Abstract: A scanning beam assembly includes a beam generator to generate a beam of radiation; at least one reflector configured to deflect the beam across a field of view; and a plurality of multi-mode optical fibers for receiving radiation reflected from the field of view, wherein the optical fibers have end surfaces that face in at least two different directions, or wherein the optical fibers are configured to receive scattered radiation from an angular field of view larger than that determined by their individual numerical apertures.

Abstract: A method for repairing or modifying an area of a patient's anatomy that comprises directing at least a portion of a scanning beam assembly to an area of a patient's anatomy, applying a radiation-responsive agent to portion of the anatomy, and exposing the radiation-responsive agent to radiation directed onto the agent by the reflector to cause the agent to therapeutically interact with the site. The scanning beam assembly including a radiation source capable of emitting radiation, a reflector that receives the radiation from the radiation source to direct the radiation onto the anatomy, wherein the reflector oscillates in at least two directions to create a scan of the anatomy, a detector to detect radiation returned from the anatomy, and a controller to convert the detected radiation into a displayable anatomy image.

Abstract: A first expression of a first apparatus includes a medical scanned beam imager including an optical dome and a scanner, wherein the optical dome has a variable optical power distribution. A first expression of a second apparatus includes a sleeve assembly which is attachable to a medical scanned beam imager and which includes an objective element which covers an optical dome of the imager when the sleeve assembly is attached to the imager. A second expression of a second apparatus includes a sleeve assembly and a medical scanned beam imager wherein the sleeve assembly is attached to the imager and an objective element of the sleeve assembly covers an optical dome of the imager. A first expression of a third apparatus includes an objective element and a medical scanned beam imager having an optical dome wherein the objective element covers the optical dome and is attached to the imager.

Abstract: A system for examining an area of a patient's anatomy that comprises a probe capable of fluorescing, and a scanning beam assembly that scans the probe with a beam of excitation radiation and detects the probe's fluorescence. The scanning beam assembly including a radiation source capable of emitting one or more wavelengths of radiation that are capable of exciting the probe and causing the probe to fluoresce, a scanning device that directs the radiation onto a field-of-view to create a scan of the field-of-view, a detector to detect radiation returned from the field-of-view, and a controller to convert the detected radiation into a displayable fluorescence image.

Abstract: An apparatus, for medically treating a patient, includes a scanned beam system including a radiation beam source assembly, a scanner, and a controller. The assembly is adapted to emit a radiation beam (such as, without limitation, a laser beam) at different wavelengths. The controller is operatively connected to the assembly and the scanner. The controller is adapted: to display an image of an area of the patient obtained by the scanned beam system; to receive from a user viewing the image an identification of an in-treatment region; and to control the assembly and the scanner to medically treat the in-treatment region using a therapeutic wavelength of the radiation beam which provides an increased scanned-beam-system-image contrast between the in-treatment region and an out-of-treatment region over another wavelength of the radiation beam available for therapy. A method for medically treating a patient using a scanned beam system is also disclosed.

Abstract: A medical device includes a radiation source assembly having at least two radiation sources, where one or more of the radiation sources is adapted to generate an imaging beam for use in visualization of a scene and one or more of the radiation sources is adapted to generate a therapeutic beam for treatment of a medical condition. An optical fiber for directing radiation energy from the radiation source assembly toward a distal end of the medical device in the form of a beam. A reflector that receives the beam from the optical fiber, the reflector configured to direct the beam onto a field-of-view. A receiving system including a detector arranged and configured to receive radiation from the field-of-view to generate a viewable image. The imaging beam and the therapeutic beam are directed to follow a common path from the at least two radiation sources to the reflector.

Abstract: An assembly comprising a radiation source to generate a beam of radiation, a modulator for modulating the power of the beam of radiation as a function of the position of the beam within a field-of-view to maintain the beam's power within a desired exposure level as the beam scans the field-of-view, and a reflector oscillating in a sinusoidal manner to direct the beam of radiation onto a field-of-view.

Abstract: A drive circuit includes a generator and a driver. The generator generates a signal having a period and a varying amplitude during a driving portion of the period, and the driver is coupled to the generator and drives a plate of an electrostatically drivable plant with the signal. The drive circuit may be used to drive a mirror plate of a comb-drive MEMS mirror.

