KR101107436B1 - Mobile communication system for estimating sensory voice quality and control method thereof - Google Patents

Abstract

The present invention relates to a mobile communication network system and a control method thereof. A control method of a mobile communication network system according to the present invention comprises the steps of: generating a signal data packet and a voice data packet; Comparing a data size of the sum of the signal data packet and the voice data packet with a preset data size; If the sum data size is not larger than the set data size, a data frame including the signal data packet and the voice data packet is generated. If the sum data size is larger than the set data size, the voice data packet is generated. Generating an excluded data frame and transmitting it to the mobile communication terminal; Calculating a statistical value of a data frame rate excluding the voice data packet among data frames generated for a preset time; Calculating the perceived call quality in the mobile communication terminal based on the calculated statistics.

Description

MOBILE COMMUNICATION SYSTEM FOR ESTIMATING SENSORY VOICE QUALITY AND CONTROL METHOD THEREOF}

The present invention relates to a mobile communication network system and a control method thereof, and more particularly, to a mobile communication network system and a method for controlling the same, which are used to calculate a perceived call quality in a mobile communication terminal.

The mobile communication terminal is a terminal that communicates with a base station through a wireless communication section. In a mobile communication system including a base station, power control of a signal transmitted to each mobile communication terminal is performed.

In other words, power control is to maintain the call quality of the mobile communication terminal at an appropriate level. For example, when the mobile communication terminal is far from the base station, the signal is transmitted at a higher power to maintain the appropriate call quality. In addition, when the mobile communication terminal is located close to the base station, the signal is transmitted with weaker power in order to prevent unnecessary waste of power and deterioration of call quality of the other mobile communication terminal.

However, in performing the power control on the signal transmitted to the mobile communication terminal in the mobile communication system, the basic data is predetermined information received from the mobile communication terminal.

That is, the mobile communication terminal determines power intensity, that is, power magnitude, of the signal received from the base station periodically or when a specific event occurs and transmits power measurement feedback information based on the determined information to the base station.

As such, the power measurement feedback information transmitted from the mobile communication terminal to the base station may be, for example, a PMRM (Power Measurement Report Message) or a predetermined frame error determination bit.

The mobile communication terminal may determine whether the received data frame is broken by analyzing each data frame received from the base station. For example, the mobile communication terminal may be performed by checking a cyclic redundancy check (CRC) bit.

In this way, the mobile communication terminal can determine that a part of the received signal is broken or lost by calculating an error rate (ie, a frame error rate) of the received data frame, and notifying the base station based on the determined information. The base station may perform power control by determining whether a signal is normally received by the mobile communication terminal (ie, determining whether the call quality is deteriorated).

However, the forward power control in the mobile communication system based on the information transmitted from the mobile communication terminal has a problem of not properly predicting the call quality in the mobile communication terminal depending on the situation.

For example, in a situation in which a mobile communication system transmits a control signal for handoff to a mobile communication terminal such as a handoff situation, the reliability of call quality related information (for example, PMRM) received from the mobile communication terminal is not guaranteed. can not do it.

That is, the information transmitted by the mobile communication terminal to the mobile communication terminal in relation to the call quality is information based on the FER of the signal received from the base station by the mobile communication terminal. In the situation of transmitting a control signal for the mobile terminal, the control signal is transmitted to the mobile communication terminal in preference to the voice signal. In this case, even if the FER measured by the mobile communication terminal is low (ie, the call quality is high), Since the voice signal is not transmitted properly due to the control signal, the call quality felt by the mobile communication terminal user is considerably degraded.

As described above, in order to more accurately determine (predict) the haptic call quality felt by the mobile terminal user in the mobile communication system, it has been argued that not only relying on information received from the mobile terminal but also reflecting other information.

The present invention has been made to meet the above-described conventional request, and an object thereof is to provide a mobile communication network system and a control method thereof for accurately predicting a perceived call quality of a mobile communication terminal user.

