Source: http://www.google.com/patents/US20050189412?dq=6985872
Timestamp: 2014-12-29 10:29:25
Document Index: 534868434

Matched Legal Cases: ['art 108', 'art 108', 'art 108', 'art 108', 'art 108', 'art 108', 'art 400', 'art 500', 'art 600', 'art 600', 'art 700']

Patent US20050189412 - Method of merchandising for checkout lanes - Google PatentsSearch Images Maps Play YouTube News Gmail Drive More »Sign inAdvanced Patent SearchPatentsMethods and computer readable media for recognizing and identifying items located on the belt of a counter and/or in a shopping cart of a store environment for the purpose of reducing/preventing bottom-of-the-basket loss, checking out the items automatically, reducing the checkout time, preventing consumer...http://www.google.com/patents/US20050189412?utm_source=gb-gplus-sharePatent US20050189412 - Method of merchandising for checkout lanesAdvanced Patent SearchPublication numberUS20050189412 A1Publication typeApplicationApplication numberUS 11/050,163Publication dateSep 1, 2005Filing dateFeb 2, 2005Priority dateFeb 27, 2004Also published asUS7246745, WO2005088569A1Publication number050163, 11050163, US 2005/0189412 A1, US 2005/189412 A1, US 20050189412 A1, US 20050189412A1, US 2005189412 A1, US 2005189412A1, US-A1-20050189412, US-A1-2005189412, US2005/0189412A1, US2005/189412A1, US20050189412 A1, US20050189412A1, US2005189412 A1, US2005189412A1InventorsAlec Hudnut, Alex Simonini, Michael Cremean, Howard MorganOriginal AssigneeEvolution Robotics, Inc.Export CitationBiBTeX, EndNote, RefManReferenced by (36), Classifications (12), Legal Events (5) External Links: USPTO, USPTO Assignment, EspacenetMethod of merchandising for checkout lanesUS 20050189412 A1Abstract Methods and computer readable media for recognizing and identifying items located on the belt of a counter and/or in a shopping cart of a store environment for the purpose of reducing/preventing bottom-of-the-basket loss, checking out the items automatically, reducing the checkout time, preventing consumer fraud, increasing revenue and replacing a conventional UPC scanning system to enhance the checking out speed. The images of the items taken by visual sensors may be analyzed to extract features using the scale-invariant feature-transformation (SIFT) method. Then, the extracted features are compared to those of trained images stored in a database to find a set of matches. Based on the set of matches, the items are recognized and associated with one or more instructions, commands or actions without the need for personnel to visually see the items, such as by having to come out from behind a check out counter or peering over a check out counter. Images(10) Claims(101)
BACKGROUND OF THE INVENTION The present invention generally relates to methods for checking out merchandise and, more particularly, to methods for automating the checkout of merchandise based on visual pattern recognition integrated with discrete product identification. In many retail store environments, such as in grocery stores, department stores, office supply stores, home improvements stores, and the like, consumers typically carry selected items in a shopping cart and utilize a checkout stand to pay for the selected items. A checkout stand, or equivalently point-of-sale (POS), can be arranged in many configurations. In general, the checkout stand, often referred to as a lane, includes one or more belts, or merely has a stationary surface, generally supported by a counter or cabinet. A bar code scanner is typically recessed into the counter or cabinet. Also included at the checkout stand are the register, cash drawer, a keyboard, a credit card machine, a receipt printer, monitor or display, telephone and other such accessory equipment. One goal within the retail industry has been to design the checkout stand in a manner that can expedite the checkout process and provide convenience to the customers and the cashier. However, at times, the experience level of the cashier becomes the major factor that limits the checkout speed. Also, during busy hours, the customer may have to wait in a line to pay for the selected items regardless of the experience level of the cashier, and, in some cases, walk away from the store without purchasing the items they selected. In addition, from time to time, the cashier may need to manually input the price information of items via the keyboard if the scanner fails to read the UPC barcode or the item is sold by weight, which can further slow down the checkout process. In addition to the checkout speed limitation, the retail industry has another problem to resolve, commonly referred to as �bottom-of-the-basket� (BoB) loss. A typical shopping cart includes a basket that is designed for storage of the consumer's merchandise. At times, a consumer will use the lower shelf space located below the shopping cart basket as additional storage space, especially for relatively large and/or bulky merchandise. On occasion, when a consumer uses the lower shelf space to carry merchandise, the consumer can leave the store without paying for the merchandise. This may occur because the consumer inadvertently forgets to present the merchandise to the cashier during checkout, or because the consumer intends to defraud the store and steal the merchandise. In both cases, the cashier and other store personnel have also failed to identify the BoB items and include them in the transaction. Another source of BoB loss is due to cashier fraud, which can occur when the cashier knows items are on the bottom of the basket and chooses not to ring them up or manually rings up an alternative, less expensive item. This practice is known as collusion or sweethearting. Estimates suggest that a typical supermarket can experience between $3,000 to $5,000 of bottom-of-the-basket revenue losses per lane per year. For a typical modern grocery store with 10 checkout lanes, this loss represents $30,000 to $50,000 of unaccounted revenue per year. For a major grocery chain with 1,000 stores, the potential revenue recovery can reach in excess of $50 million dollars annually. Several efforts have been undertaken to minimize or reduce bottom-of-the-basket losses. These efforts generally fall into three categories: process change and training; lane configuration change; and supplemental detection devices. Process changes and training is aimed at getting cashiers and baggers to inspect the cart for BOB items in every transaction. This approach has not been effective because of high personnel turnover, the requirement of constant training, low skill level of the personnel, lack of mechanisms to enforce the new behaviors, and lack of initiative to track and prevent collusion. Lane configuration change is aimed at making the bottom of the basket more visible to the cashier, either by bring the cart on a separate side of the lane from the customer, or by using a second cart that requires the customer to fully unload his or her cart and reload the items onto the second cart. Changing lane configuration is expensive, does not address the collusion, and is typically a more inconvenient, less efficient way to scan and check out items. Furthermore, heavy items on the bottom of the basket will be required to be lifted for checkout causing time delay and sometime physical injury from heavy lifting. Supplemental devices include mirrors placed on the opposite side of the lane to enable the cashier to see BoB items without leaning over or walking around the lane; infrared sensing devices to alert the cashier that there are BoB items, and video surveillance devices to project an image to the cashier. Infrared detection systems, such as those marketed by Kart Saver, Inc. <URL: http://www.kartsaver.com> and Store-Scan, Inc. <URL: http://www.store-scan.com> employ infrared sensors designed to detect the presence of merchandise located on the lower shelf of a shopping cart when the shopping cart enters a checkout lane. Disadvantageously, these systems are only able to detect the presence of an object and are not able to provide any indication as to the identity of the object. Consequently, these systems cannot be integrated with the store's existing checkout subsystems and instead rely on the cashier to recognize the merchandise and input appropriate associated information, such as the identity and price of the merchandise, into the store's checkout subsystem by either bar code scanning or manual key pad entry. As such, alerts and displays for these products can only notify the cashiers of the potential existence of an item, which cashiers can ignore or defeat. Furthermore these systems do not have mechanisms to prevent collusion. In addition, disadvantageously, these infrared systems are relatively more likely to generate false positive indications. For example, these systems are unable to distinguish between merchandise located on the lower shelf of the shopping cart and a customer's bag or other personal items, again causing cashiers to eventually ignore or defeat the system. Another supplemental device that