JP3606228B2 - Bar code reader - Google Patents

Description

【００３８】
このように走査カウント値を解読結果に割り振り、内部メモリーに解読結果と一緒に記憶することで、後から、集計処理を行った場合、どの走査線で解読が行われたかを、特定することができる。上記の場合、走査線Ｌ１ａが読み取ったデータには、偶数の走査カウント値が割り振られ、走査線Ｌ１ｂの場合には、奇数カウント値が割り振られる。
【００３９】
比較判定器１８では、Ｌ１ａとＬ１ｂの解読結果を読取開始から一定時間または、外部トリガを用いた読取時間内の集計処理を行い、データ集計終了後、各々走査線における解読結果の比較、判定を行う。
なお、比較判定器１８は、解読結果が一致しない場合には、少なくとも一方の解読結果が誤読取であるとして、これらの解読結果を破棄する。
【００４０】
すなわち、例えば読取時間内で上記のように１２３４、及び１２３５の解読結果を各走査線が得た場合、１２３４を正解データ、１２３５を誤読データとすると、走査線Ｌ１ａでは次のようなデータが得られ、
２：１２３４
４：１２３４
６：１２３５
走査線Ｌ１ｂでは次のようなデータが得られ、
３：１２３５
５：１２３５
７：？（ノーリード）
データの多数決判定を行った場合、走査線Ｌ１ａの結果は１２３４，走査線Ｌ１ｂの結果は１２３５となる。
この場合、同じバーコードラベルを走査しているのに走査線により違う結果が出来上がるため、どちらのデータが正しいかわからない、つまり解読結果にどちらかに誤読が発生していることがわかる。
よって、解読結果に信頼性がないため解読結果を破棄する。
【００４１】
上記出力器１９は、比較判定器１８からの解読結果を、図示しない外部装置に対して出力するようになっている。
【００４２】
次に、本実施形態のバーコード読取装置１０の動作について、図２を参照して説明する。
図２にて符号Ａ１で示すように、光源１１から出射された光ビームは、穴あきミラー２０の穴部分を通過して、高速回転ポリゴンミラー１２により反射されることにより、二重の走査ビームＬ１ａ，Ｌ１ｂとなって、バーコードラベル１４上のバーコード１４ａに対して走査される。
【００４３】
このとき、走査ビーム検出器１３は、符号Ａ２で示すように、この走査ビームＬ１ａ，Ｌ１ｂをそれぞれ検出して、カウントアップすると共に、そのカウント値を比較判定器１８に出力する。
この場合、走査ビーム検出器１３は、走査ビームＬ１ａに対して、偶数のカウント値を出力する場合には、走査ビームＬ１ｂに対して、奇数のカウント値を出力することになる。
【００４４】
そして、走査ビームＬ１が、バーコードラベル１４上のバーコード１４ａを走査することにより、バーコード１４ａによる反射光Ｌ２ａ，Ｌ２ｂが、再び高速回転ポリゴンミラー１２により反射されて、光源１１に向かって戻り、穴あきミラー２０で反射されて、符号Ａ３で示すように、受光部１５に入射する。
【００４５】
これにより、受光部１５は、符号Ａ４で示すように、上記反射光Ｌ２ａ，Ｌ２ｂをそれぞれ検出して、これらに対応するアナログ信号を出力する。
これを受けて、ＡＤ変換器１６は、符号Ａ５で示すように、これらのアナログ信号に基づいて、バーコード１４ａの白いバー部分と黒いバー部分に対応した二値化デジタル信号を出力する。
そして、解読器１７は、符号Ａ６で示すように、ＡＤ変換器１６からの各走査ビームＬ１ａ，Ｌ１ｂに対応する反射光Ｌ２ａ，Ｌ２ｂによる一連の二値化デジタル信号に基づいて、それぞれバーコードの解読を行ない、その解読結果が、比較判定器１８に出力される。
【００４６】
これを受けて、比較判定器１８は、符号Ａ７で示すように、走査ビーム検出器１３からの検出信号としてのカウント値に基づいて、解読器１７からの解読結果にカウント値を割り振って、バーコードの解読結果を比較する。
