JP3649347B2 - I / O switching device and matrix switcher control device - Google Patents

Description

[0001]
【table of contents】
The present invention will be described in the following order.
Industrial application fields
Conventional technology
Problems to be solved by the invention
Means for solving the problem
Action
Example (FIGS. 1 to 11)
(1) Virtual matrix space
(2) Virtual matrix space control system (Fig. 1)
(2-1) Overview
(2-2) Configuration of matrix switcher system (Figs. 1-6)
(2-2-1) Overall configuration (FIG. 1)
(2-2-2) Configuration of system configuration management unit (FIGS. 2 to 4)
(2-2-3) Processing procedure in the system configuration management unit (FIG. 5)
(2-2-4) Processing procedure in matrix switcher (FIG. 6)
(3) Mode of switching control (FIGS. 7 to 11)
(3-1) Association between physical space and virtual matrix space (FIGS. 7 to 9)
(3-2) Application example (FIGS. 10 and 11)
(4) Other embodiments
The invention's effect
[0002]
[Industrial application fields]
The present invention relates to an input / output switching device and a matrix switch control device, and can be applied to, for example, a switch used for editing video signals and the control device.
[0003]
[Prior art]
The switcher is widely used as an apparatus for switching a plurality of signals (video signal, audio signal, time code signal, other control signals, etc.) to a plurality of output destinations at the time of editing. In the switcher, the cross points of the input line and output line are arranged in a matrix, and the output destination of the input signal can be switched according to the user's operation, or the input signal can be distributed to a plurality of output lines simultaneously. It has been made possible.
[0004]
[Problems to be solved by the invention]
However, when a system is configured by using a plurality of such matrix switches, there is a problem that it is difficult to design the system because the selection range of terminal arrangement is narrow. For example, a video matrix switch having 64 input terminals and 64 output terminals and an audio matrix switch having 32 input terminals and 32 output terminals are stacked one by one. When the above system is constructed, the input terminals and output terminals of the paired video signal and audio signal must be assigned and connected to 32 consecutive terminals, and the selection range of the terminal arrangement is limited. This also has the problem that system design becomes difficult.
[0005]
As a method of expanding the selection range, it is conceivable to use a matrix switcher having up to 64 input terminals and 64 output terminals for an audio matrix switcher. However, there are input / output terminals and crosspoints that are not used. There were many problems.
In addition, when it is desired to control the component video signal and the composite video signal at the same time by using two stacked matrix switches, if the individual video signals are controlled individually, eight input terminals and eight output terminals are provided. For example, two matrix switches having 16 input terminals and 16 output terminals have to be used, which can be controlled by the small matrix switch provided. Even in this case, there is a problem that a lot of waste occurs in the terminals and cross points.
[0006]
The present invention has been made in consideration of the above points. An input / output switching device and a matrix switcher control device that can flexibly construct a system and can use terminals effectively as compared with the prior art. Is to try to propose.
[0007]
[Means for Solving the Problems]
In order to solve such a problem, in the present invention, virtual information input means for inputting virtual information so that the matrix switching means that physically exists can be controlled by virtual stacking information, virtual input information, and virtual output information; Conversion means for converting these virtual information into physical information is provided.
[0008]
[Action]
The conversion unit converts the virtual stacking information, virtual input information, and virtual output information input by the virtual information input unit into physical stacking information, physical input information, and physical output information, and supplies them to the matrix switching unit.
[0009]
【Example】
Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.
[0010]
(1) Virtual matrix space
Here, the concept of a virtual matrix space is first used in order to realize simple control of the matrix switch by the user. The virtual matrix space is formed by arranging cross points, which are logical entities, in a three-dimensional lattice pattern. Here, the three dimensions are obtained by adding dimensions corresponding to the number of matrix switches to the two dimensions of input and output, and each dimension is logically present. In this embodiment, the construction of the system configuration can be made flexible and effective by appropriately associating the cross points of the physical matrix switch with the cross points on the virtual matrix space.
[0011]
(2) Virtual matrix space control system
(2-1) Overview
Now, if the crosspoint can be operated in a virtual matrix space that is conveniently constructed for the system without being conscious of the physical crosspoint, it is possible to construct a system that is very convenient for the user. . In order to realize this, this embodiment realizes this by providing a conversion mechanism for converting the position information of the cross points in the virtual matrix space into the position information of the physical cross points. This mechanism is a system configuration management unit described in the next section. The system configuration management unit is also provided with a mechanism for inversely converting physical crosspoint control information to crosspoints in the virtual matrix space in order to notify the user of the physical crosspoint control results.
