KR101019170B1 - Method and Apparatus of Deciding an Initial Delay in Network Synchronization Systems - Google Patents

Abstract

The present invention relates to a method of setting an initial reference value for acquiring synchronization between a master and a slave in a network system. (A) An adjustment reference value and an adjustment value for removing an instantaneous extreme value using a measurement delay value between the master and the slave are provided. Determining; (b) comparing the measurement delay value and the adjustment reference value for each sample; (c) if the measurement delay value is greater than or equal to the adjustment reference value, adjusting the measurement delay value to the adjustment value and adjusting the measurement delay value. If it is smaller than the reference value, using the measurement delay value as it is, and (d) obtaining the initial reference value using the adjustment value and the measurement delay value.

Description

Method and Apparatus for Setting Initial Reference Value in Network Synchronization System {Method and Apparatus of Deciding an Initial Delay in Network Synchronization Systems}

The present invention relates to a network synchronization system, and more particularly, an average value of samples of the measurement delay value from which the instantaneous extreme value is removed among the samples of the measurement delay value between the master and the slave is determined as an initial reference value. A method and apparatus for setting a reference value.

In general, a network system performs network synchronization that matches a clock between a master and a slave forming a network. The network synchronization process may be performed differently according to the characteristics of the network system.

If the network system can receive the GPS signal, network synchronization between the master and the slave is performed according to the clock of the GPS signal. However, when the network system cannot receive the GPS signal, it is necessary to form a network by connecting a dedicated line between the master and the slave, as in the case of an indoor portable Internet system, thereby acquiring network synchronization. This is because indoor mobile Internet systems receive signals from indoor lines using dedicated lines such as VDSL (Very High Data Rate Digital Subscriber Line), FTTH (Fiber To The Home), and LAN (Local Area Network). This is because the GPS signal cannot be received.

To this end, in the related art, a technique for acquiring network synchronization through IEEE 1588 (Precision clock synchronization protocol for network measurement and control systems) has been disclosed. In the conventional IEEE 1588, a slave clock is synchronized with a master clock (actually having the most stable and accurate time base) based on the master and slave architectures.

In the conventional IEEE 1588, the slave clock offset is determined based on the assumption that the message propagation time between the master and the slave is completely symmetrical and the delay value between the master and the slave is always constant. This will be described with reference to FIG. 1.

As shown in Figure 1, the master periodically sends a 'Sync' message to the slave. The slave responds with a 'Delay_Req' message. Here, the time stamp of the 'Sync' message is t ₁ when transmitting from the master and t ₂ when receiving at the slave, and the time stamp of the 'Delay_Req' message is t ₃ when transmitting from the slave and t when receiving at the master. ₄

As described above, in the conventional IEEE 1588, both the transmission and the reception of the message are processed as time stamped by the clock, and ultimately, the slave clock offset is a 'Sync' message time stamp (t ₁ , t ₂ ) and a transmission time (T _transmission ). Through Equation 1 is calculated. In this case, T _transmission means the time taken for the message to actually move in the physical network layer.

T _transmission = [(t ₄ -t ₁ ) + (t ₃ -t ₂ )] / 2

Slave Clock Offset = t ₂ -t ₁ -T _transmission

Thereafter, the conventional IEEE 1588 synchronizes the slave clock to the master clock through the slave clock offset.

However, such a conventional synchronization method according to IEEE 1588 has a limitation in being applied as it is to a real situation. As described above, the conventional IEEE 1588 is proposed based on the assumption that the message transfer time between the master and the slave is completely symmetrical, and that the delay value between the master and the slave is always constant. For example, in an indoor portable Internet system, the amount of bidirectional data transmission, switch buffering, and the like do not always change constantly, and thus timing jitter may occur. Therefore, since the conventional method of obtaining network synchronization through IEEE 1588 can be used under the assumption that the delay value between the master and the slave must be kept constant, there is a need to reduce the timing jitter included in the measurement delay value.

