AT501945B1 - METHOD FOR OPERATING A CONTROL SYSTEM, ESPECIALLY FOR BROADCASTING - Google Patents

Description

2 AT 501 945 B1

The invention relates to a method for operating a control system, in particular for radio stations, with a process level consisting of devices and connecting devices for transmitting and / or processing multimedia signals and a control level, which comprises control devices for controlling and operating the devices and connection devices of the process level. Furthermore, the invention relates to a control system for carrying out the method.

Control Room Control systems are used in broadcasters to configure, control and monitor television or audiovisual equipment. Switch rooms are the central points from which the facilities in production rooms or transmission facilities are accessed via a network. Accordingly, the technical equipment of such central offices typically includes a number of systems for receiving, routing, leveling and distributing signals to internal and external areas, as well as metrological monitoring and monitoring of all system components of various manufacturers. The facilities of a broadcaster are divided into a process level and a control level. The process level includes all the hardware components required to process and distribute multimedia signals (video and audio signals, level signals, etc.). These are, for example, A / V and remote crossbar systems (Trinix from Thomson, Nexus from Stagetec, etc.), AA / signal processors (Snell & Wilcox, Nexus, etc.) as well as codecs, embedders, delays, and measurement systems.

In the control level, the networked hardware components of the process level are accessed by means of controller modules. The control plane contains all the controls that can be used to configure, control, and monitor the hardware components at the process level, including local operating and display systems. As a rule, the control devices are so pronounced that they can access the hardware components of the process level independently of the manufacturer.

Control systems are also known that access a process level via a network structure. Thus, e.g. US Pat. No. 5,307,456 A describes a media system which consists of a process level with various media devices, the devices being connected to one another via so-called "routing switchers". The devices of the process level are connected via a LAN to a database server and at least one workstation, whereby so-called device translators are arranged at the connection points. These device translators are used for signal conversion between the LAN and the individual devices.

Another control system for multimedia production facilities is disclosed in WO 1999/05821 A2. It is accessed by a workstation via a server to different multimedia data. These multimedia data are provided by different devices. A user has direct access to available multimedia data through the workstation application and can control their combination and transmission sequence without even addressing the playback or production facilities.

JP08279974 describes a method of operating television facilities. In this case, a control computer sends a control signal via a network to a controller unit, which converts the control signal into a hardware-specific signal. After completion of the control task, the controller unit sends a Fertigmeldungssignal (or possibly an error signal) back to the control computer.

As a rule, broadcasters in the control plane have several control units that can access the hardware components of the process level via a network. On the one hand, there has to be enough flexibility to quickly adapt to different production orders (sporting events, talk shows, etc.), while on the other, access conflicts must be avoided. 3 AT 501 945 B1

The patent application EP1065816-A1 describes a method which regulates the access of several control computers to the hardware components of the process level. In the process, that control computer receives an exclusive right of access to a hardware component which is the first to access it. 5

New production formats and increasing productivity requirements for broadcasters mean that the control, signal management, system operation and monitoring of the television and audio-technical equipment are becoming ever more extensive. The demands placed on the operating personnel - especially in television technical and audiovisual control centers, such as control rooms - are increasingly growing. Increasingly complex signaling tasks and higher availability requirements of systems and connections make it more difficult to operate at the control level. Control room tasks are concentrated in addition to regular production orders at certain times (e.g., prime time, magazine broadcasts, news) or on special days (sports events, elections, etc.). This creates concentrated workloads for the operating personnel of control rooms.

In the prior art, therefore, control systems are known that allow control processes to be defined real-time independently. For example, US 6 046 780 A discloses a control system for broadcasting devices having a hierarchical structure. In this case, a high hierarchical level is provided for the real-time independent determination of control sequences. This hierarchy level is linked to a lower hierarchy level via a shared memory or network, where real-time control operations are performed. The described hierarchy structure thus serves to decouple the control tasks from the control processes that take place in real time. The failure of the high hierarchy level in this system causes the total failure of all broadcasting facilities.

