Source: http://www.google.com.ar/patents/EP2945095A1?cl=en
Timestamp: 2018-01-18 03:48:17
Document Index: 443851698

Matched Legal Cases: ['Application No. 13', 'Application No. 13', 'Application No. 13', 'Application No. 13', 'Application No. 13', 'Application No. 13', 'Application No. 13', 'Application No. 13', 'Application No. 13', 'Application No. 13', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14', 'Application No. 14']

Patent EP2945095A1 - Indicia-reader housing with an integrated optical structure - Google Patents
An imaging engine for an indicia reader that includes a dual-purposed housing is disclosed. The housing is configured to provide support and alignment for the imaging engine's optical modules. In addition, the housing includes an integrated optical structure to focus or project light to or from the various...http://www.google.com.ar/patents/EP2945095A1?cl=en&utm_source=gb-gplus-sharePatent EP2945095A1 - Indicia-reader housing with an integrated optical structure
Publication number EP2945095 A1
Application number EP20150165284
Also published as CN105095815A, US9280693, US20150332076
Publication number 15165284, 15165284.9, 2015165284, EP 2945095 A1, EP 2945095A1, EP-A1-2945095, EP15165284, EP20150165284, EP2945095 A1, EP2945095A1
Inventors Chen Feng, Horn Erik Van, Tao Xian, Edward C. Bremer, Sean Phillip Kearney, Mehul Patel, Gregory Rueblinger, Timothy God
Patent Citations (241), Classifications (7), Legal Events (4)
Indicia-reader housing with an integrated optical structure
EP 2945095 A1
An imaging engine for an indicia reader that includes a dual-purposed housing is disclosed. The housing is configured to provide support and alignment for the imaging engine's optical modules. In addition, the housing includes an integrated optical structure to focus or project light to or from the various optical modules.
An imaging engine for an indicia reader, comprising:
an imaging module for capturing an image of the imaging engine's field of view;
an aiming module for projecting a visible aligning pattern onto a target to provide information regarding the imaging engine's field of view and to facilitate alignment of the image captured by the imaging module;
an illuminating module for projecting light onto the target to illuminate the imaging engine's field of view; and
a housing configured to provide support and alignment for the imaging module, the aiming module, and the illuminating module, the housing including an integrated optical structure.
The imaging engine according to claim 1, wherein:
the imaging module comprises an image sensor and one or more imaging-module lenses;
the housing's integrated optical structure is configured as a housing imaging lens; and
the one or more imaging-module lenses and the housing imaging lens form a lens group to render an image onto the image sensor.
the aiming module comprises an aiming-module light source for illuminating an aiming-module aperture positioned in front of the aiming-module light source, and
the housing's integrated optical structure is configured as a housing aiming lens that is positioned in front of the aiming-module light source in order to project an image of the aiming-module aperture onto the target.
The imaging engine according to claim 3, wherein the aiming-module light source is a light emitting diode.
The imaging engine according to claim 3, wherein the aiming-module light source is a laser diode.
The imaging engine according to claim 1, wherein the aiming module comprises an aiming-module light source positioned behind a housing aiming lens, the housing aiming lens being part of the housing's integrated optical structure and being configured to create a visible aligning pattern on the target.
The imaging engine according to claim 6, wherein the aiming-module light source is a laser diode.
The imaging engine according to claim 6, wherein the aiming-module light source is a light emitting diode.
The imaging engine according to claim 1, wherein the illuminating module comprises an illuminating-module light source positioned behind a housing illuminating lens, the housing illuminating lens being part of the housing's integrated optical structure and being configured to provide uniform illumination within the imaging engine's field of view.
The imaging engine according to claim 9, wherein the illumination-module light source is a light emitting diode.
The imaging engine according to claim 1, wherein the housing comprises an optically transparent material.
The imaging engine according to claim 11, wherein the housing comprises polycarbonate.
The imaging engine according to claim 11, wherein the housing comprises polymethyl methacrylate (PMMA).
The imaging engine according to claim 1, wherein the housing is formed of (i) a first molded material that provides structural support and light blocking functionality and (ii) a second molded material that is optically transparent and that forms the housing's integrated optical structure.
The present invention relates to the field of indicia readers and, more specifically, to an indicia-reader's imaging engine with a housing having an integrated optical structure.
Generally, indicia readers (e.g., barcode scanners) fall into one of three categories: wand scanners, laser scanners, and imaging barcode readers.
Wand scanners generally include a light source and photodetector housed in a pen-shaped housing. A user drags the wand reader across a code symbol (e.g., a barcode), and a signal is generated that represents the bar-space pattern of the barcode.
Laser scanners typically include a laser diode and lens combination to generate a collimated light beam. The beam is swept back-and-forth across a barcode by a reciprocating mirror. The light reflected from the barcode is collected and sensed by a photodetector. The result is an electronic signal that corresponds to the bar-space pattern of the barcode.
