Abstract: An atomic clock having a physics package that includes a vacuum chamber cavity that holds atoms of Rb-87 under high vacuum conditions, an optical bench having a single laser light source, a local oscillator, a plurality of magnetic field coils, an antenna, at least one photo-detector and integrated control electronics. The single laser light source has a fold-retro-reflected design to create three retro-reflected optical beams that cross at 90° angles relative to one another in the vacuum chamber cavity. This design allows the single laser light source to make the required six trapping beams needed to trap and cool the atoms of Rb-87. The foregoing design makes possible atomic clocks having reduced size and power consumption and capable of maintaining an ultra-high vacuum without active pumping.

Abstract: An optical-based acoustic sensor system detects sound. An exemplary embodiment has a substrate with a surface and an internal region; a shell disposed above the substrate surface, the shell operable to receive incident light emitted by a light source; a beam disposed blow the shell; a photodiode on the substrate surface below the beam, and in response to receiving a first portion of light, the photodiode is operable to generate a charge that attracts the beam such that a motion is induced in the beam to cause the beam to resonate; and a microphone device coupled to the shell, the microphone device operable to detect acoustic waves, and operable to modulate the vibratory motion of the beam, wherein a second portion of light is modulated by the vibratory motion of the beam to generate sound-modulated light that is emitted from the sensor.

Abstract: An optical-based sensor system that detects emitted light. An exemplary embodiment of an optical-based sensor has a substrate with a surface and an internal region; a shell disposed above the substrate surface, the shell operable to receive incident light characterized by a first wavelength; a beam disposed below the shell; a photodiode on the substrate surface below the beam, and in response to receiving a first portion of the incident light, the photodiode is operable to generate a charge such that a motion is induced to resonate at a resonate frequency; and a phosphor in the substrate internal region and operable to receive a second portion of the incident light, the phosphor further operable to emit light characterized by at least one second wavelength that is different from the first wavelength of the incident light, the phosphor emitted light transmitted through the photodiode, the beam, and the shell.

Abstract: A start-up circuit having a micro crush capacitor that is operatable with a small pressure. The crush capacitor may be connected to a silicon controlled rectifier or similar device. Applying the pressure to the crush capacitor may turn on the SCR which may in turn activate a sensor. The circuit may be fabricated on a flexible substrate which together may be regarded as a flexible circuit. The flexible circuit may be held down on a back plate with a form plate clamping the circuit at its perimeter edge. The flexible circuit may be held firm with the plates for component insertion and/or circuit testing.

Abstract: A method and system for detecting concealed weapons and explosives by imaging THz scenes using conventional optics and detectors is provided. Photon fields with two different wavelengths can be sent through a chopper and towards a wavelength-selective mirror. A light beam with a wavelength in the visible or IR range is sent toward a visible photon array detector. Similarly, light beams with wavelengths in the THz range can be sent towards a target, which are reflected and/or absorbed by objects in the target. The reflected or transmitted light continues on through an optional filter to remove background light, then into a non-imaging detector. The visible photon array detector can be coupled with the non-imaging detector, which will register an image of the scene that is illuminated by the THz photons.

Abstract: Miniature optically transparent windows are disclosed that extend vertically from a plane, which may be used to transmit light traveling in a direction substantially parallel with the plane. In one illustrative embodiment, a method for forming such miniature optically transparent windows includes: providing a substrate having a first surface and an opposing second surface, the substrate having a first layer and an adjacent second layer; forming a recess in the first layer of the substrate, the recess extending to the second layer; providing an optically transparent material in the recess to form an optically transparent feature; and removing at least a portion of the first layer that extends adjacent the optically transparent feature so that light can pass through the optically transparent feature in a direction that is substantially parallel to the first surface of the substrate.