The invention is therefore based on the object of specifying a technical solution for improving the state of the art. 30

This object is achieved in that a method for operating a control system is specified, in particular for broadcasters, with a process level consisting of devices and connecting devices for the transmission and / or processing of multimedia signals and a control plane, which operating devices and control facilities for Control and operation of the devices and connection devices of the process level includes, wherein the settings and line connections of the process level via the control devices are made in redundant manner both via the operator panels and by specifying setting parameters and device links via at least one workstation. In addition, the available connections of the connection devices are detected continuously and the connections for the device connections are established dynamically.

The entire management of all crossbar crosspoints of multiple systems is fully automated through an integrated so-called Pathfinder system. The operator 45 is thereby relieved, by only determine the desired device links and no longer have to worry about the circuit implementation of the connections. In this way, the operator can also loop any additional devices via crossbars in a signal chain, without the required crosspoints are determined in advance. The selection of crosspoints is determined by the Pathfinder system. The ge-50 is done in such a way that the operator indicates the period in which a Einschliffgerät is required and the Pathfinder system then unlocks from all available connections those crosspoints, which are necessary for grinding in the auxiliary device.

Furthermore, the invention provides a control system, in particular for broadcasting stations, which is set up to carry out the method, having a process level, best consisting of devices and connecting devices for transmitting and / or processing multimedia signals and a A control plane comprising operating devices and control devices for controlling and operating the process level devices and connection devices, providing a signal and system management layer comprising at least one workstation configured to make settings and line connections by specifying setting parameters and device links , a database server for storing setting parameters, device links and available connections, and a configuration unit for configuring the database server. 10

Furthermore, both the operator panels and the workstation are configured to specify settings and line connections in a redundant manner, and the controllers are configured to control the connectors to dynamically establish the connections for the device links, with the at least one workstation having the Control plane devices and on the other hand connected to the database server.

The access to the control plane facilities workstation creates the ability to centrally control even complex signaling tasks. In this case, control data, which are stored on the database server and passed on time-dependent or event-dependent via the control level to the devices of the process level, are processed on 20 of the workstations that are in the form of computers. A so-called event is the temporal and connection-technical definition of a switch room order, combined with the exact definition of all technical requirements, which are necessary for the event. If several workstations are used, the operators can process events on an equal and simultaneous basis, thereby achieving higher productivity in the execution of switch room orders. All workstations are constantly synchronized with the database server, with a so-called event manager and a so-called circuit manager being used as data processing programs. All systems in which connections, devices or any resources have to be scheduled and managed in time can thus be optimized. The invention thus makes possible above all a great savings potential in the area of the required resources as well as a temporal equalization of the workload of the operating personnel. The event manager checks the periods in which certain transfer events are to take place and saves all relevant additional information on the database server. The circuit manager uses the database information to detect timing conflicts and conflicts when using resources, and stores all event-related circuit information and settings on the database server. The database server thus represents the central storage element for all events and all related technical, documentation and logging data.

A further advantage results when the status, in particular the availability, of the devices, of the control devices and of the connection devices is continuously checked and by means of the at least one workstation is displayed. Then the operator has the opportunity to check whether all planned resources are available before a scheduled event start time. When an event is activated by the operator, the correct execution of all the circuits is tracked and controlled via the circuit manager by means of a workstation. 50

Advantageously, the setting parameters and device links are stored in a database server and thus defined settings of the control devices and connecting devices designed in a simple manner retrievable. This has the advantage that all events can be scheduled in advance and managed in the database server. So 55 events can be fully prepared, even if the event will take place at a later date. Before the activation of an event by the operating personnel, it is then checked whether, for example, the time overdraft of another event still allocates resources that were actually scheduled as free. These occupied resources are signaled to the operator so that they can exchange them for other free resources. Even with a 5 activated event, it is still possible to change the circuit at any time and to delete or insert new devices via the Circitmanager via the workstation.

