JPS6180054A - Analysis control apparatus - Google Patents

Abstract

PURPOSE:To automatically reproduce the operational procedure of an apparatus, by providing a key operational procedure memory key and a reproduction processing key and accurately reproducing operational procedure by the input of the reproduction processing key. CONSTITUTION:The key operational procedures automatic memory key 11 provided to a key operation part 10 allows memory to store key operational procedure automatically and successively and a reproduction processing key 12 automatically reads and outputs the key operational procedure once stored in the memory. A control part 20 converts the key code outputted from the key operation part 10 to an order signal to output said order signal to a processing part 40. A memory apparatus 30 successively stores the key code thereafter by pushing the key 11. The memory apparatus 30 and the control part 20 are connected to a writing data bus (a) and a reading data bus (b) while a timer 25 limits an operation time. The processing part 40 is constituted of an analysis control part 41, a data processing part 42 and an input and output processing part 43 and an analytical part 50 is connected to the analysis control part 41.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Application of the Invention] The present invention relates to an analytical device, and particularly to an analytical control device suitable for automating the operating procedures of the device.

[Background of the invention]

As a method for executing a series of device operating procedures in a conventional analyzer, an operator performs a series of key presses each time for each operator IIB. However, this method has the disadvantage of placing a very heavy burden on the operator.

Therefore, as a method to reduce the burden on the operator, a method has been considered in which a program for manipulating the internal parameters of the device is created using a programming language to realize a series of -1 operating procedures for the device. That is, as shown in Spectroscopy Research Vol. 32, No. 2, a North program for manipulating the internal parameters of the locking device was created in BASJC Hyakugo, and its source program 1fI:B
This is a method that is implemented while being interpreted and executed by an AsIc interpreter. Automation of a series of operating procedures of an analyzer using a general programming language is realized through a flow as shown in FIG. That is, ■ Create a source program by inputting alphanumeric characters from the keyboard.

■ If it is a compiled language, convert the source program into an object program and directly execute the object program.

■ If it is an interpreted language, the source program is executed before being interpreted.

This is how to achieve this.

In this method, the operator was required to perform the steps for creating a source program (learning the grammar of the programming language and creating the source program). In addition, methods using compiled languages (methods ① and ② above directly execute the object program, so there is no processing time overhead, but they require storage space for the source program and object program, and interpreter language In the methods described in (1) and (2) above, the storage capacity is sufficient for the north program, but the processing time overhead is large because the source program is executed while being interpreted.

[Purpose of the invention]

SUMMARY OF THE INVENTION An object of the present invention is to provide a complete minute-hand system capable of automatically reproducing the operating procedure of the system without any special programming by the operator, that is, without creating a north program.

[Outline of the invention]

Page 3 (The gist of the invention is as shown in the arrow. In other words, in FIG.
is 1i'/' until one song of the remaining controls is completed.
TI:).

On the other hand, Figure 11 shows Condolences! OL! By inserting the key needle memory 105 process corresponding to the input key between the key input 100 of J and the process execution 110 corresponding to the input key VC'l-j, the operator can perform the normal process. FIG. 3 is a flow diagram showing that a key code corresponding to an object program of an ia operation procedure is automatically stored only by performing a key operation. That is, according to the present invention, it is possible to automatically send a key code corresponding to an object program without performing the procedure of creating a source program.

Further, by reading out the key codes in the order in which they are written and executing the process corresponding to the key codes, it is possible to automatically reproduce the operator ++ih without overhead.

Therefore, the first invention provides an automatic key operation procedure memorization key and a reproduction processing key, stores the operator's operator no in a storage device, and inputs the reproduction processing key to accurately perform the operation +at of the operator. By appearing in the day υ
, it is possible to reproduce the operating procedure of the device without creating a source program.

The invention of the present invention, including the operator's operation procedure and time, is as it is in Eki 1. However, the idea is to reproduce the operator's operations at a fair price with a little time.

The invention of No. 3 of the present application is to memorize the operating procedures of the operator, separate operations that require time from operations that do not require time, and accurately reproduce the reproduction of the equipment including the necessary time. be.

