Communication method, communication apparatus, and communication system

Information

  • Patent Grant
  • 12028382
  • Patent Number
    12,028,382
  • Date Filed
    Tuesday, May 2, 2023
    a year ago
  • Date Issued
    Tuesday, July 2, 2024
    4 months ago
Abstract
A network that is to execute transcoding is fixed. IMS networks set an information element that requests either of the IMS networks to execute transcoding into the SDP, and use that information element to select the IMS network that is to execute transcoding between the IMS networks. Then, the selected IMS network executes transcoding of media data.
Description
TECHNICAL FIELD

The present invention relates to a call control technique using the SIP/SDP. Particularly, the present invention relates to SIP application software mounted in a Session Border Controller (SBC) that controls a boundary with a different network or terminal.


BACKGROUND ART

In audio and video communication using the Session Initiation Protocol (SIP), the Session Description Protocol (SDP) in which media information on this communication is described is exchanged between an outgoing terminal and an incoming terminal or between SIP servers in a network, media conditions of the audio and video (media type, codec, packetization period, and the like) are then settled by negotiation, and thereafter actual transmission and reception of audio packets with the Real-time Transport Protocol (RTP) are performed.


Particularly, negotiation on the media information (SDP negotiation) is performed such that the outgoing-side terminal describes the media (such as audio and video) desired to be used for communication and various parameters of the media (codec, packetization period, and the like) into SDP offer, and then the incoming-side terminal chooses media conditions to be used for the communication from the media conditions described in the SDP offer, describes the chosen media conditions into SDP answer, and sends back the SDP answer to the outgoing-side terminal. In this way, the conditions of the communication media to be used between the outgoing and incoming terminals are settled.


Meanwhile, in 3GPP, the IP Multimedia Subsystem (IMS) is defined as a system in which telecommunications carriers provide multimedia services including a telephone service. The IMS is a multimedia service system supporting any of access types (3G, LTE, WiFi, optical access, and so on) used by outgoing and incoming terminals such as mobile and fixed terminals. However, an IMS network including only the mobile terminal and an IMS network including only the fixed terminal may have a case where no common codec is supported by terminals in these different IMS networks.


For example, in general, the fixed terminal supports at least a G.711μ-law audio codec while the mobile terminal supports at least an AMR-NB audio codec. Thus, an IMS network of a telecommunications carrier requires a function of codec conversion to achieve intercommunication between the fixed terminal and the mobile terminal.


Note that, there is a function, generally called a transcoding function, in which an intermediate node in an IMS network executes not only the codec conversion but also rewrite processing of the SDP (such as adding or deleting of a codec) and conversion processing of media (RTP and the like) according to conditions before the SDP rewriting and after the SDP rewriting. Transcoding is usually executed using information on the codecs supported by the outgoing and incoming terminals, based on an operator policy defined by the carriers with an agreement between the carriers, the Service Level Agreement (SLA), and so on.



FIG. 7 is a diagram that illustrates a processing procedure of transcoding executed by an SBC. The Session Border Controller (SBC) is an intermediate node provided around a boundary of the IMS network and, for example, composed of an Interconnection Border Control Function (IBCF; SIP server) and a Translation Gateway (TrGW; media server). Thus, in an actual operation, the SIP server in the SBC uses H.248 to give an instruction to perform the rewrite processing on an SDP and the media conversion based on that SDP, and the media server in the SBC converts packets of the media based on that instruction.


Specifically, when receiving SDP offer, the SBC (IBCF) adds a codec that can be transcoded by the own IMS network or a terminal in the own IMS network (in this example, codec b) to a codec list set in the SDP offer. Then, when a codec in SDP answer received thereafter includes a codec in the previously received SDP offer (in this example, codec a), the SBC transmits the SDP answer as it is without executing the transcoding function (FIG. 7A).


On the other hand, when the codec in the received SDP answer does not include a codec in the previously received SDP offer (codec a), the SBC (IBCF) chooses one codec from the codecs included in the previously received SDP offer (in this example, there is only codec a) and transmits SDP answer in which that codec information is described (FIG. 7B). Thereafter, the SBC (TrGW) executes transcoding between the codec of the received SDP answer and the codec of the transmitted SDP answer (codec b↔a).


For example, when a single IMS network includes the mobile terminal and the fixed terminal, communication between the mobile terminal and the fixed terminal within the own IMS network is enabled by providing the transcoding function to a node such as an intermediate node (such as SIP server and media server) or the node nearest to the terminal (such as Proxy Call State Control Function (P-CSCF) and Media Gateway (MGW)).


In another case, when interconnecting the IMS network including only the mobile terminal and the IMS network including only the fixed terminal, communication between the mobile terminal and the fixed terminal in the different IMS networks is enabled by the IMS network of SDP offer transmitting side or the IMS network of SDP answer transmitting side executing transcoding. Processing procedures of the transcoding executed in the IMS network of SDP offer transmitting side and the IMS network of SDP answer transmitting side are respectively illustrated in FIGS. 8 and 9.


In addition, FIGS. 10 and 11 respectively illustrate, as a specific example thereof, processing procedures in a case where, when interconnecting an IMS network including the fixed terminal supporting only the G.711μ-law audio codec and an IMS network including the mobile terminal supporting only the AMR audio codec, the IMS network of SDP offer transmitting side executes transcoding between G.711μ-law and AMR and the IMS network of SDP answer transmitting side executes the same transcoding. Note that the codecs to be transcoded, SBC function provision, the SIP message in which the SDP is set, and so on are not limited to the present example.


As illustrated in FIGS. 10 and 11, in communication using the SIP as a call control signal, unless the call control is a service by the 3rd Party Call Control (3PCC) or the like, an Initial-INVITE request containing SDP offer is transmitted from the outgoing terminal, then SDP answer is set in a response (such as 18x response (x is a number) or 200 response) generated by the incoming terminal, and the communication is started upon completion of the initial SDP offer/answer. When the SDP offer transmitting side is responsible for transcoding, the IMS network of outgoing side as the SDP offer transmitting side executes the transcoding after the initial SDP offer/answer.


PRIOR ART DOCUMENT
Non-Patent Document



  • Non-patent document 1: “SIP: Session Initiation Protocol”, RFC3261, [online], [searched on June 29, H28], <URL: https://www.ietf.org/rfc/rfc3261.txt>

  • Non-patent document 2: “SDP: Session Description Protocol”, RFC2327, [online], [searched on June 29, H28], <URL: https://www.ietf.org/rfc/rfc2327.txt>

  • Non-patent document 3: “RTP: A Transport Protocol for Real-Time Applications”, RFC3550, [online], [searched on June 29, H28], <URL: https://www.ietf.org/rfc/rfc3550.txt>

  • Non-patent document 4: “An Offer/Answer Model with the Session Description Protocol (SDP)”, RFC3264, [online], [searched on June 29, H28], <URL: https://www.ietf.org/rfc/rfc3264.txt>

  • Non-patent document 5: “IP Multimedia Subsystem (IMS)”, 3GPP TS 23.228, [online], [searched on June 29, H28], <URL: http://www.3gpp.org/DynaReport/23228.htm>

  • Non-patent document 6: “IP multimedia call control protocol based on Session Initiation Protocol (SIP) and Session Description Protocol (SDP)”, 3GPP TS 24.229, [online], [searched on June 29, H28], <URL: http://www.3gpp.org/dynareport/24229.htm>



SUMMARY OF THE INVENTION
Problem to be Solved by the Invention

However, in an actual service, multiple times of SDP offer/answer are performed for communication involving media changing such as switching from a guidance or a video call to an audio call. Thus, there is a problem that a transcoding execution point cannot be fixed in an outgoing side network or an incoming side network like a case where, when the SDP offer is transmitted from the IMS network of incoming side, transcoding is executed in the IMS network of incoming side after the second SDP offer/answer even though transcoding is executed in the IMS network of outgoing side after the initial SDP offer/answer, as illustrated in FIG. 12. In another case, as illustrated in FIG. 13, there is a similar problem that transcoding is executed in the IMS network of outgoing side after the second SDP offer/answer even though transcoding is executed in the IMS network of incoming side after the initial SDP offer/answer.