すなわち、比較判定器１８は、解読器１７からの反射光Ｌ２ａに対応する解読結果に偶数のカウント値を割り振り、反射光Ｌ２ｂに対応する解読結果に奇数のカウント値を割り振ることにより、偶数値と奇数値のカウント値が割り振られた二つの解読結果を得ることができる。したがって、比較判定器１８は、解読結果をカウント値により分類して、解読結果の比較を行なうことにより、走査ビームＬ１ａ，Ｌ１ｂに対応する反射光Ｌ２ａ，Ｌ２ｂの解読結果の比較を行なうことができる。
【００４７】
そして、比較判定器１８は、比較する解読結果が一致した場合には、符号Ａ８で示すように、当該解読結果が正しいものとして出力器１９に出力する。
また、比較判定器１８は、比較する解読結果が一致しない場合には、符号Ａ９で示すように、少なくとも一方の解読結果が誤読取であるとして、双方の解読結果を破棄し、再びバーコードの読取を行なうために、符号Ａ１〜符号Ａ７の作業を繰り返す。
最後に、出力器１９は、符号Ａ１０で示すように、比較判定器１８からの正しい解読結果を、外部装置に出力する。
【００４８】
このようにして、本発明実施形態によるバーコード読取装置１０によれば、走査機構である高速回転ポリゴンミラー１２による二重の走査ビームＬ１ａ，Ｌ１ｂによりバーコードラベル１４上のバーコード１４ａの走査を行なう。そして、これらの走査ビームＬ１ａ，Ｌ１ｂのパターンによるバーコードの解読結果を、比較判定器１８により比較し、双方の解読結果が一致した場合にのみ、当該解読結果を正しいものとして出力器１９を介して外部装置に出力する。したがって、出力器１９からは正しい解読結果のみが出力されることになる。
【００４９】
この場合、比較判定器１８は、各走査ビームＬ１ａ，Ｌ１ｂに対応する反射光Ｌ２ａ，Ｌ２ｂによる一連の二値化デジタル信号から成る解読結果を比較することにより、解読したバーコード全体を比較するので、より一層正確な解読結果を得ることができると共に、解読結果が一致しない場合には、双方の解読結果を破棄するので、誤った解読結果が出力されるようなことはない。
また、バーコード読取装置１０によれば、複数のバーコード読取装置を使用せずに、低コストで、高精度の解読結果を出力することができる。
【００５０】
上述した実施形態においては、走査機構として、高速回転ポリゴンミラー１２を使用しているが、これに限らず、他の走査機構を使用することも可能である。また、上述した実施形態においては、光分岐手段として、穴あきミラー２０を使用しているが、これに限らず、例えばハーフミラー，ビームスプリッタ等の他の光分岐手段を使用することも可能である。
【００５１】
【発明の効果】
以上のように、本発明によれば、走査機構により複数の走査ビームパターンを生成して、各走査ビームパターンによりバーコードの読取を行なうことによって、バーコードの解読を行ない、各走査ビームパターン毎の解読結果を比較判定器により比較して、解読結果が一致したときにのみ、その解読結果を出力器を介して外部装置に出力する。
これにより、従来のように複数個のバーコード読取装置を使用することなく、一つのバーコード読取装置にて、複数の走査ビームパターンによりバーコードの読取を行なうと共に、各走査ビームパターン毎の解読結果を比較判定器により比較して、正しい解読結果のみを出力器を介して外部装置に出力する。
【図面の簡単な説明】
【図１】本発明の一実施形態のバーコード読取装置の構成を示すブロック図である。
【図２】図１のバーコード読取装置の動作を示すフローチャートである。
【図３】従来のバーコード読取装置の一例の構成を示すブロック図である。
【符号の説明】
１０ バーコード読取装置
１０ａ走査窓
１１ 光源
１２ 高速回転ポリゴンミラー（走査機構）
１３ 走査ビーム検出器
１４ バーコードラベル
１４ａ バーコード
１５ 受光部
１６ ＡＤ変換器
１７ 解読器
１８ 比較判定器
１９ 出力器
２０ 穴あきミラー（光分岐手段）
Ｌ１ａ，Ｌ１ｂ 走査ビーム
Ｌ２ａ，Ｌ２ｂ 反射光[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a barcode reader, and more particularly to a technique for barcode reading in a barcode reader.
