JP2010004139A - Programmable logic circuit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a programmable logic circuit to be easily connected to a high order apparatus on the occasion of configuration, and reusable even after it is mounted on a substrate. <P>SOLUTION: A USBI/F1a connected to a high order apparatus 10 and a substrate 30 in USB connection is prepared in a FPGA (Field Programmable Gate Array) 1. When the programmable logic circuit is connected to the high order apparatus 10 by the USBI/F1a, software for creating configuration data is activated by the high order apparatus 10. Upon receipt of the configuration data created by the software via the USBI/F1a, a logic circuit based on the configuration data is designed in a user area 6 of a logic circuit portion 2. Then, when the programmable logic circuit is connected to the substrate 30 by the USBI/F1a, an input signal is processed based on the logic circuit designed in the user area 6. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a programmable logic circuit so-called FPGA (Field Programmable Gate Array) capable of rewriting a logic circuit.

  Conventionally, an ASIC (Application Specific Integrated Circuit) that is an integrated circuit corresponding to each application is used for a control circuit of an electronic device or the like. In developing an ASIC, an ASIC for evaluation is created after designing an integrated circuit that realizes a function desired by the user, and an ASIC for evaluation is recreated by reflecting evaluation results and function changes. It is. When many such repetitive operations are performed, the development period is prolonged. In addition, even if ASICs for which development has been completed are mass-produced, if a failure is found in the circuit design, these ASICs must be discarded, resulting in significant damage.

  Therefore, in recent years, there are many cases in which an FPGA that allows a user to program a logic circuit is used. Using this FPGA, for example, by making a prototype of an ASIC, the development period can be shortened, so that the product can be put on the market early.

For example, a computer system described in Patent Document 1 is known as an electronic device equipped with an FPGA.
Japanese Patent Laid-Open No. 2001-290758

  However, since the FPGA is mounted by soldering pins with a width of about 0.5 mm, which are produced from the main body, to the board in the electronic device, once the board is mounted on the board, it is removed and reused for other electronic devices. Is difficult. Therefore, in order to rewrite the logic circuit programmed in the FPGA, the host device on which the FPGA configuration software is installed is carried to the vicinity of the board on which the FPGA is mounted, and a dedicated connector is connected to the FPGA for configuration. It was troublesome because it was necessary.

  In addition, since a high-performance FPGA is very expensive, if it can be removed from the mounted board and reused, the cost can be greatly reduced.

  The present invention has been made based on the above circumstances, and an object thereof is to provide a programmable logic circuit that can be easily connected to a host device during configuration and can be reused after being mounted on a base. It is to be.

  The present invention includes a logic circuit unit that designs a logic circuit based on configuration data received from a host device, and processes an input signal based on the logic circuit designed in the logic circuit unit when mounted on a base. In a programmable logic circuit, a USB interface for USB connection between the host device and a base, and software that activates software for creating the configuration data in the host device when connected to the host device via the USB interface In response to the configuration data generated by the activation means and the software activated by the higher-level device by the software activation means being received via the USB interface, the configuration data is based on the configuration data. And a configuration control means for designing the logic circuit in the logic circuit section, and when connected to the base via the USB interface, the configuration control means inputs based on the logic circuit designed in the logic circuit section. It is characterized by processing signals.

  According to the present invention in which such means is taken, it is possible to provide a programmable logic circuit that can be easily connected to a host device during configuration and can be reused even after being mounted on a base.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram for explaining the configuration of an FPGA 1 which is a programmable logic circuit according to the present invention. The FPGA 1 is a nonvolatile FPGA including a USB (registered trademark) interface (I / F) 1 a and a rewritable logic circuit unit 2 that retains information even after the supply of power is stopped.

  The USB interface 1a manages connection with the USB interface 10a provided in the host device 10 that executes the configuration of the FPGA 1 and the USB interface 30a provided in the base 30 of the electronic device on which the FPGA 1 is mounted.

  The logic circuit unit 2 regularly arranges a large number of logic modules having a non-volatile memory capable of defining a LUT (Look Up Table), and switches for switching the connection of each logic module therebetween, and switching information of these switches. Is provided with a wiring area including a non-volatile memory in which is stored. The user can realize a desired logic circuit by changing the definition of the LUT of each logic module and the connection of the switch in the wiring area according to the configuration described later.

  In the present embodiment, a USB driver circuit 4, a software activation circuit 5, and a configuration (CONFIG) control circuit 7 are designed in advance in the logic circuit unit 2. A user area 6 is prepared as an area for a user to freely design a circuit. The USB driver circuit 4 controls communication with the host device 10 and the board 30 connected by the USB interface 1a. The software activation circuit 5 detects that the upper device 10 is connected to the USB interface 1a, and activates later-described configuration (CONFIG) software 16a included in the upper device 10. The configuration control circuit 7 designs a logic circuit based on configuration data received from the host device 10 in the user area 6.

  Next, the host device 10 will be described. FIG. 2 is a block diagram illustrating a control circuit of the higher-level device 10. The host device 10 includes a CPU 11 which is a control subject inside. This CPU 11 receives fixed data such as a chip set 12 for controlling information distribution such as data delivery management, a BIOS-ROM 13 storing a BIOS (Basic Input / Output System) for starting the system, and various processing programs. ROM 14 stored, RAM 15 forming a storage area for work according to the processing scene, hard disk drive (HDD) 16 storing configuration software 16a, display controller 17 connected to display 17a, USB driver connected to USB interface 10a 18 and a keyboard controller 19 connected to a keyboard 19a are connected via a bus line 20 such as a PCI bus.

  The display controller 17 controls the display of data processed by the CPU 11 on the display 17a. The USB driver 18 controls communication with a device connected to the USB interface 10a. The keyboard controller 19 detects an electrical signal output when a numeric key or an alphabet key provided on the keyboard 19a is operated and transmits it to the CPU 11.

