WO2022153565A1 - Information processing device, method for controlling information processing device, and program for information processing device - Google Patents

Abstract

The present invention identifies the accuracy assurance range of an analog unit. This information processing device comprises: an accuracy assurance identification unit (13) that identifies, on the basis of an analog signal handled by an analog unit and of prescribed information, the accuracy assurance range of the analog signal; and a storage unit (20) that stores the prescribed information.

Description

Information processing device, control method of information processing device, and program of information processing device

The present invention relates to the accuracy guarantee range of the analog unit.

Various sensors are used in PLC (Programming Logic Controller) devices used in warehouses and factories. Among the sensors, there is a sensor for analog output such as temperature, and an analog input IO unit (Input / Output Unit: hereinafter also referred to as an analog unit) may be used. In the analog input IO unit, an AD (Analog-Digital) converter converts analog signals such as voltage and current into digital values.

Japanese Patent Application Laid-Open No. 2017-146103

When AD conversion is performed, there is an error. Patent Document 1 discloses a technique for determining a deteriorated state of a battery cell from a voltage measurement error of the battery cell. By grasping the measurement error associated with the AD conversion in this way, it is possible to prevent an abnormal situation and use it for investigating the cause of the abnormality.

Conventionally, it was necessary for a person to manually calculate the measurement error of the analog amount in the device according to the procedure described in the manual. Even in this case, if any abnormality occurs, it can be a clue to investigate the cause. However, it takes time for the user to specify the accuracy guarantee range, which is an index of the error associated with the AD conversion of the IO unit, and it is difficult to dynamically grasp the accuracy guarantee range.

One aspect of the present invention is to specify the accuracy guarantee range of the analog signal handled by the analog unit.

In order to solve the above problems, the information processing apparatus according to one aspect of the present invention has an accuracy of specifying the accuracy guarantee range of the analog signal based on the analog signal handled by the analog unit and predetermined information about the analog signal. It includes a guarantee identification unit and a storage unit that stores the predetermined information.

The control method of the information processing apparatus according to the other aspect is the acquisition step of acquiring predetermined information about the analog signal handled by the analog unit from the storage unit, the analog signal, and the analog signal based on the predetermined information. Includes an accuracy assurance identification step that specifies the accuracy assurance scope.

According to one aspect of the present invention, the accuracy guarantee range of the analog signal handled by the analog unit can be specified.

It is a block diagram which shows the structure of the main part of the analog system which concerns on Embodiment 1. FIG. It is a flowchart which shows the specific procedure of the accuracy guarantee range in the temperature input unit which concerns on Embodiment 1. It is a table which shows the type of the thermocouple corresponding to the temperature input unit which concerns on Embodiment 1. It is a flowchart which shows the specification procedure of the cold contact compensation error used for specifying the accuracy guarantee range of the temperature input unit which concerns on Embodiment 1. It is a block diagram which shows the structure of the main part of the analog system which concerns on Embodiment 2. It is a block diagram which shows the structure of the main part of the analog system which concerns on Embodiment 3. It is a block diagram which shows the structure of the main part of the analog system which concerns on Embodiment 4. FIG. It is a block diagram which shows the structure of the main part of the analog system which concerns on Embodiment 5. It is a flowchart which shows the specific procedure of the accuracy guarantee range in the load cell input unit which concerns on Embodiment 5. It is a block diagram which shows the structure of the main part of the analog system which concerns on Embodiment 6. It is a flowchart which shows the specific procedure of the accuracy guarantee range in the analog output unit which concerns on Embodiment 6.

[Embodiment 1]
Hereinafter, embodiments according to one aspect of the present invention (hereinafter, also referred to as “the present embodiment”) will be described with reference to the drawings. The same or corresponding parts in the drawings are designated by the same reference numerals, and the description thereof will not be repeated.

§1 Application example First, an example of a situation in which the present invention is applied will be introduced. The information processing device according to this application example is an analog input / output analog unit (IO unit (Input / Output Unit)), and inputs an analog signal from an analog output sensor. The analog unit includes an accuracy guarantee specifying unit that specifies an accuracy guarantee range that is an index of AD conversion accuracy of an input analog signal, and a storage unit that collectively stores a procedure for specifying the accuracy guarantee range. ing. Here, the accuracy guarantee range is the range of the input / output accuracy values of the analog unit guaranteed by the manufacturer or the state of the input / output accuracy. Specifically, the accuracy guarantee range is an index showing the degree of the error of the input / output value due to the conversion of the electric circuit and the conversion circuit that input / output the analog signal of the device to be AD-converted, or the temperature drift of the analog device. ..

The accuracy guarantee specifying unit specifies the accuracy guarantee range of the analog signal input / output by the analog unit according to the procedure. By specifying the accuracy guarantee range, the degree of the accuracy guarantee range of the analog unit can be notified to the administrator via the output unit.

§2 Configuration example FIG. 1 is a block diagram showing a configuration of a main part of the analog system 100a according to the first embodiment. The analog system 100a includes a temperature input unit 1a and a thermocouple 111.

