JP5263103B2 - Firmware update device and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reliably facilitate version management of firmware of each device when an acoustic signal processing system used in a concert hall or the like is constituted of a plurality of devices connected via a network. <P>SOLUTION: Each of a plurality of devices belongs to any one of a plurality of device groups and each of partial devices in each device group includes an interface (partial bridge) for communicating with the other device group. A check box 182 is provided for designating whether firmware of the partial bridge can be updated. Thus, while holding firmware relating to the partial bridge in a version communicable with the other device group, the other firmware can be automatically updated, and firmware of a different version can be applied for each device group. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a firmware updating apparatus and program suitable for mixing audio signals in a concert hall or a recording studio.

  2. Description of the Related Art In recent years, acoustic signal processing systems in concert halls, recording studios, and the like are known in which audio signals and control signals are exchanged between devices (devices) constituting the system via a network. An example thereof is disclosed in Patent Document 1. The devices constituting the system are a console for a user to operate, an engine that performs processing such as mixing on an audio signal, and an I / O unit that controls a microphone, a speaker, and the like. And a memory for storing firmware therefor is provided. These firmwares are often updated to fix bugs and add new features. The manufacturer of the device provides the latest firmware via the Internet or the like, but it is the device owner's own decision whether to actually download and update the firmware.

  When upgrading the firmware of each device, it is necessary to execute the firmware so that no inconsistency occurs. For example, if the console and engine firmware versions are both “1.00”, the console and engine operate normally, and both firmware versions are “2.00”. Suppose it works. However, for example, if the firmware version of the console is “1.00”, but the firmware version of the engine is “2.00”, it may not operate normally. When the device manufacturer provides the latest version of firmware via the Internet etc., this point is naturally taken into account, and as long as the latest version of firmware is applied to all devices, there is a conflict with the firmware. There is no room for this to occur.

JP 2008-17084 A

However, even if the latest firmware for each device is provided by the manufacturer, the user may not (or may not be able to) align the firmware of all devices to the latest version. . This is mainly due to the following reasons.
(1) First, bugs that were not found in past versions may be mixed into the latest version of firmware. As a result, the user does not want to upgrade the firmware when the function that has been used in the past version cannot be used.
(2) Even if it is not clear whether or not bugs are mixed in the latest version, the danger always exists. For example, at the timing when the concert performance is approaching, if the old version of the firmware is operating stably, the user often desires to continue using the old version.

(3) Further, there is a problem that it takes a long time to upgrade many devices. That is, the update time per device is not so long, but hundreds of devices are used in a large-scale event. In such a case, it is rare that the merchant owns all necessary devices, and in most cases, the devices are borrowed from a plurality of rental companies. Since these devices have different owners (rental companies) in the first place, there is no guarantee that firmware consistency can be secured. Usually, in order to reduce the rental cost, the device is often borrowed immediately before a concert or the like, and sufficient time cannot be secured for upgrading the firmware.
(4) Furthermore, the owner (rental company) may not be able to obtain an understanding of upgrading the firmware of the borrowed device.

For the reasons described above, there has been a demand for updating firmware in a range in which no conflict occurs, instead of making the firmware of all devices constituting the acoustic signal processing system the latest version. However, in order to realize this, it is necessary for the user to manage the firmware version so as not to cause a conflict, which is extremely complicated for the user.
The present invention has been made in view of the above-described circumstances, and an object of the present invention is to provide a firmware update apparatus and program capable of easily and reliably performing partial upgrade of firmware.