However, in a technique of reducing timing jitter for acquiring network synchronization in a network system such as an indoor portable Internet system, an instantaneous extreme value may exist among measurement delay values between a master and a slave. This instantaneous extreme value adversely affects the average value required to set the initial reference value during the initial reference setting phase required for the technique of reducing timing jitter.

For example, FIG. 2 is a graph measuring a delay value between a master and a slave in a VDSL network. Here, the number of samples of a measurement delay value is 6x10 <^3> . As shown in FIG. 2, the measurement delay value represents a change amount of 2 ms or more, and it can be seen that an extreme value exists instantaneously among samples. This means that there is a timing jitter with instantaneous extremes for the time delay between the master and the slave.

Therefore, there was a problem in obtaining the appropriate average value due to the instantaneous extreme value when setting the initial reference value that should be set in order to remove the timing jitter for the time delay between the master and the slave.

The present invention has been invented in view of the above, and provides a method and apparatus for removing timing jitter from more accurate average value derivation by removing instantaneous extremes occurring among samples measured to set an initial reference value. Has its purpose.

According to an aspect of the present invention for achieving the above object, in the initial reference value setting method for acquiring synchronization between the master and the slave in the network system, (a) using the measurement delay value between the master and the slave to determine the instantaneous extreme value Determining an adjustment reference value and adjustment value for removal; (b) comparing the measurement delay value and the adjustment reference value for each sample; and (c) adjusting the measurement delay value if the measurement delay value is greater than or equal to the adjustment reference value. And adjusting the measurement delay value as it is smaller than the adjustment reference value, and (d) obtaining an initial reference value using the adjustment value and the measurement delay value.

In this case, in step (a), the adjustment value is preferably determined as the average value of the measurement delay values. And in step (c), it is preferable to use a clipping method to adjust the measurement delay value to the adjustment value. Furthermore, in step (d), the initial reference value is preferably obtained as an arithmetic mean value of the adjustment value and the measurement delay values.

Another aspect of the present invention for achieving the above object is a delay value measuring unit for measuring the delay value of the signal between the master and the slave, in the initial reference value setting device for obtaining synchronization between the master and the slave in the network system, delay value An adjustment reference value and an adjustment value determiner for determining an adjustment reference value and an adjustment value for removing an instantaneous extreme value using a measurement delay value input from the measurement unit, a comparison unit for comparing the measurement delay value and the adjustment reference value for each sample; An adjustment unit for adjusting the measurement delay value to the adjustment value when the measurement delay value is greater than or equal to the adjustment reference value, and an initial reference value calculation unit for obtaining an initial reference value using the adjustment value input from the adjustment unit and the measurement delay value input from the comparison unit. do.

At this time, in the adjustment reference value and the adjustment value determination unit, it is preferable to determine the adjustment value as an average value of the measurement delay values. And it is preferable that the adjustment part adjusts a measurement delay value to an adjustment value using a clipping means. Furthermore, it is preferable that the initial reference value calculator calculate the initial reference value as an arithmetic mean value of the adjustment value and the measurement delay values.

The present invention can be applied to obtaining network synchronization by IEEE 1588 in an indoor portable Internet system.

As described above, according to the present invention, by using the average value of the samples of the measurement delay value from which the instantaneous extreme value is removed among the samples of the measurement delay value between the master and the slave as the initial reference value, the delay value is further increased to the stable region. At the same time, the rate of change of the delay value can be reduced to within 20 μs as specified in the mobile Internet standard. In other words, by reducing the existing timing jitter by using the initial reference value, it is possible to obtain network synchronization within the allowable range proposed in the portable Internet standard.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the following embodiments are provided to those skilled in the art to fully understand the present invention, and may be modified in various forms, and the scope of the present invention is limited to the embodiments described below. It doesn't happen.

The present invention can be applied to the case of reducing the timing jitter present in the time delay between the master and the slave of any network system to obtain network synchronization. Only the indoor WiBro system will be described. Thus, it will be apparent to those skilled in the art that the present invention may be applied to any network system even if the invention is limited to the indoor portable Internet system.

