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Description  |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
The present communications system relates in general to multimedia (audio, video, and/or data) conferencing techniques, and in particular to a multimedia bridging system which utilizes an improved multipoint control unit to provide a variety of
features in a manner that constitutes a considerable improvement over the current art.
2. Description of the Prior Art
In the field of multimedia communications, a "bridge" or "multipoint control unit" (MCU) is a computer-controlled device which includes a multiplicity of communication ports which may be selectively interconnected in a variety of ways to provide
communication among a group of endpoint devices. MCUs are often used to establish multi-party conference calls. The state-of-the-art MCU is described in ITU Document H.243, "Procedures for Establishing Communication Between Three or More Audiovisual
Terminals Using Digital Channels up to 2 Mbps," March 1993, and in ITU Document H.231, "Multipoint Control Units for Audiovisual Systems Using Digital Channels up to 2 Mbps," March 1993.
Generally speaking, such systems require conferences to be prearranged in advance. A series of steps must be performed in order to provide the system topology necessary to implement a multimedia conference call. Typically, the user calls a
reservation agent who then directs the MCU to either prepare itself to receive calls at a given time, or to dial out to the user at a given time. These setup procedures are inconvenient, tedious, and inflexible. A clear need exists to provide for
"spontaneous" or "on-demand" conferencing where the user does not need to invoke a reservation system to set up a multimedia conference.
Bellcore Generic Requirements GR-1337-CORE, Issue 1, September 1993 contains a description of a "spontaneous" conferencing system based on user control from a touch-tone (DTMF) keypad, i.e., with strings of numbers and letters, and audio feedback
from stored announcements. This method is widely used in the audio bridging industry for voice calls, and in the Bellcore GR-1337-CORE proposal, the same method is applied to multimedia calls (voice/video).
The method of spontaneous conferencing widely used for audio-only calls, and applied to multimedia calls in GR-1337-CORE, suffers from the following difficulties that represent areas of possible improvement:
1. The strings of numbers require a long period of time to enter. 2. The codes required to perform operations are numerous and difficult to remember. 3. Feedback is limited to audio messages, and the length of these messages is frequently
such that the process of conference setup is very slow. 4. The user must make an initial decision to contact the MCU for the purpose of establishing a conference. 5. The MCU contacted via the method of GR-1337-CORE may have no available resources
with which to implement a multimedia conference. 6. The user is highly aware of the "seams" (i.e., procedural discontinuities) in the process of constructing the conference. 7. The person initiating the addition of a new party to the conference may
wish to have a private conversation with the new party prior to allowing this party into the conference. The purpose of this conference might be to confirm the identity of this new party while allowing the conference to continue. However, existing
systems are not equipped to provide such a private conferencing mode. 8. The person initiating the conference might wish to select the conference mode of operation which, for example, determines the selection criteria to be applied in determining the
party or parties which will be broadcast to other conference participants at any given moment in time. Typical conference modes include chair mode voice-activated mode, and various other modes known to those skilled in the art. It would be desirable to
change this mode during the conference upon command, although such changes are difficult or impossible to implement with state-of-the-art systems.
U.S. Pat. No. 4,653,090, which is owned by the current applicant, describes a system of graphics-based call management which establishes a voice and/or data conference using a graphical user interface. U.S. Pat. No. 4,953,159 (also owned by
the current applicant) describes an audio graphics conferencing arrangement controlled by a graphical user interface. In both of the aforementioned patents, graphics-based call management is limited to voice and data calls, and is not applied to video
calls.
SUMMARY OF THE INVENTION
Techniques are disclosed for controlling the communication of multimedia electronic signals representing audio, video, and/or data. These techniques operate in conjunction with a system including a network and a plurality of endpoint devices
connected to the network. The network is comprised of communications links and switches adapted for selectively connecting and disconnecting the communications links. The endpoint devices are adapted for convening multimedia electronic signals into
audio, video, and/or data. A novel multimedia server (MMS) is coupled to the network and is equipped to utilize the network, such that multimedia signals may be exchanged among a plurality of endpoint devices, thereby providing a procedurally continuous
multimedia conference.