In order to solve the above problems, the present invention is characterized by having the following configuration. The parentheses are examples.
In the firmware updating apparatus according to claim 1, each communicates with a plurality of sound processing devices (1502 to 1510) belonging to any one of a plurality of device groups, and each of these sound processing devices (1502 to 1510). Is a firmware update apparatus (1000) for updating firmware that is a control program for controlling each sound processing device, and each sound processing device is connected to another sound processing device in the device group to which each belongs. Having a first network interface (a network card in a first slot) for communicating with each other, and transmitting or receiving audio signals to each other via the first network interface, At least one of the sound processing devices is the other device group. The second network interface (network card in the second slot) for communicating with a sound processing device belonging to the group, and transmitting or receiving audio signals to and from each other via the second network interface The device group communicates audio signals between the device groups, and designates one device group as the update target device group among the plurality of device groups as the update target device group based on a user operation. A device group specifying means (152) for performing update, a device for selecting an update target device (172) for selecting an update target device that is one or a plurality of sound processing devices belonging to the device group for update based on a user operation, and a user Based on the operation of In the inter-group interface update designating means (182) for designating whether or not to update the firmware relating to the network interface (network card in the second slot), the inter-group interface update designating means (182) Update that instructs to update the firmware of each update target device, including the firmware related to the second network interface, on the condition that the firmware related to the network interface is specified to be updated A command is transmitted to each of the update target devices, while the second group interface update specifying means (182) specifies that the firmware related to the second network interface should not be updated. Ne Firmware update command means (SP32, SP34) for transmitting an update command to each update target device to instruct that the firmware of each update target device should be updated, except for firmware related to the network interface. It is characterized by comprising.
Furthermore, in the configuration according to claim 2, in the firmware updating apparatus according to claim 1, one acoustic processing device among a plurality of acoustic processing devices belonging to the update target device group based on a user operation. A reference device designating unit (154) for designating a reference device as a reference device, and obtaining a version number of firmware stored in each acoustic processing device belonging to the device group to be updated from each acoustic processing device Means (SP8), matching table storage means (24) for storing a matching table (70) for determining a consistent combination among the combinations of version numbers of the respective firmware, and stored in the reference device Based on firmware Thus, a display for identifying a sound processing device that stores firmware that does not satisfy the consistency defined in the matching table (70) from among the sound processing devices belonging to the update target device group is not performed. And a matching device display means (156).
In the program according to claim 3, each communicates with a plurality of sound processing devices (1502 to 1510) belonging to any of a plurality of device groups, and each of these sound processing devices (1502 to 1510) A program applied to a firmware updating apparatus (1000) that updates firmware that is a control program that is stored and controls each acoustic processing device, wherein each of the acoustic processing devices is in a device group to which each belongs. A first network interface (a network card in a first slot) for communicating with the sound processing device, and transmitting or receiving audio signals to and from each other via the first network interface, At least one acoustic processing device in each device group is the other By having a second network interface (second slot network card) for communicating with a sound processing device belonging to the device group and transmitting or receiving audio signals to each other via the second network interface The voice update communication is performed between the plurality of device groups, and the firmware update device (1000) has a consistency among the combinations of the processing device (10) and the version number of each firmware. And a matching table storage unit (24) for storing a matching table (70) for defining a certain combination, and one of the plurality of device groups to be updated by the firmware based on a user operation. Update device group A device group designation process (152) for designating as a group, and an update target device selection process (172) for selecting an update target device that is one or a plurality of sound processing devices belonging to the update target device group based on a user operation. ), And an inter-group interface update designation step (182) for designating whether or not to update the firmware relating to the second network interface (the network card in the second slot) based on the user's operation, Each update including the firmware related to the second network interface on condition that the firmware related to the second network interface is specified to be updated in the inter-group interface update specifying step (182). Firmware of the target device An update command for instructing to update the network is transmitted to each of the update target devices, while in the inter-group interface update designation step (182), it is designated that the firmware related to the second network interface is not to be updated. Firmware update to send an update command to each of the update target devices to update the firmware of each of the update target devices, except for the firmware related to the second network interface. A command process (SP32, SP34) is executed by the processing device (10).

According to the present invention, the inter-group interface update designation means can designate whether or not to update the firmware related to the second network interface used for communication between the device groups. It is possible to automatically update other firmware while keeping the firmware according to the above in a version that can communicate with other device groups.
As a result, it is possible to easily and reliably execute a partial version upgrade of firmware that applies different versions of firmware for each device group.

1 is a block diagram illustrating an overall configuration of an acoustic signal processing system according to an embodiment of the present invention. It is a block diagram which shows a network structure and the detailed structure of each device. 1 is a block diagram of a PC (personal computer) 1000. FIG. It is explanatory drawing of the module structure of firmware. It is a figure which shows the device group setting window 100 displayed on PC1000. It is a figure which shows the window 150 displayed on PC1000. It is a flowchart of a reference change event processing routine. It is a flowchart of an update start event processing routine.

1． Example configuration
1.1. Overall Configuration Next, the overall configuration of an acoustic signal processing system according to an embodiment of the present invention will be described with reference to FIG. The acoustic signal processing system according to the present embodiment is configured by connecting a plurality of devices via a network. These devices are classified into any one of three types of “device types” of “console”, “engine”, and “I / O unit”. The “console” includes a number of faders, knobs, and the like operated by the user, and mainly outputs control signals based on these operation states via a network. The "engine" mainly performs mixing processing and equalizing processing on the audio signal supplied via the network based on the control signal supplied from the console, and outputs the result via the network. To do. In addition, the “I / O unit” converts an audio signal input from a microphone or the like into a packet and outputs the packet via a network, converts a packet supplied via the network into an audio signal, and passes through an amplifier. Supplied to the speaker.

  In the example of FIG. 1, 1502, 1510 and 1606 are consoles, 1504 and 1604 are engines, and 1506, 1508 and 1602 are I / O units. All of these devices 1502 to 1510 and 1602 to 1606 need to be equipped with one or two network cards in order to connect to the network. For this reason, first and second slots (Slot 1 and Slot 2) are provided as slots for mounting network cards. Here, a group of devices connected via each first slot is referred to as a “device group”. In the illustrated example, since the devices 1502 to 1510 are connected via the first slots, a device group is formed, which is referred to as a “first device group 1500”. Similarly, the devices 1602 to 1606 constitute a second device group 1600.

  In addition, the console 1510 and the I / O unit 1602 have network cards mounted not only in the first slot but also in the second slot, and transmit and receive packets via the second slot. As described above, the state of the device that transmits and receives packets through the second slot is referred to as “configure a partial bridge”. The first and second device groups 1500 and 1600 each process a certain range of audio signals. For example, each of the first and second device groups 1500 and 1600 processes an audio signal of “100 channels”. In order for both device groups to cooperate, it is necessary to input / output audio signals to / from each other, but it is not necessary to supply all audio signals to each other. You can work together by supplying audio signals. As described above, since the audio signal input / output between the device groups is partial (partial), it is referred to as “partial bridge”.

