JP2006253815A - Circuit device system and configuration method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a circuit device system upsizing of a circuit board of which can be avoided, wherein circuit information can quickly be loaded to a circuit device and the effect of noise is hardly received at loading of the circuit information and to provide a configuration method. <P>SOLUTION: A loader circuit for sequentially loading the circuit information to each PLD via each PLD is sequentially configured to each PLD on the basis of the circuit information. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a circuit device system including a plurality of circuit devices capable of configuring an arbitrary circuit, and a configuration method for each circuit device.

  2. Description of the Related Art Circuit devices capable of generating an arbitrary circuit according to input circuit information, so-called configuration, are known (for example, Patent Documents 1, 2, and 3). This circuit device is called a PLD (programmable logic device), and is configured by a ROM as shown in FIG. 8 or by a host computer as shown in FIG.

  In the configuration using the ROM of FIG. 8, a plurality of PLD1 to PLD6 and a plurality of ROMs (Read Only Memory) 61, 62, 63 are mounted on the circuit board 60. The PLD 1 is configured by loading (inputting) circuit information stored in the ROM 61. PLD 2 and PLD 3 are configured by loading circuit information stored in ROM 62. PLD4, PLD5, and PLD6 are configured by loading circuit information stored in ROM63. A wiring pattern 64 for loading is formed between each ROM and each PLD.

In the configuration by the host computer of FIG. 9, a plurality of PLD1 to PLD6 and an auxiliary circuit 71 for loading are mounted on the circuit board 60. The auxiliary circuit 71 includes an interface circuit (I / F) and a loader circuit. The auxiliary circuit 71 takes in circuit information issued from the host computer 70 outside the circuit board 60 via the interface circuit, and the fetched circuit information is received by the loader circuit. Load sequentially into the PLD. The wiring pattern 72 for loading is formed between the auxiliary circuit 71 and each PLD.
JP-A-4-227116 JP-A-8-503111 JP 11-68550 A

  In the configuration using the ROM shown in FIG. 8, a space for mounting several ROMs must be secured on the circuit board 20 on which each PLD is mounted. For this reason, there exists a problem that the circuit board 20 enlarges.

  In the configuration by the host computer of FIG. 9, the wiring pattern 72 connecting the auxiliary circuit 71 and each PLD becomes long. In particular, the length of the wiring pattern 72 increases as the number of PLDs mounted increases. If the wiring pattern 72 is long, there is a problem that loading of circuit information is limited in terms of time or is easily affected by noise during loading.

  In consideration of the above circumstances, the present invention can avoid an increase in the size of a circuit board, and can quickly load circuit information into a circuit device, and can also reduce the influence of noise when loading circuit information. An object of the present invention is to provide a circuit device system and a configuration method which are difficult to receive.

  The circuit device system of the invention according to claim 1 is configured in such a manner that a plurality of circuit devices capable of configuring an arbitrary circuit according to input circuit information and each circuit device are sequentially configured according to the circuit information. And a loader circuit that sequentially loads the circuit information to each circuit device through each circuit device.

  A circuit device system according to a second aspect of the present invention includes a plurality of circuit devices capable of configuring an arbitrary circuit according to input circuit information, a plurality of circuit boards on which these circuit devices are mounted, and the circuit A loader circuit configured to sequentially configure each circuit device in accordance with information and sequentially load the circuit information to each circuit device through each circuit device and each circuit board.

  According to a third aspect of the present invention, there is provided a configuration method comprising: a plurality of circuit devices capable of configuring an arbitrary circuit in accordance with input circuit information. A loader circuit for sequentially loading is sequentially configured in each circuit device based on the circuit information.

  The configuration method of the invention according to claim 4 includes a plurality of circuit devices capable of configuring an arbitrary circuit according to input circuit information, and mounting these circuit devices on a plurality of circuit boards. A loader circuit for sequentially loading circuit information into each circuit device through each circuit device and each circuit board is sequentially configured in each circuit device based on the circuit information.

  According to the present invention, it is possible to avoid an increase in the size of a circuit board, and it is possible to quickly load circuit information into a circuit device, and to be less susceptible to noise when loading circuit information. Can be provided.

An embodiment of the present invention will be described below with reference to the drawings.
As shown in FIG. 1, a plurality of circuit boards 1a, 1b, 1c,... 1n are arranged, and a plurality of circuit devices (hereinafter referred to as PLDs) PLD1 to PLD120 are arranged on each circuit board, for example, six by six. It is mounted with. In addition, the auxiliary circuit 2 for configuration is mounted on the circuit board 1 a at a position adjacent to the PLD 1.

