A method of generating feedback for a container load process includes: during a load process for a container at a load bay, controlling a sensor assembly disposed at the load bay to capture sensor data depicting an interior of the container; at a computing device connected to the sensor assembly, detecting, based on the sensor data, a wall of items placed in the container interior; determining, at the computing device from the sensor data: (i) a boundary attribute of the detected wall, and (ii) a composition attribute of the detected wall; comparing, at the computing device, (i) the boundary attribute to a boundary criterion, and (ii) the composition attribute to a composition criterion; and responsive to at least one of the boundary attribute not meeting the boundary criterion, or the composition attribute not meeting the composition attribute, generating an alert for transmission to a client computing device.

A liquid level detection device that is provided in a vessel and configured to detect a liquid level of fluid stored in the vessel includes a first plate formed in a plate shape, and a second plate formed in a plate shape and disposed to face the first plate. The first plate is disposed in such a manner that a surface opposite to a surface facing the second plate is orthogonal to a flow direction of fluid around the first plate in the vessel.

A liquid level detection device that is provided in a vessel and configured to detect a liquid level of fluid stored in the vessel includes a first plate formed in a plate shape, and a second plate formed in a plate shape and disposed to face the first plate. The first plate is disposed in such a manner that a surface opposite to a surface facing the second plate is orthogonal to a flow direction of fluid around the first plate in the vessel.

A system, as an engine with a crankcase containing oil or a fluid mixed with oil, has a reservoir containing liquid that extends up to a level of the fluid. A dipstick support structure supports a dipstick on it so that the dipstick extends into the fluid past the level of the fluid, and so that the dipstick is manually removable from the dipstick support structure by a user. An electrical system is connected with the dipstick, and the electrical system electrically senses the level of the fluid based on an electrical characteristic of the dipstick that varies with the varying level of the fluid when the dipstick extends into it. The electrical characteristic may be capacitance of the dipstick detected by sequential charging and discharging of the dipstick to produce a square wave electrical signal the frequency of which corresponds to the level of fluid.

A pathogen transport modelled biomimetic sensor includes a stack of capacitive electrodes with a plurality of gaps therebetween. The gaps and electrodes are structured and arranged to model an outer layer and one or more sublayers of fresh food of interest. The electrodes are arranged to provide multiple measurable impedances that are affected in response to cell or polymeric biofilm presence that affects the electrostatic field around and between the electrodes and consequently changes the measurable impedances.

A device to measure the material level inside the container includes a housing unit removably attachable to a cap of a container for holding a beverage, wherein the housing unit is configured to remain attached to the cap when the cap is at least partially removed from the container. The device further includes, a signal producing unit located in the housing unit, a first sensor located in the housing unit to sense a beverage level in the container and a controller located in the housing unit. The controller is configured to receive from the first sensor an indication of a beverage level in the container and activate the signal producing unit based at least on the indication of the beverage level in the container.

System for detecting at least one presence of foam of a medium in a bioreactor plant, wherein the system comprises: —a bioreactor plant having at least one disposable container for receiving the medium that may comprise the foam; and—at least two capacitive sensor units which are attached at at least two different situating positions of the bioreactor plant, wherein the capacitive sensor units each comprise at least one electrode system for capacitive measurement and are able to detect the presence of foam at the at least two situating positions on the basis of the capacitive measurement; and wherein the capacitive sensor units are designed to transmit captured data relating to the presence of foam to at least one monitoring unit for monitoring, open-loop and/or closed-loop control of foam formation in the bioreactor plant on the basis of said data.

System for detecting at least one presence of foam of a medium in a bioreactor plant, wherein the system comprises: —a bioreactor plant having at least one disposable container for receiving the medium that may comprise the foam; and—at least two capacitive sensor units which are attached at at least two different situating positions of the bioreactor plant, wherein the capacitive sensor units each comprise at least one electrode system for capacitive measurement and are able to detect the presence of foam at the at least two situating positions on the basis of the capacitive measurement; and wherein the capacitive sensor units are designed to transmit captured data relating to the presence of foam to at least one monitoring unit for monitoring, open-loop and/or closed-loop control of foam formation in the bioreactor plant on the basis of said data.

A system and method for remotely monitoring a sump pump system are disclosed. The sump pump system comprises a control system connected to an integrated arrangement of a sensor chamber and a sump pump. The sensor chamber includes a pressure sensor and a capacitive touch sensor for measuring the water level to automatically turn the sump pump on when the water rises to a preset level. A wireless controller is connected to the system, for wirelessly receiving monitoring instructions and wirelessly transmitting sump pump status data to a remote device. Further, a user can configure a water-attribute value by using an application in the remote device. The user can operate and manage sump pump data via the application.

A printed circuit board device includes: a first capacitive sensor configured to measure a first capacitance within a contained volume having known dimensions, wherein the first capacitance changes as a substance is received into the contained volume; a second capacitive sensor having a plurality of trigger points at a plurality of corresponding known heights within the contained volume, the second capacitive sensor configured to detect when the substance received into the contained volume has reached each of the corresponding known heights within the contained volume; and wherein at least one of a level of the substance within the contained volume, a volume of the substance within the contained volume, or a flow rate of the substance into the contained volume is determined based on data from the first capacitive sensor and the second capacitive sensor.