[Embodiments of the invention]

Examples of Akira Honkabuto will be described below.

FIG. 1 shows a block diagram showing the functional configuration of the present invention.

In the figure, in addition to the keys shown in the general operation code input diagram, the key operation unit 1O includes a key operation procedure automatic memory key 11,
A reproduction processing key 12 is provided. This key operator 1
10 The automatic storage key 11 is used to automatically and sequentially store key operation procedures in the memory. Also, the reproduction processing key 12 automatically stores the key operator song once stored in the memoryb? , for output.

The output from this key operation unit IO is output to the control unit 20. The control section 20 converts the key code output from the key operation section 1O into a command signal and outputs it to the processing section 40. Further, a storage device 30 is connected to this ii++J supra 20. This storage device 30 sequentially stores key codes after pressing the key operation procedure automatic storage key 11 of the key operation unit 10. The storage device 30 and the control unit 20 are a write data file 9.
The read data bus a and the read data bus b are connected to each other.

Further, a timer 25 is connected to the control section 20. This timer regulates the operation time from one key code to the next key code.

Further, a processing section 40 is connected to the control section 20 . This processing section 40 includes an analysis control section 41, a data processing section 42, and an input/output processing section 43. An analysis section 50 is connected to this analysis control section 41 .

FIG. 2 shows an embodiment of the first invention of the present application.

In the figure, the start of the automatic storage process of key operations is performed by inputting the key operator 11 in the control operation section 10 shown in FIG. As shown in FIG. 2, by inputting the key operator 11, the increment 120 of the pointer (61 shown in FIG. 8) in the memory scale 130 is performed.

This pointer 61 is set to the previous day in the key operator 1 storage table in the storage device 30, and the input from the control unit 20 to the storage/device 30 in FIG. 1, V; a, is selected. . 1. Next, in step 130, when the key input is waited for, the key code 1g is sent from the key operation unit 0 to the control unit 20, and the key code 1g is sent to the control unit 20 in step 14.
0, the key code is stored and step 1
At 50, a pointer update is performed. That is, the key code k received from the first illustrated key operation section 10
'The NIJ supra 20 stores the pointer in the storage device 30 via the input ff=Wa, and stores the pointer. Next, in step 145, it is determined whether or not the key that has been completely input is the key operation procedure automatic memory key 11.
-11 runs.

In other words, the fold where key operator 1 + ji memory has started is
The key operation procedure storage key 11 functions as an end key for storing key operation procedures. If the input key is the exit key, automatic storage of key operations is terminated and the normal key operation mode is entered. If the key code is not an end key, the process corresponding to the key code is executed in step 160. That is, the control unit 2 (1″ shown in FIG. 1), the processing unit 40 (analysis control unit 41 that controls the analysis unit 50) corresponding to the key code,
(consisting of a data processing unit 42 and an input/output processing unit 43). In step 165, the control unit 20 enters a waiting state until the next key input becomes available for reception, and when the next key input becomes available, the control unit 20 returns to step 130 and enters the key input waiting state again. As a result of the above-described automatic storage of key operations, the key operation procedure storage table 60 in the format shown in FIG. . . . This is a table stored in key code n-1°, key code n, and end key code. A right arrow 62 in FIG. 8 indicates the direction in which the pointer 61 is updated.

Next, the 4i+ current processing of the stored series of key operations will be explained using FIG. Execution of the reproduction process is started by the input of +1+cedar male processing unit 12 of the control unit 10 shown in FIG. 1, and is carried out according to the flowchart shown in FIG. 30. When the reproduction processing key 12 is pressed, step 12
0', note 1, pointer 61 in α equipment ff130
An initial set is performed, and the voice/receiver 61 is stored in the original memory table 60 of the key operator 1 in the storage device 30 as shown in FIG.
The beginning of is Hesenoto.

