The present invention provides an active sensory floor that provides sensations to non-auditory senses of persons at an event via one or both of movement and vibrations of the sensory floor. Sensory output of the floor may be controlled via a mixer or other controller during a performance, pre-recorded or provided based upon an input, such as music playing. Additional sensory stimulation, such as, for example, visual stimulation may also be synchronized with non-auditory stimulation.

Multi-stage acoustophoretic devices for continuously separating a second fluid or a particulate from a host fluid are disclosed. Methods of operating the multi-stage acoustophoretic devices are also disclosed. The systems may include multiple acoustophoretic devices fluidly connected to one another in series, each acoustophoretic device comprising a flow chamber, an ultrasonic transducer capable of creating a multi-dimensional acoustic standing wave, and a reflector. The systems can further include pumps and flowmeters.

The present invention provides an active sensory floor that provides sensations to non-auditory senses of persons at an event via one or both of movement and vibrations of the sensory floor. Sensory output of the floor may be controlled via a mixer or other controller during a performance, pre-recorded or provided based upon an input, such as music playing. Additional sensory stimulation, such as, for example, visual stimulation may also be synchronized with non-auditory stimulation.

The present invention provides an active sensory floor that provides sensations to non-auditory senses of persons at an event via one or both of movement and vibrations of the sensory floor. Sensory output of the floor may be controlled via a mixer or other controller during a performance, pre-recorded or provided based upon an input, such as music playing. Additional sensory stimulation, such as, for example, visual stimulation may also be synchronized with non-auditory stimulation.

Vibration systems and systems including vibration systems for filling incomplete components with slurry material are disclosed. The vibration systems may include a vibration platform, and a component retention plate releasably coupled to the vibration platform. The component retention plate may include a plurality of component holders positioned on the component retention plate. Each of the plurality of component holders may receive a distinct, incomplete component in a predetermined orientation. The vibration systems may also include a motor operatively coupled to the vibration platform to vibrate the vibration platform at a predetermined frequency. The predetermined frequency may be based on characteristic(s) of each of the incomplete components.

Vibration systems and systems including vibration systems for filling incomplete components with slurry material are disclosed. The vibration systems may include a vibration platform, and a component retention plate releasably coupled to the vibration platform. The component retention plate may include a plurality of component holders positioned on the component retention plate. Each of the plurality of component holders may receive a distinct, incomplete component in a predetermined orientation. The vibration systems may also include a motor operatively coupled to the vibration platform to vibrate the vibration platform at a predetermined frequency. The predetermined frequency may be based on characteristic(s) of each of the incomplete components.

The invention relates to a transfer stack (TS) for transferring a portion of a foil within a perimeter (P) that includes a transducer (T) to an article (A) such as a medical device or a medical needle. The transfer stack includes a carrier substrate (CS), a foil (F) having a transducer (T) incorporated therein, and the transducer is laterally surrounded by a perimeter (P). The foil (F) is separable from the carrier substrate (CS) by overcoming a first peel retaining force (PRF1). An adhesive layer (AL) is also attached to the foil. The adhesive layer (AL) is configured to provide adhesion between the foil (F) and an article (A) such that when the article (A) is attached to the foil via the adhesive layer (AL) the foil (F) is separable from the surface of the article (A) by overcoming a second peel retaining force (PRF2). The second peel retaining force (PRF2) is greater than the first peel retaining force (PRF1).

A method for estimating actuator parameters for an actuator, in-situ and in real-time, may include driving the actuator with a test signal imperceptible to a user of a device comprising the actuator during real-time operation of the device, measuring a voltage and a current associated with the actuator and caused by the test signal, determining one or more parameters of the actuator based on the voltage and the current, determining an actuator type of the actuator based on the one or more parameters, and controlling a playback signal to the actuator based on the actuator type.

An acoustic transduction unit is provided including: a first electrode on a base substrate, a support pattern on a side of the first electrode distal to the base substrate, a vibrating diaphragm pattern surrounded by the support pattern, the first electrode and the vibrating diaphragm pattern and on a side of the support pattern distal to the first electrode; and a second electrode on a side of the vibrating diaphragm pattern distal to the first electrode and opposite to the first electrode; and a first dielectric pattern at the bottom of the vibrating cavity; wherein a thickness of the first dielectric pattern gradually increases from a first vertex to an edge of the first dielectric pattern; and/or, a second dielectric pattern at the top of the vibrating cavity; wherein a thickness of the second dielectric pattern gradually increases from a second vertex to an edge of the second dielectric pattern.

In accordance with the present disclosure, ultrasound-based techniques using a combined scanning and treatment array module are employed to find and treat anomalies corresponding to bleed events. By way of example, ultrasound data may be acquired with a scanning array at one or more locations on a patient anatomy. A treatment array may deliver heat to a targeted anomaly to provide therapy. Such a technique may be useful outside of a hospital environment.