KR100236690B1 - Optical reader - Google Patents

Abstract

The present invention relates to an optical information reading apparatus capable of optically reading an object to be read such as a one-dimensional bar code, a multi-stage two-dimensional bar code, a character and matrix type two-dimensional bar code recorded on a reading surface, Which can reduce the capacity of the storage means for storing the binary data in accordance with the density of the object to be read and reduce the time required for reading the binary data from the storage means, And the binary data corresponding to the information to be read (2) is given to the latch units (16a) and (16b) in the solution means. In the latch portions 16a and 16b, among the two-value data, the image portion 12a (corresponding to the binary data necessary for reliably recognizing the partial information area 2 according to the type of the information 2) Only the binary data according to the above-mentioned area) is latched, and only the latched binary data is stored in the data buffers 18a and 18b as identification data. Therefore, according to the present invention, since the reading object can be identified only by having the data buffer having the capacity enough to store the minimum necessary binary data, the storage capacity of the data buffer can be reduced, Therefore, the cost can be reduced and the power consumption can be reduced. Further, a small amount of two-value data can be read and the identification process can be performed. Thus, the processing time can be shortened.

Description

Optical information reader

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical information reading apparatus recorded on a reading surface and capable of optically reading a reading object such as a one-dimensional bar code, a multi-stage two-dimensional bar code, a character and matrix type two-

Traditionally, in a point of sale (POS) system, a logistics management system that is spreading in factories, etc., which are distributed in stores and the like, a tag in which a name code, a price, a manufacturing number, Inventory management of a product or the like is performed by optically reading an object to be read such as a name code recorded on the tag.

The reading of the object to be read is carried out as follows. That is, the tag is irradiated with light, the reflected light is focused on the image sensor via the lens system, and the image thus formed is converted into binary data according to the density of the image. Then, the read object is identified based on the converted binary data.

However, the format of a read object recorded in a tag that is actually distributed is not uniform. Specifically, a bar code is recorded in a certain tag, and a character is recorded in the other tag. These read objects have different shapes and sizes depending on their types. For example, a barcode is a horizontally long rectangle, whereas a character is a square smaller than the barcode. For this reason, a technique capable of making a single device read a different reading object is disclosed in, for example, Japanese Patent Application Laid-Open No. 62-114072.

In the technique disclosed in the above publication, a plurality of mask patterns composed of binary data are recorded in the memory IC in order to read out read objects of different formats from a single apparatus, and 2 The logical product of the value data and the mask pattern is obtained. As a result, only the binary data of the area in the mask pattern is extracted as it is, and the binary data of the area other than the mask pattern out of the binary data corresponding to the density signal outputted from the image sensor are all at the low level " 0 & And is output.

However, in the technique disclosed in the above publication, the extracted binary data also includes data converted to a low level " 0 " in an area other than the mask pattern, and is temporarily stored in the data buffer. Then, based on the binary data recorded in the data buffer, the read object is recognized.

On the other hand, the binary data necessary for recognizing the read object is binary data in the mask pattern extracted as a result of the logical AND. Therefore, in the technique disclosed in the above publication, the storage area for storing the binary data converted to the low level " 0 " which is unnecessary for recognition of the read object becomes a useless area. In other words, it is necessary to provide a data buffer having a capacity that is actually more than the capacity required. As a result, there is a fear that the cost is increased and the power consumption is increased.

When binary data is read from the data buffer, binary data of an unnecessary low level " 0 " other than the mask pattern is also read because the data is successively read at a constant speed one row at a time. Because of this, the binary data becomes redundant, so it takes time to read the binary data. In addition, since the amount of binary data to be processed is large, the processing time is long.

It is therefore an object of the present invention to solve the technical problem described above and to reduce the capacity of the storage means for storing binary data in accordance with the shade of the object to be read, And to provide an optical information reading apparatus which can read the information.

Another object of the present invention is to provide an optical information reading device capable of shortening the time required for reading binary data from the storage means.

FIG. 1 is a schematic block diagram showing an electrical configuration of an optical information reading apparatus according to a first embodiment of the present invention; FIG.

FIG. 2 is a view showing information to be read by the optical information reading apparatus; FIG.

3 is a view showing an image-forming surface of a two-dimensional image sensor unit constituting a part of the optical information reading apparatus;

FIG. 4 is a view showing a partial reading area corresponding to a one-dimensional bar code and a multi-stage two-dimensional bar code, respectively.

FIG. 5 is a diagram for explaining latches of binary data. FIG.

FIG. 6 shows an example of a matrix-type two-dimensional barcode which is a variation of an object to be read in the optical information reading device and its partial reading area.

FIG. 7 is a schematic block diagram showing an electrical configuration of an optical information reading apparatus according to a second embodiment of the present invention; FIG.

FIG. 8 is a schematic block diagram showing an electrical configuration of an optical information reading apparatus according to a third embodiment of the present invention; FIG.