attempts to minimize or reduce bottom-of-the-basket losses is marketed by VerifEye Technologies <URL: http://www.verifeye.com/products/checkout/checkout.html>. This system employs a video surveillance device mounted in the land and directed at the bottom of the basket. A small color video display is mounted by the register to aid the cashier in identifying if a BoB item exists. Again, disadvantageously, this system is not integrated with the POS, forcing reliance on the cashier to scan or key in the item. Consequently, the system productivity issues are ignored and collusions are not addressed. In one of the VerifEye's systems, an option to log image, time and location is available. This configuration nonetheless does not recover the lost items. As can be seen, there is a need for improved systems and methods that automatically detect and recognize items, either on the belt of a counter or in the shopping cart of a checkout lane, and replace or supplement a conventional UPC scanning and manual checkout process to increase the checkout speed and eliminate bottom-of-the-basket loss. SUMMARY OF THE INVENTION The present invention provides methods and systems through which one or more visual sensors operatively coupled to a computer system can view and recognize items located, for example, on the belt of a checkout lane, or on the basket or on the lower shelf of a shopping cart in the checkout lane of a retail store environment. This reduces or prevents bottom-of-the-basket loss, enhances the check out speed, and replaces or supplements a conventional UPC scanning system, which may translate into a considerable revenue increase to the store through both shrink loss reduction and increased checkout productivity. One or more visual sensors are placed at fixed locations in a checkout register lane such that when a belt carries the items or a shopping cart moves into the register lane, one or more objects within the fields of view of the visual sensors can be recognized and associated with one or more instructions, commands or actions without the need for personnel to visually see the objects, such as by having to come out from behind a check out counter or peering over a check out counter. In one aspect of the present invention, a method of increasing a rate of revenue at a point-of-sale includes steps of: moving in a substantially horizontal direction an object past a visual sensor; receiving visual image data of the object; comparing the visual image data with data stored in a database to find a set of matches; determining if the set of matches is found; sending a recognition alert, wherein the set of matches is used to expedite a transaction process at the point-of-sale. In another aspect of the present invention, a computer readable medium embodying program code with instructions for increasing a rate of revenue at a point-of-sale includes: program code for moving in a substantially horizontal direction an object past a visual sensor; program code for receiving visual image data of the object; program code for comparing the visual image data with data stored in a database to find a set of matches; program code for determining if the set of matches is found; and program code for sending a recognition alert, wherein the set of matches is used to expedite a transaction process at the point-of-sale. In still another aspect of the present invention, a method of preventing merchandise fraud includes steps of: receiving visual image data of merchandise to be checked out, said merchandise located in a shopping cart; comparing the visual image data with data stored in a database to find a set of matches; determining if the set of matches is found; and sending a recognition alert to a point-of-sale, wherein the recognition alert is used to prevent bottom-of-the-basket (BoB) fraud. In a further aspect of the present invention, a computer readable medium embodying program code with instructions for preventing merchandise fraud includes: program code for receiving visual image data of merchandise to be checked out, said merchandise located in a shopping cart; program code for comparing the visual image data with data stored in a database to find a set of matches; program code for determining if the set of matches is found; and program code for sending a recognition alert to a point-of-sale, wherein the recognition alert is used to prevent bottom-of-the-basket (BoB) fraud. In yet another aspect of the present invention, a method of automatically including merchandise in a checkout sale transaction to reduce checkout waiting in line time for a store customer includes steps of: receiving visual image data of merchandise to be checked out, said merchandise located in a shopping cart; comparing the visual image data with data stored in a first database to find a set of matches; determining if the set of matches is found; retrieving merchandise information from a second database; and sending the merchandise information to a point-of-sale, wherein the merchandise information is included in a sale transaction automatically. In still another aspect of the present invention, a computer readable medium embodying program code with instructions for automatically including merchandise in a checkout sale transaction to reduce checkout waiting in line time for a store customer includes: program code for receiving visual image data of merchandise to be checked out, said merchandise located in a shopping cart; program code for comparing the visual image data with data stored in a first database to find a set of matches; program code for determining if the set of matches is found; program code for retrieving merchandise information from a second database; and program code for sending the merchandise information to a point-of-sale, wherein the merchandise information is included in a sale transaction automatically. In an additional aspect of the present invention, a method of monitoring behavior of a cashier includes steps of: comparing a detection log of one or more bottom-of-the basket (BoB) items with a transaction log of the one or more BoB items; recording an action taken by the cashier to process each of the one or more BoB items; and correlating the action over a predetermined period to characterize the behavior of the cashier. In yet an additional aspect of the present invention, a computer readable medium embodying program code with instructions for monitoring behavior of a cashier includes: program code for comparing a detection log of one or more bottom-of-the basket (BoB) items with a transaction log of the one or more BoB items; program code for recording an action taken by the cashier to process each of the one or more BoB items; and program code for correlating the action over a predetermined period to characterize the behavior of the cashier. In a still additional aspect of the present invention, a method for processing at least one bottom-of-the-basket (BoB) item at a point-of-sale includes steps of: receiving match data; displaying a BoB list using the match data, the BoB list including at least one BoB item; selecting a particular BoB item from the BoB list; determining if quantity of the particular BoB item needs to be changed; determining if the particular BoB item needs to be deleted from the BoB list; adding the particular BoB item to a transaction log; sending the particular BoB item to a transaction; deleting the particular BoB item from the BoB list; and determining if the transaction is finished. In another aspect of the present invention, a computer readable medium embodying program code with instructions for processing bottom-of-the-basket (BoB) items at a point-of-sale includes: program code for receiving match data; program code for displaying a BoB list using the match data, the BoB list including at least one BoB item; program code for selecting a particular BoB item from the BoB list; program code for determining if quantity of the particular BoB item needs to be changed; program code for determining if the particular BoB item needs to be deleted from the BoB list; program code for adding the particular BoB item to a transaction log; program code for sending the particular BoB item to a transaction; program code for deleting the particular BoB item from the BoB list; and program code for determining if the transaction is finished. In yet a further aspect of the present invention, a method of automatically including merchandise in a checkout sale transaction to increase revenue includes steps of: receiving visual image data of merchandise to be checked out; analyzing the visual image data to extract one or more visual features; comparing the one or more visual features with feature data stored in a database to find a set of matches; determining if the set of matches is found; sending a recognition alert to a point of sale, wherein the recognition alert is used to prevent bottom-of-the-basket fraud; and sending merchandise information to the point-of-sale, wherein the merchandise information is included in a checkout sale transaction