As a specific example, FIG. 14 illustrates an example case where, when interconnecting the IMS network including the fixed terminal and the IMS network including the mobile terminal, the IMS network of the mobile terminal provides a guidance to the outgoing terminal in the IMS network of the fixed terminal before the call is established and the SDP offer transmitting side executes transcoding. In the initial SDP offer/answer, since the SDP offer is transmitted from the outgoing terminal, transcoding for the guidance media before the call establishment is executed in the IMS network of outgoing side. However, in the second SDP offer/answer, since the SDP offer is transmitted from the IMS network of incoming side, transcoding related to talking media between the outgoing and incoming terminals is executed in the IMS network of incoming side. In an opposite way, as illustrated in FIG. 15, even though the transcoding for the guidance media before call establishment is executed in the IMS network of incoming side, the transcoding for the talking media between the outgoing and incoming terminals is executed in the IMS network of outgoing side.


Here, transcoding consumes much more resources than resources required by the processing of transparently forwarding the media packets. For this reason, when functions of a call control system are desired to be designed based on the number of outgoing and incoming calls, it is desirable to fix transcoding during one call to the outgoing side or the incoming side. In addition, since it is expected that the number of required functions varies depending on transcoding, carriers each also have a demand that, in interconnection between the carriers and another carrier, transcoding of outgoing calls from the own network be executed in the own network so as to reduce access charge from the destination network.


However, with the current processing procedure of transcoding, although transcoding can be executed on either of the SDP offer transmitting side and the SDP answer transmitting side, it is impossible to fix the transcoding execution point to the outgoing side or the incoming side through 1 call.


The present invention was made in light of the above-described circumstances and has an object to fix a transcoding execution network (outgoing side or incoming side).


Means for Solving the Problem

In order to solve the above problems, a gist of a communication method according to one aspect of the invention is that, in a communication method executed between multiple communication devices, the method comprising causing a certain communication device out of the communication devices to perform: a first step of setting parameter information that requests any of the communication devices to execute transcoding into Session Description Protocol (SDP); and a second step of executing transcoding of media data by the certain communication device itself, when the parameter information set in the SDP requests the certain communication device itself.


A gist of a communication method according to one aspect of the invention is that, in the communication method, if the certain communication device requested by the parameter information is determined not to execute transcoding, the first step involves changing the parameter information to indicate an opposite one of the communication devices.


A gist of a communication method according to one aspect of the invention is that, in a communication method executed between multiple communication devices, the method comprising, when a certain communication device out of the communication devices is to execute transcoding of media data, causing the certain communication device to perform a first step of storing a codec type currently in use that is determined by Session Description Protocol (SDP) negotiation into a codec information storing unit, a second step of receiving a Session Initiation Protocol (SIP) message containing SDP offer, and a third step of transmitting the SIP message containing the SDP offer that includes a codec type currently in use in a forwarding destination.


A gist of a communication method according to one aspect of the invention is that, in the communication method, if the SDP offer in the received SIP message includes a codec type currently in use in a forwarding source, the third step involves including the codec type currently in use in the forwarding destination into the SDP offer in the SIP message to be transmitted.


A gist of a communication method according to one aspect of the invention is that, in the communication method, if the SDP offer in the received SIP message does not include a codec type currently in use in a forwarding source and if the certain communication device is capable of transcoding between the codec type included in the SDP offer and the codec type currently in use in the forwarding destination, the third step involves including the codec type currently in use in the forwarding destination into the SDP offer in the SIP message to be transmitted.


A gist of a communication method according to one aspect of the invention is that, in a communication method executed between multiple communication devices, the method comprising causing a certain communication device of the communication devices to: store a codec type currently in use that is determined by Session Description Protocol (SDP) negotiation into a codec information storing unit and if the certain communication device is determined not to execute transcoding of media data and receives a Session Initiation Protocol (SIP) message containing SDP offer that includes a codec type currently in use in a forwarding source, forward the SIP message without adding the codec type to the SDP offer.


A gist of a communication device according to one aspect of the invention is that a communication device includes: a transcoding unit that executes transcoding of media data; a codec information storing unit that stores a codec type currently in use that is determined by Session Description Protocol (SDP) negotiation; and an SDP processing unit that, if a Session Initiation Protocol (SIP) message containing SDP offer is received, includes a codec type currently in use in a forwarding destination into the SDP offer when forwarding the SIP message.


A gist of a communication device according to one aspect of the invention is that a communication device includes: a codec information storing unit that stores a codec type currently in use that is determined by Session Description Protocol (SDP) negotiation; and an SDP processing unit that, if the communication device is determined not to execute transcoding of media data and receives a Session Initiation Protocol (SIP) message containing an SDP offer that includes a codec type currently in use in a forwarding source, forwards the SIP message without adding the codec type to the SDP offer.


A gist of a communication system according to one aspect of the invention is that a communication system includes: a first communication device; and a second communication device, in which the first communication device includes a codec information storing unit that stores a codec type currently in use that is determined by Session Description Protocol (SDP) negotiation and an SDP processing unit that, if the first communication device is determined not to execute transcoding of media data and receives a Session Initiation Protocol (SIP) message containing an SDP offer that includes a codec type currently in use in a forwarding source, forwards the SIP message to the second communication device without adding the codec type into the SDP offer, and the second communication device includes a transcoding unit that executes transcoding of media data, a codec information storing unit that stores a codec type currently in use that is determined by the SDP negotiation, and an SDP processing unit that, if the SIP message is received, includes a codec type currently in use in a forwarding destination into the SDP offer when forwarding the SIP message.


A gist of a communication program according to one aspect of the invention is to cause a computer to execute the communication method described above.


Effect of the Invention

According to the present invention, it is possible to fix a network (outgoing side, incoming side) determined to execute transcoding.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1 is a diagram that illustrates an overall configuration of a call control system and a functional block configuration of an SBC.



FIG. 2 is a diagram that illustrates a processing flow of a negotiation operation when transcoding is determined to be executed on an initial SDP offer transmitting side.



FIG. 3 is a diagram that illustrates a processing flow of a negotiation operation when transcoding is determined to be executed on an initial SDP answer transmitting side.



FIG. 4 is a diagram that illustrates a processing flow of a renegotiation operation when transcoding is impossible in an IMS network that is requested to execute the transcoding.



FIG. 5 is a diagram that illustrates a processing flow when transcoding is determined to be executed on the initial SDP offer transmitting side.



FIG. 6 is a diagram that illustrates a processing flow when transcoding is determined to be executed on the initial SDP answer transmitting side.



FIGS. 7A and 7B are collectively referred to as FIG. 7. FIG. 7 is a diagram that illustrates a processing procedure of transcoding.



FIG. 8 is a diagram that illustrates a processing procedure of transcoding executed on an SDP offer transmitting side.



FIG. 9 is a diagram that illustrates a processing procedure of transcoding executed on an SDP answer transmitting side.



FIG. 10 is a diagram that illustrates a processing procedure of the transcoding executed on the SDP offer transmitting side (specific example for a case of interconnecting a fixed terminal and a mobile terminal).



FIG. 11 is a diagram that illustrates a processing procedure of the transcoding executed on the SDP answer transmitting side (specific example for the case of interconnecting the fixed terminal and the mobile terminal).



FIG. 12 is a diagram that illustrates a processing procedure of a case where transcoding is determined to be sequentially executed in the SDP offer transmitting side and the SDP answer transmitting side.



FIG. 13 is a diagram that illustrates a processing procedure of a case where transcoding is determined to be sequentially executed in the SDP answer transmitting side and the SDP offer transmitting side.



FIG. 14 is a diagram that illustrates a processing procedure of a case where the transcoding is determined to be sequentially executed in the SDP offer transmitting side and the SDP answer transmitting side (specific example for the case of interconnecting the fixed terminal and the mobile terminal).



FIG. 15 is a diagram that illustrates a processing procedure of a case where the transcoding is determined to be sequentially executed in the SDP answer transmitting side and the SDP offer transmitting side (specific example for the case of interconnecting the fixed terminal and the mobile terminal).





MODE FOR CARRYING OUT THE INVENTION

Hereinafter, two embodiments are described for a method of fixing a network (IMS network, SBC) determined to execute transcoding on an initial SDP offer transmitting side or an initial SDP answer transmitting side.


First Embodiment

In First Embodiment, an IMS network that is to execute transcoding is selected by negotiation between an IMS network of SDP offer transmitting side and an IMS network of SDP answer transmitting side in first SDP negotiation (first SDP offer/answer).



FIG. 1 is a diagram that illustrates an overall configuration of a call control system and a functional block configuration of an SBC according to this embodiment. This call control system includes an SBC 1a and an SBC 1b interconnecting with each other. In this embodiment, the SBC 1a is provided in an IMS network of initial SDP offer transmitting side (e.g., IMS network including a fixed terminal that supports only a G.711μ-law audio codec). Meanwhile, the SBC 1b is provided in an IMS network of initial SDP answer transmitting side (e.g., IMS network including a mobile terminal that supports only an AMR audio codec). Note that SBC is an abbreviation of a session border controller, which is usually an intermediate node provided around a boundary of the IMS network. Hereinafter, functions of the SBC 1a and the SBC 1b are described.


