Patent Publication Number: US-11030477-B2

Title: Image quality assessment and improvement for performing optical character recognition

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     This application is a continuation of co-pending U.S. application Ser. No. 16/138,669, filed Sep. 21, 2018, which is a continuation of U.S. application Ser. No. 15/337,285, filed on Oct. 28, 2016 and now issued as U.S. Pat. No. 10,108,883, each of which is expressly incorporated herein by reference in its entirety. 
    
    
     FIELD 
     The present disclosure relates to techniques for extracting data from documents. More specifically, the present disclosure relates to techniques for facilitating optical character recognition (OCR) by assessing and improving the quality of an image for performing the OCR. 
     BACKGROUND 
     Data processing and exchange are essential for a variety of businesses and personal transactions. For example, small businesses use accounting and inventory data to obtain and share reports regarding inventory sales, customer invoices, or cash flow. Similarly, healthcare providers examine medical records to view patient information related to insurance providers, medical conditions, or office visits. 
     In addition, data exchange frequently relies on document exchange including electronic versions of documents such as word-processing documents, spreadsheets, or Portable Document Format (PDF) documents and paper documents (e.g., which may be generated electronically). For example, a business may manage business transactions with a set of customers by creating a set of bills, invoices, or other types of documents containing data associated with the business transactions and sending the documents to the respective customers. The customers use the data in the documents to pay the bills or invoices, respond to the business, or update their records of the transactions. Similarly, companies, banks and mortgage companies may provide several tax documents (e.g., W-2, 1099-Int, etc.) to employees and customers as needed to file their tax returns, for example, by using commercially available income tax preparation software. 
     Optical character recognition (OCR) systems are generally used to detect text present in an image of a document (e.g., a tax document) and to convert the detected text into a machine readable representation. Digital camera and mobile document image acquisition are becoming increasingly popular in the world of optical character recognition and text recognition. In order to accurately recognize text with a conventional OCR engine, the image typically needs to be of a high quality. However, images produced, for example, using digital cameras and other mobile devices may include many distortions and may produce images of poor quality. The quality of an image depends on various factors including quality of camera used to produce the image, power of the lens, resolution, light intensity, relative motion between the camera and the text document, level of focus, background including back lighting, and the like, in addition to quality of the text document. Thus, an image produced using such a device may include various forms of distortion including blur, skew, rotation, shadow marks and other forms of distortion. 
     As a result, a computing device performing optical character recognition on an image of the document may have difficulty extracting information from a given document for use by other applications (e.g., tax preparation application). Instead, the recipient or document owner may have to manually enter data from the document into an application. 
     SUMMARY 
     One embodiment presented herein includes a computer-implemented method for identifying information in an electronic document. The method generally includes obtaining a reference image of the electronic document, distorting the reference image by adjusting different sets of one or more parameters associated with a quality of the reference image to generate a plurality of distorted images, analyzing each distorted image to detect the adjusted set of parameters and corresponding adjusted values, determining an accuracy of detection of the set of parameters and the adjusted values, and training a model based at least on the plurality of distorted images and the accuracy of the detection, wherein the trained model determines at least a first technique for adjusting a set of parameters in a second image to prepare the second image for optical character recognition. 
     One embodiment presented herein includes an apparatus for identifying information in an electronic document. The apparatus includes at least one processor and a memory coupled to the at least one processor. The at least one processor is generally configured to obtain a reference image of the electronic document, distort the reference image by adjusting different sets of one or more parameters associated with a quality of the reference image to generate a plurality of distorted images, analyze each distorted image to detect the adjusted set of parameters and corresponding adjusted values, determine an accuracy of detection of the set of parameters and the adjusted values, and train a model based at least on the plurality of distorted images and the accuracy of the detection, wherein the trained model determines at least a first technique for adjusting a set of parameters in a second image of the electronic document to prepare the second image for optical character recognition (OCR) 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  illustrates an example of a computing environment  100  used to perform OCR on a document, in accordance with certain aspects of the present disclosure. 
         FIG. 2  illustrates an OCR app, in accordance with certain aspects of the present disclosure. 
         FIG. 3  illustrates an example electronic image including a document  310 , in accordance with certain aspects of the present disclosure. 
         FIG. 4  illustrates example operations performed as part of an offline process used for identifying information in a document, in accordance with certain aspects of the present disclosure. 
