the DTX mode for the terminal is inactive, the voice signal is not transmitted. The SACHH and FACCH data are transmitted even in the period in which the terminal is in an inactive state.

The terminal receiving the VAMOS signal can be classified into a GSM terminal, a VAMOS I terminal, and a VAMOS II terminal according to the 'set state of the terminal'. Among the 'set state of the terminal', the VAMOS I terminal may be referred to as a 'first type terminal', and the VAMOS II terminal may be referred to as a 'second type terminal'. In addition, by changing the above terminology, a VAMOS II terminal may be referred to as a 'first type terminal' or a VAMOS I terminal may be referred to as a 'second type terminal'. The setting state of the terminal is determined by a code set supported by the terminal. That is, the GSM terminal represents a general terminal, and is, for example, a terminal capable of supporting code sets 0 to 7. In addition, the VAMOS I and II terminals may additionally support code sets 8 to 15 in addition to the code sets 0 to 7.

When the two terminals receiving the VAMOS signal are GSM or VAMOS I terminals, the SACCHs of the two terminals receiving the VAMOS signal are transmitted in the same time slot and always overlap. However, unlike the VAMOS I terminal, the VAMOS II terminal transmits a shifted SACCH, so that the VAMOS II terminal does not transmit the SACCH in the same time slot between the two terminals receiving the VAMOS signal.

In the present invention, the voice quality can be determined based on the setting state of the two terminals receiving the VAMOS signal and the type of the measurement report. That is, the voice quality may be determined by changing a method of calculating the BER for the terminal receiving the VAMOS signal based on the configuration state of the terminal and the type of the measurement report. In the present invention, the method of calculating the BER according to the configuration state of the terminal and the type of the measurement report can be applied as follows.

- BER calculation type 1: In the case where the terminal for which the base station wants to calculate the BER transmits MR and the two terminals that receive the VAMOS signal are GSM or VAMOS I terminals

- BER calculation type 2: When the terminal for which the base station wants to calculate the BER transmits MR and both terminals receiving the VAMOS signal are VAMOS II terminals

- BER Calculation Type 3: When a UE whose base station wants to calculate BER transmits EMR

First, the BER calculation type 1 will be described. In the case where both terminals receiving the VAMOS signal are not VAMOS II terminals, as mentioned above, SACCHs are transmitted in the same time slot, so they always overlap, but FACCH transmission locations may be different. When DTX is applied to two different VAMOS signals, there is a period in which the two terminals receiving the VAMOS signals are in different states.

In the case of the first period 210 , a period in which the first terminal 200 is in an active state and the second terminal 205 is in an active state is shown. Since the first section is a section in which both terminals transmit voice signals, the voice signals, SACCH, and FACCH are overlapped as described above, so there is no problem even if the BER is calculated using RXQUAL_Full as before.

In the case of the second period 220, a period in which the first terminal 200 is in an active state and the second terminal 205 is in an inactive state is shown. In this case, since the SACCH and FACCH transmitted in the inactive state of the second terminal are transmitted overlapping the SACCH and FACCH transmitted in the active state of the first terminal, the RXQUAL_Sub value for the second terminal is the BER value when receiving the VAMOS signal. Calculated. However, the voice signal and FACCH transmitted in the active state of the first terminal are transmitted without overlapping the FACCH in the inactive state of the second terminal, and only the SACCH of the first terminal is transmitted overlaid with the SACCH of the second terminal. In this case, since most signals are transmitted in a non-overlapping state, the BER value calculated by RXQUAL_Full will be low, and the voice quality is determined well. However, since the SACCH always overlaps with the counterpart SACCH, the BER of only SACCH has a value much higher than the BER of RXQUAL_Full, and the voice quality is determined to be inferior. That is, there is a problem that the BER value of RXQUAL_Full does not represent the BER value of SACCH.

In the case of the third period 230 , that is, when both the first terminal 200 and the second terminal 205 are in an inactive state, FACCHs do not overlap with each other, but SACCHs always overlap between the two terminals. RXQUAL_Sub calculated in the inactive state of the first terminal 200 is calculated with a low BER value since FACCHs do not overlap each other, and the voice quality is determined to be good. However, since the SACCHs of the first terminal 200 and the second terminal 205 overlap each other, the BER of only the SACCH in the inactive state of the first terminal 200 is high, that is, the voice quality is determined to be inferior. In the third period 230 , as in the second period 220 , a problem occurs that the BER value of RXQUAL_Sub does not represent the BER value of SACCH.