FIG. 9 is a view showing an example of a barcode sheet; FIG.

FIG. 10 is a view showing the external appearance of the scanner in a case where a part of an optical information reading device according to the third embodiment is incorporated in a scanner and a switching switch is applied as a configuration for switching a partial reading area.

FIG. 11 is a flowchart for explaining processing in the optical information reading device according to the third embodiment when returning to the initial state after the partial reading area is switched; FIG.

FIG. 12 is a diagram for explaining a configuration in the optical information reading device according to the third embodiment, in which a partial reading area can be viewed by a user; FIG.

FIG. 13 is a view for explaining a configuration in which in the optical information reading device according to the third embodiment, a partial reading area can be viewed by a user.

FIG. 14 is a view for explaining a configuration of the optical information reading device according to the third embodiment, in which a partial reading area can be viewed by a user.

FIG. 15 is a view for explaining a configuration in the optical information reading device according to the third embodiment, in which a partial reading area can be viewed by a user.

FIG. 16 is a view for explaining a configuration that allows the user to view the partial reading area in the optical information reading apparatus according to the third embodiment.

FIG. 17 is a diagram for explaining a configuration that allows a user to visually recognize a partial reading area in the optical information reading apparatus according to the third embodiment; FIG.

DESCRIPTION OF THE REFERENCE NUMERALS

1: Reading side 2: Information

10: light source 11: lens system

12: two-dimensional image sensor unit 12a: image plane

15a: one-dimensional barcode processing unit 15b: multi-stage two-dimensional barcode processing unit

16a, 16b, 30: latch unit 17:

18a, 18b, 31: data buffers 19a, 19b, 32: CPU

22: identification result determination section 35: switching input section

41: Switch 44, 50a, 50b, 60a, 60b, 71a, 71b:

80: concave portion 90: convex portion

Pe: read pixel YE ₁ , YE ₂ , YE ₃ : partial read area

An optical information reading device according to a first aspect of the present invention for achieving the above object is an optical reading device for optically reading a plurality of types of reading objects to be recorded on a reading surface and having an imaging surface composed of reading pixels, An image sensor for producing a gradation signal corresponding to the density of the image to be shared by each of the read pixels and sequentially outputting a density signal generated by each of the read pixels; Signal extracting means for extracting only a gray-scale signal corresponding to a plurality of partial reading regions according to the kind of the reading object among the gray-scale signals outputted from the image sensor; Storage means for storing a gray-scale signal corresponding to the partial read region to be read out; The identification according to the type of each of the read target, and characterized in that, including recognition means for recognizing that on the basis of the identification result of a successful read is read.

In this arrangement, the density signals corresponding to the plurality of partial reading regions according to the type of the reading object are respectively extracted and stored in the storage means. In the recognition means, the contents displayed by the shading signal stored in the storage means are identified according to the type of the object to be read, and it is recognized that the reading of the object to be read is successful based on the result of the identification.

The partial read area is an area on the image plane for creating a shading signal only to the minimum necessary to accurately identify an object to be read. This partial reading area differs depending on the kind of the reading object.

That is, for example, when the two-dimensional image sensor is used as the image sensor, since the one-dimensional barcodes do not include the density information in the row direction, if there is a density signal generated by the reading pixel group for one row of the image- Suffice. On the other hand, in the multi-stage two-dimensional bar code, since the one-dimensional bar codes are arranged in a plurality of rows in the row direction, a density signal created by the reading pixel group corresponding to at least the number of rows is required.

As described above, since the identification processes according to the type of the reading object are performed independently of each other, any of the reading objects having different formats such as the one-dimensional bar code, the multi-stage two-dimensional bar code, and the character and matrix type two- It is possible to reliably identify the read object.

In addition, since only the shading signal corresponding to the partial reading region corresponding to the kind of the reading object corresponding to a part of all the shading signals outputted from the image sensor is stored in the storage means, as the capacity of the storage means, It is only necessary to have a capacity enough to memorize the tone signal.

The optical information reading apparatus of the second invention is characterized in that in the optical reading apparatus of the first invention described above, the signal extracting means also includes designation means for designating which part of the readout area corresponds to which shade signal should be extracted .

When reading a reading target, it is sometimes desired to know the type of the reading target from among a plurality of types of reading targets from the beginning, and to read only a reading target of a certain type. In this case, as in the second aspect of the present invention, if the signal extracting means is capable of indicating to which partial reading region the extracting signal corresponding to the extracted reading region should be extracted, the recognition of the reading target can be performed efficiently.

