KR101222866B1 - Method and device for communicating with multiple terminals - Google Patents

Abstract

According to an embodiment of the present disclosure, an apparatus for performing communication includes a delay measuring module configured to perform communication with a plurality of terminals, the down delay time of the plurality of terminals; An alignment module configured to perform a first alignment in which the plurality of terminals are arranged in a reverse order based on a down delay time, and determine a transmission interval of each terminal according to the first alignment order; And a transmission regulator module for transmitting data to the respective terminals in the first sorting order, wherein the transmission regulator module transmits the data to the first terminal and waits for the transmission interval of the first terminal. And transmitting the data to a second terminal which is in a lower order of the first terminal in a first sorting order.

Description

Method and apparatus for communicating with a plurality of terminals {METHOD AND DEVICE FOR COMMUNICATING WITH MULTIPLE TERMINALS}

The present invention relates to a method and apparatus for performing communication through a network, and more particularly, to a method and apparatus for providing a data service through a network.

The data service provided through a packet-based network varies depending on the network environment and the performance of the device, that is, a data service providing environment, that is, data transmission speed and delay time.

In particular, in the case of providing a network-based data service in which a plurality of terminals participate together, it is important to overcome the differences in the network environment between the terminals.

Accordingly, an object of the present invention is to solve the above problems.

Specifically, an object of the present invention is to provide a method and apparatus for allowing each terminal to receive the content at substantially the same time with respect to terminals having different network environments.

It is also an object of the present invention to provide a method and apparatus for transmitting data transmitted from different terminals having different network environments to a server side by compensating for delay due to the network environment.

In order to solve the above problems, the present disclosure provides an apparatus for communicating with a plurality of terminals.

The apparatus may include a delay measuring module measuring down delay times of the plurality of terminals; An alignment module configured to perform a first alignment in which the plurality of terminals are arranged in a reverse order based on a down delay time, and determine a transmission interval of each terminal according to the first alignment order; And a transmission regulator module for transmitting data to the respective terminals in the first sorting order, wherein the transmission regulator module transmits the data to the first terminal and waits for the transmission interval of the first terminal. It may be a device for transmitting the data to the second terminal in the lower order of the first terminal in the first sort order.

In addition, the data may be received from another device.

In addition, the transmission interval of the first terminal may be determined by the difference between the down delay time of the first terminal and the down delay time of the second terminal.

Further, the sorting module is further configured to determine each up to the first terminal in the first sorting order when the sum of the respective transmission intervals to the terminal in the first sorting order of the first terminal exceeds a transmission delay threshold. The transmission interval can be determined as '0'.

In addition, the delay measuring module may be a unidirectional measuring module.

The delay measurement module may be a bidirectional measurement module and may measure the downlink delay time based on the round trip delay time of each terminal.

In addition, the delay measuring module measures the up delay time of the plurality of terminals, the alignment module performs a second alignment to sort the plurality of terminals in the reverse order based on the up delay time, the second sort order The reception regulator module may further include a reception regulator module configured to determine a reception interval of each terminal and to process data received from each terminal according to the second sorting order, wherein the reception regulator module may receive data received from a third terminal. Processing the data, and after waiting for the receiving interval of the third terminal, it is possible to process the data received from the fourth terminal in the lower order of the third terminal in the second sorting order.

In addition, the processing of the data received from each terminal may be to transmit the data received from each terminal to another device.

In addition, the reception interval of the third terminal may be determined by a difference between an up delay time of the third terminal and an up delay time of the fourth terminal.

Further, the sorting module is further configured to determine each up to the third terminal in the second sorting order when the sum of the respective reception intervals to the terminal in the third sorting order of the third terminal exceeds the reception delay threshold. The reception interval can be determined as '0'.

In addition, the delay measuring module may be a unidirectional measuring module.

In addition, the delay measurement module is a bidirectional measurement module, and may measure the up delay time based on the round trip delay time of each terminal.

On the other hand, to solve the above problems the present specification provides another apparatus for performing communication with a plurality of terminals.