[0002]
[Prior art]
Conventionally, a barcode reader is configured as shown in FIG. 3, for example.
In FIG. 3, a barcode reader 100 receives reflected light from a light source 110, a high-speed rotating polygon mirror 120 as a scanning mechanism for scanning light from the light source 110, and a barcode label 130 to be read. A light receiving unit 140, an AD converter 150 that converts a detection signal from the light receiving unit 140 into a digital signal, a decoder 160 that decodes a barcode based on the digital signal from the AD converter 150, and a decoder 160 And an output device 170 for outputting the decrypted decryption result to the outside.
[0003]
The light source 110 is composed of, for example, a laser oscillator or the like, and emits a light beam such as a laser beam having a predetermined wavelength.
The high-speed rotating polygon mirror 120 is composed of mirrors attached to each surface of a polyhedron, and is rotated at high speed by a driving means (not shown) to reflect the light beam from the light source 110 and to generate the scanning beam L1. It is designed to generate.
[0004]
The light receiving unit 140 receives the reflected light L2 reflected by the bar code label 130 when the scanning beam L1 is scanned on the bar code label 130 affixed to the surface of a baggage or the like, for example. The level fluctuation of the reflected light L2 due to the bar code 131 on the code label 130 is detected, that is, an analog signal is output based on the level of the reflected light L2.
[0005]
Here, in the illustrated case, the reflected light L2 from the barcode label 130 is reflected again toward the light source 110 by the high-speed rotating polygon mirror 120 and reflected by the perforated mirror 180 as a light branching means, thereby receiving light. It is configured to enter the portion 140. In this case, the light beam from the light source 110 passes through the hole of the perforated mirror 180.
[0006]
The AD converter 150 outputs an H level signal when the analog signal from the light receiving unit 140 is equal to or greater than a predetermined threshold value, and outputs an L level signal when the analog signal is less than the threshold value. By doing so, an H level signal is output for the reflected light L2 from the white bar portion of the barcode 131 on the barcode label 130, and an L level signal is output for the reflected light L2 from the black bar portion. It has become.
[0007]
Based on the digital signal from the AD converter 150, the decoder 160 decodes the barcode 131 on the barcode label 130 from a series of digital signals obtained by scanning with the scanning beam L1, and outputs the decoded result. It is like that.
The output unit 170 outputs the decoding result decoded by the decoding unit 160 to an external device (not shown).
[0008]
According to the barcode reading apparatus 100 having such a configuration, the light beam from the light source 110 passes through the perforated mirror 180, is reflected by the high-speed rotating polygon mirror 120, and is applied to the barcode 131 on the barcode label 130. The scanning beam L1 is scanned with respect to this.
[0009]
The scanning beam L1 scans the barcode 131 on the barcode label 130, so that the reflected light L2 from the barcode 131 is reflected again by the high-speed rotating polygon mirror 120 and returns toward the light source 110 to form a hole. The light is reflected by the mirror 180 and enters the light receiving unit 140.
[0010]
Thus, the light receiving unit 140 detects the reflected light L2 and outputs an analog signal, and the AD converter 150 corresponds to the white bar portion and the black bar portion of the barcode 131 based on the analog signal. Outputs a binary digital signal.
Then, the decoder 160 decodes the barcode based on the binary digital signal from the AD converter 150, and the decoded result is output to the external device via the output unit 170.
[0011]
[Problems to be solved by the invention]
Incidentally, the reflection level of the reflected light L2 by the barcode 131 on the barcode label 130 varies depending on the material of the barcode label 130, reflection characteristics such as printing of the barcode, and the like.
[0012]
For this reason, depending on the incident condition of the scanning beam L1 on the barcode label 130, the level of the reflected light L2 of the white bar portion and the level of the reflected light L2 of the black bar portion regarding the detection signal by the light receiving unit 140 is a predetermined threshold. It becomes impossible to discriminate by the value. As a result, the barcode 131 cannot be read accurately, and the decoder 160 performs an incorrect decoding, so that the incorrect decoding result is output to the external device via the output unit 170. was there.
[0013]
In order to prevent such erroneous barcode reading, various systems are disclosed in, for example, Japanese Utility Model Laid-Open No. 2-23764, Japanese Patent Laid-Open No. 61-26185, and Japanese Patent Laid-Open No. 64-36382. .