In the case of the second period 220 and the third period 230, the BER value of RXQUAL_Sub calculated in the inactive state of the first terminal is reported to the base station as a value lower than the BER value of the SACCH. The base station determines the voice quality for the first terminal based on the reported RXQUAL_Sub. If the BER value calculated from RXQUAL_Sub is low, the base station may determine that the current voice signal state is good and reduce the transmission power. That is, if the BER of the SACCH alone is high and the transmission power is lowered based on only the BER of RXQUAL_Sub, the BER of the SACCH becomes worse. When the base station transmits by lowering the transmit power, the BER of the SACCH is further lowered, and the terminal may continuously fail to detect the SACCH in the received signal. As mentioned above, since the SACCH is a channel through which important information such as a power control message is received, the terminal can disconnect a voice call received from the base station when SACCH detection continuously fails for a predetermined period or more.

In the present invention, when the influence from other terminals allocated at the same time in one resource is not considered in the VAMOS mode as described above, the BER of the signal determined by the base station and the BER of the SACCH are different as described above. This problem is solved A method for doing this will be described below.

When determining the voice quality for the terminal receiving the VAMOS signal in the above-mentioned DTX mode, in order to improve the phenomenon that the BER for the SACCH is not properly reflected, the BER is calculated based on the BER value of the SACCH and the voice quality is determined. have to decide When RXUQAL is calculated based on the BER of the SACCH, the power control of the base station operates based on this value to improve the BER of the SACCH.

In order to determine the BER value of the SACCH as the BER value of the RXQUAL, the RXQUAL value calculated when the state of the DTX operation for the second terminal allocated to the same resource as the first terminal to be measured is in an inactive state must be adjusted.

When the base station transmits the VAMOS signal, since the SACCHs of the two terminals allocated to the same resource are transmitted in the same time slot, the SACCH signals for the two terminals are always overlapped and transmitted. Therefore, since the BER value of the SACCH is a BER value when the two signals transmitted to the two terminals overlap each other, when the voice quality information received from the terminal is calculated based on when the two signals overlap, the SACCH BER value can be reflected.

That is, as described above, when the DTX mode state of the first terminal receiving the VAMOS signal is active and the DTS mode state of the second terminal is inactive, the BER calculated from the RXQUAL of the first terminal is the SACCH It is calculated as a value lower than the BER. In this case, if the first terminal calculates the BER using RXQUAL_Sub instead of RXQUAL_Full, the BER is calculated using only the SACCH and the FACCH, so that the BER value of the SACCH can be reflected more closely. However, even if calculated with RXQUAL_Sub as described above, when SACCH is overlapped during data transmission but FACCH is not overlapped, the BER calculated from RXQUAL_Sub is still lower than the BER when calculating only SACCH. Therefore, in order to more accurately reflect the BER of the SACCH, a method of calculating the BER value when all FACCHs overlap each other and reflecting this value to the BER value of the RXQUAL can be used.

One SACCH is transmitted for a period of 480 msec, and 480 msec is composed of M time slots. It is assumed that the number of FACCHs transmitted during the 480 msec is N. Assuming that the probability that FACCHs do not overlap each other when transmitting MRs to the base station is Pc, as described above, the BER when all N FACCHs are transmitted overlapping can be calculated as in Equation 1. _{That is, by extracting the BER RXQUAL _Sub} received from the MR, multiplying this by the probability that all N _{FACCHs overlap,} and correcting the extracted BER RXQUAL _Sub, the BER for accurately reflecting the SACCH BER can be obtained as described above.

[Equation 1]

BER = BER _{RXQUAL _Sub} *(1-Pc)*N

P _c = N*(N-1)*(N-2)* ... * 1 / {(M-2)*(M-3)*(M-4)*...*(M-1-N )}

Next, when both terminals receiving the VAMOS signal are in the inactive state of the DTX mode, the RXQUAL of the terminal in the inactive state is calculated as a value lower than the BER of the SACCH. Even in this case, in order to obtain a BER that accurately reflects the BER of the SACCH, Equation 1 above can be used.

Therefore, when determining the voice quality of a GSM terminal or a VAMOS I terminal that receives a VAMOS signal in DTX mode, the BER of the first terminal is calculated according to the active states of the first terminal and the second terminal when calculating the BER Equation 2 is calculated as

[Equation 2]

BER = BER _{RXQUAL _Full (The period in which} the state of the DTX mode for the first terminal is active, and the state of the DTX mode for the second terminal is inactive.)

