Abstract: Spectrophotometer system configured to characterize and/or measure spectrally (wavelength)-dependent properties of material components (such as molecular, viral, and/or bacterial analytes) associated with or of an object prior to the time when optical fingerprints of such material components start to degrade, and associated methods. System can be enhanced by a capability of selecting specific wavelengths of operation for such system to optimize cost-efficiency of the system.

Abstract: Spectrophotometer system configured to characterize and/or measure spectrally (wavelength)-dependent properties of material components (such as molecular, viral, and/or bacterial analytes) associated with or of an object prior to the time when optical fingerprints of such material components start to degrade, and associated methods. System can be enhanced by a capability of selecting specific wavelengths of operation for such system to optimize cost-efficiency of the system.

Abstract: A fall detection system includes a plurality of sensors in which at least one of the sensors is coupled to or disposed near a floor. The fall detection system further includes a central monitoring system in signal communication with the plurality of sensors. The central monitoring system is configured to receive a response signal in response to an activation signal being transmitted from at least one of the plurality of sensors, and determine whether the response signal is indicative of a person being arranged in a prone position on the floor.

Abstract: In accordance with some embodiments of the disclosed subject matter, mechanisms (which can, for example, include systems, apparatuses, methods, and media) for determining three dimensional location of an object associated with a person at risk of falling down are provided.

Abstract: A fall detection system includes a plurality of sensors in which at least one of the sensors is coupled to or disposed near a floor. The fall detection system further includes a central monitoring system in signal communication with the plurality of sensors. The central monitoring system is configured to receive a response signal in response to an activation signal being transmitted from at least one of the plurality of sensors, and determine whether the response signal is indicative of a person being arranged in a prone position on the floor.

Abstract: A system and method of dynamically localizing a measurement of parameter characterizing tissue sample with waves produced by spectrometric system at multiple wavelengths and detected at a fixed location of the detector of the system. The parameter is calculated based on impulse response of the sample, reference data representing characteristics of material components of the sample, and path lengths through the sample corresponding to different wavelengths. Dynamic localization is effectuated by considering different portions of a curve representing the determined parameter, and provides for the formation of a spatial map of distribution of the parameter across the sample. Additional measurement of impulse response at multiple detectors facilitates determination of change of the measured parameter across the sample as a function of time.

Abstract: A system and method of dynamically localizing a measurement of parameter characterizing tissue sample with waves produced by spectrometric system at multiple wavelengths and detected at a fixed location of the detector of the system. The parameter is calculated based on impulse response of the sample, reference data representing characteristics of material components of the sample, and path lengths through the sample corresponding to different wavelengths. Dynamic localization is effectuated by considering different portions of a curve representing the determined parameter, and provides for the formation of a spatial map of distribution of the parameter across the sample. Additional measurement of impulse response at multiple detectors facilitates determination of change of the measured parameter across the sample as a function of time.

Abstract: A system and method of dynamically localizing a measurement of parameter characterizing tissue sample with waves produced by spectrometric system at multiple wavelengths and detected at a fixed location of the detector of the system. The parameter is calculated based on impulse response of the sample, reference data representing characteristics of material components of the sample, and path lengths through the sample corresponding to different wavelengths. Dynamic localization is effectuated by considering different portions of a curve representing the determined parameter, and provides for the formation of a spatial map of distribution of the parameter across the sample. Additional measurement of impulse response at multiple detectors facilitates determination of change of the measured parameter across the sample as a function of time.

Abstract: A system and method of dynamically localizing a measurement of parameter characterizing tissue sample with waves produced by spectrometric system at multiple wavelengths and detected at a fixed location of the detector of the system. The parameter is calculated based on impulse response of the sample, reference data representing characteristics of material components of the sample, and path lengths through the sample corresponding to different wavelengths. Dynamic localization is effectuated by considering different portions of a curve representing the determined parameter, and provides for the formation of a spatial map of distribution of the parameter across the sample. Additional measurement of impulse response at multiple detectors facilitates determination of change of the measured parameter across the sample as a function of time.

Abstract: A system and method of dynamically localizing a measurement of parameter characterizing tissue sample with waves produced by spectrometric system at multiple wavelengths and detected at a fixed location of the detector of the system. The parameter is calculated based on impulse response of the sample, reference data representing characteristics of material components of the sample, and path lengths through the sample corresponding to different wavelengths. Dynamic localization is effectuated by considering different portions of a curve representing the determined parameter, and provides for the formation of a spatial map of distribution of the parameter across the sample. Additional measurement of impulse response at multiple detectors facilitates determination of change of the measured parameter across the sample as a function of time.

Abstract: A system and optimization algorithm for determining the preferred operational wavelengths of a device configured for measurement of molecular analytes in a sample. Operational wavelengths are determined by solving a system of equations linking empirically defined functions representative of these analytes, spectrally dependent coefficients corresponding to these analytes, path lengths traversed by waves probing the analytes at wavelengths corresponding to the absorption level described by the functions representative of these analytes, and, optionally, a cost-function taking into account at least one of spectral separation between the operational wavelengths, manufacturability of wave source(s) producing wave(s) at operational wavelength(s), and the noise factor associated with the operation of such wave source(s).

