KR100334775B1 - Method for calculating number of effective traffic channel in coder mixed base station - Google Patents

Abstract

The present invention relates to a method for calculating the number of effective traffic channels that can be served by a mixed vocoder base station using a plurality of vocoders having different data rates and different data types.

The present invention calculates the average data transmission rate per subscriber of the base station according to the pre-allocated ratio of subscribers using each vocoder at the same time as the data processing speed of each vocoder and the call volume per subscriber pre-assigned to each vocoder, and calculated Calculate the number of effective traffic channels that the base station can serve using the average data rate per subscriber.

As a result, by calculating the number of effective traffic channels required by a mixed vocoder base station using a plurality of vocoders having different data processing rates or different data types, various system parameters required for designing a mixed vocoder base station, that is, call volume per vocoder And the ratio of subscribers per vocoder can be effectively determined.

Description

Calculation method of effective traffic channel number of mixed encoder base station {METHOD FOR CALCULATING NUMBER OF EFFECTIVE TRAFFIC CHANNEL IN CODER MIXED BASE STATION}

The present invention relates to a method for calculating the number of effective traffic channels of a base station. In particular, a plurality of voice coders having different data rates and different data types, that is, using a vocoder, are used. The present invention relates to a method of calculating the number of traffic channels that a vocoder mixed base station can serve.

Conventional wireless base stations that carry voice between wireless subscribers use an 8K Enhanced Variable Rate CODEC (EVRC) vocoder or 13K vocoder. This Voice Coder (Vocoder) is a kind of voice band coder, which decomposes a voice signal into several parameters representing the characteristics and activity of the sound source and resonator, and transmits the original voice according to these parameters. To synthesize the signal. In order to transmit information between the base station and the subscriber, an accurate analysis of the radio capacity between the forward link and the reverse link, that is, the number of traffic channels must be performed. The design consideration of the base station is the number of effective traffic channels, which are traffic channels that the base station can actually service.

In the conventional system, since the voice-oriented service was mainly provided using 8K EVRC vocoder, only one channel (voice channel) was set up for one subscriber. Therefore, only one vocoder speed and the number of effective traffic channels of the system for voice need to be determined.

In recent years, in response to various needs of subscribers, base stations have been introduced that use 8K EVRC vocoder and 13K vocoder, or use a vocoder providing data service as well as a vocoder providing voice service. In this case, since a large amount of information must be transmitted between the system and the subscriber in order to provide Internet service or video service to the data service subscriber, several traffic channels can be allocated for one subscriber.

However, in the related art, a method for calculating the number of effective traffic channels for the mixed vocoder base station has not been proposed at all. Therefore, there is a need to calculate the number of effective traffic channels of a base station by distinguishing between using 8K vocoder and using 13K vocoder, or using voice service vocoder and using data service vocoder. That is, in order to be able to provide both voice and data services to all subscribers who want various services, there is a need to determine the number of effective traffic channels that a mixed vocoder base station can serve.

Accordingly, an object of the present invention, which is designed to solve the problems of the prior art operating as described above, provides a method for calculating the number of effective traffic channels of a mixed encoder base station using a plurality of encoders having different data processing rates. It is.

Another object of the present invention is to provide a method for calculating the number of effective traffic channels of a mixed encoder base station using a plurality of encoders having different data types.

It is still another object of the present invention to provide a method for calculating the number of effective traffic channels of a mixed encoder base station using a plurality of encoders having different data rates and data types.

An embodiment of a method for calculating the effective traffic channel number of a mixed encoder base station according to the present invention, which has been devised to achieve the above object,

Calculating an average data transmission rate per subscriber of a base station using a plurality of encoders having different data processing rates and data types; And

And calculating the effective traffic channel number that can be served by the base station using the average data transmission rate per subscriber and predetermined parameters defined by an operator.

1 is a diagram illustrating an effective traffic channel number calculation operation of a mixed encoder base station according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described the operating principle of the preferred embodiment of the present invention. In the following description of the present invention, detailed descriptions of well-known functions or configurations will be omitted if it is determined that the detailed description of the present invention may unnecessarily obscure the subject matter of the present invention.

The present invention provides a method for calculating the number of effective traffic channels of a mixed encoder base station using a plurality of encoders having different data rates or different data types. The main task of the present invention for this purpose is to find the average data rate (data rate) for each subscriber of the base station mixed with the encoder. In the present specification, the operation of the present invention will be described with reference to a base station using two vocoder, but the present invention is not limited to the vocoder and can be applied to any encoder that compresses voice or data. It is self-evident to.

