SE454030B - Audio / video editing system - Google Patents

Description

454 030 10 15 20 25 30 35 2 an encoded reference track, which accompanies each tape recording and which identifies each recording image or field. Such reference tracks typically involve the use of a time code (recorded either directly in the reference track or in the video tracks during the vertical range or a combination of both) as specified in various documents of the Society Of Motion Picture And Television Engineers (SMPTE) and the European Broadcasting Union. (EBU). In a typical editing operation, the operator handles a keyboard while viewing a video monitor, which provides a visual presentation of the video information recorded on the recording tape player. The keyboard is typically a specially designed keyboard, which means that it consists of different keys, which represent special editing functions.

The keys can be arranged in ASCII format or in any other suitable format. Keys arranged in the ASCII format are also provided with letters, which are arranged in the same way as in a conventional typewriter, so that the various editing functions can largely be selected according to feeling and on the basis of experience and memory, essentially in the same way as when a experienced typewriter printer.

As editing systems have become more sophisticated and complicated, they, together with the keyboards used, have become larger and more confusing. For example, it is not uncommon for an editing keyboard to have more than 100 keys, each of which represents a particular editing function or type of function. As a result, considerable time and experience with a given machine is required before the operator can perform the editing functions quickly and efficiently. However, even in cases where the operator is experienced and completely familiar with a given editing system, there is an inherent problem with conventional editing systems in that the mechanical considerations imposed by a fixed keyboard with so many functions seriously impair the creative aspects of editing. 10 10 20 20 25 30 35 454 030 3 typically rely on time code representations of edit entry points and starting points rather than on editing in accordance with the image itself.

A further limitation of many conventional editing systems lies in the bonding of system intelligence to a central location. The systems utilizing a central data processor or other data processing unit in conjunction with the editing functions typically concentrate limited processing equipment in a central location, thereby limiting the future flexibility of a particular system.

Over the years, various attempts have been made to improve the human-machine interface involved in editing. Such a solution involves, for example, the use of a light pen. The pen moves relative to a sensitive element for selecting certain editing functions, thereby reducing the number of required buttons. At best, however, these systems replace the keyboard buttons with the stylus, which requires the operator to pick up and handle the stylus for each operation. The object of the invention is to provide an editing system with an improved human-machine interface, so that the artistic aspects of and approach to Video Editing is facilitated. A further object is to provide an editing system, which has the ability to present different editing function menus, from which the operator can choose, as well as the ability to accommodate varying numbers and types of information inputs and the ability for intelligent operations at peripheral parts of such a system. the central part of the system.

The above and other objects are achieved according to the invention by means of an intelligent operator line control unit, which is connected to the operator-controlled input device for identifying, converting and buffering the multiple, serial editing function messages into simultaneous, parallel editing 454 l0 15 20 25 30 35 030 4 function messages in corresponding multiple parallel channels in order to provide corresponding simultaneous, multiple, parallel editing instructions in response to the computer means's editing instructions; a plurality of intelligent machine control controllers, which are connected to the intelligent operator control unit via the multiple parallel channels for establishing simultaneous parallel connections with each of the recording devices and the switching device, and for converting and buffering the parallel editing instructions to depending on the computer means defining serial editing instructions; a plurality of interfaces, which are connected between each of the intelligent machine control controllers and each of the recording devices and the switching device for translating the various simultaneous, serial editing instructions into a form corresponding to the requirements for the respective devices, and for simultaneous translation. of device edit state messages from the respective device, when they occur for return to the associated intelligent machine control unit depending on the computer means; wherein the intelligent machine control controllers each further converts and buffers their serial editing instructions and their returned device editing condition1 state messages and simultaneously transmits the device editing condition messages to the intelligent operator control unit via each of the multiple operations of the multiple depending on the computer body.

The versatility and mode of operation of editing systems according to the invention is enhanced by the use of a system arrangement which provides intelligent capacity in peripheral locations as well as in a central location.

In this way, a single central data processor can in fact simultaneously communicate with a variety of input signaling equipment. A suitable interface equipment provides the data conversion into a machine-usable form, which is tailored to the specific requirements of peripheral input and output equipment.

In a preferred arrangement of an audio-video editing system according to the invention, a data monitor, comprising a cathode ray tube or other display screen, is connected to an editing control unit, from which it receives the various menus of editing information and selections. The display screen is equipped with a device for providing a network of interruptible beams across the screen. When the operator points to a particular character or group of characters on the presentation screen, the beams in this area are interrupted by the presentation screen and a corresponding signal is output to the editing controller. The editing controller, which includes a central unit, a memory, and a character generator, responds by making appropriate changes to the menu that is presented visually. The character generator connected to the central unit leaves the various characters, which are included in the various menus presented on the data monitor. At the same time, the central unit, together with the associated memory, provides data to other parts of the editing system for performing ordered editing functions, when the operator touches on specific parts of the presented menus. In addition to the touch-sensitive data monitor, the editing system may be equipped with one or more conventional keyboards, which are also capable of providing editing information and selection to the editing controller.

