GB2255696A - Audio mixer systems - Google Patents

Abstract

An audio mixer system, for use with a parallel editor interface, uses a configuration selector (30) to select a desired configuration of a plurality of multichannel devices (80) in order to enable such various configurations and reconfigurations. An output of the configuration selector (30) may be provided to a memory (50) to select prestored commands to be provided to appropriate channels. Additionally or alternatively, the configuration selection signals are decoded (40) and supplied to multiplexers (60) in combination with editor control signals to enable the editor control signals to be routed to appropriate channels. <IMAGE>

Description

AUDIO MIXER SYSTEMS This invention relates to audio mixer systems, for example audio for video mixer systems.

In order to accomplish audio editing, it is known to use a mixer to control a plurality of multi-channel devices, such as video tape recorders (VTRs), for example. It is also known that an editor may be advantageously used to control the mixer via a parallel editor interface to enable various VTR functions including PREVIEW/REVIEW and FADE UP/DOWN, for example. In general, the PREVIEW/REVIEW functions require a digital signal (e.g. 5 or O V) to be supplied to an appropriate channel to activate the channel. The FADE UP/DOWN functions generally require analog signals (0-5 V, for example) to be supplied to the appropriate channels.

These signals are commonly referred to as VCA signals and are supplied to voltage controlled amplifiers associated with the channels.

Other analog and digital control signals may be used to implement other known functions.

Generally, in a mixer system, a mixer is connected to a plurality of devices such as VTRs or other multi-channel devices, for example.

The mixer may also be connected to an editor via a parallel editor interface to enable editor control of the mixer. However, such prior systems generally enable editor control of either only all four-channel devices or only all two-channel devices. This is clearly an undesirable limitation. Some systems allow for the use of hard wired jumpers to enable various combinations of two and four-channel devices to be used. This avoids the above-mentioned undesirable limitation, but adds a new drawback in that using hard wired jumpers is time consuming and can be difficult if several devices are to be connected.

Additionally, if it is desired to reconfigure the devices, for example to replace a four-channel device with 2 two-channel devices, rewiring is necessary, once again requiring a time consuming operation.

To further elaborate, if a mixer has twenty channels, for example, it is possible to connect 5 four-channel devices or 10 twochannel devices or some combination thereof, for example 2 four-channel devices and 6 two-channel devices.

In order for the editor control signals to be sent to a selected device, it must be known what channels of the mixer are associated with that device. If, as in the prior art, all four-channel devices, for example, are used, it is known that device 1 corresponds to channels 1 4, device 2 corresponds to channels 5-8, etc. For this reason, some prior art systems do not allow the flexibility of using two and fourchannel devices together under editor control. However, as described above, some systems allow a combination of two and four-channel devices but require hard wired jumpers to enable editor control signals to be sent to the appropriate device. The disadvantages of these systems are pointed out above.

According to the invention there is provided an audio mixer system comprising comprising: audio mixer means for mixing audio signals from a plurality of devices comprising a combination of devices having a first number of channels and devices having a second number of channels; editor control means operatively connected with said audio mixer means for controlling the audio mixer means by editor control signals; configuration selection means for enabling selection of a desired configuration of said plurality of devices and for producing configuration selection signals corresponding to a selected configuration; storage means for storing device control information in a plurality of memory locations wherein said memory locations are accessed by said editor control signals and said configuration selection signals; and means associated with said storage means for outputting to said audio mixer means device control information which is stored at said accessed memory locations.

The invention also provides an audio mixer system comprising: audio mixer means for mixing audio signals from a plurality of devices comprising a combination of devices having a first number of channels and devices having a second number of channels; editor control means operatively connected with said audio mixer means for controlling the audio mixer means by editor control signals; configuration selection means for enabling selection of a desired configuration of said plurality of devices and for producing configuration selection signals corresponding to a selected configuration; and switching means responsive to said editor control signals and said configuration selection signals for selectively routing said editor control signals to said plurality of devices.

Further, the invention provides an audio mixer under editor control, via a parallel editor interface, which is connected to a plurality of VTRs or other devices including multi-channel devices. A configuration selector is provided for selecting a desired configuration of the plurality of devices. The configuration can include various combinations of two and four-channel VTRs, for example.

