Code symbol reading system having adaptive autofocus
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G06K-007/10
G06K-007/14
G02B-003/14
출원번호
US-0818528
(2015-08-05)
등록번호
US-9582698
(2017-02-28)
발명자
/ 주소
Todeschini, Erik
출원인 / 주소
Hand Held Products, Inc.
대리인 / 주소
Additon, Higgins & Pendleton, P.A.
인용정보
피인용 횟수 :
1인용 특허 :
218
초록▼
A system for reading code symbols includes an imaging subsystem that includes a focusing module and an image processor. The image processor selects an initial, predicted focal distance for the imaging subsystem's focusing module with respect to a code symbol. The focal distance for each successfully
A system for reading code symbols includes an imaging subsystem that includes a focusing module and an image processor. The image processor selects an initial, predicted focal distance for the imaging subsystem's focusing module with respect to a code symbol. The focal distance for each successfully decoded code symbol is stored in memory, and a weighted average of a pre-selected number of memorized focal distances is used to calculate the next initial, predicted focal distance.
대표청구항▼
1. A system for reading code symbols, comprising: an imaging subsystem for capturing images within the imaging subsystem's field of view, the imaging subsystem including a focusing module; andan image processor configured for: selecting an initial, predicted focal distance for the imaging subsystem'
1. A system for reading code symbols, comprising: an imaging subsystem for capturing images within the imaging subsystem's field of view, the imaging subsystem including a focusing module; andan image processor configured for: selecting an initial, predicted focal distance for the imaging subsystem's focusing module;processing an image of a code symbol captured by the imaging subsystem in order to decode the code symbol; andstoring in memory the focal distance associated with the decoded code symbol;calculating a weighted moving average of the stored focal distances; andselecting the initial, predicted focal distance based on the calculated, weighted moving average of the stored focal distances. 2. The system for reading code symbols according to claim 1, wherein the image processor is configured to perform an autofocus routine if processing the captured image of the code symbol at the initial, predicted focal distance fails to decode the code symbol. 3. The system for reading code symbols according to claim 1, wherein the image processor is configured to perform an autofocus routine if the number of memorized focal distances associated with previously decoded code symbols is less than a predetermined minimum. 4. The system for reading code symbols according to claim 1, wherein the imaging subsystem detects the presence of a code symbol within the imaging subsystem's field of view. 5. The system for reading code symbols according to claim 1, comprising an object detection subsystem for detecting the presence of an object within the imaging subsystem's field of view. 6. The system for reading code symbols according to claim 1, comprising a hand-supportable housing, wherein the imaging subsystem and image processor are disposed within the hand-supportable housing. 7. The system for reading code symbols according to claim 1, comprising an input/output subsystem for outputting system signals. 8. A system for reading code symbols, comprising: an imaging subsystem for capturing images, the imaging subsystem comprising a focusing module; andan image processor configured for: selecting an initial, predicted focal distance for the imaging subsystem's focusing module;processing an image of a code symbol captured by the imaging subsystem in order to decode the code symbol; andstoring in memory the focal distance associated with the decoded code symbol;wherein the image processor is configured to select the initial, predicted focal distance as a function of memorized focal distances associated with previously decoded code symbols if the number of memorized focal distances associated with previously decoded code symbols is equal to or greater than a predetermined minimum. 9. The system for reading code symbols according to claim 8, wherein the image processor is configured to perform an autofocus routine if processing the captured image of the code symbol at the initial, predicted focal distance fails to decode the code symbol. 10. The system for reading code symbols according to claim 8, wherein the imaging subsystem detects the presence of a code symbol within the imaging subsystem's field of view. 11. The system for reading code symbols according to claim 8, comprising an object detection subsystem for detecting the presence of an object within the imaging subsystem's field of view. 12. The system for reading code symbols according to claim 8, comprising a hand-supportable housing, wherein the imaging subsystem and image processor are disposed within the hand-supportable housing. 13. The system for reading code symbols according to claim 8, comprising an input/output subsystem for outputting system signals. 14. A system for reading code symbols, comprising: an imaging subsystem for capturing images within the imaging subsystem's field of view, the imaging subsystem including a focusing module; andan image processor configured for: selecting an initial, predicted focal distance for the imaging subsystem's focusing module with respect to a code symbol;processing one or more images of a code symbol captured by the imaging subsystem at the initial, predicted focal distance;if processing a predetermined number of captured images of a code symbol fails to decode the code symbol, then performing an autofocus routine; andif processing a captured image of the code symbol decodes the code symbol, then storing in memory the focal distance associated with the decoded code symbol;calculating a weighted moving average of the focal distances associated with decoded code symbols stored in memory;selecting the initial, predicted focal distance based on the calculated, weighted moving average of the stored focal distances. 15. The system for reading code symbols according to claim 14, wherein the image processor is configured to store in memory the initial, predicted focal distance associated with the decoded code symbol if processing a captured image of a code symbol at the initial, predicted focal distance decodes the code symbol. 16. The system for reading code symbols according to claim 14, wherein the image processor is configured to perform an autofocus routine if the number of memorized focal distances associated with previously decoded code symbols is less than a predetermined minimum. 17. The system for reading code symbols according to claim 14, wherein, the image processor is configured to process one or more additional captured images of the code symbol after the image processor performs an autofocus routine. 18. The system for reading code symbols according to claim 14, wherein the imaging subsystem detects the presence of a code symbol within the imaging subsystem's field of view. 19. The system for reading code symbols according to claim 14, comprising an object detection subsystem for detecting the presence of a code symbol within the imaging subsystem's field of view. 20. The system for reading code symbols according to claim 14, comprising a hand-supportable housing, wherein the imaging subsystem and image processor are disposed within the hand-supportable housing.
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