JPH0787516B2 - Magnification setting device - Google Patents

Description

The present invention relates to a main scanning magnification for enlarging or reducing an image in the main scanning direction and a sub-scanning magnification for enlarging or reducing an image in the sub-scanning direction. The present invention relates to a magnification setting device that can be set independently.

[Conventional technology]

FIG. 6A is a block diagram showing the configuration of the image reading device.

In this figure, reference numeral 61 denotes a photoelectric conversion element composed of, for example, a CCD, which converts the reflected light of the document into an electric signal. An amplifier (AMP) 62 amplifies the output of the photoelectric conversion element 61. 63 is A
The / D converter converts the output of the amplifier 62 into a digital signal. A scaling memory unit 64 stores the A / D converted digital image signal. A gamma correction circuit 65 converts the density of the digital image signal stored in the scaling memory unit 64. Reference numeral 66 denotes a CPU, which varies the read address clock of the digital image signal stored in the scaling memory unit 64 to arbitrarily set the scaling factor in the main scanning direction.

FIG. 6B is a sectional view of the image reading device.

In this figure, 67 is an optical scanning unit, which is composed of a lamp 67a for exposing a document, a light converging lens 67b for focusing reflected light on a photoelectric conversion element 61, a control board 67c, and the like. 68
Is a motor that causes the optical scanning unit 67 to scan in the arrow direction A at an arbitrary speed.

First, the optical information of the document is converted into an electric signal by the photoelectric conversion element 61 to generate an image electric signal. Image electrical signal amplifier
Amplified at 62. The A / D converter 63 converts the amplified analog electric signal into a digital electric signal and generates a digital image signal. The digital image signal is
The data is written to the scaling memory unit 64, and the CPU 66 sets the scaling memory unit 64.
Read address for reading digital image signals from
By variably setting the clock, a digital image signal according to the set magnification in the main scanning direction can be obtained.
The digital image signal changed to an arbitrary magnification is input to the gamma correction circuit 65 in the subsequent stage, converted into a digital image signal linear to the density, and the digital image density signal is output to a printer unit (not shown).

On the other hand, with respect to the magnification in the sub-scanning direction, the speed of the motor 68 shown in FIG. 6B is arbitrarily set to control the moving speed (scanning speed) of the optical scanning unit 67 in the arrow direction A. Therefore, the photoelectric conversion element 61 outputs the digital image signal converted to the set magnification in the sub-scanning direction.

Therefore, it is possible to read an image according to the magnification in the main scanning direction, the magnification, and the magnification in the sub scanning direction.

[Problems to be solved by the invention]

By the way, when setting an arbitrary magnification in the main scanning direction and the sub-scanning direction as described above, for example, Japanese Patent Laid-Open No. 60-114082
As described in the publication, the operator alternately sets an arbitrary numerical value (numerical value) while referring to each variable magnification setting key provided for each scanning direction provided in the operation section and one magnification display.
Was.

Further, although the magnifications in both the main scanning direction and the sub-scanning direction can be set together, a preset changing operation for slightly increasing or decreasing the respective magnifications in both the main scanning direction and the sub-scanning direction together. Could not be done.

Therefore, in order to carry out the above-described change operation, the desired magnification cannot be set unless the key operation using the magnification setting key in the main scanning direction and the magnification setting key in the sub-scanning direction is repeated. There was a problem in operation.

The present invention has been made in order to solve the above problems, and an object of the present invention is to provide a magnification setting device capable of giving a magnification change instruction with good operability.

[Means for solving problems]

A magnification setting device according to the present invention is a magnification setting device that sets a main scanning magnification for enlarging or reducing an image in a main scanning direction and a sub-scanning magnification for enlarging or reducing an image in the sub-scanning direction. First instructing means for instructing to change the magnification, second instructing means for instructing to change the sub-scanning magnification, and third instructing means for instructing to change both the main-scanning magnification and the sub-scanning magnification The main scanning magnification is increased / decreased according to the change instruction by the first instruction means, the sub-scan magnification is increased / decreased according to the change instruction by the second instruction means, and the main scanning magnification and the main scan magnification are increased according to the change instruction by the third instruction means. A main scanning magnification and a sub-scanning magnification different from each other when there is a change instruction from the third instruction means. In this case, after the main scanning magnification and the sub-scanning magnification are matched, the main scanning magnification and the sub-scanning magnification are increased / decreased together in the same step width according to the change instruction by the third instructing means. When the sub-scanning magnification is different, the ratio between the main-scanning magnification and the sub-scanning magnification is calculated, and the calculated ratio of the main-scanning magnification and the sub-scanning magnification is maintained according to the change instruction by the third instructing means. It increases or decreases together with different step widths.