  A plurality of device groups connected via a partial bridge form a “zone”. In the illustrated example, a zone 1400 is formed by first and second device groups 1500 and 1600. However, the number of device groups belonging to one zone may be “3” or more. In this case, in each device belonging to each device group, a network card may be mounted in the second slot, and the network cards in the second slot may be connected to each other. The device group is configured to play various “collective roles” (for example, mixing of back choruses, mixing of musical instrument sounds, etc.), as well as device owners (for example, vendors themselves, rental company A, rental company B, etc.) It is preferable to configure each unit collectively.

  Reference numeral 1000 denotes a PC (personal computer), which can be connected to any device. The PC 1000 can acquire information on the entire zone (for example, firmware version information on all devices connected to the zone 1400) via the connected device, and can be assigned to any device belonging to the zone 1400. On the other hand, an update command (a command to instruct firmware update together with firmware binary data) can be transmitted. Acquisition of information on another device group to which a device connected to the PC 1000 does not belong and transmission of an update command to the other device group are realized via a partial bridge. The “update” in the present embodiment is a concept including not only updating the firmware to a new version but also returning the firmware to an old version (so-called down date).

1.2. Network Configuration In this embodiment, devices belonging to each device group configure a token ring network by connecting network cards installed in the first slot to each other. A configuration example of the network 1520 in the first device group 1500 is shown in FIG. In a token ring network, any one device (I / O unit 1508 in the illustrated example) becomes a master node and generates a signal called “token”. This token is cyclically transmitted to each device belonging to the first device group 1500 in a predetermined order.

  Here, only the device that obtained the token has the right to transmit data. In other words, a device that is going to transmit data first captures a vacant token, converts it into a frame, and transmits it with data. Each device monitors incoming frames and captures the contents only when the address of its own device is specified as the receiving destination. For frames that are not addressed to its own device, it should be sent to the next node as it is. It has become. As a result, data communication can be performed between devices without data collision. Although the network configuration of the first device group 1500 has been described above, the network of the second device group 1600 is configured in the same manner, and the network mounted in the second slot is also between the devices configuring the partial bridge. -A token ring network is also formed by connecting cards. In this way, it is also possible to exchange data between device groups by interconnecting a plurality of networks via a partial bridge.

1.3. Next, the detailed configuration of each device will be described. First, the configuration of the “console” will be described with reference to FIG. In the figure, reference numeral 1110 denotes a panel display unit, which is composed of a large dot matrix display and a touch panel, and displays various information to the user. Reference numeral 1112 denotes a panel operation unit, which includes operation units such as knobs and buttons. An electric fader 1122 is used for adjusting the volume of the input / output channel. A memory 1116 includes a flash ROM and a RAM, and firmware, which is a console control program, is stored in the flash ROM. Reference numeral 1114 denotes a CPU, which controls each unit in the console via the CPU bus 1120 based on the firmware. Reference numeral 1118 denotes a PCIO unit, which is provided with an interface for communicating with the PC 1000. Reference numeral 1124 denotes an audio I / O unit which inputs and outputs small audio signals such as monitor signals for communication between workers.

  Reference numeral 1126 denotes a network I / O unit, which is provided with the above-described first and second slots. When a network card is inserted into these slots, the network I / O unit 1126 can communicate with other devices via one or two networks. Data can be sent and received between them. That is, the network I / O unit 1126 converts the control signal supplied from the CPU bus 1120 and the audio signal supplied from the audio bus 1130 into packets, transmits them to the network, and sends the packets supplied from the network. Are converted into control signals or audio signals and output via the CPU bus 1120 or audio bus 1130.

  Next, the configuration of the “engine” will be described with reference to FIG. A memory 1212 includes a flash ROM and a RAM, and firmware, which is an engine control program, is stored in the flash ROM. Reference numeral 1210 denotes a CPU which controls each part in the engine via the CPU bus 1220 based on the firmware. Reference numeral 1214 denotes a PCIO unit, which is provided with an interface for communicating with the PC 1000. Reference numeral 1216 denotes a simple UI unit which includes an operator operated by the user and a display for displaying various information to the user. An audio I / O unit 1218 inputs and outputs small audio signals for communication between workers. Reference numeral 1222 denotes a DSP that performs mixing processing or equalizing processing on the audio signal received via the audio bus 1230 and outputs the result via the audio bus 1230. The firmware for controlling the DSP 1222 is also included in the firmware.

  Reference numeral 1226 denotes a network I / O unit, which is provided with the above-described first and second slots. By attaching a network card to these slots, it is possible to communicate with other devices via one or two networks. Data can be sent and received between them. That is, the network I / O unit 1226 converts the control signal supplied from the CPU bus 1220 and the audio signal supplied from the audio bus 1230 into packets, transmits them to the network, and sends the packets supplied from the network. Are converted into control signals or audio signals and output via the CPU bus 1220 or audio bus 1230.

