EP1261934A1 - Multiformat barkodeleser - Google Patents

Multiformat barkodeleser

Info

Publication number
EP1261934A1
EP1261934A1 EP01923310A EP01923310A EP1261934A1 EP 1261934 A1 EP1261934 A1 EP 1261934A1 EP 01923310 A EP01923310 A EP 01923310A EP 01923310 A EP01923310 A EP 01923310A EP 1261934 A1 EP1261934 A1 EP 1261934A1
Authority
EP
European Patent Office
Prior art keywords
imaging
flying
spot
barcode
subsystem
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP01923310A
Other languages
English (en)
French (fr)
Inventor
Edward C. Bremer
Alexander M. Mcqueen
Craig D. Cherry
Brad R. Reddersen
Steven A. Mcmahon
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Datalogic Scanning Inc
Original Assignee
PSC Scanning Inc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by PSC Scanning Inc filed Critical PSC Scanning Inc
Publication of EP1261934A1 publication Critical patent/EP1261934A1/de
Withdrawn legal-status Critical Current

Links

Classifications

    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06KGRAPHICAL DATA READING; PRESENTATION OF DATA; RECORD CARRIERS; HANDLING RECORD CARRIERS
    • G06K7/00Methods or arrangements for sensing record carriers, e.g. for reading patterns
    • G06K7/10Methods or arrangements for sensing record carriers, e.g. for reading patterns by electromagnetic radiation, e.g. optical sensing; by corpuscular radiation
    • G06K7/14Methods or arrangements for sensing record carriers, e.g. for reading patterns by electromagnetic radiation, e.g. optical sensing; by corpuscular radiation using light without selection of wavelength, e.g. sensing reflected white light
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06KGRAPHICAL DATA READING; PRESENTATION OF DATA; RECORD CARRIERS; HANDLING RECORD CARRIERS
    • G06K7/00Methods or arrangements for sensing record carriers, e.g. for reading patterns
    • G06K7/10Methods or arrangements for sensing record carriers, e.g. for reading patterns by electromagnetic radiation, e.g. optical sensing; by corpuscular radiation
    • G06K7/10544Methods or arrangements for sensing record carriers, e.g. for reading patterns by electromagnetic radiation, e.g. optical sensing; by corpuscular radiation by scanning of the records by radiation in the optical part of the electromagnetic spectrum
    • G06K7/10821Methods or arrangements for sensing record carriers, e.g. for reading patterns by electromagnetic radiation, e.g. optical sensing; by corpuscular radiation by scanning of the records by radiation in the optical part of the electromagnetic spectrum further details of bar or optical code scanning devices
    • G06K7/10861Methods or arrangements for sensing record carriers, e.g. for reading patterns by electromagnetic radiation, e.g. optical sensing; by corpuscular radiation by scanning of the records by radiation in the optical part of the electromagnetic spectrum further details of bar or optical code scanning devices sensing of data fields affixed to objects or articles, e.g. coded labels
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06KGRAPHICAL DATA READING; PRESENTATION OF DATA; RECORD CARRIERS; HANDLING RECORD CARRIERS
    • G06K7/00Methods or arrangements for sensing record carriers, e.g. for reading patterns
    • G06K7/10Methods or arrangements for sensing record carriers, e.g. for reading patterns by electromagnetic radiation, e.g. optical sensing; by corpuscular radiation
    • G06K7/10544Methods or arrangements for sensing record carriers, e.g. for reading patterns by electromagnetic radiation, e.g. optical sensing; by corpuscular radiation by scanning of the records by radiation in the optical part of the electromagnetic spectrum
    • G06K7/10821Methods or arrangements for sensing record carriers, e.g. for reading patterns by electromagnetic radiation, e.g. optical sensing; by corpuscular radiation by scanning of the records by radiation in the optical part of the electromagnetic spectrum further details of bar or optical code scanning devices
    • G06K7/10861Methods or arrangements for sensing record carriers, e.g. for reading patterns by electromagnetic radiation, e.g. optical sensing; by corpuscular radiation by scanning of the records by radiation in the optical part of the electromagnetic spectrum further details of bar or optical code scanning devices sensing of data fields affixed to objects or articles, e.g. coded labels
    • G06K7/10871Methods or arrangements for sensing record carriers, e.g. for reading patterns by electromagnetic radiation, e.g. optical sensing; by corpuscular radiation by scanning of the records by radiation in the optical part of the electromagnetic spectrum further details of bar or optical code scanning devices sensing of data fields affixed to objects or articles, e.g. coded labels randomly oriented data-fields, code-marks therefore, e.g. concentric circles-code
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06KGRAPHICAL DATA READING; PRESENTATION OF DATA; RECORD CARRIERS; HANDLING RECORD CARRIERS
    • G06K7/00Methods or arrangements for sensing record carriers, e.g. for reading patterns
    • G06K7/10Methods or arrangements for sensing record carriers, e.g. for reading patterns by electromagnetic radiation, e.g. optical sensing; by corpuscular radiation
    • G06K7/10544Methods or arrangements for sensing record carriers, e.g. for reading patterns by electromagnetic radiation, e.g. optical sensing; by corpuscular radiation by scanning of the records by radiation in the optical part of the electromagnetic spectrum
    • G06K7/10821Methods or arrangements for sensing record carriers, e.g. for reading patterns by electromagnetic radiation, e.g. optical sensing; by corpuscular radiation by scanning of the records by radiation in the optical part of the electromagnetic spectrum further details of bar or optical code scanning devices
    • G06K7/1092Methods or arrangements for sensing record carriers, e.g. for reading patterns by electromagnetic radiation, e.g. optical sensing; by corpuscular radiation by scanning of the records by radiation in the optical part of the electromagnetic spectrum further details of bar or optical code scanning devices sensing by means of TV-scanning

Definitions

  • the field of the present invention relates to optical reading systems and, more particularly, to optical code readers capable of reading multiple code formats that can selectively read barcodes or other symbols or indicia using either an imaging approach or a flying-spot approach.
  • CMOS-based imaging systems several one dimensional arrays of pixels oriented at different angles may be used in a crossing pattern, to provide multi-directional imaging capability.
  • flying-spot and imaging readers have drawbacks, neither type is optimum for all situations.
  • imaging readers are best suited for situations in which the imaging head can be positioned very close the target barcode. But if the target barcode is further away, an optical reader relying upon an imaging device for gathering data can have much more difficulty reading the target. This problem is due, in part, to difficulties in focusing images from distant targets onto the CCD or other imaging device, and to difficulties in illuminating a distant target using a local illumination source.