〔Example〕

FIG. 1 (a) is an operation panel main body view of an image reading apparatus to which a magnification setting device according to an embodiment of the present invention is applied, and 1 shows the operation panel main body. Reference numeral 2 denotes a magnification change instruction operation unit, which has a display unit for each magnification and a change instruction unit. That is,
The display section includes a sub-scanning magnification display section 2a, a sub-scanning direction display section 2b, a main-scanning magnification display section 2d, a main-scanning direction display section 2e, and an area display section 2f. The unit is composed of a magnification change instruction unit 2c. Reference numeral 3 denotes a zoom designation key, which selects the same-size copying and variable-magnification transfer. Reference numeral 4 denotes an enlargement / fixed magnification change designation key, which allows selection of several types (three types in FIG. 1) of enlargement / reduction of a predetermined magnification. Reference numeral 5 designates fixed reduction scaling, which allows selection of several types (three types in FIG. 1) of reduced scaling having a predetermined magnification. Reference numeral 6 is a numeral key (numerical key), and 7 is a copy start key for designating the start of the copying operation. Reference numeral 8 is a message display section for displaying the number of characters, troubles, copying status, operation method and the like.

FIG. 1 (b) is a magnification change instruction unit shown in FIG. 1 (a).
In the enlarged view of 2c, reference numeral 11 denotes a main scanning direction reduction key which serves as a main scanning direction magnification changing unit of the present invention, and gives an instruction to reduce or change the magnification displayed on the main scanning magnification display unit 2d. A main-scanning-direction enlargement key 12 serves as a main-scanning-direction magnification changing unit of the present invention, and gives an instruction to enlarge or change the magnification displayed on the main-scanning magnification display unit 2d.
Reference numeral 13 denotes a sub-scanning direction reduction key which serves as a sub-scanning direction magnification changing unit of the present invention, and gives an instruction to reduce or change the magnification displayed on the sub-scanning magnification display unit 2a. Reference numeral 14 denotes a sub-scanning direction enlargement key which serves as a sub-scanning direction magnification changing unit of the present invention, and gives an instruction to enlarge or change the magnification displayed on the sub-scanning magnification display unit 2a. Reference numeral 15 denotes a zoom reduction key which serves as a main / sub-magnification changing unit of the present invention, and gives an instruction to reduce or change the magnification displayed on the main-scanning magnification display unit 2d and the sub-scanning magnification display unit 2a. Reference numeral 16 denotes a zoom enlargement key which serves as a main / sub-magnification changing unit of the present invention, and gives an instruction to enlarge / change the magnification displayed on the main-scanning magnification display unit 2d and the sub-scanning magnification display unit 2a. It should be noted that the main scanning direction reduction key 11 and the main scanning direction enlargement key 12 constitute a first indicating means, the sub scanning direction reduction key 13 and the sub scanning direction enlargement key 14 constitute a second indicating means, and the zoom reduction key 15 is provided. The zoom magnifying key 16 constitutes a third instructing means, and the CPU section 21 which executes the function as the magnification changing means according to the magnification changing instruction by the main scanning direction reduction key 11 and the main scanning direction enlargement key 12 increases or decreases the main scanning magnification. The sub-scanning direction reduction key 13 and the sub-scanning direction enlargement key 14 are used to increase or decrease the sub-scanning magnification in accordance with the magnification change instruction, and the zoom reduction key 15,
The main-scanning magnification and the sub-scanning magnification are increased / decreased together according to the magnification change instruction from the zoom magnification key 16. At that time, CPU part 2
1 indicates a case where the main scanning magnification and the sub-scanning magnification are different when there is a change instruction by the zoom reduction key 15 and the zoom enlargement key 16 according to the procedure of the flowchart shown in FIGS. 4 (c) and (d) described later. , After matching the main scanning magnification and the sub-scanning magnification (step (3) in FIGS. 4 (c) and 4 (d)), the main scanning magnification and the sub-scanning are performed in accordance with the change instruction by the zoom reduction key 15 and the zoom enlargement key 16. Increase / decrease the magnification together with the same step width (step (8) in FIGS. 4 (c) and 4 (d))
Or zoom reduction key 15, zoom enlargement key 16
If the main scanning magnification and the sub-scanning magnification are different from each other when there is a change instruction by, the ratio between the main scanning magnification and the sub-scanning magnification is calculated (step (8) in FIGS. 5B and 5C). , The main scanning magnification and the sub-scanning magnification are calculated in accordance with the change instruction by the zoom reduction key 15 and the zoom enlargement key 16, and the ratios are increased or decreased together with different step widths.

Next, the operation of FIG. 1A will be described with reference to FIG.