  Next, the configuration of the “I / O unit” will be described with reference to FIG. A memory 1312 includes a flash ROM and a RAM, and firmware, which is a control program for the I / O unit, is stored in the flash ROM. Reference numeral 1310 denotes a CPU, which controls each unit in the I / O unit via the CPU bus 1320 based on the firmware. Reference numeral 1314 denotes a PCIO unit, which is provided with an interface for communicating with the PC 1000. Reference numeral 1316 denotes a simple UI unit which includes an operator operated by the user and a display for displaying various information to the user. An audio I / O unit 1324 converts an audio signal received via the audio bus 1330 into an analog signal or a digital signal suitable for a target amplifier and outputs the audio signal, and an audio signal input from a microphone or the like. Is converted to a digital signal and supplied to the network I / O unit 1326 via the audio bus 1330.

  Reference numeral 1326 denotes a network I / O unit, which is provided with the above-described first and second slots. By attaching a network card to these slots, it is possible to communicate with other devices via one or two networks. Data can be sent and received between them. That is, in the network I / O unit 1326, the control signal supplied from the CPU bus 1320 and the audio signal supplied from the audio bus 1330 are converted into packets and transmitted to the network, and the packet supplied from the network is also transmitted. Are converted into control signals or audio signals and output via the CPU bus 1320 or audio bus 1330.

1.4. Next, the configuration of the PC 1000 will be described with reference to FIG.
In the figure, reference numeral 2 denotes a communication interface, which communicates with a file server or the like via the Internet for downloading firmware, etc., and communicates with the PCIO units 1118, 1214, and 1314 of any device for controlling the zone 1400. Is provided to do. Reference numeral 4 denotes an input device, which includes a character input keyboard and a mouse. Reference numeral 8 denotes a display that displays various information to the user. Reference numeral 10 denotes a CPU, which controls other components via the CPU bus 16 based on a program described later. A ROM 12 stores an initial program loader and the like. A removable disk drive 18 reads / writes data from / to a removable disk 20 such as a CD-ROM or MO. A hard disk 24 stores an operating system, firmware of devices in the zone 1400, application programs for updating these firmware, and the like. A RAM 30 is used as a work memory for the CPU 10.

2． Firmware configuration
2.1. Firmware Module Configuration in Device As described above, firmware for controlling each device is stored in the memory 1116, 1212, and 1312 (flash ROM) of each device. It consists of multiple modules. The contents will be described with reference to FIG. First, the firmware 40 in the console is mounted in the first and second slots, a panel module 41 that controls the panel operation unit 1112, the electric fader 1122, and the like, a display module 44 that controls the panel display unit 1110, and the like. The network modules 46 and 48 for controlling the network card, and the CPU module 42 for performing other controls.

  The firmware 50 in the engine includes a DSP module 54, which is a micro program of the DSP 1222, network modules 56 and 58 for controlling the network cards installed in the first and second slots, and a CPU for performing other controls. The module 52 is comprised. The firmware 60 in the I / O unit includes a voice I / O module 64 that controls the function of the voice I / O unit 1324, and a network module that controls the network card installed in the first and second slots. 66 and 68, and a CPU module 62 for performing other controls.

  In the example of FIG. 4 (a), it is assumed that each device has a network card installed in both the first and second slots, but a network card is installed in the second slot. If not, the corresponding modules 48, 58, 68 are not included in the firmware in these devices. In these devices, either of two types of network cards (hereinafter referred to as type A and type B) having different transmission capacities (for example, 1 Gbps and 2 Gbps) can be selected and mounted. Accordingly, the network card may be used in the case where only one or two type A network cards are installed, in which only one or two type B network cards are installed, and A case where one of each of type A and B network cards is mounted is considered.

2.2. Firmware module configuration in the PC Also, the firmware for update corresponding to each device type is stored in a predetermined folder of the hard disk 24 of the PC 1000. These firmware are also stored in a plurality of modules. It is configured. The contents will be described with reference to FIG. First, the console firmware 240 corresponds to each of the modules 41, 42, and 44 in the above-described console firmware 40, a panel module 241, a CPU module 242, and a display module. 244. The firmware 240 includes a type A network module 246 and a type B network module 248 corresponding to the type A and B network cards.

  Whether or not both network modules 246 and 248 are necessary depends on the configuration of the actual device (in this case, the console), but the modules included in the PC 1000 include all modules that may be necessary. When actually updating the device firmware, only the necessary modules are selected and transferred to each device. Since the modules 241 to 248 in the firmware 240 are updated according to different circumstances, the version numbers (for example, “1.0”, “2.0”, “ 1.5 ”etc.). As shown in the figure, the console firmware 240 is given a version number of “2.0”. In other words, this version number is a version number assigned to the entire set of modules 241 to 248 shown in the figure.

  The engine firmware 250 includes a CPU module 252 and a DSP module 254 for updating the modules 52 and 54 in the firmware 50 in the engine. Further, network modules 256 and 258 for type A and B are included. The network modules 256 and 258 are similar to the console network modules 246 and 248 described above. Then, a version number of “2.5” is assigned to the engine firmware 250 (in other words, to the set of all engine modules).