(Structure of thermocouple 111)
The thermocouple 111 is a sensor having a function of outputting the temperature of the measurement point as an analog signal. Here, a thermocouple is used to explain the temperature input unit as an example of the analog unit, but any analog device may be used. Examples of analog devices include, but are not limited to, thermocouples, resistance temperature detectors, accelerometers, load cells, pressure gauges, flow meters, and the like. The analog output of the analog device may be a voltage output, a current output, or an IEPE output, and the output range is arbitrary.

(Structure of temperature input unit 1a)
The temperature input unit 1a includes a control unit 10a, a storage unit 20, and a display 141. The temperature input unit 1a is an analog unit capable of connecting various types of thermocouples and measuring the temperature by the thermoelectromotive force of the thermocouple 111.

The storage unit 20 stores parameters, programs, and processing procedures necessary for specifying the accuracy guarantee range of the analog unit. The storage unit 20 may be configured by a non-volatile memory.

The display 141 displays the degree of the accuracy guarantee range in accordance with the command of the control unit 10a. Here, the display 141 has displays from Rank 0 to Rank 3, and as a result of processing by the control unit 10a, one of them lights up. Further, the display 141 may be a display device that performs an arbitrary display.

(Structure of control unit 10a)
The control unit 10a controls each unit of the temperature input unit 1a in an integrated manner. The control unit 10a includes a measurement value acquisition unit 11, an environmental information acquisition unit 12a (acquisition unit), an accuracy guarantee identification unit 13, and an output unit 14.

The measurement value acquisition unit 11 performs a process of AD-converting an analog signal input from the thermocouple 111, which is a thermocouple input, and converting it into a digital value. The measurement value acquisition unit 11 outputs the converted digital value to the accuracy guarantee identification unit 13.

The environmental information acquisition unit 12a acquires the environmental information of the analog unit. The environmental information may include the power consumption of the unit adjacent to the analog unit, the ambient temperature of the analog unit, the installation direction of the analog unit, and the like, and some environmental information may be missing. The administrator sets these environmental information in the storage unit 20 in advance, and the environmental information acquisition unit 12a reads the set value. The environmental information acquisition unit 12a outputs the environmental information to the accuracy guarantee identification unit 13.

The accuracy guarantee specifying unit 13 specifies the accuracy guarantee range of the analog amount based on the analog signal handled by the analog unit and predetermined information including various parameters and the procedure for specifying the accuracy guarantee range. Various parameters include environmental information such as the ambient temperature or installation direction of the analog unit and / or information about the device handling the analog signal such as the sensor type. The specified accuracy guarantee range is output to the output unit 14.

The output unit 14 displays the level of the accuracy guarantee range on the display 141 based on the input accuracy guarantee range. The level of the accuracy guarantee range is an index in which the specified accuracy guarantee range is classified into several stages. The user can determine whether or not the accuracy guarantee range is sufficient simply by checking the level. Further, the output unit 14 may output the digital value (measured value) measured by the analog unit and the accuracy guarantee range to a higher-level device (for example, PLC).

§3 Operation example Among the analog units, a certain temperature input unit 1a will be taken as an example, and an example of the procedure for specifying the accuracy guarantee range will be described as an operation example. The procedure for specifying the accuracy guarantee range is an example, and the present invention is not limited to this.

FIG. 2 is a flowchart showing a procedure for specifying the accuracy guarantee range in the temperature input unit according to the first embodiment. FIG. 3 is a table showing the types of thermocouples supported by the temperature input unit according to the first embodiment. FIG. 4 is a flowchart showing a procedure for specifying a cold contact compensation error used for specifying the accuracy guarantee range of the temperature input unit according to the first embodiment.

(Specification of accuracy guarantee range in temperature input unit)
The procedure for specifying the accuracy guarantee range in the temperature input unit 1a will be described with reference to FIG.

Prior to specifying the accuracy guarantee range, it is necessary to set the ambient temperature change of the temperature input unit 1a in the storage unit 20 in advance. The ambient temperature change is the increase / decrease in the ambient temperature of the temperature input unit 1a with respect to the reference temperature determined by the equipment specifications. That is, when the ambient temperature is 30 ° C. and the reference temperature is 25 ° C., the change in ambient temperature is 5 ° C.

In S11, the accuracy guarantee specifying unit 13 confirms whether the energization time of the temperature input unit 1a is equal to or longer than a predetermined time. The energizing time is the elapsed time since the power of the analog unit is turned on, and is calculated by counting up with the firmware of the analog unit. The predetermined time is, for example, 30 minutes, which is the time until the temperature characteristics of the analog unit stabilize depending on the temperature of the analog unit itself and the environment in which the analog unit is installed. The temperature input unit 1a measures the energizing time. If the time is equal to or longer than the predetermined time (Yes in S11), the process proceeds to S12. If it is less than the predetermined time (No in S11), the process proceeds to S17.

In S12, the accuracy guarantee specifying unit 13 specifies the cold contact compensation error. The procedure for specifying the cold contact compensation error will be described later. A thermocouple is a sensor that measures the temperature difference between the reference contact (cold contact) connected to the temperature input unit and the temperature measurement contact (warm contact) installed at the temperature measurement point due to the Seebeck effect in which current flows between dissimilar metals. Is. That is, since the thermocouple measures the relative temperature, another sensor that can measure the temperature at the reference contact as the absolute temperature is required. The cold contact compensation error is an error that occurs because the temperature at the reference contact is separately measured by a sensor such as another thermistor or resistance temperature detector and added to the relative temperature measured by the thermocouple.