After the power switch (not shown) is turned on, the main scanning magnification display portion 2d and the sub-scanning magnification display portion 2a show the same magnification, that is, 100%.

In this state, when the main scanning direction reduction key 11 is pressed and turned “ON”, it is determined whether the main scanning magnification displayed on the main scanning magnification display portion 2d is 50% or less which is the lower limit value of the reduction magnification. The main scanning magnification display section 2d displays 1% at a rate of 50% or more, and the main scanning direction reduction key 11 displays "OF".
"F" or count down until the lower limit of 50% is reached.

Further, when the main scanning direction enlargement key 12 is pressed and turned “ON”, it is determined by the CPU unit 21 to be described later whether the main scanning magnification is 200% or more, which is the upper limit value of the enlargement ratio. The display of the main scanning magnification display portion 2d is incremented by 1% until the main scanning direction enlargement key 12 is turned "OFF" or the enlargement magnification upper limit value of 200% is reached.

On the other hand, when the sub-scanning direction reduction key 13 is pressed and turned “ON”, it is determined by the CPU unit 21 to be described later whether the sub-scanning magnification is 50% or less, which is the lower limit value of the reduction magnification. The display on the sub-scanning magnification display portion 2a is counted down by 1% until the sub-scanning direction reduction key 13 is turned "OFF" or the lower limit of the reduction magnification reaches 50%.

When the sub-scanning direction enlargement key 14 is pressed and turned “ON”, it is determined by the CPU unit 21 described later whether the sub-scanning magnification is 200% or more, which is the upper limit of the enlargement magnification, and 200%
Hereinafter, the display of the sub-scanning magnification display portion 2a is counted down by 1% until the enlargement key 14 in the sub-scanning direction is turned "OFF" or the upper limit of the enlargement magnification reaches 200%.

Next, the functions of the zoom reduction key 15 and the zoom enlargement key 16 for changing the magnification in the main scanning direction and the magnification in the sub scanning direction at the same magnification will be described.

After the power switch (not shown) is inserted, the main scanning magnification display section 2d and the sub-scanning magnification display section 2a display the same magnification, that is, 100%, but the main scanning magnification display section 2d and the sub-scanning magnification display section are displayed by the above operation. The zoom reduction display and zoom enlargement display operations in a state where the main scanning magnification is 70% and the sub-scanning magnification is 120% when 2a respectively display different magnifications will be described.

At this point, if the zoom reduction key 15 is pressed and turned “ON”, the CPU unit 21 described later compares the displayed main scanning magnification with the sub-scanning magnification and determines that the two display magnifications are different. , Whichever is smaller. That is, the main scanning magnification and the sub scanning magnification are made equal. Therefore, 70% is displayed on the main scanning magnification display section 2d and the sub-scanning magnification display section 2a. Next, if the displayed zoom magnification is not less than the lower limit of 50% for the reduction magnification, the main scanning magnification display section
The display of 2d and the sub-scanning magnification display portion 2a is in the display state, that is,
Whether the zoom reduction key 15 is "OFF" from 70% to 1%
Alternatively, the countdown is performed until the lower limit of the reduction ratio, 50%, is reached.

Also, at this point, the zoom magnification key 16 is pressed to
In the case of `` N '', the CPU unit 21 described later compares the displayed main scanning magnification and the sub-scanning magnification and determines that both display magnifications are different, and sets the larger display magnification. To do. That is, the main scanning magnification and the sub scanning magnification are made equal. Therefore, 120% is displayed on the main scanning magnification display portion 2d and the sub-scanning magnification display portion 2a. Next, if the displayed zoom magnification is not more than 200%, which is the upper limit of the enlargement magnification, the display of the main scanning magnification display unit 2d and the sub-scanning magnification display unit 2a is in the display state, that is, from 120% to 1%. The zoom magnification key 16 is turned "OFF" or the count is incremented until the magnification reaches the upper limit value of 200%. In this way, after the image reading magnification in the main scanning direction and the image reading magnification in the sub-scanning direction are matched, the image reading magnifications in the main and sub-scanning directions can be collectively changed.

On the other hand, after the power switch (not shown) is turned on, the main scanning magnification display portion 2d and the sub-scanning magnification display portion 2a display the same magnification, that is, 100%, the zoom designation key 3, the enlargement / fixed magnification designation key 4 When the main scanning magnification and the sub-scanning magnification displayed on the main-scanning magnification display section 2d and the sub-scanning magnification display section 2a are equal to each other with the reduction-fixed variable-magnification designation key 5 or the like, the zoom reduction key 15 is pressed to turn "ON". In this case, if the CPU section 21 compares the main scanning magnification and the sub-scanning magnification and determines that both display magnifications are equal, the zoom magnification is not less than 50%, which is the lower limit of the reduction magnification,
Main scanning magnification display section 2d and sub-scanning magnification display section 2a display 1%
The zoom reduction key 15 turns off, or
Count down until the lower limit of 50% is reached.