The editing control unit comprises a plurality of intelligent line control units, which are connected to the central unit. One of the intelligent line controllers is connected to the touch-sensitive device associated with the data monitor. Another of the intelligent line controllers is connected to a recording tape recorder, on which the material being edited is recorded. Another of the intelligent line controllers is connected to a switch. The remaining of the intelligent control units are each connected to a separate input information source. The input information sources may be such as camcorders or audio microphones but are typically source tape recorders. The switch is connected between the recording tape recorder and the various input sources, such as the source tape recorders, to control the connection of the input sources to the recording tape recorder. Each of the intelligent control units, which has its own central unit and its own memory, can perform intelligent functions at a distance from the central unit. In addition to converting parallel data from the central unit into a serial data form and vice versa, each intelligent line controller acts as a data buffer between the central unit and the various tape recorders as well as other peripheral equipment. The intelligent functions performed by the intelligent control controllers enable the central unit to actually communicate with the various parts of peripheral equipment simultaneously. The result is an unrestricted editing system, which can be connected to inputs of varying numbers and types. The various inputs, such as source tape recorder as well as the switch and record tape recorder, are connected to the various intelligent line controllers via interfaces, which serve to convert serial data from the intelligent line controllers into a form useful by the particular tape recorder or other connected connector.

A preferred embodiment of the invention will be described in more detail below with reference to the accompanying drawings. Fig. 1 is a perspective view of an audio-video editing system according to the invention. Fig. 2 is a perspective view of the data monitor of the editing system of Fig. 1 showing the touch sensitive device used in conjunction with that system. Fig. 3 is a block diagram of the editing system of Fig. 1. Fig. 4 is a block diagram of the interface portion with the operator of the editing system of Fig. 3. Fig. 5 is a block diagram of the various basic functions performed by the editing controller. in the editing system according to Fig. 3. Fig. 6 is a block diagram of a part of the editing system in Fig. 3 and shows the editing control unit in more detail. Fig. 7 is a block diagram of the video machine interfaces of the arrangement of Fig. 6.

Fig. 8 is a block diagram of one of the intelligent line controllers in the arrangement of Fig. 6.

Fig. 9 is a block diagram of the switch and power generator of the arrangement of Fig. 6. Fig. 10 is a flow chart showing the manner in which the editing system uses the data monitor and the touch sensitive device for converting user decisions to editing operations.

Fig. 1 depicts a video editing system 10 according to the invention. The video editing system is mounted on or housed in a console 12 and includes a data monitor 14 with a touch screen and a video monitor 16, which are mounted on the top of the console 12. On top of this, a control lever panel 18 is also mounted.

A specified keyboard 20 or such a keyboard 22 with keys arranged in an ASCII format, both shown in Fig. 1, can also be used to form alternative operator interfaces to the system 10.

The video editing system 10 of Fig. 1 may have up to three different interfaces to the operator, which interfaces are the touch screen data monitor 14, the designated keyboard 20 and the ASCII keyboard 22, each of which uses a control lever panel 18.

The control lever panel 18 has several control buttons and a control lever. When control of a particular belt transport is achieved by means of one of the operator interfaces 14, 20 and 22, the control lever panel 18 can be used to control the operation of that transport. The designated keyboard 20 may be of conventional construction and include all of the various keys and controls required to perform the various editing functions used in a modern, sophisticated editing system. The ASCII keyboard 454 030 10 15 20 25 30 35 8 table 22 has its various keys arranged in conventional typewriter format, so that the various editing functions can be entered into the system 10 by the operator.

The keyboards 20 and 22 are two different alternative ways in which the editing system 10 can be controlled by the operator.

The touch screen video monitor 16 provides an image of the video information recorded on a recording tape recorder as the editing is performed by the operator.

In accordance with the invention, a superior and highly advantageous interface between the operator and the editing system 10 is provided by the touch screen data monitor 14. As shown in detail in Fig. 2, the touch screen data monitor 14 is a cathode ray tube 26 with a display screen 28 at its display screen. . Next to the presentation screen 28, a touch input system 30 is mounted. The touch input system 30 establishes a pattern of interruptible beams over the surface of the display screen 28 using LEDs and photodetectors. In the present example, the touch input system 30 is of the type manufactured by the Carroll Manufacturing Company of Champaign, Illinois and includes two different sets of LEDs 32 and 34 on the left side and the lower side, respectively, of the display screen 28. The touch input system 30 has also a first set of photodetectors 36 on the right side of the display screen 28 opposite the LEDs 32 and a second set of photodetectors 38 along the upper side of the display screen 28 and opposite the LEDs 34. The LEDs 32 emit infrared rays, which propagate on substantially parallel across the surface of the display screen 28 to the photodetectors 36. Each of the LEDs 32 corresponds to a particular one of the photodetectors 36, so that the infrared beam from the LED hits that photodetector.