Each of the SBC 1a and the SBC 1b includes an SDP processing unit 11, a transcoding unit 12, and a codec information storing unit 13.


The SDP processing unit 11 has not only a conventional function that is for example SDP rewrite processing (such as processing of adding and deleting a codec to and from the SDP) but also a function of selecting an IMS network that is to execute transcoding by negotiation. Specifically, the SDP processing unit 11 sets an information element (parameter information) that requests any of the IMS network to execute transcoding into the SDP and, at a timing when the SDP negotiation is performed, uses that information element to select an IMS network that executes transcoding with another IMS network (SBC).


For example, when the SBC 1a determines (requests) to execute transcoding in the own IMS network (SBC 1a) when transmitting the SDP offer to the other IMS network (SBC 1b), the SBC 1a sets an information element indicating that the transcoding is charged with the SDP offer transmitting side. For example, that information element is set as a transcoding execution point designation parameter “transcoder”, and “own-side” is set as a value of that information element. On the other hand, when the SBC 1a wants (requests) the other IMS network (SBC 1b) to be in charge of transcoding, the SBC 1a sets “opposite-side” as the value of the above-described information element. That information element and the value of that information element can be used in an arbitrary form such as a header field of the SIP and a value of that header field, “attribute” of the SDP, and the like.


If the other IMS network (SBC 1b) cannot execute transcoding even when the SBC 1a wants (requests) that other IMS network to be in charge of transcoding, that other IMS network may request the SBC 1a to be in charge of transcoding.


Thus, the SDP processing unit 11 further has a function of changing the above-described information element so as to indicate an IMS network other than the IMS network requested by that information element if the IMS network requested by that information element cannot execute transcoding.


The transcoding unit 12 has not only a conventional function of transcoding a media packet (media data) but also a function of executing or not executing transcoding depending on a result of the negotiation on a transcoding executor by the SDP processing unit 11. Specifically, when the IMS network determined to execute transcoding is the own IMS network, the transcoding unit 12 executes the transcoding, and when the IMS network determined to execute transcoding is the other IMS network, the transcoding unit 12 executes no transcoding.


The codec information storing unit 13 has not only a conventional function of storing codec information that can be transcoded by the own IMS network (own SBC) or a terminal in the own IMS network (e.g., when the G.711μ-law audio codec is supported by the own IMS network, G.711μ-law) and the operator policy defined with the agreement between the carriers or the SLA and so on, but also has a function of storing the above-described information element to be set or already set in the SDP while allowing that information element to be read or referred by the SDP processing unit 11 or the transcoding unit 12.


Note that, in the present invention, transcoding mainly indicates a function and processing of converting a codec (coding system) of audio and video communication media. For example, this is conversion of the G.711μ-law audio codec to the AMR audio codec and its inverse conversion. Note that G.711μ-law and AMR are an example of codecs, and the present invention is not limited to a specific type of codec.


So far, the functions of the SBC 1a and the SBC 1b are schematically described. However, detailed descriptions of the functions of the SBC 1a and the SBC 1b are needed for actually selecting the IMS network that is to execute transcoding by negotiation. Thus, specific operations performed by the SBC 1a (initial SDP offer transmitting side) and the SBC 1b (initial SDP answer transmitting side) are respectively exemplified in Table 1 and Table 2. The SDP processing unit 11 of the SBC 1a executes operation and processing according to the described details in Table 1 while the SDP processing unit 11 of the SBC 1b executes operation and processing according to the described details in Table 2.









TABLE 1







Table 1: Operation of Initial SDP Offer Transmitting Side










Receive from the
Receive from the



own network (own
other network (own



network −> SBC −>
network <− SBC <−


Receiving condition
other network)
other network)













SDP
Initial
If it is set to



offer

execute




transcoding when




the own SBC is the




initial SDP offer




side, add one or




more transcodable




codecs into a codec




list, set




“own-side”, and




transmit the SDP




offer to the other




network.




If it is not set to




execute




transcoding when




the own SBC is the




initial SDP offer




side, add no codec,




set “opposite-side”,




and transmit the




SDP offer to the




other network.



Subsequent
If it is set to
If “own-side” is




execute
set in the received




transcoding when
SDP offer, delete




the own SBC is the
“own-side” and




initial SDP offer
transmit




side or if
(transparently)




“opposite-side” is
the SDP offer to the




set in the SDP
own network.




previously
If “opposite-side”




received from the
is set and it is




other network and a
set to execute




transcodable codec
transcoding when




is included, add
the own SBC is the




one or more
initial SDP offer




transcodable
side, add one or




codecs into the
more transcodable




codec list, set
codecs into the




“own-side”, and
codec list and




transmit the SDP
transmit the SDP




offer to the other
offer to the own




network.
network. If




If it is not set to
transcoding is




execute
already being




transcoding when
executed by the own




the own SBC is the
SBC when the SDP




initial SDP offer
offer is received,




side, add no codec,
at least include




set “opposite-side”,
the codec currently




and transmit the
in use on the own




SDP offer to the
network side as the




other network.
codec to be added.









SDP answer
If “own-side” was
If the SDP answer


(initial/subsequent)
set in the
includes the codec



previously
included in the



received SDP offer,
previously



set “opposite-side”
received SDP offer,



into the SDP
transmit



answer, and if
(transparently)



“opposite-side”
the SDP answer to



was set in the
the own network (no



previously
transcoding



received SDP offer,
occurs).



set “own-side” into
If the SDP answer



the SDP answer.
does not include



If the SDP answer
the codec included



includes the codec
in the previously



included in the
received SDP offer



previously
but the previously



received SDP offer,
transmitted codec



transmit
added by the own



(transparently)
SBC, choose one



the SDP answer to
from the codecs



the other network
included in the



(no transcoding
previously



occurs).
received SDP offer,



If the SDP answer
set its codec



does not include
information to the



the codec included
SDP answer, and



in the previously
transmit the SDP



received SDP offer
answer to the own



but the previously
network



transmitted codec
(transcoding



added by the own
occurs).



SBC, choose one



from the codecs



included in the



previously



received SDP offer,



set its codec



information to the



SDP answer, and



transmit the SDP



answer to the other



network



(transcoding



occurs).


SDP set to 488 response
If “opposite-side”
Transmit the



was set in the
received SDP to the



previously
own network.



received SDP offer,



set “opposite-side”



into the SDP and



transmit the SDP to



the other network.





Note:


Since “own-side” and “opposite-side” are parameters of hop by hop, they will be deleted after being saved by the SBC. This operation is a common operation and thus not being described in the table.













TABLE 2







Table 2: Operation of Initial SDP Answer Transmitting Side










Receive from the
Receive from the



own network (other
other network (other



network <− SBC <−
network −> SBC −>


Receiving condition
own network)
own network)













SDP
Initial

If “own-side” is


offer


set in the received





SDP offer, transmit





(transparently)





the SDP offer to the





own network.





If “opposite-side” is





set and it is set to





execute





transcoding when





the own SBC is the





initial SDP answer





side, add one or





more transcodable





codecs into the





codec list and





transmit the SDP





offer to the own





network.





If “opposite-side” is





set and it is set to





not execute





transcoding when





the own SBC is the





initial SDP answer





side, transmit





(transparently)





the initial SDP





offer to the own





network.



Subsequent
If it is set to
If “own-side” is




execute
set in the received




transcoding when
SDP offer, transmit




the own SBC is the
the SDP offer to the




initial SDP answer
own network, and if




side, or if
“opposite-side” is




“opposite-side”
set and it is set to




was set in the SDP
execute




previously
transcoding when




received from the
the own SBC is the




other network and a
initial SDP answer




transcodable codec
side, add one or




is included, add
more transcodable




one or more
codecs into the




transcodable
codec list and




codecs into the
transmit the SDP




codec list, set
offer to the own




“own-side”, and
network. If




transmit the SDP
transcoding is




offer to the other
already being




network.
executed by the own




If it is not set to
SBC, at least




execute
include the codec




transcoding when
currently in use on




the own SBC is the
the own network




initial SDP answer
side as the codec to




side, add no codec,
be added.




set “opposite-side”,




and transmit the




SDP offer to the




other network.