[0012]
(2-2) Configuration of matrix switcher system
(2-2-1) Overall configuration
FIG. 1 shows a configuration example of a matrix switcher system 1 having these management functions. The matrix switcher system 1 shown in this example includes two matrix switches 2A and 2B, a control panel 3 used for instructing switching on a virtually constructed matrix space, and an input to the control panel 3. The system controller 4 and the system configuration management unit 5 convert the virtual crosspoint information thus obtained into physical crosspoint information.
[0013]
Here, the control panel 3 is used to input virtual stacking information Z, virtual input information Y, and virtual output information X, which are connection information in the virtual matrix space, and a matrix based on the connection information in the virtual matrix space. The switch 2A or 2B is used to notify the user by lighting or the like of whether or not the switch 2A or 2B has actually been switched.
[0014]
Further, the system controller 4 sends a switching signal S1 such as virtual stacking information Z input via the control panel 3 to the system configuration management unit 5 and a response signal to the switching signal S1 input from the system configuration management unit 5 S2 is transferred to the control panel 3.
[0015]
Further, the system configuration management unit 5 located between the system controller 4 and the matrix switches 2A, 2B functions as a means for associating the cross points in the virtual matrix space with the cross points in the matrix switches 2A, 2B. Yes.
In this connection, the correspondence operation here refers to the virtual stack information Z, the virtual input information Y, and the virtual output information X given by the switching signal S1, the physical stack information z, which is the switching signal S3 of the matrix switches 2A and 2B, The operation of converting into static input information y and physical output information x and its inverse conversion operation.
[0016]
That is, the system configuration management unit 5 converts the cross point position information in the virtual matrix space designated by the user into physical cross point position information and sends it to the matrix switches 2A and 2B, and the matrix switch 2A, The position information of the cross point in the physical matrix space after the switching control sent back from 2B is inversely converted into the position information of the cross point in the virtual matrix space and sent back to the system controller 4.
[0017]
As a result, the crosspoint of the matrix switch which is physically present can be determined by instructing the control panel 3 to switch the crosspoint in the virtual matrix space without the user being aware of the physical crosspoint. It can be switched. Further, the user can grasp on the control panel 3 the switching state by the matrix switch that physically exists as the switching state in the virtual matrix switch.
[0018]
(2-2-2) Configuration of system configuration management unit
Here, FIG. 2 shows a detailed internal configuration of the system configuration management unit 5 described in the previous section. The system configuration management unit 5 is configured with a control circuit 5A as a center, and is configured to transmit and receive the response signal S2 and the switching signal S3 via the I / O interface unit 5B.
[0019]
The random access memory 5C is used for storing data transmitted and received through the I / O interface unit 5B. The random access memory 5C includes virtual information such as virtual stack information Z received via the I / O interface unit 5B and physical information such as physical stack information z transmitted via the I / O interface unit 5B. Is to be stored.
[0020]
When the virtual stack information Z or the like is stored in the random access memory 5C, the control circuit 5A develops the virtual stack information Z and virtual input information Y into a set of virtual stack information Z and virtual input information Y in order to convert them into physical information. It is expanded into a set of output information X and collated with two conversion tables 5D and 5E.
Among these, the conversion table 5D is a table for converting the virtual stacking information Z and the virtual output information X into the physical stacking information z and the physical output information x, and is configured as shown in FIG. 3, for example. The conversion table 5E is a table for converting the virtual stacking information Z and the virtual input information Y into the physical stacking information z and the physical input information y, and is configured as shown in FIG. 4, for example.
[0021]
An example of the conversion operation using these two conversion tables 5D and 5E will be described with reference to FIGS. Assuming that “1” is input as the virtual stacking information Z and “1” and “2” are input as the virtual output information X and the virtual input information Y, respectively, the control circuit 5A has virtual information composed of three parameters. Are expanded into a set “1, 1” of the virtual stacking information Z and virtual output information X and a set “1,2” of the virtual stacking information Z and virtual input information Y, which are respectively converted by conversion tables 5D and 5E. It is converted into a set “2, 1” of physical stacking information z and physical output information x and a set “2, 2” of physical stacking information z and physical input information y.