When set at the beginning, the readout line from the storage device 30 shown in FIG. 1 to the control section 20 is selected, and the manual input of keys to the key operation section 10 is interrupted until the reproduction process is completed. Next, in step 125, the key code is read, and in step 150, the pointer is updated. That is, the control unit 20 shown in FIG. 1 reads the key code from the key operation procedure storage table 60 in the storage device 30 via the readout line and updates the pointer. Next, in step 155, the control unit 20 determines whether the key code is an end key code. This step 155
If it is the end key code, the reproduction process is ended, the key operation unit 10 is enabled to receive human input, and the normal key operation mode is set. Further, in step 155, if it is the end key code, the reproduction process is ended, the key operation unit 10 is enabled to accept manual input of keys, and the normal key operation mode is set. Further, if it is determined in step 155 that the key code is not the end key code, the process corresponding to the key code is executed in step 160. That is, the control unit 201-1, the processing unit 4 corresponding to the key code
Execute the process within 0.

Then, in step 165, the control unit 20 enters a waiting state until the next key input is ready for reception, that is, the next key code is ready for processing. Then, in step 165, if it is determined that the next key code can be processed, the process returns to step 125 and repeats the next key operation reproduction process. In the process of reproducing the above key operation procedure, the pointer 6 shown in FIG.
1 indicates the right arrow 6 for the key operation procedure storage table 60.
The key code in the key operation procedure storage table 60 is updated in the direction of 0, and the key code in the key operation procedure storage table 60 is the key code 1. Key code 2. ...
..., key code n-1, key code n.

'Fvl' is output to the end key code j song, and the above key operation reproduction processing is executed one after another.

Next, the operation when the R1 embodiment is applied to the spectrophotometric intensity ΔF will be explained with reference to FIG. 9. That is, the operator presses the key operator Il! When the automatic ♂ self presses key 2 and performs key manual operation, in step 200, key! Starts automatic memorization of the operating procedure. Next, in step 210, the operator inputs the operator C@ of the device. This a! In Figure 9, in order to set the AbS mode,
Input the Abs mode key. Next, in step 220, in order to set the AbS range to -0, 3 to 07, first manually press the Abs range key to enter the Al)S input mode, and press the key in the key manipulation section 10 to ! 2]
Enter m1(3), press the EN'l'E key, and press the key on the key operation unit 10 to press L! l! l11. Enter j leap and set the key to ENT'E. Next, in step 230, the slow key is input to set the wavelength scanning speed to slow. Next, in step 240, in order to set the wavelength range from 400 to 700, input the WL range key to set the wavelength mounting mode, and press the key on the key operation unit 10 to manually set the wavelength range (9). Then press the ENTER key to set υ, and press the key operation section 10.
Press the key to input (7) Cut, and press the ENTER key to set. Next, in step 250, the 5CAN key is input to start wavelength scanning. Like this-
I am using the slow operation procedure in the same way as normal key operation to operate the device. Soshi-C1 Step 2
At step 60, the key operator j is again inputted with the erroneous automatic memory key, thereby ending the automatic recognition of the key operation procedure.

On the other hand, the reproduction of the old key operator j in FIG.
executed.

From the above, according to the present implementation 1fl+, the operator can memorize a series of device operating procedures by simply operating the device's keys, and while operating the device, it is possible to create a north program. You can save steps. Furthermore, automatic reproduction of the maintenance hand 110 of a slow device can be performed without overhead for reproduction processing.

FIG. 4 shows an embodiment of the second invention of the present application. In contrast to the embodiment of the first invention shown in FIG. 2 which stores only the key code, this embodiment stores the key code and the time from the previous manual key press to the current key manual press. By doing so, key operation procedures and keystroke intervals can be faithfully reproduced. The process of automatically storing key operations in this embodiment will be explained with reference to FIG.

In the figure, the start of automatic memory processing of key operations is performed by key operator 11 automatic memory key 1 in key border section 10 shown in Figure 1.
This is done by inputting 1. First, in step 120, the pointer 61 in the storage device 30 is initialized, and the pointer 611d is set to the beginning of the key operation procedure storage table in the storage device 30, and is transferred from the control 20 shown in FIG. 1 to the storage device 30. 4iia can be selected.