In the barcode scanning method disclosed in Japanese Utility Model Laid-Open No. Hei 2-23764, a light beam is scanned in multiple paths on a barcode label, and the head pattern of the digital read signal in each scanning path is compared. In this case, since only a part of the digital read signal is compared, there is a problem that the accuracy is low.
[0014]
In the barcode scanning method disclosed in Japanese Patent Application Laid-Open No. 61-26185, a plurality of read data is determined as one data by majority logic for each bar portion of the barcode. In this case, the barcode reading operation is required at least three times and the determination operation is complicated, so that it takes time to decode the barcode.
[0015]
Further, in the barcode reading apparatus disclosed in Japanese Patent Application Laid-Open No. 64-36382, image data of the entire barcode is taken into a memory, and a barcode reading signal is obtained from the image data through a plurality of paths. However, in this case, since it is necessary to process the image data, the processing data becomes enormous, and it takes time to decode the barcode.
[0016]
On the other hand, there is a method of using a plurality of barcode readers, for example, in order to prevent the barcode from being read erroneously. It is necessary to compare the decryption results.
[0017]
The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a barcode decoding apparatus capable of decoding barcodes quickly and accurately with a simple configuration. To do.
[0018]
[Means for Solving the Problems]
In order to achieve this object, a barcode reader according to claim 1 of the present invention generates a scanning beam by a scanning mechanism from a light beam emitted from a light source, and scans the scanning beam on a barcode label. The reflected light is received by the light receiving unit, the analog signal from the light receiving unit is converted into a binary digital signal, the barcode is decoded by the decoder, and the decoded result is output to the external device by the output unit. A barcode reader configured as described above, wherein the scanning mechanism is configured to generate a plurality of scanning beam patterns, and detects each of the scanning beam patterns and each time a scanning beam pattern is detected. A scanning beam detector for outputting a detection result; a decoder for decoding a bar code from a series of signals obtained by scanning the scanning beam and outputting a decoding result; Based on the detection results from the scanning beam detector, the decoding results from the decoder are allocated to obtain a plurality of decoding results. The plurality of decoding results are compared, and when the decoding results match, the decoding results are output. When it does not do it, it is set as the structure provided with the comparison judgment device which discards a decoding result .
[0019]
When the barcode reader has such a configuration, the scanning mechanism generates a plurality of scanning beam patterns, and reads the barcode by each scanning beam pattern, thereby decoding the barcode and each scanning beam pattern. Each decryption result is compared by the comparison / determination unit, and only when the decryption result matches, the decryption result is output to the external device via the output unit.
[0020]
As a result, it is possible to read a barcode with a plurality of scanning beam patterns with a single barcode reading apparatus and to decode each scanning beam pattern without using a plurality of barcode reading apparatuses as in the prior art. The result is compared by the comparison / determination unit, and only the correct decoding result is output to the external device via the output unit.
If the decoding results do not match by comparison of the decoding results by the comparison / determination unit, each decoding result is discarded and the barcode is read again, so that an incorrect decoding result is output to the external device. There is nothing wrong.
[0021]
The bar code reader according to claim 2, wherein the scanning beam detector is a counter, and outputs a count value that is counted up every time a scanning beam pattern is detected, and the comparison / determination unit detects the scanning beam. Based on the count value from the decoder, the count value is assigned to the decoding result from the decoder, and the barcode decoding result is compared.
[0022]
When the bar code reader has such a configuration, the comparison / determination unit associates the decoding result from the decoder with the detection result from the scanning beam detector, that is, the count value. You can grasp and compare the results of code decoding.
[0023]
According to a third aspect of the present invention, the scanning mechanism is a high-speed rotating polygon mirror. When the barcode reader has such a configuration, a scanning beam can be easily obtained by rotating the high-speed rotating polygon mirror at a high speed.
[0024]
According to a fourth aspect of the present invention, there is provided a bar code reader comprising a light branching unit that splits the reflected light from the bar code label toward the light source via the high-speed rotating polygon mirror. The bar code reader according to claim 6 is configured such that the light branching means is a perforated mirror.
[0025]
When the barcode reader has such a configuration, the reflected light from the barcode label is easily branched from the optical path of the scanning beam scanned from the light source through the high-speed rotating polygon mirror by the light branching means such as a perforated mirror. Can be made.