[0022]
When two sets of physical information are obtained in this way, the control circuit 5A confirms that the physical stack information z of each set matches, and the physical stack information z and the physical output information output as the switching signal S3. Reconstruct x and physical input information y. As a result, “2, 1, 2” is stored in the random access memory 5C as the physical stack information z, the physical output information x, and the physical input information y.
[0023]
(2-2-3) Processing procedure in the system configuration management unit
Next, a processing procedure executed by the system configuration management unit 5 will be described. The control circuit 5A starts processing from step SP1, and first determines whether or not a command is input via the I / O interface unit 5B at step SP2. Here, while a negative result is obtained, this determination process is repeated and the input of a command is awaited. If a command is input and a positive result is obtained, the process proceeds to step SP3 to determine whether the command is a switching command input from the control panel 3.
[0024]
If an affirmative result is obtained here, the control circuit 5A moves to the processing of step SP4, where the virtual stacking information Z, the virtual input information Y and the virtual output information X are combined with the virtual stacking information Z and the virtual output information X, It develops into a set of information Z and virtual input information Y.
When the expansion process is completed, the process proceeds to the subsequent step SP5, where a combination of the physical stacking information z and the physical output information x is extracted by applying to the conversion table 5D for XZ conversion.
[0025]
Further, when this process is finished, this time, in step SP6, a combination of the physical stacking information z ′ and the physical output information y is extracted by applying to the conversion table 5E for YZ conversion.
When the conversion work to the physical information is completed by the conversion tables 5D and 5E in this way, the control circuit 5A moves to the processing of step SP7, and the physical stacking information z and the information obtained from the conversion tables 5D and 5E and It is determined whether z ′ matches each other.
[0026]
This is because if the physical stacking information does not match, the matrix switcher to which the signal is input and the matrix switcher to which the signal is output are different, so that the physical switching operation cannot be performed practically. It is.
If an affirmative result is obtained in step SP7, the control circuit 5A moves to the processing of step SP8 because it is confirmed that the conversion results are virtually consistent, and the physical data obtained by the conversion tables 5D and 5E is obtained. Physical stacking information z, physical output information y, and physical input information x are reconstructed from two sets of information (x, z) and (y, z ′).
[0027]
Thereafter, the control circuit 5A outputs the physical stack information z, the physical output information y, and the physical input information x to the matrix switches 2A and 2B via the bus, and the series of processes is terminated at step SP10.
On the other hand, if a negative result is obtained in step SP7, the control circuit 5A directly moves to step SP10 because there is no control object to be actually controlled, and the series of processes is terminated.
[0028]
The above processing is processing when an affirmative result is obtained at step SP3. However, when a negative result is obtained at step SP3, the control circuit 5A receives a response signal for the switching result from the matrix switch 2A or 2B. If not, the process proceeds to step SP11. Here, the control circuit 5A expands the physical stack information z, the physical output information y, and the physical input information x input from the actually connected matrix switch into two sets of physical information for the processing of step SP12. Move.
[0029]
Here, the control circuit 5A converts the set of the physical input information x and the physical stack information z obtained in the previous step SP11 by the inverse conversion process using the conversion table 5D into the set of the virtual input information X and the virtual stack information Z. Convert.
When this processing is completed, the control circuit 5A proceeds to the inverse conversion processing using the conversion table 5E in the subsequent step SP13, and the virtual circuit corresponding to the set of the physical output information y and the physical stacking information z obtained in the previous step SP11. A set of output information Y and virtual stacking information Z is obtained.
[0030]
When the conversion operation for each group is completed in this way, the control circuit 5A reconstructs the virtual stack information Z, the virtual output information Y, and the virtual input information X that specify the cross points on the virtual matrix space in step SP14.
Thereafter, the control circuit 5A moves to the process of step SP15, sends the reconfigured virtual information to the system controller 4 via the I / O interface unit 5B, and ends a series of processing operations.
The virtual information is transferred to the control panel 3 via the system controller 4 and the lamps of the control panel 3 are turned on.
