JPS644388B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Technical Field The present invention relates to an optical image reading device, and more specifically, an image sensor using a solid-state image sensor that decomposes a document image into predetermined pixel signals, and stores the pixel signals in a storage device. The present invention relates to an optical image reading device that stores images.

Prior Art In general, a document image is formed on the light receiving surface of an image sensor such as a line sensor in which solid-state imaging devices such as CCD image sensors are arranged in a one-dimensional direction, and the image or line sensor is scanned in a direction perpendicular to the line direction. An image reading apparatus is known in which pixel signals of the original image are obtained from each bit of an image sensor every line at a predetermined interval using an appropriate synchronization signal.

In some types of reading devices, depending on the type of document, only information written on a portion of the document is required, and the position of this information on the surface of the document is determined in advance. Even for such originals, in conventional reading devices, the storage device has enough capacity to store the entire area of the original in order to deal with the case where the information position changes. However, since the capacity of the storage device required for a given document is actually only for a specific portion, such conventional devices have the disadvantage of being wasteful and increasing costs.

Purpose The present invention aims to improve this type of image reading device, and specifically, an image reading device in which a reading area of a document is determined in advance and only pixel information within that area is stored in a storage device. The purpose is to provide a device.

Example Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows the main parts of a specific configuration of an image reading device 1 to which the present invention is applied, in which an original 3 is placed on the upper surface of an original placing plate 2 made of a transparent material such as glass. , by lighting the original illumination lamp 4, the original 3
The image is projected via reflecting mirrors 5, 6 and scanning lens 7 onto line sensor 8, which is a CCD image sensor.

For example, as shown in FIG. 2, the line sensors 8 are arranged and held so as to cover the X and Y directions of the document 3, and the line sensors 8 are arranged and held so as to cover the X direction of the document 3. It is possible to scan the entire surface of 3.

The scanning lens 7 has one end wound around a pulley fixed to the rotating shaft of the motor 9, and the other end movable in the Y direction by a wire 11 stretched by a spring 10. The rotation of the motor 9 is detected by an encoder 12, a lens position signal is obtained, and the output from each bit of the line sensor 8 is read using an appropriate synchronization signal.

As shown in FIG. 3, the line sensor 8 includes a photo sensor array 18 with a large number of bits (usually 1000 bits or more) arranged in a row, and shift registers 19 and 20 that store the photoelectric output of each photo sensor. Therefore, each photo sensor 18
It is configured to sequentially read out the signals from the output terminal 21. Since this type of line sensor is well known, detailed description thereof will be omitted.

FIG. 4 is a block diagram showing a control circuit that reads the output signal from the line sensor 8 and controls the motor 9, etc. The output of the line sensor 8 is sent to the storage section via an amplifier 24 and a shift register 29. The output from the encoder 12 is input to the CPU 22 as lens position information, and based on this, the
A reading command signal for each line is output from the CPU 22 to the line sensor 8. This reading command signal is applied to the clock pulse generation circuit 23, and the clock pulse generated therefrom is applied to the sensor 8, thereby causing the shift registers 19, 20 of the line sensor 8 to
Signals representing black and white at each point of the original image are sequentially read out from the output signal, and the output is amplified by the amplifier 24 to become a normalized binary signal.

The output of the amplifier 24 is stored in the shift register 29, converted into parallel information, and written to the storage section via the CPU 22. The information written in this way is converted into a video signal within the CPU 22 by appropriate means, such as a CRT (cathode ray tube).
It is also possible to display an image by applying the voltage to a display device 50 such as the like.

The document illumination lamp 4 and lens drive motor 9 are connected via a lighting control circuit 30 and a drive circuit 31, respectively.
The operation is controlled by a command signal from the CPU 22.

In the above-mentioned apparatus, for example, as shown in FIG. 2, the reading apparatus reads only the information within a predetermined reading area 3a of the original 3, and the storage capacity of the storage means is kept to the minimum necessary. explain. Such a device can be used, for example, for document 3 in FIG.
However, if common information is printed outside the reading area 3a and changeable information is written in the reading area 3a, only the changeable information is read and displayed or printed. This is effective when applied to devices that store information, and since it is not necessary to have a capacity large enough to store information over the entire surface of the document 3, a small-capacity storage device can be used extremely efficiently. Note that, as will be clear from the description below, the predetermined reading area can be easily changed by rewriting or exchanging the reading area information in a predetermined storage device.

FIG. 5 shows a schematic block diagram of the reading device of the present invention, and FIG. 6 shows a flowchart of its operation.

In Figure 5, similar to that shown in Figure 4 is shown.
The CPU 22 has a read-only memory (hereinafter referred to as ROM) that stores data such as programs.
101, random access memory (hereinafter referred to as RAM) 102 for reading data, RAM 103 for counters in both X and Y directions, input/output interface (hereinafter referred to as I/O) 104, etc. are connected via bus lines. An output line 106 for an operation command signal to an image sensor circuit 105 including the line sensor 8, amplifier 24, shift register 29, etc. and an input line 107 for read image data are connected to the I/O 104. . Also,
In the counter RAM 103, two registers are set as an X direction register 108 and a Y direction register 109.

The operation of the reading device having the above configuration is as follows when reading the area 3a of the original 3 shown in FIG.
This will be explained using the flowchart shown in FIG. In addition, the symbols (xn, ym) in Fig. 2 are respectively in the X direction and Y.
This indicates the coordinate position in pixel units in the direction.

Furthermore, in the above configuration, the output from the image sensor circuit 105 is output as an 8-bit parallel signal, so the X register 108 is set to count up every 8 bits, and the Y register 108 is set to count up every 8 bits.
09, the count number of the X register 108 is x = x ₀ =
It is programmed to count up each time the number of bytes for one line is reached.

In FIG. 6, first, the scan motor 9 shown in FIGS. 1 and 4 is driven by an appropriate image reading start signal, and the document placement reference position 0,0 is set by an encoder or a specific mark on the document placement plate 2. etc., the contents of the X and Y registers 108 and 109 are cleared in step, and an activation signal is output from the CPU 22 to the image sensor circuit 105 via line 106, Image data is input via.

In the step, the input image data signal is counted by the X register 108 with the 0,0 point as the origin of the coordinates, and the operation x=x+1 is performed every 8 bits in the X direction.

In this step, when the contents of the X register 108 reach x= _x0 , the contents of the Y register 109 are counted up by the operation y=y+1, and the X register 108 is cleared in preparation for reading the next line. Reading of the next line is started by the synchronization signal from the encoder 12 described above, and this operation is repeated thereafter.

In step, it is determined whether or not the line of the reading setting area 3a of the original 3 has been reached, and y=
When y becomes ₁ , move to the next step.

The step is the same as the above step
Direction counting is done, in this case, in this line (y=y ₁ ), from (x=x ₁ ) to (x
= x ₂ ), so when (x = x ₁ ) is determined in the step, the X register 1 is stored in the step.
At every count of 08, the input image data is stored in RAM.
102, and in step (x=
This operation is repeated until x ₂ ) is determined.

In step , the above steps ~
This indicates that the operation is repeated from the line (y=y ₁ ) to (y=y ₂ ), and when the line reaches (y=y ₂ +1), proceed to the next step.

In this step, counting is performed in the X direction as in the above step, but in the line (y=y ₂ + ₁ ), the count is counted from (x=x 3 ) to (x=x ₃ ).
In order to store the image signal in the RAM 102 until x ₂ ), (x=x ₃ ) is determined in step, and until (x=x ₂ ) is determined in step, X is stored in the same way as in step. The input image data is transferred to the RAM 102 every time the register 108 counts. And in step , this operation is (y=y ₂ +
₁ ) to (y=y ₃ ) are repeated.

As is clear from the above description of the operation, in the image reading apparatus of the present invention, only the image data within the predetermined reading area 3a of the original 3 is stored in the storage device, and the data of other parts are cut. Therefore, the capacity of the RAM 102 can be made extremely small compared to a device that stores data over the entire surface of the document 3, which is not only advantageous in terms of cost, but also allows processing of stored data to be performed at the minimum necessary level. Since only data is stored, it can be extremely simplified.

In the above description, the coordinate position data for setting the reading area is calculated in advance as numerical data from the pixel size, and is stored in the ROM 101.
However, instead of the ROM 101, use a programmable ROM (P-ROM) and rewrite the numerical data as appropriate to store it in the reading area 3a.
It is also possible to change the range of , and other numerical data input means and RAM may be used for area setting.

Further, in the above embodiment, an image reading device using a line sensor in which image sensors are arranged in a one-dimensional direction is shown, but this may be one in which image sensors are arranged in a two-dimensional plane. effect can be obtained.

Furthermore, the image data stored in the RAM 102 in this way is converted into a video signal, etc., as described above, and can be displayed on the CRT display device 50. Although it is possible to obtain a hard copy depending on the device, the pixel signals (mainly binary information indicating white and black) stored in the RAM can be used to decompose the characters or figures of the original into pixels of appropriate size. However, since this is stored as white or black information, if this is output and displayed as is, a white or black pattern may sometimes be displayed that is inconvenient for actual characters or figures. . This occurs due to, for example, the sensitivity error of each photo sensor of the line sensor 8 and the difficulty in determining white and black for intermediate value inputs, and is likely to occur at the boundary between black and white areas.

Therefore, the information stored in the RAM 102 is displayed on a CRT display device, and the erroneous black and white pattern is corrected using a light pen.
By performing an operation to change the memory contents of the RAM 102, accurate character and graphic patterns can be obtained even when this information is made into a hard copy. Further, as a means for modifying the information stored in the RAM 102, a numeric keypad may be used to rewrite pattern information at a predetermined coordinate position on the CRT display surface.

Effects As explained above, the present invention provides an optical image in which an image sensor using a solid-state image sensor decomposes a document image into predetermined pixel signals, and the pixel signals are stored in a storage device. In the reading device, a means for specifying the position of a predetermined area on a document surface, a discriminating means for discriminating whether the pixel signal is a pixel signal within the designated area or a pixel signal outside the area, and the discriminating means Therefore, since the optical image reading device has means for sequentially transferring only pixel signals determined to be pixel signals within the area to the storage device, the capacity of the storage device is limited to within a predetermined reading area on the document surface. It is extremely efficient and economical, and is practically useful.

[Brief explanation of drawings]

FIG. 1 is a diagram showing a specific example of the configuration of an image reading device, FIG. 2 is a diagram showing a document and its reading area, and FIG. 3 is a diagram showing a specific example of a line sensor.
Figure 4 is a diagram showing the control system of the image reading device, Figure 5 is a diagram showing the control system of the image reading device.
The figure is a block diagram showing an example of the circuit of the image reading apparatus of the present invention, and FIG. 6 is a diagram showing a flowchart of its operation. DESCRIPTION OF SYMBOLS 1... Image reading device, 3... Document, 3a... Reading area, 7... Lens, 8... Line sensor, 9... Motor, 12... Encoder, 22...
...CPU, 101...ROM, 102...RAM for reading data, 103...RAM for counter, 1
04...I/O, 105...Image sensor circuit.

Claims (1)

[Scope of Claims] 1. An optical image reading device in which an image sensor using a solid-state image sensor decomposes a document image into predetermined pixel signals, and the pixel signals are stored in a storage device, means for specifying the position of a predetermined area on the document surface; discriminating means for discriminating whether the pixel signal is a pixel signal within the specified area or a pixel signal outside the area; an optical image reading device comprising means for sequentially transferring only pixel signals determined to be pixel signals to the storage device. 2. A patent in which the means for specifying the position of the area is configured to specify the position by two-dimensional X-Y coordinates with a pixel of the document image as one unit and a predetermined position on the document as the origin. An optical image reading device according to claim 1. 3 The means for associating the line sensor output with the position of a specified area includes a Y counter that counts up for each line, an X counter that counts a predetermined information unit for each line, and a count number of the Y counter that is specified. and means for determining whether or not the count number of the X counter in that line is the specified value when the count number of the Y counter is the specified value. An optical image reading device according to claim 1 or 2, comprising: 4. The means for specifying the location of the area is a program storage device of a microcomputer,
Claim 2 in which the coordinate position on the X-Y coordinates is stored in advance as numerical data.
The optical image reading device according to item 1 or 3.