JP4747811B2 - Node device and dimming system - Google Patents

Description

  The present invention relates to a node device used when transmitting a dimming signal for controlling dimming of a lighting load in a lighting facility such as a stage or a studio, and a dimming system configured using the node device.

Conventionally, as a dimming system that collects a plurality of dimmers in one system and controls the dimming of a large number of illumination loads by providing a plurality of dimmers, as shown in Patent Document 1, a wireless device is provided for each system. A device provided with a machine as a node device is known.
JP 2000-195681 A

  In recent years, DMX512, which is a dimming signal standard for dimming control using a digital signal used in a production field or the like standardized by the American Theater Technology Association (USITT), has been increasingly used. In the dimming system using the DMX signal, which is the dimming signal by the DMX 512, a dimming signal from the dimming console and transmitting to the dimmer side as a DMX signal are transmitted. The reception side nodes provided on the optical device side and receiving the DMX signal are connected in a one-to-one relationship.

  That is, in the dimming system using the DMX signal, only one system (512 channels) is transmitted between the one-to-one node devices. Accordingly, dimming data for 512 channels at maximum can be transmitted between one-to-one node devices, and in a system that needs to transmit dimming data exceeding 512 channels, every 512 channels. It was necessary to add one-to-one node devices. Further, it is necessary to prepare a separate distributor for branching the DXM signal on the DMX output side, which requires another hardware configuration.

  The present invention has been made in view of the current state of the dimming system using the DMX signal as described above, and an object of the present invention is to transmit data of a plurality of systems of DMX signals without adding a node device. The present invention also provides a node device capable of transmitting data of a desired DMX signal on the input side to a desired system on the DMX output side. Another object is to reduce the amount of information sent to the LAN by setting the data in the necessary channel range and transmitting the data when the DMX signal data is transmitted via the LAN using the node device. It is to provide a dimming system that makes it possible.

The node device according to the present invention includes a plurality of input units each receiving a DMX signal in which data of a predetermined number of channels are multiplexed in one system; and a plurality of DMX signals input to the plurality of input units. In the case of multiplexing data, an arrangement position setting means for setting position information for arranging the data of the DMX signal for each system; and using the position information set in the arrangement position setting means, the DMX signal of a plurality of systems A multiplexing unit that multiplexes the data; and a transmission unit that transmits the data multiplexed by the multiplexing unit to the LAN.
Here, Ethernet (registered trademark) is allowed as the LAN. Further, a rotary switch capable of setting a range of 1 to 2048 can be used as the arrangement position setting means. The input unit may include a connector for receiving a single system 512-channel DMX signal.

A node device according to the present invention includes: a receiving unit that receives, from a LAN, data in which data of a plurality of systems of DMX signals is multiplexed; data in which data of a plurality of systems of DMX signals are multiplexed; Extraction position setting means for setting position information for extracting DMX signal data for each system when separating into DMX signal data; and data multiplexed using the position information set in the extraction position setting means And a plurality of output units for outputting DMX signal data of several systems separated by the separation unit as DMX signal data for each system And characterized by comprising: and.
Here, Ethernet is allowed as the LAN. Further, a rotary switch that can set a range of 1 to 2048 can be used as the take-out position setting means. The input unit can include a connector for outputting a single-system 512-channel DMX signal.

The node device according to the present invention includes: an identification information setting unit in which identification information for each node device is set; an IP address creating unit that creates an IP address including the identification information set in the identification information setting unit; A setting inspection that broadcasts inspection packets every predetermined time using the IP address created by the means as a transmission source address, receives an inspection packet, and detects an error in the identification information set in the identification information setting unit And a portion.
Here, a rotary switch capable of setting a 2-digit numerical value can be used for the identification information setting unit.

  The node device according to the present invention includes a display unit for displaying a setting error; the setting inspection unit receives the inspection packet including the identification information set in the identification information setting unit in the transmission source address. A setting error is displayed on the display unit.

  A dimming system according to the present invention is a dimming system in which the node device according to claim 1 and the node device according to claim 2 transmit and receive data via a LAN, and the node according to claim 2 The apparatus includes a position information notification unit that broadcasts a status packet including the position information set in the extraction position setting unit every predetermined time; the node device according to claim 1, A multiplexing control unit that obtains a required channel range based on position information transmitted from the mobile station, sets data of the DMX signal to the corresponding channel in the required channel range, and performs multiplexing. .