Similarly, the LEDs 34 emit infrared rays, which propagate upwardly along the surface of the display screen 28 in a generally parallel manner to the photodetectors 38. The LEDs 32 and 34 and the photodetectors 36 and 38 form an XY coordinate system of the beams. or radiates over the surface of the display screen 28. When the operator touches a particular spot on the display screen 28, as shown in Fig. 1, one or more of the infrared rays from the LEDs 32 and 34 will be interrupted.

A control logic box 40, which is connected to the photodetectors 36 and 38, responds by emitting a signal representing the particular location of the operator affected on the screen 28. The control logic box 40 does this by determining the Y-average position of the infrared rays from the LEDs 32, which rays are interrupted, and by determining the X average position of the infrared rays from the LEDs 34 which are interrupted. The resulting output signal from the control logic box 40 thus represents the X and Y means positions of the area on the display screen 28 which is touched by the operator. The control logic box 40 is of conventional construction and can be designed or purchased separately or in conjunction with the LEDs 32 and 34 and the photodetectors 36 and 38 as part of a complete touch input signal system 30.

The particular touch signal system 30 shown and described is for illustrative purposes only and it is clear that other touch systems which may provide an output signal indicating an area touched on the display screen 28 may be used. Other touch systems that can be used include a variety of manufactured products, such as those utilizing a conductive glass and plastic laminate, those utilizing acoustic waves, and those products in which a conductive pattern is etched on the display screen.

As will become more fully apparent from the following discussion, the data monitor 14 with associated touch input signal system forms a highly versatile and advantageous interface between operator and editing system 10. The editing system 10 can present any of a variety of editing information menus. and selection on the data monitor 14. 10 15 20 25 30 35 454 030 10 The operator then selects one or more of the editing choices by touching the characters on the presentation screen_28 that describe or represent these choices. Each time the display screen 28 is touched by the operator, the resulting output signal from the control logic box 40 is applied to a portion of the editing system 10, which portion compares this information with characters presented on the screen to determine the particular function selected by the operator. The system 10 then performs any requested editing functions and at the same time changes the information presented on the screen 28. These changes can be made by presenting a completely new menu of information and selections on the monitor 14 or simply by modifying the original menu presented. This allows the operator to concentrate on editing based on different levels or different types of functions. Due to the fact that the structure of a specially presented menu is in fact unlimited, considerable versatility and flexibility are also introduced in the editing system 10.

Pig 3 produces a block diagram of the editing system 10. The editing system 10 includes an operator interface 42, shown in Fig. 4 as including the control lever panel 18 and the specified keyboard 20, the ASCII keyboard 22, and the touch input system 30. The operator interface 42 is coupled to an editing controller 44 as well as a touch screen 14 data monitor.

Each time one of the keys or other controllers on the panel 18 or the keyboards 20 and 22 is actuated or the touch signal system 30 detects the touch of an area on the display screen of the data monitor 14, a corresponding signal is output to the editing controller 44.

In addition to providing menus of editing information and selections to the data monitor 14, the editing controller 44 controls all other parts of the editing system 10, including three different audio-video source tape recorders 46, 48 and 50, an audio-video recording tape recorder 52 and a switch and power generator 54. players 46, 48 and 50 leave their audio and video input signal to the switch and power generator 54. The switch and power generator 54 responds to instructions from the editing controller 44 and switches one or more several of the audio and video inputs thereto to the audio-video recorder 52. The video information recorded on the audio-video recorder 52 is also supplied to a preview switch 56, which is controlled by the editing controller 44. The preview switch 56 in turn outputs the video information for presentation on the video. 16. The preview switch 56 is required f for certain types of tape recorders, when used as audio-video recording tape recorders. Still other types of tape recorders have eliminated the need for the preview switch 56. The editing controller 44 is also connected to control a printer and paper belt system 58.

A flex disk system 60 controller 44 for both inputting data to and receiving data from the editing controller 44. The flex disk system 60 is an example of a mass storage medium that may be used for this purpose, with a variety of other types of mass storage media being useful for the purpose. . Instructions for the various menus to be presented on the data monitor 14 and the various editing functions recorded on a flex disk are initially fed from the disk system 60 into the editing control unit 44. As editing functions are performed, certain information indicating the position and nature may then be performed. of various editing functions, performed along the length of the tape in the audio-video recording tape recorder 52, are output by the editing controller 44 for storage in the flex disk system 60. Other mass storage systems may store the information in a separate programmable read only memory (PROM) or a charger utilizing memory (CCD ).

