JP5441200B1 - Bar code reading apparatus and bar code reading method - Google Patents

Abstract

A technique capable of improving the reliability of barcode reading is provided.
A bar code reader (10) projects light onto a bar code (18), receives light reflected from the bar code (18), converts it into an electrical signal, and generates a light reception signal, and a light reception signal generation. Among the received light signals generated by the unit 11, the filter circuit 13 that generates a filter signal, the window detection circuit 14 that determines whether the filter signal includes bar pattern information, and the filter signal includes bar pattern information. When it is determined that the filter signal is not included, the filter signal is selected. When it is determined that the filter signal includes bar pattern information, the switch circuit 15 that selects the light reception signal and the signal selected by the switch circuit 15 are binarized. A binary signal generation circuit 16 that generates a binary signal and a decode circuit 17 that decodes the binary signal.
[Selection] Figure 2

Description

  The present invention relates to a barcode reading apparatus and a barcode reading method.

  As this type of technology, Patent Document 1 discloses a technology for collecting information encoded in bar and space of a bar code by projecting a light beam onto the bar code and a photodiode obtaining the reflected light. doing. The photocurrent output from the photodiode is filtered by a low-pass filter.

Special table 2008-518320

  Incidentally, a signal obtained by receiving reflected light from a barcode and converting it into an electrical signal includes noise such as paper noise and photoelectric conversion noise. In order to remove noise, a low-pass filter may be provided after the signal obtained by receiving the reflected light and converting it to an electrical signal. However, if the cutoff frequency of the low-pass filter is too low, the noise can be removed, but the bar pattern The signal is affected and the barcode cannot be read correctly. For the electrical signal in the quiet area of the barcode, pass the low-pass filter with a low cutoff frequency, and for the electrical signal in the barcode pattern area, do not pass the low-pass filter, or pass the low-pass filter with a high cutoff frequency. If it is allowed to pass, it is considered that the barcode can be read more reliably than in the prior art.

  An object of the present invention is to provide a technique capable of improving the reliability of barcode reading.

