Abstract: Flavor and additive delivery systems and methods for beverage dispensers are disclosed. An example beverage dispenser includes flavor containers configured to contain flavor mixtures, flavor tags each of which is fixed to a respective one of the flavor containers, flavor sensors each of which is positioned to read tag information from a respective one of the flavor tags to monitor the respective one of the flavor containers, memory configured to store instructions related to dispensing water and the flavor mixtures, and a processor. The processor is configured to detect, based on the tag information collected by the flavor sensors, whether any of the flavor containers is at least one of expired, counterfeit, or out-of-position. The processor is configured to disable use of each of the flavor containers that are detected to be at least one of expired, counterfeit, or out-of-position.

Abstract: Flavor and additive delivery systems and methods for beverage dispensers are disclosed. An example beverage dispenser includes flavor containers configured to contain flavor mixtures, a manifold configured to blend water with flavor mixtures, a flowrate sensor configured to detect a current flowrate of the water flowing to the manifold, memory configured to store instructions related to dispensing the water and the flavor mixtures, and a processor. The processor is configured to receive a request for a selected beverage, identify a ratio between the water and one or more of the flavor mixtures for the selected beverage, transmit a water control signal to cause the water to flow at a requested water flowrate, and transmit one or more first flavor control signals to cause one or more of the flavor mixtures to flow from the flavor containers based on the ratio.

Abstract: Flavor and additive delivery systems and methods for beverage dispensers are disclosed. An example manifold of a beverage dispenser includes a base defining a base cavity and configured to extend through an opening defined by an outer wall. The manifold includes a first housing coupled to the base and defining a housing cavity. The base cavity and the housing cavity are adjacent to each other to form a chamber. The manifold includes a body coupled to the first housing and defining a body cavity and angled apertures. The manifold includes an insert housing that is coupled to the body and extends at least partially through the body cavity. The manifold includes an insert housed within the insert housing and defining a water outlet for spraying water downward into the chamber. The angled apertures are configured to receive nozzles that extend at least partially into the chamber at the predefined angle.

Abstract: Flavor and additive delivery systems and methods for beverage dispensers are disclosed. An example beverage dispenser includes flavor containers configured to contain flavor mixtures, a manifold configured to blend water with flavor mixtures, a flowrate sensor configured to detect a current flowrate of the water flowing to the manifold, memory configured to store instructions related to dispensing the water and the flavor mixtures, and a processor. The processor is configured to receive a request for a selected beverage, identify a ratio between the water and one or more of the flavor mixtures for the selected beverage, transmit a water control signal to cause the water to flow at a requested water flowrate, and transmit one or more first flavor control signals to cause one or more of the flavor mixtures to flow from the flavor containers based on the ratio.

Abstract: Flavor and additive delivery systems and methods for beverage dispensers are disclosed. An example manifold of a beverage dispenser includes a base defining a base cavity and configured to extend through an opening defined by an outer wall. The manifold includes a first housing coupled to the base and defining a housing cavity. The base cavity and the housing cavity are adjacent to each other to form a chamber. The manifold includes a body coupled to the first housing and defining a body cavity and angled apertures. The manifold includes an insert housing that is coupled to the body and extends at least partially through the body cavity. The manifold includes an insert housed within the insert housing and defining a water outlet for spraying water downward into the chamber. The angled apertures are configured to receive nozzles that extend at least partially into the chamber at the predefined angle.

Abstract: A sensing system including a cover layer for covering an underlying structure and at least a first electrode and at least a second electrode is described. The at least first and second electrodes are connectable to a signal source, for providing a signal coupling between the at least first and second electrodes, the at least first and second electrodes being isolated from each other. The at least first and second electrodes and the cover layer are configured so that the signal is at least partially transmitted through the cover layer, wherein the cover layer has an impedance, so that a change of the signal coupling between the at least first and at least second electrodes can be detected upon changes of impedance of the cover layer.