[0026]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
First, a first embodiment of the barcode reading apparatus of the present invention will be described with reference to FIG.
FIG. 1 is a block diagram showing the configuration of the barcode reader according to the present embodiment.
[0027]
As shown in FIG. 1, the barcode reader 10 detects a light source 11, a high-speed rotating polygon mirror 12 as a scanning mechanism for scanning light from the light source 11, and a scanning beam from the high-speed rotating polygon mirror 12. Scanning beam detector 13, a light receiving unit 15 that receives reflected light from a barcode label 14 to be read, an AD converter 16 that converts a detection signal from the light receiving unit 15 into a digital signal, and an AD converter 16. A decoder 17 that decodes the bar code based on the digital signal from the digital signal, a comparison / determination unit 18 that compares the decoding result decoded by the decoder 17, and an output that outputs the decoding result from the comparison / determination unit 18 to the outside. And a container 19.
[0028]
The light source 11 is composed of a laser oscillator, for example, and emits a light beam such as a laser beam having a predetermined wavelength.
[0029]
The high-speed rotating polygon mirror 12 is composed of mirrors attached to each surface of the polyhedron, and is rotated at high speed by a driving means (not shown) to reflect the light beam from the light source 11 and to generate the scanning beam L1. It is designed to generate.
Here, in this case, the high-speed rotating polygon mirror 12 generates a pattern of double scanning beams L1a and L1b alternately as a scanning beam pattern.
[0030]
The scanning beam detector 13 is provided in a region where the scanning beam L1 exits from a scanning window 10a provided in the main body of the barcode reader 10, and detects each scanning beam pattern of the scanning beam L1. It has become.
In other words, the scanning beam detector 13 is specifically configured as a counter, and outputs a count value that is counted up each time the scanning beam L1 (L1a, L1b) is detected.
[0031]
The light receiving unit 15 receives the reflected light L2 reflected by the barcode label 14 when the scanning beam L1 is scanned on the barcode label 14 attached to the surface of, for example, a baggage, and the like. The level fluctuation of the reflected light L2 due to the barcode 14a on the code label 14 is detected, that is, an analog signal is output based on the level of the reflected light L2.
[0032]
Here, in the illustrated case, the reflected light L2 from the barcode label 14 is reflected again toward the light source 11 by the high-speed rotating polygon mirror 12, and is reflected by the perforated mirror 20 as the light branching means. It is configured to enter the portion 15. In this case, the light beam from the light source 11 passes through the hole of the perforated mirror 20.
[0033]
The AD converter 16 converts the analog signal from the light receiving unit 15 into a binary digital signal.
Specifically, the AD converter 16 outputs an H level signal when the analog signal from the light receiving unit 15 is equal to or greater than a predetermined threshold value, and when the analog signal is less than the threshold value. Outputs an L level signal to output an H level signal with respect to the reflected light L2 from the white bar portion of the barcode 14a on the barcode label 14, and to an L level with respect to the reflected light L2 from the black bar portion. The signal is output.
[0034]
Based on the digital signal from the AD converter 16, the decoder 17 decodes the barcode 14a on the barcode label 14 from a series of digital signals obtained by scanning with the scanning beam L1, and outputs the decoded result. It is like that.
[0035]
The comparison / determination unit 18 compares the decoding results from the decoder 17 obtained by the respective scanning beam patterns on the basis of the detection results of the scanning beam detector 13. Only when these decoding results match, The result is output to the output unit 19.
That is, the comparison / determination unit 18 sets the detection signal from the scanning beam detector 13 to an even count value when the scanning beam L1a is detected, and to an odd count value when the scanning beam L1b is detected. Based on this, a count value is assigned to the decoding result corresponding to the reflected light L2a from the decoder 17 and the decoding result corresponding to the reflected light L2b, and the decoding results of the two barcodes are compared.
[0036]
In the case shown in FIG. 1, since the scanning lines are alternately scanned L1a and L1b, the count values are assigned to the data from the decoder as follows.
[0037]
[Table 1]

[0038]
By assigning the scan count value to the decryption result in this way and storing it together with the decryption result in the internal memory, it is possible to specify which scanning line was decrypted when the aggregation process was performed later. it can. In the above case, even scan count values are assigned to the data read by the scan line L1a, and odd count values are assigned to the scan line L1b.