  • a drawback of handheld flying-spot laser readers is that the scan line (i.e., the path traveled by the scanning spot across the target) must usually be aimed manually at the target barcode, with a relatively high degree of accuracy, for each scan.
  • the scan line i.e., the path traveled by the scanning spot across the target
  • this drawback is relatively minor.
  • the scanning head when the barcodes being scanned are oriented randomly (e.g., when an assortment of products are being checked out at a cashier) , the scanning head must be rotated for each scan until the scan line lines up with the axis of the bar code. This can slow down the scanning process significantly.
  • flying-spot laser scanners are generally have a larger depth of field than optical readers using imaging devices. However, it is nevertheless difficult to design a flying-spot laser reader that can read well both distant targets and targets that are very close to the scanning device.
  • Two dimensional barcodes and other codes are becoming increasingly common, and include, for example, stacked codes (e.g., Code 16K, Code 49, etc.), matrix codes (e.g., DataMatrix, Code 1, Maxicode, etc.), PDF417, micro-PDF, and RSS codes.
  • stacked codes e.g., Code 16K, Code 49, etc.
  • matrix codes e.g., DataMatrix, Code 1, Maxicode, etc.
  • PDF417 e.g., PDF417
  • micro-PDF micro-PDF
  • RSS codes e.g., RSS codes.
  • two-dimensional codes may be present as part of a composite code or linked code, wherein a one-dimensional barcode appears on the same label as, and indicates the presence of, a two-dimensional barcode.
  • Reading a two-dimensional code with a flying-spot laser scanner is difficult or impossible because the data is read by the flying-spot laser scanner along either a linear scan line caused by the sweeping of the outgoing laser beam, or possibly along several scan lines at different angular orientations, depending upon the scanning pattern.
  • an imaging device is utilized to gather data over a two- dimensional imaging region, and the gathered data is then processed by specialized software algorithms in an attempt to identify features of the two-dimensional code, symbol or other indicia.
  • optical readers relying solely on an imaging device for gathering data can read two-dimensional bar codes (or in some cases both two-dimensional and one- ⁇ dimensional bar codes)
  • the relatively small depth of field of such imaging devices limits their usefulness .
  • the present invention is directed in one aspect to methods and apparatuses for reading a barcode or other symbol, indicia, character or combination thereof using either a flying-spot laser scanning device or an imaging device, or both, either selectively, sequentially or simultaneously.
  • an integrated optical reader is provided, having both a flying-spot laser scanning subsystem and an imaging subsystem. Either, or both, the flying-spot laser scanning subsystem or the imaging subsystem may be utilized to read a target, thereby allowing a single integrated optical reader to obtain the advantages and strengths of each method of gathering data.
  • Embodiments of various integrated optical readers as disclosed herein may be either fixed or portable (e.g., handheld) in nature. Particularly in handheld embodiments, various components, such as a lens, a detector, and certain signal processing circuitry, may be shared between the flying spot laser subsystem and the imaging subsystem. In fixed embodiments wherein a viewing window is used, the imaging device of the imaging subsystem may be located at a predefined area (e.g., corner) of the viewing window, or else may be located in the center of the viewing window in various hardware configurations.
  • a predefined area e.g., corner
  • Mode selection between flying-spot laser scanning and imaging may be made in a variety of fashions .
  • the selection between the flying-spot laser scanning subsystem and the imaging subsystem is based on either on a predetermined pattern (e.g. alternating), a selectable switch position, the type of barcode being read (as indicated, for example, by initial data characterization) , the target range, or a previous failed attempt to read the barcode.
  • flying-spot laser scanning and imaging enables the reading method to be tailored to the particular type of code that is being read.
  • one dimensional or linear codes may be read using the flying-spot laser subsystem
  • two-dimensional codes may be read using the imaging subsystem.
  • the flying-spot laser scanning subsystem may provide a relatively large depth of field
  • the imaging subsystem may provide the capability of capturing two-dimensional images and thus allowing more types of codes to be read, albeit with a closer range.
  • FIG. 1 is a block diagram of one embodiment of an integrated optical reader.
  • FIG. 2 is a block diagram of a proximity detector for use in an integrated optical reader as described herein.
  • FIGS. 3 through 7 are flow charts of various processes for selecting between reading by using a flying-spot laser scanning method or by using an imaging method.
  • FIG. 8 is a diagram of an integrated optical reader illustrating the relative fields of view of a flying-spot laser scanner and an imager.
  • FIG. 9 is a diagram of an integrated optical reader illustrating the relative fields of view of a multi-planar flying-spot laser scanner and an imager.
  • FIG. 10 is a diagram of a facet wheel with a hole for allowing an imaging device located beneath the facet wheel to gather data periodically.
  • FIG. 11 is a diagram of an integrated optical reader as may be implemented in a handheld optical reading device.
  • FIG. 12 is a schematic block diagram of another embodiment of an integrated optical reader.
  • FIG. 1 is a schematic block diagram of a preferred embodiment of an integrated optical reader 90 capable of performing optical reading using a flying-spot laser scanner or a pixel-based imager.
  • the integrated optical reading system 90 depicted in FIG. 1 includes a controller 300, a flying-spot front-end (or subsystem) 100, and an imaging front-end (or subsystem) 200.
  • the flying-spot front-end 100 and the imaging front-end 200 provide output data 125, 225 to the controller 300, and the controller 300 provides control signals to each of the two front-ends 100, 200.
  • the controller 300 preferably comprises a microprocessor or micro-controller (uP/uC) 310, a sufficient amount of memory to store the necessary program code (such as program code 351 and 352, described later herein) and data, and appropriate glue logic.
  • uP/uC-based controllers are generally well known in the field of imaging readers as well as in the field of flying-spot laser scanners.
  • controllers based on, for example, microprogrammed bit-slice hardware, digital signal processors, or hard-wired control logic may be used instead of a uP/uC-based controller 300.
  • Reading barcodes or other symbols or indicia using a flying-spot laser scanning method is accomplished by capturing data using the flying-spot front-end 100, and processing the captured data using the controller 300.
  • the flying-spot front-end 100 preferably includes a beam-former 130, which includes a light source 131 that projects a scanning beam 150 out to the target barcode or other symbol 60.
  • the light source 131 comprises a laser diode.
  • other types of light sources such as a He-Ne laser, other types of lasers, and/or focused beams of non-laser light may be used instead of a laser diode .
  • the beam-former 130 also preferably includes a laser driver 133 that controls whether the light beam 150 generated by the light source 131 is on or off.
  • the laser driver 133 may also control the brightness of the light beam 150.
  • Implementation of the laser driver 133 is conventional in the field of flying-spot scanners, as is the primary interface between the controller 300 and the remaining components of the beam-former 130.
