NO861168L - PROCEDURE FOR CONNECTING CONFERENCE PARTICIPANTS. - Google Patents

Description

The invention relates to a method for interconnection

of conference participants in computer-controlled telephone switching systems with digital pass-through.

It is known in telephone switching facilities to connect conference connections where the number of connected telephone handsets is limited to a low value. These conference devices are preferably designed for telephone two-station systems and only allow the participation of a participant who is connected via a central line. Therefore, strict provisions on transmission technical regulations (DE-PS 3144267) must be observed.

For the structure of such conferences, it is also known for computer-controlled telephone systems to store a participant entitlement and with the help of concatenation stores, priority stores and central conference participant stores to monitor the number of the connected participants so that e.g. a maximum of four conference participants are connected at the same time (DE-OS 3206830).

The invention is based on the task of obtaining

a procedure that makes it possible for public local communication centers to allow a so-called large conference (or teleconference) with e.g. a maximum of twenty participants, at the same time that each participant can be associated with an arbitrary communication center at home or abroad and only the participant who convenes the conference is associated with a local communication center with a conference facility.

This task is solved with the help of the invention as it is

is stated in the characteristic of the first patent claim. Further favorable designs of the subject invention appear from the non-independent claims.

The invention will be explained in more detail below with reference to the drawing. Fig. 1 is a block diagram of a digital computer-controlled local communication center with conference set. Fig. 2 is a block diagram of a cascading arrangement of conference links, and

fig. 3 is a block kernel of the control of the level assessment.

A digital local dissemination center (fig. 1) is divided

in three areas: the connection groups LTG, the connecting network SN and

the coordination processor CP.

The connection construction groups LTG constitute the interface between the analogue or digitally controlled subscriber stations and the connection network SN. Each connection group LTG disposes of a separate group processor GP, a group switch or a speech multiplexer SPMX, a signal unit SU and interface units LTU for line connections and LTU for the connection with the switching network SN.

The group processor GP serves to control the participant sets, the group coupler or voice multiplexer SPMX and the interfaces LIU as well as to process the selection information and carry out tests.

Such a connection group LTG is an independent unit, where typically 256 participants or 120 digital connection lines or combinations thereof can be connected.

For conference connections in such a digital communication center, either a separate conference connection group LTGK is arranged, or the conference modules KM are placed in existing connection groups LTG, whereby in small communication centers no space is lost for a complete connection group.

The example that will be given in the following goes

based on a separate conference affiliation group according to fig. 1, but is equally valid for conference modules KM plugged into connection building groups LTG.

Connections for large conferences are controlled via conference modules KM (Fig. 1) arranged in a special conference connection group LTGK. A conference connection group LTGK is equipped with a maximum of four conference modules KM1..KM4. Each conference module KM in turn consists of four conference links K, each of which disposes of eight ports. Thus, each conference module KM can serve 32 ports.

The smallest unit that can fulfill the requirements relating to connecting participants to a conference connection is the conference connection K. For each conference connection, therefore, a whole number of conference connections K is always needed.

Allocation of individual ports in a conference link K

is not possible. All conference participants participating in a conference connection are served by a conference facility

ning that is connected to the local communication center for the participant calling the conference.

Depending on the need, the dissemination center is assigned there

a different number of conference affiliation groups LTGK.

Each of the conference connection groups LTGK works independently of the others, as they represent independent building units and never two conference links K with two different conference connection groups LTGK either on the same or also on different communication centers participate in the same conference connection. In that context, several different conference connections within a conference connection group LTGK are of course possible at the same time, and in the case of small conference connection groups LTGK also several conference connections within the same conference module KM.

On the part of the participants, no special additional hardware is required to utilize the "large conference" (or "teleconference") scope format.

The connection operations required for the connection

of the conference participants, is carried out with the help of the conference affiliation group LTGK. Only the KATLN participant who convenes the conference must have a terminal with multi-frequency options available to carry out the necessary operations. The participants KBTLN who take part in the conference can dispose of arbitrary terminals, e.g. also pulse selection equipment, and be associated with arbitrary local communication centers at home and/or abroad.