= BER _{RXQUAL _Sub *(1-Pc)*N (Interval in which} the first terminal is active and the second terminal is inactive.)

= BER _{RXQUAL _Sub} (Terminal 1 is inactive, UE 2 is active.)

= BER _{RXQUAL _Sub} *(1-Pc)*N (Interval in which terminal 1 is inactive, terminal 2 is inactive.)

Pc = N*(N-1)*(N-2)* ... * 1 / {(M-2)*(M-3):(M-4)*...*(M-1- N)}

N: Number of FACCHs transmitted during 480 msec

M: the number of time slots for 480 msec

BER _{RXQUAL _Full} : BER value converted from RXQUAL_Full using Table 1.

BER _{RXQUAL _Sub} : BER value converted from RXQUAL_Sub using Table 1

In fact, since Pc has a value close to 0, Equation 2 can be simplified as Equation 2-1 below in order to reduce calculation complexity.

[Equation 2-1]

BER = BER _{RXQUAL _Full (The period in which} the state of the DTX mode for the first terminal is active, and the state of the DTX mode for the second terminal is inactive.)

= BER _{RXQUAL _Sub * N (Interval in which} the first terminal is active and the second terminal is inactive.)

= BER _{RXQUAL _Sub} (Terminal 1 is inactive, UE 2 is active.)

= BER _{RXQUAL _Sub} * N (Terminal 1, Terminal 2 are inactive.)

N: Number of FACCHs transmitted during 480 msec

BER _{RXQUAL _Full} : BER value converted from RXQUAL_Full using Table 1.

BER _{RXQUAL _Sub} : BER value converted from RXQUAL_Sub using Table 1

Hereinafter, BER calculation type 2 will be described. When one of the two terminals receiving the VAMOS signal is a VAMOS II terminal, the shifted SACCH is applied to the VAMOS II terminal as described above, so that the transmission position of the SACCH is changed. Therefore, in the above case, the SACCHs between the two terminals receiving the VAMOS signal do not overlap each other. In this case, unlike the case where both terminals receiving the VAMOS signal are not VAMOS II terminals, even if the state of the DTX mode for the second terminal, which is the counterpart terminal of the first terminal to be measured, is inactive, to measure the BER The difference between the BER calculated from the RXQUAL of the VAMOS II terminal and the BER of the SACCH is not large.

However, the BER calculated from the RXQUAL received by the base station may have a value close to 0 because the SACCHs of the two terminals do not overlap. In this case, the base station may determine that the voice signal state is good, and may reduce transmission power. Then, when the state of the DTX mode for the second terminal is suddenly changed to the active state, since the voice signals, SACCH, and FACCH of the first terminal and the second terminal overlap, the BER calculated from the RXQUAL of the first terminal is rises sharply In this case, the BER rapidly increases from a value close to zero, so that the base station can control the transmission power to have a large variation, and in this case, unstable signal transmission can be performed. In order to prevent this problem, even when the state of the DTX mode for the second terminal is inactive, when calculating the BER for the first terminal, an operation for adding a certain BER value is required. At this time, the value to be added may be determined based on an expected BER value when the SACCH and the FACCH are transmitted overlappingly. In the present invention, the added BER value is determined as the average value of the BER generated by the terminal receiving the VAMOS signal. However, this corresponds to an embodiment of the present invention, and the present invention is not limited to the average value of the BER.

The average value of the BER value uses the average value of the upper value and the lower value of the BER value used in the power control of the VAMOS signal transmission in the base station. The expected BER when the SACCH and the N FACCHs are all overlapped and transmitted can be calculated as follows. That is, in the case of BER calculation type 2, the BER may be calculated as in Equation 3 below.