SDP answer
If “own-side” was
If the SDP answer


(initial/subsequent)
set in the
includes the codec



previously
included in the



received SDP offer,
previously



set “opposite-side”
received SDP offer,



into the SDP
transmit



answer, and if
(transparently)



“opposite-side”
the SDP answer to



was set in the
the own network (no



previously
transcoding



received SDP offer,
occurs).



set “own-side” into
If the SDP answer



the SDP answer.
does not include



If the SDP answer
the codec included



includes the codec
in the previously



included in the
received SDP offer



previously
but the previously



received SDP offer,
transmitted codec



transmit the SDP
added by the own



answer to the other
SBC, choose one



network (no
from the codecs



transcoding
included in the



occurs).
previously



If the SDP answer
received SDP offer,



does not include
set its codec



the codec included
information to the



in the previously
SDP answer, and



received SDP offer
transmit the SDP



but the previously
answer to the own



transmitted codec
network



added by the own
(transcoding



SBC, choose one
occurs).



from the codecs



included in the



previously



received SDP offer,



set its codec



information to the



SDP answer, and



transmit the SDP



answer to the other



network



(transcoding



occurs).


SDP set to 488 response
If “opposite-side”
Transmit the



was set in the
received SDP to the



previously
own network.



received SDP offer,



set “opposite-side”



into the SDP and



transmit the SDP to



the other network.





Note:


Since “own-side” and “opposite-side” are parameters of hop by hop, they will be deleted after being saved by the SBC. This operation is a common operation and thus not being described in the table.






Next, a negotiation operation for selecting an executor (IMS network, SBC) of transcoding is described.


Firstly, a negotiation operation in a case where transcoding is to be executed in the IMS network of initial SDP offer transmitting side (SBC 1a) is described with reference to FIG. 2.


First, after the SBC 1a receives the initial SDP offer from the own IMS network, if codec conversion is to be executed in the own IMS network (SBC 1a) based on the operator policy, the SBC 1a adds the codec that can be transcoded by the own IMS network or a terminal in the own IMS network (codec b) into the codec list set in the initial SDP offer, sets “own-side” into the initial SDP offer, and transmits the initial SDP offer to the other IMS network (SBC 1b) (step S101).


Next, once the SBC 1b receives the initial SDP offer from the SBC 1a, since “own-side” is set in the initial SDP offer, the SBC 1b transmits (transparently) the initial SDP offer to the own IMS network (step S102). At this time, the SBC 1b stores “own-side” into the codec information storing unit 13 and deletes “own-side” from the initial SDP offer.


Thereafter, a codec that the incoming-side terminal itself in the IMS network of the SBC 1b wants to use is selected. Specifically, when the media conditions in the initial SDP offer (codec a, b) includes a media condition that can be used by the incoming-call terminal itself for communication, the incoming-call terminal chooses that media condition (codec b), describes it into the initial SDP answer, and sends back the initial SDP answer.


Next, once the SBC 1b receives the initial SDP answer from the own IMS network, since “own-side” was set in the previously received SDP offer, the SBC 1b sets “opposite-side” into the initial SDP answer and transmits the initial SDP answer to the other IMS network (SBC 1a) (step S103).


Next, once the SBC 1a receives the initial SDP answer from the SBC 1b, since the initial SDP answer does not include the codec included in the previously received SDP offer (codec a) but the previously transmitted codec added by the SBC 1a itself (codec b), the SBC 1a chooses one codec from the codecs included in the previously received initial SDP offer (only codec a), sets that codec to the initial SDP answer, and transmits the initial SDP answer to the own IMS network (step S104).


With the processing so far, it is possible to select the IMS network of initial SDP offer transmitting side (SBC 1a) as the executor of transcoding based on “own-side” and “opposite-side” communicated between the SBC 1a and the SBC 1b in the first SDP negotiation. For example, the SBC 1b can figure out that the SBC 1b does not have to execute transcoding and the SBC 1a has to execute transcoding by referring to “own-side” set by the SBC 1a. Note that the SBC 1a may save “own-side” set by itself in step S101 and “opposite-side” set by the SBC 1b in step S104 and figure out that transcoding is executed by itself by referring to them.


Thereafter, when the media packet is transmitted from the other IMS network (SBC 1b), the SBC 1a executes transcoding of “codec b→a” and transmits the media packet to the own IMS network, and when the media packet is transmitted from the own IMS network, the SBC 1a executes transcoding of “codec a→b” and transmits the media packet to the other IMS network (step S105).


Then, a case where subsequent SDP offer is generated in the IMS network of initial SDP answer transmitting side is described.


Once the SBC 1b receives the subsequent SDP offer from the own IMS network, since the executor of transcoding is not the SBC 1b itself, the SBC 1b adds no codec into the codec list set in the subsequent SDP offer, sets “opposite-side” into the subsequent SDP offer, and transmits the subsequent SDP offer to the other IMS network (SBC 1a) (step S106).


Next, once the SBC 1a receives the subsequent SDP offer from the SBC 1b, since the executor of transcoding is the SBC 1a itself, the SBC 1a adds the codec that can be transcoded by the own IMS network or a terminal in the own IMS network (codec a) into the codec list set in the subsequent SDP offer, and transmits the subsequent SDP offer to the own IMS network (step S107).


Note that, if the SBC 1a is already executing transcoding by itself when receiving the subsequent SDP offer from the SBC 1b in step S107, the SBC 1a at least includes the codec currently in use in the own IMS network (codec a) as the codec to be added.


In addition, in step S107, independent of the result of selecting by the first SDP negotiation, the SBC 1a may newly select itself as the executor of transcoding based on “opposite-side” set in the subsequent SDP offer or the operator policy.


Next, once the SBC 1a receives subsequent SDP answer from the own IMS network, since the subsequent SDP answer does not include the codec included in the previously received SDP offer (codec b) but the previously transmitted codec added by the SBC 1a itself (codec a), the SBC 1a chooses one codec from the codecs included in the previously received SDP offer (only codec b), sets that codec to the subsequent SDP answer, and transmits the subsequent SDP answer to the other IMS network (SBC 1b) (step S108). At this time, since “opposite-side” was set in the previously received SDP offer, the SBC 1a sets “own-side” into the subsequent SDP offer.


Next, once the SBC 1b receives the subsequent SDP answer from the SBC 1a, since the subsequent SDP answer includes the codec included in the previously received SDP offer (codec b), the SBC 1b transmits (transparently) the subsequent SDP answer to the own IMS network (step S109).


Thereafter, when the media packet is transmitted from the other IMS network (SBC 1b), the SBC 1a executes the transcoding of “codec b→a” and transmits the media packet to the own IMS network, and when the media packet is transmitted from the own IMS network, the SBC 1a executes the transcoding of “codec a→b” and transmits the media packet to the other IMS network (step S110).


With the processing in steps S106 to S110, even when the subsequent SDP offer is generated in the IMS network of initial SDP answer transmitting side, it is possible to continue the transcoding in the IMS network of initial SDP offer transmitting side (SBC 1a).


Next, a negotiation operation in a case where transcoding is to be executed in the IMS network of initial SDP answer transmitting side (SBC 1b) is described with reference to FIG. 3.


First, after the SBC 1a receives the initial SDP offer from the own IMS network, if no codec conversion is executed in the own IMS network (SBC 1a) based on the operator policy, the SBC 1a adds no codec into the codec list set in the initial SDP offer, sets “opposite-side” into the initial SDP offer, and transmits the initial SDP offer to the other IMS network (SBC 1b) (step S201).


Next, once the SBC 1b receives the initial SDP offer from the SBC 1a, if “opposite-side” is set in the initial SDP offer and the codec conversion is to be executed in the own IMS network (SBC 1b) based on the operator policy, the SBC 1b adds the codec that can be transcoded by the own IMS network or a terminal in the own IMS network (codec b) into the codec list set in the initial SDP offer, and transmits the initial SDP offer to the own IMS network (step S202).


Thereafter, the codec that the incoming-side terminal itself in the IMS network of the SBC 1b wants to use is selected. Specifically, when the media conditions in the initial SDP offer (codec a, b) includes a media condition that can be used by the incoming-call terminal itself for communication, the incoming-call terminal chooses that media condition (codec b), describes it into the initial SDP answer, and sends back the initial SDP answer.


Next, once the SBC 1b receives the initial SDP answer from the own IMS network, since “opposite-side” was set in the previously received SDP offer, the SBC 1b sets “own-side” into the initial SDP answer and transmits the initial SDP answer to the other IMS network (SBC 1a) (step S203).