The optical information reading apparatus of the third invention is an apparatus for optically reading a reading target of the same type having a different size recorded on a reading surface and has an imaging surface composed of reading pixels, And an image sensor for sequentially outputting the density signals generated by the respective reading pixels and generating an image for forming an image corresponding to the image to be read on the image plane on the image plane, A designation means for manually switching a plurality of partial reading regions according to the size of a reading object; and a display means for displaying a gradation signal corresponding to a partial reading region designated by the designating means, out of the gradation signals output from the image sensor, A signal extracting means for extracting a tone signal corresponding to the partial readout region extracted by the signal extracting means, By identifying the contents represented by a density signal stored in the storage means, the storage means, characterized in that, including recognition means for recognizing a read is recorded in the read surface.

According to this configuration, when reading the same type of reading target, the partial reading area can be switched manually, and therefore, the reading target can be read according to the size. Therefore, for example, when a specific reading target is desired to be read out from a dense reading target, it is not read to the reading target only, which is unnecessary.

The designating means and the signal extracting means may be the same as those of the fourth invention, for example. That is, the designation means includes a designation key for the user to designate when designating the partial reading region according to the size of the object to be read, and the signal extracting means performs the specified partial reading The area may be a partial reading area corresponding to the shading signal to be extracted.

The specifying means, the recognizing means and the signal extracting means may be the same as those of the fifth invention, for example. That is, the designation means includes a designation key for the user to operate when designating the partial readout region according to the size of the readout object, and when the recognition is normally completed, In response to the operation of the designation key, the specified partial readout area is set as a partial readout area corresponding to the grayscale signal to be extracted, and then the recognition end signal May be returned to the state before the designation key is operated in response to reception of the designation key.

In this case, as in the configuration of the sixth aspect of the present invention, for example, when the recognition termination signal to be transmitted from the recognition means is not received within a predetermined time after the start of operation, May be returned to the state before being operated.

In the optical information reading apparatus of the seventh invention, in the optical information reading apparatus of the second, third, fourth, and fifth invention or the sixth invention, the partial reading region to be extracted by the signal extracting means And a pointing means for confirming the pointing point.

According to this configuration, the user can visually recognize the partial reading area to extract the shading signal. Thus, for example, when the partial reading area can be manually designated, the user is prompted to confirm whether or not the partial reading area is mis- .

Further, the indicating means may include a light irradiating portion for irradiating visible light, for example, as in the eighth aspect of the present invention, and the partial reading region to be extracted by the signal extracting means from another region The visible light may be irradiated from the light irradiating unit.

The instruction means may include an opening having a shape corresponding to the partial reading region in which the signal extracting means extracts the shading signal, as in the ninth invention, for example.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a schematic block diagram showing an electrical configuration of an optical information reading apparatus according to a first embodiment of the present invention; FIG. This optical information reading device is for optically reading the information 2 to be read, which is recorded on the reading surface 1.

In this optical information reading apparatus, the one-dimensional bar code and the multi-stage two-dimensional bar code shown in FIG. 2 are to be read.

As shown in FIG. 2 (a), the one-dimensional bar code is one-dimensionally arranged bar b, which is a black line, and space s, which is a white blank portion. As shown in FIG. 2 (b), the multi-stage two-dimensional barcode is a plurality of one-dimensional barcodes arranged in the row direction.

Returning to FIG. 1, this optical information reading device is provided with a light source 10 for irradiating light. The light source 10 may be an LED (light emitting diode) or a semiconductor laser. In the case of reading the information 2, the light irradiated from the light source 10 is irradiated toward the information 2. Thereby, the light according to the density of the information 2 is diffusely reflected. The diffused light enters the two-dimensional image sensor unit 12 via the lens system 11. The two-

As described above, in this embodiment, the light source 10 and the lens system 11 function as imaging means.

The two-dimensional image sensor unit 12 is constituted by, for example, a CCD (Charge Coupled Device) image sensor, and has a field of view capable of imaging the entire image of the information 2. [ The two-dimensional image sensor unit 12 is provided with an image-forming surface 12a. The reflected light incident through the lens system 12b or the like is imaged on the imaging plane 12a. The imaging plane 12a is composed of a plurality of reading pixels Pe as shown in FIG. Specifically, the reading pixels Pe of m (for example, m = 490) x n (for example, n = 640) are two-dimensionally arranged in the row direction G and the column direction R. One readout pixel Pe is, for example, a substantially square pixel having a size of 10 (占 퐉) 占 10 (占 퐉), and is constituted by a photoelectric conversion element such as a phototransistor.

When an image corresponding to the information 2 is formed on the image plane 12a of the two-dimensional image sensor unit 12, an electric signal (hereinafter referred to as "Quot;) is created.

Specifically, when a relatively black image such as a bar is imaged, a relatively high-level shading signal is generated. For example, when a relatively white image such as a space is imaged, a relatively low- Is created. When an image corresponding to a black top edge such as an edge of a bar is formed, a gradation signal having a level proportional to the area occupation rate with respect to the black reading pixel Pe is generated.