In S13, the accuracy guarantee identification unit 13 confirms whether the cold contact compensation error is a guaranteed condition. If the cold contact compensation error is a guaranteed condition (Yes in S13), the process proceeds to S14. If the cold contact compensation error is a condition without guarantee (No in S13), the process proceeds to S17.

In S14, the accuracy guarantee specifying unit 13 refers to the input mode (input type) stored in the storage unit 20 corresponding to the conversion time and the type of thermocouple, and uses the current measured values to obtain the reference accuracy and the reference accuracy. Find the temperature coefficient. The conversion time represents the time required for AD conversion, and the input mode represents the type of thermocouple 111. FIG. 3 is a table showing the measurable temperature range for each type of thermocouple at a certain conversion time, and the reference accuracy and temperature coefficient for each temperature range. The storage unit 20 stores a table in which the conversion time, the type of thermocouple, the range of the measurement temperature, the reference accuracy, and the temperature coefficient are associated with each other. For example, when the measurement temperature of the K-type thermocouple is 500 ° C, the temperature range is −200 to 1300 ° C, the measurement temperature is divided into three stages, and the reference accuracy is ± in the division of -100 to 400 ° C. It is shown that the temperature coefficient is ± 0.30 ° C./° C. at 1.5 ° C. Further, the environmental information acquisition unit 12a reads the ambient temperature change from the storage unit 20. The conversion time is a fixed value unique to the analog unit, and here it takes a unique value. However, depending on the analog unit, the conversion accuracy may decrease instead of performing high-speed conversion by changing the conversion time, and the conversion time is a parameter used for calculating the reference accuracy.

In S15, the accuracy guarantee specifying unit 13 specifies the accuracy guarantee range according to the following equation.

Accuracy guarantee range = reference accuracy + temperature characteristic x ambient temperature change + cold contact compensation error In the above formula, the sign of the reference characteristic, temperature characteristic and cold contact compensation error is a value of plus or minus error, so it depends on the absolute value. Make a calculation.

In S16, the output unit 14 determines whether the accuracy guarantee range is within the first range. If the accuracy guarantee range falls within the first range (Yes in S16), the process proceeds to S18. If the accuracy guarantee range does not fall within the first range (No in S16), the process proceeds to S17.

In S17, the output unit 14 determines that the condition cannot guarantee the accuracy, and issues a command to turn on the Rank 0 display on the display 141.

In S18, the output unit 14 determines whether the accuracy guarantee range is within the second range, and outputs the accuracy guarantee range to the output unit 14. The second range is a range inside the first range and is more accurate. If the accuracy guarantee range is within the second range (Yes in S18), the process proceeds to S20. If the accuracy guarantee range is outside the second range (No in S18), the process proceeds to S19.

In S19, the output unit 14 determines that the accuracy guarantee range is within the first range, which is a condition for which the accuracy can be guaranteed, and issues a command to the display 141 to light the Rank 1 display.

In S20, the output unit 14 determines whether the accuracy guarantee range is within the third range, and outputs the accuracy guarantee range to the output unit 14. The third range is a range inside the second range and is more accurate. If the guaranteed accuracy value is within the third range (Yes in S20), the process proceeds to S22. If the accuracy guarantee range is outside the third range (No in S20), the process proceeds to S21.

In S21, the output unit 14 determines that the accuracy guarantee range is within the second range, which is a condition for which the accuracy can be guaranteed, and issues a command to turn on the Rank 2 display on the display 141.

In S22, the output unit 14 determines that the accuracy guarantee range is within the third range, which is a condition for which the accuracy can be guaranteed, and issues a command to turn on the Rank 3 display on the display 141.

(Identification of cold contact compensation error)
The procedure for specifying the cold contact compensation error in S12 in the temperature input unit 1a will be described with reference to FIG.

Prior to specifying the cold contact compensation error, it is necessary to set the input mode, the installation direction of the temperature input unit 1a, and the power consumption of the adjacent unit in the storage unit 20 in advance. Further, the power consumption of the adjacent unit may be automatically generated and set from the configuration of the analog system 100a set by the setting software when the setting software writes the setting to the analog unit. An adjacent unit is a unit that is connected to an analog unit and shares a power source with the analog unit. Adjacent units may be connected to both sides of the analog unit.

In S31, the environmental information acquisition unit 12a determines whether the installation direction of the temperature input unit 1a is the predetermined installation direction and the power consumption of the unit adjacent to the temperature input unit is equal to or less than the first power threshold. For example, the installation direction of the temperature input unit 1a may be front mounting (vertical direction or horizontal direction), ceiling mounting, floor mounting, or the like. For example, the predetermined installation direction is front mounting (vertical direction). If the condition is not satisfied (No in S31), the process proceeds to S32. If the condition is satisfied (Yes in S31), the process proceeds to S41.

