Abstract: A buffer arrangement for providing pixel information in a Lissajous scanning projection system is provided. The projection system includes a memory, a MEMS mirror, a projection unit, and a data unit. The memory includes a projection buffer and a shadow buffer. An incoming stream of pixel information scanned from the MEMS mirror is written to the shadow buffer. The incoming stream of pixel information is forwarded to the projection buffer. The projection buffer forwards the incoming stream of pixel information to the projection unit. The projection unit projects the incoming stream of pixel information based on the Lissajous pattern through a mirror projector trajectory. The shadow buffer and the projection buffer operate at different frequencies.

Abstract: There is provided a micro-electromechanical system (MEMS) device (102, 200, 300, 404) for cancelling noise generated by oscillation of a movable micro-electromechanical system (MEMS) element (104, 204, 304, 406). The micro-electromechanical system (MEMS) device (102, 200, 300, 404) includes the movable micro-electromechanical system (MEMS) element (104, 204, 304, 406), an actuator (106, 208, 306, 408), a controller (108, 410) and a movable noise cancelling element (110, 202, 312, 412). The controller (108, 410) provides electrical signals to drive the actuator (106, 208, 306, 408) and the movable noise cancelling element (110, 202, 312, 412) in a way to cancel the noise generated in the micro-electromechanical system (MEMS) device (102, 200, 300, 404) by oscillation of the movable MEMS element (104, 204, 304, 406).

Abstract: The present disclosure provides a deflection device (100, 200, 300, 400) for use in a scanner. The deflection device (100, 200, 300, 400) includes a substrate (102, 202), a mirror (106, 206, 304, 404) and actuator means (110). The mirror (106, 206, 304, 404) arranged in a recess (104, 204, 306, 406) in the substrate (102, 202) by connector means (108) in such a way that it can rotate about at least two axes in an oscillatory manner. The actuator means (110) causes the mirror (106, 206, 304, 404) to oscillate. The actuator means (110) are arranged in one or more trenches (112A-D) in the substrate (102, 202) surrounding the recess (104, 204, 306, 406), in such a way that a change of shape of the actuator means (110) will cause a movement in the substrate (102, 202), thereby inducing oscillatory movement of the mirror (106, 206, 304, 404).

Abstract: The present disclosure provides a Lissajous dual-axial scan component (100) that includes an outer frame (102), a first pair of supports (104A-B), a second pair of supports (106A-B), an inner frame (108), a mirror (110), a sensing arrangement (112), a controller (114) and a memory (116). The memory (116) stores multiple tuples each including a first-axial bias frequency value, a second-axial bias frequency value, and a phase difference between actual driving frequencies (i.e. a first-axial bias frequency and a second-axial bias frequency) of the mirror (110). The controller (114) is coupled to the sensing arrangement (112) to receive signals indicative of current resonant frequencies of the mirror (110) and configured to select one of the tuples from the memory (116) based on the signals received from the sensing arrangement (112) and set the applied bias frequencies, and their phase difference, according to the selected tuple.

Abstract: The invention relates to a glass substrate-based MEMS mirror device for variable deflection of an incident electromagnetic beam, as well as a method for its production. The MEMS mirror device has a disk-shaped first glass substrate structured into a plurality of subregions with a mirror subregion formed at least partially as a MEMS mirror for reflecting electromagnetic radiation and a frame subregion surrounding the mirror subregion at least in sections. The mirror subregion is designed as a subregion of the first glass substrate suspended so as to be capable of oscillating in several dimensions relative to the frame subregion by means of at least one connecting element connecting the mirror subregion and the frame subregion and which can be designed in particular as a connecting web or mechanical spring.

Abstract: A converter assembly for converting a primary light into a secondary light includes at least one element which has a light-converting structure with open pores and which is laterally held by a frame. The surfaces of both the light-converting structure as well as of the inner face of the frame are covered with a transparent layer such that each of the afore-mentioned elements forms a region in which a property of the incident light and preferably of the wavelength thereof is changed. In specific embodiments, the converter assembly can be part of display assemblies or of miniaturized components for example. There is also described a method for producing the converter assembly.