Furthermore, it is advantageous if data from monitoring and signal measuring systems in the process level are stored in the database server and displayed by means of the at least one workstation. The workstation then serves as a measuring station for the operating personnel. If necessary, the circuit manager defines each input and output in the device network as a measuring point for any type of signal by means of so-called signal-accompanying measuring. All the necessary switching operations are automatically calculated and the crosspoints are set via several crossbars. The operator can concentrate on the metrological examination of the signal path. The system automatically recognizes which signal type it is and on which measuring path it must be switched.

For a further advantageous embodiment of the invention, a structure of the process level 20 and the control level is determined via a configuration unit and the structure configuration thus defined is stored in the database server. The mirroring of the physical device and network structure stored in the database server enables the offline processing of event switching tasks from all workstations. It is also envisaged that structures will be deposited that are physically realized only at a later date. The hardware structure to be configured includes, for example, the number, type and structure of all crossbar systems, cross connections between crossbars and other devices, all signal processing devices and cross connections to the crossbars and each other, VDAs, A / D and D / A converters, De- / embedder, frame synchroniser and identgenerators (identification transmitter) as well as measurement and storage locations. The information to be stored in the database server, if present, can be taken directly from the configuration programs of the crossbar and level controller systems.

It is advantageous if the process level includes remote controllable crossbars, Einschliffgeräte and 35 signal processing units and monitoring and signal measuring systems. Then a central access to all device settings is possible in the control room.

An advantageous embodiment of the invention also provides that the at least one workstation is connected on the one hand to the control devices of the control level and on the other hand to the data server via a TCP / IP network. This provides the opportunity to access common hardware products from many manufacturers that use the TCP / IP protocol. This has a positive effect on the hardware costs and thus also on the possibility of ensuring a sufficient redundancy of the resources. It is also favorable if the multimedia signals transmitted and / or processed in the process level are video and audio signals.

The invention will now be described by way of example with reference to the accompanying drawings. Shown schematically: 50

Fig. 1: System structure of the control room control

Fig. 2: System structure of the switch room crossbar control

FIG. 1 shows the system structure with the signal and system management level C, the control level B and as part of the process level the monitoring and signal measuring systems 7. In the control plane B are the so-called controller systems for crossbars 1, the so-called controller systems for video processing 2 and the so-called controller systems for audio processing 3, wherein in each case at least one unit is present. At least one workstation 4, a configuration unit 6 and a database server 5 for recording all resources and connections are arranged in the signal and system management level C lying above them. This database server 5 has open interfaces for docking systems, e.g. Scheduling systems D (e.g., line office) or accounting systems E (e.g., SAP). With the data transfer from upstream scheduling systems D io, for example, switching room orders can also be prepared at office workstations.

In the system structure, the workstations 4 access the controller systems 1 to 3, in which case control commands from the workstations 4 to the controller systems 1 to 3 and feedback 15 or measurement signals from the controller systems 1 to 3 are routed to the workstations 4. From the controller systems 1 to 3, in turn, a connection is established to the monitoring and signal measuring systems 7, from where the monitoring or measuring signals are routed via the controller systems 1 to 3 to the workstations 4. From the workstations 4 control data, disposition data, event data, etc. are forwarded to the database server 5 and stored there. If an event is called by means of a workstation 4, the stored data is retrieved from the database server 5.

By means of the configuration unit 6, the overall system is configured in such a way that first 25 mirrored in the database server 5, the physical structure conditions and then settings are made. All devices and connections that exist in the system are recorded with device-specific parameters.