Use of the MMS described herein eliminates the need for reservation systems which are utilized by existing multimedia conferencing systems. The conference is initiated by a multimedia endpoint that is equipped with a user interface device for
encoding user input as BAS signals. For example, the user interface device may include a keypad, in which case key presses are encoded as BAS signals. The characteristics of BAS signals are described in ITU-T H.221/H.230, and are referred to as "BAS
DTMF." The term "BAS DTMF" is defined hereinafter in the Detailed Description. The MMS includes an MMS data transceiver for decoding BAS signals. In this manner, the MMS is adapted to communicate with a plurality of endpoint devices over an existing
network by utilizing a BAS DTMF-based multimedia communications control protocol.
The BAS DTMF capabilities of the multimedia protocol are extended to provide additional controls from endpoint devices to the MMS, such as the selection of a specific conference mode and the addition of endpoint devices, and the private screening
of incoming communications from other endpoint devices. Feedback from the MMS is provided to endpoint devices in the form of audio and/or video messages or tones. Controls from the endpoint device to the MMS include commands to re-establish
communications with a selected endpoint device, drop communications with a selected endpoint device, and establish communications with a selected endpoint device. The selected endpoint device is selected by the endpoint device user in conjunction with
the user interface device. Feedback from the MMS to the endpoint device include indications specifying the current status of a requested control issued by an endpoint device. If a telephone network is utilized to carry communications to and from
endpoint devices, these indications specify whether or not a given telephone number is ringing, busy, answered, connected; or that there are insufficient resources in the MMS or the network to complete the requested action.
BRIEF DESCRIPTION OF
THE DRAWINGS
FIG. 1 is a hardware block diagram showing a prior-art multimedia conferencing system which utilizes a reservation system for bridging multimedia signals;
FIG. 2 is a block diagram setting forth the system architecture of a multimedia conferencing system which includes an MMS, a plurality of endpoint devices, and a communications network;
FIG. 3 sets forth the data structures utilized by the multimedia conferencing system of FIG. 2;
FIG. 4 is a hardware block diagram setting forth system configuration for a preferred embodiment disclosed herein;
FIG. 5 is a hardware block diagram setting forth the system topology of network 108 in the context of multimedia signals;
FIG. 6 is a hardware block diagram of a multimedia signal routing device for use in the MMS of FIG. 2 wherein each of the individual media (i.e., video, audio, data) is carried over a separate communications link from the MMS to an endpoint
device;
FIG. 7 is a hardware block diagram of a multimedia signal routing device for use in the MMS of FIG. 2 that supports multimedia protocols where, for each endpoint device, all media (i.e., video, audio, data) are multiplexed onto a single
communications link in the form of a connection between the endpoint and the MMS; and
FIGS. 8A, 8B and 9 are flowcharts setting forth procedures whereby an MMS implements a multimedia conference call.
DETAILED DESCRIPTION
MMS Reservation System
With reference to FIG. 1, a prior-art MMS reservation system 700 is shown. MMS 700 is a device that communicates over a communications network, such as network A 709, to MMS 713 and to endpoint device 715. The reservation system 700 includes
one or more network interfaces, such as network interface for network A 707, and network interface for network C 705. In addition to providing a communications protocol interface between network A 709 and reservation system 700, the network interface
for network A 707 is responsive to endpoint device 715 requests for MMS 102 resources. Reservation system 700 also includes a microprocessor and memory 703 which issues requests for required information to the endpoint devices, confirms the availability
of MMS 102 resources by checking against a database of previous MMS reservations, and responds to endpoint device 715 with access codes and network identifiers as needed stored in a data storage device 701.
Note that MMS 713 may be coupled to a plurality of networks, including network A 709 and network B 711. These networks may or may not be the same network. Endpoint device 715 may be equipped to communicate over a plurality of networks via a
network interface for network A 717, and a network interface for network B 719. Bellcore GR-1337-CORE describes an illustrative example of a reservation system 700. Examples of such systems include the AT&T CRS (Conference Reservation System), and
CONVENE.