After the menus and other information are entered in the editing control unit 44 from the flex disk system is connected to the editing 60, the editing control unit 44 leaves a first information and selection menu on the data monitor 14. When the operator responds by pressing a key on one of the keyboards 20 and 22 or by touching the presentation screen 28 of the data monitor 14, the signal is sent from the operator interface 42 to the editing controller 44. The editing controller 44 identifies the editing function represented by the signal and then changes the presentation, if necessary. on the data monitor 14 by either making changes to the present menu or leaving a new menu to the data monitor 14. At the same time, any editing functions to be performed in the system 10 are performed under the control of the editing controller 44.

For example, when video information from one or more of the source tape players 46, 48 and 50 is to be recorded on the recording tape player 52, the editing controller 44 controls the included source tape players 46, 48 and 50, the recording tape player S2 and the switch and power generator 54. The processing of the various video information is synchronous. be carefully analyzed using the time code or control track recorded on the different band lengths and which identifies the recordings field by field. The editing controller 44 continues to respond to inputs from the operator interface 42 as well as ähamwampâümmmwml4æhußmrwmanß functions accordingly until all editing functions have been completed.

As previously pointed out, the editing controller 44 controls the source tape players 46, 48 and 50, the recording tape player 52 and the switch and power generator 54.

The editing controller 44 has a selection of cuts, gradients, transitions, and special effects. Insertion points are selected manually to control band speed and direction. Editing start and edit end points are marked manually in this mode. If desired, insertion points can also be selected by entering time code values for start and end points. Values for "pre-roll" and "post-roll" are also introduced, as is the duration of transitions and special effects. The audio-video source tape recorders 46, 48 and 50 are connected to the editing controller 44 via machine interfaces 62, 64 and 66, respectively. The audio-video recording tape player S2 is connected to the editing controller 44 by means of a machine interface 68. The printer and paper belt system 58 are connected to the editing controller 44 by means of an interface 70. The switch and power generator 54 is connected to the editing controller 44 by means of a switch interface 72. The various interfaces 62, 64, 66, 68, 70 and 72 serve to convert the data transmitted from and to the editing controller. 44 between a serial form, when data appears on the output of the editing controller 44, and a form suitable for use by the particular tape recorder component or other component to which the interface is connected. A particular type of tape recorder requires, for example, a DC voltage in the range from 0 V to +10 V for controlling tape movement forward and backward, while another type of tape recorder requires a signal which varies in frequency for controlling the tape motion. The various interfaces perform the applicable conversion of data from the editing controller 44 into such forms. A typical interface is described in detail in connection with Fig. 7.

Fig. 5 illustrates the basic functions performed by the editing controller 44, while Fig. 6 shows the controller 44 in detail. From Fig. 6, to which reference is first made, it can be seen that the editing control unit 44 comprises a central unit 74 and an associated memory 76. The memory 76 has both read-only memory parts (ROM) and direct access memory parts (RAM). The central unit 74 is connected to the flex disk system 60 via a disk control unit 78. The central unit 74 is also connected to the operator interface 42 via a character generator 80, which sends an output signal to the data monitor 14, which output signal represents the information presented on the monitor 14. When the information from the flex disk in the flex disk system 60 is input to the editing controller 44, this information is stored in the memory 76. The central unit 74 responds to the signals from the operator interface 42, which signals are applied via an intelligent line controller 82 and a data bus 84. On the basis of the signals transmitted from the operator interface 42, the central unit 74 performs any editing functions in the system 10 which are determined by those signals. At the same time, the central unit 74 makes a change to the menu currently presented on the data monitor 14 or presents a new menu, if required. This is accomplished by determining the desired characters to be presented on the data monitor 14 from the memory 76 and outputting these characters to the character generator 80. The character generator 80, which stores the various characters in dot matrix format, provides in response to those from the memory 76, the characters output a presentation of the desired characters on the monitor 14.

Included in the data stored in memory 76 from the flex disk system 60 are general instructions, designated operating systems 86 in Fig. 5. Operating system 86 controls four separate processes, termed instruction generator 88, presentation generator 90, input / control 92, and machine control 94. The four different processes 88, 90, 92 and 94 are performed in parallel under the control of the operating system 86. The instruction generator 88 determines on the basis of signals from the operator interface 42 what is to be done. This results in the generation of data, which is entered into a common database 96. The presentation generation process 90 involves the evaluation of the data entered in the common database 96 to determine what is to be presented on the data monitor 14. The presentation generator 90 provides any required data in connection with changes in the presentation to the character generator 80. The input / control process 92 provides control of the printer paper belt system 58 and file system as well as any other peripheral equipment in addition to the various tape recorders and switches. The machine control process 94 determines, on the basis of data entered in the common database 96, what actions are to be taken by the source tape recorders 46, 48 and 50, the recording tape recorder 52 and the switches. This results in appropriate instructions being issued by the editing controller 44 to the tape recorders and switches.

