JPH0140001Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Technical Field of the Invention] The present invention relates to an electronic scale that displays a scale based on input numerical values or numerical values obtained by calculation.

[Prior art and its problems]

An electronic scale configured to display the length by inputting a numerical value representing the length is generally known from the prior art, for example, in Japanese Utility Model Application Publication No. 54-33749.

However, the conventional electronic scales described above do not have a function to shift the displayed scale, and therefore it is not possible to display a certain scale, shift this scale by a predetermined length, and then display another scale. Ta. Therefore, this has caused inconvenience when creating tables and the like.

[Purpose of invention]

The present invention was developed in view of the above points, and allows the displayed scale to be shifted arbitrarily, and then another scale can be displayed.
To provide an electronic scale that can effectively use the display range of a scale display part and is convenient for creating tables and the like.

[Example of idea]

An embodiment of the present invention will be described below with reference to the drawings. First, the external configuration will be explained with reference to FIG. In the figure, 1 is the case body, and the top surface includes a scale part 2, a numerical display part 3, a keyboard 4,
A power switch 5 is provided. The scale section 2 is provided along one side edge of the case body 1, and consists of a scale section 6 and a scale display section 7. The scale section 6 has, for example, a scale of up to 150 mm printed on it, and the minimum scale is 1 mm.
It is becoming. The scale display section 7 is constructed using, for example, a liquid crystal display element, and has a linear segment electrode arranged at the origin position and 150 segment electrodes each having a length of 1 mm parallel to the scale section 6. and arranged in a straight line. Then, the scale part 2 has "0", "50", etc. at intervals of 50 mm, for example.
Numbers "100" and "150" are attached.

The numerical display section 3 can display, for example, an 8-digit numerical value, and the index display section 3a can display 2 digits.
Digit exponents can now be displayed.

The keyboard 4 also includes numeric keys 11 and various function keys 12. The function key 12 includes, in addition to keys for specifying various calculations, a scale key (Scale) 1 for displaying the actual length on the scale display section 7, for example.
3. It is provided with a conversion key 14 for selecting and specifying the function of the double function key, a shift key 15 for shifting the origin of the scale, a pitch key 16 for setting pitch, and the like.

Next, the structure of the electronic circuit provided in the case body 1 will be explained with reference to FIG. 2. In the figure, reference numeral 20 denotes a key input section, which is constituted by the keyboard 4 described above. Then, the key input section 2
The data input from 0 is sent to the key discrimination section 21. The key discrimination section 21 discriminates the contents of the operation keys, outputs the discrimination results to the control section 22, and transfers numerical inputs to the X register 23 or Y register 24. In this case, the first digit data is set in the X register 23, and the digit data after the function key is operated is set in the Y register 24. The data held in the X register 23 or Y register 24 is input to the input terminal B of the arithmetic circuit 25 and is also sent to the display processing section 26. On the other hand, the control section 22 provides a display control signal to the display section 27 consisting of the numerical value display section 3 and the scale display section 7, and also provides a control signal and a shift command to the display processing section 26. Also,
The control section 22 provides the arithmetic operation command OP to the arithmetic circuit 25, and also provides a count-up signal and a reset signal to the counter 28. The output of the counter 28 is input as a digit designation signal to a register 29 for storing pitch data, and is also input to the arithmetic circuit 25.
It is input to input terminal A of . The arithmetic circuit 255 is
A calculation is performed on the input data according to the calculation instruction OP from the control unit 22, and the result of the calculation is sent to the register 29 as pitch data, and the result is sent to the register 29.
Write to the column specified by . Further, the calculation result of the calculation circuit 25 is sent to the X register 23 and the Y register 24. Furthermore, the arithmetic circuit 25
determines the presence or absence of data, the presence or absence of a carry signal, etc. from the calculation result, and sends the determination result J to the control unit 2.
Output to 2. Then, the data written in the register 29 is transferred to the display processing section 26 and the judgment circuit 3.
Sent to 0. The display processing unit 26 has a range of 0 to 150.
It is equipped with a bit display register 31, and writes "1" into the digit of the display register 31 corresponding to the data sent from the register 29, and also shifts the contents when a shift command is given from the control section 22. do. Further, the determination circuit 30 determines that the data read from the register 29 is
It is determined whether or not the most significant bit of the specified address is "150" or less, and the determination result is output to the control unit 22. The display processing section 26 outputs the data from the X register 23 or the Y register 24 to the numerical display section 3 via the output line 26a, and outputs the data held in the display register 31 via the output line 26b. Output to scale display section 7.