The other device includes a delay measurement module for measuring the up delay time of the plurality of terminals; An alignment module configured to perform a second alignment to align the plurality of terminals in reverse order based on an up delay time, and to determine a reception interval of each terminal according to the second alignment order; And a reception regulator module for processing data received from each terminal according to the second sorting order, wherein the reception regulator module processes data received from a third terminal and waits for a reception interval of the third terminal. Thereafter, the data received from the fourth terminal in the second order of the third terminal in the second sort order may be processed.

In addition, the processing of the data received from each terminal may be to transmit the data received from each terminal to another device.

In addition, the reception interval of the third terminal may be determined by a difference between an up delay time of the third terminal and an up delay time of the fourth terminal.

Further, the sorting module is further configured to determine each up to the third terminal in the second sorting order when the sum of the respective reception intervals to the terminal in the third sorting order of the third terminal exceeds the reception delay threshold. The reception interval can be determined as '0'.

In addition, the delay measuring module may be a unidirectional measuring module.

In addition, the delay measurement module is a bidirectional measurement module, and may measure the up delay time based on the round trip delay time of each terminal.

On the other hand, to solve the above problems the present specification provides a method for performing communication with a plurality of terminals.

The method includes measuring downlink delay times of the plurality of terminals; Determining a transmission interval of each terminal; And transmitting data to each terminal, wherein the transmitting of the data includes transmitting the data to a first terminal, waiting for a transmission interval of the first terminal, and then transmitting the plurality of terminals. The data may be transmitted to a second terminal in a lower order of the first terminal on the terminal list.

In addition, the data may be received from another device.

In addition, the transmission interval of the first terminal may be determined by the difference between the down delay time of the first terminal and the down delay time of the second terminal.

The method may further include performing a first sorting of the plurality of terminals in reverse order based on a down delay time, wherein a transmission interval of each terminal is determined according to the first sorting order. The transmitting terminal list may be in accordance with the first sorting order.

The method may further include measuring an up delay time of the plurality of terminals;

Determining a reception interval of each terminal; And processing data received from each terminal, wherein processing data received from each terminal processes data received from a third terminal and waits for a receiving interval of the third terminal. Subsequently, data received from a fourth terminal that is next to the third terminal on the receiving terminal list including the plurality of terminals may be processed.

In addition, the processing of the data received from each terminal may be to transmit the received data to another device.

In addition, the reception interval of the third terminal may be determined by a difference between an up delay time of the third terminal and an up delay time of the fourth terminal.

The method may further include performing a second sorting of sorting the plurality of terminals in reverse order based on an up delay time, wherein a reception interval of each terminal is determined according to the second sorting order, and the receiving terminal list May be in accordance with the second sort order.

The data providing method according to the exemplary embodiment disclosed herein may reduce the difference in time at which the contents are provided even when the network environments of the respective terminals are different so that users of the terminals may experience the contents at substantially similar times.

The data providing method according to the embodiment disclosed in the present specification enables users of each terminal to compensate for differences in their respective network environments when receiving data services requiring collaboration in a network environment.

The data providing method according to the exemplary embodiment disclosed herein may be implemented without additional modification to the server and the terminal providing the data service or by minimizing the modification.

1 is a block diagram of a media service system according to an embodiment of the present disclosure;
2 is a flowchart of a method for a media service system to transmit data and receive a response according to an embodiment of the present disclosure;
3 is a block diagram of a media service system according to a second embodiment of the present disclosure.

The subject matter described herein applies to network based data providing services. However, the matters described in this specification are not limited thereto, and may be applied to all data service devices and methods to which the technical spirit of the matters described herein may be applied.

It is to be noted that the technical terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting, as set forth herein. In addition, the technical terms used in the present specification should be interpreted as meanings generally understood by those of ordinary skill in the technical field to which the matters described herein belong, unless specifically defined otherwise. It should not be interpreted in an excessively inclusive sense or in an excessively reduced sense.