automatically. In another aspect of the present invention, a computer readable medium embodying program code with instructions for automatically including merchandise in a checkout sale transaction to increase revenue includes: program code for receiving visual image data of merchandise to be checked out; program code for analyzing the visual image data to extract one or more visual features; program code for comparing the one or more visual features with feature data stored in a database to find a set of matches; program code for determining if the set of matches is found; program code for sending a recognition alert to a point of sale, wherein the recognition alert is used to prevent bottom-of-the-basket fraud; and program code for sending merchandise information to the point-of-sale, wherein the merchandise information is included in a checkout sale transaction automatically. In an additional aspect of the present invention, a method of increasing accuracy in including merchandise in a checkout sale transaction to account for a store inventory includes steps of: receiving visual image data of merchandise to be checked out; comparing the visual image data with data stored in a database to find a set of matches; determining if the set of matches is found; and sending a recognition alert to a point of sale, wherein the recognition alert is used to prevent bottom-of-the-basket fraud. In another aspect of the present invention, a computer readable medium embodying program code with instructions for increasing accuracy in including merchandise in a checkout sale transaction to account for a store inventory includes: program code for receiving visual image data of merchandise to be checked out; program code for comparing the visual image data with data stored in a database to find a set of matches; program code for determining if the set of matches is found; and program code for sending a recognition alert to a point of sale, wherein the recognition alert is used to prevent bottom-of-the-basket fraud. In an additional aspect of the present invention, a method of linking a visual image of merchandise to a checkout sale transaction includes steps of: receiving visual image data of merchandise to be checked out; identifying the merchandise using the visual image data; and sending merchandise information to the point-of-sale, wherein the merchandise information is included in a checkout sale transaction automatically. In another aspect of the present invention, a computer readable medium embodying program code with instructions for linking a visual image of merchandise to a checkout sale transaction includes: program code for receiving visual image data of merchandise to be checked out; program code for identifying the merchandise using the visual image data; and program code for sending merchandise information to the point-of-sale, wherein the merchandise information is included in a checkout sale transaction automatically. These and other features, aspects and advantages of the present invention will become better understood with reference to the following drawings, description and claims.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a partial cut-away view of a system for merchandise checkout in accordance with one embodiment of the present invention; FIG. 2A is a schematic diagram of one embodiment of the system for merchandise checkout in FIG. 1; FIG. 2B is a schematic diagram of another embodiment of the system for merchandise checkout in FIG. 1; FIG. 2C is a schematic diagram of yet another embodiment of the system for merchandise checkout in FIG. 1; FIG. 3 is a schematic diagram of an object database and operation database illustrating an example of a relational database structure in accordance with one embodiment of the present invention; FIG. 4 is a flowchart that illustrates a process for recognizing and identifying objects in accordance with one embodiment of the present invention; FIG. 5 is a flowchart that illustrates a process for training the system for merchandise checkout in FIG. 1 in accordance with one embodiment of the present invention; and FIG. 6 is a flowchart illustrating exemplary steps for processing Bottom-of-the-Basket (BoB) items at a point-of-sale (POS) incorporated with the system of FIG. 1 in accordance with one embodiment of the present invention. FIG. 7 is a flowchart illustrating exemplary steps for monitoring the behavior of a cashier in accordance with one embodiment of the present invention. DETAILED DESCRIPTION OF THE INVENTION The following detailed description is of the best currently contemplated modes of carrying out the invention. The description is not to be taken in a limiting sense, but is made merely for the purpose of illustrating the general principles of the invention, since the scope of the invention is best defined by the appended claims. Broadly, the present invention provides systems and methods through which one or more visual sensors, such as one or more cameras, operatively coupled to a computer system can view, recognize and identify items for automatic check out. For example, the items may be checked out for purchase in a store, and as a further example, the items may be located in the basket or on the lower shelf of a shopping cart and/or on the counter belt of a checkout lane (or, equivalently, POS) in a store environment. The retail store environment can correspond to any environment in which shopping carts or other similar means of carrying items are used. One or more visual sensors can be placed at locations in a checkout register lane such that when a shopping cart moves into the register lane or a belt carries items, the items are within the field of view of the visual sensor(s). In contrast to the prior art which depends on a cashier to checkout the items manually, in the present invention, visual features present on one or more items within the field of view of the visual sensor(s) can be automatically detected as well as recognized, and then associated with one or more instructions, commands, or actions. The present invention can be applied, for example, to a point-of-sale replacing a conventional UPC barcode and/or manual checkout system with enhanced check out speed. Also, by detecting and recognizing the items carried on the lower shelf of a shopping cart, the present invention can provide a bottom-of-the-shelf prevention system. In addition, the present invention may be used to identify various objects on other moving means, such as luggage on a moving conveyor belt. More specifically, in one embodiment, by reducing or preventing bottom-of-the-basket loss, enhancing the check out speed, and replacing or supplementing a conventional UPC scanning system, the present invention may provide a considerable revenue increase to the store through both shrink loss reduction and increased checkout productivity. In yet another embodiment, the current invention prevents BoB loss occurring from automated or �self-checkout� lanes by utilizing the same visual scanning and pattern recognition and matching method to identify and ring up BoB items if the customer has not scanned or paid for the items and attempts to leave without doing so. In this embodiment, the placement of the visual scanning device in the checkout lane becomes part of the method to identify when BoB items have not yet been scanned by the customer, which then prevents the customer from closing out the transaction until these items have been acknowledged and accepted. In a further embodiment, the present invention can be fully integrated with the store's existing checkout subsystems on a plug-and-play configuration or a non-interfering parallel processing basis. Reliance on the cashier to recognize the merchandise and input appropriate associated information, such as the identity and price of the merchandise, into the store's checkout subsystem by either bar code scanning or manual key pad entry is replaced with a fully automated item identification and the associated product information including price and inventory information. As such, alerts and displays for these products can not only notify the cashier of the potential existence of an item, which cashier must respond to in order to complete a transaction, but provide a non-interrupt continuous customer checkout flow at the POS. Furthermore, the invention has mechanisms to prevent collusion, such as the freezing of a sale transaction until human intervention occurs, which may be the inclusion of the BoB item in the transaction. FIG. 1 is a partial cut-away view of a system 100 for automatic merchandise checkout in accordance with one embodiment of the present invention. FIG. 1 illustrates an exemplary application of the system 100 that has a capability to recognize and identify objects on a moveable structure. For the purpose of illustration, the system 100 is described as a tool for recognizing items 112, 116 and 122 carried in a basket 110, a lower shelf 114 of a shopping cart 108 and on a belt 120, respectively. However, it should be apparent