JP4154982B2 - CPU-controlled analog mixer - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an analog mixer used in various places for handling analog audio signals such as a theater, a concert hall, a studio, and the like, and more particularly, to an analog mixer digitally controlled by a CPU. The present invention relates to taking measures so as to cope with an abnormality in a digital control system such as a CPU.
[0002]
[Prior art]
In an analog mixer that mixes audio signals in an analog manner, in order to perform scene control (control that presets the state of each switch and fader) for a plurality of switches and faders for mixing setting, those switches and faders that are subject to scene control Is controlled digitally by the CPU. For example, scene setting data composed of data indicating ON / OFF for each switch to be controlled by the scene and data indicating setting / operation amount for each fader is stored in each scene memory provided with the CPU. This is stored for each scene, and when the mixer operator operates the desired scene recall switch, the corresponding scene setting data is read from the scene memory, and the state of each switch is set to ON or OFF accordingly. Then, set the setting / operation status for each fader.
[0003]
[Problems to be solved by the invention]
In such an analog mixer controlled by the CPU, each of the digital mixers that are digitally controlled by the CPU, such as when the CPU is shut down due to a software or hardware cause, or when the digital power supply is shut off. There is a disadvantage that the switch and the fader become uncontrollable and the analog mixer cannot be used at all. For example, when the CPU stops functioning, the on / off control of the analog switch element that is controlled by the CPU becomes impossible. It becomes an unstable state that swings between off. In addition, since it becomes impossible to control the voltage control type amplifier for the fader whose gain is controlled by the CPU, the gain gradually changes from the gain when the CPU function is stopped, and the gain is stuck to the maximum or minimum. I'll be relaxed. If the gain of the voltage-controlled amplifier for the fader is not stable, trying to recover as much as possible using other manually adjustable controls will not work. Also, since the power supply for the analog switch element of the analog mixing unit is the same as the power supply for the digital control unit (digital power supply), the analog switch element itself switches when the power supply for the digital control unit goes down. It became inoperable and could not be recovered.
[0004]
The present invention has been made in view of the above points, and an object of the present invention is to provide a CPU-controlled analog mixer in which measures are taken so as to cope with an abnormality in a digital control system such as a CPU.
[0005]
[Means for Solving the Problems]
The CPU-controlled analog mixer according to the present invention is Multiple input Analog signal The ON / OFF controlled by control signal for mixing setting plural Analog switch element And a mixing unit that selectively mixes the analog signals that have passed through the analog switch elements that are turned on. When, Corresponding to each analog switch element Operator Every The first control signal Respectively A CPU control unit for storing and outputting the stored first control signal under the control of the CPU; each The second control signal corresponding to the operation of the operation element is not passed through the control of the CPU. Respectively Generate and select the first control signal normally output by the CPU controller While When the CPU control unit is abnormal, the second control signal is selected and selected. First or second Control signal To the mixing unit Switching control means for controlling on / off of the analog switch element.
According to this, while it is possible to perform the mixing setting by controlling on / off of the analog switch element with the first control signal normally output by the CPU control unit, the CPU control is performed when the CPU control unit is abnormal. The second control signal generated without going through The Mixing setting can be performed by controlling on / off of the analog switch element, and it is possible to cope with CPU abnormality.
[0006]
A CPU controlled analog mixer according to another aspect of the present invention comprises: Multiple input Analog signal Respectively A voltage-controlled amplifier that controls the amplitude of an analog signal according to a control voltage signal A mixing unit that mixes the analog signal whose amplitude is controlled by the voltage-controlled amplifier When, F A CPU control unit that generates digital data in accordance with the operation amount of the fader operator, converts the digital data into analog data, and outputs the digital data as a first control voltage signal, and the first control unit that is normally output by the CPU control unit Select control voltage signal for While When the CPU control unit is abnormal, the second control voltage signal consisting of a predetermined voltage is selected and selected. First or second Control voltage signal To the mixing unit Selection control means for controlling the voltage controlled amplifier.
According to this, the fader operation state can be set by the CPU control by controlling the voltage control type amplifier with the first control voltage signal output by the CPU control unit. By controlling the voltage control type amplifier to a predetermined gain with the second control voltage signal having a predetermined voltage, it is possible to ensure that the analog signal is introduced into the mixing unit with the predetermined gain, and to cope with the abnormality of the CPU.
[0007]
A CPU controlled analog mixer according to another aspect of the present invention comprises: Multiple input Analog signal Respectively A voltage-controlled amplifier that controls the amplitude of an analog signal according to a control voltage signal A mixing unit that mixes the analog signal whose amplitude is controlled by the voltage-controlled amplifier When, F A CPU control unit that generates digital data in accordance with an operation amount of a fader operator, converts the digital data into analog data, and outputs the digital data as a first control voltage signal; F A voltage generation means for generating an analog voltage according to the operation amount of the fader operator, and the first control voltage signal normally output by the CPU control unit are selected. While The second control voltage signal composed of an analog voltage generated by the voltage generating means is selected when the CPU control unit is abnormal, and is selected. First or second Control voltage signal To the mixing unit Selection control means for controlling the voltage controlled amplifier.
According to this, the fader operation state can be set by the CPU control by controlling the voltage control type amplifier with the first control voltage signal output by the CPU control unit. By controlling the voltage control type amplifier (with a control voltage corresponding to the operation amount of the fader operation element) with the second control voltage signal composed of the analog voltage generated by the voltage generating means, the analog signal becomes the operation amount of the fader operation element. It can be introduced into the mixing unit with a gain according to the above, so that it is possible to deal with a CPU abnormality.
[0008]
An analog mixer according to still another aspect of the present invention is A plurality of power inputs from a first power source Analog signal The Analog switch element that is on / off controlled by a control signal for a predetermined mixing setting A mixing unit that selectively mixes the analog signals that have been supplied to and passed through the analog switch elements that are turned on. When, Powered from a second power source, Above each Depending on the operation of the control corresponding to the analog switch element Respectively A control signal is output, and the analog switch element is controlled by the control signal. Respectively Digital control for on / off control Part And said From the digital control unit to the mixing unit Analog switch element To Connected to the control signal supply line Based on the first power source A pull-up or pull-down control signal source, and when the second power source is down, the analog switch element is turned on / off by the pull-up or pull-down control signal source. To do.