Next, in the above embodiment, the flowchart shown in FIGS. 3 and 4 shows the operation when displaying a scale of a specified pitch, then shifting this display scale by a predetermined length, and then displaying another pitch scale. The explanation will be as follows. For example, the pitch interval is
If five 10 mm scales are to be displayed, the key input unit 20 first displays □1 as shown in Figure 5 (1).
Key operations □0□×□5 are performed, and then the pitch key 16 is operated as shown in FIG. 5(2). The first numerical value "10" input from the key input section 20 is written into the X register 23 via the key discrimination section 21. The data written to this X register 23 is
It is sent to the display processing section 26 and displayed on the numerical display section 3. Next, after operating the multiplication key from the key input section 20, the input numerical value "5" is written into the Y register 24 via the key discrimination section 21. The data written in this Y register 24 is sent to the display processing section 26 and displayed on the numerical display section 3. After that, when the pitch key 16 is operated, the control unit 2
2, the processing shown in the flowchart of FIG. 3 is performed. That is, when the pitch key 16 is operated, the counter 28 is first reset as shown in step _A1 of FIG. Next, the process proceeds to step _A2 , where the count value n of the counter 28 and the number data Y of the Y register 24 are sent to the arithmetic circuit 25, and a subtraction operation determines whether "n≧Y" or "n<". A determination is made as to whether the answer is "Y". If the value n of the counter 28 is smaller than the value Y of the Y register 24, the process advances to step _A3 , where the number data X of the X register 23 and the value n of the counter 28 are sent to the arithmetic circuit 25, and the controller 22
Multiplication by "X.n" is performed by a multiplication command from . In this case, the number data X in the “0” is sent to register 29. At this time, the count value n of the counter 28
is "0", the _S0 digit is designated in the register 29, and the output "0" of the arithmetic circuit 25 is written therein.
The data written to the S ₀ digit of the register 29 above is
The signal is sent to the display processing section 26 and the judgment circuit 30. The judgment circuit 30 judges whether the output of the register 29 is "150" or less, as shown in step _A4 ,
The determination result is output to the control section 22. As mentioned above, if the output of the register 29 is "0" and is less than "150", the process proceeds to step _A5 according to the control command from the control unit 22, and the display register corresponding to the contents of the _S0 digit output from the register 29 is displayed. Write “1” to the corresponding bit of 31. In this case, the register 29
Since the content of the S ₀ digit is “0”, “1” is written to the 0th bit of the display register 31. Thereafter, as shown in step _A6 , the content "0" of the counter 28 is incremented by "+1" by the count-up signal from the control section 22, and the process returns to the judgment step _A2 . Then, the process proceeds from step _A2 to step _A3 , where the arithmetic circuit 25 multiplies "X.n", but at this point, the value of the counter n has been counted up to "1", so "X. n=10×1=10”. This multiplication result "10" is written into the S ₁ digit of the register 29 designated by the counter 28. Next, the program proceeds to step _A5 via judgment step _A4 , and writes "1" into the 10th bit of the display register 31 corresponding to the content "10" of the _1- digit S outputted from the register 29. After that, in step _A6 , the count value n of the counter 28 becomes "+1".
After that, return to step _A2 . The same process is repeated thereafter, and as shown in FIG. 5(2), the register 29 is
" ₀ ", "10", "20" in each digit of S ₀ , S 1 , S ₂ , ...
The value obtained by sequentially adding "30", "40" and the numeric data "10" is written, and the bit of the display register 31 corresponding to the data stored in the register 29 is set to "1".
is written. Then, when data up to "40" is written to register 29, the step
Proceeding to _A6 , the value n of the counter 28 is incremented to "5". As a result, the count value n of the counter 28 and the content Y of the Y register 24 become equal, and this state is determined at step _A2 and the process proceeds to display processing at step _A7 . In this display processing step _A7 , "1" written in the display register 31 is
The scale display section 7 is driven to display by the signal.
As a result, in the scale display section 7, as shown in FIG.
As shown in (2), five scales are displayed at 10mm pitch intervals from the origin position. Further, even if the value n of the counter 28 does not reach the value Y of the Y register 24, if the data written to the register 29 becomes "150" or more, the state is determined by the determination circuit 30, and step _A4 is performed. From display processing step A ₇
Then proceed to perform the display processing as described above.