[0031]
(2-2-4) Processing procedure in matrix switcher
Finally, a series of processing procedures executed in the matrix switches 2A and 2B will be described with reference to FIG. When the matrix switches 2A and 2B start processing from step SP21, the matrix switches 2A and 2B first move to step SP22 and determine whether or not a switching command is input from the system configuration management unit 5.
[0032]
The matrix switches 2A and 2B repeat this determination process until an affirmative result is obtained, and when the input of the switching command is confirmed, the process proceeds to step SP23 to check whether or not the physical stacking information z matches the respective stacking information. Judgment is made. Each of the matrix switches 2A and 2B holds different stacking information from other switchers.
If a negative result is obtained here, the matrix switches 2A and 2B determine that the switching command is addressed to a matrix switch other than itself, the process proceeds to step SP24, and the series of switching operations ends. Then, it waits for the input of the next switching command.
[0033]
If an affirmative result is obtained, the matrix switches 2A and 2B determine that the switching command is a command sent to itself and move to step SP25, and further input physical input information y and It is determined whether or not a cross point corresponding to the physical output information x exists in the user.
If a negative result is obtained, it is determined that the matrix switches 2A and 2B should be switched or there is no cross point, and the process proceeds to step SP24.
[0034]
On the other hand, if a positive result is obtained at step SP25, the matrix switches 2A and 2B move to step SP26 to execute a switching operation, and determine whether or not the cross point has actually been switched at the next step SP27. Move on.
If a positive result is obtained, the matrix switches 2A and 2B move to step SP28 to notify the system configuration management unit 5 of the completion of the switching process and prepare for the input of the next switching command.
On the other hand, if a negative result is obtained, the matrix switches 2A and 2B move to step SP29 to notify the system controller 4 of an error in switching processing. The matrix switches 2A and 2B operate through these series of processes.
[0035]
(3) Mode of switching control
(3-1) Association between physical space and virtual matrix space
Here, the state of the conversion process of the virtual information into the physical information by the system configuration management unit 5 described above will be visually described using a three-dimensional model.
Here, FIG. 7 is used as a model of the virtual matrix space VM, and the model of FIG. 8 is used as a model of the matrix switcher MS that physically exists. Incidentally, FIG. 9 shows a model of the cross point CP constituting the matrix switcher.
[0036]
The correspondence between the cross points on the virtual matrix space (FIG. 7) and the cross points of the matrix switch (FIG. 8) is set in the system configuration management unit 5 as the conversion tables 5D and 5E as described above.
For example, the input terminal ((y ₂ , Z ₁ ) Includes input terminals (Y on the virtual matrix space VM shown in FIG. 7). _Three , Z ₁ ) And the output terminal (x of the matrix switch MS shown in FIG. 8) _Three , Z ₁ ) Includes output terminals (X on the virtual matrix space VM shown in FIG. ₂ , Z _Three ) Corresponds.
[0037]
However, in this way, the matrix switch MS input terminal (y ₂ , Z ₁ ) And output terminal (x _Three , Z ₁ ), Even though the cross point physically exists, the input terminal (Y on the virtual matrix space VM) _Three , Z ₁ ) And output terminal (X ₂ , Z _Three ) And the cross point of these terminals do not exist because the level of lamination of these terminals is different. Therefore, the output terminal (x _Three , Z ₁ ) Are output terminals (X in the virtual matrix space VM) _Three , Z _Three ) Is used to associate the physical crosspoint A with the crosspoint B in the virtual matrix space.
[0038]
(3-2) Application examples
Next, examples of such association are shown in FIGS.
First, a case will be described in which one matrix switch shown in FIG. 10A is virtually operated as a two-layer matrix switch as shown in FIG. 10B. In this case, the input terminal (y of the matrix switch) (y ₁ , Z ₁ ), (Y ₂ , Z ₁ ), (Y _Three , Z ₁ ), (Y _Four , Z ₁ ) And output terminal (x ₁ , Z ₁ ), (X ₂ , Z ₁ ), (X _Three , Z ₁ ), (X _Four , Z ₁ ) For each input terminal (Y ₁ , Z ₁ ), (Y ₂ , Z ₁ ), (Y ₁ , Z ₂ ), (Y ₂ , Z ₂ ) And output terminal (X ₁ , Z ₁ ), (X ₂ , Z ₁ ), (X ₁ , Z ₂ ), (X ₂ , Z ₂ ).