For the generation and distribution of a conference signal

access to a conference port is arranged for each conference participant via the SN connection network.

In a conference connection, when using the scope format "large conference", in addition to the calling participant KATLN (conference-requiring participant), at least three and at most twenty called participants KBTLN (number of conference participants) participate.

In accordance with the number of participants in a conference group

a number of conference ports will be needed. As each conference link K exhibits eight ports, it can be associated with a maximum of eight conference participants. If there are more than eight participants, several conference connections K must be connected by cascading.

The cascade formation is visualized in fig. 2. It is made via internal connections within the conference connection group LTGK, each time from a K port in one conference link to a K port in the other (eg Kl,6 to K4,1).

The conference links are interconnected in a star-shaped manner, always with the center point in the conference link K which is assigned to the calling participant KATLN. A chain-like connection of conference links K.. is also possible, but does not offer any advantages over the star-shaped connection arrangement.

For this type of connection of conference participants, it has been ensured that, in the case of a conference connection, a maximum of three channels are connected simultaneously. In this connection, the sum signal on the conference modules KM is generated using particularly fast digital signal processors. If more than three participants speak at the same time, all n speaking participants are not taken into account, but only the three who speak the loudest. This means that the sum signal will always be formed from them

n speaking participants, as the speech channels of the three loudest speaking participants are distributed in direction of hearing. It offers the advantage that each conference participant hears the maximum three speakers without attenuation.

The decision regarding which channels in the conference connection are active and which are not is made by the user program in the group processor GP at the conference connection group LTGK. For this purpose, in order to determine the active channels in a conference connection at all times, it is necessary for each participating conference link to determine and assess a relevant level. A suitable representation of a conference connection with the levels appearing in that context is stored in the group processor GP for each conference port. A new decision with regard to which conference ports are to be controlled to active and which to inactive state is made with each new level message. The result of this matching is delivered via a signal multiplexer in the form of setting commands to the participating ports in the conference links K.. However, every new level message does not lead to another matching or to a switchover.

The image per conference connection contains the storage space for the last reported level and has max. 21 places (1KATLN max. 20 KB-TLN). As a signal processor for dynamic reasons can only handle max. eight PCM channels, there can only be max. sixteen conference connections, each for eight participants. Therefore, this depiction contains sixteen variants. Due to expensive equipment in hardware and firmware, it is not possible for the eight ports that a signal processor serves to belong to different conference connections. Therefore, eight gates is the smallest administrative unit. Conference connections with more than eight ports are provided by cascading these units as already discussed.

A special advantage is obtained from the fitting proposed here

in that the devices that belong to a conference connection do not need to be located on one hardware-related device, the conference module KM. This is possible because the user program has equal access

to all (max. 128) ports in the conference connection group LTGK, while the hardware/firmware used cannot exceed the conference module limit (i.e. 32 ports). As between 4 and 21 participants can participate in conference connections, the possibility of cascading the 8er units on different conference modules KM is always beneficial when there are no longer as many free ports available on any conference module KM alone as

it would be necessary for a conference connection to be rebuilt. Here, however, the restriction applies that the units must be located in a conference connection group LTGK.

In the event of a necessary cascade formation, the software adaptation has a further advantage over a hardware adaptation of the conference module.

While the software used can distinguish between a port to which a conference B participant is connected, and one to which an additional 8er device is connected, this

not possible for the hardware/firmware used. This would

in the case of the hardware/firmware solution cause such ports as

an 8er unit hangs on would be preferred, since it usually delivers far higher total signal levels than from a conference B participant KBTLN.

In this connection, with regard to the software off-match, it must be ensured that the K ports in the conference links K do not report so often with a new level that the group processor GP was overloaded by the message flood.

The hardware/firmware used in the conference connection group LTGK ensures that individual level messages on the individual K-ports only reach the group processor GP when there is a noticeable change, so short-term level variations do not cause any switching from active to inactive state.

For this purpose, the level is integrated over m speech samples in the conference module KM. As the storage in the group processor GP would be overloaded with the additional data about level values from m speech samples from max. 128 K-ports and as it is desirable to separate the further processing of this data from the actual tasks of the signal processor, a conference module's voice samples are via a direct storage access DMA, fig. 3, loaded cyclically into a buffer RAM. The signal processor CPU reads out this data and processes it. Only when there are noticeable level changes is a message sent from the signal processor CPU to a conference link group processor GP to switch from active to inactive state or vice versa.