In order to achieve the above object, a mobile communication network system according to the present invention includes a data packet generation unit for generating a signal data packet and a voice data packet; A data size comparison unit for comparing the data size of the sum of the signal data packet and the voice data packet with a preset data size; When the sum data size is not greater than the set data size as a result of the comparison of the data size comparison unit, a data frame including the signal data packet and the voice data packet is generated and the sum data size is larger than the set data size. A data frame generator for generating a data frame excluding the voice data packet; A transmission unit which transmits the generated data frame to the mobile communication terminal; A statistical value calculator for calculating a statistical value of a data frame rate excluding the voice data packet among data frames generated during a preset time; And a haptic call quality calculation unit that calculates haptic call quality in the mobile communication terminal based on the calculated statistics.

In addition, the control method of the mobile communication network system according to the present invention for achieving the above object comprises the steps of: generating a signal data packet and a voice data packet; Comparing a data size of the sum of the signal data packet and the voice data packet with a preset data size; If the sum data size is not larger than the set data size, a data frame including the signal data packet and the voice data packet is generated. If the sum data size is larger than the set data size, the voice data packet is generated. Generating an excluded data frame and transmitting it to the mobile communication terminal; Calculating a statistical value of a data frame rate excluding the voice data packet among data frames generated for a preset time; Calculating the perceived call quality in the mobile communication terminal based on the calculated statistics.

As described above, according to the present invention, the mobile communication network system can more accurately predict the perceived call quality of the mobile communication terminal.

Accordingly, since the mobile communication network system can calculate and analyze statistics closer to haptic call quality, the haptic call quality can be improved by increasing the ratio of voice data packets for each region.

1 is an example of the overall configuration of a mobile communication system and a mobile communication terminal according to an embodiment of the present invention,
FIG. 2 is a functional diagram of the mobile communication network system of FIG. 1;
3 is a view showing a process of generating a voice data packet,
4 is a diagram illustrating types of generated voice data packets as an example;
5 is a view showing a process of generating a data frame,
6 is a diagram illustrating examples of a configuration of a data frame;
7 is a view showing a control process of a mobile communication system according to an embodiment of the present invention,
8 and 9 illustrate examples of statistical values calculated in a mobile communication network system.

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

A schematic configuration of a mobile communication network system 100 and a mobile communication terminal 200 according to an embodiment of the present invention is shown in FIG. 1.

As shown in the figure, the mobile communication terminal 200 communicates with the mobile communication network system 100 through a wireless section, for example, forms a communication channel with the base station 140 to perform communication.

The mobile communication terminal 200 according to the present embodiment includes all portable wireless communication terminals such as a mobile phone, a smart phone, and personal digital assistants (PDAs). A function of calculating a frame error rate and transmitting a call quality feedback signal (or power measurement feedback information) based on the calculated FER may be performed.

Meanwhile, the mobile communication network system 100 may include a base station 140, a base station controller 120, and a management server 130.

Here, the base station 140 forms a predetermined communication channel for communication with the mobile communication terminal 200, transmits a signal to the mobile communication terminal 200, and performs a function of receiving a signal from the mobile communication terminal 200.

The base station controller 120 controls at least one base station 140, and in particular, a voice signal received through the mobile communication network 110 and a predetermined control signal for controlling the mobile communication terminal 200 are transmitted through the base station 140. Controls the transmission.

In particular, the base station controller 120 divides the voice signal into predetermined packets, generates a data frame including the divided voice signal and the control signal, and each of the generated data frames passes through the base station 140 through the mobile communication terminal 200. Control to be sent). Of course, only one of a voice signal and a control signal may be included in the data frame.

As such, one data frame may include both data corresponding to a voice signal and data corresponding to a control signal. Hereinafter, a voice signal divided into a predetermined size to be included in the data frame is called a voice data packet. The control signal included in the data frame is called a signal data packet.

That is, the voice data packet may be a part of the voice signal actually heard by the user of the mobile communication terminal 200, and the signal data packet may correspond to a part of a predetermined control signal affecting the operation of the mobile communication terminal 200. .

An example of a control signal corresponding to the signal data packet is a message related to handoff, for example, a handoff direction message (HDM).

In particular, when the base station controller 120 fails to include both the signal data packet and the voice data packet in one frame due to the difference in capacity when generating the data frame, the base station controller 120 prioritizes the signal data packet, that is, discards the voice data packet and processes the signal data. A data frame including only a packet is generated and transmitted to the mobile communication terminal 200.

At this time, due to the discarded voice data packet, the mobile communication terminal 200 causes a decrease in call quality.