According to this, normally, the digital control unit controls the on / off of the analog switch element according to the control signal. However, when the second power source for the digital control unit is down, the control by the digital control unit becomes impossible. But, Based on the first power supply for the mixing unit Since the analog switch element is turned on / off by the pull-up or pull-down control signal source, the analog switch element can be controlled by appropriately setting the pull-up or pull-down. The Digital control unit can be set to on or off to enable mixing operation of Can handle power down.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
An analog mixer controlled by a CPU according to an embodiment of the present invention is roughly divided into a mixing unit 10 and a CPU control unit 50. FIG. 1 shows a configuration example of the mixing unit 10, and FIG. 2 shows a CPU control unit. 50 configuration examples are shown.
The mixing unit 10 only needs to have an analog mixing function similar to a known analog mixer with respect to the mixing function itself. For example, the mixing unit 10 inputs analog audio signals via a plurality of input channels, and inputs the analog of each input channel. The audio signal is distributed to an arbitrary mixing bus, mixed for each mixing bus, and the mixed analog audio signal is output via an output channel corresponding to each mixing bus.
[0010]
First, a configuration example of the input channel will be described. In FIG. 1, the schematic configuration of only one input channel INch # 1 with respect to the input channels of the mixing unit 10 is illustrated, but a plurality of other input channels that are not illustrated may be configured in the same manner. The analog audio signal input to the input channel INch # 1 includes an input gain adjustment amplifier 11, an equalizer (EQ) 12, a fader voltage control amplifier (hereinafter abbreviated as VCA) 13, and an input channel on / off switch. Processing is performed through the route of the relay 14 and the buffer amplifier 15. FIG. 3A shows an array of operator groups in an input channel operator module provided corresponding to one input channel INch # 1 in the operation panel of the analog mixer according to this embodiment.
[0011]
The input gain adjustment amplifier 11 is operated in response to an operator's operation of a knob type operator (hereinafter, this type of knob is referred to as “A knob”) that can only be manually operated (that is, not controlled by the CPU). This is an amplifier that adjusts the input gain of an analog audio signal to a channel. In FIG. 1, the symbol “A knob” illustrated in FIG. 1 is obtained by superimposing an arrow indicating a variable volume on a circle indicating a knob. In FIG. 1, there is no particular description of what is drawn with this symbol. Is also an “A knob”. In FIG. 3, the symbol “A” is shown as a symbol of “A knob”. An input gain knob 11 a in FIG. 3A is an “A knob” corresponding to the input gain adjustment amplifier 11.
A plurality of equalizer control knobs 12a in FIG. 3A are operating elements for adjusting the characteristics of the equalizer 12, and are also composed of “A knobs” that can only be manually operated.
[0012]
The fader VCA 13 is gain-controlled according to the operation amount of the fader operator 13a corresponding to the input channel INch # 1, and is controlled by the CPU. Hereinafter, the fader controlled by the CPU is referred to as “C fader”. In FIG. 3, “C” is indicated as a symbol of the faders and switches controlled by the CPU. The fader operation element 13a itself includes a slide type variable resistor 13b and a slide type knob 13c (see FIG. 3A) for sliding the variable resistor. A configuration example for controlling the fader VCA 13 via the CPU control unit 50 in accordance with the operation of the fader operator 13a will be described later.
The input channel on / off relay 14 turns on / off (passes or cuts off) the audio signal in the input channel INch # 1, and is a CPU-controlled switch, that is, a channel ON switch 14a which is a “C switch”. The on / off control is performed by the CPU according to the operation (see FIG. 3A).
[0013]
The output signal of the buffer amplifier 15 is distributed to a plurality of mixing setting lines corresponding to various buses for mixing. The mixing setting lines corresponding to the left and right stereo buses L and R will be described. The analog audio signal output from the buffer amplifier 15 is input to the pan control balance volume 16, and the left and right volume of the stereo pan set by the volume 16 is set. Are distributed to the left channel and the right channel at a ratio corresponding to the above, and are input to the analog switch elements 17a and 17b via the buffer amplifiers for the left and right channels. The output of the left channel analog switch element 17a is connected to the left channel bus L for stereo. The output of the right channel analog switch element 17b is connected to the right channel bus R for stereo. An operator for manually operating the pan control balance volume 16 is a PAN knob 16a shown in FIG. 3A, and is an "A knob", that is, a CPU not controlled. On the other hand, “Esw” is indicated in the block of each analog switch element 17a, 17b. In this way, the display with “Esw” indicates an electronic control switch, that is, a CPU-controlled switch. The analog switch elements 17a and 17b perform on / off setting (that is, mixing setting) for supplying the audio signal of the input channel INch # 1 to the left and right stereo buses L and R. FIG. In response to the operation of one ST (abbreviation of stereo) switch 17c shown in FIG. 1, the left and right channel analog switch elements 17a and 17b are set in an on or off state in conjunction with each other. As shown in FIG. 3A, the ST switch 17c is marked with “C”, which indicates that it is controlled by the CPU, that is, the “C switch”. A configuration example for controlling the analog switch element labeled “Esw” in FIG. 1 via the CPU control unit 50 will be described later.
[0014]
The mixing setting line corresponding to a plurality of n group buses GROUP will be described. Analog audio signals output from the buffer amplifier 15 are respectively supplied to analog switch elements 18a to 18n provided corresponding to the respective buses of the group bus GROUP. Entered. The outputs of the analog switch elements 18a to 18n are connected to the corresponding buses in the group bus GROUP. The analog switch elements 18a to 18n perform on / off setting (that is, mixing setting) for supplying the audio signal of the input channel INch # 1 to each bus of the group bus GROUP, as shown in FIG. Although only four GROUP switches 18 are shown for convenience, a GROUP switch 18 is provided corresponding to each bus of the group bus GROUP, and the control of the CPU control unit 50 is performed according to the operation of each GROUP switch 18. Accordingly, the corresponding analog switch elements 18a to 18n are set to the on or off state.