Next, once the SBC 1a receives the initial SDP answer from the SBC 1b, since the initial SDP answer includes the codec included in the previously received SDP offer (codec a), the SBC 1a transmits (transparently) the initial SDP answer to the own IMS network (step S204).


With the processing so far, it is possible to select the IMS network of initial SDP answer transmitting side (SBC 1b) as the executor of transcoding based on “own-side” and “opposite-side” communicated between the SBC 1a and the SBC 1b in the first SDP negotiation. It is needless to say that the SBC 1b may save “opposite-side” set by the SBC 1a and figure out that transcoding is executed by itself by referring to it. In addition, the SBC 1a may save “own-side” set by the SBC 1b and figure out that the SBC 1a does not have to execute transcoding and the SBC 1b has to execute transcoding by referring to it.


Thereafter, when the media packet is transmitted from the own IMS network, the SBC 1b executes the transcoding of “codec b→a” and transmits the media packet to the other IMS network (SBC 1a), and when the media packet is transmitted from the other IMS network, the SBC 1b executes the transcoding of “codec a→b” and transmits the media packet to the own IMS network (step S205).


Then, a case where the subsequent SDP offer is generated in the IMS network of initial SDP answer transmitting side is described.


Once the SBC 1b receives the subsequent SDP offer from the own IMS network, since the executor of transcoding is the SBC 1b itself, the SBC 1b adds the codec that can be transcoded by the own IMS network or a terminal in the own IMS network (codec a) into the codec list set in the subsequent SDP offer, sets “own-side” into the subsequent SDP offer, and transmits the subsequent SDP offer to the other IMS network (SBC 1a) (step S206).


Next, once the SBC 1a receives the subsequent SDP offer from the SBC 1b, since the executor of transcoding is not the SBC 1a itself, the SBC 1a adds no codec into the codec list set in the subsequent SDP offer, deletes “own-side” from the subsequent SDP offer, and transmits the subsequent SDP offer to the own IMS network (step S207).


Next, once the SBC 1a receives the subsequent SDP answer from the own IMS network, since the subsequent SDP answer includes the codec included in the previously received SDP offer (codec a), the SBC 1a transmits (transparently) the subsequent SDP answer to the other IMS network (SBC 1b) (step S208). At this time, since “own-side” was set in the previously received SDP offer, the SBC 1a sets “opposite-side” into the subsequent SDP offer.


Next, once the SBC 1b receives the subsequent SDP answer from the SBC 1a, since the subsequent SDP answer does not include the codec included in the previously received SDP offer (codec b) but the previously transmitted codec added by the SBC 1b itself (codec a), the SBC 1b chooses one codec from the codecs included in the previously received SDP offer (only codec b), sets that codec to the subsequent SDP answer, and transmits (transparently) the subsequent SDP answer to the own IMS network (step S209).


Thereafter, when the media packet is transmitted from the own IMS network, the SBC 1b executes the transcoding of “codec b→a” and transmits the media packet to the other IMS network (SBC 1a), and when the media packet is transmitted from the other IMS network, the SBC 1b executes the transcoding of “codec a→b” and transmits the media packet to the own IMS network (step S210).


With the processing in steps S206 to S210, even when the subsequent SDP offer is generated in the IMS network of initial SDP answer transmitting side, it is possible to continue the transcoding in the IMS network of initial SDP answer transmitting side (SBC 1b).


Next, a renegotiation operation in a case where the IMS network that is requested to execute the transcoding cannot execute transcoding is described with reference to FIG. 4.


First, after the SBC 1a receives the initial SDP offer from the own IMS network, if no codec conversion is executed in the own IMS network (SBC 1a) based on the operator policy, the SBC 1a adds no codec into the codec list set in the initial SDP offer, sets “opposite-side” into the initial SDP offer, and transmits the initial SDP offer to the other IMS network (SBC 1b) (step S301).


Next, once the SBC 1b receives the initial SDP offer from the SBC 1a, if no codec conversion is executed in the own IMS network (SBC 1b) based on the operator policy although “opposite-side” is set in the initial SDP offer, the SBC 1b transmits (transparently) the initial SDP offer to the own IMS network (step S302).


Thereafter, the codec that the incoming-side terminal itself in the IMS network of the SBC 1b wants to use is selected. Specifically, when the media condition in the initial SDP offer (codec a) does not include a media condition that can be used by the incoming-call terminal itself for communication, the incoming-call terminal sets the SDP to a 488 response (=Not Acceptable response; error response), describes the media condition that the incoming terminal itself wants to use for communication (codec b) into the SDP, and sends back the SDP.


Next, once the SBC 1b receives the SDP set to the 488 response from the own IMS network, since this is the 488 response although “opposite-side” was set in the previously received SDP offer, the SBC 1b sets “opposite-side” into the SDP and transmits the SDP to the other IMS network (SBC 1a) (step S303).


Note that, in step S303, although the same information element value “opposite-side” is formally set in the SDP, it is actually a request to change the executor of transcoding from the SBC 1b to the SBC 1a.


Next, once the SBC 1a receives the SDP from the SBC 1b, since no codec conversion is performed in the own IMS network (SBC 1a) at this timing likewise step S301 although “opposite-side” is set in the SDP, the SBC 1a transmits (transparently) the SDP to the own IMS network (step S304).


Thereafter, a second initial SDP offer to which the same codec (codec a) is set is transmitted again from the outgoing-call terminal in the IMS network of the SBC 1a.


Next, once the SBC 1a receives the second initial SDP offer from the own IMS network, if “opposite-side” is set in the SDP previously received from the other IMS network and transcoding can be executed by the SBC 1a itself although execution of the codec conversion was not planned in step S301, the SBC 1a adds the codec that can be transcoded by the own IMS network or a terminal in the own IMS network into the codec list set in the second initial SDP offer, sets “own-side” into the second initial SDP offer, and transmits the second initial SDP offer to the other IMS network (SBC 1b) (step S305).


Step S306 to Step S309 after this are the same as the above-described steps S102 to S105.


According to this embodiment, since the multiple IMS networks (SBC 1a and SBC 1b) set the information element that requests any of the IMS networks to execute transcoding into the SDP, use that information element to select an IMS network (SBC 1a or SBC 1b) that is to execute transcoding between the IMS networks (between SBC 1a and SBC 1b), and execute transcoding of media data in the selected IMS network, it is possible to fix the IMS network that is determined to execute the transcoding.


Thus, since the execution point and the executor of transcoding which consumes enormous resources can be fixed on the initial SDP offer transmitting side or the initial SDP answer transmitting side, it is possible to predict a resource to be required by the communications carrier and to design equipment, and this facilitates organizing access charges between the communications carriers.


In addition, according to this embodiment, when the IMS network requested by the information element of the SDP cannot execute transcoding, that information element is changed so as to indicate an IMS network other than that IMS network, and this makes it possible to appropriately change the IMS network (SBC) that is to execute transcoding. Thus, even when one IMS network cannot execute transcoding, transcoding still can be executed in any different IMS network, and this improves establishment of call connection between the outgoing and incoming terminals.


Second Embodiment

In Second Embodiment, the SDP offer transmitting side and/or the SDP answer transmitting side manage codec information, which is selected by the last SDP negotiation between the two sides of the own IMS network, as session-relevant information element to continue transcoding.


The overall configuration of the call control system according to this embodiment and the functional block configurations of the SBCs 1a, 1b are similar to those of First Embodiment illustrated in FIG. 1.


The SDP processing unit 11 has the conventional function that is for example the SDP rewrite processing (such as processing of adding and deleting a codec to and from the SDP).


The codec information storing unit 13 has not only the conventional function of storing the codec information that can be transcoded by the own IMS network (own SBC) or a terminal in the own IMS network but also a function of storing the before-converted and after-converted codec information selected by the SDP negotiation as the session-relevant information element.


The transcoding unit 12 has not only the conventional function of transcoding the media packet (media data) but also a function of executing or not executing transcoding based on the session-relevant information element of the codec information storing unit 13. Specifically, when the converted codec information managed by the session-relevant information element is not included in the received SDP, the transcoding unit 12 is determined to execute transcoding, and when the converted codec information is included, the transcoding unit 12 is determined to not execute transcoding.


So far, the functions of the SBC 1a and the SBC 1b are schematically described. Note that, more specifically, each SDP processing unit 11 of the SBC 1a and the SBC 1b performs operation and processing according to the operation details exemplified in Table 3 and Table 4.