Therefore, in order to accurately determine the call quality state in the mobile communication terminal 200, the base station controller 120 in this embodiment collects statistical information about the rate at which the voice data packet is discarded when generating a data frame and manages the server 130. To be sent).

The management server 130 may properly predict and calculate the actual call quality, ie, the perceived call quality, felt by the user in the mobile communication terminal 200 according to a preset algorithm based on statistical information received from the base station controller 120. .

The estimated call quality information of the mobile communication terminal 200 thus predicted and calculated may be basic data for efficiently configuring the base station 140 related to forward power control or handoff processing.

In FIG. 1, the base station 140, the base station controller 120, and the management server 130 are divided into one example. However, the mobile communication network system 100 according to the present invention is limited to a specific function implemented in a specific device. It doesn't work.

Therefore, hereinafter, the mobile communication network system 100 according to an embodiment of the present invention will be described in detail with reference to FIG. 2.

As shown in the figure, the mobile communication network system 100 includes a transmitter 151, a data frame generator 152, a data packet generator 153, a data size comparator 154, and a statistical value calculator 155. And a haptic call quality calculation unit 156 and a receiving unit 157.

The data packet generator 153 performs a function of generating a signal data packet and a voice data packet. As described above, the signal data packet corresponds to a control message that does not have a direct correlation with the voice signal, and the voice data packet corresponds to a part of the voice signal that can be heard by the user of the mobile terminal 200. That is, the data packet generator 153 performs a function of dividing and generating, for example, a voice signal received from the calling terminal in predetermined "packet" units.

An example of a process of generating a voice data packet is shown in FIG. 3.

In FIG. 3, when a voice signal is received, a process of determining whether the voice signal corresponds to a real voice signal or noise (voice activity detection) and classifying each of the voice data into four types of voice data packets is illustrated. That is, the four types of classified voice data packets are full rate, half rate, quarter rate, and eighth rate.

This classification is classified according to the size (size) of the voice data packet by a predetermined algorithm.

For example, if the size of the voice data packet of the 'full rate' is as shown in Fig. 4 (a), half the size of the voice data packet of the 'full rate' as shown in Fig. 4 (b) The voice data packet corresponding to 'Quarter rate' corresponds to half of the 'Half rate' voice data packet shown in FIG. 4 (b), and the 'Eighth rate' voice data packet shown in FIG. 4 (c). As shown in (d), it corresponds to half of the voice data packet having a 'Quarter rate' of FIG.

The division of the voice signal into voice data packets having a specific size may be performed by various algorithms. For example, when the call between the mobile communication terminal 200 is continuous, a voice signal may be generated at the size of 'Full rate'. As another example, when the communication load of the mobile communication network 110 increases, the 'Quarter rate' It is also possible to generate a voice data packet having a size of '.

What is important is not the method of dividing into a specific size, but the fact that a voice signal is generated as a voice data packet of a specific size.

Meanwhile, the data size comparison unit 154 compares the data size of the signal data packet and the voice data packet with the preset data size.

The preset data size may correspond to, for example, the size of a data frame that will include a signal data packet and a voice data packet.

That is, the size of each data frame is determined, and the comparator determines whether the data size of the signal data packet and the voice data packet is larger or smaller than the predetermined size of the data frame.

The data frame generator 152 is configured to set a data size obtained by comparing the data size comparator 154 (that is, a data size obtained by adding a signal data packet and a voice data packet) to a preset data size (that is, a predetermined size of the data frame). If not greater than), a data frame including a signal data packet and a voice data packet is generated.

Here, the process performed by the data frame generation unit 152 is schematically illustrated in FIG. 5. For example, the generated voice data packet and the signal data packet are multiplexed by the data frame generator 152 and included in the data frame.

In addition to the method of sequentially including the signal data packet and the voice data packet in a data frame of a specific size as shown in FIG. 6, the data multiplexing method easily separates the signal data packet and the voice data packet from the other mobile communication terminal 200. Any way you can do it is fine.

In addition, the data frame generator 152 performs a function of generating a data frame excluding the voice data packet when the combined data size of the signal data packet and the voice data packet is larger than the preset data size. That is, in this case, the data frame includes only the signal data packet among the voice data packet and the signal data packet.