  According to the node device of the present invention, when data of a plurality of DMX signal signals input to a plurality of input units is multiplexed, an arrangement in which position information for disposing DMX signal data for each system is set. Since the position information set in the position setting means is used to multiplex the DMX signal data of a plurality of systems and transmit the multiplexed data to the LAN, the data of the DMX signals of a plurality of systems are multiplexed. Can be transmitted from one node device.

  Also, according to the node device of the present invention, data obtained by multiplexing data of DMX signals of a plurality of systems is received from the LAN, and the multiplexed data is separated into data of DMX signals of several systems. In this case, the multiplexed data is separated into DMX signal data of several systems using the position information set in the extraction position setting means in which the position information for extracting DMX signal data for each system is set. In addition, since a configuration is used in which data of several separated DMX signal data is output as DMX signal data for each system, data obtained by multiplexing data of DMX signals of a plurality of systems is used. The data can be received by one node device, separated into DMX signal data of several systems, and the DMX signal data can be output for each system.

  According to the dimming system of the present invention, in a node device that receives data obtained by multiplexing DMX signal data of a plurality of systems from a LAN, a status packet including position information set in the extraction position setting means is predetermined. In a node apparatus that broadcasts every time and transmits data obtained by multiplexing data of DMX signals of a plurality of systems to a LAN, a required channel range is obtained based on position information that has arrived by the broadcast transmission. Since the DMX signal data is set in the corresponding channel and multiplexed, the amount of information sent to the LAN can be reduced.

  In the present invention, a plurality of DMX signal data input to a plurality of input units are multiplexed and transmitted from one node device to the LAN, and the multiplexed data of the plurality of DMX signal data is transmitted. Received by one node device from LAN, separated into several DMX signal data, and output several separated DMX signal data as DMX signal data for each system By adopting such a configuration, data transmission of a plurality of systems of DMX signals and reception of data obtained by multiplexing data of a plurality of systems of DMX signals are realized by a single node device connected to the LAN. This has been achieved.

  Further, in the present invention, data obtained by multiplexing the data of a plurality of DMX signals is received from the LAN and separated into several DMX signal data. Understand the channel range used in the node device on the side that outputs the data as DMX signal data for each system, and set the DMX signal data to the corresponding channel in the required channel range to perform multiplexing This achieves the purpose of reducing the amount of information sent to the LAN.

  Embodiments of a node device and a dimming system according to the present invention will be described below with reference to the accompanying drawings. In each figure, the same components are denoted by the same reference numerals, and redundant description is omitted. FIG. 1 is a diagram showing an embodiment of a dimming system using a node device according to the present invention. In this embodiment, a node device 20 that can multiplex data of four systems of DMX signals and an Ethernet (Ethernet cross cable) 15 that constitutes a LAN with data multiplexed of data of four systems of DMX signals. As an example, a dimming system using the node device 30 that receives the data from the DMX signal and separates the data into DMX signal data of up to four systems.

  The node device 20 is a device that transmits dimming data, and includes four input units 21-1 to 21-4 as shown in FIG. As shown in FIG. 1, dimming tables 11 to 14 are connected to the input units 21-1 to 21-4. If the dimming console can transmit data of four DMX signals, the dimming consoles 11 to 14 can be integrated. If the dimming console can transmit data of two DMX signals, the dimming console can adjust the data. It is shown that two optical tables 11 to 14 can be substituted, and the number of dimming tables that can be connected to the input units 21-1 to 21-4 is four at the maximum.

  The node device 30 is a device connected to the dimmer, and includes four output units 31-1 to 31-4 as shown in FIG. As shown in FIG. 1, a maximum of 512 dimmers 171-1, 171-2,... Are connected to the output unit 31-1 via the DMX signal line 16-1, and the output unit 31- 2 is connected to a maximum of 512 dimmers 172-1, 172-2,... Via the DMX signal line 16-2, and the output unit 31-3 via the DMX signal line 16-3. Are connected to the output unit 31-4 via the DMX signal line 16-4, and a maximum of 512 dimmers 174-1, 174-2,... Are connected. That is, up to four DMX signal lines can be connected to the output units 31-1 to 31-4.