TABLE 3







Table 3: Operation of Initial SDP Offer Transmitting Side










Receive from the
Receive from the



own network (own
other network (own



network −> SBC −>
network <− SBC <−


Receiving condition
other network)
other network)













SDP
Initial
If it is set to



offer

execute




transcoding when




the own SBC is the




initial SDP offer




side, add one or




more transcodable




codecs into the




codec list and




transmit the SDP




offer to the other




network.




If it is not set to




execute




transcoding when




the own SBC is the




initial SDP offer




side, add no codec




and transmit the




SDP offer to the




other network.



Subsequent
The own SBC checks
Same to the left




if the codec
operation




selected by the




previous SDP




offer/answer




negotiation




between the own SBC




and a device




located in a




direction of




transmitting the




SDP offer is




included in the




received SDP offer,




and if the selected




codec is not




included and also




transcoding is




possible between




the previously




negotiated codec




and the codec




included in the




received SDP offer,




the own SBC adds the




previously




negotiated codec.









SDP answer
If the SDP answer
If the SDP answer


(first/subsequent)
includes the codec
includes the codec



included in the
included in the



previously
previously



received SDP offer,
received SDP offer,



transmit
transmit



(transparently)
(transparently)



the SDP answer to
the SDP answer to



the other network
the own network (no



(no transcoding
transcoding



occurs).
occurs).



If the SDP answer
If the SDP answer



does not include
does not include



the codec included
the codec included



in the previously
in the previously



received SDP offer
received SDP offer



but the previously
but the previously



transmitted codec
transmitted codec



added by the own
added by the own



SBC, choose one
SBC, choose one



from the codecs
from the codecs



included in the
included in the



previously
previously



received SDP offer,
received SDP offer,



set its codec
set its codec



information into
information into



the SDP answer, and
the SDP answer, and



transmit the SDP
transmit the SDP



answer to the other
answer to the own



network
network



(transcoding
(transcoding



occurs).
occurs).



Save the codec
Save the codec



negotiated by the
negotiated by the



two sides (SDP
two sides (SDP



answer receiving
answer receiving



side/transmitting
side/transmitting



side) of the own SBC
side) of the own SBC



and determined to
and determined to



be used.
be used.
















TABLE 4







Table 4: Operation of Initial SDP Answer Transmitting Side










Receive from the
Receive from the



own network (other
other network (other



network <− SBC <−
network −> SBC −>


Receiving condition
own network)
own network)













SDP
Initial

If it is set to


offer


execute





transcoding when





the own SBC is the





initial SDP answer





side, add one or





more transcodable





codecs into the





codec list, and





transmit the SDP





offer to the other





network.





If it is not set to





execute





transcoding when





the own SBC is the





initial SDP answer





side, add no codec





and transmit the





SDP offer to the





other network.



Subsequent
The own SBC checks
Same to the left




if the codec
operation




selected by the




previous SDP




offer/answer




negotiation




between the own SBC




and a device




located in a




direction of




transmitting the




SDP offer is




included in the




received SDP offer,




and if the selected




codec is not




included and also




transcoding is




possible between




the previously




negotiated codec




and the codec




included in the




received SDP offer,




the own SBC adds the




previously




negotiated codec.









SDP answer
If the SDP answer
If the SDP answer


(first/subsequent)
includes the codec
includes the codec



included in the
included in the



previously
previously



received SDP offer,
received SDP offer,



transmit
transmit



(transparently)
(transparently)



the SDP answer to
the SDP answer to



the other network
the other network



(no transcoding
(no transcoding



occurs).
occurs).



If the SDP answer
If the SDP answer



does not include
does not include



the codec included
the codec included



in the previously
in the previously



received SDP offer
received SDP offer



but the previously
but the previously



transmitted codec
transmitted codec



added by the own
added by the own



SBC, choose one
SBC, choose one



from the codecs
from the codecs



included in the
included in the



previously
previously



received SDP offer,
received SDP offer,



set its codec
set its codec



information into
information into



the SDP answer, and
the SDP answer, and



transmit to the
transmit to the



other network
other network



(transcoding
(transcoding



occurs).
occurs).



Save the codec
Save the codec



negotiated by the
negotiated by the



two sides (SDP
two sides (SDP



answer receiving
answer receiving



side/transmitting
side/transmitting



side) of the own SBC
side) of the own SBC



and determined to
and determined to



be used.
be used.









Next, an operation in a case where transcoding is determined to be executed in the IMS network of initial SDP offer transmitting side (SBC 1a) is described with reference to FIG. 5.


First, after the SBC 1a receives the initial SDP offer from the own IMS network, if the codec conversion is determined to be executed in the own IMS network, the SBC 1a adds the codec that can be transcoded by the own IMS network or a terminal in the own IMS network (codec b) into the codec list set in the initial SDP offer and transmits the initial SDP offer to the other IMS network (SBC 1b) (step S401).


Next, once the SBC 1b receives the initial SDP offer from the SBC 1a, when no codec conversion is determined to be executed in the own IMS network, the SBC 1b adds no codec into the codec list set in the initial SDP offer and transmits (transparently) the initial SDP offer to the own IMS network (step S402).


Thereafter, the codec that the incoming-side terminal itself in the IMS network of the SBC 1b wants to use is selected. Specifically, when the media conditions in the initial SDP offer (codec a, b) includes a media condition that can be used by the incoming-call terminal itself for communication, the incoming-call terminal chooses that media condition (codec b), describes it into the initial SDP answer, and sends back the initial SDP answer.


Next, once the SBC 1b receives the initial SDP answer from the own IMS network, since the initial SDP answer includes the codec included in the previously received SDP offer, the SBC 1b transmits (transparently) the initial SDP answer to the other IMS network (SBC 1a) (step S403). At this time, the SBC 1b saves information on the received codec (codec b) and information on the transmitted codec (codec b). Particularly, the SBC 1b manages the information on the transmitted codec (codec b) as the converted codec information.


Next, once the SBC 1a receives the initial SDP answer from the SBC 1b, since the initial SDP answer does not include the codec included in the previously received SDP offer (codec a) but the previously transmitted codec added by the SBC 1a itself (codec b), the SBC 1a chooses one codec from the codecs included in the previously received initial SDP offer (only codec a), sets that codec to the initial SDP answer, and transmits the initial SDP answer to the own IMS network (step S404). At this time, the SBC 1a saves information on the received codec (codec b) and information on the transmitted codec (codec a). Particularly, the SBC 1b manages the information on the transmitted codec (codec a) as the converted codec information.


Thereafter, when the media packet is transmitted from the other IMS network (SBC 1b), the SBC 1a executes the transcoding of “codec b→a” and transmits the media packet to the own IMS network, and when the media packet is transmitted from the own IMS network, the SBC 1a executes the transcoding of “codec a→b” and transmits the media packet to the other IMS network (step S405).


Then, a case where the subsequent SDP offer is generated in the IMS network of initial SDP answer transmitting side is described.


Once the SBC 1b receives the subsequent SDP offer from the own IMS network, since the subsequent SDP offer includes the codec selected by the previous SDP negotiation between the SBC 1b itself and the opposite IMS network opposing to itself (SBC 1a) (the converted codec saved in step S403 (codec b)), the SBC 1b transmits (transparently) the subsequent SDP offer to the other IMS network (SBC 1a) (step S406).


Next, once the SBC 1a receives the subsequent SDP offer from the SBC 1b, since the subsequent SDP offer does not include the codec selected by the previous SDP negotiation between the SBC 1a itself and a device in the own IMS network (outgoing-side terminal and the like) (the converted codec saved in step S404 (codec a)) and since transcoding is possible between the codec selected by the previous SDP negotiation (codec a) and the codec included in the subsequent SDP offer (codec b), the SBC 1a adds the codec selected by the previous SDP negotiation (codec a) and transmits the subsequent SDP offer to the own IMS network (step S407).


Next, once the SBC 1a receives the subsequent SDP answer from the own IMS network, since the subsequent SDP answer does not include the codec included in the previously received SDP offer (codec b) but the previously transmitted codec added by the SBC 1a itself (codec a), the SBC 1a chooses one codec from the codecs included in the previously received SDP offer (only codec b), sets that codec to the subsequent SDP answer, and transmits the subsequent SDP answer to the other IMS network (SBC 1b) (step S408).


Next, once the SBC 1b receives the subsequent SDP answer from the SBC 1a, since the subsequent SDP answer includes the codec included in the previously received SDP offer (codec b), the SBC 1b transmits (transparently) the subsequent SDP answer to the own IMS network (step S409).


Thereafter, when the media packet is transmitted from the other IMS network (SBC 1b), the SBC 1a executes the transcoding of “codec b→a” and transmits the media packet to the own IMS network, and when the media packet is transmitted from the own IMS network, the SBC 1a executes the transcoding of “codec a→b” and transmits the media packet to the other IMS network (step S410).