         FIG. 5  illustrates example operations performed as part of a run-time process used for identifying information in a document, in accordance with certain aspects of the present disclosure. 
         FIG. 6  illustrates an example computing system used to identify information in a document, in accordance with certain aspects of the present disclosure. 
     
    
    
     DETAILED DESCRIPTION 
     Embodiments presented herein provide techniques for assessing and improving quality of images of documents for optical character recognition (OCR). Traditionally images are obtained from various sources, subjectively evaluated, and an attempt is made to determine the viability of the images using a very limited source image set. When dealing with a small number of devices with a limited set of image capture conditions and related operational parameters, optimizing the images using the traditional optimization techniques may work. However, these traditional techniques are not scalable and do not provide the operational parameters that affect image quality. 
     Conventional systems attempt to obtain as many source images as possible, do a crude subjective categorization and then determine accuracy of OCR with respect to a candidate image based on the image set. However, conventional systems have access to a very limited image set since raw test images are generally obtained from a single image source or a select number of images are obtained from multiple sources. The limited image set tends to bias the results of image processing since the analysis tends to be biased on the limited set of images as a whole without isolating the specific characteristics that may affect accuracy. There is generally little opportunity to discern the specific characteristics that affect accuracy or degrade OCR. Providing raw images does not allow for the isolation of very specific image characteristics that may affect OCR accuracy, and subsequently the ability to tune or adjust for those anomalies in the image. Evaluating images as a whole (especially from small image sets) does not allow correlation of image correction techniques with specific measurable values. For example, if we know that a specific histogram (gathered from image analysis) results in better recognition applying a certain binarization threshold, the process may be further refined to determine a function that varies the binarization threshold over a range of histograms. Looking at entire images and subjectively categorizing them does not allow for this subtle correlation to be made. 
     Aspects of the present disclosure provide a scalable technique for optimizing (e.g., improving quality) images for OCR. These techniques allow generation of a large amount of test images representing real life images with various kinds and amounts of distortions by an automated random process and include determining the operational parameters affecting the quality of an image, and determining how and to what extent the determined parameters are to be adjusted to improve the quality of the image to acceptable levels for OCR. The techniques also include determining whether or not an image may be optimized for OCR. 
     In some cases, data may be included in a document such as a word-processing document, spreadsheet, Portable Document Format (PDF) document, web page, paper document or another type of formatted document containing structured or semi-structured data. For example, the document may be a bill, invoice, form, statement, transcript, record, receipt, tax document (e.g., W-2, 1099-Int, 1099-Dive, consolidated brokerage statement, 1040, 1040A, 1040EZ, Schedule A, Schedule C), or other type of document that includes a specific type or set of data without adhering to a strict layout or format for showing the data. Further references to “document” in the following description include all forms of documents noted above. 
     Optical character recognition (OCR) systems are generally used to detect text present in an image of a document (e.g., a tax document) and to convert the detected text into its equivalent electronic representation for use in certain applications (e.g. tax applications). 
     Easy access to computing devices including personal computers (PCs) and portable computing devices (e.g., smart phones) and plentiful network bandwidth have made these computing devices very popular for sharing and processing data. For instance, users may easily download and execute a range of applications on their computing devices such as PCs, tablets and smartphones to process and share data. Factors such as larger screen sizes, increased computational capabilities, and inherent portability and convenience have made such devices the favorite computing platform of many users. 
     These computing devices generally include or support camera devices that may be used to capture images of documents (e.g., tax documents) for OCR of data (e.g., text and non-text) included in the documents. In order to accurately recognize text with an OCR engine, the image typically needs to be of a high quality. However, images produced, for example, using digital cameras and other devices may include many distortions and may produce images of poor quality. An image produced using such a device may include various forms of distortion including blur, skew, rotation, shadow marks and other forms of distortion. Each image is associated with a combination of these parameters and a quality of the image is generally dictated by the values each of these parameters take. Each of these parameters typically has a base value representative of an ideal or close to ideal value and any deviation from this value may adversely affect the quality of an image with respect to the parameter. Generally, a larger deviation from the base value of a parameter leads to a larger distortion of the image with respect to the parameter. 