  The configuration software 16 a is software for configuring the user area 6 provided in the logic circuit unit 2 of the FPGA 1. Specifically, it accepts programming by the user, and transmits the created configuration data to the FPGA 1 connected to the USB interface 10a, and a function for creating configuration data for constructing a logic circuit based on the programming. And a function for instructing the configuration of the user area 6 provided in the logic circuit section 2.

Next, the effect | action by the structure of the above FPGA1 is demonstrated.
FIG. 3 is a flowchart of processing executed by the FPGA 1. When the USB interface 1a of the FPGA 1 is connected to the USB interface 10a of the host device 10 or the USB interface 30a included in the base 30 of the electronic device, power supply starts from the host device 10 or the base 30 via the USB interface 1a. At the same time, an initial signal for the host device 10 or the board 30 to recognize the FPGA 1 is input. At this time, as ST1, the USB driver circuit 4 determines whether the connection destination is the host device 10 or the board 30 based on the initial signal.

  When the USB driver circuit 4 determines that the connection destination is a higher-level device (“high-level device” in ST1), the software activation circuit 5 causes the higher-level device 10 to activate the configuration software 16a as ST2. Specifically, a startup command for the configuration software 16a is transmitted to the host device 10 via the USB interface 1a. In response to receiving this signal, the CPU 11 of the host device 10 loads the execution program of the configuration software 16a into the RAM 15 and executes it.

  Configuration data is created in response to an operation input from the keyboard 19a under the control of the activated configuration software 16a. The USB driver 18 transmits the configuration data to the FPGA 1 and instructs the execution of the configuration in response to an instruction to execute the configuration by a predetermined operation.

  After the configuration software 16a is activated in the host device in the process of ST2, in the FPGA 1, the USB driver circuit 4 waits for reception of configuration data (No in ST3). When the configuration data is received and the execution of the configuration is instructed (Yes in ST3), the configuration control circuit 7 designs a logic circuit based on the configuration data in the user area 6 as ST4. Specifically, the LUT of each logic module constituting the user area 6 is defined in the contents indicated by the configuration data, and the switch connection of the wiring area is changed. Then, after a series of configuration is completed, the process is terminated.

  On the other hand, when the USB driver circuit 4 determines in step ST1 that the connection destination of the USB interface 1a is the base 30 of the electronic device (ST1 “base”), it is input as ST5 thereafter via the USB interface 1a. Is processed based on a logic circuit designed in the user area 6. This process is continued until the power supply is stopped thereafter.

  As described above, the FPGA 1 according to the present invention can be mounted on the substrate 30 of the electronic device via the USB interface 1a without requiring soldering or the like. Thereby, even after it is once mounted on the substrate 30, it can be easily removed and reused, leading to cost reduction.

  In addition, when the user area 6 of the logic circuit unit 2 is configured for use in another electronic device after being removed from the base 30 as described above, it is easily connected to the host device 10 via the USB interface 1a. be able to. Therefore, the troublesome work of carrying the host device 10 to the vicinity of the board on which the FPGA 1 is mounted for connection and connecting a dedicated connector can be omitted.

  In addition, when the FPGA 1 is connected to the host device 10 via the USB interface 1a, the configuration software 16a is automatically activated by the software activation circuit 5, so that the user can immediately start programming the configuration data. This leads to a reduction in the work time required for configuration.

  In addition, this invention is not limited to the said embodiment as it is, In an implementation stage, in the range which does not deviate from the summary, each component can be deform | transformed and embodied suitably.

  For example, the USB driver circuit 4, the software activation circuit 5, and the configuration control circuit 7 may not be designed in the logic circuit unit 2, or may be all or one of them as separate circuits provided in the FPGA 1. Good.

  In the above embodiment, the case where the present invention is applied to an FPGA including a nonvolatile logic circuit unit has been described. However, the present invention can also be applied to an FPGA including a volatile logic circuit unit. When the present invention is applied to an FPGA including a volatile logic circuit unit, a nonvolatile memory for storing configuration data is provided in the FPGA. At the time of configuration, configuration data is stored in the nonvolatile memory. Thereafter, a logic circuit based on the configuration data stored in the nonvolatile memory is designed in the logic circuit unit in response to being mounted on the base and starting to supply power. Even with this configuration, it is possible to obtain the same effects as in the above embodiment.

  In addition, 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 the overall components shown in the embodiment.

The block diagram for demonstrating the structure of FPGA in one Embodiment of this invention. The block diagram which shows the control circuit of the high-order apparatus in the embodiment. The flowchart of the process performed by FPGA in the same embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... FPGA, 1a ... USB interface, 2 ... Logic circuit part, 4 ... USB driver circuit, 5 ... Software start-up circuit, 6 ... User area, 7 ... Configuration control circuit, 10 ... High-order apparatus, 10a ... USB interface, 30 ... Base, 30a ... USB interface

Claims (2)

A programmable logic circuit comprising a logic circuit unit for designing a logic circuit based on configuration data received from a host device, and processing an input signal based on the logic circuit designed in the logic circuit unit when mounted on a base In
A USB interface for USB connection of the host device and the platform;
Software activation means for activating the software for creating the configuration data in the host device when connected to the host device via the USB interface;
When the configuration data created by the software activated by the higher-level device by the software activation unit is received via the USB interface, a logic circuit based on the configuration data is added to the logic circuit unit. And a configuration control means designed in
A programmable logic circuit, wherein when connected to the board by the USB interface, the configuration control means processes an input signal based on a logic circuit designed in the logic circuit unit.   The programmable logic circuit according to claim 1, wherein the software activation unit and the configuration control unit are realized by a logic circuit designed in the logic circuit unit.

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