Figure 1 shows the effective traffic channel number calculation operation of the mixed vocoder base station according to the present invention.

Referring to FIG. 1, first, each vocoder is considered in consideration of the allocated call volume per subscriber of two vocoders having different data processing speeds or different data types (voice or data), and the ratio of subscribers using the respective vocoders at the same time. Determine the traffic load ratio of the.

In this case, the traffic load, that is, the traffic unit of traffic, is Erlang. Since the traffic volume has no dimension, the unit is set to 1 and this is called Erlang. For example, when one line is observed for 1 hour, when all lines are in use for one hour or when an arbitrary group of lines is observed at any time, the number of lines in use is five. .

When the traffic load rate of each vocoder is multiplied by the data throughput rate of each vocoder and the voice activity (or data activity) of each vocoder, and the two results are summed together, the average data transmission per subscriber of the base station considering both vocoders is added. You can get speed.

As a first embodiment, if the data types of the first vocoder and the second vocoder having different data throughputs are the same as voice and the traffic load per subscriber is the same, the traffic load ratio of the two vocoder is equal to the subscriber ratio of the two vocoder. Since the same, the average data transmission rate for each subscriber of the base station is as shown in Equation 1 below.

Average data transfer rate by subscriber = (data rate of first vocoder) x (first subscriber rate) x (voice activity) + (data rate of second vocoder) x (second subscriber rate) x (voice activity)

As a second embodiment, when the first vocoder and the second vocoder serve voice and data, respectively, and the traffic load for each subscriber is also different, the average data transmission rate for each subscriber of the base station is expressed by Equation 2 below.

Average data transfer rate by subscriber = (data rate of first vocoder) · (traffic load rate of first vocoder) · (voice activity) + (data rate of second vocoder) · (traffic load rate of second vocoder) ) · (Data Activity)

When the average data transmission rate for each subscriber is determined as described above, the number of effective traffic channels that the base station can serve can be calculated using this. The procedure for calculating the number of effective traffic channels is the same in the first and second embodiments above.

However, in general, the base station is sectorized to increase frequency reuse efficiency. In this case, the effective traffic channel number should be calculated for each sector. This is because each sector of the base station provides services independently of each other. Therefore, a procedure for calculating the number of effective traffic channels for each sector will be described below.

Spreading bandwidth W of the base station, average signal-to-noise ratio Eb / No required by the base station, frequency reuse efficiency F according to sectorization of the base station, sectorization gain Gs according to sectorization of the base station, and number of sectors of the base station Considering N, the maximum number of users Nmax per sector that each sector of the base station can accommodate can be obtained by Equation 3 below.

However, in a typical base station design, the ratio of the number of traffic channels to the maximum number of users (hereinafter referred to as a loading factor) is pre-assigned in units of%, and the number of traffic channels is determined according to this value. Therefore, the traffic channel number Na of each sector is obtained by multiplying the maximum number Nmax by the loading factor. In addition, considering the ratio of calls introduced from the outside through handoff, the number of effective traffic channels for each sector that can service all the calls of the corresponding sector can be obtained.

Hereinafter, the present invention will be described in detail by using an example of a three-sectorized base station by serving a mixed 8K EVRC voice vocoder and 13K voice vocoder for each subscriber.

In the base station using two different speed vocoder, other base station system capacity-related factors, for example, Voice Activity, except for the speed of the vocoder are the same. This is because both vocoders code speech. In this case, if the allocated ratio of the subscriber using the 8K EVRC voice vocoder and the subscriber using the 13K voice vocoder is the same as 50%, the traffic load ratio of each vocoder is also the same. Therefore, the traffic load ratio of each vocoder is 50%: 50%.

Since the data processing speed of the 8K EVRC voice vocoder is 9.6kbps and the data processing speed of the 13K voice vocoder is 14.4kbps, when voice activity is 0.4, in this case, the average data transmission rate per subscriber is 9.6k × 0.5 × 0.4 + 14.4. k x 0.5 x 0.4 = 4.8 kbps.

If the average data transmission rate for each subscriber is R, the spreading bandwidth W (= 1.23 MHz), the average signal-to-noise ratio Eb / No (7 dB = 10 ^7/10 = 5.011), the frequency reuse efficiency F (= 0.67), and 3 In consideration of the sectorization gain Gs (2.55 / 3) according to sectorization, the maximum number of users Nmax for each sector can be obtained by Equation 4 below.