[0015]
The mixing setting line corresponding to the plurality of n auxiliary buses AUX will be described. For each bus of the auxiliary bus AUX, the variable volumes 19a to 19n consisting of “A knobs” and the analog switch element 20a consisting of “C switches”. ~ 20n are provided in series. The analog audio signal output from the buffer amplifier 15 is input to the variable volumes 19a to 19n, and further input to the buses of the auxiliary bus AUX via the analog switch elements 20a to 20n. The variable volumes 19a to 19n manually adjust the mixing level of the audio signal of the input channel INch # 1 for each bus of the auxiliary bus AUX. In FIG. 3A, for convenience, four AUX level knobs are used. Although only 19 is shown, an AUX level knob 19 is provided corresponding to each bus of the auxiliary bus AUX. The analog switch elements 20a to 20n perform on / off setting for supplying the audio signal of the input channel INch # 1 to each bus of the auxiliary bus AUX. In FIG. Although only the AUX switch 20 is shown, an AUX switch 20 is provided corresponding to each bus of the auxiliary bus AUX, and the AUX switch 20 is controlled by the control of the CPU control unit 50 according to the operation of each AUX switch 20. Each analog switch element 20a-20n is set to an on or off state.
[0016]
Other input channels not shown are also configured in the same manner as described above, and are connected to the mixing buses L, R, GROUP, and AUX.
Next, a configuration example of output channels corresponding to the mixing buses L, R, GROUP, and AUX will be described. The output channel corresponding to the stereo left channel bus L has a buffer amplifier 21a for inputting the mixed signal via the bus L and the output level of the mixed signal output from the buffer amplifier 21a manually. It comprises a fader operator 22a for adjustment and a relay 23a for controlling on / off of the stereo left channel. Similarly, the output channel corresponding to the stereo right channel bus R also has a buffer amplifier 21b for inputting the mixed signal via the bus R, and the output level of the mixed signal output from the buffer amplifier 21b. Is composed of a fader operation element 22b for manually adjusting the stereo channel and a relay 23ab for controlling on / off of the stereo right channel. FIG. 3B shows an array of operator groups in the operator module provided corresponding to the stereo output channel in the operation panel of the analog mixer according to this embodiment. In the figure, two slide-type knobs 22 are slide-type knobs for faders 22a and 22b dedicated to manual adjustment that are not CPU-controlled, and “A” is indicated to indicate that they are “A faders” that are not CPU-controlled. It is written. Each of the relays 23a and 23b is for turning on / off (passing or blocking) the audio signal in the output channel, and is a switch controlled by the CPU, that is, a “C switch”, of the corresponding output channel ON switch 23. Depending on the operation, on / off control is performed by the CPU.
[0017]
The output channel corresponding to one bus of the group bus GROUP manually adjusts the output level of the mixed signal output from the buffer amplifier 24 and the buffer amplifier 24 that inputs the mixed signal through the bus. And a relay 26 for controlling on / off of the output channel. Further, the mixed signal whose output level is adjusted by the fader operator 25 is input to the left and right stereo buses L and R. A pan control balance volume 27 for performing the on / off control of the signal distributed to the left channel and the right channel at a ratio corresponding to the left and right volume of the stereo pan set by the volume 27 , 28b. The output of the analog switch element 28a is connected to the left channel bus L, and the output of the analog switch element 28b is connected to the right channel bus R. FIG. 3C shows an array of operator groups in an operator module provided corresponding to the output channel of one bus of the group bus GROUP in the operation panel of the analog mixer according to this embodiment. In the figure, one slide-type knob 25a is a slide-type knob of each fader operation element 25 dedicated to manual adjustment that is not CPU-controlled, and is an “A fader” that is not CPU-controlled. The relay 26 turns on / off (passes or cuts off) the audio signal in the output channel, and is turned on by the CPU in accordance with the operation of the output channel ON switch 26a which is a CPU-controlled switch, that is, a “C switch”. / Off controlled. An operator for manually operating the pan control balance volume 27 is a PAN knob 27a shown in FIG. 3 (c), and is an "A knob", that is, a CPU not controlled. On the other hand, the analog switch elements 28a and 28b of the left and right channels are set to the on or off state in conjunction with one ST switch 28c (FIG. 3C) which is a “C switch”. Although not shown, output channels corresponding to other buses of the group bus GROUP are similarly configured.
[0018]
Since the configuration of the input channel and the output channel related to the group bus GROUP is as described above, this group bus GROUP is used as a pre-stage of the final mixing in the stereo bus. It can be used as a bus for mixing audio signals. For example, when it is desired to group two input channels (assumed to be # 1 and # 2), the analog switch element 18a of the input channel # 1 is turned on and mixed with the bus of the first group, and the input channel # 2 The analog switch element 18a is turned on and mixed to the first group of buses. As a result, since the audio signals of the input channels # 1 and # 2 are mixed by the first group bus, the A fader operator 25 of the output channel (assumed to be GROUP # 1) corresponding to the first group bus. The level can be adjusted in common, and the pan control balance volume 27 can be set in common and supplied to the stereo buses L and R.
[0019]
The output channel corresponding to one bus of the auxiliary bus AUX manually adjusts the output level of the mixed signal output from the buffer amplifier 29 and the buffer amplifier 29 that inputs the mixed signal through the bus. And a relay 31 for controlling on / off of the output channel. FIG. 3D shows an array of operator groups in an operator module provided corresponding to the output channel of one bus of the auxiliary bus AUX in the operation panel of the analog mixer according to this embodiment. In the figure, a slide-type knob 30a is a slide-type knob of the manual adjustment dedicated fader 30 that is not CPU-controlled, and is an “A fader” that is not CPU-controlled. The relay 31 turns on / off (passes or cuts off) the audio signal in the output channel, and is turned on by the CPU in response to an operation of the output channel ON switch 31a which is a CPU-controlled switch, that is, a “C switch”. / Off controlled. Although not shown, output channels corresponding to other buses of the auxiliary bus AUX are configured in the same manner.