Abstract: Miniature optically transparent windows are disclosed that extend vertically from a plane, which may be used to transmit light traveling in a direction substantially parallel with the plane. In one illustrative embodiment, a method for forming such miniature optically transparent windows includes: providing a substrate having a first surface and an opposing second surface, the substrate having a first layer and an adjacent second layer; forming a recess in the first layer of the substrate, the recess extending to the second layer; providing an optically transparent material in the recess to form an optically transparent feature; and removing at least a portion of the first layer that extends adjacent the optically transparent feature so that light can pass through the optically transparent feature in a direction that is substantially parallel to the first surface of the substrate.

Abstract: Systems and methods for optically pumping alkali-metal atoms using Coherence Population Trapping (CPT) resonances are disclosed. An illustrative push-pull optical pumping system for inducing CPT resonances in a resonance cell containing an admixture of alkali-metal atoms and one or more buffer gasses may include a laser assembly adapted to produce alternating orthogonally polarized light, and at least one DC current source adapted to output a constant-intensity carrier current signal for inducing laser emission from the laser assembly at a carrier wavelength of the alkali-metal atoms. An RF modulated signal outputted from an RF modulation source can be rectified, split, and phase-shifted for inducing a time-dependent polarization of the laser light that can be used to enhance CPT resonances.

Abstract: A self-healing liquid contact switch and methods for producing such devices are disclosed. An illustrative self-healing liquid contact switch can include an upper actuating surface and a lower actuating surface each having a number of liquid contact regions thereon configured to wet with a liquid metal. The upper and lower actuating surfaces can be brought together electrostatically by an upper and lower actuating electrode. During operation, the liquid metal can be configured to automatically rearrange during each actuating cycle to permit the switch to self-heal.

Abstract: A dynamic micro-structured reflector includes a substrate having a generally planar major surface and a plurality of cavities on the planar major surface. Each cavity having at least a first and second sidewalls set at an angle offset from the planar major surface. The first sidewall being a stationary optical face and the second sidewall being a dynamic optical face. The dynamic optical face is deflectable between a first position and a second position. The dynamic optical face in the first position redirects more light back to a light source than the dynamic optical face in the second position. Methods of making a dynamic micro-structured reflector are also disclosed.

Abstract: An elongated robotic member that is simple in design and structure, relatively inexpensive and consumes little power. In one illustrative embodiment, one or more linear actuators are used in conjunction with two or more plates that are fixed at spaced locations along a spine member. Fixed between each pair of plates is one or more actuators, which when activated, pull or push corresponding portions of the plates towards or away from each other. This changes the relative orientation of the plate pairs, thus providing a bending movement. The spine preferably is flexible at least in the lateral direction, and bends in response to the relative movement of the plates. A number of plate pairs may be provided to create an arbitrarily long robotic member.

Abstract: A tunable bolometer device for detecting infrared light (IR) from a target at specific frequencies and in a broadband mode. The device may have an array of pixels of which each is controllable to be sensitive to a particular wavelength of light that is selected and detected. The detection of particular frequencies on a pixel level may result in spectral analysis of the target. Further, each pixel of the bolometer via an associated etalon may be tuned to detect a different frequency of IR or be switched to broadband detection of IR. The device may be packaged in an integrated vacuum package where the etalon array becomes the topcap which is bonded to the wafer containing the bolometer array.

Abstract: A dynamic micro-structured reflector includes a substrate having a generally planar major surface and a plurality of cavities on the planar major surface. Each cavity having at least a first and second sidewalls set at an angle offset from the planar major surface. The first sidewall being a stationary optical face and the second sidewall being a dynamic optical face. The dynamic optical face is deflectable between a first position and a second position. The dynamic optical face in the first position redirects more light back to a light source than the dynamic optical face in the second position. Methods of making a dynamic micro-structured reflector are also disclosed.

Abstract: A pressure sensor is formed on a substrate, the surface of the substrate having a p-n junction and a shell with a beam inside the shell over the p-n junction. The beam and the shell and the p-n junction surface form optical Fabry-Pérot cavities. An optical fiber is positioned in a hole formed in the underside of the substrate below the p-n junction. Light from the fiber charges the p-n junction and drives it into vibration mode. Pressure changes change the tension in the diaphram to vary the frequency with changes in pressure, so that pressure can be detected.