Next, the scale of the predetermined pitch displayed on the scale as described above is displayed using the numerical key 11 and the shift key 15.
Shift to the desired position by operating . For example, if it is desired to display the pitch scale from the 80 mm position, input "80" using the numerical keys 11 as shown in FIG. 5(3), and then operate the shift key 15. The above numerical input data “80” is X register 2
3, and the subsequent operation of the shift key 15 executes the process shown in the flowchart of FIG. First, as shown in step _B1 , the number data "80" in the X register 23 is transferred to the Y register 24 via the arithmetic circuit 25. Then step
Proceeding to step _B2 , the contents of the display register 31 are shifted to the right by one bit, and the contents Y of the Y register 24 are set to "-1" as shown in step _B3 . Thereafter, in step _B4 , it is determined whether the contents of the Y register 24 have become "0", and if not, the process returns to step _B2 . The following steps _B2 to _B4 are repeated to shift the contents of the display register 31 to the right and to sequentially shift the contents of the Y register 24 to "-1".
do. When the contents of the display register 31 are shifted to the right by 80 bits as shown in _{FIG .} Proceed to display processing. In this display processing step _B5 , the scale display section 7 is driven to display according to the contents of the display register 31. As a result, the pitch scale shown in FIG. 5(2) is displayed on the scale display section 7, shifted to the right by 80 bits, as shown in FIG. 5(3).

In the above scale display state, if it is desired to display a pitch scale other than the origin position, pitch data is input in the same manner as in the case of FIGS. 5(1) and (2). For example, a scale with a pitch interval of 5 mm is 4
If you want to display one, □5 as shown in Figure 5 (4).
□×□4 keys are operated, and then the pitch key 16 is operated as shown in FIG. 5(5). The first numerical data "5" is written to the X register 23, and the numerical data after the multiplication key is operated is written to the Y register 24. Then, by operating the pitch key 16, the process shown in the flowchart of FIG. 3 is executed, and as shown in FIG _.
Data is written in the digit ``0'', ``5'' in _{the 1st} digit of S, ``10'' in <sub>the 2nd</sub> digit of S, and ``15'' in _{the 3rd} digit of S. Then, the display register 3 corresponding to the value of the Sn digit of the register 29 above
“1” is written to the 1 bit. In this case, the data written in the display register 31 by the previous process is retained as is. Therefore, the scale display section 7 displays the previously specified scale of 10 mm pitch and the currently specified scale of 5 mm pitch, as shown in FIG. 5(5).

FIG. 6 shows an example of shifting the scale display using line segments. First, as shown in FIG. 6(1), when data "40" indicating the length of a line segment is input using the numerical key 11, this data "40" is written into the X register 23. Next, by operating the scale key 13, a predetermined calculation is performed to set bits 0 to 40 of the display register 31 to "1", and a line segment having a length of 40 mm from the origin is displayed on the scale display section 7. In this state, as shown in Figure 6 (2),
When the numerical data "90" is input and the shift key 15 is operated, the process shown in the flowchart of FIG. 4 is executed, and the line segment currently displayed is shifted to the right by 90 mm. Next, as shown in Fig. 6 (3), when the numerical data "30" is input and the scale key 13 is operated, the scale display section 7 shows a distance of 30 mm from the origin position.
line segments are displayed.

In the above embodiment, the display data is shifted to the right, but the display data may be shifted to the left.

In addition, the shift number is not limited to inputting the shift number using a key, but may be shifted by a predetermined number (1 bit, 5 bits, 10 bits, etc.) by operating a specific key.

[Effect of idea]

As described above, according to the present invention, the displayed scale can be shifted arbitrarily, so another scale can be displayed afterwards, and the display range of the scale display section can be used effectively. . In addition, you can move only the scale without moving the main body.
This is very useful when creating tables, etc.

[Brief explanation of the drawing]

The drawings show one embodiment of the present invention; FIG. 1 is a front view showing the external configuration, FIG. 2 is a flowchart showing the configuration of the electronic circuit, and FIGS. 3 and 4 are flowcharts showing the operation contents. FIG. 5 is a diagram showing key operations, the contents of each register, and a scale display state in response to the key operations, and FIG. 6 is a diagram showing an example of key operations different from those in FIG. 5 and the scale display state in response to the key operations. 1...Case body, 2...Scale part, 3...
Numerical display section, 4...Keyboard, 5...Power switch, 6...Scale section, 7...Scale display section, 1
1...Numeric key, 12...Function key,
13...Scale key, 15...Shift key, 1
6... Pitch key, 20... Key input section, 22...
...Control unit, 23, 24, 29...Register, 26
...Display processing unit, 31...Display register.

Claims (1)

[Scope of utility model registration request] In an electronic scale that displays the length or scale of input numerical data or calculated numerical data, there is a means for displaying a scale display section according to designated numerical data, and a means for displaying a predetermined number of scales by key operation. 1. An electronic scale comprising: shift instruction means for instructing a shift; and means for shifting scale data displayed on the scale display section in accordance with an instruction from the means.