[0020]
Each bus of the auxiliary bus AUX can be mixed to the corresponding output channel by individually adjusting the level by the “A knob” operation elements 19a to 19n on the mixing setting line of the input channel related thereto. Therefore, it is possible to connect the output channels corresponding to each bus of the auxiliary bus AUX to an external effector or to monitor headphones for each individual player for returning to the individual player performing the performance. It is. For example, an output channel (assuming AUX # 1) corresponding to the first bus of the auxiliary bus AUX is connected to an external effector, and audio signals of input channels # 1 and # 2 are supplied to the external effector. When applying an effect, the “A knob” operation element 19a in the input channel # 1 is set to a desired send level, and the “A knob” operation element 19a in the input channel # 2 is set to a desired send level. Can be mixed with the first bus of the auxiliary bus AUX and supplied to the external effector via the output channel AUX # 1. Alternatively, when an output channel (assumed to be AUX # 2) corresponding to the second bus of the auxiliary bus AUX is connected to a monitor headphone of a specific individual player, the specific individual player desires to monitor 1 Alternatively, it is possible to set a desired send level for each input channel with the “A knob” operation element 19b corresponding to the second bus in a plurality of input channels, and mix them.
[0021]
Next, a configuration example of the CPU control unit 50 shown in FIG. 2 will be described. The CPU control unit 50 has a flash memory 52, a RAM (random access memory) 53, and a timer 55 connected to an address and data bus 54 of a CPU (central processing unit) 51, and various input / output (I / O) interfaces. 56 to 60 and an analog-digital converter (ADC) 61 are connected. The flash memory 52 stores various programs executed by the CPU 51 and preset states (that is, “scenes”) of various operators (C faders and C switches) controlled by the CPU in the mixing unit 10. It is a non-volatile memory. That is, the conventionally known “scene memory” is configured in the flash memory 52. The RAM 53 is a volatile memory used for working memory or temporary data storage, as is well known. For example, data indicating the current operation state or operation amount of various operation elements (C fader and C switch) controlled by the CPU in the mixing unit 10 is stored in the RAM 53. The display I / O interface 56 is an interface for connecting a known type of display 62 for a computer such as liquid crystal or CRT to the CPU bus 54. The parallel I / O interface 57 is an interface for connecting a known computer operator group 63 such as a keyboard and a mouse to the CPU bus 54. The serial I / O interface 58 inputs / outputs digital data serially under the control of the CPU 51. In this example, the digital I / O converter (DAC) 64 converts the output serial digital data into an analog signal. Is connected. The parallel I / O interface 59 inputs and outputs digital data in parallel under the control of the CPU 51. In this example, a CPU controllable signal CCE indicating normal / abnormal CPU is output under the control of the CPU 51. . The other I / O interface 60 comprehensively shows I / O interfaces that can be used for various other purposes. For example, I / O for connecting the hard disk drive 65, USB, MIDI, and the like. The I / O for communication may be used.
[0022]
Next, a connection example between the mixing unit 10 shown in FIG. 1 and the CPU control unit 50 shown in FIG. 2 will be described, and further a CPU control example will be described.
First, the output of the slide type variable resistor 13b of the fader operator 13a, which is the “C fader” in FIG. 1, is input to the analog-digital converter (ADC) 61 in the CPU control unit 50 of FIG. Is done. In this embodiment, it is assumed that the slide type variable resistor 13b of the fader operator 13a generates an operation amount output voltage having a linear characteristic with respect to the slide operation position. The ADC 61 converts the operation amount output voltage of the fader operation element 13 a into digital data, and supplies it to the CPU 51 via the bus 54. Actually, the fader operator 13a is graduated with a decibel characteristic so as to match the decibel characteristic of human hearing sense, and the corresponding fader VCA 13 should be controlled in accordance with this decibel characteristic. . However, a linear variable variable resistor is used as the slide type variable resistor 13b of the fader operator 13a at a relatively low cost and the accuracy of the detection position can be easily increased. Since the number of input channels of the mixing unit 10 is considerably large (for example, 96 channels), it is economically advantageous to use a low-cost sliding variable resistor 13b for the fader operator 13a. The CPU 51 converts the linear characteristic of the manipulated variable output voltage of the fader operator 13a (a value corresponding to the fader position linearly) into a decibel characteristic (a value corresponding to the scale of the fader position) and converts it into the decibel characteristic. The fader VCA 13 is controlled by the voltage.
[0023]
That is, the CPU 51 stores the fader operation amount digital data of linear characteristics given from the ADC 61 via the bus 54 in the RAM 53 and stores / saves the current fader operation amount data in the RAM 53 as the current fader operation amount data. Then, the current fader operation amount data is read and converted to decibel characteristics, and the fader operation amount digital data having decibel characteristics is applied to the serial I / O interface 58 via the bus 54 and input to the DAC 64. Thus, a fader operation amount analog voltage having a decibel characteristic is output from the DAC 64 and applied to the input X of the selector 32 of FIG. A CPU control enable signal CCE is input to the selection control input of the selector 32 from the parallel I / O interface 59 of FIG. This CPU controllable signal CCE indicates an active level (for example, “1”) when the CPU control unit 50 is operating normally, and sets the selector 32 in the X input selection state. Thus, during normal operation of the CPU, the fader operation amount analog voltage (that is, the first control signal) output from the DAC 64 is selected via the X input of the selector 32, and this is applied to the VCA 13 as a control voltage. .
[0024]
The same applies when a preset scene is selected. Preset operation amount data for the fader operator 13a included in the selected scene is read from the scene memory (52), and the preset operation amount data is read out. If it is expressed in decibel characteristics, it is converted to analog voltage as it is in DAC 64, while if this preset manipulated variable data is expressed in linear characteristics, it is converted into decibel characteristics and then converted into analog voltage in DAC 64. It is given to the X input of the selector 32 (that is, as the first control signal). As a result, the control voltage of the fader VCA 13 is set to a value corresponding to the preset operation amount data for the fader operator 13a in the selected scene. A C fader drive circuit 66 (FIG. 2) is provided corresponding to each of the “C fader” type fader operators 13a. By this C fader driving circuit 66, the slide-type knob 13c (see FIG. 3A) of the corresponding fader operator 13a corresponds to the preset operation amount data for the fader operator 13a included in the selected scene. The position of the knob 13c itself is automatically set to a state corresponding to the preset operation amount data.
The processing for converting the fader operation amount data into the decibel characteristic is performed by setting the characteristic so that the digital / analog conversion characteristic itself in the DAC 64 is subjected to the linear decibel conversion without performing the digital processing by the CPU 51. Also good.
Further, the ADC 61 and / or the DAC 64 may be configured to be shared in time division between the fader operators 13a and / or the VCA 13 of each input channel.