In addition, when the technical terms used herein are incorrect technical terms that do not accurately express the technical spirit of the matters described in this specification, they should be replaced with technical terms that can be properly understood by those skilled in the art. Also, the general terms used in the present specification should be interpreted in accordance with the predefined or prior context, and should not be construed as being excessively reduced in meaning.

Also, the singular forms "as used herein include plural referents unless the context clearly dictates otherwise. In the present application, the term "comprising" or "comprising" or the like should not be construed as necessarily including the various elements or steps described in the specification, Or may be further comprised of additional components or steps.

When a component is said to be "connected" or "connected" to another component, it may be directly connected or connected to that other component, but there may be other components in between. On the other hand, when a component is said to be "directly connected" or "directly connected" to another component, it should be understood that no other component exists in the middle.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments disclosed herein will be described in detail with reference to the accompanying drawings, and the same or similar components will be given the same reference numerals regardless of the reference numerals, and redundant description thereof will be omitted. In addition, in describing the matters disclosed herein, if it is determined that the detailed description of the related known technology may obscure the gist of the matters disclosed herein, the detailed description thereof will be omitted. In addition, it should be noted that the accompanying drawings are only for easily understanding the technical spirit of the matter disclosed in the present specification, and the technical spirit disclosed in the present specification should not be construed as being limited by the accompanying drawings. The technical spirit disclosed in the present specification should be construed to extend to all changes, equivalents, and substitutes in addition to the accompanying drawings.

Hereinafter, a terminal may be referred to as a user equipment (UE), a device, a mobile equipment (ME), or a mobile station (MS). The terminal may be a portable device having a communication function such as a mobile phone, a PDA, a smart phone, a laptop, a tablet, or the like, or a non-portable device such as a PC or a vehicle-mounted device.

1 is a block diagram of a media service system according to an exemplary embodiment disclosed herein. The media service system is configured to include a server 10 and a plurality of terminals 30, 40, 50 connected to the server 10 through a network 20.

The server 10 stores and provides service data to be transmitted to the plurality of terminals, a service module 12, a delay measurement module 14, an alignment module 15, a transmission regulator 16, and a reception regulator ( 18). The network 20 is a communication system connecting the server 10 and the plurality of terminals 30, 40, and 50, and is not limited to a specific communication scheme. 1 is illustratively illustrated, and the numbers of the terminals 30, 40, and 50 are not limited, and represent one or more terminals connected to the server 10 through the network 20. The terminal 30 includes a client module 32 and a delay measurement module 34. Other terminals 40, 50, etc. constituting the media service system according to the present disclosure also include a client module and a delay measurement module, respectively, like the terminal 30, but are not shown.

The service module 12 included in the server 10 is a module that provides service data transmitted to the terminals 30, 40, and 50. The service module 12 may provide multimedia content such as a video, an image, or other data in real time.

The delay measuring module 14 is a module for measuring a transmission delay time occurring between entities connected to the network 20. The delay measuring module 14 may be a unidirectional module or a bidirectional module.

The one-way module included in the server 10 measures the downlink one-way transmission delay time by transmitting a message for measuring the transmission delay from the server to the terminal. For example, when measuring the downlink one-way transmission delay time of the service data transmitted from the server 10 to the terminal 30, the one-way module 14 included in the server 10 is the terminal 30 It operates in pairs with the unidirectional module 34 included in the.

That is, the server 10 side unidirectional module 14 transmits a message for transmission delay measurement to the terminal 30 side unidirectional module 34 and the measurement from the terminal 30 side unidirectional module 34. The downlink unidirectional transmission delay time may be measured by receiving a result of receiving a message for. At this time, the one-way module 14 on the server 10 side and the one-way module 34 on the terminal 30 side may be synchronized with each other.

The unidirectional module may measure a predetermined time average value of the downlink unidirectional transmission delay time. That is, the unidirectional module can determine the downlink unidirectional transmission delay time by periodically measuring the downlink unidirectional transmission delay time and calculating the average of the measured values in the manner described above.