Due to the fact that the editing process has become increasingly sophisticated, the efficient use of expensive "on-line" editing time is of the utmost importance, edits, which are designed and previewed in less expensive time "off-line", must, on the other hand, be accompanied by a registration of the parameters for future reference, reproduction or transfer to equipment "on-line".

To ensure this, a list of such editing decisions is stored along with all the parameters necessary for their execution. This information can be stored in the flex disk system 60, in the memory 76 or in the printer and paper strip system 58, shown in Fig. 3.

If an editing session is interrupted, the editing decisions and parameters can be temporarily stored in one of these places for re-entry and termination later.

Once the editing design is complete, this information can be used to preview the editing or to transfer these edits to "on-line" equipment. Referring again to Fig. 6, the central unit may be any suitable central unit, such as the single card central unit sold under the designation LSI-11 by Digital Equipment Corporation. The memory 76 preferably has a direct access capacity of 64k bytes or more. A time generator 98 generates system time signals for the editing controller 44. As previously discussed, the touch signal system 30 operates in conjunction with the touch screen data monitor 14 to perform various functions in response to the operator touching the screen. These functions include the operation of the system, the data entry and the change of an editing decision.

The control lever panel 18 is used in conjunction with the touch input signal system 30 to provide manual transport control and selection of edit entry and exit points. The control lever panel 18 can also be used in conjunction with the specified keyboard 20 or ASCII keyboard 22. Together, the keyboard 20 or 22 and the panel 18 allow the operator to enter system editing data, select menus, adjust edit points and control the transport operation. The specified keyboard 20 has keys for particular system operations. All system operating functions are controlled by specified keys, such as preview, editing, searching, setting, rewinding, playback selection input / selection output, tone transition, and setting / adjusting input / output.

In addition, software keys on the specified keyboard 20 can be used by the editor to define functions, which can be changed from editing to editing.

Each such software key can be used to control the editing controller 44 in a manner similar to the operation of the touch input system 30 for changing items on a menu presented by the data monitor 14, or for changing menus.

The switch and power generator 54 can be used to select a cut, transition, fade or one of many different smear patterns. The smearing patterns occur from one source to another, allowing the choice of hard or soft edges. All effects are reversible to the direction. The fade mode creates a fade or fade of a foreground in a background.

The toning input signal effectively cuts a hole in the background in the form of the image to be toned, such as a title or text. The fade foreground fills the hole in the background.

Tint lengths can be selected. During all effects except toning, transitions in audio from one source to another occur.

To understand the nature of the various menus presented on the data monitor 14, it is helpful to consider a particular example of an editing system 10 with both primary menus and secondary menus, on which the primary menus are intended to perform the more commonly performed editing tasks. They typically have a moderate amount of information and allow the editor to follow the many steps without changing the menus while maintaining the total information presented to someone to avoid confusion and clutter. There are six primary menus, which include the following: l. System parameters. This is the first menu that appears on the data monitor 14 after the editing system has been turned on. It was used primarily as a reference point or sender, from which other menus are selected for editing. General controls for system start-up are typically found in this menu. 2. Edit decision list. This menu presents part of the current editing decision and provides the control for modifying it. Controls for preview edits are also presented with switch 54. 3. Edit decision list configuration. This menu was used to select editing decision parameters. The menu lists all parameters that can be used as headings on the editing decision list as well as their current configuration.

The menu retains several versions of editing decision headings and provides controls for adding, removing, or rearranging parameters in the editing decision lists. 4. Editing design. This menu includes an active presentation of the special edit that is being considered. It characterizes and allows the operator to select editing input and editing starting points, transports, scrolls and effects. This menu can be combined with a number of secondary menus to accommodate the menu, limiting more special editing requirements. 5. Transport configuration. This menu provides for selection and presentation of the status of transport parameters, such as logical order, channel for intelligent line control unit, interface type, roll number and transport condition.

In the present example, the secondary menus are designed for discrete, special editing functions and are not included in the primary menus. All secondary menus with the exception of a numeric keypad 10 15 20 25 30 35 454 030 I8 appear in addition to the lower part of the primary menus. The key pads cause the operator to enter numerical data, such as the duration of "pre-roll" and "post-roll". Transport controls for VCRs provide playback, rewind, fast forward, search and commute functions. Special effects are performed with a variety of flexible controls. Split audio and video editing modes can be selected from different points on the source video tapes. Guides for preview edits, cuts, transitions, smears, toning to or from black, and toning modes of programmable duration are included as well as controls over rolls - Fig. 7 shows the details of a typical of the interfaces, such as machine interfaces 62, 64, 66 and 68. As previously pointed out, each such interface provides bidirectional communication between the controller 44 and the tape recorder being controlled. The input to the interface includes a pair of serial data lines 100 and 102. The line 100 outputs serial data from a serial data processor 104 to the editing controller 44. Conversely, the line 102 provides serial data from the editing controller 44 to the serial data processor 104. The serial data processor 104 includes a universal asynchronous receiver. serial data to parallel form, before being added to central unit and memory 105. A personality module 106 is special for the particular peripheral device to which the interface refers, such as a tape recorder 108. The personality module 106 converts the parallel data from the central unit and memory l05 into transport instructions of suitable form for use in the tape recorder 108. As previously pointed out, different peripherals require different kinds of signals. Some tape recorders require, for example, a direct voltage to control the speed of the drive roller, while others require an AC signal, the frequency of which determines the tape speed.