[0025]
Here, a description will be given of measures for ensuring the operation of the VCA 13 for the “C fader” when the CPU is abnormal. As described above, the CPU controllable signal CCE is generated based on software processing in the CPU 51 so as to indicate an active level (for example, “1”) when the CPU control unit 50 is operating normally. As shown in FIG. 1, the CPU controllable signal CCE is pulled down by the resistor 46, and when a software operation abnormality or a hardware abnormality such as a power down occurs in the CPU control unit 50, the CPU control enable signal CCE falls to an inactive level. Indicates that it is impossible. Thereby, the selector 32 is switched to the Y input selection state. The Y input of the selector 32 is fixed to a predetermined analog voltage. In the illustrated example, the predetermined analog voltage is a ground voltage (0 volts), which sets the gain of the VCA 13 to 0 dB. Since the VCA 13 can attenuate the input signal by minus decibels, it means that the input signal is passed at a predetermined sufficient level when the gain is 0 decibels. As described above, when the CPU control unit 50 is abnormal, a predetermined analog voltage (that is, the second control voltage signal) is selected and output via the Y input of the selector 32, and the fader VCA 13 is predetermined with the selected analog voltage. Controlled by the gain, it is ensured that the input analog audio signal passes through the fader VCA 13 with the predetermined gain, and an appropriate action can be taken by manual operation of the operator as will be described later even when the CPU is abnormal. Note that the route drawn with a dotted line so as to be input to the Y input of the selector 32 shows another example of countermeasures, which will be described later.
[0026]
FIG. 5 shows a processing example for generating the CPU controllable signal CCE in the course of the main processing of the CPU 51. When the power of the analog mixer is turned on and the main processing of the CPU 51 starts, various initial settings are performed by the initial setting processing. As one of them, the CPU controllable signal CCE is set to “0” (inactive level). Initial setting. When the initial setting ends normally, the CPU controllable signal CCE is set to “1” (active level). Here, when an abnormality occurs during the initial setting, it is assumed that the process exits from the main show in FIG. 5 and the subsequent processing is not performed. Therefore, if the CPU 51 fails in the initial setting, the CPU controllable signal CCE remains “0” (inactive level), and the CPU controllable signal CCE is “1” (active level) only when the CPU 51 is started up smoothly. ). Thereafter, the CPU main process repeats the normal main routine. That is, various factors such as the presence / absence of an operation event of the operator group 63 are checked, and if an operation factor occurs, event processing corresponding to the factor is performed. In FIG. 2, a digital power supply voltage of 12 volts or 5 volts is supplied to each part of the CPU controller 50 by digital power supplies 68 and 69. When the digital power supply voltage is lowered, the CPU controllable signal CCE is also lowered to “0” (inactive level). The main digital power supply 68 is supplied with a commercial AC power supply of 100 volts via a power switch attached to the CPU control unit 50.
[0027]
Next, a configuration example in which the “C switch” is controlled by the CPU control unit 50 will be described.
In FIG. 1, a block 47 labeled Csw representatively shows one “C switch” operator. The “C switch” operation element 47 is not limited to one, and is provided for each analog switch element indicated as Esw in FIG. 1, and a specific arrangement example is indicated by “C” in FIG. As shown. The output of each “C switch” operator 47 is input to the Csw switching control unit 67 of the CPU control unit 50 shown in FIG. A detailed example of the Csw switching control unit 67 is shown in FIG. In FIG. 4, only the configuration of the Csw switching control unit 67 corresponding to one “C switch” operator 47 is shown for convenience, but the Csw switching control unit 67 having the same configuration corresponds to each “C switch”. Provided.
[0028]
In FIG. 4, the “C switch” operation element 47 is composed of a self-return type push button switch 47 a, and an ON operation signal is input to the input port IN of the input / output port 70 in response to one pressing operation. This input / output port 70 is connected to the bus 54 (FIG. 2) of the CPU 51, and an ON operation signal input via the input port IN is input to the RAM 53 together with the switch number data, and shown in FIG. By such processing, the value of the on / off data stored in the RAM 53 corresponding to the switch number is inverted. That is, each time the self-return type push button switch 47a is pressed, the ON / OFF state of the “C switch” is reversed to ON or OFF. FIG. 6 shows an example of the ON operation event processing of the “C switch” Csw (i) under the control of the CPU 51. ST (i) corresponds to the switch number i of the “C switch” Csw (i). Indicates the value of stored on / off data. That is, in response to the ON operation event of the “C switch” of the switch number i, the value ST (i) of the ON / OFF data of the switch number i is inverted. Then, the value of the on / off data ST (i) stored in the RAM 53 is read, and the input / output port 70 (FIG. 4) of the analog switch element Esw (i) corresponding to the switch number i via the bus 54. Output to.
[0029]
In FIG. 4, the input / output port 70 outputs the on / off data ST (i) corresponding to the switch number i received from the bus 54 from the output OUT, and gives it to the X input of the selector 71. The selection control input of the selector 71 is input with the CPU control enable signal CCE, and when the CPU control unit 50 is operating normally, the selector 71 is in the X input selection state. Thus, during normal operation of the CPU, data indicating the on / off state of the “C switch” output from the input / output port 70 under the control of the CPU (that is, the first control signal) is transmitted via the X input of the selector 71. This is applied via line 45 to the switching control input of the corresponding analog switch element or Esw in mixing section 10. Thus, on / off of the analog switch element corresponding to the “C switch” is controlled by the CPU control unit 50.
The same applies when a preset scene is selected. Preset on / off data for the “C switch” included in the selected scene is read from the scene memory (52). Preset on / off data is set in the input / output port 70 and is selectively output via the X input of the selector 71. As a result, the analog switch element (Esw) corresponding to the “C switch” is set to the on or off state.