Next, an operation in a case where transcoding is determined to be executed in the IMS network of initial SDP answer transmitting side (SBC 1b) is described with reference to FIG. 6.


First, after the SBC 1a receives the initial SDP offer from the own IMS network, if no codec conversion is determined to be executed in the own IMS network, the SBC 1a adds no codec into the codec list set in the initial SDP offer and transmits the initial SDP offer to the other IMS network (SBC 1b) (step S501).


Next, once the SBC 1b receives the initial SDP offer from the SBC 1a, when the codec conversion is determined to be executed in the own IMS network, the SBC 1b adds the codec that can be transcoded by the own IMS network or a terminal in the own IMS network (codec b) into the codec list set in the initial SDP offer, and transmits the initial SDP offer to the own IMS network (step S502).


Thereafter, the codec that the incoming-side terminal itself in the IMS network of the SBC 1b wants to use is selected. Specifically, when the media conditions in the initial SDP offer (codec a, b) includes a media condition that can be used by the incoming-call terminal itself for communication, the incoming-call terminal chooses that media condition (codec b), describes it into the initial SDP answer, and sends back the initial SDP answer.


Next, once the SBC 1b receives the initial SDP answer from the own IMS network, since the initial SDP answer does not include the codec included in the previously received SDP offer (codec a) but the previously transmitted codec added by the SBC 1b itself (codec b), the SBC 1b chooses one codec from the codecs included in the previously received initial SDP offer (only codec a), sets that codec to the initial SDP answer, and transmits the initial SDP answer to the other IMS network (SBC 1a) (step S503). At this time, the SBC 1b saves information on the received codec (codec b) and information on the transmitted codec (codec a). Particularly, the SBC 1b manages the information on the transmitted codec (codec a) as the converted codec information.


Next, once the SBC 1a receives the initial SDP answer from the SBC 1b, since the initial SDP answer includes the codec included in the previously received SDP offer (codec a), the SBC 1a transmits (transparently) the initial SDP answer to the own IMS network (step S504). At this time, the SBC 1a saves information on the received codec (codec a) and information on the transmitted codec (codec a). Particularly, the SBC 1a manages the information on the transmitted codec (codec a) as the converted codec information.


Thereafter, when the media packet is transmitted from the own IMS network, the SBC 1b executes transcoding of “codec b→a” and transmits the media packet to the other IMS network (SBC 1a), and when the media packet is transmitted from the other IMS network, the SBC 1b executes the transcoding of “codec a→b” and transmits the media packet to the own IMS network (step S505).


Then, a case where the subsequent SDP offer is generated in the IMS network of initial SDP answer transmitting side is described.


Once the SBC 1b receives the subsequent SDP offer from the own IMS network, since the subsequent SDP offer does not include the codec selected by the previous SDP negotiation between the SBC 1b itself and the opposite IMS network opposing to itself (SBC 1a) (the converted codec saved in step S503 (codec a)) and since transcoding is possible between the codec selected by the previous SDP negotiation (codec a) and the codec included in the subsequent SDP offer (codec b), the SBC 1b adds the codec selected by the previous SDP negotiation (codec a) and transmits the subsequent SDP offer to the other IMS network (SBC 1a) (step S506).


Next, once the SBC 1a receives the subsequent SDP offer from the SBC 1b, since the subsequent SDP offer includes the codec selected by the previous SDP negotiation between the SBC 1a itself and a device in the own IMS network (outgoing-side terminal and the like) (the converted codec saved in step S504 (codec a)), the SBC 1a transmits (transparently) the subsequent SDP offer to the own IMS network (step S507).


Next, once the SBC 1a receives the subsequent SDP answer from the own IMS network, since the subsequent SDP answer includes the codec included in the previously received SDP offer (codec a), the SBC 1a transmits (transparently) the subsequent SDP answer to the other IMS network (SBC 1b) (step S508).


Next, once the SBC 1b receives the subsequent SDP answer from the SBC 1a, since the subsequent SDP answer does not include the codec included in the previously received SDP offer (codec b) but the previously transmitted codec added by the SBC 1b itself (codec a), the SBC 1b chooses one codec from the codecs included in the previously received SDP offer (only codec b), sets that codec to the subsequent SDP answer, and transmits the subsequent SDP answer to the own IMS network (step S509).


Thereafter, when the media packet is transmitted from the own IMS network, the SBC 1b executes transcoding of “codec b→a” and transmits the media packet to the other IMS network (SBC 1a), and when the media packet is transmitted from the other IMS network, the SBC 1b executes transcoding of “codec a→b” and transmits the media packet to the own IMS network (step S510).


According to this embodiment, since each of the multiple IMS networks (SBC 1a and SBC 1b) stores the converted codec information selected by the SDP negotiation and executes transcoding of the media data in the own IMS network (SBC 1a or SBC 1b) when the received SDP does not include the converted codec information, it is possible to fix the IMS network that is determined to execute the transcoding.


Thus, since the execution point and the executor of transcoding which consumes enormous resources can be fixed on the initial SDP offer transmitting side or the initial SDP answer transmitting side, it is possible to predict a resource to be required by the communications carrier and to design equipment, and this facilitates organizing access charges between the communications carriers.


Lastly, the SBC 1a and SBC 1b described in this embodiment can be implemented by a computer (information processing device) provided with a CPU, a memory, a hard disk, and so on. In addition, it is also possible to create a program for functioning the computer as the SBC 1a and SBC 1b (call control program) and a storing medium of that program.


At last, Table 3 and Table 4 are further described. In Second Embodiment, as described in the operation description column of “Subsequent” of “SDP offer” in Table 3 or Table 4, the processing of “If the selected codec is not included and also transcoding is possible between the previously negotiated codec and the codec included in the received SDP offer, add the previously negotiated codec” is executed.


As for such a processing, for example, a processing can be considered such as “In the SBC 1a determined to execute transcoding, if the SDP offer from the SBC 1b does not include the previously selected codec (codec b) and transcoding is possible between the codec selected by the previous negotiation (S401 to S404) (codec a) and the codec included in the received SDP offer (e.g., codec c), add the previously negotiated codec (codec a) to the SDP offer”. In this case, the SBC 1a keeps a transcodable list in advance for example, and if a codec type of “codec a” and a codec type of “codec c” are being associated with each other in that transcodable list, the SBC 1a determines that the transcoding is possible.


In other words, based on Table 3 or Table 4, an SBC 1 (communication device) may also execute a processing such as “If the own communication device is executing transcoding and also receives an SIP message containing the SDP offer not including the previously selected codec (codec b), and if transcoding is possible between the codec included in such an SDP offer (e.g., codec c) and the codec currently in use in the forwarding destination (codec a), add the codec currently in use in the forwarding destination (codec a) into the codec list in the SDP offer”.


Note that the transcodable list is an example of a method that enables the SBC 1 to figure out the transcodable codec type.