The tape recorder 108 is connected to the central unit and the memory 105 both via the personality module 106 and a time code processor reader 110. The connection from the tape recorder 108 to the time code processor reader 110 provides connection for the time code track between the tape and the time code processor. reader 110. The time code track is typically read from the tape on the tape player 108 and passed to the time code processor reader 110, where it is decoded from a serial bit stream to parallel data.

Output signals from the interface in Fig. 7 to the editing control unit 44 consist of transport marking signals, state signals and time code data. The mark and state signals are passed through buffer circuits and then fed to the data bus 84 in the editing controller 44.

Serial time code data is converted to parallel data by the time code processor reader 110, as previously pointed out.

This data is then fed to the editing controller 44.

It was previously pointed out with reference to Fig. 6 that the operator interface 42 is connected to the central unit 74 via an intelligent line control unit 82.

In the present example, the editing controller 44 includes the intelligent control controller 82 and three additional intelligent control controllers 112, 114 and 116. The intelligent control controller 112 connects the central unit 74 to the machine interface 62. The intelligent control controller 114 connects the central unit 74 to the switch interface 72. the intelligent line controller 116 connects the central unit 74 to the machine interface 68. Each of the intelligent line controllers 82, 112, 114 and 116 includes an intelligent connection interface between the editing controller 44 and external peripheral devices, such as audio-video the tape recorders and the operator interface 42. The data transmitted from the central unit 74 on the data bus 84 has a parallel form. Each of the controllers 82, 112, 114 and 116 converts the data into serial form, before the data is supplied to the peripheral device. Conversely, data transferred from the peripheral device to the central unit 74 from serial form to parallel form by the various control units 82, 112, 114 and 116. In addition to conversion according to the data form, the various control units 82, 112, 114 and 10 operate. 030 20 116 which buffer circuits between the peripheral device and the central unit 74. The intelligent line controllers also verify data input formats, convert data formats and perform certain primary control unit functions, such as automatic time code and state requirements. The central unit 74 cannot simultaneously communicate with two or more sets of the peripheral device. However, the effect of the presence of the various control units is that a substantially simultaneous communication is achieved by receiving and holding data until the central unit 74 is free to receive such data.

The various intelligent line controllers 82, 112, 114 and 116 are identical in construction, one of which is shown in Fig. 8. The intelligent line controller shown in Fig. 8 includes a first bus receiver 118 which is connected to the central unit 74 for address transmission. and data between the intelligent line controller and the central unit 74. The bus transceiver 118 is connected to an ILC central unit 120 by means of an address bus 122 and a data bus 124. The address bus 122 is also connected to a direct access memory 126 of 4k and to a read memory 128 of lk. The data bus 124 is also connected to the direct access memory 126 of 4k and also to the read only memory 128 of lk. A second bus receiver 130 is connected to the central unit 120 via a control bus 132 and to the central unit 74 and is arranged to process time and control requirements, which are transmitted between the intelligent line control unit and the central unit 74.

An address comparator 134 has two different inputs, one from the bus transceiver 118 and the other from a short address selection switch group 136. The address comparator 134 compares the contents of the address received from the central unit 74 with the setting of the short address selection switch group 136.

If the comparison is positive, the comparator 134 requests control of the data and address buses 122 and 124 from the ILC control unit 120. When the intelligent line controller relinquishes this control, data is transmitted from the control unit 74 to the intelligent control controller. 454 454 030 21 unit with the direct access memory 126. in turn formats data in the memory 126 and then sends data via a universal asynchronous transmitter 138 to the interface, as shown in Fig. 7. Incoming serial data from the interface is converted to parallel form by the univer sella synchronous receiver-transmitter 138, which generates and outputs an interrupt signal to the ILC central unit 120.

When it processes the interrupt signal, the incoming data is formatted and written in the direct access memory 126. The new data in the memory 126 is then read by the central unit 174 by requesting bus control from the ILC central unit 120 and reading the data. The frequency with which the serial signals from the universal asynchronous receiver transmitter 138 are transmitted to the interface is determined by a transmission rate generator 140 in conjunction with a transmission rate selection switch group 142.

