Abstract: The present invention relates to a method for providing three-dimensional ultrasound images of a volume (50) and an ultrasound imaging system (10). In particular, the current invention applies to live three-dimensional imaging. To maintain a steady frame rate of the displayed images even if a user changes a region of interest and, therewith, the size of the volume (50) to be scanned, it is contemplated to adjust a density of the scanning lines within the volume (50) as a function of a size of the volume while maintaining a total number of scanning lines across the volume (50).

Abstract: The present invention relates to a method for providing three-dimensional ultrasound images of a volume (50) and an ultrasound imaging system (10). In particular, the current invention applies to live three-dimensional imaging. To maintain a steady frame rate of the displayed images even if a user changes a region of interest and, therewith, the size of the volume (50) to be scanned, it is contemplated to adjust a density of the scanning lines within the volume (50) as a function of a size of the volume while maintaining a total number of scanning lines across the volume (50).

Abstract: A technique for designing a multipass optical cell utilizes an iterative artificial intelligence-based optimization process based upon evaluation of direct ray tracing with mirrors simulated as having true spherical surfaces (i.e., defined as a “thick lens”) to identify particular cell configurations that result in creating spot patterns which fill a significant portion of the surface of each mirror without significant spot overlap. This technique allows the use of relatively simple, low-cost spherical mirrors while providing the desired dense spot patterns.

Abstract: A novel low-power and compact laser spectroscopic sensor is described herein. Embodiments of the disclosed sensor utilize state-of-the-art microprocessors and digital processing techniques to reduce power consumption and integrate functions into a small device. In particular, novel software methods are disclosed which allow the use of low-power microprocessors which draw no more than about 0.02 W of power. Such low-power enables long battery life and allows embodiments of the sensor to be used in portable applications. In addition, the system architecture and methods described in this disclosure allow a single integrated embedded processor to control all the subsystems necessary for a laser spectroscopic sensor further reducing sensor size and power consumption. In addition, a power efficient method of calibrating a photoacoustic laser spectroscopic sensor is disclosed.

Abstract: A technique for designing a multipass optical cell utilizes an iterative artificial intelligence-based optimization process based upon evaluation of direct ray tracing with mirrors simulated as having true spherical surfaces (i.e., defined as a “thick lens”) to identify particular cell configurations that result in creating spot patterns which fill a significant portion of the surface of each mirror without significant spot overlap. This technique allows the use of relatively simple, low-cost spherical mirrors while providing the desired dense spot patterns.

Abstract: An optical multipass cell (MPC) configuration is presented that utilizes pairs of split spherical mirrors to provide a beam pattern density on the order of a pure astigmatic arrangement without the need to utilize specially-ground and aligned astigmatic mirrors. Relatively inexpensive spherical mirrors are “split” into at least pairs, and tilted inward along the optical axis. Each mirror half may be tilted at a common angle or, alternatively, each mirror half may be positioned at a unique tilt angle. The spot pattern density is on the order of a pure astigmatic cell, but at a significantly reduced cost.

Abstract: A novel low-power and compact laser spectroscopic sensor is described herein. Embodiments of the disclosed sensor utilize state-of-the-art microprocessors and digital processing techniques to reduce power consumption and integrate functions into a small device. In particular, novel software methods are disclosed which allow the use of low-power microprocessors which draw no more than about 0.02 W of power. Such low-power enables long battery life and allows embodiments of the sensor to be used in portable applications. In addition, the system architecture and methods described in this disclosure allow a single integrated embedded processor to control all the subsystems necessary for a laser spectroscopic sensor further reducing sensor size and power consumption. In addition, a power efficient method of calibrating a photoacoustic laser spectroscopic sensor is disclosed.

Abstract: A novel low-power and compact laser spectroscopic sensor is described herein. Embodiments of the disclosed sensor utilize state-of-the-art microprocessors and digital processing techniques to reduce power consumption and integrate functions into a small device. In particular, novel software methods are disclosed which allow the use of low-power microprocessors which draw no more than about 0.02 W of power. Such low-power enables long battery life and allows embodiments of the sensor to be used in portable applications. In addition, the system architecture and methods described in this disclosure allow a single integrated embedded processor to control all the subsystems necessary for a laser spectroscopic sensor further reducing sensor size and power consumption. In addition, a power efficient method of calibrating a photoacoustic laser spectroscopic sensor is disclosed.

Abstract: A novel low-power and compact laser spectroscopic sensor is described herein. Embodiments of the disclosed sensor utilize state-of-the-art microprocessors and digital processing techniques to reduce power consumption and integrate functions into a small device. In particular, novel software methods are disclosed which allow the use of low-power microprocessors which draw no more than about 0.02 W of power. Such low-power enables long battery life and allows embodiments of the sensor to be used in portable applications. In addition, the system architecture and methods described in this disclosure allow a single integrated embedded processor to control all the subsystems necessary for a laser spectroscopic sensor further reducing sensor size and power consumption. In addition, a power efficient method of calibrating a photoacoustic laser spectroscopic sensor is disclosed.

Abstract: A computer-user wrist support for supporting the wrist during operation of a computer inputting device. A resilient cushion located at the underside of the wrist provides the support while fastening means, comprising an elongated radially-stretchable fabric tube with closure means, secure the resilient cushion in place against the wrist.