EXPLANATION OF THE REFERENCE NUMERALS






    • 1 (1a, 1b) SBC


    • 11 SDP processing unit


    • 12 transcoding unit


    • 13 codec information storing unit




Claims
  • 1. A first communication device, comprising: a memory storing instructions; andone or more processors configured to execute the instructions to:when the first communication device is in one of an incoming call side and an outgoing call side,negotiate, by exchanging an SDP (Session Description Protocol) offer and an SDP answer, an SDP with a second communication device in another of the incoming call side and the outgoing call side as to whether the first communication device or the second communication device performs transcoding of media data;store a codec type currently in use that is determined by the SDP negotiation; andif performing the transcoding and receiving a SIP (Session Initiation Protocol) message containing a subsequent SDP offer, including a codec type currently in use in a forwarding destination into the subsequent SDP offer when forwarding the SIP message.
  • 2. The first communication device according to claim 1, wherein the one or more processors is further configured to execute the instructions to:if the subsequent SDP offer in the received SIP message includes a codec type currently in use in a forwarding source, includes the codec type currently in use in the forwarding destination into the subsequent SDP offer in the SIP message to be transmitted.
  • 3. The first communication device according to claim 1, wherein the one or more processors is further configured to execute the instructions to:if the subsequent SDP offer in the received SIP message does not include a codec type currently in use in a forwarding source and if the first communication device is capable of transcoding between a codec type included in the subsequent SDP offer and the codec type currently in use in the forwarding destination, includes the codec type currently in use in the forwarding destination into the subsequent SDP offer in the SIP message to be transmitted.
  • 4. A communication system, comprising: a first communication device; anda second communication device,the first communication device and the second communication device each comprise:a memory storing instructions; andone or more processors configured to execute the instructions to: wherein when the first communication device is in one of an incoming call side and an outgoing call side, the first communication device is configured to: negotiate, by exchanging an SDP (Session Description Protocol) offer and an SDP answer, an SDP with the second communication device in another of the incoming call side and the outgoing call side as to whether the first communication device or the second communication device performs transcoding of media data;store a codec type currently in use that is determined by the SDP negotiation; andif performing the transcoding and receiving a SIP (Session Initiation Protocol) message containing a subsequent SDP offer from the second communication device, including a codec type currently in use in a forwarding destination into the subsequent SDP offer when forwarding the SIP message.
  • 5. A communication method executed between a first communication device and a second communication device, the method comprising: when the first communication device is in one of an incoming call side and an outgoing call side, the first communication device performs: a first step of negotiating, by exchanging an SDP (Session Description Protocol) offer and an SDP answer, an SDP with a second communication device in another of the incoming call side and the outgoing call side as to whether the first communication device or the second communication device performs transcoding of media data;a second step of storing a codec type currently in use that is determined by the SDP negotiation into a codec information storing unit,if performing the transcoding and receiving a SIP (Session Initiation Protocol) message containing a subsequent SDP offer, a third step of transmitting the SIP message containing the subsequent SDP offer that includes a codec type currently in use in a forwarding destination.
  • 6. The communication method according to claim 5, wherein the third step includes, if the subsequent SDP offer in the received SIP message includes a codec type currently in use in a forwarding source, including the codec type currently in use in the forwarding destination into the subsequent SDP offer in the SIP message to be transmitted.
  • 7. The communication method according to claim 5, wherein the third step includes, if the subsequent SDP offer in the received SIP message does not include a codec type currently in use in a forwarding source and if being capable of transcoding between a codec type included in the subsequent SDP offer and the codec type currently in use in the forwarding destination, including the codec type currently in use in the forwarding destination into the subsequent SDP offer in the SIP message to be transmitted.
Priority Claims (1)
Number Date Country Kind
2016-139714 Jul 2016 JP national
Parent Case Info

This application is a divisional of Ser. No. 16/923,358 filed Jul. 8, 2020, which is a divisional of U.S. Ser. No. 16/309,612 filed Jul. 14, 2017, issued as U.S. Pat. No. 11,012,478. This application is also related to co-pending application U.S. Ser. No. 18/142,183 filed concurrently herewith and to U.S. Ser. No. 18/204,613 filed Jun. 1, 2023, all of which are hereby incorporated by reference in their entireties for all purposes.

US Referenced Citations (54)
Number Name Date Kind
6359902 Putzolu Mar 2002 B1
7512118 Stephens Mar 2009 B1
7617319 Burks et al. Nov 2009 B2
7751359 Bienn et al. Jul 2010 B1
7940793 Zilbershtein et al. May 2011 B2
7944862 Taylor et al. May 2011 B2
8059656 Telikepalli et al. Nov 2011 B1
8139541 Ejzak et al. Mar 2012 B2
8199727 Bienn et al. Jun 2012 B1
8213365 Bienn et al. Jul 2012 B2
8249076 Bertone et al. Aug 2012 B1
8289368 Gopal et al. Oct 2012 B2
8472453 Bangalore et al. Jun 2013 B2
8560729 Jabri et al. Oct 2013 B2
8595018 Kampmann et al. Nov 2013 B2
8670770 Fitzgerald et al. Mar 2014 B2
8776161 Gazier et al. Jul 2014 B2
8843992 Fernandez Alonso et al. Sep 2014 B2
8893204 Levin et al. Nov 2014 B2
9143534 Kelliher Sep 2015 B1
9282131 Hosur et al. Mar 2016 B2
9509725 Belling et al. Nov 2016 B2
9629131 Ozgur Apr 2017 B2
9876838 Li et al. Jan 2018 B2
9961116 Prajapat May 2018 B2
10075479 Belling et al. Sep 2018 B2
10129300 Sharma et al. Nov 2018 B2
10148703 Mufti et al. Dec 2018 B2
10412136 Gonzalez De Langarica et al. Sep 2019 B2
10594744 Hori Mar 2020 B2
10848602 Frankkila et al. Nov 2020 B2
11012478 Ogawa et al. May 2021 B2
20040037312 Spear Feb 2004 A1
20040240399 Corrao et al. Dec 2004 A1
20050105511 Poikselka May 2005 A1
20060153102 Kuure et al. Jul 2006 A1
20070047707 Mayer et al. Mar 2007 A1
20070153766 Bienn et al. Jul 2007 A1
20080025414 Kim et al. Jan 2008 A1
20080081648 Kang Apr 2008 A1
20090183211 Yan et al. Jul 2009 A1
20100134590 Lindstrom Jun 2010 A1
20100150141 Lee Jun 2010 A1
20110136483 Dwight Jun 2011 A1
20120185600 Belling Jul 2012 A1
20120219130 Zhu et al. Aug 2012 A1
20130232273 Lawn Sep 2013 A1
20130246052 Tanaka et al. Sep 2013 A1
20140101328 Coulombe Apr 2014 A1
20140328323 Zhang et al. Nov 2014 A1
20150045041 Polisetty et al. Feb 2015 A1
20160021163 Lee Jan 2016 A1
20160149984 Prajapat May 2016 A1
20180014168 Lau et al. Jan 2018 A1
Foreign Referenced Citations (6)
Number Date Country
1069738 Jan 2001 EP
2010512106 Apr 2010 JP
2010273103 Dec 2010 JP
2011166453 Aug 2011 JP
2012209638 Oct 2012 JP
2013012856 Jan 2013 JP
Non-Patent Literature Citations (20)
Entry
JP 2019-208007—Decision to Grant a Patent mailed Aug. 25, 2020.
“IP Multimedia Call Control Protocol Based on Session Initiation Protocol (SIP) and Session Description Protocol (SDP)”, 3GPP TS 24.229 V14.0.1, Jun. 2016, 932 pages.
“IP Multimedia Subsystem (IMS)”, 3GPP TS 23.228 V14.0.0, Jun. 2016, 40 pages.
U.S. Appl. No. 16/309,612 , “Final Office Action”, filed Nov. 13, 2020, 7 pages.
U.S. Appl. No. 16/309,612 , “Non-Final Office Action”, filed Aug. 7, 2020, 8 pages.
U.S. Appl. No. 16/309,612 , “Notice of Allowance”, filed Mar. 19, 2021, 9 pages.
U.S. Appl. No. 16/923,358 , “Final Office Action”, filed Feb. 2, 2023, 21 pages.
U.S. Appl. No. 16/923,358 , “Final Office Action”, filed May 12, 2022, 15 pages.
U.S. Appl. No. 16/923,358 , “Non-Final Office Action”, filed Feb. 4, 2022, 11 pages.
U.S. Appl. No. 16/923,358 , “Non-Final Office Action”, filed Oct. 28, 2022, 16 pages.
Handley , et al., “SDP: Session Description Protocol”, Network Working Group, Apr. 1998, 42 pages.
JP2018-527680 , “Office Action”, Sep. 17, 2019, 6 pages.
PCT/JP2017/025713 , “International Preliminary Report on Patentability”, Jan. 24, 2019, 8 pages.
PCT/JP2017/025713 , “International Search Report and Written Opinion”, Oct. 3, 2017, 10 pages.
PCT/JP2017/025713 , “Written Opinion”, Oct. 3, 2017, 4 pages.
Rosenberg , et al., “An Offer/Answer Model With Tile Session Description Protocol (SDP)”, Network Working Group, Jun. 2002, 25 pages.
Rosenberg , et al., “SIP: Session Initiation Protocol”, Network Working Group, Available Online At: https://www.rfc-editor.org/rfc/rfc3261.txt; Jun. 2002, 269 pages.
Schulzrinne, et al., “RTP: A Transport Protocol for Real-Time Applications”, Network Working Group, Request for Comments: 3550, Jul. 2003, 104 pages.
U.S. Appl. No. 18/142,183, Non-Final Office Action mailed on Dec. 8, 2023, 13 pages.
U.S. Appl. No. 18/204,613, Notice of Allowance mailed on Jan. 31, 2024, 11 pages.
Related Publications (1)
Number Date Country
20230269279 A1 Aug 2023 US
Divisions (2)
Number Date Country
Parent 16923358 Jul 2020 US
Child 18142143 US
Parent 16309612 US
Child 16923358 US