According to a first aspect of the present invention, a light receiving signal generating means for projecting light on a bar code, receiving reflected light from the bar code, converting it into an electric signal and generating a light receiving signal, and the light receiving signal generation Filter means for generating a filter signal by blocking a frequency component equal to or higher than a predetermined cut-off frequency among the received light signals generated by the means, and bar pattern information is included in the filter signal generated by the filter means A bar pattern information presence / absence judging means for judging whether or not, a signal selecting means for selecting one of the received light signal and the filter signal, and binarizing the signal selected by the signal selecting means. Binary signal generating means for generating a signal; and decoding means for decoding the binary signal generated by the binary signal generating means, The signal selection means selects the filter signal when the bar pattern information presence / absence determination means determines that the bar pattern information is not included in the filter signal, and the bar pattern information presence / absence determination means determines the filter signal as the filter signal. When it is determined that the bar pattern information is included, a bar code reader is provided that selects the light reception signal.
According to a second aspect of the present invention, a step of projecting light onto a bar code, receiving reflected light from the bar code, converting it into an electrical signal, and generating a received light signal; Generating a filter signal by cutting off a frequency component equal to or higher than the cut-off frequency, and selecting the filter signal if the filter signal does not include bar pattern information, and including the bar pattern information in the filter signal If so, a barcode reading method is provided, comprising: selecting the received light signal; binarizing the selected signal to generate a binary signal; and decoding the binary signal. Is done.
According to a third aspect of the present invention, a received light signal generating means for projecting light onto a barcode, receiving reflected light from the barcode, converting it to an electrical signal and generating a received light signal, and the received light signal generation A first filter means for generating a first filter signal by blocking a frequency component equal to or higher than a first cut-off frequency among the light reception signals generated by the means; and among the light reception signals generated by the light reception signal generation means , Second filter means for generating a second filter signal by cutting off a frequency component equal to or higher than the second cut-off frequency, which is higher than the first cut-off frequency, and the first filter generated by the first filter means A bar pattern information presence / absence judging means for judging whether or not the signal contains bar pattern information, and one of the signals of the first filter signal and the second filter signal. A signal selection means for selecting the signal, a binary signal generation means for binarizing the signal selected by the signal selection means to generate a binary signal, and the binary signal generated by the binary signal generation means Decoding means, and the signal selection means, when the bar pattern information presence / absence determination means determines that the previous filter pattern description information is not included in the first filter signal, the first filter signal A bar code reader is provided that selects the second filter signal when the bar pattern information presence / absence determining means determines that the bar pattern information is included in the first filter signal.
According to a fourth aspect of the present invention, a step of projecting light onto a bar code, receiving reflected light from the bar code, converting it into an electrical signal and generating a received light signal, A step of generating a first filter signal by cutting off a frequency component equal to or higher than one cut-off frequency; A step of generating a second filter signal; and if the first filter signal does not include bar pattern information, the first filter signal is selected, and the first filter signal includes the bar pattern information. In some cases, the method includes: selecting the second filter signal; binarizing the selected signal to generate a binary signal; and decoding the binary signal. Code reading method is provided.
According to a fifth aspect of the present invention, a received light signal generating means for projecting light onto a barcode, receiving reflected light from the barcode, converting it into an electrical signal and generating a received light signal, and generating the received light signal A first filter means for generating a first filter signal by blocking a frequency component equal to or higher than a first cut-off frequency among the light reception signals generated by the means; and among the light reception signals generated by the light reception signal generation means , Second filter means for generating a second filter signal by blocking a frequency component equal to or higher than the second cutoff frequency which is higher than the first cutoff frequency, and the second filter generated by the second filter means A bar pattern information presence / absence judging means for judging whether or not the signal contains bar pattern information, and one of the signals of the first filter signal and the second filter signal. A signal selection means for selecting the signal, a binary signal generation means for binarizing the signal selected by the signal selection means to generate a binary signal, and the binary signal generated by the binary signal generation means Decoding means, and the signal selection means, when the bar pattern information presence / absence determination means determines that the bar pattern information is not included in the second filter signal, the signal selection means outputs the first filter signal. A bar code reader is provided that selects and selects the second filter signal when the bar pattern information presence / absence determining means determines that the bar pattern information is included in the second filter signal.
According to a sixth aspect of the present invention, a step of projecting light onto a bar code, receiving reflected light from the bar code, converting it into an electrical signal and generating a received light signal, A step of generating a first filter signal by cutting off a frequency component equal to or higher than one cut-off frequency; A step of generating a second filter signal; and if the second filter signal does not include bar pattern information, the first filter signal is selected, and the second filter signal includes the bar pattern information. In some cases, the method includes: selecting the second filter signal; binarizing the selected signal to generate a binary signal; and decoding the binary signal. Code reading method is provided.

  According to the present invention, when decoding a barcode, a signal that has passed through a low-pass filter having a low cutoff frequency is used for the quiet area, and the bar pattern area is not passed through the low-pass filter, or A signal that has passed through a low-pass filter having a high cutoff frequency is used. Therefore, the reliability of barcode reading can be improved.

FIG. 1 is a functional block diagram of a barcode reader. (First embodiment) FIG. 2 is a functional block diagram of the barcode reader. (Second Embodiment) FIG. 3 is a diagram illustrating an example of a light reception signal. (Second Embodiment) FIG. 4 is a functional block diagram of the barcode reader. (Third embodiment)

(First embodiment)
The first embodiment will be described below with reference to FIG. In the present embodiment, the barcode reader 1 (barcode reader) includes a light reception signal generation unit 2 (light reception signal generation means), a filter circuit 3 (filter means), and a window detection circuit 4 (bar pattern information presence / absence determination means). ), A switch circuit 5 (signal selection means), a binary signal generation circuit 6 (binary signal generation means), and a decoding circuit 7 (decoding means).

  The received light signal generation unit 2 is a part that projects light onto a barcode, receives reflected light from the barcode, converts it into an electrical signal, and generates a received light signal.

  The filter circuit 3 is a circuit that generates a filter signal by blocking a frequency component equal to or higher than a predetermined cut-off frequency in the light reception signal generated by the light reception signal generation unit 2. The predetermined cut-off frequency is a frequency that affects the bar pattern signal but can determine the presence or absence of the bar pattern from the filter signal.

  The window detection circuit 4 is a circuit that determines whether or not the bar signal information is included in the filter signal generated by the filter circuit 3.

  The switch circuit 5 is a circuit that selects one of the light reception signal and the filter signal.

  The binary signal generation circuit 6 is a circuit that generates a binary signal by binarizing the signal selected by the switch circuit 5.