[Equation 3]

BER= BER _{RXQUAL _Full (interval in which} the state of the DTX mode for the first terminal is active, and the state of the DTX mode for the second terminal is inactive)

= BER _RXQUAL _Sub + P _{avg (interval in which} the state of the DTX mode for the first terminal is active, and the state of the DTX mode for the second terminal is inactive)

= BER _{RXQUAL _Sub} (Terminal 1 is inactive, UE 2 is active)

= BER _{RXQUAL _Sub} + P _avg (interval in which UE 1 and UE 2 are inactive)

P _avg = (VAMOS _upperBER +VAMOS _lowerBER )/2

VAMOS _upperBER : The upper value of the BER value used in power control of VAMOS signal transmission in the base station

VAMOS _lowerBER : The lower value of the BER value used in power control of VAMOS signal transmission in the base station

Hereinafter, the BER calculation type 3 will be described. When the terminal receiving the VAMOS signal transmits an Enhanced Measurement Report (EMR) to the base station, the EMR includes mean BEP as voice quality information of the terminal. The mean BEP may have an integer value ranging from 0 to 31, and is determined by calculating only the BER for a successfully transmitted data burst. When calculating the BER of the first terminal receiving the VAMOS signal in the DTX mode of the base station, it will be described when the DTX mode state for the second terminal being allocated the same resource is inactive. In this case, the mean BEP value of the first terminal for which the BER is to be calculated is calculated as a very low value when the FACCH does not overlap and the SACCH is successfully detected. When the base station receives the EMR for the first terminal, similarly to the BER calculation type 2, a BER value of mean BEP close to 0 may be calculated. Therefore, as in BER calculation type 2, in order for the base station to stably control the transmit power, an operation for adding a certain BER value is required. At this time, the value to be added may be determined based on an expected BER value when the SACCH and the FACCH are transmitted overlappingly. In the present invention, the added BER value is determined as the average value of the BER values generated by the terminal receiving the VAMOS signal. The BER when the SACCH and the N FACCHs are all overlapped and transmitted can be calculated as in Equation 4 below.

[Equation 4]

BER = BERMean BEP (the period in which the state of the DTX mode for the first terminal is active, the state of the DTX mode for the second terminal is inactive)

= BERMean BEP + Pavg (the period in which the state of the DTX mode for the first terminal is active, the state of the DTX mode for the second terminal is inactive)

= BERMean BEP (the period in which the first terminal is in an inactive state, and the second terminal is in an active state)

= BERMean BEP + Pavg (interval in which the first terminal and the second terminal are inactive)

P _avg = (VAMOS _upperBER +VAMOS _lowerBER )/2

VAMOS _upperBER : The upper value of the BER value used in power control of VAMOS signal transmission in the base station

VAMOS _lowerBER : The lower value of the BER value used in power control of VAMOS signal transmission in the base station

3 is a flowchart for determining, by a transmission device, a voice quality of a terminal receiving a VAMOS signal according to an embodiment of the present invention.

More specifically, FIG. 3 is a method for calculating a BER of a terminal receiving a VAMOS signal by a base station, which is a transmission device for transmitting a signal to a terminal. As mentioned above, the base station may determine the voice quality based on the configuration state of the two terminals receiving the VAMOS signal and the type of the measurement report. That is, the BER may be calculated by changing a method of calculating the BER for the terminal receiving the VAMOS signal based on the configuration state of the terminals and the type of the measurement report information. The base station can classify the BER calculation type into three types according to the configuration state of the terminal and the type of measurement report information, as described above. 3 is a diagram illustrating an embodiment of the determination process of the base station.

The base station receives the MR from the first terminal in step S300. The base station determines whether the MR is an EMR in step S310. If the MR is not the EMR, the BER may be calculated based on the configuration states of the first terminal and the second terminal in step S320. In this case, the base station calculates the BER based on the BER calculation types 1 and 2, and a detailed calculation method will be described later with reference to FIG. 4(a). When the MR is the EMR, the BER may be calculated based on the configuration state of the second terminal in step S330. In this case, the base station calculates the BER based on the BER calculation type 3, and a detailed calculation method will be described later with reference to FIG. 4(b). The method of FIG. 3 merely shows an embodiment of the operation of the base station of the present invention, and the present invention is not limited thereto.

`FIG. 4 is a detailed flowchart of FIG. 3 in which the transmission device determines the voice quality of the terminal receiving the VAMOS signal according to an embodiment of the present invention.

More specifically, FIG. 4(a) is a diagram illustrating BER calculation based on BER calculation types 1 and 2 when step S320 of FIG. 3, that is, when MR is received from the terminal, FIG. 4(b) ) is a diagram illustrating step S330 of FIG. 3, that is, calculating BER based on BER calculation type 3 when EMR is received from the terminal.