[0039]
The comparison / determination unit 18 performs a totaling process for a predetermined time from the start of reading the decoding results of L1a and L1b or within a reading time using an external trigger, and compares and determines the decoding results on each scanning line after the data totaling is completed. Do.
If the decryption results do not match, the comparison / determination unit 18 discards these decryption results on the assumption that at least one decryption result is erroneously read.
[0040]
That is, for example, when each scanning line obtains the decoding results of 1234 and 1235 as described above within the reading time, if 1234 is the correct answer data and 1235 is the misreading data, the following data is obtained on the scanning line L1a. And
2: 1234
4: 1234
6: 1235
In the scanning line L1b, the following data is obtained,
3: 1235
5: 1235
7 :? (No lead)
When data majority decision is performed, the result of the scanning line L1a is 1334, and the result of the scanning line L1b is 1235.
In this case, although the same bar code label is scanned, different results are obtained depending on the scanning line, so that it is understood that which data is correct, that is, there is an error in the decoding result.
Therefore, since the decryption result is not reliable, the decryption result is discarded.
[0041]
The output unit 19 outputs the decoding result from the comparison / determination unit 18 to an external device (not shown).
[0042]
Next, the operation of the barcode reader 10 of this embodiment will be described with reference to FIG.
2, the light beam emitted from the light source 11 passes through the hole portion of the perforated mirror 20 and is reflected by the high-speed rotating polygon mirror 12, thereby providing a double scanning beam. The bar code 14a on the bar code label 14 is scanned with L1a and L1b.
[0043]
At this time, as indicated by reference numeral A2, the scanning beam detector 13 detects the scanning beams L1a and L1b, counts up, and outputs the count value to the comparison / determination unit 18.
In this case, when the scanning beam detector 13 outputs an even count value to the scanning beam L1a, the scanning beam detector 13 outputs an odd count value to the scanning beam L1b.
[0044]
Then, the scanning beam L1 scans the barcode 14a on the barcode label 14, so that the reflected lights L2a and L2b from the barcode 14a are reflected again by the high-speed rotating polygon mirror 12 and return toward the light source 11. The light is reflected by the perforated mirror 20 and enters the light receiving unit 15 as indicated by reference numeral A3.
[0045]
As a result, the light receiving unit 15 detects the reflected lights L2a and L2b, respectively, and outputs analog signals corresponding to them as indicated by reference numeral A4.
In response to this, the AD converter 16 outputs a binary digital signal corresponding to the white bar portion and the black bar portion of the barcode 14a based on these analog signals, as indicated by reference numeral A5.
Then, as shown by reference numeral A6, the decoder 17 is configured to generate a barcode based on a series of binary digital signals by the reflected lights L2a and L2b corresponding to the scanning beams L1a and L1b from the AD converter 16, respectively. Decoding is performed, and the decoding result is output to the comparison / determination unit 18.
[0046]
In response to this, the comparison / decision unit 18 assigns a count value to the decoding result from the decoder 17 based on the count value as the detection signal from the scanning beam detector 13 as indicated by reference numeral A7, Compare the decoding results of the code.
That is, the comparison / decision unit 18 assigns an even count value to the decryption result corresponding to the reflected light L2a from the decryptor 17, and assigns an odd count value to the decryption result corresponding to the reflected light L2b. Two decoding results to which odd count values are assigned can be obtained. Therefore, the comparison / determination unit 18 can compare the decoding results of the reflected lights L2a and L2b corresponding to the scanning beams L1a and L1b by classifying the decoding results based on the count value and comparing the decoding results. .
[0047]
When the decryption results to be compared match, the comparison / determination unit 18 outputs the decryption result to the output unit 19 as being correct, as indicated by reference numeral A8.
In addition, when the decoded results to be compared do not match, the comparison / decision unit 18 discards both of the decoded results as indicated by reference numeral A9 and determines that at least one of the decoded results is erroneously read, and again displays the barcode. In order to perform reading, the operations of reference signs A1 to A7 are repeated.
Finally, the output unit 19 outputs the correct decoding result from the comparison / determination unit 18 to the external device as indicated by reference numeral A10.