  • the algorithms implemented in the controller 300 for interfacing with the laser driver 133 are also largely conventional.
  • the beam deflector 132 comprises an oscillating mirror driven by an oscillating beam dither driver (neither of which is shown in FIG. 1) , which are both conventional in the field of flying-spot scanners. Movement of the oscillating mirror causes the scanning light beam 150 to move back and forth, and to thereby trace a line-shaped path over the target barcodes or other target symbols or indicia.
  • other types of beam deflectors such as, for example, a rotating polygon with a plurality of mirrored facets may be used instead of a dithering mechanism.
  • the scanning beam 150 from the light source 131 sweeps across a target barcode (or other symbol) 60
  • the scanning beam 150 is reflected by the target 60. Because the "bars" of the barcode 60 have lower reflectivity than the "spaces" between the bars, the amount of reflected light will vary depending on whether the projected spot of scanning beam 150 is incident upon a bar or a space.
  • Reflected light 170 from the target barcode 60 is collected by appropriate collection optics (which may include lenses and/or collecting mirrors) , and directed towards a photodetector such as the photodiode 110 shown in FIG. 1.
  • a photodetector such as the photodiode 110 shown in FIG. 1.
  • the design of the collection optics and selection of an appropriate photodetector are conventional in the field of flying-spot scanners.
  • the photodiode 110 converts the variations in the incident light level into an analog signal 115 that is an electrical representation of the physical bar and space widths of the target (e.g., bar code) 60.
  • the photodiode 110 converts variations in incident light level into an analog signal that has features (i.e., peaks and valleys) which correspond (in width) to the physical width of relatively darker and relatively lighter portions of a symbol, indicia or bar code to be read.
  • the signal 115 output from the photodiode 110 is then processed by the signal processor 120.
  • the signal processor 120 includes an amplifier 121, an edge detector 122, and a noise reduction circuit 123, as illustrated in FIG. 1.
  • Alternative signal processor configurations may also be chosen, as will be apparent to those skilled in the art.
  • the amplifier 121 amplifies the signal 115 output from the photodiode 110.
  • the gain of the amplifier 121 is adjusted using an automatic gain control (AGC) system, in which an output of either the amplifier itself or another component (e.g., the noise reduction circuit 105) is fed back to control the gain of the amplifier 121.
  • AGC automatic gain control
  • the edge detector 122 locates the edges of the amplified signal output from amplifier 121 using any of a variety of techniques that are well known in the art. Suitable techniques of edge detection are described, for example, in U.S. Patent 5,463,211 (Arends et al . ) or U.S. Patent 4,000,397 (Hebert et al . ) , both of which are hereby incorporated by reference as if set forth fully herein.
  • the edge detector 122 may locate edges of the amplified signal output from amplifier 121 by detecting when the second derivative of the amplified signal is zero.
  • a noise reduction circuit 123 eliminates or reduces edges in the amplified signal attributed to noise, and operates for example, by discarding or ignoring edges detected whenever the first derivative of the amplified signal is below a threshold value.
  • the resulting output signal 125 from the signal processor 120 is a digital signal that contains an edge (i.e., a low-to-high or high-to-low transition) corresponding to each edge (i.e., a dark-to-light or light- to-dark transition) of the target barcode.
  • edge i.e., a low-to-high or high-to-low transition
  • Alternative output formats may also be used, depending on the selected signal processor configuration.
  • the output signal 125 may be formatted in a run-length encoded or other format.
  • the output signal 125 is provided to the controller 300.
  • the controller 300 includes program code 351 run by the uP/uC 310 for, among other things, controlling the input of data from the flying-spot front-end 100 and for decoding that data.
  • the program code 351 is stored in a nonvolatile memory.
  • the controller 300 receives the digital edge data in the output signal 125 from the signal processor 120.
  • the controller 300 then decodes the digital edge data to interpret the information represented by the target barcode 60 that was scanned by the flying-spot front end 100.
  • decoding is accomplished by determining the time segments between the edges contained in the output signal 125 from the signal processor 120.
  • program code 351 is used to decode the information represented in the target barcode 60 in a manner well known to those skilled in the art.
  • Design and implementation of a program 351 for decoding edge data from a flying-spot front-end may be accomplished in any conventional manner, and is considered to be well within the purview of those skilled in the art.
  • a preferred integrated optical reading system 90 is also capable of reading bar codes or other symbols or indicia using an imaging method.
  • Reading barcodes using the imaging method is preferably accomplished by capturing data using the imaging front-end 200, and processing the captured data in the controller 300.
  • the imaging front-end 200 includes an image sensor 210, an image sensor interface 220, and an illumination source 230.
  • the image sensor 210 comprises is a two-dimensional active pixel CMOS array, and the description that follows assumes that this type of image sensor is being used.
  • the image sensor 210 may comprise a rectangular two-dimensional array of CMOS pixels, or else may, for example, comprise several intersecting or crossing linear arrays of CMOS pixels, oriented at different angles.
  • An example of one type of active pixel CMOS array that may be used as image sensor 210 is described in copending U.S. Patent Application Ser.
  • the illumination source 230 is activated to illuminate the bar code, symbol or other target 60.
  • the illumination source 230 comprises a row of light emitting diodes (LEDs) .
  • LEDs light emitting diodes
  • Other types of illumination sources including, e.g., flash strobes and incandescent or fluorescent lamps) may be used instead of LEDs.
  • the illumination source may be omitted altogether, and the imaging front-end 200 can rely on ambient light to illuminate the target barcodes.
  • ambient light imaging systems are described, for example, in U.S. Patents 5,770,847 and 5,814,803, both of which are incorporated by reference as if set forth fully herein.
  • a preferred image sensor 210 is constructed as an active pixel CMOS device containing a two-dimensional array of pixels. Each pixel of the image sensor 210 detects the amount of light incident at its particular location and stores an electrical charge that varies as a function of the incident light. After the image sensor 210 has been exposed to the light 270 reflected by the target, data from all the CMOS pixels is sequentially read out in a selectable pattern (which may be row-by-row, column-by-column, or some other pattern) . The data read out from the image sensor 210 results in the generation of an analog video output signal 215.
  • the image sensor interface 220 conditions the analog video output signal 215 received from the image sensor 210 and generates an output signal 225 that generally identifies which regions of the image correspond to light areas, and which correspond to dark areas. Either analog or digital signal processing (which may include, for example, amplification and/or filtering) may be utilized in the image sensor interface 220. Preferably, the image sensor interface 220 sets the exposure time and thresholding so that the bars or relatively darker regions of the barcode or other target are reported as being dark, and the spaces or relatively lighter regions between the bars or darker regions are reported as being light, according to any of a number of techniques well known in the art. Exposure control techniques are described, for example, in copending
  • the output signal 225 of the image sensor interface 220 may comprise binary digital image data, with the two output states corresponding to the dark and light regions (i.e., pixels) of the image.