Abstract: A scanning beam assembly for use in medical applications comprising a plurality of radiation emitters that emit radiation over different wavelength ranges, wherein at least one of the emitters emits radiation that is minimally absorbed by blood; a scanner including a reflector that receives radiation from the emitters and directs it onto a field-of-view; and at least one detector configured to receive the radiation scattered, reflected or transmitted by the field-of-view and generate an electrical signal.

Abstract: A scanning beam assembly comprising: a beam generator to generate a beam of radiation, and two or more oscillating reflectors configured to deflect the beam in sequence, each reflector being driven to contribute an incremental deflection of the beam so as to achieve a desired scanning beam waveform, at least one oscillating reflector aligned to receive the beam from the beam generator and deflect the beam to a second oscillating reflector, each oscillating reflector operating in a sinusoidal mode having a frequency and amplitude, and a controller for controlling the phase and/or frequency and/or amplitude of the oscillation of the reflectors so as to provide a desired scanning beam waveform.

Abstract: A micro-electromechanical device includes a frame, a moveable member movably connected to the frame such that the moveable member is capable of movement relative to the frame and drive system for use in moving the moveable member relative to the frame. A braking system is provided that inhibits movement of the moveable member relative to the frame.

Abstract: Apparatuses and methods for scanned beam imagers and scanned beam endoscopes that utilize multiple light collectors are disclosed. In one aspect, a scanned beam imager is disclosed. The scanned beam imager includes a scanned beam source operable to scan a beam onto a region of interest of an object. The scanned beam imager further includes a first light collector structured to collect light reflected from the region of interest and a second light collector positionable relative to the scanning tip. The second light collector structured to collect light transmitted through the region of interest.

Abstract: Devices and methods are provided for identifying tissue cells, such as cancerous cells. The device can include a swallowable capsule having a detector. A patient can be given a substance which includes a marker material (such as a radioactive marker or a magnetic marker material), and which substance can be preferentially bound to or otherwise associated with the particular cell type.

Abstract: A system for testing the integrity of critical circuitry, lines and wires employs a differential amplifier having an input resistance R.sub.in and a feedback loop with a resistance R.sub.fb. The critical wires being tested must be a signal wire series connected to a resistance R.sub.S, which is in turn series connected to a return wire. A test voltage source is connected to the noninverting input of the differential amplifier. The signal wire is connected to the inverting input of the differential amplifier. The test voltage source is activated by a test control unit. When activated, the test voltage source provides two distinct outputs allowing computation of a test gain in the presence of other functional signals. The test control unit measures the output V.sub.out of the differential amplifier and computes the value of the test gain. A break in either the signal wire or the return wire will result in a test gain of 1. If the signal and return wires are shorted, the test gain will be 1+R.sub.fb /R.sub.in.

Abstract: A system for testing the integrity of critical circuitry, lines and wires employs a differential amplifier having an input resistance R.sub.in and a feedback loop with a resistance R.sub.fb. The critical wires being tested must be a signal wire series connected to a resistance R.sub.s, which is in turn series connected to a return wire. A test voltage source is connected to the noninverting input of the differential amplifier. The signal wire is connected to the inverting input of the differential amplifier. The test voltage source is activated by a test control unit. When activated, the test voltage source provides two distinct outputs allowing computation of a test gain in the presence of other functional signals. The test control unit measures the output V.sub.out of the differential amplifier and computes the value of the test gain. A break in either the signal wire or the return wire will result in a test gain of 1. If the signal and return wires are shorted, the test gain will be 1+R.sub.fb /R.sub.in.

Abstract: A general absolute value circuit for developing a true, symmetric or bipolar, absolute value output signal from an input charge signal, compact enough to be used on a sensor chip incorporated into (or used in combination with) a pixel processor of the type used in imaging and other systems that collect electromagnetic radiation as part of on-chip circuitry, includes a balanced differential amplifier combined with a merged dual shelf transistor structure. The balanced differential amplifier, in response to an input charge signal, drives the merged dual shelf transistor structure which in turn generates the desired true absolute value output signal. Such circuitry may be used in imaging systems to implement focal-plane processing algorithms or may be used for performing a single read true absolute value computation by a pixel processor located on a sensor chip. The merged dual shelf transistor structure enhances performance and speed of the processor in which it is incorporated.