  Also, the firmware 260 for the I / O unit corresponds to the modules 62 and 64 in the firmware 60 in the I / O unit described above, and a CPU module 262 for updating them, and an audio I / O unit. O module 264 and network modules 266 and 268 for type A and B are further included. The network modules 266 and 268 are similar to the console network modules 246 and 248 described above. A version number of “1.5” is assigned to the firmware 260 for the I / O unit (in other words, to the set of the entire module for the I / O unit). The version number for each module and the version number as a set of modules for each device are transmitted from the PC 1000 to each device when updating the firmware, and the flash ROMs of the memories 1116, 1212 and 1312 in each device. These version numbers are also stored.

2.3. Matching Table Further, a matching table 70 shown in FIG. 4C is stored in the predetermined folder of the hard disk 24 of the PC 1000. This table defines combinations that do not cause inconsistencies (conflicts) with respect to firmware versions of devices (versions in device units). For example, according to the top column of FIG. 4 (c), if the version of firmware 40 in the console is “2.0”, the version of firmware 50 in the engine cooperating with this console is “2”. .5 "or" 2.0 "and the version of firmware 60 in the I / O unit cooperating with this console must be" 1.5 ".

3． Operation of the embodiment
3.1. Processing in Device Group Setting Window Next, the operation of this embodiment will be described. First, the hard disk 24 of the PC 1000 stores data (device group data) in which the configuration of each device group in the zone 1400 is recorded. When the user performs a predetermined operation on the PC 1000, a device group setting window 100 shown in FIG. 5 is displayed on the display 8 in order to edit the device group data. In FIG. 5, reference numeral 102 denotes a device group selection list box, which selects one device group to be set. A device setting column 103 displays a list of devices belonging to the device group. In the device setting field 103, reference numeral 104 denotes an identification number display field, which displays a unique identification number (ID) automatically assigned to each device belonging to the selected device group. A device name display unit 106 displays the name of each device.

  A device type display unit 108 displays a device type to which each device belongs. Reference numeral 110 denotes a partial bridge setting unit, which includes check boxes for setting whether each device is a device constituting a partial bridge. In the illustrated example, the console with “ID = 5” constitutes a partial bridge. A device type selection unit 112 includes radio buttons for selecting a type of a device to be newly added. Reference numeral 114 denotes an Add button. When the button is clicked with a mouse, the device of the type selected by the device type selection unit 112 is added to the current device group.

  Reference numeral 116 denotes a rename button, which is provided for changing the name of an arbitrary device. That is, when the user selects an arbitrary device in the device setting field 103 and clicks on the rename button 116 with the mouse, the corresponding device field in the device name display unit 106 is changed to a text box, and the user enters the text box. The name of the device can be changed. Reference numeral 118 denotes a remove button, which is provided to delete an arbitrary device. That is, when the user selects an arbitrary device in the device setting field 103 and clicks the remove button 118 with the mouse, the device is deleted from the currently selected device group. When an OK button 122 is clicked with the mouse, the device group data in the hard disk 24 is updated based on the setting contents in the device group setting window 100, and the window 100 is closed. When a cancel button 120 is clicked with the mouse, the setting contents in the window 100 are discarded, and the window 100 is closed without updating the device group data.

  The contents of the device setting field 103 in FIG. 5 correspond to the configuration of the first device group 1500 shown in FIG. That is, the devices with IDs “1” to “5” correspond to the devices 1502 to 1510. Since the device group setting window 100 is for editing the device group data stored in the hard disk 24 of the PC 1000, the device group data can be edited differently from the actual device group configuration. The device group data can be edited even when the PC 1000 is not connected to any device.

  After that, when the user connects the PC 1000 to one of the devices and performs a predetermined operation on the PC 1000, the device group data in the PC 1000 and the status of the device group actually configured are collated, and there is a difference between the two. In some cases, an error message is displayed on the PC 1000 to correct either one. On the other hand, if there is no contradiction between the device group data in the PC 1000 and the actual device group state, the firmware version numbers in all the devices in the zone 1400 are set via the connected devices. Obtained and the result is taken into the device group data.

3.2. Display of Firmware Update Window After the version number of the device in the zone 1400 is taken into the device group data in the PC 1000, when the user performs a predetermined operation on the PC 1000, the firmware update window 150 shown in FIG. Is done. In FIG. 6, reference numeral 152 denotes a device group selection list box, which selects a device group to be a firmware update target based on a user operation. In this embodiment, by providing this device group selection list box 152, for example, when there is no time to upgrade all devices, version upgrade is performed only for device groups that need to be upgraded. It can be carried out. In addition, for devices whose firmware upgrade is prohibited due to the circumstances of the owner (rental company), etc., other devices (upgraded) can be created by configuring a device group with only such devices. It is possible to prevent a conflict with the device.