  The auxiliary circuit 2 includes an interface circuit (I / F) 2a and a loader circuit 2b. The auxiliary circuit 2 takes in circuit information issued from the host computer 10 outside the circuit board 1a via the interface circuit 2a, and loads the taken circuit information into the loader circuit. Loading (input) into the PLD 1 by 2b. The wiring pattern 11 for loading is formed in advance between the auxiliary circuit 2 and the PLD 1.

  In the PLD 1 loaded with circuit information, an arbitrary circuit according to the circuit information is configured (generated). Any circuit that is configured includes a loader circuit 12, as shown in FIG. Along with this configuration, a high-speed data bus 13 using a wiring pattern formed in advance is opened between the auxiliary circuit 2 and the PLD 1.

  The loader circuit 2b of the auxiliary circuit 2 functions as a data through circuit that passes through circuit information as it is after loading the PLD 1.

  The host computer 10 sends circuit information for the next PLD 2 after sending the circuit information for the PLD 1. The sent circuit information is supplied to the PLD 1 through the auxiliary circuit 2 and the data bus 13. The circuit information supplied to the PLD 1 is loaded into the adjacent PLD 2 by the loader circuit 12 formed in the PLD 1. This wiring pattern 14 for loading is formed in advance between PLD1 and PLD2.

  In the PLD 2 loaded with circuit information, an arbitrary circuit corresponding to the circuit information is configured. Any circuit that is configured includes a loader circuit 15 as shown in FIG. With this configuration, a high-speed data bus 16 using a wiring pattern formed in advance is opened between PLD1 and PLD2.

  The loader circuit 12 of the PLD 1 functions as a data through circuit that passes through the circuit information as it is until the configuration for the last PLD 6 on the same circuit board 1a is completed after loading to the PLD 2.

  The host computer 10 sends circuit information for the next PLD 3 after sending the circuit information for the PLD 2. The sent circuit information is supplied to the PLD 2 through the auxiliary circuit 2, the data bus 13, the PLD 1, and the data bus 16. The circuit information supplied to the PLD 2 is loaded into the adjacent PLD 3 by the loader circuit 15 formed in the PLD 2. This wiring pattern 17 for loading is formed in advance between PLD2 and PLD3.

  In the PLD 3 loaded with circuit information, an arbitrary circuit corresponding to the circuit information is configured. Any circuit that is configured includes a loader circuit 18, as shown in FIG. With this configuration, a high-speed data bus 19 using a wiring pattern formed in advance is opened between PLD2 and PLD3.

  The loader circuit 15 of the PLD 2 functions as a data through circuit that directly passes through circuit information after loading the PLD 3.

  After sending the circuit information to the PLD 3, the host computer 10 sends the circuit information to the next PLD 4. The sent circuit information is supplied to the PLD 3 through the auxiliary circuit 2, the data bus 13, the PLD 1, the data bus 16, the PLD 2, and the data bus 19. The circuit information supplied to the PLD 3 is loaded into the adjacent PLD 4 by the loader circuit 18 formed in the PLD 3. The wiring pattern 21 for loading is formed in advance between the PLD 3 and the PLD 4.

  In the PLD 4 loaded with circuit information, an arbitrary circuit corresponding to the circuit information is configured. Any circuit that is configured includes a loader circuit 22, as shown in FIG. With this configuration, a high-speed data bus 23 using a wiring pattern formed in advance is opened between the PLD 3 and the PLD 4.

  The loader circuit 18 of the PLD 3 functions as a data through circuit that passes through the circuit information as it is after loading the PLD 4.

  The host computer 10 sends circuit information for the next PLD 5 after sending the circuit information for the PLD 4. The sent circuit information is supplied to the PLD 4 through the auxiliary circuit 2, the data bus 13, the PLD 1, the data bus 16, the PLD 2, the data bus 19, the PLD 3, and the data bus 23. The circuit information supplied to the PLD 4 is loaded into the adjacent PLD 5 by the loader circuit 22 formed in the PLD 4. The wiring pattern 26 for loading is formed in advance between the PLD 4 and the PLD 5.

  In the PLD 5 loaded with circuit information, an arbitrary circuit corresponding to the circuit information is configured. Any circuit that is configured includes a loader circuit 25, as shown in FIG. With this configuration, a high-speed data bus 26 using a wiring pattern formed in advance is opened between the PLD 4 and the PLD 5.

  The loader circuit 22 of the PLD 4 functions as a data through circuit that directly passes through circuit information after loading to the PLD 5.

  After sending the circuit information to the PLD 5, the host computer 10 sends the circuit information to the next PLD 6. The sent circuit information is supplied to the PLD 5 through the auxiliary circuit 2, the data bus 13, the PLD 1, the data bus 16, the PLD 2, the data bus 19, the PLD 3, the data bus 23, the PLD 4, and the data bus 26. The circuit information supplied to the PLD 5 is loaded into the adjacent PLD 6 by the loader circuit 25 formed in the PLD 5. The wiring pattern 27 for loading is formed in advance between the PLD 5 and the PLD 6.