  • the output signal 225 may comprise gray-scale pixel data, or else may comprise run-length encoded binary data.
  • the analog video output signal 215 may be converted to digital form (represented by any suitable number of bits, depending upon accuracy requirements and component tolerances) by the image sensor interface 220 using an analog-to-digital (A/D) converter.
  • the analog video output signal 215 may be edge-detected in a manner similar to the photodiode output signal 115 of the flying-spot front-end 100.
  • the output of the image sensor interface 220 is provided to the controller 300. Transfer of the digital image data of the image sensor interface output signal 225 from the interface 220 to the controller 300 may be accomplished by any of a number of suitable techniques.
  • the image sensor output signal 225 may be in the form of binary video information, in which the lines of video information are sent one at a time, sequentially, with the data from individual pixels sent sequentially within each line.
  • the image sensor interface 220 may load the digital image data of the image sensor interface output signal 225 into a memory 311, such as a dual-port or shared random-access memory (RAM) , which could then be accessed by the controller 300.
  • the image sensor interface 220 may load the digital image data of the image sensor interface output signal 225 into a first-in-first-out (FIFO) buffer (not shown) .
  • FIFO first-in-first-out
  • the controller 300 includes program code 352 run by the uP/uC 310 for inputting data from the imaging front-end 200, and for decoding that data.
  • the program code 352 also controls, among other things, the illumination source 230 and the image sensor interface 220.
  • the program code 352 is stored in nonvolatile memory.
  • the data from the imaging front-end 200 may be pre-processed so that it will have the same format as the data generated by the flying-spot front-end 100. When such pre-processing is implemented, a single decoding algorithm may be used for decoding the data from the flying-spot front-end 100 and the data from the imaging front-end 200.
  • the controller 300 receives the digital image data of the image sensor interface output signal 225 from the image sensor interface 220.
  • the handling of the inputted image data depends upon the format in which it was sent. For example, if the image sensor interface 220 generates binary video information, the controller 300 will preferably take this data and store it in memory 311 (e.g., RAM) , so that the controller 300 will have access to the entirety of the pixel data necessary for decoding.
  • memory 311 e.g., RAM
  • the controller 300 After receiving the digital image data of the image sensor interface output signal 225, the controller 300 then decodes the image data to determine the information represented by the target barcode, symbol, or other indicia contained within the captured image. Preferably, decoding is accomplished by identifying which areas of the image contain barcodes or symbols or recognizable portions thereof, and then determining the information represented by those barcodes based on the patterns of light and dark pixels within the identified areas. Design and implementation of program code 352 for controlling the imaging front-end 200 and for decoding the captured image data is considered well within the purview of those skilled in the art .
  • the imaging front-end 200 may use a one-dimensional CMOS imaging array (i.e., a linear array) or a linear CCD array that only images a single line of a target at a time.
  • a linear imaging array may be used to build up a two dimensional image by moving either the imaging sensor 200 or the target across the field of view of the linear array, and capturing successive one-dimensional scans.
  • the resulting built-up image may be stored in a RAM, and, once captured, can be processed in the same manner as the two-dimensional image described above.
  • a one- dimensional image captured by a one-dimensional CMOS imaging array may be processed directly.
  • a technique might require a more precise alignment of the image sensor 210 with the target barcode or other symbol or indicia as compared to the two-dimensional system described above.
  • a preferred integrated optical reader 90 incorporates both a flying-spot front-end 100 and an imaging front-end 200 into a single system.
  • the controller 300 is able to select a ' desired reading method, and to use the selected method to try to read a target barcode, symbol or other indicia.
  • both front- ends 100, 200 are housed in a single housing behind a single window 80 that is transparent to the relevant frequencies of light.
  • the integrated optical reader 90 may be either employed as a fixed optical reader or as a handheld optical reader.
  • the controller 300 selects and executes program code 351.
  • program code 351 When program code 351 is executing, the controller 300 provides appropriate control signals to the flying-spot front-end
  • the controller 300 selects and executes program code 352.
  • program code 352 When program code 352 is executing, the controller 300 provides appropriate control signals to the imaging front-end 200, receives input data from the imaging front-end 200, and decodes that data, as described previously herein.
  • the output data 305 from the controller 300 represents the information or value of one or more target barcodes, symbols or other indicia and may be provided in any desired parallel, serial or other format including, for example, a Centronics, RS232, or Universal Serial Bus (USB) format.
  • USB Universal Serial Bus
  • the output data 305 from the controller 300 is always provided in the same format, regardless of which front-end 100, 200 was used to read the target barcode or symbol .
  • This embodiment has the advantage of making the particulars of the front-end processing transparent to downstream recipients of the output information.
  • a data bit or field indicative of the data's origin may be sent from the controller 300 together with the output data 305.
  • the output data 305 from the controller 300 may be presented in different formats depending on which front-end 100, 200 was used for reading.
  • the decision to use either the flying-spot front-end 100 or the imaging front-end 200 in a given situation may be based on any of a variety of criteria, conditions or techniques.
  • a relatively simple approach uses a two- position mechanical switch (not shown) , which is preferably mounted on the imaging/scanning head, to select the desired front-end. For this approach, the operator manually moves the switch to a first position when desiring to read using the imaging front-end 200, and moves the switch to a second position when desiring to read using the flying-spot front- end 100.
  • An alternative mode selector such as a momentary pushbutton switch combined with a mode-indicator display (e.g., an LED) may be used instead of a mechanical switch.
  • the operator may be trained to select the imaging front end 200 for nearby objects, and to select a flying-spot front end 100 for more distant objects.
  • the operator may instead choose, using either of the switching techniques referred to above, or any other suitable switching technique involving manual initiation, to select the imaging front end 200 for reading two-dimensional barcodes, and to select the flying- spot front-end 100 for reading one-dimensional barcodes.
  • the integrated optical reader 90 initially defaults to one of two modes (e.g., the imaging mode) for each target, and switches to the other mode (e.g., the flying-spot mode) when the user squeezes a trigger switch on the imaging/scanning head.
  • the other mode e.g., the flying-spot mode
  • the integrated optical reader 90 initially defaults to one of two modes (e.g., the imaging mode) for each target, and switches to the other mode (e.g., the flying-spot mode) when the user squeezes a trigger switch on the imaging/scanning head.
  • the other mode e.g., the flying-spot mode
  • the trigger may also be used to activate an aiming beam when squeezed lightly, in a manner that is conventionally known.