The level assessment is not carried out on the basis of absolute level, as it is predominantly the pure speech signal that is assessed. This has the advantage that any persistent background noise is not overestimated and distributed in the direction of hearing of all the conference participants. Admittedly, such an assessment threshold cannot be determined arbitrarily, as in each case a distinction must be made between disturbances from background noise and a speech signal, and the participant has to scream to be perceived as active, but it is easily possible to determine a port-specific upper and lower limit .

This adaptive rating threshold becomes at the beginning

of a conference connection set to the value of the lower limit for each conference link K. This initial value can only be changed in the direction of the upper limit value. The initial value of the adaptive assessment threshold is determined as a rest level is determined for all inactive channels for each

conference link K, and integration is carried out over the number of inactive rest levels. If this integrated rest level is very low, then the adaptive assessment threshold stays at the initial value. If the resting level is high, the assessment threshold rises accordingly, up to the maximum upper value.

For balancing between inactive and active channels becomes

at all times the difference value between the integrated speech level and the resting level for the adaptive assessment threshold determined.

As long as the channels are active, i.e. distributed in the direction of hearing, this resting level determination is not carried out. For the participant KATLN who calls the conference, a special position is provided provided that the adaptive threshold for the assigned conference link K is constantly kept at the initial value, so that the corresponding channel is constantly connected in the listening direction, e.g. to ensure moderator functions.

Claims (11)

1. Procedure for connecting conference participants in computer-controlled telephone switching systems with digital pass-through, characterized by the fact that a) the individual voice channels of the conference participants are summarized on a digital basis, b) special conference connections (K) are aggregated into conference modules (KM) within a connection group (LTG) or a special conference connection group (LTGK), c) the conference links (K) for carrying out conferences with a larger number of participants are connected in cascade in series, d) a sum signal is formed from the speech levels of a maximum of three most active (loudest speakers) speaking at the same time and is distributed without attenuation, e) in case of simultaneous speech by more than three participants in the conference, only the three most active (loudest speaking) speakers are connected in the listening direction, f) a further signal is formed to produce a judgment threshold based on the resting levels of the inactive participants' conference links (K), and g) the difference value between the integrated absolute level of the number of the participating conference connections and the level of the assessment threshold is used to balance between inactive and actively connected channels (participants). 2. Method as specified in claim 1, characterized in that the assessment threshold for each conference connection (K) before the start of each conference connection is set to the lower limit value. 3. Method as stated in claim 1, characterized in that the level of voice samples from the individual conference connections (K) via a direct memory access (DMA) is cyclically entered into a buffer (RAM), evaluated by a signal processor (CPU) and passed on to the conference attachment group's (LTGK) group processor (GP). 4. Method as stated in claim 1, 2 or 3, characterized in that only tangible changes in the level from individual conference links (K) are forwarded to the group processor (GP). 5. Procedure as stated in one of the requirements 1-4, characterized by the fact that predominantly the conference participants' speech levels are assessed. 6. Method as stated in one of claims 1-5, characterized in that a typical representation of a conference connection with the levels appearing in that context is stored in the connection group's group processor (GP) as a comparison pattern. 7. Procedure as specified in claim 1, characterized in that within a conference module (KM) cascade formation of the conference links (K) is carried out if one conference link (K) is not sufficient to serve all participants in the conference. 8. Method as specified in one of claims 1-7, characterized in that the cascaded conference links (K) can be arranged on different conference modules (KM). 9. Method as set forth in one of claims 1-8, characterized in that the conference links (K) are connected in a star-shaped manner between them. 10. Procedure as stated in claim 9, characterized in that the participant (KATLN) who calls a conference is constantly assigned to the center of the star. 11. Procedure as stated in one of the requirements 1-10, characterized by the fact that the conference participants can be connected to arbitrary mediation centers at home and abroad, under which only the conference links (K) on the mediation center for the participant who convenes the conference, will be coated.