Imaging indicia readers (i.e., barcode readers) include an image sensor (e.g., CCD) and a group of lenses (i.e., lens group) for focusing the image of a target (i.e., barcode) onto the image sensor. The image sensor captures a digital picture of the barcode, and a processor running algorithms detects and decodes the barcode from the image. The optical subsystems (i.e., modules) in an imaging barcode reader responsible for creating a good image of a barcode is known as the imaging engine.
Most thin-profile, hand-held, mobile computing devices (e.g., smart-phones) now have integrated cameras that can be used as the imaging engine for indicia reading, and numerous applications for barcode scanning have been developed for these devices. While these applications perform reasonably well for the casual user, they lack the features, functions, and performance present in dedicated imaging barcode readers. Illumination, alignment, and image quality may all suffer when using a mobile computing device's camera as the imaging engine for barcode scanning.
Because most users want to carry only one mobile computing device, they will be reluctant to trade their mobile device for a dedicated indicia reader. A need, therefore, exists for a dedicated imaging indicia reader that is integrated within a hand-held mobile computing device. This integration, however, puts severe limitations on the imaging indicia reader's design. Unique design approaches and construction methods must be combined to allow for such novel integration. One such approach incorporates an optical structure within the housing of the indicia reading module.
Accordingly, in one aspect, the present invention embraces an imaging engine for an indicia reader. The imaging engine includes three optical modules: (i) an imaging module for capturing an image of the imaging engine's field of view, (ii) an aiming module for projecting a visible aligning pattern onto a target in order to provide information regarding the imaging engine's field of view and to help align the image captured by the imaging module, and (iii) an illuminating module for projecting light onto the target to illuminate the imaging engine's field of view. The modules are held by a housing configured to provide support and alignment. The housing also includes an integrated optical structure.
In an exemplary embodiment, the imaging engine's imaging module includes an image sensor and one or more imaging-module lenses. The housing's integrated optical structure is configured as a housing imaging lens. The combination of the housing imaging lens and one or more imaging-module lenses form a lens group. This lens group is used to render (i.e., focus) an image onto the image sensor.
In another exemplary embodiment, the imaging engine's aiming module includes an aiming-module light source for illuminating an aiming-module aperture positioned in front of the aiming-module light source. The housing's integrated optical structure is configured as a housing aiming lens and is positioned in front of the aiming-module aperture in order to project an image of the aiming-module aperture onto the target.
In another exemplary embodiment, the imaging engine's aiming-module light source is a light emitting diode.
In another exemplary embodiment, the imaging engine's aiming-module light source is a laser diode.
In another exemplary embodiment, the imaging engine's aiming module includes an aiming-module light source positioned behind a housing aiming lens. The housing aiming lens is part of the housing's integrated optical structure and is configured to create a visible aligning pattern on the target.
In another exemplary embodiment, the imaging engine's aiming module includes a laser diode that is positioned behind a housing aiming lens. The housing aiming lens is part of the housing's integrated optical structure and is configured to create a visible aligning pattern on the target.
In another exemplary embodiment, the imaging engine's aiming module includes a light emitting diode that is positioned behind a housing aiming lens. The housing aiming lens is part of the housing's integrated optical structure and is configured to create a visible aligning pattern on the target.
In another exemplary embodiment, the imaging engine's illuminating module includes an illuminating-module light source positioned behind a housing illuminating lens. The housing illuminating lens is part of the housing's integrated optical structure and is configured to provide uniform illumination within the imaging engine's field of view.
In another exemplary embodiment, the imaging engine's illuminating module includes a light emitting diode positioned behind a housing illuminating lens. The housing illuminating lens is part of the housing's integrated optical structure and is configured to provide uniform illumination within the imaging engine's field of view.
In another exemplary embodiment, the imaging engine's housing is an optically transparent material.
In another exemplary embodiment, the imaging engine's optically transparent housing is polycarbonate.
In another exemplary embodiment, the imaging engine's optically transparent housing is polymethyl methacrylate (PMMA).
In yet another exemplary embodiment, the imaging engine's housing is formed of two materials. A first molded material provides structural support for the housing. The first molded material having glass fibers added to improve the structural strength. Pigment is also added to block light and minimize unwanted stray light between optical modules. A second molded optically transparent material forms the housing's integrated optical structure. The second material has high optical clarity and is formed with precise surface profile control.
In another aspect, the present invention embraces an indicia-reading imaging engine including the following: (i) an imaging module, (ii) an aiming module, (iii) an illuminating module, and (iv) a housing. The imaging module captures images of the imaging engine's field of view and includes an image sensor and one or more imaging-module lenses. The aiming module projects a visible aligning pattern onto a target to facilitate alignment of the image captured by the imaging module. The visible aligning pattern corresponds to an aiming-module aperture and provides information regarding the imaging engine's field of view. The illumination module projects light via an illuminating-module light source onto the target to highlight the imaging engine's field of view. The housing is dual purposed. First, it provides support and alignment for the imaging module, the aiming module, and the illuminating module. It also has integrated, optically-transparent optical-structures that correspond to the various modules.