[0039]
In this way, the first crosspoint group CPG1 (input terminal (y _Three , Z ₁ ), (Y _Four , Z ₁ ) And output terminal (x _Three , Z ₁ ), (X _Four , Z ₁ ) And the second cross point group CPG2 (input terminal (y ₁ , Z ₁ ), (Y ₂ , Z ₁ ) And output terminal (x ₁ , Z ₁ ), (X ₂ , Z ₁ ) Can be realized by stacking four cross points).
In this way, since one matrix switch can be handled physically in a two-layer structure, the user controls the component video signal with the upper virtual matrix switch, and controls the lower virtual matrix. When the composite video signal is controlled by the switcher, it can be used anytime without being aware of the physical connection state.
[0040]
Similarly, one matrix switch can be used as a virtual matrix switch having three or more layers. In this case, for example, if a digital video signal of a high definition television standard is assigned by a virtual matrix switch in the third layer, it can be used anytime.
[0041]
If these functions are used, for example, even when the number of terminals required for switching between the component video signal and the composite video signal is 8 inputs × 8 outputs, the physically required video matrix switcher is It is only necessary to prepare one 16-input × 16-output device, and it is not necessary to prepare two 16-input × 16-output devices as in the prior art. As a result, the waste of input / output terminals and cross points can be significantly reduced as compared with the prior art.
[0042]
If this function is used, the assignment of terminals can be changed within the same stacking level. For example, as shown in FIG. 11A, input terminals (y ₁ , Z ₁ ), (Y ₂ , Z ₁ ) And output terminal (x ₁ , Z ₁ ), (X ₂ , Z ₁ ) As shown in FIG. 11B, every other input terminal (Y ₁ , Z ₁ ), (Y _Three , Z ₁ ) And output terminal (X ₁ , Z ₁ ), (X _Three , Z ₁ ).
[0043]
In this way, the input terminal (Y ₁ , Z ₁ ) And input terminal (Y _Three , Z ₁ ) As if there is an input terminal I, and the output terminal (X ₁ , Z ₁ ) And output terminal (X _Three , Z ₁ ) As if there is an output terminal J. If this function is used, the terminal positions of the matrix switches that physically exist can be freely set on the virtual matrix switch according to the system. For example, when a system is configured by stacking two matrix switches of 64 input × 64 output video matrix switch and 32 input × 32 output audio matrix switcher, in the virtual matrix space The input / output terminals of the audio matrix switch can be easily assigned so as to be paired with the input / output terminals of the video signal that handles audio.
[0044]
As a result, it is not necessary to physically assign video signals that handle audio signals to 32 sets of terminals as in the prior art, and the usability is further improved.
In addition, even if it is necessary to change the terminal position to which a video signal with sound is input or the terminal position to be output, the position of a terminal to which sound is input can be easily changed on the virtual matrix switcher. Therefore, it is not necessary to prepare a matrix switch with a maximum of 64 inputs × 64 outputs as an audio matrix switch only for the purpose of expanding the selection range. As a result, the utilization efficiency of the voice matrix switch can be further improved.
[0045]
According to the above configuration, by displaying the cross points on the virtual matrix space in which the logical correspondence relationship with the physical cross points is formed on the control panel 3, the user can perform the physical cross points. It is possible to change the cross point without being aware of the point. As a result, the user-friendliness can be further improved.
Further, the combination and switching of the cross points can be arbitrarily set on the virtual matrix space, so that the selection range of the terminal arrangement can be expanded. As a result, it is not necessary to prepare a matrix switch having a larger scale than necessary, and the terminals and cross points of the matrix switch can be used effectively without waste.
[0046]
(4) Other embodiments
In the above embodiment, the case where the number of matrix switches constituting the matrix switch system 1 is two has been described. However, the present invention is not limited to this, and the number of matrix switches is one. It may be three or more. Similarly, although the case where the number of control panels constituting the matrix switcher system 1 is one has been described, the number of control panels may be two or more. Incidentally, the control panel used here may be a remote controller.
[0047]
In the above-described embodiment, the system configuration management unit 5 for managing the correspondence between the physical matrix switch cross points and the virtual matrix switch cross points is prepared as hardware separately from the system controller 4. However, the present invention is not limited to this, and may be provided as software inside the system controller 4. Moreover, you may provide as both software and hardware.