     Thus, an image generally needs to be processed to optimize parameters which contribute to image distortion and to improve image quality for subsequent OCR. In some cases, determining the quality of an image, and determining the operational parameters of an OCR system is difficult due the factors discussed above. This difficulty is further compounded when the number potential sources of the images and the various operational parameters these sources contribute associated with quality of an image are considered. For example, mobile devices may be associated with parameters including differing operating systems, cameras, versions, on-device image processing and the like. Scanners may be associated with parameters including resolution, gamuts, feed quality, and the like. PC cameras may be associated with parameters including resolutions, image framing, quality and the like. Each of these parameters associated with an image needs to be determined and optimized to optimize the quality of the image for OCR. 
     Further, various methods may be used to adjust each parameter or a combination of parameters associated with the quality of an image, in order to improve the quality of the image. For example, binarization is a method that is used to turn a color image into a black and white image. Different techniques may be used to perform binarization of an image. Each of these techniques may further include various parameters that may affect and alter the result of the binarization, which may need to be optimized to optimize the binarization. 
     Traditionally images are obtained from the various sources discussed above, subjectively evaluated, and an attempt is made to determine the viability of the images using a very limited source image set. For example, if a particular technique of binarization generally achieves good results for a number of images, the technique is chosen and used for all images. Thus, the binarization technique and associated parameters are not optimized for each image. 
     When we are dealing with a small number of devices with a limited set of image capture conditions and related operational parameters, optimizing the images using the traditional optimization techniques may work. However, these traditional techniques are not scalable and do not provide the operational parameters that affect image quality. Thus, there is a need for a scalable solution that objectively defines the operating parameters. 
     Aspects of the present disclosure provide a scalable technique for optimization (e.g., improving quality) of images for OCR. These techniques include determining the operational parameters affecting the quality of an image, and determining how and to what extent the determined parameters are to be adjusted to improve the quality of the image to acceptable levels for OCR. The techniques also include determining whether or not an image may be optimized for OCR. 
     In certain aspects, a computing device may be configured to obtain one or more reference images of a document. In an aspect, each of the reference images represents a high quality digital representation of the document in which values of parameters associated with the quality of the document are within acceptable ranges. In particular, the computing device may obtain high quality electronic (also referred to as “digital”) images of the documents. The documents may correspond to different structured or semi-structured documents, e.g., tax forms. The electronic images may correspond to electronic versions of the documents (e.g., PDF or Microsoft Word formats), or may correspond to high quality captured images of a physical document that are captured using an image capturing device, such as a camera phone, video camera, digital camera, digital scanner, etc., that is connected to or implemented in the computing device, or separate from the computing device. 
     The computing device may deliberately distort (e.g., reduce in quality) an obtained reference image by adjusting values of one or more parameters (e.g., blur, skew, rotation, shadow marks and other forms of distortion) associated with the quality of the image by known amounts to deviate from their acceptable value ranges. The goal is to generate images that are representative of typical images in real life scenarios. By modifying the high quality reference images to generate the distorted images, the computing device has control over the process and exactly knows what parameters and by what amounts the parameters were adjusted. This is more practical than looking up thousands of images, and addresses the industry problem of limited image sets available for evaluation and system training. The computing device may then analyze the deliberately distorted reference image using an independent process to attempt to determine the parameters that need to be adjusted and to what extent the values of these parameters are to be adjusted to optimize the distorted image, that is, bring the distorted reference image close to its original quality. 
     As the computing device already knows what parameters were adjusted and by what amounts were they adjusted for distorting the reference image, it may determine whether the independent process successfully determined one or more of the parameters that were adjusted and the accuracy of the determined adjustment amounts by comparing the results of the analyzing by the independent process with the information regarding the distorting of the reference images. Thus, this technique provides the operating parameters and provides a correlation of the parameters to accuracy. The distorted images and other information including the information relating to the distortion of the reference images, the operational parameters and accuracy of the distorted image analysis is used to train a computer model (e.g., a Convolutional Neural Network, CNN). 
     In certain aspects, when a client image of a candidate document is presented to the computing system, the computing device, based on the trained computer model, determines a set of parameters that need to be adjusted and by what amounts these parameters need to be adjusted (e.g., to bring the parameter values within acceptable ranges) in order to improve the quality of the image for OCR. The computer model (or another process of the computing system) further determines one or more techniques (e.g., techniques for binarization, rotation, de-skew, keystone correction etc.) for adjusting the determined parameters by the determined amounts. In certain aspects, the computing system, based on the trained computer model, may determine whether or not the quality of the client image may be improved to an acceptable level for OCR. If not, the client image may be discarded and the client may be asked to capture another image of the candidate document. 