[0030]
Next, countermeasures for ensuring the operation of the “C switch” when the CPU is abnormal will be described. Therefore, in the Csw switching control unit 67 of FIG. 4, the output signal of the push button switch 47a of the “C switch” operator 47 is input to the D flip-flop 72, and each push operation of the push button switch 47a is performed. The output state of the D flip-flop 72 is inverted to “1” or “0”. As a result, the output of the D flip-flop 72 corresponds to the on / off data ST (i) of the “C switch” operator 47 stored in the RAM 53 by the CPU 51 without being controlled by the CPU 51. It becomes. The output of the D flip-flop 72 is input to the Y input of the selector 71. The selector 71 selects the Y input when the CPU controllable signal CCE falls to the inactive level, that is, when the CPU is abnormal, and selectively outputs the output signal (that is, the second control signal) of the D flip-flop 72. This is applied to the switching control input of the corresponding analog switch element (Esw) in the mixing unit 10 via the line 45. Thus, in the Csw switching control unit 67, on / off data (second control signal) corresponding to the operation of the “C switch” operation element 47 is not stored in the D flip-flop 72 without the control of the CPU 51. Since the data is stored, the on / off data (second control signal) of the D flip-flop 72 is alternatively used in the event of an abnormality such as a stop of the function of the CPU 51, so that the corresponding analog switch element (Esw) is turned on / off. The state can be recovered.
Each “C switch” operation element 47 is composed of a self-illuminating key top including an LED lamp for indicating its on / off state, and outputs the corresponding selector 71 output signal to the LED lamp. By turning on or off (lighting off), the operator can recognize the current on / off setting state.
[0031]
By the way, since the power supply to the Csw switching control unit 67 is performed by the 5-volt digital power supply 69, when the power supply to the CPU control unit 50 goes down, the stored contents of the D flip-flop 72 are also erased. Therefore, the Csw switching control unit 67 can cope with the abnormal operation of the CPU, but cannot cope with the down of the digital power supply. Conventionally, the power supply voltage for the analog switch element (Esw) in the analog mixing unit is digitally controlled and is supplied from a digital power supply. Therefore, when the digital power source is down, the analog switch element (Esw) in the analog mixing unit itself cannot be operated.
[0032]
In view of this point, in this embodiment, measures are taken so that the analog switch element (Esw) in the analog mixing unit 10 does not become inoperable even when the digital power supply is down. For this purpose, first, as shown in FIG. 1, a 15-volt power supply voltage generated by the main analog power supply 73 is supplied to each part in the mixing unit 10 and dropped to 5 volts by the second analog power supply 74. The power supply voltage for the analog switch element (Esw) is supplied to them. The main analog power source 73 is supplied with commercial AC power 100 volts via a power switch attached to the mixing unit 10.
A control signal source Vc pulled up via a resistor 33 to a control signal supply line of each analog switch element (Esw), for example, a control signal supply line 45 of the analog switch element 20n in the illustrated example of FIG. A pull-down control signal source (for example, ground voltage) is connected. In FIG. 1, for convenience, only one analog switch element 20n is pulled up to the control signal source Vc via the resistor 33. However, control signal supply lines for all analog switch elements labeled Esw are provided. Each is pulled up or pulled down to a predetermined control signal source. Whether to pull up or pull down the control signal supply line of the analog switch element (Esw) is appropriate to turn on the analog switch element (Esw) when the CPU cannot be controlled by the digital power down. Depending on whether it is appropriate to turn off or not, it is determined appropriately for each mixing setting line.
[0033]
When the digital power supplies 68 and 69 in the CPU control unit 50 are normal, the output line 45 of each Csw switching control unit 67 has a predetermined voltage for turning on the corresponding analog switch element (Esw) or a predetermined voltage for turning off. The voltage is set, and on / off of these analog switch elements (Esw) is controlled by the CPU. On the other hand, when the digital power supplies 68 and 69 in the CPU control unit 50 are down, the outputs of all the Csw switching control units 67 are turned off to enter a floating state, and a control signal supply line (45) for the corresponding analog switch element (Esw). Follows the resistance pull-up or pull-down state. That is, when the resistance is pulled up, “1” is supplied as the control signal of the corresponding analog switch element (Esw), and the analog switch element (Esw) is turned on. When the resistance is pulled down, “0” is supplied as the control signal of the corresponding analog switch element (Esw), and the analog switch element (Esw) is turned off.
[0034]
The Csw switching control unit 67 is not limited to the analog switch element (Esw), and is similarly provided for each input relay 14 and the output relays 23a, 23b, 26, and 31 in the mixing unit 10. However, for these relays, resistance pull-down or pull-up as in the case of the analog switch element (Esw) is not performed as a countermeasure when the digital power is down. As countermeasures when the digital power supply for these input relays 14 and output relays 23a, 23b, 26, 31 is down, each of these relays is configured using a normally closed contact so The relay contacts are automatically set to the on (closed) state by default.
[0035]
Next, a recovery example related to mixing processing that can be realized by the present embodiment when the function of the CPU 51 is stopped will be described.
In this case, the “C switch”, that is, each analog switch element (Esw) and each relay is turned on / off for mixing setting by the control of the corresponding Csw switching control unit 67 without depending on the CPU. The control can be continued, and further, the mixing setting can be changed as desired by controlling on / off of these “C switches” based on manual operation. On the other hand, the “C fader” in the input channel, that is, the VCA 13 controlled by the fader operator 13a, is fixed to a predetermined gain (0 dB) by a predetermined voltage given via the Y input of the selector 32. As a result, the audio signal can pass through the “C fader” of each input channel, but the level cannot be variably controlled by the “C fader”. Therefore, the level control as much as possible is performed by using the “A fader” operation element that is not CPU-controlled / manually operated according to the subsequent mixing path.
[0036]
Since the level cannot be controlled by the “C fader” of each input channel, the mixing level for each input channel for the stereo buses L and R cannot be variably set. For input channels that may be mixed with a predetermined reference level (0 dB), the analog switch elements 17a and 17b for the stereo buses L and R may be turned on and passed as they are. On the other hand, the analog switch elements 17a and 17b for the stereo buses L and R are turned off for the input channel for which the mixing level for the stereo buses L and R is to be variably adjusted. Instead, an appropriate one of the group buses GROUP is selected as a preprocessing bus to the stereo bus. For example, when the first bus (GROUP # 1) of the group bus GROUP is selected as a preprocessing bus to the stereo bus, the analog switch element 18a for the first bus (GROUP # 1) is turned on, and the group The analog switch elements 28a and 28b to the stereo bus of the output channel (GROUP # 1) for the first bus of the bus GROUP are turned on. Then, the “A fader” operator 25 of the output channel (GROUP # 1) is manually operated to variably set the desired level. Further, the pan control balance volume 27 which is the “A knob” of the output channel (GROUP # 1) is manually operated to variably set the desired pan control state. As a result, the audio signal of the input channel is mixed to the first bus of the group bus GROUP via the analog switch element 18a, and a desired output channel (GROUP # 1) "A fader" operator 25 performs a desired operation. The level is variably adjusted and redistributed to the stereo buses L and R via the pan control balance volume 27 and the analog switch elements 28a and 28b and mixed. In this way, desired mixing with respect to the stereo buses L and R can be performed via the group bus GROUP. In the output channels for the stereo buses L and R, the output level is adjusted by the “A fader” operators 22a and 22b, so that the output level can be adjusted without any problem.