  The decode circuit 7 is a circuit that decodes the binary signal generated by the binary signal generation circuit 6. The decoded data is transmitted to the host device by communication means (not shown).

  When the window detection circuit 4 determines that the filter signal does not include the bar pattern information, the switch circuit 5 selects the filter signal, and the window detection circuit 4 includes the bar pattern information in the filter signal. If it is determined, the received light signal is selected.

  According to the above configuration, when decoding a barcode, a signal that has passed a low-pass filter with a low cutoff frequency is used for the quiet area, and a signal that does not pass the low-pass filter is used for the bar pattern area. To do. Therefore, reliable reading of the barcode can be realized.

(Second Embodiment)
Next, a second embodiment of the present invention will be described with reference to FIGS. In this embodiment, the barcode reader 10 (barcode reader) includes a light reception signal generation unit 11 (light reception signal generation means), an amplification circuit 12 (amplification means), a filter circuit 13 (filter means), and window detection. A circuit 14 (bar pattern information presence / absence determination means), a switch circuit 15 (signal selection means), a binary signal generation circuit 16 (binary signal generation means), and a decode circuit 17 (decode means) are configured. Has been.

  The received light signal generation unit 11 is a part that projects a barcode label 19 on which the barcode 18 is printed, receives reflected light from the barcode 18, converts it into an electrical signal, and generates a received light signal. The light reception signal generation unit 11 generates a light reception signal as an electric signal by receiving a light projection unit 20 that projects light onto the barcode 18 of the barcode label 19 and reflected light from the barcode 18. And a light receiving unit 21 such as a CCD image sensor. An example of the received light signal is shown in FIG. The horizontal axis in FIG. 3 is time, and the vertical axis is the voltage of the light reception signal output from the light receiving unit 21. It shows that it is the reflected light from a whiter part, so that a voltage is high. As shown in FIG. 3, the received light signal is roughly divided into a bar pattern region and two quiet regions sandwiching the bar pattern region. The bar pattern area is a portion corresponding to the area where the bar pattern is printed. The two quiet areas are portions corresponding to white areas provided so as to sandwich the area where the bar pattern is printed.

  The amplifier circuit 12 is a circuit that amplifies the light reception signal output from the light reception signal generation unit 11.

  The filter circuit 13 is a circuit that generates a filter signal by blocking a frequency component equal to or higher than a predetermined cutoff frequency in the light reception signal amplified by the amplifier circuit 12. The predetermined cut-off frequency is a frequency that affects the bar pattern signal but can determine the presence or absence of the bar pattern from the filter signal.

  The window detection circuit 14 is a circuit that determines whether or not the bar signal information is included in the filter signal generated by the filter circuit 13. The window detection circuit 14 determines whether or not the bar pattern information is included in the filter signal by comparing the differential value of the filter signal generated by the filter circuit 13 with a predetermined value. Specifically, the window detection circuit 14 outputs HIGH based on the filter signal generated by the filter circuit 13 when the filter signal includes bar pattern information, and the filter signal includes the bar pattern information. If not, LOW is output. In the present embodiment, the window detection circuit 14 includes a differentiation circuit 22, an absolute value circuit 23, a comparator 24, a variable reference voltage generation circuit 25, a one-shot multivibrator 26, and a pulse width adjustment variable capacitor 27. And is composed of. The differentiation circuit 22 is a circuit that generates a differential signal by time-differentiating the filter signal generated by the filter circuit 13. The absolute value circuit 23 is a circuit that acquires the absolute value of the differential signal generated by the differentiating circuit 22 and generates an absolute value signal. The comparator 24 is a circuit that compares the absolute value signal generated by the absolute value circuit 23 with the reference voltage (predetermined value) generated by the variable reference voltage generation circuit 25. The comparator 24 outputs HIGH when the absolute value signal is equal to or higher than the reference voltage, and outputs LOW when the absolute value signal is lower than the reference voltage. The one-shot multivibrator 26 is a retriggerable one-shot multivibrator. The one-shot multivibrator 26 outputs LOW in the stable period. When the output of the comparator 24 becomes HIGH, the one-shot multivibrator 26 outputs HIGH for a predetermined time set by the pulse width adjusting variable capacitor 27 from that time. The capacitance of the pulse width adjusting variable capacitor 27 is set such that the predetermined time set by using the pulse width adjusting variable capacitor 27 is longer than the time corresponding to the width of the thickest bar of the barcode. It is preferable to set to. With the above configuration, the window detection circuit 14 outputs HIGH based on the filter signal generated by the filter circuit 13 when the bar signal information is included in the filter signal, and the bar pattern information is included in the filter signal. If not, LOW is output. Here, as shown in FIG. 3, the bar pattern region is a signal with undulations, and the quiet region is a signal with almost no undulations. Therefore, the window detection circuit 14 outputs HIGH when it is a bar pattern area (window area), and outputs LOW when it is a quiet area.