  A device setting field 153 displays a list of devices belonging to the device group. The contents of the device setting field 153 in FIG. 6 correspond to the configuration of the first device group 1500 shown in FIG. 1 and the contents of the device setting field 103 in FIG. In the device setting field 153, reference numeral 154 denotes a reference setting unit that selectively sets any one device in the device group as a “reference device” based on a user operation. The “reference device” is a device that serves as a reference when determining whether or not there is a firmware version conflict. A conflict display unit 156 displays whether or not a conflict has occurred on the reference device. A device name display unit 158 displays the name of the device. A device type display unit 160 displays the type of the device. Reference numeral 162 denotes a partial bridge display unit which is turned on when the device constitutes a partial bridge. Reference numeral 164 denotes a current version display unit, which displays the firmware version currently stored in each device.

  Here, specific contents of the display contents in the device setting field 153 will be described. In the illustrated example, the reference device is the device in the first row in the device setting field 153, which has the name “Main Console” and the device type is “console”. According to the current version display unit 164, the current version of the firmware is “2.0”. According to the matching table 70 shown in FIG. 4C, if the firmware version of the console is “2.0”, the firmware version of the engine cooperating with the console is “ It must be “2.5” or “2.0” and the firmware version of the I / O unit cooperating with the console must be “1.5”.

  However, since the versions of the I / O units in the third and fourth lines of the device setting column 153 shown in the figure are “1.2” and “1.1”, they do not follow the contents of the matching table 70. That is, the firmware of these I / O units has a conflict with the firmware of the reference device. As a result, in the device setting field 153, the conflict display section 156 corresponding to these I / O units is lit. Reference numeral 168 denotes a firmware / folder setting unit, which includes a text box for designating a folder in the hard disk 24 in which firmware (firmware 240, 250, 260 in FIG. 4B) is stored. Reference numeral 170 denotes a browse button. When the button is clicked with a mouse, a browse window opens, and a folder name to be described in the firmware / folder setting unit 168 can be input by a browse operation. The firmware 240, 250, and 260 are the latest versions, but if older versions of firmware are stored in the same folder, the older versions of firmware can be selected as update destinations. Become.

  Reference numeral 171 denotes an update setting field, which is composed of a plurality of lines each corresponding to a device type. In the update setting column 171, reference numeral 176 denotes a device type name display section, and device type names “Console”, “Engine”, and “I / O unit (I / O)” corresponding to each row are displayed. Is displayed. Reference numeral 172 denotes an update target device selection unit, which includes check boxes for each device type, and selects a device type for which the firmware is to be updated (checked) based on a user operation. A conflict display unit 174 displays the device type in which the conflict has occurred according to the lighting state. If a conflict occurs in at least one device among the devices belonging to the device type, the conflict occurs in the device type.

  Reference numeral 178 denotes a version selection list box, which selects an update destination version number for each device type based on a user operation from one or a plurality of version numbers suitable for the reference device. The options listed in these list boxes are as described in the matching table 70. That is, if the firmware version in the console as the reference device is “2.0”, the firmware version in the other consoles must also be “2.0”. Only “2.0” can be selected. As for the engine, since both firmware versions “2.5” and “2.0” are compatible, both are set as options in the list box. For the I / O unit, since the firmware version must be “1.5”, only “1.5” can be selected.

In this way, in this embodiment, the user can specify the firmware update destination version for each “device type”, so even if the number of devices in the device group is large, the update destination of these devices can be specified. The version can be easily specified with few operations. As described above, the reason for designating the version for each device type is that there is generally no reason to make the firmware version different for devices of the same type belonging to the same device group.
In addition, according to the present embodiment, since the version of the firmware is selected in the version selection list box 178, the user can reliably select a version that is consistent with the reference device (no conflict occurs). can do.

  Reference numeral 180 denotes a status display unit that displays the progress of the update. “Rebooting” in the figure indicates a state in which each device is restarted after the firmware update is completed. “Complete” indicates a state where the restart is completed. “Updating” indicates that the firmware is being written to the flash ROM. Reference numeral 182 denotes a partial bridge exclusion check box, which sets whether to exclude the firmware for the network card installed in the second slot for the partial bridge from the update target based on a user operation. That is, when the check box is checked, the network card is excluded from the update target.

  When an update start button 184 is clicked with the mouse, an update command (along with firmware binary data and firmware binary data) is sent from the PC 1000 to the target device in accordance with the specification in the update setting field 171 and the check box 182. (Command to command update) starts to be transmitted. As described above, the display content of the status display unit 180 is appropriately updated according to the progress of the update. When a cancel button 186 is clicked with the mouse, the setting contents in the firmware update window 150 are discarded and the window 150 is closed. A close button 188 closes the window 150 after the device group data is updated based on the setting contents in the window 150. Note that once the update start button 184 is clicked, the update itself is executed in a separate process, so that the update continues even if the window 150 is closed.

  Here, the significance of providing the partial bridge exclusion check box 182 described above will be described with reference to FIG. 1 again. In FIG. 1, devices 1502 to 1510 belonging to the first device group 1500 are devices owned by a certain company, and devices 1602 to 1606 belonging to the second device group 1600 are borrowed from the rental company by the company. Suppose there is. For these borrowed devices, as described above, situations such as “the time for updating the firmware cannot be secured” or “update of the firmware is prohibited” often occur. In that case, first, the firmware version of the network card (rental product) installed in the second slot of the I / O unit 1602 is checked, and the network card (contractor) installed in the second slot of the console 1510 is checked. It is preferable to update (or down-date) manually (without using the application program according to FIG. 6) so as to match the firmware version of

  As a result, since the version numbers of the network cards in the second slot constituting the partial bridge are aligned, there should be no trouble in communication between the console 1510 and the I / O unit 1602. Thereafter, the application program according to FIG. 6 is started, the check box 182 is checked, and the firmware other than the network card is updated. As a result, communication between the first and second device groups 1500 and 1600 becomes possible without performing any firmware update for the second device group 1600.