In addition, the unidirectional module may receive a message for measuring an uplink unidirectional transmission delay time transmitted from the unidirectional modules 34, etc. included in the terminals 30, 40, 50, or the uplink unidirectional measurement message. You can also calculate the average by receiving more than one time. In addition, the unidirectional module may receive and manage each uplink unidirectional transmission delay time from the terminals 30, 40, 50 to the server 10, and the respective uplink unidirectional transmission delay times will be described later. It may be provided for use in the operation of the reception regulator 18.

The bidirectional module included in the server 10 may measure a transmission delay time by transmitting a message for measuring a transmission delay that is transmitted to a terminal and then returns to the server. For example, when measuring the one-way transmission delay time of the service data transmitted from the server 10 to the terminal 30, the bidirectional module 14 included in the server 10 is an Internet protocol (Internet Protocol). Echo request using the ICMP (Internet Control Message Protocol) message to send to the terminal 30 and check the round-trip-time (RTT) according to it can be measured based on this one-way transmission delay time. In this case, the terminal 30 may not have a delay measuring module corresponding to the bidirectional module on the server 10 side.

In addition, the bidirectional module on the server 10 side measures the RTT periodically, calculates an average of the measured RTT values, and calculates a time corresponding to one-half of the average value in the same manner as described above. The transmission delay time can be measured.

As described above, the unidirectional transmission delay time measured by the bidirectional module may be provided as a downlink unidirectional transmission delay time from the server 10, and the uplink unidirectional transmission from each of the terminals 30, 40, and 50. It may be provided with a delay time. However, the unidirectional transmission delay time measured by the bidirectional module on the server 10 side is measured by the unidirectional module included in pairs in the server 10 and the terminals 30, 40, and 50. Although the accuracy may be lower than the delay time, although the terminals 30, 40, and 50 do not each have a delay measurement module, the bidirectional module on the server 10 transmits an approximation of the actual one-way transmission delay time. Delay time can be measured.

The sorting module 15 is a module for sorting the list of the terminals 30, 40, 50 and determining the transmission delay interval and the reception delay interval of each terminal.

Specifically, the sorting module 15 sorts the list of the terminals 30, 40, and 50 connected to the server 10 based on the downlink transmission delay time measured by the delay measuring module 14. The service data received from the service module 12 is managed, and a transmission delay interval is determined based on the downlink transmission delay times of the terminals 30, 40, and 50. Thereafter, the transmission regulator 16 delays and transmits the signals to the terminals 30, 40, and 50 according to the order in which they are arranged at intervals according to transmission delay intervals of the terminals determined by the alignment module 15. Can be. The service data received by the service module 12 is transmitted by the transmission regulator 16 according to the transmission delay interval of each terminal determined by the alignment module 15, so that each of the terminals 30, 40, 50 Even though each network environment is different, the service data can be received and processed at substantially the same time.

For example, in the alignment module 15, a terminal having a long downlink one-way transmission delay time from the server 10 among the terminals 30, 40, and 50 may be substantially similar to other terminals. In order to receive at a time, the list of the terminals (30, 40, 50) is sorted in the reverse order of the downlink unidirectional transmission delay time, and between the terminals (30, 40, 50) according to the sorted order The delay interval can be calculated.

In addition, the sorting module 15 sets a transmission delay threshold value so that the time for transmitting the service data to the terminals 30, 40, 50 does not exceed the transmission delay threshold value for any one terminal. The delay interval can be determined. That is, the sorting module 15 accumulates and calculates the sum of the delay intervals according to the sorted order, and if the cumulative sum of the delay intervals exceeds the transmission delay threshold, the sorting module 15 is earlier in the sorted order. The delay interval of each terminal may be determined as '0'.

Such an operation of the alignment module 15 may be represented by [Table 1].

sort CL desc by Downward-Delay
sum_Dg = 0
for i = 1 to n-1
Dg _i = Dd _i -Dd _{i +1}
sum_Dg = sum_Dg + Dg _i
end

i = 1
while (sum_Dg> D _T ) AND (i <n)
sum_Dg = sum_Dg-Dg _i
Dg _i = 0
i = i + 1
end

Here, CL denotes a list of terminals, Dd _i denotes a downlink unidirectional transmission delay of an i-th terminal, Dg _i denotes a delay interval between an i-th terminal and an i + 1 th terminal, and D _T denotes a transmission delay threshold. Since the sum of the delay intervals must be smaller than the D _T , when the cumulative sum of the delay intervals exceeds the transmission delay threshold value, the delay intervals before the delay period are set to '0'.