FIG. 2 is a block diagram setting forth the system architecture of a multimedia conferencing system 100 which includes an MMS 102, a plurality of endpoint devices 104, 106, and a network 108. Network 108 includes a plurality of switches 110,
112, 116 connected to a plurality of communications links 118, 120, 122, so as to provide selective interconnection of the communications links. Switches 110, 112, 114 are controlled by a network processor 116 coupled to network memory 124.
Communications links 118, 120, 122 may be any known device or devices capable of transporting multimedia electronic signals from one location to another. Multimedia electronic signals are signals which represent data, video, and/or audio information.
Examples of communications links 118, 120, 122 include conventional telephonic links, ISDN links, Ethernet connections, Asynchronous Transfer Mode (ATM) links, or the like. Network memory 124 may be any combination of read-only memory (ROM) and
random-access memory (RAM). Suitable devices for use as network memory 124 are known to those skilled in the art. Network processor 116 may be a microprocessor of a type known to those skilled in the art. Switches 110, 112, and 114 are adapted for use
in conjunction with the specific type or types of communications links 118, 120, 122 employed in the multimedia conferencing system 100. The selection of suitable devices for switches 110, 112, and 114 is a matter well-known to those skilled in the art.
Multimedia server (MMS) 102 provides for the communication of multimedia information among a plurality of endpoint devices 104, 106. The MMS 102 is connected to a plurality of endpoint devices 104, 106 via network 108 over communications link
122. The MMS 102 includes an MMS processor 126 connected to an MMS memory 128. MMS processor 126 controls the operation of an MMS data transceiver 130, an MMS communications link establishment device 132, and a multimedia signal routing device 129.
Communications link establishment device 132 may be a conventional call-establishment device of a type well-known to those skilled in the art. MMS data transceiver 130 may be a conventional digital or analog modem, and MMS processor 126 may be a
conventional microprocessor device. Communications link 122 could be a plurality of standard wire-pair telephonic links, and MMS memory 128 could be a combination of conventional ROM and RAM. Multimedia signal routing device 129 provides for the
selective routing of video, audio, and/or data to and from a plurality of endpoint devices via network 108. The structure and operation of multimedia signal routing device 129 will be described in greater detail hereinafter with reference to FIGS. 6 and
7.
MMS 102 may operate in such a manner that electronic signals representing each medium (i.e., video, audio, and data) are separated into their own virtual circuit comprising a media stream, such that a first media stream carries electronic signals
representing video information, a second media stream carries electronic signals representing audio information, and a third media stream carries electronic signals representing data (i.e., FIG. 6, to be described hereinafter). Alternatively, MMS 102
may operate by multiplexing all media streams together into a single media stream (i.e., FIG. 7, to be described hereinafter). It is also possible to combine the two aforementioned media stream approaches, for example, by providing a data/control media
stream separate from an audio/video media stream wherein video and audio signals are multiplexed together on a first media stream and data and control signals are multiplexed together on a second media stream. The term "enhanced MMS" is applicable to
any MMS constructed in accordance with the principles of the invention disclosed herein.
MMS 102 may be implemented using an MCU. An MCU (multipoint control unit) may be defined as a device which supports the bridging of ITU-T multimedia protocols according to ITU-T H.231/H.243. An MCU is considered to be a specific category of
MMS.
A multimedia protocol is any protocol which allows the multiplexing of audio, video, and data together into a single stream adapted for transmission over a communications link. A multimedia protocol may alternatively separate video, audio, and
data into three or more streams, where respective streams are accompanied by corresponding control messages. For some protocols, digital encoding techniques are used, while for others analog techniques such as FDM are used. Typically, one or more
codings are specified for audio, video, and/or data. The ITU-T H.320 protocol is an example of a standard multimedia protocol. Intel PCS (Personal Conferencing System) is another example, this time of a non-standard protocol. The procedures of this
invention apply without regard to the specific multimedia protocol being used.
First endpoint device 104 and second endpoint device 106 are coupled to MMS 102 via network 108. These endpoint devices 104, 106 include one or more user interface devices 105, 107, 109, 111. Each user interface device 105, 107, 109, 111
includes either an input means, an output means, or an input means combined with an output means. Output means are adapted to convert multimedia electronic signals representing audio, video, and/or data into actual audio, video, and/or data. Input
means are adapted to accept audio, video, and/or data inputs, and to convert these inputs into electronic signals representing audio, video, and/or data. Examples of user interface devices 105, 107, 109, 111 include video displays, keyboards,
microphones, speakers, video cameras, DTMF keypads, or keypads that generate either DTMF signals or "BAS DTMF," or the like.