Returning to Fig. 1, the density signal generated by the reading pixel Pe is output based on the control of the sensor driving unit 13. Fig. That is, the sensing driver 13 sequentially gives the reading clock to the two-dimensional image sensor unit 12. [ As a result, the density signals are sequentially output from the two-dimensional image sensor unit 12 by scanning. The gradation signal output from the reading pixel Pe is given to the preprocessing unit 14 in sequence.

In the preprocessing section 14, processing such as sampling and holding, noise elimination, amplification, and the like is performed on the supplied grayscale signal, and then binarization processing is performed. As a result, binary data is created. The created binary data is given to the one-dimensional bar code processing unit 15a and the multi-stage two-dimensional bar code processing unit 15b.

Each of the processing sections 15a and 15b is provided with latch sections 16a and 16b for taking logical AND. In the latch units 16a and 16b, two-value data corresponding to the one-dimensional bar code and the partial reading area corresponding to the multi-stage two-dimensional bar code are latched. As a result, binary data corresponding to the partial reading area is extracted.

Here, the partial reading area refers to an area on the image plane 12a corresponding to the minimum binary data necessary for reliably recognizing the one-dimensional bar code and the multi-stage two-dimensional bar code.

That is, the one-dimensional bar code is one in which bar b and space s are arranged one-dimensionally as described with reference to the second (a). Therefore, if the bar / space arrangement pattern in the column direction can be determined, the one-dimensional bar code can be recognized. Therefore, two-value data for one row is sufficient as the minimum value data necessary for recognizing the one-dimensional barcode. Therefore, the partial reading area YE ₁ according to the one-dimensional bar code is an arbitrary one-row area on the imaging plane 12a, as shown in Fig. 4 (a).

In addition, the multi-stage two-dimensional barcode is a plurality of one-dimensional barcodes arranged in the row direction as described above. Accordingly, if the one-dimensional barcode of each stage can be recognized, the multi-stage two-dimensional barcode can be recognized. Therefore, as shown in FIG. 4 (b), the partial reading area YE ₂ according to the multistage two-dimensional bar code is divided into a plurality of areas corresponding to the number of stages (six stages in the drawing) on the imaging surface 12a do.

Returning to the first state, the latching operation in the latching portions 16a, 16b is controlled by the extraction processing section 17. [

The extraction processing unit 17 has a function of independently assigning the latch signals to the latch units 16a and 16b. The latch signal is independently applied to the latch units 16a and 16b in synchronization with the timing at which the binary data corresponding to the partial reading region is given to the latch units 16a and 16b. The transmission timing of the latch signal is determined as follows.

For example, when two-value data as shown in Fig. 5 (a) is outputted to the latch portions 16a and 16b, the extraction processing section 17 is provided with the binary data as shown in Fig. 5 And a row end signal for displaying the leading end of the row like the bar is given from the sensor driving unit 13. [ At this time, a read clock is also given to the extraction processing section 17 from the sensor driving section 13. [

In the extraction processing section 17, the above-mentioned step adrenal lakes are counted. As a result, it is possible to recognize how many rows of binary data are assigned to the latch units 16a and 16b. In the extraction processing section 17, the read clock is also counted on the leading edge. As a result, it is possible to recognize which row of the binary data is assigned to the latch units 16a and 16b.

If the binary data given to the latch units 16a and 16b are binary data corresponding to the respective partial read areas as a result of the counts, the extraction processing unit 17 displays As described above, a latch signal is transmitted to the latch portions 16a and 16b. As a result, in the latch portions 16a and 16b, while the latch signal is being applied, binary data is latched as shown in FIG. 5 (d).

Returning to Fig. 1, the binary data latched by the latch units 16a and 16b are respectively given to the data buffers 18a and 18b. As a result, in the data buffers 18a and 18b, only the latched binary data is stored. That is, in the data buffers 18a and 18b, the latch signal is given from the extraction control unit 17, and binary data is received and stored only when this latch signal is given.

Thus, in the data buffers 18a and 18b of the first embodiment, only the binary data latched corresponding to the partial reading area is stored. Therefore, the data buffers 18a and 18b need only have a capacity enough to store the binary data corresponding to the partial reading area, Quot;) < / RTI >

Specifically, the data buffer 18a to store the binary data corresponding to the partial reading area according to the one-dimensional bar code may have a capacity enough to store binary data of one row. The data buffer 18b to store the binary data corresponding to the partial reading area in accordance with the multistage two-dimensional bar code may have a capacity enough to store binary data of multiple rows.

The binary data stored in the data buffers 18a and 18b are read by the CPUs 19a and 19b. That is, in the CPU 19a (19b), when all the binary data corresponding to the partial reading area is stored in the data buffers 18a and 18b, the binary data is read. Thereafter, in the CPUs 19a and 19b, one-dimensional barcode identification processing and multistage two-dimensional barcode identification processing are executed in accordance with a unique program stored in the ROMs 20a and 20b. Specifically, each processing section is executed in the RAMs 21a and 21b each functioning as a work area.