In addition, the sorting module 15 sorts and manages the list of the terminals 30, 40, and 50 connected to the server 10 based on the uplink transmission delay time measured by the delay measuring module 14. The reception delay interval is determined based on the uplink transmission delay times of the terminals 30, 40, and 50 based on the responses received from the terminals. After that, the reception regulator module 18 is a module that delays and transmits the delayed intervals to the service module 12 in a sorted order, with time intervals according to the reception delay intervals of the respective terminals determined by the alignment module 15. . Responses are transmitted by the terminals 30, 40, and 50 at substantially the same time, but delayed by the upward one-way delay time of each of the terminals 30, 40, and 50. Is received at different times, the reception regulator 18 performs a function of compensating for each of the uplink one-way delay time of each of the terminals (30, 40, 50) and delivers it to the service module (12). Done.

For example, the sorting module 15 sorts the list of the terminals 30, 40, 50 in the reverse order of the uplink unidirectional transmission delay time, and according to the sorted order, the respective terminals 30, 40, The delay interval between 50 can be calculated.

In addition, the alignment module 15 sets a reception delay threshold and delays a time until the response received from each of the terminals 30, 40, and 50 is transmitted to the service module 12. The delay interval can be determined so as not to exceed the value. That is, the sorting module 15 accumulates and calculates the sum of the delay intervals according to the sorted order, and if the cumulative sum of the delay intervals exceeds the reception delay threshold, the sorting module 15 is earlier in the sorted order. The delay interval of each terminal may be determined as '0'.

Such an operation of the alignment module 15 may be represented by [Table 2].

sort CL desc by delay
sum_Dg = 0
for i = 1 to n-1
Dg _i = Du _{i + 1} -Du _i
sum_Dg = sum_Dg + Dg _i
end

i = 1
while (sum_Dg> D _T ) AND (i <n)
sum_Dg = sum_Dg-Dg _i
Dg _i = 0
i = i + 1
end

Here, CL denotes the list of terminals, Du _i denotes the uplink one-way transmission delay of the i-th terminal, Dg _i denotes the delay interval between the i-th terminal and the i + 1th terminal, and D _T denotes the reception delay threshold. The sum of the delay intervals is the D _T If the sum of the delay intervals cumulatively exceeds the reception delay threshold, the delay intervals before the delay intervals are set to '0'.

As described above, the reception regulator 18 compensates only the delay time due to the network 20 environment between the terminals 30, 40, and 50 and the server 10. , 40 and 50 may be operated so as not to compensate for the difference in the actual response time. On the other hand, even if the actual response time of each of the terminals 30, 40, 50 is different, such as when a real-time collaboration is required in the network 20 environment, the reception regulator 18 is configured to all the terminals 30. It may be operable to transmit to the service module 12 at one time after receiving a response from, 40, 50. The reception regulator 18 may have a different operation method according to the type of data service provided by the service module 12.

2 is a flow diagram of a method for a media service system to transmit service data and receive a response according to an embodiment disclosed herein.

Hereinafter, a media service synchronization method according to the first embodiment disclosed herein will be described with reference to FIG. 2. The media service system according to the first embodiment disclosed in the present specification is configured to include a delay measuring module in the terminal side as well as the server, respectively, and includes unidirectional modules to measure the downlink one-way transmission delay time and the uplink one-way transmission delay time, respectively. Can be configured.

First, the delay measuring module 14 transmits a message for measuring a downlink unidirectional transmission delay time to each of the terminals 30, 40, and 50, and transmits a message for the measurement message from the terminals 30, 40, and 50. The downlink unidirectional transmission delay time is measured by receiving the response (S10). The transmission of the message for the measurement and the reception of the response thereof may be performed between the one-way module 14 and each one-way module included in the terminals 30, 40, and 50. ) And synchronization between the unidirectional modules included in the terminals 30, 40, and 50. The unidirectional transmission delay time measuring process (S10) may be performed after a predetermined time passes or is periodically repeated.