Endpoint devices 104, 106 are adapted to communicate using any of a number of existing multimedia communication protocols known to those skilled in the art. The endpoint device multimedia communication protocol controls the presentation of media
streams (electronic signals representing audio, video, and/or data information) to the endpoint device user. Endpoint devices 104, 106 may function bidirectionally, both sending and receiving multimedia information, or, alternatively, endpoint devices
may function unidirectionally, receiving but not sending multimedia information, or sending but not receiving multimedia information. Similarly, in a given multimedia system, some endpoint devices may be equipped to operate bidirectionally whereas other
endpoint devices may be equipped to operate unidirectionally.
An example of a suitable endpoint device is an ITU-T H.320 audiovisual terminal, but any device capable of terminating a digital multimedia stream and presenting it to the user constitutes an endpoint device for the purposes of this patent. A
particular product example of an H.320 endpoint is the AT&T GIS Vistium. If the endpoint device is a "plain old telephone set" rather than a computer controlled general-purpose device, it cannot by its very nature participate fully in a multimedia
conference. However, such an endpoint device could be used to generate electronic signals representing control information, i.e., a control stream, to an MMS via the use of DTMF signals. However, any conference setup and control using such a technology
cannot, by its nature, be "seamless". However, many of the features described in this patent could be controlled from such a device. Using DTMF device 166, codes could be sent to an enhanced MMS for various purposes, after joining a conference with
104, 106, and 102, including:
(1) add a party to an ongoing multimedia conference (e.g., *A9496000#),
(2) add a party privately to an ongoing multimedia conference (e.g., *P9496001#),
(3) change conference mode (e.g., from voice activated switching to broadcast with *MB),
(4) drop parties using ITU-T H.243 terminal id number (e.g., *D15-drop endpoint 15),
(5) silence parties using ITU-T H.243 terminal id number (e.g., *S13-mute endpoint 13), and
(6) make a party the broadcaster using ITU-T H.243 terminal id number (e.g., *H5-make endpoint 5 the broadcaster). Others are possible.
Endpoint devices 104, 106 may utilize various existing signalling techniques and multimedia communication protocols for the purpose of communicating with other system components, such as other endpoint devices 104, 106, MMS 102 and/or network
108. Examples of such signalling techniques and multimedia communication protocols include BAS (AIM, AIA), MBE, NS-com, or the like. Definitions for these protocols and signalling schemes are as follows.
AIA
This is a Bit Rate Allocation Signal (BAS) code that is sent by an endpoint device conforming to the ITU-T H.243 MCU or the ITU-T H.320-standard for the purpose of indicating that audio is active as opposed to muted. This BAS code is defined in
ITU-T recommendation H.230.
AIM
This is a Bit Rate Allocation Signal (BAS) code that is sent by an endpoint device conforming to the ITU-T H.243 MCU or the ITU-T H.320-standard for the purpose of indicating that audio is muted. This BAS code is defined in ITU-T recommendation
H.230.
BAS code
BAS (Bit Rate Allocation Signals) codes are control messages defined in the ITU-T H.221 recommendation and additionally defined in ITU-T H.230. Such codes are used to control the multimedia multiplex allocation for an ITU-T H.320-conformant
endpoint, and to indicate status, such as whether the audio is muted(see AIM/AIA).
BAS DTMF
In the ITU-T H.230 standard, a method is described for encoding numbers into "BAS" (Bit rate Allocation Signals). This method may be used to encode touch-tone key-presses instead of the existing DTMF method of sending sinusoidal tones through a
conventional voice channel. Since DTMF in the voice channel is disruptive to the conference and is not very reliable, the "BAS DTMF" is the preferred method of simulating DTMF features on ITU-T H.320 equipment, such as ITU-T H.320-compatible endpoint
device and/or MMS. This general approach could be used (although different in detail) with any multimedia protocol.