  Illumination loads 181-1, 181-2,... Are connected to the dimmers 171-1, 171-2,..., Respectively, and the dimmers 172-1, 172-1,. The lighting loads 182-1, 182-2,..., Which are not necessarily one, are connected to the 172-2,..., And the dimmers 173-1, 173-2,. Are connected to lighting loads 183-1, 183-2,... That are not necessarily one, and each of the dimmers 174-1, 174-2,. Not limited lighting loads 184-1, 184-2, ... are connected.

  The DMX signal sent from the light control tables 11 to 14 and the DMX signal sent via the DMX signal lines 16-1 to 16-4 are the DMX 512 described above. This DMX 512 is sandwiched between a start bit and a stop bit, and a channel composed of 8 bits each is multiplexed into 512 channels to form one frame. Each of the 512 channels constitutes dimming data (8 bits, 256 gradations) for one dimmer. The start of one frame is detected by detecting a break (BREAK) and a start code. In addition, the dimming data of the channel corresponding to each dimmer counts how many channels between the start bit and the stop bit have arrived from the start of the frame, and the channel assigned to the dimmer Detect and take out as many channels as there are numbers. Each dimmer performs dimming by controlling the power applied to the illumination load based on the extracted dimming data.

  The input units 21-1 to 21-4 of the node device 20 include input connectors C21 to C24 provided in FIG. 3 showing the front panel of the node device 20, and a DMX signal line is connected to the input connectors C21 to C24. The A jack connected to the end of the cross cable of the Ethernet 15 is inserted into the connector CE1 shown in FIG.

  As illustrated in FIG. 2, the node device 20 includes an arrangement position setting unit 22, a multiplexing unit 23, and a transmission unit 24. When the arrangement position setting means 22 multiplexes the data of a plurality of DMX signals input to the plurality of input units 21-1 to 21-4, position information for arranging the DMX signal data for each system is obtained. Is set. Specifically, the arrangement position setting means 22 is composed of four-digit rotary switches S21 to S24 in which each digit shown in FIG. 3 showing the front panel of the node device 20 can be set from 0 to 9. In the example illustrated in FIG. 3, “0001”, “0513”, “1025”, and “1536” are set in the rotary switches S21 to S24, respectively. Thereby, the DMX signal data (512 channel) of the first system sent from the dimming console 11 is arranged from the channel “0001” to the channel “0512”, and the DMX signal of the second system sent from the dimming table 12 is sent. Data (512 channels) is arranged from channel “0513” to channel “1024”, and the data (512 channels) of the third system DMX signal sent from the dimming console 13 is from channel “1025” to channel “1535”. The DMX signal data (512 channel) of the fourth system sent from the dimming console 14 is set to be arranged from the channel “1536” to the channel “2048”.

  The multiplexing unit 23 multiplexes DMX signal data of a plurality of systems (here, 4 systems) using the position information set in the arrangement position setting means 22. Here, the four DMX signal data are multiplexed from channel “0001” to channel “2048” as described above. The transmission unit 24 transmits the data multiplexed by the multiplexing unit 23 to the Ethernet 15, which is a LAN. Here, the dimming data is packed in a UDP (User Datagram Protocol) packet and broadcasted. . A code (a dimming data code, a status data code) indicating whether the data to be packed subsequently is dimming data or status data is set at the head of the data portion of the UDP packet. Here, a packet in which the dimming data code is set is referred to as a dimming data packet, and a packet in which the status data code is set is referred to as a status packet. Note that when dimming data is packed and transmitted in one dimming data packet, the dimming data to be packed is up to 1024 channels, and when dimming data of 1025 channels or more is packed and transmitted, it is 2 Transmit in divided packets.

  The node device 20 includes an identification information setting unit 25 in which identification information of the node device 20 is set, and an IP address creation unit 26 that creates an IP address including the identification information set in the identification information setting unit 25. . The identification information setting unit 25 includes a two-digit rotary switch S25 in which each digit can be set from 0 to 9, as shown in FIG. In this example, it is desirable to be able to set a value of 1 to 254 using 3 digits but 3 digits. The transmission unit 24 adopts the C class as the IP address, and the IP address creating unit 26 sets the value set in the rotary switch S25 as the value of the fourth column, and the values up to the third column are, for example, “192.168 .. 2 ”. If the value set in the rotary switch S25 is “01” as shown in FIG. 3, the IP address is “192.168.2.01”.