[0048]
Thus, according to the barcode reader 10 according to the embodiment of the present invention, the barcode 14a on the barcode label 14 is scanned by the double scanning beams L1a and L1b by the high-speed rotating polygon mirror 12 which is a scanning mechanism. Do. The bar code decoding results based on the patterns of the scanning beams L1a and L1b are compared by the comparison / determination unit 18, and only when both the decoding results match, the decoding result is regarded as correct and is output via the output unit 19. Output to the external device. Therefore, only the correct decoding result is output from the output device 19.
[0049]
In this case, the comparison / decision unit 18 compares the decoded barcodes as a whole by comparing the decoding results composed of a series of binary digital signals by the reflected lights L2a and L2b corresponding to the scanning beams L1a and L1b. A more accurate decoding result can be obtained, and if the decoding results do not match, both decoding results are discarded, so that an incorrect decoding result is not output.
Further, according to the barcode reader 10, it is possible to output a highly accurate decoding result at low cost without using a plurality of barcode readers.
[0050]
In the above-described embodiment, the high-speed rotating polygon mirror 12 is used as the scanning mechanism. However, the present invention is not limited to this, and other scanning mechanisms can be used. In the above-described embodiment, the perforated mirror 20 is used as the light branching means. However, the present invention is not limited to this, and other light branching means such as a half mirror and a beam splitter can also be used. is there.
[0051]
【The invention's effect】
As described above, according to the present invention, a plurality of scanning beam patterns are generated by the scanning mechanism, and the barcode is read by each scanning beam pattern, whereby the barcode is decoded and each scanning beam pattern is read. The comparison result is compared by the comparison / determination unit, and only when the decoding result matches, the decoding result is output to the external device via the output unit.
As a result, it is possible to read a barcode with a plurality of scanning beam patterns with a single barcode reading apparatus and to decode each scanning beam pattern without using a plurality of barcode reading apparatuses as in the prior art. The result is compared by the comparison / determination unit, and only the correct decoding result is output to the external device via the output unit.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a barcode reader according to an embodiment of the present invention.
FIG. 2 is a flowchart showing an operation of the barcode reading apparatus of FIG.
FIG. 3 is a block diagram showing a configuration of an example of a conventional bar code reader.
[Explanation of symbols]
10 Barcode reader 10a Scanning window 11 Light source 12 High-speed rotating polygon mirror (scanning mechanism)
13 Scanning Beam Detector 14 Barcode Label 14a Barcode 15 Light Receiving Unit 16 AD Converter 17 Decoder 18 Comparison Judger 19 Output Device 20 Perforated Mirror (Optical Branching Unit)
L1a, L1b Scanning beams L2a, L2b Reflected light

Claims (5)

A scanning beam is generated from the light beam emitted from the light source by the scanning mechanism, the scanning beam is scanned on the bar code label, the reflected light is received by the light receiving unit, and the analog signal from the light receiving unit is binary. A barcode reader that converts the digital signal into a digital signal, decodes the barcode with a decoder, and outputs the decoded result to an external device with an output device,
The scanning mechanism is configured to generate a plurality of scanning beam patterns;
A scanning beam detector that detects each of the scanning beam patterns and outputs a detection result each time the scanning beam pattern is detected;
A decoder for decoding a barcode from a series of signals obtained by scanning the scanning beam and outputting a decoding result;
Based on the detection results from the scanning beam detector, assign the decoding results from the decoder to obtain a plurality of decoding results, compare the plurality of decoding results, and output the decoding results when the decoding results match, A bar code reader, comprising: a comparison / determination unit that discards a decoding result when they do not match . The scanning beam detector is a counter, and outputs a count value that is counted up each time a scanning beam pattern is detected. The comparison / determination unit is a decoder based on the count value from the scanning beam detector. 2. The bar code reader according to claim 1 , wherein a count value is assigned to a decoding result obtained from the data to obtain a bar code decoding result. The bar code reader according to claim 1 or 2 , wherein the scanning mechanism is a high-speed rotating polygon mirror. 4. The bar code reader according to claim 3 , further comprising a light branching unit for branching reflected light from the bar code label toward the light source via a high-speed rotating polygon mirror. 5. The barcode reader according to claim 4 , wherein the light branching means is a perforated mirror.

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