According to a first embodiment, the output of the configuration selector is provided to a multiplexer or other type of switching apparatus which is also responsive to editor control signals for routing editor control signals (e.g. analog signals) to selected channels of the mixer to enable various operations including FADE UP/DOWN. According to a second embodiment, the output of the configuration selector is provided to a memory for selecting a portion of a memory address. Signals from the editor are also provided to the memory to select another portion of the memory address.Based on the selected address, previously stored control signals (e.g. digital signals) can be provided to selected channels of the mixer to enable various operations including PREVIEW/HEVIEW. According to a third embodiment, the output of the configuration selector is provided to both the switching apparatus and to the memory to enable both analog and digital control signals to be supplied to selected channels of the mixer to enable various functions to be performed including those described above with respect to the first and second embodiments.

Embodiments of the invention provide the following advantageous features: a mixer can easily be configured and reconfigured for many different combinations of two and four-channel VTRs; the configuration selector enables multiple configurations of VTRs easily to be implemented under editor control; analog control signals can be provided to a mixer based on preselected configuration information; and digital control signals can be provided to a mixer based on preselected configuration information.

The invention will now be further described, by way of illustrative and non-limiting example, with reference to the accompanying drawings, in which: Figure 1 is a simplified block diagram of a mixer system embodying the invention; Figure 2 is a more detailed representation of the mixer system shown in Figure 1; Figure 3 is a VTR configuration chart illustrating various configurations of two and four-channel VTRs and a corresponding Mode number for each such configuration; and Figures 4A and 4B collectively are a detailed schematic diagram of a mixer system according to a preferred embodiment of the invention.

Figure 1 is a block diagram of an exemplary mixer system according to a preferred form of implementation of the invention, which is (for example) in the form of an audio for video mixer system. A more detailed representation of the system is shown in Figure 2. The system of Figures 1 and 2 includes an editor 10 connected through an interface, preferably a parallel editor interface 20, to a mixer 70, which is turn is connected to a plurality of devices to be controlled by the editor, e.g. a plurality of multi-channel VTRs 80. For convenience only, the following description will refer to VTRs, but it is to be understood that the invention is not so limited. Other devices, including other multi-channel devices, may be used with this invention.

As shown in Figures 2 and 3, some of the VTRs 80 may be of the two-channel type and some may be of the four-channel type. For editor control operations, it is necessary to know which configuration, i.e., a particular combination of two and four-channel VTRs, is being used, so that if an operator desires to PREVIEW the audio from a VTR 2, for example, the signals from the channels associated with the VTR 2 can be monitored. In general, this occurs by activating the channels associated with the VTR 2 in a manner discussed in more detail below.

The mixer system comprises a configuration selector 30 to enable the Mode number of a selected configuration of VTRs to be selected.

The Mode number corresponding to a selected configuration can be obtained from a configuration chart, for example as shown in Figure 3.

The VTR Configuration Chart of Figure 3 shows one example of various possible configurations of two and four-channel VTRs. The invention is not limited to these configurations and more or less combinations may be desirable. Additionally, devices other than VTRs may be used.

As shown in Figure 3, for a mixer with 20 channels (1-4, 5L, 5R, 6L, 6R, . . . 12L, 12R) ten different configurations may be desirable, for example. A first configuration could be 5 four-channel VTRs as indicated by Mode 0. Mode 1 corresponds to 1 four-channel VTR and 8 two-channel VTRs. Mode 2 corresponds to 2 four-channel VTRs and 6 twochannel VTRs, and so on, down to Mode 9 which corresponds to 10 twochannel VTRs.

A desired configuration is set up, and the Mode number corresponding to the desired configuration is selected, using the configuration selector 30 (Figure 1, for example) which may be a rotary thumbwheel switch bearing numbers 0-9 or any other suitable selection apparatus. If more than 10 configurations are desired, two thumbwheel switches bearing digits 0-9 could be used to permit 100 combinations, and so forth.

Of course, other selection apparatus and displays can be used and such variations will be readily apparent to one of ordinary skill in the art. Other methods of associating a Mode number with a particular configuration and other configuration selection devices will also be readily apparent to one of ordinary skill in the art.