     Different aspects of these techniques are described in more detail herein, along with additional examples of how the techniques may be used to assess and improve image quality to perform OCR. 
       FIG. 1  illustrates an example of a computing environment  100  used to perform OCR on a document, in accordance with certain aspects of the present disclosure. As shown, the computing environment  100  includes client system  110 , a mobile device  120 , and a server  130 , each connected to a network  150 . The network  150 , in general, may be a wide area network (WAN), local area network (LAN), wireless LAN (WLAN), personal area network (PAN), a cellular network, or any other technology that allows devices to communicate electronically with other devices. In a particular embodiment, the network  150  is the Internet. 
     Client system  110  is included to be representative of a general purpose computing system hosting software applications that may be installed and run locally, or may be used to access applications running on the server  130 . The client system  110  may include mobile computing systems including smart phones, tablet computers, laptop computers, or any other mobile computing devices or systems capable of running software applications, capturing images and communicating over a network (e.g., the internet). In an aspect, client system  110  includes non-mobile computing devices such as desktop computers or other non-mobile computing devices capable of capturing images and communicating over a network (e.g., the internet). As shown, client system  110  includes web browser  112  used to access the server  130  by rendering web pages (e.g., generated by the OCR module  134 ) from or running applications on the server  130 . In certain aspects, the web browser  112  may include mobile versions of the web browser  112  when the client system  110  is a mobile computing system such as a smart phone or a tablet computer. The client system  110  includes an OCR app  114 . The OCR app  114  may be a local application that is installed and run locally on the client system  110 . In certain aspects, the OCR app  114  may be representative of a component of a client server application (or other distributed application) which can communicate with the server  130  over network  150 . For example, OCR app  114  may be a “thin” client where the processing is largely directed by the OCR app  114 , but performed by computing systems of the server  130  or a software application installed on client system  110 . The client system  110  may further include a camera  116  for capturing images. The client system  110  may also include other devices that may be used for image capturing, for example, a digital scanner (not shown). 
     As shown, the server  130  includes an OCR module  134  that may run locally on the server  130 . Further, the OCR module  134  may be accessed and executed by devices on the network  150 , such as the client system  110 . The OCR module  134 , for example, may generate web pages that are rendered by a browser such as browser  112 . In another example, OCR module  134  may be accessed by or work along with client side applications, such as OCR app  114  as discussed. 
     In certain aspects, the OCR app  114  and the OCR module  134  may be used to implement the techniques for facilitating identifying information in a document in accordance with aspects of the present disclosure. For example, the OCR module  134  may perform an offline process including obtaining high quality reference images corresponding to various documents, deliberately distorting the reference images by adjusting one or more quality parameters by known amounts to generate distorted images representative of real life images, analyzing the distorted images to attempt to detect the parameters and the adjusted values, determining accuracy of the detection, and training a computer model (e.g., CNN) using the distorted reference images and information regarding the distorting, analyzing and determined accuracy of detection. 
     OCR app  114  may start a run-time process by obtaining a client image of a candidate document. The OCR module  134  at the server  130  may receive the obtained client image from the client system  110  over the network  150  and determine a set of parameters that are to be adjusted and by what amounts the determined parameters are to be adjusted based on the trained computer model of the offline process, and determine one or more techniques to be used for adjusting the determined parameters by the determined amounts for improving the quality of the client image (e.g., optimize the client image) for OCR. The OCR module  134  may process the client image by adjusting the determined parameters by the determined amounts to improve the quality of the client image for OCR. In an aspect, the results of analyzing the client image based on the trained computer model (e.g., determined parameters, adjustment values, and adjustment techniques) may be communicated to the client system  110  and the client image may be adjusted by the OCR app  114  based on the received results. 
     The runtime process may further include performing OCR on the optimized client image. In an aspect, the OCR is performed by the OCR app  114  at the client system  110 . In an alternative aspect, the OCR is performed by the OCR module  134  at the server  130  and the results of the OCR are communicated to the client system  110 . The runtime process may also determine whether a client image is viable or not for OCR recognition. If not, the client image may be discarded and the client system  110  or the mobile device  120  may be directed to capture another image of the candidate document. In an aspect, this step is performed by the OCR module at the server  110  and the results including whether or not the client image is viable for OCR are communicated to the client system  110 . 