  The node device 20 receives a packet from the Ethernet 15 with reference to the output of the IP address creation means 26, receives a packet addressed to itself (including broadcast), a setting check unit 29, a display unit 29A, and a multiplex 23C is provided. The setting check unit 29 broadcasts a check packet, which is a status packet using the IP address generated by the IP address generating unit 26 as a transmission source address, via the transmission unit 24 every predetermined time (for example, 1 second). At the same time, the inspection packet transmitted through the Ethernet 15 is received and an error in the identification information set in the identification information setting unit 25 is detected.

  The display unit 29A is for displaying a setting error, and is configured by an LED, for example. When the inspection packet including the identification information set in the identification information setting unit 25 in the transmission source address is received via the reception unit 28, the setting inspection unit 29 displays a setting error on the display unit 29A. For example, an LED that is the display unit 29A blinks at intervals of 3 seconds to display a setting error. The multiplexing control unit 23C controls the multiplexing unit 23 as will be described later.

  As shown in FIG. 4, the node device 30 includes a receiving unit 32R, a transmitting unit 32S, a separating unit 38, an identification information setting unit 33, an IP address creating unit 34, a setting checking unit 35, a display unit 35A, and an extraction position setting unit 36. Is provided. The identification information setting unit 33 corresponds to the identification information setting unit 25 of the node device 20, and as shown in FIG. 5 showing the front panel of the node device 30, a two-digit rotary switch S35 in which each digit can be set to 0-9. Composed. In this example, it is desirable to be able to set a value of 1 to 254 using 3 digits but 3 digits. The IP address creating means 34 is exactly the same as the IP address creating means 26 of the node device 20. Since the display unit 35A is exactly the same as the display unit 29A of the node device 20, and the setting check unit 35 is exactly the same as the setting check unit 29 of the node device 20, description thereof will be omitted.

  The receiving unit 32R receives data obtained by multiplexing data of a plurality of systems of DMX signals from the Ethernet 15, which is a LAN, and a packet including the address created by the IP address creating unit 34 as a destination address and broadcast transmission The received packet is captured.

  The take-out position setting means 36, when the separation unit 38 separates the data obtained by multiplexing the data of the DMX signals of a plurality of systems into the data of the DMX signals of several systems, extracts the data of the DMX signals for each system. Position information to be extracted is set. Here, each digit corresponding to the output units 31-1 to 31-4 including the output connectors C31 to C34 provided in FIG. It consists of 4-digit rotary switches S31 to S34 that can be set from 0 to 9.

  In the example of FIG. 5, “0001”, “0513”, “1025”, and “1536” are set in the rotary switches S31 to S34, respectively. As a result, the data (512 channels) of the first system DMX signal sent to the DMX signal line 16-1 designates the data multiplexed from the channel “000” 1 to the channel “0512” in the Ethernet 15. The data (512 channel) of the second system DMX signal sent to the signal line 16-2 designates the data multiplexed from the channel “0513” to the channel “1024” in the Ethernet 15, and the DMX signal line 16-3 The DMX signal data (512 channels) sent to the third line designates the data multiplexed from the channel “1025” to the channel “1535” in the Ethernet 15 and is sent to the DMX signal line 16-4. The data of the DMX signal of the system (512 channels) is transmitted on the Ethernet 15 through the channel “153 It specifies what has been multiplexed on the channel "2048" from ". In the connector CE2 shown in FIG. 5, a jack of a cross cable connected to the end of the Ethernet 15 is inserted.

  The separation unit 38 separates the multiplexed data using the position information set in the extraction position setting means 36 into DMX signal data of several systems (here, 4 systems). The output units 31-1 to 31-4 use DMX signal lines 16-1 to 16-DMX signal data of several systems (here, 4 systems) separated by the separation unit 38 as DMX signals for each system. Output to 16-4.

  The node device 30 includes a position information notification unit 37 that broadcasts a status packet including the position information set in the extraction position setting unit 36 via the transmission unit 32S at predetermined time intervals. At this time, the transmission unit 32S sets the address created by the IP address creation unit 34 as a transmission source address in the packet.

  As shown in FIG. 2, the node device 20 includes a multiplexing control unit 23C. The multiplexing control unit 23C obtains a necessary channel range based on the position information transmitted from the position information notification unit 37 of the node device 30, sets the data of the DMX signal to the corresponding channel in the necessary channel range, and performs multiplexing. The multiplexing unit 23 is controlled so as to be performed.