According to a first embodiment, with reference to Figure 1, the output of the configuration selector 30 is provided to a decoder 40 so that the output can be decoded in a known manner to generate a signal corresponding to the selected configuration. The output of the decoder 40 is then applied to a multiplexer 60 which supplies signals, e.g. VCA signals, to selected channels of the mixer 70 associated with the VTRs 80.

The multiplexer 60 is responsive to the decoded configuration selector output signals and editor control signals sent from the editor 10. In this embodiment, the multiplexer 60 is used to cause editor signals, e.g. analog VCA control signals, to be appropriately routed to channel(s) associated with a selected VTR. For example, the multiplexer 60 can be used to route VCA control signals from the editor 10 to individual or plural channels of the mixer 70 to enable FADE UP/DOWN functions to be implemented (in a known manner) for one or more channels of the VTRs 80.

A preferred circuit layout for implementing this embodiment is presented in Figure 4A, the operation of which will be readily apparent to one of ordinary skill in the art in connection with the description contained herein. Reference numerals appearing in Figure 4A (and 4B) correspond to those described with reference to Figure 1. As shown in Figure 4A, various editor control signals from the editor 10 are supplied to the multiplexer 60. Additionally, output signals from the configuration selector 30 are decoded by the decoder 40 and are also supplied to the multiplexer 60. These signals are collectively used by the multiplexer 60 to route the editor control signals to the mixer 70.

The decoding of the configuration selector output signals may be implemented by hard wired logic circuitry as shown in Figure 4A or by using PALs, for example. Other types of decoding may also be used as will be readily apparent to one of ordinary skill in the art.

According to this embodiment, the editor control signals generally comprise a portion containing data indicating which device is to be controlled and a portion containing function data, for example VCA control signals.

This embodiment is advantageously used with, but is not limited to, analog control signals, e.g. 0-5 volt signals, which are to be supplied to one or more channels of the mixer 70. Preferably, these analog signals are VCA control voltages which are supplied to a particular channel based on selections made at the editor 10.

If the configuration is changed, the operator merely needs to manipulate the configuration selector 30 to the Mode number corresponding to the new configuration, thereby automatically causing the signals from the decoder 40 to change and concomitantly causing the multiplexer 60 to reroute the signals to the appropriate channels.

According to a second embodiment, with reference to Figure 1, the output of the configuration selector 30 is supplied to a memory 50.

The memory 50 may be one or more EPROMS containing previously stored data. This data may correspond to digital control signals for controlling the activation of various channels of the mixer 70.

Preferably, the data is stored in a format comprising pages and portions of pages (e.g. memory locations) which are accessed by providing address signals to the memory 50. As best illustrated in Figure 4B, a portion of the address is selected based on the output signal from the configuration selector 30. Preferably, this output selects a page of the memory 50. Another portion of the address corresponding, for example, to a portion of the selected page (memory location), is selected based on control signals from the editor 10.

The data contained in the selected memory location of the selected page is then outputted to the mixer 70. For example, selected data may enable one or more channels of a selected VTR to be activated to enable a PREVIEW operation.

According to this embodiment, the editor control signals generally comprise a portion containing data indicating which device is to be controlled and a portion containing function data, for example PREVIEW control signals.

For example, assume the VTRs are configured in a manner corresponding to Mode 3 (Figure 3). If a user desires to preview VTR 4, for example, then it would be desired to control the mixer to activate channels 9L and 9R (i.e. the channels associated with the VTR 4). Preferably, this is done by providing a HIGH (or LOW) level logic signal (e.g. 5 or 0 volts) to the channels 9L and 9R. To accomplish this, the configuration selector 30 would be set to Mode 3 thereby generating an output signal which is supplied as first address information to select the appropriate page of the memory 50. This page preferably contains data corresponding to the configuration of Mode 3, in this case.The editor 10, in response to the operator's selection of PREVIEW VTR 4, would supply an editor control signal as second address information to the memory 50 to enable data stored in a memory location associated with the particular portion of the selected page of the memory 50 to be supplied to the mixer 70. This data is preferably a signal which would activate the channels 9L and 9R, in this case. In this way, the PREVIEW VTR 4 command can be executed.

