• 专利附录
  • 专利说明
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    • 专利摘要:
    The present invention relates to a digital conference system comprising a central unit and at least two conference devices. The central unit is connected to the at least two conference devices in a point-to-multipoint topology. The digital conference system is designed for bi-directional data traffic between the central unit and the conference equipment. The data traffic in each direction comprises multiplexed packets of data of at least two data classes, the data traffic from the central unit to the conference equipment being split from the data traffic from the conference equipment to the central unit. The central unit and the conference equipment comprise multiplexing means adapted to combine data from the at least two data classes. The multiplexing means is arranged to assign to the at least two data classes a downlink priority level when they are sent to the conference equipment, and an uplink priority level when they are sent to the central unit, before transmission.
    公开号:BE1022465B1
    申请号:E2015/5191
    申请日:2015-03-27
    公开日:2016-04-07
    发明作者:Cedric Melange;Patrick Talloen;Pieter Demuytere
    申请人:Televic Conference Nv;
    IPC主号:
    专利说明:

    Digital conference system
    Field of the Invention The present invention relates generally to the field of digital conference systems comprising a central unit and a plurality of conference devices such as participant units, extension units, interpreter units, ... that can be connected to the central unit.
    Background of the Invention A digital conference system comprises a central unit, which is connected via powered network ports to different participant units for the participating members. In addition to the participant units, various other types of conference devices may be present in the digital conference system: video units, channel selection units, extension units, and interpreter units. Any of those units can be connected to the central unit via a network port. The central unit includes a number of conference network ports to which different devices of the conference network can be connected, e.g., participant units, video units, channel selection units, extension units, legacy units, and interpreter units. Fig. 1 illustrates a typical network topology for a digital conference system as known in the current state of the art.
    Participant units are provided for the conference participants. This equipment usually includes discussion, voting, video, and interactivity features for participants. This equipment comes in a variety of forms (eg with a subset of these functions for the conference participant (for example, a device with audio functions only)). Video units may be needed to connect all kinds of video equipment, such as cameras, to the conference network. Channel selection units offer a functionality for selecting the audio channel for a conference participant. Extension units make it possible to increase the number of units that can be connected to the network, since there is a limitation on the maximum number of units that can be included in one branch (power supply, bandwidth). Interpreter units are devices that allow interpreters to simultaneously listen to a specific audio channel in the network and place the interpreted version of that channel (that language) on the conference network.
    The conference network is in fact a combination of point-to-multi-point connections (central unit to participant units) and multi-point-to-point connections (participant units, interpreter units, etc. to the central unit). All communication in the network goes through the central unit that directs the behavior of the entire network.
    Patent application WO2005 / 101755 provides a method for transferring data from different data sources via a data packet communication network with a congestion controller to limit the effects of congestion by selectively prioritizing certain data packets. The data packets can contain data in a number of different multimedia types, e.g. voice, video, audio, e-mail, each within a separate partition in the package. The packets can be sent as a train of data packets with some association in time and an order of priority. The association and order of priority are used to decide which packets can be retained and which packets can be scrapped when network congestion occurs.
    US2007 / 083666 relates to bandwidth management when sending multimedia via a network. An audio, video and data stream is created that each have their own speed, which is determined independently of the others. They are sent together according to a priority hierarchy that gives priority to the audio stream to the detriment of the video stream and data stream, and gives priority to the data stream to the detriment of the video stream.
    There is a need for a distributed intelligent conference system that can guarantee correct performance levels for different data streams in the network. It must be guaranteed that mission-critical data is delivered at all times, while other data may be discarded without a major impact on overall system behavior.
    Summary of the Invention It is an object of embodiments of the present invention to provide a digital conference system in which different data streams can be combined in a scalable manner and in which Quality of Service can be optimized and / or guaranteed for specific data streams. The invention also has for its object to provide a digital conference system with a central unit that is able to carry out a centralized management of the total bandwidth usage and the type of bandwidth usage in the conference network.
    The above object is achieved by the solution according to the present invention.