The identification results of the CPUs 19a and 19b are given to the identification result determination unit 22, respectively. The identification result determination unit 22 determines which identification result is successfully identified based on the identification result. The determination result is transmitted to a host computer other than the drawing.

As described above, according to the optical information reading apparatus of the first embodiment, since the identification process is performed for each of the one-dimensional bar code or the multi-stage two-dimensional bar code, regardless of which is recorded on the reading surface 1, have.

Since the data buffers 18a and 18b for temporarily storing the extracted binary data need only have a capacity corresponding to the partial reading area according to the type of information, The cost can be reduced and the power consumption can be reduced as compared with the prior art in which a data buffer having a capacity is required.

Since only the minimum necessary binary data corresponding to the partial reading area is stored in the data buffers 18a and 18b, the CPUs 19a and 19b fetch binary data from the data buffers 18a and 18b The time required for reading can be shortened. Therefore, the processing time can be shortened.

In the above description, the primary bar code and the multi-stage two-dimensional bar code are employed as the reading targets. However, for example, instead of or in addition to the bar codes, character and / or matrix type 2 Dimensional bar code may be read. An example of a matrix-type two-dimensional bar code is shown in Fig. 6 (a).

In order to realize this configuration, the optical information reader is provided with a character processing unit and / or a matrix type two-dimensional bar code processing unit having the same configuration as the one-dimensional bar code processing unit 15a and the multi-stage two-dimensional bar code processing unit 15b in parallel . At this time, it is necessary to register the partial reading areas corresponding to the character and / or matrix type two-dimensional bar codes in the extraction control part 17. That is, the entire imaging plane 12a is registered as a partial reading area according to characters, and YE ₃ in the substantially square form shown in FIG. 6 (b) is registered as a partial reading area according to the matrix type two-dimensional barcode. The reason why the partial reading areas corresponding to the character and matrix type two-dimensional bar codes are performed in this manner is that image processing needs to be performed when recognizing the character and matrix type two-dimensional bar codes.

FIG. 7 is a block diagram showing an electrical configuration of an optical information reading apparatus according to a second embodiment of the present invention. FIG. In FIG. 7, the same reference numerals are used for the same functional parts as in the first embodiment.

In the first embodiment, the identification processing for a plurality of types of information is executed in parallel, and the information is recognized by finally determining whether or not the information is success. In the second embodiment, The identification processing is performed by designating the partial reading area with respect to the image, and the result is recognized as information.

7, the optical information reading apparatus according to the second embodiment is provided with a latch unit 30, a data buffer 31, a CPU One RAM 32 and one RAM 33 are provided. Further, the data buffer 31 needs to have a capacity in which the partial reading area has the capacity corresponding to the largest type so that it can be discriminated from any kind of information. Specifically, it is necessary to provide a data buffer 31 having a flow rate at which the entire image-forming surface 12a is a partial reading area.

The optical information reading apparatus of the second embodiment is also provided with ROMs 34a, 34b, 34c (corresponding to the respective types of identification processing programs) 34d (hereinafter referred to collectively as " ROM 34 ").

This optical information reading device is also provided with a switching input section 35. [ The switching input unit 35 is used by the user to designate what kind of information is to be identified. For example, the switching input unit 35 stores therein an internal switch, a host computer connectable to the optical information reading apparatus, a ROM in which a type to be designated is stored, Media and the like are applicable.

In this configuration, when any one of a plurality of types is designated by the switching input section 35, the extraction control section 17 gives the CPU 32 a signal indicating the designated type. In the CPU 32, an identification processing program corresponding to the kind displayed by the given signal is read from the corresponding ROM 34. [

In this state, when an image is formed on the two-dimensional image sensor unit 12 to start outputting a density signal, the extraction control unit 17 determines whether or not the two The latch signal is transmitted to the latch unit 30 and the data buffer 31 at a predetermined timing so that the latch unit 30 latches the value data. As a result, only the binary data corresponding to the partial reading area according to the designated type is received and stored in the data buffer 31.

On the other hand, the CPU 32 performs identification processing based on the binary data stored in the data buffer 31 in accordance with the identification processing program for identifying the specified type of information. As a result, the content displayed by the binary data is identified, and this identification content is recognized as the information (2) recorded on the reading surface (1).

As described above, according to the optical information reading apparatus of the second embodiment, when only one kind of information of a plurality of kinds of information is not to be read out, only the identification processing according to the kind can be executed, It is possible to simplify the processing and to simplify the configuration as compared with the first embodiment in which all the identification processes according to the first embodiment are executed in parallel.

Since only the minimum necessary binary data corresponding to the partial reading area is stored in the data buffer 31, the time required for the CPU 32 to read the binary data from the data buffer 31 can be shortened . Therefore, the processing time can be shortened.