3 is a flowchart illustrating a method of setting an initial reference value in a network synchronization system according to a preferred embodiment of the present invention, and FIG. 4 is a block for explaining an apparatus of setting an initial reference value in a network synchronization system according to an embodiment of the present invention. It is also.

In indoor mobile Internet system, the arithmetic mean value of samples of delay value measured between master and slave is called initial reference value. This initial reference value converges to the actual delay value as the number of samples of the measurement delay value decreases due to variable timing jitter. At this time, in order to obtain a reliable initial reference value, an instantaneous extreme value that adversely affects the initial reference value is removed as follows.

First, the indoor portable Internet system determines an adjustment reference value to remove the instantaneous extreme value by using the measurement delay value extracted according to the preset number of samples through the experiment (step 301). The extreme value refers to values much higher than the typical average value of the samples (for example, the delay value is 0.0045 to 0.005 seconds), for example, the delay value is more than 0.0055 seconds. At this time, the adjustment reference value may be determined to be 0.0055 seconds, and this adjustment reference value is determined experimentally according to the measurement delay value.

Then, an adjustment value for adjusting the instantaneous extreme value is determined (step 302). The adjustment value is a value for adjusting the extreme values and is preferably set as an average value of the measurement delay values. For example, in FIG. 2, the adjustment value may be determined to a value of 0.0045 to 0.005 seconds, and this adjustment value is determined experimentally according to the measurement delay value.

Such adjustment reference value determination and adjustment value determination are performed in the adjustment reference value and adjustment value determination unit 402 of the initial delay value setting device shown in FIG. 4, and the adjustment reference value and adjustment value determination unit 402 is a delay value measurement unit ( The measurement delay value is input from the 401.

Next, the measurement delay value and the adjustment reference value are compared for each sample (step 303). This comparison is performed in the comparison unit 403, and the comparison unit 403 receives the adjustment reference value and the adjustment value from the adjustment reference value and the adjustment value determination unit 402.

If the measurement delay value is greater than or equal to the adjustment reference value, the measurement delay value is adjusted to the adjustment value (step 304). In other words, if the measurement delay value is larger than the adjustment reference value, it corresponds to the extreme value and is adjusted to the adjustment value. In this embodiment, when the measurement delay value is greater than or equal to the adjustment reference value, the measurement delay value is adjusted to the adjustment value. However, the measurement delay value may be adjusted to the adjustment value only when the measurement delay value is larger than the adjustment reference value. This adjustment is performed by the adjustment unit 404 of FIG. 4, and the adjustment unit 404 receives a signal from the comparison unit 403 that the measurement delay value is greater than or equal to the adjustment reference value, and adjusts the measurement delay value to the adjustment value. To this end, the adjusting unit 404 may use a clipping method, and a known clipping circuit may be used.

On the contrary, if the measurement delay value is smaller than the adjustment reference value, the measurement delay value is used as it is (step 305). If the measurement delay value is smaller than the adjustment reference value, there is no reason to regard the measurement reference value as an extreme value, and there is no problem even if it is used as it is without the need to adjust the measurement reference value.

Subsequently, an initial reference value is obtained using the adjustment values and the measurement delay values obtained in steps 304 and 305 (step 306). The initial reference value can be found as the arithmetic mean value of measurement delays and adjustments of a certain number of samples. The process of obtaining the initial reference value is performed by receiving the measurement delay value and the adjustment value from the comparator 403 and the adjustment unit 404 in the initial reference value calculator 405. Therefore, by removing the extreme value, the initial reference value closer to the actual delay value is obtained.

Hereinafter, a case in which an initial reference value is set by applying the present invention in a network synchronization system will be described in comparison with a conventional method.

FIG. 5 is a graph of the delay value determined for obtaining network synchronization using the existing method with respect to FIG. 2. Here, the sample number of the measurement delay value for setting an initial reference value shows the case where N = 100.