to those of ordinary skill that the system 100 can also be used to recognize and identify objects in various applications, such as an automatic luggage checking system, based on the same principles as described hereinafter. As illustrated in FIG. 1, the system includes an aisle 102 and a checkout counter 104. The system 100 also includes visual sensors 118 a-c, a checkout subsystem 106 and a processing unit 103 that may include a computer system and/or databases. In one embodiment, the system 100 may include additional visual sensor 118 d that may be affixed to a neighboring checkout counter wall facing the shopping cart 108. Details of the system 100 will be given in following sections in connection with FIGS. 2A-3. For simplicity, only four visual sensors 118 a-d and one checkout subsystem 106 are shown in FIG. 1. However, it should be apparent to those of ordinary skill that any number of visual sensors and checkout subsystems may be used without deviating from the sprit and scope of the present invention. The checkout subsystem 106, such as a cash register, may rest on the checkout counter 104 and include one or more input devices. Exemplary input devices may include a barcode scanner, a scale, a keyboard, keypad, touch screen, card reader, and the like. In one embodiment, the checkout subsystem 106 may correspond to a checkout terminal used by a checker or cashier. In another embodiment, the checkout subsystem 106 may correspond to a self-service checkout terminal. For simplicity, only three visual sensors 118 a-c affixed to the checkout counter 104 are shown in FIG. 1. In some cases, one or more of the items 112, 116 and 122 may be blocked by neighboring item(s) such that the blocked items may not be seen by the three visual sensors 118 a-c. To obviate such blockage, in yet another embodiment, additional visual sensor 118 e may be installed over the cart 108 to capture the images of the items 112, 116 and 122. In a further embodiment, additional visual sensor 118 f may be floor mounted. In another embodiment, additional visual sensors may be mounted in a separate housing, and the like. Each of the visual sensors 118 a-f may be a digital camera with a CCD imager, a CMOS imager, an infrared imager, and the like. The visual sensors 118 a-f may include normal lenses or special lenses, such as wide-angle lenses, fish-eye lenses, omni-directional lenses, and the like. Further, the lens may include reflective surfaces, such as planar, parabolic, or conical mirrors, which may be used to provide a relatively large field of view or multiple viewpoints. During checkout, a shopping cart 108 may occupy the aisle 102. The shopping cart 108 may include the basket 110 and lower shelf 114. In one embodiment, as will be described in greater detail later in connection with FIG. 4, the visual sensors 118 a-f may be used to recognize the presence and identity of the items 112 and 116, which may replace a conventional UPC scanning system as well as manual checkout operation. In another embodiment, the customer or cashier may place the items 122 on the belt to expedite the checkout process. One of the major advantages of the system 100 may be that due to the nature of the pattern recognition performed by the system 100, only if an item is recognized and matched does the subsequent business process to display the item on the checkout subsystem 106 occur. This method may virtually eliminate false positives (i.e., alerts of BoB items that are not something that needs to be rung up), particularly of the type that occur with existing detection devices that alert the cashier based on the presence of any item on the bottom of the basket, which could include a customer's own packages, handbags, and the like. The negligible false positive rate of the system 100 may serve to reduce the likelihood a cashier will ignore the notification a BoB item needs to be rung up, and save time and enhance checkout lane productivity by not causing cashiers to spend time investigating items that do not need to be rung up. Another key advantage of the system 100 may be its ability to identify the item and thereby enable display and business process by the cashier (or customer in a self-checkout lane) integrated into the checkout subsystem 106. This may enable a requirement to acknowledge and accept the BoB item(s) before completing the transaction. Again, this is advantageous versus existing devices because it may not require the cashier or customer to remove the item from the BoB, manually scan the item, and then replace it. This may not only help to reduce shrink loss but also provide an improvement in checkout lane throughput and efficiency. Industry analysis typically puts this value at $1,500-$2,000 per second of delay per year per store (i.e., assuming the checkout process could be made faster by 1 second for every transaction, across every lane in a store, over the course of a year it would save $1,500-$2,000 per store annually). By reducing the number of items a cashier or customer needs to physically remove from the BoB, an estimated 5-10 seconds may be saved for every BoB transaction. Since BoB transactions may amount to approximately 10-15% of all store transactions, between 0.5-1.5 seconds could be saved by the system 100. FIG. 2A is a schematic diagram of one embodiment 200 of the system for merchandise checkout in FIG. 1. It will be understood that the system 200 may be implemented in a variety of ways, such as by dedicated hardware, by software executed by a microprocessor, by firmware and/or computer readable medium executed by a microprocessor or by a combination of both dedicated hardware and software. Also, for simplicity, only one visual sensor 202 and one checkout subsystem 212 are shown in FIG. 2A. However, it should be apparent to those of ordinary skill that any number of visual sensors and checkout subsystems may be used without deviating from the sprit and scope of the present invention. The visual sensor 202 may continuously capture images at a predetermined rate and compare two consecutive images to detect motion of an object that is at least partially within the field of view of the visual sensor 202. Thus, when a customer carries one or more items 116 on, for example, the lower shelf 114 of the shopping cart 108 and moves into the checkout lane 100, the visual sensor 202 may recognize the presence of the items 116 and send visual data 204 to the computer 206 that may process the visual data 204. In one embodiment, the visual data 204 may include the visual images of the one or more items 116. In another embodiment, an IR detector may be used to detect motion of an object. It will be understood that the visual sensor 202 may communicate with the computer 206 via an appropriate interface, such as a direct connection or a networked connection. This interface may be hard wired or wireless. Examples of interface standards that may be used include, but are not limited to, Ethernet, IEEE 802.11, Bluetooth, Universal Serial Bus, FireWire, S-Video, NTSC composite, frame grabber, and the like. The computer 206 may analyze the visual data 204 provided by the visual sensor 202 and identify visual features of the visual data 204. In one example, the features may be identified using an object recognition process that can identify visual features of an image. In another embodiment, the visual features may correspond to scale-invariant features. The concept of scale-invariant feature transformation (SIFT) has been extensively described by David G. Lowe, �Object Recognition from Local Scale-Invariant Features,� Proceedings of the International Conference on Computer Vision, Corfu, Greece, September, 1999 and by David G. Lowe, �Local Feature View Clustering for 3D Object Recognition,� Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, Kauai, Hi., December, 2001; both of which are incorporated herein by reference. It is noted that the present invention teaches an object recognition process that comprises two steps; (1) feature extraction and (2) recognize the object using the extracted features. However, it is not necessary to extract the features to recognize the object. The computer 206 may be a PC, a server computer, or the like, and may be equipped with a network communication device such as a network interface card, a modem, infra-red (IR) port, or other network connection device suitable for connecting to a network. The computer 206 may be connected to a network such as a local area network or a wide area network, such that information, including information about merchandise sold by the store, may be accessed from the computer 206. The information may be stored on a central computer system, such as a network fileserver, a mainframe, a secure Internet site, and the like. Furthermore, the computer 206 may execute an appropriate operating system. As is conventional, the appropriate operating system may advantageously include a communications protocol implementation that handles incoming and outgoing message traffic passed over the network. The computer 