3.3. Reference change event processing (Figure 7)
Next, details of processing executed when the reference setting unit 154 is operated in FIG. 6 and the reference device is changed will be described. When the operation is detected, the reference change event processing routine shown in FIG. 7 is started.
When the processing proceeds to step SP2 in the figure, one device checked by the reference setting unit 154, that is, a reference device is specified. Next, when the process proceeds to step SP4, the device type of the reference device and the firmware version are acquired. Next, when the process proceeds to step SP6, the contents of the column corresponding to the acquired version are acquired from the matching table 70 (see FIG. 4C).

  Next, when the process proceeds to step SP8, version numbers are acquired for all devices other than the reference device. Then, it is determined whether or not there is a version mismatch (conflict) between the reference device and all other devices, and display contents corresponding to each device in the conflict display unit 174 are determined based on the result. Is updated. Next, when the process proceeds to step SP10, a list of versions that cause no version mismatch is set as an option in the version selection list box 178 for the reference device and all other devices. Thus, the processing of this routine ends.

3.4. Update start event processing (Figure 8)
Next, details of processing executed when the update start button 184 is clicked with the mouse in FIG. 6 will be described. When the operation is detected, an update start event processing routine shown in FIG. 8 is started.
In FIG. 8, when the process proceeds to step SP20, it is determined whether or not update command transmission start processing (steps SP32 and SP34 described later) is completed for all the update target device types. If “NO” is determined here, the process proceeds to step SP22, and one of the unprocessed device types is selected. Next, when the processing proceeds to step SP24, it is determined whether or not the update command transmission start processing has been completed for all devices belonging to the selected device type. If "NO" is determined here, the process proceeds to step SP26, and one of the devices belonging to the type is selected. The device selected here is referred to as “target device”.

  Next, when the process proceeds to step SP28, it is determined whether or not a network card for partial bridge is installed in the second slot of the target device. If it is determined “NO” (not installed), the process proceeds to step SP34, and all modules stored in the target device are within the version specified in the version selection list box 178 previously. An update command is sent to update the module. That is, a new process for transmitting an update command is started, and the update command is transmitted in the process. On the other hand, if a network card for partial bridge is installed in the second slot of the target device, “YES” is determined in step SP28, and the process proceeds to step SP30. Here, based on whether or not the above-mentioned partial bridge exclusion check box 182 is checked, whether the network card for the partial bridge installed in the second slot is also subject to firmware update. It is determined whether or not. If "YES" is determined here, the process proceeds to step SP34, and an update command is transmitted so that all modules stored in the target device are updated to modules within the specified version as described above. Is started.

  On the other hand, if the partial bridge exclusion check box 182 is checked, it is determined as “NO” (not subject to update) in step SP30, and the process proceeds to step SP32. Here, without updating the network card of the second slot for the partial bridge, all other modules are updated to the modules in the version specified in the version selection list box 178 first. An update command is sent to the device. When the process of step SP32 or SP34 is completed, the process returns to step SP24, and is the update command transmission start process (SP32, SP34) completed for all devices belonging to the device type previously selected in step SP22? It is determined whether or not. If “NO” is determined here, the processing of steps SP26 to SP34 is repeated, and transmission of an update command is started to the new target device via steps SP32 and SP34 each time.

  On the other hand, when the update command transmission start process is completed for all devices belonging to the selected device type, “YES” is determined in step SP24, and the process returns to step SP20. Here, if update command transmission start processing has not been completed for all device types to be updated, it is determined as “NO” in step SP20, and the processing in steps SP22 to SP34 is repeated. When the update command transmission start processing is completed for all devices belonging to the device group to be updated and belonging to the device type to be updated, “YES” is determined in step SP20, and the processing of this routine is performed. finish.

Four. Modifications The present invention is not limited to the above-described embodiments, and various modifications can be made as follows, for example.
(1) In the above embodiment, the update process is performed by the application program running on the PC 1000. However, only this application program is stored in a recording medium such as a CD-ROM or a memory card and distributed or transmitted. It can also be distributed through the road.

(2) In the above embodiment, “specify the firmware version for each device type in the version selection list box 178 (feature 1)” and “second slot related to the partial bridge by the partial bridge exclusion check box 182”. However, only one of the features may be applied. When only “Feature 1” is applied, the check box 182 is simply removed from the window 150. When only “feature 2” is applied, the update setting field 171 is not “device type”, but a row is provided for each “device” in the same way as the device setting field 153, and the version number of the update destination for each device. Should be specified.