  The switch circuit 15 is a circuit that selects one of the light reception signal amplified by the amplifier circuit 12 and the filter signal generated by the filter circuit 13. Based on the output of the window detection circuit 14, the switch circuit 15 selects one of the light reception signal amplified by the amplification circuit 12 and the filter signal generated by the filter circuit 13. The switch circuit 15 selects the light reception signal amplified by the amplifier circuit 12 when the output of the window detection circuit 14 is HIGH, and selects the filter signal generated by the filter circuit 13 when the output of the window detection circuit 14 is LOW. select.

  The binary signal generation circuit 16 is a circuit that generates a binary signal by binarizing the signal selected by the switch circuit 15.

  The decode circuit 17 is a circuit that decodes the binary signal generated by the binary signal generation circuit 16. The decoded data is transmitted to the host device by communication means (not shown).

  Next, the operation of the barcode reader 10 will be described.

  First, the light reception signal generation unit 11 projects light onto the barcode label 19 on which the barcode 18 is printed, receives the reflected light from the barcode 18 and converts it into an electrical signal, as shown in FIG. Starts output of received light signal. The light reception signal output from the light reception signal generation unit 11 is amplified by the amplifier circuit 12 and then input to the filter circuit 13 and the switch circuit 15. The filter circuit 13 performs filter processing for noise removal. The filtered signal as the received light signal is input to the window detection circuit 14 and the switch circuit 15. The window detection circuit 14 determines whether the area is a quiet area or a bar pattern area, and outputs the determination result to the switch circuit 15. Based on the result of determination by the window detection circuit 14, the switch circuit 15 selects a filter signal output from the filter circuit 13 and outputs the selected signal to the binary signal generation circuit 16 in the quiet area. On the other hand, based on the determination result by the window detection circuit 14, the switch circuit 15 selects the light reception signal amplified by the amplification circuit 12 and outputs it to the binary signal generation circuit 16 in the case of the bar pattern region. The binary signal generation circuit 16 binarizes the filter signal or the light reception signal selected by the switch circuit 15 to generate a binary signal, and outputs the binary signal to the decoding circuit 17. The decode circuit 17 decodes the binary signal input from the binary signal generation circuit 16. The decoded data is transmitted to the host device by communication means (not shown).

  Accordingly, until the bar pattern area is detected, the switch circuit 15 operates so that the filter signal filtered by the filter circuit 13 is sent to the binary signal generation circuit 16 so as to remove noise in the quiet area. When the bar pattern area is detected, the absolute value signal exceeds the reference voltage, so that the one-shot multivibrator 26 is operated and the unfiltered received light signal is sent to the binary signal generation circuit 16, and a signal with higher resolution is obtained. Is performed.

  According to the above configuration, a signal that has passed through a low-pass filter having a low cutoff frequency is used for the quiet area of the barcode 18, and a signal that does not pass through the low-pass filter is used for the bar pattern area. Therefore, reliable reading of the barcode 18 can be realized.

  Although the second embodiment has been described above, the second embodiment has the following features.

(1) The bar code reader 10 (bar code reader) projects the bar code 18, receives the reflected light from the bar code 18, converts it into an electrical signal, and generates a received light signal 11 (Light reception signal generation means), a filter circuit 13 (filter means) that generates a filter signal by cutting off a frequency component equal to or higher than a predetermined cutoff frequency among the light reception signals generated by the light reception signal generation section 11, and a filter circuit A window detection circuit 14 (bar pattern information presence / absence determining means) for determining whether the filter signal generated by 13 includes bar pattern information, and a switch circuit 15 for selecting one of the light reception signal and the filter signal. (Signal selection means) and a binary signal generation circuit that generates a binary signal by binarizing the signal selected by the switch circuit 15 Comprises a 6 (binary signal generating means), a decoding circuit 17 for decoding a binary signal generated by the binary signal generating circuit 16 (the binary signal generating means) and (decoding means), a. The switch circuit 15 selects the filter signal when the window detection circuit 14 determines that the bar pattern information is not included in the filter signal, and the window detection circuit 14 determines that the bar pattern information is included in the filter signal. If this happens, select the light reception signal. According to the above configuration, a signal that has passed through a low-pass filter having a low cutoff frequency is used for the quiet area of the barcode 18, and a signal that does not pass through the low-pass filter is used for the bar pattern area. Therefore, reliable reading of the barcode 18 can be realized.