  • the operator can switch modes of the integrated optical reader 90 by scanning a specialized symbol which, when read and interpreted by the integrated optical reader 90, causes the controller 300 to switch reading modes.
  • the controller 300 may maintain an internal mode flag (i.e., a stored data bit) in software indicating the current reading or operation mode, and may change the mode flag, if appropriate, when the specialized symbol is read.
  • FIG. 5 is a flow chart illustrating one embodiment of process by which selection between the flying-spot front end 100 and the imaging front end 200 may be accomplished by the controller 300.
  • the controller 300 reads an operation mode flag.
  • the value of the operation mode flag may be set by, for example, a mechanical switch or trigger, as described above, or by reading a specialized symbol, as also described above.
  • a test is performed to see whether the operation mode flag is enabled for flying-spot laser scanning or for imaging.
  • the operation mode flag may indicate whether the integrated optical reader is in an operation mode for reading one-dimensional symbols or for reading two-dimensional symbols, but the effect is similar: for one-dimensional symbols, reading with the flying-spot front end 100 is preferred, while for two- dimensional symbols, reading with the imaging front end 200 is preferred.
  • the controller 300 selects, in step
  • the flying-spot front end 100 for reading.
  • the data gathered by the flying-spot front end 100 is then processed and transferred to the controller 300 for decoding, in step
  • FIG. 3 is a flowchart of a control program in accordance with such an embodiment .
  • the program represented by the flow chart in FIG. 3 is preferably implemented by the controller 300 (shown in FIG. 1) .
  • the controller 300 starts execution at step 521.
  • the controller 300 adjusts the parameters for the upcoming imaging read, preferably based on previously performed imaging reads. These parameters may include, for example, exposure control for the imaging process.
  • the controller 300 attempts to read the target barcode (or other symbol or indicia) using the imaging front-end 200. This step 523 may include, for example, exposure control , clocking the data out of the CCD or other image sensor, and decoding of the data from the CCD as described previously herein.
  • step 524 a test is preformed to determine whether the attempted read (in step 523) was successful. If the attempted read was successful, processing jumps to step 529, where the data corresponding to the target barcode or other symbol or indicia is reported. If, on the other hand, the attempted read in step 523 was not successful, processing passes to step 525, which is the start of the flying-spot scanning routine.
  • step 525 a test is performed to determine whether the trigger switch on the handheld head has been pressed. If the trigger switch has not been pressed, the system will not attempt to read the barcode or other symbol or indicia using a flying-spot scan, and control returns to step 522 so that another attempt can be made using an imaging read.
  • the test of step 525 may be included for safety reasons, to prevent, for example, the unintentional discharge of laser light.
  • step 525 determines that the trigger has been pressed
  • control passes to step 526, where the controller 300 adjusts the parameters for the upcoming flying-spot scan, preferably based on previously performed flying-spot scans. These parameters may include, for example, the speed of the scanning spot.
  • step 527 the system attempts to read the target barcode using a flying-spot scan. Details of implementing this step (including, for example, reading and decoding the edge data) have been described previously herein.
  • step 528 a test is performed to determine whether the attempted read (in step 527) was successful. If the attempted read was successful, processing continues in step 529, where the data corresponding to the target barcode or other symbol or indicia is reported. If, on the other hand, the attempted read in step 527 was not successful, processing returns to step 522, which is the start of the imaging reading routine. This process is repeated to effectuate reading of the bar code, symbol or other indicia.
  • the integrated optical reader 90 alternates between reading with the flying-spot front end 100 and the imaging front end 200, and performs data capture using one reading method in parallel with decoding data gathered using a different reading method.
  • step 540 A flow chart depicting such an operational process is shown in FIG. 4.
  • the controller 300 starts execution in step 540.
  • step 540 the controller 300 starts execution in step 540.
  • the integrated optical reader 90 first attempts to read with the flying-spot front end 100.
  • the flying spot front end 100 is selected first because the decoding time is generally less, although in alternative embodiments the imaging front end 200 may be selected first.
  • the imaging front end 200 may be selected first.
  • the data gathered by the flying spot front end 100 is processed and transferred to the controller 300 for decoding.
  • the controller 300 switches the reading mode, and selects the imaging front end 200 to read in data.
  • the integrated optical reader 90 operates in parallel, decoding data gathered from one source (the flying spot front end 100) while gathering data from another source (the imaging front end 200) .
  • the data is processed and sent to the controller 300 for decoding, in step 544. While decoding of the data gathered by the imaging front end 200 is in progress, the cycle may repeat, and the controller 300 may switch back to reading with the flying spot front end 100, in step 541.
  • an advantage of the processes shown in FIGS. 3 and 4 is that both near and far targets may be read, without the need for manual selection between different modes .
  • the integrated optical reader 90 performs automatic switching between the modes, thus reducing the need for manual intervention in its operation.
  • the operation of the two front ends 100, 200 is synchronized so that they are not operating simultaneously. The reason for this is because the flying spot laser beam traversing the target may interfere with collection of good data by the imaging front end 200. Thus, simultaneous operation of both the flying spot front end 100 and the imaging front end 200 may degrade performance of the imaging front end 200.
  • data from the imaging front-end 200 is used to confirm the validity of data obtained from the flying-spot front-end 100 or vice versa.
  • This confirmation process can be used to decrease the probability of a reading error in cases where the barcode or other symbol can be successfully decoded, but the confidence level in the decoding result is low.
  • the flying-spot subsystem decodes a given barcode or other symbol with a low degree of confidence
  • an imaging read can be performed to verify the data.
  • the imaging sub-system detects the same information for the given barcode or symbol, the original data reading can be accepted.
  • This process is particularly advantageous when the data confidence is relatively low for both the imaging and flying-spot reads, but the combined confidence is high enough to be usable.
  • the integrated optical reader 90 may first read using one reading method (e.g., using the flying spot front end 100) , and then switch to the other reading method based upon data derived in a partial pattern recognition step (or a partial decoding step) .
  • the controller 300 causes data to be gathered using the flying-spot front end 100.
  • the controller 300 then performs a partial pattern recognition (or partial decoding) step to search for indicia indicative of either a one-dimensional or two-dimensional code, symbol or indicia.
  • the partial pattern recognition (or partial decoding) step takes less time than a full decode, because the particular value or specific information of the barcode or symbol is not needed at this stage of the processing.
  • the controller 300 may continue to attempt to decode on the assumption that the target comprises a one-dimensional code, symbol or indicia, and may also instruct the flying spot front end 100 to continue to gather data continuously or periodically in case complete data was not initially read.