Abstract: The invention relates to an appliance for detecting objects in a detection region, with a radiation device for emitting an electromagnetic scanning beam into at least a part of the detection region and with a device for modulating the scanning beam as well as with a detection device for the detection of reflected radiation from at least a part of the detection region and with a device for evaluating the time response of the detected, reflected radiation, in dependence on the modulation of the scanning beam. According to the invention, one can envisage the radiation device comprising a radiation source radiating a diffusion device scattering the radiation at least partly into the detection region, in order to be able to apply an as powerful as possible laser as a t source without endangering the eye safety or the general safety of persons.

Abstract: A converter assembly for converting a primary light into a secondary light includes at least one element which has a light-converting structure with open pores and which is laterally held by a frame. The surfaces of both the light-converting structure as well as of the inner face of the frame are covered with a transparent layer such that each of the afore-mentioned elements forms a region in which a property of the incident light and preferably of the wavelength thereof is changed. In specific embodiments, the converter assembly can be part of display assemblies or of miniaturized components for example. There is also described a method for producing the converter assembly.

Abstract: A method for activating a deflection device comprising at least one deflection unit, for a projection device for projecting trajectories upon a projection surface, wherein the deflection device deflects electromagnetic radiation which is directed upon it, for producing trajectories, and the at least one deflection unit is activated by way of an activation signal delivered from a control device, for producing oscillations in each case with a turning amplitude at a direction change of the oscillation, about at least one deflection axis, wherein in the case of resonance, the oscillations have a maximal amplitude, at which the produced trajectories reach an edge of the projection surface.

Abstract: What is proposed is: a micromirror arrangement which comprises: a first spring-mass oscillator, which has an oscillatory body forming a mirror plate (1) and first spring elements (2); a second spring-mass oscillator, which has a drive plate (3) and second spring elements (4) and which is connected to a carrier arrangement (5, 8, 9) via the second spring elements (4), wherein the first spring-mass oscillator is suspended in the second spring-mass oscillator via the first spring elements (2); and a drive arrangement (11), which is assigned to the drive plate and is designed to cause the drive plate (3) to oscillate.

Abstract: The invention relates to an appliance for detecting objects in a detection region, with a radiation device for emitting an electromagnetic scanning beam into at least a part of the detection region and with a device for modulating the scanning beam as well as with a detection device for the detection of reflected radiation from at least a part of the detection region and with a device for evaluating the time response of the detected, reflected radiation, in dependence on the modulation of the scanning beam. According to the invention, one can envisage the radiation device comprising a radiation source radiating a diffusion device scattering the radiation at least partly into the detection region, in order to be able to apply an as powerful as possible laser as a t source without endangering the eye safety or the general safety of persons.

Abstract: What is proposed is: a micromirror arrangement which comprises: a first spring-mass oscillator, which has an oscillatory body forming a mirror plate (1) and first spring elements (2); a second spring-mass oscillator, which has a drive plate (3) and second spring elements (4) and which is connected to a carrier arrangement (5, 8, 9) via the second spring elements (4), wherein the first spring-mass oscillator is suspended in the second spring-mass oscillator via the first spring elements (2); and a drive arrangement (11), which is assigned to the drive plate and is designed to cause the drive plate (3) to oscillate.

Abstract: A method for activating a deflection device comprising at least one deflection unit, for a projection device for projecting trajectories upon a projection surface, wherein the deflection device deflects electromagnetic radiation which is directed upon it, for producing trajectories, and the at least one deflection unit is activated by way of an activation signal delivered from a control device, for producing oscillations in each case with a turning amplitude at a direction change of the oscillation, about at least one deflection axis, wherein in the case of resonance, the oscillations have a maximal amplitude, at which the produced trajectories reach an edge of the projection surface.