Next, the sorting module 15 sorts the terminals 30, 40, and 50 connected to the server 10 in the reverse order of the downlink transmission delay time measured by the delay measuring module 14. In step S20, the transmission delay intervals of the terminals are calculated in the order. The step of calculating the transmission delay interval (S20) may be performed to use the measured downlink transmission delay time for the service data transmission when the step S10 of measuring the one-way transmission delay time is performed. .

Next, the transmission regulator 16 transmits the service data received from the service module 12 to the terminals (30, 40, 50), but delays by the calculated transmission delay interval in the sorted order To transmit (S30).

Next, the delay measuring module 14 measures an upward one-way transmission delay time (S40). The one-way transmission delay time is the delay measurement module 14 by receiving a message for measuring the upward one-way transmission delay time transmitted from the one-way modules 34, etc. included in the terminals (30, 40, 50) The delay measurement module 14 may also be measured by receiving the measurement message one or more times and calculating an average value. The time point at which the process of measuring the uplink one-way transmission delay time (S40) is performed is not limited to the step of transmitting the service data (S30), but is performed while performing the service data transmission method according to the embodiment disclosed herein. For example, it may be performed at the same time as the step S10 of measuring the downward unidirectional transmission delay time.

Next, the alignment module 15 aligns the terminals 30, 40, and 50 connected to the server 10 in the reverse order of the uplink transmission time measured by the delay measurement module 14, and the alignment. In step S50, the reception delay intervals of the respective terminals are calculated in the order. In the calculating of the reception delay interval (S50), when the process of measuring the uplink one-way transmission delay time (S40) is performed, the uplink delay time measured as a result of the execution of the terminals (30, 40, 50). It may be performed for use in the reception of a response sent from.

Next, the reception regulator 18 receives data from the terminals 30, 40, and 50, and calculates the transmission delay interval by the transmission delay interval calculated in step S50 of calculating the reception delay interval according to the sorted order. The data is processed by the delay (S60). Receiving data from the terminals by the reception regulator 18 may be performed at any of the above-described steps (S10 to S50), and the step (S50) of necessarily calculating the reception delay intervals of the respective terminals may be performed. It is not limited to the following. Processing the received data by the reception regulator 18 may indicate, for example, transmitting to the service module 12.

The execution of the downward unidirectional delay measurement process (S10) to the service data transmission process (S30) and the execution of the upward unidirectional delay measurement process (S40) to the data reception process (S60) in the above process in view of the nature of the processes It can be run independently.

Hereinafter, a modified application example of the media service synchronization method according to the first embodiment disclosed herein will be described. The media service system according to the modified application of the first embodiment disclosed herein may be configured to include the delay measurement module 14 only on the server 10 side, and the delay measurement module 14 may be configured as a bidirectional module. .

Differences between the first embodiment disclosed in the present specification and variations thereof include a downlink unidirectional transmission delay time and an uplink unidirectional transmission delay time in the process of measuring the downlink unidirectional delay (S10) and the process of measuring the uplink unidirectional delay (S40), respectively. In order to measure the bidirectional module of the server 10.

That is, the bidirectional module included in the server 10 transmits a message for measuring a transmission delay, which is transmitted to the terminals 30, 40, and 50 and then returns to the server, to each terminal, and By receiving the response, the round trip delay time may be measured, and one half of the measured round trip delay time may be determined as the downlink unidirectional transmission delay time and the uplink unidirectional transmission delay time.

In addition, the bidirectional module periodically measures the round trip transmission delay time, calculates an average of the measured round trip transmission delay values, and calculates a time corresponding to one half of the average value in the above-described manner. One-way transmission delay time can be measured.

The first embodiment disclosed herein is the same as the modifications and processes other than the above-described difference, so that duplicate description is omitted.