The term "mode" may be applied in the context of multiplexing multimedia signals on a communications link. In this context, "mode" refers to the combination of coding techniques used to encode/decode the media information and, if the coding
technique is a frame-based one, the particular bit rate allocations being used. For example, in ITU-T H.320, a typical mode might include ITU-T G.711 audio, ITU-T H.261 video, and ITU-T 6.4 kbs low-speed data as described in ITU-T H.221.
Returning now to FIG. 2, the illustrative hardware embodiments set forth for the first and second endpoint devices 104, 106, respectively, will be described further. Communications links 118, 120 may be conventional telephonic communications
lines, such as wire pairs, fiber optic cable, ISDN lines, or the like.
The multimedia conferencing techniques disclosed herein provide for controlling the communication of multimedia electronic signals representing audio, video, and/or data. These techniques are operable in conjunction with the system shown in FIG.
2 and including network 108, multimedia server (MMS) 102 connected to network 108, and the plurality of endpoint devices 104, 106 connected to network 108. The network 108 is comprised of communications links 118, 120, 122 and switches 110, 112, 114
adapted for connecting and disconnecting the communications links 118, 120, 122. The endpoint devices 104, 106 are adapted for convening multimedia electronic signals into audio, video, and/or data. MMS 102 is equipped to control network 108 such that
multimedia signals may be exchanged among a plurality of endpoint devices 104, 106, thereby providing a multimedia conference.
To summarize the techniques discussed in conjunction with FIG. 2, at least one of the endpoint devices 104 includes an endpoint communications link establishment device 136, an endpoint data transceiver 140, an endpoint processor 144, endpoint
memory 148, and one or more user interface devices 105, 107. The MMS 102 includes an MMS communications link establishment device 132, an MMS data transceiver 130, an MMS processor 126, an MMS memory 128, and a multimedia signal routing device 129.
Several novel methods are disclosed for implementing a multimedia conference. The network 108 assigns the MMS 102 a network address uniquely specifying a particular MMS 102. Techniques are disclosed for controlling the communication of
multimedia electronic signals representing audio, video, and/or data. These techniques operate in conjunction with a system including a network and a plurality of endpoint devices connected to the network. The network is comprised of communications
links and switches adapted for selectively connecting and disconnecting the communications links. The endpoint devices are adapted for convening multimedia electronic signals into audio, video, and/or data. A novel multimedia server (MMS) is coupled to
the network and is equipped to utilize the network, such that multimedia signals may be exchanged among a plurality of endpoint devices, thereby providing a procedurally continuous multimedia conference.
Use of the MMS described herein eliminates the need for reservation systems which are utilized by existing multimedia conferencing systems. The conference is initiated by a multimedia endpoint that is equipped with a user interface device for
encoding user input as BAS signals. The characteristics of BAS signals are described in ITU-T H.221/H.230, and are referred to as "BAS DTMF." The MMS includes an MMS data transceiver for decoding BAS signals. In this manner, the MMS is adapted to
communicate with a plurality of non-enhanced endpoint devices over an existing network by utilizing a BAS DTMF multimedia communications protocol.
The BAS DTMF capabilities of the multimedia protocol are extended to provide additional controls from endpoint devices to the MMS, such as the selection of a specific conference mode and the private screening of incoming communications from other
endpoint devices. Feedback from the MMS is provided to endpoint devices in the form of audio and/or video messages or audio tones. Controls from the endpoint device to the MMS include commands to re-establish communications with a selected endpoint
device, drop communications with a selected endpoint device, and establish communications with a selected endpoint device. The selected endpoint device is chosen by the endpoint device user in conjunction with the user interface device. Feedback from
the MMS to the endpoint device include indications specifying the current status of a requested control issued by an endpoint device. If a telephone network is utilized to carry communications to and from endpoint devices, these indications specify
whether or not a given telephone number is ringing, busy, answered, connected; or that there are insufficient resources in the MMS or the network to complete the requested action. Similar indications could be provided for other networks, such as
Ethernet.