Referring to Figure 4 (a), the base station determines whether the state of the DTX mode for the second terminal allocated to the same resource as the first terminal when the MR is generated in step S400 is active. If the second terminal is not in the active state, the base station determines whether the setting state of either the first terminal or the second terminal is VAMOS II in step S410. When the setting state of either the first terminal or the second terminal is VAMOS II, the base station extracts the RXQUAL_Sub value from the voice quality information included in the received MR in step S412, and the VAMOS state pre-stored in the base station Calculate the BER by adding the average values of the BERs in . As mentioned above, the average value of the BER value uses the average value of the upper value and the lower value of the BER value used in the power control of the VAMOS signal transmission in the base station.

In step S410, when the setting state of the first terminal and the second terminal are not VAMOS II, the base station extracts the RXQUAL_Sub value from the voice quality information included in the received MR in step S415, and pre-stored in the base station The number of FACCHs transmitted to the UE during a certain period is added.

In addition, if the base station determines that the state of the DTX mode for the second terminal at the time the received MR is generated in step S400 is the active state, the base station determines the first time when the received MR is generated in step S420. 1 It is determined whether the state of the terminal is active. When the state of the first terminal is active, the base station extracts RXQUAL_Full from among the voice quality information included in the received MR in step S422, and calculates a BER value corresponding to the RXQUAL_Full value.

In addition, when the base station determines that the state of the first terminal is inactive in step S420, the base station extracts RXQUAL_Sub from the voice quality information included in the received MR in step S425, and a BER value corresponding to the RXQUAL_Sub value. to calculate The base station may calculate the BER value corresponding to the received RXQUAL_Full or RXQUAL_Sub using Table 1 as described above in steps S422 and S425.

Referring to Figure 4 (b), the base station determines whether the state of the DTX mode for the second terminal when the received EMR is generated in step S430 is an active state. When the second terminal is in an inactive state, the base station extracts the BEP, which is the voice quality information included in the received EMR, in step S440, and provides the BER calculated using the median value of the extracted BEP to the base station. The BER can be calculated by adding the average values of the BERs in the pre-stored VAMOS state. As mentioned above, the average value of the BER value uses the average value of the upper value and the lower value of the BER value used in the power control of the VAMOS signal transmission in the base station.

In addition, when it is determined in step S430 that the second terminal is in an active state, in step S445, the base station extracts the BEP, which is the voice quality information included in the received EMR, and uses an intermediate value of the extracted BEP. BER can be calculated. The median value of the mean BEP may have an integer value ranging from 0 to 31, and the BER may be calculated according to Table 2 as described above. In addition, the method of FIG. 4 only shows an embodiment of the operation of the base station of the present invention, and the present invention is not limited thereto.

5 is a block diagram illustrating an internal configuration of a transmission apparatus according to an embodiment of the present invention.

More specifically, the transmission device may include a communication unit 500 , a storage unit 510 , and a control unit 520 .

The communication unit 500 may transmit and receive signals. The communication unit 500 may transmit/receive signals necessary for operation in the control unit 520 of the transmission device. The communication unit 500 may transmit a voice signal, data of a fast associated control channel (FACCH) and a slow associated control channel (SACCH) to the terminal. The communication unit 500 may receive measurement report information on the signal received from the terminal.

The storage unit 510 may store information necessary for the transmission device to operate. The storage unit 510 may store information received from the communication unit 500 . The storage unit 510 may transmit the measurement report information of the terminal received and stored by the communication unit 500 to the control unit 520 . The storage unit 510 may store information necessary for operation in the control unit 520 in advance. For example, the storage unit 510 may store an average value of voice quality information in the VAMOS operation region or information on the number of fast associated control channels (FACCHs) transmitted to the first terminal during a predetermined period. can be saved.

The controller 520 may control the operation of the transmission device. More specifically, when providing voice services over adaptive multi-user channels on one slot, VAMOS, the control unit 520 receives the measurement report information of the first terminal, and It is possible to control the extraction of voice quality information from one measurement report information and the calculation of a bit error rate (BER) based on the setting state of the first terminal and the second terminal and the extracted voice quality information. have.

The control unit 520 determines whether the measurement report information received from the first terminal is the first type of measurement report information, and when the received measurement report information is the first type of measurement report information, the measurement information is generated Determining the state of the DTX mode for the first terminal and the second terminal at the time, the state of the DTX mode for the first terminal is the active state, and the state of the DTX mode for the second terminal is the active state, Extracting the first type of voice quality information, and when at least one of the states of the DTX mode for the first terminal and the second terminal is inactive, it is possible to control the extraction of the second type of voice quality information.