(2) The window detection circuit 14 determines whether bar pattern information is included in the filter signal by comparing the differential value of the filter signal with a predetermined value. According to the above configuration, it can be accurately determined whether or not the bar pattern information is included in the filter signal.

  Note that the window detection circuit 14 determines whether the bar pattern information is included based on the filter signal instead of the light reception signal. Therefore, since the determination is made based on the signal from which noise has been removed in advance, the determination accuracy is good.

(3) The barcode reading method includes a step of projecting light onto the barcode 18, receiving reflected light from the barcode, converting it into an electrical signal, and generating a received light signal, and a predetermined cutoff frequency of the received light signal A step of generating a filter signal by cutting off the above frequency components, and a filter signal is selected if the filter signal does not contain bar pattern information, and a light receiving signal if the filter signal contains bar pattern information. Selecting a signal, binarizing the selected signal to generate a binary signal, and decoding the binary signal. According to the above method, a signal that has passed through a low-pass filter having a low cutoff frequency is used for the quiet area of the barcode 18, and a signal that does not pass through the low-pass filter is used for the bar pattern area. Therefore, reliable reading of the barcode 18 can be realized.

  In addition, the said 2nd Embodiment can be changed as follows.

  In the second embodiment, the reference voltage of the comparator 24 is generated by semi-fixed hardware. Instead, it may be generated by software using a CPU or the like. Accordingly, by appropriately changing the reference voltage, the barcode 18 can be read regardless of the contrast density (the magnitude of the amplitude of the received light signal). For example, if the paper noise is large and the amplitude of the light reception signal in the bar pattern region is large, the reference voltage may be set high. When the barcode reader 10 is close to the barcode 18, paper noise is large, and the amplitude of the received light signal in the bar pattern region tends to be large. On the contrary, when the paper noise is small and the amplitude of the light reception signal in the bar pattern region is small, the reference voltage may be set low. When the bar code reader 10 is far from the bar code 18, the paper noise is small and the amplitude of the light reception signal in the bar pattern area tends to be small.

(Third embodiment)
Next, a third embodiment of the present invention will be described with reference to FIG. Here, the present embodiment will be described with a focus on differences from the second embodiment, and a duplicate description will be omitted as appropriate. In addition, in principle, the same reference numerals are assigned to components corresponding to the components of the second embodiment.

  In the second embodiment, as shown in FIG. 2, one filter circuit 13 is used. On the other hand, in this embodiment, as shown in FIG. 4, two filter circuits are used. In this embodiment, the barcode reader 10 includes a first filter circuit 28 (first filter means) and a second filter circuit 29 (second filter means) instead of the filter circuit 13.

  The first filter circuit 28 is a circuit that generates a first filter signal by blocking a frequency component equal to or higher than the first cut-off frequency in the light reception signal amplified by the amplifier circuit 12. The first cut-off frequency affects the bar pattern signal, but is a frequency at which the presence or absence of the bar pattern can be determined from the first filter signal.

  The second filter circuit 29 is a circuit that generates a second filter signal by cutting off a frequency component equal to or higher than the second cutoff frequency that is higher than the first cutoff frequency in the light reception signal amplified by the amplifier circuit 12. is there. The second cut-off frequency is a frequency that is higher than the first cut-off frequency and does not affect the bar pattern signal.

  The window detection circuit 14 determines whether bar pattern information is included in the first filter signal generated by the first filter circuit 28.

  The switch circuit 15 selects one of the first filter signal generated by the first filter circuit 28 and the second filter signal generated by the second filter circuit 29. Based on the output of the window detection circuit 14, the switch circuit 15 selects one of the first filter signal generated by the first filter circuit 28 and the second filter signal generated by the second filter circuit 29. select. The switch circuit 15 selects the second filter signal generated by the second filter circuit 29 when the output of the window detection circuit 14 is HIGH, and the first filter circuit 28 when the output of the window detection circuit 14 is LOW. The generated first filter signal is selected.

