Abstract: In certain examples, methods and apparatuses, such as circuits, are directed to scanning in a field of view (FoV) by using a pattern that improves sensing in a region of interest (RoI) within the FoV. In one example, a signal having multiple frequency components and a scan-pattern design are used, with a balanced or optimized set of attributes including a sampling density attribute, to scan a RoI in a FoV by sampling or traversing the RoI more times than other regions in the FoV. In more specific examples, circuitry finds the scan-pattern design based on an algorithm that processes different parameters involving at least one of amplitude and phase and processes a. number of different frequency components related to or including the multiple frequency components, wherein the number of different frequency components is from three to a threshold limit whereat processing different frequency components provides negligible improvement.

Abstract: Certain examples are directed to circuitry and methods involving adaptive scanning of a target area, by use of a scanning output controlled by a multiple-axis scanner, within a selected region of interest (RoI) in a field of view (FoV) as a function of a first drive signal having a first set of one or more frequency components and of a second drive signal having a second set of one or more frequency components. One or more aspects of at least the first drive signal is modulated to produce a plurality of drive signals including the modulated first drive signal, and the drive signals at the multiple-axis scanner are used to: control the scanning output, cause the scanning output to traverse the selected RoI more times than other portions of the FoV and spatially sample the target area via a higher concentrations of samples in the RoI.

Abstract: Aspects are directed to a MEMS device configurable to receive signals from a first, a second, a third, and a fourth signal source operating at a first, a second, a third, and a fourth frequency, respectively. The MEMS device may be configured to combine the first signal with the second signal generating a first combined signal, and to combine the third signal with the fourth signal generating a second combined signal. The first combined signal may be coupled to the first terminal of the MEMS device while the second combined signal may be coupled to the second terminal of the MEMS device. The first common terminal may be configured to produce an output associated with the second and fourth frequencies. The MEMS device may be further configured to derive from the produced output a signal indicative of nonlinearities or of changes in capacitance related to the MEMS device.

Abstract: Aspects are directed to a MEMS device configurable to receive signals from a first, a second, a third, and a fourth signal source operating at a first, a second, a third, and a fourth frequency, respectively. The MEMS device may be configured to combine the first signal with the second signal generating a first combined signal, and to combine the third signal with the fourth signal generating a second combined signal. The first combined signal may be coupled to the first terminal of the MEMS device while the second combined signal may be coupled to the second terminal of the MEMS device. The first common terminal may be configured to produce an output associated with the second and fourth frequencies. The MEMS device may be further configured to derive from the produced output a signal indicative of nonlinearities or of changes in capacitance related to the MEMS device.