Abstract: A system and optimization algorithm for determining the preferred operational wavelengths of a device configured for measurement of molecular analytes in a sample. Operational wavelengths are determined by solving a system of equations linking empirically defined functions representative of these analytes, spectrally dependent coefficients corresponding to these analytes, path lengths traversed by waves probing the analytes at wavelengths corresponding to the absorption level described by the functions representative of these analytes, and, optionally, a cost-function taking into account at least one of spectral separation between the operational wavelengths, manufacturability of wave source(s) producing wave(s) at operational wavelength(s), and the noise factor associated with the operation of such wave source(s).

Abstract: A system and method of dynamically localizing a measurement of parameter characterizing tissue sample with waves produced by spectrometric system at multiple wavelengths and detected at a fixed location of the detector of the system. The parameter is calculated based on impulse response of the sample, reference data representing characteristics of material components of the sample, and path lengths through the sample corresponding to different wavelengths. Dynamic localization is effectuated by considering different portions of a curve representing the determined parameter, and provides for the formation of a spatial map of distribution of the parameter across the sample. Additional measurement of impulse response at multiple detectors facilitates determination of change of the measured parameter across the sample as a function of time.

Abstract: A process is disclosed for configuring a base platform having ASIC and FPGA modules to perform a plurality of functions. A verified RTL hardware description of a circuit is mapped and annotated to identify memory programmable functions. The memory programmable functions are grouped for assignment to FPGA modules. The non-memory programmable functions are synthesized to ASIC modules, and the memory programmable functions are synthesized to FPGA modules. Placement, signal routing and boundary timing closure are completed and the platform is configured by adding metallization layer(s) to configure the ASIC modules and creating a firmware memory to configure the FPGA modules. An over-provisioning feature in the FPGA modules permits post-fabrication alteration of logic functions.

Abstract: A basic cell circuit architecture having plurality of cells with fixed transistors configurable for the formation of logic devices and single and dual port memory devices within a structured ASIC is provided. Different configurations of ensuing integrated circuits are achieved by forming variable interconnect layers above the fixed structures. The circuit architecture can achieve interconnection of transistors within a single cell or across multiple cells. The interconnection can be configured to form basic logic gates as well as more complex digital and analog subsystems. In addition, each cell contains a layout of transistors that can be variably coupled to achieve a memory device, such as a SRAM device. By having the capability of forming a logic circuit element, a memory device, or both, the circuit architecture is both memory-centric and logic-centric, and more fully adaptable to modern-day SoCs.

Abstract: An apparatus includes a first semiconductor die and at least one further semiconductor die. A substrate is attached to the first die and the further die and has an electrical interconnect pattern that interconnects contacts on the first die with respective contacts on the further die. Features of the interconnect pattern have positions on the substrate with smaller tolerances relative to positions of the contacts on the first die than to positions of the contacts on the further die.

Abstract: A process is disclosed for configuring a base platform having ASIC and FPGA modules to perform a plurality of functions. A verified RTL hardware description of a circuit is mapped and annotated to identify memory programmable functions. The memory programmable functions are grouped for assignment to FPGA modules. The non-memory programmable functions are synthesized to ASIC modules, and the memory programmable functions are synthesized to FPGA modules. Placement, signal routing and boundary timing closure are completed and the platform is configured by adding metallization layer(s) to configure the ASIC modules and creating a firmware memory to configure the FPGA modules. An over-provisioning feature in the FPGA modules permits post-fabrication alteration of logic functions.

Abstract: A process is disclosed for configuring a base platform having ASIC and FPGA modules to perform a plurality of functions. A verified RTL hardware description of a circuit is mapped and annotated to identify memory programmable functions. The memory programmable functions are grouped for assignment to FPGA modules. The non-memory programmable functions are synthesized to ASIC modules, and the memory programmable functions are synthesized to FPGA modules. Placement, signal routing and boundary timing closure are completed and the platform is configured by adding metallization layer(s) to configure the ASIC modules and creating a firmware memory to configure the FPGA modules. An over-provisioning feature in the FPGA modules permits post-fabrication alteration of logic functions.

Abstract: A method for generalizing design attributes in a design capture environment comprising the steps of (A) defining a procedure for adding one or more auxiliary configurators to a tool or suite of tools, (B) linking the auxiliary configurators to predetermined object points in an abstracted design and (C) defining a procedure for the tool or suite of tools to reference the one or more auxiliary configurators, wherein the auxiliary configurators are neither referenced by a core nor built into the tool or suite of tools.

Abstract: An SIP for performing a plurality of hard and soft functions comprises standard IC die and custom platforms mounted to a substrate. Die are identified for each standard hard function, such as memory, processing, I/O and other standard functions and one or more user-configurable base platforms are selected that, when configured, execute the custom soft functions. Optionally, the substrate is laminated to the die and the platforms are attached to the substrate. Testing is performed by defining the configured base platforms coupled to logic representing the die and their connections and performing placement and timing closure on the combination.