  In the dimming system configured using the node device 20 and the node device 30 configured as described above, the numerical values shown in FIG. 3 are set in the rotary switches S21 to S25. The data (512 channels) of the first system DMX signal sent from the light control console 11 is arranged from the channel “0001” to the channel “0512”, and the data of the second system DMX signal sent from the light control console 12 ( 512 channel) is arranged from channel “0513” to channel “1024”, and DMX signal data (512 channel) sent from the light control console 13 is arranged from channel “1025” to channel “1535”. The DMX signal data (512 channels) sent from the dimming console 14 is transmitted from the channel “1536”. Yaneru "2048" multiplexing disposed is performed by sending to the Ethernet 15 is made.

  In the node device 30, since the numerical values shown in FIG. 5 are set in the rotary switches S31 to S34, the data (512 channels) of the first system DMX signal sent to the DMX signal line 16-1 is the channel “ The data of the second DMX signal (512 channel) sent to the DMX signal line 16-2 is separated from the channel “0513” from the channel “0513” on the Ethernet 15. The data of the third system DMX signal (512 channels) sent to the DMX signal line 16-3 is separated and taken out from what was multiplexed on “1024”, and the data is transferred from the channel “1025” to the channel “1535” on the Ethernet 15. Separate and take out the multiplexed ones, and DMX signal line 1 Data of the fourth line of the DMX signals sent to 4 (512 channels) are separated off what has been multiplexed from the channel "1536" to the channel "2048" in Ethernet 15. Thus, the four DMX signal data are multiplexed and sent, and the node receiving the multiplexed data separates it back into the four DMX signal data and sends it to the required dimmer for dimming control. .

  Thus, the four DMX signal data are multiplexed and sent by the node device 20, and the node device 30 that has received the multiplexed data separates it back into the four DMX signal data and sends it to the required dimmer. Dimming control is performed. In addition, the setting inspection units 29 and 35 broadcast inspection packets using the IP address created by the IP address creating means 26 and 34 as the transmission source address via the transmission unit 24 every predetermined time (for example, 1 second). When the inspection packet transmitted through the Ethernet 15 is received and the inspection packet including the identification information set in the identification information setting units 25 and 33 in the transmission source address is received, the display unit A setting error is displayed at 29A and 35A. In the example of FIG. 5, a numerical value “02” is set in the rotary switch S 35 of the node device 30. However, if “01” is mistakenly set, the setting inspection unit 35 sends the IP address creating unit 34. The check packet including “192.168.2.01” created as the transmission source address is transmitted to the setting check unit 29 of the node device 20, and this is created by the IP address creating means 26. Compared with the address “192.168.2.01”, the display unit 29A blinks. Since it is configured in this way, it is possible to quickly find an error in setting identification information of a node device, and it is possible to operate the system efficiently by making correction settings.

  The node device 20 and the node device 30 according to the present embodiment can reduce the amount of information sent to the LAN in consideration of communication of another communication device (not shown) connected to the Ethernet 15. Is provided.

  That is, the node device 30 is provided with a position information notification unit 37 as shown in FIG. 4, and the position information notification unit 37 sends a status packet including the position information set in the extraction position setting means 36 every predetermined time. To broadcast via the transmitter 32S. For example, in the dimming system shown in FIG. 7, since “0001” is set in all the rotary switches S31 to S34 of the node device 30, “0001” is broadcasted. In the dimming system shown in FIG. 8, “0001” is set in the rotary switch S21 of the node device 30, “0201” is set in the rotary switch S32, and the rotary switches S33 to S34 are not used. Since a meaningless value is set, “0001” and “0201” are broadcast.

  The node device 20 includes a multiplexing control unit 23C. The multiplexing control unit 23C receives the position information transmitted from the position information notification unit 37 of the node device 30 via the receiving unit 28, and receives the received position information. Based on the position information, the required channel range is obtained, and the multiplexing unit 23 is controlled so that the DMX signal data is set in the corresponding channel in the required channel range and multiplexed. That is, in the dimming system shown in FIG. 7, since only “0001” is broadcasted, it is detected that one channel from channel “0001” to channel “0512” is the necessary channel range. Then, the multiplexing control unit 23C of the node device 20 illustrated in FIG. 7 causes the multiplexing unit 23 to perform multiplexing for setting the data of the DMX signal from the channel “0001” to the channel “0512”. Dimming data after channel “0513” is not output. Further, the multiplexing control unit 23C gives the minimum channel number “0001” and the maximum channel number “0512” detected above to the transmission unit 24 via the multiplexing unit 23.