If the VTR configuration is changed, the operator merely needs to manipulate the configuration selector 30 to the Mode number corresponding to the new configuration, thereby automatically selecting a new page of the memory 50 to enable editor control signals once again appropriately to be supplied to the channels associated with the selected device, despite the reconfiguration of the devices.

This embodiment is advantageously used with, but is not limited to, supplying a digital HIGH or LOW level logic signal (e.g. 5 or O volts) to one or more channels of the mixer. These digital signals may be used, for example, to activate or deactivate a particular channel.

Of course, if desired, analog signals could also be stored and accessed in a similar manner According to a third embodiment, the output of the configuration selector 30 is supplied to both the multiplexer 60 (through the decoder 40) and the memory 50 to enable a combination of the separately aforedescribed features to be implemented. In this way, both analog and digital control signals can be most efficiently supplied to appropriate channels even if different VTR configurations are used.

Referring again to Figure 3, there is shown only one configuration for each combination of two and four-channel VTRs capable of use with a 20 channel system. That is to say, for example, if 1 four-channel VTR and 8 two-channel VTRs are desired, the four-channel VTR is shown to be associated with the first four channels (1-4). Of course, if it were desired to enable various permutations of a given configuration, additional Mode numbers could be assigned. For example, as indicated above, Mode 1 corresponds to 1 four-channel VTR and 8 twochannel VTRs, where channels 1-4 are associated with the four-channel device and the remaining channels are associated with the two-channel devices. If, for example, it were desired to have 2 two-channel devices associated with channels 1-4, the four-channel device associated with 5L, 5R, 6L and 6R, and the remaining two-channel devices associated with channels 7L, 7R - 12L, 12R, this would constitute a permutation of the configuration of Mode 1, i.e. a different ordering of the combination of 1 four-channel device and 8 two-channel devices.

Claims (13)

1. An audio mixer system comprising: audio mixer means for mixing audio signals from a plurality of devices comprising a combination of devices having a first number of channels and devices having a second number of channels; editor control means operatively connected with said audio mixer means for controlling the audio mixer means by editor control signals; configuration selection means for enabling selection of a desired configuration of said plurality of devices and for producing configuration selection signals corresponding to a selected configuration; storage means for storing device control information in a plurality of memory locations wherein said memory locations are accessed by said editor control signals and said configuration selection signals; and means associated with said storage means for outputting to said audio mixer means device control information which is stored at said accessed memory locations.

2. An audio mixer system according to claim 1, wherein said editor control means comprises parallel editor control means.

3. An audio mixer system according to claim 1 or claim 2, wherein said configuration selection means comprises a thumbwheel switch.

An An audio mixer system according to claim 1, claim 2 or claim 3, wherein said storage means comprises one or more EPROMS.

5. An audio mixer system according to any one of the preceding claims, comprising decoder means operably connected to decode said configuration selection signals.

6. The audio mixer system of claim 5, wherein said decoder means comprises PAL circuitry.

7. An audio mixer system according to any one of the preceding claims, comprising switching means responsive to said editor control signals and said configuration selection signals for selectively routing said editor control signals to said plurality of devices.

8. An audio mixer system comprising: audio mixer means for mixing audio signals from a plurality of devices comprising a combination of devices having a first number of channels and devices having a second number of channels; editor control means operatively connected with said audio mixer means for controlling the audio mixer means by editor control signals; configuration selection means for enabling selection of a desired configuration of said plurality of devices and for producing configuration selection signals corresponding to a selected configuration; and switching means responsive to said editor control signals and said configuration selection signals for selectively routing said editor control signals to said plurality of devices.

9. An audio mixer system according to claim 8, wherein said editor control means comprises a parallel editor control means.

10. An audio mixer system according to claim 8 or 9, wherein said configuration selection means comprises one or more thumbwheel switches.

11. An audio mixer system according to any one of claims 7 to 10, wherein said switching means comprises a multiplexer.

12. An audio mixer system according to any one of the preceding claims, wherein said plurality of devices comprises a combination of two and four-channel VTRs and said desired configuration corresponds to a particular combination of said two and four-channel VTRs.

13. An audio mixer system substantially as herein described with reference to the accompanying drawings.