When the state of the DTX mode for the second terminal is active, the controller 520 may control calculating the bit error rate based on the extracted voice quality information. In addition, the control unit 520 receives the measurement information of the first type, and when the state of the DTX mode for the second terminal is inactive, either the first terminal or the second terminal is the first type of It is determined whether the terminal is a terminal, and when either the first terminal or the second terminal is the first type terminal, the bit error rate is calculated by adding a preset first value to the bit error rate based on the extracted voice quality information. can do.

In addition, when the first terminal and the second terminal are the second type terminals, the control unit 520 controls the calculation of the bit error rate by multiplying the bit error rate based on the extracted voice quality information by a preset second value. The second preset value may include the number of fast associated control channels (FACCHs) transmitted to the first terminal during a predetermined period. Also, the controller 520 determines whether the measurement report information received from the first terminal is the first type of measurement report information, and when the received measurement report information is the second type of measurement report information, the third type It is possible to control the extraction of voice quality information of

Also, the controller 520 determines whether the measurement report information received from the first terminal is the first type of measurement report information, and when the received measurement report information is the second type of measurement report information, the second terminal It is possible to determine the state of the DTX mode for , and when the state of the DTX mode for the second terminal is in the active state, it is possible to control calculating the bit error rate based on the extracted voice quality information.

In addition, when the DTX mode state for the second terminal is inactive, the control unit 520 may control calculating the bit error rate by adding a preset first value to the bit error rate based on the extracted voice quality information, The preset first value may include an average value of voice quality information in the VAMOS operation region.

On the other hand, in the present specification and drawings, preferred embodiments of the present invention have been disclosed, and although specific terms are used, these are only used in a general sense to easily explain the technical content of the present invention and help the understanding of the present invention, It is not intended to limit the scope of the invention. It will be apparent to those of ordinary skill in the art to which the present invention pertains that other modifications based on the technical spirit of the present invention can be implemented in addition to the embodiments disclosed herein.

Claims (22)