≒ 30.12

In this example, the maximum number of users Nmax that each sector of the base station can serve is set to 30, which is an integer closest to the result of Equation 4 above. If the loading factor value assigned to the base station is 75%, the number Na of traffic channels per sector is 30x0.75x22. In addition, if the ratio of incoming calls through the handoff is 40%, the number of effective traffic channels per sector is 22 / 1.4? 15.71, which is 15 considering the margin.

According to Willam.CYLee, "Mobile Cellular Telecommunications," which describes the relationship between the number of effective traffic channels and volume, a sector having 15 effective traffic channels per sector when a blocking rate of calls is assumed to be 2%. The quantity of is determined by 9.0 lang. Thus, the volume of each sector is 4.5 Er. In addition, the total number of traffic loads required by the base station having three sectors is 9.0 × 3 = 18.

Hereinafter, the present invention will be described in detail using an example of a three-sectorized base station that serves a mixture of 8K EVRC voice vocoder and 13K data vocoder for each subscriber.

At the same time, the allocated ratios of subscribers using the 8K EVRC voice vocoder and subscribers using the 13K data vocoder are 90% and 10%, respectively, and the volumes assigned to each vocoder by subscriber are 0.03 Erlang and 0.1 Erlang, respectively. In this case, since the subscriber volume is different from that of the base station serving only voice, the ratio of the traffic load for the two vocoders is obtained first.

The traffic load of the 8K EVRC voice vocoder is 0.03 × 90% = 2.7 because the product of the subscriber-specific volume allocated to the 8K EVRC voice vocoder and the ratio of subscribers using the 8K EVRC voice vocoder. In addition, the traffic load of the 13K data vocoder is 0.1 × 10% = 1 since the product of the call volume per subscriber assigned to the second vocoder and the ratio of subscribers using the 13K data vocoder. Therefore, the traffic load ratio of the 8K EVRC voice vocoder and the 13K data vocoder is 2.7: 1 = 73%: 27%.

Meanwhile, since the data processing speed of the 8K EVRC voice vocoder is 9.6kbps and the data processing speed of the 13K data vocoder is 14.4kbps, the average data transmission rate of each subscriber of the base station is calculated in consideration of this value (9.6kbps × 0.4 × 0.73) + (14.4 kbps x 1 x 0.27) = 6.7 kbps. Wherein 0.4 is negative activity and 1 is data activity.

If the average data transmission rate for each subscriber is R, spreading bandwidth W (= 1.23 MHz), average signal-to-noise ratio Eb / No (7dB = 10 ^7/10 = 5.011), frequency reuse efficiency F (= 0.67), 3 In consideration of the sectorization gain Gs (2.55 / 3) according to sectorization, the maximum number of users Nmax for each sector can be obtained by Equation 5 below.

≒ 21.877

In this example, the maximum number of users Nmax that each sector of the base station can serve is set to 22, which is an integer closest to the result of Equation 5 above. If the loading factor value assigned to the base station is 75%, the number Na of sectoral traffic channels is 22x0.75x16. In consideration of the handoff call, the number of effective traffic channels per sector is 16 / 1.4? 11.43, which is 11 when considering the margin.

According to Willam.C.Y.Lee, " Mobile Cellular Telecommunications, " assuming that the call blocking rate is 2%, the volume of a sector using 11 effective traffic channels per sector becomes 5.8 lang. Thus, the volume of 8K EVRC voice service subscribers in each sector is 5.8 × 0.73 × 4.23 Earl, and the volume of 13K data service subscribers is 5.8 × 0.27 ≒ 1.57 Earl. In addition, the total amount of traffic load required by the base station having three sectors is 5.8 × 3 = 17.4.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by those equivalent to the scope of the claims.

In the present invention operating as described in detail above, the effects obtained by the representative ones of the disclosed inventions will be briefly described as follows.

The present invention provides a method for calculating the number of effective traffic channels that a base station can serve in a mixed vocoder base station using a plurality of vocoders having different data rates or different data types, thereby designing a mixed vocoder base station. Various necessary system parameters, i.e. call volume for each subscriber, can be effectively determined. Therefore, the present invention has the effect that it is possible to provide both voice and data services to all subscribers who want a variety of services.