At least one of the housing's integrated, optically-transparent optical-structures is configured as a housing imaging lens. This lens, when combined with the one or more imaging-module lenses, form a lens group to render an image onto the image sensor.
At least one of the housing's integrated optically-transparent optical-structures is configured as a housing aiming lens. This lens is positioned in front of the aiming-module aperture in order to project the aiming-module aperture's image onto the target.
At least one of the housing's integrated, optically-transparent optical-structures is configured as a housing illuminating lens. This lens is positioned in front of the illuminating-module light source in order to provide uniform illumination within the imaging engine's field of view.
In an exemplary embodiment, the indicia-reading imaging engine's housing imaging lens is a meniscus lens.
In another exemplary embodiment, the indicia-reading imaging engine's housing aiming lens is positioned in front of the aiming-module aperture and is a bi-convex lens.
In another exemplary embodiment, the indicia-reading imaging engine's housing illuminating lens is positioned in front of the illuminating-module light source and is a plano-convex lens.
In another exemplary embodiment, the indicia-reading imaging engine's housing illuminating lens is positioned in front of the illuminating-module light source and is a non-rotational aspheric lens.
In yet another exemplary embodiment, the indicia-reading imaging engine's housing includes (i) a first co-molded material to provide support and alignment for the imaging module, the aiming module, and the illuminating module, the housing having glass fiber added to improve the structural strength and pigment added to block light, and (ii) a second co-molded material to provide the integrated, optically-transparent optical-structures with high optical clarity and precise surface profile control.
Fig. 1 graphically depicts an exemplary housing for an imaging engine.
Fig. 2 graphically depicts an exploded view of an exemplary housing and the various modules for an imaging engine.
The present invention embraces an imaging engine for an indicia reader. The imaging engine includes (i) an imaging module, (ii) an aiming module, (iii) an illuminating module, and (iv) a housing. The imaging module captures images of the imaging engine's field of view. The aiming module projects a visible aligning pattern onto a target to provide information regarding the imaging engine's field of view and facilitates alignment of the captured image. The illuminating module projects light onto the target to illuminate the imaging engine's field of view, which helps with imaging. The housing has dual purposes. First, it provides support and alignment for the imaging module, the aiming module, and the illuminating module. Second, it includes an integrated optical structure that aids the modules in their functions.
Mobile computing devices (e.g., a personal data assistant or a portable data terminal) may be integrated with dedicated indicia readers for reading indicia (e.g., barcodes) or for capturing document information (e.g., optical character recognition). Both of these applications require high quality images. Images that are misaligned or poorly illuminated may make decoding more difficult. As a result, an imaging engine for these devices includes several modules that help provide the best possible image of the target.
One module in the imaging engine is the imaging module. The imaging module creates an image of a target (e.g., barcode). A group of lenses (i.e., lens group) in this module creates an image of a target (positioned in front of the lens group) on an image sensor (positioned behind the lens group) mounted to a circuit board. The lens group is designed with an optical power, a depth of field, and a field of view suitable for imaging indicia (e.g., barcodes). Typically, the individual lenses of the lens group are assembled into a barrel suitable for mounting in front of the image sensor. This barrel is installed in a holder in front of the image sensor. This holder itself may be mounted to the same circuit board as the image sensor. The circuit board may be mounted into a housing with other circuit boards that form the indicia reader. This approach, while straightforward, has added size and weight and may be unsuitable for the integration into a small hand-held mobile computing device. The size and weight of the imaging engine may be reduced by eliminating parts through the use of dual purpose housing. That is, a housing with an integrated optical structure.
An integrated optical structure may be formed into the housing if high quality optical materials are used in its construction. For example, a material with high optical transmission and low optical dispersion such as polycarbonate or polymethyl methacrylate (PMMA) may be molded (e.g., injection molded) to form a housing with an optical structure including lenses. Alternatively a co-molding process could be used with two materials. One material, having high optical clarity and precise surface profile control may form the optical structures. The other material, having glass fibers added for structural strength and pigment for light blocking, may have other advantageous properties (e.g., strength) required by the housing. The housing's integrated optical structure may be configured as a housing imaging lens. This lens may replace the first lens in the lens group for the imaging module. In this way, the one or more imaging-module lenses and the housing imaging lens form a lens group that can render an image onto the image sensor. In an exemplary embodiment, this housing imaging lens is a meniscus lens formed into the front wall of the housing. One or two additional lenses between the housing imaging lens and the image sensor are used to achieve the total combined optical power and aberration control necessary to form a good target image with the required resolution for decoding.