In the optical information reading device of the second embodiment, for example, when only one-dimensional barcode is used, binary data corresponding to the partial reading area according to the one-dimensional barcode is stored as the data buffer 31 Or the like may be provided in a manufacturing step or the like. According to this configuration, since the capacity of the data buffer 31 can be reduced, cost reduction can be achieved and power consumption can be reduced.

In the above description, the case where only one kind of information among a plurality of kinds of information is specified is exemplified. However, for example, two or more types of information among a plurality of kinds of information may be designated.

FIG. 8 is a schematic block diagram showing an electrical configuration of an optical information reading apparatus according to a third embodiment of the present invention; FIG. In FIG. 8, the same reference numerals are used for the same functional parts as in FIG.

In the first embodiment and the second embodiment, a plurality of types of information are to be read, whereas the third embodiment is characterized in that the same kind of information is to be read.

Therefore, since the CPU 32 can use the same recognition processing program, only one ROM 34 is provided. Also, it is not necessary to give the CPU 32 a signal indicating the designated partial reading area.

When the same type of information is to be read, the same information may have different sizes. That is, for example, the one-dimensional barcode recorded on the barcode label is larger in size than the one-dimensional barcode recorded on the barcode sheet. Therefore, when the one-dimensional barcode recorded on the barcode sheet is read, if the switching input section 35 designates a small partial reading area in terms of size, the amount of binary data stored in the data buffer 31 can be reduced , The processing time in the CPU 32 can be shortened.

In addition, if a small partial reading area can be specified in terms of size, the following advantages are also obtained.

Namely, as shown in FIG. 9, for example, a barcode sheet is a sheet of 4 × 10 barcodes of 1-dimensional barcode on a sheet of paper No. 4 in Japanese Industrial Standard,

When one of the one-dimensional barcodes recorded on the bar-coatsheet is read, the one-dimensional barcode in the vicinity is likely to enter the field of view of the two-dimensional image sensor unit 12 because it is small in size. In this case, since the image is formed on the image-forming surface 12a, which is not necessary, the desired one-dimensional barcode may not be correctly identified.

Thus, if a partial reading area corresponding to a small one-dimensional barcode in terms of size is specified in the disease input unit 35, the image corresponding to the desired one-dimensional barcode can be imaged on the imaging plane 12a. Therefore, it is possible to accurately read even a small one-dimensional bar code in a dense size.

The description of the embodiments of the present invention is as described above, but the present invention is not limited to the above embodiments. For example, in the third embodiment, a case where an internal switch or the like is applied as the switching input section 35 is described. However, for example, a switching switch operable within the range of a user's hand may be applied.

More specifically, for example, it is assumed that a configuration for imaging an image of the two-dimensional image sensor unit 12 or the like is incorporated in the scanner 40 shown in FIG. In this case, the selector switch 41 is mounted at a position where the scanner 40 is held by hand. The change-over switch 41 is pressed once and released when the hand is released. On the other hand, in the extraction control section 17 (ninth draft) connected to the change-over switch 41, for example, when the change-over switch 41 is not pressed, Is designated. On the other hand, when the changeover switch 41 is pressed and a switching signal is outputted, it is judged that the partial readout area corresponding to the one-dimensional bar code smaller in size is designated.

According to this configuration, when the hand is released from the change-over switch 41, it automatically returns to the initial state, so that the partial readout area can be switched as needed. Therefore, the user interface can be improved.

In response to the fact that the switch 41 has been pressed once, it is judged that the partial reading area corresponding to the one-dimensional bar code smaller in size is specified in the extraction control unit 17, It is possible to automatically return to the initial state when a specific condition is satisfied irrespective of whether or not it is apart.

Here, in order to realize this configuration, the CPU 32 causes the extraction control section 17 to transmit a recognition end signal. The recognition end signal is a signal output by the CPU 32 when information recognition is successful.

FIG. 11 is a flowchart for explaining the flow of processing relating to the above configuration. FIG.

11, in the extraction control unit 17, when a switching signal outputted from the changeover switch 41 is received (step S1), the timer is started to be measured (step S2). Thereafter, it is determined whether or not the measurement time has reached a predetermined time and has expired (step S3). As a result, if it is determined that the time-up is not being performed, it is determined whether or not the recognition type signal has been transmitted from the CPU 32 (step S4). As a result, if it is determined that the recognition end signal has not been transmitted, the process proceeds to step S3. When it is determined in step S3 that the time has expired or that the recognition end signal has been received in step S4, the original state of the switch 41 is restored to the initial state (step S5).

As described above, when the information recognition is ended in a round-up, or when information can not be normally recognized until a predetermined time elapses, the partial readout area is automatically returned to the original initial state. Therefore, it is possible to reduce the trouble of returning the user to the initial state.

Further, in the third embodiment, it is more preferable that the designated partial reading area can be viewed by the user.