  The transmitter 24 packs the dimming data from the channel “0001” to the channel “0512”, the minimum channel number “0001”, and the maximum channel number “0512” into a packet and transmits the packet. Thus, the transmission packet does not include the dimming data after the channel “0513”, and the amount of information sent to the LAN can be reduced. Further, in the dimming system shown in FIG. 8, since “0001” and “0201” are broadcasted in the dimming system, one channel from channel “0001” to channel “0512” is transmitted. Then, it is detected that the necessary channel range is from the channel “0001” to the channel “0712”, which is a range including one channel from the channel “0201” to the channel “0712”, and is shown in FIG. The multiplexing control unit 23C of the node device 20 causes the multiplexing unit 23 to perform multiplexing by setting the DMX signal data to the channels from channel “0001” to channel “0712”, and performs the adjustment after channel “0713”. Does not output optical data. The dimming data from channel “0001” to channel “0712”, the minimum channel number “0001”, and the maximum channel number “0712” are packed into a packet and transmitted. In addition, the multiplexing control unit 23C does not include the dimming data after the channel “0713” in the transmission packet detected as described above, and can reduce the amount of information transmitted to the LAN. The separation unit 38 that has received the packet as described above detects the minimum channel number and the maximum channel number, and uses the position information set in the extraction position setting unit 36 to obtain the dimming data of the corresponding position (channel). The data is separated into DMX signal data of several systems. Thus, it is possible to prevent a problem that unnecessary data is sent to the Ethernet 15.

  FIG. 6 shows a dimming system in which only the data of one DMX signal is transmitted using the node device 20 and the node device 30 described above, and is copied and distributed to four systems on the receiving side. ing. In this case, the DMX signal line is not connected to the input connectors C22 to C24. As shown in FIG. 6, since “0001” is set in the rotary switch S21 in the node device 20 and the rotary switches S22 to S24 are not used, for example, meaningless values are set. On the other hand, in the node device 30, all of the rotary switches S31 to S34 are set to “0001”.

  Thereby, in the node device 20, for example, data (512 channels) of the first system DMX signal sent from the dimming console 11 is arranged from the channel “0001” to the channel “0512” and transmitted. On the other hand, in the node device 30, the data of the first system DMX signal (512 channels) sent to the DMX signal line 16-1 and the data of the second system DMX signal sent to the DMX signal line 16-2 (512 channels). And the third system DMX signal data (512 channels) sent to the DMX signal line 16-3 and the fourth system DMX signal data (512 channels) sent to the DMX signal line 16-4. Also, in the Ethernet 15, what is multiplexed from the channel “0001” to the channel “512” is separated and copied. Accordingly, the DMX signal data of one system is sent from the node device 20, and the node device 30 that receives the data copies the data to the DMX signal data of the four systems and sends the data to the required dimmer in each system. Light control is performed.

  In FIG. 7, two receiving-side node devices 30 and 30A having the same configuration are connected to the switching hub 40, and the first-system DMX signal data is transmitted from the transmitting-side node device 20 to the channel “ The data of the second system DMX signal is allocated from the channel “0513” on the Ethernet 15, and the node device 30 on the reception side receives 4 data for one channel from the channel “0001” on the Ethernet 15. On the other hand, the node device 30A copies and distributes data for one system from the channel “0001” on the Ethernet 15 to the first and second systems and distributes the data to the system “A” on the Ethernet 15 channel “0513”. 1 shows a dimming system that copies and distributes data for one system to the third and fourth systems. In this case, the DMX signal line is not connected to the input connectors C23 to C24. In the node device 20, “0001” is set in the rotary switch S21, “0513” is set in the rotary switch S22, and the rotary switches S23 to S24 are not used. For example, a meaningless value is set. On the other hand, in the node device 30, all of the rotary switches S31 to S34 are set to “0001”, in the node device 30A, all of the rotary switches S31 to S32 are set to “0001”, and all of the rotary switches S33 to S34 are set. “0513” is set.

  In FIG. 8, using the node device 20 and the node device 30 described above, the data channel of the first system DMX signal transmitted from one dimming console and the other dimming console are used. A dimming system is shown in which dimming data is transmitted that partially overlaps the data channel of the second DMX signal transmitted. In this case, the multiplexing unit 23 employs the dimming data of the overlapping channels having a high level. In the example of FIG. 8, no DMX signal line is connected to the input connectors C22 to C24 in the node device 20. In the node device 20, “0001” is set in the rotary switch S21, “0201” is set in the rotary switch S22, and the rotary switches S23 to S24 are not used. On the other hand, in the node device 30, all of the rotary switches S31 to S34 are set to “0001”.

  In the data of the DMX signal of the first system and the data of the DMX signal of the second system, there are dimming levels (greater than 0) from the channel “0001” to the channel “0200”, and from the channel “0201” to the channel “ The dimming level is 0 until “0512”. The multiplexing unit 23 arranges the data of the first system DMX signal in one system from the channel “0001” on the Ethernet 15 based on “0001” set in the rotary switch S 21, and the second system DMX signal Is arranged in one line from the channel “0201” on the Ethernet 15 based on “0201” set in the rotary switch S21. Therefore, an overlap occurs in the channel “0201” to the channel “0512” on the Ethernet 15, but the dimming level is 0 from the channel “0201” to the channel “0512” in the DMX signal data of the first system and the second system. Therefore, in the range of the channel “0001” to the channel “0200” on the Ethernet 15, the DMX signal data of the first system is adopted without overlapping the dimming signals. In the range of “0400”, the data of the DMX signal of the first system has a dimming level of 0, and therefore the data of the DMX signal of the second system having a large dimming level is employed. In the data of the DMX signal of the first system and the second system, since the dimming level is 0 from the channel “0201” to the channel “0512”, the data after the channel “0401” on the Ethernet 15 is 0.

  On the other hand, since “0001” is set in all of the rotary switches S31 to S34 in the node device 30, DMX signal data for one system from the channel “0001” to the channel “0512” on the Ethernet 15 is extracted. And distributed output to the four systems. In a range where the dimming level is not 0, the data of the DMX signal of the first system on the transmission side is from the channel “0001” to the channel “0200”, and the second side of the transmission side is from the channel “0201” to the channel “0400”. The system DMX signal data is output to 4 systems.

  In FIG. 9, node devices 20 and 20A having the same configuration as node devices that receive and transmit DMX signal data transmitted from the dimming console are connected to the switching hub 40, and 2 of the same configuration is connected via the switching hub 40. A dimming system connected to the node devices 30 and 30A on the receiving side of the base is shown. In the example of FIG. 9, the DMX signal line is not connected to the input connectors C23 to C24 of the node device 20 and the input connectors C23 to C24 of the node device 20A. In the node device 20, “0001” is set in the rotary switch S21, “0513” is set in the rotary switch S22, and the rotary switches S23 to S24 are not used. In the node device 20A, “1025” is set in the rotary switch S21, “1536” is set in the rotary switch S22, and the rotary switches S23 to S24 are not used.

  On the other hand, in the node device 30, “0001” is set in the rotary switch S31, “0513” is set in the rotary switch S33, “1025” is set in the rotary switch S33, and “1536” is set in the rotary switch S34. Is set. In the node device 30A, “1025” is set to the rotary switches S31 to S32, and “1536” is set to the rotary switches S33 to S34.

  By setting as described above, the node device 20 arranges the data of the DMX signal of the first system for one system from the channel “0001” on the Ethernet 15 based on “0001” set in the rotary switch S21. Then, the data of the second system DMX signal is arranged for one system from the channel “0513” on the Ethernet 15 based on “0513” set in the rotary switch S22. In the node device 20A, the DMX signal data of the first system is arranged for one system from the channel “1025” on the Ethernet 15 based on “1025” set in the rotary switch S21, and the DMX signal of the second system is arranged. Is arranged for one system from the channel “1536” on the Ethernet 15 based on “1536” set in the rotary switch S22.

  The node devices 20 and 20A transmit the packets arranged in the channels as described above, and the node devices 30 and 30A receive the packets. When the node device 30 receives the packet sent by the node device 20, the data for one system is extracted from the channel “0001” on the Ethernet 15 and distributed to the first system, while the channel “0513” on the Ethernet 15 is used. The data for one system is taken out from and distributed to the second system. The packet sent by the node device 20 is not packed after the channel “1025”, and is not distributed from the node device 30 to the third system and the fourth system using the data of the packet.

  When the node device 30 receives the packet sent by the node device 20A, one line of data is extracted from the channel “1025” on the Ethernet 15 and distributed to the third system, while the channel “1536” on the Ethernet 15 The data for one system is taken out from and distributed to the fourth system. The packet sent by the node device 20A is not packed before the channel “1024”, and is not distributed from the node device 30 to the first system and the second system using the data of the packet.

  Further, when the node device 30A receives the packet sent by the node device 20, the packet is not packed after the channel “1025”, and the data of the packet is used as the first to first data from the node device 30. There is no distribution to the four systems. When the node device 30A receives the packet sent by the node device 20A, the data for one system after the channel “1025” on the Ethernet 15 is taken out and distributed to the first system and the second system, while on the Ethernet 15 The data for one system after channel “1536” is taken out and distributed to the third system and the fourth system.

  As described above, by configuring the dimming system using the node device according to the embodiment of the present invention, a plurality of DMX signals are integrated and transmitted, and a desired DMX signal is extracted and transmitted for each system. Therefore, efficient dimming data can be transmitted.

The block diagram which shows the Example of the light modulation system comprised using the node apparatus of the Example which concerns on this invention. The block diagram which shows the Example of the node apparatus which concerns on this invention. The figure which shows the front panel of the Example of the node apparatus shown in FIG. The block diagram which shows the Example of the node apparatus which concerns on this invention. The figure which shows the front panel of the Example of the node apparatus shown in FIG. The figure which shows the example which changed the value set to a rotary switch in the Example of the light modulation system comprised using the node apparatus of the Example which concerns on this invention. The figure which shows the example which changed the value set to a rotary switch in the Example of the light modulation system comprised using the node apparatus of the Example which concerns on this invention. The figure which shows the example which changed the value set to a rotary switch in the Example of the light modulation system comprised using the node apparatus of the Example which concerns on this invention. The figure which shows the example which changed the value set to a rotary switch in the Example of the light modulation system comprised using the node apparatus of the Example which concerns on this invention.

Explanation of symbols

11-14 Light control table
15 LAN (Ethernet)
20, 20A, 30, 30A node device
21-1 to 21-4 Input section
22 Arrangement position setting means
23 Multiplexer
23C Multiplexing control unit
24 Transmitter
25 Identification information setting section
26 IP address generator
29 Setting inspection section
29A Display section
31-1 to 31-4 Output section
32S transmitter
32R receiver
33 Identification information setting section
34 IP address generator
35 Setting and Inspection Department
35A display unit
36 Extraction position setting means
38 Separation part

Claims (5)

A plurality of input units each receiving a DMX signal in which data of a predetermined number of channels are multiplexed in one system;
Arrangement position setting means for setting position information for arranging data of DMX signals for each system when multiplexing data of DMX signals of a plurality of systems input to a plurality of input units;
A multiplexing unit that multiplexes DMX signal data of a plurality of systems using the position information set in the arrangement position setting means;
A transmission unit for transmitting the data multiplexed by the multiplexing unit to the LAN;
A node device comprising: A receiving unit for receiving, from the LAN, data in which data of a plurality of DMX signal data is multiplexed;
Extraction position setting means for setting position information for extracting DMX signal data for each system when data obtained by multiplexing data of DMX signals of a plurality of systems is separated into DMX signal data of several systems When;
A demultiplexing unit that demultiplexes the data multiplexed using the position information set in the extraction position setting means into DMX signal data of several systems;
A plurality of output units for outputting DMX signal data of several systems separated by the separation unit as DMX signal data for each system;
A node device comprising: An identification information setting unit in which identification information for each node device is set;
An IP address creating means for creating an IP address including the identification information set in the identification information setting unit;
Broadcast inspection packets with the IP address created by the IP address creation means as the source address at predetermined time intervals, receive inspection packets, and detect errors in identification information set in the identification information setting unit A setting inspection unit to perform;
The node device according to claim 1, further comprising: Provide a display for displaying setting errors;
The node according to claim 3, wherein the setting inspection unit displays a setting error on the display unit when an inspection packet including the identification information set in the identification information setting unit in the transmission source address is received. apparatus. A dimming system in which the node device according to claim 1 and the node device according to claim 2 transmit and receive data via a LAN,
The node device according to claim 2 includes a position information notification unit that broadcasts a status packet including the position information set in the extraction position setting unit at predetermined time intervals;
The node device according to claim 1 obtains a necessary channel range based on the position information transmitted from the position information notification unit, sets the data of the DMX signal to the corresponding channel in the necessary channel range, and performs multiplexing. A dimming system comprising a multiplexing control unit.

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