In a method for determining voice quality for a terminal of a base station in a discontinuous transmission (DTX) mode,
Receiving measurement report information of a first terminal when providing a one-slot adaptive multi-user channel voice service (voice services over adaptive multi-user channels on one slot, VAMOS);
extracting voice quality information from the received measurement report information; and
Calculating a bit error rate (BER) based on the configuration state of the first terminal and the second terminal and the extracted voice quality information;
The voice quality information includes, when the measurement report information is the first type of measurement report information, a first type of voice quality information and a second type of voice quality information, and the received measurement report information is of the second type In the case of measurement report information, it further includes a third type of voice quality information,
The first type of voice quality information is determined based on data transmitted during a certain period of the base station,
The second type of voice quality information is determined based on data of a fast associated control channel (FACCH) and a slow associated control channel (SACCH) transmitted during a predetermined period of the base station,
The third type of voice quality information is determined based on data successfully transmitted from the base station to the terminal. According to claim 1, wherein the setting state,
A method comprising at least one of a type of the measurement report information, a state of the DTX mode for the terminal when the measurement report information is generated, and the type of the terminal. delete delete The method of claim 1, wherein the extracting comprises:
determining whether the measurement report information received from the first terminal is the first type of measurement report information;
If the received measurement report information is the first type of measurement report information, determining the state of the DTX mode for the first terminal and the second terminal when the received measurement report information is generated;
When the state of the DTX mode for the first terminal is the active state, and the state of the DTX mode for the second terminal is the active state, extracting the first type of voice quality information; and
When at least one of the states of the DTX mode for the first terminal and the second terminal is an inactive state, extracting the second type of voice quality information; method comprising: a. The method of claim 5, wherein the calculating comprises:
When the state of the DTX mode for the second terminal is active, calculating a bit error rate based on the extracted voice quality information; method comprising: a. The method of claim 6, wherein the calculating comprises:
Receiving the first type of measurement information, when the state of the DTX mode for the second terminal is inactive, determining which one of the first terminal or the second terminal is a first type of terminal; and
calculating a bit error rate by adding a preset first value to a bit error rate based on the extracted voice quality information when either the first terminal or the second terminal is the first type of terminal;
The first preset value includes an average value of voice quality information in the VAMOS operation region. The method of claim 7, wherein the calculating comprises:
calculating the bit error rate by multiplying the bit error rate based on the extracted voice quality information by a preset second value when the first terminal and the second terminal are the second type of terminal;
The second preset value includes the number of FACCHs transmitted to the first terminal during a certain period. The method of claim 1, wherein the extracting comprises:
determining whether the measurement report information received from the first terminal is the first type of measurement report information; and
and extracting the third type of voice quality information when the received measurement report information is the second type of measurement report information. The method of claim 9, wherein the calculating comprises:
determining whether the measurement report information received from the first terminal is the first type of measurement report information;
If the received measurement report information is the second type of measurement report information, determining the state of the DTX mode for the second terminal; and
When the state of the DTX mode for the second terminal is active, calculating a bit error rate based on the extracted voice quality information; Method comprising a. The method of claim 10, wherein the calculating comprises:
When the DTX mode state for the second terminal is inactive, calculating the bit error rate by adding a preset first value to the bit error rate based on the extracted voice quality information;
The method of claim 1, wherein the preset first value includes an average value of voice quality information in a VAMOS operation region. In the base station for determining the voice quality for the terminal in discontinuous transmission (DTX) mode,
a communication unit for transmitting and receiving signals; and
In the case of providing voice services over adaptive multi-user channels on one slot (VAMOS), measurement report information of the first terminal is received, and voice quality information is obtained from the received measurement report information. and a control unit controlling the calculation of a bit error rate (BER) based on the extracted voice quality information and the setting state of the first terminal and the second terminal,
The voice quality information includes a first type of voice quality information and a second type of voice quality information when the measurement report information is the first type of measurement report information, and the received measurement report information is of the second type In the case of measurement report information, it further includes a third type of voice quality information,
The first type of voice quality information is determined based on data transmitted during a certain period of the base station,
The second type of voice quality information is determined based on data of a fast associated control channel (FACCH) and a slow associated control channel (SACCH) transmitted during a certain period of the base station,
The third type of voice quality information is determined based on data successfully transmitted from the base station to the terminal. 13. The method of claim 12, wherein the setting state,
A base station, characterized in that it includes at least one of the type of the measurement report information, the state of the DTX mode for the terminal when the measurement report information is generated, and the type of the terminal. delete delete 13. The method of claim 12, wherein the control unit,
It is determined whether the measurement report information received from the first terminal is the first type of measurement report information, and when the received measurement report information is the first type of measurement report information, when the received measurement report information is generated Determining the state of the DTX mode for the first terminal and the second terminal, the state of the DTX mode for the first terminal is an active state, when the state of the DTX mode for the second terminal is the active state, the first type Base station, characterized in that for extracting the voice quality information of, and controlling the extraction of the second type of voice quality information when at least one of the states of the DTX mode for the first terminal and the second terminal is inactive. The method of claim 16, wherein the control unit,
When the state of the DTX mode for the second terminal is active, the base station comprising a control unit for controlling the calculation of the bit error rate based on the extracted voice quality information. The method of claim 17, wherein the control unit,
Receive the first type of measurement information, and when the state of the DTX mode for the second terminal is inactive, determine which one of the first terminal or the second terminal is a first type of terminal, and When any one of the first terminal or the second terminal is the first type of terminal, controlling the calculation of the bit error rate by adding a preset first value to the bit error rate based on the extracted voice quality information;
The preset first value includes an average value of voice quality information in the VAMOS operation region. The method of claim 18, wherein the control unit,
When the first terminal and the second terminal are the second type of terminal, controlling the calculation of the bit error rate by multiplying the bit error rate based on the extracted voice quality information by a preset second value,
The second preset value includes the number of fast associated control channels (FACCHs) transmitted to the first terminal during a predetermined period. 13. The method of claim 12, wherein the control unit,
determining whether the measurement report information received from the first terminal is the first type of measurement report information, and when the received measurement report information is the second type of measurement report information, extracting the third type of voice quality information Base station, characterized in that it comprises controlling the. The method of claim 20, wherein the control unit,
It is determined whether the measurement report information received from the first terminal is the first type of measurement report information, and if the received measurement report information is the second type of measurement report information, the state of the DTX mode for the second terminal Determining, when the state of the DTX mode for the second terminal is active, the base station, characterized in that for controlling the calculation of the bit error rate based on the extracted voice quality information. The method of claim 21, wherein the control unit,
When the DTX mode state for the second terminal is in an inactive state, controlling the calculation of the bit error rate by adding a preset first value to the bit error rate based on the extracted voice quality information,
The preset first value includes an average value of voice quality information in a VAMOS operation region.

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