For example, as shown in Fig. 12, a guide light source 44 composed of a plurality of LEDs 43 is arranged along the longitudinal direction F of the opening 42 of the scanner 40. As shown in Fig. In this configuration, for example, when a partial reading area according to a one-dimensional barcode having a smaller size is specified, only the LED 43 corresponding to the designated partial reading area is lit, and a part When the reading area is designated, all the LEDs 43 are turned on.

According to this configuration, the user can visually recognize the partial reading area designated by looking at the LED 43 which is being turned on. Therefore, only the desired information can be reliably read.

In addition, if the guide light source 44 is also used as the light source 10, the configuration is not complicated.

As shown in FIG. 13, for example, the guide light sources 50a and 50b constituted by LEDs or semiconductor lasers for spot-irradiating the respective corners of the partial reading area are provided so as to correspond to the respective reading areas, The guide light sources 50a and 50b are selectively turned on in accordance with the designated partial readout area. According to this configuration, similarly to the above, the user can visually recognize the partial reading area.

Incidentally, as shown in FIG. 14, for example, a pair of guide light sources 60a and 60b and a pair of cylindrical lenses 61a and 61b, each of which is composed of a semiconductor laser or the like, And the light from the guide light sources 60a and 60b is irradiated to different areas in a planar manner. In this configuration, if the guide light sources 60a and 60b are selectively turned on in accordance with the designated partial readout area, the partial readout area designated by the user can be visually recognized as described above.

In addition, as shown in FIG. 15, for example, a cut portion 70 is formed at both ends of the opening 42 of the scanner 40. The guide light source 71a and the lens 71b are provided so that the light is irradiated over a wide range through the cut portion 70 and the guide light source 72a and the lens 71b are arranged so that light is irradiated in a narrow range, (72b). In this configuration, if the guide light sources 71a and 72a are selectively turned on according to the designated partial readout area, the user can visually recognize the partial readout area.

As shown in Figs. 12 to 15, in addition to visualizing the partial reading area by the user with light, the partial reading area may be provided to the user by the shape of the opening 42 of the scanner 40 I can think of poetry.

15, for example, a concave portion 80 is formed in the opening 42 of the scanner 40, and the width of the concave portion 80 is smaller than that of the one-dimensional bar code Width. With this configuration, when the user reads the small one-dimensional bar code on the size side, if the scanner 40 is positioned so that the width of the concave portion 80 corresponds to the width of the one-dimensional bar code to be read, The image corresponding to the one-dimensional bar code can be imaged on the image-forming surface 12a corresponding to the partial reading area along the one-dimensional bar code.

17, the convex portions 90 are respectively attached to both end portions of the openings 42 of the scanner 40, and the convex portions 90 corresponding to the longitudinal direction F of the openings 42 90 to the width of a large one-dimensional bar code in terms of size. With this configuration, when the user reads a large one-dimensional barcode in terms of size, when the scanner 40 is positioned so that the width of the convex portion 90 corresponds to the width of the one-dimensional barcode to be read, The image corresponding to the large one-dimensional bar code can be imaged on the image forming surface 12a corresponding to the partial reading area according to the one-dimensional bar code.

In the above-described embodiments, the case where two partial reading areas can be designated is described. However, for example, as in the first embodiment or the second embodiment, even if three or more partial reading areas can be designated do. In this case, it is conceivable to provide two or more change-over switches 41. It is also conceivable that a plurality of the concave portions 80 and the convex portions 90 are provided so as to correspond to the designated partial reading region.

In the first embodiment, the bar code, the multi-stage two-dimensional bar code, and the matrix type two-dimensional bar code are described as one unit, but various types included in the bar code or the like may be used as one unit.

Specifically, the bar code includes a kind such as JAN, EAN, UPC, ITF, Code 39, Code 93, Code 128 in addition to NW7 shown in the second (a) The multistage two-dimensional bar code has the same kind as Code 16k and PDF 417 in addition to Code 49 shown in the second (b).

In addition, the matrix type two-dimensional bar code includes a data code, a Maxi code, a Cpcode, a QR code, a ruler code, and an array tag in addition to the data code shown in FIG. 6 (a).

Therefore, for example, the one-dimensional bar code processing unit may be divided into NW7 processing unit, JAN processing unit, EAN processing unit, and so on. Similarly, the multi-stage two-dimensional barcode processing unit may be divided into a Code49 processing unit, a Code16k processing unit, a PDF417 processing unit, and a matrix type two-dimensional barcode processing unit, such as a Datacode processing unit, a Vericode processing unit, a Maxicode processing unit,

According to this configuration, for example, the identification process for the one-dimensional bar code can be executed in parallel for each type, so that the processing time can be drastically shortened.

In the above embodiments, a two-dimensional image sensor is used as an image sensor. However, the present invention can also be applied to a case where a one-dimensional image sensor is employed as the image sensor.

In addition, it is possible to carry out various design changes within the scope of the present invention.

As described above, according to the optical information reading apparatus of the first aspect of the present invention, since the identification processing according to the type of the reading object is performed independently of each other, the format of the one- dimensional barcode, the multi- Whichever of the other read objects is recorded on the read surface, the read object can be reliably identified.

