A MEMS sensor comprising preloaded suspension springs and a method for mechanically preloading suspension springs of a MEMS sensor are described. The MEMS sensor comprises a MEMS support structure; a plurality of suspension springs connected to said support structure; and, a proof mass flexibly suspended by said suspension springs; wherein at least one of said suspension springs is mechanically preloaded with a compressive force for reducing the natural frequency of said proof mass.

A vibration energy harvester includes: a first electrode; and a second electrode that can be displaced relative to the first electrode along a predetermined vibrating direction. At least either of a surface of the first electrode and a surface of the second electrode facing opposite each other is electrically charged. Power is generated as the second electrode becomes displaced causing a change in electrostatic capacitance between the first electrode and the second electrode. A range having included therein at least a vibrational center of the second electrode, over which the electrostatic capacitance remains unchanged even as the second electrode is displaced, is set.

A sensor element includes a membrane structure suspended on a frame structure, wherein the membrane structure includes a membrane element and an actuator. The membrane structure is deflectable in a first stable deflection state and in a second stable deflection state and is operable in a resonance mode in at least one of the first and the second stable deflection states. The actuator is configured to deflect the membrane structure in a first actuation state into one of the first and the second stable deflection states, and to operate the membrane structure in a second actuation state in a resonance mode having an associated resonance frequency.

A method of fabricating a MEMS structure includes providing a substrate comprising a logic element region and a MEMS region. Next, a logic element is formed within the logic element region. A nitrogen-containing material layer is formed to cover the logic element region and the MEMS region conformally. Then, part of the nitrogen-containing material layer within the MEMS region is removed to form at least one shrinking region. Subsequently, a dielectric layer is formed to cover the logic element region and MEMS region, and the dielectric layer fills in the shrinking region. After that, the dielectric layer is etched to form at least one releasing hole, wherein the shrinking region surrounds the releasing hole. Finally, the substrate is etched to form a chamber.

A MEMS sensor comprising preloaded suspension springs and a method for mechanically preloading suspension springs of a MEMS sensor are described. The MEMS sensor comprises a MEMS support structure; a plurality of suspension springs connected to the support structure; and, a proof mass flexibly suspended by the suspension springs; wherein at least one of the suspension springs is mechanically preloaded with a compressive force for reducing the natural frequency of said proof mass.

A vibration sensor with monitoring function is provided, which includes a substrate, a microelectromechanical vibration sensor chip and an application-specific integrated circuit chip. The microelectromechanical vibration sensor chip is disposed on the substrate and detects a vibration applied to an object to generate a plurality of vibration signals. The application-specific integrated circuit chip is disposed on the substrate and electrically connected to the microelectromechanical vibration sensor chip, which includes a sampling module, a transform module and an analysis module. The sampling module receives and converts the vibration signals into a plurality of digital signals, and filters the digital signals to generate a plurality of time-domain data. The transform module transforms the time-domain data into a frequency-domain data according to a predetermined number. The analysis module executes a comparison process to compare the frequency-domain data with a predetermined spectrum feature table and generates a notification signal according to the comparison result.

The invention relates to a sensing module and a manufacturing method thereof, which firstly provides a transparent substrate, and then a sensor, a colloid, and an optical cover body disposed on a first surface of the transparent substrate. The colloid is surrounded the encrypted chip and is connected with the transparent substrate and the optical cover. Finally, a light source irradiates the colloid through a second surface of the transparent substrate to cure the colloid for obtaining the sensing module.

A sensor package is disclosed. The sensor package can include a support structure that is configured to couple with a vibration source by way of a stud. The sensor package can include a cap that is at least partially disposed over the support structure. The cap at least partially defines a cavity. The sensor package can include a vibration sensor module that is coupled to a portion of the support structure and disposed in the cavity. The sensor package can have a mechanical resonant frequency in a range of 0.1 Hz to 11 kHz. The sensor package can include a connector that is coupled to the support structure. The connector can connect to a connection line is electrically connect the vibration sensor module to an external substrate or system. The support structure can include a material that has a Young's modulus of at least 60 GPa and a density less than 3000 kg/m3. The sensor package can include a filler material disposed in the cavity.

An electronic device including a substrate, a sensor, a partition wall structure, a pressurizing component, and a stopping structure is provided. The substrate has a carrying surface. The sensor is disposed on the carrying surface. The partition wall structure is disposed on the carrying surface and surrounds the sensor. The pressurizing component is disposed on the partition wall structure. The pressurizing component, the partition wall structure, and the substrate jointly form a cavity, and the pressurizing component includes a mass and a vibration membrane. The stopping structure is disposed between the pressurizing component and the partition wall structure and extends into the cavity. The stopping structure has at least one opening penetrating the stopping structure.

A physical quantity detection device includes a semiconductor element and a physical quantity detection vibrator element a portion of which overlaps the semiconductor element in a plan view of the semiconductor element. The physical quantity detection vibrator element includes a drive portion including a drive electrode, and a detection portion. At least a partial region of the drive electrode does not overlap the semiconductor element in the plan view of the semiconductor element.