  • initial processing of the gathered data indicates that the bar code (or other symbol or indicia) is two-dimensional, based, for example, on the feature ratios of a portion of the data, or by detecting certain key features (such as start/stop characters in PDF417, or a Maxicode bullseye)
  • the controller 300 may switch to an image capture mode, and cause the imaging front end 200 to capture an image for decoding.
  • the controller 300 may either discard the original data gathered by the flying spot front end 100, or maintain it and use it to assist decoding of the data gathered by the imaging front end 200.
  • an integrated optical reader such as integrated optical reader 90 shown in FIG.
  • FIG. 2 is a schematic block diagram of one type of proximity detector 400 that may be used to detect whether a target is near or far.
  • the controller 300 selects the imaging front-end 200 for near targets and the flying-spot front end 100 for far targets based on an output of the proximity detector 400.
  • the proximity detector 400 is integrated into a handheld imaging/scanning head.
  • the illustrated proximity detector 400 makes use of the existing illumination source 230 (e.g., a forward-facing LED array) located in the imaging front-end 200, together with an additional forward-facing photodetector 410.
  • this added photodetector 410 comprises a photodiode with a peak detecting frequency that matches the frequency of the light from the illumination source 230.
  • the output of the photodetector 410 is amplified by a transimpedance amplifier 420.
  • the transimpedance amplifier's output 425 is then compared to a preset threshold voltage by, for example, a comparator 430.
  • the photodetector 410 will detect light from the illumination source 230 that has been reflected by the target 460.
  • the target 460 is near (for example, less than one inch from the front of the imaging/scanning head 480)
  • the amount of reflected light will be relatively large, and the amplifier output 425 will exceed the preset threshold.
  • the amount of reflected light detected by the photodetector 410 will be smaller, and will not exceed the preset threshold.
  • the controller 300 uses the output of the comparator 435 to decide whether to perform an imaging scan (for near targets) or a flying-spot scan (for far targets) .
  • the proximity detector 400 may be referred to as a "near/far proximity detector” because it simply outputs an indication of whether the target 460 is near or far, but not necessarily the precise distance of the target 460. However, with suitable modification (e.g., additional threshold levels to provide range “buckets", or analog-to- digital conversion of the amplifier output signal 425) , a closer estimate of the distance to the target 460 can be achieved, if desired for other purposes (e.g., auto-focus).
  • suitable modification e.g., additional threshold levels to provide range "buckets", or analog-to- digital conversion of the amplifier output signal 425.
  • FIG. 6 is a flow chart illustrating a technique for selecting between flying-spot scanning and imaging when proximity information is available.
  • the controller 300 starts execution in step 560.
  • the range to the target 460 is measured using a proximity detector (e.g., proximity detector 400 shown in FIG. 2) .
  • the output from the proximity detector is tested step 562. If the target 460 is near, then, in step 563, the controller 300 selects the imaging front-end 200. The data gathered by the imaging front-end 200 is then processed and sent for decoding in step 564. If, on the other hand, the target 460 is not near, then, in step 566, the controller 300 selects the flying-spot front end 100. The data gathered by the flying-spot front end 100 is then processed and sent for decoding in step 567.
  • a proximity detector e.g., proximity detector 400 shown in FIG. 2 .
  • the output from the proximity detector is tested step 562. If the target 460 is near, then, in step 563, the controller 300
  • step 561 Should step 561 not result in a determination of target distance (i.e., the proximity detector 400 is unable to detect the target) , typically the near/far proximity detector 400 will output an indication that the target is
  • the controller 300 may choose to default, or may naturally default, to using the flying-spot front end 100.
  • proximity detector 400 Besides the proximity detector 400 illustrated in FIG. 2, other types of proximity or range detectors may be used. For example, an ultrasonic sonar-based proximity detector may be utilized. Another example of a proximity detector is described in copending U.S. Patent Application Ser. No. 09/422,619 (attorney docket 239/290) filed on October 21, 1999, which application is assigned to the assignee of the present invention, and hereby incorporated by reference as if set forth fully herein.
  • the • controller 300 causes the integrated optical reader 90 to issue an audible beep having a recognizable tone or pattern, indicating to the operator to move the target close, within the range and field of view of the imaging front end 200.
  • the imaging front end 200 is selected by the controller 300 in response to reading of a specialized linear (i.e., one-dimensional) code indicating that a two-dimensional bar code, symbol or indicia is present.
  • a specialized linear (i.e., one-dimensional) code indicating that a two-dimensional bar code, symbol or indicia is present.
  • step 571 the flying-spot front end 100 is used to gather data.
  • step 572 the data gathered by the flying-spot front end 100 is processed and transferred to the controller 300 for decoding.
  • step 573 the controller 300 determines whether the data is in the format of a composite, or linked, code, indicating that a two-dimensional bar code, symbol or indicia is present. If not, then the process is done (unless no code was detected, in which case the process may return to step 571) . If, however, a composite or linked code was present, the process then continues with step 574, wherein the imaging front end 200 is used to gather data. In step 575, the data gathered by the imaging front end 200 is processed and transferred to the controller 300 for decoding.
  • FIG. 12 is a block diagram of an alternative embodiment of an integrated optical reader 900 similar to the embodiment shown in FIG. 1, except that instead of transferring undecoded data 725, 825 from the front-ends 700, 800 to the controller 950, the decoding function is performed locally in each individual front-end 700, 800. More specifically, the undecoded edge data in the signal processor output signal 725 is decoded in a local flying- spot decoder 740 of any suitable conventional design, and the undecoded image data 825 is decoded in a local imaging decoder 840 of any suitable conventional design.
  • the decoders 740, 840 may be uP/uC-based.
  • Both decoders 740, 840 may provide their output in the same format (e.g., ASCII data), thus simplifying the design of the controller 950.
  • the controller 950 may be implemented in hardware using a simple 2-to-l multiplexer to route the data from the desired front-end 700, 800 to the output.
  • the controller 950 may be uP/uC-based, or may comprise a finite state machine, field-programmable gate array (FPGA) , or logic network, or may have any other hardware- or software- based architecture.
  • FIG. 8 is a diagram of an integrated optical reader 601 embodied as a fixed device. As illustrated in FIG.
  • the integrated optical reader 601 includes a system enclosure 602 having a window (or aperture) 603 atop it, such as may be found at, for example, a retail store or in other point- of-sale applications.
  • the integrated optical reader 601 further comprises a flying-spot laser scanner front end 605 (such as flying spot front end 100 shown in FIG. 1 and described earlier herein) as well as an imaging front end 604 (such as imaging front end 200 shown in FIG. 1 and described earlier herein) , both of which are connected to a control system 606 (such as controller 300 shown in FIG. 1) .
