Patent Publication Number: US-11048898-B2

Title: Coded information reader

Description:
This application claims priority to PCT/IT2015/000320, filed Dec. 24, 2015, entitled “Coded Information Reader,” which is incorporated in its entirety by reference herein. 
     The present invention relates to a coded information reader. 
     The present invention also relates to a method for reading coded information. 
     In the present description and claims, the expression “coded information” is used to indicate information contained in a code, preferably an optical code. The term “code” is used to indicate any graphical representation having the function of storing said coded information. The expression “optical code” comprises graphical representations, which are detectable in the field of visible light and, preferably, also in the range of wavelengths comprised between infrared and ultraviolet. 
     Particular examples of optical code consist of linear or two-dimensional codes, wherein the information is coded through suitable combinations of elements with a predetermined shape, for example squared, rectangular or hexagonal, of dark color (usually black) separated by clear elements (spaces, usually white), such as barcodes, stacked codes, two-dimensional codes in general, color codes, etc. The term optical code further comprises, more generally, also other graphical patterns with information coding function, including clear printed characters (letters, numbers, etc.) and special patterns (such as stamps, logos, signatures, fingerprints, etc.). 
     The coded information may relate, for example, to distance, volume, overall dimensions, or identification data of an object. 
     Coded information readers are of various types; they may be based on laser technology or imaging technology. 
     Furthermore, coded information readers may be intended for handheld use (portable readers), or to be fixedly resting in a predetermined position (fixed position readers). Fixed position readers are in turn classified as on-counter and in-counter readers, the former being those typically resting on the top of a surface, which is usually the check counter surface, the latter being commonly integrated in the check counter and oriented so that its reading field projects from the check counter surface towards the user or operator. 
     On-counter readers are also sometimes referred to as “presentation scanners”, due to the fact that the user grabs the object to be identified, typically a good or a document of any type, and moves her/his hand towards the terminal reading face, thus “presenting” the object to be read to it. 
     In-counter readers are also sometimes called “flatbed scanners”, because the reading window lies flush with the counter surface, or, “vertical scanners” when the reading window lies in a substantially vertical plane facing the operator, or else, “bi-optic scanners” when both configurations—flatbed and vertical—are simultaneously present. 
     U.S. Pat. No. 7,533,819 discloses an imaging system for an imaging-based bar code reader having a housing and a window. The imaging system includes a dual camera assembly having a first camera assembly with a first field of view and a second camera assembly with a second field of view. The first field of view and the second field of view are overlapping upon exiting the window and are substantially congruent outside the housing. The first camera assembly comprises a 2D sensor array using a global shutter pixel readout structure such as a VGA sensor with array size on the order of 640×480 pixels. The second camera assembly includes a 2D mega pixel sensor array adapted to provide high resolution imaging of 2D target bar codes, with array size on the order of 1280×1024 pixels and using a rolling shutter pixel readout structure. In operation, the first camera is continuously operated. If the imaging and decoding systems detect a 2D bar code that cannot be read, the first camera module is turned off and the second camera module is activated until the 2D bar code is successfully imaged and decoded. 
     US 2003/0016297 discloses an image sensing apparatus comprising a single sensor which generates an image signal of an object. In operation, a bar code on a printed matter is sensed at a low resolution; a microcomputer performs exposure adjustment and focus adjustment on the basis of a low-resolution image signal from the sensor; after the adjustment is completed, the resolution is switched from a low resolution to a high resolution and the image of the bar code in input to the bar code reader main body is decoded. After completion of decoding, the resolution is switched back from high resolution to low resolution. The reading time of an image signal of a frame image from the sensor is set in advance as a fixed frame reading time and one image is read every frame reading time regardless of the resolution. 
     The Applicant observes that the imaging system of U.S. Pat. No. 7,533,819 does not enable to efficiently exploit the dual camera assembly. Indeed, the two cameras are operated independently so that each camera needs a time to adjust the camera gain, exposure time and/or illumination, and a time for decoding. In other word, only part of the field of view of each camera is exploited for decoding so that there is the risk that an optical code flies away from the camera field of view without being decoded yet. Moreover, in the imaging system of U.S. Pat. No. 7,533,819 a distinct sensor to detect object presence is required. 
     As stated above, US 2003/0016297 teaches to adjust exposure and focus on the basis of a low-resolution image signal from the sensor; and—after the adjustment is completed—to switch the resolution from a low resolution to a high resolution so as to decode the image of the bar code on the basis of a high-resolution image signal from the sensor. The Applicant notes that in this solution, which makes use of a single sensor, there is a waste of time due to the time required for switching the resolution from low resolution to high resolution. Moreover, as the frame reading time is the same regardless of the resolution, the speed capacity of the low resolution operation is not exploited. Furthermore, as a single sensor is used, the field of view crossed by the bar code during low-resolution and high-resolution reading is the same, so that only part of the field of view of the sensor is exploited for decoding on the basis of a high-resolution image signal. 
     The Applicant thus faced the technical problem of providing an improved coded information reader. 
     In particular, the Applicant faced the technical problem of providing a coded information reader that guarantees improved performances as far as concerns reader responsivity (in terms of average time to decode and average number of successful decoding) while preserving high-resolution capability. 
     The Applicant found that the above technical problem can be solved by using two cameras: a low resolution camera and a high resolution camera, wherein the low resolution camera is faster in that it has a frame rate higher than the high resolution camera and is exploited in order to quickly detect object presence, adjust gain/exposure time/illumination values for both cameras, attempt decoding, and, in case of unsuccessful decoding, trigger the high resolution camera for decoding. This advantageously enables to exploit the low resolution (fast) camera to quickly perform all the operations needed by both cameras to perform decoding so that, when necessary, the high resolution camera is efficiently exploited for decoding operation only (without wasting time to perform said operations). This is based on the Applicant&#39;s perception that the fast, low resolution camera can be efficiently exploited to determine the operating parameters of the high resolution camera too, taking into consideration that the ambient light conditions are substantially the same for the two cameras (that operate, as a whole, in few hundredths of a second) and that a suitable calibration procedure (that may be performed in a manufacturing phase or an initial set-up phase of the reader) can be set (taking into account the peculiarities of the high resolution camera with respect to the fast, low resolution camera) for deriving the operating parameters of the high resolution camera from the ones determined by the fast, low resolution camera. 
     In a first aspect, the present invention thus relates to a coded information reader for reading coded information from an object, comprising:
         a first camera assembly having a first resolution, a first frame rate and a first field of view;   a second camera assembly having a second resolution, a second frame rate and a second field of view, the first resolution being lower than the second resolution and the first frame rate being higher than the second frame rate,
 
wherein said first camera assembly is configured to acquire frames and to process the acquired frames to perform:
   detection of object presence,   determination of operating parameters for both the first camera assembly and the second camera assembly,   coded information decoding,   in case of failure of said coded information decoding, triggering of the second camera assembly to acquire frames and to process the acquired frames to perform coded information decoding with the operating parameters set as determined by the first camera assembly for the second camera assembly.       

     In a second aspect, the present invention thus relates to method for reading coded information from an object, comprising the steps of: 
     a) acquiring first frames at a first resolution and at a first frame rate with a first camera assembly; 
     b) processing the acquired first frames so as to perform the steps of:
         b1) detecting object presence, and, in case of object presence detected:   b2) determining operating parameters for the first camera assembly and for a second camera assembly, and   b3) decoding coded information,       

     c) in case of failure of step b3) of coded information decoding, setting the operating parameters of the second camera assembly as determined in step b2) and triggering acquisition of second frames at a second resolution and at a second frame rate by the second camera assembly, the first resolution being lower than the second resolution and the first frame rate being higher than the second frame rate; 
     d) processing the second frames acquired in step c) so as to perform coded information decoding. 
     The present invention in at least one of the aforementioned aspects can have at least one of the following preferred characteristics. 
     Preferably, the operating parameters are at least one of: gain, exposure time and illumination level. 
     Preferably, the operating parameters for the first camera assembly are determined by analyzing pixels of the frames acquired by the first camera assembly, which cover said first field of view. 
     Preferably, the operating parameters for the second camera assembly are determined by analyzing pixels of the frames acquired by the first camera assembly, which cover said second field of view. 
     Preferably, the first field of view and the second field of view overlap at least in part. 
     Preferably, the first field of view is comprised between 40° and 70°. 
     Preferably, the second field of view is comprised between 40° and 60°. 
     In a preferred embodiment, the second field of view is smaller than the first field of view. 
     Preferably, a major part of the or substantially the whole second field of view is comprised within the first field of view. 
     Preferably, the ratio between the first field of view and the second field of view is comprised between 1 and 1.5. 
     According to another embodiment, the first field of view and the second field of view are substantially the same and are substantially overlapping. 
     Preferably, the first camera assembly and the second camera assembly respectively have a first imaging sensor and a second imaging sensor, distinct to each other. 
     Preferably, the gain and/or the exposure time for the first camera assembly and for the second camera assembly are the gain and/or the exposure time of the first imaging sensor and a second imaging sensor, respectively. 
     Preferably, the first imaging sensor and the second imaging sensor are 2D sensors. 
     Preferably, the first imaging sensor is a VGA or WVGA global shutter sensor. 
     Preferably, the second imaging sensor is a mega pixel imaging sensor. 
     Preferably the first resolution is a resolution of a VGA sensor (that is, up to 640×480 pixels) or of a WVGA global shutter sensor (that is up to 800×480 pixels). 
     Preferably, the second resolution is a resolution of a megapixel imaging sensor or higher resolution imaging sensor. More preferably, the second resolution denotes a resolution at least equal to 1024×768 (XVGA sensor), more preferably at least equal to 1280×1024 pixels. 
     Preferably, the first frame rate is at least equal to 100 fps. 
     Preferably, the second frame rate is lower than 100 fps. 
     In a preferred embodiment, the first camera assembly is configured to perform at least one operation among: localization of coded information position and determination of coded information speed. 
     Preferably, the second camera assembly is configured to perform coded information decoding by using the coded information position localized by the first camera assembly and/or by using the coded information speed determined by the first camera assembly. 
     Preferably, the object is moving with respect to the coded information reader. 
     Preferably, the coded information reader is a fixed position reader. 
     Preferably, said first camera assembly is configured to trigger the second camera assembly when the object enters or approaches the second field of view of the second camera assembly (if coded information position is localized by the first camera assembly) or after lapse of a predetermined period of time from object presence detection. Preferably, said first camera assembly is configured to trigger the second camera assembly when one of said conditions is first met. 
     Preferably, in a standby condition of the coded information reader, the first camera assembly is configured to perform object presence detection by periodically checking object presence in a first phase wherein the first camera assembly is used with a resolution lower than said first resolution and a frame rate higher than said first frame rate and, in case of object detection in said first phase, to switch to a second phase, wherein object presence detection is verified by using the first camera assembly set with said first resolution and said first frame rate. This advantageously enables to optimize the time required to perform object presence detection. 
     Preferably, the first camera assembly is configured to start the determination of the operating parameters and the coded information decoding after object presence is detected in said first phase. 
     Preferably, the second camera assembly is on, in a status wherein it does not perform frame acquisition but it is “ready to acquire” until triggered by the first camera assembly. 
     Preferably, the first camera assembly comprises at least one of an infrared illuminator and a far-red illuminator. 
     Preferably, said object presence detection is performed by using said at least one of infrared illuminator and far-red illuminator. 
     Preferably, in the first phase of object presence detection, said at least one of infrared illuminator and far-red illuminator is turned on in a flashing mode. This advantageously enables to optimize power consumption and reduce blurring in the image. 
     Preferably, in the second phase of object presence detection, said at least one of infrared illuminator and far-red illuminator is kept continuously on. 
     The coded information reader preferably comprises at least one visible-light illuminator. 
     Preferably, at least one among said operations of determination of operating parameters, localization of coded information position and determination of coded information speed is performed with said visible-light illuminator. 
     Preferably, the illumination level for the first camera assembly and for the second camera assembly is the illumination level of said at least one visible-light illuminator. 
     Preferably, in case coded information decoding performed by the second camera assembly is unsuccessful, the coded information reader is configured to acquire frames with both the first camera assembly and the second camera assembly and to process them together so as to determine distance of the coded information and to perform coded information decoding, based on the frames acquired by the second camera assembly, only when the determined distance reaches a determined value. 
    
    
     
       Further characteristics and advantages of the present invention will become clear from the following detailed description of some example embodiments thereof, provided just as non-limiting examples, said description being made with reference to the attached drawings, in which: 
         FIG. 1  schematically shows a coded information reader according to the invention; 
         FIG. 2  schematically shows a first field of view and a second field of view according to an embodiment of the coded information reader of  FIG. 1 ; 
         FIG. 3  schematically shows an embodiment of the coded information reader of  FIG. 1 ; 
         FIG. 4  shows a flow chart describing an example of operation of the coded information reader of  FIG. 3 ; 
         FIG. 5  schematically shows the interactions of components of the coded information reader of  FIG. 3  during the operation of  FIG. 4 ; 
         FIG. 6  schematically shows three examples of response times for high resolution decoding. 
     
    
    
       FIG. 1  shows a coded information reader  1  according to the invention, comprising a housing  5  with a transparent window (not shown). The housing  5  houses a first camera assembly  10 , a second camera assembly  20 , a speaker  2 , a lighting device  3 , and a user interface  4 . 
     Preferably, the coded information reader  1  is a fixed position reader, intended to fixedly rest in a predetermined position. More preferably, the coded information reader  1  is a presentation scanner. Objects (not shown) with coded information  6  (shown in  FIG. 6 ) to be read by the reader  1  are grabbed by a user (e.g. a cashier) and moved towards the terminal reading face (corresponding to the transparent window). 
     The first camera assembly  10  and a second camera assembly  20  comprise each an imaging sensor, a processing unit, a lighting system and an optical system (optical lenses and/or mirrors). The imaging sensors of the two camera assemblies  10 ,  20  are different and separate, while the processing unit, the lighting system and the optical system may be all separate or at least in part shared. 
     For example, in the embodiment shown in  FIG. 3 , the two camera assemblies  10 ,  20  have separate imaging sensors, lighting systems and optical systems, and a common processing unit. In particular, the first camera assembly  10  and the second camera assembly  20  respectively comprise a first imaging sensor  12  and a second imaging sensor  22 , a first lighting system  14  and a second lighting system  24 , a first optical system  16  and a second optical system  26  and a single shared processing unit  30 . 
     The first imaging sensor  12  and the second imaging sensor  22  are 2D sensor arrays, having pixels arranged in rows and columns. 
     The first imaging sensor  12  and the second imaging sensor  22  respectively have a first (low) resolution and a second (high) resolution, higher than the first resolution. The first imaging sensor  12  and the second imaging sensor  22  respectively have a first frame rate and a second frame rate, lower than the first frame rate. 
     The first imaging sensor  12  preferably is a global shutter sensor. The first imaging sensor  12  is, for example, a video graphic array (VGA) sensor with a resolution of 640×480 pixels. For example, the first frame rate of the first imaging sensor  12  is equal to 100 fps or 120 fps (frame per second). 
     The second imaging sensor  22  preferably is a global shutter mega pixel array sensor, for example with a resolution of 1280×1024 pixels. For example, the second frame rate of the second imaging sensor  22  is equal to 45 fps or 60 fps (frame per second). The mega pixel array sensor may be, for example, a charged coupled device (CCD) or a complementary oxide semiconductor (CMOS). 
     The first optical system  16  and the second optical system  26  comprise each suitable optical lenses and/or mirrors (not shown) adapted to define a first field of view  18  and a second field of view  28  (shown in  FIG. 2 ), respectively. The first field of view  18  and the second field of view  28  substantially have a pyramidal shape. Frames of objects in transit within the first field of view  18  and the second field of view  28  are acquired by the first imaging sensor  12  and the second imaging sensor  22 , respectively. 
     In the preferred embodiment shown in  FIGS. 2 and 6   c , the second field of view  28  is smaller than the first field of view  18  and is substantially comprised within the first field of view  18 . In particular, upon exiting the transparent window of the housing  5 , a major part of the (or preferably almost the whole) second field of view  28  is within the first field of view  18 . Moreover, as shown in  FIGS. 2 and 6   c , the optical axis  28 ′ of the second field of view  28  is substantially parallel to and close to or coincident with the optical axis  18 ′ of the first field of view  18  so that the second field of view  28  is almost centered within the first field of view  18 . For example, the second field of view  28  may be equal to 50° or 40°. For example, the first field of view  18  can be 20% bigger than the second field of view  28 . 
     According to another embodiment (shown in  FIG. 6 b   ), the second field of view  28  and the first field of view  18  have substantially the same size and are fully or in a major part overlapping upon exiting the transparent window of the housing  5 . 
     The embodiments of  FIGS. 2, 6   c  and  6   b  advantageously enable the bar code reader  1  to read coded information  6  from objects entering the field of views  18 ,  28  from any direction. 
     The first lighting system  14  comprises an infrared illuminator  13  and a visible-light illuminator  15 . 
     In alternative or in addition to the infrared illuminator  13 , the first lighting system  14  can comprise a far red illuminator (not shown) corresponding to the O 2  hole of the solar spectrum, this in order to improve object detection performances even if the coded information reader  1  is placed in a position in front of a window, so receiving sun light radiations. 
     The second lighting system  24  comprises a visible-light illuminator  25 . The visible-light illuminator  25  of the second lighting system  24  preferably is the same as the visible-light illuminator  15  of the first lighting system  14 . In  FIG. 3  they are shown as distinct. 
     The processing unit  30  comprises a processor  32  and a memory  34 . The processing unit  30  may also comprise suitable filter(s) and/or analog to digital converter and/or amplifier circuitry (not shown). In an embodiment, at least part of the filter(s), analog to digital converter and amplifier circuitry are part of the first imaging sensor  12  and the second imaging sensor  22 . 
     The first imaging sensor  12  and the second imaging sensor  22  are associated with a control circuit (not shown) for adjusting the exposure time of the first imaging sensor  12  and the second imaging sensor  22  and the gain of the amplifier circuitry. The control circuit may be part of the imaging sensors and/or of the processing unit  30 . 
     The processing unit  30  has a dual camera interface (that is, two data links) to download frames from the first imaging sensor  12  and the second imaging sensor  22 . In an alternative embodiment (not shown), the processing unit  30  can have a single data link with a multiplexer. 
     As schematically shown in  FIG. 5 , in the coded information reader  1 , the first camera assembly  10  is configured to provide the following functions:
         detecting object presence by using the infrared and/or far red illuminator  13  (block  501 ) and by acquiring frames from the first imaging sensor  12  (blocks  502 ,  503 ), and, in case of object presence detected:
           turning the visible-light illuminator  15  on (block  506 ) and the infrared and/or far red illuminator  13  off;   acquiring frames from the first imaging sensor  12  for determining operating parameters for the first camera assembly  10  and also for the second camera assembly  20  and trying to decode coded information  6  (blocks  502 ,  503 );   and, in case of failure:
               activating the second camera assembly  20 , which performs coded information decoding, with the visible-light illuminator  25  on and with the operating parameters set as determined by the first camera assembly  10  (blocks  504 ,  505 ,  506 ).   
               
               

     In case of successful coded information decoding either by the first camera assembly  10  or the second camera assembly  20  (block  507 ), the reader  1  outputs a green spot and a beep sound via the speaker  2  and the lighting device  3 , and resets operation (block  508 ). 
     In the following, the operation of the coded information reader  1  will be explained more in detail with reference to the flow chart of  FIG. 4  and to the embodiment of  FIGS. 2 and 3 . 
     In a standby mode of the reader  1  (block  401  of  FIG. 4 ), the second imaging sensor  22  is inactive (that is, powered on without acquiring frames, but ready to acquire) while the first imaging sensor  12  is active to acquire frames and to send them to the control unit  30  to perform object presence detection on the basis of the acquired frames. The infrared illuminator and/or the far red illuminator  13  is (are) working and the visible light illuminator(s)  15 ,  25  is (are) switched off. The first imaging sensor  12  is preferably binned so as to use it at a lower resolution with respect to said first resolution and at a faster speed. Typical values could be QVGA (320×240 pixels) at 180 fps with binning, or QQVGA (160×120 pixels) at 360 fps with binning. 
     Moreover, the infrared illuminator and/or the far red illuminator  13  is (are) turned on periodically, only for a short time, in flashing mode. This advantageously enables to save power consumption. Moreover, the use of infrared illuminator and/or far red illuminator  13  advantageously enables to perform object presence detection without the user being aware of it and, thus, without bothering him/her. 
     The reader  1  operates in this first phase of object presence detection (block  401 ) until at block  402  some significant changes of the brightness are detected in the binned acquired frames by the control unit  30 . In this case, the coded information reader  1  passes into a second phase of object presence detection (block  403 ). 
     In this second phase, the control unit  30  sets the operating parameters of the first camera assembly  20  using information coming from the binned frames acquired in the first phase (typically 2 frames). Thereafter, with the operating parameters set in this way, the first imaging sensor  12  acquires frames at its full resolution (i.e. the said first resolution) and sends them to the control unit  30  to verify object presence detection on the basis of the frames thus acquired (typically 1 frame) and, at the same, to make a first attempt of coded information decoding. In this second phase, the infrared illuminator and/or the far red illuminator  13  is (are) kept continuously on. Purpose of this second phase is to evaluate more deeply the presence of a moving object into the field of view  18  of the first camera assembly  10  and to make, at the same, the first attempt of decoding. At block  404 , it is checked the success of object presence detection and of coded information decoding. If they are both successful, the reader  1  returns to block  401  via block  411 , wherein the result of the decoding is outputted (for example through the speaker  2 , the lighting device  3  and/or the user interface  4 ). If presence of a moving object is detected (with unsuccessful coded information decoding), the reader  1  passes to block  405 . On the other side, if no moving object is detected, the reader  1  carries on the second phase of block  403  for a predetermined time; thereafter it returns to block  401 . 
     It is observed that the splitting of the object presence detection is said first phase of block  401  and said second phase of block  403  advantageously enables to optimize processing time and power consumption required by object presence detection operation. Moreover, the second phase of block  403  enables to improve the efficiency of object presence detection avoiding to erroneously turn visible light on (and consequently distract customer) when no moving object (or coded information  6 ) is actually present in the field of view  18 . 
     At block  405 , the infrared illuminator and/or the far red illuminator  13  is (are) turned off and the visible-light illuminator  15  of the first camera assembly is turned on. Moreover, the first imaging sensor  12  acquires frames and sends them to the control unit  30  in order to simultaneously:
         try to decode coded information  6  (according to algorithms known in the art),   analyse the pixels of the first imaging sensor  12  covering the first field of view  18  of the first camera assembly  10  in order to determine the operating parameters thereof,   analyse the pixels of the first imaging sensor  12  covering the second field of view  28  of the second camera assembly  20  in order to determine the operating parameters thereof.       

     The operating parameters are on of: gain of the amplifier circuitry, exposure time of the first or second imaging sensor  12 ,  22 , object illumination level, or any combination thereof. The object illumination level relates to the status (on/off) of the visible-light illuminator  15 ,  25  and to its degree of illumination. Depending on the ambient light conditions, it may be suitable to keep the visible-light illuminator  15 ,  25  off (for example, if the object is already illuminated by a proper illuminator such as in the case of the screen of a mobile phone displaying coded information  6  to be read) or to properly adjust the illumination level of the illuminator. 
     At block  405 , the operating parameters for the second camera assembly  20  are in particular obtained by:
         analysing the pixels of the first imaging sensor  12 , which cover the second field of view  28  of the second camera assembly  20 , in order to determine intermediate values for the operating parameters, and   deriving actual values for the operating parameters of the second camera assembly  20  from the determined intermediate values by using suitable conversion parameters, which may be established thanks to a suitable calibration procedure that may be performed in a manufacturing stage or an initial set-up phase of the reader  1 .       

     Preferably, at block  405 , the control unit  30  also tries to localize, according to techniques that are within the skills of a person skilled in the art, coded information position and/or coded information speed. 
     At block  406 , it is checked the success of the attempt for coded information decoding. If coded information  6  is decoded, the reader  1  returns to block  401  via block  411 , wherein the result of the decoding is outputted. On the other side, if no coded information  6  is decoded, the reader  1  carries on the attempt of coded information decoding at block  405  till a first one of the following conditions is met: lapse of a predetermined time from object detection or coded information position approaching (or entering) the field of view  28  of the second camera assembly  20  (this latter condition being used only when the coded information position is localized at block  405 ). Thereafter, at block  407 , the control unit  30  activates the second imaging sensor  22  to acquire frames, with the operating parameters thereof set as determined at block  405 . At the same time, the first imaging sensor  12  stops acquiring frames. Moreover, the control unit  30  processes the frames acquired by the second imaging sensor  22  to decode coded information  6 . 
     When coded information position and/or coded information speed have been determined at block  405 , this information will be used by the control unit  30  in order to quickly localize coded information position into the first frame acquired by the second imaging sensor  22  and analyse only a small portion of said frame. 
     At block  408 , it is checked the success of coded information decoding performed on the basis of frames acquired by the second imaging sensor  22 . If coded information is decoded, the reader  1  returns to block  401  via block  411 . On the other side, if no coded information  6  is decoded, the reader  1  carries on the attempt of coded information decoding at block  407  for a predetermined time. Thereafter, at block  409 , the control unit  30  activates both the first imaging sensor  12  and the second imaging sensor  22  to acquire frames and performs a triangulation calculation (if needed projecting a spot light pattern during acquisition) in order to estimate distance (and raw estimation of the resolution) of the coded information  6 . If the control unit  30  finds that distance and resolution of the coded information  6  are too much challenging for being decoded on the basis of frames from the second (high resolution) imaging sensor  22 , then the reader  1  will stay in this intermediate mode wherein frames from both imaging sensors  12 ,  22  are processed in order to estimate distance of the coded information  6 . Once the distance is not so challenging, the control unit  30  tries to decode the coded information  6  on the basis of frames acquired from the second (high resolution) imaging sensor  22  only. 
     At block  410 , it is checked the success of coded information decoding. If coded information  6  is decoded, the reader  1  returns to block  401  via block  411 . On the other side, if no coded information  6  is decoded, the reader  1  carries on the attempt of coded information decoding at block  409  for a predetermined time. Thereafter, it returns directly to block  401 . 
     As schematically shown in  FIG. 2 , for any specific coded information moving velocity, the reader  1  can guarantee decoding capability over a specific minimum distance from the vertex of the pyramidal field of view, hereinafter named “guaranteed distance” d g . For distances lower than the guaranteed distance d g , the reader  1  is not able to guarantee decoding capability. The more reactive is the reader  1 , (that is, the faster is the reader  1  in decoding coded information  6 ), the shorter is the guaranteed distance d g . 
     The Applicant estimated the guaranteed distance d g  for two different readers, considering the guaranteed distance d g  as the distance from the vertex of the pyramidal field of view at which, for a specific coded information moving velocity, the coded information  6  reaches the optical axis  28 ′ of the second field of view  28  at the time the high resolution coded information decoding starts. 
     For comparison purposes, the Applicant estimated the guaranteed distance d g  of a reader based on a single (high resolution) camera by using the following formula:
 
 d   g =MV*(( N   pre /FR pre )+(( N   dec −1)/FR dec ))/(tangent(FOV HR /2))
 
wherein:
 
     MV=the coded information moving velocity 
     FOV HR =is the field of view of the high resolution camera 
     N pre =needed frames in order to perform object presence detection and optimization of operating parameters 
     N dec =needed frames (considering operating parameters already optimized) in order to perform coded information decoding 
     FR pre =is the frame rate used during object presence detection and optimization of operating parameters 
     FR dec =is the frame rate used during coded information decoding 
     The Applicant also estimated the guaranteed distance d g  for a reader made according to the invention, using both a first (low resolution and fast) camera assembly  10  and a second (high resolution) camera assembly  20 , by using the following formula:
 
 d   g =MV*(( N   pre /FR pre )+(( N   dec −1)/FR dec ))/(tangent(FOV FC /2))
 
where FOV FC  is the first filed of field of view  18  of the first (fast) camera assembly  10 .
 
     Tables 1 and 2 below show the values of d g  obtained by using the above formulas for the three following cases: 
     Case 1: reader with a single HR camera (mega pixel sensor with array size of 1280×1024 pixels with a frame rate of 45 fps) making coded information decoding at full resolution, while performing object presence detection and operating parameters optimization at lower resolution (640×480 pixels) and higher frame rate (60 fps), by using the HR camera binned in VGA resolution; 
     Case 2: reader according to the invention wherein the first of view  18  and the second field of view  28  are substantially the same and overlap (FOC FC =FOV HR ); 
     Case 3: reader according to the invention wherein the first of view  18  is 20% bigger than the second field of view  28  (FOC FC =1.2*FOV HR ). 
     The d g  values of table 1 have been calculated using the following values: 
     FOV HR =50°; N pre =5 (2 for object presence detection and 3 for operating parameters optimization); N dec =1; FR dec =45 fs (considering a mega pixel sensor 1280×1024 pixels); FR pre =100 fs (for cases 2 and 3, considering a VGA sensor 640×480 pixels); FR pre =60 fs (for case 1, considering the mega pixel sensor binned in VGA configuration). 
     The d g  values of table 2 are calculated using the same values used for the table 1 apart from the FOV HR  value that, in this case, is 40°. 
     
       
         
           
               
               
             
               
                   
                 TABLE 1 
               
             
            
               
                   
                   
               
               
                   
                 d g  (cm) 
               
            
           
           
               
               
               
               
               
            
               
                   
                 MV (m/s) 
                 Case 1 
                 Case 2 
                 Case 3 
               
               
                   
                   
               
            
           
           
               
               
               
               
               
            
               
                   
                 4 
                 71 
                 43 
                 35 
               
               
                   
                 3 
                 54 
                 32 
                 26 
               
               
                   
                 2 
                 36 
                 21 
                 17 
               
               
                   
                 1 
                 18 
                 11 
                 9 
               
               
                   
                   
               
            
           
         
       
     
     
       
         
           
               
               
             
               
                   
                 TABLE 2 
               
             
            
               
                   
                   
               
               
                   
                 d g  (cm) 
               
            
           
           
               
               
               
               
               
            
               
                   
                 MV (m/s) 
                 Case 1 
                 Case 2 
                 Case 3 
               
               
                   
                   
               
            
           
           
               
               
               
               
               
            
               
                   
                 4 
                 92 
                 55 
                 45 
               
               
                   
                 3 
                 69 
                 41 
                 34 
               
               
                   
                 2 
                 46 
                 27 
                 22 
               
               
                   
                 1 
                 23 
                 14 
                 11 
               
               
                   
                   
               
            
           
         
       
     
     For the above cases the Applicant also calculated the response time for high resolution decoding (as the processing time necessary for performing object presence detection and operating parameters determination before starting coded information decoding by the high resolution sensor). The following values were obtained by considering a coded information moving velocity of 1 m/s:
         83 ms for case 1 (which becomes 133 ms taking into account a waste of time corresponding to about three frames for switching the mega pixel sensor from binned configuration into full resolution configuration);   50 ms for cases 2 and 3.       

     These results are schematically represented in  FIG. 6  wherein the horizontal arrows F, G schematically represent the path covered by a coded information  6  in the response time, respectively in case 1 (arrow F) and in cases 2-3 (arrow G). The longer is the arrow, the longer is the covered path and, thus, the response time. From  FIG. 6 c   , it can be observed that for case 3 (wherein the first field of view  18  is bigger than and comprises the second field of view  28 ) the farer is the coded information  6  the higher is the path covered within the first field of view  18  of the first imaging sensor  12 . For example, considering a coded information  6  at a distance of 17.8 cm from the vertex of the pyramidal field of view, the Applicant calculated that for the reader of case 3, Table 1, of said 50 ms of response time, 13 ms are spent in the first field of view  18  of the first imaging sensor  12  while 37 ms are spent in the second field of view  28  of the second imaging sensor  22  (situation represented by the arrow G below in  FIG. 6 c   , crossing both field of views  18 ,  28 ). On the other hand, considering a coded information  6  at a distance of 45 cm from the vertex of the pyramidal field of view, the Applicant calculated that for the reader of case 3, Table 1, the whole response time of 50 ms is spent in the first field of view  18  of the first imaging sensor  12  (situation represented by the upper arrow G in  FIG. 6 c   , crossing only field of view  18 ). 
     Accordingly, the results of the above calculations show that the reader  1  of the invention (cases 2 and 3) is more reactive (that is, faster in decoding coded information  6 ) and provides a shorter guaranteed distance d g . The invention thus enables to improve responsivity of the reader  1  while preserving high resolution capabilities. 
     Moreover, the embodiment of case 3, wherein the first field of view  18  is bigger than and comprises the second field of view  28 , enables to obtain an even shorter guaranteed distance d g . The responsivity of the reader  1  is thus further improved, still preserving high resolution capabilities. Indeed, as schematically shown in  FIG. 6 c   , this latter embodiment advantageously enable to have—as a whole—a bigger field of view and to exploit a part of or the whole first field of view  18  of the first (fast) camera assembly to perform object presence detection and operating parameters optimization. The second field of view  28  of the second camera assembly  20  can thus be in a major part or fully exploited only for coded information decoding (without wasting any time to carry out said operations). In these cases, the Applicant estimates that, on average, coded information decoding can be already carried out at the first frame taken by the second (high resolution) imaging sensor  22 . 
     It is observed that the optimal value FOV FC  for the first filed of field of view  18  of the first camera assembly  10  depends on the decoding capability of the first camera assembly  10 . In particular, it shall be a trade-off between two effects:
         bigger FOV FC  means more reactive reader and consequently shorter guaranteed distances d g ;   smaller FOV FC  means bigger decoding depth of field of the first camera assembly  10  and, consequently, more decoding support to second camera assembly  20  in order to speed up decoding of low resolution coded information  6 . Preferably, the ratio between the first field of view and the second field of view is comprised between 1 and 1.5 (1≤FOV FC /FOV HR ≤1.5).