In addition, as the capacity of the storage means for storing the density signal after extraction, it suffices to have a capacity enough to store the density signal corresponding to the partial reading region corresponding to a part of all the density signals output from the image sensor. Therefore, cost reduction can be achieved and power consumption can be reduced.

Since the storage means stores only the shading signal corresponding to the partial reading region according to the type of the reading object and does not store the shading signal (low level) of the other portion, it is possible to shorten the reading time, The time can be shortened.

According to the optical information reading apparatus of the second invention, only a specific kind of reading target among a plurality of types of reading targets can be efficiently read.

In the same manner as in the first aspect of the invention described above, only the tone signal corresponding to the partial reading region corresponding to the type of the reading object is stored in the memory means, and the tone signal (low level) And the identification processing time can be shortened.

According to the optical information reading apparatus of the third invention, the reading object can be read according to the size. Therefore, no unnecessary reading target which is not the object is read. Therefore, the reading object can be reliably identified.

In the same manner as in the first and second aspects of the present invention, since only the shading signal corresponding to the partial reading region according to the type of the reading object is stored in the storage means, and the shading signal (low level) The signal reading time and the identification processing time can be shortened.

According to the optical information reading apparatuses of the fourth to sixth aspects of the invention, once the partial reading area is switched, the state returns to the state before the automatic switching, thereby saving the user's labor. Therefore, the user interface can be improved.

According to the optical information reading apparatuses of the seventh to ninth aspects, since the partial reading region designated to the user can be visually recognized, execution of the identification processing of the reading object in a state in which the designation of the partial reading region is erroneous can be prevented . Therefore, only a desired read object can be reliably identified.

Claims (9)

There is provided an apparatus for optically reading a plurality of types of read objects to be recorded on a read surface, the apparatus comprising an image forming surface composed of read pixels, and a density signal corresponding to a density of an image formed on the image forming surface is shared for each of the read pixels An image sensor for sequentially outputting the density signals generated by the respective read pixels; an image forming means for forming an image corresponding to a read object recorded on the read surface on the image forming surface; Signal extracting means for extracting only a gray-scale signal corresponding to a plurality of partial readout regions according to the type of the readout object, storage means for storing a gray-scale signal corresponding to the partial readout region extracted by the signal extracting means, And contents indicated by the shading signal stored in the storage means are identified according to the type of each read object, To optical information reading apparatus, characterized in that, including recognition means for recognizing that a successful read of the read target. The optical information reading apparatus according to claim 1, further comprising designating means for designating, in the signal extracting means, which one of the partial reading regions should be extracted. There is provided an apparatus for optically reading a read object of the same type having a different size to be recorded on a read surface, the apparatus comprising: an image forming surface composed of read pixels; and a density signal in accordance with the density of an image formed on the image surface, And an imaging means for sequentially outputting the density signals generated by the respective reading pixels, an imaging means for imaging an image corresponding to the reading target recorded on the reading surface onto the imaging surface, A signal extracting means for extracting a density signal corresponding to a partial reading region specified by the designating means from among the density signals outputted from the image sensor, Storage means for storing a density signal corresponding to the partial reading region extracted by the signal extracting means, And identification means for recognizing the content to be displayed by the reproduced tone signal so as to recognize the read target recorded on the read surface. 4. The apparatus according to claim 2 or 3, wherein the designation means includes a designation key for a user to operate when designating a partial reading area according to the size of the reading object, and the signal extracting means And the specified partial reading area is set as a partial reading area corresponding to the density signal to be extracted only for the predetermined period of time. The information processing apparatus according to claim 2 or 3, wherein the designation means includes a designation key for a user to operate when designating a partial reading area according to the size of the reading object, and when the recognition is normally completed, In response to the operation of the designated key, the specified partial reading area is made to be a partial reading area corresponding to a shading signal to be extracted, and then, In response to reception of the recognition end signal from the recognition means, to return to the state before the designation key is operated. 6. The apparatus according to claim 5, wherein, when the recognition termination signal to be transmitted from the recognition means is not received within a predetermined time after the start of operation, the signal extraction means returns to the state before the designation key is operated unconditionally Wherein the optical information reading device comprises: The image processing apparatus according to any one of claims 2, 3, 4, 5, and 6, further comprising an instruction means for allowing the user to visually recognize a partial readout area to be extracted by the signal extracting means The optical information reading apparatus comprising: 8. The apparatus according to claim 7, wherein the indicating means includes a light irradiating portion for irradiating visible light, and the light irradiating portion irradiates the visible light from the light irradiating portion so that the partial reading region, The optical information reading apparatus comprising: 9. The optical information reading apparatus according to claim 7 or 8, wherein the instruction means includes an opening having a shape corresponding to the partial reading region to which the signal extracting means extracts the shading signal.