Hereinafter, a synchronization method of a media service system according to a second embodiment disclosed herein will be described with reference to FIG. 3.

3 is a block diagram of a media service system according to a second embodiment of the present disclosure. The media service system includes a service device 12-1 providing service data, a synchronization server 10-1 and a synchronization server 10-1 connected to the service device 12-1 to provide a synchronization service. It is configured to include a plurality of terminals (30, 40, 50) connected via the network 20 to.

Compared to the first embodiment described above, the media service system according to the second embodiment of the present disclosure has a separate service module (10 of FIG. 1), which stores and manages service data. 12) is configured as a separate independent device as the service device 12-1, and includes a delay measuring module 14, an alignment module 15, a transmission regulator 16 and a reception regulator 18. The synchronization server 10-1 is configured in the form of an independent device, the function of each of which is the same as in the case of the first embodiment disclosed herein.

The media service system according to the second embodiment disclosed in the present specification provides a synchronization service by simply connecting the service device 12-1 without applying any modification to the service device 12-1 for providing a conventional data service. can do.

Hereinafter, a modified application example of the media service synchronization system according to the second embodiment disclosed herein will be described. In a media service system according to a modified application of the second embodiment disclosed herein, a function of the synchronization server 10-1 is separated, and includes a delay measuring module, an alignment module for determining a transmission delay interval, and a transmission regulator. A regulator device and a delay measurement module, an alignment module for determining a reception delay interval, and a reception regulator device including a reception regulator, each of which has the same function as the case of the second embodiment disclosed herein.

Hereinafter, another modified application example of the media service synchronization system according to the second embodiment disclosed herein will be described. The media service system according to another modified application of the second embodiment disclosed herein aligns the terminals based on the downlink transmission delay time or the uplink transmission delay time as compared to the media service synchronization system according to the second embodiment described above. You may not perform the process. In this case, the transmission delay interval or the reception delay interval of each terminal may be determined according to the order on the terminal list, and data may be transmitted and received.

In the foregoing description, the embodiments disclosed in the specification have been exemplarily described, but the scope of the matters disclosed in the present specification is not limited only to the specific embodiments, and thus, the matters disclosed in the present specification are the technical idea and the claims disclosed herein. It may be modified, changed or improved in various forms within the scope described in the scope.

Claims (26)