The illuminating module uses an illuminating-module light source (e.g., light emitting diode) to highlight the imaging engine's field of view. Without this illumination, the image captured by the image sensor would have low contrast and would be noisy, neither quality being conducive to algorithmic decoding. The light from the illuminating-module light source is focused by a lens formed into the integrated optical structure of the housing. This lens (i.e., housing illuminating lens) is positioned in front of the illumination-module light source in order to provide uniform illumination within the field of view of the imaging engine. The lens may be a plano-convex lens. The convex surface of the lens may be a non-rotational aspheric (i.e., free form) surface to redistribute the light source's light uniformly within the field of view. In some embodiments, an aperture may be used between the illuminating-module light source and the housing illuminating lens in order to limit the extent of the illumination. Again, this aperture can be achieved by co-molding of non-transparent material. The aperture can provide a well-defined illumination pattern edge to improve user experience. The aperture may also reduce the potential for light crosstalk between the imaging module optics.
The aiming module creates a visible aligning pattern on the target. An operator may use this aligning pattern to position the indicia reader with respect to the target. The aligning pattern may be any shape or form that allows proper positioning. For example, the pattern may be a line, a crosshair, a frame, or any combination of these forms. The aligning pattern gives the operator a visual indication of the center, orientation, width, and height of the imaging engine's field of view. In this way, the operator may align the indicia reader with the target (e.g., barcode) to facilitate decoding.
The aiming module may be one of two forms: an LED (i.e., light emitting diode) aimer or a laser aimer. As the name implies, the aiming-module light source is a laser, and the aiming-module light source for the LED aimer is an LED. The type of aimer used depends on the applications. Laser aimers for example typically have more range than LED aimers due to the high intensity of the laser light.
In an exemplary embodiment of the aiming module, a collimating lens is positioned in front of a laser to collimate the laser's light. A diffractive optical element (i.e., DOE) is positioned in front of the collimating lens (i.e., between the source and the target) to form an aligning pattern on the target.
In another embodiment, the aiming-module light source (i.e., LED or laser diode) is positioned behind an aiming-module aperture, the aperture corresponding to the aligning pattern. The housing's integrated optical structure is configured to form a housing aiming lens, and the housing aiming lens is used to project an image of the aiming-module aperture onto the target.
In still another embodiment, no aiming-module aperture is used. The housing aiming lens is used to form an aligning pattern (e.g., line) on the target. Here, the housing aiming lens is a bi-convex lens molded into the front wall of the housing directly in front of the aiming-module light source (i.e., LED or laser diode). The inner convex surface is a rotationally symmetric surface that collimates the light from the LED. The outer convex surface (i.e., target side) is an aspherical toric surface that spreads the collimated light to form a uniform line pattern on the target. Combinations of toric segments with wedges could generate multi-line patterns, frame patterns, or other aligning patterns.
An exemplary housing for an imaging engine is shown in Fig. 1. The housing 10 is molded from an optically transparent material and has an integrated optical structure. Lenses are molded into the housing 10 for the various modules.
A housing illuminating lens 1 is a plano-convex lens that redistributes the illuminating-module light source LED into a well-defined area with a uniform illumination level.
A housing aiming lens 2 is a bi-convex lens integrated into the front wall of the housing 10. The inner convex surface is rotationally symmetric and serves to collimate the light from the aiming-module light source. The outer convex surface (i.e., towards the target) is an aspherical toric surface that spreads the collimated light to form a uniform line pattern on the target. This line pattern serves as the visible aligning pattern, allowing the operator to align the imaging engine with the target.
A housing imaging lens 3 is a meniscal lens formed into the front wall of the housing 10 and serves as the first element of the imaging lens assembly. This lens, when combined with one or two more lens elements, achieves the proper optical power and aberration control to form a satisfactory image with the required optical resolution on the image sensor.
As shown in Fig. 2, various modules are mounted (e.g., snap-fit) into the housing so that the modules line up with their respective optical structures. The housing provides support and alignment for the imaging module 5, the illuminating module 6, and the aiming module 7. The housing 10 also supports circuit subassemblies like the interface subassembly 8 and the processing subassembly 9. Folded rigid flex cables are used to connect the modules and the circuit subassemblies. This approach minimizes the interconnections between circuit boards and reduces size. The entire indicia reader is small enough to fit within a hand-held mobile computing device (e.g., smart phone).
There are many advantages to the approach of using a housing with an integrated optical structure. This approach reduces part count and improves tolerances as some lenses are integrated within the housing's integrated optical structure. It reduces the difficulty of assembly but simplifies alignment, as well as reducing cost, weight, and complexity.
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Cooperative Classification G02B7/00, G06K7/10831, G06K7/015, G06K7/10881, G06K7/1098, G06K2207/1011
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