Abstract: A self-contained, hand-held device for providing a dermatological treatment includes a radiation source configured to generate one or more radiation beams, and an optical system configured to deliver the one or more radiation beams to the skin to provide a dermatological treatment. Each radiation beam includes a first axis beam profile and an orthogonal second axis beam profile. The optical system includes a first axis optic configured to influence the first axis beam profile of each radiation beam by a greater extent than the second axis beam profile of each radiation beam, and a second axis optic configured to influence the second axis beam profile of each radiation beam by a greater extent than the first axis beam profile of each radiation beam.

Abstract: A dermatological treatment device includes a handheld device body, and a laser control circuit housed in the device body and configured to generate laser radiation for delivery to a target area of tissue. The laser control circuit includes a multiple-emitter laser diode and a battery source. The multiple-emitter laser diode includes a monolithic stack of layers formed on a substrate, the monolithic stack of layers including a multiple-emitter region defining at least two emitter junctions, each emitter junction configured to emit a laser beam. The battery source provides current to the laser diode such that each of the at least two emitter junctions concurrently emits a laser beam, the at least two concurrently emitted laser beams forming a collective beam. The device delivers the collective beam to the target area of tissue to provide a dermatological treatment.

Abstract: A self-contained, hand-held device for providing radiation-based dermatological treatments includes a device body configured to be handheld by a user; a laser device supported in the device body, the laser device including a laser beam source configured to emit laser radiation; an application end configured to be manually moved across the surface of the skin during a treatment session; and electronics configured to control the laser beam source to emit laser radiation toward the skin to provide a dermatological treatment; wherein the device includes no optics downstream of the laser source.

Abstract: A device for providing radiation-based dermatological treatments includes a device body configured to be handheld by a user; a VCSEL laser supported in the device body, the VCSEL laser including multiple spaced-apart VCSEL beam sources configured to generate multiple discrete laser beams for generating multiple discrete treatment spots on the skin; an application end configured to be manually moved across the surface of the skin during a treatment session; and electronics configured to control the multiple VCSEL beam sources to emit the multiple discrete laser beams toward the skin to provide a dermatological treatment.

Abstract: A self-contained, hand-held device for providing fractional treatment to the skin includes a device body configured to be handheld by a user; a radiation source supported in the device body, the radiation source including a single beam source configured to emit a single energy beam; an application end configured to be manually moved across the skin during a treatment session; and electronics configured to pulse the single beam source to emit a sequence of pulsed energy beams to the skin while the application end is manually moved across the skin, thereby generating an array of treatment spots on the skin, wherein adjacent treatment spots generated on the skin are spaced apart from each other by areas of non-treated skin between the adjacent treatment spots, thereby providing a fractional treatment. Each pulsed energy beam emitted by the beam source has the same, fixed propagation path with respect to the device body.

Abstract: A self-contained, hand-held device for providing radiation-based dermatological treatments includes a device body configured to be handheld by a user; a laser supported in the device body, the laser including a laser beam source configured to emit a laser beam; an application end configured to be manually moved across the skin during a treatment session; and electronics configured to control the laser beam source to deliver the laser beam to the skin at a delivered radiation intensity at the skin sufficient to provide an effective dermatological treatment.

Abstract: A phototherapy device includes a light source; a light emanation block; and a heat exchanger for the dissipation of heat from one or more heat loads associated with the device. Heat may be transferred via the heat exchanger from the light source independently of the dissipation of heat from one or more of the other device heat loads. Substantially thermally isolated heat transfer regions may be provided, and such regions may be maintained at different operating temperatures, to control the transfer of heat in conjunction with a phototherapy method and to promote efficient and enhanced device operation and performance.

Abstract: A bright light-source includes four diode-laser bars stacked on another in the fast-axis direction. Each of the diode-laser bars has a substrate side and an expitaxial side. In one example of the light-source, the diode-laser bars are soldered together with the epitaxial side of one soldered to the substrate side of another such that the bars are and connected electrically in series.

Abstract: A Faraday filter rejects background light from self-luminous thermal objects, but transmits laser light at the passband wavelength, thus providing an ultra-narrow optical bandpass filter. The filter preserves images so a camera looking through a Faraday filter at a hot target illuminated by a laser will not see the thermal radiation but will see the laser radiation. Faraday filters are useful for monitoring or inspecting the uranium separator chamber in an atomic vapor laser isotope separation process. Other uses include viewing welds, furnaces, plasma jets, combustion chambers, and other high temperature objects. These filters are can be produced at many discrete wavelengths. A Faraday filter consists of a pair of crossed polarizers on either side of a heated vapor cell mounted inside a solenoid.

Abstract: The present invention provides a diffraction limited, high numerical aperture (fast) cylindrical microlens. The method for making the microlens is adaptable to produce a cylindrical lens that has almost any shape on its optical surfaces. The cylindrical lens may have a shape, such as elliptical or hyperbolic, designed to transform some particular given input light distribution into some desired output light distribution. In the method, the desired shape is first formed in a glass preform. Then, the preform is heated to the minimum drawing temperature and a fiber is drawn from it. The cross-sectional shape of the fiber bears a direct relation to the shape of the preform from which it was drawn. During the drawing process, the surfaces become optically smooth due to fire polishing.