As shown in FIG. 5, when the number of samples of the measurement delay value is 2000 or more, it can be seen that the variation range of the delay value for network synchronization exceeds 30 μs (that is, 0.03 ms). Only when the number of samples of the measurement delay value is 2000 or more, the change range of the delay value converges to the stable region. This means that in the case where the initial reference value does not approach the actual delay value probabilisticly, convergence time is required to acquire network synchronization within the allowable ranges specified in the portable Internet standard.

FIG. 6 is a graph of the determined delay value when the present invention is applied to obtain network synchronization with respect to FIG. 2. Here, 50 samples were used to set the adjustment reference value and the adjustment value, and the number of samples of the measurement delay value for setting the initial reference value was used when N = 100. The sample of the measurement delay value was measured every 1 second.

As shown in Fig. 6, when the present invention is applied for the instantaneous extreme value removal of the measurement delay value, the variation range of the delay value for network synchronization does not exceed 20 μs (ie 0.02 ms). It can be seen. In other words, it can be seen that the convergence speed is fast and the network synchronization can be effectively obtained within the allowable range suggested in the portable Internet standard.

1 is a view for explaining a method for setting a slave delay value by a conventional method.

2 is a graph measuring a delay value between a master and a slave in a network using a VDSL.

3 is a flowchart illustrating a method of setting an initial reference value in a network synchronization system according to a preferred embodiment of the present invention.

4 is a block diagram illustrating an apparatus for setting an initial reference value in a network synchronization system according to an exemplary embodiment of the present invention.

FIG. 5 is a graph of the delay value determined for obtaining network synchronization using the conventional method with respect to FIG. 2.

FIG. 6 is a graph of the determined delay value when the present invention is applied to obtain network synchronization with respect to FIG. 2.

Claims (10)

In the network system, the first reference value setting method for obtaining synchronization between the master and the slave, (a) determining an adjustment reference value and an adjustment value for removing the instantaneous extreme value using the measurement delay value between the master and the slave; (b) comparing the measurement delay value and the adjustment reference value for every sample; (c) adjusting the measurement delay value to the adjustment value using a clipping method if the measurement delay value is greater than or equal to the adjustment reference value, and using the measurement delay value as it is if the measurement delay value is smaller than the adjustment reference value; (d) using an adjustment value and a measurement delay value, to obtain an initial reference value which is an arithmetic mean value of samples of the delay value measured between the master and the slave. The method of claim 1, wherein in step (a), The adjustment value is determined as an average value of the measurement delay values. delete The method of claim 1, wherein in step (d), Wherein the initial reference value is obtained as an arithmetic mean value of the adjustment value and the measurement delay value. A method according to claim 1, which is applied to obtaining network synchronization by IEEE 1588 in an indoor portable Internet system. In the first reference value setting device for obtaining synchronization between the master and the slave in the network system, A delay value measuring unit measuring a delay value of a signal between a master and a slave; An adjustment reference value and an adjustment value determination unit that determines an adjustment reference value and an adjustment value for removing an instantaneous extreme value using the measurement delay value input from the delay value measurement unit; A comparison unit for comparing the measurement delay value and the adjustment reference value for each sample; An adjusting unit for adjusting the measurement delay value to an adjustment value by using clipping means when the measurement delay value is greater than or equal to the adjustment reference value; And an initial reference value calculator for calculating an initial reference value which is an arithmetic mean value of samples of the delay value measured between the master and the slave, using the adjustment value input from the adjustment unit and the measurement delay value input from the comparison unit. Device. The apparatus of claim 6, wherein the adjustment reference value and the adjustment value determination unit determine the adjustment value as an average value of measurement delay values. delete The apparatus of claim 6, wherein the initial reference value calculator calculates an initial reference value as an arithmetic mean value of the adjustment value and the measurement delay values. 7. The apparatus of claim 6, applied to obtaining network synchronization by IEEE 1588 in an indoor portable Internet system.

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