2: communication interface, 4: input device, 8: display, 10: CPU (processing device), 12: ROM, 16: CPU bus, 18: removable disk drive device, 20: removable disk, 24: hard disk, 30: RAM 40, 50, 60: Firmware, 41: Panel module, 42: CPU module, 44: Display module, 46, 48: Network module, 52: CPU module, 54: DSP module, 56, 58: Network module, 62 : CPU module, 64: Audio I / O module, 66, 68: Network module, 70: Matching table, 100: Device group setting window, 102: Device group selection list box, 103: Device setting column 104: Identification number display field 106: Device name display part 108: Device type display part 110: Partial bridge setting part 112: Device type selection part 114: Add button 116: Rename button 118: Remove Button: 120: Cancel button 122: OK button 150: Window 150: Firmware update window 152: Device group selection list box (device group designation means) 153: Device setting field 154: Reference setting section 156: Conflict display section (mismatched device display means), 158: Device name display section, 160: Device type display section, 162: Partial bridge display section, 164: Current version display section, 168: Firmware / folder setting section, 170: Bu Use button, 171: Update setting field (update target device selection means), 172: Update target device selection section (update target type selection means), 174: Conflict display section, 176: Device type name display section, 178: Version selection List box (version number selection means), 180: status display section, 182: check box, 182: partial bridge exclusion check box, 184: update start button, 186: cancel button, 188: close button, 240, 250, 260: Firmware, 241: Panel module, 242, 252, 262: CPU module, 244: Display module, 246, 248, 256, 258, 266, 268: Network module, 254: DSP module 264: Voice I / O module, 1000: PC (firmware update device), 1400: Zone, 1500: First device group, 1600: Second device group, 1502-1510, 1602-1606: Device.

Claims (3)

Firmware updating apparatus that communicates with a plurality of sound processing devices each belonging to any one of a plurality of device groups and updates firmware that is stored in each of the sound processing devices and is a control program for controlling each sound processing device Because
Each of the sound processing devices has a first network interface for communicating with other sound processing devices in a device group to which the sound processing device belongs, and transmits or receives audio signals to each other via the first network interface. Is what
At least one acoustic processing device in each of the device groups has a second network interface for communicating with acoustic processing devices belonging to another device group, and audio signals are mutually transmitted via the second network interface. To communicate audio signals between the plurality of device groups by transmitting or receiving
A device group designating unit for designating, as an update target device group, one device group to be updated of the firmware among the plurality of device groups based on a user operation;
Update target device selection means for selecting an update target device that is one or a plurality of sound processing devices belonging to the update target device group based on a user operation;
An inter-group interface update designation means for designating whether to update the firmware related to the second network interface based on a user operation;
Each update target device including the firmware related to the second network interface on the condition that the inter-group interface update specifying means specifies that the firmware related to the second network interface is updated An update command for instructing that the firmware of the second network interface should be updated is sent to each of the update target devices, while the inter-group interface update designation means designates not to update the firmware related to the second network interface On the condition that the update command for instructing that the firmware of each update target device should be updated, except for the firmware related to the second network interface, is sent to each update target device. Firmware update apparatus characterized by comprising a wear updating command means. Reference device designating means for designating one of the plurality of sound processing devices belonging to the update target device group as a reference device based on a user operation;
Version number acquisition means for acquiring the version number of the firmware stored in each sound processing device belonging to the update target device group from each sound processing device;
Matching table storage means for storing a matching table that defines a consistent combination among the combinations of version numbers of the firmware,
Audio that stores firmware that does not satisfy the consistency defined in the matching table from among the audio processing devices that belong to the device group to be updated with reference to the firmware stored in the reference device The firmware update apparatus according to claim 1, further comprising: an inconsistent device display unit that performs display for specifying a processing device. Firmware updating apparatus that communicates with a plurality of sound processing devices each belonging to any one of a plurality of device groups and updates firmware that is stored in each of the sound processing devices and is a control program for controlling each sound processing device A program that applies to
Each of the sound processing devices has a first network interface for communicating with other sound processing devices in a device group to which the sound processing device belongs, and transmits or receives audio signals to each other via the first network interface. Is what
At least one acoustic processing device in each of the device groups has a second network interface for communicating with acoustic processing devices belonging to another device group, and audio signals are mutually transmitted via the second network interface. To communicate audio signals between the plurality of device groups by transmitting or receiving
The firmware update device includes a processing device and a matching table storage unit that stores a matching table that defines a consistent combination among the combinations of version numbers of the firmware.
A device group designation process for designating one device group that is an update target of the firmware among the plurality of device groups as an update target device group based on a user operation;
An update target device selection process for selecting an update target device that is one or more acoustic processing devices belonging to the update target device group based on a user operation;
An inter-group interface update designation process for designating whether to update the firmware related to the second network interface based on a user operation;
Each update target device including the firmware related to the second network interface on the condition that the firmware related to the second network interface is specified to be updated in the inter-group interface update specification process An update command instructing that the firmware of the second network interface should be updated is sent to each of the update target devices, while it is designated not to update the firmware related to the second network interface in the inter-group interface update designation process On the condition that the update command for instructing that the firmware of each update target device should be updated, except for the firmware related to the second network interface, is sent to each update target device. A program characterized by executing the software update command process in the processing device.

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