206 may be connected to a server 218 that may provide the database information 214 stored in an Object Database 222 and/or a Log Data Storage 224. The server 218 may send a query to the computer 206. A query is an interrogating process initiated by the Supervisor Application 220 residing in the server 218 to acquire Log Data from the computer 206 regarding the status of the computer 206, transactional information, cashier identification, time stamp of a transaction and the like. The computer 206, after receiving a query 214 from the server 218, may retrieve information from the log data 216 to pass on relevant information back to the server 218, thereby answering the interrogation. A Supervisor Application 220 in the server 218 may control the flow of information therethrough and manage the Object Database 222 and Log Data Storage 224. When the system 200 operates in a �training� mode, the server 218 may store all or at least part of the analyzed visual data, such as features descriptors and coordinates associated with the identified features, along with other relevant information in the Object Database 222. The Object Database 222 will be discussed in greater detail later in connection with FIG. 3. It will be understood that during system training, it may be convenient to use a visual sensor that is not connected to a checkout subsystem and positioned near the floor. For example, training images may be captured in a photography studio or on a �workbench,� which can result in higher-quality training images and less physical strain on a human system trainer. Further, it will be understood that during system training, the computer 206 may not need to output match data 208. In one embodiment, the features of the training images may be captured and stored in the Object Database 222. When the system 200 operates in an �operation� mode, the computer 206 may compare the visual features with the database information 214 that may include a plurality of known objects stored in the Object Database 222. If the computer 206 finds a match in the database information 214, it may return match data 208 to the checkout subsystem 206. Examples of appropriate match data will be discussed in greater detail later in connection with FIG. 3. The server 218 may provide the computer 206 with an updated, or synchronized copy of the Object Database 222 at regular intervals, such as once per hour or once per day, or when an update is requested by the computer 206 or triggered by a human user. When the computer 206 cannot find a match, it may send a signal to the checkout subsystem 212 that may subsequently display a query on a monitor and request the operator of the checkout subsystem 212 to take an appropriate action, such as identifying the item 116 associated with the query and providing the information of the item 116 using an input device connected to the checkout subsystem 212. In the operational mode, the checkout subsystem 212 may provide transaction data 210 to the computer 206. Subsequently, the computer 206 may send log data 216 to the server 218 that may store the data in the Object Database 222, wherein the log data 216 may include data for one or more transactions. In one embodiment, the computer 206 may store the transaction data 210 locally and provide the server 218 with the stored transaction data for storage in the Object Database 222 at regular intervals, such as once per hour or once per day. The server 218, Object Database 222 and Log Data Storage 224 may be connected to a network such as a local area network or a wide area network, such that information, including information from the Object Database 222 and the Log Data Storage 224, can be accessed remotely. Furthermore, the server 208 may execute an appropriate operating system. As is conventional, the appropriate operating system may advantageously include a communications protocol implementation that handles incoming and outgoing message traffic passed over the network. When the checkout subsystem 212 receives the match data 208 from the computer 206, the checkout subsystem 212 may take one or more of a wide variety of actions. In one embodiment, the checkout subsystem 212 may provide a visual and/or audible indication that a match has been found for the operator of the checkout subsystem 212. In one example, the indication may include the name of the object. In another embodiment, the checkout subsystem 212 may automatically add the item or object associated with the identified match to a list or table of items for purchase without any action required from the operator of the checkout subsystem 212. It will be understood that the list or table may be maintained in the checkout system 212 memory. In one embodiment, when the entry of merchandise or items or purchase is complete, a receipt of the items and their corresponding prices may be generated at least partly from the list or table. The checkout system 212 may also store an electronic log of the item, with a designation that it was sent by the computer 206. FIG. 2B is a schematic diagram of another embodiment 230 of the system for merchandise checkout in FIG. 1. It will be understood that the system 230 may be similar to the system 200 in FIG. 2A with some differences. Firstly, the system 230 may optionally include a feature extractor 238 for analyzing visual data 236 sent by a visual sensor 234 to extract features. The feature extractor 238 may be dedicated hardware. The feature extractor 238 may also send visual display data 240 to a checkout subsystem 242 that may include a display monitor for displaying the visual display data 240. Secondly, in the system 200, the computer 206 may analyze the visual data 204 to extract features, recognize the items associated with the visual data 204 using the extracted features and send the match data 208 to the checkout subsystem 212. In contrast, in the system 230, the feature extractor 238 may analyze the visual data 236 to extract features and send the analyzed visual data 244 to the server 246 that may subsequently recognize the items. As a consequence, the server 246 may send the match data 248 to the checkout subsystem 242. Thirdly, in the system 200, the checkout subsystem 212 may send transaction log data to the server 218 via the computer 206, while, in the system 230, the checkout subsystem 242 may send the transaction log data 250 to the server 246 directly. It is noted that both systems 200 and 230 may use the same object recognition technique, such as SIFT method, even though different components may perform the process of analysis and recognition. Fourthly, the server 246 may include a recognition application 245. It is noted that the system 230 may operate without the visual display data 240. In an alternative embodiment of the system 230, the visual display data 240 may be included in the match data 248. It will be understood that the components of the system 230 may communicate with one another via connection mechanisms similar to those of the system 200. For example, the visual sensor 234 may communicate with the server 246 via an appropriate interface, such as a direct connection or a networked connection, wherein examples of interface standards may include, but are not limited to, Ethernet, IEEE 802.11, Bluetooth, Universal Serial Bus, FireWire, S-Video, NTSC composite, frame grabber, and the like. Likewise, the Object Database 252 and the Log Data Storage 254 may be similar to their counterparts of FIG. 2A. The server 246 may execute an appropriate operating system. The appropriate operating system may include but is not limited to operating systems such as Linux, Unix, Microsoft� Windows� 3.1, Microsoft� Windows� 95, Microsoft� Windows� 98, Microsoft� Windows� NT, Microsoft� Windows� 2000, Microsoft� Windows� Me, Microsoft� Windows� XP, Apple� MacOS�, or IBM OS/2�. As is conventional, the appropriate operating system may advantageously include a communications protocol implementation that handles incoming and outgoing message traffic passed over the network. The system 230 may operate in an operation mode and a training mode. In the operation mode, when the checkout subsystem 242 receives match data 248 from the server 246, the checkout subsystem 242 may take actions similar to those performed by the checkout subsystem 212. In the operational mode, the checkout subsystem 242 may provide transaction log data 250 to the server 246. Subsequently, the server 246 may store the data in the Object Database 252. In one embodiment, the checkout subsystem 242 may store the match data 248 locally and provide the server 246 with the match data for storage in the Object Database 252 at regular intervals, such as once per hour or once per day. FIG. 2C is a schematic diagram of another embodiment 260 of the system for merchandise checkout in FIG. 1. The system 260 may be similar to the system 230 in FIG. 2B with a difference that the functionality of the feature extractor 238 may be implemented in a checkout subsystem 268. As illustrated in FIG. 2C, a visual sensor 262 may