Also, at this point, the zoom magnification key 16 is pressed to
In the case of “N”, the CPU unit 21 compares the main scanning magnification and the sub-scanning magnification and determines that both display magnifications are equal, and if the zoom magnification is not more than 200% which is the upper limit value of the enlargement magnification, the main scanning magnification The display on the display unit 2d and the sub-scanning magnification display unit 2a is counted up by 1% until the zoom magnification key 16 is turned "OFF" or the upper limit of the magnification ratio reaches 200%.

FIG. 2 is a block diagram illustrating the control configuration of the operation unit shown in FIG. Reference numeral 21 denotes a CPU section which also serves as the control means of the present invention. The operation section is displayed and the image is read in FIGS. 3 (e), (f), 4 (a)-(d), 5 (b), Control is performed based on the flowchart shown in (c). Reference numeral 22 is a key matrix, which corresponds to each key of the magnification change instruction section 2c shown in FIG. An LED matrix 23 corresponds to the main scanning magnification display section 2d and the sub-scanning magnification display section 2a shown in FIG. 1 (a). 24 is an I / O port,
CP of key data of key matrix 22 via bus line
While being transferred to the U unit 21, the display data processed by the CPU unit 21 is output to the LED matrix 23. Reference numeral 64 denotes a variable magnification memory unit, which stores the main scanning magnification. A motor driver 25 controls the speed of the motor 68 which is determined by the sub-scanning scaling ratio. The above 21 to 25,64 are connected by a bus line, and C
It is controlled by the software of the PU unit 21. 26 is a bus line.

FIG. 3A is a circuit configuration diagram of the key matrix 22 shown in FIG. 2, and the same elements as those in FIG. 2 are designated by the same reference numerals.

FIG. 3B shows a driver circuit of the LED matrix 23 shown in FIG. 2, and the same parts as those in FIG. 2 are designated by the same reference numerals.

In this figure, 31 is a decoder and 32 is a driver.

Next, the operation of FIGS. 3 (a) and 3 (b) will be described with reference to FIGS. 3 (c) and 3 (d).

FIG. 3 (c) shows the A port 2 of the I / O port 24 shown in FIG.
9 is a timing chart for explaining output timing of signals output from 8. The output timing of the A port 28 is output using an internal interrupt using the internal timer of the CPU section 21. In this figure, Digit 0 to 7 are scanning signals, which are output from the CPU section 21 at predetermined time intervals. FIG. 3D is a schematic diagram for explaining the data structure of the RAM in the CPU section 21 shown in FIG. In this figure, DG0 to DG7 are data storage areas in which display data calculated by the CPU unit 21 are stored. The data stored in the RAM and the display data of the main scanning magnification display unit 2d and the sub-scanning magnification display unit 2a have a one-to-one correspondence, and the hundreds of display data of the main scanning magnification display unit 2d is data. In the storage area DG0, the display data of the tenth place corresponds to the data storage area DG1, the display data of the same place corresponds to the data storage area DG2, and the display data of the hundredth place of the sub-scanning magnification display portion 2a stores the data. In the area DG3, the display data of the tens digit corresponds to the data storage area DG4, and the display data of the same digit corresponds to the data storage area DG5.

First, the scanning signals Digit 0 to 2 are sequentially input to each line of the key matrix 22 from the A port 28 shown in FIG.

When the main scanning direction reduction key 11 is pressed while the scanning signal Digit0 is at the "High" level, the scanning signal bit0 becomes "High" and is input to the B port 29, and the CPU unit via the bus line. 21 recognizes the input of the reduction key 11 in the main scanning direction.

When the main scanning direction enlargement key 12 is pressed, the B port 29
Scan signal bit1 is input as "High",
The CPU section 21 recognizes the input of the enlargement key 12 in the main scanning direction via the bus line.

Similarly, when the scanning signals Digit1 and 2 are at "High" level, the CPU section 21 inputs the scanning signals bit0 and bit1 to the B port 29, respectively, and recognizes the respective key inputs.

Next, in FIG. 3B, of the scanning signals Digit0 to 5 output from the A port 28, the scanning signal Digit0 is output to the LED1 of the LED matrix 23 via the driver 27 and the numerical data from the C port 30 is output. Is displayed as the hundredth digit of the main scanning magnification, and the scanning signal Digit1 is output via the driver 27 to the LED.
Numerical data output from the C port 30 to the LED2 of the matrix 23 is displayed as the tens digit of the main scanning magnification, and the scanning signal Digit2 is transmitted via the driver 27 to the LED of the LED matrix 23.
Numerical data output from C port 30 is displayed as the ones digit of the main scanning magnification.