The switch and power generator 54 are shown in detail in Fig. 9. The intelligent line controller 114 associated with the switch 54 is connected via the switch interface 72 to the switch 54. The switch interface 72, which may be of the same construction as that shown in Fig. 7, is connected to receive composite synchronization signals and composite extinguishing signals. The switch interface 72 has an address bus 144 and a data bus 146 on its output side. The buses 144 and 146 are connected to a video processor mixer 148 on the output side of the switch 54 by means of either a video switching circuit 150 or a waveform generator 152 and a video data processor 154.

Buses 144 and 146 are also connected to an audio switching circuit 156.

The switch and power generator 54 are used substantially for mixing and spreading operations. In the case of a mixing operation, one of the inputs to the audio exchange circuit 156 and one of the inputs to the video exchange circuit 150 are fed to the video processor-mixer 148.

The video data processor 154 was also used in this operation. A smoothing operation is performed using the waveform generator 152 and the video data processor 154.

The ILC central unit 120 10 15 20 25 30 35 454 030 22 Pig 10 is a flow chart showing the manner in which the editing system 10 uses the data monitor 14 together with the touch input signal system 30 to convert the operator's decision into editing measures.

In a step 160 shown in Fig. 10, the system 10, via the editing controller 44, creates a list of valid decision choices to be presented to the operator. A specific set of operator requirements is considered valid at each specific point in an editing process. The editing controller 44 first determines this set of decision choices in step 160. This is usually a function of the type of action currently being performed. In addition, the editing controller 44 may need to review information received from other transmissions or sources, as well as information previously stored in the memory 76.

In a next step 162, each valid decision choice is presented on the data monitor l4 screen 28. Each decision choice in the set of valid choices includes several significant pieces of information. One of these is a description of where on screen 28 the selection is to be presented to the operator. An additional piece of information is the designation to be written on the screen 28, so that the operator can identify and understand the selection. Once a valid set of selections has been compiled, each designation is presented in its corresponding position on screen 28.

The operator is thus made aware of what the current set of choices consists of and is now expected to select one of them.

In a next step 164, the screen 28 of the data monitor 14 is scanned and a decision 166 is made as to whether or not a beam has been interrupted. Once the operator has determined which of the designations presented on the screen 28 corresponds to the action he wishes the editing system 10 to take, he places a finger (or other object) on that designation on the screen 28. As previously pointed out, LEDs 32 and 34 emit. mounted next to the screen 28, infrared light beams directed at each of the photodetectors 36 and 38. Placing the operator's finger 10 in a particular position on the screen 28 results in one or more of the photodetectors 36 detects an interruption in the infrared rays normally received by the detector or detectors. By periodically examining the output signals from the photodetectors 36 and 38, the editing system detects the presence of a finger.

By assigning numerical values to the different photodetectors 36 and 38, the editing system can also calculate numbers representing the horizontal and vertical coordinates of the finger on the screen 28. As a result of the periodic examination of the output signals from the photodetectors 36 and 38, the decision 166 indicates whether a or several of the infrared rays have been interrupted or not.

If the decision 166 means that one or more of the infrared rays has been interrupted, then in a next step 168 the distance from the finger to each of the decision choices presented on the screen 28 is calculated.

It was previously pointed out that each selection presented on the screen 28 is associated with an indication of a position on the screen where it is presented. Each element in a set of selections is examined and the distance between the position belonging to the selection and the position of the finger is calculated. The choice that has the smallest distance from the position of the finger is assumed to be that intended by the operator. If the finger is too far away from the next selection, no action is taken.

These measures are represented by a decision 170 shown in Fig. 10.

If the decision 170 results in a determination "yes" indicating that the finger has placed at least a nominal distance from one of the decision choices and that the choice has been determined to be the one desired by the operator, the value associated with the choice is determined in a subsequent step 172.

Each choice in a set of plague-tuned choices has a value. During step 172, the value associated with the selection made by the operator is determined. Using this value, the editing system 10 performs the desired action, which is represented in a subsequent step 174 in Fig. 10. The value determined in step 172 corresponds to the type of signal emitted when either the specified key the table 30 or the ASCII keyboard 22 is used.

The various operations depicted in the flow chart of Fig. 10 can be better understood by considering an example. If it is assumed that at a particular point in an editing session the operator is expected to enter a number between 0 and 9, then under these conditions there are ten possible choices. Each of the selections includes a position on the screen of the data monitor 14. For each selection, a designation is written on the screen 28, so that the numbers "1", "2", "3", etc. are presented on the screen. If the operator wishes to select the number "7", he places a finger on the screen 28 at the place where the designation "7" has been presented. The infrared rays corresponding to this place are interrupted and the editing system determines the horizontal and vertical coordinates of the finger. of the ten possible choices is examined and the distance between its position on the screen 28 and the position of the finger on the screen 28 is calculated.In the present example, the choice corresponding to the number "7" is determined to be the closest. example, the value for "7" could be the ASCII code for '7 ". This is the value that most computer and communication equipment uses to represent a key designated "7." The editing system 10 now uses this value as if it had come from a conventional keyboard or communication device, such as the specified keyboard. 20 or the ASCII keyboard 22.

