Abstract: Systems, methods and tools for tracking the amounts of merchandise being displayed or available for sale in a retail environment using measurements of air displacement caused by the movement of customers, employees and shopping carts throughout a retail environment. The disclosed embodiments may position air displacement sensors throughout a store and near the products being offered for sale. As the merchandise is removed by customers, a greater amount of air may be measured. Embodiments of each sensor device may be calibrated with a maximum threshold measurement of air displacement corresponding to the amount of merchandise surrounding the sensor. After enough of the products have been removed from the surrounding proximity of the sensor, the maximum threshold of air displacement may be reached, wherein upon exceeding the maximum threshold of air displacement a signal may be sent alerting employees to restock the specified merchandise proximate to the sensor's location.

Abstract: Provided is a stocking tool. The stocking tool includes a first adjustable rigid side member, a second adjustable rigid side member, and a handle operatively coupled to the first adjustable rigid side member and the second adjustable rigid side member. The first adjustable rigid side member and the second adjustable rigid side member move toward and away from each other to adjust a width defined between the first and second adjustable rigid side members. The handle is moveable between a locked position with the handle activating a locking device and an unlocked position with the handle deactivating the locking device. The width defined between the first and second adjustable rigid side members receives product on the shelf and the first and second adjustable rigid side members align the received product on the shelf.

Abstract: Described in detail herein are methods and systems for a label position determination. A label position determination system can include labels mounted on the front face of the shelving units. The labels can include conductive patterns on the back face of the label. The conductive patterns of the labels can be electrically coupled with electrically conductive wires extending along a front face of a shelf. The system can further include a controller coupled to with electrically conductive wires, configured to transmit electrical pulses through the electrically conductive wires. The controller can determine at least one of: an identity of each of the labels mounted to the front face, whether a label has been mounted at an incorrect location on the front face of the shelf, or whether a label is missing from the front face of the shelf based on a response to the electrical pulse.

Abstract: A technique for monitoring objects in a cart is disclosed. A cart is configured to receive an object and includes a plurality of sensors configured to detect a location of the cart and a characteristic of an object in the cart. The cart also includes a docking station that can receive an electronic device and operatively and electrically couple the sensors to the electronic device. A computing system is in communication with the electronic device and configured to access a database containing a stored list generated by the user. The computing can identify the object in the cart based, at least in part, on data received from the plurality of sensors and the location of the cart. The computing system can also determine whether the object in the cart is included on the stored list.

Abstract: An example shelf system and associated methods are described. The shelf system includes a frame with a base member and a vertical member, first and second shelves extending from opposite sides of the vertical member, and first and second pairs of sensors disposed below the base member. In response to positioning a physical object on the first shelf or the second shelf, the physical object applies a torque on the vertical member and each of the sensors output electrical signals corresponding to a change in weight sensed by each of the sensors based on the torque. The shelf system includes a central computing system configured to determine which of the first shelf or the second shelf received the physical object, an estimated location of the physical object on the first or second shelf, and whether the physical object is positioned on the first or second shelf in an expected location.

Abstract: A technique for monitoring the quality of objects is disclosed. A container includes a multiple sensors and is configured to receive an object. The sensors monitor various metrics associated with the quality of the object, and a display is affixed to the container for displaying a visual indication of the quality of the object. The visual indication is based on data collected from the sensors. A quality monitoring module is executed by a processor to control the sensors to switch operation between a first mode of operation and a second mode of operation based on a detected change in one of the metrics monitored by the sensors.

Abstract: An example secure enclosure system and associated methods are described. The example enclosure system includes a housing, a shelf disposed within the housing, an array of sensors arranged within the housing, and an interface operatively coupled to the array of sensors. The shelf includes a supporting surface configured to support physical objects. The array of sensors is configured to detect characteristics of the each physical object supported by the supporting surface of the shelf. The interface is configured to transmit the detected characteristics from the array of sensors to a central computing system. The central computing system is configured to determine an identity of each physical object based on the detected characteristics.

Abstract: Methods, systems, and machine readable medium are provided for autonomous item identification in an environment including a mobile computational device and a container. One or more sensors are disposed at the container to sense a selected item being placed in the container. In response to sensing the selected item being placed in the container, a location of the container is determined using a positioning system. One or more physical characteristics of the selected item is sensed via the one or more sensors at the container. A set of stored characteristics is retrieved from a database for available items proximate to the location of the container. An identification code for the selected item is identified based on a comparison of the one or more physical characteristics of the selected item with the stored characteristics retrieved from the database of the available items based on the location of the container.

Abstract: Described in detail herein are methods and systems for estimating storage capacity of a storage unit disposed in a facility based on echoes detected by microphones. The microphones can detect sounds generated in the warehouse and reflected off the storage unit structures. The microphones detect the intensity of the sounds. The microphones can encode the sounds and the intensity of the sounds in time-varying electrical signals and transmit the time-varying electrical signals to a computing system. The computing system can decode the sounds and the intensity of the sounds from the time-varying electrical signals and estimate storage capacity of a storage unit from which the sounds reflected off of based on the intensity of the sounds.

Abstract: Described in detail herein are methods and systems for identifying actions based on detected sounds in a facility. An array of microphones can be disposed in a facility. The microphones can detect various sounds and encode the sounds in an electrical signal and transmit the sounds to a computing system. The computing system can determine the sound signature of each sound and based on the sound signature the chronological order of the sounds and the time interval in between the sounds the computing system can determine the action being performed causing the sounds.

Abstract: Described in detail herein are methods and systems for dynamic projection. The dynamic projection system includes a projector configured to project a first set of information associated with a set of like physical objects onto a front portion of a shelving unit. The first set of information includes an image of a machine-readable element encoded with an identifier associated with the set of like physical objects. An optical scanner can scan and decode the identifier from the image of the machine-readable element. The optical scanner can transmit the identifier or location of the scanner to a computing system The computing system can further control an output of the projector to dynamically project the second set of information associated with the set of like physical objects onto the front portion of the shelving unit receiving the identifier or location of the optical scanner.

Abstract: Methods, systems, and machine readable medium are provided for analyzing remotely located facilities based on sensed data. Exemplary embodiments include sensing data by one or more sensors located at or near a first facility to determine customer traffic and adding the sensed data to a set of stored data associated with the first facility. Customer demographics of the first facility are determined based on the sensed data, and transaction data for the first facility is received from one or more computing systems at the first facility. A second facility is identified that has customer demographics with a pre-defined degree of similarity to the customer demographics of the first facility. Transaction data of the second facility is analyzed with respect to the transaction data of the first facility and an improvement or change in item assortment at the first facility is determined based on the analysis.

Abstract: A vehicle identification system that includes exhaust emissions sensors that identify a vehicle type based on detected exhaust emission profiles and further determines vehicle stay duration and related metrics is discussed. Additional audio sensors may be used to further identify a change in load on the vehicle due to purchases made at the retail facility. The exhaust emission profiles detected by the vehicle identification system can be correlated with transaction data for the customer to determine the exact items purchased by the customer.

Abstract: A shopping cart deflection measurement system and associated methods are described. The shopping cart deflection measurement system includes a shopping cart, a sensor, and a processing device equipped with a processor. The shopping cart includes a frame, a basket portion pivotably mounted to the frame so as to enable deflection of at least one edge of the basket portion downward in the direction of gravity following a weight being placed in the basket portion, and a lower rack portion mounted to the frame and disposed below the basket portion. The processing device can be configured to execute instructions to measure deflection of the basket portion relative to the lower rack portion of the shopping cart using data acquired by the sensor. The measured deflection can be indicative of a fullness of the basket portion with one or more products.

Abstract: Described in detail herein are methods and systems for identifying actions performed by a forklift based on detected sounds in a facility. An array of microphones can be disposed in a facility. The microphones can detect various sounds and encode the sounds in an electrical signal and transmit the sounds to a computing system. The computing system can determine the sound signature of each sound and based on the sound signature the chronological order of the sounds and the time interval in between the sounds the computing system can determine the action being performed by the forklift which is causing the sounds.

Abstract: Sensor systems, methods and machine readable medium are provided for a sensor system for analyzing the ripeness of produce items.

Abstract: An example customer assistance system and associated methods are described. The example customer assistance system includes a shopping cart, a customer assistance unit mounted on the shopping cart, and a location system disposed remotely from the shopping cart and the customer assistance unit. The customer assistance unit includes a light source oriented upwards relative to horizontal, and an actuator for actuating the light source into an illumination position. In the illumination position, the light source projects a light beam over the shopping cart. The locating system includes at least one image capturing device configured to scan a ceiling for the light beam and to determine a source location of the shopping cart based on a ceiling location of the light beam.

Abstract: Methodologies, systems, and computer-readable media are provided for detection motion using an air curtain. An air flow source generates an air curtain that can rotate an airfoil located downstream of the air flow source. The airfoil contains an RF reflective material, and a sensor can detect RF reflections from the airfoil. The sensor communicates data associated with the RF energy reflections detected from the airfoil to a computing device that can compare this data against a reflection threshold value. The computing device can determine whether an object has obstructed the air curtain if the reflections detected by the sensor decrease below the reflection threshold value. The computing device can also compute a number of objects passing through the air curtain during a specified period of time.

Abstract: An example cart inventory system and associated methods are described. The example cart inventory system includes a cart and a detection system. The cart includes a frame, and a shelf movably mounted to the frame and configured to be positioned between an extended position and a folded position. A top surface and a rear surface of the shelf include first and second identifiers, respectively. The detection system is configured to detect the first identifier when the shelf is in the extended position and detect the second identifier when the shelf is positioned in the folded position. In the extended position, the top surface is oriented upwards relative to horizontal and the rear surface is disposed against the frame. In the folded position, the rear surface is oriented upwards relative to horizontal.

Abstract: A vehicle suspension measurement system that allows for tracking of customer traffic at a retail environment, and for determining whether items were purchased by a customer during their visit to the retail environment is discussed. Using a passive sensor-based system, data may be gathered by visually analyzing a vehicle's suspension system upon entry to the retail environment and again upon exit from the retail environment. A comparison of the entry and exit images may be performed to determine the degree of engagement of the vehicle suspension system and thereby provide an indicator as to whether the customer in the vehicle has made a purchase.