  • the control system 606 selectively operates the flying spot front end 605 and the imaging front end 604, so as to gather data over the respective field -of-view 609, 608 of the two front ends 605, 604. Selection between the flying spot front end 605 and the imaging front end 604 may be made according to any of the techniques described elsewhere herein, in connection with FIGS. 3-7, for example. Data gathered by the flying spot front end 605 and imaging front end 605 may be decoded locally in each front end 605, 604, or else may be decoded by the controller 626. Data gathered by, or decoded by, the control system 606 may be passed along to a host computer (not shown) through an interface 607.
  • the imaging front end 604 may be located so that the components for the imaging front end 604 are a sufficient distance away from the flying spot front end 605 that they do not interfere with the operation (e.g., generation of the scanning pattern) of the flying spot front end 605.
  • a special area of the window 603, such as a corner section thereof, is designated for reading two- dimensional bar codes, symbols or indicia, and the imaging front end 604 is located beneath that area of the window 603. Operators may be trained to recognize labels bearing two-dimensional bar codes, symbols or indicia, and to place such labels above and relatively close to, or touching, the special area of the window 603, so as to allow the imaging front end 604 to read the two-dimensional bar code, symbol or indicia.
  • Such labels are preferably presented very close to the imaging front end 604, such as by placing them on the window 603, because the imaging device of the imaging front end 604 would ordinarily have a limited depth of field.
  • one-dimensional bar codes, symbols or other indicia may still be presented to the flying spot front end 605 anyplace over its typically much larger depth of field.
  • control system 606 when the control system 606 (including a decoder internal thereto) decodes a one-dimensional bar code or symbol that is part of a linked or composite code, or the control system 606 recognizes data from a linear scan by the flying spot front end 605 indicating that a two-dimensional bar code, symbol or indicia is present, the control system 606 causes a signal to be conveyed to the operator, such as by sounding an audible beep or by illuminating a light-emitting diode (LED) located externally in a visible part of the system enclosure 602.
  • LED light-emitting diode
  • FIG. 9 is a diagram of an integrated optical reader 621 similar to the integrated optical reader 601 shown in FIG. 8, but having an additional flying spot laser scanning front end 631 for multi-planar scanning.
  • the integrated optical reader 621 of FIG. 9 includes a system enclosure 622 having a window (or aperture) 623, through which a flying spot front end 625 and an imaging front end 624 may gather data.
  • the system enclosure 622 also has an upper part having a window (or aperture) 632 generally perpendicular to the plane of the window 623.
  • the second flying spot front end 631 is positioned so as to scan through the window 632 in the upper part of the system enclosure 622, and is connected to the controller 626.
  • the data gathered by the flying spot front end 631 may be decoded locally therein, or may be sent to the controller 626 for decoding, or, alternatively, may be sent to a host computer (not shown) via an interface 627 for decoding.
  • the imaging front end may be desirable to have the field of view of the imaging front end by located in the center of the window 603 (FIG. 8) or 623 (FIG. 9) .
  • the flying spot front end uses a facet wheel to generate a scanning pattern
  • the imaging device e.g., CCD or CMOS imager
  • lens for the imaging front end are suspended above the facet wheel but underneath the window 603 (or 623) , using a cantilever arm to hold the lens and imaging device.
  • a wire may be run along the cantilever arm to allow electronic signals from the imaging device to reach signal processing electronics and, eventually, an image capture memory and/or decoder.
  • FIG. 10 is a diagram of a facet wheel 641 with a hole 643 for allowing an imaging device 642 located beneath the facet wheel 641 to gather data periodically.
  • a flying spot scanning pattern is generated according to techniques well known in the art.
  • the hole 643 for allowing an imaging device 642 located beneath the facet wheel 641 to gather data periodically.
  • the imaging device 642 passes above the imaging device 642, the imaging device 642 is provided an unobstructed view above it, and captures data during that time.
  • the facet wheel 641 can be temporarily stopped to allow the imaging device 642 to gather data over a longer exposure time.
  • a shared imaging device preferably a two-dimensional active pixel CMOS array
  • the facet wheel is stopped in an orientation such that a view is provided down the centerpath of the integrated optical reader.
  • the captured image can then be transferred from the imaging device to a memory and/or decoder.
  • flying spot reading is desired, the facet wheel is rotated.
  • a selected group of pixels on the imaging device (such as a 40 x 40 area of pixels) is preferably used as a readout area to "emulate" a photodiode in the flying spot scanner - that is, to gather light reflected from the target and focused by the optical system onto the imaging device, and provide a signal to processing and decoding parts of the system downstream.
  • the data from the readout area of the imaging device is read out periodically, at a rate dependent in part upon the speed with which the beam is swept and the desired resolution, so as to yield a stair-step analog (video) signal, having signal features (i.e., peaks and valleys) corresponding to the lighter and darker features of the target.
  • Using an active pixel CMOS array allows selection only of the pixels in the readout area for each read, avoiding the need to read out the entire contents of the imaging device, and permitting a higher readout rate.
  • the number of pixels selected for the readout area of the imaging device approximates the size and/or light sensitivity of a photodiode.
  • the size of the image (that is, spot) on the imaging device will vary depending upon how distant the target is.
  • the size of the spot will be relatively small, and when the object is close, the size of the spot will be relatively large.
  • the area of the imaging pixel selected for use as the readout area for flying spot scanning thus depends upon the expected size of the spot over the operable range of the optical reader.
  • a proximity detector or ranging device is used to optimize the readout area of the imaging device.
  • the proximity detector indicates that the target is close, the spot would be expected to be large, and so a larger area of pixels would be read out.
  • the spot would be expected to be small, and so a smaller area of pixels would be read out.
  • the size of the readout area can be varied dynamically from close to distant targets, in direct proportion to the target distance.
  • FIG. 11 is a diagram of an integrated optical reader 650 as may be particularly well suited for a handheld optical reading device.
  • an integrated optical reader 650 comprises a lens 651 for focusing light from a target (not shown) onto an image sensor 652.
  • the image sensor 652 may comprise any of the imaging devices previously mentioned herein, such as a CCD or CMOS array, for example.
  • the image sensor 652 comprises a two-dimensional active-pixel CMOS array.
  • the sensor array 652 is connected to a signal processor 653, which may comprise an amplifier 655 (with or without automatic gain control circuitry), a filter circuit 656, an A/D converter 657 and an edge detection circuit 658.
  • the A/D converter 657 may be connected to a memory 670 for storing captured images (as well as for storing program variables, data and the like)
  • the edge detection circuit 658 may be connected to a buffer 671. Both the memory 670 and the buffer 671 are accessible to a decoder 672 (or a controller) .
  • the decoder 672 preferably comprises a microprocessor or microcontroller and program code for causing the microprocessor or micro-controller to perform certain functions in accordance with the description herein.