On the other hand, the scanning signal Digit3 is output to the LED4 of the LED matrix 23 via the driver 27, and the numerical data from the C port 30 is displayed as the data of the hundreds of the sub-scanning magnification.
The git4 is output to the LED5 of the LED matrix 23 via the driver 27, and the numerical data from the C port 30 is displayed as the tens digit of the sub-scanning magnification.
Is output to LED6 of LED matrix 23 via C port 30
The numerical data from is displayed as the ones digit data of the sub-scanning magnification.

In this way, the key matrix 22 and the LED matrix 23 are dynamically scanned by the scanning signals DIgit0-5.

Next, the interrupt processing operation according to the present invention will be described with reference to FIG.

FIG. 3 (e) is a flowchart for explaining the interrupt processing operation procedure according to the present invention, in which (1) to (12) show respective steps.

CPU module 21 uses an internal interrupt timer (not shown) for 2ms
An interrupt is generated for each (1), and progressive scan signals Digit0-7
Is output through the A port 28 and the key input data is read through the B port 29 (2). Then scan signal Digit0
Turn off all of ~ 7 (3), then scan signal Digit0
After setting the display data corresponding to 7 to C port 30 (4), the next display data is set to C port 30 to display the magnification (5). Next, it is judged from the contents of the RAM of the CPU section 21 whether or not the previous key input was made (6). If NO, it is judged in step (2) whether or not there was a key input (7). Next Digit to output to 28
After setting in the data RAM (8), it returns.

On the other hand, if the determination in step (7) is YES, the key code of step (2) is set in the RAM (9), and then the process returns to step (8).

On the other hand, if YES in the determination in step (6), it is determined whether the previous key input and the key input in step (2) are the same (10), and if NO, after resetting the chattering flag of the key ( 11), return to step (8).

On the other hand, if the determination in step (10) is YES, after setting the chattering flag of the key (12), the process returns to step (8).

FIG. 3 (f) is a flow chart for explaining the key input selection processing operation according to the present invention. Note that (1) to (3)
Indicates each step.

First, after key input (1), it is determined whether or not the chattering flag is set (2). If YES, a key processing routine corresponding to the key input (FIGS. 4A to 4B described later). , And FIG. 5 (b), (c)) (3).

On the other hand, if the determination in step (2) is NO, the process returns.

FIG. 4 (a) is a flow chart for explaining the reduction scale independent setting key processing operation procedure according to the present invention. In addition,
(1) to (5) show each step.

First, after inputting the main scanning direction reduction key 11 or the sub scanning direction reduction key 13 (1), it is judged whether the main scanning magnification or the sub scanning magnification is 50% or less which is the lower limit of reduction (2). , NO, the display magnification of the main scanning magnification display portion 2d or the sub-scanning magnification display portion 2a is counted down by 1% (3). Then, after converting the value into display data (4), the display data is set in the RAM (5) and the process returns.

On the other hand, if the determination in step (2) is YES, the process returns.

FIG. 4 (b) is a flow chart for explaining the operation procedure of the enlarging magnification independent setting key processing according to the present invention. In addition,
(1) to (5) show each step.

First, after the main scanning direction enlargement key 12 or the sub scanning direction enlargement key 14 is pressed (1), it is determined whether the upper limit of the main scanning magnification or the sub scanning enlargement magnification is 200% or more (2), If NO, the display magnification of the main scanning magnification display portion 2d or the sub-scanning magnification display portion 2a is counted up by 1% (3). Then, after converting the value into display data (4), the display data is set in the RAM (5) and the process returns.

On the other hand, if the determination in step (2) is YES, the process returns.

FIG. 4 (c) is a flow chart for explaining the zoom reduction key processing operation procedure according to the present invention. In addition, (1) ~
(8) shows each step.

First, after inputting the zoom reduction key 15 (1), it is judged whether the main scanning magnification and the sub-scanning magnification are the same (2). If NO, the larger display magnification is changed to the smaller display magnification and displayed. Yes (3). Next, it is judged whether the changed display magnification is 50% or less, which is the lower limit value of the reduction magnification (4). If NO, after converting the value into display data (5), the display data is stored in RAM. Set to (6) and return.

On the other hand, if the determination in step (2) is YES, it is determined whether the display magnification is less than or equal to the lower limit of the reduction magnification of 50% (7). If NO, the main scanning magnification display section 2d and the sub scanning The magnification displayed on the magnification display portion 2a is counted down by 1% (8), and the process returns to step (5).