Abstract: A method and system for accelerated fatigue damage testing of an object excited via an actor, wherein a drive signal is generated and transmitted to the actor, where the acceleration of the object or a mounting base of the actor is measured and supplied to a control system, where a Power Spectral Density (PSD) and a Fatigue Damage Spectrum FDS within the control system are calculated from the measured acceleration, whereby the calculated PSD is compared with a target PSD, whereby the calculated Fatigue Damage Spectrum FDS is compared with a target FDS, whereby a new drive frequency spectrum is calculated based on the comparisons and, one or multiple time domain blocks for the drive signal for a next cycle are generated from the new drive frequency spectrum and transmitted to the actor such that accelerated vibration testing without affecting the failure mode is achieved which provides realistic results.

Abstract: A collimator filter (10) comprises an entry surface (11) to receive incident light (Li, Li?) at different angles of incidence (?i, ?i?) and an exit surface (12) to allow output light (Lo) to exit from the collimator filter (10). A filter structure between the entry surface (11) and the exit surface (12) transmits only parts of the incident light (Li) having angles of incidence (?i) below a threshold angle (?max). The filter structure comprises a patterned array of carbon nanotubes (1), wherein the nanotubes (1) are aligned extending in a principal transmission direction (Z) between the entry surface (11) and the exit surface (12). The nanotubes (1) are arranged to form a two dimensional pattern (P) transverse to the principal transmission direction (Z). Open areas of the pattern (P) without nanotubes (1) form micro-apertures (A) between the nanotubes (1) for transmitting the output light (Lo) through the filter structure.

Abstract: A method and system for accelerated fatigue damage testing of an object excited via an actor, wherein a drive signal is generated and transmitted to the actor, where the acceleration of the object or a mounting base of the actor is measured and supplied to a control system, where a Power Spectral Density (PSD) and a Fatigue Damage Spectrum FDS within the control system are calculated from the measured acceleration, whereby the calculated PSD is compared with a target PSD, whereby the calculated Fatigue Damage Spectrum FDS is compared with a target FDS, whereby a new drive frequency spectrum is calculated based on the comparisons and, one or multiple time domain blocks for the drive signal for a next cycle are generated from the new drive frequency spectrum and transmitted to the actor such that accelerated vibration testing without affecting the failure mode is achieved which provides more realistic results.

Abstract: An electronic device having a first part, a second part, and a touch sensitive panel disposed on the second part has an opened and a closed state, and the touch sensitive panel is covered by the first part in the closed state. The electronic device includes a sensor circuit, a touch simulation facility and a comparator. The sensor circuit is for generating a touch signal indicative for a position where a touch of the touch sensitive panel is detected. The touch simulation facility is for evoking a touch signal at a position of the touch sensitive panel, and includes a touch simulation element which in the closed state of the electronic device is arranged opposite the touch sensitive panel.

Abstract: An electronic device having a touch sensitive panel has an opened and a closed state, and comprises a sensor circuit, a touch simulation facility and a comparator. The sensor circuit is for generating a touch signal indicative for a position where a touch of the touch sensitive panel is detected. The touch simulation facility is for evoking a touch signal at a position of the touch sensitive panel, and comprises a touch simulation element which in the closed state of the electronic device is arranged opposite the touch sensitive panel. The comparator is for comparing the touch signal with a reference value corresponding to the touch simulation element and for generating a correction signal for adjusting a setting of the sensor circuit for compensation of a difference detected between the position where the touch signal is evoked and the position indicated by the touch signal.

Abstract: A touch screen display device is described that includes a display panel, a display driver, a sensor circuit and a combination unit. The display panel has a plurality of display elements arranged between a first and a second electrode layer. The display driver is arranged for providing display signals comprising a common display signal and an input control signal to the display panel. The sensor circuit is arranged for providing a probe signal and a shield signal mutually having the same phase and frequency and for generating a touch signal in response to the output signal received from the first electrode layer. The combination unit provides a drive signal to the first electrode layer derived from the common display signal and the probe signal, and further provides an output control signal for the display panel from the input control signal and the shield signal.

Abstract: An electrophoretic display unit is presented that comprises an electrophoretic display panel (1). A medium (5) having embedded therein a plurality of electrophoretic display elements (7) is controlled by a first and a second pixel electrode (22b, 6). In addition a sensor constructed to generate a signal (ST) indicative for a temperature of the display panel and a driver (15) for driving the display panel (1) is provided. The sensor (250) includes a resistance sensor constructed to detect a resistance of the medium (5) between a first (22c) and a second sensor electrode (6), and the driver is controllable according to the resistance detected by the resistance sensor.

