Patent application number | Description | Published |
20110010136 | Micro Electromechanical Device With Stress and Stress Gradient Compensation - Methods for designing a micro electromechanical device are disclosed. In one embodiment, the method comprises extending a floating element between a first anchor point and a second anchor point. The floating element includes a predetermined reference portion. The method further comprises determining a first location for a first stress relieving element on a first flexible section located between the first anchor point and the reference point, and determining a second location for a second stress relieving element on a second flexible section located between the second anchor point and the reference point. The method additionally comprises placing the first and second stress relieving elements at the first and second determined locations, respectively, thereby causing the reference portion to be located within a predetermined reference plane while in at least one predetermined state. | 01-13-2011 |
20110175492 | Temperature Compensation Device and Method for MEMS Resonator - The present disclosure provides a device including a MEMS resonating element, provided for resonating at a predetermined resonance frequency, the MEMS resonating element having at least one temperature dependent characteristic, a heating circuit arranged for heating the MEMS resonating element to an offset temperature (T | 07-21-2011 |
20110210801 | TEMPERATURE MEASUREMENT SYSTEM COMPRISING A RESONANT MEMS DEVICE - A micromechanical resonator device and a method for measuring a temperature are disclosed. In one aspect, the device has a resonator body, an excitation module, a control module, and a frequency detection module. The resonator body is adapted to resonate separately in at least a first and a second predetermined resonance state, selected by applying a different bias, the states being of the same eigenmode but having a different resonance frequency, each resonance frequency having a different temperature dependence. The micromechanical resonator device may have a passive temperature compensated resonance frequency. | 09-01-2011 |
20120132529 | METHOD FOR PRECISELY CONTROLLED MASKED ANODIZATION - The present invention is related to a method for masked anodization of an anodizable layer on a substrate, for example an aluminum layer present on a sacrificial layer, wherein the sacrificial layer needs to be removed from a cavity comprising a Micro or Nano Electromechanical System (MEMS or NEMS). Anodization of an Al layer leads to the formation of elongate pores, through which the sacrificial layer can be removed. According to the method of the invention, the anodization of the Al layer is done with the help of a first mask which defines the area to be anodized, and a second mask which defines a second area to be anodized, said second area surrounding the first area. Anodization of the areas defined by the first and second mask leads to the formation of an anodized structure in the form of a closed ring around the first area, which forms a barrier against unwanted lateral anodization in the first area. | 05-31-2012 |
20120188023 | Optimal Leg Design for MEMS Resonator - A microelectromechanical (MEMS) resonator is disclosed that comprises a substrate and a resonator body suspended above the substrate by means of clamped-clamped beams, where each beam comprises two support legs with a common connection to the resonator body, and the resonator body is configured to resonate at an operating frequency. The MEMS resonator further comprises an excitation component configured to excite the resonator body to resonate at the operating frequency, where each beam is further configured to oscillate in a flexural mode at a flexural wavelength as a result of resonating at the operating frequency, and each leg is acoustically long with respect to the flexural wavelength. | 07-26-2012 |
20120305542 | Oven Controlled MEMS Oscillator Device - A system is disclosed that includes an oven and a micromechanical oscillator inside the oven configured to oscillate at a predetermined frequency at a predetermined temperature, where the predetermined frequency is based on a temperature dependency and at least one predetermined property. The system further includes an excitation mechanism configured to excite the micromechanical oscillator to oscillate at the predetermined frequency and a temperature control loop configured to detect a temperature of the micromechanical oscillator using resistive sensing, determine whether the temperature of the micromechanical oscillator is within a predetermined range of the predetermined temperature based on the temperature dependency and the at least one predetermined property in order to minimize frequency drift, and adapt the temperature of the micromechanical oscillator to remain within the predetermined range. The system further includes a frequency output configured to output the predetermined frequency of the micromechanical oscillator. | 12-06-2012 |
20140292323 | Two Axes MEMS Resonant Magnetometer - A two-axes MEMS magnetometer includes, in one plane, a freestanding rectangular frame having inner walls and four torsion springs, wherein opposing inner walls of the frame are contacted by one end of only two torsion springs, each torsion spring being anchored by its other end, towards the centre of the frame, to a substrate. In operation, the magnetometer measures the magnetic field in two orthogonal sensing modes using differential capacitance measurements. | 10-02-2014 |