    In a first aspect, the invention relates to a digital conference system comprising a central unit and at least two other conference devices. The central unit is connected to the at least two conference devices in a point-to-point multi-point topology and the at least two conference devices are connected to the central unit in a point-to-point multi-point topology. The digital conference system is arranged for bi-directional data traffic between the central unit and the at least two conference devices. The data traffic in each direction is organized in multiplexed packages comprising data from at least two data classes, one of the data classes being for audio data and the data traffic from the central unit to the at least two conference devices (downlink data traffic) being logically split from the data traffic from the at least two conference devices to the central unit (uplink data traffic). The central unit and the at least two conference devices include multiplexing means adapted to combine data from the at least two data classes in each direction. The digital conference system is characterized in that the multiplexing means are adapted to assign a downlink priority level to the at least two data classes when they are sent to the at least two conference devices, and an uplink priority level when they are sent to the central unit are sent. As such, priority levels can be assigned in an optimized way.
    The proposed solution indeed makes it possible to combine data from different data classes in a scalable manner. Due to the assigned priority level for each type of data class, and this for the upstream and downstream direction separately, a large number of options are available to compile the resulting stream to be sent. These options are usually specified in the design, but adjustment is also possible during use (by means of software / firmware updates).
    In a preferred embodiment, at least the central unit comprises at least two ports for receiving and transmitting the data traffic and processing means which are arranged to detect the speed of the data traffic at the ports, in order to enable optimum bandwidth usage in the network in this way to make. Advantageously, the processing means are arranged to detect whether the data traffic is sent in the uplink or downlink direction, which makes a simple network installation possible.
    In one embodiment, at least one of the at least two conference devices is an extension unit adapted to connect various devices, such as attendee units and / or interpreter units.
    In a preferred embodiment, the multiplexing means are arranged to combine data from the at least two data classes into a first and a second stream, said first stream comprising audio data and the second stream having a higher bandwidth than the first stream. Each of the at least two ports is preferably equipped with storage means for storing the first and the second stream. The multiplexing means are advantageously arranged to combine the first and second streams stored in the storage means. As such, uniquely assigned units (e.g., equipped with network ports with a lower bandwidth) can be connected to the specific port that processes the stream with lower bandwidth (cheaper equipment).
    In a preferred embodiment, the first stream further comprises control data for managing the digital conference system.
    Advantageously, the central unit comprises a control unit which is arranged to control and manage the bandwidth of the first and second data stream. In one embodiment, the control unit is arranged to assign a guaranteed QoS level to the first and second stream.
    In a preferred embodiment, at least a first conference device of the at least two conference devices is connected to a plurality of further conference devices.
    In another preferred embodiment, the multiplexing means of at least one of the at least two conference devices are arranged to perform rate control on incoming data traffic and on internal data traffic in the at least one conference device.
    In another preferred embodiment of the invention, the digital conference system comprising a plurality of conference devices is provided with a central unit adapted to be connected to at least two conference devices of that plurality in a point-to-multi-point topology and for data traffic to send and receive that multiplexed packets of data from at least two classes in each direction. One of the data classes is intended for audio data. The central unit comprises: - first multiplexing means for combining data from the at least two data classes in a first and a second stream, said first stream comprising audio data and said second stream having a higher bandwidth than the first stream, - a multiple number of ports to connect the at least two conference devices, each of the ports being equipped with storage means for storing the first and second streams and transmitting means for forwarding at least the first stream, each of the ports being further adapted to accommodate a detect an indication of the bandwidth of the link via which one of the at least two conference devices is connected to the central unit, and with second multiplexing means to combine the first and second streams stored in the storage means, and - a control unit that is arranged to control and manage the bandwidth of the first and second data stream.
    In a preferred embodiment, at least the first multiplexing means of the central unit are adapted to assign downlink priority levels to the at least two data classes before transmitting.
    In another embodiment, an upper limit is set in the central unit for the bandwidth of the second stream. The first stream preferably has a bandwidth of 100 Mbps and the second stream has a bandwidth of 1 Gbps.
    In order to summarize the invention and the realized advantages over the prior art, certain objects and advantages of the invention have been described above. It goes without saying that all such objectives or advantages are not necessarily achieved according to one specific embodiment of the invention. Thus, for example, persons skilled in the art will recognize that the invention may be embodied or embodied in a manner that achieves or optimizes one advantage or group of benefits as described herein, without necessarily realizing other goals or benefits described or suggested herein. .
    The above and other aspects of the invention will become clear and further explained with reference to the embodiment (s) described below.
    Brief description of the drawings The invention will now be further described, by way of example, with reference to the accompanying drawings, in which like reference numerals refer to like elements in the various figures.
    Fig. 1 illustrates a general diagram of a digital conference system and its main components.
    Fig. 2 illustrates downstream routes of the data on the conference network and the way in which they are combined / multiplexed / demultiplexed.
    Fig. 3 illustrates upstream routes of the data on the conference network and the way in which they are combined / multiplexed / demultiplexed.
    Fig. 4 illustrates data classes that typically occur on a conference network.
    Detailed Description of Illustrative Embodiments The present invention will be described with reference to specific embodiments and with reference to certain drawings, but the invention is not limited thereto, but is only limited by the claims.
    Moreover, the terms first, second and so forth are used in the description and in the claims to distinguish between similar elements and not necessarily for describing a sequence, either in time, in space, in terms of importance or in any other way. It is to be understood that the terms used are interchangeable under proper conditions and that the embodiments of the invention described herein are capable of operating in sequences other than those described or illustrated herein.
    It is to be noted that the term "comprising" as used in the claims should not be interpreted as being limited to the means specified thereafter; it does not exclude other elements or steps. It must therefore be interpreted as a specification of the presence of the listed features, units, steps or components referred to, but it does not exclude the presence or addition of one or more other features, units, steps or components or groups thereof. Therefore, the scope of the expression "a device comprising means A and B" should not be limited to devices consisting only of parts A and B. It means that with regard to the present invention, the only relevant parts of the device A and B to be.
    References in this specification to "one embodiment" or "an embodiment" mean that a particular feature, structure, or feature described in connection with the embodiment is included in at least one embodiment of the present invention. Statements of the phrase "in one embodiment" or "in an embodiment" at different places in this specification do not necessarily all refer to the same embodiment, but it is possible. Furthermore, the specific features, structures or characteristics may be combined in any suitable manner in one or more embodiments, as will be apparent to those skilled in the art from this disclosure.
    In a similar manner, it should be noted that in the description of exemplary embodiments of the invention, various features of the invention are sometimes grouped into a single embodiment, figure, or description thereof to streamline the disclosure and understanding of one or more of the facilitate various inventive aspects. However, this method of disclosure should not be interpreted as an expression of an intention that the claimed invention requires more features than expressly stated in each claim. As shown in the following claims, the inventive aspects lie in less than all the features of a single preceding disclosed embodiment. Therefore, the claims that follow the detailed description are hereby explicitly included in this detailed description, wherein each claim stands on its own as a separate embodiment of the present invention.
    In addition, since some embodiments described herein include some, but not other, features included in other embodiments, combinations of features of different embodiments are intended to fall within the scope of the invention and form different embodiments, such as will be understood by someone skilled in this field. For example, in the following claims, any of the claimed embodiments can be used in any combination.
    It should be noted that the use of particular terminology in describing certain aspects of the invention does not imply that the terminology herein is redefined to be limited to any specific features of the features or aspects of the invention with which that terminology is associated.
    In the description given here, numerous specific details are set forth. However, it is understood that embodiments of the invention can be worked out without these specific details. In other cases, well-known methods, structures and techniques were not shown in detail in order not to obstruct the understanding of this description.
    In the description below, the downstream link is defined as the direction from the central unit to the participant units, interpreter units, etc., while the upstream traffic goes in the opposite direction.
    The present invention proposes a digital conference system comprising a number of new features. First, both downstream and upstream traffic is organized into data classes that are given a separate priority level for downstream and upstream from priority multiplexers in the different parts of the conference system. The priority multiplexers in the components of the conference system then combine data from the different data classes, taking into account the assigned priority levels. In this way the combination of data streams of different classes (such as control, data, audio, video, interactivity) in the high-performing conference system is obtained in a fully scalable manner. In contrast to the current state-of-the-art solutions, in a digital conference system according to the invention, all of these multimedia streams can be combined in a fully integrated manner, i.e. different user experiences can be combined in one network with the required performance level. Secondly, the central unit (CU) is able to centrally manage the bandwidth used in the conference network. In this context, application-specific QoS requirements (such as latency, responsiveness, etc.) are taken into account. More details about these functions are given below.
    In the downstream direction (the CU is the source) (Fig. 1), the conference network has a point-to-multiple point structure (P2MP). Downstream forwarding of data is fairly easy. All packages sent by the CU are received by all conference devices according to their capabilities. The central unit is the only point where the bandwidth can and must be controlled. The total bandwidth typically has an upper limit (as determined by the physical limitations of the network, e.g., below 1 Gbps). Another example in which controlling bandwidth receives special attention is the presence of price-sensitive audio devices. To limit the cost of network ports (e.g., limited to 100 Mbps ports), the CU can be controlled so that the combined bandwidth of audio and control data does not exceed this predetermined amount. Different routes for downstream traffic are shown schematically in Figure 2. Different "daisy chain" topologies are allowed (including loops and nested loops, eg to provide redundancy when certain network components fail). A "minimal stress tree" algorithm is implemented to ensure optimum data transfer load in the network.
    In the central unit, all available data classes to be sent downstream are combined in specific streams by means of priority multiplexers. As an example, the first stream contains the classes required for operating audio-only devices: audio and control packages. The bandwidth of this first stream should be limited to a speed that depends on the audio device. A typical value is, for example, 100 Mbps. The second stream contains all the multimedia-related traffic: video and IP packages. This second stream fills the bandwidth that has not yet been assigned to the audio stream up to the maximum available bandwidth (e.g. 1 Gbps).
    The two streams are then copied in a separate queue per exit port. This is necessary to accommodate all "dual rate" output ports in the central unit (and, optionally, one or more extension units). When the transmitter detects a 100 Mbps link, only data from the audio queue is sent. Otherwise, when the output port is connected to a 1 Gbps compatible device, both streams are combined with a priority multiplexer before they are sent. The downstream ports of an extension unit work in the same way as the output ports in the central unit. Only in the extension units is a multiplexer added before the output part to separate the data classes with audio only from the other classes.
    The 2-port upstream portion of the extension unit behaves exactly like a normal 2-port device (e.g., subscriber units, interpreter units, ...). One of the two ports is always selected as the input port by the spanning tree algorithm, the other is than the output port. Data received from the input port is copied twice: once to internal device software and once directly to the output port to be forwarded to other devices further downstream in the daisy chain, therefore, each downstream device receives an exact copy of the power created in the central unit, with the restriction that devices with limited data rate capabilities (e.g., 100 Mbps) only have audio and receive control packages.
    In the upstream direction, where the central unit is the destination, the conference network has a multi-point-to-point topology (MP2P). Consequently, devices on each node in the conference network must merge their own upstream traffic with the upstream data of devices further downstream in the daisy chain. It should also be appreciated that within the network, typically only the bandwidth of the audio and video information is known, because it is the central unit that gives access to the sources to send their data. On the other hand, devices can send control packets and generate IP traffic at any time since this traffic is generated by the user and user interaction is asynchronous. This makes sending upstream data more complex and challenging than the downstream connection described earlier. The different routes and manipulations of the upstream traffic are shown schematically in Fig.3.
    The internal network streaming data bus in the central unit (CU) has a flow rate adapted to accommodate the maximum upstream traffic of the different conference network points that can therefore simply be multiplexed with a standard "Round Robin" multiplexer. Afterwards, the packages are filtered based on their data classes (port number conference network).
    In the upstream direction, the different units (extension units, participant units, ...) have a complex logic to handle combining and forwarding the upstream data.
    Before the internal traffic is merged (coming from the downstream ports in the case of an extension unit, generated by device logic in a pure 2 port device) with the upstream data stream coming from further downstream in the daisy chain to the central unit, the information must be broken down into the multiple data class components. This is necessary to prevent low priority classes in one stream from being given a higher priority than high priority classes from a stream added during multiplexing. The streams are therefore first multiplexed per data class. Only afterwards are the various merged data classes multiplexed to the desired output current according to their relative priority.
    As an example of the use of rate control, one additional measure is added in multiplexing "Application IP" and "External LAN" packets to increase the fair availability of bandwidth across all nodes in a branch. If a normal "Round Robin" multiplexer were to be used, each node would occupy half the available bandwidth at the expense of the traffic that is further downstream generated, meaning that the node closest to the CU would receive preferential treatment gets. Therefore, the multiplexers processing the "Application IP" and "LAN" packets include a speed control mechanism that limits the bandwidth of internal traffic to 1/10 (2-port devices) or 1/4 (extension units) of the total available bandwidth for that specific class. If the other part of the bandwidth were not fully used, the speed-controlled multiplexer can temporarily ignore the bandwidth limitation and completely fill the remaining bandwidth.
    Also in the downstream portion of an extension unit, the received data is immediately split according to the different classes. Subsequently, the data packages from downstream ports are merged per data class with a standard "Round Robin" multiplexer, providing a fair bandwidth distribution across all ports. Finally, these merged data classes are further mixed with the upstream data stream in the input section as described above.
    In Fig. 3, the combining and forwarding of upstream data is illustrated for Gbps-compatible devices. For audio-only devices that only support a much more limited data rate (eg 100 Mbps), the same approach can be used, except that the streams are split into only two data classes ("Audio" and "Control") since the other three are not present are in a link with limited bandwidth.
    A schematic overview of different data classes that are typically sent via the conference network is shown in Fig. 4. Note that this image is not intended to contain detailed routing information of the different streams, but only shows the communication paths between the different parts of the system. It goes without saying that more complicated schemes can be introduced. 1. Control This stream contains the information needed to control and manage the conference system. This includes packages related to initialization, configuration, update, microphone management, redundancy, device status. This information flow has guaranteed QoS in the downstream direction (away from the central unit), thanks to a priority scheme and bandwidth control on the central unit side. In the upstream direction (to the central unit) the quality level is "best effort". 2. Audio This stream contains the audio channels embedded in conference data packets. This stream always has a guaranteed QoS, thanks to the bandwidth control and a priority schedule. There is one exceptional package that is also considered a member of the audio class: the "Negative Confirmation" for control packages. The reason is that these packages must also be given the highest priority in the upstream direction. 3. Video This stream contains all video channels embedded in data packets. Equivalent to the audio link, this stream always has a guaranteed QoS, thanks to the bandwidth control and a priority schedule.
    4. Application IP
    The fourth data exchange path contains all data relating to the interactive functions on the touch screens in the case of a multimedia participant unit. This stream has a quality level "best effort", since only the bandwidth that is not occupied by the first three classes is filled with this type of packages.
    5. External LAN
    Another class of data that can be sent via the conference network is the "External LAN" traffic. This includes both traffic from / to external devices (eg participants' laptops) and information exchange between interactive participants and external sources (eg browsing the web). This stream has a quality level of "best effort" and has the lowest priority. Bandwidth that is not used for one of the above data types can be filled with external LAN packets.
    The table below lists the priority levels for the different data classes in the conference network. Level 1 corresponds to the highest priority
    Priority Level_Downstream_Upstream_
    The relative position of the control class differs for the downstream (from the central unit) and upstream (to the central unit) direction. Downstream control packages have the highest priority to minimize their latency and to increase the responsiveness of the system to control commands (initialization, update, ...). Since audio and video packages also require guaranteed QoS, the speed of the control packages must be limited on the side of the central unit.
    In the upstream direction, the situation is different because the aggregated temporary bandwidth can no longer be controlled from a central point due to the asynchronous nature of the packets in combination with a multi-point-to-point topology of the network. To avoid possible effects on the QoS of Audio and Video in the upstream direction, the control packages have a priority level 3. There is one exception: the "Hello neighbor" packages that are used to build the spanning tree. These packages always have the highest priority (level 0). The bandwidth occupied by these frames is very limited and they are not forwarded to the central unit, which means that the bandwidth is never aggregated.
    Although the invention has been illustrated and described in detail in the drawings and foregoing description, such illustrations and descriptions are to be considered as illustrative or exemplary and not restrictive. The foregoing description explains certain embodiments of the invention in detail. It should be noted, however, that no matter how detailed the foregoing is contained in the text, the invention can be made in many ways. The invention is not limited to the disclosed embodiments.
    Other variations on the disclosed embodiments may be understood and performed by persons skilled in the art and by practicing the claimed invention, through a study of the drawings, the disclosure, and the appended claims. In the claims, the word "comprising" does not exclude other elements or steps and the indefinite article "a" does not exclude a plural. A single processor or other unit can perform the functions of different items in the claims. The mere fact that certain measures are listed in mutually different dependent claims does not mean that a combination of those measures cannot be used to benefit. A computer program can be stored / distributed on a suitable medium, such as an optical storage medium or semiconductor medium supplied with or as part of other hardware, but can also be distributed in other forms, such as via the internet or other wired or wireless telecommunication systems. Any references in the claims should not be construed as limiting the scope.
    权利要求:
    Claims (13)
    [1]
    Conclusions
    A digital conference system comprising a central unit (CU) and at least two conference devices, said central unit being connected to said at least two conference devices in a point-to-multiple point topology, said digital conference system being arranged for bidirectional data traffic between said central unit and said at least two conference devices, wherein said data traffic comprises multiplexed packets of data from at least two data classes in each direction, one of said data classes being for audio data and wherein said data traffic from said central unit to said at least two conference devices is split from data traffic from said at least two conference devices to said central unit, said central unit and said at least two conference devices comprising multiplexing means adapted to combine data from said at least two data classes characterized in that said multiplexing means are arranged to assign a downlink priority level to said at least two data classes when they are sent to said at least two conference devices, and an uplink priority level when they are sent to said central unit sent.
    [2]
    The digital conference system of claim 1, wherein at least said central unit comprises at least two ports for receiving and transmitting said data traffic and processing means adapted to detect the speed of said data traffic at said ports.
    [3]
    The digital conference system of claim 2, wherein said processing means is arranged to detect whether said data traffic is moving in the uplink or downlink direction.
    [4]
    The digital conference system of claim 1, wherein at least one of said at least two conference devices is an extension unit that is arranged to connect a plurality of participant units and / or interpreter units.
    [5]
    The digital conference system of any one of the preceding claims, wherein said multiplexing means are arranged to combine data from said at least two data classes into a first and a second stream, wherein said first stream comprises audio data and said second stream has a higher bandwidth than said first stream.
    [6]
    The digital conference system of claim 5, wherein each of said at least two ports is equipped with storage means for storing said first and said second stream.
    [7]
    The digital conference system of claim 6, wherein said multiplexing means are arranged to combine and / or spread said first and second stream stored in said storage means.
    [8]
    The digital conference system of any one of claims 5 to 7, wherein said first stream further comprises control data to control said digital conference system.
    [9]
    The digital conference system of any one of claims 5 to 8, wherein said central unit comprises a control unit adapted to control and manage the bandwidth of said first and second data stream.
    [10]
    The digital conference system of claim 9, wherein said control unit is arranged to allocate a reserved amount of bandwidth to at least one of said data classes.
    [11]
    A digital conference system according to any one of the preceding claims, wherein at least one first conference device of said at least two conference devices is connected to a plurality of further conference devices.
    [12]
    The digital conference system of any one of the preceding claims, wherein said multiplexing means of at least one of said at least two conference devices is arranged to perform rate control on incoming data traffic and on internal data traffic in said at least one conference device.
    [13]
    A digital conference system according to any one of the preceding claims, wherein said central unit is adapted to be connected to at least two conference devices in a point-to-multiple point topology and to transmit and receive data traffic containing multiplexed packets of data from at least two data classes, one of said data classes being for audio data, said central unit comprising: - first multiplexing means for combining data from said at least two data classes in a first and a second stream, said first stream comprising audio data and said second stream having a higher bandwidth then has said first stream, - a plurality of ports to connect said at least two conference devices, each of said ports being equipped with storage means for storing said first and said second stream and transmitting means for transmitting at least said first stream send, where each of said ports is further adapted to detect an indication of the bandwidth of a link through which one of said at least two conference devices is connected to said central unit, and with second multiplexing means to combine said first and second stream stored in said storage means, and - a control unit adapted to control and manage the bandwidth of said first and second data stream.
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    同族专利:
    公开号 | 公开日
    EP2924984A1|2015-09-30|
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    EP14162020.3A|EP2924984A1|2014-03-27|2014-03-27|Digital conference system|
    EP14162020.3|2014-03-27|
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