  Next, the operation of the barcode reader 10 will be described.

  First, the light reception signal generation unit 11 projects light onto the barcode label 19 on which the barcode 18 is printed, receives the reflected light from the barcode 18 and converts it into an electrical signal, as shown in FIG. Starts output of received light signal. The light reception signal output from the light reception signal generation unit 11 is amplified by the amplifier circuit 12 and then input to the first filter circuit 28 and the second filter circuit 29. In the first filter circuit 28 and the second filter circuit 29, filter processing for noise removal is performed. The first filter signal is input to the window detection circuit 14 and the switch circuit 15. The second filter signal is input to the switch circuit 15. The window detection circuit 14 determines whether the first filter signal is a quiet area signal or a bar pattern area signal, and outputs the determination result to the switch circuit 15. Based on the result of determination by the window detection circuit 14, the switch circuit 15 selects the first filter signal output from the first filter circuit 28 and outputs the selected signal to the binary signal generation circuit 16 when it is a quiet region. On the other hand, based on the determination result by the window detection circuit 14, the switch circuit 15 selects the second filter signal output from the second filter circuit 29 and outputs it to the binary signal generation circuit 16 in the case of the bar pattern region. To do. The binary signal generation circuit 16 binarizes the first filter signal or the second filter signal selected by the switch circuit 15 to generate a binary signal, and outputs the binary signal to the decoding circuit 17. The decode circuit 17 decodes the binary signal input from the binary signal generation circuit 16. The decoded data is transmitted to the host device by communication means (not shown).

  Accordingly, until the bar pattern area is detected, the switch circuit 15 is configured so that the first filter signal filtered by the first filter circuit 28 is sent to the binary signal generation circuit 16 in order to strongly remove the noise in the quiet area. Works. When the bar pattern area is detected, the absolute value signal exceeds the reference voltage, so that the one-shot multivibrator 26 operates and the second filter signal is sent to the binary signal generation circuit 16 to process the signal with a higher resolution. Done.

  According to the above configuration, a signal that has passed through the first filter having a low cutoff frequency is used for the quiet area of the barcode 18, and a signal that has passed through the second filter having a high cutoff frequency is used for the bar pattern area. Is used. Therefore, reliable reading of the barcode 18 can be realized.

  Although the third embodiment has been described above, the third embodiment has the following features.

(4) The bar code reader 10 projects the light on the bar code 18, receives the reflected light from the bar code symbol, converts it into an electrical signal, and generates a light reception signal (light reception signal generation means). ), A first filter circuit 28 (first filter means) that generates a first filter signal by blocking a frequency component equal to or higher than the first cut-off frequency among the received light signals generated by the received light signal generation unit 11, Of the received light signal generated by the signal generator 11, a second filter circuit 29 (second filter) that generates a second filter signal by blocking a frequency component equal to or higher than the second cutoff frequency that is higher than the first cutoff frequency. And a window detection circuit 14 (bar pattern) for determining whether or not the bar pattern information is included in the first filter signal generated by the first filter circuit 28. Information signal determination means), a switch circuit 15 (signal selection means) for selecting one of the first filter signal and the second filter signal, and the signal selected by the switch circuit 15 is binarized. A binary signal generation circuit 16 (binary signal generation means) that generates a binary signal and a decode circuit 17 (decode means) that decodes the binary signal generated by the binary signal generation circuit 16 are provided. The switch circuit 15 selects the first filter signal when the window detection circuit 14 determines that the bar pattern information is not included in the first filter signal, and the window detection circuit 14 includes the bar pattern information in the first filter signal. If it is determined that it is included, the second filter signal is selected. According to the above configuration, the signal that has passed through the first filter having a low cutoff frequency is used for the quiet area of the barcode 18, and the second filter having the high cutoff frequency is passed for the bar pattern area. Use a signal. Therefore, reliable reading of the barcode 18 can be realized.

(5) The window detection circuit 14 determines whether the bar pattern information is included in the first filter signal by comparing the differential value of the first filter signal with a predetermined value. According to the above configuration, it can be accurately determined whether or not the bar pattern information is included in the first filter signal.