An apparatus for communicating with a plurality of terminals,
A delay measuring module measuring down delay times of the plurality of terminals;
An alignment module configured to perform a first alignment in which the plurality of terminals are arranged in a reverse order based on a down delay time, and determine a transmission interval of each terminal according to the first alignment order; And
Including a transmission regulator module for transmitting data to each terminal in the first sorting order,
The transmission regulator module transmits the data to a first terminal, waits for a transmission interval of the first terminal, and then transmits the data to a second terminal that is next to the first terminal in the first sorting order. And allowing the first terminal and the second terminal to receive and process the data at a similar time. The method of claim 1, wherein the data is
Communication device received from another device. The method of claim 1, wherein the transmission interval of the first terminal is
And determine the difference between the down delay time of the first terminal and the down delay time of the second terminal. The method of claim 1, wherein the alignment module
If the sum of each transmission interval to the terminal in the first order in the first sorting order exceeds the transmission delay threshold, each transmission interval to the first terminal in the first sorting order is '0'. Communication device characterized in that for determining. The method of claim 1, wherein the delay measuring module
Communication device, characterized in that the one-way measurement module. The method of claim 1,
The delay measuring module is a bidirectional measuring module,
The downlink delay time is measured based on the round trip delay time of each terminal. The method of claim 1,
The delay measuring module measures the up delay time of the plurality of terminals,
The sorting module performs a second sorting of sorting the plurality of terminals in reverse order based on an up delay time, and determines a reception interval of each terminal according to the second sorting order.
Further comprising a receiving regulator module for processing data received from each terminal according to the second sorting order,
The receiving regulator module processes the data received from the third terminal, waits for the receiving interval of the third terminal, and then processes the data received from the fourth terminal that is next to the third terminal in the second sorting order. Communication device, characterized in that. The method of claim 7, wherein the processing of the data received from each terminal is
And transmitting data received from each terminal to another device. The method of claim 7, wherein the receiving interval of the third terminal is
And a difference between an up delay time of the third terminal and an up delay time of the fourth terminal. The method of claim 7, wherein the alignment module
If the sum of the respective reception intervals to the terminal of the third terminal in the second sorting order exceeds the reception delay threshold value, each reception interval to the third terminal in the second sorting order is '0'. Communication device characterized in that for determining. The method of claim 7, wherein the delay measuring module
Communication device, characterized in that the one-way measurement module. The method of claim 7, wherein
The delay measuring module is a bidirectional measuring module,
The uplink delay time is measured based on a round trip delay time of each terminal. An apparatus for communicating with a plurality of terminals,
A delay measuring module measuring upward delay time of the plurality of terminals;
An alignment module configured to perform a second alignment to align the plurality of terminals in reverse order based on an up delay time, and to determine a reception interval of each terminal according to the second alignment order; And
A receiving regulator module for processing data received from each terminal according to the second sorting order;
The receiving regulator module processes the data received from the third terminal, waits for the receiving interval of the third terminal, and then processes the data received from the fourth terminal that is next to the third terminal in the second sorting order. To compensate for the delay time for the data received from the third terminal or the fourth terminal, or to transmit the received data to the server at a time. The method of claim 13, wherein the processing of data received from each terminal is performed.
And transmitting data received from each terminal to another device. The method of claim 13, wherein the receiving interval of the third terminal is
And a difference between an up delay time of the third terminal and an up delay time of the fourth terminal. The method of claim 13, wherein the alignment module
If the sum of the respective reception intervals to the terminal of the third terminal in the second sorting order exceeds the reception delay threshold value, each reception interval to the third terminal in the second sorting order is '0'. Communication device characterized in that for determining. The method of claim 13, wherein the delay measuring module
Communication device, characterized in that the one-way measurement module. The method of claim 13,
The delay measuring module is a bidirectional measuring module,
The uplink delay time is measured based on a round trip delay time of each terminal. As a method of communicating with a plurality of terminals,
Measuring down delay times of the plurality of terminals by a delay measuring module;
Determining a transmission interval of each terminal by an alignment module; And
Transmitting data to each terminal by a transmission regulator module;
The transmitting of the data may include transmitting the data to a first terminal, waiting for a transmission interval of the first terminal, and then placing a second terminal that is next to the first terminal on the transmission terminal list including the plurality of terminals. And transmitting the data to the first terminal and the second terminal to receive and process the data at a similar time. 20. The method of claim 19, wherein said data is received from another device. 20. The method of claim 19, wherein the transmission interval of the first terminal is
The communication method is determined by the difference between the down delay time of the first terminal and the down delay time of the second terminal. 20. The method of claim 19,
Performing a first sorting by the sorting module to sort the plurality of terminals in a reverse order based on a downward delay time;
The transmission interval of each terminal is determined according to the first sorting order,
And the transmitting terminal list follows the first sorting order. 20. The method of claim 19,
Measuring upward delay times of the plurality of terminals by the delay measurement module;
Determining a reception interval of each terminal by the alignment module; And
Further comprising the step of processing data received from each terminal by a reception regulator module,
The processing of data received from each terminal may include processing the data received from a third terminal, waiting for a receiving interval of the third terminal, and then waiting for the receiving interval of the third terminal on the list of receiving terminals including the plurality of terminals. And processing the data received from the fourth terminal in the subordinated order. 24. The method of claim 23,
The processing method of the data received from each terminal is characterized in that for transmitting the received data to another device. The method of claim 23, wherein the receiving interval of the third terminal is
The communication method is determined by the difference between the up delay time of the third terminal and the up delay time of the fourth terminal. 24. The method of claim 23,
Performing a second sorting by the sorting module to sort the plurality of terminals in reverse order based on an up delay time;
The reception interval of each terminal is determined according to the second sorting order,
And the receiving terminal list follows the second sorting order.

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