Claims (11)

10 15 20 25 30 454 030 25 PATENT REQUIREMENTS An audio / video editing system, comprising at least one source recording device (46, 48, 50), which forms a source of audio / video information to be edited; a recording apparatus (52) for recording selected, edited audio / video information from said source recording apparatus (46, 48, 50); a switching device (54) for selectively interconnecting said source recording device (46, 48, 50) and the recording recording device (52); computer means (74) for providing selected editing instructions; an operator-controlled input device (18, 20, 22, 30), comprising presentation / indicating means for the editing functions for outputting multiple, serial editing function messages, which indicate the selected editing functions to be performed by the recording devices and the switching device (54): characterized of an intelligent operator management controller (82) coupled to the operator controlled input device (18, 20, 22, 30) for identifying, converting and buffering the multiple serial editing function messages into simultaneous, parallel editing function messages in corresponding multiple parallel channels to responding to the computer body's editing instructions to provide corresponding simultaneous, multiple, parallel editing instructions; a plurality of intelligent machine control controllers (112, 114, 116) connected to the intelligent operator control controller (82) via the multiple parallel channels for establishing simultaneous parallel connections with each of the recording devices (46, 48, 50, 52) and the switching device (54), and for converting and buffering the parallel editing instructions to define serial editing instructions depending on the computer means 10 15 20 25 30 35 454 030 26; a plurality of interfaces (62, 64, 66, 68, 72), which are connected between each of the intelligent control line controllers (112, 114, 116) and each of the recording devices (46, 48, 50, 52) and switch the device (54) for translating the various simultaneous, serial editing instructions into a form corresponding to the requirements of the respective devices, and for the simultaneous translation of device editing state messages from the respective device, when they occur for retransmission to the associated intelligent machine control controller (112, 114, 116) depending on the computer means; the intelligent machine control controllers (112, 114, 116) each further converting and buffering their serial editing instructions and their returned device editing state messages and simultaneously transmitting the device editing state messages to the intelligent operator control unit (82) in parallel with each of the the channels (84) to enable continuous real-time editing operations depending on the computer means. System according to claim 1, characterized in that the display / indicating means comprise a cathode ray tube (26) with a display screen (28), and display means (30), which are arranged in the event of an operator touching a special portion of the display screen (28). to give the computer means a corresponding indication of the selected editing functions to be performed. A system according to claim 2, characterized in that the indicating means comprise means for selecting a menu of selected editing functions for presentation on the presentation screen (28) in response to the operator's touch of the editing information presented in a specific mode on the presentation screen. A system according to claim 1, characterized in that each of the line controllers (82, 112, 114, 116) is arranged to convert data between parallel form and serial form to allow optional separation of 454 030 27 the operator-controlled input device, the recording devices and the switch device (54) from the respective line control unit and from the computer means. A system according to claim 1, characterized in that the operator-controlled input device further comprises at least one keyboard (20, 22) with a plurality of keys, which represent the selected editing functions. The system of claim 2, wherein the operator-controlled input device further comprises at least one control lever panel (18) and control keys for outputting additional serial editing function messages indicating additional characteristic editing functions. The system of claim 1, wherein the interfaces comprise a first interface (62, 64, 66) coupled to said source recording device (46, 48, 50); a second interface (68) coupled to the recording device (52), and a third interface (72) coupled to the switching device (54): and each of the interfaces comprises a serial data processor (104) and a of this actuated data conversion module (106) for converting data between serial form and the particular forms required by the various devices. k ä n n e t e c k n a t k ä n n e t e c k n a t The system of claim 7, wherein each interface serial data processor (104) is connected to the respective line controller (112, 114, 116), a time code processor (110) is connected to the serial data processor (104), and the data conversion module (106) is connected from the serial data processor for the corresponding recording device and switch device. System according to claim 7, characterized in that the intelligent machine control units (112, 114, 116) comprise a first, a second and a third control unit which connect the corresponding first, second and third interfaces (62, 68, 72) to the system. intelligent 454 030 10 15 28 operator line controller (82) and to the computer means; and that the control units are each arranged to convert data from serial form to parallel form and vice versa and to store parallel data under the instruction of the computer means. 0 System according to claim 9, characterized in that the control units (112, 114, 116) each comprise a central unit (120), a transceiver (118, 130) which connects the central unit to the computer means, a memory (126, 128) which is connected to the central unit and to the transceiver, and an address comparator (134) which is connected between the transceiver and the central unit. 11. ll. System according to claim 10, characterized in that a receiver transmitter (138) is connected from the central unit (120) to the respective interface and is arranged to convert data between parallel form and serial form.