[0037]
Regarding the mixing for the auxiliary bus AUX, since the “A fader” operators 19a to 19n are provided in the mixing setting line for each auxiliary bus AUX in the input channel, the level control cannot be performed by the “C fader” of each input channel. These “A fader” operators 19a to 19n may be used to manually set a desired mixing level.
[0038]
Next, a recovery example related to the mixing process that can be realized by the present embodiment when the digital power supply is shut down will be described.
In this case, the “C fader”, that is, the VCA 13 controlled by the fader operation element 13a is fixed to a predetermined gain (0 dB) as described above, and the recovery control by each Csw switching control unit 67 is invalidated. Is done. On the other hand, since each input / output relay is a normally closed contact, the input / output relay is automatically turned on by default and passes all audio signals. Each analog switch element including the electronic control switch (Esw) is turned on or off according to the resistance pull-up or pull-down state.
An example of ON / OFF setting by resistance pull-up or pull-down of each analog switch element shows that there is no element (A fader) whose level can be adjusted in the mixing setting line to the stereo buses L and R. For example, an analog switch It is preferable to set the pull-down setting so that the elements 17a and 17b are turned off.
[0039]
On the other hand, in the output channel corresponding to the group bus GROUP, as described above, the signal variably adjusted to a desired level by the “A fader” operation element 25 passes through the pan control balance volume 27 and the analog switch elements 28a and 28b. Then, by redistribution to the stereo buses L and R, mixing setting at a desired level can be performed. Therefore, it is preferable to assign a group to each input channel so that the group bus GROUP can be used. As an example, if the number of input channels is 16 and the number of output channels corresponding to the group bus GROUP is 4, it is assumed that one group is assigned to every 4 input channels, and the analog corresponding to the group to which the input channels are assigned. The resistor pull-up is set so that only the switch elements 18a to 18n are turned on, and the resistor pull-down is set so that the other analog switch elements are turned off. For example, if the input channel # 1 is assigned to the first bus group (GROUP # 1), it corresponds to the first bus group (GROUP # 1) in the mixing setting line for the group bus GROUP in the input channel # 1. The resistor pull-up is set so that only the analog switch element 18a is turned on, and the resistor pull-down is set so that the other analog switch elements 18b to 18n are turned off. Further, it is preferable to set the resistance pull-up so that the analog switch elements 28a and 28b for the stereo buses L and R in each output channel corresponding to the group bus GROUP are all turned on by default. Accordingly, even if the digital power source is down, the mixing level can be adjusted and the mixing processing to the stereo buses L and R can be performed even if the digital power source is down.
[0040]
Regarding the mixing for the auxiliary bus AUX, since the “A fader” operators 19a to 19n are provided in the mixing setting line for each auxiliary bus AUX in the input channel, the level control cannot be performed by the “C fader” of each input channel. These “A fader” operators 19a to 19n may be used to manually set a desired mixing level. Therefore, the resistor pull-up setting may be made so that the analog switch elements 20a to 20n in the mixing setting line for each auxiliary bus AUX in each input channel are all turned on by default.
[0041]
In the above embodiment, a predetermined reference voltage (ground level) is supplied to the Y input of the selector 32 of FIG. 1, and the VCA 13 is fixed to a predetermined gain when the CPU function is stopped. However, the present invention is not limited to this, and the operation amount by the fader operation element 13a may be reflected in the control of the VCA 13 even when the CPU function is stopped. For this purpose, as shown by the dotted line in FIG. 1, a slide type variable resistor 13d having a decibel characteristic is provided corresponding to the fader operator 13a, and the voltage generating circuit 13e is operated based on the output of the slide type variable resistor 13d. An analog voltage having a decibel characteristic corresponding to the operation amount of the fader operation element 13a may be generated and input to the Y input of the selector 32 instead of the predetermined reference voltage (ground level). Then, when the CPU function is stopped, when the Y input of the selector 32 is selected according to the CPU controllable signal CCE, the decibel characteristic corresponding to the operation amount of the fader operator 13a generated from the voltage generation circuit 13e is obtained. An analog voltage is selected, and the gain of the VCA 13 is set accordingly. In this case, a linear variable slide variable resistor 13b and a decibel characteristic slide variable resistor 13d may be provided in parallel to the fader operator 13a. Further, in this case, in order to reduce the manufacturing cost, the slide variable resistor 13d having the decibel characteristic is omitted, and the output of the slide variable resistor 13b having the linear characteristic is input to the voltage generation circuit 13e, and the fader operator 13a. An analog voltage having a linear characteristic may be generated according to the operation amount. In that case, although the operation performance of the VCA 13 is inferior, it can be adopted as an emergency response measure when the CPU function is stopped in consideration of the cost.
[0042]
The pull-up or pull-down resistor circuit for the control signal supply line of each analog switch element (Esw) is preliminarily set in a factory set with a predetermined pull-up or pull-down specification when the manufacturer implements the product of the present invention. You may make a circuit board like that. Alternatively, the pull-up or pull-down specification of the manufacturer may be appropriately set / changed by a jumper line. Alternatively, a dip switch for controlling the pull-up or pull-down specification may be prepared, and the setting specification may be disclosed to the user so that the user can freely set it by operating the dip switch.
[0043]
In the above embodiment, the power source for the Csw switching control unit 67 is supplied from the digital power sources 68 and 69 from the point of insufficient capacity of the analog power sources 73 and 74. However, if the capacity of the analog power supplies 73 and 74 permits, the power supply to the Csw switching control unit 67 may be supplied from the analog power supplies 73 and 74. By doing so, even when the digital power supplies 68 and 69 are shut down, the Csw switching control unit 67 operates effectively, and the operation of the analog switch element (Esw) and the relay corresponding to the “C switch” can be ensured. Therefore, in this case, setting of pull-up or pull-down for the control signal supply line of each analog switch element (Esw) becomes unnecessary.