     In certain aspects, the client image of the candidate document may be obtained by capturing the image of the document using the camera  116  of the client system  110 , or other image capturing mechanisms available at the client system  110 . In an aspect, the image of the candidate document may include an electronic version of the candidate document (e.g., in PDF format, Microsoft Word format etc.). 
     In certain aspects, the offline processing and run time processing may be performed independently by the OCR app  114  and the OCR module  134  or may be distributed over the OCR app  114  and the OCR module  134  as discussed above. For example, if the client system  110  includes relatively powerful computing system, one or more processing steps of the offline and run time processes may be carried out by the client system  110 . However, if the client system is a mobile computing system with limited processing capabilities, most of the offline and runtime processing may be carried out at the server  130 . 
     In certain aspects, OCR module  134  may obtain the set of reference images for the offline processing from production images stored locally at the server (e.g., reference image bank  136 ) or received from the client system  110 . In an aspect, one or more of the reference images may be captured by an operator of the client system  110  using camera  116  and may be sent to the server  130 . In an aspect, reference images include electronic versions of one or more documents (e.g., in PDF format, Microsoft Word format etc.). In certain aspects, the client image may be captured at the client system  110  and may be sent to the server  130  for run-time processing by OCR module  134 , for example, in order to take advantage of relatively faster processing speeds at the server  130 . The results of the run-time process (e.g., labels and corresponding values identified in the document as a result of OCR) may be sent back to the client system  110 , for example, for use by one or more applications at these devices (e.g., tax preparation application). 
       FIG. 2  illustrates an OCR app  200   a  (e.g. OCR app  114  as shown in  FIG. 1 ) and an OCR module  200   b  (e.g., OCR module  134  as shown in  FIG. 1 ), in accordance with certain aspects of the present disclosure. As shown in  FIG. 2 , OCR app  200   a  includes an image capture component  202  and an OCR results. The OCR module includes a data overlay module  204 , an image distortion module  206 , an image analyzer  208 , a machine learning module  210 , an image adjuster  215  and an OCR component  216 . The machine learning module  210  further includes machine learning algorithm  212  and a computer model  214 . 
     At the OCR app  200   a , the image capture component  202  controls an image capture device (e.g., camera  116  of client system  110  of  FIG. 1 ) to obtain image of a document. In certain aspects, the images captured by the image capture component  202  may include client images that need to be processed for carrying out OCR as part of runtime processing or reference images used to train a computer model (e.g., computer model  214 ) as part of offline processing as discussed above. In an aspect, the images captured by the image capture component  202  are sent to the OCR module  200   b  for further processing. 
     The OCR module  200   b  may obtain a reference image of a particular document from a local storage or a storage server over a network (e.g., network  150 ) or may use a high quality image of the document captured by an image capture device (e.g., camera  116 ) at a client system as a reference image. The data overlay module  204  overlays data (e.g., associates data) upon a reference image. The data may include information regarding at least one characteristic corresponding to the reference image including a type of the reference image (e.g., tax form W2, 1099 etc.), labels within the reference image (e.g., Name, SSN etc.), and formats of values associated with the labels (e.g., SSN format). The overlaid information may improve accuracy of OCR. In an aspect, this information may also be used to train the computer model  214 . 
     Image distortion module  206  deliberately distorts reference images by adjusting values of one or more quality parameters associated with the images by known amounts to generate one or more distorted images that are representative of real life images. 
     The image analyzer  208  analyzes the distorted reference images to attempt to detect the adjusted parameters and their adjustment values. The image analyzer  208  further determines an accuracy of the detection by determining how accurately the adjusted parameters and the adjusted values were detected. 
     The machine learning module  210  includes a machine learning algorithm  212  that trains a computer model  214  using the distorted reference images and information regarding the distorting, image analysis and the determined accuracy of detection of the parameters and the adjusted values. The trained computer model  214  accepts client images (e.g., client images captured by the image capture component  202  and received from the OCR app  202   a ) and determines a set of parameters that are to be adjusted and by what amounts the determined parameters are to be adjusted, and further determines one or more techniques to be used for adjusting the determined parameters by the determined amounts for improving the quality of the client image for OCR. The trained computer model also determines whether a client image is viable or not for OCR. If not, the image capture component  202  may be directed to capture another image of the candidate document. 
     The image adjuster  215  adjusts a client image by adjusting the determined parameters by the determined amounts to improve the quality of the client image for OCR. 
     The OCR component  216  evaluates the adjusted/optimized client images to identify what text or numeric content is depicted in the images. The results of the OCR including the identified text and numeric content is sent to the OCR results component  203  at the OCR app  200   a  for use by one or more applications (e.g., tax related applications) at a client system (e.g., client system  110  of  FIG. 1 ). 
       FIG. 3  illustrates an example electronic image  300  including a document  310 , in accordance with certain aspects of the present disclosure. In the embodiment shown, the electronic image  300  includes the document  310  in a portion of the electronic image  300 , as well as other background imagery  305 . For example, the electronic image  300 , as shown, may correspond to a client image of the document  310  captured using an image capture device (e.g., camera of a mobile device) and include the background imagery  305  (e.g. the physical surface upon which the document is placed by a customer, so that the customer can acquire an image of the document with her/his device camera). However, in some other embodiments, the electronic image  300  may not include any background imagery  305 , for example, the electronic image  300  corresponds to a high quality electronic version of the document  310  and may be used as a reference image, or if the customer is providing an electronic version of a document  310 . 
     In certain aspect, a client image (e.g., image  300 ) of a candidate document (e.g., document  310 ) captured using a camera device (e.g., camera  116  or  126 ) may include several distortions including blur, rotation, skew, or background imagery  305 . Aspects of the present disclosure discuss techniques for improving quality of a client image including adjusting parameters corresponding to these distortions. 
     The document  310 , as shown, may be a form (e.g., tax form such as a W2). The document  310  includes a number of elements  320  (e.g., grid elements, boxes, rectangles, etc.). The elements  320  may correspond to areas on the document  310  where textual information may be found. For example, an element  320  may include a label  322  (e.g., text label), which may indicate the type of data (e.g., social security number (SSN)) that is within the element  320 . The element  320  may further include a value  324  (e.g., text), which may be the actual value of the textual information (e.g., SSN) included in the element. The value  324  may be found within a region  326  (e.g., a text entry area) within the element  320  designated as the location for the value  324 . Aspects of the present disclosure identify such elements  320  and regions  326  within a document  310  via segmentation, identifying at least labels (e.g., label  322 ) of the document  310  and formats of corresponding values for overlaying upon a reference document. 
       FIG. 4  illustrates example operations performed as part of an offline process  400  used for identifying information in a document, in accordance with certain aspects of the present disclosure. Offline process  400  begins, at  402  by obtaining, for each type of document at least one reference image. In an aspect, the document is a semi-structured document such as a W2 tax document. In some aspects, the document may be a structured document. In an aspect, the reference image for a particular type of document is selected from a pool of reference images  420  corresponding to several types of documents. For example, the pool of images  420  may include a reference image for each type of document (e.g., bill, invoice, standard form, statement, transcript, record, receipt, or tax document) and a reference image may be selected from the pool for further processing that corresponds to a particular type of document frequently requested for OCR. In certain aspects, the pool of reference images  420  may be constructed by obtaining the images from multiple sources. For example, as shown in  FIG. 4 , reference images may be obtained from an end user device (e.g., mobile device  422 ), which, for example are captured using an image capturing device or available as electronic versions. Similarly, the reference images may be obtained from a server  424 , a local storage  426  or over a network  428  (e.g., stored in a cloud or other remote computing system). 
     As noted above, each of the reference images represents a high quality digital representation of a document in which values of parameters associated with the quality of the image are within acceptable ranges. 
     At  404 , each of the obtained reference image is deliberately distorted (e.g., reduced in quality) adjusting different sets of one or more parameters associated with a quality of the reference image to generate a plurality of distorted images. For example, to generate each distorted image values of one or more parameters associated with the quality of the reference image are adjusted by known amounts to deviate from their acceptable value ranges. As noted above, the goal is to generate images that are representative of typical real life images, for example, captured using a camera device on a mobile device. In certain aspects, different combinations of parameters may be adjusted (or the same combination of parameters may be adjusted by different amounts) to obtain a plurality of distorted images with respect to the reference image, each distorted image representative of a real life client image. In an aspect, a random process is used to model the distribution of various parameters (e.g., blur, luminosity, skew etc.) in a real world scenario to produce the distorted images. 
     At  406  information regarding one or more characteristics is associated with the reference image. The information may include a type of the reference image (e.g., tax form W2, 1099 etc.), labels within the reference image (e.g., Name, SSN etc.), and formats of values associated with the labels (e.g., SSN format). In an aspect, regions are identified (e.g., via a segmentation technique) within a reference image as corresponding to certain types of data (e.g., labels, values etc.) included in the document based on information known about the document. These regions are identified within the reference image and associated with the reference image to improve accuracy of OCR. 
     At  408 , each of the deliberately distorted reference images is analyzed using an independent process to attempt to detect the adjusted parameters and to what extent the values of these parameters were adjusted. In an aspect, analysis of the distorted reference image is performed using a combination of EXIF data and simple machine learning techniques. The machine learning techniques use a simple anomaly classification of trained anomalies that are used to classify the extent of aberrations (e.g., distortions), for example, significance of blur, apparent contrast, overall luminosity, etc. These aberrations are pre-trained and use a simple scale that may be reproduced through artificial means (e.g., Gaussian blur, binarization, color balance adjustments, etc.) 
     At  410 , it is determined how accurately the adjusted parameters and their corresponding adjusted values were detected. As the process already knows what parameters were adjusted and by what amounts were they adjusted for distorting the reference image, it may determine whether the independent process successfully determined one or more of the parameters that were adjusted and the accuracy of the determined adjustment amounts by comparing the results of the analyzing by the independent process with the information regarding the distorting of the reference image. For example, if the skew parameter of the reference image was adjusted by 20% the system ideally should detect that the skew parameter was adjusted and that the adjustment value is 20%. Thus, by comparing the result of analyzing the distorted reference image and the known adjust parameters and corresponding values, the system may determine how accurately are the parameters and adjusted amounts are detected. 
     At  412 , a model (e.g., computer model including CNN) is trained based at least on the distorted reference images and the determined accuracy of detecting the parameters and their corresponding adjustment values, the trained computer model to be used to determine at least one technique for adjusting a set of parameters in a second client image (e.g., that corresponds to the distorted reference image in quality) to prepare the image for OCR. 
       FIG. 5  illustrates example operations performed as part of a run time process  500  used for identifying information in a document, in accordance with certain aspects of the present disclosure. 
     At  502 , an image (e.g., client image)  524  of a candidate document is obtained. In an aspect, the candidate document corresponds to the document whose reference image was processed in the offline process of  FIG. 4 . For example, the candidate document is a semi-structured document such as a W2 tax document. In an aspect, the image  524  is captured using a camera of a mobile device (e.g. mobile device  520 ). In an aspect, a user may capture multiple images of the candidate document and may manually select the image  524  from the multiple captured images for further processing. 
     At  504 , based on the trained model of the offline process  400  of  FIG. 4 , at least one technique is determined for adjusting one or more parameters associated with the acquired image  524  to improve the quality of the image in preparation for OCR. In an aspect, it is also determined how much these parameters are to be adjusted to optimize the client image for OCR. 
     At  510  the adjusted/optimized client image is evaluated using OCR techniques to identify information from the client image. 
     In certain aspects, once OCR of the optimized client image is completed, accuracy of the OCR may be determined. For example, an operator may manually check the identified information and confirm if various text/values were accurately identified. If the operator determines that certain information was not accurately identified, the optimized/adjusted client images may be feedback to the computer model to repeat the process of determining parameters, corresponding adjustment values and techniques for adjustment to improve the OCR. With this feedback loop the computer model may learn how best to optimize certain parameters. 
     In an aspect, the identified information (e.g., including labels and corresponding obtained values of a W2 tax document) may be used for further processing of data by one or more applications at a device. For example, the identified labels and values of a candidate W2 tax document may be used to populate labels and value fields in an interface  530  of a tax preparation application at a mobile device. 
       FIG. 6  illustrates an example computing system  600  used to identify information in a document, in accordance with certain aspects of the present disclosure. In an aspect, the computing system  600  is used to process one or more steps related to image quality assessment and improvement discussed above and store related information including one or more components shown in  FIGS. 1 and 2 . As shown, the computing system  600  includes, without limitation, a central processing unit (CPU)  606 , a network interface  615 , a memory  620 , and storage  640 , each connected to a bus  617 . The computing system  600  may also include an I/O device interface  610  connecting I/O devices  612  (e.g., keyboard, display, mouse devices, image capture devices, etc.) to the computing system  600 . Further, the computing elements shown in computing system  600  may correspond to a physical computing system (e.g., a system in a data center), a physical computing system with one or more components being accessed via a network, or may be a virtual computing instance executing within a computing cloud. 
     The CPU  606  retrieves and executes programming instructions stored in the memory  620  as well as stored in the storage  640 . The bus  617  is used to transmit programming instructions and application data between the CPU  606 , I/O device interface  610 , storage  640 , network interface  615 , and memory  620 . It may be noted that CPU  606  is included to be representative of a single CPU, multiple CPUs, a single CPU having multiple processing cores, and the like, and the memory  640  is generally included to be representative of a random access memory or other volatile memory. The storage  640  may be a disk drive, or flash storage device, or other non-volatile memory device. Although shown as a single unit, the storage  640  may be a combination of fixed and/or removable storage devices, such as fixed disc drives, removable memory cards, optical storage, network attached storage (NAS), or a storage area-network (SAN). 
     It may be noted that, descriptions of embodiments of the present disclosure are presented above for purposes of illustration, but embodiments of the present disclosure are not intended to be limited to any of the disclosed embodiments. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the described embodiments. The terminology used herein was chosen to best explain the principles of the embodiments, the practical application or technical improvement over technologies found in the marketplace, or to enable others of ordinary skill in the art to understand the embodiments disclosed herein. 
     In the preceding, reference is made to embodiments presented in this disclosure. However, the scope of the present disclosure is not limited to specific described embodiments. Instead, any combination of the following features and elements, whether related to different embodiments or not, is contemplated to implement and practice contemplated embodiments. Furthermore, although embodiments disclosed herein may achieve advantages over other possible solutions or over the prior art, whether or not a particular advantage is achieved by a given embodiment is not limiting of the scope of the present disclosure. Thus, the following aspects, features, embodiments and advantages are merely illustrative and are not considered elements or limitations of the appended claims except where explicitly recited in a claim(s). Likewise, reference to “the invention” shall not be construed as a generalization of any inventive subject matter disclosed herein and shall not be considered to be an element or limitation of the appended claims except where explicitly recited in a claim(s). 
     Aspects of the present disclosure may take the form of an entirely hardware embodiment, an entirely software embodiment (including firmware, resident software, micro-code, etc.) or an embodiment combining software and hardware aspects that may all generally be referred to herein as a “component,” “circuit,” “module” or “system.” Furthermore, aspects of the present disclosure may take the form of a computer program product embodied in one or more computer readable medium(s) having computer readable program code embodied thereon. 
     Any combination of one or more computer readable medium(s) may be utilized. The computer readable medium may be a computer readable signal medium or a computer readable storage medium. A computer readable storage medium may be, for example, but not limited to, an electronic, magnetic, optical, electromagnetic, infrared, or semiconductor system, apparatus, or device, or any suitable combination of the foregoing. More specific examples a computer readable storage medium include: an electrical connection having one or more wires, a hard disk, a random access memory (RAM), a read-only memory (ROM), an erasable programmable read-only memory (EPROM or Flash memory), an optical fiber, a portable compact disc read-only memory (CD-ROM), an optical storage device, a magnetic storage device, or any suitable combination of the foregoing. In the current context, a computer readable storage medium may be any tangible medium that can contain, or store a program. 
     The flowchart and block diagrams in the figures illustrate the architecture, functionality and operation of possible implementations of systems, methods and computer program products according to various embodiments of the present invention. In this regard, each block in the flowchart or block diagrams may represent a module, segment or portion of code, which comprises one or more executable instructions for implementing the specified logical function(s). In some alternative implementations the functions noted in the block may occur out of the order noted in the figures. For example, two blocks shown in succession may, in fact, be executed substantially concurrently, or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved. Each block of the block diagrams and/or flowchart illustrations, and combinations of blocks in the block diagrams and/or flowchart illustrations can be implemented by special-purpose hardware-based systems that perform the specified functions or acts, or combinations of special purpose hardware and computer instructions. 
     While the foregoing is directed to embodiments of the present disclosure, other and further embodiments of the disclosure may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.