  • a readout control circuit 661 is connected to the image sensor 652.
  • the readout control 661 may comprise, for example, clocking circuitry to read out the pixels of the imaging array 652 sequentially, or in a particular pattern, in addition to logic circuitry for responding to commands from the mode controller 663.
  • the readout control 661 may also comprise adaptive exposure control circuitry, such as described in relation to an active-pixel CMOS image sensor in copending U.S. Patent Application Ser. No. 08/697,408, previously incorporated by reference herein.
  • the image sensor 652 is exposed for an amount of time (either a fixed or adaptive time period) , and the image captured by the image sensor 652 is clocked out under control of the readout control circuit 661.
  • the image sensor output signal 654 is provided to the signal processor 653, which amplifies and filters the signal, and then either digitizes the signal using A/D converter 657 (if in imaging mode) or else detects transitions in the signal using edge detection circuitry 658 (if in flying-spot scanning mode) .
  • the operation of the signal processor 653 is dictated by the mode controller 663, which indicates to the various circuitry of the optical reader 650 whether the optical reader 650 is in an imaging mode or a flying spot scanning mode.
  • Laser control circuitry 660 (including a beam former and other such circuitry as described in relation to elements 131 through 133 in FIG. 1) is preferably included to permit flying-spot laser scanning capability.
  • the digitized data from A/D converter 657 is transferred to a data structure in memory 670 for storing the image data, for subsequent processing by the decoder 672.
  • the edge detection data from edge detection circuitry 658 is preferably run-length encoded and transferred to buffer 671, for subsequent processing by the decoder 672.
  • the mode of the integrated optical reader 650 may be manually selected using a switch or other manual selection means as previously described herein.
  • the mode controller 663 may be connected to a range detector 662, which detects the proximity of the target and indicates such to the mode controller 663.
  • the mode controller 663 may select the imaging mode, whereas if the target is not near, the mode controller may select the flying spot scanning mode.
  • the range detector 662 may share certain circuitry with the image sensor 652 and signal processor 653 (in order to obtain ranging information) , and therefore is shown optionally connected to the signal processor 653. Alternatively, the range detector 662 may be stand-alone in nature. If in imaging mode, the image data from the image sensor 652 is clocked out and processed much in the same manner as with the imaging front end 200 shown in FIG. 1. If, however, the integrated optical reader 650 is in flying spot scanning mode, then certain modifications are made, so as to permit the laser scanning circuitry to share some of the components with the imaging circuitry.
  • a selected group of pixels on the imaging sensor 652 (e.g., a 40 x 40 area of pixels) is preferably used as a readout area to "emulate" a photodiode in the flying spot scanner.
  • the data from the readout area of the imaging sensor 652 is read out periodically, at a rate dependent in part upon the speed with which the beam generated by the laser control 660 is swept and upon the desired resolution.
  • the image sensor output signal 654 thereby comprises a stair-step analog
  • video signal having signal features (i.e., peaks and valleys) corresponding to the lighter and darker features of the target .
  • an active pixel CMOS array for the image sensor 652 allows selection only of the pixels in the readout area for each read, avoiding the need to read out the entire contents of the imaging device, and permitting a higher readout rate.
  • the number of pixels selected for the readout area of the imaging sensor 652 approximates the size and/or light sensitivity of a photodiode, and depends in part upon the expected size of the spot over the operable range of the optical reader 650 when used in flying-spot scanning mode.
  • the range detector 662 is used to optimize the readout area of the imaging sensor 652. Suitable examples of range detectors are described in U.S. Patent Application Ser. No. 09/422,619, previously incorporated herein by reference.
  • the range detector 662 indicates that the target is close, the spot would be expected to be large, and so a larger area of pixels would be read out from the imaging sensor 652.
  • the range detector 662 indicates that the target is distant, the spot would be expected to be small, and so a smaller area of pixels would be read out.
  • the size of the readout area can be varied dynamically from close to distant targets, in direct proportion to the target distance.
  • Integrated optical readers in accordance with various preferred embodiments described herein advantageously enable a user to read near barcodes, symbols, or other indicia using an imaging technique, without sacrificing the ability to read distant barcodes, symbols, or other indicia (which can be read using a flying-spot scan) .
  • the imaging front-end 200 or 800
  • the design of the flying-spot front-end does not need to accommodate near barcodes, symbols, or other indicia.
  • the flying-spot front-end 100 (or 700) can be optimized for a larger depth of field when reading distant barcodes and other symbols and indicia.
  • the integrated optical reader in accordance with the preferred embodiments described herein also enables the user to read two-dimensional barcodes using imaging, and one-dimensional barcodes using flying-spot scans .
  • an auto-focus capability may be provided.
  • a component in the optical path is adjusted in response to an indication of the distance to the target as derived by the optical reader.
  • Such an adjustable component may comprise, for example, a lens or a mirror in the optical path.
  • a proximity detector including any of the types previously described or referred to herein, or any other suitable proximity detector or ranging mechanism as conventionally known, may be used to sense the distance to the target and adjust the focus of the integrated optical reader in response thereto.
  • the focus of the integrated optical reader may be adjusted to optimize for high frequency information in response to analysis of the image data, according to any of a variety of techniques that are well known in the art .
  • a multi- focal lens may be used.
  • a multi-focal lens may be used to increase the depth of field of the optical system, particularly for the imaging front end 200.
  • a variety of multi-focal lenses and other optical techniques which may be utilized in conjunction with the embodiments described herein are set forth in U.S. Patents 5,770,847 and 5,814,803, each of which is hereby incorporated by reference as if set forth fully herein.
  • the type of data that may be read and captured by the image front end of an integrated optical reader is not limited to bar codes and similar symbols.
  • any type of data or image may be captured by the image front end, including any type of symbols, characters, or pictures (e.g., driver's license photos) .
  • the controller of the integrated optical reader may attempt to decode it; alternatively, the data may be passed along to a host system, or stored locally for later read-out.

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US7380719B1 (en) * 2006-09-21 2008-06-03 Ncr Corporation Barcode scanner with configurable video modes
US8662397B2 (en) 2007-09-27 2014-03-04 Symbol Technologies, Inc. Multiple camera imaging-based bar code reader
US8479996B2 (en) 2008-11-07 2013-07-09 Symbol Technologies, Inc. Identification of non-barcoded products
US8079523B2 (en) 2008-12-15 2011-12-20 Symbol Technologies, Inc. Imaging of non-barcoded documents

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US5672858A (en) * 1994-06-30 1997-09-30 Symbol Technologies Inc. Apparatus and method for reading indicia using charge coupled device and scanning laser beam technology

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