On the other hand, when the determination in step (7) is YES, the process returns, and when the determination in step (4) is YES, the process returns.

FIG. 4 (d) is a flow chart for explaining the zoom enlargement key processing operation procedure according to the present invention. In addition, (1) ~
(8) shows each step.

First, after inputting the zoom magnification key 16 (1), it is judged whether the main scanning magnification and the sub-scanning magnification are the same (2). If NO, the smaller display magnification is changed to the larger display magnification and displayed. (3). Next, it is judged whether the changed display magnification is 200% or more which is the upper limit value of the enlargement magnification (4). If NO, after converting the value into display data (5), the display data is stored in RAM. Set to (6) and return.

On the other hand, if YES in the determination in step (2), it is determined whether the display magnification is 200% or more, which is the upper limit value of the enlargement magnification (7), and if NO, the main scanning magnification display section 2d and The magnification displayed on the sub-scanning magnification display portion 2a is counted up by 1% (8), and the process returns to step (5).

On the other hand, if YES in the determinations in steps (4) and (7), the process returns.

Next, referring to FIG. 5 (a), the zoom ratio holding zoom operation according to the present invention will be described.

FIG. 5 (a) is a diagram for explaining the relationship between the zoom ratio holding zoom ratio according to the present invention. Incidentally, as in the above embodiment,
A case where the main scanning magnification is 70% and the sub-scanning magnification is 120% will be described.

At this point, when the zoom reduction key 15 is pressed and turned “ON”, the CPU unit 21 compares the main scanning magnification of 70% and the sub-scanning magnification of 120% and determines that the two magnifications are different. The ratio of the larger magnification to the magnification is calculated and set in RAM. In this embodiment, 120/70 = 1.7142 (magnification ratio)
Then, for example, set 1.714, which is rounded down to the fourth decimal place. Then, the step width of the smaller magnification is set to 1%, and the step width of the larger magnification is set to X ₂ . That is, if the ratio of the main scanning magnification and the sub-scanning magnification is kept constant and the set magnification after countdown is X ₁ and the step width is X ₂ , then X ₁ /71=1.714 and the set magnification X ₁ is 11
It becomes 8.226%, and the value rounding down the decimal point is the set magnification X
It is adopted as ₁ (118%). Therefore, the step width X ₂ is
2% is obtained by subtracting 118 from 120. Then, the step widths of the main scanning magnification and the sub-scanning magnification are set in the RAM. Next, if the smaller one of the main scanning magnification and the sub-scanning magnification is less than or equal to the lower limit of 50% of the reduction magnification, the main scanning magnification 70
% Is counted down to 1% and sub-scan magnification 120% is counted down to 2%, and the display data is set in the RAM. That is, the main scanning magnification is 69% and the sub-scanning magnification is 118%. When the zoom reduction key 15 continues to be "ON", the main scanning magnification and the sub-scanning magnification are sequentially counted down with the above step width. This operation is the zoom reduction key 15 is "OFF",
The main scanning magnification or the sub-scanning magnification, whichever is smaller, continues until the reduction magnification reaches the lower limit of 50%.

On the other hand, when the main-scan magnification and the sub-scan magnification are equal, the step widths of the main-scan magnification and the sub-scan magnification are each set to 1%, and the countdown is performed. This operation is performed by turning the zoom reduction key 15 “OFF” or the zoom magnification is the lower limit of the reduction magnification.
It continues until it reaches 0%.

On the other hand, when the zoom enlargement key 16 is pressed and turned "ON",
When the CPU section 21 compares the main scanning magnification of 70% with the sub-scanning magnification of 120% and determines that there is a difference, it calculates the ratio of the larger magnification to the smaller magnification and sets it in RAM. In this case, 120/70 = 1.7142 (magnification ratio), and for example, set to 1.714, which is rounded down to the fourth decimal place. Next, the smaller step width is set to 1% and the larger step size Y ₂ is set. That is, since the ratio between the main scanning magnification and the sub-scanning magnification is kept constant, if the set magnification after counting up is Y ₁ and the step width is Y ₁ , then Y ₁ /71=1.714
Therefore, the set magnification Y ₁ becomes 121.694%, and the value after rounding down the decimal point is adopted as the set magnification Y ₁ (121%). Therefore, the step width Y ₂ is 1% obtained by subtracting 120 from 121. Then, the step widths of the main scanning magnification and the sub-scanning magnification are set in the RAM. If the larger of the main scanning magnification and the sub-scanning magnification is 200% or more, which is the upper limit of the enlargement magnification, the main scanning magnification 70% is counted up to 1%, and the sub-scanning magnification 120% is counted up to 1%. Set the data in RAM. That is, the main scanning magnification is 71% and the sub-scanning magnification is 121%. When the zoom magnification key 16 continues to be "ON", the main scanning magnification and the sub-scanning magnification are sequentially counted up by the above step width. This operation is continued until the zoom magnification key 16 is turned "OFF" or the main scanning magnification or the sub-scanning magnification, whichever is larger, reaches 200% which is the upper limit of the magnification.