[0044]
In the above embodiment, the fader operation element 13a is provided with the slide type variable resistor 13b, and the operation amount is detected from the output voltage. However, the fader operation element 13a is provided with a linear encoder or a rotary encoder, and its encoder output From this, the operation amount may be detected.
In the above embodiment, a relay is used as a circuit element for on / off control of an input channel, and an analog switch is used as a circuit element for on / off control of an output to a mixing bus such as a stereo bus L or R. Although an element is used, the present invention is not limited to this, and both may use a relay, or both may use an analog switch element. In addition, the switching element is not limited to a relay or an analog switching element, and any switching element that can be electrically controlled from the outside can be used.
In the above embodiment, the fader of the input channel is “C fader” and the fader of each output channel is “A fader”. However, this is not restrictive, and which fader is “C fader” and which fader is “A fader”. You may decide arbitrarily.
The number n of group buses GPOUP and the number n of auxiliary buses AUX may be the same or different from each other.
[0045]
In the embodiment of FIG. 5, whether or not the operation of the CPU 51 is normal is checked only when the analog mixer power is turned on, but this is not a limitation, and this check continues even after the power is turned on. Of course, it may be performed automatically. For example, the CPU controllable signal CCE output from the parallel I / O 59 is changed to automatically return to “0” after a predetermined time after the CPU 51 is set to “1” by the CPU 51. What is necessary is just to comprise so that this CPU controllable signal CCE may be reset to "1" regularly with a short period. Then, when an abnormality occurs in the CPU 51, the resetting of the CPU 51 fails, so that the CPU controllable signal CCE output from the parallel I / O 59 automatically becomes “0” after a predetermined time, and the CPU operation Abnormalities can be notified.
[0046]
【The invention's effect】
As described above, according to the present invention, in an analog mixer controlled by a CPU, it is possible to cope with an abnormality of a digital control system such as a CPU function stop or a shutdown of a digital system power supply and to continue mixing processing as much as possible. , Has an excellent effect.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration example of a mixing unit of an analog mixer according to an embodiment of the present invention.
2 is a block diagram showing a configuration example of a CPU control unit connected to the mixing unit in FIG. 1;
FIG. 3 is a diagram showing an arrangement example of operation module provided on the operation panel of the analog mixer according to the embodiment.
4 is a block diagram illustrating a configuration example of a Csw switching control unit in FIG. 2;
FIG. 5 is a flowchart showing a processing example of a main routine executed by a CPU in FIG.
6 is a flowchart showing an example of an on-event process of “C switch” (Csw) executed by the CPU in FIG. 2. FIG.
[Explanation of symbols]
10 Mixing section
13 VCA for faders
13a Fader control ("C fader" type)
17a, 17b, 18a-18n, 20a-20n, 28a, 28b Analog switch element ("C switch" type electronic control switch Esw)
14, 23a, 23b, 26, 31 Relay ("C switch" type)
22a, 22b, 25, 30 Fader control ("A fader" type)
47 “C switch” type controller (Csw)
50 CPU controller
51 CPU
52 flash memory
53 RAM
67 Csw switching control unit
L, R stereo bus
GROUP group bus
AUX auxiliary bus

Claims (4)

A plurality of input analog signals are respectively supplied to a plurality of analog switch elements that are controlled to be turned on / off by a control signal for mixing setting, and the analog signals that have passed through the turned on analog switch elements are selectively mixed. Mixing section ,
Wherein each corresponding to the analog switch device a first control signal respectively stored for each operator, CPU control unit that the first control signal the storage outputs the control of the CPU,
While the second control signal corresponding to the operation of the operating element respectively generated without passing through the control of the CPU, usually to select the first control signal output by the CPU control unit, said CPU A switching control means for selecting the second control signal when the control section is abnormal and supplying the selected first or second control signal to the mixing section to control on / off of the analog switch element; CPU-controlled analog mixer. A plurality of analog signals to be input to a voltage control type amplifier that controls the amplitude of the analog signal according to the control voltage signal , respectively, and a mixing unit that mixes the analog signal whose amplitude is controlled by the voltage control type amplifier ; ,
The digital data generated according to the operation amount of the full Eda operator, a CPU control unit for outputting the digital data as a first control voltage signal to analog conversion,
Normally, the first control voltage signal output by the CPU control unit is selected , while the second control voltage signal having a predetermined voltage is selected when the CPU control unit is abnormal, and the selected first or second signal is selected . A CPU-controlled analog mixer comprising selection control means for controlling the voltage-controlled amplifier by supplying the control voltage signal to the mixing unit . A plurality of analog signals to be input to a voltage control type amplifier that controls the amplitude of the analog signal according to the control voltage signal , respectively, and a mixing unit that mixes the analog signal whose amplitude is controlled by the voltage control type amplifier ; ,
The digital data generated according to the operation amount of the full Eda operator, a CPU control unit for outputting the digital data as a first control voltage signal to analog conversion,
A voltage generating means for generating an analog voltage in response to the operation amount of the full Eda operator,
Normally, the first control voltage signal output by the CPU control unit is selected , while when the CPU control unit is abnormal, the second control voltage signal consisting of an analog voltage generated by the voltage generating unit is selected, A CPU-controlled analog mixer comprising selection control means for supplying the selected first or second control voltage signal to the mixing unit to control the voltage-controlled amplifier. A plurality of input analog signals supplied with power from the first power supply are supplied to analog switch elements that are controlled to be turned on / off by a control signal for a predetermined mixing setting, and passed through the turned-on analog switch elements. A mixing unit that selectively mixes analog signals ;
Powered from the second power supply, wherein each output a control signal in response to the operation of the operation element corresponding to the analog switch device, and a digital controller for each on / off control of the analog switch element by the control signal ,
Coupled from the digital control unit to the supply line of the control signal to the analog switch device of the mixing unit, comprising a pull-up or pull-down control signal source based on the first power supply, the second power supply An analog mixer characterized in that when the control signal source is pulled down, the analog switch element is on / off controlled by the pull-up or pull-down control signal source.

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