In accordance with a preferred embodiment disclosed herein, the MMS 102 is enhanced as follows: The MMS is equipped with a data transceiver 130 for receiving requests for the creation of "progressive" or "spontaneous" conferences. The MMS 102
also includes an MMS communications link establishment device 132, for example, in the form of dial-out means for dialing out onto a telephone line when such an operation is requested by an endpoint device 104, 106 in the conference for the purpose of
incorporating an additional endpoint device or devices 104, 106 into the conference. The MMS 102 includes private communications link means in the multimedia signal routing device 129 for providing a private conference between the endpoint device 104
initiating the dial-out and the endpoint device 165 to be incorporated into the conference, while continuing to maintain the original conference with 106. This original conference takes place between endpoint device 106 and one or more additional
endpoint devices, if present. The MMS data transceiver 130 also includes means for receiving and acting on requests received from the initiating endpoint device 104 for a particular conference mode.
FIG. 3 sets forth the data structures utilized by network 108, and MMS 102 of FIG. 2. Network memory 124 is organized to include one or more network address tables for network 216. Each of these network address tables for network 216 associates
a given network address with a corresponding list of one or more communications links. For example, network address 15924 stored in field 218 is associated with communications link 122 stored in field 220. Network address 15925 stored in field 222 is
associated with communications links 215 and 217, stored in fields 223 and 224, respectively. Network address 15926 (field 226) is associated with communications links 120 and 122 (fields 227 and 228, respectively). Network address "n" (field 230) is
associated with three communications links, referred to as "m", "x", and "y", and stored in fields 232, 234, and 236, respectively.
MMS memory 128 contains one or more network address registers 238. Each network address register 238 associates a given network with a given network address. For example, network 108 (fields 246, 248, 250, and 252) is associated with network
addresses 15926, 45634, 76892, and n (fields 240, 242, 244, and 252, respectively). Network 109 (field 258) is associated with network address 94763 (field 256).
FIG. 4 sets forth a hardware configuration for an exemplary endpoint device 300 constructed according to a preferred embodiment disclosed herein. In this example, endpoint device 300 is coupled to a first network 304 and a second network 316.
First network 304 provides a connection to an MMS reservation system 302, and second network 316 provides connections to an MMS 310, endpoint device 312, and endpoint device 314. In the configuration of FIG. 2, endpoint device 300 may be incorporated
into the multimedia conferencing system as endpoint device 104 and/or endpoint device 106. Alternatively, other types of endpoint devices may be used for endpoint devices 104, 106.
FIG. 5 is a hardware block diagram setting forth the system topology of network 108 (FIG. 2) in the context of multimedia signals such as audio, video, and data. Many existing networks 108 (FIG. 2) were developed for the purpose of switching
voice and/or data, and are not especially well-suited to the wide bandwidth requirements of video. Examples of such networks include conventional central switching office equipment and computer local area networks (LANs). Moreover, certain prior art
networks, such as the central switching office example discussed above, were developed to handle point-to-point communications to and from a first party and a second party.
Difficulties arise when conventional networks are called upon to implement a multipoint communications connection between three or more parties, i.e., between three or more endpoint devices. Difficulties also arise with respect to the
implementation of video communications links. Accordingly, special hardware and software are required to implement video communications over a network, and special hardware and software are also required to implement multipoint communications. The MMS
102 (FIG. 2) was developed for the purpose of providing multipoint communications in a multimedia environment (including video), where the parties requiring communication services are restricted to using endpoint devices connected to conventional
networks 108. The MMS 102 is geared to utilizing network 108 such that network 108 conveys multimedia information to and from selected endpoint devices, in a manner consistent with the needs of communication services recipients.
FIG. 5 demonstrates the manner in which a conventional network 108 may be adapted for multimedia conferencing applications through the use of an MMS 102. In the example of FIG. 5, network 108 is a conventional central switching office at a local
telephone company. The network 108 was designed for the purpose of carrying voice communications over point-to-point links and includes a plurality of communication pathways such as lines 402-424 for this purpose. However, these lines 402-424 may be
grouped together to carry information, such as video and data, in addition to voice. Although network 108 is described as a central switching office, this is done for illustrative purposes, it being understood that the network could be another type of
existing network, such as a LAN.