Abstract: A pressure sensor is formed on a substrate, the surface of the substrate having a p-n junction and a shell with a beam inside the shell over the p-n junction. The beam and the shell and the p-n junction surface form optical Fabry-Pérot cavities. An optical fiber is positioned in a hole formed in the underside of the substrate below the p-n junction. Light from the fiber charges the p-n junction and drives it into vibration mode. Pressure changes change the tension in the diaphram to vary the frequency with changes in pressure, so that pressure can be detected.

Abstract: A pressure sensor is formed on a substrate, the surface of the substrate having a p-n junction and a shell with a beam inside the shell over the p-n junction. The beam and the shell and the p-n junction surface form optical Fabry-Pérot cavities. An optical fiber is positioned in a hole formed in the underside of the substrate below the p-n junction. Light from the fiber charges the p-n junction and drives it into vibration mode. Pressure changes change the tension in the diaphram to vary the frequency with changes in pressure, so that pressure can be detected.

Abstract: A tunable bolometer device for detecting infrared light (IR) from a target at specific frequencies and in a broadband mode. The device may have an array of pixels of which each is controllable to be sensitive to a particular wavelength of light that is selected and detected. The detection of particular frequencies on a pixel level may result in spectral analysis of the target. Further, each pixel of the bolometer via an associated etalon may be tuned to detect a different frequency of IR or be switched to broadband detection of IR. The device may be packaged in an integrated vacuum package where the etalon array becomes the topcap which is bonded to the wafer containing the bolometer array.

Abstract: A device 10 for sensing a magnetic field gradient using an optically powered resonant integrated microstructure (O-RIMS). The O-RIMS comprises a microbeam 11 having a resonant frequency, a shell 16 supporting the microbeam 11, sensor electronics, a light transporter 36, such as an optical fiber or optical waveguide, in proximity to the shell 16, and a ferromagnetic or magnetically permeable element 26 attached to the shell 16. The ferromagnetic or magnetically permeable element 26 experiences a torque about the fulcrum 24 when a magnetic field gradient is present, and causes a strain on the shell 16. The strain is in turn transmitted to the microbeam 11, thereby affecting its resonant frequency. The change in resonant frequency of the microbeam 11 is conveyed to the sensor electronics via the light transporter 36.

Abstract: A pressure sensor using an optically powered resonant integrated microstructure (O-RIMS). The pressure sensor comprises a planar substrate having a photodiode, a polysilicon shell, a microbeam having a resonant frequency and fastened to the shell, and one or more optical fibers. A fluorescent material, such as erbium, is placed on the surface of the substrate in proximity to the microbeam. A Fabry-Perot cavity is formed comprising the substrate, the microbeam, and the shell. Changes in the vibratory frequency of the microbeam caused by pressure on the shell causes light delivered by a optical fiber to be modulated as the microbeam vibrates. The modulated light is conveyed to a sensor electronics arrangement via the optical fiber. The sensor electronics arrangement determines the pressure surrounding the O-RIMS from the modulated light.

Abstract: A pressure sensor using an optically powered resonant integrated microstructure (O-RIMS). The pressure sensor comprises a planar substrate having a photodiode, a polysilicon shell, a microbeam having a resonant frequency and fastened to the shell, and one or more optical fibers. A fluorescent material, such as erbium, is placed on the surface of the substrate in proximity to the microbeam. A Fabry-Perot cavity is formed comprising the substrate, the microbeam, and the shell. Changes in the vibratory frequency of the microbeam caused by pressure on the shell causes light delivered by a optical fiber to be modulated as the microbeam vibrates. The modulated light is conveyed to a sensor electronics arrangement via the optical fiber. The sensor electronics arrangement determines the pressure surrounding the O-RIMS from the modulated light.