JP2542723B2 - Image reader - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an image reading apparatus for reading a two-dimensional image and transferring the obtained image data to a host computer and a host device.

[Prior Art] Conventionally, when image data is transferred between different devices, the data processing speeds are often different between the devices, and therefore timing processing is required.

In order to meet such a demand, a data transfer system as shown in FIG. 4 has been conventionally proposed. This fourth
The figure is a block diagram showing a conventional image reading apparatus disclosed in Japanese Utility Model Laid-Open No. 63-173971, in which 8 is a document on which an image to be read is drawn, and 9 is a document 8 placed. A transparent glass plate, 10 is placed below the glass plate 9 and the original 8
The image sensor 10 is a contact type image sensor that reads an image and converts it into an electric signal. In the image sensor 10, a unit including a light source, a rod lens array (imaging means), a CCD sensor and the like is provided.

Further, 11 is a belt for receiving the driving force from the pulse motor 12 and moving the image sensor 10 in the direction of the arrow A along the glass plate 9, 13 is a CPU for controlling the program of this apparatus, and 14 is for storing various data and programs. A memory, 15 is a transfer control unit for transmitting / receiving data to / from an upper device (host computer) not shown, and 16 is the pulse motor described above.
A mechanism control unit for controlling the drive state of 12, 18 is the CPU 1 described above
3, a system bus for connecting a memory 14, a transfer control unit 15, a mechanism control unit 16 and a timer 21, which will be described later, to perform data transmission, 21
Is a timer for measuring a dummy data transfer time T described later,
22a to 22c are line buffers for storing one line of read data from the image sensor 10, and 23a and 23b are arranged on the input side and the output side of the line buffers 22a to 22c, respectively, and input to the line buffers 22a to 22c. Is a changeover switch for sequentially connecting the output side and the output side to the image sensor 10 and the transfer control unit 15.

Next, the operation will be described. The image reading apparatus shown in FIG. 4 receives the dummy data transfer instruction command C ₁ from the host apparatus, as shown in FIG. This command C ₁ does not include various parameters for actual reading, and only the transfer data length is specified. CPU13 uses command C
_{When 1} is recognized, fixed data is transmitted by the designated transfer data length via the transfer control unit 15. During the transfer period, the CPU 13 operates the timer 21 and measures the dummy data transfer time T. Then, the CPU 13 sets the dummy data transfer time T
Calculate the transfer time for the amount of data for one line, and if the transfer time is shorter than the transfer time that matches the maximum reading speed Vmax of this device, the image sensor at the maximum reading speed Vmax.
Move 10 to read the image. On the other hand, if the data transfer time for one line is longer than the transfer time that matches the maximum reading speed Vmax, the image sensor 10 is moved at about 80% of the moving speed that matches the measurement time to read an image. The data reading speed at this time is V ₁ . The movement control of the image sensor 10 is performed by controlling the operating state of the pulse motor 12 by the mechanism control unit 16 based on a control command from the CPU 13.

In this way, when the moving speed (data reading speed) of the image sensor 10 is determined by the transfer measurement time of the dummy data, the normal reading instruction command C ₂
Will be sent. This command C ₂ contains various information such as paper size or reading area, resolution, data length, binary / multivalued, slice level, black / white inversion. CPU1
3 recognizes it, starts the image sensor 10 up to a preset moving speed, and starts reading image data. At this time, the image sensor 10 illuminates the original 8 with the built-in light source, receives the reflected light and photoelectrically converts the reflected light to obtain image data for one line, and reads the image data for each line. The pulse motor 12 and the belt 11 move one dot at a time. By repeating this, the entire image surface of the original 8 is read. The image data for one line is sequentially stored in the line buffers 22a to 22a.
It is stored in 2c and is transferred from the respective line buffers 22a to 22c to the host device via the transfer control unit 15.

Conventionally, optimum image data is always read by changing the drive clock frequency of the CCD sensor forming the image sensor 10 according to the determined reading speed V ₁ .

[Problems to be Solved by the Invention] Since the conventional image reading apparatus is configured as described above, for example, when the data amount for one line changes significantly due to a change in resolution, the CCD sensor is driven. At the same time as changing the clock frequency, the accumulation time of the CCD sensor will change greatly. Especially when the data amount for one line becomes large, the accumulation time becomes longer by lowering the driving clock frequency of the CCD sensor. , The linearity of the photoelectric conversion of the CCD sensor is broken, or in some cases,
There was a problem such as blooming.

The present invention has been made to solve the above problems, and an object of the present invention is to provide an image reading apparatus that widens the selection range of reading resolution and enables optimum reading of image data.

[Means for Solving the Problem] In the image reading apparatus according to the present invention, a line sensor having a length equal to the width of the document table and reading the image line by line is used as the line sensor. An image reading apparatus that transfers the read image data to the higher-level device at a resolution and a reading range according to a command from the higher-level device while moving the image data while moving it vertically. In advance, dummy data transfer means for transferring dummy data to the host device, measuring means for measuring the transfer time of the dummy data by the dummy data transfer means, and data for the host device based on the measurement result by the measuring means. A calculation means for calculating the data transfer rate,
The control means for controlling the moving speed of the line sensor, and the thinning means for thinning out the image data read by the line sensor on a line-by-line basis are provided, and the line sensor always reads at a constant accumulation time. And the thinning means, based on the data transfer rate obtained by the arithmetic means, the resolution commanded by the host device, and the reading range, the data transfer rate at the time of the actual reading operation,
The moving speed of the line sensor and the number of thinned lines are determined so as not to exceed the data transfer speed obtained by the calculating means.

[Operation] In the image reading device according to the present invention, the dummy data transfer means transfers the dummy data to the host device and the transfer time is measured by the measuring means before the reading / transferring of the image on the document. The data transfer rate is calculated by the calculating means based on the measurement time, and the data transfer rate obtained by the calculating means and the resolution commanded by the host device are calculated.
Based on the reading range, the moving speed of the line sensor and the number of thinned lines are determined so that the data transfer speed during the actual reading operation does not exceed the data transfer speed obtained by the calculating means. Is controlled by the control means, and the thinning means controls the thinning of the image data read by the image sensor in units of lines to transfer the image data to the host device. This will prevent the maximum data transfer rate from being exceeded without changing the image sensor clock frequency as much as possible, regardless of the resolution, reading range, and interface data transfer rate. Since the image data can be transferred to the higher-level device, stable image reading can be always performed without breaking the linearity of photoelectric conversion and causing blooming of the image sensor.

[Embodiment of the Invention] An embodiment of the present invention will be described below with reference to the drawings.

In FIG. 1, reference numeral 1 is a host computer as a host device, 2 is an I / F (interface) LSI for controlling reception of various commands from the host computer 1 and transfer of data to the host computer 1, and 3 is the present embodiment. This is a CPU that controls the device in this example.
The function as a dummy data transfer means for transferring the dummy data to the host computer 1 and the function as a calculation means for calculating the data transfer rate to the host computer 1 based on the measurement result by the timer 6 (described later) are calculated. It has a function as a control unit that outputs a control command to the pulse motor 12 to control the reading movement speed of the image sensor 7 (described later) based on the data transfer speed.

Further, 4 is an image sensor 7 according to an instruction from the CPU 3.
A signal processing unit that performs signal processing such as correction and thinning on image data from (described later), and this signal processing unit 4 reads the image data line by line based on the data transfer rate calculated by the CPU 3. It has a function as thinning means.

Further, 5 is a drive circuit that changes the drive clock frequency of the CCD sensor that constitutes the image sensor 7 (described later) according to the determined reading speed V ₁ , and 6 is the transfer time of the dummy data by the dummy data transfer function of the CPU 3. Is a timer (measuring means) for measuring the temperature, and 7 is a glass plate (document table) 9 as in the conventional image sensor (see reference numeral 10 in FIG. 4).
Is a contact type image sensor (line sensor) which is arranged below the table and reads the image of the document 8 line by line and converts it into an electric signal. In the image sensor 7, a light source, a rod lens array (imaging means), a CCD A unit including a sensor and the like is provided. Then, the image sensor 7
It is attached to belt 11, and this belt 11 is a pulse motor.
It is adapted to move along the original 8 (glass plate 9) by being driven by 12.

Next, the operation of the apparatus of this embodiment will be described with reference to FIGS. C from host computer 1 via I / F LSI2
When the reading area and reading condition setting command is transmitted to the PU 3 (step S1), the CPU 3 writes dummy data having a known data amount in the signal processing unit 4 (step S2).
Then, the dummy data starts to be transferred from the signal processing unit 4 to the host computer 1 via the I / F LSI 2 (step
S3). At the same time, the timer 6 starts the time counting operation (step S4), and ends the data transfer (determines based on whether or not a data transfer interrupt is entered; step S5) and simultaneously stops the timer 6 time counting operation (step S5). In step S6), the CPU 3 reads the timer value at that time as the measurement time of the transfer time of the dummy data (step S7). Based on this measurement time, the CPU 3 calculates the transfer speed of the interface bus with the host computer 1 (step S8).
Based on the transfer speed calculation result, the CPU 3 calculates the data thinning ratio and the reading movement speed of the image sensor 7 (steps S9 and S10).

At this time, as shown in FIG. 3, the data transfer time from the image sensor 7 to the signal processing unit 4 is made longer than the data transfer time on the interface bus. That is, the data transfer speed on the interface bus is set to be higher than the data transfer speed from the image sensor 7 to the signal processing unit 4. The graph shown in Fig. 3 shows one line with a resolution of 50 DPI (dot / inch) to 600 DPI.
This is the range of data amount when reading 8.5 inches.
In the figure, a part reads data one line at a time without thinning out data, b part thins data at a ratio of 1 line to 2 lines, and c part reads data at a ratio of 2 lines to 3 lines. This is when thinning out. The ratio of thinning out data is determined so that the data transfer time on the interface bus is as close to a straight line as possible. The reading movement speed of the image sensor 7 is determined in consideration of the ratio.

As described above, according to the apparatus of this embodiment, the image data can be transferred to the host computer 1 so as not to exceed the maximum data transfer rate, the selection range of the resolution at the time of reading the image is widened, and the data overflows. The transfer to the host computer 1 can be performed without causing the above.

In the above embodiment, the CPU 3 and the timer 6 are separated, but a one-chip CPU having a built-in timer function may be used as the CPU 3, and in this case, the timer is not provided separately, The same effect as in the above embodiment can be obtained.

Further, in the above embodiment, the interface between the host computer 1 and the image reading apparatus may be either a parallel interface such as GP-IB or SCSI or a serial interface such as RS-232C. It is not limited by the method or speed.

[Effects of the Invention] As described above, according to the present invention, the data transfer speed to the host device is calculated from the transfer time of the dummy data, and based on the data transfer speed and the resolution and reading range commanded by the host device. In order to prevent the data transfer rate during the actual reading operation from exceeding the data transfer rate obtained by the calculation means, the control for thinning out the image data in line units and the control for the moving speed of the image sensor are performed. Since it is configured to, the maximum data transfer speed is not exceeded without changing the image sensor clock frequency as much as possible, regardless of the resolution, reading range, and interface data transfer speed. Image data can be transferred to a higher-level device, and the linearity of photoelectric conversion is destroyed,
Without causing the line sensor to bloom
There is an effect that stable image reading can be always performed.

[Brief description of drawings]

FIG. 1 is a block diagram showing an image reading apparatus according to an embodiment of the present invention, FIG. 2 is a flow chart for explaining the operation of the apparatus of the above embodiment, and FIG. 3 is per line in the apparatus of the above embodiment. 4 is a graph showing the relationship between the amount of data and the data transfer time per line, FIG. 4 is a configuration diagram showing a conventional image reading device, and FIG. 5 is a transfer of image data between the conventional device and a host device. It is a sequence diagram for explaining a control procedure. In the figure, 1 ... Host computer (upper device),
3 ... CPU, 4 ... Signal processing unit, 6 ... Timer (measuring means), 7 ... Image sensor (line sensor), 8 ...
Manuscript. In the drawings, the same reference numerals indicate the same or corresponding parts.

Claims (1)

(57) [Claims] 1. A high-order apparatus for reading an image original on an original plate while moving a line sensor having a length equal to the width of the original plate and reading the image line by line in a direction perpendicular to the line. In the image reading device for transferring the read image data to the higher-level device with the resolution and the read range according to the command from, the dummy data transfer means for transferring the dummy data to the higher-level device prior to the transfer of the read image data. Measuring means for measuring the transfer time of the dummy data by the dummy data transfer means, calculating means for calculating the data transfer rate to the host device based on the measurement result by the measuring means, and the line sensor Control means for controlling the moving speed; and thinning means for thinning out the image data read by the line sensor in line units, The line sensor always reads at a fixed accumulation time, and the control unit and the thinning unit are based on the data transfer rate obtained by the calculation unit, the resolution commanded by the host device, and the reading range, and The moving speed of the line sensor and the number of thinned lines are determined so that the data transfer speed during the reading operation does not exceed the data transfer speed obtained by the arithmetic means. Image reading device.