FIG. 2 shows the system structure of the control room crossbar control in the three levels 30 process level A, control level B and signal and system management level C. The process level A comprises all audio / video crossbar systems 12 and 13 (eg Venus video crossbar, NEXUS Star Router System audio crossbar) with a main crossbar 14 (eg Trinix SDI crossbar), video signal processing units 9 (eg Snell & Wilcox video processors for coding, encoding , noise recuction systems, etc.) Server systems 10 35 (eg Leitch server), audio signal processing units 11 (eg audio DSPs), and Montitoring-

Signal measuring systems and the like. The signal processing units 9 and 11 are also available as Einschliffgeräte. The connection to the control level B takes place manufacturer-neutral, e.g. via RS422 or MPX interfaces. In the control plane B itself are networked crossbar controllers 1 and 8 with control units 16 (eg for level control), display units 18 (monitor wall) and so-called multiviewers 19 and process control controllers 2 and 3 with control units for process settings 15. A crossbar system 13 with a Crossbar controller 8 with operating and display device 17 is configured by way of example as a so-called intercom system. The control plane B is operable with all operating and display systems 15 to 19 even without the higher-level signal and system management level C and belongs to the state of the art.

According to the invention, the controllers 1 to 3 and 8 are connected to the elements of the signal and system management level C via a dedicated network (shown in dashed lines). In this case, by way of example, three workstations 4 with multiscreen displays, a database server 5 and a configuration unit 6 are shown. By means of the central configuration unit 6, the database server 5 designed to manage the events, resources, settings, connections and logging is accessed and configured directly. All control plane operation is via workstations 4. These are exemplified as computers with triple TFT screens. Due to the networked system structure with synchronization in progress via the database server 5, a parallel operation by means of several workstations 4 is provided. 5 Each switch room workstation then includes e.g. in addition to the manual operating devices, measuring equipment, intercom facilities, the triple TFT screen of a workstation 4, each of which on one screen, the information of the event manager, the circuit manager and a device or audio manager are shown. The distribution of the three manager systems on the screens is freely adjustable. Device monitoring may e.g. also include several iO broadcasting-specific views. The control room workstation thus becomes a combined workstation for scheduling, operation, metrological monitoring as well as documentation and archiving of all switch room orders. The classic division of these areas of work into different jobs is no longer necessary. The basis for the operating functions of the signal and system management level C is the database server 5, on which the data of all devices, connections and resources of the entire audio / video control room system are stored. All resources and connections can be booked via a workstation 4 via the database server 5 for specific periods. In this case, the monitoring and signal measuring systems 7 arranged in the process level A recognize all failed or non-operational devices, this information being collected via the network in the database server and displayed on the workstations 4.

Specifically, the event manager displays the switching orders for all events bundled on the 25 screen, whereby the individual events are listed in chronological relation to each other. Each new order for a switch room (for example, all connections for a scheduled sports transmission) is defined by the operator as a new event for a certain period of time and stored in database server 5 with various management information such as activation time, comments, error messages, log files, etc. 30 default entries can also be used or saved events can be duplicated and adjusted. For the specified time period, the system calculates all available resources and displays them as a resource list using Circuit Manager on a workstation 4 screen. Copied events offer the advantage that, in addition to the event information, all the circuit information available for the event is simultaneously available in Circuit Manager 35, where it can be modified directly. For example, the workstation 4 screens then display all scheduled events in a time-bar graph, with additional bars indicating early or late manual activation or deactivation of events. Already completed events are stored in the database server 5 and can be accessed, copied and reactivated via a workstation 4 by the operating personnel.

With the circuit manager available on a workstation alongside the event manager, operators define the circuits and make changes to them. The views of the circuit manager are displayed on a screen as soon as 45 of the operator an event is selected. The individual components of all system resources and their time availability are displayed in a list. Resources may include, for example, input and output lines of the switch room, or dipters, signal processors, and other devices that will use in a video or audio connection. The operator selects from the available free resources the resources that are required for the planned circuit of an event.

