JP2013073342A - Field device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve the unification and selective installation of firmware different for each product.SOLUTION: In a field device in which a CPU for processing an input signal from a sensor executes start processing of reading firmware stored in a first non-volatile memory and storing the firmware in a volatile memory and then executes main processing, the first non-volatile memory includes model type information storage means for storing unified firmware including a common part in which the specifications of a standard product are described and a highly functional addition part in which the additional specifications of a highly functional product obtained by adding additional specifications to the specifications of the standard product are described, and for storing model type information for selecting either the standard product or the highly functional product. The CPU reads and stores the common part or the common part and the highly functional addition part from the unified firmware stored in the first non-volatile memory in the volatile memory on the basis of the model type information read from the model type information storage means.

Description

  The present invention relates to a field device in which a CPU that processes an input signal from a sensor reads a firmware held in a first non-volatile memory and executes a start-up process that stores the firmware in a volatile memory, and then executes a main process. It is.

  FIG. 7 is a functional block diagram showing a configuration example of a conventional field device. In the embodiments described below, application examples to a differential pressure / pressure transmitter will be described as field devices to which the present invention is applied.

  The sensor unit 1 includes a sensor 2 that inputs a physical quantity P of differential pressure or pressure, and a second non-volatile memory 3 (EEPROM_2) that stores parameters unique to the sensor. The measurement result of the sensor 2 is subjected to processing such as amplification and range setting by the input processing unit 4, converted into a digital value by the A / D conversion circuit 5, and signal processed by the CPU 6.

  The CPU 6 is connected to a volatile memory 7 such as a RAM for storing firmware and executing main processing, and a first non-volatile memory 8 (EEPROM_1) that holds firmware, parameters, and the like.

  The result of the main processing by the CPU 6 is converted into an analog value by the D / A conversion circuit 9, converted into a current signal of 4-20 mA or the like by the output unit 10, and transmitted to the external device via the two-wire output cable 11. Is done.

  A communication unit 12 is connected between the CPU 6 and the output cable 11, and the communication unit 12 enables the CPU 6 and the host PC 14 to perform digital communication according to a communication standard such as heart via the network 13 connected to the output cable 11. Yes.

  Assuming a product lineup of differential pressure / pressure transmitters, there are two types, a standard product (hereinafter referred to as product A) and a high-function product (hereinafter referred to as product B). The functional difference between the product A and the product B depends on the firmware installed and held in the first nonvolatile memory 8.

  In general, the firmware of the product A is realized by a common part in which the specifications of the standard product of the differential pressure / pressure transmitter are described. The firmware of the product B takes a form in which specifications of the common part and additional specifications added thereto are described. Additional specifications include advanced diagnostic applications and high-precision calibration specifications.

  In FIG. 7, the firmware 15 in which the specifications of the product A are described and the firmware 16 in which the specifications of the product B are described are selectively installed in the first nonvolatile memory 8 in the manufacturing process, so that two types of lineup are provided. Is realized.

  FIG. 8 is an image diagram of firmware reading for each of the products A and B of the conventional field device. 8A shows a hardware installation image, and FIG. 8B shows a software installation image.

  In FIG. 8A, in the product (A), the firmware for the product A is installed in the CPU assembly that holds the RAM and the first nonvolatile memory (EEPROM_1), and the second nonvolatile memory (EEPROM_2) is held. It is mounted on the sensor part with common specifications.

  In the product (B), the firmware for the product B is installed in the CPU assembly that holds the RAM and the first nonvolatile memory (EEPROM_1), and the sensor unit of the common specification that has the second nonvolatile memory 3 (EEPROM_2) To be implemented.

  In the software image shown in FIG. 8B, the product (A) and the product (B) are common. In step S1, internal data is read from the first and second nonvolatile memories, this data is stored in the volatile memory in step S2, and the operation of product A or product B is realized in the main process in step S3.

JP 2005-309913 A

  In the field device of the conventional configuration, the difference between the product A and the product B is that the value of the data (parameter group necessary for operating as a transmitter) held in the first nonvolatile memory 8 and the additional specification added. Although it is firmware and the main processing and the like (processing for executing the specifications of the common part) are the same, it is necessary to manage different firmware for the product A and the product B, so that maintainability is lacking. In addition, separating them increases the man-hours during development and production, which is inefficient.

  An object of the present invention is to realize a field device that enables integration and selective installation of different firmware for each product.

In order to achieve such a subject, the present invention has the following configuration.
(1) In a field device in which a CPU that processes an input signal from a sensor reads a firmware held in a first non-volatile memory and executes a start-up process that stores the firmware in a volatile memory.
The first nonvolatile memory includes a common part in which specifications of a standard product are described, and a high-function addition part in which the additional specifications of a high-function product in which an additional specification is added to the specifications of the standard product are described. Keeps integrated firmware,
Model type information holding means for holding model type information for selecting either the standard product or the highly functional product,
The CPU reads the common unit, or the common unit and the high function adding unit from the integrated firmware held in the first nonvolatile memory based on the model type information read from the model type information holding unit. And storing it in the volatile memory.

(2) The field device according to (1), wherein the model type information holding unit is formed in the first nonvolatile memory.

(3) a second nonvolatile memory for holding information unique to the sensor;
The field device according to (1) or (2), wherein the model type information holding unit is formed in the second nonvolatile memory.

(4) The field device according to (1), wherein type information of hardware mounted on the standard product or the high-functional product is the model type information.

(5) The field device according to (1), wherein type information of communication performed via a communication terminal is the model type information.

According to the present invention, the following effects can be expected.
(1) Firmware can be integrated for each product, and it is excellent in maintainability such as maintenance by being unified.

(2) Since the firmware is integrated, development man-hours and production man-hours can be reduced, which is efficient. The product A or the product B can be operated by the connected sensor without depending on the CPU assembly. For example, it is possible to operate the product B by connecting the CPU assembly that was operating in the product A to the sensor of the product B.

(3) Without being limited to two types of products A and B, it is possible to cope with an increase in the number of models to 3 or more. As a result, a plurality of different models can be centrally managed by the integrated firmware.

It is a functional block diagram which shows one Example of the field apparatus to which this invention is applied. It is an image figure of firmware and model type information reading of the field device of the present invention. It is a flowchart which shows the process sequence of firmware and model type information reading. It is a flowchart which shows the process sequence of the firmware and model type information reading in other embodiment of the field device to which this invention is applied. It is an image figure of firmware and model type information reading in further another embodiment of the field device to which the present invention is applied. It is an image figure of firmware and model type information reading in further another embodiment of the field device to which the present invention is applied. It is a functional block diagram which shows the structural example of the conventional field device. It is an image figure of the firmware reading of the conventional field device.

  Hereinafter, the present invention will be described in detail with reference to the drawings. FIG. 1 is a functional block diagram showing an embodiment of a field device to which the present invention is applied. The same elements as those of the conventional configuration described with reference to FIG.

  The characteristic portions of the present invention that are different from the conventional configuration shown in FIG. 7 reside in the integrated firmware 100 and model type information 200. The configuration of the integrated firmware 100 includes a common unit 101 and a high function adding unit 102 additionally described in the common unit.

  When realizing the product A, the CPU 6 reads the common unit 101 from the integrated firmware 100 and stores it in the volatile memory 7 (RAM) in the startup process. When the product B is realized, firmware obtained by combining the common unit 101 and the high function adding unit 102 is read from the integrated firmware 100 and stored in the RAM.

  The model type information 200 is information for identifying the product A and the product B, and is held in the first nonvolatile memory 8 or the second nonvolatile memory 3, thereby realizing a model type information holding unit. For this information, the size and type of the data to be held are not particularly specified. For example, it may be binary data that can be identified, such as 0 for product A and 1 for product B.

  Based on the model type information 200 acquired from the model type information holding means formed in the first nonvolatile memory 8 or the second nonvolatile memory 3, the CPU 6 uses the common unit 101 of the integrated firmware 100 or the entire integrated firmware (101 + 102). Are selectively read out and stored in the volatile memory 7.

  FIG. 2 is an image diagram of reading firmware and model type information of the field device of the present invention. FIG. 2A shows a hardware installation image, and FIG. 2B shows a software installation image.

  In FIG. 2A, the firmware for realizing the product (A) or the product B is installed in the first non-volatile memory 8 of the common CPU assembly having the volatile memory and the first non-volatile memory. .

  When the product (A) is manufactured based on the model type information acquired from the model type information holding unit, the CPU assembly that reads the common unit 101 of the integrated firmware 100 and stores it in the nonvolatile memory is stored in the second nonvolatile memory. It is mounted on a sensor unit with a common specification that has a memory 3.

  When manufacturing the product (B) based on the model type information acquired from the model type information holding unit, the CPU assembly that reads the entire integrated firmware (101 + 102) from the integrated firmware 100 and stores it in the nonvolatile memory is 2 Mounted on a sensor unit of common specifications having a nonvolatile memory 3.

  The software image shown in FIG. 2B is common to the product (A) and the product (B), and internal data is read from the first and second nonvolatile memories in step S1, and the model type is read in step S2. The information is read, the firmware data selected in the activation process in step S3 is stored in the volatile memory, and the operation of the product A or product B is realized in the main process in step S4.

  FIG. 3 is a detailed flowchart showing a processing procedure for reading firmware and model type information. Internal data (firmware) is acquired from the first nonvolatile memory 8 in step S1 after the power is turned on.