  The window detection circuit 14 determines whether or not bar pattern information is included based on the first filter signal that is neither the light reception signal nor the second filter signal. Therefore, the determination accuracy is good because the determination is made based on the signal from which noise has been strongly removed in advance.

(6) In the barcode reading method, a step of projecting light onto the barcode 18, receiving reflected light from the barcode symbol, converting it into an electrical signal and generating a received light signal, and a first cutoff among the received light signals A step of generating a first filter signal by cutting off a frequency component equal to or higher than the frequency, and a second filter signal by cutting off a frequency component of the received light signal that is higher than the second cutoff frequency that is higher than the first cutoff frequency. And when the first filter signal does not contain bar pattern information, the first filter signal is selected, and when the first filter signal contains bar pattern information, the second filter signal is selected. A step of binarizing the selected signal to generate a binary signal, and a step of decoding the binary signal. According to the above method, a signal that has passed through a first filter having a low cutoff frequency is used for the quiet area of the barcode 18, and a signal that has passed through a second filter having a high cutoff frequency is used for the bar pattern area. Is used. Therefore, reliable reading of the barcode 18 can be realized.

  In the third embodiment, the first filter signal is input to the window detection circuit 14, but instead of the first filter signal, the second filter signal is input to the window detection circuit 14, and the bar pattern information is included in the second filter signal. You may make it determine whether it is contained. Also in this case, the second cutoff frequency of the second filter is a frequency that does not affect the signal of the bar pattern. The first cut-off frequency of the first filter is lower than the second cut-off frequency of the second filter, and is lower than the second cut-off frequency when the first filter signal is input to the window detection circuit 14. It may be.

  The barcode readers of the first to third embodiments irradiate the barcode surface while reflecting the laser beam with the rotating mirror and scanning the laser beam, and detect the reflected light from the barcode with the optical sensor. A laser scan method that converts the signal into an electrical signal and outputs it, diffuses light from a plurality of light sources (LEDs) with a lens and irradiates the barcode uniformly, and forms an image of the barcode on the CCD sensor with the lens, CCD scan system in which the CCD sensor converts the electrical signal sequentially from the end of the line sensor and outputs it. The light from multiple light sources (LEDs) is diffused by the lens, and the barcode surface is irradiated uniformly to the barcode. Any of the image sensing methods in which an image is formed on a CCD area sensor or a CMOS area sensor, converted into an electrical signal sequentially from the end of the sensor, and output. Good.

  Although the first to third embodiments have been described above, the first to third embodiments can be modified as follows.

  Although the barcode reader 1 of the first embodiment and the barcode reader 10 of the second and third embodiments are realized by hardware, they may be realized by software instead.

DESCRIPTION OF SYMBOLS 10 Barcode reader 11 Light reception signal generation part 12 Amplifier circuit 13 Filter circuit 14 Window detection circuit 15 Switch circuit 16 Binary signal generation circuit 17 Decoding circuit 18 Barcode 19 Bar code label 20 Light projection part 21 Light reception part 22 Differentiation circuit 23 Absolute Value circuit 24 Comparator 25 Variable reference voltage generation circuit 26 One-shot multivibrator 27 Variable capacitor for pulse width adjustment

Claims (9)