On the other hand, when the main-scan magnification and the sub-scan magnification are equal, the step widths of the main-scan magnification and the sub-scan magnification are each set to 1% and the count-up is performed. This operation is performed when the zoom magnification key 16 is turned "OFF" or the zoom magnification is the upper limit of the magnification 2
It continues until it reaches 00%. In this way, while maintaining the ratio between the sub-scanning direction magnification and the main scanning direction magnification constant,
The image reading magnification in the sub-scanning direction can be collectively changed.

FIG. 5B is a flowchart for explaining the zoom reduction processing procedure in the magnification ratio holding zoom magnification / reduction processing according to the present invention. Note that (1) to (9) indicate each step.

First, after pressing the zoom reduction key 15 (1), it is judged whether the main scanning magnification and the sub scanning magnification are equal (2). If NO, the ratio of the larger magnification to the smaller magnification is determined. Calculate (3). Next, the step width of the smaller magnification is set to 1%, the step width of the larger magnification is set to the calculated value, and each step width is set in the RAM (4), and the main scanning magnification and the sub-scanning magnification are set. Count down at each step width (5). Next, it is judged whether the main scanning magnification or the sub-scanning magnification is less than or equal to the lower limit value of the reduction magnification of 50% (6). If NO, after changing the main scanning magnification and the sub-scanning magnification to display data. (7), display data as RA
Set to M (8) and return.

On the other hand, when the determination in step (2) is YES, the step widths of the main scanning magnification and the sub scanning magnification are set to 1% (9), and the process returns to step (5).

On the other hand, if the determination in step (6) is YES, the process returns.

By these steps (1) to (9), the zoom reduction magnifications in which the ratio of the main scanning magnification and the sub scanning magnification is kept constant are sequentially displayed on the main scanning magnification display section 2d and the sub scanning magnification display section 2a.

FIG. 5C is a flow chart for explaining the zoom enlargement processing procedure in the magnification ratio holding zoom magnification / reduction processing according to the present invention. Note that (1) to (9) indicate each step.

First, after pressing the zoom magnification key 16 (1), it is determined whether the main scanning magnification and the sub-scanning magnification are equal (2). If NO, the ratio of the larger magnification to the smaller magnification is calculated. Yes (3). Next, the step width of the smaller magnification is set to 1%, the width of the larger magnification is set to the calculated value, and each step width is set in the RAM (4), and the main scanning magnification and the sub-scanning magnification are respectively set. Count up with the step width of (5). Subsequently, it is judged whether the main scanning magnification or the sub scanning magnification is 200% which is the upper limit value of the enlargement magnification (6), and if NO, the main scanning magnification and the sub scanning magnification are converted into display data (7). ), Set display data in RAM (8), and return.

On the other hand, if the determination in step (2) is YES, the step width of the sub-scanning magnification of the main scanning magnification is set to 1% (9), and the process returns to step (5).

On the other hand, if the determination in step (6) is YES, the process returns.

By these steps (1) to (9), the zoom magnifications with the ratio of the main scanning magnification and the sub scanning magnification kept constant are sequentially displayed on the main scanning magnification display section 2d and the sub scanning magnification display section 2a.

It should be noted that, in the above-mentioned embodiment, it is not necessary to change the magnification that is increased or decreased by the step width of 1% at the time of setting the magnification in a fixed time. For example, for the first 5 seconds, the magnification is changed by 1% per second, and thereafter the magnification change instruction is given. It is "5%" in 1 second until the key of part 2c is "OFF" or the upper limit value or the lower limit value of the magnification is reached, that is,
It may be changed by 1% in 0.2 seconds. As a result, when the difference between the magnification at the start of magnification setting and the magnification of the setting target is large, the operation time can be greatly shortened.

〔The invention's effect〕

As described above, according to the present invention, the main scanning magnification for enlarging or reducing the image in the main scanning direction and the sub-scanning magnification for enlarging or reducing the image in the sub-scanning direction are respectively the first instructing means and the first instructing means. It is possible to increase / decrease independently according to the change instruction by the two instruction means, and both the main scanning magnification and the sub-scanning magnification set in advance are set as the same step width or the main scanning / sub-scanning magnification according to the change instruction of the third instruction means. It is possible to increase / decrease together with different step widths that maintain the set magnification ratio, thus reducing the number of key operations, freeing you from complicated key operations, and reducing the mistakes in setting magnification. Have.

[Brief description of drawings]

FIG. 1 (a) is a main view of an operation panel of an image reading apparatus to which a magnification setting device according to an embodiment of the present invention is applied, and FIG. 1 (b) is a magnification change instruction section shown in FIG. 1 (a). 2 is an enlarged view of FIG. 2, FIG. 2 is a block diagram illustrating the control configuration of the operation unit shown in FIG. 1 (a), and FIG. 3 (a) is a circuit configuration diagram of the key matrix shown in FIG. FIG. 2B is a timing chart for explaining the output timing of the signal output from the LED matrix driver circuit shown in FIG. 2, and FIG. 3C is the I / O port A port shown in FIG. , Third
FIG. 3 (d) is a schematic diagram for explaining the data structure of the RAM in the CPU section shown in FIG. 2, FIG. 3 (e) is a flow chart for explaining the interrupt processing procedure according to the present invention, and FIG. FIG. 4A is a flowchart for explaining the key input selection processing operation according to the present invention, and FIG. 4A is a flowchart for explaining the reduction magnification independent setting key processing operation procedure according to the present invention.
FIG. 4B is a flow chart for explaining the enlargement magnification independent setting key processing operation procedure according to this invention, FIG. 4C is a flow chart for explaining the zoom reduction key processing procedure according to this invention, and FIG. 4D is this invention. FIG. 5A is a flow chart for explaining the zoom enlargement key processing procedure according to the present invention, FIG. 5A is a view for explaining the relationship of the magnification ratio holding zoom magnification change according to the present invention, and FIG. 5B is a magnification ratio holding zoom magnification change according to the present invention. FIG. 5 (c) is a flowchart for explaining the zoom reduction processing procedure of the processing, FIG. 5 (c) is a flowchart for explaining the zoom magnification processing procedure of the magnification ratio holding zoom magnification / reduction processing according to the present invention, and FIG. 6 (a) is an image reading apparatus. FIG. 6B is a block diagram showing the configuration of FIG. 6, and FIG. 6B is a sectional view of the image reading apparatus. In the figure, 1 is an operation panel main body, 2 is a magnification change instruction operation unit,
2a is a sub-scanning magnification display unit, 2c is a magnification change instruction unit, 2d is a main scanning magnification display unit, 11 is a main scanning direction reduction key, 12 is a main scanning direction enlargement key, 13 is a sub scanning direction reduction key, and 14 is a sub scanning direction. Scan direction enlargement key, 15 zoom reduction key, 16 zoom enlargement key,
21 is a CPU part, 22 is a key matrix, and 23 is an LED matrix.

Claims (2)

[Claims] 1. A magnification setting device for setting a main scanning magnification for enlarging or reducing an image in the main scanning direction and a sub-scanning magnification for enlarging or reducing an image in the sub-scanning direction. First instructing means for instructing, second instructing means for instructing to change the sub-scanning magnification, third instructing means for instructing to change both of the main scanning magnification and the sub-scanning magnification, and the first instruction The main scanning magnification is increased / decreased according to the change instruction by the means, the sub scanning magnification is increased / decreased according to the change instruction by the second instruction means, and the main scanning magnification and the sub scanning magnification are changed according to the change instruction by the third instruction means. And a magnification changing unit that increases and decreases together. The magnification changing unit is configured to change the main scanning magnification and the sub-scanning magnification when the change instruction is given by the third instruction unit. After the main scanning magnification and the sub-scanning magnification are matched, the main-scanning magnification and the sub-scanning magnification are increased / decreased together in the same step width in accordance with a change instruction by the third instruction means. Setting device. 2. A magnification setting device for setting a main scanning magnification for enlarging or reducing an image in the main scanning direction and a sub scanning magnification for enlarging or reducing an image in the sub scanning direction. First instructing means for instructing, second instructing means for instructing to change the sub-scanning magnification, third instructing means for instructing to change both of the main scanning magnification and the sub-scanning magnification, and the first instruction The main scanning magnification is increased / decreased according to the change instruction by the means, the sub scanning magnification is increased / decreased according to the change instruction by the second instruction means, and the main scanning magnification and the sub scanning magnification are changed according to the change instruction by the third instruction means. And a magnification changing unit that increases and decreases together. The magnification changing unit is configured to change the main scanning magnification and the sub-scanning magnification when the change instruction is given by the third instruction unit. , A ratio between the main scanning magnification and the sub-scanning magnification is calculated, and the main-scanning magnification and the sub-scanning magnification are increased / decreased together with different step widths while maintaining the calculated ratio according to the change instruction by the third instruction means. A magnification setting device characterized by the above.