In S32, in the environmental information acquisition unit 12a, the installation direction of the temperature input unit 1a is a predetermined installation direction, and the power consumption of the unit adjacent to the temperature input unit is equal to or less than the second power threshold value, or the temperature input unit. It is determined whether the installation direction of 1a is not a predetermined installation direction and the condition that the power consumption of the unit adjacent to the temperature input unit satisfies the condition of being equal to or less than the second power threshold. In short, the environmental information acquisition unit 12a determines whether or not the condition that the power consumption of the unit adjacent to the temperature input unit satisfies the condition of being equal to or less than the second power threshold value is satisfied. The second power threshold value is larger than the first power threshold value. If the condition is not satisfied (No in S32), the process proceeds to S33. If the condition is satisfied (Yes in S32), the process proceeds to S51.

In S33, the accuracy guarantee specifying unit 13 determines that there is no guarantee of the cold contact compensation error.

In S41, the accuracy guarantee specifying unit 13 refers to the storage unit 20 and determines whether or not the first condition is satisfied based on the input mode of the connected thermocouple 111 and the current measured value. The first condition is, for example, that the input mode of the thermocouple is any of J, E, K, and N, and the temperature measured by the measured value acquisition unit 11 is a temperature threshold value (for example, -100) according to the input mode. ℃) or less. As described above, as the first condition, the determination may be made based on the input mode, the measured value, and the like. The temperature threshold can vary depending on the input mode. If the condition is satisfied (Yes in S41), the process proceeds to S43. If the condition is not satisfied (No in S41), the process proceeds to S42.

In S42, the accuracy guarantee specifying unit 13 refers to the storage unit 20 and determines whether or not the second condition is satisfied based on the input mode of the connected thermocouple 111 and the current measured value. The second condition includes, for example, a condition that the input mode of the thermocouple is W. If the condition is satisfied (Yes in S42), the process proceeds to S43. If the condition is not satisfied (No in S42), the process proceeds to S44.

In S43, the accuracy guarantee specifying unit 13 determines that the cold contact compensation error is the first error range. The first error range is, for example, ± 3.0 ° C.

Further, in S44, the accuracy guarantee specifying unit 13 determines that the cold contact compensation error is the second error range. The second error range is, for example, no guarantee of cold contact compensation error (ie, the second error range is infinite).

In S51, the accuracy guarantee specifying unit 13 refers to the storage unit 20 and determines whether or not the first condition is satisfied based on the input mode of the connected thermocouple 111 and the current measured value. If the condition is satisfied (Yes in S51), the process proceeds to S52. If the condition is not satisfied (No in S51), the process proceeds to S53.

In S52, the accuracy guarantee specifying unit 13 determines that the cold contact compensation error is in the third error range. The third value is, for example, ± 7.0 ° C., which is wider than the first error range.

In S53, the accuracy guarantee specifying unit 13 refers to the storage unit 20 and determines whether or not the second condition is satisfied based on the input mode of the connected thermocouple 111 and the current measured value. If the condition is satisfied (Yes in S53), the process proceeds to S54. If the condition is not satisfied (No in S53), the process proceeds to S55.

In S54, the accuracy guarantee specifying unit 13 determines that the cold contact compensation error is in the fourth error range. The fourth error range is, for example, ± 9.0 ° C., which is wider than the third error range.

Further, in S55, the accuracy guarantee specifying unit 13 determines that the cold contact compensation error is in the fifth error range. The fifth error range is wider than the fourth error range, for example, there is no guarantee of cold contact compensation error.

(Specific example of accuracy guarantee range in temperature input unit)
Here, a specific example of the accuracy guarantee range in a certain temperature input unit 1a is shown. As specific conditions, the energizing time is 30 minutes or more, the installation direction is front mounting, the power consumption of the adjacent unit is 1.5 W or less, the input mode is K thermocouple, and the conversion time is 250 msec. It is assumed that the measurement temperature is 100 ° C. and the ambient temperature is 30 ° C.

First, for comparison, the conventional method of specifying the accuracy guarantee range is shown. Conventionally, a person checks the energizing time and installation direction, uses a dedicated tool to check the power consumption, input mode, and measured temperature of the adjacent unit, installs a temperature sensor, measures the ambient temperature, and judges the variation. There is a need. It is very complicated because it is necessary to specify the accuracy guarantee range according to a predetermined procedure while referring to the manual or the data sheet.

On the other hand, in the present embodiment, first, in S11, the timer that is counted up by the firmware from the start of energization of the temperature input unit 1a is confirmed, and since the energization time is 30 minutes or more and the predetermined time or more, the process is performed in S12. move on. In S12, when the cold contact compensation error is specified from the conditions of the installation direction, the power consumption of the adjacent unit, the input mode, and the measurement temperature, the process proceeds to S44, and it is assumed that the cold contact compensation error is ± 1.2 ° C. ..

Since there is a cold contact compensation error, the process proceeds to S14 and the ambient temperature is 30 ° C. Therefore, when the reference temperature is 25 ° C, the ambient temperature change is 5 ° C, and the input mode, conversion time, and measurement temperature From the conditions, the reference accuracy is ± 1.5 ° C and the temperature coefficient is ± 0.30 ° C / ° C. The accuracy guarantee range is specified from these conditions as follows.

Accuracy guarantee range = ± 1.5 ° C + ± 0.30 ° C / ° C x 5 ° C + ± 1.2 ° C = ± 4.2 ° C
Here, in the calculation of the accuracy guarantee range, the error range of ± is added because of the numerical value of the error. When adding the error ranges, the absolute values of the errors shall be added. That is, the value obtained by adding the errors on the plus side is set as the upper limit of the error range, and the value obtained by adding the errors on the minus side is set as the lower limit of the error range.