  In step S2 of the model information identification unit, provisional determination processing is executed, and the common part of the integrated firmware is read and provisionally determined using the product A as a manufacturing model. In step S <b> 3, model type information is acquired from the model type information holding unit formed in the first nonvolatile memory 8 (or the second nonvolatile memory 3) and stored in the volatile memory 7.

  In step S4 of the activation processing unit, activation processing for storing data acquired from the integrated firmware in the volatile memory based on the acquired model type information is executed, and branch processing for product A and product B is executed in step S5.

  Step S6 of the main processing unit starts the main processing as product A when the branching process in step S5 is product A. Step S7 of the main processing unit starts the main processing as the product B when the branching process at step S5 is the product B. These main processes are terminated when the power is turned off.

  FIG. 4 is a flowchart showing a processing procedure for reading firmware and model type information in another embodiment of the field device to which the present invention is applied. As a countermeasure when EEPROM_1 of the non-volatile memory 8 fails, EEPROM_2 of the non-volatile memory 3 also has model type information, and if the model type information can be read normally from EEPROM_1, it operates with the information of EEPROM_1. However, when EEPROM_1 is faulty (abnormal), it operates with the model type information of EEPROM_2.

  In step S8 added to the model identification unit in the flowchart of FIG. 4, the EEPROM_1 of the nonvolatile memory 8 is checked, and if normal, the processing flow is the same as that of FIG. If abnormal, the EEPROM_2 of the nonvolatile memory 3 is checked in step S9. If normal, the process proceeds to step S10, the model type information of the EEPROM_2 is acquired, and the process proceeds to step S4. Become. If the EEPROM_2 is also abnormal, the process proceeds to step S6 and main processing is started as the product A.

  FIG. 5 is an image diagram of firmware and model type information reading in still another embodiment of a field device to which the present invention is applied. The feature of this embodiment is that the type information of hardware mounted on the product A or the product B is the model type information.

  When the LCD 1 is connected to the common CPU assembly, the CPU 6 obtains hardware type information representing the LCD 1 and operates on the product A. When the LCD 2 is connected, the CPU 6 obtains hardware type information representing the LCD 2 and obtains the product B on the product B. Operate. In this case, for example, the LCD 1 may be a high-precision full-dot type LCD, and the LCD 2 may be a segment type LCD.

  FIG. 6 is an image diagram of firmware and model type information reading in still another embodiment of a field device to which the present invention is applied. The feature of this embodiment is that the type information of communication to be connected is the model type information.

  When the form of communication that is connected and executed via the communication terminal is a current output of 4-20 mA, the CPU 6 acquires communication type information indicating the current output and operates on the product A. When the communication form to be connected is digital communication, the CPU 6 acquires communication type information representing digital communication and operates on the product B. When the connected communication form is a voltage output of 1-5V, the CPU 6 acquires communication type information indicating the voltage output and operates on the product C.

  In the embodiment described above, the differential pressure / pressure transmitter is exemplified as the field device. However, the present invention can be applied to general field devices for manufacturing a plurality of models.

  Further, in the embodiment, the example of the product A having the standard function and the product B to which the high function is added has been described. However, the present invention is not limited to this, and there are three or more model types that can use the integrated firmware. It can be applied to product manufacturing.

1 Sensor part 2 Sensor 3 Second non-volatile memory (EEPROM_2)
4 Input processing unit 5 A / D conversion circuit 6 CPU
7 Volatile memory (RAM)
8 First non-volatile memory (EEPROM_1)
9 D / A conversion circuit 10 Output unit 100 Integrated firmware 101 Common unit 102 High function addition unit 200 Model type information

Claims (5)

In the field device in which the CPU that processes the input signal from the sensor reads the firmware held in the first non-volatile memory and executes the start-up process that stores the firmware in the volatile memory.
The first nonvolatile memory includes a common part in which specifications of a standard product are described, and a high-function addition part in which the additional specifications of a high-function product in which an additional specification is added to the specifications of the standard product are described. Keeps integrated firmware,
Model type information holding means for holding model type information for selecting either the standard product or the highly functional product,
The CPU reads the common unit, or the common unit and the high function adding unit from the integrated firmware held in the first nonvolatile memory based on the model type information read from the model type information holding unit. And storing it in the volatile memory.   The field device according to claim 1, wherein the model-type information holding unit is formed in the first nonvolatile memory. A second non-volatile memory for holding information unique to the sensor;
3. The field device according to claim 1, wherein the model type information holding unit is formed in the second nonvolatile memory.   The field device according to claim 1, wherein the model type information is hardware type information mounted on the standard product or the high-functional product.   The field device according to claim 1, wherein type information of communication performed via a communication terminal is the model type information.