send visual data 264 to a checkout subsystem 268 that may analyze the data to generate analyzed visual data 272. In an alternative embodiment, the visual data 264 may be provided as an input to a server 274 via the checkout subsystem 268 if the server 274 has the capability to analyze the input and recognize the item associated with the input. In this alternative embodiment, the server 274 may receive the unmodified visual data 264 via the checkout subsystem 268, and perform the analysis and feature extraction of the unmodified visual data 264. Optionally, a feature extractor 266 may be used to extract features and generate analyzed visual data. The visual extractor 266 may be implemented within a visual sensor unit as shown in FIG. 2B or may be separate from the visual sensor. In this case, the checkout subsystem 268 may simply pass the analyzed visual data 272 to the server 274. The system 260 may operate in an operation mode and a training mode. In the operation mode, the checkout subsystem 268 may store a local copy of the Object Database 276, which advantageously may allow the matching process to occur relatively quickly. In the training mode, the server 274 may provide the checkout subsystem 268 with an updated, or synchronized copy of the Object Database 276 at regular intervals, such as once per hour or once per day, or when an update is requested by the checkout subsystem 268. When the system 260 operates in the operation mode, the server 274 may send the match data 270 to the checkout subsystem 268. Subsequently, the checkout subsystem 268 may take actions similar to those performed by the checkout subsystem 242. The server 274 may also provide the match data to a Log Data Storage 278. It will be understood that the match data provided to the Log Data Storage 278 can be the same as or can differ from the match data 270 provided to the checkout subsystem 268. In one embodiment, the match data provided to the Log Data Storage 278 may include an associated timestamp, but the match data 270 provided to the checkout subsystem 268 may not include a timestamp. The Log Data Storage 278, as well as examples of appropriate match data provided for the Log Data Storage 278, will be discussed in greater detail later in connection with FIG. 3. In an alternative embodiment, the checkout subsystem 268 may store match data locally and provide the server 274 with the match data for storage in the Log Data Storage 278 at regular intervals, such as once per hour or once per day. It will be understood that the components of the system 260 may communicate with one another via connection mechanisms similar to those of the system 230. Also, it is noted that the Object Database 276 and Log Data Storage 278 may be similar to their counterparts of FIG. 2B and explained in the following sections in connection with FIG. 3. Optionally, the server 274 can reside inside the checkout subsystem 268 using the same processing and memory power in the checkout subsystem 268 to run both the supervisor application 275 and recognition application 273. FIG. 3 is a schematic diagram of an Object Database 302 and Log Data Storage 312 (or, equivalently, log data storage database) illustrating an example of a relational database structure in accordance with one embodiment of the present invention. It will be understood by one of ordinary skill in the art that a database may be implemented on an addressable storage medium and may be implemented using a variety of different types of addressable storage mediums. For example, the Object Database 302 and/or the Log Data Storage 312 may be entirely contained in a single device or may be spread over several devices, computers, or servers in a network. The Object Database 302 and/or the Log Data Storage 312 may be implemented in such devices as memory chips, hard drives, optical drives, and the like. Though the databases 302 and 312 have the form of a relational database, one of ordinary skill in the art will recognize that each of the databases may also be, by way of example, an object-oriented database, a hierarchical database, a lightweight directory access protocol (LDAP) directory, an object-oriented-relational database, and the like. The databases may conform to any database standard, or may even conform to a non-standard private specification. The databases 302 and 312 may also be implemented utilizing any number of commercially available database products, such as, by way of example, Oracle� from Oracle Corporation, SQL Server and Access from Microsoft Corporation, Sybase� from Sybase, Incorporated, and the like. The databases 302 and 312 may utilize a relational database management system (RDBMS). In a RDBMS, the data may be stored in the form of tables. Conceptually, data within the table may be stored within fields, which may be arranged into columns and rows. Each field may contain one item of information. Each column within a table may be identified by its column name one type of information, such as a value for a SIFT feature descriptor. For clarity, column names may be illustrated in the tables of FIG. 3. A record, also known as a tuple, may contain a collection of fields constituting a complete set of information. In one embodiment, the ordering of rows may not matter, as the desired row may be identified by examination of the contents of the fields in at least one of the columns or by a combination of fields. Typically, a field with a unique identifier, such as an integer, may be used to identify a related collection of fields conveniently. As illustrated in FIG. 3, by way of example, two tables 304 and 306 may be included in the Object Database 302, and one table 314 may be included in the Log Data Storage 312. The exemplary data structures represented by the five tables in FIG. 3 illustrate a convenient way to maintain data such that an embodiment using the data structures can efficiently store and retrieve the data therein. The tables for the Object Database 302 may include a Feature Table 304, and an optional Object Recognition Table 306. The Feature Table 304 may store data relating to the identification of an object and a view. For example, a view can be characterized by a plurality of features. The Feature Table 304 may include fields for an Object ID, a View ID, a Feature ID for each feature stored, a Feature Coordinates for each feature stored, and a Feature Descriptor associated with each feature stored, view name field, an object name field. The Object ID field and the View ID field may be used to identify the records that correspond to a particular view of a particular object. A view of an object may be typically characterized by a plurality of features. Accordingly, the Feature ID field may be used to identify records that correspond to a particular feature of a view. The View ID field for a record may be used to identify the particular view corresponding to the feature and may be used to identify related records for other features of the view. The Object ID field for a record may used to identify the particular object corresponding to the feature and may be used to identify related records for other views of the object and/or other features associated with the object. The Feature Descriptor field may be used to store visual information about the feature such that the feature may be readily identified when the visual sensor observes the view or object again. The Feature Coordinates field may be used to store the coordinates of the feature. This may provide a reference for calculations that depend at least in part on the spatial relationships between multiple features. An Object Name field may be used to store the name of the object and may be used to store the price of the object. The View Name field may be used to store the name of the view. For example, it may be convenient to construct a view name by appending a spatial designation to the corresponding object name. As an illustration, if an object name is �Cola 24-Pack,� and the object is packaged in the shape of a box, it may be convenient to name the associated views �Cola 24-Pack Top View,� �Cola 24-Pack Bottom View,� �Cola 24-Pack Front View,� �Cola 24-Pack Back View,� �Cola 24-Pack Left View,� and �Cola 24-Pack Right View.�
The optional Object Recognition Table 306 may include the Feature Descriptor field, the Object ID field (such as a Universal Product Code), the View ID field, and the Feature ID field. The optional Object Recognition Table 306 may advantageously be indexed by the Feature Descriptor, which may facilitate the matching of observed images to views and/or objects. The illustrated Log Data Storage 312 includes an Output Table 314. The Output Table 314 may include fields for an Object ID, a View ID, a Camera ID, a Timestamp, and an Image. The system may append records to the Output Table 314 as it recognizes objects during operation. This may advantageously provide a system administrator with the ability to track, log, and report the objects recognized by the system. In one embodiment, when the Output Table 314 receives inputs from multiple visual sensors, the Camera ID field for a record may be used to identify the particular visual sensor associated with the record. The Image field for a record may be used to store the image associated with the record. FIG. 4 is a flowchart 400 that illustrates a process for recognizing and identifying objects in accordance with one embodiment of the present invention. It will be appreciated by those of the ordinary skill that the illustrated process may be modified in a variety of ways without departing from the spirit and scope of the present invention. For example, in another embodiment, various portions of the illustrated process may be combined, be rearranged in an alternate sequence, be removed, and the like. In addition, it should be noted that the process may be performed in a variety of ways, such as by software executing in a general-purpose computer, by firmware and/or computer readable medium executed by a microprocessor, by dedicated hardware, and the like. At the start of the process illustrated in FIG. 4, the system 100 has already been trained or programmed to recognize selected objects. The process may begin in a state 402. In the state 402, a visual sensor, such as a camera, may capture an image of an object to make visual data. In one embodiment, the visual sensor may continuously capture images at a predetermined rate. The process may advance from the state 402 to a state 404. In one of the exemplary embodiments, a state 404 can be added to the process. In the state 404, two or more consecutive images may be compared to determine if a motion of an item is detected. If a motion is detected, the process may proceed to step 406. Otherwise, the visual sensor may capture more images. State 404 is useful when the image capture speed of the visual device and the object recognition process are limited to certain number of frame per second. When the image capture speed of the visual device and the object recognition process are sufficiently fast, the process may proceed directly to an optional step 406. In the state 406, the process may analyze the visual data acquired in the state 404 to extract visual features. As mentioned above, the process of analyzing the visual data may be performed by a computer 206, a feature extractor 238, a checkout system 268 or a server 274 (shown in FIGS. 2A-C). A variety of visual recognition techniques may be used, and it will be understood by one of ordinary skill in the art that an appropriate visual recognition technique may depend on a variety of factors, such as the visual sensor used and/or the visual features used. In one embodiment, the visual features may be identified using an object recognition process that can identify visual features. In one example, the visual features may correspond to SIFT features. Next, the process may advance from the state 406 to a state 408. In the state 408, the identified visual features may be compared to visual features stored in a database, such as an object database. In one embodiment, the comparison may be done using the SIFT method described earlier. The process may find one match, may find multiple matches, or may find no matches. In one embodiment, if the process finds multiple matches, it may, based on one or more measures of the quality of the matches, designate one match, such as the match with the highest value of an associated quality measure, as the best match. Optionally, a match confidence may be associated with a match, wherein the confidence is a variable that is set by adjusting a parameter with a range, such as 0% to 100%, that relates to the fraction of the features that are recognized as matching between the visual data and a particular stored image, or stored set of features. If the match confidence does not exceed a pre-determined threshold, such as a 90% confidence level, the match may not be used. In one embodiment, if the process finds multiple matches with match confidence that exceed the pre-determined threshold, the process may return all such matches. The process may advance from the state 408 to a decision block 410. In the decision block 410, a determination may be made as to whether the process found a match in the state 408. If the process does not identify a match in the state 408, the process may returns to the state 402 to acquire another image. If the process identifies a match in the state 408, the process may proceed to an optional decision block 412. In the optional decision block 412, a determination may be made as to whether the match found in the state 408 is considered reliable. In one embodiment, when a match is found, the system 100 may optionally wait for one or more extra cycles to compare the matched object from these extra cycles, so that the system 100 can more reliably determine the true object. In one implementation, the system 100 may verify that the matched object is identically recognized for two or more cycles before determining a reliable match. Another implementation may compute the statistical probability that each object that can be recognized is present over several cycles. In another embodiment, a match may be considered reliable if the value of the associated quality measure or associated confidence exceeds a predetermined threshold. In another embodiment, a match may be considered reliable if the number of identified features exceeds a predetermined threshold. In yet another embodiment, the optional decision block 412 may not be used, and the match may always be considered reliable. If the optional decision block 412 determines that the match is not considered reliable, the process may return to the state 402 to acquire another image. If the process determines that the match is considered reliable, the process may proceed to a state 414. In the state 414, the process may send recognition alert, where the recognition alert may is followed by one or more actions. Exemplary action may be displaying item information on a display monitor of a checkout subsystem, adding the item in a shopping list, sending match data to a checkout subsystem, storing match data into an operation database, or the actions described in connection with FIGS. 1 and 2. FIG. 5 is a flowchart 500 that illustrates a process for training the system 100 in accordance with one embodiment of the present invention. It will be appreciated by those of ordinary skill that the illustrated process may be modified in a variety of ways without departing from the spirit and scope of the present invention. In addition, it should be noted that the process may be performed in a variety of ways, such as by software executing in a general-purpose computer, by firmware and/or computer readable medium executed by a microprocessor, by dedicated hardware, and the like. The process may begin in a state 502. In the state 502, the process may receive or monitors visual data from a visual sensor, such as an image from a camera. In one embodiment, the process may receive electronic data from the manufacturer of the item, where the electronic data may include information associated with the item, such as merchandise specifications and visual images. As described earlier, it may be convenient, during system training, to use a visual sensor that is not connected to a checkout subsystem and positioned near the floor. For example, training images may be captured in a photography studio or on a �workbench,� which may result in higher-quality training images and less physical strain on a human system trainer. The process may advance from the state 502 to a state 504. In the state 504, the process may receive data associated with the image received in the state 502. Data associated with a visual image may include the distance between the camera and the object of the image at the time of image capture, may include an object name, may include a view name, may include an object ID, may include a view ID, may include a unique identifier, may include a text string associated with the object of the image, may include a name of a computer file (such as a sound clip, a movie clip, or other media file) associated with the image, may include a price of the object of the image, may include the UPC associated with the object of the image, and may include a flag indicating that the object of the image is a relatively high security-risk item. The associated data may be manually entered, may be automatically generated or retrieved, may be electronically received from the manufacturer or a combination of both. For example, in one embodiment, the operator of the system 100 may input all of the associated data manually. In another embodiment, one or more of the associated data items, such as the object ID or the view ID, may be generated automatically, such as sequentially, by the system. In another embodiment, one or more of the associated data items may be generated through another input method. For example, a UPC associated with an image may be inputted using a barcode scanner. Several images may be taken at different angles or poses with respect to a specific item. Preferably, each face of an item that needs to be recognized should be captured. In one embodiment, all such faces of a given object may be associated with the same object ID, but associated with different view IDs. Additionally, if an item that needs to be recognized is relatively malleable and/or deformable, such as a bag of pet food or a bag or charcoal briquettes, several images may be taken at different deformations of the item. It may be beneficial to capture a relatively high-resolution image, such as a close-up, of the most visually distinctive regions of the object, such as the product logo. It may also be beneficial to capture a relatively high-resolution image of the least malleable portions of the item. In one embodiment, all such deformations and close-ups captured of a given object may be associated with the same object ID, but associated with different view IDs. The process may advance from the state 504 to a state 506. In the state 506, the process may store the image received in the state 502 and the associated data collected in the state 504. In one embodiment, the system 100 may store the image and the associated data in an object database, which was described earlier in connection with FIGS. 2A-C. The process may advance to a decision block 508. In the decision block 508, the process may determine whether or not there are additional images to capture. In one embodiment, the system 100 may ask user whether or not there are additional images to capture, and the user's response may determine the action taken by the process. In this embodiment, the query to the user may be displayed on a checkout subsystem and the user may respond via the input devices of the checkout subsystem. If there are additional images to capture, the process may return to the state 502 to receive additional images. If there is no additional image to capture, the process may proceed to a state 510. In the state 510, the process may perform a training subprocess on the received visual data. In one embodiment, the process may scan the object database that contains the images stored in the state 506, select images that have not been trained, and run the training subroutine on the untrained images. For each untrained image, the system 100 may analyze the image, find the features present in the image and save the features in the object database. The process may advance to an optional state 512. In the optional state 512, the process may delete the images on which the system 100 was trained in the state 510. In one embodiment, the matching process, like using SIFT, described earlier in connection with FIG. 4 may use the features associated with an image and may not use the actual trained image but may rather use another form of digital image information that is readily available to be imported. Advantageously, deleting the trained images may reduce the amount of disk space or memory required to store the object information. Then, the process may end and be repeated as desired. In one embodiment, the system may be trained prior to its initial use, and additional training may be performed repeatedly. It will be understood that the number of training images acquired in different training cycle may vary in a wide range. FIG. 6 is a flowchart 600 illustrating exemplary steps for processing Bottom-of-the-Basket (BoB) items at a POS incorporated within the system of FIG. 1 in accordance with one embodiment of the present invention. For simplicity, the steps in the flowchart 600 describe the process to verify and acknowledge BoB items. However, it should be apparent to those of ordinary skill in the art that the similar steps can be applied to an automatic checkout system without deviating from the present teachings. The process may begin in a state 602. In the state 602, a checkout subsystem, which may operate as a POS interface, may receive match data of one or more BoB items carried on, for example, the lower shelf of a shopping cart. As illustrated in FIGS. 2A-C, a checkout subsystem may get match data from a computer 206 or a recognition server 246 (or 274). Then, in a state 604, it may be determined whether a cashier may be ready to process the BoB items. Upon negative answer to the step 604, the process may proceed to the step 602. Otherwise, the process may proceed to a state 606. In the state 606, the list of BoB items may be displayed on the monitor of the checkout subsystem 268. Each element of the list may include a brief description of an item, an image of the object, and a quantity that may be set to 1 by default. In one embodiment, the checkout subsystem 268 may have screens set aside for BoB detection, where each screen may provide various selections and menu options to the cashier. In a state 607, the cashier may select one item in the list. Subsequently, in a state 608, the cashier may determine whether the quantity of the selected item needs to be changed by verifying the quantity of the item. If any change is required, the cashier may modify the quantity in a state 614. Otherwise, the process may proceed to a state 610. In a state 610, the cashier may determine whether the selected item needs to be deleted from the list. The cashier may check if the customer wants to purchase the item. If the customer does not want to purchase the selected item, the process may proceed to a step 616 to remove the selected item from the list. Otherwise, the process may proceed to a state 612. In the state 612, the cashier may add the selected item in the transaction log. Then, the selected item is sent for transaction in a state 618 and deleted from the list in the state 616. Next, in the state 620, the cashier may check if the transaction is finished. If the answer to the state 620 is NO, the process may proceed to the state 606. It is noted that the cashier may terminate the transaction even though there are unprocessed items in the list. If answer to the state 620 is YES, the process may stop. In addition to the BoB loss, the retail industry has another type of fraud: cashier collusion. On occasion, a cashier may intentionally, or unintentionally, check out BoB items without charging the same to customers. By comparing the stolen BoB items to a corresponding transaction log and then correlating the comparison with either specific cashiers, or more generally with stores or regions, the managers may take appropriate actions to reduce the collusion loss. FIG. 7 is a flowchart 700 illustrating exemplary steps for monitoring the behavior of a cashier in accordance with one embodiment of the present invention. In a state 702, a detection log of BoB items may be compared with a transaction log of the BoB items, wherein the transaction is performed by a cashier. Next, based on the comparison, an action taken by the cashier to process each of the BoB items may be analyzed and recorded in a state 704. Then, in a state 706, the actions recorded over a predetermined period may be correlated to characterize the behavior of the cashier. For example, the correlation may indicate the average time it takes for the cashier to ring up a BoB item. Based on the correlation, the cashier's performance may be monitored and, consequently, collusion may be prevented. As described above, embodiments of the system and method may advantageously permit one or more visual sensors, such as one or more cameras, operatively coupled to a computer system to view and recognize items located on the belt of a counter or in a shopping cart of a retail store environment. These techniques can advantageously be used for the purpose of checking out merchandise automatically and/or reducing or preventing the bottom-of-the-basket loss. It should be understood, of course, that the foregoing relates to exemplary embodiments of the invention and that modifications may be made without departing from the spirit and scope of the invention as set forth in the following claims. 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G07G1/00Cooperative ClassificationG07F7/02, G07G3/003, G06Q20/343, A47F9/046European ClassificationG06Q20/343, A47F9/04D, G07G3/00B, G07F7/02Legal EventsDateCodeEventDescriptionDec 16, 2010FPAYFee paymentYear of fee payment: 4Jun 24, 2010ASAssignmentEffective date: 20100609Owner name: EVOLUTION ROBOTICS, INC.,CALIFORNIAFree format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:HUDNUT, ALEC;CREMEAN, MICHAEL;MORGAN, HOWARD;REEL/FRAME:24593/936Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:HUDNUT, ALEC;CREMEAN, MICHAEL;MORGAN, HOWARD;REEL/FRAME:024593/0936Apr 17, 2008ASAssignmentOwner name: EVOLUTION ROBOTICS RETAIL, INC., CALIFORNIAFree format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:EVOLUTION ROBOTICS, INC.;REEL/FRAME:020820/0346Effective date: 20051230Jul 26, 2006ASAssignmentOwner name: EVOLUTION ROBOTICS RETAIL, INC., CALIFORNIAFree format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:EVOLUTION ROBOTICS, INC.;REEL/FRAME:018006/0635Effective date: 20051230Feb 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