Claims (11)

Calculating an average data rate for each subscriber of a base station using a plurality of encoders having different data rates; And And calculating the effective traffic channel number that can be served by the base station using the average data transmission rate per subscriber and predetermined parameters defined by an operator. The method of claim 1, wherein the average data transmission rate for each subscriber, In response to each of the plurality of encoders, a product of a data processing rate of each encoder, a subscriber ratio assigned to each encoder, and a speech activity of each encoder is calculated, and the sum of the results of the products calculated for each of the encoders is calculated. The method of calculating the effective traffic channel number of the encoder mixed base station determined. The method of claim 1 or 2, wherein the calculating of the number of effective traffic channels of the base station comprises: Obtaining a maximum number of users that the base station can serve according to the average data transmission rate for each subscriber and predetermined parameters among the predetermined parameters; And calculating the effective traffic channel number of the base station using the maximum number of users and predetermined parameters required among the predetermined parameters. 4. The method of claim 3, wherein the base station has a sectorization structure, and the predetermined parameters required for obtaining the maximum number of users are the average signal-to-noise ratio of the base station and the frequency reuse efficiency according to the sectorization of the base station and the base station. Sectorization gain according to sectorization, spreading bandwidth of the base station and the number of sectors of the base station, The maximum number of users Nmax for each sector of the base station is an integer closest to the result of Equation 6 below, the effective traffic channel number calculation method of the mixed encoder base station. R: Average data transfer rate by subscriber W is the spreading bandwidth of the base station Eb / No: Average signal-to-noise ratio of base station F: Frequency reuse efficiency according to sectorization of base station Gs: Sectorization Gain by Sectorization of Base Station N: number of sectors of base station The method of claim 3, wherein the calculating of the number of effective traffic channels of the base station comprises: The predetermined parameters required for calculating the number of effective traffic channels of the base station are multiplied by the maximum number of users per sector by the loading factor of the base station when the ratio of the handoff call and the loading factor pre-assigned to the base station. Calculating the number of traffic channels per sector; And Calculating the number of effective traffic channels per sector of the base station by dividing the number of traffic channels per sector by the ratio of total calls including the ratio of the handoff call. Way. Calculating an average data transmission rate per subscriber of a base station using a plurality of encoders having different data processing rates and data types; And And calculating the effective traffic channel number that can be served by the base station using the average data transmission rate per subscriber and predetermined parameters defined by an operator. The method of claim 6, wherein the average data transmission rate for each subscriber, In response to each of the plurality of encoders, a product of a data processing speed of each encoder, a traffic load ratio of each encoder, and an activity of each encoder is calculated, and is determined as a sum of the results of the products calculated for each of the encoders. , Effective traffic channel count calculation method of a mixed base station. The traffic load ratio of each of the encoders is: And determining the effective traffic channel number of the mixed encoder base station by a product of a call amount per subscriber previously allocated to each encoder and a pre-allocated ratio of subscribers using the respective encoders at the same time. 9. The method of any one of claims 6 to 8, wherein calculating the number of effective traffic channels of the base station comprises: Obtaining a maximum number of users that the base station can serve according to the average data transmission rate for each subscriber and required parameters among the predetermined parameters; And calculating the effective traffic channel number of the base station using the maximum number of users and predetermined parameters required among the predetermined parameters. 10. The apparatus of claim 9, wherein the base station has a sectorization structure, and the predetermined parameters required for obtaining the maximum number of users are spreading bandwidth of the base station, an average signal-to-noise ratio of the base station, and a frequency according to sectorization of the base station. When the reuse efficiency and the sectorization gain according to the sectorization of the base station and the number of sectors of the base station, The maximum number of users Nmax for each sector of the base station is an integer closest to the result of Equation 7 below, the effective traffic channel number calculation method of the mixed encoder base station. R: Average data transfer rate by subscriber W is the spreading bandwidth of the base station Eb / No: Average signal-to-noise ratio of base station F: Frequency reuse efficiency according to sectorization of base station Gs: Sectorization Gain by Sectorization of Base Station N: number of sectors of base station The method of claim 9, wherein the calculating of the number of effective traffic channels of the base station comprises: When the predetermined parameter required to calculate the number of effective traffic channels of the base station is a ratio of a loading factor and a handoff call pre-assigned to the base station, the maximum number of users per sector is multiplied by the loading factor of the base station. Calculating the number of traffic channels per sector; Calculating the number of effective traffic channels per sector of the base station by dividing the number of traffic channels per sector by the ratio of total calls including the ratio of the handoff call. Way.