Since the accuracy guarantee range is ± 4.2 ° C. (<third threshold value), the process proceeds to S22, and the output unit 14 turns on the Rank 3 indicator. These steps are performed automatically.

§4 Action / Effect By setting some parameters in the storage unit 20 in advance, the accuracy guarantee range can be automatically specified in real time from the parameters and measured values according to a predetermined procedure.

In addition, since the approximate value of the accuracy guarantee range can be confirmed on the display without preparing a dedicated program for confirming and processing the accuracy guarantee range, it is easy to confirm the state of the analog device during regular maintenance.

[Embodiment 2]
Other embodiments of the present invention will be described below. For convenience of explanation, the same reference numerals will be added to the members having the same functions as the members described in the above embodiment, and the description will not be repeated.

FIG. 5 is a block diagram showing a configuration of a main part of the analog system 100b according to the second embodiment. The second embodiment is different from the first embodiment in that the accuracy guarantee range can be specified by a person without separately setting a part of the parameters necessary for specifying the accuracy guarantee range in the storage unit 20. Of course, some parameters such as the input mode need to be set separately.

In the analog system 100b, the temperature input unit 1a is changed to the temperature input unit 1b, the control unit 10a is changed to the control unit 10b, and the environmental information acquisition unit 12a is changed to the environmental information acquisition unit 12b. Further, the temperature input unit 1b includes a temperature sensor 121 and an acceleration sensor 122.

The temperature sensor 121 is a temperature sensor built-in or externally installed in the analog unit. As the temperature sensor, a sensor that measures the absolute temperature, such as a thermistor or a resistance temperature detector, is used. Depending on the type of analog unit, the temperature sensor 121 may not be provided.

The acceleration sensor 122 is an acceleration sensor built in the analog unit. The accelerometer may be a tilt sensor or any sensor capable of determining the installation direction of the analog unit.

Unlike the environmental information acquisition unit 12a, the environmental information acquisition unit 12b is different in that it automatically acquires the environmental information of the analog unit instead of reading the set value set in advance by a person. The environmental information acquisition unit 12b acquires the ambient temperature of the analog unit by the temperature sensor 121, and acquires the installation direction of the analog unit by the acceleration sensor 122.

Therefore, in the second embodiment, since the parameters necessary for specifying the accuracy guarantee range preset by a person are automatically acquired, the accuracy guarantee range can be determined simply by attaching and starting the analog unit. Easy to use. In addition, even if the environmental information changes, there is an advantage that it can be automatically dealt with without changing the settings.

Further, by notifying the PLC, which is a higher-level device of the analog unit, of the accuracy guarantee range by the output unit 14, it is possible to perform arbitrary processing based on the accuracy guarantee range by the program in the PLC. For example, when the accuracy guarantee range becomes larger than the predetermined range and deteriorates, the PLC that has acquired the information of the temperature input unit 1b automatically stops the production and asks the administrator to check the state of the analog system 100b. It will be possible to notify.

[Embodiment 3]
Other embodiments of the present invention will be described below.

FIG. 6 is a block diagram showing a configuration of a main part of the analog system 100c according to the third embodiment. The third embodiment is different from the first embodiment in that the accuracy guarantee range is not specified by the analog unit but by the PLC which is the master of the analog unit.

The analog system 100c includes a PLC 2c, a temperature input unit 3c, and a thermocouple 111. The PLC 2c includes a control unit 10c, a storage unit 20, and a display 141. The control unit 10c includes an environment information acquisition unit 12a, an accuracy guarantee identification unit 13, an output unit 14, and a unit communication unit 15c.

The unit communication unit 15c communicates with the temperature input unit 3c to acquire the digital value of the analog amount of the thermocouple 111. At the same time, the unit communication unit 15c acquires the input mode / conversion time from the non-volatile memory of the temperature input unit 3c.

The temperature input unit 3c includes a measured value acquisition unit 11. The temperature input unit 3c converts the analog amount of the thermocouple 111 into a digital value and communicates with the unit communication unit 15c. At the same time, the input mode and conversion time are acquired from the non-volatile memory of the temperature input unit 3c and communicated.

The PLC 2c acquires the measured temperature, the input mode, and the conversion time from the temperature input unit 3c, and the environmental information acquisition unit 12a acquires the installation direction, the power consumption of the adjacent unit, and the ambient temperature from the storage unit 20, and the same as the first embodiment. The accuracy guarantee range is specified by the same process.

Therefore, unlike the first embodiment, there is no change in the analog unit, and the accuracy guarantee range can be specified only by modifying the program of the PLC corresponding to the master, which is suitable for modifying the existing system.

Further, in order to specify the accuracy guarantee range in the PLC, the control unit 10c of the PLC2c can execute the user's own program based on the specified accuracy guarantee range. The control unit 10c of the PLC 2c can automatically stop the production and notify the administrator to check the status of the analog system 100b.

[Embodiment 4]
Other embodiments of the present invention will be described below.

FIG. 7 is a block diagram showing a configuration of a main part of the analog system 100d according to the fourth embodiment. In the fourth embodiment, unlike the first embodiment, the accuracy guarantee range is not specified by the analog unit, but is performed by the PLC of the master of the analog unit, and all the parameters necessary for specifying the accuracy guarantee range are acquired from the analog unit. The point to do is different.

The analog system 100d includes a PLC 2d, a temperature input unit 3d, and a thermocouple 111. The PLC 2d includes a control unit 10d, a storage unit 20, and a display 141. The control unit 10d includes an accuracy guarantee specifying unit 13, an output unit 14, and a unit communication unit 15d.

The unit communication unit 15d is different from the unit communication unit 15c in that the parameters acquired by the environmental information acquisition unit in the first embodiment are also acquired from the temperature input unit 3d. The acquired parameters are output to the accuracy guarantee specifying unit 13.

Therefore, the temperature input unit 3d includes a measurement value acquisition unit 11, an environmental information acquisition unit 12d, a temperature sensor 121, and an acceleration sensor 122. In the temperature input unit 3d, the measurement value acquisition unit 11 converts the analog amount of the thermocouple 111 into a digital value, communicates with the unit communication unit, and acquires the input mode / conversion time from the non-volatile memory of the temperature input unit 3d. connect. At the same time, the environmental information acquisition unit 12d communicates the ambient temperature and the installation direction acquired from the temperature sensor 121 and the acceleration sensor 122 with the unit communication unit 15d.

Therefore, the PLC 2d acquires the measurement temperature, the input mode, the conversion time, the ambient temperature, and the installation direction from the temperature input unit 3d, and specifies the accuracy guarantee range by the same process as in the first embodiment.

Therefore, unlike the first embodiment, it is not necessary to set the parameters of the analog unit, and the functions in the accuracy guarantee range can be implemented only by creating the PLC program which is the master. Therefore, there is an advantage that the system can be easily constructed and can be easily started up. be.

[Embodiment 5]
Other embodiments of the present invention will be described below.

FIG. 8 is a block diagram showing a configuration of a main part of the analog system 100e according to the fifth embodiment. The fifth embodiment is different from the first embodiment in that the load cell input unit 4 is used instead of using the temperature input unit as the analog unit. The load cell input unit 4 is an analog unit that connects a load cell that detects pressure.

Unlike the analog system 100a, the analog system 100e uses a load cell input unit 4 instead of the temperature input unit 1a, a load cell 112 instead of the thermocouple 111, a control unit 10e instead of the control unit 10a, and a measurement value acquisition unit 11. Instead of, it is composed of the measured value acquisition unit 11e. The measured value acquisition unit 11e has the same basic functions as the measured value acquisition unit 11, except that it is a load cell input rather than a thermocouple input.

FIG. 9 is a flowchart showing a procedure for specifying the accuracy guarantee range in the load cell input unit 4 according to the fifth embodiment.

In S61, the accuracy guarantee specifying unit 13 confirms whether the energization time of the load cell input unit 4 is equal to or longer than a predetermined time. If the time is equal to or longer than the predetermined time (Yes in S61), the process proceeds to S62. If it is less than the predetermined time (No in S61), the process proceeds to S63.

In S62, the accuracy guarantee specifying unit 13 refers to the storage unit 20 and confirms whether the input mode of the connected load cell 112 is a 6-wire system. If it is not a 6-wire system (No in S62), the process proceeds to S63. If it is a 6-wire system (Yes in S62), the process proceeds to S64.

In S63, the accuracy guarantee specifying unit 13 determines that there is no guarantee for all accuracy items. The accuracy items in the load cell input unit include zero drift, gain drift, and non-linearity. The deviation width due to the ambient temperature change of the intercept and the slope in the linear approximation of the measured value and the actual pressure corresponds to zero drift and gain drift, respectively, and the non-linearity is an index showing the deviation between the linear approximation and the constituent curve. The output unit 14 lights the display of Rank 0 on the display 141.

In S64, in the accuracy guarantee specifying unit 13, the ambient temperature of the analog unit acquired by the environmental information acquisition unit 12a is within a predetermined temperature range, the digital filter setting of the load cell input unit 4 is a predetermined value, and the full scale setting is a predetermined value. Check if it is (predetermined range). If the condition is not satisfied (No in S64), the process proceeds to S65. If the condition is satisfied (Yes in S64), the process proceeds to S66.

In S65, the accuracy guarantee specifying unit 13 determines that some accuracy items are guaranteed. Guaranteed accuracy items are zero drift and gain drift. Regarding non-linearity, the accuracy guarantee range is not determined. The output unit 14 turns on the display of Rank 1 on the display 141.

In S66, the accuracy guarantee specifying unit 13 determines that all accuracy items are guaranteed. The output unit 14 lights the display of Rank 2 on the display 141.

In this way, even when the analog unit has a large number of accuracy guarantee ranges like the load cell input unit 4, all the accuracy guarantee ranges can be automatically specified. Further, the procedure for specifying the accuracy guarantee range may be different for each item, and the accuracy guarantee range may not be specified for only some items.

[Embodiment 6]
Other embodiments of the present invention will be described below. For convenience of explanation, the same reference numerals will be added to the members having the same functions as the members described in the above embodiment, and the description will not be repeated.

FIG. 10 is a block diagram showing a configuration of a main part of the analog system 100f according to the sixth embodiment. The sixth embodiment is different from the first embodiment in that the accuracy guarantee range is obtained when the analog output unit 5 is used instead of the temperature input unit as the analog unit. The analog output unit 5 is an analog unit that outputs an analog voltage or current corresponding to a digital value.

Unlike the analog system 100a, the analog system 100f is composed of an analog output unit 5 instead of the temperature input unit 1a and an analog device 113 instead of the thermocouple 111. The configuration of the analog output unit 5 is different from the configuration of the temperature input unit 1a, and includes a control unit 10f instead of the control unit 10a and an analog value output unit 11f instead of the measurement value acquisition unit 11.

The analog value output unit 11f is provided with a DA (Digital-Analog) converter inside, converts the input digital value into an analog signal, and outputs the analog signal to the analog device 113. The converted analog signal is a voltage or current. Further, the analog value output unit 11f may output the digital value to the accuracy guarantee specifying unit 13, and in this case, the accuracy guarantee range may be calculated using the digital value.

FIG. 11 is a flowchart showing a procedure for specifying the accuracy guarantee range in the analog output unit according to the sixth embodiment.

In S71, the environmental information acquisition unit 12a confirms whether the ambient temperature is within the predetermined temperature range. If it is not within the predetermined temperature range (No in S71), the process proceeds to S72. If it is within the predetermined temperature range (Yes in S71), the process proceeds to S73.

In S72, the accuracy guarantee specifying unit 13 determines that the accuracy guarantee range is the first range. Further, the output unit 14 lights the display of Rank 1 on the display 141.

In S73, the accuracy guarantee specifying unit 13 determines that the accuracy guarantee range is the second range. The second range is a range that falls within the first range. That is, it can be said that the accuracy of the second range is higher than the accuracy of the first range. The output unit 14 lights the display of Rank 2 on the display 141.

In this way, as in the analog output unit 5, the accuracy guarantee range can be automatically specified not only for analog input but also for analog output as an analog unit.

[Embodiment 7]
A use case of one aspect of the present invention will be introduced. This embodiment is an assumed example in which a temperature input unit is used for temperature control in a production apparatus whose temperature is controlled by a furnace based on the first embodiment.

(Assumed case)
From a certain time, defective products began to occur frequently in the production equipment.

When the temperature inside the furnace was measured with another measuring instrument for temperature measurement in order to investigate the cause of the defect, the temperature was different from the temperature indicated by the temperature input unit. The temperature error between the temperature input unit and the measuring instrument for temperature measurement was worse than the design accuracy of the device.

Also, when the ambient temperature of the temperature input unit was measured with a measuring device for temperature measurement, it was found that the temperature was higher than when the production equipment was delivered. As a result, the accuracy guarantee range deteriorated, the furnace could not be controlled as intended, and the quality of the product deteriorated. When we investigated the cause of the rise in the ambient temperature of the temperature input unit, it was because the delivery time and season were different and the environmental temperature was rising.

If the present invention is not implemented, even if it is found that the temperature inside the furnace cannot be controlled as expected, the device will reach the point where the accuracy guarantee range of the temperature input unit is lowered, which is the true cause of the defect. And many trials such as unit replacement are repeated, and a lot of man-hours are required. During that time, defective products will continue to appear, resulting in a large loss.

On the other hand, when one aspect of the present invention has been implemented, the display 141 is confirmed, and it can be seen at a glance that the accuracy guarantee range is lower than the delivery time. Therefore, the cause can be investigated from the viewpoint of why the accuracy guarantee range is lowered, and the true cause can be easily reached. That is, troubles can be solved with low man-hours.

In addition, if the accuracy guarantee range is constantly monitored by a program, a warning indicating that the accuracy guarantee range has deteriorated before the defective product is released can be issued at the turn of the season, which is easy to understand. Can be reached. Therefore, the occurrence of defective products can be suppressed, and troubles can be prevented in advance with low man-hours.

[Example of realization by software]
Control blocks of temperature input units 1a / 1b, PLC2c / 2d, load cell input unit 4 or analog output unit 5 (particularly measurement value acquisition units 11 / 11e, analog value output units 11f, environmental information acquisition 12a / 12b, accuracy guarantee identification The unit 13 and the output unit 14) may be realized by a logic circuit (hardware) formed in an integrated circuit (IC chip) or the like, or may be realized by software.

In the latter case, the temperature input units 1a / 1b, PLC2c / 2d, the load cell input unit 4, or the analog output unit 5 are provided with a computer that executes program instructions that are software that realizes each function. The computer includes, for example, one or more processors and a computer-readable recording medium that stores the program. Then, in the computer, the processor reads the program from the recording medium and executes it, thereby achieving the object of the present invention. As the processor, for example, a CPU (Central Processing Unit) can be used. As the recording medium, in addition to a “non-temporary tangible medium” such as a ROM (Read Only Memory), a tape, a disk, a card, a semiconductor memory, a programmable logic circuit, or the like can be used. Further, a RAM (RandomAccessMemory) or the like for expanding the above program may be further provided. Further, the program may be supplied to the computer via an arbitrary transmission medium (communication network, broadcast wave, etc.) capable of transmitting the program. It should be noted that one aspect of the present invention can also be realized in the form of a data signal embedded in a carrier wave, in which the above program is embodied by electronic transmission.