Next, in step 130, 0 waits for key human power.
In step 130, if it is determined that the key has been manually activated, a key code is transmitted from the key operation unit IO to the control unit 20. Step 1: Check whether the key input of this transmission key code is the first time the key operation automatic storage process has started.
The judgment is made at 35. In this step 135,
If it is determined that the key input is not the first, the time from the previous key input to the current key input is stored in step 170, and the pointer is updated in step 150. That is, the control 20 calculates the time from the previous manual key press to the current key manual press using the timer 25 shown in FIG. and update the pointer. If it is determined in step 135 that the key input is the first, the process moves to step 140 without storing the above-mentioned time. Next, in step 140, the key code is stored, and in step 150, the pointer is updated. That is, the control unit 20 records the received key code via the aging line a? :5 device 3
0 in the key operation procedure storage table and update the pointer. Next, in step 145, it is determined whether the input key is the key operation procedure automatic memory key 11, which serves as the end key for automatically storing the key operation procedure. If it is determined in this step 145 that it is the end key, the automatic memory of the key operation is ended and the normal key operation mode is entered.
If it is determined in step 145 that the key code is not an end key, the process corresponding to the key code is executed in step 160. That is, the output section 20 executes the processing within the processing section 40 (consisting of an analysis control section 41 that controls the analysis section 50, a data processing section 42, and an input/output processing section 43) corresponding to the key code. Next, in step 165, the 1ttll 8 unit 20 waits until the next key input is available, and if it is determined in step 165 that the key input can be accepted, the process returns to step 130 and waits for the next key input. become a state.

Figure 8 [F])
A key operation procedure storage table 70 in the format shown in is created. This key operation procedure storage table 70 stores the key code corresponding to the input key and the time interval (time i is from the time when the first key is manually pressed!).
The time until the 1st key is manually operated) is the input order (key code 1. time 1. key code Zl time Zl...
..., key code n-1, time n-1, key code n, time n, end key code). A right arrow 62 in FIG. 8 indicates the direction of update of the pointer 61. On the other hand, the process of reproducing the stored series of key operations will be explained using FIG. Execution of the reproduction process is performed using the key operation unit 10! )
The process is started by inputting the current process key 120 and is carried out according to the flowchart shown in FIG.

First, when the reproduction processing key 12 is pressed, step 120
At ', the pointer 61 in the storage device 30 is initialized, and the voice/removal 61 is set to the beginning of the key operation procedure storage table 70 in the storage device 30 shown in FIG. Part 20
ωC extrusion is selected, and the key (1-key) is pressed manually until the end of the reproduction process.Next, in step 125, the key code ωC is extracted. is performed, and in step 150 the history of the pointer [[
is called bamboo. That is, in FIG. 1, the key code is read out from the key operator memory unit 70 in the control unit 30 via the readout line, and the pointer 61 is updated. Next, in step 155, the 1til control unit 20 determines whether the key code is an end key code. If it is determined in this step 155 that the key code is the end key code, the reproduction process is terminated, the key operation section 10 is enabled to accept manual key input, and the normal key 9! Set to work mode.

Further, if it is determined in step 155 that the key code is not the end key code, the process proceeds to step 160 and executes the process corresponding to the key code. That is, the '+Ir1l phloem 20 executes processing within the processing unit 40 corresponding to the key code. Slightly, step 180Vc
At step 150, only a time extension is performed, and a pointer update is performed at step 150. That is, the control unit 20 stores the key operation procedure storage table 7 in the storage device 30.
The time, which is the key manual time interval, is read from 0 via the read line and the pointer is updated. Next, in step 185, the control unit 20 calculates the elapsed time from the time when the key code is read from the timer 25, and enters a waiting state until the elapsed time exceeds the time, and in step 18
If it is determined in step 5 that the time has been exceeded, step 125
Then, the next key operation is reproduced again. In the above key operation procedure reproduction process, the pointer 61 shown in FIG. is key code 1. Time 1. Medium-Code 2. Time 2I...

Key code n-1, time n-1, #-: 7-do n.

The time n and end key code are read out in this order, and the above key operation reproduction process is sequentially executed.