In an exemplary manner, an operation is provided for this, in which the operator moves the component entries from a list on the screen into a drawing area also displayed on the screen by means of an input unit and there connecting lines (graphic gummets) between the individual circuit components 8 thus arranged on the screen AT 501 945 B1 pulls. In this way, the overall circuit of an event is graphically created on the screen and the links thus defined between the individual circuit components and the set parameters of the individual components are stored in the database server 5. Upon activation of the event by the operator, this link information 5 is retrieved and the system calculates the necessary connections on the basis of all free crossbar crosspoints for the specified period of the event and switches through the corresponding crosspoints. The system offers the signal distribution to several consumers or - as required for audio signals - also the summation of signals. For the operator, there is the advantage that all circuits can be created offline by means of circuit manager and later manually activated, whereby only the links, but not the then actually connected crosspoints are defined in the crossbars. All crossbar connections are thus managed via the network connections from the signal and system management level C (only one line as tieline). There are 15 circuit changes in the same way even with active event online feasible. In addition, Circuit Manager provides further favorable functions to support the operating personnel. These are, for example, the display of bidirectional signal flow between external locations (e.g., football stadium) and internal consumers (e.g., gym) and the display of all types of signal connections (video, audio, intercom, etc.). 20

It also provides for continuous signal labeling from the circuit manager to the operator panels. The level settings for all devices including the Einschliffgeräte done either by means of a workstation 4 or in redundant manner via control units 15 to 17 in the control plane B (disaster mode). 25

By incorporating an intercom system 8, 13, and 17 into the network between control plane B and signal and system management layer C, operators can access the intercom functions from workstations 4 (e.g., voice in the output line). 30

FIG. 3 shows a control system for a plurality of production units T1, T2 to Tn (studios, OB vans). This results in a matrix structure over a TCP / IP network (thick dashed line), wherein three workstations 4 are connected to two production units T1 and T2 shown, whose components in turn each with a LAN network (thin 35 dashed line, eg ESBUS) with each other are connected. In the TCP / IP network, the database server 5 and the configuration unit 6 are integrated again.

A production unit T1 is divided into a process level A1 and a control level B2. The same applies to further production units T2 to Tn, which are all connected to the workstations 4 via the TCP / IP network 40. In the process level A1, devices for image acquisition 25 (cameras), server systems 10, signal processing units 9, crossbar systems 12, signal mixers 26, display units 18 (monitor wall) and multiviewer 19 (flat screen wall) for displaying the signals routed via the crossbar systems 12 are arranged by way of example. The components of the process level A1 are all interconnected via the 45 crossbar systems 12 (thin solid line), wherein the crossbar system 12 different production units T1 to Tn are in turn interconnected. Through this networking within and between the process levels A1 to An, all components of the process levels A1 to An can be interconnected via the crossbar systems 12. 50

In the control level B1 are exemplified a crossbar controller 1, a process control controller 2, a mixer controller 27, a display controller 28, a multiviewer controller 20, operating devices for process settings 15, a so-called matching router controller 21, crossbar operator panels 16 and other controls - And display devices 22 are arranged. 55 These components are interconnected via the LAN network (thin dashed line)

Claims (9)