〔summary〕
In order to solve the above problems, the information processing apparatus according to one aspect of the present invention has an accuracy of specifying the accuracy guarantee range of the analog signal based on the analog signal handled by the analog unit and predetermined information about the analog signal. It includes a guarantee identification unit and a storage unit that stores the predetermined information.

According to the above configuration, the accuracy guarantee range can be automatically specified, and the decrease in the accuracy of the analog signal can be detected. Therefore, it is possible to avoid troubles associated with a decrease in the accuracy of the analog signal.

The predetermined information may include a procedure for specifying the accuracy guarantee range, information on a device that handles the analog signal, and / or environmental information of the analog unit.

According to the above configuration, the predetermined information is processed together with the device information such as the sensor type or the connection form and / or the environmental information around the analog unit according to a predetermined procedure such as a flowchart. Therefore, the accuracy guarantee range can be specified.

The information processing device may further include an acquisition unit for acquiring the environmental information.

According to the above configuration, the environmental information can be acquired, and the environmental information can be used to specify the accuracy guarantee range.

The environmental information may include the ambient temperature and / or installation direction of the analog unit.

According to the above configuration, the environmental information may include the ambient temperature and / or the installation direction, the thermal characteristics of the electronic components in the analog unit, and / or the heat exhaust property of the analog unit itself based on the installation direction of the analog unit. Etc. can be taken into consideration when specifying the accuracy guarantee range.

The information processing device may further include an output unit that outputs the accuracy guarantee range.

According to the above configuration, the accuracy guarantee range can be output and used for processing by a higher-level device, or a warning can be issued to the administrator.

The output unit may display the level of guaranteed accuracy on the display device.

According to the above configuration, the approximate value of the accuracy guarantee range can be displayed on the display unit, so that the deterioration of the state of the analog unit itself can be confirmed only by visually observing the analog unit. Therefore, the problem can be easily identified and countermeasures can be taken at an early stage.

The analog signal may be input from a thermocouple or a load cell.

According to the above configuration, the analog unit can be a temperature input unit or a load cell input unit.

The control method of the information processing apparatus according to the other aspect is the acquisition step of acquiring predetermined information about the analog signal handled by the analog unit from the storage unit, the analog signal, and the analog signal based on the predetermined information. Includes an accuracy assurance identification step that specifies the accuracy assurance scope.

The information processing device according to each aspect of the present invention may be realized by a computer. In this case, the information processing device is made into a computer by operating the computer as each part (software element) included in the information processing device. The accuracy assurance program of the information processing apparatus, the storage program, and the computer-readable recording medium on which the information processing device is recorded are also included in the scope of the present invention.

[Additional notes]
The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the claims, and the embodiments obtained by appropriately combining the technical means disclosed in the different embodiments. Is also included in the technical scope of the present invention.

1a, 1b, 3c, 3d temperature input unit (information processing device)
2c, 2d PLC (information processing device)
4 Load cell input unit (information processing device)
5 Analog output unit (information processing device)
10a to 10f Control unit 11, 11e Measurement value acquisition unit 11f Analog value output unit 12a, 12b, 12d Environmental information acquisition unit (acquisition unit)
13 Accuracy guarantee identification unit 14 Output unit 15c, 15d Unit communication unit 20 Storage unit 100a to 100f Analog system 111 Thermocouple 112 Load cell 113 Analog device 121 Temperature sensor 122 Accelerometer 141 Display (display device)

Claims (13)

1. An accuracy guarantee specifying unit that specifies the accuracy guarantee range of the analog signal based on the analog signal handled by the analog unit and predetermined information about the analog signal.
   An information processing device including a storage unit that stores the predetermined information.
2. The information processing device according to claim 1, wherein the predetermined information includes a procedure for specifying the accuracy guarantee range.
3. The information processing device according to claim 1 or 2, wherein the predetermined information is information about a device that handles the analog signal.
4. The information processing device according to any one of claims 1 to 3, wherein the predetermined information includes environmental information of the analog unit.
5. The information processing device according to claim 4, wherein the information processing device further includes an acquisition unit for acquiring the environmental information.
6. The information processing device according to claim 4 or 5, wherein the environmental information includes the ambient temperature of the analog unit.
7. The information processing device according to any one of claims 4 to 6, wherein the environmental information includes the installation direction of the analog unit.
8. The information processing device according to any one of claims 1 to 7, further comprising an output unit that outputs the accuracy guarantee range.
9. The information processing device according to claim 8, wherein the output unit displays the level of the accuracy guarantee range on the display device.
10. The information processing device according to any one of claims 1 to 9, wherein the analog signal is an input from a thermocouple.
11. The information processing device according to any one of claims 1 to 9, wherein the analog signal is an input from a load cell.
12. An acquisition step of acquiring predetermined information about an analog signal handled by an analog unit from a storage unit, and
    A control method of an information processing apparatus including the analog signal and an accuracy guarantee specifying step for specifying an accuracy guarantee range of the analog signal based on the predetermined information.
13. The program of the information processing device for operating the computer as the information processing device according to claim 1, and the program of the information processing device for operating the computer as the accuracy guarantee specifying unit.

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