First endpoint device 104 is connected to network 108 via communications link 118, which contains a video line 402, an audio line 404, and a control/data link 406. (In actuality, video line 402 could represent several conventional wire pairs,
whereas audio line 404 may only include one conventional wire pair.) Video line 402 connects to switch 440 in network 108. Audio line 404 connects to switch 442, and control/data line 406 connects to switch 444.
Second endpoint device 106 is connected to network 108 via communications link 120, which contains video line 408, audio link 410, and control/data line 412. Video line 408 connects to switch 452, audio line 410 connects to switch 454, and
control/data line connects to switch 456.
Signal routing device 129 of MMS 102 is connected to network 108 via communications link 122. This communications link 122 includes a plurality of video lines 414, 420, a plurality of audio lines 416, 422, and a plurality of control/data lines
418, 424. Video line 414 connects to switch 446 in network 108, audio line 416 connects to switch 448, control/data line 418 connects to switch 450, video line 420 connects to switch 458, audio line 422 connects to switch 460, and control/data line 424
connects to switch 462.
The switches 440-462 of network 108 are under the control of network processor 116, which may be a conventional microprocessor device known to those skilled in the art. The network processor 116 controls the operation of each switch 440-462, and
selectively connects and/or disconnects a given switch (i.e., switch 440) to/from another switch (i.e., switch 452). The circuit topology of network 108 with respect to switches 440-462 is shown for illustrative purposes only, it being understood that
network 108 may include any switching topology equipped to selectively connect and/or disconnect a plurality of communication links.
Refer now to FIG. 6, which sets forth the hardware configuration for the signal routing device 129 of MMS 102 (FIGS. 2 and 5). Signal routing device 129 provides for the bidirectional switching and mixing of a plurality of electronic multimedia
signals to/from a plurality of endpoint devices 104, 106 (FIG. 2). The signal routing device of FIG. 6 is designed to process video, audio, and control/data signals separately. However, signal processing device 129 could alternatively be designed to
process these signals in a multiplexed manner. The signal routing device 129 of FIG. 6 interfaces with each endpoint device 104, 106 via network 108 (FIG. 2). Signal routing device 129 includes three signal routing entities: an audio signal routing
device 506, a video signal routing device 500, and a control/data signal routing device 512. With respect to audio signal routing device 506, an electronic multimedia signal representing audio from first endpoint device 104 is coupled to audio line 404
through network 108. An aggregate audio signal representing audio to first endpoint device 104 is also coupled to audio line 404 through network 108. Audio line 404 interfaces with audio circuit termination #1 (508), which is equipped to buffer, switch
and/or amplify audio signals.
In a manner analogous to that of audio signal routing device 506, video signal routing device 500 selectively routes electronic multimedia signals among a plurality of endpoint devices 104, 106 (FIG. 2). Video signals to and from first endpoint
device 104 are coupled to video line 402 via network 108. Video line 402 interfaces with a first video circuit termination #1 (502), which buffers, amplifies and/or switches video signals. Similarly, control/data line 406 handles control/data signals
to and from first endpoint device 104. This control/data line is coupled to control/data circuit termination #1 (514), which buffers, amplifies, and/or switches control/data signals.
Signals from additional endpoint devices, i.e., from an Nth endpoint device, are routed in a manner analogous to that described above for first endpoint device 104. For example, audio to and from the Nth endpoint device traverses audio line 422,
video to and from the Nth endpoint device traverses video line 420, and control/data signals to and from the Nth endpoint device traverse control/data line 424. Audio line 422 is coupled to audio circuit termination #N (510), video line 420 is coupled
to video circuit termination #N (504), and control/data line is coupled to control/data circuit termination #N (516).
Audio circuit termination #1 (508), audio circuit termination #N (510), video circuit termination #1 (502), video circuit termination #N (504), control/data circuit termination #1 (514), and control/data circuit termination #N (516) are all
coupled to a common internal switch 518 equipped to switch, buffer, and/or amplify multimedia electronic signals. The common internal switch 518 is equipped to independently process a plurality of multimedia electronic signal types. For instance,
electronic signals representing audio information are processed using a set of audio switches, signals representing video information are processed using a set of video switches, and signals representing control/data are processed using a set of
control/data switches.
Common internal switch 518 is coupled to an audio mixer/switch 520, a video m | | |