Referring to FIG. 6, when the signal data packet has a half size of the data frame, for example, a voice data packet having a half rate size may be included in the data frame as shown in FIG. 6 (a). Voice data packets with size are assumed to be half the size of the data frame.)

Of course, when the signal data packet has a half size of the data frame as shown in FIG. 6 (a), the voice data packet having a size smaller than the half rate (that is, the Quarter rate or the Eighth rate voice data packet) is included in the data frame. It may be transmitted to the mobile communication terminal 200.

On the contrary, if the size of the signal data packet to be transmitted to the mobile communication terminal 200 has half the size of the data frame as shown in FIG. 6 (a), the voice data packet having a size larger than the half rate (for example, Full rate voice data packet) means to be discarded (ie not included in the data frame).

Referring to the case of FIG. 6 (b), when the signal data packet to be transmitted to the mobile communication terminal 200 has the size of 3/4 of the data frame, the voice data packet having the quarter rate (of course, the smaller Eighth size) Rate data voice data packet) is included in the data frame together with the corresponding signal data packet to be transmitted to the mobile communication terminal 200.

Similarly, in the case of FIG. 6 (b), voice data packets (eg, half rate or full rate voice data packets) having a size larger than the quarter rate are discarded. 6 (c) and 6 (d) may be fully understood based on the above description.

The transmitter 151 transmits the generated data frame to the mobile communication terminal 200, and the receiver 157 receives the power measurement feedback information from the mobile communication terminal 200.

Here, the power measurement feedback information received by the receiver 157 is well known. For example, when the mobile communication terminal 200 receives the forward signal from the base station 140, the FER (Frame Error Rate) of the signal is calculated. It means information transmitted to the base station 140 in response to the calculated FER. Using the power measurement feedback information, the mobile communication network system 100 may determine whether the forward signal is properly transmitted to the mobile communication terminal 200.

The statistical value calculator 155 calculates a statistical value of a data frame rate excluding a voice data packet among data frames generated during a preset time.

That is, as described above, the data frame generator 152 may generate a data frame in which the voice data packet is excluded (that is, the exclusion here means discarding the voice data packet). Each time a frame is generated, the statistical value calculator 155 records and stores the data in a predetermined storage unit (not shown) and calculates the statistical value based on the stored information.

For example, a ratio of data frames generated by discarding voice data packets among data frames generated for 2 seconds and transmitted to the mobile communication terminal 200 may be calculated as statistics.

In this case, the statistical value calculator 155 may calculate statistical values classified according to the size of the voice data packet excluded from the data frame. That is, the calculated statistics may include information on the size of the voice data packet that is discarded without being included in the data frame.

The haptic call quality calculating unit 156 calculates the haptic call quality in the mobile communication terminal 200 based on the statistic calculated by the statistic calculator 155.

For example, the tangible call quality calculation unit 156 may set the tangible call quality numerically according to the ratio of data frames generated by discarding the voice data packet. In particular, in calculating the haptic call quality of the mobile communication terminal 200, the haptic call quality calculating unit 156 may use not only the calculated statistics but also power measurement feedback information received from the mobile communication terminal 200.

That is, it is possible to calculate the perceived call quality in the mobile communication terminal 200 by applying respective weights to the calculated statistics and the received power measurement feedback information.

Hereinafter, a control process of the mobile communication network system 100 according to an embodiment of the present invention will be described with reference to FIG. 7.

First, the mobile communication network system 100 generates a signal data packet and a voice data packet (step S1), and sets the size of the sum of the generated signal data packet and the voice data packet to a preset data size (for example, one data frame). The size of?) Is compared (step S3).

If the combined data size is larger than the preset data size (step S5), a data frame including only signal data packets except for voice data packets (i.e., discarded) is generated (step S7).

If the combined data size is not larger than the preset data size (step S5), a data frame including both the voice data packet and the signal data packet is generated (step S9).

Subsequently, the mobile communication network system 100 transmits the generated data frame to the mobile communication terminal 200 (step S11).

This process, that is, the process of generating a signal data packet and a voice data packet and transmitting the data frame to the mobile communication terminal 200 is repeated as long as there is data to be transmitted.