[0048]
Further, in the above-described embodiment, the case where the system controller 4 is provided as hardware has been described. However, the present invention is not limited to this, and the function of the system controller 4 is prepared as software even if it is prepared as hardware. Or both.
[0049]
In the above-described embodiment, the matrix switcher system 1 having the configuration shown in FIG. 1 has been described. However, each of the components may be housed in one apparatus, or a combination of several units. One device may be configured. For example, the system configuration management unit 5 may be integrally provided in each of the matrix switches 2A and 2B to constitute one device.
[0050]
In the above-described embodiments, the case where the input / output of a plurality of video signals is switched by the matrix switch and the case where the inputs / outputs of a plurality of audio signals are switched have been described. However, the present invention is not limited to this. The present invention can also be applied to switching codes and other control signals. Further, the present invention can be widely applied when switching input / output of a plurality of signals having different properties.
[0051]
【The invention's effect】
As described above, according to the present invention, since the connection state of the matrix switch means that physically exists can be managed in a virtual connection state, the system configuration can be constructed more flexibly than in the past. An output switching device and a matrix switch control device can be realized.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a system configuration example of an input / output switching device according to the present invention.
FIG. 2 is a block diagram illustrating a configuration example of a system configuration management unit.
FIG. 3 is a schematic diagram illustrating an example of a second conversion table.
FIG. 4 is a schematic diagram illustrating an example of a first conversion table.
FIG. 5 is a flowchart showing an example of a processing procedure executed by a system configuration management unit.
FIG. 6 is a flowchart showing an example of a processing procedure executed by the matrix switch.
FIG. 7 is a schematic perspective view for explaining a virtual matrix space model.
FIG. 8 is a schematic perspective view for explaining a matrix switcher model that physically exists.
FIG. 9 is a schematic perspective view for explaining a cross-point model.
FIG. 10 is a schematic perspective view for explaining a case where one matrix switch is treated as a virtual stack of two matrix switches.
FIG. 11 is a schematic perspective view for explaining the case where the position of the input / output terminal is virtually allocated to another terminal position at the same layer level.
[Explanation of symbols]
1 ... Matrix switcher system, 2A, 2B ... Matrix switcher, 3 ... Control panel, 4 ... System controller, 5 ... System configuration manager, 5A ... Control circuit, 5B ... I / O interface Ace part, 5D, 5E ... Conversion table.

Claims (6)

Virtual information input means for inputting virtual stacking information, virtual input information and virtual output information;
Conversion means for converting the virtual stack information, virtual input information and virtual output information into physical stack information, physical input information and physical output information, respectively;
A plurality of matrix switching means each having a plurality of input terminals and output terminals and holding different physical stacking information;
The plurality of matrix switching means are selected based on the physical input information and the physical output information when the physical stack information supplied from the conversion means matches the physical stack information held. An input / output switching device characterized by switching an input terminal and an output terminal. The conversion means is
A first conversion table for converting the virtual input information and the virtual stack information into the physical input information and the physical output information;
2. The input / output switching device according to claim 1, further comprising a second conversion table that converts the virtual output information and the virtual stack information into the physical output information and the physical output information. The conversion means is
When the physical stacking information obtained by the first conversion table matches the physical stacking information obtained by the second conversion table, the physical stacking information and the physical input information are obtained. The input / output switching device according to claim 2, wherein the physical output information is supplied to the plurality of matrix switching means. 2. The input / output switching device according to claim 1, wherein said converting means and one of said plurality of matrix switching means are configured as one device. Virtual stack information supplied from virtual information input means for inputting virtual stack information, virtual input information and virtual output information, a first table for converting the virtual input information into physical stack information and physical input information;
A second table for converting the virtual stacking information and the virtual output information supplied from the virtual information input means into physical stacking information and physical output information;
The physical stack information obtained through the first table and the second table, the physical input information, and the physical output information, each having a plurality of input terminals and output terminals, and different physical stacks A matrix switcher control device comprising: control means for supplying a plurality of matrix switching means for holding information. When the physical stacking information obtained from the first table matches the physical stacking information obtained from the second table, the control means, when the physical stacking information and the physical input information are obtained 6. The matrix switch control device according to claim 5, wherein the physical output information is supplied to the plurality of matrix switches.

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