Abstract: A MEMS apparatus for scanning an optical beam comprises a mirror operative to perform a rotational motion to a maximum rotation angle around a mirror rotation axis, and a bouncing mechanism operative to provide a bouncing event and to reverse the rotational motion. The bouncing event provides the mirror with a piecewise linear response to actuation by intrinsically nonlinear electrostatic forces. The bouncing mechanism includes an element chosen to impart an overall nonlinear stiffness to the system and is selected from the group of elements consisting of a bouncer and a pre-curved nonlinear stiffness element.

Abstract: A MEMS apparatus for scanning an optical beam comprises a mirror operative to perform a rotational motion to a maximum rotation angle around a mirror rotation axis, and a bouncing mechanism operative to provide a bouncing event and to reverse the rotational motion. The bouncing event provides the mirror with a piecewise linear response to actuation by intrinsically nonlinear electrostatic forces. The bouncing mechanism includes an element chosen to impart an overall nonlinear stiffness to the system and is selected from the group of elements consisting of a bouncer and a pre-curved nonlinear stiffness element.

Abstract: Magnetically and electromagnetically driven MEMS devices for reflecting light signals and for switching radio frequency (RF) signals are provided. In a preferred embodiment, a light reflecting device such as a mirror or micro-scanner comprises a plate operative to reflect light and at least two conductive flexural actuators connected to the plate and to a substrate and operative to impart a rotation or tilt motion to the plate under a force arising from the interaction of a current passing through the conductive flexural actuators and a magnetic field parallel to the substrate. An RF switch comprises a substrate and a membrane having a longitudinal dimension and a lateral dimension, the membrane positioned substantially parallel to and attached to the substrate and operative to provide at least two switching positions in response to actuation by a Lorenz force acting on it.

Abstract: A MEMS variable optical attenuator (VOA) comprises at least one semitransparent refraction-mode shutter having a wedge shape and operative to attenuate an optical beam transmitted from a first optical fiber to a second optical fiber using refraction of the beam, and an actuator operative to position the shutter in the path of the beam. Optionally, the VOA further comprises a locking mechanism for locking the shutter after actuation, and at least one damper connected to the shutter for shortening the VOA switching time. The actuator may include in various embodiments a folding suspension with straight or curved springs, some springs interacting electrostatically with one or more side electrodes to provide an essentially linear dependence of shutter movement on actuation voltage.

Abstract: A RF switch comprises a substrate having two RF traces separated by a first gap, and coplanar ground traces separated from tile RF traces by a second gap, a membrane substantially parallel to the substrate and incorporating a conductive bridge, and an electrical mechanism for bringing the bridge into contact with the RF and ground traces, and for spacing the bridge apart from these traces. The membrane flexes in a membrane mode toward and away from the traces, providing extremely fast switching. A series configuration includes the bridge shorting the two RF traces, and a shunt configuration includes the bridge shorting the RF and aground traces. A separate embodiment provides a membrane vertical to the substrate and flexing in a direction parallel to it.

Abstract: The system can include one or more optical switching devices. Each optical switching device can achieve relatively high switching speeds such as between thirty (30) nano-seconds to fifty (50) nano-seconds with precise angular movement. The switching speed can be defined as the movement of an optical element from a first switching position to a second switching position. The relatively high switching speeds and precise angular movement of the optical element can be attributed to utilizing a combination of electrodes and membrane supports made from predefined materials that react to the electrodes. The optical switching device can be a microelectromechanical system (MEMS) device that can be fabricated by the adding or etching layers of materials such as in photolithography manufacturing techniques. The optical element can include a mirror made from reflective materials such as a layer of gold.

Abstract: The system can include one or more optical switching devices. Each optical switching device can achieve relatively high switching speeds such as between thirty (30) nano-seconds to fifty (50) nano-seconds with precise angular movement. The switching speed can be defined as the movement of an optical element from a first switching position to a second switching position. The relatively high switching speeds and precise angular movement of the optical element can be attributed to utilizing a combination of electrodes and membrane supports made from predefined materials that react to the electrodes. The optical switching device can be a microelectromechanical system (MEMS) device that can be fabricated by the adding or etching layers of materials such as in photolithography manufacturing techniques. The optical element can include a mirror made from reflective materials such as a layer of gold.