Next, the effect of applying this embodiment to a spectrophotometer will be explained. For example, as shown in Fig. 9, the 9-hand 11 of the 9th sail 11 @ i of the entire book implementation sequence (the combination performed by Implementation of the invention in 1. Reproduction processing is performed in the same manner as in ``ri''.
In the 10th embodiment of the invention, reproduction is impossible, but in the 2nd embodiment of the present invention, it is possible to reproduce.

From the above, according to this embodiment, the present application 743
In addition to the effect of the embodiment of invention 1, including the 113 key works (time scan, etc.) that require t, 1 or open control, the CI creator of the device has the power and It will be done.

Figure 10 shows an embodiment 13 of the invention of Part 3 of the present application. , 144 Figure 1 Illustrated implementation “Suha, time 111
For key operations that do not require the use of one's legs, we memorize the time required for the key manually and perform S-handling. ] Separately, “y
[lit] Z-j to the 2nd key of the system, 1:
1.21: Adopt the same method as in the example shown in 'Jji'1, and apply the same method as in the example shown in FIG. , automatic storage and reproduction of key operation procedures is performed.

The process of automatically storing key operations in this embodiment will be explained using FIG. 6. In the figure, the start of the automatic storage process of key operations is carried out in the same manner as in FIGS. Re,
At step 7'130, the key is placed in a waiting state for human power. Next, when a key is pressed manually, a key is sent from the key operation unit 10 to the control unit 20, and in step 135 it is determined that the key is pressed for the first time since the automatic key operation storage process has started. If it is determined in step 135 that the key is not manually operated, it is determined in step 190 whether the key requires time control (goods), and if it is determined in step 190 that the key requires time control, step 170 In step 150, the time from the previous key input to the current key input is stored, and in step 150, the pointer is updated in the same manner as in the operation shown in FIG. Also, if it is determined in step 135 that the first key is manually operated, or if it is determined in step x9oVc that time key 1j-〇 is an unnecessary key,
At step 1700, IHI is not stored. next,
Similar to the fourth illustrated embodiment, key codes are stored in step 140, and pointers are updated in step 152.

Next, in step 145, the end key is determined, in step 160, the process corresponding to the key code is executed, and in step 165, the reception of the next key manually is executed waiting for a possible state, and the state is again in the key human power waiting state. .

Through the automatic storage process of the key operations described above, the key operator 11U storage table 80 in the format shown in FIG. 8 (Q) is created.
i-1, if the input key is a key that requires a time system (goods), enter the key code and time (for time summer, 'Tir
This is the time from the 1,000-th manual power operation to the 1+11 U-th key manual power operation), and if the key does not require time control, then only the 1,000-code is input and stored in the table. The right arrow 62 in the diagram of the beam 8 indicates the direction in which the pointer 61 is updated.

On the other hand, the process of reproducing the series of key operations described above will be explained using the seventh factor. The execution of the reproduction process is carried out in the same manner as in the embodiment shown in FIG. 2 and the embodiment shown in FIG. The key code is read out in step 125, and step 150
The pointer is updated at . Next step 1
At step 55, it is determined whether the key code is the end key code, and if it is determined that it is the end key code, the process corresponding to the key code is executed at step 160. Processing is performed in the same manner as in Step 190, and it is determined whether the key code extracted from Me is a key code that requires time control. Time in this step 190? If it is determined that the 1iIJ control is required, the ml protrusion value of the time is updated (step 152) in the same way as in the embodiment shown in FIG. Wait until the elapsed time exceeds the time. Further, if it is determined in step 190 that the kill code does not require time control, then in step 165 the next key input is determined to be within the range, that is, processing for the next key code is possible, similar to the embodiment shown in FIG. It will be in a waiting state until . Next, return to step 125 and repeat the key operation again. Execute. Above key 1
In the process of reproducing the cover maker 1M, the pointer 61 shown in Figure 88 (0 is the key role maker' + il If the key food ejected from the table 80 requires time control, the time will be read out next, and if control is not required, the key code input next will be read out. 'T is extracted, and the reproduction process of the upstream key erosion is performed one after another.

Next, we will explain the effects of this embodiment in the case where this embodiment is fully applied to the spectral lights j1 and Δ1. Since time control is not required for each key operation in the tree top 9 diagram, the state of the key operation procedure storage table and the reproduction process are the same as in the case where the embodiment shown in the tree tree 2 diagram is applied. However, when trying to automate a series of key operation procedures that require time control such as time scanning, it is impossible to do so using the method shown in Figure 4. Although it is possible in the embodiment, the time interval U of key human power is memorized even for unnecessary key a! operation of time ' + (i control), and in your case, the unnecessary key human power time waiting is reproduced. If this example is applied,
Key h that requires time control! Since the time interval of the key human power is stored only in the work, there is no need to wait for an unnecessary time at the time of Pj.

From the above, according to the actual flow value 1j, in addition to the effect of the implementation shown in Figure 2, is the storage efficiency of the device? +
This has the effect of improving current time efficiency.

〔Effect of the invention〕

According to the present invention, an operator creates a source program; 1. The device's ry・1゛"hand j:
γ1's own memory (for object program generation) can be created, and Kakura Hi can also predict C's tJl, /c (y1's 110's own Hli+) without overhead. Therefore, 1) a procedure for creating a source program (programmatically, learning i and t, and creating a north progera l) is required.

2) Compared to the method using only one conopile, the processing time is 5 times longer, and the storage space of the source program can be reduced.

3) In the interpreter Utg, 1: Comparison with O method ゛1.,
1. HATANI:・i is the same issue, and when processing 1riJ, there is no need to run the interpreter k 41jl and the source 70 grano・beg h'l'0<, so there is no need to run it. Early l;l,.

Such as 1 no 1 F 2 is tor◎ 91 surrounding III'1 fi F, situation 2゛151 figure is Mizuka Akari; Kono drop lG11 l~J
0-)l,,,ability1.1. Figure 2, Figure 3 shows the main body of the song, the first part of the song, and the loss of the invention 70
-M, Fig. 4, L) Fig. 5, Fig. 70-g showing an embodiment of the invention of the present flute 2, Fig. 7-1, a flow diagram showing an embodiment of the third invention of the present invention, FIG. 8 shows the implementation of the present invention] 1 to 3
Figure 9 shows the flowchart showing the opening for opening the sheathing array of the present invention. Memory key, 12...
・Reproduction processing key, 20...ft1ll rise, 25...
・Timer, 30...Memory device, 40...Processing unit,
41... Analysis control unit, 42... Data processing unit, 43
. . . input/output processing unit, 50 . . . analysis unit, 60 .
61...Pointer, 62...Right arrow, 70...Key operator in implementation 902; PoI memory table, 80
...≠Key operation procedure storage table in MM example 3,
a...1 input gland, b...readout line.

Claims (1)

[Claims] 1. An analysis section that analyzes a sample and converts its physical and chemical characteristics into electrical signals, a processing section that performs data processing, input/output processing, and control of the analysis section, and a key operation section. In an analyzer comprising a control unit that receives a key code corresponding to an input key and controls execution of a process assigned to the key code, and a key operation unit having keys assigned with unique functions, A first step of sequentially storing the key codes in a storage device while executing the process corresponding to the key operated by the operator; and reading the key codes from the storage device in the order in which they were stored, and executing the process corresponding to the key code. An analysis control device characterized in that it is capable of reproducing a series of key operations performed by an operator by having a second step to be executed. 2. In the analyzer according to claim 1, in the first step, the storage device sequentially stores the key code operated by the operator as well as the time interval for each subsequent key operation, and in the second step, reads the key codes and time intervals from the storage device in the order in which they were stored, executes the process corresponding to the key code, and also controls the time interval between key operations. An analytical control device that is characterized by being able to reproduce exactly the same results. 3. In the analysis device according to claim 2,
In the first step described above, the time interval for each subsequent key operation is stored only for keys specified in advance, and in the second storage step, the key code and the time interval or only the key code are read out from the storage device in the order in which they were stored, and the key Execute the process corresponding to the code, and if the time interval is stored, control the time interval of key operations; if the time interval is not stored, execute the process corresponding to the next key code in sequence, An analysis control device that is capable of optimizing and reproducing only keys specified in advance in a series of key operations performed by an operator, including control of key operation time intervals.