A method for manufacturing a micromechanical device includes providing a silicon substrate having a front side and a rear side, where a first normal of the front side deviates by a first angle from the <111> direction of the silicon substrate; forming in the front side first and second trenches that are spaced apart from and essentially parallel to each other, with the first and second trenches extending along a direction of the deviation; forming on the front side a first etching mask that covers the front side except for a first opening area between the first and second trenches; and anisotropically etching the front side using the etching mask, thereby forming in the opening area an oblique surface having a second angle to the first normal, which approximately corresponds to the first angle.

A microfabricated optical apparatus that includes a light source driven by a waveform, wherein the waveform is delivered to the light source by at least one through silicon via. The microfabricated optical apparatus may also include a light-sensitive receiver which generates an electrical signal in response to an optical signal. The electrical signal may be communicated to external devices by at least one additional through silicon via, and the signals routed to the encapsulated devices by metal traces. The vias may couple a ground plane to a metal trace layer at intervals, effectively quashing the ability of the bondline to interfere with the absorbed or radiated signal frequency.

An optical scanner including micro-electromechanical system phased-arrays suitable for use in a LiDAR system, and methods of operating the same are described. Generally, the scanner includes an optical transmitter having first phased-arrays to receive light from a light source, form a swath of illumination in a far field scene and to modulate phases of the light to sweep or steer the swath over the scene in two-dimensions (2D). An optical receiver in the scanner includes second phased-arrays to receive light from the far field scene and direct at least some of the light onto a detector. The second phased-arrays are configured to de-scan the received light by directing light reflected from the far field scene onto the detector while rejecting background light. In one embodiment the second phased-arrays direct light from a slice of the far field scene onto a 1D detector array.

An electro-optic device includes a chip provided with a mirror and a drive element adapted to drive the mirror, a light-transmitting cover adapted to cover the mirror in a planar view, and a spacer having contact with one surface of the chip between the cover and the chip. The entire part of one surface of the chip having contact with the spacer is made of a firs material such as silicon oxide film having first thermal conductivity, and the spacer is made of a second material such as a quartz crystal having second thermal conductivity higher than the first thermal conductivity. The cover is made of a third material such as sapphire having third thermal conductivity higher than the second thermal conductivity.

An assembly body for micromirror chips that partly encloses an internal cavity, the assembly body including at two sides oriented away from one another, at least one respective partial outer wall that is fashioned transparent for a specified spectrum, and the assembly body having at least one first outer opening on which a first micromirror chip can be attached, and a second outer opening on which a second micromirror chip can be attached, in such a way that a light beam passing through the first partial outer wall is capable of being deflected by the first micromirror chip onto the second micromirror chip, and is capable of being deflected by the second micromirror chip through the second partial outer wall. A mirror device and a production method for a mirror device are also described.

A microfabricated optical apparatus that includes a light source driven by a waveform, wherein the waveform is delivered to the light source by at least one through silicon via. The microfabricated optical apparatus may also include a light-sensitive receiver which generates an electrical signal in response to an optical signal. An optical source may be attached to a carrier substrate with the TOSA by a flexible connector, in order to align the optical source before affixing it permanently.

A device can comprise an outer frame, a platform, and a motion control mechanism. The motion control mechanism can be adapted to permit movement of the platform in a desired direction with respect to the outer frame and inhibit rotation of the platform with respect to the outer frame. An actuator can be contained at least partially within the motion control mechanism.

A microfabricated optical apparatus that includes a light source driven by a waveform, wherein the waveform is delivered to the light source by at least one through silicon via. The microfabricated optical apparatus may also include a light-sensitive receiver which generates an electrical signal in response to an optical signal. The electrical signal may be communicated to external devices by at least one additional through silicon via, and the signals routed to the encapsulated devices by metal traces. The vias may couple a ground plane to a metal trace layer at intervals, effectively quashing the ability of the bondline to interfere with the absorbed or radiated signal frequency.

For an optical electronic device and method that forms cavities through an interposer wafer after bonding the interposer wafer to a window wafer, the cavities are etched into the bonded interposer/window wafer pair using the anti-reflective coating of the window wafer as an etch stop. After formation of the cavities, the bonded interposer/window wafer pair is bonded peripherally of die areas to the MEMS device wafer, with die area micromechanical elements sealed within respectively corresponding ones of the cavities.

A transducer modulus, comprising: a substrate; a cap on the substrate, defining a chamber; and a sensor modulus in the chamber, integrating a first MEMS transducer facing the chamber, and a second MEMS transducer facing the supporting substrate. The cap has a first opening that forms a path for access of the first environmental quantity exclusively towards a sensitive element of the first transducer, and the supporting substrate has a second opening that forms a path for access of the second environmental quantity exclusively towards a sensitive element of the second transducer.