Abstract: A display device (100) includes a row driver (520) configured to provide a row voltage, and a row electrode (320) connected to the row driver (520). A column driver (530) is configured to provide N column voltage levels to a column electrode (330). Further, a common electrode driver (570) is configured to provide M common voltage levels to a common electrode (170). A pixel (CDE) is connected between the column electrode (330) and the common electrode (170); and a controller (515) is configured to control timing of application of the N column voltage levels relative the M common voltage levels to provide NM effective pixel voltage levels across the pixel (CDE).

Abstract: An electronic device having a touch sensitive panel has an opened and a closed state, and comprises a sensor circuit, a touch simulation facility and a comparator. The sensor circuit is for generating a touch signal indicative for a position where a touch of the touch sensitive panel is detected. The touch simulation facility is for evoking a touch signal at a position of the touch sensitive panel, and comprises a touch simulation element which in the closed state of the electronic device is arranged opposite the touch sensitive panel. The comparator is for comparing the touch signal with a reference value corresponding to the touch simulation element and for generating a correction signal for adjusting a setting of the sensor circuit for compensation of a difference detected between the position where the touch signal is evoked and the position indicated by the touch signal.

Abstract: A touch screen display device is described that includes a display panel, a display driver, a sensor circuit and a combination unit. The display panel has a plurality of display elements arranged between a first and a second electrode layer. The display driver is arranged for providing display signals comprising a common display signal and an input control signal to the display panel. The sensor circuit is arranged for providing a probe signal and a shield signal mutually having the same phase and frequency and for generating a touch signal in response to the output signal received from the first electrode layer. The combination unit provides a drive signal to the first electrode layer derived from the common display signal and the probe signal, and further provides an output control signal for the display panel from the input control signal and the shield signal.

Abstract: An electrophoretic display unit is presented that comprises an electrophoretic display panel (1). A medium (5) having embedded therein a plurality of electrophoretic display elements (7) is controlled by a first and a second pixel electrode (6, 22b). In addition a sensor constructed to generate a signal (ST) indicative for a temperature of the display panel and a driver (15) for driving the display panel (1) is provided. The sensor (250) includes a resistance sensor constructed to detect a resistance of the medium (5) between a first (22c) and a second sensor electrode (6), and the driver is controllable according to the resistance detected by the resistance sensor.

Abstract: A display device (100) includes a row driver (520) configured to provide a row voltage, and a row electrode (320) connected to the row driver (520). A column driver (530) is configured to provide N column voltage levels to a column electrode (330). Further, a common electrode driver (570) is configured to provide M common voltage levels to a common electrode (170). A pixel (CDE) is connected between the column electrode (330) and the common electrode (170); and a controller (515) is configured to control timing of application of the N column voltage levels relative the M common voltage levels to provide NM effective pixel voltage levels across the pixel (CDE).

Abstract: A method of determining the position of a transmitting beacon transmitting a signal to certain satellites in a constellation of satellites, which satellites in turn retransmit retransmitted signals to at least one detection ground station, wherein each of said ground stations is provided with at least one antenna whose directional characteristics do not make it possible to identify which satellite retransmitted any given retransmitted signal, and wherein the method implements the following steps: a) computing position for all combinations associating signals with satellites that might correspond to retransmission of transmitted signals; b) computing the position of the beacon for at least some of the satellite combinations, using the least squares method; and c) determining the combination which presents the smallest computation residue by the least squares method, the position of the transmitting beacon corresponding to this combination then being considered to be the position of the transmitting beacon.

Abstract: A method of determining the position of a transmitting beacon transmitting a signal to certain satellites in a constellation of satellites, which satellites in turn retransmit retransmitted signals to at least one detection ground station, wherein each of said ground stations is provided with at least one antenna whose directional characteristics do not make it possible to identify which satellite retransmitted any given retransmitted signal, and wherein the method implements the following steps: