Abstract: A system is provided for providing vibration isolation and acceleration compensation for a device such as a vibration-sensitive oscillator or sensor. The system has an assembly that moves or vibrates relative to an external component. The assembly includes a plurality of components mounted to either side of a PCB. One or more accelerometers are configured to detect acceleration of the PCB in at least one of an X-axis direction, a Y-axis direction, and a Z-axis direction. The system includes plurality of isolators coupled to the assembly and configured to isolate or dampen vibrations that would otherwise transfer to the assembly from an underlying component to which the assembly is configured to attach to. In certain embodiments, the isolators are located between the assembly and the underlying component within vertical confines of an exterior perimeter of the PCB.

Abstract: A system is provided for providing vibration isolation and acceleration compensation for a device such as a vibration-sensitive oscillator or sensor. The system has an assembly that moves or vibrates relative to an external component. The assembly includes a plurality of components mounted to either side of a PCB. One or more accelerometers are configured to detect acceleration of the PCB in at least one of an X-axis direction, a Y-axis direction, and a Z-axis direction. The system includes plurality of isolators coupled to the assembly and configured to isolate or dampen vibrations that would otherwise transfer to the assembly from an underlying component to which the assembly is configured to attach to. In certain embodiments, the isolators are located between the assembly and the underlying component within vertical confines of an exterior perimeter of the PCB.

Abstract: A method and system for using ultrasound for evaluating pressure of a vessel of a user, the method including: providing an ultrasound system configured to be placed at a body region proximal the vessel of the user, generating a correlation between a set of push pulse parameters and a set of push pulse-dependent values associated with the vessel, wherein generating the correlation includes providing a push pulse and determining a push pulse-dependent value based on the push pulse, generating a pressure value from the vessel based on the correlation, and generating a pressure waveform from the pressure value and a set of supplemental pressure values.

Abstract: A system is provided for providing vibration isolation and acceleration compensation for a device such as a vibration-sensitive oscillator or sensor. The system has an assembly that moves or vibrates relative to an external component. The assembly includes a plurality of components mounted to either side of a PCB. One or more accelerometers are configured to detect acceleration of the PCB in at least one of an X-axis direction, a Y-axis direction, and a Z-axis direction. The system includes plurality of isolators coupled to the assembly and configured to isolate or dampen vibrations that would otherwise transfer to the assembly from an underlying component to which the assembly is configured to attach to. In certain embodiments, the isolators are located between the assembly and the underlying component within vertical confines of an exterior perimeter of the PCB.

Abstract: A space-efficient, planar interposer for packaging and support of a device (e.g., MEMS device) is provided. The interposer has a device-mounting region for supporting a device, such as a sensor, accelerometer, gyroscope, etc. The interposer is formed from a single layer of material, and has cut-outs or gaps formed therein to define springs. The springs connect the device-mounting region to anchor regions configured to anchor the interposer to an underlying substrate or package. The cut-outs or gaps of the interposer are made with space-efficiency in mind. In certain embodiments, the cut-outs or gaps extend inwardly toward the center of the interposer such that the anchor regions can also extend inwardly, and at least a portion of each anchor region is further inboard on the interposer than a portion of the device-mounting region. As such, the anchor regions can be located within an extended or virtual perimeter of the device-mounting region.

Abstract: A method and system for using ultrasound for evaluating pressure of a vessel of a user, the method including: providing an ultrasound system configured to be placed at a body region proximal the vessel of the user, generating a correlation between a set of push pulse parameters and a set of push pulse-dependent values associated with the vessel, wherein generating the correlation includes providing a push pulse and determining a push pulse-dependent value based on the push pulse, generating a pressure value from the vessel based on the correlation, and generating a pressure waveform from the pressure value and a set of supplemental pressure values.

Abstract: The first integrated circuit/transducer device 36 of the handheld probe includes CMOS circuits 110 and cMUT elements 112. The cMUT elements 112 function to generate an ultrasonic beam, detect an ultrasonic echo, and output electrical signals, while the CMOS circuits 110 function to perform analog or digital operations on the electrical signals generated through operation of the cMUT elements 112. The manufacturing method for the first integrated circuit/transducer device 36 of the preferred embodiment includes the steps of depositing the lower electrode S102; depositing a sacrificial layer S104; depositing a dielectric layer S106; depositing the upper electrode S108; depositing a protective layer on the upper electrode S110; and removing the sacrificial layer S112. In the preferred embodiment, the manufacturing method also includes the step of depositing a sealant layer to seal a cavity between the lower electrode and the upper electrode S114.

Abstract: The first integrated circuit/transducer device 36 of the handheld probe includes CMOS circuits 110 and cMUT elements 112. The cMUT elements 112 function to generate an ultrasonic beam, detect an ultrasonic echo, and output electrical signals, while the CMOS circuits 110 function to perform analog or digital operations on the electrical signals generated through operation of the cMUT elements 112. The manufacturing method for the first integrated circuit/transducer device 36 of the preferred embodiment includes the steps of depositing the lower electrode S102; depositing a sacrificial layer S104; depositing a dielectric layer S106; removing the sacrificial layer S108, followed by the steps of depositing the upper electrode S110 and depositing a protective layer on the upper electrode S112.

Abstract: The preferred embodiment of the invention includes a single integrated circuit for a handheld probe of an ultrasound system. The integrated circuit includes a two-dimensional array of at least 512 transducer cells, each transducer cell is adapted to receive a beam signal, generate an ultrasonic beam, detect an ultrasonic echo at multiple locations, and combine the ultrasonic echoes into a single multiplexed echo signal. Each transducer cell includes at least one ultrasonic beam generator and at least four ultrasonic echo detectors. The integrated circuit also includes a series of beam signal leads adapted to carry the beam signals to the transducer cells and a series of echo signal leads adapted to carry the multiplexed echo signals from the transducer cells.