  An arbitrary circuit corresponding to the circuit information is configured in the PLD 6 loaded with the circuit information.

  After sending the circuit information to the PLD 6, the host computer 10 sends the circuit information to the PLD 7 of the next circuit board 1b. The sent circuit information is supplied to the PLD 1 through the auxiliary circuit 2 and the data bus 13. At this time, the loader circuit 12 of the PLD 1 ends the data through operation for the PLD 2 to PLD 6 so far, and loads the circuit information received this time onto the PLD 7 of the adjacent circuit board 1b. The loading wiring pattern 31 and input / output terminals (not shown) are formed in advance on the circuit boards 1a and 1b.

  In the PLD 7 loaded with circuit information, an arbitrary circuit corresponding to the circuit information is configured. Any circuit that is configured includes a loader circuit 32, as shown in FIG. With this configuration, a high-speed data bus 33 using a wiring pattern formed in advance is opened between the circuit boards 1a and 1b.

  The loader circuit 12 of the PLD 1 functions as a data through circuit that passes the circuit information directly to the circuit board 1b side after loading to the PLD 7.

  After sending the circuit information to the PLD 7, the host computer 10 sends the circuit information to the next PLD 8. The sent circuit information is supplied to the PLD 7 through the auxiliary circuit 2, the data bus 13, the PLD 1, and the data bus 31. The circuit information supplied to the PLD 7 is loaded into the adjacent PLD 8 by the loader circuit 32 formed in the PLD 7. The wiring pattern 34 for loading is formed in advance between the PLD 7 and the PLD 8.

  In the PLD 8 loaded with the circuit information, an arbitrary circuit corresponding to the circuit information is configured. Any circuit that is configured includes a loader circuit 35, as shown in FIG. Along with this configuration, a high-speed data bus 36 using a wiring pattern formed in advance is opened between the PLD 7 and the PLD 8.

  The loader circuit 32 of the PLD 7 functions as a data through circuit that passes through the circuit information as it is until the configuration for the last PLD 12 on the same circuit board 1b is completed after loading to the PLD 8.

  After sending the circuit information to the PLD 8, the host computer 10 sends the circuit information to the next PLD 9. The sent circuit information is supplied to the PLD 8 through the auxiliary circuit 2, the data bus 13, the PLD 1, the data bus 33, the PLD 7, and the data bus 36. The circuit information supplied to the PLD 8 is loaded into the adjacent PLD 9 by the loader circuit 35 formed in the PLD 8. The wiring pattern 37 for loading is formed in advance between the PLD 8 and the PLD 9.

  An arbitrary circuit corresponding to the circuit information is configured in the PLD 9 loaded with the circuit information. Any circuit that is configured includes a loader circuit 38, as shown in FIG. Along with this configuration, a high-speed data bus 39 using a wiring pattern formed in advance is opened between the PLD 8 and the PLD 9.

  The loader circuit 35 of the PLD 8 functions as a data through circuit that passes through the circuit information as it is after loading the PLD 9.

  After sending the circuit information to the PLD 9, the host computer 10 sends the circuit information to the next PLD 10. The sent circuit information is supplied to the PLD 9 through the auxiliary circuit 2, the data bus 13, the PLD 1, the data bus 31, the PLD 7, the data bus 36, the PLD 8, and the data bus 39. The circuit information supplied to the PLD 9 is loaded into the adjacent PLD 10 by the loader circuit 38 formed in the PLD 9. The wiring pattern 41 for loading is formed in advance between the PLD 9 and the PLD 10.

  In the PLD 10 loaded with circuit information, an arbitrary circuit corresponding to the circuit information is configured. Any circuit that is configured includes a loader circuit 42, as shown in FIG. Along with this configuration, a high-speed data bus 43 using a wiring pattern formed in advance is opened between the PLD 9 and the PLD 10. The loader circuit 38 of the PLD 9 functions as a data through circuit that directly passes through circuit information after loading to the PLD 10.

  After sending the circuit information to the PLD 10, the host computer 10 sends the circuit information to the next PLD 11. The sent circuit information is supplied to the PLD 10 through the auxiliary circuit 2, the data bus 13, the PLD 1, the data bus 33, the PLD 7, the data bus 36, the PLD 8, the data bus 39, the PLD 9, and the data bus 43. The circuit information supplied to the PLD 10 is loaded into the adjacent PLD 11 by the loader circuit 42 formed in the PLD 10. The wiring pattern 44 for loading is formed in advance between the PLD 10 and the PLD 11.

  In the PLD 11 loaded with the circuit information, an arbitrary circuit corresponding to the circuit information is configured. Any circuit that is configured includes a loader circuit 45, as shown in FIG. Along with this configuration, a high-speed data bus 46 using a wiring pattern formed in advance is opened between the PLD 10 and the PLD 11.

  The loader circuit 42 of the PLD 10 functions as a data through circuit that directly passes through circuit information after loading to the PLD 11.

  After sending the circuit information to the PLD 11, the host computer 10 sends the circuit information to the next PLD 12. The transmitted circuit information passes through the auxiliary circuit 2, data bus 13, PLD 1, data bus 33, PLD 7, data bus 36, PLD 8, data bus 39, PLD 9, data bus 43, PLD 10, and data bus 46 to the PLD 11. Supplied. The circuit information supplied to the PLD 11 is loaded into the adjacent PLD 12 by the loader circuit 45 formed in the PLD 11. The wiring pattern 47 for loading is formed in advance between the PLD 11 and the PLD 12.

  An arbitrary circuit corresponding to the circuit information is configured in the PLD 12 loaded with the circuit information.

  After sending the circuit information to the PLD 12, the host computer 10 sends the circuit information to the PLD 13 of the next circuit board 1c. The sent circuit information is supplied to the PLD 7 through the auxiliary circuit 2, the data bus 13, the PLD 1, and the data bus 33. At this time, the loader circuit 32 of the PLD 7 ends the data through operation for the PLDs 8 to PLD 12 so far, and loads the circuit information received this time onto the PLD 13 of the adjacent circuit board 1c. The loading wiring pattern 51 and input / output terminals (not shown) are formed in advance on the circuit boards 1b and 1c.

  Thereafter, the same processing is executed for the PLDs of all remaining circuit boards. Thereby, the configuration for all PLD1 to PLD120 is completed.

  As described above, a loader circuit for sequentially loading circuit information into each PLD through each PLD is sequentially configured in each PLD by the circuit information, so that a number as shown in FIG. There is no need to mount a single ROM on the circuit board, and therefore an increase in size of the circuit board can be avoided. In addition, since each PLD is loaded sequentially, the wiring pattern for loading can be shortened. Since the wiring pattern is short, circuit information can be quickly loaded and it is difficult to be affected by noise when loading circuit information.

In the above-described embodiment, an example has been described in which sixty 120 PLDs are mounted on one circuit board, but the number of PLDs is not limited.
In addition, the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. Moreover, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment.

The figure which shows the structure of one Embodiment, and the initial loading of circuit information. The figure which shows the configuration and loading following FIG. The figure which shows the configuration and loading following FIG. The figure which shows the configuration and loading following FIG. The figure which shows the configuration and loading following FIG. FIG. 6 is a diagram illustrating configuration and loading following FIG. 5. FIG. 7 is a diagram illustrating configuration and loading following FIG. 6. The figure which shows the configuration by the conventional ROM. The figure which shows the configuration by the conventional host computer.

Explanation of symbols

  PLD1 to PLD120 ... circuit devices, 1a, 1b, 1c, ... 1n ... circuit board, 2 ... auxiliary circuit, 2a ... interface circuit, 2b ... loader circuit, 10 ... host computer, 11, 14, 17, 21, 24, 27, 31, 34, 37, 41, 44, 47, 51 ... wiring pattern, 12, 15, 18, 22, 25, 32, 35, 38, 42, 45 ... loader circuit, 13, 16, 19, 23, 26, 33, 36, 39, 43, 46 ... data bus, 60 ... circuit board, 61, 62, 63 ... ROM, 64 ... wiring pattern, 70 ... host computer, 71 ... auxiliary circuit, 72 ... wiring pattern

Claims (4)

A plurality of circuit devices capable of configuring an arbitrary circuit in accordance with input circuit information;
A loader circuit configured to sequentially configure each circuit device according to the circuit information, and sequentially loading the circuit information to each circuit device through each circuit device;
A circuit device system comprising: A plurality of circuit devices capable of configuring an arbitrary circuit in accordance with input circuit information;
A plurality of circuit boards on which the respective circuit devices are mounted;
A loader circuit configured to sequentially configure each circuit device according to the circuit information, and sequentially loading the circuit information to each circuit device through each circuit device and each circuit board;
A circuit device system comprising: In what has a plurality of circuit devices that can configure any circuit according to the input circuit information,
A configuration method comprising: sequentially configuring a loader circuit for sequentially loading the circuit information into each circuit device through each circuit device according to the circuit information. In what is equipped with a plurality of circuit devices that can configure any circuit according to the input circuit information, and these circuit devices are mounted on a plurality of circuit boards,
A loader circuit for sequentially loading the circuit information on each circuit device through each circuit device and each circuit board is configured in sequence on each circuit device based on the circuit information. Method.

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