9 AT 501 945 B1 connected. Via the crossbar controller 1, this local network is connected to the TCP / IP network of the signal and system management level C, via which in each production unit T1 to Tn also a WinControl PC 24 and a TCP / IP network operating unit 23 are shot , 5 In complex and comprehensive system installations, measuring and monitoring points are often switched to a measuring station in a complicated manner. The present structure has the advantage that switchable Abhörpunkte or measuring points by the operator by means of a workstation 4 at each point of the signal path can be activated by io by means of Circuit Manager the corresponding links to the monitoring and signal measuring systems 7 of the process levels A1 - set become. The system calculates the required measuring and interception paths and switches them off. By means of device or audio manager, the information is displayed on a screen of the workstation-4, wherein for the sake of clarity, a uniform, device manufacturer-independent representation is provided. If required, however, the manufacturer-specific configuration and user interfaces can also be displayed on the screen of a workstation 4. Levels and settings on devices are also possible here. It is also provided that, depending on the task, different representations of the 20 monitoring and signal measurement information are displayed. This can be either the task-related representation of all systems involved in an event (video, audio, intercom ...), or specific representations of complete signal processing chains with multiple measurement points, or complete overviews of entire device groups with representations of detailed information (all codes of the switch room with device status and connection information , Display of signal parameters and audio level detection, activation of measuring points or intercom functions such as mic voicing or ident). In the process, all the data for the system representations are supplied online by the process controllers (parameters and status information) and operating personnel have direct control access to the process levels A1 to An via workstations (switching the crossbars, setting device parameters, changing signal designations). The WinControl PC 24 provided in each production unit T1 to Tn provides the operator with additional functions (for example, salvo controls). 35 Patentansprüche: 1. A method for operating a control system, in particular for radio stations, 40 with a process level (A), consisting of devices (9, 10, 11, 25, 26) and connection means (12, 13, 14) for transmission and / or processing of multimedia signals and a control plane (B), which operating devices (15-19, 22) and control devices (1, 2, 3, 8, 27) for controlling and operating the devices (9, 10, 11, 25, 26 ) and connecting means (12, 13, 14) of the process level (A), characterized in that settings and line connections of the process level (A) via the Steuerein directions (1, 2, 3, 8, 27) in a redundant manner via both the operating devices (15-19, 22) and by setting parameters and device links via at least one workstation (4) are made and that available connections of the connecting means (12, 13, 14) are continuously detected and that the Verbin-50 fertilize be built dynamically for the device links. 2. The method according to claim 1, characterized in that the status, in particular the availability of the devices (9, 10, 11, 25, 26), the control means (1, 2, 3, 8, 27) and the connecting means (12 , 13, 14) is checked continuously and by means of at least 55 a workstation (4) is displayed. 1 0 AT 501 945 B1 3. The method according to claim 1 or 2, characterized in that the setting parameters and device links in a database server (5) are stored as so-called events and that the thus defined settings of the control devices (1, 2, 3, 8, 27) and connecting devices ( 12, 13, 14) assigned as an event from 5 callable. 4. The method according to any one of claims 1 to 3, characterized in that data from monitoring and signal measuring systems (7) in the database server (5) are stored and by means of at least one workstation (4) are displayed. 10 5. The method according to any one of claims 1 to 4, characterized in that a structure of the process level (A) and the control level (B) via a configuration unit (6) is set and that the so-defined structure configuration in the database server (5) is stored. 15 6. Control system, in particular for radio stations, which is set up for carrying out the method according to one of claims 1 to 5, with a process level (A) consisting of devices (9, 10, 11, 25, 26) and connecting means (12, 13 , 14) for the transmission and / or processing of multimedia signals and a control plane (B), 20 which control devices (15-19, 22) and control devices (1, 2, 3, 8, 27) for controlling and operating the devices (9, 10, 11, 25, 26) and connecting means (12, 13, 14) of the process level (A), characterized in that a signal and system management level (C) is provided, which at least one workstation (4) is configured to make settings and line connections by specifying 25 setting parameters and device links, a database server (5) for storing setting parameters, device links and available connections, and a configuration unit (6) for configuring the database server (5), that in redundant manner, both the operating devices (15-19, 22) and the workstation (4) are set up for specifying settings and line connections 30 and the control devices (1, 2, 3, 8, 27) are configured to control the connection means (12, 13, 14) to dynamically set up the connections for the device links, and that the at least one workstation (4) is connected on the one hand to the control plane devices (B ) and on the other hand connected to the database server (5). 35 7. Control system according to claim 6, characterized in that the process level (A) remote-controlled crossbars, Einschliffgeräte and signal processing units and monitoring and signal measuring systems (7). 8. Control system according to claim 6 or 7, characterized in that the at least one workstation (4) on the one hand with the control means (1, 2, 3, 8, 27) of the control plane (B) and on the other hand with the database server (5) via a TCP / IP network is connected. 9. Control system according to one of claims 6 to 8, characterized in that in the process level (A) transmitted and / or processed multimedia signals are video and audio signals. So for this 3 sheets of drawings 55