Meanwhile, the mobile communication network system 100 calculates a statistical value using a ratio of data frames generated by excluding voice data packets among data frames transmitted to the mobile communication terminal 200 for a preset time (step S13) (step S13). S15).

One example of the statistical values thus calculated is shown in FIGS. 8 and 9.

That is, in FIG. 8, 'FAR' is a new one borrowed corresponding to the FER for the convenience of description and means a frame abort ratio. That is, the ratio of the data frame generated by only the signal data packet after discarding the voice data packet among all data frames was expressed as FAR.

In addition, in FIG. 8, 'FAR' is based on 100 data frames as an example.

Therefore, the meaning of the first field means that 50 voices are generated when discarding the voice data packet among 100 data frames for one preset time (for example, 10 seconds) and the number of data frames is one or less. This means that a total of 10 times is the case where more than one and three or less data frames are generated after discarding voice data packets among 100 data frames for the same preset time (that is, 10 seconds).

As such, the mobile communication network system 100 may discard voice data packets among the generated data frames and calculate predetermined statistics using the generated data frames.

9 also shows separate statistics including the size of the discarded (excluding) voice data packet to generate the data frame. That is, the first field of FIG. 9 means that the voice of the full rate voice is discarded twice without being included in the data frame, and the second field indicates that half voice of the discarded voice data packets is lost. It means three times abandoned.

Using the various statistical values calculated as described above, the mobile communication network system 100 may more accurately calculate the perceived call quality in the mobile communication terminal 200 (step S17).

For example, in a handoff situation, many signal data packets are transmitted from the mobile communication network system 100 to the mobile communication terminal 200. In this case, voice data packets are often discarded due to the signal data packets. When the mobile communication terminal 200 receives a data frame in which the voice data packet is discarded (excluded), the mobile terminal 200 cannot properly demodulate the voice signal, and the user may think that the call quality is poor. Can be correctly determined.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. It is to be understood that such variations and modifications are intended to be included in the scope of the appended claims.

100: mobile communication network system 200: mobile communication terminal
110: mobile communication network 120: base station controller
130: management server 140: base station
151 transmission unit 152 data frame generation unit
153: data packet generation unit 154: data size comparison unit
155: Statistics calculation unit 156: Diminishing call quality calculation
157: receiving unit

Claims (6)

(a) generating a signal data packet and a voice data packet;
(b) comparing the data size of the sum of the signal data packet and the voice data packet with a preset data size;
(c) generating a data frame including the signal data packet and the voice data packet when the sum data size is not larger than the set data size, and generating the voice frame when the sum data size is larger than the set data size. Generating a data frame excluding the data packet and transmitting the data frame to a mobile communication terminal;
(d) calculating statistics of a data frame rate excluding the voice data packet among data frames generated during a preset time;
and (e) calculating a perceived call quality in the mobile communication terminal based on the calculated statistics. The method of claim 1,
In step (d),
And calculating statistical values classified according to the size of the voice data packet excluded from the data frame. The method according to claim 1 or 2,
The step (e) includes calculating the perceived call quality in the mobile communication terminal using both the power measurement feedback information received from the mobile communication terminal and the statistics calculated in the step (d). Control method of mobile communication network system. A data packet generator for generating signal data packets and voice data packets;
A data size comparison unit for comparing the data size of the sum of the signal data packet and the voice data packet with a preset data size;
When the sum data size is not greater than the set data size as a result of the comparison of the data size comparison unit, a data frame including the signal data packet and the voice data packet is generated and the sum data size is larger than the set data size. A data frame generator for generating a data frame excluding the voice data packet;
A transmitter for transmitting the generated data frame to a mobile communication terminal;
A statistical value calculator for calculating a statistical value of a data frame rate excluding the voice data packet among data frames generated during a preset time;
And a haptic call quality calculation unit for calculating haptic call quality in the mobile communication terminal based on the calculated statistics. The method of claim 4, wherein
The statistical value calculating unit calculates the statistical values classified according to the size of the voice data packet excluded from the data frame. The method according to claim 4 or 5,
Further comprising a receiving unit for receiving power measurement feedback information from the mobile communication terminal,
The haptic call quality calculating unit calculates haptic call quality in the mobile communication terminal using both the power measurement feedback information received from the receiving unit and the statistics calculated by the statistic calculator.

Images