Light receiving signal generating means for projecting light onto a bar code, receiving reflected light from the bar code, converting it into an electric signal, and generating a light receiving signal;
Filter means for generating a filter signal by cutting off a frequency component equal to or higher than a predetermined cut-off frequency among the light reception signals generated by the light reception signal generation means;
Bar pattern information presence / absence determining means for determining whether the filter signal generated by the filter means includes bar pattern information;
Signal selection means for selecting one of the light reception signal and the filter signal;
Binary signal generation means for binarizing the signal selected by the signal selection means to generate a binary signal;
Decoding means for decoding the binary signal generated by the binary signal generating means;
With
The signal selection unit selects the filter signal when the bar pattern information presence / absence determination unit determines that the bar pattern information is not included in the filter signal, and the bar pattern information presence / absence determination unit selects the filter signal. If it is determined that the bar pattern information is included, the light reception signal is selected.
Bar code reader. The barcode reader according to claim 1,
The bar pattern information presence / absence determining means determines whether the bar pattern information is included in the filter signal by comparing a differential value of the filter signal with a predetermined value.
Bar code information reader. Projecting the barcode, receiving the reflected light from the barcode, converting it into an electrical signal and generating a received light signal;
A step of generating a filter signal by cutting off a frequency component equal to or higher than a predetermined cut-off frequency in the received light signal;
Selecting the filter signal if the filter signal does not include bar pattern information, and selecting the light reception signal if the filter signal includes the bar pattern information;
Binarizing the selected signal to generate a binary signal;
Decoding the binary signal;
including,
Bar code reading method. Light receiving signal generating means for projecting light onto a bar code, receiving reflected light from the bar code, converting it into an electric signal, and generating a light receiving signal;
First filter means for generating a first filter signal by cutting off a frequency component equal to or higher than a first cut-off frequency among the light reception signals generated by the light reception signal generation means;
Second filter means for generating a second filter signal by blocking a frequency component equal to or higher than a second cutoff frequency, which is higher than the first cutoff frequency, among the received light signals generated by the received light signal generation means; ,
Bar pattern information presence / absence determining means for determining whether or not the first filter signal generated by the first filter means includes bar pattern information;
Signal selection means for selecting one of the first filter signal and the second filter signal;
Binary signal generation means for binarizing the signal selected by the signal selection means to generate a binary signal;
Decoding means for decoding the binary signal generated by the binary signal generating means;
With
The signal selection means selects the first filter signal when the bar pattern information presence / absence determination means determines that the bar pattern information is not included in the first filter signal, and the bar pattern information presence / absence determination means Selects the second filter signal when it is determined that the bar pattern information is included in the first filter signal,
Bar code reader. The barcode reader according to claim 4, wherein
The bar pattern information presence / absence determining means determines whether or not the readable bar pattern information is included in the first filter signal by comparing a differential value of the first filter signal with a predetermined value.
Bar code reader. Projecting the barcode, receiving the reflected light from the barcode, converting it into an electrical signal and generating a received light signal;
A step of generating a first filter signal by cutting off a frequency component equal to or higher than a first cut-off frequency in the received light signal;
A step of generating a second filter signal by blocking a frequency component equal to or higher than a second cutoff frequency, which is a frequency higher than the first cutoff frequency, among the received light signals;
When the bar pattern information is not included in the first filter signal, the first filter signal is selected, and when the bar pattern information is included in the first filter signal, the second filter signal is selected. Steps,
Binarizing the selected signal to generate a binary signal;
Decoding the binary signal;
including,
Bar code reading method. Light receiving signal generating means for projecting light onto a bar code, receiving reflected light from the bar code, converting it into an electric signal, and generating a light receiving signal;
First filter means for generating a first filter signal by cutting off a frequency component equal to or higher than a first cut-off frequency among the light reception signals generated by the light reception signal generation means;
Second filter means for generating a second filter signal by blocking a frequency component equal to or higher than a second cutoff frequency, which is higher than the first cutoff frequency, among the received light signals generated by the received light signal generation means; ,
Bar pattern information presence / absence determining means for determining whether the second filter signal generated by the second filter means includes bar pattern information;
Signal selection means for selecting one of the first filter signal and the second filter signal;
Binary signal generation means for binarizing the signal selected by the signal selection means to generate a binary signal;
Decoding means for decoding the binary signal generated by the binary signal generating means;
With
The signal selection unit selects the first filter signal when the bar pattern information presence / absence determination unit determines that the bar pattern information is not included in the second filter signal, and the bar pattern information presence / absence determination unit Selects the second filter signal when it is determined that the bar pattern information is included in the second filter signal,
Bar code reader. The barcode reader according to claim 7, wherein
The bar pattern information presence / absence determining means determines whether the readable bar pattern information is included in the second filter signal by comparing a differential value of the second filter signal with a predetermined value.
Bar code reader. Projecting the barcode, receiving the reflected light from the barcode, converting it into an electrical signal and generating a received light signal;
A step of generating a first filter signal by cutting off a frequency component equal to or higher than a first cut-off frequency in the received light signal;
A step of generating a second filter signal by blocking a frequency component equal to or higher than a second cutoff frequency, which is a frequency higher than the first cutoff frequency, among the received light signals;
When the bar pattern information is not included in the second filter signal, the first filter signal is selected, and when the bar pattern information is included in the second filter signal, the second filter signal is selected. Steps,
Binarizing the selected signal to generate a binary signal;
Decoding the binary signal;
including,
Bar code reading method.

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